diff --git a/sys/amd64/amd64/pmap.c b/sys/amd64/amd64/pmap.c index c7151fa59b91..b10997fd657b 100644 --- a/sys/amd64/amd64/pmap.c +++ b/sys/amd64/amd64/pmap.c @@ -1,12266 +1,12272 @@ /*- * SPDX-License-Identifier: BSD-4-Clause * * Copyright (c) 1991 Regents of the University of California. * All rights reserved. * Copyright (c) 1994 John S. Dyson * All rights reserved. * Copyright (c) 1994 David Greenman * All rights reserved. * Copyright (c) 2003 Peter Wemm * All rights reserved. * Copyright (c) 2005-2010 Alan L. Cox * All rights reserved. * * This code is derived from software contributed to Berkeley by * the Systems Programming Group of the University of Utah Computer * Science Department and William Jolitz of UUNET Technologies Inc. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * from: @(#)pmap.c 7.7 (Berkeley) 5/12/91 */ /*- * Copyright (c) 2003 Networks Associates Technology, Inc. * Copyright (c) 2014-2020 The FreeBSD Foundation * All rights reserved. * * This software was developed for the FreeBSD Project by Jake Burkholder, * Safeport Network Services, and Network Associates Laboratories, the * Security Research Division of Network Associates, Inc. under * DARPA/SPAWAR contract N66001-01-C-8035 ("CBOSS"), as part of the DARPA * CHATS research program. * * Portions of this software were developed by * Konstantin Belousov under sponsorship from * the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #define AMD64_NPT_AWARE #include /* * Manages physical address maps. * * Since the information managed by this module is * also stored by the logical address mapping module, * this module may throw away valid virtual-to-physical * mappings at almost any time. However, invalidations * of virtual-to-physical mappings must be done as * requested. * * In order to cope with hardware architectures which * make virtual-to-physical map invalidates expensive, * this module may delay invalidate or reduced protection * operations until such time as they are actually * necessary. This module is given full information as * to which processors are currently using which maps, * and to when physical maps must be made correct. */ #include "opt_ddb.h" #include "opt_pmap.h" #include "opt_vm.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef DDB #include #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef SMP #include #endif #include #include #ifdef NUMA #define PMAP_MEMDOM MAXMEMDOM #else #define PMAP_MEMDOM 1 #endif static __inline boolean_t pmap_type_guest(pmap_t pmap) { return ((pmap->pm_type == PT_EPT) || (pmap->pm_type == PT_RVI)); } static __inline boolean_t pmap_emulate_ad_bits(pmap_t pmap) { return ((pmap->pm_flags & PMAP_EMULATE_AD_BITS) != 0); } static __inline pt_entry_t pmap_valid_bit(pmap_t pmap) { pt_entry_t mask; switch (pmap->pm_type) { case PT_X86: case PT_RVI: mask = X86_PG_V; break; case PT_EPT: if (pmap_emulate_ad_bits(pmap)) mask = EPT_PG_EMUL_V; else mask = EPT_PG_READ; break; default: panic("pmap_valid_bit: invalid pm_type %d", pmap->pm_type); } return (mask); } static __inline pt_entry_t pmap_rw_bit(pmap_t pmap) { pt_entry_t mask; switch (pmap->pm_type) { case PT_X86: case PT_RVI: mask = X86_PG_RW; break; case PT_EPT: if (pmap_emulate_ad_bits(pmap)) mask = EPT_PG_EMUL_RW; else mask = EPT_PG_WRITE; break; default: panic("pmap_rw_bit: invalid pm_type %d", pmap->pm_type); } return (mask); } static pt_entry_t pg_g; static __inline pt_entry_t pmap_global_bit(pmap_t pmap) { pt_entry_t mask; switch (pmap->pm_type) { case PT_X86: mask = pg_g; break; case PT_RVI: case PT_EPT: mask = 0; break; default: panic("pmap_global_bit: invalid pm_type %d", pmap->pm_type); } return (mask); } static __inline pt_entry_t pmap_accessed_bit(pmap_t pmap) { pt_entry_t mask; switch (pmap->pm_type) { case PT_X86: case PT_RVI: mask = X86_PG_A; break; case PT_EPT: if (pmap_emulate_ad_bits(pmap)) mask = EPT_PG_READ; else mask = EPT_PG_A; break; default: panic("pmap_accessed_bit: invalid pm_type %d", pmap->pm_type); } return (mask); } static __inline pt_entry_t pmap_modified_bit(pmap_t pmap) { pt_entry_t mask; switch (pmap->pm_type) { case PT_X86: case PT_RVI: mask = X86_PG_M; break; case PT_EPT: if (pmap_emulate_ad_bits(pmap)) mask = EPT_PG_WRITE; else mask = EPT_PG_M; break; default: panic("pmap_modified_bit: invalid pm_type %d", pmap->pm_type); } return (mask); } static __inline pt_entry_t pmap_pku_mask_bit(pmap_t pmap) { return (pmap->pm_type == PT_X86 ? X86_PG_PKU_MASK : 0); } static __inline boolean_t safe_to_clear_referenced(pmap_t pmap, pt_entry_t pte) { if (!pmap_emulate_ad_bits(pmap)) return (TRUE); KASSERT(pmap->pm_type == PT_EPT, ("invalid pm_type %d", pmap->pm_type)); /* * XWR = 010 or 110 will cause an unconditional EPT misconfiguration * so we don't let the referenced (aka EPT_PG_READ) bit to be cleared * if the EPT_PG_WRITE bit is set. */ if ((pte & EPT_PG_WRITE) != 0) return (FALSE); /* * XWR = 100 is allowed only if the PMAP_SUPPORTS_EXEC_ONLY is set. */ if ((pte & EPT_PG_EXECUTE) == 0 || ((pmap->pm_flags & PMAP_SUPPORTS_EXEC_ONLY) != 0)) return (TRUE); else return (FALSE); } #if !defined(DIAGNOSTIC) #ifdef __GNUC_GNU_INLINE__ #define PMAP_INLINE __attribute__((__gnu_inline__)) inline #else #define PMAP_INLINE extern inline #endif #else #define PMAP_INLINE #endif #ifdef PV_STATS #define PV_STAT(x) do { x ; } while (0) #else #define PV_STAT(x) do { } while (0) #endif #undef pa_index #ifdef NUMA #define pa_index(pa) ({ \ KASSERT((pa) <= vm_phys_segs[vm_phys_nsegs - 1].end, \ ("address %lx beyond the last segment", (pa))); \ (pa) >> PDRSHIFT; \ }) #define pa_to_pmdp(pa) (&pv_table[pa_index(pa)]) #define pa_to_pvh(pa) (&(pa_to_pmdp(pa)->pv_page)) #define PHYS_TO_PV_LIST_LOCK(pa) ({ \ struct rwlock *_lock; \ if (__predict_false((pa) > pmap_last_pa)) \ _lock = &pv_dummy_large.pv_lock; \ else \ _lock = &(pa_to_pmdp(pa)->pv_lock); \ _lock; \ }) #else #define pa_index(pa) ((pa) >> PDRSHIFT) #define pa_to_pvh(pa) (&pv_table[pa_index(pa)]) #define NPV_LIST_LOCKS MAXCPU #define PHYS_TO_PV_LIST_LOCK(pa) \ (&pv_list_locks[pa_index(pa) % NPV_LIST_LOCKS]) #endif #define CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, pa) do { \ struct rwlock **_lockp = (lockp); \ struct rwlock *_new_lock; \ \ _new_lock = PHYS_TO_PV_LIST_LOCK(pa); \ if (_new_lock != *_lockp) { \ if (*_lockp != NULL) \ rw_wunlock(*_lockp); \ *_lockp = _new_lock; \ rw_wlock(*_lockp); \ } \ } while (0) #define CHANGE_PV_LIST_LOCK_TO_VM_PAGE(lockp, m) \ CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, VM_PAGE_TO_PHYS(m)) #define RELEASE_PV_LIST_LOCK(lockp) do { \ struct rwlock **_lockp = (lockp); \ \ if (*_lockp != NULL) { \ rw_wunlock(*_lockp); \ *_lockp = NULL; \ } \ } while (0) #define VM_PAGE_TO_PV_LIST_LOCK(m) \ PHYS_TO_PV_LIST_LOCK(VM_PAGE_TO_PHYS(m)) /* * Statically allocate kernel pmap memory. However, memory for * pm_pcids is obtained after the dynamic allocator is operational. * Initialize it with a non-canonical pointer to catch early accesses * regardless of the active mapping. */ struct pmap kernel_pmap_store = { .pm_pcidp = (void *)0xdeadbeefdeadbeef, }; vm_offset_t virtual_avail; /* VA of first avail page (after kernel bss) */ vm_offset_t virtual_end; /* VA of last avail page (end of kernel AS) */ int nkpt; SYSCTL_INT(_machdep, OID_AUTO, nkpt, CTLFLAG_RD, &nkpt, 0, "Number of kernel page table pages allocated on bootup"); static int ndmpdp; vm_paddr_t dmaplimit; vm_offset_t kernel_vm_end = VM_MIN_KERNEL_ADDRESS; pt_entry_t pg_nx; static SYSCTL_NODE(_vm, OID_AUTO, pmap, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "VM/pmap parameters"); static int __read_frequently pg_ps_enabled = 1; SYSCTL_INT(_vm_pmap, OID_AUTO, pg_ps_enabled, CTLFLAG_RDTUN | CTLFLAG_NOFETCH, &pg_ps_enabled, 0, "Are large page mappings enabled?"); int __read_frequently la57 = 0; SYSCTL_INT(_vm_pmap, OID_AUTO, la57, CTLFLAG_RDTUN | CTLFLAG_NOFETCH, &la57, 0, "5-level paging for host is enabled"); static bool pmap_is_la57(pmap_t pmap) { if (pmap->pm_type == PT_X86) return (la57); return (false); /* XXXKIB handle EPT */ } #define PAT_INDEX_SIZE 8 static int pat_index[PAT_INDEX_SIZE]; /* cache mode to PAT index conversion */ static u_int64_t KPTphys; /* phys addr of kernel level 1 */ static u_int64_t KPDphys; /* phys addr of kernel level 2 */ static u_int64_t KPDPphys; /* phys addr of kernel level 3 */ u_int64_t KPML4phys; /* phys addr of kernel level 4 */ u_int64_t KPML5phys; /* phys addr of kernel level 5, if supported */ #ifdef KASAN static uint64_t KASANPDPphys; #endif #ifdef KMSAN static uint64_t KMSANSHADPDPphys; static uint64_t KMSANORIGPDPphys; /* * To support systems with large amounts of memory, it is necessary to extend * the maximum size of the direct map. This could eat into the space reserved * for the shadow map. */ _Static_assert(DMPML4I + NDMPML4E <= KMSANSHADPML4I, "direct map overflow"); #endif static pml4_entry_t *kernel_pml4; static u_int64_t DMPDphys; /* phys addr of direct mapped level 2 */ static u_int64_t DMPDPphys; /* phys addr of direct mapped level 3 */ static int ndmpdpphys; /* number of DMPDPphys pages */ vm_paddr_t kernphys; /* phys addr of start of bootstrap data */ vm_paddr_t KERNend; /* and the end */ /* * pmap_mapdev support pre initialization (i.e. console) */ #define PMAP_PREINIT_MAPPING_COUNT 8 static struct pmap_preinit_mapping { vm_paddr_t pa; vm_offset_t va; vm_size_t sz; int mode; } pmap_preinit_mapping[PMAP_PREINIT_MAPPING_COUNT]; static int pmap_initialized; /* * Data for the pv entry allocation mechanism. * Updates to pv_invl_gen are protected by the pv list lock but reads are not. */ #ifdef NUMA static __inline int pc_to_domain(struct pv_chunk *pc) { return (vm_phys_domain(DMAP_TO_PHYS((vm_offset_t)pc))); } #else static __inline int pc_to_domain(struct pv_chunk *pc __unused) { return (0); } #endif struct pv_chunks_list { struct mtx pvc_lock; TAILQ_HEAD(pch, pv_chunk) pvc_list; int active_reclaims; } __aligned(CACHE_LINE_SIZE); struct pv_chunks_list __exclusive_cache_line pv_chunks[PMAP_MEMDOM]; #ifdef NUMA struct pmap_large_md_page { struct rwlock pv_lock; struct md_page pv_page; u_long pv_invl_gen; }; __exclusive_cache_line static struct pmap_large_md_page pv_dummy_large; #define pv_dummy pv_dummy_large.pv_page __read_mostly static struct pmap_large_md_page *pv_table; __read_mostly vm_paddr_t pmap_last_pa; #else static struct rwlock __exclusive_cache_line pv_list_locks[NPV_LIST_LOCKS]; static u_long pv_invl_gen[NPV_LIST_LOCKS]; static struct md_page *pv_table; static struct md_page pv_dummy; #endif /* * All those kernel PT submaps that BSD is so fond of */ pt_entry_t *CMAP1 = NULL; caddr_t CADDR1 = 0; static vm_offset_t qframe = 0; static struct mtx qframe_mtx; static int pmap_flags = PMAP_PDE_SUPERPAGE; /* flags for x86 pmaps */ static vmem_t *large_vmem; static u_int lm_ents; #define PMAP_ADDRESS_IN_LARGEMAP(va) ((va) >= LARGEMAP_MIN_ADDRESS && \ (va) < LARGEMAP_MIN_ADDRESS + NBPML4 * (u_long)lm_ents) int pmap_pcid_enabled = 1; SYSCTL_INT(_vm_pmap, OID_AUTO, pcid_enabled, CTLFLAG_RDTUN | CTLFLAG_NOFETCH, &pmap_pcid_enabled, 0, "Is TLB Context ID enabled ?"); int invpcid_works = 0; SYSCTL_INT(_vm_pmap, OID_AUTO, invpcid_works, CTLFLAG_RD, &invpcid_works, 0, "Is the invpcid instruction available ?"); int pmap_pcid_invlpg_workaround = 0; SYSCTL_INT(_vm_pmap, OID_AUTO, pcid_invlpg_workaround, CTLFLAG_RDTUN | CTLFLAG_NOFETCH, &pmap_pcid_invlpg_workaround, 0, "Enable small core PCID/INVLPG workaround"); int pmap_pcid_invlpg_workaround_uena = 1; int __read_frequently pti = 0; SYSCTL_INT(_vm_pmap, OID_AUTO, pti, CTLFLAG_RDTUN | CTLFLAG_NOFETCH, &pti, 0, "Page Table Isolation enabled"); static vm_object_t pti_obj; static pml4_entry_t *pti_pml4; static vm_pindex_t pti_pg_idx; static bool pti_finalized; struct pmap_pkru_range { struct rs_el pkru_rs_el; u_int pkru_keyidx; int pkru_flags; }; static uma_zone_t pmap_pkru_ranges_zone; static bool pmap_pkru_same(pmap_t pmap, vm_offset_t sva, vm_offset_t eva); static pt_entry_t pmap_pkru_get(pmap_t pmap, vm_offset_t va); static void pmap_pkru_on_remove(pmap_t pmap, vm_offset_t sva, vm_offset_t eva); static void *pkru_dup_range(void *ctx, void *data); static void pkru_free_range(void *ctx, void *node); static int pmap_pkru_copy(pmap_t dst_pmap, pmap_t src_pmap); static int pmap_pkru_deassign(pmap_t pmap, vm_offset_t sva, vm_offset_t eva); static void pmap_pkru_deassign_all(pmap_t pmap); static COUNTER_U64_DEFINE_EARLY(pcid_save_cnt); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, pcid_save_cnt, CTLFLAG_RD, &pcid_save_cnt, "Count of saved TLB context on switch"); static LIST_HEAD(, pmap_invl_gen) pmap_invl_gen_tracker = LIST_HEAD_INITIALIZER(&pmap_invl_gen_tracker); static struct mtx invl_gen_mtx; /* Fake lock object to satisfy turnstiles interface. */ static struct lock_object invl_gen_ts = { .lo_name = "invlts", }; static struct pmap_invl_gen pmap_invl_gen_head = { .gen = 1, .next = NULL, }; static u_long pmap_invl_gen = 1; static int pmap_invl_waiters; static struct callout pmap_invl_callout; static bool pmap_invl_callout_inited; #define PMAP_ASSERT_NOT_IN_DI() \ KASSERT(pmap_not_in_di(), ("DI already started")) static bool pmap_di_locked(void) { int tun; if ((cpu_feature2 & CPUID2_CX16) == 0) return (true); tun = 0; TUNABLE_INT_FETCH("vm.pmap.di_locked", &tun); return (tun != 0); } static int sysctl_pmap_di_locked(SYSCTL_HANDLER_ARGS) { int locked; locked = pmap_di_locked(); return (sysctl_handle_int(oidp, &locked, 0, req)); } SYSCTL_PROC(_vm_pmap, OID_AUTO, di_locked, CTLTYPE_INT | CTLFLAG_RDTUN | CTLFLAG_MPSAFE, 0, 0, sysctl_pmap_di_locked, "", "Locked delayed invalidation"); static bool pmap_not_in_di_l(void); static bool pmap_not_in_di_u(void); DEFINE_IFUNC(, bool, pmap_not_in_di, (void)) { return (pmap_di_locked() ? pmap_not_in_di_l : pmap_not_in_di_u); } static bool pmap_not_in_di_l(void) { struct pmap_invl_gen *invl_gen; invl_gen = &curthread->td_md.md_invl_gen; return (invl_gen->gen == 0); } static void pmap_thread_init_invl_gen_l(struct thread *td) { struct pmap_invl_gen *invl_gen; invl_gen = &td->td_md.md_invl_gen; invl_gen->gen = 0; } static void pmap_delayed_invl_wait_block(u_long *m_gen, u_long *invl_gen) { struct turnstile *ts; ts = turnstile_trywait(&invl_gen_ts); if (*m_gen > atomic_load_long(invl_gen)) turnstile_wait(ts, NULL, TS_SHARED_QUEUE); else turnstile_cancel(ts); } static void pmap_delayed_invl_finish_unblock(u_long new_gen) { struct turnstile *ts; turnstile_chain_lock(&invl_gen_ts); ts = turnstile_lookup(&invl_gen_ts); if (new_gen != 0) pmap_invl_gen = new_gen; if (ts != NULL) { turnstile_broadcast(ts, TS_SHARED_QUEUE); turnstile_unpend(ts); } turnstile_chain_unlock(&invl_gen_ts); } /* * Start a new Delayed Invalidation (DI) block of code, executed by * the current thread. Within a DI block, the current thread may * destroy both the page table and PV list entries for a mapping and * then release the corresponding PV list lock before ensuring that * the mapping is flushed from the TLBs of any processors with the * pmap active. */ static void pmap_delayed_invl_start_l(void) { struct pmap_invl_gen *invl_gen; u_long currgen; invl_gen = &curthread->td_md.md_invl_gen; PMAP_ASSERT_NOT_IN_DI(); mtx_lock(&invl_gen_mtx); if (LIST_EMPTY(&pmap_invl_gen_tracker)) currgen = pmap_invl_gen; else currgen = LIST_FIRST(&pmap_invl_gen_tracker)->gen; invl_gen->gen = currgen + 1; LIST_INSERT_HEAD(&pmap_invl_gen_tracker, invl_gen, link); mtx_unlock(&invl_gen_mtx); } /* * Finish the DI block, previously started by the current thread. All * required TLB flushes for the pages marked by * pmap_delayed_invl_page() must be finished before this function is * called. * * This function works by bumping the global DI generation number to * the generation number of the current thread's DI, unless there is a * pending DI that started earlier. In the latter case, bumping the * global DI generation number would incorrectly signal that the * earlier DI had finished. Instead, this function bumps the earlier * DI's generation number to match the generation number of the * current thread's DI. */ static void pmap_delayed_invl_finish_l(void) { struct pmap_invl_gen *invl_gen, *next; invl_gen = &curthread->td_md.md_invl_gen; KASSERT(invl_gen->gen != 0, ("missed invl_start")); mtx_lock(&invl_gen_mtx); next = LIST_NEXT(invl_gen, link); if (next == NULL) pmap_delayed_invl_finish_unblock(invl_gen->gen); else next->gen = invl_gen->gen; LIST_REMOVE(invl_gen, link); mtx_unlock(&invl_gen_mtx); invl_gen->gen = 0; } static bool pmap_not_in_di_u(void) { struct pmap_invl_gen *invl_gen; invl_gen = &curthread->td_md.md_invl_gen; return (((uintptr_t)invl_gen->next & PMAP_INVL_GEN_NEXT_INVALID) != 0); } static void pmap_thread_init_invl_gen_u(struct thread *td) { struct pmap_invl_gen *invl_gen; invl_gen = &td->td_md.md_invl_gen; invl_gen->gen = 0; invl_gen->next = (void *)PMAP_INVL_GEN_NEXT_INVALID; } static bool pmap_di_load_invl(struct pmap_invl_gen *ptr, struct pmap_invl_gen *out) { uint64_t new_high, new_low, old_high, old_low; char res; old_low = new_low = 0; old_high = new_high = (uintptr_t)0; __asm volatile("lock;cmpxchg16b\t%1" : "=@cce" (res), "+m" (*ptr), "+a" (old_low), "+d" (old_high) : "b"(new_low), "c" (new_high) : "memory", "cc"); if (res == 0) { if ((old_high & PMAP_INVL_GEN_NEXT_INVALID) != 0) return (false); out->gen = old_low; out->next = (void *)old_high; } else { out->gen = new_low; out->next = (void *)new_high; } return (true); } static bool pmap_di_store_invl(struct pmap_invl_gen *ptr, struct pmap_invl_gen *old_val, struct pmap_invl_gen *new_val) { uint64_t new_high, new_low, old_high, old_low; char res; new_low = new_val->gen; new_high = (uintptr_t)new_val->next; old_low = old_val->gen; old_high = (uintptr_t)old_val->next; __asm volatile("lock;cmpxchg16b\t%1" : "=@cce" (res), "+m" (*ptr), "+a" (old_low), "+d" (old_high) : "b"(new_low), "c" (new_high) : "memory", "cc"); return (res); } static COUNTER_U64_DEFINE_EARLY(pv_page_count); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, pv_page_count, CTLFLAG_RD, &pv_page_count, "Current number of allocated pv pages"); static COUNTER_U64_DEFINE_EARLY(user_pt_page_count); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, user_pt_page_count, CTLFLAG_RD, &user_pt_page_count, "Current number of allocated page table pages for userspace"); static COUNTER_U64_DEFINE_EARLY(kernel_pt_page_count); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, kernel_pt_page_count, CTLFLAG_RD, &kernel_pt_page_count, "Current number of allocated page table pages for the kernel"); #ifdef PV_STATS static COUNTER_U64_DEFINE_EARLY(invl_start_restart); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, invl_start_restart, CTLFLAG_RD, &invl_start_restart, "Number of delayed TLB invalidation request restarts"); static COUNTER_U64_DEFINE_EARLY(invl_finish_restart); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, invl_finish_restart, CTLFLAG_RD, &invl_finish_restart, "Number of delayed TLB invalidation completion restarts"); static int invl_max_qlen; SYSCTL_INT(_vm_pmap, OID_AUTO, invl_max_qlen, CTLFLAG_RD, &invl_max_qlen, 0, "Maximum delayed TLB invalidation request queue length"); #endif #define di_delay locks_delay static void pmap_delayed_invl_start_u(void) { struct pmap_invl_gen *invl_gen, *p, prev, new_prev; struct thread *td; struct lock_delay_arg lda; uintptr_t prevl; u_char pri; #ifdef PV_STATS int i, ii; #endif td = curthread; invl_gen = &td->td_md.md_invl_gen; PMAP_ASSERT_NOT_IN_DI(); lock_delay_arg_init(&lda, &di_delay); invl_gen->saved_pri = 0; pri = td->td_base_pri; if (pri > PVM) { thread_lock(td); pri = td->td_base_pri; if (pri > PVM) { invl_gen->saved_pri = pri; sched_prio(td, PVM); } thread_unlock(td); } again: PV_STAT(i = 0); for (p = &pmap_invl_gen_head;; p = prev.next) { PV_STAT(i++); prevl = (uintptr_t)atomic_load_ptr(&p->next); if ((prevl & PMAP_INVL_GEN_NEXT_INVALID) != 0) { PV_STAT(counter_u64_add(invl_start_restart, 1)); lock_delay(&lda); goto again; } if (prevl == 0) break; prev.next = (void *)prevl; } #ifdef PV_STATS if ((ii = invl_max_qlen) < i) atomic_cmpset_int(&invl_max_qlen, ii, i); #endif if (!pmap_di_load_invl(p, &prev) || prev.next != NULL) { PV_STAT(counter_u64_add(invl_start_restart, 1)); lock_delay(&lda); goto again; } new_prev.gen = prev.gen; new_prev.next = invl_gen; invl_gen->gen = prev.gen + 1; /* Formal fence between store to invl->gen and updating *p. */ atomic_thread_fence_rel(); /* * After inserting an invl_gen element with invalid bit set, * this thread blocks any other thread trying to enter the * delayed invalidation block. Do not allow to remove us from * the CPU, because it causes starvation for other threads. */ critical_enter(); /* * ABA for *p is not possible there, since p->gen can only * increase. So if the *p thread finished its di, then * started a new one and got inserted into the list at the * same place, its gen will appear greater than the previously * read gen. */ if (!pmap_di_store_invl(p, &prev, &new_prev)) { critical_exit(); PV_STAT(counter_u64_add(invl_start_restart, 1)); lock_delay(&lda); goto again; } /* * There we clear PMAP_INVL_GEN_NEXT_INVALID in * invl_gen->next, allowing other threads to iterate past us. * pmap_di_store_invl() provides fence between the generation * write and the update of next. */ invl_gen->next = NULL; critical_exit(); } static bool pmap_delayed_invl_finish_u_crit(struct pmap_invl_gen *invl_gen, struct pmap_invl_gen *p) { struct pmap_invl_gen prev, new_prev; u_long mygen; /* * Load invl_gen->gen after setting invl_gen->next * PMAP_INVL_GEN_NEXT_INVALID. This prevents larger * generations to propagate to our invl_gen->gen. Lock prefix * in atomic_set_ptr() worked as seq_cst fence. */ mygen = atomic_load_long(&invl_gen->gen); if (!pmap_di_load_invl(p, &prev) || prev.next != invl_gen) return (false); KASSERT(prev.gen < mygen, ("invalid di gen sequence %lu %lu", prev.gen, mygen)); new_prev.gen = mygen; new_prev.next = (void *)((uintptr_t)invl_gen->next & ~PMAP_INVL_GEN_NEXT_INVALID); /* Formal fence between load of prev and storing update to it. */ atomic_thread_fence_rel(); return (pmap_di_store_invl(p, &prev, &new_prev)); } static void pmap_delayed_invl_finish_u(void) { struct pmap_invl_gen *invl_gen, *p; struct thread *td; struct lock_delay_arg lda; uintptr_t prevl; td = curthread; invl_gen = &td->td_md.md_invl_gen; KASSERT(invl_gen->gen != 0, ("missed invl_start: gen 0")); KASSERT(((uintptr_t)invl_gen->next & PMAP_INVL_GEN_NEXT_INVALID) == 0, ("missed invl_start: INVALID")); lock_delay_arg_init(&lda, &di_delay); again: for (p = &pmap_invl_gen_head; p != NULL; p = (void *)prevl) { prevl = (uintptr_t)atomic_load_ptr(&p->next); if ((prevl & PMAP_INVL_GEN_NEXT_INVALID) != 0) { PV_STAT(counter_u64_add(invl_finish_restart, 1)); lock_delay(&lda); goto again; } if ((void *)prevl == invl_gen) break; } /* * It is legitimate to not find ourself on the list if a * thread before us finished its DI and started it again. */ if (__predict_false(p == NULL)) { PV_STAT(counter_u64_add(invl_finish_restart, 1)); lock_delay(&lda); goto again; } critical_enter(); atomic_set_ptr((uintptr_t *)&invl_gen->next, PMAP_INVL_GEN_NEXT_INVALID); if (!pmap_delayed_invl_finish_u_crit(invl_gen, p)) { atomic_clear_ptr((uintptr_t *)&invl_gen->next, PMAP_INVL_GEN_NEXT_INVALID); critical_exit(); PV_STAT(counter_u64_add(invl_finish_restart, 1)); lock_delay(&lda); goto again; } critical_exit(); if (atomic_load_int(&pmap_invl_waiters) > 0) pmap_delayed_invl_finish_unblock(0); if (invl_gen->saved_pri != 0) { thread_lock(td); sched_prio(td, invl_gen->saved_pri); thread_unlock(td); } } #ifdef DDB DB_SHOW_COMMAND(di_queue, pmap_di_queue) { struct pmap_invl_gen *p, *pn; struct thread *td; uintptr_t nextl; bool first; for (p = &pmap_invl_gen_head, first = true; p != NULL; p = pn, first = false) { nextl = (uintptr_t)atomic_load_ptr(&p->next); pn = (void *)(nextl & ~PMAP_INVL_GEN_NEXT_INVALID); td = first ? NULL : __containerof(p, struct thread, td_md.md_invl_gen); db_printf("gen %lu inv %d td %p tid %d\n", p->gen, (nextl & PMAP_INVL_GEN_NEXT_INVALID) != 0, td, td != NULL ? td->td_tid : -1); } } #endif #ifdef PV_STATS static COUNTER_U64_DEFINE_EARLY(invl_wait); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, invl_wait, CTLFLAG_RD, &invl_wait, "Number of times DI invalidation blocked pmap_remove_all/write"); static COUNTER_U64_DEFINE_EARLY(invl_wait_slow); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, invl_wait_slow, CTLFLAG_RD, &invl_wait_slow, "Number of slow invalidation waits for lockless DI"); #endif #ifdef NUMA static u_long * pmap_delayed_invl_genp(vm_page_t m) { vm_paddr_t pa; u_long *gen; pa = VM_PAGE_TO_PHYS(m); if (__predict_false((pa) > pmap_last_pa)) gen = &pv_dummy_large.pv_invl_gen; else gen = &(pa_to_pmdp(pa)->pv_invl_gen); return (gen); } #else static u_long * pmap_delayed_invl_genp(vm_page_t m) { return (&pv_invl_gen[pa_index(VM_PAGE_TO_PHYS(m)) % NPV_LIST_LOCKS]); } #endif static void pmap_delayed_invl_callout_func(void *arg __unused) { if (atomic_load_int(&pmap_invl_waiters) == 0) return; pmap_delayed_invl_finish_unblock(0); } static void pmap_delayed_invl_callout_init(void *arg __unused) { if (pmap_di_locked()) return; callout_init(&pmap_invl_callout, 1); pmap_invl_callout_inited = true; } SYSINIT(pmap_di_callout, SI_SUB_CPU + 1, SI_ORDER_ANY, pmap_delayed_invl_callout_init, NULL); /* * Ensure that all currently executing DI blocks, that need to flush * TLB for the given page m, actually flushed the TLB at the time the * function returned. If the page m has an empty PV list and we call * pmap_delayed_invl_wait(), upon its return we know that no CPU has a * valid mapping for the page m in either its page table or TLB. * * This function works by blocking until the global DI generation * number catches up with the generation number associated with the * given page m and its PV list. Since this function's callers * typically own an object lock and sometimes own a page lock, it * cannot sleep. Instead, it blocks on a turnstile to relinquish the * processor. */ static void pmap_delayed_invl_wait_l(vm_page_t m) { u_long *m_gen; #ifdef PV_STATS bool accounted = false; #endif m_gen = pmap_delayed_invl_genp(m); while (*m_gen > pmap_invl_gen) { #ifdef PV_STATS if (!accounted) { counter_u64_add(invl_wait, 1); accounted = true; } #endif pmap_delayed_invl_wait_block(m_gen, &pmap_invl_gen); } } static void pmap_delayed_invl_wait_u(vm_page_t m) { u_long *m_gen; struct lock_delay_arg lda; bool fast; fast = true; m_gen = pmap_delayed_invl_genp(m); lock_delay_arg_init(&lda, &di_delay); while (*m_gen > atomic_load_long(&pmap_invl_gen_head.gen)) { if (fast || !pmap_invl_callout_inited) { PV_STAT(counter_u64_add(invl_wait, 1)); lock_delay(&lda); fast = false; } else { /* * The page's invalidation generation number * is still below the current thread's number. * Prepare to block so that we do not waste * CPU cycles or worse, suffer livelock. * * Since it is impossible to block without * racing with pmap_delayed_invl_finish_u(), * prepare for the race by incrementing * pmap_invl_waiters and arming a 1-tick * callout which will unblock us if we lose * the race. */ atomic_add_int(&pmap_invl_waiters, 1); /* * Re-check the current thread's invalidation * generation after incrementing * pmap_invl_waiters, so that there is no race * with pmap_delayed_invl_finish_u() setting * the page generation and checking * pmap_invl_waiters. The only race allowed * is for a missed unblock, which is handled * by the callout. */ if (*m_gen > atomic_load_long(&pmap_invl_gen_head.gen)) { callout_reset(&pmap_invl_callout, 1, pmap_delayed_invl_callout_func, NULL); PV_STAT(counter_u64_add(invl_wait_slow, 1)); pmap_delayed_invl_wait_block(m_gen, &pmap_invl_gen_head.gen); } atomic_add_int(&pmap_invl_waiters, -1); } } } DEFINE_IFUNC(, void, pmap_thread_init_invl_gen, (struct thread *)) { return (pmap_di_locked() ? pmap_thread_init_invl_gen_l : pmap_thread_init_invl_gen_u); } DEFINE_IFUNC(static, void, pmap_delayed_invl_start, (void)) { return (pmap_di_locked() ? pmap_delayed_invl_start_l : pmap_delayed_invl_start_u); } DEFINE_IFUNC(static, void, pmap_delayed_invl_finish, (void)) { return (pmap_di_locked() ? pmap_delayed_invl_finish_l : pmap_delayed_invl_finish_u); } DEFINE_IFUNC(static, void, pmap_delayed_invl_wait, (vm_page_t)) { return (pmap_di_locked() ? pmap_delayed_invl_wait_l : pmap_delayed_invl_wait_u); } /* * Mark the page m's PV list as participating in the current thread's * DI block. Any threads concurrently using m's PV list to remove or * restrict all mappings to m will wait for the current thread's DI * block to complete before proceeding. * * The function works by setting the DI generation number for m's PV * list to at least the DI generation number of the current thread. * This forces a caller of pmap_delayed_invl_wait() to block until * current thread calls pmap_delayed_invl_finish(). */ static void pmap_delayed_invl_page(vm_page_t m) { u_long gen, *m_gen; rw_assert(VM_PAGE_TO_PV_LIST_LOCK(m), RA_WLOCKED); gen = curthread->td_md.md_invl_gen.gen; if (gen == 0) return; m_gen = pmap_delayed_invl_genp(m); if (*m_gen < gen) *m_gen = gen; } /* * Crashdump maps. */ static caddr_t crashdumpmap; /* * Internal flags for pmap_enter()'s helper functions. */ #define PMAP_ENTER_NORECLAIM 0x1000000 /* Don't reclaim PV entries. */ #define PMAP_ENTER_NOREPLACE 0x2000000 /* Don't replace mappings. */ /* * Internal flags for pmap_mapdev_internal() and * pmap_change_props_locked(). */ #define MAPDEV_FLUSHCACHE 0x00000001 /* Flush cache after mapping. */ #define MAPDEV_SETATTR 0x00000002 /* Modify existing attrs. */ #define MAPDEV_ASSERTVALID 0x00000004 /* Assert mapping validity. */ TAILQ_HEAD(pv_chunklist, pv_chunk); static void free_pv_chunk(struct pv_chunk *pc); static void free_pv_chunk_batch(struct pv_chunklist *batch); static void free_pv_entry(pmap_t pmap, pv_entry_t pv); static pv_entry_t get_pv_entry(pmap_t pmap, struct rwlock **lockp); static int popcnt_pc_map_pq(uint64_t *map); static vm_page_t reclaim_pv_chunk(pmap_t locked_pmap, struct rwlock **lockp); static void reserve_pv_entries(pmap_t pmap, int needed, struct rwlock **lockp); static void pmap_pv_demote_pde(pmap_t pmap, vm_offset_t va, vm_paddr_t pa, struct rwlock **lockp); static bool pmap_pv_insert_pde(pmap_t pmap, vm_offset_t va, pd_entry_t pde, u_int flags, struct rwlock **lockp); #if VM_NRESERVLEVEL > 0 static void pmap_pv_promote_pde(pmap_t pmap, vm_offset_t va, vm_paddr_t pa, struct rwlock **lockp); #endif static void pmap_pvh_free(struct md_page *pvh, pmap_t pmap, vm_offset_t va); static pv_entry_t pmap_pvh_remove(struct md_page *pvh, pmap_t pmap, vm_offset_t va); static void pmap_abort_ptp(pmap_t pmap, vm_offset_t va, vm_page_t mpte); static int pmap_change_props_locked(vm_offset_t va, vm_size_t size, vm_prot_t prot, int mode, int flags); static boolean_t pmap_demote_pde(pmap_t pmap, pd_entry_t *pde, vm_offset_t va); static boolean_t pmap_demote_pde_locked(pmap_t pmap, pd_entry_t *pde, vm_offset_t va, struct rwlock **lockp); static boolean_t pmap_demote_pdpe(pmap_t pmap, pdp_entry_t *pdpe, vm_offset_t va); static int pmap_enter_2mpage(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, struct rwlock **lockp); static int pmap_enter_pde(pmap_t pmap, vm_offset_t va, pd_entry_t newpde, u_int flags, vm_page_t m, struct rwlock **lockp); static vm_page_t pmap_enter_quick_locked(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, vm_page_t mpte, struct rwlock **lockp); static void pmap_fill_ptp(pt_entry_t *firstpte, pt_entry_t newpte); static int pmap_insert_pt_page(pmap_t pmap, vm_page_t mpte, bool promoted, bool allpte_PG_A_set); static void pmap_invalidate_cache_range_selfsnoop(vm_offset_t sva, vm_offset_t eva); static void pmap_invalidate_cache_range_all(vm_offset_t sva, vm_offset_t eva); static void pmap_invalidate_pde_page(pmap_t pmap, vm_offset_t va, pd_entry_t pde); static void pmap_kenter_attr(vm_offset_t va, vm_paddr_t pa, int mode); static vm_page_t pmap_large_map_getptp_unlocked(void); static vm_paddr_t pmap_large_map_kextract(vm_offset_t va); #if VM_NRESERVLEVEL > 0 static bool pmap_promote_pde(pmap_t pmap, pd_entry_t *pde, vm_offset_t va, vm_page_t mpte, struct rwlock **lockp); #endif static boolean_t pmap_protect_pde(pmap_t pmap, pd_entry_t *pde, vm_offset_t sva, vm_prot_t prot); static void pmap_pte_props(pt_entry_t *pte, u_long bits, u_long mask); static void pmap_pti_add_kva_locked(vm_offset_t sva, vm_offset_t eva, bool exec); static pdp_entry_t *pmap_pti_pdpe(vm_offset_t va); static pd_entry_t *pmap_pti_pde(vm_offset_t va); static void pmap_pti_wire_pte(void *pte); static int pmap_remove_pde(pmap_t pmap, pd_entry_t *pdq, vm_offset_t sva, struct spglist *free, struct rwlock **lockp); static int pmap_remove_pte(pmap_t pmap, pt_entry_t *ptq, vm_offset_t sva, pd_entry_t ptepde, struct spglist *free, struct rwlock **lockp); static vm_page_t pmap_remove_pt_page(pmap_t pmap, vm_offset_t va); static void pmap_remove_page(pmap_t pmap, vm_offset_t va, pd_entry_t *pde, struct spglist *free); static bool pmap_remove_ptes(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, pd_entry_t *pde, struct spglist *free, struct rwlock **lockp); static boolean_t pmap_try_insert_pv_entry(pmap_t pmap, vm_offset_t va, vm_page_t m, struct rwlock **lockp); static void pmap_update_pde(pmap_t pmap, vm_offset_t va, pd_entry_t *pde, pd_entry_t newpde); static void pmap_update_pde_invalidate(pmap_t, vm_offset_t va, pd_entry_t pde); static pd_entry_t *pmap_alloc_pde(pmap_t pmap, vm_offset_t va, vm_page_t *pdpgp, struct rwlock **lockp); static vm_page_t pmap_allocpte_alloc(pmap_t pmap, vm_pindex_t ptepindex, struct rwlock **lockp, vm_offset_t va); static vm_page_t pmap_allocpte_nosleep(pmap_t pmap, vm_pindex_t ptepindex, struct rwlock **lockp, vm_offset_t va); static vm_page_t pmap_allocpte(pmap_t pmap, vm_offset_t va, struct rwlock **lockp); static void _pmap_unwire_ptp(pmap_t pmap, vm_offset_t va, vm_page_t m, struct spglist *free); static int pmap_unuse_pt(pmap_t, vm_offset_t, pd_entry_t, struct spglist *); static vm_page_t pmap_alloc_pt_page(pmap_t, vm_pindex_t, int); static void pmap_free_pt_page(pmap_t, vm_page_t, bool); /********************/ /* Inline functions */ /********************/ /* * Return a non-clipped indexes for a given VA, which are page table * pages indexes at the corresponding level. */ static __inline vm_pindex_t pmap_pde_pindex(vm_offset_t va) { return (va >> PDRSHIFT); } static __inline vm_pindex_t pmap_pdpe_pindex(vm_offset_t va) { return (NUPDE + (va >> PDPSHIFT)); } static __inline vm_pindex_t pmap_pml4e_pindex(vm_offset_t va) { return (NUPDE + NUPDPE + (va >> PML4SHIFT)); } static __inline vm_pindex_t pmap_pml5e_pindex(vm_offset_t va) { return (NUPDE + NUPDPE + NUPML4E + (va >> PML5SHIFT)); } static __inline pml4_entry_t * pmap_pml5e(pmap_t pmap, vm_offset_t va) { MPASS(pmap_is_la57(pmap)); return (&pmap->pm_pmltop[pmap_pml5e_index(va)]); } static __inline pml4_entry_t * pmap_pml5e_u(pmap_t pmap, vm_offset_t va) { MPASS(pmap_is_la57(pmap)); return (&pmap->pm_pmltopu[pmap_pml5e_index(va)]); } static __inline pml4_entry_t * pmap_pml5e_to_pml4e(pml5_entry_t *pml5e, vm_offset_t va) { pml4_entry_t *pml4e; /* XXX MPASS(pmap_is_la57(pmap); */ pml4e = (pml4_entry_t *)PHYS_TO_DMAP(*pml5e & PG_FRAME); return (&pml4e[pmap_pml4e_index(va)]); } /* Return a pointer to the PML4 slot that corresponds to a VA */ static __inline pml4_entry_t * pmap_pml4e(pmap_t pmap, vm_offset_t va) { pml5_entry_t *pml5e; pml4_entry_t *pml4e; pt_entry_t PG_V; if (pmap_is_la57(pmap)) { pml5e = pmap_pml5e(pmap, va); PG_V = pmap_valid_bit(pmap); if ((*pml5e & PG_V) == 0) return (NULL); pml4e = (pml4_entry_t *)PHYS_TO_DMAP(*pml5e & PG_FRAME); } else { pml4e = pmap->pm_pmltop; } return (&pml4e[pmap_pml4e_index(va)]); } static __inline pml4_entry_t * pmap_pml4e_u(pmap_t pmap, vm_offset_t va) { MPASS(!pmap_is_la57(pmap)); return (&pmap->pm_pmltopu[pmap_pml4e_index(va)]); } /* Return a pointer to the PDP slot that corresponds to a VA */ static __inline pdp_entry_t * pmap_pml4e_to_pdpe(pml4_entry_t *pml4e, vm_offset_t va) { pdp_entry_t *pdpe; pdpe = (pdp_entry_t *)PHYS_TO_DMAP(*pml4e & PG_FRAME); return (&pdpe[pmap_pdpe_index(va)]); } /* Return a pointer to the PDP slot that corresponds to a VA */ static __inline pdp_entry_t * pmap_pdpe(pmap_t pmap, vm_offset_t va) { pml4_entry_t *pml4e; pt_entry_t PG_V; PG_V = pmap_valid_bit(pmap); pml4e = pmap_pml4e(pmap, va); if (pml4e == NULL || (*pml4e & PG_V) == 0) return (NULL); return (pmap_pml4e_to_pdpe(pml4e, va)); } /* Return a pointer to the PD slot that corresponds to a VA */ static __inline pd_entry_t * pmap_pdpe_to_pde(pdp_entry_t *pdpe, vm_offset_t va) { pd_entry_t *pde; KASSERT((*pdpe & PG_PS) == 0, ("%s: pdpe %#lx is a leaf", __func__, *pdpe)); pde = (pd_entry_t *)PHYS_TO_DMAP(*pdpe & PG_FRAME); return (&pde[pmap_pde_index(va)]); } /* Return a pointer to the PD slot that corresponds to a VA */ static __inline pd_entry_t * pmap_pde(pmap_t pmap, vm_offset_t va) { pdp_entry_t *pdpe; pt_entry_t PG_V; PG_V = pmap_valid_bit(pmap); pdpe = pmap_pdpe(pmap, va); if (pdpe == NULL || (*pdpe & PG_V) == 0) return (NULL); KASSERT((*pdpe & PG_PS) == 0, ("pmap_pde for 1G page, pmap %p va %#lx", pmap, va)); return (pmap_pdpe_to_pde(pdpe, va)); } /* Return a pointer to the PT slot that corresponds to a VA */ static __inline pt_entry_t * pmap_pde_to_pte(pd_entry_t *pde, vm_offset_t va) { pt_entry_t *pte; KASSERT((*pde & PG_PS) == 0, ("%s: pde %#lx is a leaf", __func__, *pde)); pte = (pt_entry_t *)PHYS_TO_DMAP(*pde & PG_FRAME); return (&pte[pmap_pte_index(va)]); } /* Return a pointer to the PT slot that corresponds to a VA */ static __inline pt_entry_t * pmap_pte(pmap_t pmap, vm_offset_t va) { pd_entry_t *pde; pt_entry_t PG_V; PG_V = pmap_valid_bit(pmap); pde = pmap_pde(pmap, va); if (pde == NULL || (*pde & PG_V) == 0) return (NULL); if ((*pde & PG_PS) != 0) /* compat with i386 pmap_pte() */ return ((pt_entry_t *)pde); return (pmap_pde_to_pte(pde, va)); } static __inline void pmap_resident_count_adj(pmap_t pmap, int count) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT(pmap->pm_stats.resident_count + count >= 0, ("pmap %p resident count underflow %ld %d", pmap, pmap->pm_stats.resident_count, count)); pmap->pm_stats.resident_count += count; } static __inline void pmap_pt_page_count_pinit(pmap_t pmap, int count) { KASSERT(pmap->pm_stats.resident_count + count >= 0, ("pmap %p resident count underflow %ld %d", pmap, pmap->pm_stats.resident_count, count)); pmap->pm_stats.resident_count += count; } static __inline void pmap_pt_page_count_adj(pmap_t pmap, int count) { if (pmap == kernel_pmap) counter_u64_add(kernel_pt_page_count, count); else { if (pmap != NULL) pmap_resident_count_adj(pmap, count); counter_u64_add(user_pt_page_count, count); } } pt_entry_t vtoptem __read_mostly = ((1ul << (NPTEPGSHIFT + NPDEPGSHIFT + NPDPEPGSHIFT + NPML4EPGSHIFT)) - 1) << 3; vm_offset_t PTmap __read_mostly = (vm_offset_t)P4Tmap; PMAP_INLINE pt_entry_t * vtopte(vm_offset_t va) { KASSERT(va >= VM_MAXUSER_ADDRESS, ("vtopte on a uva/gpa 0x%0lx", va)); return ((pt_entry_t *)(PTmap + ((va >> (PAGE_SHIFT - 3)) & vtoptem))); } pd_entry_t vtopdem __read_mostly = ((1ul << (NPDEPGSHIFT + NPDPEPGSHIFT + NPML4EPGSHIFT)) - 1) << 3; vm_offset_t PDmap __read_mostly = (vm_offset_t)P4Dmap; static __inline pd_entry_t * vtopde(vm_offset_t va) { KASSERT(va >= VM_MAXUSER_ADDRESS, ("vtopde on a uva/gpa 0x%0lx", va)); return ((pt_entry_t *)(PDmap + ((va >> (PDRSHIFT - 3)) & vtopdem))); } static u_int64_t allocpages(vm_paddr_t *firstaddr, int n) { u_int64_t ret; ret = *firstaddr; bzero((void *)ret, n * PAGE_SIZE); *firstaddr += n * PAGE_SIZE; return (ret); } CTASSERT(powerof2(NDMPML4E)); /* number of kernel PDP slots */ #define NKPDPE(ptpgs) howmany(ptpgs, NPDEPG) static void nkpt_init(vm_paddr_t addr) { int pt_pages; #ifdef NKPT pt_pages = NKPT; #else pt_pages = howmany(addr - kernphys, NBPDR) + 1; /* +1 for 2M hole @0 */ pt_pages += NKPDPE(pt_pages); /* * Add some slop beyond the bare minimum required for bootstrapping * the kernel. * * This is quite important when allocating KVA for kernel modules. * The modules are required to be linked in the negative 2GB of * the address space. If we run out of KVA in this region then * pmap_growkernel() will need to allocate page table pages to map * the entire 512GB of KVA space which is an unnecessary tax on * physical memory. * * Secondly, device memory mapped as part of setting up the low- * level console(s) is taken from KVA, starting at virtual_avail. * This is because cninit() is called after pmap_bootstrap() but * before vm_init() and pmap_init(). 20MB for a frame buffer is * not uncommon. */ pt_pages += 32; /* 64MB additional slop. */ #endif nkpt = pt_pages; } /* * Returns the proper write/execute permission for a physical page that is * part of the initial boot allocations. * * If the page has kernel text, it is marked as read-only. If the page has * kernel read-only data, it is marked as read-only/not-executable. If the * page has only read-write data, it is marked as read-write/not-executable. * If the page is below/above the kernel range, it is marked as read-write. * * This function operates on 2M pages, since we map the kernel space that * way. */ static inline pt_entry_t bootaddr_rwx(vm_paddr_t pa) { /* * The kernel is loaded at a 2MB-aligned address, and memory below that * need not be executable. The .bss section is padded to a 2MB * boundary, so memory following the kernel need not be executable * either. Preloaded kernel modules have their mapping permissions * fixed up by the linker. */ if (pa < trunc_2mpage(kernphys + btext - KERNSTART) || pa >= trunc_2mpage(kernphys + _end - KERNSTART)) return (X86_PG_RW | pg_nx); /* * The linker should ensure that the read-only and read-write * portions don't share the same 2M page, so this shouldn't * impact read-only data. However, in any case, any page with * read-write data needs to be read-write. */ if (pa >= trunc_2mpage(kernphys + brwsection - KERNSTART)) return (X86_PG_RW | pg_nx); /* * Mark any 2M page containing kernel text as read-only. Mark * other pages with read-only data as read-only and not executable. * (It is likely a small portion of the read-only data section will * be marked as read-only, but executable. This should be acceptable * since the read-only protection will keep the data from changing.) * Note that fixups to the .text section will still work until we * set CR0.WP. */ if (pa < round_2mpage(kernphys + etext - KERNSTART)) return (0); return (pg_nx); } static void create_pagetables(vm_paddr_t *firstaddr) { pd_entry_t *pd_p; pdp_entry_t *pdp_p; pml4_entry_t *p4_p; uint64_t DMPDkernphys; vm_paddr_t pax; #ifdef KASAN pt_entry_t *pt_p; uint64_t KASANPDphys, KASANPTphys, KASANphys; vm_offset_t kasankernbase; int kasankpdpi, kasankpdi, nkasanpte; #endif int i, j, ndm1g, nkpdpe, nkdmpde; TSENTER(); /* Allocate page table pages for the direct map */ ndmpdp = howmany(ptoa(Maxmem), NBPDP); if (ndmpdp < 4) /* Minimum 4GB of dirmap */ ndmpdp = 4; ndmpdpphys = howmany(ndmpdp, NPDPEPG); if (ndmpdpphys > NDMPML4E) { /* * Each NDMPML4E allows 512 GB, so limit to that, * and then readjust ndmpdp and ndmpdpphys. */ printf("NDMPML4E limits system to %d GB\n", NDMPML4E * 512); Maxmem = atop(NDMPML4E * NBPML4); ndmpdpphys = NDMPML4E; ndmpdp = NDMPML4E * NPDEPG; } DMPDPphys = allocpages(firstaddr, ndmpdpphys); ndm1g = 0; if ((amd_feature & AMDID_PAGE1GB) != 0) { /* * Calculate the number of 1G pages that will fully fit in * Maxmem. */ ndm1g = ptoa(Maxmem) >> PDPSHIFT; /* * Allocate 2M pages for the kernel. These will be used in * place of the one or more 1G pages from ndm1g that maps * kernel memory into DMAP. */ nkdmpde = howmany((vm_offset_t)brwsection - KERNSTART + kernphys - rounddown2(kernphys, NBPDP), NBPDP); DMPDkernphys = allocpages(firstaddr, nkdmpde); } if (ndm1g < ndmpdp) DMPDphys = allocpages(firstaddr, ndmpdp - ndm1g); dmaplimit = (vm_paddr_t)ndmpdp << PDPSHIFT; /* Allocate pages. */ KPML4phys = allocpages(firstaddr, 1); KPDPphys = allocpages(firstaddr, NKPML4E); #ifdef KASAN KASANPDPphys = allocpages(firstaddr, NKASANPML4E); KASANPDphys = allocpages(firstaddr, 1); #endif #ifdef KMSAN /* * The KMSAN shadow maps are initially left unpopulated, since there is * no need to shadow memory above KERNBASE. */ KMSANSHADPDPphys = allocpages(firstaddr, NKMSANSHADPML4E); KMSANORIGPDPphys = allocpages(firstaddr, NKMSANORIGPML4E); #endif /* * Allocate the initial number of kernel page table pages required to * bootstrap. We defer this until after all memory-size dependent * allocations are done (e.g. direct map), so that we don't have to * build in too much slop in our estimate. * * Note that when NKPML4E > 1, we have an empty page underneath * all but the KPML4I'th one, so we need NKPML4E-1 extra (zeroed) * pages. (pmap_enter requires a PD page to exist for each KPML4E.) */ nkpt_init(*firstaddr); nkpdpe = NKPDPE(nkpt); KPTphys = allocpages(firstaddr, nkpt); KPDphys = allocpages(firstaddr, nkpdpe); #ifdef KASAN nkasanpte = howmany(nkpt, KASAN_SHADOW_SCALE); KASANPTphys = allocpages(firstaddr, nkasanpte); KASANphys = allocpages(firstaddr, nkasanpte * NPTEPG); #endif /* * Connect the zero-filled PT pages to their PD entries. This * implicitly maps the PT pages at their correct locations within * the PTmap. */ pd_p = (pd_entry_t *)KPDphys; for (i = 0; i < nkpt; i++) pd_p[i] = (KPTphys + ptoa(i)) | X86_PG_RW | X86_PG_V; /* * Map from start of the kernel in physical memory (staging * area) to the end of loader preallocated memory using 2MB * pages. This replaces some of the PD entries created above. * For compatibility, identity map 2M at the start. */ pd_p[0] = X86_PG_V | PG_PS | pg_g | X86_PG_M | X86_PG_A | X86_PG_RW | pg_nx; for (i = 1, pax = kernphys; pax < KERNend; i++, pax += NBPDR) { /* Preset PG_M and PG_A because demotion expects it. */ pd_p[i] = pax | X86_PG_V | PG_PS | pg_g | X86_PG_M | X86_PG_A | bootaddr_rwx(pax); } /* * Because we map the physical blocks in 2M pages, adjust firstaddr * to record the physical blocks we've actually mapped into kernel * virtual address space. */ if (*firstaddr < round_2mpage(KERNend)) *firstaddr = round_2mpage(KERNend); /* And connect up the PD to the PDP (leaving room for L4 pages) */ pdp_p = (pdp_entry_t *)(KPDPphys + ptoa(KPML4I - KPML4BASE)); for (i = 0; i < nkpdpe; i++) pdp_p[i + KPDPI] = (KPDphys + ptoa(i)) | X86_PG_RW | X86_PG_V; #ifdef KASAN kasankernbase = kasan_md_addr_to_shad(KERNBASE); kasankpdpi = pmap_pdpe_index(kasankernbase); kasankpdi = pmap_pde_index(kasankernbase); pdp_p = (pdp_entry_t *)KASANPDPphys; pdp_p[kasankpdpi] = (KASANPDphys | X86_PG_RW | X86_PG_V | pg_nx); pd_p = (pd_entry_t *)KASANPDphys; for (i = 0; i < nkasanpte; i++) pd_p[i + kasankpdi] = (KASANPTphys + ptoa(i)) | X86_PG_RW | X86_PG_V | pg_nx; pt_p = (pt_entry_t *)KASANPTphys; for (i = 0; i < nkasanpte * NPTEPG; i++) pt_p[i] = (KASANphys + ptoa(i)) | X86_PG_RW | X86_PG_V | X86_PG_M | X86_PG_A | pg_nx; #endif /* * Now, set up the direct map region using 2MB and/or 1GB pages. If * the end of physical memory is not aligned to a 1GB page boundary, * then the residual physical memory is mapped with 2MB pages. Later, * if pmap_mapdev{_attr}() uses the direct map for non-write-back * memory, pmap_change_attr() will demote any 2MB or 1GB page mappings * that are partially used. */ pd_p = (pd_entry_t *)DMPDphys; for (i = NPDEPG * ndm1g, j = 0; i < NPDEPG * ndmpdp; i++, j++) { pd_p[j] = (vm_paddr_t)i << PDRSHIFT; /* Preset PG_M and PG_A because demotion expects it. */ pd_p[j] |= X86_PG_RW | X86_PG_V | PG_PS | pg_g | X86_PG_M | X86_PG_A | pg_nx; } pdp_p = (pdp_entry_t *)DMPDPphys; for (i = 0; i < ndm1g; i++) { pdp_p[i] = (vm_paddr_t)i << PDPSHIFT; /* Preset PG_M and PG_A because demotion expects it. */ pdp_p[i] |= X86_PG_RW | X86_PG_V | PG_PS | pg_g | X86_PG_M | X86_PG_A | pg_nx; } for (j = 0; i < ndmpdp; i++, j++) { pdp_p[i] = DMPDphys + ptoa(j); pdp_p[i] |= X86_PG_RW | X86_PG_V | pg_nx; } /* * Instead of using a 1G page for the memory containing the kernel, * use 2M pages with read-only and no-execute permissions. (If using 1G * pages, this will partially overwrite the PDPEs above.) */ if (ndm1g > 0) { pd_p = (pd_entry_t *)DMPDkernphys; for (i = 0, pax = rounddown2(kernphys, NBPDP); i < NPDEPG * nkdmpde; i++, pax += NBPDR) { pd_p[i] = pax | X86_PG_V | PG_PS | pg_g | X86_PG_M | X86_PG_A | pg_nx | bootaddr_rwx(pax); } j = rounddown2(kernphys, NBPDP) >> PDPSHIFT; for (i = 0; i < nkdmpde; i++) { pdp_p[i + j] = (DMPDkernphys + ptoa(i)) | X86_PG_RW | X86_PG_V | pg_nx; } } /* And recursively map PML4 to itself in order to get PTmap */ p4_p = (pml4_entry_t *)KPML4phys; p4_p[PML4PML4I] = KPML4phys; p4_p[PML4PML4I] |= X86_PG_RW | X86_PG_V | pg_nx; #ifdef KASAN /* Connect the KASAN shadow map slots up to the PML4. */ for (i = 0; i < NKASANPML4E; i++) { p4_p[KASANPML4I + i] = KASANPDPphys + ptoa(i); p4_p[KASANPML4I + i] |= X86_PG_RW | X86_PG_V | pg_nx; } #endif #ifdef KMSAN /* Connect the KMSAN shadow map slots up to the PML4. */ for (i = 0; i < NKMSANSHADPML4E; i++) { p4_p[KMSANSHADPML4I + i] = KMSANSHADPDPphys + ptoa(i); p4_p[KMSANSHADPML4I + i] |= X86_PG_RW | X86_PG_V | pg_nx; } /* Connect the KMSAN origin map slots up to the PML4. */ for (i = 0; i < NKMSANORIGPML4E; i++) { p4_p[KMSANORIGPML4I + i] = KMSANORIGPDPphys + ptoa(i); p4_p[KMSANORIGPML4I + i] |= X86_PG_RW | X86_PG_V | pg_nx; } #endif /* Connect the Direct Map slots up to the PML4. */ for (i = 0; i < ndmpdpphys; i++) { p4_p[DMPML4I + i] = DMPDPphys + ptoa(i); p4_p[DMPML4I + i] |= X86_PG_RW | X86_PG_V | pg_nx; } /* Connect the KVA slots up to the PML4 */ for (i = 0; i < NKPML4E; i++) { p4_p[KPML4BASE + i] = KPDPphys + ptoa(i); p4_p[KPML4BASE + i] |= X86_PG_RW | X86_PG_V; } kernel_pml4 = (pml4_entry_t *)PHYS_TO_DMAP(KPML4phys); TSEXIT(); } /* * Bootstrap the system enough to run with virtual memory. * * On amd64 this is called after mapping has already been enabled * and just syncs the pmap module with what has already been done. * [We can't call it easily with mapping off since the kernel is not * mapped with PA == VA, hence we would have to relocate every address * from the linked base (virtual) address "KERNBASE" to the actual * (physical) address starting relative to 0] */ void pmap_bootstrap(vm_paddr_t *firstaddr) { vm_offset_t va; pt_entry_t *pte, *pcpu_pte; struct region_descriptor r_gdt; uint64_t cr4, pcpu0_phys; u_long res; int i; TSENTER(); KERNend = *firstaddr; res = atop(KERNend - (vm_paddr_t)kernphys); if (!pti) pg_g = X86_PG_G; /* * Create an initial set of page tables to run the kernel in. */ create_pagetables(firstaddr); pcpu0_phys = allocpages(firstaddr, 1); /* * Add a physical memory segment (vm_phys_seg) corresponding to the * preallocated kernel page table pages so that vm_page structures * representing these pages will be created. The vm_page structures * are required for promotion of the corresponding kernel virtual * addresses to superpage mappings. */ vm_phys_early_add_seg(KPTphys, KPTphys + ptoa(nkpt)); /* * Account for the virtual addresses mapped by create_pagetables(). */ virtual_avail = (vm_offset_t)KERNSTART + round_2mpage(KERNend - (vm_paddr_t)kernphys); virtual_end = VM_MAX_KERNEL_ADDRESS; /* * Enable PG_G global pages, then switch to the kernel page * table from the bootstrap page table. After the switch, it * is possible to enable SMEP and SMAP since PG_U bits are * correct now. */ cr4 = rcr4(); cr4 |= CR4_PGE; load_cr4(cr4); load_cr3(KPML4phys); if (cpu_stdext_feature & CPUID_STDEXT_SMEP) cr4 |= CR4_SMEP; if (cpu_stdext_feature & CPUID_STDEXT_SMAP) cr4 |= CR4_SMAP; load_cr4(cr4); /* * Initialize the kernel pmap (which is statically allocated). * Count bootstrap data as being resident in case any of this data is * later unmapped (using pmap_remove()) and freed. */ PMAP_LOCK_INIT(kernel_pmap); kernel_pmap->pm_pmltop = kernel_pml4; kernel_pmap->pm_cr3 = KPML4phys; kernel_pmap->pm_ucr3 = PMAP_NO_CR3; TAILQ_INIT(&kernel_pmap->pm_pvchunk); kernel_pmap->pm_stats.resident_count = res; vm_radix_init(&kernel_pmap->pm_root); kernel_pmap->pm_flags = pmap_flags; if ((cpu_stdext_feature2 & CPUID_STDEXT2_PKU) != 0) { rangeset_init(&kernel_pmap->pm_pkru, pkru_dup_range, pkru_free_range, kernel_pmap, M_NOWAIT); } /* * The kernel pmap is always active on all CPUs. Once CPUs are * enumerated, the mask will be set equal to all_cpus. */ CPU_FILL(&kernel_pmap->pm_active); /* * Initialize the TLB invalidations generation number lock. */ mtx_init(&invl_gen_mtx, "invlgn", NULL, MTX_DEF); /* * Reserve some special page table entries/VA space for temporary * mapping of pages. */ #define SYSMAP(c, p, v, n) \ v = (c)va; va += ((n)*PAGE_SIZE); p = pte; pte += (n); va = virtual_avail; pte = vtopte(va); /* * Crashdump maps. The first page is reused as CMAP1 for the * memory test. */ SYSMAP(caddr_t, CMAP1, crashdumpmap, MAXDUMPPGS) CADDR1 = crashdumpmap; SYSMAP(struct pcpu *, pcpu_pte, __pcpu, MAXCPU); virtual_avail = va; /* * Map the BSP PCPU now, the rest of the PCPUs are mapped by * amd64_mp_alloc_pcpu()/start_all_aps() when we know the * number of CPUs and NUMA affinity. */ pcpu_pte[0] = pcpu0_phys | X86_PG_V | X86_PG_RW | pg_g | pg_nx | X86_PG_M | X86_PG_A; for (i = 1; i < MAXCPU; i++) pcpu_pte[i] = 0; /* * Re-initialize PCPU area for BSP after switching. * Make hardware use gdt and common_tss from the new PCPU. */ STAILQ_INIT(&cpuhead); wrmsr(MSR_GSBASE, (uint64_t)&__pcpu[0]); pcpu_init(&__pcpu[0], 0, sizeof(struct pcpu)); amd64_bsp_pcpu_init1(&__pcpu[0]); amd64_bsp_ist_init(&__pcpu[0]); __pcpu[0].pc_common_tss.tss_iobase = sizeof(struct amd64tss) + IOPERM_BITMAP_SIZE; memcpy(__pcpu[0].pc_gdt, temp_bsp_pcpu.pc_gdt, NGDT * sizeof(struct user_segment_descriptor)); gdt_segs[GPROC0_SEL].ssd_base = (uintptr_t)&__pcpu[0].pc_common_tss; ssdtosyssd(&gdt_segs[GPROC0_SEL], (struct system_segment_descriptor *)&__pcpu[0].pc_gdt[GPROC0_SEL]); r_gdt.rd_limit = NGDT * sizeof(struct user_segment_descriptor) - 1; r_gdt.rd_base = (long)__pcpu[0].pc_gdt; lgdt(&r_gdt); wrmsr(MSR_GSBASE, (uint64_t)&__pcpu[0]); ltr(GSEL(GPROC0_SEL, SEL_KPL)); __pcpu[0].pc_dynamic = temp_bsp_pcpu.pc_dynamic; __pcpu[0].pc_acpi_id = temp_bsp_pcpu.pc_acpi_id; /* * Initialize the PAT MSR. * pmap_init_pat() clears and sets CR4_PGE, which, as a * side-effect, invalidates stale PG_G TLB entries that might * have been created in our pre-boot environment. */ pmap_init_pat(); /* Initialize TLB Context Id. */ if (pmap_pcid_enabled) { kernel_pmap->pm_pcidp = (void *)(uintptr_t) offsetof(struct pcpu, pc_kpmap_store); PCPU_SET(kpmap_store.pm_pcid, PMAP_PCID_KERN); PCPU_SET(kpmap_store.pm_gen, 1); /* * PMAP_PCID_KERN + 1 is used for initialization of * proc0 pmap. The pmap' pcid state might be used by * EFIRT entry before first context switch, so it * needs to be valid. */ PCPU_SET(pcid_next, PMAP_PCID_KERN + 2); PCPU_SET(pcid_gen, 1); /* * pcpu area for APs is zeroed during AP startup. * pc_pcid_next and pc_pcid_gen are initialized by AP * during pcpu setup. */ load_cr4(rcr4() | CR4_PCIDE); } TSEXIT(); } /* * Setup the PAT MSR. */ void pmap_init_pat(void) { uint64_t pat_msr; u_long cr0, cr4; int i; /* Bail if this CPU doesn't implement PAT. */ if ((cpu_feature & CPUID_PAT) == 0) panic("no PAT??"); /* Set default PAT index table. */ for (i = 0; i < PAT_INDEX_SIZE; i++) pat_index[i] = -1; pat_index[PAT_WRITE_BACK] = 0; pat_index[PAT_WRITE_THROUGH] = 1; pat_index[PAT_UNCACHEABLE] = 3; pat_index[PAT_WRITE_COMBINING] = 6; pat_index[PAT_WRITE_PROTECTED] = 5; pat_index[PAT_UNCACHED] = 2; /* * Initialize default PAT entries. * Leave the indices 0-3 at the default of WB, WT, UC-, and UC. * Program 5 and 6 as WP and WC. * * Leave 4 and 7 as WB and UC. Note that a recursive page table * mapping for a 2M page uses a PAT value with the bit 3 set due * to its overload with PG_PS. */ pat_msr = PAT_VALUE(0, PAT_WRITE_BACK) | PAT_VALUE(1, PAT_WRITE_THROUGH) | PAT_VALUE(2, PAT_UNCACHED) | PAT_VALUE(3, PAT_UNCACHEABLE) | PAT_VALUE(4, PAT_WRITE_BACK) | PAT_VALUE(5, PAT_WRITE_PROTECTED) | PAT_VALUE(6, PAT_WRITE_COMBINING) | PAT_VALUE(7, PAT_UNCACHEABLE); /* Disable PGE. */ cr4 = rcr4(); load_cr4(cr4 & ~CR4_PGE); /* Disable caches (CD = 1, NW = 0). */ cr0 = rcr0(); load_cr0((cr0 & ~CR0_NW) | CR0_CD); /* Flushes caches and TLBs. */ wbinvd(); invltlb(); /* Update PAT and index table. */ wrmsr(MSR_PAT, pat_msr); /* Flush caches and TLBs again. */ wbinvd(); invltlb(); /* Restore caches and PGE. */ load_cr0(cr0); load_cr4(cr4); } vm_page_t pmap_page_alloc_below_4g(bool zeroed) { return (vm_page_alloc_noobj_contig((zeroed ? VM_ALLOC_ZERO : 0), 1, 0, (1ULL << 32), PAGE_SIZE, 0, VM_MEMATTR_DEFAULT)); } extern const char la57_trampoline[], la57_trampoline_gdt_desc[], la57_trampoline_gdt[], la57_trampoline_end[]; static void pmap_bootstrap_la57(void *arg __unused) { char *v_code; pml5_entry_t *v_pml5; pml4_entry_t *v_pml4; pdp_entry_t *v_pdp; pd_entry_t *v_pd; pt_entry_t *v_pt; vm_page_t m_code, m_pml4, m_pdp, m_pd, m_pt, m_pml5; void (*la57_tramp)(uint64_t pml5); struct region_descriptor r_gdt; if ((cpu_stdext_feature2 & CPUID_STDEXT2_LA57) == 0) return; TUNABLE_INT_FETCH("vm.pmap.la57", &la57); if (!la57) return; r_gdt.rd_limit = NGDT * sizeof(struct user_segment_descriptor) - 1; r_gdt.rd_base = (long)__pcpu[0].pc_gdt; m_code = pmap_page_alloc_below_4g(true); v_code = (char *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m_code)); m_pml5 = pmap_page_alloc_below_4g(true); KPML5phys = VM_PAGE_TO_PHYS(m_pml5); v_pml5 = (pml5_entry_t *)PHYS_TO_DMAP(KPML5phys); m_pml4 = pmap_page_alloc_below_4g(true); v_pml4 = (pdp_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m_pml4)); m_pdp = pmap_page_alloc_below_4g(true); v_pdp = (pdp_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m_pdp)); m_pd = pmap_page_alloc_below_4g(true); v_pd = (pdp_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m_pd)); m_pt = pmap_page_alloc_below_4g(true); v_pt = (pt_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m_pt)); /* * Map m_code 1:1, it appears below 4G in KVA due to physical * address being below 4G. Since kernel KVA is in upper half, * the pml4e should be zero and free for temporary use. */ kernel_pmap->pm_pmltop[pmap_pml4e_index(VM_PAGE_TO_PHYS(m_code))] = VM_PAGE_TO_PHYS(m_pdp) | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M; v_pdp[pmap_pdpe_index(VM_PAGE_TO_PHYS(m_code))] = VM_PAGE_TO_PHYS(m_pd) | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M; v_pd[pmap_pde_index(VM_PAGE_TO_PHYS(m_code))] = VM_PAGE_TO_PHYS(m_pt) | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M; v_pt[pmap_pte_index(VM_PAGE_TO_PHYS(m_code))] = VM_PAGE_TO_PHYS(m_code) | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M; /* * Add pml5 entry at top of KVA pointing to existing pml4 table, * entering all existing kernel mappings into level 5 table. */ v_pml5[pmap_pml5e_index(UPT_MAX_ADDRESS)] = KPML4phys | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M | pg_g; /* * Add pml5 entry for 1:1 trampoline mapping after LA57 is turned on. */ v_pml5[pmap_pml5e_index(VM_PAGE_TO_PHYS(m_code))] = VM_PAGE_TO_PHYS(m_pml4) | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M; v_pml4[pmap_pml4e_index(VM_PAGE_TO_PHYS(m_code))] = VM_PAGE_TO_PHYS(m_pdp) | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M; /* * Copy and call the 48->57 trampoline, hope we return there, alive. */ bcopy(la57_trampoline, v_code, la57_trampoline_end - la57_trampoline); *(u_long *)(v_code + 2 + (la57_trampoline_gdt_desc - la57_trampoline)) = la57_trampoline_gdt - la57_trampoline + VM_PAGE_TO_PHYS(m_code); la57_tramp = (void (*)(uint64_t))VM_PAGE_TO_PHYS(m_code); invlpg((vm_offset_t)la57_tramp); la57_tramp(KPML5phys); /* * gdt was necessary reset, switch back to our gdt. */ lgdt(&r_gdt); wrmsr(MSR_GSBASE, (uint64_t)&__pcpu[0]); load_ds(_udatasel); load_es(_udatasel); load_fs(_ufssel); ssdtosyssd(&gdt_segs[GPROC0_SEL], (struct system_segment_descriptor *)&__pcpu[0].pc_gdt[GPROC0_SEL]); ltr(GSEL(GPROC0_SEL, SEL_KPL)); /* * Now unmap the trampoline, and free the pages. * Clear pml5 entry used for 1:1 trampoline mapping. */ pte_clear(&v_pml5[pmap_pml5e_index(VM_PAGE_TO_PHYS(m_code))]); invlpg((vm_offset_t)v_code); vm_page_free(m_code); vm_page_free(m_pdp); vm_page_free(m_pd); vm_page_free(m_pt); /* * Recursively map PML5 to itself in order to get PTmap and * PDmap. */ v_pml5[PML5PML5I] = KPML5phys | X86_PG_RW | X86_PG_V | pg_nx; vtoptem = ((1ul << (NPTEPGSHIFT + NPDEPGSHIFT + NPDPEPGSHIFT + NPML4EPGSHIFT + NPML5EPGSHIFT)) - 1) << 3; PTmap = (vm_offset_t)P5Tmap; vtopdem = ((1ul << (NPDEPGSHIFT + NPDPEPGSHIFT + NPML4EPGSHIFT + NPML5EPGSHIFT)) - 1) << 3; PDmap = (vm_offset_t)P5Dmap; kernel_pmap->pm_cr3 = KPML5phys; kernel_pmap->pm_pmltop = v_pml5; pmap_pt_page_count_adj(kernel_pmap, 1); } SYSINIT(la57, SI_SUB_KMEM, SI_ORDER_ANY, pmap_bootstrap_la57, NULL); /* * Initialize a vm_page's machine-dependent fields. */ void pmap_page_init(vm_page_t m) { TAILQ_INIT(&m->md.pv_list); m->md.pat_mode = PAT_WRITE_BACK; } static int pmap_allow_2m_x_ept; SYSCTL_INT(_vm_pmap, OID_AUTO, allow_2m_x_ept, CTLFLAG_RWTUN | CTLFLAG_NOFETCH, &pmap_allow_2m_x_ept, 0, "Allow executable superpage mappings in EPT"); void pmap_allow_2m_x_ept_recalculate(void) { /* * SKL002, SKL012S. Since the EPT format is only used by * Intel CPUs, the vendor check is merely a formality. */ if (!(cpu_vendor_id != CPU_VENDOR_INTEL || (cpu_ia32_arch_caps & IA32_ARCH_CAP_IF_PSCHANGE_MC_NO) != 0 || (CPUID_TO_FAMILY(cpu_id) == 0x6 && (CPUID_TO_MODEL(cpu_id) == 0x26 || /* Atoms */ CPUID_TO_MODEL(cpu_id) == 0x27 || CPUID_TO_MODEL(cpu_id) == 0x35 || CPUID_TO_MODEL(cpu_id) == 0x36 || CPUID_TO_MODEL(cpu_id) == 0x37 || CPUID_TO_MODEL(cpu_id) == 0x86 || CPUID_TO_MODEL(cpu_id) == 0x1c || CPUID_TO_MODEL(cpu_id) == 0x4a || CPUID_TO_MODEL(cpu_id) == 0x4c || CPUID_TO_MODEL(cpu_id) == 0x4d || CPUID_TO_MODEL(cpu_id) == 0x5a || CPUID_TO_MODEL(cpu_id) == 0x5c || CPUID_TO_MODEL(cpu_id) == 0x5d || CPUID_TO_MODEL(cpu_id) == 0x5f || CPUID_TO_MODEL(cpu_id) == 0x6e || CPUID_TO_MODEL(cpu_id) == 0x7a || CPUID_TO_MODEL(cpu_id) == 0x57 || /* Knights */ CPUID_TO_MODEL(cpu_id) == 0x85)))) pmap_allow_2m_x_ept = 1; TUNABLE_INT_FETCH("hw.allow_2m_x_ept", &pmap_allow_2m_x_ept); } static bool pmap_allow_2m_x_page(pmap_t pmap, bool executable) { return (pmap->pm_type != PT_EPT || !executable || !pmap_allow_2m_x_ept); } #ifdef NUMA static void pmap_init_pv_table(void) { struct pmap_large_md_page *pvd; vm_size_t s; long start, end, highest, pv_npg; int domain, i, j, pages; /* * For correctness we depend on the size being evenly divisible into a * page. As a tradeoff between performance and total memory use, the * entry is 64 bytes (aka one cacheline) in size. Not being smaller * avoids false-sharing, but not being 128 bytes potentially allows for * avoidable traffic due to adjacent cacheline prefetcher. * * Assert the size so that accidental changes fail to compile. */ CTASSERT((sizeof(*pvd) == 64)); /* * Calculate the size of the array. */ pmap_last_pa = vm_phys_segs[vm_phys_nsegs - 1].end; pv_npg = howmany(pmap_last_pa, NBPDR); s = (vm_size_t)pv_npg * sizeof(struct pmap_large_md_page); s = round_page(s); pv_table = (struct pmap_large_md_page *)kva_alloc(s); if (pv_table == NULL) panic("%s: kva_alloc failed\n", __func__); /* * Iterate physical segments to allocate space for respective pages. */ highest = -1; s = 0; for (i = 0; i < vm_phys_nsegs; i++) { end = vm_phys_segs[i].end / NBPDR; domain = vm_phys_segs[i].domain; if (highest >= end) continue; start = highest + 1; pvd = &pv_table[start]; pages = end - start + 1; s = round_page(pages * sizeof(*pvd)); highest = start + (s / sizeof(*pvd)) - 1; for (j = 0; j < s; j += PAGE_SIZE) { vm_page_t m = vm_page_alloc_noobj_domain(domain, 0); if (m == NULL) panic("failed to allocate PV table page"); pmap_qenter((vm_offset_t)pvd + j, &m, 1); } for (j = 0; j < s / sizeof(*pvd); j++) { rw_init_flags(&pvd->pv_lock, "pmap pv list", RW_NEW); TAILQ_INIT(&pvd->pv_page.pv_list); pvd->pv_page.pv_gen = 0; pvd->pv_page.pat_mode = 0; pvd->pv_invl_gen = 0; pvd++; } } pvd = &pv_dummy_large; rw_init_flags(&pvd->pv_lock, "pmap pv list dummy", RW_NEW); TAILQ_INIT(&pvd->pv_page.pv_list); pvd->pv_page.pv_gen = 0; pvd->pv_page.pat_mode = 0; pvd->pv_invl_gen = 0; } #else static void pmap_init_pv_table(void) { vm_size_t s; long i, pv_npg; /* * Initialize the pool of pv list locks. */ for (i = 0; i < NPV_LIST_LOCKS; i++) rw_init(&pv_list_locks[i], "pmap pv list"); /* * Calculate the size of the pv head table for superpages. */ pv_npg = howmany(vm_phys_segs[vm_phys_nsegs - 1].end, NBPDR); /* * Allocate memory for the pv head table for superpages. */ s = (vm_size_t)pv_npg * sizeof(struct md_page); s = round_page(s); pv_table = kmem_malloc(s, M_WAITOK | M_ZERO); for (i = 0; i < pv_npg; i++) TAILQ_INIT(&pv_table[i].pv_list); TAILQ_INIT(&pv_dummy.pv_list); } #endif /* * Initialize the pmap module. * Called by vm_init, to initialize any structures that the pmap * system needs to map virtual memory. */ void pmap_init(void) { struct pmap_preinit_mapping *ppim; vm_page_t m, mpte; int error, i, ret, skz63; /* L1TF, reserve page @0 unconditionally */ vm_page_blacklist_add(0, bootverbose); /* Detect bare-metal Skylake Server and Skylake-X. */ if (vm_guest == VM_GUEST_NO && cpu_vendor_id == CPU_VENDOR_INTEL && CPUID_TO_FAMILY(cpu_id) == 0x6 && CPUID_TO_MODEL(cpu_id) == 0x55) { /* * Skylake-X errata SKZ63. Processor May Hang When * Executing Code In an HLE Transaction Region between * 40000000H and 403FFFFFH. * * Mark the pages in the range as preallocated. It * seems to be impossible to distinguish between * Skylake Server and Skylake X. */ skz63 = 1; TUNABLE_INT_FETCH("hw.skz63_enable", &skz63); if (skz63 != 0) { if (bootverbose) printf("SKZ63: skipping 4M RAM starting " "at physical 1G\n"); for (i = 0; i < atop(0x400000); i++) { ret = vm_page_blacklist_add(0x40000000 + ptoa(i), FALSE); if (!ret && bootverbose) printf("page at %#lx already used\n", 0x40000000 + ptoa(i)); } } } /* IFU */ pmap_allow_2m_x_ept_recalculate(); /* * Initialize the vm page array entries for the kernel pmap's * page table pages. */ PMAP_LOCK(kernel_pmap); for (i = 0; i < nkpt; i++) { mpte = PHYS_TO_VM_PAGE(KPTphys + (i << PAGE_SHIFT)); KASSERT(mpte >= vm_page_array && mpte < &vm_page_array[vm_page_array_size], ("pmap_init: page table page is out of range")); mpte->pindex = pmap_pde_pindex(KERNBASE) + i; mpte->phys_addr = KPTphys + (i << PAGE_SHIFT); mpte->ref_count = 1; /* * Collect the page table pages that were replaced by a 2MB * page in create_pagetables(). They are zero filled. */ if ((i == 0 || kernphys + ((vm_paddr_t)(i - 1) << PDRSHIFT) < KERNend) && pmap_insert_pt_page(kernel_pmap, mpte, false, false)) panic("pmap_init: pmap_insert_pt_page failed"); } PMAP_UNLOCK(kernel_pmap); vm_wire_add(nkpt); /* * If the kernel is running on a virtual machine, then it must assume * that MCA is enabled by the hypervisor. Moreover, the kernel must * be prepared for the hypervisor changing the vendor and family that * are reported by CPUID. Consequently, the workaround for AMD Family * 10h Erratum 383 is enabled if the processor's feature set does not * include at least one feature that is only supported by older Intel * or newer AMD processors. */ if (vm_guest != VM_GUEST_NO && (cpu_feature & CPUID_SS) == 0 && (cpu_feature2 & (CPUID2_SSSE3 | CPUID2_SSE41 | CPUID2_AESNI | CPUID2_AVX | CPUID2_XSAVE)) == 0 && (amd_feature2 & (AMDID2_XOP | AMDID2_FMA4)) == 0) workaround_erratum383 = 1; /* * Are large page mappings enabled? */ TUNABLE_INT_FETCH("vm.pmap.pg_ps_enabled", &pg_ps_enabled); if (pg_ps_enabled) { KASSERT(MAXPAGESIZES > 1 && pagesizes[1] == 0, ("pmap_init: can't assign to pagesizes[1]")); pagesizes[1] = NBPDR; if ((amd_feature & AMDID_PAGE1GB) != 0) { KASSERT(MAXPAGESIZES > 2 && pagesizes[2] == 0, ("pmap_init: can't assign to pagesizes[2]")); pagesizes[2] = NBPDP; } } /* * Initialize pv chunk lists. */ for (i = 0; i < PMAP_MEMDOM; i++) { mtx_init(&pv_chunks[i].pvc_lock, "pmap pv chunk list", NULL, MTX_DEF); TAILQ_INIT(&pv_chunks[i].pvc_list); } pmap_init_pv_table(); pmap_initialized = 1; for (i = 0; i < PMAP_PREINIT_MAPPING_COUNT; i++) { ppim = pmap_preinit_mapping + i; if (ppim->va == 0) continue; /* Make the direct map consistent */ if (ppim->pa < dmaplimit && ppim->pa + ppim->sz <= dmaplimit) { (void)pmap_change_attr(PHYS_TO_DMAP(ppim->pa), ppim->sz, ppim->mode); } if (!bootverbose) continue; printf("PPIM %u: PA=%#lx, VA=%#lx, size=%#lx, mode=%#x\n", i, ppim->pa, ppim->va, ppim->sz, ppim->mode); } mtx_init(&qframe_mtx, "qfrmlk", NULL, MTX_SPIN); error = vmem_alloc(kernel_arena, PAGE_SIZE, M_BESTFIT | M_WAITOK, (vmem_addr_t *)&qframe); if (error != 0) panic("qframe allocation failed"); lm_ents = 8; TUNABLE_INT_FETCH("vm.pmap.large_map_pml4_entries", &lm_ents); if (lm_ents > LMEPML4I - LMSPML4I + 1) lm_ents = LMEPML4I - LMSPML4I + 1; #ifdef KMSAN if (lm_ents > KMSANORIGPML4I - LMSPML4I) { printf( "pmap: shrinking large map for KMSAN (%d slots to %ld slots)\n", lm_ents, KMSANORIGPML4I - LMSPML4I); lm_ents = KMSANORIGPML4I - LMSPML4I; } #endif if (bootverbose) printf("pmap: large map %u PML4 slots (%lu GB)\n", lm_ents, (u_long)lm_ents * (NBPML4 / 1024 / 1024 / 1024)); if (lm_ents != 0) { large_vmem = vmem_create("large", LARGEMAP_MIN_ADDRESS, (vmem_size_t)lm_ents * NBPML4, PAGE_SIZE, 0, M_WAITOK); if (large_vmem == NULL) { printf("pmap: cannot create large map\n"); lm_ents = 0; } for (i = 0; i < lm_ents; i++) { m = pmap_large_map_getptp_unlocked(); /* XXXKIB la57 */ kernel_pml4[LMSPML4I + i] = X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M | pg_nx | VM_PAGE_TO_PHYS(m); } } } SYSCTL_UINT(_vm_pmap, OID_AUTO, large_map_pml4_entries, CTLFLAG_RDTUN | CTLFLAG_NOFETCH, &lm_ents, 0, "Maximum number of PML4 entries for use by large map (tunable). " "Each entry corresponds to 512GB of address space."); static SYSCTL_NODE(_vm_pmap, OID_AUTO, pde, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "2MB page mapping counters"); static COUNTER_U64_DEFINE_EARLY(pmap_pde_demotions); SYSCTL_COUNTER_U64(_vm_pmap_pde, OID_AUTO, demotions, CTLFLAG_RD, &pmap_pde_demotions, "2MB page demotions"); static COUNTER_U64_DEFINE_EARLY(pmap_pde_mappings); SYSCTL_COUNTER_U64(_vm_pmap_pde, OID_AUTO, mappings, CTLFLAG_RD, &pmap_pde_mappings, "2MB page mappings"); static COUNTER_U64_DEFINE_EARLY(pmap_pde_p_failures); SYSCTL_COUNTER_U64(_vm_pmap_pde, OID_AUTO, p_failures, CTLFLAG_RD, &pmap_pde_p_failures, "2MB page promotion failures"); static COUNTER_U64_DEFINE_EARLY(pmap_pde_promotions); SYSCTL_COUNTER_U64(_vm_pmap_pde, OID_AUTO, promotions, CTLFLAG_RD, &pmap_pde_promotions, "2MB page promotions"); static SYSCTL_NODE(_vm_pmap, OID_AUTO, pdpe, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "1GB page mapping counters"); static COUNTER_U64_DEFINE_EARLY(pmap_pdpe_demotions); SYSCTL_COUNTER_U64(_vm_pmap_pdpe, OID_AUTO, demotions, CTLFLAG_RD, &pmap_pdpe_demotions, "1GB page demotions"); /*************************************************** * Low level helper routines..... ***************************************************/ static pt_entry_t pmap_swap_pat(pmap_t pmap, pt_entry_t entry) { int x86_pat_bits = X86_PG_PTE_PAT | X86_PG_PDE_PAT; switch (pmap->pm_type) { case PT_X86: case PT_RVI: /* Verify that both PAT bits are not set at the same time */ KASSERT((entry & x86_pat_bits) != x86_pat_bits, ("Invalid PAT bits in entry %#lx", entry)); /* Swap the PAT bits if one of them is set */ if ((entry & x86_pat_bits) != 0) entry ^= x86_pat_bits; break; case PT_EPT: /* * Nothing to do - the memory attributes are represented * the same way for regular pages and superpages. */ break; default: panic("pmap_switch_pat_bits: bad pm_type %d", pmap->pm_type); } return (entry); } boolean_t pmap_is_valid_memattr(pmap_t pmap __unused, vm_memattr_t mode) { return (mode >= 0 && mode < PAT_INDEX_SIZE && pat_index[(int)mode] >= 0); } /* * Determine the appropriate bits to set in a PTE or PDE for a specified * caching mode. */ int pmap_cache_bits(pmap_t pmap, int mode, boolean_t is_pde) { int cache_bits, pat_flag, pat_idx; if (!pmap_is_valid_memattr(pmap, mode)) panic("Unknown caching mode %d\n", mode); switch (pmap->pm_type) { case PT_X86: case PT_RVI: /* The PAT bit is different for PTE's and PDE's. */ pat_flag = is_pde ? X86_PG_PDE_PAT : X86_PG_PTE_PAT; /* Map the caching mode to a PAT index. */ pat_idx = pat_index[mode]; /* Map the 3-bit index value into the PAT, PCD, and PWT bits. */ cache_bits = 0; if (pat_idx & 0x4) cache_bits |= pat_flag; if (pat_idx & 0x2) cache_bits |= PG_NC_PCD; if (pat_idx & 0x1) cache_bits |= PG_NC_PWT; break; case PT_EPT: cache_bits = EPT_PG_IGNORE_PAT | EPT_PG_MEMORY_TYPE(mode); break; default: panic("unsupported pmap type %d", pmap->pm_type); } return (cache_bits); } static int pmap_cache_mask(pmap_t pmap, boolean_t is_pde) { int mask; switch (pmap->pm_type) { case PT_X86: case PT_RVI: mask = is_pde ? X86_PG_PDE_CACHE : X86_PG_PTE_CACHE; break; case PT_EPT: mask = EPT_PG_IGNORE_PAT | EPT_PG_MEMORY_TYPE(0x7); break; default: panic("pmap_cache_mask: invalid pm_type %d", pmap->pm_type); } return (mask); } static int pmap_pat_index(pmap_t pmap, pt_entry_t pte, bool is_pde) { int pat_flag, pat_idx; pat_idx = 0; switch (pmap->pm_type) { case PT_X86: case PT_RVI: /* The PAT bit is different for PTE's and PDE's. */ pat_flag = is_pde ? X86_PG_PDE_PAT : X86_PG_PTE_PAT; if ((pte & pat_flag) != 0) pat_idx |= 0x4; if ((pte & PG_NC_PCD) != 0) pat_idx |= 0x2; if ((pte & PG_NC_PWT) != 0) pat_idx |= 0x1; break; case PT_EPT: if ((pte & EPT_PG_IGNORE_PAT) != 0) panic("EPT PTE %#lx has no PAT memory type", pte); pat_idx = (pte & EPT_PG_MEMORY_TYPE(0x7)) >> 3; break; } /* See pmap_init_pat(). */ if (pat_idx == 4) pat_idx = 0; if (pat_idx == 7) pat_idx = 3; return (pat_idx); } bool pmap_ps_enabled(pmap_t pmap) { return (pg_ps_enabled && (pmap->pm_flags & PMAP_PDE_SUPERPAGE) != 0); } static void pmap_update_pde_store(pmap_t pmap, pd_entry_t *pde, pd_entry_t newpde) { switch (pmap->pm_type) { case PT_X86: break; case PT_RVI: case PT_EPT: /* * XXX * This is a little bogus since the generation number is * supposed to be bumped up when a region of the address * space is invalidated in the page tables. * * In this case the old PDE entry is valid but yet we want * to make sure that any mappings using the old entry are * invalidated in the TLB. * * The reason this works as expected is because we rendezvous * "all" host cpus and force any vcpu context to exit as a * side-effect. */ atomic_add_long(&pmap->pm_eptgen, 1); break; default: panic("pmap_update_pde_store: bad pm_type %d", pmap->pm_type); } pde_store(pde, newpde); } /* * After changing the page size for the specified virtual address in the page * table, flush the corresponding entries from the processor's TLB. Only the * calling processor's TLB is affected. * * The calling thread must be pinned to a processor. */ static void pmap_update_pde_invalidate(pmap_t pmap, vm_offset_t va, pd_entry_t newpde) { pt_entry_t PG_G; if (pmap_type_guest(pmap)) return; KASSERT(pmap->pm_type == PT_X86, ("pmap_update_pde_invalidate: invalid type %d", pmap->pm_type)); PG_G = pmap_global_bit(pmap); if ((newpde & PG_PS) == 0) /* Demotion: flush a specific 2MB page mapping. */ pmap_invlpg(pmap, va); else if ((newpde & PG_G) == 0) /* * Promotion: flush every 4KB page mapping from the TLB * because there are too many to flush individually. */ invltlb(); else { /* * Promotion: flush every 4KB page mapping from the TLB, * including any global (PG_G) mappings. */ invltlb_glob(); } } /* * The amd64 pmap uses different approaches to TLB invalidation * depending on the kernel configuration, available hardware features, * and known hardware errata. The kernel configuration option that * has the greatest operational impact on TLB invalidation is PTI, * which is enabled automatically on affected Intel CPUs. The most * impactful hardware features are first PCID, and then INVPCID * instruction presence. PCID usage is quite different for PTI * vs. non-PTI. * * * Kernel Page Table Isolation (PTI or KPTI) is used to mitigate * the Meltdown bug in some Intel CPUs. Under PTI, each user address * space is served by two page tables, user and kernel. The user * page table only maps user space and a kernel trampoline. The * kernel trampoline includes the entirety of the kernel text but * only the kernel data that is needed to switch from user to kernel * mode. The kernel page table maps the user and kernel address * spaces in their entirety. It is identical to the per-process * page table used in non-PTI mode. * * User page tables are only used when the CPU is in user mode. * Consequently, some TLB invalidations can be postponed until the * switch from kernel to user mode. In contrast, the user * space part of the kernel page table is used for copyout(9), so * TLB invalidations on this page table cannot be similarly postponed. * * The existence of a user mode page table for the given pmap is * indicated by a pm_ucr3 value that differs from PMAP_NO_CR3, in * which case pm_ucr3 contains the %cr3 register value for the user * mode page table's root. * * * The pm_active bitmask indicates which CPUs currently have the * pmap active. A CPU's bit is set on context switch to the pmap, and * cleared on switching off this CPU. For the kernel page table, * the pm_active field is immutable and contains all CPUs. The * kernel page table is always logically active on every processor, * but not necessarily in use by the hardware, e.g., in PTI mode. * * When requesting invalidation of virtual addresses with * pmap_invalidate_XXX() functions, the pmap sends shootdown IPIs to * all CPUs recorded as active in pm_active. Updates to and reads * from pm_active are not synchronized, and so they may race with * each other. Shootdown handlers are prepared to handle the race. * * * PCID is an optional feature of the long mode x86 MMU where TLB * entries are tagged with the 'Process ID' of the address space * they belong to. This feature provides a limited namespace for * process identifiers, 12 bits, supporting 4095 simultaneous IDs * total. * * Allocation of a PCID to a pmap is done by an algorithm described * in section 15.12, "Other TLB Consistency Algorithms", of * Vahalia's book "Unix Internals". A PCID cannot be allocated for * the whole lifetime of a pmap in pmap_pinit() due to the limited * namespace. Instead, a per-CPU, per-pmap PCID is assigned when * the CPU is about to start caching TLB entries from a pmap, * i.e., on the context switch that activates the pmap on the CPU. * * The PCID allocator maintains a per-CPU, per-pmap generation * count, pm_gen, which is incremented each time a new PCID is * allocated. On TLB invalidation, the generation counters for the * pmap are zeroed, which signals the context switch code that the * previously allocated PCID is no longer valid. Effectively, * zeroing any of these counters triggers a TLB shootdown for the * given CPU/address space, due to the allocation of a new PCID. * * Zeroing can be performed remotely. Consequently, if a pmap is * inactive on a CPU, then a TLB shootdown for that pmap and CPU can * be initiated by an ordinary memory access to reset the target * CPU's generation count within the pmap. The CPU initiating the * TLB shootdown does not need to send an IPI to the target CPU. * * * PTI + PCID. The available PCIDs are divided into two sets: PCIDs * for complete (kernel) page tables, and PCIDs for user mode page * tables. A user PCID value is obtained from the kernel PCID value * by setting the highest bit, 11, to 1 (0x800 == PMAP_PCID_USER_PT). * * User space page tables are activated on return to user mode, by * loading pm_ucr3 into %cr3. If the PCPU(ucr3_load_mask) requests * clearing bit 63 of the loaded ucr3, this effectively causes * complete invalidation of the user mode TLB entries for the * current pmap. In which case, local invalidations of individual * pages in the user page table are skipped. * * * Local invalidation, all modes. If the requested invalidation is * for a specific address or the total invalidation of a currently * active pmap, then the TLB is flushed using INVLPG for a kernel * page table, and INVPCID(INVPCID_CTXGLOB)/invltlb_glob() for a * user space page table(s). * * If the INVPCID instruction is available, it is used to flush user * entries from the kernel page table. * * When PCID is enabled, the INVLPG instruction invalidates all TLB * entries for the given page that either match the current PCID or * are global. Since TLB entries for the same page under different * PCIDs are unaffected, kernel pages which reside in all address * spaces could be problematic. We avoid the problem by creating * all kernel PTEs with the global flag (PG_G) set, when PTI is * disabled. * * * mode: PTI disabled, PCID present. The kernel reserves PCID 0 for its * address space, all other 4095 PCIDs are used for user mode spaces * as described above. A context switch allocates a new PCID if * the recorded PCID is zero or the recorded generation does not match * the CPU's generation, effectively flushing the TLB for this address space. * Total remote invalidation is performed by zeroing pm_gen for all CPUs. * local user page: INVLPG * local kernel page: INVLPG * local user total: INVPCID(CTX) * local kernel total: INVPCID(CTXGLOB) or invltlb_glob() * remote user page, inactive pmap: zero pm_gen * remote user page, active pmap: zero pm_gen + IPI:INVLPG * (Both actions are required to handle the aforementioned pm_active races.) * remote kernel page: IPI:INVLPG * remote user total, inactive pmap: zero pm_gen * remote user total, active pmap: zero pm_gen + IPI:(INVPCID(CTX) or * reload %cr3) * (See note above about pm_active races.) * remote kernel total: IPI:(INVPCID(CTXGLOB) or invltlb_glob()) * * PTI enabled, PCID present. * local user page: INVLPG for kpt, INVPCID(ADDR) or (INVLPG for ucr3) * for upt * local kernel page: INVLPG * local user total: INVPCID(CTX) or reload %cr3 for kpt, clear PCID_SAVE * on loading UCR3 into %cr3 for upt * local kernel total: INVPCID(CTXGLOB) or invltlb_glob() * remote user page, inactive pmap: zero pm_gen * remote user page, active pmap: zero pm_gen + IPI:(INVLPG for kpt, * INVPCID(ADDR) for upt) * remote kernel page: IPI:INVLPG * remote user total, inactive pmap: zero pm_gen * remote user total, active pmap: zero pm_gen + IPI:(INVPCID(CTX) for kpt, * clear PCID_SAVE on loading UCR3 into $cr3 for upt) * remote kernel total: IPI:(INVPCID(CTXGLOB) or invltlb_glob()) * * No PCID. * local user page: INVLPG * local kernel page: INVLPG * local user total: reload %cr3 * local kernel total: invltlb_glob() * remote user page, inactive pmap: - * remote user page, active pmap: IPI:INVLPG * remote kernel page: IPI:INVLPG * remote user total, inactive pmap: - * remote user total, active pmap: IPI:(reload %cr3) * remote kernel total: IPI:invltlb_glob() * Since on return to user mode, the reload of %cr3 with ucr3 causes * TLB invalidation, no specific action is required for user page table. * * EPT. EPT pmaps do not map KVA, all mappings are userspace. * XXX TODO */ #ifdef SMP /* * Interrupt the cpus that are executing in the guest context. * This will force the vcpu to exit and the cached EPT mappings * will be invalidated by the host before the next vmresume. */ static __inline void pmap_invalidate_ept(pmap_t pmap) { smr_seq_t goal; int ipinum; sched_pin(); KASSERT(!CPU_ISSET(curcpu, &pmap->pm_active), ("pmap_invalidate_ept: absurd pm_active")); /* * The TLB mappings associated with a vcpu context are not * flushed each time a different vcpu is chosen to execute. * * This is in contrast with a process's vtop mappings that * are flushed from the TLB on each context switch. * * Therefore we need to do more than just a TLB shootdown on * the active cpus in 'pmap->pm_active'. To do this we keep * track of the number of invalidations performed on this pmap. * * Each vcpu keeps a cache of this counter and compares it * just before a vmresume. If the counter is out-of-date an * invept will be done to flush stale mappings from the TLB. * * To ensure that all vCPU threads have observed the new counter * value before returning, we use SMR. Ordering is important here: * the VMM enters an SMR read section before loading the counter * and after updating the pm_active bit set. Thus, pm_active is * a superset of active readers, and any reader that has observed * the goal has observed the new counter value. */ atomic_add_long(&pmap->pm_eptgen, 1); goal = smr_advance(pmap->pm_eptsmr); /* * Force the vcpu to exit and trap back into the hypervisor. */ ipinum = pmap->pm_flags & PMAP_NESTED_IPIMASK; ipi_selected(pmap->pm_active, ipinum); sched_unpin(); /* * Ensure that all active vCPUs will observe the new generation counter * value before executing any more guest instructions. */ smr_wait(pmap->pm_eptsmr, goal); } static inline void pmap_invalidate_preipi_pcid(pmap_t pmap) { struct pmap_pcid *pcidp; u_int cpuid, i; sched_pin(); cpuid = PCPU_GET(cpuid); if (pmap != PCPU_GET(curpmap)) cpuid = 0xffffffff; /* An impossible value */ CPU_FOREACH(i) { if (cpuid != i) { pcidp = zpcpu_get_cpu(pmap->pm_pcidp, i); pcidp->pm_gen = 0; } } /* * The fence is between stores to pm_gen and the read of the * pm_active mask. We need to ensure that it is impossible * for us to miss the bit update in pm_active and * simultaneously observe a non-zero pm_gen in * pmap_activate_sw(), otherwise TLB update is missed. * Without the fence, IA32 allows such an outcome. Note that * pm_active is updated by a locked operation, which provides * the reciprocal fence. */ atomic_thread_fence_seq_cst(); } static void pmap_invalidate_preipi_nopcid(pmap_t pmap __unused) { sched_pin(); } DEFINE_IFUNC(static, void, pmap_invalidate_preipi, (pmap_t)) { return (pmap_pcid_enabled ? pmap_invalidate_preipi_pcid : pmap_invalidate_preipi_nopcid); } static inline void pmap_invalidate_page_pcid_cb(pmap_t pmap, vm_offset_t va, const bool invpcid_works1) { struct invpcid_descr d; uint64_t kcr3, ucr3; uint32_t pcid; /* * Because pm_pcid is recalculated on a context switch, we * must ensure there is no preemption, not just pinning. * Otherwise, we might use a stale value below. */ CRITICAL_ASSERT(curthread); /* * No need to do anything with user page tables invalidation * if there is no user page table, or invalidation is deferred * until the return to userspace. ucr3_load_mask is stable * because we have preemption disabled. */ if (pmap->pm_ucr3 == PMAP_NO_CR3 || PCPU_GET(ucr3_load_mask) != PMAP_UCR3_NOMASK) return; pcid = pmap_get_pcid(pmap); if (invpcid_works1) { d.pcid = pcid | PMAP_PCID_USER_PT; d.pad = 0; d.addr = va; invpcid(&d, INVPCID_ADDR); } else { kcr3 = pmap->pm_cr3 | pcid | CR3_PCID_SAVE; ucr3 = pmap->pm_ucr3 | pcid | PMAP_PCID_USER_PT | CR3_PCID_SAVE; pmap_pti_pcid_invlpg(ucr3, kcr3, va); } } static void pmap_invalidate_page_pcid_invpcid_cb(pmap_t pmap, vm_offset_t va) { pmap_invalidate_page_pcid_cb(pmap, va, true); } static void pmap_invalidate_page_pcid_noinvpcid_cb(pmap_t pmap, vm_offset_t va) { pmap_invalidate_page_pcid_cb(pmap, va, false); } static void pmap_invalidate_page_nopcid_cb(pmap_t pmap __unused, vm_offset_t va __unused) { } DEFINE_IFUNC(static, void, pmap_invalidate_page_cb, (pmap_t, vm_offset_t)) { if (pmap_pcid_enabled) return (invpcid_works ? pmap_invalidate_page_pcid_invpcid_cb : pmap_invalidate_page_pcid_noinvpcid_cb); return (pmap_invalidate_page_nopcid_cb); } static void pmap_invalidate_page_curcpu_cb(pmap_t pmap, vm_offset_t va, vm_offset_t addr2 __unused) { if (pmap == kernel_pmap) { pmap_invlpg(kernel_pmap, va); } else if (pmap == PCPU_GET(curpmap)) { invlpg(va); pmap_invalidate_page_cb(pmap, va); } } void pmap_invalidate_page(pmap_t pmap, vm_offset_t va) { if (pmap_type_guest(pmap)) { pmap_invalidate_ept(pmap); return; } KASSERT(pmap->pm_type == PT_X86, ("pmap_invalidate_page: invalid type %d", pmap->pm_type)); pmap_invalidate_preipi(pmap); smp_masked_invlpg(va, pmap, pmap_invalidate_page_curcpu_cb); } /* 4k PTEs -- Chosen to exceed the total size of Broadwell L2 TLB */ #define PMAP_INVLPG_THRESHOLD (4 * 1024 * PAGE_SIZE) static void pmap_invalidate_range_pcid_cb(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, const bool invpcid_works1) { struct invpcid_descr d; uint64_t kcr3, ucr3; uint32_t pcid; CRITICAL_ASSERT(curthread); if (pmap != PCPU_GET(curpmap) || pmap->pm_ucr3 == PMAP_NO_CR3 || PCPU_GET(ucr3_load_mask) != PMAP_UCR3_NOMASK) return; pcid = pmap_get_pcid(pmap); if (invpcid_works1) { d.pcid = pcid | PMAP_PCID_USER_PT; d.pad = 0; for (d.addr = sva; d.addr < eva; d.addr += PAGE_SIZE) invpcid(&d, INVPCID_ADDR); } else { kcr3 = pmap->pm_cr3 | pcid | CR3_PCID_SAVE; ucr3 = pmap->pm_ucr3 | pcid | PMAP_PCID_USER_PT | CR3_PCID_SAVE; pmap_pti_pcid_invlrng(ucr3, kcr3, sva, eva); } } static void pmap_invalidate_range_pcid_invpcid_cb(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { pmap_invalidate_range_pcid_cb(pmap, sva, eva, true); } static void pmap_invalidate_range_pcid_noinvpcid_cb(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { pmap_invalidate_range_pcid_cb(pmap, sva, eva, false); } static void pmap_invalidate_range_nopcid_cb(pmap_t pmap __unused, vm_offset_t sva __unused, vm_offset_t eva __unused) { } DEFINE_IFUNC(static, void, pmap_invalidate_range_cb, (pmap_t, vm_offset_t, vm_offset_t)) { if (pmap_pcid_enabled) return (invpcid_works ? pmap_invalidate_range_pcid_invpcid_cb : pmap_invalidate_range_pcid_noinvpcid_cb); return (pmap_invalidate_range_nopcid_cb); } static void pmap_invalidate_range_curcpu_cb(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { vm_offset_t addr; if (pmap == kernel_pmap) { if (PCPU_GET(pcid_invlpg_workaround)) { struct invpcid_descr d = { 0 }; invpcid(&d, INVPCID_CTXGLOB); } else { for (addr = sva; addr < eva; addr += PAGE_SIZE) invlpg(addr); } } else if (pmap == PCPU_GET(curpmap)) { for (addr = sva; addr < eva; addr += PAGE_SIZE) invlpg(addr); pmap_invalidate_range_cb(pmap, sva, eva); } } void pmap_invalidate_range(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { if (eva - sva >= PMAP_INVLPG_THRESHOLD) { pmap_invalidate_all(pmap); return; } if (pmap_type_guest(pmap)) { pmap_invalidate_ept(pmap); return; } KASSERT(pmap->pm_type == PT_X86, ("pmap_invalidate_range: invalid type %d", pmap->pm_type)); pmap_invalidate_preipi(pmap); smp_masked_invlpg_range(sva, eva, pmap, pmap_invalidate_range_curcpu_cb); } static inline void pmap_invalidate_all_pcid_cb(pmap_t pmap, bool invpcid_works1) { struct invpcid_descr d; uint64_t kcr3; uint32_t pcid; if (pmap == kernel_pmap) { if (invpcid_works1) { bzero(&d, sizeof(d)); invpcid(&d, INVPCID_CTXGLOB); } else { invltlb_glob(); } } else if (pmap == PCPU_GET(curpmap)) { CRITICAL_ASSERT(curthread); pcid = pmap_get_pcid(pmap); if (invpcid_works1) { d.pcid = pcid; d.pad = 0; d.addr = 0; invpcid(&d, INVPCID_CTX); } else { kcr3 = pmap->pm_cr3 | pcid; load_cr3(kcr3); } if (pmap->pm_ucr3 != PMAP_NO_CR3) PCPU_SET(ucr3_load_mask, ~CR3_PCID_SAVE); } } static void pmap_invalidate_all_pcid_invpcid_cb(pmap_t pmap) { pmap_invalidate_all_pcid_cb(pmap, true); } static void pmap_invalidate_all_pcid_noinvpcid_cb(pmap_t pmap) { pmap_invalidate_all_pcid_cb(pmap, false); } static void pmap_invalidate_all_nopcid_cb(pmap_t pmap) { if (pmap == kernel_pmap) invltlb_glob(); else if (pmap == PCPU_GET(curpmap)) invltlb(); } DEFINE_IFUNC(static, void, pmap_invalidate_all_cb, (pmap_t)) { if (pmap_pcid_enabled) return (invpcid_works ? pmap_invalidate_all_pcid_invpcid_cb : pmap_invalidate_all_pcid_noinvpcid_cb); return (pmap_invalidate_all_nopcid_cb); } static void pmap_invalidate_all_curcpu_cb(pmap_t pmap, vm_offset_t addr1 __unused, vm_offset_t addr2 __unused) { pmap_invalidate_all_cb(pmap); } void pmap_invalidate_all(pmap_t pmap) { if (pmap_type_guest(pmap)) { pmap_invalidate_ept(pmap); return; } KASSERT(pmap->pm_type == PT_X86, ("pmap_invalidate_all: invalid type %d", pmap->pm_type)); pmap_invalidate_preipi(pmap); smp_masked_invltlb(pmap, pmap_invalidate_all_curcpu_cb); } static void pmap_invalidate_cache_curcpu_cb(pmap_t pmap __unused, vm_offset_t va __unused, vm_offset_t addr2 __unused) { wbinvd(); } void pmap_invalidate_cache(void) { sched_pin(); smp_cache_flush(pmap_invalidate_cache_curcpu_cb); } struct pde_action { cpuset_t invalidate; /* processors that invalidate their TLB */ pmap_t pmap; vm_offset_t va; pd_entry_t *pde; pd_entry_t newpde; u_int store; /* processor that updates the PDE */ }; static void pmap_update_pde_action(void *arg) { struct pde_action *act = arg; if (act->store == PCPU_GET(cpuid)) pmap_update_pde_store(act->pmap, act->pde, act->newpde); } static void pmap_update_pde_teardown(void *arg) { struct pde_action *act = arg; if (CPU_ISSET(PCPU_GET(cpuid), &act->invalidate)) pmap_update_pde_invalidate(act->pmap, act->va, act->newpde); } /* * Change the page size for the specified virtual address in a way that * prevents any possibility of the TLB ever having two entries that map the * same virtual address using different page sizes. This is the recommended * workaround for Erratum 383 on AMD Family 10h processors. It prevents a * machine check exception for a TLB state that is improperly diagnosed as a * hardware error. */ static void pmap_update_pde(pmap_t pmap, vm_offset_t va, pd_entry_t *pde, pd_entry_t newpde) { struct pde_action act; cpuset_t active, other_cpus; u_int cpuid; sched_pin(); cpuid = PCPU_GET(cpuid); other_cpus = all_cpus; CPU_CLR(cpuid, &other_cpus); if (pmap == kernel_pmap || pmap_type_guest(pmap)) active = all_cpus; else { active = pmap->pm_active; } if (CPU_OVERLAP(&active, &other_cpus)) { act.store = cpuid; act.invalidate = active; act.va = va; act.pmap = pmap; act.pde = pde; act.newpde = newpde; CPU_SET(cpuid, &active); smp_rendezvous_cpus(active, smp_no_rendezvous_barrier, pmap_update_pde_action, pmap_update_pde_teardown, &act); } else { pmap_update_pde_store(pmap, pde, newpde); if (CPU_ISSET(cpuid, &active)) pmap_update_pde_invalidate(pmap, va, newpde); } sched_unpin(); } #else /* !SMP */ /* * Normal, non-SMP, invalidation functions. */ void pmap_invalidate_page(pmap_t pmap, vm_offset_t va) { struct invpcid_descr d; struct pmap_pcid *pcidp; uint64_t kcr3, ucr3; uint32_t pcid; if (pmap->pm_type == PT_RVI || pmap->pm_type == PT_EPT) { pmap->pm_eptgen++; return; } KASSERT(pmap->pm_type == PT_X86, ("pmap_invalidate_range: unknown type %d", pmap->pm_type)); if (pmap == kernel_pmap || pmap == PCPU_GET(curpmap)) { invlpg(va); if (pmap == PCPU_GET(curpmap) && pmap_pcid_enabled && pmap->pm_ucr3 != PMAP_NO_CR3) { critical_enter(); pcid = pmap_get_pcid(pmap); if (invpcid_works) { d.pcid = pcid | PMAP_PCID_USER_PT; d.pad = 0; d.addr = va; invpcid(&d, INVPCID_ADDR); } else { kcr3 = pmap->pm_cr3 | pcid | CR3_PCID_SAVE; ucr3 = pmap->pm_ucr3 | pcid | PMAP_PCID_USER_PT | CR3_PCID_SAVE; pmap_pti_pcid_invlpg(ucr3, kcr3, va); } critical_exit(); } } else if (pmap_pcid_enabled) { pcidp = zpcpu_get(pmap->pm_pcidp); pcidp->pm_gen = 0; } } void pmap_invalidate_range(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { struct invpcid_descr d; struct pmap_pcid *pcidp; vm_offset_t addr; uint64_t kcr3, ucr3; uint32_t pcid; if (pmap->pm_type == PT_RVI || pmap->pm_type == PT_EPT) { pmap->pm_eptgen++; return; } KASSERT(pmap->pm_type == PT_X86, ("pmap_invalidate_range: unknown type %d", pmap->pm_type)); if (pmap == kernel_pmap || pmap == PCPU_GET(curpmap)) { for (addr = sva; addr < eva; addr += PAGE_SIZE) invlpg(addr); if (pmap == PCPU_GET(curpmap) && pmap_pcid_enabled && pmap->pm_ucr3 != PMAP_NO_CR3) { critical_enter(); pcid = pmap_get_pcid(pmap); if (invpcid_works) { d.pcid = pcid | PMAP_PCID_USER_PT; d.pad = 0; d.addr = sva; for (; d.addr < eva; d.addr += PAGE_SIZE) invpcid(&d, INVPCID_ADDR); } else { kcr3 = pmap->pm_cr3 | pcid | CR3_PCID_SAVE; ucr3 = pmap->pm_ucr3 | pcid | PMAP_PCID_USER_PT | CR3_PCID_SAVE; pmap_pti_pcid_invlrng(ucr3, kcr3, sva, eva); } critical_exit(); } } else if (pmap_pcid_enabled) { pcidp = zpcpu_get(pmap->pm_pcidp); pcidp->pm_gen = 0; } } void pmap_invalidate_all(pmap_t pmap) { struct invpcid_descr d; struct pmap_pcid *pcidp; uint64_t kcr3, ucr3; uint32_t pcid; if (pmap->pm_type == PT_RVI || pmap->pm_type == PT_EPT) { pmap->pm_eptgen++; return; } KASSERT(pmap->pm_type == PT_X86, ("pmap_invalidate_all: unknown type %d", pmap->pm_type)); if (pmap == kernel_pmap) { if (pmap_pcid_enabled && invpcid_works) { bzero(&d, sizeof(d)); invpcid(&d, INVPCID_CTXGLOB); } else { invltlb_glob(); } } else if (pmap == PCPU_GET(curpmap)) { if (pmap_pcid_enabled) { critical_enter(); pcid = pmap_get_pcid(pmap); if (invpcid_works) { d.pcid = pcid; d.pad = 0; d.addr = 0; invpcid(&d, INVPCID_CTX); if (pmap->pm_ucr3 != PMAP_NO_CR3) { d.pcid |= PMAP_PCID_USER_PT; invpcid(&d, INVPCID_CTX); } } else { kcr3 = pmap->pm_cr3 | pcid; if (pmap->pm_ucr3 != PMAP_NO_CR3) { ucr3 = pmap->pm_ucr3 | pcid | PMAP_PCID_USER_PT; pmap_pti_pcid_invalidate(ucr3, kcr3); } else load_cr3(kcr3); } critical_exit(); } else { invltlb(); } } else if (pmap_pcid_enabled) { pcidp = zpcpu_get(pmap->pm_pcidp); pcidp->pm_gen = 0; } } PMAP_INLINE void pmap_invalidate_cache(void) { wbinvd(); } static void pmap_update_pde(pmap_t pmap, vm_offset_t va, pd_entry_t *pde, pd_entry_t newpde) { struct pmap_pcid *pcidp; pmap_update_pde_store(pmap, pde, newpde); if (pmap == kernel_pmap || pmap == PCPU_GET(curpmap)) pmap_update_pde_invalidate(pmap, va, newpde); else { pcidp = zpcpu_get(pmap->pm_pcidp); pcidp->pm_gen = 0; } } #endif /* !SMP */ static void pmap_invalidate_pde_page(pmap_t pmap, vm_offset_t va, pd_entry_t pde) { /* * When the PDE has PG_PROMOTED set, the 2MB page mapping was created * by a promotion that did not invalidate the 512 4KB page mappings * that might exist in the TLB. Consequently, at this point, the TLB * may hold both 4KB and 2MB page mappings for the address range [va, * va + NBPDR). Therefore, the entire range must be invalidated here. * In contrast, when PG_PROMOTED is clear, the TLB will not hold any * 4KB page mappings for the address range [va, va + NBPDR), and so a * single INVLPG suffices to invalidate the 2MB page mapping from the * TLB. */ if ((pde & PG_PROMOTED) != 0) pmap_invalidate_range(pmap, va, va + NBPDR - 1); else pmap_invalidate_page(pmap, va); } DEFINE_IFUNC(, void, pmap_invalidate_cache_range, (vm_offset_t sva, vm_offset_t eva)) { if ((cpu_feature & CPUID_SS) != 0) return (pmap_invalidate_cache_range_selfsnoop); if ((cpu_feature & CPUID_CLFSH) != 0) return (pmap_force_invalidate_cache_range); return (pmap_invalidate_cache_range_all); } #define PMAP_CLFLUSH_THRESHOLD (2 * 1024 * 1024) static void pmap_invalidate_cache_range_check_align(vm_offset_t sva, vm_offset_t eva) { KASSERT((sva & PAGE_MASK) == 0, ("pmap_invalidate_cache_range: sva not page-aligned")); KASSERT((eva & PAGE_MASK) == 0, ("pmap_invalidate_cache_range: eva not page-aligned")); } static void pmap_invalidate_cache_range_selfsnoop(vm_offset_t sva, vm_offset_t eva) { pmap_invalidate_cache_range_check_align(sva, eva); } void pmap_force_invalidate_cache_range(vm_offset_t sva, vm_offset_t eva) { sva &= ~(vm_offset_t)(cpu_clflush_line_size - 1); /* * XXX: Some CPUs fault, hang, or trash the local APIC * registers if we use CLFLUSH on the local APIC range. The * local APIC is always uncached, so we don't need to flush * for that range anyway. */ if (pmap_kextract(sva) == lapic_paddr) return; if ((cpu_stdext_feature & CPUID_STDEXT_CLFLUSHOPT) != 0) { /* * Do per-cache line flush. Use a locked * instruction to insure that previous stores are * included in the write-back. The processor * propagates flush to other processors in the cache * coherence domain. */ atomic_thread_fence_seq_cst(); for (; sva < eva; sva += cpu_clflush_line_size) clflushopt(sva); atomic_thread_fence_seq_cst(); } else { /* * Writes are ordered by CLFLUSH on Intel CPUs. */ if (cpu_vendor_id != CPU_VENDOR_INTEL) mfence(); for (; sva < eva; sva += cpu_clflush_line_size) clflush(sva); if (cpu_vendor_id != CPU_VENDOR_INTEL) mfence(); } } static void pmap_invalidate_cache_range_all(vm_offset_t sva, vm_offset_t eva) { pmap_invalidate_cache_range_check_align(sva, eva); pmap_invalidate_cache(); } /* * Remove the specified set of pages from the data and instruction caches. * * In contrast to pmap_invalidate_cache_range(), this function does not * rely on the CPU's self-snoop feature, because it is intended for use * when moving pages into a different cache domain. */ void pmap_invalidate_cache_pages(vm_page_t *pages, int count) { vm_offset_t daddr, eva; int i; bool useclflushopt; useclflushopt = (cpu_stdext_feature & CPUID_STDEXT_CLFLUSHOPT) != 0; if (count >= PMAP_CLFLUSH_THRESHOLD / PAGE_SIZE || ((cpu_feature & CPUID_CLFSH) == 0 && !useclflushopt)) pmap_invalidate_cache(); else { if (useclflushopt) atomic_thread_fence_seq_cst(); else if (cpu_vendor_id != CPU_VENDOR_INTEL) mfence(); for (i = 0; i < count; i++) { daddr = PHYS_TO_DMAP(VM_PAGE_TO_PHYS(pages[i])); eva = daddr + PAGE_SIZE; for (; daddr < eva; daddr += cpu_clflush_line_size) { if (useclflushopt) clflushopt(daddr); else clflush(daddr); } } if (useclflushopt) atomic_thread_fence_seq_cst(); else if (cpu_vendor_id != CPU_VENDOR_INTEL) mfence(); } } void pmap_flush_cache_range(vm_offset_t sva, vm_offset_t eva) { pmap_invalidate_cache_range_check_align(sva, eva); if ((cpu_stdext_feature & CPUID_STDEXT_CLWB) == 0) { pmap_force_invalidate_cache_range(sva, eva); return; } /* See comment in pmap_force_invalidate_cache_range(). */ if (pmap_kextract(sva) == lapic_paddr) return; atomic_thread_fence_seq_cst(); for (; sva < eva; sva += cpu_clflush_line_size) clwb(sva); atomic_thread_fence_seq_cst(); } void pmap_flush_cache_phys_range(vm_paddr_t spa, vm_paddr_t epa, vm_memattr_t mattr) { pt_entry_t *pte; vm_offset_t vaddr; int error __diagused; int pte_bits; KASSERT((spa & PAGE_MASK) == 0, ("pmap_flush_cache_phys_range: spa not page-aligned")); KASSERT((epa & PAGE_MASK) == 0, ("pmap_flush_cache_phys_range: epa not page-aligned")); if (spa < dmaplimit) { pmap_flush_cache_range(PHYS_TO_DMAP(spa), PHYS_TO_DMAP(MIN( dmaplimit, epa))); if (dmaplimit >= epa) return; spa = dmaplimit; } pte_bits = pmap_cache_bits(kernel_pmap, mattr, 0) | X86_PG_RW | X86_PG_V; error = vmem_alloc(kernel_arena, PAGE_SIZE, M_BESTFIT | M_WAITOK, &vaddr); KASSERT(error == 0, ("vmem_alloc failed: %d", error)); pte = vtopte(vaddr); for (; spa < epa; spa += PAGE_SIZE) { sched_pin(); pte_store(pte, spa | pte_bits); pmap_invlpg(kernel_pmap, vaddr); /* XXXKIB atomic inside flush_cache_range are excessive */ pmap_flush_cache_range(vaddr, vaddr + PAGE_SIZE); sched_unpin(); } vmem_free(kernel_arena, vaddr, PAGE_SIZE); } /* * Routine: pmap_extract * Function: * Extract the physical page address associated * with the given map/virtual_address pair. */ vm_paddr_t pmap_extract(pmap_t pmap, vm_offset_t va) { pdp_entry_t *pdpe; pd_entry_t *pde; pt_entry_t *pte, PG_V; vm_paddr_t pa; pa = 0; PG_V = pmap_valid_bit(pmap); PMAP_LOCK(pmap); pdpe = pmap_pdpe(pmap, va); if (pdpe != NULL && (*pdpe & PG_V) != 0) { if ((*pdpe & PG_PS) != 0) pa = (*pdpe & PG_PS_FRAME) | (va & PDPMASK); else { pde = pmap_pdpe_to_pde(pdpe, va); if ((*pde & PG_V) != 0) { if ((*pde & PG_PS) != 0) { pa = (*pde & PG_PS_FRAME) | (va & PDRMASK); } else { pte = pmap_pde_to_pte(pde, va); pa = (*pte & PG_FRAME) | (va & PAGE_MASK); } } } } PMAP_UNLOCK(pmap); return (pa); } /* * Routine: pmap_extract_and_hold * Function: * Atomically extract and hold the physical page * with the given pmap and virtual address pair * if that mapping permits the given protection. */ vm_page_t pmap_extract_and_hold(pmap_t pmap, vm_offset_t va, vm_prot_t prot) { pdp_entry_t pdpe, *pdpep; pd_entry_t pde, *pdep; pt_entry_t pte, PG_RW, PG_V; vm_page_t m; m = NULL; PG_RW = pmap_rw_bit(pmap); PG_V = pmap_valid_bit(pmap); PMAP_LOCK(pmap); pdpep = pmap_pdpe(pmap, va); if (pdpep == NULL || ((pdpe = *pdpep) & PG_V) == 0) goto out; if ((pdpe & PG_PS) != 0) { if ((pdpe & PG_RW) == 0 && (prot & VM_PROT_WRITE) != 0) goto out; m = PHYS_TO_VM_PAGE((pdpe & PG_PS_FRAME) | (va & PDPMASK)); goto check_page; } pdep = pmap_pdpe_to_pde(pdpep, va); if (pdep == NULL || ((pde = *pdep) & PG_V) == 0) goto out; if ((pde & PG_PS) != 0) { if ((pde & PG_RW) == 0 && (prot & VM_PROT_WRITE) != 0) goto out; m = PHYS_TO_VM_PAGE((pde & PG_PS_FRAME) | (va & PDRMASK)); goto check_page; } pte = *pmap_pde_to_pte(pdep, va); if ((pte & PG_V) == 0 || ((pte & PG_RW) == 0 && (prot & VM_PROT_WRITE) != 0)) goto out; m = PHYS_TO_VM_PAGE(pte & PG_FRAME); check_page: if (m != NULL && !vm_page_wire_mapped(m)) m = NULL; out: PMAP_UNLOCK(pmap); return (m); } vm_paddr_t pmap_kextract(vm_offset_t va) { pd_entry_t pde; vm_paddr_t pa; if (va >= DMAP_MIN_ADDRESS && va < DMAP_MAX_ADDRESS) { pa = DMAP_TO_PHYS(va); } else if (PMAP_ADDRESS_IN_LARGEMAP(va)) { pa = pmap_large_map_kextract(va); } else { pde = *vtopde(va); if (pde & PG_PS) { pa = (pde & PG_PS_FRAME) | (va & PDRMASK); } else { /* * Beware of a concurrent promotion that changes the * PDE at this point! For example, vtopte() must not * be used to access the PTE because it would use the * new PDE. It is, however, safe to use the old PDE * because the page table page is preserved by the * promotion. */ pa = *pmap_pde_to_pte(&pde, va); pa = (pa & PG_FRAME) | (va & PAGE_MASK); } } return (pa); } /*************************************************** * Low level mapping routines..... ***************************************************/ /* * Add a wired page to the kva. * Note: not SMP coherent. */ PMAP_INLINE void pmap_kenter(vm_offset_t va, vm_paddr_t pa) { pt_entry_t *pte; pte = vtopte(va); pte_store(pte, pa | pg_g | pg_nx | X86_PG_A | X86_PG_M | X86_PG_RW | X86_PG_V); } static __inline void pmap_kenter_attr(vm_offset_t va, vm_paddr_t pa, int mode) { pt_entry_t *pte; int cache_bits; pte = vtopte(va); cache_bits = pmap_cache_bits(kernel_pmap, mode, 0); pte_store(pte, pa | pg_g | pg_nx | X86_PG_A | X86_PG_M | X86_PG_RW | X86_PG_V | cache_bits); } /* * Remove a page from the kernel pagetables. * Note: not SMP coherent. */ PMAP_INLINE void pmap_kremove(vm_offset_t va) { pt_entry_t *pte; pte = vtopte(va); pte_clear(pte); } /* * Used to map a range of physical addresses into kernel * virtual address space. * * The value passed in '*virt' is a suggested virtual address for * the mapping. Architectures which can support a direct-mapped * physical to virtual region can return the appropriate address * within that region, leaving '*virt' unchanged. Other * architectures should map the pages starting at '*virt' and * update '*virt' with the first usable address after the mapped * region. */ vm_offset_t pmap_map(vm_offset_t *virt, vm_paddr_t start, vm_paddr_t end, int prot) { return PHYS_TO_DMAP(start); } /* * Add a list of wired pages to the kva * this routine is only used for temporary * kernel mappings that do not need to have * page modification or references recorded. * Note that old mappings are simply written * over. The page *must* be wired. * Note: SMP coherent. Uses a ranged shootdown IPI. */ void pmap_qenter(vm_offset_t sva, vm_page_t *ma, int count) { pt_entry_t *endpte, oldpte, pa, *pte; vm_page_t m; int cache_bits; oldpte = 0; pte = vtopte(sva); endpte = pte + count; while (pte < endpte) { m = *ma++; cache_bits = pmap_cache_bits(kernel_pmap, m->md.pat_mode, 0); pa = VM_PAGE_TO_PHYS(m) | cache_bits; if ((*pte & (PG_FRAME | X86_PG_PTE_CACHE)) != pa) { oldpte |= *pte; pte_store(pte, pa | pg_g | pg_nx | X86_PG_A | X86_PG_M | X86_PG_RW | X86_PG_V); } pte++; } if (__predict_false((oldpte & X86_PG_V) != 0)) pmap_invalidate_range(kernel_pmap, sva, sva + count * PAGE_SIZE); } /* * This routine tears out page mappings from the * kernel -- it is meant only for temporary mappings. * Note: SMP coherent. Uses a ranged shootdown IPI. */ void pmap_qremove(vm_offset_t sva, int count) { vm_offset_t va; va = sva; while (count-- > 0) { KASSERT(va >= VM_MIN_KERNEL_ADDRESS, ("usermode va %lx", va)); pmap_kremove(va); va += PAGE_SIZE; } pmap_invalidate_range(kernel_pmap, sva, va); } /*************************************************** * Page table page management routines..... ***************************************************/ /* * Schedule the specified unused page table page to be freed. Specifically, * add the page to the specified list of pages that will be released to the * physical memory manager after the TLB has been updated. */ static __inline void pmap_add_delayed_free_list(vm_page_t m, struct spglist *free, boolean_t set_PG_ZERO) { if (set_PG_ZERO) m->flags |= PG_ZERO; else m->flags &= ~PG_ZERO; SLIST_INSERT_HEAD(free, m, plinks.s.ss); } /* * Inserts the specified page table page into the specified pmap's collection * of idle page table pages. Each of a pmap's page table pages is responsible * for mapping a distinct range of virtual addresses. The pmap's collection is * ordered by this virtual address range. * * If "promoted" is false, then the page table page "mpte" must be zero filled; * "mpte"'s valid field will be set to 0. * * If "promoted" is true and "allpte_PG_A_set" is false, then "mpte" must * contain valid mappings with identical attributes except for PG_A; "mpte"'s * valid field will be set to 1. * * If "promoted" and "allpte_PG_A_set" are both true, then "mpte" must contain * valid mappings with identical attributes including PG_A; "mpte"'s valid * field will be set to VM_PAGE_BITS_ALL. */ static __inline int pmap_insert_pt_page(pmap_t pmap, vm_page_t mpte, bool promoted, bool allpte_PG_A_set) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT(promoted || !allpte_PG_A_set, ("a zero-filled PTP can't have PG_A set in every PTE")); mpte->valid = promoted ? (allpte_PG_A_set ? VM_PAGE_BITS_ALL : 1) : 0; return (vm_radix_insert(&pmap->pm_root, mpte)); } /* * Removes the page table page mapping the specified virtual address from the * specified pmap's collection of idle page table pages, and returns it. * Otherwise, returns NULL if there is no page table page corresponding to the * specified virtual address. */ static __inline vm_page_t pmap_remove_pt_page(pmap_t pmap, vm_offset_t va) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); return (vm_radix_remove(&pmap->pm_root, pmap_pde_pindex(va))); } /* * Decrements a page table page's reference count, which is used to record the * number of valid page table entries within the page. If the reference count * drops to zero, then the page table page is unmapped. Returns TRUE if the * page table page was unmapped and FALSE otherwise. */ static inline boolean_t pmap_unwire_ptp(pmap_t pmap, vm_offset_t va, vm_page_t m, struct spglist *free) { --m->ref_count; if (m->ref_count == 0) { _pmap_unwire_ptp(pmap, va, m, free); return (TRUE); } else return (FALSE); } static void _pmap_unwire_ptp(pmap_t pmap, vm_offset_t va, vm_page_t m, struct spglist *free) { pml5_entry_t *pml5; pml4_entry_t *pml4; pdp_entry_t *pdp; pd_entry_t *pd; vm_page_t pdpg, pdppg, pml4pg; PMAP_LOCK_ASSERT(pmap, MA_OWNED); /* * unmap the page table page */ if (m->pindex >= NUPDE + NUPDPE + NUPML4E) { /* PML4 page */ MPASS(pmap_is_la57(pmap)); pml5 = pmap_pml5e(pmap, va); *pml5 = 0; if (pmap->pm_pmltopu != NULL && va <= VM_MAXUSER_ADDRESS) { pml5 = pmap_pml5e_u(pmap, va); *pml5 = 0; } } else if (m->pindex >= NUPDE + NUPDPE) { /* PDP page */ pml4 = pmap_pml4e(pmap, va); *pml4 = 0; if (!pmap_is_la57(pmap) && pmap->pm_pmltopu != NULL && va <= VM_MAXUSER_ADDRESS) { pml4 = pmap_pml4e_u(pmap, va); *pml4 = 0; } } else if (m->pindex >= NUPDE) { /* PD page */ pdp = pmap_pdpe(pmap, va); *pdp = 0; } else { /* PTE page */ pd = pmap_pde(pmap, va); *pd = 0; } if (m->pindex < NUPDE) { /* We just released a PT, unhold the matching PD */ pdpg = PHYS_TO_VM_PAGE(*pmap_pdpe(pmap, va) & PG_FRAME); pmap_unwire_ptp(pmap, va, pdpg, free); } else if (m->pindex < NUPDE + NUPDPE) { /* We just released a PD, unhold the matching PDP */ pdppg = PHYS_TO_VM_PAGE(*pmap_pml4e(pmap, va) & PG_FRAME); pmap_unwire_ptp(pmap, va, pdppg, free); } else if (m->pindex < NUPDE + NUPDPE + NUPML4E && pmap_is_la57(pmap)) { /* We just released a PDP, unhold the matching PML4 */ pml4pg = PHYS_TO_VM_PAGE(*pmap_pml5e(pmap, va) & PG_FRAME); pmap_unwire_ptp(pmap, va, pml4pg, free); } pmap_pt_page_count_adj(pmap, -1); /* * Put page on a list so that it is released after * *ALL* TLB shootdown is done */ pmap_add_delayed_free_list(m, free, TRUE); } /* * After removing a page table entry, this routine is used to * conditionally free the page, and manage the reference count. */ static int pmap_unuse_pt(pmap_t pmap, vm_offset_t va, pd_entry_t ptepde, struct spglist *free) { vm_page_t mpte; if (va >= VM_MAXUSER_ADDRESS) return (0); KASSERT(ptepde != 0, ("pmap_unuse_pt: ptepde != 0")); mpte = PHYS_TO_VM_PAGE(ptepde & PG_FRAME); return (pmap_unwire_ptp(pmap, va, mpte, free)); } /* * Release a page table page reference after a failed attempt to create a * mapping. */ static void pmap_abort_ptp(pmap_t pmap, vm_offset_t va, vm_page_t mpte) { struct spglist free; SLIST_INIT(&free); if (pmap_unwire_ptp(pmap, va, mpte, &free)) { /* * Although "va" was never mapped, paging-structure caches * could nonetheless have entries that refer to the freed * page table pages. Invalidate those entries. */ pmap_invalidate_page(pmap, va); vm_page_free_pages_toq(&free, true); } } static void pmap_pinit_pcids(pmap_t pmap, uint32_t pcid, int gen) { struct pmap_pcid *pcidp; int i; CPU_FOREACH(i) { pcidp = zpcpu_get_cpu(pmap->pm_pcidp, i); pcidp->pm_pcid = pcid; pcidp->pm_gen = gen; } } void pmap_pinit0(pmap_t pmap) { struct proc *p; struct thread *td; PMAP_LOCK_INIT(pmap); pmap->pm_pmltop = kernel_pmap->pm_pmltop; pmap->pm_pmltopu = NULL; pmap->pm_cr3 = kernel_pmap->pm_cr3; /* hack to keep pmap_pti_pcid_invalidate() alive */ pmap->pm_ucr3 = PMAP_NO_CR3; vm_radix_init(&pmap->pm_root); CPU_ZERO(&pmap->pm_active); TAILQ_INIT(&pmap->pm_pvchunk); bzero(&pmap->pm_stats, sizeof pmap->pm_stats); pmap->pm_flags = pmap_flags; pmap->pm_pcidp = uma_zalloc_pcpu(pcpu_zone_8, M_WAITOK); pmap_pinit_pcids(pmap, PMAP_PCID_KERN + 1, 1); pmap_activate_boot(pmap); td = curthread; if (pti) { p = td->td_proc; PROC_LOCK(p); p->p_md.md_flags |= P_MD_KPTI; PROC_UNLOCK(p); } pmap_thread_init_invl_gen(td); if ((cpu_stdext_feature2 & CPUID_STDEXT2_PKU) != 0) { pmap_pkru_ranges_zone = uma_zcreate("pkru ranges", sizeof(struct pmap_pkru_range), NULL, NULL, NULL, NULL, UMA_ALIGN_PTR, 0); } } void pmap_pinit_pml4(vm_page_t pml4pg) { pml4_entry_t *pm_pml4; int i; pm_pml4 = (pml4_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(pml4pg)); /* Wire in kernel global address entries. */ for (i = 0; i < NKPML4E; i++) { pm_pml4[KPML4BASE + i] = (KPDPphys + ptoa(i)) | X86_PG_RW | X86_PG_V; } #ifdef KASAN for (i = 0; i < NKASANPML4E; i++) { pm_pml4[KASANPML4I + i] = (KASANPDPphys + ptoa(i)) | X86_PG_RW | X86_PG_V | pg_nx; } #endif #ifdef KMSAN for (i = 0; i < NKMSANSHADPML4E; i++) { pm_pml4[KMSANSHADPML4I + i] = (KMSANSHADPDPphys + ptoa(i)) | X86_PG_RW | X86_PG_V | pg_nx; } for (i = 0; i < NKMSANORIGPML4E; i++) { pm_pml4[KMSANORIGPML4I + i] = (KMSANORIGPDPphys + ptoa(i)) | X86_PG_RW | X86_PG_V | pg_nx; } #endif for (i = 0; i < ndmpdpphys; i++) { pm_pml4[DMPML4I + i] = (DMPDPphys + ptoa(i)) | X86_PG_RW | X86_PG_V; } /* install self-referential address mapping entry(s) */ pm_pml4[PML4PML4I] = VM_PAGE_TO_PHYS(pml4pg) | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M; /* install large map entries if configured */ for (i = 0; i < lm_ents; i++) pm_pml4[LMSPML4I + i] = kernel_pmap->pm_pmltop[LMSPML4I + i]; } void pmap_pinit_pml5(vm_page_t pml5pg) { pml5_entry_t *pm_pml5; pm_pml5 = (pml5_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(pml5pg)); /* * Add pml5 entry at top of KVA pointing to existing pml4 table, * entering all existing kernel mappings into level 5 table. */ pm_pml5[pmap_pml5e_index(UPT_MAX_ADDRESS)] = KPML4phys | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M | pg_g | pmap_cache_bits(kernel_pmap, VM_MEMATTR_DEFAULT, FALSE); /* * Install self-referential address mapping entry. */ pm_pml5[PML5PML5I] = VM_PAGE_TO_PHYS(pml5pg) | X86_PG_RW | X86_PG_V | X86_PG_M | X86_PG_A | pmap_cache_bits(kernel_pmap, VM_MEMATTR_DEFAULT, FALSE); } static void pmap_pinit_pml4_pti(vm_page_t pml4pgu) { pml4_entry_t *pm_pml4u; int i; pm_pml4u = (pml4_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(pml4pgu)); for (i = 0; i < NPML4EPG; i++) pm_pml4u[i] = pti_pml4[i]; } static void pmap_pinit_pml5_pti(vm_page_t pml5pgu) { pml5_entry_t *pm_pml5u; pm_pml5u = (pml5_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(pml5pgu)); pagezero(pm_pml5u); /* * Add pml5 entry at top of KVA pointing to existing pml4 pti * table, entering all kernel mappings needed for usermode * into level 5 table. */ pm_pml5u[pmap_pml5e_index(UPT_MAX_ADDRESS)] = pmap_kextract((vm_offset_t)pti_pml4) | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M | pg_g | pmap_cache_bits(kernel_pmap, VM_MEMATTR_DEFAULT, FALSE); } /* Allocate a page table page and do related bookkeeping */ static vm_page_t pmap_alloc_pt_page(pmap_t pmap, vm_pindex_t pindex, int flags) { vm_page_t m; m = vm_page_alloc_noobj(flags); if (__predict_false(m == NULL)) return (NULL); m->pindex = pindex; pmap_pt_page_count_adj(pmap, 1); return (m); } static void pmap_free_pt_page(pmap_t pmap, vm_page_t m, bool zerofilled) { /* * This function assumes the page will need to be unwired, * even though the counterpart allocation in pmap_alloc_pt_page() * doesn't enforce VM_ALLOC_WIRED. However, all current uses * of pmap_free_pt_page() require unwiring. The case in which * a PT page doesn't require unwiring because its ref_count has * naturally reached 0 is handled through _pmap_unwire_ptp(). */ vm_page_unwire_noq(m); if (zerofilled) vm_page_free_zero(m); else vm_page_free(m); pmap_pt_page_count_adj(pmap, -1); } _Static_assert(sizeof(struct pmap_pcid) == 8, "Fix pcpu zone for pm_pcidp"); /* * Initialize a preallocated and zeroed pmap structure, * such as one in a vmspace structure. */ int pmap_pinit_type(pmap_t pmap, enum pmap_type pm_type, int flags) { vm_page_t pmltop_pg, pmltop_pgu; vm_paddr_t pmltop_phys; bzero(&pmap->pm_stats, sizeof pmap->pm_stats); /* * Allocate the page directory page. Pass NULL instead of a * pointer to the pmap here to avoid calling * pmap_resident_count_adj() through pmap_pt_page_count_adj(), * since that requires pmap lock. Instead do the accounting * manually. * * Note that final call to pmap_remove() optimization that * checks for zero resident_count is basically disabled by * accounting for top-level page. But the optimization was * not effective since we started using non-managed mapping of * the shared page. */ pmltop_pg = pmap_alloc_pt_page(NULL, 0, VM_ALLOC_WIRED | VM_ALLOC_ZERO | VM_ALLOC_WAITOK); pmap_pt_page_count_pinit(pmap, 1); pmltop_phys = VM_PAGE_TO_PHYS(pmltop_pg); pmap->pm_pmltop = (pml5_entry_t *)PHYS_TO_DMAP(pmltop_phys); if (pmap_pcid_enabled) { if (pmap->pm_pcidp == NULL) pmap->pm_pcidp = uma_zalloc_pcpu(pcpu_zone_8, M_WAITOK); pmap_pinit_pcids(pmap, PMAP_PCID_NONE, 0); } pmap->pm_cr3 = PMAP_NO_CR3; /* initialize to an invalid value */ pmap->pm_ucr3 = PMAP_NO_CR3; pmap->pm_pmltopu = NULL; pmap->pm_type = pm_type; /* * Do not install the host kernel mappings in the nested page * tables. These mappings are meaningless in the guest physical * address space. * Install minimal kernel mappings in PTI case. */ switch (pm_type) { case PT_X86: pmap->pm_cr3 = pmltop_phys; if (pmap_is_la57(pmap)) pmap_pinit_pml5(pmltop_pg); else pmap_pinit_pml4(pmltop_pg); if ((curproc->p_md.md_flags & P_MD_KPTI) != 0) { /* * As with pmltop_pg, pass NULL instead of a * pointer to the pmap to ensure that the PTI * page counted explicitly. */ pmltop_pgu = pmap_alloc_pt_page(NULL, 0, VM_ALLOC_WIRED | VM_ALLOC_WAITOK); pmap_pt_page_count_pinit(pmap, 1); pmap->pm_pmltopu = (pml4_entry_t *)PHYS_TO_DMAP( VM_PAGE_TO_PHYS(pmltop_pgu)); if (pmap_is_la57(pmap)) pmap_pinit_pml5_pti(pmltop_pgu); else pmap_pinit_pml4_pti(pmltop_pgu); pmap->pm_ucr3 = VM_PAGE_TO_PHYS(pmltop_pgu); } if ((cpu_stdext_feature2 & CPUID_STDEXT2_PKU) != 0) { rangeset_init(&pmap->pm_pkru, pkru_dup_range, pkru_free_range, pmap, M_NOWAIT); } break; case PT_EPT: case PT_RVI: pmap->pm_eptsmr = smr_create("pmap", 0, 0); break; } vm_radix_init(&pmap->pm_root); CPU_ZERO(&pmap->pm_active); TAILQ_INIT(&pmap->pm_pvchunk); pmap->pm_flags = flags; pmap->pm_eptgen = 0; return (1); } int pmap_pinit(pmap_t pmap) { return (pmap_pinit_type(pmap, PT_X86, pmap_flags)); } static void pmap_allocpte_free_unref(pmap_t pmap, vm_offset_t va, pt_entry_t *pte) { vm_page_t mpg; struct spglist free; mpg = PHYS_TO_VM_PAGE(*pte & PG_FRAME); if (mpg->ref_count != 0) return; SLIST_INIT(&free); _pmap_unwire_ptp(pmap, va, mpg, &free); pmap_invalidate_page(pmap, va); vm_page_free_pages_toq(&free, true); } static pml4_entry_t * pmap_allocpte_getpml4(pmap_t pmap, struct rwlock **lockp, vm_offset_t va, bool addref) { vm_pindex_t pml5index; pml5_entry_t *pml5; pml4_entry_t *pml4; vm_page_t pml4pg; pt_entry_t PG_V; bool allocated; if (!pmap_is_la57(pmap)) return (&pmap->pm_pmltop[pmap_pml4e_index(va)]); PG_V = pmap_valid_bit(pmap); pml5index = pmap_pml5e_index(va); pml5 = &pmap->pm_pmltop[pml5index]; if ((*pml5 & PG_V) == 0) { if (pmap_allocpte_nosleep(pmap, pmap_pml5e_pindex(va), lockp, va) == NULL) return (NULL); allocated = true; } else { allocated = false; } pml4 = (pml4_entry_t *)PHYS_TO_DMAP(*pml5 & PG_FRAME); pml4 = &pml4[pmap_pml4e_index(va)]; if ((*pml4 & PG_V) == 0) { pml4pg = PHYS_TO_VM_PAGE(*pml5 & PG_FRAME); if (allocated && !addref) pml4pg->ref_count--; else if (!allocated && addref) pml4pg->ref_count++; } return (pml4); } static pdp_entry_t * pmap_allocpte_getpdp(pmap_t pmap, struct rwlock **lockp, vm_offset_t va, bool addref) { vm_page_t pdppg; pml4_entry_t *pml4; pdp_entry_t *pdp; pt_entry_t PG_V; bool allocated; PG_V = pmap_valid_bit(pmap); pml4 = pmap_allocpte_getpml4(pmap, lockp, va, false); if (pml4 == NULL) return (NULL); if ((*pml4 & PG_V) == 0) { /* Have to allocate a new pdp, recurse */ if (pmap_allocpte_nosleep(pmap, pmap_pml4e_pindex(va), lockp, va) == NULL) { if (pmap_is_la57(pmap)) pmap_allocpte_free_unref(pmap, va, pmap_pml5e(pmap, va)); return (NULL); } allocated = true; } else { allocated = false; } pdp = (pdp_entry_t *)PHYS_TO_DMAP(*pml4 & PG_FRAME); pdp = &pdp[pmap_pdpe_index(va)]; if ((*pdp & PG_V) == 0) { pdppg = PHYS_TO_VM_PAGE(*pml4 & PG_FRAME); if (allocated && !addref) pdppg->ref_count--; else if (!allocated && addref) pdppg->ref_count++; } return (pdp); } /* * The ptepindexes, i.e. page indices, of the page table pages encountered * while translating virtual address va are defined as follows: * - for the page table page (last level), * ptepindex = pmap_pde_pindex(va) = va >> PDRSHIFT, * in other words, it is just the index of the PDE that maps the page * table page. * - for the page directory page, * ptepindex = NUPDE (number of userland PD entries) + * (pmap_pde_index(va) >> NPDEPGSHIFT) * i.e. index of PDPE is put after the last index of PDE, * - for the page directory pointer page, * ptepindex = NUPDE + NUPDPE + (pmap_pde_index(va) >> (NPDEPGSHIFT + * NPML4EPGSHIFT), * i.e. index of pml4e is put after the last index of PDPE, * - for the PML4 page (if LA57 mode is enabled), * ptepindex = NUPDE + NUPDPE + NUPML4E + (pmap_pde_index(va) >> * (NPDEPGSHIFT + NPML4EPGSHIFT + NPML5EPGSHIFT), * i.e. index of pml5e is put after the last index of PML4E. * * Define an order on the paging entries, where all entries of the * same height are put together, then heights are put from deepest to * root. Then ptexpindex is the sequential number of the * corresponding paging entry in this order. * * The values of NUPDE, NUPDPE, and NUPML4E are determined by the size of * LA57 paging structures even in LA48 paging mode. Moreover, the * ptepindexes are calculated as if the paging structures were 5-level * regardless of the actual mode of operation. * * The root page at PML4/PML5 does not participate in this indexing scheme, * since it is statically allocated by pmap_pinit() and not by pmap_allocpte(). */ static vm_page_t pmap_allocpte_nosleep(pmap_t pmap, vm_pindex_t ptepindex, struct rwlock **lockp, vm_offset_t va) { vm_pindex_t pml5index, pml4index; pml5_entry_t *pml5, *pml5u; pml4_entry_t *pml4, *pml4u; pdp_entry_t *pdp; pd_entry_t *pd; vm_page_t m, pdpg; pt_entry_t PG_A, PG_M, PG_RW, PG_V; PMAP_LOCK_ASSERT(pmap, MA_OWNED); PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_RW = pmap_rw_bit(pmap); /* * Allocate a page table page. */ m = pmap_alloc_pt_page(pmap, ptepindex, VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (m == NULL) return (NULL); /* * Map the pagetable page into the process address space, if * it isn't already there. */ if (ptepindex >= NUPDE + NUPDPE + NUPML4E) { MPASS(pmap_is_la57(pmap)); pml5index = pmap_pml5e_index(va); pml5 = &pmap->pm_pmltop[pml5index]; KASSERT((*pml5 & PG_V) == 0, ("pmap %p va %#lx pml5 %#lx", pmap, va, *pml5)); *pml5 = VM_PAGE_TO_PHYS(m) | PG_U | PG_RW | PG_V | PG_A | PG_M; if (pmap->pm_pmltopu != NULL && pml5index < NUPML5E) { if (pmap->pm_ucr3 != PMAP_NO_CR3) *pml5 |= pg_nx; pml5u = &pmap->pm_pmltopu[pml5index]; *pml5u = VM_PAGE_TO_PHYS(m) | PG_U | PG_RW | PG_V | PG_A | PG_M; } } else if (ptepindex >= NUPDE + NUPDPE) { pml4index = pmap_pml4e_index(va); /* Wire up a new PDPE page */ pml4 = pmap_allocpte_getpml4(pmap, lockp, va, true); if (pml4 == NULL) { pmap_free_pt_page(pmap, m, true); return (NULL); } KASSERT((*pml4 & PG_V) == 0, ("pmap %p va %#lx pml4 %#lx", pmap, va, *pml4)); *pml4 = VM_PAGE_TO_PHYS(m) | PG_U | PG_RW | PG_V | PG_A | PG_M; if (!pmap_is_la57(pmap) && pmap->pm_pmltopu != NULL && pml4index < NUPML4E) { /* * PTI: Make all user-space mappings in the * kernel-mode page table no-execute so that * we detect any programming errors that leave * the kernel-mode page table active on return * to user space. */ if (pmap->pm_ucr3 != PMAP_NO_CR3) *pml4 |= pg_nx; pml4u = &pmap->pm_pmltopu[pml4index]; *pml4u = VM_PAGE_TO_PHYS(m) | PG_U | PG_RW | PG_V | PG_A | PG_M; } } else if (ptepindex >= NUPDE) { /* Wire up a new PDE page */ pdp = pmap_allocpte_getpdp(pmap, lockp, va, true); if (pdp == NULL) { pmap_free_pt_page(pmap, m, true); return (NULL); } KASSERT((*pdp & PG_V) == 0, ("pmap %p va %#lx pdp %#lx", pmap, va, *pdp)); *pdp = VM_PAGE_TO_PHYS(m) | PG_U | PG_RW | PG_V | PG_A | PG_M; } else { /* Wire up a new PTE page */ pdp = pmap_allocpte_getpdp(pmap, lockp, va, false); if (pdp == NULL) { pmap_free_pt_page(pmap, m, true); return (NULL); } if ((*pdp & PG_V) == 0) { /* Have to allocate a new pd, recurse */ if (pmap_allocpte_nosleep(pmap, pmap_pdpe_pindex(va), lockp, va) == NULL) { pmap_allocpte_free_unref(pmap, va, pmap_pml4e(pmap, va)); pmap_free_pt_page(pmap, m, true); return (NULL); } } else { /* Add reference to the pd page */ pdpg = PHYS_TO_VM_PAGE(*pdp & PG_FRAME); pdpg->ref_count++; } pd = (pd_entry_t *)PHYS_TO_DMAP(*pdp & PG_FRAME); /* Now we know where the page directory page is */ pd = &pd[pmap_pde_index(va)]; KASSERT((*pd & PG_V) == 0, ("pmap %p va %#lx pd %#lx", pmap, va, *pd)); *pd = VM_PAGE_TO_PHYS(m) | PG_U | PG_RW | PG_V | PG_A | PG_M; } return (m); } /* * This routine is called if the desired page table page does not exist. * * If page table page allocation fails, this routine may sleep before * returning NULL. It sleeps only if a lock pointer was given. Sleep * occurs right before returning to the caller. This way, we never * drop pmap lock to sleep while a page table page has ref_count == 0, * which prevents the page from being freed under us. */ static vm_page_t pmap_allocpte_alloc(pmap_t pmap, vm_pindex_t ptepindex, struct rwlock **lockp, vm_offset_t va) { vm_page_t m; m = pmap_allocpte_nosleep(pmap, ptepindex, lockp, va); if (m == NULL && lockp != NULL) { RELEASE_PV_LIST_LOCK(lockp); PMAP_UNLOCK(pmap); PMAP_ASSERT_NOT_IN_DI(); vm_wait(NULL); PMAP_LOCK(pmap); } return (m); } static pd_entry_t * pmap_alloc_pde(pmap_t pmap, vm_offset_t va, vm_page_t *pdpgp, struct rwlock **lockp) { pdp_entry_t *pdpe, PG_V; pd_entry_t *pde; vm_page_t pdpg; vm_pindex_t pdpindex; PG_V = pmap_valid_bit(pmap); retry: pdpe = pmap_pdpe(pmap, va); if (pdpe != NULL && (*pdpe & PG_V) != 0) { pde = pmap_pdpe_to_pde(pdpe, va); if (va < VM_MAXUSER_ADDRESS) { /* Add a reference to the pd page. */ pdpg = PHYS_TO_VM_PAGE(*pdpe & PG_FRAME); pdpg->ref_count++; } else pdpg = NULL; } else if (va < VM_MAXUSER_ADDRESS) { /* Allocate a pd page. */ pdpindex = pmap_pde_pindex(va) >> NPDPEPGSHIFT; pdpg = pmap_allocpte_alloc(pmap, NUPDE + pdpindex, lockp, va); if (pdpg == NULL) { if (lockp != NULL) goto retry; else return (NULL); } pde = (pd_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(pdpg)); pde = &pde[pmap_pde_index(va)]; } else panic("pmap_alloc_pde: missing page table page for va %#lx", va); *pdpgp = pdpg; return (pde); } static vm_page_t pmap_allocpte(pmap_t pmap, vm_offset_t va, struct rwlock **lockp) { vm_pindex_t ptepindex; pd_entry_t *pd, PG_V; vm_page_t m; PG_V = pmap_valid_bit(pmap); /* * Calculate pagetable page index */ ptepindex = pmap_pde_pindex(va); retry: /* * Get the page directory entry */ pd = pmap_pde(pmap, va); /* * This supports switching from a 2MB page to a * normal 4K page. */ if (pd != NULL && (*pd & (PG_PS | PG_V)) == (PG_PS | PG_V)) { if (!pmap_demote_pde_locked(pmap, pd, va, lockp)) { /* * Invalidation of the 2MB page mapping may have caused * the deallocation of the underlying PD page. */ pd = NULL; } } /* * If the page table page is mapped, we just increment the * hold count, and activate it. */ if (pd != NULL && (*pd & PG_V) != 0) { m = PHYS_TO_VM_PAGE(*pd & PG_FRAME); m->ref_count++; } else { /* * Here if the pte page isn't mapped, or if it has been * deallocated. */ m = pmap_allocpte_alloc(pmap, ptepindex, lockp, va); if (m == NULL && lockp != NULL) goto retry; } return (m); } /*************************************************** * Pmap allocation/deallocation routines. ***************************************************/ /* * Release any resources held by the given physical map. * Called when a pmap initialized by pmap_pinit is being released. * Should only be called if the map contains no valid mappings. */ void pmap_release(pmap_t pmap) { vm_page_t m; int i; KASSERT(vm_radix_is_empty(&pmap->pm_root), ("pmap_release: pmap %p has reserved page table page(s)", pmap)); KASSERT(CPU_EMPTY(&pmap->pm_active), ("releasing active pmap %p", pmap)); m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((vm_offset_t)pmap->pm_pmltop)); if (pmap_is_la57(pmap)) { pmap->pm_pmltop[pmap_pml5e_index(UPT_MAX_ADDRESS)] = 0; pmap->pm_pmltop[PML5PML5I] = 0; } else { for (i = 0; i < NKPML4E; i++) /* KVA */ pmap->pm_pmltop[KPML4BASE + i] = 0; #ifdef KASAN for (i = 0; i < NKASANPML4E; i++) /* KASAN shadow map */ pmap->pm_pmltop[KASANPML4I + i] = 0; #endif #ifdef KMSAN for (i = 0; i < NKMSANSHADPML4E; i++) /* KMSAN shadow map */ pmap->pm_pmltop[KMSANSHADPML4I + i] = 0; for (i = 0; i < NKMSANORIGPML4E; i++) /* KMSAN shadow map */ pmap->pm_pmltop[KMSANORIGPML4I + i] = 0; #endif for (i = 0; i < ndmpdpphys; i++)/* Direct Map */ pmap->pm_pmltop[DMPML4I + i] = 0; pmap->pm_pmltop[PML4PML4I] = 0; /* Recursive Mapping */ for (i = 0; i < lm_ents; i++) /* Large Map */ pmap->pm_pmltop[LMSPML4I + i] = 0; } pmap_free_pt_page(NULL, m, true); pmap_pt_page_count_pinit(pmap, -1); if (pmap->pm_pmltopu != NULL) { m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((vm_offset_t)pmap-> pm_pmltopu)); pmap_free_pt_page(NULL, m, false); pmap_pt_page_count_pinit(pmap, -1); } if (pmap->pm_type == PT_X86 && (cpu_stdext_feature2 & CPUID_STDEXT2_PKU) != 0) rangeset_fini(&pmap->pm_pkru); KASSERT(pmap->pm_stats.resident_count == 0, ("pmap_release: pmap %p resident count %ld != 0", pmap, pmap->pm_stats.resident_count)); } static int kvm_size(SYSCTL_HANDLER_ARGS) { unsigned long ksize = VM_MAX_KERNEL_ADDRESS - VM_MIN_KERNEL_ADDRESS; return sysctl_handle_long(oidp, &ksize, 0, req); } SYSCTL_PROC(_vm, OID_AUTO, kvm_size, CTLTYPE_LONG | CTLFLAG_RD | CTLFLAG_MPSAFE, 0, 0, kvm_size, "LU", "Size of KVM"); static int kvm_free(SYSCTL_HANDLER_ARGS) { unsigned long kfree = VM_MAX_KERNEL_ADDRESS - kernel_vm_end; return sysctl_handle_long(oidp, &kfree, 0, req); } SYSCTL_PROC(_vm, OID_AUTO, kvm_free, CTLTYPE_LONG | CTLFLAG_RD | CTLFLAG_MPSAFE, 0, 0, kvm_free, "LU", "Amount of KVM free"); #ifdef KMSAN static void pmap_kmsan_shadow_map_page_array(vm_paddr_t pdppa, vm_size_t size) { pdp_entry_t *pdpe; pd_entry_t *pde; pt_entry_t *pte; vm_paddr_t dummypa, dummypd, dummypt; int i, npde, npdpg; npdpg = howmany(size, NBPDP); npde = size / NBPDR; dummypa = vm_phys_early_alloc(-1, PAGE_SIZE); pagezero((void *)PHYS_TO_DMAP(dummypa)); dummypt = vm_phys_early_alloc(-1, PAGE_SIZE); pagezero((void *)PHYS_TO_DMAP(dummypt)); dummypd = vm_phys_early_alloc(-1, PAGE_SIZE * npdpg); for (i = 0; i < npdpg; i++) pagezero((void *)PHYS_TO_DMAP(dummypd + ptoa(i))); pte = (pt_entry_t *)PHYS_TO_DMAP(dummypt); for (i = 0; i < NPTEPG; i++) pte[i] = (pt_entry_t)(dummypa | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M | pg_nx); pde = (pd_entry_t *)PHYS_TO_DMAP(dummypd); for (i = 0; i < npde; i++) pde[i] = (pd_entry_t)(dummypt | X86_PG_V | X86_PG_RW | pg_nx); pdpe = (pdp_entry_t *)PHYS_TO_DMAP(pdppa); for (i = 0; i < npdpg; i++) pdpe[i] = (pdp_entry_t)(dummypd + ptoa(i) | X86_PG_V | X86_PG_RW | pg_nx); } static void pmap_kmsan_page_array_startup(vm_offset_t start, vm_offset_t end) { vm_size_t size; KASSERT(start % NBPDP == 0, ("unaligned page array start address")); /* * The end of the page array's KVA region is 2MB aligned, see * kmem_init(). */ size = round_2mpage(end) - start; pmap_kmsan_shadow_map_page_array(KMSANSHADPDPphys, size); pmap_kmsan_shadow_map_page_array(KMSANORIGPDPphys, size); } #endif /* * Allocate physical memory for the vm_page array and map it into KVA, * attempting to back the vm_pages with domain-local memory. */ void pmap_page_array_startup(long pages) { pdp_entry_t *pdpe; pd_entry_t *pde, newpdir; vm_offset_t va, start, end; vm_paddr_t pa; long pfn; int domain, i; vm_page_array_size = pages; start = VM_MIN_KERNEL_ADDRESS; end = start + pages * sizeof(struct vm_page); for (va = start; va < end; va += NBPDR) { pfn = first_page + (va - start) / sizeof(struct vm_page); domain = vm_phys_domain(ptoa(pfn)); pdpe = pmap_pdpe(kernel_pmap, va); if ((*pdpe & X86_PG_V) == 0) { pa = vm_phys_early_alloc(domain, PAGE_SIZE); dump_add_page(pa); pagezero((void *)PHYS_TO_DMAP(pa)); *pdpe = (pdp_entry_t)(pa | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M); } pde = pmap_pdpe_to_pde(pdpe, va); if ((*pde & X86_PG_V) != 0) panic("Unexpected pde"); pa = vm_phys_early_alloc(domain, NBPDR); for (i = 0; i < NPDEPG; i++) dump_add_page(pa + i * PAGE_SIZE); newpdir = (pd_entry_t)(pa | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M | PG_PS | pg_g | pg_nx); pde_store(pde, newpdir); } vm_page_array = (vm_page_t)start; #ifdef KMSAN pmap_kmsan_page_array_startup(start, end); #endif } /* * grow the number of kernel page table entries, if needed */ void pmap_growkernel(vm_offset_t addr) { vm_paddr_t paddr; vm_page_t nkpg; pd_entry_t *pde, newpdir; pdp_entry_t *pdpe; vm_offset_t end; TSENTER(); mtx_assert(&kernel_map->system_mtx, MA_OWNED); /* * The kernel map covers two distinct regions of KVA: that used * for dynamic kernel memory allocations, and the uppermost 2GB * of the virtual address space. The latter is used to map the * kernel and loadable kernel modules. This scheme enables the * use of a special code generation model for kernel code which * takes advantage of compact addressing modes in machine code. * * Both regions grow upwards; to avoid wasting memory, the gap * in between is unmapped. If "addr" is above "KERNBASE", the * kernel's region is grown, otherwise the kmem region is grown. * * The correctness of this action is based on the following * argument: vm_map_insert() allocates contiguous ranges of the * kernel virtual address space. It calls this function if a range * ends after "kernel_vm_end". If the kernel is mapped between * "kernel_vm_end" and "addr", then the range cannot begin at * "kernel_vm_end". In fact, its beginning address cannot be less * than the kernel. Thus, there is no immediate need to allocate * any new kernel page table pages between "kernel_vm_end" and * "KERNBASE". */ if (KERNBASE < addr) { end = KERNBASE + nkpt * NBPDR; if (end == 0) { TSEXIT(); return; } } else { end = kernel_vm_end; } addr = roundup2(addr, NBPDR); if (addr - 1 >= vm_map_max(kernel_map)) addr = vm_map_max(kernel_map); if (addr <= end) { /* * The grown region is already mapped, so there is * nothing to do. */ TSEXIT(); return; } kasan_shadow_map(end, addr - end); kmsan_shadow_map(end, addr - end); while (end < addr) { pdpe = pmap_pdpe(kernel_pmap, end); if ((*pdpe & X86_PG_V) == 0) { nkpg = pmap_alloc_pt_page(kernel_pmap, pmap_pdpe_pindex(end), VM_ALLOC_WIRED | VM_ALLOC_INTERRUPT | VM_ALLOC_ZERO); if (nkpg == NULL) panic("pmap_growkernel: no memory to grow kernel"); paddr = VM_PAGE_TO_PHYS(nkpg); *pdpe = (pdp_entry_t)(paddr | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M); continue; /* try again */ } pde = pmap_pdpe_to_pde(pdpe, end); if ((*pde & X86_PG_V) != 0) { end = (end + NBPDR) & ~PDRMASK; if (end - 1 >= vm_map_max(kernel_map)) { end = vm_map_max(kernel_map); break; } continue; } nkpg = pmap_alloc_pt_page(kernel_pmap, pmap_pde_pindex(end), VM_ALLOC_WIRED | VM_ALLOC_INTERRUPT | VM_ALLOC_ZERO); if (nkpg == NULL) panic("pmap_growkernel: no memory to grow kernel"); paddr = VM_PAGE_TO_PHYS(nkpg); newpdir = paddr | X86_PG_V | X86_PG_RW | X86_PG_A | X86_PG_M; pde_store(pde, newpdir); end = (end + NBPDR) & ~PDRMASK; if (end - 1 >= vm_map_max(kernel_map)) { end = vm_map_max(kernel_map); break; } } if (end <= KERNBASE) kernel_vm_end = end; else nkpt = howmany(end - KERNBASE, NBPDR); TSEXIT(); } /*************************************************** * page management routines. ***************************************************/ static const uint64_t pc_freemask[_NPCM] = { [0 ... _NPCM - 2] = PC_FREEN, [_NPCM - 1] = PC_FREEL }; #ifdef PV_STATS static COUNTER_U64_DEFINE_EARLY(pc_chunk_count); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, pc_chunk_count, CTLFLAG_RD, &pc_chunk_count, "Current number of pv entry cnunks"); static COUNTER_U64_DEFINE_EARLY(pc_chunk_allocs); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, pc_chunk_allocs, CTLFLAG_RD, &pc_chunk_allocs, "Total number of pv entry chunks allocated"); static COUNTER_U64_DEFINE_EARLY(pc_chunk_frees); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, pc_chunk_frees, CTLFLAG_RD, &pc_chunk_frees, "Total number of pv entry chunks freed"); static COUNTER_U64_DEFINE_EARLY(pc_chunk_tryfail); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, pc_chunk_tryfail, CTLFLAG_RD, &pc_chunk_tryfail, "Number of failed attempts to get a pv entry chunk page"); static COUNTER_U64_DEFINE_EARLY(pv_entry_frees); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, pv_entry_frees, CTLFLAG_RD, &pv_entry_frees, "Total number of pv entries freed"); static COUNTER_U64_DEFINE_EARLY(pv_entry_allocs); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, pv_entry_allocs, CTLFLAG_RD, &pv_entry_allocs, "Total number of pv entries allocated"); static COUNTER_U64_DEFINE_EARLY(pv_entry_count); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, pv_entry_count, CTLFLAG_RD, &pv_entry_count, "Current number of pv entries"); static COUNTER_U64_DEFINE_EARLY(pv_entry_spare); SYSCTL_COUNTER_U64(_vm_pmap, OID_AUTO, pv_entry_spare, CTLFLAG_RD, &pv_entry_spare, "Current number of spare pv entries"); #endif static void reclaim_pv_chunk_leave_pmap(pmap_t pmap, pmap_t locked_pmap, bool start_di) { if (pmap == NULL) return; pmap_invalidate_all(pmap); if (pmap != locked_pmap) PMAP_UNLOCK(pmap); if (start_di) pmap_delayed_invl_finish(); } /* * We are in a serious low memory condition. Resort to * drastic measures to free some pages so we can allocate * another pv entry chunk. * * Returns NULL if PV entries were reclaimed from the specified pmap. * * We do not, however, unmap 2mpages because subsequent accesses will * allocate per-page pv entries until repromotion occurs, thereby * exacerbating the shortage of free pv entries. */ static vm_page_t reclaim_pv_chunk_domain(pmap_t locked_pmap, struct rwlock **lockp, int domain) { struct pv_chunks_list *pvc; struct pv_chunk *pc, *pc_marker, *pc_marker_end; struct pv_chunk_header pc_marker_b, pc_marker_end_b; struct md_page *pvh; pd_entry_t *pde; pmap_t next_pmap, pmap; pt_entry_t *pte, tpte; pt_entry_t PG_G, PG_A, PG_M, PG_RW; pv_entry_t pv; vm_offset_t va; vm_page_t m, m_pc; struct spglist free; uint64_t inuse; int bit, field, freed; bool start_di, restart; PMAP_LOCK_ASSERT(locked_pmap, MA_OWNED); KASSERT(lockp != NULL, ("reclaim_pv_chunk: lockp is NULL")); pmap = NULL; m_pc = NULL; PG_G = PG_A = PG_M = PG_RW = 0; SLIST_INIT(&free); bzero(&pc_marker_b, sizeof(pc_marker_b)); bzero(&pc_marker_end_b, sizeof(pc_marker_end_b)); pc_marker = (struct pv_chunk *)&pc_marker_b; pc_marker_end = (struct pv_chunk *)&pc_marker_end_b; /* * A delayed invalidation block should already be active if * pmap_advise() or pmap_remove() called this function by way * of pmap_demote_pde_locked(). */ start_di = pmap_not_in_di(); pvc = &pv_chunks[domain]; mtx_lock(&pvc->pvc_lock); pvc->active_reclaims++; TAILQ_INSERT_HEAD(&pvc->pvc_list, pc_marker, pc_lru); TAILQ_INSERT_TAIL(&pvc->pvc_list, pc_marker_end, pc_lru); while ((pc = TAILQ_NEXT(pc_marker, pc_lru)) != pc_marker_end && SLIST_EMPTY(&free)) { next_pmap = pc->pc_pmap; if (next_pmap == NULL) { /* * The next chunk is a marker. However, it is * not our marker, so active_reclaims must be * > 1. Consequently, the next_chunk code * will not rotate the pv_chunks list. */ goto next_chunk; } mtx_unlock(&pvc->pvc_lock); /* * A pv_chunk can only be removed from the pc_lru list * when both pc_chunks_mutex is owned and the * corresponding pmap is locked. */ if (pmap != next_pmap) { restart = false; reclaim_pv_chunk_leave_pmap(pmap, locked_pmap, start_di); pmap = next_pmap; /* Avoid deadlock and lock recursion. */ if (pmap > locked_pmap) { RELEASE_PV_LIST_LOCK(lockp); PMAP_LOCK(pmap); if (start_di) pmap_delayed_invl_start(); mtx_lock(&pvc->pvc_lock); restart = true; } else if (pmap != locked_pmap) { if (PMAP_TRYLOCK(pmap)) { if (start_di) pmap_delayed_invl_start(); mtx_lock(&pvc->pvc_lock); restart = true; } else { pmap = NULL; /* pmap is not locked */ mtx_lock(&pvc->pvc_lock); pc = TAILQ_NEXT(pc_marker, pc_lru); if (pc == NULL || pc->pc_pmap != next_pmap) continue; goto next_chunk; } } else if (start_di) pmap_delayed_invl_start(); PG_G = pmap_global_bit(pmap); PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); if (restart) continue; } /* * Destroy every non-wired, 4 KB page mapping in the chunk. */ freed = 0; for (field = 0; field < _NPCM; field++) { for (inuse = ~pc->pc_map[field] & pc_freemask[field]; inuse != 0; inuse &= ~(1UL << bit)) { bit = bsfq(inuse); pv = &pc->pc_pventry[field * 64 + bit]; va = pv->pv_va; pde = pmap_pde(pmap, va); if ((*pde & PG_PS) != 0) continue; pte = pmap_pde_to_pte(pde, va); if ((*pte & PG_W) != 0) continue; tpte = pte_load_clear(pte); if ((tpte & PG_G) != 0) pmap_invalidate_page(pmap, va); m = PHYS_TO_VM_PAGE(tpte & PG_FRAME); if ((tpte & (PG_M | PG_RW)) == (PG_M | PG_RW)) vm_page_dirty(m); if ((tpte & PG_A) != 0) vm_page_aflag_set(m, PGA_REFERENCED); CHANGE_PV_LIST_LOCK_TO_VM_PAGE(lockp, m); TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; if (TAILQ_EMPTY(&m->md.pv_list) && (m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); if (TAILQ_EMPTY(&pvh->pv_list)) { vm_page_aflag_clear(m, PGA_WRITEABLE); } } pmap_delayed_invl_page(m); pc->pc_map[field] |= 1UL << bit; pmap_unuse_pt(pmap, va, *pde, &free); freed++; } } if (freed == 0) { mtx_lock(&pvc->pvc_lock); goto next_chunk; } /* Every freed mapping is for a 4 KB page. */ pmap_resident_count_adj(pmap, -freed); PV_STAT(counter_u64_add(pv_entry_frees, freed)); PV_STAT(counter_u64_add(pv_entry_spare, freed)); PV_STAT(counter_u64_add(pv_entry_count, -freed)); TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); if (pc_is_free(pc)) { PV_STAT(counter_u64_add(pv_entry_spare, -_NPCPV)); PV_STAT(counter_u64_add(pc_chunk_count, -1)); PV_STAT(counter_u64_add(pc_chunk_frees, 1)); /* Entire chunk is free; return it. */ m_pc = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((vm_offset_t)pc)); dump_drop_page(m_pc->phys_addr); mtx_lock(&pvc->pvc_lock); TAILQ_REMOVE(&pvc->pvc_list, pc, pc_lru); break; } TAILQ_INSERT_HEAD(&pmap->pm_pvchunk, pc, pc_list); mtx_lock(&pvc->pvc_lock); /* One freed pv entry in locked_pmap is sufficient. */ if (pmap == locked_pmap) break; next_chunk: TAILQ_REMOVE(&pvc->pvc_list, pc_marker, pc_lru); TAILQ_INSERT_AFTER(&pvc->pvc_list, pc, pc_marker, pc_lru); if (pvc->active_reclaims == 1 && pmap != NULL) { /* * Rotate the pv chunks list so that we do not * scan the same pv chunks that could not be * freed (because they contained a wired * and/or superpage mapping) on every * invocation of reclaim_pv_chunk(). */ while ((pc = TAILQ_FIRST(&pvc->pvc_list)) != pc_marker) { MPASS(pc->pc_pmap != NULL); TAILQ_REMOVE(&pvc->pvc_list, pc, pc_lru); TAILQ_INSERT_TAIL(&pvc->pvc_list, pc, pc_lru); } } } TAILQ_REMOVE(&pvc->pvc_list, pc_marker, pc_lru); TAILQ_REMOVE(&pvc->pvc_list, pc_marker_end, pc_lru); pvc->active_reclaims--; mtx_unlock(&pvc->pvc_lock); reclaim_pv_chunk_leave_pmap(pmap, locked_pmap, start_di); if (m_pc == NULL && !SLIST_EMPTY(&free)) { m_pc = SLIST_FIRST(&free); SLIST_REMOVE_HEAD(&free, plinks.s.ss); /* Recycle a freed page table page. */ m_pc->ref_count = 1; } vm_page_free_pages_toq(&free, true); return (m_pc); } static vm_page_t reclaim_pv_chunk(pmap_t locked_pmap, struct rwlock **lockp) { vm_page_t m; int i, domain; domain = PCPU_GET(domain); for (i = 0; i < vm_ndomains; i++) { m = reclaim_pv_chunk_domain(locked_pmap, lockp, domain); if (m != NULL) break; domain = (domain + 1) % vm_ndomains; } return (m); } /* * free the pv_entry back to the free list */ static void free_pv_entry(pmap_t pmap, pv_entry_t pv) { struct pv_chunk *pc; int idx, field, bit; PMAP_LOCK_ASSERT(pmap, MA_OWNED); PV_STAT(counter_u64_add(pv_entry_frees, 1)); PV_STAT(counter_u64_add(pv_entry_spare, 1)); PV_STAT(counter_u64_add(pv_entry_count, -1)); pc = pv_to_chunk(pv); idx = pv - &pc->pc_pventry[0]; field = idx / 64; bit = idx % 64; pc->pc_map[field] |= 1ul << bit; if (!pc_is_free(pc)) { /* 98% of the time, pc is already at the head of the list. */ if (__predict_false(pc != TAILQ_FIRST(&pmap->pm_pvchunk))) { TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_HEAD(&pmap->pm_pvchunk, pc, pc_list); } return; } TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); free_pv_chunk(pc); } static void free_pv_chunk_dequeued(struct pv_chunk *pc) { vm_page_t m; PV_STAT(counter_u64_add(pv_entry_spare, -_NPCPV)); PV_STAT(counter_u64_add(pc_chunk_count, -1)); PV_STAT(counter_u64_add(pc_chunk_frees, 1)); counter_u64_add(pv_page_count, -1); /* entire chunk is free, return it */ m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((vm_offset_t)pc)); dump_drop_page(m->phys_addr); vm_page_unwire_noq(m); vm_page_free(m); } static void free_pv_chunk(struct pv_chunk *pc) { struct pv_chunks_list *pvc; pvc = &pv_chunks[pc_to_domain(pc)]; mtx_lock(&pvc->pvc_lock); TAILQ_REMOVE(&pvc->pvc_list, pc, pc_lru); mtx_unlock(&pvc->pvc_lock); free_pv_chunk_dequeued(pc); } static void free_pv_chunk_batch(struct pv_chunklist *batch) { struct pv_chunks_list *pvc; struct pv_chunk *pc, *npc; int i; for (i = 0; i < vm_ndomains; i++) { if (TAILQ_EMPTY(&batch[i])) continue; pvc = &pv_chunks[i]; mtx_lock(&pvc->pvc_lock); TAILQ_FOREACH(pc, &batch[i], pc_list) { TAILQ_REMOVE(&pvc->pvc_list, pc, pc_lru); } mtx_unlock(&pvc->pvc_lock); } for (i = 0; i < vm_ndomains; i++) { TAILQ_FOREACH_SAFE(pc, &batch[i], pc_list, npc) { free_pv_chunk_dequeued(pc); } } } /* * Returns a new PV entry, allocating a new PV chunk from the system when * needed. If this PV chunk allocation fails and a PV list lock pointer was * given, a PV chunk is reclaimed from an arbitrary pmap. Otherwise, NULL is * returned. * * The given PV list lock may be released. */ static pv_entry_t get_pv_entry(pmap_t pmap, struct rwlock **lockp) { struct pv_chunks_list *pvc; int bit, field; pv_entry_t pv; struct pv_chunk *pc; vm_page_t m; PMAP_LOCK_ASSERT(pmap, MA_OWNED); PV_STAT(counter_u64_add(pv_entry_allocs, 1)); retry: pc = TAILQ_FIRST(&pmap->pm_pvchunk); if (pc != NULL) { for (field = 0; field < _NPCM; field++) { if (pc->pc_map[field]) { bit = bsfq(pc->pc_map[field]); break; } } if (field < _NPCM) { pv = &pc->pc_pventry[field * 64 + bit]; pc->pc_map[field] &= ~(1ul << bit); /* If this was the last item, move it to tail */ if (pc->pc_map[0] == 0 && pc->pc_map[1] == 0 && pc->pc_map[2] == 0) { TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&pmap->pm_pvchunk, pc, pc_list); } PV_STAT(counter_u64_add(pv_entry_count, 1)); PV_STAT(counter_u64_add(pv_entry_spare, -1)); return (pv); } } /* No free items, allocate another chunk */ m = vm_page_alloc_noobj(VM_ALLOC_WIRED); if (m == NULL) { if (lockp == NULL) { PV_STAT(counter_u64_add(pc_chunk_tryfail, 1)); return (NULL); } m = reclaim_pv_chunk(pmap, lockp); if (m == NULL) goto retry; } else counter_u64_add(pv_page_count, 1); PV_STAT(counter_u64_add(pc_chunk_count, 1)); PV_STAT(counter_u64_add(pc_chunk_allocs, 1)); dump_add_page(m->phys_addr); pc = (void *)PHYS_TO_DMAP(m->phys_addr); pc->pc_pmap = pmap; pc->pc_map[0] = PC_FREEN & ~1ul; /* preallocated bit 0 */ pc->pc_map[1] = PC_FREEN; pc->pc_map[2] = PC_FREEL; pvc = &pv_chunks[vm_page_domain(m)]; mtx_lock(&pvc->pvc_lock); TAILQ_INSERT_TAIL(&pvc->pvc_list, pc, pc_lru); mtx_unlock(&pvc->pvc_lock); pv = &pc->pc_pventry[0]; TAILQ_INSERT_HEAD(&pmap->pm_pvchunk, pc, pc_list); PV_STAT(counter_u64_add(pv_entry_count, 1)); PV_STAT(counter_u64_add(pv_entry_spare, _NPCPV - 1)); return (pv); } /* * Returns the number of one bits within the given PV chunk map. * * The erratas for Intel processors state that "POPCNT Instruction May * Take Longer to Execute Than Expected". It is believed that the * issue is the spurious dependency on the destination register. * Provide a hint to the register rename logic that the destination * value is overwritten, by clearing it, as suggested in the * optimization manual. It should be cheap for unaffected processors * as well. * * Reference numbers for erratas are * 4th Gen Core: HSD146 * 5th Gen Core: BDM85 * 6th Gen Core: SKL029 */ static int popcnt_pc_map_pq(uint64_t *map) { u_long result, tmp; __asm __volatile("xorl %k0,%k0;popcntq %2,%0;" "xorl %k1,%k1;popcntq %3,%1;addl %k1,%k0;" "xorl %k1,%k1;popcntq %4,%1;addl %k1,%k0" : "=&r" (result), "=&r" (tmp) : "m" (map[0]), "m" (map[1]), "m" (map[2])); return (result); } /* * Ensure that the number of spare PV entries in the specified pmap meets or * exceeds the given count, "needed". * * The given PV list lock may be released. */ static void reserve_pv_entries(pmap_t pmap, int needed, struct rwlock **lockp) { struct pv_chunks_list *pvc; struct pch new_tail[PMAP_MEMDOM]; struct pv_chunk *pc; vm_page_t m; int avail, free, i; bool reclaimed; PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT(lockp != NULL, ("reserve_pv_entries: lockp is NULL")); /* * Newly allocated PV chunks must be stored in a private list until * the required number of PV chunks have been allocated. Otherwise, * reclaim_pv_chunk() could recycle one of these chunks. In * contrast, these chunks must be added to the pmap upon allocation. */ for (i = 0; i < PMAP_MEMDOM; i++) TAILQ_INIT(&new_tail[i]); retry: avail = 0; TAILQ_FOREACH(pc, &pmap->pm_pvchunk, pc_list) { #ifndef __POPCNT__ if ((cpu_feature2 & CPUID2_POPCNT) == 0) bit_count((bitstr_t *)pc->pc_map, 0, sizeof(pc->pc_map) * NBBY, &free); else #endif free = popcnt_pc_map_pq(pc->pc_map); if (free == 0) break; avail += free; if (avail >= needed) break; } for (reclaimed = false; avail < needed; avail += _NPCPV) { m = vm_page_alloc_noobj(VM_ALLOC_WIRED); if (m == NULL) { m = reclaim_pv_chunk(pmap, lockp); if (m == NULL) goto retry; reclaimed = true; } else counter_u64_add(pv_page_count, 1); PV_STAT(counter_u64_add(pc_chunk_count, 1)); PV_STAT(counter_u64_add(pc_chunk_allocs, 1)); dump_add_page(m->phys_addr); pc = (void *)PHYS_TO_DMAP(m->phys_addr); pc->pc_pmap = pmap; pc->pc_map[0] = PC_FREEN; pc->pc_map[1] = PC_FREEN; pc->pc_map[2] = PC_FREEL; TAILQ_INSERT_HEAD(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&new_tail[vm_page_domain(m)], pc, pc_lru); PV_STAT(counter_u64_add(pv_entry_spare, _NPCPV)); /* * The reclaim might have freed a chunk from the current pmap. * If that chunk contained available entries, we need to * re-count the number of available entries. */ if (reclaimed) goto retry; } for (i = 0; i < vm_ndomains; i++) { if (TAILQ_EMPTY(&new_tail[i])) continue; pvc = &pv_chunks[i]; mtx_lock(&pvc->pvc_lock); TAILQ_CONCAT(&pvc->pvc_list, &new_tail[i], pc_lru); mtx_unlock(&pvc->pvc_lock); } } /* * First find and then remove the pv entry for the specified pmap and virtual * address from the specified pv list. Returns the pv entry if found and NULL * otherwise. This operation can be performed on pv lists for either 4KB or * 2MB page mappings. */ static __inline pv_entry_t pmap_pvh_remove(struct md_page *pvh, pmap_t pmap, vm_offset_t va) { pv_entry_t pv; TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { if (pmap == PV_PMAP(pv) && va == pv->pv_va) { TAILQ_REMOVE(&pvh->pv_list, pv, pv_next); pvh->pv_gen++; break; } } return (pv); } /* * After demotion from a 2MB page mapping to 512 4KB page mappings, * destroy the pv entry for the 2MB page mapping and reinstantiate the pv * entries for each of the 4KB page mappings. */ static void pmap_pv_demote_pde(pmap_t pmap, vm_offset_t va, vm_paddr_t pa, struct rwlock **lockp) { struct md_page *pvh; struct pv_chunk *pc; pv_entry_t pv; vm_offset_t va_last; vm_page_t m; int bit, field; PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT((pa & PDRMASK) == 0, ("pmap_pv_demote_pde: pa is not 2mpage aligned")); CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, pa); /* * Transfer the 2mpage's pv entry for this mapping to the first * page's pv list. Once this transfer begins, the pv list lock * must not be released until the last pv entry is reinstantiated. */ pvh = pa_to_pvh(pa); va = trunc_2mpage(va); pv = pmap_pvh_remove(pvh, pmap, va); KASSERT(pv != NULL, ("pmap_pv_demote_pde: pv not found")); m = PHYS_TO_VM_PAGE(pa); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; /* Instantiate the remaining NPTEPG - 1 pv entries. */ PV_STAT(counter_u64_add(pv_entry_allocs, NPTEPG - 1)); va_last = va + NBPDR - PAGE_SIZE; for (;;) { pc = TAILQ_FIRST(&pmap->pm_pvchunk); KASSERT(pc->pc_map[0] != 0 || pc->pc_map[1] != 0 || pc->pc_map[2] != 0, ("pmap_pv_demote_pde: missing spare")); for (field = 0; field < _NPCM; field++) { while (pc->pc_map[field]) { bit = bsfq(pc->pc_map[field]); pc->pc_map[field] &= ~(1ul << bit); pv = &pc->pc_pventry[field * 64 + bit]; va += PAGE_SIZE; pv->pv_va = va; m++; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_pv_demote_pde: page %p is not managed", m)); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; if (va == va_last) goto out; } } TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&pmap->pm_pvchunk, pc, pc_list); } out: if (pc->pc_map[0] == 0 && pc->pc_map[1] == 0 && pc->pc_map[2] == 0) { TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&pmap->pm_pvchunk, pc, pc_list); } PV_STAT(counter_u64_add(pv_entry_count, NPTEPG - 1)); PV_STAT(counter_u64_add(pv_entry_spare, -(NPTEPG - 1))); } #if VM_NRESERVLEVEL > 0 /* * After promotion from 512 4KB page mappings to a single 2MB page mapping, * replace the many pv entries for the 4KB page mappings by a single pv entry * for the 2MB page mapping. */ static void pmap_pv_promote_pde(pmap_t pmap, vm_offset_t va, vm_paddr_t pa, struct rwlock **lockp) { struct md_page *pvh; pv_entry_t pv; vm_offset_t va_last; vm_page_t m; KASSERT((pa & PDRMASK) == 0, ("pmap_pv_promote_pde: pa is not 2mpage aligned")); CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, pa); /* * Transfer the first page's pv entry for this mapping to the 2mpage's * pv list. Aside from avoiding the cost of a call to get_pv_entry(), * a transfer avoids the possibility that get_pv_entry() calls * reclaim_pv_chunk() and that reclaim_pv_chunk() removes one of the * mappings that is being promoted. */ m = PHYS_TO_VM_PAGE(pa); va = trunc_2mpage(va); pv = pmap_pvh_remove(&m->md, pmap, va); KASSERT(pv != NULL, ("pmap_pv_promote_pde: pv not found")); pvh = pa_to_pvh(pa); TAILQ_INSERT_TAIL(&pvh->pv_list, pv, pv_next); pvh->pv_gen++; /* Free the remaining NPTEPG - 1 pv entries. */ va_last = va + NBPDR - PAGE_SIZE; do { m++; va += PAGE_SIZE; pmap_pvh_free(&m->md, pmap, va); } while (va < va_last); } #endif /* VM_NRESERVLEVEL > 0 */ /* * First find and then destroy the pv entry for the specified pmap and virtual * address. This operation can be performed on pv lists for either 4KB or 2MB * page mappings. */ static void pmap_pvh_free(struct md_page *pvh, pmap_t pmap, vm_offset_t va) { pv_entry_t pv; pv = pmap_pvh_remove(pvh, pmap, va); KASSERT(pv != NULL, ("pmap_pvh_free: pv not found")); free_pv_entry(pmap, pv); } /* * Conditionally create the PV entry for a 4KB page mapping if the required * memory can be allocated without resorting to reclamation. */ static boolean_t pmap_try_insert_pv_entry(pmap_t pmap, vm_offset_t va, vm_page_t m, struct rwlock **lockp) { pv_entry_t pv; PMAP_LOCK_ASSERT(pmap, MA_OWNED); /* Pass NULL instead of the lock pointer to disable reclamation. */ if ((pv = get_pv_entry(pmap, NULL)) != NULL) { pv->pv_va = va; CHANGE_PV_LIST_LOCK_TO_VM_PAGE(lockp, m); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; return (TRUE); } else return (FALSE); } /* * Create the PV entry for a 2MB page mapping. Always returns true unless the * flag PMAP_ENTER_NORECLAIM is specified. If that flag is specified, returns * false if the PV entry cannot be allocated without resorting to reclamation. */ static bool pmap_pv_insert_pde(pmap_t pmap, vm_offset_t va, pd_entry_t pde, u_int flags, struct rwlock **lockp) { struct md_page *pvh; pv_entry_t pv; vm_paddr_t pa; PMAP_LOCK_ASSERT(pmap, MA_OWNED); /* Pass NULL instead of the lock pointer to disable reclamation. */ if ((pv = get_pv_entry(pmap, (flags & PMAP_ENTER_NORECLAIM) != 0 ? NULL : lockp)) == NULL) return (false); pv->pv_va = va; pa = pde & PG_PS_FRAME; CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, pa); pvh = pa_to_pvh(pa); TAILQ_INSERT_TAIL(&pvh->pv_list, pv, pv_next); pvh->pv_gen++; return (true); } /* * Fills a page table page with mappings to consecutive physical pages. */ static void pmap_fill_ptp(pt_entry_t *firstpte, pt_entry_t newpte) { pt_entry_t *pte; for (pte = firstpte; pte < firstpte + NPTEPG; pte++) { *pte = newpte; newpte += PAGE_SIZE; } } /* * Tries to demote a 2MB page mapping. If demotion fails, the 2MB page * mapping is invalidated. */ static boolean_t pmap_demote_pde(pmap_t pmap, pd_entry_t *pde, vm_offset_t va) { struct rwlock *lock; boolean_t rv; lock = NULL; rv = pmap_demote_pde_locked(pmap, pde, va, &lock); if (lock != NULL) rw_wunlock(lock); return (rv); } static void pmap_demote_pde_check(pt_entry_t *firstpte __unused, pt_entry_t newpte __unused) { #ifdef INVARIANTS #ifdef DIAGNOSTIC pt_entry_t *xpte, *ypte; for (xpte = firstpte; xpte < firstpte + NPTEPG; xpte++, newpte += PAGE_SIZE) { if ((*xpte & PG_FRAME) != (newpte & PG_FRAME)) { printf("pmap_demote_pde: xpte %zd and newpte map " "different pages: found %#lx, expected %#lx\n", xpte - firstpte, *xpte, newpte); printf("page table dump\n"); for (ypte = firstpte; ypte < firstpte + NPTEPG; ypte++) printf("%zd %#lx\n", ypte - firstpte, *ypte); panic("firstpte"); } } #else KASSERT((*firstpte & PG_FRAME) == (newpte & PG_FRAME), ("pmap_demote_pde: firstpte and newpte map different physical" " addresses")); #endif #endif } static void pmap_demote_pde_abort(pmap_t pmap, vm_offset_t va, pd_entry_t *pde, pd_entry_t oldpde, struct rwlock **lockp) { struct spglist free; vm_offset_t sva; SLIST_INIT(&free); sva = trunc_2mpage(va); pmap_remove_pde(pmap, pde, sva, &free, lockp); if ((oldpde & pmap_global_bit(pmap)) == 0) pmap_invalidate_pde_page(pmap, sva, oldpde); vm_page_free_pages_toq(&free, true); CTR2(KTR_PMAP, "pmap_demote_pde: failure for va %#lx in pmap %p", va, pmap); } static boolean_t pmap_demote_pde_locked(pmap_t pmap, pd_entry_t *pde, vm_offset_t va, struct rwlock **lockp) { pd_entry_t newpde, oldpde; pt_entry_t *firstpte, newpte; pt_entry_t PG_A, PG_G, PG_M, PG_PKU_MASK, PG_RW, PG_V; vm_paddr_t mptepa; vm_page_t mpte; int PG_PTE_CACHE; bool in_kernel; PG_A = pmap_accessed_bit(pmap); PG_G = pmap_global_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_PTE_CACHE = pmap_cache_mask(pmap, 0); PG_PKU_MASK = pmap_pku_mask_bit(pmap); PMAP_LOCK_ASSERT(pmap, MA_OWNED); in_kernel = va >= VM_MAXUSER_ADDRESS; oldpde = *pde; KASSERT((oldpde & (PG_PS | PG_V)) == (PG_PS | PG_V), ("pmap_demote_pde: oldpde is missing PG_PS and/or PG_V")); /* * Invalidate the 2MB page mapping and return "failure" if the * mapping was never accessed. */ if ((oldpde & PG_A) == 0) { KASSERT((oldpde & PG_W) == 0, ("pmap_demote_pde: a wired mapping is missing PG_A")); pmap_demote_pde_abort(pmap, va, pde, oldpde, lockp); return (FALSE); } mpte = pmap_remove_pt_page(pmap, va); if (mpte == NULL) { KASSERT((oldpde & PG_W) == 0, ("pmap_demote_pde: page table page for a wired mapping" " is missing")); /* * If the page table page is missing and the mapping * is for a kernel address, the mapping must belong to * the direct map. Page table pages are preallocated * for every other part of the kernel address space, * so the direct map region is the only part of the * kernel address space that must be handled here. */ KASSERT(!in_kernel || (va >= DMAP_MIN_ADDRESS && va < DMAP_MAX_ADDRESS), ("pmap_demote_pde: No saved mpte for va %#lx", va)); /* * If the 2MB page mapping belongs to the direct map * region of the kernel's address space, then the page * allocation request specifies the highest possible * priority (VM_ALLOC_INTERRUPT). Otherwise, the * priority is normal. */ mpte = pmap_alloc_pt_page(pmap, pmap_pde_pindex(va), (in_kernel ? VM_ALLOC_INTERRUPT : 0) | VM_ALLOC_WIRED); /* * If the allocation of the new page table page fails, * invalidate the 2MB page mapping and return "failure". */ if (mpte == NULL) { pmap_demote_pde_abort(pmap, va, pde, oldpde, lockp); return (FALSE); } if (!in_kernel) mpte->ref_count = NPTEPG; } mptepa = VM_PAGE_TO_PHYS(mpte); firstpte = (pt_entry_t *)PHYS_TO_DMAP(mptepa); newpde = mptepa | PG_M | PG_A | (oldpde & PG_U) | PG_RW | PG_V; KASSERT((oldpde & (PG_M | PG_RW)) != PG_RW, ("pmap_demote_pde: oldpde is missing PG_M")); newpte = oldpde & ~PG_PS; newpte = pmap_swap_pat(pmap, newpte); /* * If the PTP is not leftover from an earlier promotion or it does not * have PG_A set in every PTE, then fill it. The new PTEs will all * have PG_A set. */ if (!vm_page_all_valid(mpte)) pmap_fill_ptp(firstpte, newpte); pmap_demote_pde_check(firstpte, newpte); /* * If the mapping has changed attributes, update the PTEs. */ if ((*firstpte & PG_PTE_PROMOTE) != (newpte & PG_PTE_PROMOTE)) pmap_fill_ptp(firstpte, newpte); /* * The spare PV entries must be reserved prior to demoting the * mapping, that is, prior to changing the PDE. Otherwise, the state * of the PDE and the PV lists will be inconsistent, which can result * in reclaim_pv_chunk() attempting to remove a PV entry from the * wrong PV list and pmap_pv_demote_pde() failing to find the expected * PV entry for the 2MB page mapping that is being demoted. */ if ((oldpde & PG_MANAGED) != 0) reserve_pv_entries(pmap, NPTEPG - 1, lockp); /* * Demote the mapping. This pmap is locked. The old PDE has * PG_A set. If the old PDE has PG_RW set, it also has PG_M * set. Thus, there is no danger of a race with another * processor changing the setting of PG_A and/or PG_M between * the read above and the store below. */ if (workaround_erratum383) pmap_update_pde(pmap, va, pde, newpde); else pde_store(pde, newpde); /* * Invalidate a stale recursive mapping of the page table page. */ if (in_kernel) pmap_invalidate_page(pmap, (vm_offset_t)vtopte(va)); /* * Demote the PV entry. */ if ((oldpde & PG_MANAGED) != 0) pmap_pv_demote_pde(pmap, va, oldpde & PG_PS_FRAME, lockp); counter_u64_add(pmap_pde_demotions, 1); CTR2(KTR_PMAP, "pmap_demote_pde: success for va %#lx in pmap %p", va, pmap); return (TRUE); } /* * pmap_remove_kernel_pde: Remove a kernel superpage mapping. */ static void pmap_remove_kernel_pde(pmap_t pmap, pd_entry_t *pde, vm_offset_t va) { pd_entry_t newpde; vm_paddr_t mptepa; vm_page_t mpte; KASSERT(pmap == kernel_pmap, ("pmap %p is not kernel_pmap", pmap)); PMAP_LOCK_ASSERT(pmap, MA_OWNED); mpte = pmap_remove_pt_page(pmap, va); if (mpte == NULL) panic("pmap_remove_kernel_pde: Missing pt page."); mptepa = VM_PAGE_TO_PHYS(mpte); newpde = mptepa | X86_PG_M | X86_PG_A | X86_PG_RW | X86_PG_V; /* * If this page table page was unmapped by a promotion, then it * contains valid mappings. Zero it to invalidate those mappings. */ if (vm_page_any_valid(mpte)) pagezero((void *)PHYS_TO_DMAP(mptepa)); /* * Demote the mapping. */ if (workaround_erratum383) pmap_update_pde(pmap, va, pde, newpde); else pde_store(pde, newpde); /* * Invalidate a stale recursive mapping of the page table page. */ pmap_invalidate_page(pmap, (vm_offset_t)vtopte(va)); } /* * pmap_remove_pde: do the things to unmap a superpage in a process */ static int pmap_remove_pde(pmap_t pmap, pd_entry_t *pdq, vm_offset_t sva, struct spglist *free, struct rwlock **lockp) { struct md_page *pvh; pd_entry_t oldpde; vm_offset_t eva, va; vm_page_t m, mpte; pt_entry_t PG_G, PG_A, PG_M, PG_RW; PG_G = pmap_global_bit(pmap); PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT((sva & PDRMASK) == 0, ("pmap_remove_pde: sva is not 2mpage aligned")); oldpde = pte_load_clear(pdq); if (oldpde & PG_W) pmap->pm_stats.wired_count -= NBPDR / PAGE_SIZE; if ((oldpde & PG_G) != 0) pmap_invalidate_pde_page(kernel_pmap, sva, oldpde); pmap_resident_count_adj(pmap, -NBPDR / PAGE_SIZE); if (oldpde & PG_MANAGED) { CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, oldpde & PG_PS_FRAME); pvh = pa_to_pvh(oldpde & PG_PS_FRAME); pmap_pvh_free(pvh, pmap, sva); eva = sva + NBPDR; for (va = sva, m = PHYS_TO_VM_PAGE(oldpde & PG_PS_FRAME); va < eva; va += PAGE_SIZE, m++) { if ((oldpde & (PG_M | PG_RW)) == (PG_M | PG_RW)) vm_page_dirty(m); if (oldpde & PG_A) vm_page_aflag_set(m, PGA_REFERENCED); if (TAILQ_EMPTY(&m->md.pv_list) && TAILQ_EMPTY(&pvh->pv_list)) vm_page_aflag_clear(m, PGA_WRITEABLE); pmap_delayed_invl_page(m); } } if (pmap == kernel_pmap) { pmap_remove_kernel_pde(pmap, pdq, sva); } else { mpte = pmap_remove_pt_page(pmap, sva); if (mpte != NULL) { KASSERT(vm_page_any_valid(mpte), ("pmap_remove_pde: pte page not promoted")); pmap_pt_page_count_adj(pmap, -1); KASSERT(mpte->ref_count == NPTEPG, ("pmap_remove_pde: pte page ref count error")); mpte->ref_count = 0; pmap_add_delayed_free_list(mpte, free, FALSE); } } return (pmap_unuse_pt(pmap, sva, *pmap_pdpe(pmap, sva), free)); } /* * pmap_remove_pte: do the things to unmap a page in a process */ static int pmap_remove_pte(pmap_t pmap, pt_entry_t *ptq, vm_offset_t va, pd_entry_t ptepde, struct spglist *free, struct rwlock **lockp) { struct md_page *pvh; pt_entry_t oldpte, PG_A, PG_M, PG_RW; vm_page_t m; PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); PMAP_LOCK_ASSERT(pmap, MA_OWNED); oldpte = pte_load_clear(ptq); if (oldpte & PG_W) pmap->pm_stats.wired_count -= 1; pmap_resident_count_adj(pmap, -1); if (oldpte & PG_MANAGED) { m = PHYS_TO_VM_PAGE(oldpte & PG_FRAME); if ((oldpte & (PG_M | PG_RW)) == (PG_M | PG_RW)) vm_page_dirty(m); if (oldpte & PG_A) vm_page_aflag_set(m, PGA_REFERENCED); CHANGE_PV_LIST_LOCK_TO_VM_PAGE(lockp, m); pmap_pvh_free(&m->md, pmap, va); if (TAILQ_EMPTY(&m->md.pv_list) && (m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); if (TAILQ_EMPTY(&pvh->pv_list)) vm_page_aflag_clear(m, PGA_WRITEABLE); } pmap_delayed_invl_page(m); } return (pmap_unuse_pt(pmap, va, ptepde, free)); } /* * Remove a single page from a process address space */ static void pmap_remove_page(pmap_t pmap, vm_offset_t va, pd_entry_t *pde, struct spglist *free) { struct rwlock *lock; pt_entry_t *pte, PG_V; PG_V = pmap_valid_bit(pmap); PMAP_LOCK_ASSERT(pmap, MA_OWNED); if ((*pde & PG_V) == 0) return; pte = pmap_pde_to_pte(pde, va); if ((*pte & PG_V) == 0) return; lock = NULL; pmap_remove_pte(pmap, pte, va, *pde, free, &lock); if (lock != NULL) rw_wunlock(lock); pmap_invalidate_page(pmap, va); } /* * Removes the specified range of addresses from the page table page. */ static bool pmap_remove_ptes(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, pd_entry_t *pde, struct spglist *free, struct rwlock **lockp) { pt_entry_t PG_G, *pte; vm_offset_t va; bool anyvalid; PMAP_LOCK_ASSERT(pmap, MA_OWNED); PG_G = pmap_global_bit(pmap); anyvalid = false; va = eva; for (pte = pmap_pde_to_pte(pde, sva); sva != eva; pte++, sva += PAGE_SIZE) { if (*pte == 0) { if (va != eva) { pmap_invalidate_range(pmap, va, sva); va = eva; } continue; } if ((*pte & PG_G) == 0) anyvalid = true; else if (va == eva) va = sva; if (pmap_remove_pte(pmap, pte, sva, *pde, free, lockp)) { sva += PAGE_SIZE; break; } } if (va != eva) pmap_invalidate_range(pmap, va, sva); return (anyvalid); } static void pmap_remove1(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, bool map_delete) { struct rwlock *lock; vm_page_t mt; vm_offset_t va_next; pml5_entry_t *pml5e; pml4_entry_t *pml4e; pdp_entry_t *pdpe; pd_entry_t ptpaddr, *pde; pt_entry_t PG_G, PG_V; struct spglist free; int anyvalid; PG_G = pmap_global_bit(pmap); PG_V = pmap_valid_bit(pmap); /* * If there are no resident pages besides the top level page * table page(s), there is nothing to do. Kernel pmap always * accounts whole preloaded area as resident, which makes its * resident count > 2. * Perform an unsynchronized read. This is, however, safe. */ if (pmap->pm_stats.resident_count <= 1 + (pmap->pm_pmltopu != NULL ? 1 : 0)) return; anyvalid = 0; SLIST_INIT(&free); pmap_delayed_invl_start(); PMAP_LOCK(pmap); if (map_delete) pmap_pkru_on_remove(pmap, sva, eva); /* * special handling of removing one page. a very * common operation and easy to short circuit some * code. */ if (sva + PAGE_SIZE == eva) { pde = pmap_pde(pmap, sva); if (pde && (*pde & PG_PS) == 0) { pmap_remove_page(pmap, sva, pde, &free); goto out; } } lock = NULL; for (; sva < eva; sva = va_next) { if (pmap->pm_stats.resident_count == 0) break; if (pmap_is_la57(pmap)) { pml5e = pmap_pml5e(pmap, sva); if ((*pml5e & PG_V) == 0) { va_next = (sva + NBPML5) & ~PML5MASK; if (va_next < sva) va_next = eva; continue; } pml4e = pmap_pml5e_to_pml4e(pml5e, sva); } else { pml4e = pmap_pml4e(pmap, sva); } if ((*pml4e & PG_V) == 0) { va_next = (sva + NBPML4) & ~PML4MASK; if (va_next < sva) va_next = eva; continue; } va_next = (sva + NBPDP) & ~PDPMASK; if (va_next < sva) va_next = eva; pdpe = pmap_pml4e_to_pdpe(pml4e, sva); if ((*pdpe & PG_V) == 0) continue; if ((*pdpe & PG_PS) != 0) { KASSERT(va_next <= eva, ("partial update of non-transparent 1G mapping " "pdpe %#lx sva %#lx eva %#lx va_next %#lx", *pdpe, sva, eva, va_next)); MPASS(pmap != kernel_pmap); /* XXXKIB */ MPASS((*pdpe & (PG_MANAGED | PG_G)) == 0); anyvalid = 1; *pdpe = 0; pmap_resident_count_adj(pmap, -NBPDP / PAGE_SIZE); mt = PHYS_TO_VM_PAGE(*pmap_pml4e(pmap, sva) & PG_FRAME); pmap_unwire_ptp(pmap, sva, mt, &free); continue; } /* * Calculate index for next page table. */ va_next = (sva + NBPDR) & ~PDRMASK; if (va_next < sva) va_next = eva; pde = pmap_pdpe_to_pde(pdpe, sva); ptpaddr = *pde; /* * Weed out invalid mappings. */ if (ptpaddr == 0) continue; /* * Check for large page. */ if ((ptpaddr & PG_PS) != 0) { /* * Are we removing the entire large page? If not, * demote the mapping and fall through. */ if (sva + NBPDR == va_next && eva >= va_next) { /* * The TLB entry for a PG_G mapping is * invalidated by pmap_remove_pde(). */ if ((ptpaddr & PG_G) == 0) anyvalid = 1; pmap_remove_pde(pmap, pde, sva, &free, &lock); continue; } else if (!pmap_demote_pde_locked(pmap, pde, sva, &lock)) { /* The large page mapping was destroyed. */ continue; } else ptpaddr = *pde; } /* * Limit our scan to either the end of the va represented * by the current page table page, or to the end of the * range being removed. */ if (va_next > eva) va_next = eva; if (pmap_remove_ptes(pmap, sva, va_next, pde, &free, &lock)) anyvalid = 1; } if (lock != NULL) rw_wunlock(lock); out: if (anyvalid) pmap_invalidate_all(pmap); PMAP_UNLOCK(pmap); pmap_delayed_invl_finish(); vm_page_free_pages_toq(&free, true); } /* * Remove the given range of addresses from the specified map. * * It is assumed that the start and end are properly * rounded to the page size. */ void pmap_remove(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { pmap_remove1(pmap, sva, eva, false); } /* * Remove the given range of addresses as part of a logical unmap * operation. This has the effect of calling pmap_remove(), but * also clears any metadata that should persist for the lifetime * of a logical mapping. */ void pmap_map_delete(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { pmap_remove1(pmap, sva, eva, true); } /* * Routine: pmap_remove_all * Function: * Removes this physical page from * all physical maps in which it resides. * Reflects back modify bits to the pager. * * Notes: * Original versions of this routine were very * inefficient because they iteratively called * pmap_remove (slow...) */ void pmap_remove_all(vm_page_t m) { struct md_page *pvh; pv_entry_t pv; pmap_t pmap; struct rwlock *lock; pt_entry_t *pte, tpte, PG_A, PG_M, PG_RW; pd_entry_t *pde; vm_offset_t va; struct spglist free; int pvh_gen, md_gen; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_remove_all: page %p is not managed", m)); SLIST_INIT(&free); lock = VM_PAGE_TO_PV_LIST_LOCK(m); pvh = (m->flags & PG_FICTITIOUS) != 0 ? &pv_dummy : pa_to_pvh(VM_PAGE_TO_PHYS(m)); rw_wlock(lock); retry: while ((pv = TAILQ_FIRST(&pvh->pv_list)) != NULL) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); goto retry; } } va = pv->pv_va; pde = pmap_pde(pmap, va); (void)pmap_demote_pde_locked(pmap, pde, va, &lock); PMAP_UNLOCK(pmap); } while ((pv = TAILQ_FIRST(&m->md.pv_list)) != NULL) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; md_gen = m->md.pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen || md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); goto retry; } } PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); pmap_resident_count_adj(pmap, -1); pde = pmap_pde(pmap, pv->pv_va); KASSERT((*pde & PG_PS) == 0, ("pmap_remove_all: found" " a 2mpage in page %p's pv list", m)); pte = pmap_pde_to_pte(pde, pv->pv_va); tpte = pte_load_clear(pte); if (tpte & PG_W) pmap->pm_stats.wired_count--; if (tpte & PG_A) vm_page_aflag_set(m, PGA_REFERENCED); /* * Update the vm_page_t clean and reference bits. */ if ((tpte & (PG_M | PG_RW)) == (PG_M | PG_RW)) vm_page_dirty(m); pmap_unuse_pt(pmap, pv->pv_va, *pde, &free); pmap_invalidate_page(pmap, pv->pv_va); TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; free_pv_entry(pmap, pv); PMAP_UNLOCK(pmap); } vm_page_aflag_clear(m, PGA_WRITEABLE); rw_wunlock(lock); pmap_delayed_invl_wait(m); vm_page_free_pages_toq(&free, true); } /* * pmap_protect_pde: do the things to protect a 2mpage in a process */ static boolean_t pmap_protect_pde(pmap_t pmap, pd_entry_t *pde, vm_offset_t sva, vm_prot_t prot) { pd_entry_t newpde, oldpde; vm_page_t m, mt; boolean_t anychanged; pt_entry_t PG_G, PG_M, PG_RW; PG_G = pmap_global_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT((sva & PDRMASK) == 0, ("pmap_protect_pde: sva is not 2mpage aligned")); anychanged = FALSE; retry: oldpde = newpde = *pde; if ((prot & VM_PROT_WRITE) == 0) { if ((oldpde & (PG_MANAGED | PG_M | PG_RW)) == (PG_MANAGED | PG_M | PG_RW)) { m = PHYS_TO_VM_PAGE(oldpde & PG_PS_FRAME); for (mt = m; mt < &m[NBPDR / PAGE_SIZE]; mt++) vm_page_dirty(mt); } newpde &= ~(PG_RW | PG_M); } if ((prot & VM_PROT_EXECUTE) == 0) newpde |= pg_nx; if (newpde != oldpde) { /* * As an optimization to future operations on this PDE, clear * PG_PROMOTED. The impending invalidation will remove any * lingering 4KB page mappings from the TLB. */ if (!atomic_cmpset_long(pde, oldpde, newpde & ~PG_PROMOTED)) goto retry; if ((oldpde & PG_G) != 0) pmap_invalidate_pde_page(kernel_pmap, sva, oldpde); else anychanged = TRUE; } return (anychanged); } /* * Set the physical protection on the * specified range of this map as requested. */ void pmap_protect(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, vm_prot_t prot) { vm_page_t m; vm_offset_t va_next; pml4_entry_t *pml4e; pdp_entry_t *pdpe; pd_entry_t ptpaddr, *pde; pt_entry_t *pte, PG_G, PG_M, PG_RW, PG_V; pt_entry_t obits, pbits; boolean_t anychanged; KASSERT((prot & ~VM_PROT_ALL) == 0, ("invalid prot %x", prot)); if (prot == VM_PROT_NONE) { pmap_remove(pmap, sva, eva); return; } if ((prot & (VM_PROT_WRITE|VM_PROT_EXECUTE)) == (VM_PROT_WRITE|VM_PROT_EXECUTE)) return; PG_G = pmap_global_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_RW = pmap_rw_bit(pmap); anychanged = FALSE; /* * Although this function delays and batches the invalidation * of stale TLB entries, it does not need to call * pmap_delayed_invl_start() and * pmap_delayed_invl_finish(), because it does not * ordinarily destroy mappings. Stale TLB entries from * protection-only changes need only be invalidated before the * pmap lock is released, because protection-only changes do * not destroy PV entries. Even operations that iterate over * a physical page's PV list of mappings, like * pmap_remove_write(), acquire the pmap lock for each * mapping. Consequently, for protection-only changes, the * pmap lock suffices to synchronize both page table and TLB * updates. * * This function only destroys a mapping if pmap_demote_pde() * fails. In that case, stale TLB entries are immediately * invalidated. */ PMAP_LOCK(pmap); for (; sva < eva; sva = va_next) { pml4e = pmap_pml4e(pmap, sva); if (pml4e == NULL || (*pml4e & PG_V) == 0) { va_next = (sva + NBPML4) & ~PML4MASK; if (va_next < sva) va_next = eva; continue; } va_next = (sva + NBPDP) & ~PDPMASK; if (va_next < sva) va_next = eva; pdpe = pmap_pml4e_to_pdpe(pml4e, sva); if ((*pdpe & PG_V) == 0) continue; if ((*pdpe & PG_PS) != 0) { KASSERT(va_next <= eva, ("partial update of non-transparent 1G mapping " "pdpe %#lx sva %#lx eva %#lx va_next %#lx", *pdpe, sva, eva, va_next)); retry_pdpe: obits = pbits = *pdpe; MPASS((pbits & (PG_MANAGED | PG_G)) == 0); MPASS(pmap != kernel_pmap); /* XXXKIB */ if ((prot & VM_PROT_WRITE) == 0) pbits &= ~(PG_RW | PG_M); if ((prot & VM_PROT_EXECUTE) == 0) pbits |= pg_nx; if (pbits != obits) { if (!atomic_cmpset_long(pdpe, obits, pbits)) /* PG_PS cannot be cleared under us, */ goto retry_pdpe; anychanged = TRUE; } continue; } va_next = (sva + NBPDR) & ~PDRMASK; if (va_next < sva) va_next = eva; pde = pmap_pdpe_to_pde(pdpe, sva); ptpaddr = *pde; /* * Weed out invalid mappings. */ if (ptpaddr == 0) continue; /* * Check for large page. */ if ((ptpaddr & PG_PS) != 0) { /* * Are we protecting the entire large page? If not, * demote the mapping and fall through. */ if (sva + NBPDR == va_next && eva >= va_next) { /* * The TLB entry for a PG_G mapping is * invalidated by pmap_protect_pde(). */ if (pmap_protect_pde(pmap, pde, sva, prot)) anychanged = TRUE; continue; } else if (!pmap_demote_pde(pmap, pde, sva)) { /* * The large page mapping was destroyed. */ continue; } } if (va_next > eva) va_next = eva; for (pte = pmap_pde_to_pte(pde, sva); sva != va_next; pte++, sva += PAGE_SIZE) { retry: obits = pbits = *pte; if ((pbits & PG_V) == 0) continue; if ((prot & VM_PROT_WRITE) == 0) { if ((pbits & (PG_MANAGED | PG_M | PG_RW)) == (PG_MANAGED | PG_M | PG_RW)) { m = PHYS_TO_VM_PAGE(pbits & PG_FRAME); vm_page_dirty(m); } pbits &= ~(PG_RW | PG_M); } if ((prot & VM_PROT_EXECUTE) == 0) pbits |= pg_nx; if (pbits != obits) { if (!atomic_cmpset_long(pte, obits, pbits)) goto retry; if (obits & PG_G) pmap_invalidate_page(pmap, sva); else anychanged = TRUE; } } } if (anychanged) pmap_invalidate_all(pmap); PMAP_UNLOCK(pmap); } static bool pmap_pde_ept_executable(pmap_t pmap, pd_entry_t pde) { if (pmap->pm_type != PT_EPT) return (false); return ((pde & EPT_PG_EXECUTE) != 0); } #if VM_NRESERVLEVEL > 0 /* * Tries to promote the 512, contiguous 4KB page mappings that are within a * single page table page (PTP) to a single 2MB page mapping. For promotion * to occur, two conditions must be met: (1) the 4KB page mappings must map * aligned, contiguous physical memory and (2) the 4KB page mappings must have * identical characteristics. */ static bool pmap_promote_pde(pmap_t pmap, pd_entry_t *pde, vm_offset_t va, vm_page_t mpte, struct rwlock **lockp) { pd_entry_t newpde; pt_entry_t *firstpte, oldpte, pa, *pte; pt_entry_t allpte_PG_A, PG_A, PG_G, PG_M, PG_PKU_MASK, PG_RW, PG_V; int PG_PTE_CACHE; PMAP_LOCK_ASSERT(pmap, MA_OWNED); if (!pmap_ps_enabled(pmap)) return (false); PG_A = pmap_accessed_bit(pmap); PG_G = pmap_global_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_RW = pmap_rw_bit(pmap); PG_PKU_MASK = pmap_pku_mask_bit(pmap); PG_PTE_CACHE = pmap_cache_mask(pmap, 0); /* * Examine the first PTE in the specified PTP. Abort if this PTE is * ineligible for promotion due to hardware errata, invalid, or does * not map the first 4KB physical page within a 2MB page. */ firstpte = (pt_entry_t *)PHYS_TO_DMAP(*pde & PG_FRAME); newpde = *firstpte; if (!pmap_allow_2m_x_page(pmap, pmap_pde_ept_executable(pmap, newpde))) return (false); if ((newpde & ((PG_FRAME & PDRMASK) | PG_V)) != PG_V) { counter_u64_add(pmap_pde_p_failures, 1); CTR2(KTR_PMAP, "pmap_promote_pde: failure for va %#lx" " in pmap %p", va, pmap); return (false); } /* * Both here and in the below "for" loop, to allow for repromotion * after MADV_FREE, conditionally write protect a clean PTE before * possibly aborting the promotion due to other PTE attributes. Why? * Suppose that MADV_FREE is applied to a part of a superpage, the * address range [S, E). pmap_advise() will demote the superpage * mapping, destroy the 4KB page mapping at the end of [S, E), and * clear PG_M and PG_A in the PTEs for the rest of [S, E). Later, * imagine that the memory in [S, E) is recycled, but the last 4KB * page in [S, E) is not the last to be rewritten, or simply accessed. * In other words, there is still a 4KB page in [S, E), call it P, * that is writeable but PG_M and PG_A are clear in P's PTE. Unless * we write protect P before aborting the promotion, if and when P is * finally rewritten, there won't be a page fault to trigger * repromotion. */ setpde: if ((newpde & (PG_M | PG_RW)) == PG_RW) { /* * When PG_M is already clear, PG_RW can be cleared without * a TLB invalidation. */ if (!atomic_fcmpset_long(firstpte, &newpde, newpde & ~PG_RW)) goto setpde; newpde &= ~PG_RW; CTR2(KTR_PMAP, "pmap_promote_pde: protect for va %#lx" " in pmap %p", va & ~PDRMASK, pmap); } /* * Examine each of the other PTEs in the specified PTP. Abort if this * PTE maps an unexpected 4KB physical page or does not have identical * characteristics to the first PTE. */ allpte_PG_A = newpde & PG_A; pa = (newpde & (PG_PS_FRAME | PG_V)) + NBPDR - PAGE_SIZE; for (pte = firstpte + NPTEPG - 1; pte > firstpte; pte--) { oldpte = *pte; if ((oldpte & (PG_FRAME | PG_V)) != pa) { counter_u64_add(pmap_pde_p_failures, 1); CTR2(KTR_PMAP, "pmap_promote_pde: failure for va %#lx" " in pmap %p", va, pmap); return (false); } setpte: if ((oldpte & (PG_M | PG_RW)) == PG_RW) { /* * When PG_M is already clear, PG_RW can be cleared * without a TLB invalidation. */ if (!atomic_fcmpset_long(pte, &oldpte, oldpte & ~PG_RW)) goto setpte; oldpte &= ~PG_RW; CTR2(KTR_PMAP, "pmap_promote_pde: protect for va %#lx" " in pmap %p", (oldpte & PG_FRAME & PDRMASK) | (va & ~PDRMASK), pmap); } if ((oldpte & PG_PTE_PROMOTE) != (newpde & PG_PTE_PROMOTE)) { counter_u64_add(pmap_pde_p_failures, 1); CTR2(KTR_PMAP, "pmap_promote_pde: failure for va %#lx" " in pmap %p", va, pmap); return (false); } allpte_PG_A &= oldpte; pa -= PAGE_SIZE; } /* * Unless all PTEs have PG_A set, clear it from the superpage mapping, * so that promotions triggered by speculative mappings, such as * pmap_enter_quick(), don't automatically mark the underlying pages * as referenced. */ newpde &= ~PG_A | allpte_PG_A; /* * EPT PTEs with PG_M set and PG_A clear are not supported by early * MMUs supporting EPT. */ KASSERT((newpde & PG_A) != 0 || safe_to_clear_referenced(pmap, newpde), ("unsupported EPT PTE")); /* * Save the PTP in its current state until the PDE mapping the * superpage is demoted by pmap_demote_pde() or destroyed by * pmap_remove_pde(). If PG_A is not set in every PTE, then request * that the PTP be refilled on demotion. */ if (mpte == NULL) mpte = PHYS_TO_VM_PAGE(*pde & PG_FRAME); KASSERT(mpte >= vm_page_array && mpte < &vm_page_array[vm_page_array_size], ("pmap_promote_pde: page table page is out of range")); KASSERT(mpte->pindex == pmap_pde_pindex(va), ("pmap_promote_pde: page table page's pindex is wrong " "mpte %p pidx %#lx va %#lx va pde pidx %#lx", mpte, mpte->pindex, va, pmap_pde_pindex(va))); if (pmap_insert_pt_page(pmap, mpte, true, allpte_PG_A != 0)) { counter_u64_add(pmap_pde_p_failures, 1); CTR2(KTR_PMAP, "pmap_promote_pde: failure for va %#lx in pmap %p", va, pmap); return (false); } /* * Promote the pv entries. */ if ((newpde & PG_MANAGED) != 0) pmap_pv_promote_pde(pmap, va, newpde & PG_PS_FRAME, lockp); /* * Propagate the PAT index to its proper position. */ newpde = pmap_swap_pat(pmap, newpde); /* * Map the superpage. */ if (workaround_erratum383) pmap_update_pde(pmap, va, pde, PG_PS | newpde); else pde_store(pde, PG_PROMOTED | PG_PS | newpde); counter_u64_add(pmap_pde_promotions, 1); CTR2(KTR_PMAP, "pmap_promote_pde: success for va %#lx" " in pmap %p", va, pmap); return (true); } #endif /* VM_NRESERVLEVEL > 0 */ static int pmap_enter_largepage(pmap_t pmap, vm_offset_t va, pt_entry_t newpte, int flags, int psind) { vm_page_t mp; pt_entry_t origpte, *pml4e, *pdpe, *pde, pten, PG_V; PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT(psind > 0 && psind < MAXPAGESIZES && pagesizes[psind] != 0, ("psind %d unexpected", psind)); KASSERT(((newpte & PG_FRAME) & (pagesizes[psind] - 1)) == 0, ("unaligned phys address %#lx newpte %#lx psind %d", newpte & PG_FRAME, newpte, psind)); KASSERT((va & (pagesizes[psind] - 1)) == 0, ("unaligned va %#lx psind %d", va, psind)); KASSERT(va < VM_MAXUSER_ADDRESS, ("kernel mode non-transparent superpage")); /* XXXKIB */ KASSERT(va + pagesizes[psind] < VM_MAXUSER_ADDRESS, ("overflowing user map va %#lx psind %d", va, psind)); /* XXXKIB */ PG_V = pmap_valid_bit(pmap); restart: if (!pmap_pkru_same(pmap, va, va + pagesizes[psind])) return (KERN_PROTECTION_FAILURE); pten = newpte; if (va < VM_MAXUSER_ADDRESS && pmap->pm_type == PT_X86) pten |= pmap_pkru_get(pmap, va); if (psind == 2) { /* 1G */ pml4e = pmap_pml4e(pmap, va); if (pml4e == NULL || (*pml4e & PG_V) == 0) { mp = pmap_allocpte_alloc(pmap, pmap_pml4e_pindex(va), NULL, va); if (mp == NULL) goto allocf; pdpe = (pdp_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(mp)); pdpe = &pdpe[pmap_pdpe_index(va)]; origpte = *pdpe; MPASS(origpte == 0); } else { pdpe = pmap_pml4e_to_pdpe(pml4e, va); KASSERT(pdpe != NULL, ("va %#lx lost pdpe", va)); origpte = *pdpe; if ((origpte & PG_V) == 0) { mp = PHYS_TO_VM_PAGE(*pml4e & PG_FRAME); mp->ref_count++; } } *pdpe = pten; } else /* (psind == 1) */ { /* 2M */ pde = pmap_pde(pmap, va); if (pde == NULL) { mp = pmap_allocpte_alloc(pmap, pmap_pdpe_pindex(va), NULL, va); if (mp == NULL) goto allocf; pde = (pd_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(mp)); pde = &pde[pmap_pde_index(va)]; origpte = *pde; MPASS(origpte == 0); } else { origpte = *pde; if ((origpte & PG_V) == 0) { pdpe = pmap_pdpe(pmap, va); MPASS(pdpe != NULL && (*pdpe & PG_V) != 0); mp = PHYS_TO_VM_PAGE(*pdpe & PG_FRAME); mp->ref_count++; } } *pde = pten; } KASSERT((origpte & PG_V) == 0 || ((origpte & PG_PS) != 0 && (origpte & PG_PS_FRAME) == (pten & PG_PS_FRAME)), ("va %#lx changing %s phys page origpte %#lx pten %#lx", va, psind == 2 ? "1G" : "2M", origpte, pten)); if ((pten & PG_W) != 0 && (origpte & PG_W) == 0) pmap->pm_stats.wired_count += pagesizes[psind] / PAGE_SIZE; else if ((pten & PG_W) == 0 && (origpte & PG_W) != 0) pmap->pm_stats.wired_count -= pagesizes[psind] / PAGE_SIZE; if ((origpte & PG_V) == 0) pmap_resident_count_adj(pmap, pagesizes[psind] / PAGE_SIZE); return (KERN_SUCCESS); allocf: if ((flags & PMAP_ENTER_NOSLEEP) != 0) return (KERN_RESOURCE_SHORTAGE); PMAP_UNLOCK(pmap); vm_wait(NULL); PMAP_LOCK(pmap); goto restart; } /* * Insert the given physical page (p) at * the specified virtual address (v) in the * target physical map with the protection requested. * * If specified, the page will be wired down, meaning * that the related pte can not be reclaimed. * * NB: This is the only routine which MAY NOT lazy-evaluate * or lose information. That is, this routine must actually * insert this page into the given map NOW. * * When destroying both a page table and PV entry, this function * performs the TLB invalidation before releasing the PV list * lock, so we do not need pmap_delayed_invl_page() calls here. */ int pmap_enter(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, u_int flags, int8_t psind) { struct rwlock *lock; pd_entry_t *pde; pt_entry_t *pte, PG_G, PG_A, PG_M, PG_RW, PG_V; pt_entry_t newpte, origpte; pv_entry_t pv; vm_paddr_t opa, pa; vm_page_t mpte, om; int rv; boolean_t nosleep; PG_A = pmap_accessed_bit(pmap); PG_G = pmap_global_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_RW = pmap_rw_bit(pmap); va = trunc_page(va); KASSERT(va <= VM_MAX_KERNEL_ADDRESS, ("pmap_enter: toobig")); KASSERT(va < UPT_MIN_ADDRESS || va >= UPT_MAX_ADDRESS, ("pmap_enter: invalid to pmap_enter page table pages (va: 0x%lx)", va)); KASSERT((m->oflags & VPO_UNMANAGED) != 0 || !VA_IS_CLEANMAP(va), ("pmap_enter: managed mapping within the clean submap")); if ((m->oflags & VPO_UNMANAGED) == 0) VM_PAGE_OBJECT_BUSY_ASSERT(m); KASSERT((flags & PMAP_ENTER_RESERVED) == 0, ("pmap_enter: flags %u has reserved bits set", flags)); pa = VM_PAGE_TO_PHYS(m); newpte = (pt_entry_t)(pa | PG_A | PG_V); if ((flags & VM_PROT_WRITE) != 0) newpte |= PG_M; if ((prot & VM_PROT_WRITE) != 0) newpte |= PG_RW; KASSERT((newpte & (PG_M | PG_RW)) != PG_M, ("pmap_enter: flags includes VM_PROT_WRITE but prot doesn't")); if ((prot & VM_PROT_EXECUTE) == 0) newpte |= pg_nx; if ((flags & PMAP_ENTER_WIRED) != 0) newpte |= PG_W; if (va < VM_MAXUSER_ADDRESS) newpte |= PG_U; if (pmap == kernel_pmap) newpte |= PG_G; newpte |= pmap_cache_bits(pmap, m->md.pat_mode, psind > 0); /* * Set modified bit gratuitously for writeable mappings if * the page is unmanaged. We do not want to take a fault * to do the dirty bit accounting for these mappings. */ if ((m->oflags & VPO_UNMANAGED) != 0) { if ((newpte & PG_RW) != 0) newpte |= PG_M; } else newpte |= PG_MANAGED; lock = NULL; PMAP_LOCK(pmap); if ((flags & PMAP_ENTER_LARGEPAGE) != 0) { KASSERT((m->oflags & VPO_UNMANAGED) != 0, ("managed largepage va %#lx flags %#x", va, flags)); rv = pmap_enter_largepage(pmap, va, newpte | PG_PS, flags, psind); goto out; } if (psind == 1) { /* Assert the required virtual and physical alignment. */ KASSERT((va & PDRMASK) == 0, ("pmap_enter: va unaligned")); KASSERT(m->psind > 0, ("pmap_enter: m->psind < psind")); rv = pmap_enter_pde(pmap, va, newpte | PG_PS, flags, m, &lock); goto out; } mpte = NULL; /* * In the case that a page table page is not * resident, we are creating it here. */ retry: pde = pmap_pde(pmap, va); if (pde != NULL && (*pde & PG_V) != 0 && ((*pde & PG_PS) == 0 || pmap_demote_pde_locked(pmap, pde, va, &lock))) { pte = pmap_pde_to_pte(pde, va); if (va < VM_MAXUSER_ADDRESS && mpte == NULL) { mpte = PHYS_TO_VM_PAGE(*pde & PG_FRAME); mpte->ref_count++; } } else if (va < VM_MAXUSER_ADDRESS) { /* * Here if the pte page isn't mapped, or if it has been * deallocated. */ nosleep = (flags & PMAP_ENTER_NOSLEEP) != 0; mpte = pmap_allocpte_alloc(pmap, pmap_pde_pindex(va), nosleep ? NULL : &lock, va); if (mpte == NULL && nosleep) { rv = KERN_RESOURCE_SHORTAGE; goto out; } goto retry; } else panic("pmap_enter: invalid page directory va=%#lx", va); origpte = *pte; pv = NULL; if (va < VM_MAXUSER_ADDRESS && pmap->pm_type == PT_X86) newpte |= pmap_pkru_get(pmap, va); /* * Is the specified virtual address already mapped? */ if ((origpte & PG_V) != 0) { /* * Wiring change, just update stats. We don't worry about * wiring PT pages as they remain resident as long as there * are valid mappings in them. Hence, if a user page is wired, * the PT page will be also. */ if ((newpte & PG_W) != 0 && (origpte & PG_W) == 0) pmap->pm_stats.wired_count++; else if ((newpte & PG_W) == 0 && (origpte & PG_W) != 0) pmap->pm_stats.wired_count--; /* * Remove the extra PT page reference. */ if (mpte != NULL) { mpte->ref_count--; KASSERT(mpte->ref_count > 0, ("pmap_enter: missing reference to page table page," " va: 0x%lx", va)); } /* * Has the physical page changed? */ opa = origpte & PG_FRAME; if (opa == pa) { /* * No, might be a protection or wiring change. */ if ((origpte & PG_MANAGED) != 0 && (newpte & PG_RW) != 0) vm_page_aflag_set(m, PGA_WRITEABLE); if (((origpte ^ newpte) & ~(PG_M | PG_A)) == 0) goto unchanged; goto validate; } /* * The physical page has changed. Temporarily invalidate * the mapping. This ensures that all threads sharing the * pmap keep a consistent view of the mapping, which is * necessary for the correct handling of COW faults. It * also permits reuse of the old mapping's PV entry, * avoiding an allocation. * * For consistency, handle unmanaged mappings the same way. */ origpte = pte_load_clear(pte); KASSERT((origpte & PG_FRAME) == opa, ("pmap_enter: unexpected pa update for %#lx", va)); if ((origpte & PG_MANAGED) != 0) { om = PHYS_TO_VM_PAGE(opa); /* * The pmap lock is sufficient to synchronize with * concurrent calls to pmap_page_test_mappings() and * pmap_ts_referenced(). */ if ((origpte & (PG_M | PG_RW)) == (PG_M | PG_RW)) vm_page_dirty(om); if ((origpte & PG_A) != 0) { pmap_invalidate_page(pmap, va); vm_page_aflag_set(om, PGA_REFERENCED); } CHANGE_PV_LIST_LOCK_TO_PHYS(&lock, opa); pv = pmap_pvh_remove(&om->md, pmap, va); KASSERT(pv != NULL, ("pmap_enter: no PV entry for %#lx", va)); if ((newpte & PG_MANAGED) == 0) free_pv_entry(pmap, pv); if ((om->a.flags & PGA_WRITEABLE) != 0 && TAILQ_EMPTY(&om->md.pv_list) && ((om->flags & PG_FICTITIOUS) != 0 || TAILQ_EMPTY(&pa_to_pvh(opa)->pv_list))) vm_page_aflag_clear(om, PGA_WRITEABLE); } else { /* * Since this mapping is unmanaged, assume that PG_A * is set. */ pmap_invalidate_page(pmap, va); } origpte = 0; } else { /* * Increment the counters. */ if ((newpte & PG_W) != 0) pmap->pm_stats.wired_count++; pmap_resident_count_adj(pmap, 1); } /* * Enter on the PV list if part of our managed memory. */ if ((newpte & PG_MANAGED) != 0) { if (pv == NULL) { pv = get_pv_entry(pmap, &lock); pv->pv_va = va; } CHANGE_PV_LIST_LOCK_TO_PHYS(&lock, pa); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; if ((newpte & PG_RW) != 0) vm_page_aflag_set(m, PGA_WRITEABLE); } /* * Update the PTE. */ if ((origpte & PG_V) != 0) { validate: origpte = pte_load_store(pte, newpte); KASSERT((origpte & PG_FRAME) == pa, ("pmap_enter: unexpected pa update for %#lx", va)); if ((newpte & PG_M) == 0 && (origpte & (PG_M | PG_RW)) == (PG_M | PG_RW)) { if ((origpte & PG_MANAGED) != 0) vm_page_dirty(m); /* * Although the PTE may still have PG_RW set, TLB * invalidation may nonetheless be required because * the PTE no longer has PG_M set. */ } else if ((origpte & PG_NX) != 0 || (newpte & PG_NX) == 0) { /* * This PTE change does not require TLB invalidation. */ goto unchanged; } if ((origpte & PG_A) != 0) pmap_invalidate_page(pmap, va); } else pte_store(pte, newpte); unchanged: #if VM_NRESERVLEVEL > 0 /* * If both the page table page and the reservation are fully * populated, then attempt promotion. */ if ((mpte == NULL || mpte->ref_count == NPTEPG) && (m->flags & PG_FICTITIOUS) == 0 && vm_reserv_level_iffullpop(m) == 0) (void)pmap_promote_pde(pmap, pde, va, mpte, &lock); #endif rv = KERN_SUCCESS; out: if (lock != NULL) rw_wunlock(lock); PMAP_UNLOCK(pmap); return (rv); } /* * Tries to create a read- and/or execute-only 2MB page mapping. Returns * KERN_SUCCESS if the mapping was created. Otherwise, returns an error * value. See pmap_enter_pde() for the possible error values when "no sleep", * "no replace", and "no reclaim" are specified. */ static int pmap_enter_2mpage(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, struct rwlock **lockp) { pd_entry_t newpde; pt_entry_t PG_V; PMAP_LOCK_ASSERT(pmap, MA_OWNED); PG_V = pmap_valid_bit(pmap); newpde = VM_PAGE_TO_PHYS(m) | pmap_cache_bits(pmap, m->md.pat_mode, 1) | PG_PS | PG_V; if ((m->oflags & VPO_UNMANAGED) == 0) newpde |= PG_MANAGED; if ((prot & VM_PROT_EXECUTE) == 0) newpde |= pg_nx; if (va < VM_MAXUSER_ADDRESS) newpde |= PG_U; return (pmap_enter_pde(pmap, va, newpde, PMAP_ENTER_NOSLEEP | PMAP_ENTER_NOREPLACE | PMAP_ENTER_NORECLAIM, NULL, lockp)); } /* * Returns true if every page table entry in the specified page table page is * zero. */ static bool pmap_every_pte_zero(vm_paddr_t pa) { pt_entry_t *pt_end, *pte; KASSERT((pa & PAGE_MASK) == 0, ("pa is misaligned")); pte = (pt_entry_t *)PHYS_TO_DMAP(pa); for (pt_end = pte + NPTEPG; pte < pt_end; pte++) { if (*pte != 0) return (false); } return (true); } /* * Tries to create the specified 2MB page mapping. Returns KERN_SUCCESS if * the mapping was created, and one of KERN_FAILURE, KERN_NO_SPACE, * KERN_PROTECTION_FAILURE, or KERN_RESOURCE_SHORTAGE otherwise. Returns * KERN_FAILURE if either (1) PMAP_ENTER_NOREPLACE was specified and a 4KB * page mapping already exists within the 2MB virtual address range starting * at the specified virtual address or (2) the requested 2MB page mapping is * not supported due to hardware errata. Returns KERN_NO_SPACE if * PMAP_ENTER_NOREPLACE was specified and a 2MB page mapping already exists at * the specified virtual address. Returns KERN_PROTECTION_FAILURE if the PKRU * settings are not the same across the 2MB virtual address range starting at * the specified virtual address. Returns KERN_RESOURCE_SHORTAGE if either * (1) PMAP_ENTER_NOSLEEP was specified and a page table page allocation * failed or (2) PMAP_ENTER_NORECLAIM was specified and a PV entry allocation * failed. * * The parameter "m" is only used when creating a managed, writeable mapping. */ static int pmap_enter_pde(pmap_t pmap, vm_offset_t va, pd_entry_t newpde, u_int flags, vm_page_t m, struct rwlock **lockp) { struct spglist free; pd_entry_t oldpde, *pde; pt_entry_t PG_G, PG_RW, PG_V; vm_page_t mt, pdpg; KASSERT(pmap == kernel_pmap || (newpde & PG_W) == 0, ("pmap_enter_pde: cannot create wired user mapping")); PG_G = pmap_global_bit(pmap); PG_RW = pmap_rw_bit(pmap); KASSERT((newpde & (pmap_modified_bit(pmap) | PG_RW)) != PG_RW, ("pmap_enter_pde: newpde is missing PG_M")); PG_V = pmap_valid_bit(pmap); PMAP_LOCK_ASSERT(pmap, MA_OWNED); if (!pmap_allow_2m_x_page(pmap, pmap_pde_ept_executable(pmap, newpde))) { CTR2(KTR_PMAP, "pmap_enter_pde: 2m x blocked for va %#lx" " in pmap %p", va, pmap); return (KERN_FAILURE); } if ((pde = pmap_alloc_pde(pmap, va, &pdpg, (flags & PMAP_ENTER_NOSLEEP) != 0 ? NULL : lockp)) == NULL) { CTR2(KTR_PMAP, "pmap_enter_pde: failure for va %#lx" " in pmap %p", va, pmap); return (KERN_RESOURCE_SHORTAGE); } /* * If pkru is not same for the whole pde range, return failure * and let vm_fault() cope. Check after pde allocation, since * it could sleep. */ if (!pmap_pkru_same(pmap, va, va + NBPDR)) { pmap_abort_ptp(pmap, va, pdpg); return (KERN_PROTECTION_FAILURE); } if (va < VM_MAXUSER_ADDRESS && pmap->pm_type == PT_X86) { newpde &= ~X86_PG_PKU_MASK; newpde |= pmap_pkru_get(pmap, va); } /* * If there are existing mappings, either abort or remove them. */ oldpde = *pde; if ((oldpde & PG_V) != 0) { KASSERT(pdpg == NULL || pdpg->ref_count > 1, ("pmap_enter_pde: pdpg's reference count is too low")); if ((flags & PMAP_ENTER_NOREPLACE) != 0) { if ((oldpde & PG_PS) != 0) { if (pdpg != NULL) pdpg->ref_count--; CTR2(KTR_PMAP, "pmap_enter_pde: no space for va %#lx" " in pmap %p", va, pmap); return (KERN_NO_SPACE); } else if (va < VM_MAXUSER_ADDRESS || !pmap_every_pte_zero(oldpde & PG_FRAME)) { if (pdpg != NULL) pdpg->ref_count--; CTR2(KTR_PMAP, "pmap_enter_pde: failure for va %#lx" " in pmap %p", va, pmap); return (KERN_FAILURE); } } /* Break the existing mapping(s). */ SLIST_INIT(&free); if ((oldpde & PG_PS) != 0) { /* * The reference to the PD page that was acquired by * pmap_alloc_pde() ensures that it won't be freed. * However, if the PDE resulted from a promotion, then * a reserved PT page could be freed. */ (void)pmap_remove_pde(pmap, pde, va, &free, lockp); if ((oldpde & PG_G) == 0) pmap_invalidate_pde_page(pmap, va, oldpde); } else { pmap_delayed_invl_start(); if (pmap_remove_ptes(pmap, va, va + NBPDR, pde, &free, lockp)) pmap_invalidate_all(pmap); pmap_delayed_invl_finish(); } if (va < VM_MAXUSER_ADDRESS) { vm_page_free_pages_toq(&free, true); KASSERT(*pde == 0, ("pmap_enter_pde: non-zero pde %p", pde)); } else { KASSERT(SLIST_EMPTY(&free), ("pmap_enter_pde: freed kernel page table page")); /* * Both pmap_remove_pde() and pmap_remove_ptes() will * leave the kernel page table page zero filled. */ mt = PHYS_TO_VM_PAGE(*pde & PG_FRAME); if (pmap_insert_pt_page(pmap, mt, false, false)) panic("pmap_enter_pde: trie insert failed"); } } if ((newpde & PG_MANAGED) != 0) { /* * Abort this mapping if its PV entry could not be created. */ if (!pmap_pv_insert_pde(pmap, va, newpde, flags, lockp)) { if (pdpg != NULL) pmap_abort_ptp(pmap, va, pdpg); CTR2(KTR_PMAP, "pmap_enter_pde: failure for va %#lx" " in pmap %p", va, pmap); return (KERN_RESOURCE_SHORTAGE); } if ((newpde & PG_RW) != 0) { for (mt = m; mt < &m[NBPDR / PAGE_SIZE]; mt++) vm_page_aflag_set(mt, PGA_WRITEABLE); } } /* * Increment counters. */ if ((newpde & PG_W) != 0) pmap->pm_stats.wired_count += NBPDR / PAGE_SIZE; pmap_resident_count_adj(pmap, NBPDR / PAGE_SIZE); /* * Map the superpage. (This is not a promoted mapping; there will not * be any lingering 4KB page mappings in the TLB.) */ pde_store(pde, newpde); counter_u64_add(pmap_pde_mappings, 1); CTR2(KTR_PMAP, "pmap_enter_pde: success for va %#lx in pmap %p", va, pmap); return (KERN_SUCCESS); } /* * Maps a sequence of resident pages belonging to the same object. * The sequence begins with the given page m_start. This page is * mapped at the given virtual address start. Each subsequent page is * mapped at a virtual address that is offset from start by the same * amount as the page is offset from m_start within the object. The * last page in the sequence is the page with the largest offset from * m_start that can be mapped at a virtual address less than the given * virtual address end. Not every virtual page between start and end * is mapped; only those for which a resident page exists with the * corresponding offset from m_start are mapped. */ void pmap_enter_object(pmap_t pmap, vm_offset_t start, vm_offset_t end, vm_page_t m_start, vm_prot_t prot) { struct rwlock *lock; vm_offset_t va; vm_page_t m, mpte; vm_pindex_t diff, psize; int rv; VM_OBJECT_ASSERT_LOCKED(m_start->object); psize = atop(end - start); mpte = NULL; m = m_start; lock = NULL; PMAP_LOCK(pmap); while (m != NULL && (diff = m->pindex - m_start->pindex) < psize) { va = start + ptoa(diff); if ((va & PDRMASK) == 0 && va + NBPDR <= end && m->psind == 1 && pmap_ps_enabled(pmap) && ((rv = pmap_enter_2mpage(pmap, va, m, prot, &lock)) == KERN_SUCCESS || rv == KERN_NO_SPACE)) m = &m[NBPDR / PAGE_SIZE - 1]; else mpte = pmap_enter_quick_locked(pmap, va, m, prot, mpte, &lock); m = TAILQ_NEXT(m, listq); } if (lock != NULL) rw_wunlock(lock); PMAP_UNLOCK(pmap); } /* * this code makes some *MAJOR* assumptions: * 1. Current pmap & pmap exists. * 2. Not wired. * 3. Read access. * 4. No page table pages. * but is *MUCH* faster than pmap_enter... */ void pmap_enter_quick(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot) { struct rwlock *lock; lock = NULL; PMAP_LOCK(pmap); (void)pmap_enter_quick_locked(pmap, va, m, prot, NULL, &lock); if (lock != NULL) rw_wunlock(lock); PMAP_UNLOCK(pmap); } static vm_page_t pmap_enter_quick_locked(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, vm_page_t mpte, struct rwlock **lockp) { pd_entry_t *pde; pt_entry_t newpte, *pte, PG_V; KASSERT(!VA_IS_CLEANMAP(va) || (m->oflags & VPO_UNMANAGED) != 0, ("pmap_enter_quick_locked: managed mapping within the clean submap")); PG_V = pmap_valid_bit(pmap); PMAP_LOCK_ASSERT(pmap, MA_OWNED); pde = NULL; /* * In the case that a page table page is not * resident, we are creating it here. */ if (va < VM_MAXUSER_ADDRESS) { pdp_entry_t *pdpe; vm_pindex_t ptepindex; /* * Calculate pagetable page index */ ptepindex = pmap_pde_pindex(va); if (mpte && (mpte->pindex == ptepindex)) { mpte->ref_count++; } else { /* * If the page table page is mapped, we just increment * the hold count, and activate it. Otherwise, we * attempt to allocate a page table page, passing NULL * instead of the PV list lock pointer because we don't * intend to sleep. If this attempt fails, we don't * retry. Instead, we give up. */ pdpe = pmap_pdpe(pmap, va); if (pdpe != NULL && (*pdpe & PG_V) != 0) { if ((*pdpe & PG_PS) != 0) return (NULL); pde = pmap_pdpe_to_pde(pdpe, va); if ((*pde & PG_V) != 0) { if ((*pde & PG_PS) != 0) return (NULL); mpte = PHYS_TO_VM_PAGE(*pde & PG_FRAME); mpte->ref_count++; } else { mpte = pmap_allocpte_alloc(pmap, ptepindex, NULL, va); if (mpte == NULL) return (NULL); } } else { mpte = pmap_allocpte_alloc(pmap, ptepindex, NULL, va); if (mpte == NULL) return (NULL); } } pte = (pt_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(mpte)); pte = &pte[pmap_pte_index(va)]; } else { mpte = NULL; pte = vtopte(va); } if (*pte) { if (mpte != NULL) mpte->ref_count--; return (NULL); } /* * Enter on the PV list if part of our managed memory. */ if ((m->oflags & VPO_UNMANAGED) == 0 && !pmap_try_insert_pv_entry(pmap, va, m, lockp)) { if (mpte != NULL) pmap_abort_ptp(pmap, va, mpte); return (NULL); } /* * Increment counters */ pmap_resident_count_adj(pmap, 1); newpte = VM_PAGE_TO_PHYS(m) | PG_V | pmap_cache_bits(pmap, m->md.pat_mode, 0); if ((m->oflags & VPO_UNMANAGED) == 0) newpte |= PG_MANAGED; if ((prot & VM_PROT_EXECUTE) == 0) newpte |= pg_nx; if (va < VM_MAXUSER_ADDRESS) newpte |= PG_U | pmap_pkru_get(pmap, va); pte_store(pte, newpte); #if VM_NRESERVLEVEL > 0 /* * If both the PTP and the reservation are fully populated, then * attempt promotion. */ if ((mpte == NULL || mpte->ref_count == NPTEPG) && (m->flags & PG_FICTITIOUS) == 0 && vm_reserv_level_iffullpop(m) == 0) { if (pde == NULL) pde = pmap_pde(pmap, va); /* * If promotion succeeds, then the next call to this function * should not be given the unmapped PTP as a hint. */ if (pmap_promote_pde(pmap, pde, va, mpte, lockp)) mpte = NULL; } #endif return (mpte); } /* * Make a temporary mapping for a physical address. This is only intended * to be used for panic dumps. */ void * pmap_kenter_temporary(vm_paddr_t pa, int i) { vm_offset_t va; va = (vm_offset_t)crashdumpmap + (i * PAGE_SIZE); pmap_kenter(va, pa); pmap_invlpg(kernel_pmap, va); return ((void *)crashdumpmap); } /* * This code maps large physical mmap regions into the * processor address space. Note that some shortcuts * are taken, but the code works. */ void pmap_object_init_pt(pmap_t pmap, vm_offset_t addr, vm_object_t object, vm_pindex_t pindex, vm_size_t size) { pd_entry_t *pde; pt_entry_t PG_A, PG_M, PG_RW, PG_V; vm_paddr_t pa, ptepa; vm_page_t p, pdpg; int pat_mode; PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_RW = pmap_rw_bit(pmap); VM_OBJECT_ASSERT_WLOCKED(object); KASSERT(object->type == OBJT_DEVICE || object->type == OBJT_SG, ("pmap_object_init_pt: non-device object")); if ((addr & (NBPDR - 1)) == 0 && (size & (NBPDR - 1)) == 0) { if (!pmap_ps_enabled(pmap)) return; if (!vm_object_populate(object, pindex, pindex + atop(size))) return; p = vm_page_lookup(object, pindex); KASSERT(vm_page_all_valid(p), ("pmap_object_init_pt: invalid page %p", p)); pat_mode = p->md.pat_mode; /* * Abort the mapping if the first page is not physically * aligned to a 2MB page boundary. */ ptepa = VM_PAGE_TO_PHYS(p); if (ptepa & (NBPDR - 1)) return; /* * Skip the first page. Abort the mapping if the rest of * the pages are not physically contiguous or have differing * memory attributes. */ p = TAILQ_NEXT(p, listq); for (pa = ptepa + PAGE_SIZE; pa < ptepa + size; pa += PAGE_SIZE) { KASSERT(vm_page_all_valid(p), ("pmap_object_init_pt: invalid page %p", p)); if (pa != VM_PAGE_TO_PHYS(p) || pat_mode != p->md.pat_mode) return; p = TAILQ_NEXT(p, listq); } /* * Map using 2MB pages. Since "ptepa" is 2M aligned and * "size" is a multiple of 2M, adding the PAT setting to "pa" * will not affect the termination of this loop. */ PMAP_LOCK(pmap); for (pa = ptepa | pmap_cache_bits(pmap, pat_mode, 1); pa < ptepa + size; pa += NBPDR) { pde = pmap_alloc_pde(pmap, addr, &pdpg, NULL); if (pde == NULL) { /* * The creation of mappings below is only an * optimization. If a page directory page * cannot be allocated without blocking, * continue on to the next mapping rather than * blocking. */ addr += NBPDR; continue; } if ((*pde & PG_V) == 0) { pde_store(pde, pa | PG_PS | PG_M | PG_A | PG_U | PG_RW | PG_V); pmap_resident_count_adj(pmap, NBPDR / PAGE_SIZE); counter_u64_add(pmap_pde_mappings, 1); } else { /* Continue on if the PDE is already valid. */ pdpg->ref_count--; KASSERT(pdpg->ref_count > 0, ("pmap_object_init_pt: missing reference " "to page directory page, va: 0x%lx", addr)); } addr += NBPDR; } PMAP_UNLOCK(pmap); } } /* * Clear the wired attribute from the mappings for the specified range of * addresses in the given pmap. Every valid mapping within that range * must have the wired attribute set. In contrast, invalid mappings * cannot have the wired attribute set, so they are ignored. * * The wired attribute of the page table entry is not a hardware * feature, so there is no need to invalidate any TLB entries. * Since pmap_demote_pde() for the wired entry must never fail, * pmap_delayed_invl_start()/finish() calls around the * function are not needed. */ void pmap_unwire(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { vm_offset_t va_next; pml4_entry_t *pml4e; pdp_entry_t *pdpe; pd_entry_t *pde; pt_entry_t *pte, PG_V, PG_G __diagused; PG_V = pmap_valid_bit(pmap); PG_G = pmap_global_bit(pmap); PMAP_LOCK(pmap); for (; sva < eva; sva = va_next) { pml4e = pmap_pml4e(pmap, sva); if (pml4e == NULL || (*pml4e & PG_V) == 0) { va_next = (sva + NBPML4) & ~PML4MASK; if (va_next < sva) va_next = eva; continue; } va_next = (sva + NBPDP) & ~PDPMASK; if (va_next < sva) va_next = eva; pdpe = pmap_pml4e_to_pdpe(pml4e, sva); if ((*pdpe & PG_V) == 0) continue; if ((*pdpe & PG_PS) != 0) { KASSERT(va_next <= eva, ("partial update of non-transparent 1G mapping " "pdpe %#lx sva %#lx eva %#lx va_next %#lx", *pdpe, sva, eva, va_next)); MPASS(pmap != kernel_pmap); /* XXXKIB */ MPASS((*pdpe & (PG_MANAGED | PG_G)) == 0); atomic_clear_long(pdpe, PG_W); pmap->pm_stats.wired_count -= NBPDP / PAGE_SIZE; continue; } va_next = (sva + NBPDR) & ~PDRMASK; if (va_next < sva) va_next = eva; pde = pmap_pdpe_to_pde(pdpe, sva); if ((*pde & PG_V) == 0) continue; if ((*pde & PG_PS) != 0) { if ((*pde & PG_W) == 0) panic("pmap_unwire: pde %#jx is missing PG_W", (uintmax_t)*pde); /* * Are we unwiring the entire large page? If not, * demote the mapping and fall through. */ if (sva + NBPDR == va_next && eva >= va_next) { atomic_clear_long(pde, PG_W); pmap->pm_stats.wired_count -= NBPDR / PAGE_SIZE; continue; } else if (!pmap_demote_pde(pmap, pde, sva)) panic("pmap_unwire: demotion failed"); } if (va_next > eva) va_next = eva; for (pte = pmap_pde_to_pte(pde, sva); sva != va_next; pte++, sva += PAGE_SIZE) { if ((*pte & PG_V) == 0) continue; if ((*pte & PG_W) == 0) panic("pmap_unwire: pte %#jx is missing PG_W", (uintmax_t)*pte); /* * PG_W must be cleared atomically. Although the pmap * lock synchronizes access to PG_W, another processor * could be setting PG_M and/or PG_A concurrently. */ atomic_clear_long(pte, PG_W); pmap->pm_stats.wired_count--; } } PMAP_UNLOCK(pmap); } /* * Copy the range specified by src_addr/len * from the source map to the range dst_addr/len * in the destination map. * * This routine is only advisory and need not do anything. */ void pmap_copy(pmap_t dst_pmap, pmap_t src_pmap, vm_offset_t dst_addr, vm_size_t len, vm_offset_t src_addr) { struct rwlock *lock; pml4_entry_t *pml4e; pdp_entry_t *pdpe; pd_entry_t *pde, srcptepaddr; pt_entry_t *dst_pte, PG_A, PG_M, PG_V, ptetemp, *src_pte; vm_offset_t addr, end_addr, va_next; vm_page_t dst_pdpg, dstmpte, srcmpte; if (dst_addr != src_addr) return; if (dst_pmap->pm_type != src_pmap->pm_type) return; /* * EPT page table entries that require emulation of A/D bits are * sensitive to clearing the PG_A bit (aka EPT_PG_READ). Although * we clear PG_M (aka EPT_PG_WRITE) concomitantly, the PG_U bit * (aka EPT_PG_EXECUTE) could still be set. Since some EPT * implementations flag an EPT misconfiguration for exec-only * mappings we skip this function entirely for emulated pmaps. */ if (pmap_emulate_ad_bits(dst_pmap)) return; end_addr = src_addr + len; lock = NULL; if (dst_pmap < src_pmap) { PMAP_LOCK(dst_pmap); PMAP_LOCK(src_pmap); } else { PMAP_LOCK(src_pmap); PMAP_LOCK(dst_pmap); } PG_A = pmap_accessed_bit(dst_pmap); PG_M = pmap_modified_bit(dst_pmap); PG_V = pmap_valid_bit(dst_pmap); for (addr = src_addr; addr < end_addr; addr = va_next) { KASSERT(addr < UPT_MIN_ADDRESS, ("pmap_copy: invalid to pmap_copy page tables")); pml4e = pmap_pml4e(src_pmap, addr); if (pml4e == NULL || (*pml4e & PG_V) == 0) { va_next = (addr + NBPML4) & ~PML4MASK; if (va_next < addr) va_next = end_addr; continue; } va_next = (addr + NBPDP) & ~PDPMASK; if (va_next < addr) va_next = end_addr; pdpe = pmap_pml4e_to_pdpe(pml4e, addr); if ((*pdpe & PG_V) == 0) continue; if ((*pdpe & PG_PS) != 0) { KASSERT(va_next <= end_addr, ("partial update of non-transparent 1G mapping " "pdpe %#lx sva %#lx eva %#lx va_next %#lx", *pdpe, addr, end_addr, va_next)); MPASS((addr & PDPMASK) == 0); MPASS((*pdpe & PG_MANAGED) == 0); srcptepaddr = *pdpe; pdpe = pmap_pdpe(dst_pmap, addr); if (pdpe == NULL) { if (pmap_allocpte_alloc(dst_pmap, pmap_pml4e_pindex(addr), NULL, addr) == NULL) break; pdpe = pmap_pdpe(dst_pmap, addr); } else { pml4e = pmap_pml4e(dst_pmap, addr); dst_pdpg = PHYS_TO_VM_PAGE(*pml4e & PG_FRAME); dst_pdpg->ref_count++; } KASSERT(*pdpe == 0, ("1G mapping present in dst pmap " "pdpe %#lx sva %#lx eva %#lx va_next %#lx", *pdpe, addr, end_addr, va_next)); *pdpe = srcptepaddr & ~PG_W; pmap_resident_count_adj(dst_pmap, NBPDP / PAGE_SIZE); continue; } va_next = (addr + NBPDR) & ~PDRMASK; if (va_next < addr) va_next = end_addr; pde = pmap_pdpe_to_pde(pdpe, addr); srcptepaddr = *pde; if (srcptepaddr == 0) continue; if (srcptepaddr & PG_PS) { /* * We can only virtual copy whole superpages. */ if ((addr & PDRMASK) != 0 || addr + NBPDR > end_addr) continue; pde = pmap_alloc_pde(dst_pmap, addr, &dst_pdpg, NULL); if (pde == NULL) break; if (*pde == 0 && ((srcptepaddr & PG_MANAGED) == 0 || pmap_pv_insert_pde(dst_pmap, addr, srcptepaddr, PMAP_ENTER_NORECLAIM, &lock))) { /* * We leave the dirty bit unchanged because * managed read/write superpage mappings are * required to be dirty. However, managed * superpage mappings are not required to * have their accessed bit set, so we clear * it because we don't know if this mapping * will be used. */ srcptepaddr &= ~PG_W; if ((srcptepaddr & PG_MANAGED) != 0) srcptepaddr &= ~PG_A; *pde = srcptepaddr; pmap_resident_count_adj(dst_pmap, NBPDR / PAGE_SIZE); counter_u64_add(pmap_pde_mappings, 1); } else pmap_abort_ptp(dst_pmap, addr, dst_pdpg); continue; } srcptepaddr &= PG_FRAME; srcmpte = PHYS_TO_VM_PAGE(srcptepaddr); KASSERT(srcmpte->ref_count > 0, ("pmap_copy: source page table page is unused")); if (va_next > end_addr) va_next = end_addr; src_pte = (pt_entry_t *)PHYS_TO_DMAP(srcptepaddr); src_pte = &src_pte[pmap_pte_index(addr)]; dstmpte = NULL; for (; addr < va_next; addr += PAGE_SIZE, src_pte++) { ptetemp = *src_pte; /* * We only virtual copy managed pages. */ if ((ptetemp & PG_MANAGED) == 0) continue; if (dstmpte != NULL) { KASSERT(dstmpte->pindex == pmap_pde_pindex(addr), ("dstmpte pindex/addr mismatch")); dstmpte->ref_count++; } else if ((dstmpte = pmap_allocpte(dst_pmap, addr, NULL)) == NULL) goto out; dst_pte = (pt_entry_t *) PHYS_TO_DMAP(VM_PAGE_TO_PHYS(dstmpte)); dst_pte = &dst_pte[pmap_pte_index(addr)]; if (*dst_pte == 0 && pmap_try_insert_pv_entry(dst_pmap, addr, PHYS_TO_VM_PAGE(ptetemp & PG_FRAME), &lock)) { /* * Clear the wired, modified, and accessed * (referenced) bits during the copy. */ *dst_pte = ptetemp & ~(PG_W | PG_M | PG_A); pmap_resident_count_adj(dst_pmap, 1); } else { pmap_abort_ptp(dst_pmap, addr, dstmpte); goto out; } /* Have we copied all of the valid mappings? */ if (dstmpte->ref_count >= srcmpte->ref_count) break; } } out: if (lock != NULL) rw_wunlock(lock); PMAP_UNLOCK(src_pmap); PMAP_UNLOCK(dst_pmap); } int pmap_vmspace_copy(pmap_t dst_pmap, pmap_t src_pmap) { int error; if (dst_pmap->pm_type != src_pmap->pm_type || dst_pmap->pm_type != PT_X86 || (cpu_stdext_feature2 & CPUID_STDEXT2_PKU) == 0) return (0); for (;;) { if (dst_pmap < src_pmap) { PMAP_LOCK(dst_pmap); PMAP_LOCK(src_pmap); } else { PMAP_LOCK(src_pmap); PMAP_LOCK(dst_pmap); } error = pmap_pkru_copy(dst_pmap, src_pmap); /* Clean up partial copy on failure due to no memory. */ if (error == ENOMEM) pmap_pkru_deassign_all(dst_pmap); PMAP_UNLOCK(src_pmap); PMAP_UNLOCK(dst_pmap); if (error != ENOMEM) break; vm_wait(NULL); } return (error); } /* * Zero the specified hardware page. */ void pmap_zero_page(vm_page_t m) { vm_offset_t va; #ifdef TSLOG_PAGEZERO TSENTER(); #endif va = PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m)); pagezero((void *)va); #ifdef TSLOG_PAGEZERO TSEXIT(); #endif } /* * Zero an area within a single hardware page. off and size must not * cover an area beyond a single hardware page. */ void pmap_zero_page_area(vm_page_t m, int off, int size) { vm_offset_t va = PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m)); if (off == 0 && size == PAGE_SIZE) pagezero((void *)va); else bzero((char *)va + off, size); } /* * Copy 1 specified hardware page to another. */ void pmap_copy_page(vm_page_t msrc, vm_page_t mdst) { vm_offset_t src = PHYS_TO_DMAP(VM_PAGE_TO_PHYS(msrc)); vm_offset_t dst = PHYS_TO_DMAP(VM_PAGE_TO_PHYS(mdst)); pagecopy((void *)src, (void *)dst); } int unmapped_buf_allowed = 1; void pmap_copy_pages(vm_page_t ma[], vm_offset_t a_offset, vm_page_t mb[], vm_offset_t b_offset, int xfersize) { void *a_cp, *b_cp; vm_page_t pages[2]; vm_offset_t vaddr[2], a_pg_offset, b_pg_offset; int cnt; boolean_t mapped; while (xfersize > 0) { a_pg_offset = a_offset & PAGE_MASK; pages[0] = ma[a_offset >> PAGE_SHIFT]; b_pg_offset = b_offset & PAGE_MASK; pages[1] = mb[b_offset >> PAGE_SHIFT]; cnt = min(xfersize, PAGE_SIZE - a_pg_offset); cnt = min(cnt, PAGE_SIZE - b_pg_offset); mapped = pmap_map_io_transient(pages, vaddr, 2, FALSE); a_cp = (char *)vaddr[0] + a_pg_offset; b_cp = (char *)vaddr[1] + b_pg_offset; bcopy(a_cp, b_cp, cnt); if (__predict_false(mapped)) pmap_unmap_io_transient(pages, vaddr, 2, FALSE); a_offset += cnt; b_offset += cnt; xfersize -= cnt; } } /* * Returns true if the pmap's pv is one of the first * 16 pvs linked to from this page. This count may * be changed upwards or downwards in the future; it * is only necessary that true be returned for a small * subset of pmaps for proper page aging. */ boolean_t pmap_page_exists_quick(pmap_t pmap, vm_page_t m) { struct md_page *pvh; struct rwlock *lock; pv_entry_t pv; int loops = 0; boolean_t rv; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_page_exists_quick: page %p is not managed", m)); rv = FALSE; lock = VM_PAGE_TO_PV_LIST_LOCK(m); rw_rlock(lock); TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { if (PV_PMAP(pv) == pmap) { rv = TRUE; break; } loops++; if (loops >= 16) break; } if (!rv && loops < 16 && (m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { if (PV_PMAP(pv) == pmap) { rv = TRUE; break; } loops++; if (loops >= 16) break; } } rw_runlock(lock); return (rv); } /* * pmap_page_wired_mappings: * * Return the number of managed mappings to the given physical page * that are wired. */ int pmap_page_wired_mappings(vm_page_t m) { struct rwlock *lock; struct md_page *pvh; pmap_t pmap; pt_entry_t *pte; pv_entry_t pv; int count, md_gen, pvh_gen; if ((m->oflags & VPO_UNMANAGED) != 0) return (0); lock = VM_PAGE_TO_PV_LIST_LOCK(m); rw_rlock(lock); restart: count = 0; TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { md_gen = m->md.pv_gen; rw_runlock(lock); PMAP_LOCK(pmap); rw_rlock(lock); if (md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } pte = pmap_pte(pmap, pv->pv_va); if ((*pte & PG_W) != 0) count++; PMAP_UNLOCK(pmap); } if ((m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { md_gen = m->md.pv_gen; pvh_gen = pvh->pv_gen; rw_runlock(lock); PMAP_LOCK(pmap); rw_rlock(lock); if (md_gen != m->md.pv_gen || pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } pte = pmap_pde(pmap, pv->pv_va); if ((*pte & PG_W) != 0) count++; PMAP_UNLOCK(pmap); } } rw_runlock(lock); return (count); } /* * Returns TRUE if the given page is mapped individually or as part of * a 2mpage. Otherwise, returns FALSE. */ boolean_t pmap_page_is_mapped(vm_page_t m) { struct rwlock *lock; boolean_t rv; if ((m->oflags & VPO_UNMANAGED) != 0) return (FALSE); lock = VM_PAGE_TO_PV_LIST_LOCK(m); rw_rlock(lock); rv = !TAILQ_EMPTY(&m->md.pv_list) || ((m->flags & PG_FICTITIOUS) == 0 && !TAILQ_EMPTY(&pa_to_pvh(VM_PAGE_TO_PHYS(m))->pv_list)); rw_runlock(lock); return (rv); } /* * Destroy all managed, non-wired mappings in the given user-space * pmap. This pmap cannot be active on any processor besides the * caller. * * This function cannot be applied to the kernel pmap. Moreover, it * is not intended for general use. It is only to be used during * process termination. Consequently, it can be implemented in ways * that make it faster than pmap_remove(). First, it can more quickly * destroy mappings by iterating over the pmap's collection of PV * entries, rather than searching the page table. Second, it doesn't * have to test and clear the page table entries atomically, because * no processor is currently accessing the user address space. In * particular, a page table entry's dirty bit won't change state once * this function starts. * * Although this function destroys all of the pmap's managed, * non-wired mappings, it can delay and batch the invalidation of TLB * entries without calling pmap_delayed_invl_start() and * pmap_delayed_invl_finish(). Because the pmap is not active on * any other processor, none of these TLB entries will ever be used * before their eventual invalidation. Consequently, there is no need * for either pmap_remove_all() or pmap_remove_write() to wait for * that eventual TLB invalidation. */ void pmap_remove_pages(pmap_t pmap) { pd_entry_t ptepde; pt_entry_t *pte, tpte; pt_entry_t PG_M, PG_RW, PG_V; struct spglist free; struct pv_chunklist free_chunks[PMAP_MEMDOM]; vm_page_t m, mpte, mt; pv_entry_t pv; struct md_page *pvh; struct pv_chunk *pc, *npc; struct rwlock *lock; int64_t bit; uint64_t inuse, bitmask; int allfree, field, i, idx; #ifdef PV_STATS int freed; #endif boolean_t superpage; vm_paddr_t pa; /* * Assert that the given pmap is only active on the current * CPU. Unfortunately, we cannot block another CPU from * activating the pmap while this function is executing. */ KASSERT(pmap == PCPU_GET(curpmap), ("non-current pmap %p", pmap)); #ifdef INVARIANTS { cpuset_t other_cpus; other_cpus = all_cpus; critical_enter(); CPU_CLR(PCPU_GET(cpuid), &other_cpus); CPU_AND(&other_cpus, &other_cpus, &pmap->pm_active); critical_exit(); KASSERT(CPU_EMPTY(&other_cpus), ("pmap active %p", pmap)); } #endif lock = NULL; PG_M = pmap_modified_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_RW = pmap_rw_bit(pmap); for (i = 0; i < PMAP_MEMDOM; i++) TAILQ_INIT(&free_chunks[i]); SLIST_INIT(&free); PMAP_LOCK(pmap); TAILQ_FOREACH_SAFE(pc, &pmap->pm_pvchunk, pc_list, npc) { allfree = 1; #ifdef PV_STATS freed = 0; #endif for (field = 0; field < _NPCM; field++) { inuse = ~pc->pc_map[field] & pc_freemask[field]; while (inuse != 0) { bit = bsfq(inuse); bitmask = 1UL << bit; idx = field * 64 + bit; pv = &pc->pc_pventry[idx]; inuse &= ~bitmask; pte = pmap_pdpe(pmap, pv->pv_va); ptepde = *pte; pte = pmap_pdpe_to_pde(pte, pv->pv_va); tpte = *pte; if ((tpte & (PG_PS | PG_V)) == PG_V) { superpage = FALSE; ptepde = tpte; pte = (pt_entry_t *)PHYS_TO_DMAP(tpte & PG_FRAME); pte = &pte[pmap_pte_index(pv->pv_va)]; tpte = *pte; } else { /* * Keep track whether 'tpte' is a * superpage explicitly instead of * relying on PG_PS being set. * * This is because PG_PS is numerically * identical to PG_PTE_PAT and thus a * regular page could be mistaken for * a superpage. */ superpage = TRUE; } if ((tpte & PG_V) == 0) { panic("bad pte va %lx pte %lx", pv->pv_va, tpte); } /* * We cannot remove wired pages from a process' mapping at this time */ if (tpte & PG_W) { allfree = 0; continue; } /* Mark free */ pc->pc_map[field] |= bitmask; /* * Because this pmap is not active on other * processors, the dirty bit cannot have * changed state since we last loaded pte. */ pte_clear(pte); if (superpage) pa = tpte & PG_PS_FRAME; else pa = tpte & PG_FRAME; m = PHYS_TO_VM_PAGE(pa); KASSERT(m->phys_addr == pa, ("vm_page_t %p phys_addr mismatch %016jx %016jx", m, (uintmax_t)m->phys_addr, (uintmax_t)tpte)); KASSERT((m->flags & PG_FICTITIOUS) != 0 || m < &vm_page_array[vm_page_array_size], ("pmap_remove_pages: bad tpte %#jx", (uintmax_t)tpte)); /* * Update the vm_page_t clean/reference bits. */ if ((tpte & (PG_M | PG_RW)) == (PG_M | PG_RW)) { if (superpage) { for (mt = m; mt < &m[NBPDR / PAGE_SIZE]; mt++) vm_page_dirty(mt); } else vm_page_dirty(m); } CHANGE_PV_LIST_LOCK_TO_VM_PAGE(&lock, m); if (superpage) { pmap_resident_count_adj(pmap, -NBPDR / PAGE_SIZE); pvh = pa_to_pvh(tpte & PG_PS_FRAME); TAILQ_REMOVE(&pvh->pv_list, pv, pv_next); pvh->pv_gen++; if (TAILQ_EMPTY(&pvh->pv_list)) { for (mt = m; mt < &m[NBPDR / PAGE_SIZE]; mt++) if ((mt->a.flags & PGA_WRITEABLE) != 0 && TAILQ_EMPTY(&mt->md.pv_list)) vm_page_aflag_clear(mt, PGA_WRITEABLE); } mpte = pmap_remove_pt_page(pmap, pv->pv_va); if (mpte != NULL) { KASSERT(vm_page_any_valid(mpte), ("pmap_remove_pages: pte page not promoted")); pmap_pt_page_count_adj(pmap, -1); KASSERT(mpte->ref_count == NPTEPG, ("pmap_remove_pages: pte page reference count error")); mpte->ref_count = 0; pmap_add_delayed_free_list(mpte, &free, FALSE); } } else { pmap_resident_count_adj(pmap, -1); TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; if ((m->a.flags & PGA_WRITEABLE) != 0 && TAILQ_EMPTY(&m->md.pv_list) && (m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); if (TAILQ_EMPTY(&pvh->pv_list)) vm_page_aflag_clear(m, PGA_WRITEABLE); } } pmap_unuse_pt(pmap, pv->pv_va, ptepde, &free); #ifdef PV_STATS freed++; #endif } } PV_STAT(counter_u64_add(pv_entry_frees, freed)); PV_STAT(counter_u64_add(pv_entry_spare, freed)); PV_STAT(counter_u64_add(pv_entry_count, -freed)); if (allfree) { TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&free_chunks[pc_to_domain(pc)], pc, pc_list); } } if (lock != NULL) rw_wunlock(lock); pmap_invalidate_all(pmap); pmap_pkru_deassign_all(pmap); free_pv_chunk_batch((struct pv_chunklist *)&free_chunks); PMAP_UNLOCK(pmap); vm_page_free_pages_toq(&free, true); } static boolean_t pmap_page_test_mappings(vm_page_t m, boolean_t accessed, boolean_t modified) { struct rwlock *lock; pv_entry_t pv; struct md_page *pvh; pt_entry_t *pte, mask; pt_entry_t PG_A, PG_M, PG_RW, PG_V; pmap_t pmap; int md_gen, pvh_gen; boolean_t rv; rv = FALSE; lock = VM_PAGE_TO_PV_LIST_LOCK(m); rw_rlock(lock); restart: TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { md_gen = m->md.pv_gen; rw_runlock(lock); PMAP_LOCK(pmap); rw_rlock(lock); if (md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } pte = pmap_pte(pmap, pv->pv_va); mask = 0; if (modified) { PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); mask |= PG_RW | PG_M; } if (accessed) { PG_A = pmap_accessed_bit(pmap); PG_V = pmap_valid_bit(pmap); mask |= PG_V | PG_A; } rv = (*pte & mask) == mask; PMAP_UNLOCK(pmap); if (rv) goto out; } if ((m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { md_gen = m->md.pv_gen; pvh_gen = pvh->pv_gen; rw_runlock(lock); PMAP_LOCK(pmap); rw_rlock(lock); if (md_gen != m->md.pv_gen || pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } pte = pmap_pde(pmap, pv->pv_va); mask = 0; if (modified) { PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); mask |= PG_RW | PG_M; } if (accessed) { PG_A = pmap_accessed_bit(pmap); PG_V = pmap_valid_bit(pmap); mask |= PG_V | PG_A; } rv = (*pte & mask) == mask; PMAP_UNLOCK(pmap); if (rv) goto out; } } out: rw_runlock(lock); return (rv); } /* * pmap_is_modified: * * Return whether or not the specified physical page was modified * in any physical maps. */ boolean_t pmap_is_modified(vm_page_t m) { KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_is_modified: page %p is not managed", m)); /* * If the page is not busied then this check is racy. */ if (!pmap_page_is_write_mapped(m)) return (FALSE); return (pmap_page_test_mappings(m, FALSE, TRUE)); } /* * pmap_is_prefaultable: * * Return whether or not the specified virtual address is eligible * for prefault. */ boolean_t pmap_is_prefaultable(pmap_t pmap, vm_offset_t addr) { pd_entry_t *pde; pt_entry_t *pte, PG_V; boolean_t rv; PG_V = pmap_valid_bit(pmap); /* * Return TRUE if and only if the PTE for the specified virtual * address is allocated but invalid. */ rv = FALSE; PMAP_LOCK(pmap); pde = pmap_pde(pmap, addr); if (pde != NULL && (*pde & (PG_PS | PG_V)) == PG_V) { pte = pmap_pde_to_pte(pde, addr); rv = (*pte & PG_V) == 0; } PMAP_UNLOCK(pmap); return (rv); } /* * pmap_is_referenced: * * Return whether or not the specified physical page was referenced * in any physical maps. */ boolean_t pmap_is_referenced(vm_page_t m) { KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_is_referenced: page %p is not managed", m)); return (pmap_page_test_mappings(m, TRUE, FALSE)); } /* * Clear the write and modified bits in each of the given page's mappings. */ void pmap_remove_write(vm_page_t m) { struct md_page *pvh; pmap_t pmap; struct rwlock *lock; pv_entry_t next_pv, pv; pd_entry_t *pde; pt_entry_t oldpte, *pte, PG_M, PG_RW; vm_offset_t va; int pvh_gen, md_gen; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_remove_write: page %p is not managed", m)); vm_page_assert_busied(m); if (!pmap_page_is_write_mapped(m)) return; lock = VM_PAGE_TO_PV_LIST_LOCK(m); pvh = (m->flags & PG_FICTITIOUS) != 0 ? &pv_dummy : pa_to_pvh(VM_PAGE_TO_PHYS(m)); rw_wlock(lock); retry: TAILQ_FOREACH_SAFE(pv, &pvh->pv_list, pv_next, next_pv) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); goto retry; } } PG_RW = pmap_rw_bit(pmap); va = pv->pv_va; pde = pmap_pde(pmap, va); if ((*pde & PG_RW) != 0) (void)pmap_demote_pde_locked(pmap, pde, va, &lock); KASSERT(lock == VM_PAGE_TO_PV_LIST_LOCK(m), ("inconsistent pv lock %p %p for page %p", lock, VM_PAGE_TO_PV_LIST_LOCK(m), m)); PMAP_UNLOCK(pmap); } TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; md_gen = m->md.pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen || md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); goto retry; } } PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); pde = pmap_pde(pmap, pv->pv_va); KASSERT((*pde & PG_PS) == 0, ("pmap_remove_write: found a 2mpage in page %p's pv list", m)); pte = pmap_pde_to_pte(pde, pv->pv_va); oldpte = *pte; if (oldpte & PG_RW) { while (!atomic_fcmpset_long(pte, &oldpte, oldpte & ~(PG_RW | PG_M))) cpu_spinwait(); if ((oldpte & PG_M) != 0) vm_page_dirty(m); pmap_invalidate_page(pmap, pv->pv_va); } PMAP_UNLOCK(pmap); } rw_wunlock(lock); vm_page_aflag_clear(m, PGA_WRITEABLE); pmap_delayed_invl_wait(m); } /* * pmap_ts_referenced: * * Return a count of reference bits for a page, clearing those bits. * It is not necessary for every reference bit to be cleared, but it * is necessary that 0 only be returned when there are truly no * reference bits set. * * As an optimization, update the page's dirty field if a modified bit is * found while counting reference bits. This opportunistic update can be * performed at low cost and can eliminate the need for some future calls * to pmap_is_modified(). However, since this function stops after * finding PMAP_TS_REFERENCED_MAX reference bits, it may not detect some * dirty pages. Those dirty pages will only be detected by a future call * to pmap_is_modified(). * * A DI block is not needed within this function, because * invalidations are performed before the PV list lock is * released. */ int pmap_ts_referenced(vm_page_t m) { struct md_page *pvh; pv_entry_t pv, pvf; pmap_t pmap; struct rwlock *lock; pd_entry_t oldpde, *pde; pt_entry_t *pte, PG_A, PG_M, PG_RW; vm_offset_t va; vm_paddr_t pa; int cleared, md_gen, not_cleared, pvh_gen; struct spglist free; boolean_t demoted; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_ts_referenced: page %p is not managed", m)); SLIST_INIT(&free); cleared = 0; pa = VM_PAGE_TO_PHYS(m); lock = PHYS_TO_PV_LIST_LOCK(pa); pvh = (m->flags & PG_FICTITIOUS) != 0 ? &pv_dummy : pa_to_pvh(pa); rw_wlock(lock); retry: not_cleared = 0; if ((pvf = TAILQ_FIRST(&pvh->pv_list)) == NULL) goto small_mappings; pv = pvf; do { if (pvf == NULL) pvf = pv; pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); goto retry; } } PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); va = pv->pv_va; pde = pmap_pde(pmap, pv->pv_va); oldpde = *pde; if ((oldpde & (PG_M | PG_RW)) == (PG_M | PG_RW)) { /* * Although "oldpde" is mapping a 2MB page, because * this function is called at a 4KB page granularity, * we only update the 4KB page under test. */ vm_page_dirty(m); } if ((oldpde & PG_A) != 0) { /* * Since this reference bit is shared by 512 4KB * pages, it should not be cleared every time it is * tested. Apply a simple "hash" function on the * physical page number, the virtual superpage number, * and the pmap address to select one 4KB page out of * the 512 on which testing the reference bit will * result in clearing that reference bit. This * function is designed to avoid the selection of the * same 4KB page for every 2MB page mapping. * * On demotion, a mapping that hasn't been referenced * is simply destroyed. To avoid the possibility of a * subsequent page fault on a demoted wired mapping, * always leave its reference bit set. Moreover, * since the superpage is wired, the current state of * its reference bit won't affect page replacement. */ if ((((pa >> PAGE_SHIFT) ^ (pv->pv_va >> PDRSHIFT) ^ (uintptr_t)pmap) & (NPTEPG - 1)) == 0 && (oldpde & PG_W) == 0) { if (safe_to_clear_referenced(pmap, oldpde)) { atomic_clear_long(pde, PG_A); pmap_invalidate_page(pmap, pv->pv_va); demoted = FALSE; } else if (pmap_demote_pde_locked(pmap, pde, pv->pv_va, &lock)) { /* * Remove the mapping to a single page * so that a subsequent access may * repromote. Since the underlying * page table page is fully populated, * this removal never frees a page * table page. */ demoted = TRUE; va += VM_PAGE_TO_PHYS(m) - (oldpde & PG_PS_FRAME); pte = pmap_pde_to_pte(pde, va); pmap_remove_pte(pmap, pte, va, *pde, NULL, &lock); pmap_invalidate_page(pmap, va); } else demoted = TRUE; if (demoted) { /* * The superpage mapping was removed * entirely and therefore 'pv' is no * longer valid. */ if (pvf == pv) pvf = NULL; pv = NULL; } cleared++; KASSERT(lock == VM_PAGE_TO_PV_LIST_LOCK(m), ("inconsistent pv lock %p %p for page %p", lock, VM_PAGE_TO_PV_LIST_LOCK(m), m)); } else not_cleared++; } PMAP_UNLOCK(pmap); /* Rotate the PV list if it has more than one entry. */ if (pv != NULL && TAILQ_NEXT(pv, pv_next) != NULL) { TAILQ_REMOVE(&pvh->pv_list, pv, pv_next); TAILQ_INSERT_TAIL(&pvh->pv_list, pv, pv_next); pvh->pv_gen++; } if (cleared + not_cleared >= PMAP_TS_REFERENCED_MAX) goto out; } while ((pv = TAILQ_FIRST(&pvh->pv_list)) != pvf); small_mappings: if ((pvf = TAILQ_FIRST(&m->md.pv_list)) == NULL) goto out; pv = pvf; do { if (pvf == NULL) pvf = pv; pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; md_gen = m->md.pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen || md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); goto retry; } } PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); pde = pmap_pde(pmap, pv->pv_va); KASSERT((*pde & PG_PS) == 0, ("pmap_ts_referenced: found a 2mpage in page %p's pv list", m)); pte = pmap_pde_to_pte(pde, pv->pv_va); if ((*pte & (PG_M | PG_RW)) == (PG_M | PG_RW)) vm_page_dirty(m); if ((*pte & PG_A) != 0) { if (safe_to_clear_referenced(pmap, *pte)) { atomic_clear_long(pte, PG_A); pmap_invalidate_page(pmap, pv->pv_va); cleared++; } else if ((*pte & PG_W) == 0) { /* * Wired pages cannot be paged out so * doing accessed bit emulation for * them is wasted effort. We do the * hard work for unwired pages only. */ pmap_remove_pte(pmap, pte, pv->pv_va, *pde, &free, &lock); pmap_invalidate_page(pmap, pv->pv_va); cleared++; if (pvf == pv) pvf = NULL; pv = NULL; KASSERT(lock == VM_PAGE_TO_PV_LIST_LOCK(m), ("inconsistent pv lock %p %p for page %p", lock, VM_PAGE_TO_PV_LIST_LOCK(m), m)); } else not_cleared++; } PMAP_UNLOCK(pmap); /* Rotate the PV list if it has more than one entry. */ if (pv != NULL && TAILQ_NEXT(pv, pv_next) != NULL) { TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; } } while ((pv = TAILQ_FIRST(&m->md.pv_list)) != pvf && cleared + not_cleared < PMAP_TS_REFERENCED_MAX); out: rw_wunlock(lock); vm_page_free_pages_toq(&free, true); return (cleared + not_cleared); } /* * Apply the given advice to the specified range of addresses within the * given pmap. Depending on the advice, clear the referenced and/or * modified flags in each mapping and set the mapped page's dirty field. */ void pmap_advise(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, int advice) { struct rwlock *lock; pml4_entry_t *pml4e; pdp_entry_t *pdpe; pd_entry_t oldpde, *pde; pt_entry_t *pte, PG_A, PG_G, PG_M, PG_RW, PG_V; vm_offset_t va, va_next; vm_page_t m; bool anychanged; if (advice != MADV_DONTNEED && advice != MADV_FREE) return; /* * A/D bit emulation requires an alternate code path when clearing * the modified and accessed bits below. Since this function is * advisory in nature we skip it entirely for pmaps that require * A/D bit emulation. */ if (pmap_emulate_ad_bits(pmap)) return; PG_A = pmap_accessed_bit(pmap); PG_G = pmap_global_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_RW = pmap_rw_bit(pmap); anychanged = false; pmap_delayed_invl_start(); PMAP_LOCK(pmap); for (; sva < eva; sva = va_next) { pml4e = pmap_pml4e(pmap, sva); if (pml4e == NULL || (*pml4e & PG_V) == 0) { va_next = (sva + NBPML4) & ~PML4MASK; if (va_next < sva) va_next = eva; continue; } va_next = (sva + NBPDP) & ~PDPMASK; if (va_next < sva) va_next = eva; pdpe = pmap_pml4e_to_pdpe(pml4e, sva); if ((*pdpe & PG_V) == 0) continue; if ((*pdpe & PG_PS) != 0) continue; va_next = (sva + NBPDR) & ~PDRMASK; if (va_next < sva) va_next = eva; pde = pmap_pdpe_to_pde(pdpe, sva); oldpde = *pde; if ((oldpde & PG_V) == 0) continue; else if ((oldpde & PG_PS) != 0) { if ((oldpde & PG_MANAGED) == 0) continue; lock = NULL; if (!pmap_demote_pde_locked(pmap, pde, sva, &lock)) { if (lock != NULL) rw_wunlock(lock); /* * The large page mapping was destroyed. */ continue; } /* * Unless the page mappings are wired, remove the * mapping to a single page so that a subsequent * access may repromote. Choosing the last page * within the address range [sva, min(va_next, eva)) * generally results in more repromotions. Since the * underlying page table page is fully populated, this * removal never frees a page table page. */ if ((oldpde & PG_W) == 0) { va = eva; if (va > va_next) va = va_next; va -= PAGE_SIZE; KASSERT(va >= sva, ("pmap_advise: no address gap")); pte = pmap_pde_to_pte(pde, va); KASSERT((*pte & PG_V) != 0, ("pmap_advise: invalid PTE")); pmap_remove_pte(pmap, pte, va, *pde, NULL, &lock); anychanged = true; } if (lock != NULL) rw_wunlock(lock); } if (va_next > eva) va_next = eva; va = va_next; for (pte = pmap_pde_to_pte(pde, sva); sva != va_next; pte++, sva += PAGE_SIZE) { if ((*pte & (PG_MANAGED | PG_V)) != (PG_MANAGED | PG_V)) goto maybe_invlrng; else if ((*pte & (PG_M | PG_RW)) == (PG_M | PG_RW)) { if (advice == MADV_DONTNEED) { /* * Future calls to pmap_is_modified() * can be avoided by making the page * dirty now. */ m = PHYS_TO_VM_PAGE(*pte & PG_FRAME); vm_page_dirty(m); } atomic_clear_long(pte, PG_M | PG_A); } else if ((*pte & PG_A) != 0) atomic_clear_long(pte, PG_A); else goto maybe_invlrng; if ((*pte & PG_G) != 0) { if (va == va_next) va = sva; } else anychanged = true; continue; maybe_invlrng: if (va != va_next) { pmap_invalidate_range(pmap, va, sva); va = va_next; } } if (va != va_next) pmap_invalidate_range(pmap, va, sva); } if (anychanged) pmap_invalidate_all(pmap); PMAP_UNLOCK(pmap); pmap_delayed_invl_finish(); } /* * Clear the modify bits on the specified physical page. */ void pmap_clear_modify(vm_page_t m) { struct md_page *pvh; pmap_t pmap; pv_entry_t next_pv, pv; pd_entry_t oldpde, *pde; pt_entry_t *pte, PG_M, PG_RW; struct rwlock *lock; vm_offset_t va; int md_gen, pvh_gen; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_clear_modify: page %p is not managed", m)); vm_page_assert_busied(m); if (!pmap_page_is_write_mapped(m)) return; pvh = (m->flags & PG_FICTITIOUS) != 0 ? &pv_dummy : pa_to_pvh(VM_PAGE_TO_PHYS(m)); lock = VM_PAGE_TO_PV_LIST_LOCK(m); rw_wlock(lock); restart: TAILQ_FOREACH_SAFE(pv, &pvh->pv_list, pv_next, next_pv) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); va = pv->pv_va; pde = pmap_pde(pmap, va); oldpde = *pde; /* If oldpde has PG_RW set, then it also has PG_M set. */ if ((oldpde & PG_RW) != 0 && pmap_demote_pde_locked(pmap, pde, va, &lock) && (oldpde & PG_W) == 0) { /* * Write protect the mapping to a single page so that * a subsequent write access may repromote. */ va += VM_PAGE_TO_PHYS(m) - (oldpde & PG_PS_FRAME); pte = pmap_pde_to_pte(pde, va); atomic_clear_long(pte, PG_M | PG_RW); vm_page_dirty(m); pmap_invalidate_page(pmap, va); } PMAP_UNLOCK(pmap); } TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { md_gen = m->md.pv_gen; pvh_gen = pvh->pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen || md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } PG_M = pmap_modified_bit(pmap); PG_RW = pmap_rw_bit(pmap); pde = pmap_pde(pmap, pv->pv_va); KASSERT((*pde & PG_PS) == 0, ("pmap_clear_modify: found" " a 2mpage in page %p's pv list", m)); pte = pmap_pde_to_pte(pde, pv->pv_va); if ((*pte & (PG_M | PG_RW)) == (PG_M | PG_RW)) { atomic_clear_long(pte, PG_M); pmap_invalidate_page(pmap, pv->pv_va); } PMAP_UNLOCK(pmap); } rw_wunlock(lock); } /* * Miscellaneous support routines follow */ /* Adjust the properties for a leaf page table entry. */ static __inline void pmap_pte_props(pt_entry_t *pte, u_long bits, u_long mask) { u_long opte, npte; opte = *(u_long *)pte; do { npte = opte & ~mask; npte |= bits; } while (npte != opte && !atomic_fcmpset_long((u_long *)pte, &opte, npte)); } /* * Map a set of physical memory pages into the kernel virtual * address space. Return a pointer to where it is mapped. This * routine is intended to be used for mapping device memory, * NOT real memory. */ static void * pmap_mapdev_internal(vm_paddr_t pa, vm_size_t size, int mode, int flags) { struct pmap_preinit_mapping *ppim; vm_offset_t va, offset; vm_size_t tmpsize; int i; offset = pa & PAGE_MASK; size = round_page(offset + size); pa = trunc_page(pa); if (!pmap_initialized) { va = 0; for (i = 0; i < PMAP_PREINIT_MAPPING_COUNT; i++) { ppim = pmap_preinit_mapping + i; if (ppim->va == 0) { ppim->pa = pa; ppim->sz = size; ppim->mode = mode; ppim->va = virtual_avail; virtual_avail += size; va = ppim->va; break; } } if (va == 0) panic("%s: too many preinit mappings", __func__); } else { /* * If we have a preinit mapping, re-use it. */ for (i = 0; i < PMAP_PREINIT_MAPPING_COUNT; i++) { ppim = pmap_preinit_mapping + i; if (ppim->pa == pa && ppim->sz == size && (ppim->mode == mode || (flags & MAPDEV_SETATTR) == 0)) return ((void *)(ppim->va + offset)); } /* * If the specified range of physical addresses fits within * the direct map window, use the direct map. */ if (pa < dmaplimit && pa + size <= dmaplimit) { va = PHYS_TO_DMAP(pa); if ((flags & MAPDEV_SETATTR) != 0) { PMAP_LOCK(kernel_pmap); i = pmap_change_props_locked(va, size, PROT_NONE, mode, flags); PMAP_UNLOCK(kernel_pmap); } else i = 0; if (!i) return ((void *)(va + offset)); } va = kva_alloc(size); if (va == 0) panic("%s: Couldn't allocate KVA", __func__); } for (tmpsize = 0; tmpsize < size; tmpsize += PAGE_SIZE) pmap_kenter_attr(va + tmpsize, pa + tmpsize, mode); pmap_invalidate_range(kernel_pmap, va, va + tmpsize); if ((flags & MAPDEV_FLUSHCACHE) != 0) pmap_invalidate_cache_range(va, va + tmpsize); return ((void *)(va + offset)); } void * pmap_mapdev_attr(vm_paddr_t pa, vm_size_t size, int mode) { return (pmap_mapdev_internal(pa, size, mode, MAPDEV_FLUSHCACHE | MAPDEV_SETATTR)); } void * pmap_mapdev(vm_paddr_t pa, vm_size_t size) { return (pmap_mapdev_attr(pa, size, PAT_UNCACHEABLE)); } void * pmap_mapdev_pciecfg(vm_paddr_t pa, vm_size_t size) { return (pmap_mapdev_internal(pa, size, PAT_UNCACHEABLE, MAPDEV_SETATTR)); } void * pmap_mapbios(vm_paddr_t pa, vm_size_t size) { return (pmap_mapdev_internal(pa, size, PAT_WRITE_BACK, MAPDEV_FLUSHCACHE)); } void pmap_unmapdev(void *p, vm_size_t size) { struct pmap_preinit_mapping *ppim; vm_offset_t offset, va; int i; va = (vm_offset_t)p; /* If we gave a direct map region in pmap_mapdev, do nothing */ if (va >= DMAP_MIN_ADDRESS && va < DMAP_MAX_ADDRESS) return; offset = va & PAGE_MASK; size = round_page(offset + size); va = trunc_page(va); for (i = 0; i < PMAP_PREINIT_MAPPING_COUNT; i++) { ppim = pmap_preinit_mapping + i; if (ppim->va == va && ppim->sz == size) { if (pmap_initialized) return; ppim->pa = 0; ppim->va = 0; ppim->sz = 0; ppim->mode = 0; if (va + size == virtual_avail) virtual_avail = va; return; } } if (pmap_initialized) { pmap_qremove(va, atop(size)); kva_free(va, size); } } /* * Tries to demote a 1GB page mapping. */ static boolean_t pmap_demote_pdpe(pmap_t pmap, pdp_entry_t *pdpe, vm_offset_t va) { pdp_entry_t newpdpe, oldpdpe; pd_entry_t *firstpde, newpde, *pde; pt_entry_t PG_A, PG_M, PG_RW, PG_V; vm_paddr_t pdpgpa; vm_page_t pdpg; PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_RW = pmap_rw_bit(pmap); PMAP_LOCK_ASSERT(pmap, MA_OWNED); oldpdpe = *pdpe; KASSERT((oldpdpe & (PG_PS | PG_V)) == (PG_PS | PG_V), ("pmap_demote_pdpe: oldpdpe is missing PG_PS and/or PG_V")); pdpg = pmap_alloc_pt_page(pmap, va >> PDPSHIFT, VM_ALLOC_WIRED | VM_ALLOC_INTERRUPT); if (pdpg == NULL) { CTR2(KTR_PMAP, "pmap_demote_pdpe: failure for va %#lx" " in pmap %p", va, pmap); return (FALSE); } pdpgpa = VM_PAGE_TO_PHYS(pdpg); firstpde = (pd_entry_t *)PHYS_TO_DMAP(pdpgpa); newpdpe = pdpgpa | PG_M | PG_A | (oldpdpe & PG_U) | PG_RW | PG_V; KASSERT((oldpdpe & PG_A) != 0, ("pmap_demote_pdpe: oldpdpe is missing PG_A")); KASSERT((oldpdpe & (PG_M | PG_RW)) != PG_RW, ("pmap_demote_pdpe: oldpdpe is missing PG_M")); newpde = oldpdpe; /* * Initialize the page directory page. */ for (pde = firstpde; pde < firstpde + NPDEPG; pde++) { *pde = newpde; newpde += NBPDR; } /* * Demote the mapping. */ *pdpe = newpdpe; /* * Invalidate a stale recursive mapping of the page directory page. */ pmap_invalidate_page(pmap, (vm_offset_t)vtopde(va)); counter_u64_add(pmap_pdpe_demotions, 1); CTR2(KTR_PMAP, "pmap_demote_pdpe: success for va %#lx" " in pmap %p", va, pmap); return (TRUE); } /* * Sets the memory attribute for the specified page. */ void pmap_page_set_memattr(vm_page_t m, vm_memattr_t ma) { m->md.pat_mode = ma; /* * If "m" is a normal page, update its direct mapping. This update * can be relied upon to perform any cache operations that are * required for data coherence. */ if ((m->flags & PG_FICTITIOUS) == 0 && pmap_change_attr(PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m)), PAGE_SIZE, m->md.pat_mode)) panic("memory attribute change on the direct map failed"); } void pmap_page_set_memattr_noflush(vm_page_t m, vm_memattr_t ma) { int error; m->md.pat_mode = ma; if ((m->flags & PG_FICTITIOUS) != 0) return; PMAP_LOCK(kernel_pmap); error = pmap_change_props_locked(PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m)), PAGE_SIZE, PROT_NONE, m->md.pat_mode, 0); PMAP_UNLOCK(kernel_pmap); if (error != 0) panic("memory attribute change on the direct map failed"); } /* * Changes the specified virtual address range's memory type to that given by * the parameter "mode". The specified virtual address range must be * completely contained within either the direct map or the kernel map. If * the virtual address range is contained within the kernel map, then the * memory type for each of the corresponding ranges of the direct map is also * changed. (The corresponding ranges of the direct map are those ranges that * map the same physical pages as the specified virtual address range.) These * changes to the direct map are necessary because Intel describes the * behavior of their processors as "undefined" if two or more mappings to the * same physical page have different memory types. * * Returns zero if the change completed successfully, and either EINVAL or * ENOMEM if the change failed. Specifically, EINVAL is returned if some part * of the virtual address range was not mapped, and ENOMEM is returned if * there was insufficient memory available to complete the change. In the * latter case, the memory type may have been changed on some part of the * virtual address range or the direct map. */ int pmap_change_attr(vm_offset_t va, vm_size_t size, int mode) { int error; PMAP_LOCK(kernel_pmap); error = pmap_change_props_locked(va, size, PROT_NONE, mode, MAPDEV_FLUSHCACHE); PMAP_UNLOCK(kernel_pmap); return (error); } /* * Changes the specified virtual address range's protections to those * specified by "prot". Like pmap_change_attr(), protections for aliases * in the direct map are updated as well. Protections on aliasing mappings may * be a subset of the requested protections; for example, mappings in the direct * map are never executable. */ int pmap_change_prot(vm_offset_t va, vm_size_t size, vm_prot_t prot) { int error; /* Only supported within the kernel map. */ if (va < VM_MIN_KERNEL_ADDRESS) return (EINVAL); PMAP_LOCK(kernel_pmap); error = pmap_change_props_locked(va, size, prot, -1, MAPDEV_ASSERTVALID); PMAP_UNLOCK(kernel_pmap); return (error); } static int pmap_change_props_locked(vm_offset_t va, vm_size_t size, vm_prot_t prot, int mode, int flags) { vm_offset_t base, offset, tmpva; vm_paddr_t pa_start, pa_end, pa_end1; pdp_entry_t *pdpe; pd_entry_t *pde, pde_bits, pde_mask; pt_entry_t *pte, pte_bits, pte_mask; int error; bool changed; PMAP_LOCK_ASSERT(kernel_pmap, MA_OWNED); base = trunc_page(va); offset = va & PAGE_MASK; size = round_page(offset + size); /* * Only supported on kernel virtual addresses, including the direct * map but excluding the recursive map. */ if (base < DMAP_MIN_ADDRESS) return (EINVAL); /* * Construct our flag sets and masks. "bits" is the subset of * "mask" that will be set in each modified PTE. * * Mappings in the direct map are never allowed to be executable. */ pde_bits = pte_bits = 0; pde_mask = pte_mask = 0; if (mode != -1) { pde_bits |= pmap_cache_bits(kernel_pmap, mode, true); pde_mask |= X86_PG_PDE_CACHE; pte_bits |= pmap_cache_bits(kernel_pmap, mode, false); pte_mask |= X86_PG_PTE_CACHE; } if (prot != VM_PROT_NONE) { if ((prot & VM_PROT_WRITE) != 0) { pde_bits |= X86_PG_RW; pte_bits |= X86_PG_RW; } if ((prot & VM_PROT_EXECUTE) == 0 || va < VM_MIN_KERNEL_ADDRESS) { pde_bits |= pg_nx; pte_bits |= pg_nx; } pde_mask |= X86_PG_RW | pg_nx; pte_mask |= X86_PG_RW | pg_nx; } /* * Pages that aren't mapped aren't supported. Also break down 2MB pages * into 4KB pages if required. */ for (tmpva = base; tmpva < base + size; ) { pdpe = pmap_pdpe(kernel_pmap, tmpva); if (pdpe == NULL || *pdpe == 0) { KASSERT((flags & MAPDEV_ASSERTVALID) == 0, ("%s: addr %#lx is not mapped", __func__, tmpva)); return (EINVAL); } if (*pdpe & PG_PS) { /* * If the current 1GB page already has the required * properties, then we need not demote this page. Just * increment tmpva to the next 1GB page frame. */ if ((*pdpe & pde_mask) == pde_bits) { tmpva = trunc_1gpage(tmpva) + NBPDP; continue; } /* * If the current offset aligns with a 1GB page frame * and there is at least 1GB left within the range, then * we need not break down this page into 2MB pages. */ if ((tmpva & PDPMASK) == 0 && tmpva + PDPMASK < base + size) { tmpva += NBPDP; continue; } if (!pmap_demote_pdpe(kernel_pmap, pdpe, tmpva)) return (ENOMEM); } pde = pmap_pdpe_to_pde(pdpe, tmpva); if (*pde == 0) { KASSERT((flags & MAPDEV_ASSERTVALID) == 0, ("%s: addr %#lx is not mapped", __func__, tmpva)); return (EINVAL); } if (*pde & PG_PS) { /* * If the current 2MB page already has the required * properties, then we need not demote this page. Just * increment tmpva to the next 2MB page frame. */ if ((*pde & pde_mask) == pde_bits) { tmpva = trunc_2mpage(tmpva) + NBPDR; continue; } /* * If the current offset aligns with a 2MB page frame * and there is at least 2MB left within the range, then * we need not break down this page into 4KB pages. */ if ((tmpva & PDRMASK) == 0 && tmpva + PDRMASK < base + size) { tmpva += NBPDR; continue; } if (!pmap_demote_pde(kernel_pmap, pde, tmpva)) return (ENOMEM); } pte = pmap_pde_to_pte(pde, tmpva); if (*pte == 0) { KASSERT((flags & MAPDEV_ASSERTVALID) == 0, ("%s: addr %#lx is not mapped", __func__, tmpva)); return (EINVAL); } tmpva += PAGE_SIZE; } error = 0; /* * Ok, all the pages exist, so run through them updating their * properties if required. */ changed = false; pa_start = pa_end = 0; for (tmpva = base; tmpva < base + size; ) { pdpe = pmap_pdpe(kernel_pmap, tmpva); if (*pdpe & PG_PS) { if ((*pdpe & pde_mask) != pde_bits) { pmap_pte_props(pdpe, pde_bits, pde_mask); changed = true; } if (tmpva >= VM_MIN_KERNEL_ADDRESS && (*pdpe & PG_PS_FRAME) < dmaplimit) { if (pa_start == pa_end) { /* Start physical address run. */ pa_start = *pdpe & PG_PS_FRAME; pa_end = pa_start + NBPDP; } else if (pa_end == (*pdpe & PG_PS_FRAME)) pa_end += NBPDP; else { /* Run ended, update direct map. */ error = pmap_change_props_locked( PHYS_TO_DMAP(pa_start), pa_end - pa_start, prot, mode, flags); if (error != 0) break; /* Start physical address run. */ pa_start = *pdpe & PG_PS_FRAME; pa_end = pa_start + NBPDP; } } tmpva = trunc_1gpage(tmpva) + NBPDP; continue; } pde = pmap_pdpe_to_pde(pdpe, tmpva); if (*pde & PG_PS) { if ((*pde & pde_mask) != pde_bits) { pmap_pte_props(pde, pde_bits, pde_mask); changed = true; } if (tmpva >= VM_MIN_KERNEL_ADDRESS && (*pde & PG_PS_FRAME) < dmaplimit) { if (pa_start == pa_end) { /* Start physical address run. */ pa_start = *pde & PG_PS_FRAME; pa_end = pa_start + NBPDR; } else if (pa_end == (*pde & PG_PS_FRAME)) pa_end += NBPDR; else { /* Run ended, update direct map. */ error = pmap_change_props_locked( PHYS_TO_DMAP(pa_start), pa_end - pa_start, prot, mode, flags); if (error != 0) break; /* Start physical address run. */ pa_start = *pde & PG_PS_FRAME; pa_end = pa_start + NBPDR; } } tmpva = trunc_2mpage(tmpva) + NBPDR; } else { pte = pmap_pde_to_pte(pde, tmpva); if ((*pte & pte_mask) != pte_bits) { pmap_pte_props(pte, pte_bits, pte_mask); changed = true; } if (tmpva >= VM_MIN_KERNEL_ADDRESS && (*pte & PG_FRAME) < dmaplimit) { if (pa_start == pa_end) { /* Start physical address run. */ pa_start = *pte & PG_FRAME; pa_end = pa_start + PAGE_SIZE; } else if (pa_end == (*pte & PG_FRAME)) pa_end += PAGE_SIZE; else { /* Run ended, update direct map. */ error = pmap_change_props_locked( PHYS_TO_DMAP(pa_start), pa_end - pa_start, prot, mode, flags); if (error != 0) break; /* Start physical address run. */ pa_start = *pte & PG_FRAME; pa_end = pa_start + PAGE_SIZE; } } tmpva += PAGE_SIZE; } } if (error == 0 && pa_start != pa_end && pa_start < dmaplimit) { pa_end1 = MIN(pa_end, dmaplimit); if (pa_start != pa_end1) error = pmap_change_props_locked(PHYS_TO_DMAP(pa_start), pa_end1 - pa_start, prot, mode, flags); } /* * Flush CPU caches if required to make sure any data isn't cached that * shouldn't be, etc. */ if (changed) { pmap_invalidate_range(kernel_pmap, base, tmpva); if ((flags & MAPDEV_FLUSHCACHE) != 0) pmap_invalidate_cache_range(base, tmpva); } return (error); } /* * Demotes any mapping within the direct map region that covers more than the * specified range of physical addresses. This range's size must be a power * of two and its starting address must be a multiple of its size. Since the * demotion does not change any attributes of the mapping, a TLB invalidation * is not mandatory. The caller may, however, request a TLB invalidation. */ void pmap_demote_DMAP(vm_paddr_t base, vm_size_t len, boolean_t invalidate) { pdp_entry_t *pdpe; pd_entry_t *pde; vm_offset_t va; boolean_t changed; if (len == 0) return; KASSERT(powerof2(len), ("pmap_demote_DMAP: len is not a power of 2")); KASSERT((base & (len - 1)) == 0, ("pmap_demote_DMAP: base is not a multiple of len")); if (len < NBPDP && base < dmaplimit) { va = PHYS_TO_DMAP(base); changed = FALSE; PMAP_LOCK(kernel_pmap); pdpe = pmap_pdpe(kernel_pmap, va); if ((*pdpe & X86_PG_V) == 0) panic("pmap_demote_DMAP: invalid PDPE"); if ((*pdpe & PG_PS) != 0) { if (!pmap_demote_pdpe(kernel_pmap, pdpe, va)) panic("pmap_demote_DMAP: PDPE failed"); changed = TRUE; } if (len < NBPDR) { pde = pmap_pdpe_to_pde(pdpe, va); if ((*pde & X86_PG_V) == 0) panic("pmap_demote_DMAP: invalid PDE"); if ((*pde & PG_PS) != 0) { if (!pmap_demote_pde(kernel_pmap, pde, va)) panic("pmap_demote_DMAP: PDE failed"); changed = TRUE; } } if (changed && invalidate) pmap_invalidate_page(kernel_pmap, va); PMAP_UNLOCK(kernel_pmap); } } /* * Perform the pmap work for mincore(2). If the page is not both referenced and * modified by this pmap, returns its physical address so that the caller can * find other mappings. */ int pmap_mincore(pmap_t pmap, vm_offset_t addr, vm_paddr_t *pap) { pdp_entry_t *pdpe; pd_entry_t *pdep; pt_entry_t pte, PG_A, PG_M, PG_RW, PG_V; vm_paddr_t pa; int val; PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_RW = pmap_rw_bit(pmap); PMAP_LOCK(pmap); pte = 0; pa = 0; val = 0; pdpe = pmap_pdpe(pmap, addr); if (pdpe == NULL) goto out; if ((*pdpe & PG_V) != 0) { if ((*pdpe & PG_PS) != 0) { pte = *pdpe; pa = ((pte & PG_PS_PDP_FRAME) | (addr & PDPMASK)) & PG_FRAME; val = MINCORE_PSIND(2); } else { pdep = pmap_pde(pmap, addr); if (pdep != NULL && (*pdep & PG_V) != 0) { if ((*pdep & PG_PS) != 0) { pte = *pdep; /* Compute the physical address of the 4KB page. */ pa = ((pte & PG_PS_FRAME) | (addr & PDRMASK)) & PG_FRAME; val = MINCORE_PSIND(1); } else { pte = *pmap_pde_to_pte(pdep, addr); pa = pte & PG_FRAME; val = 0; } } } } if ((pte & PG_V) != 0) { val |= MINCORE_INCORE; if ((pte & (PG_M | PG_RW)) == (PG_M | PG_RW)) val |= MINCORE_MODIFIED | MINCORE_MODIFIED_OTHER; if ((pte & PG_A) != 0) val |= MINCORE_REFERENCED | MINCORE_REFERENCED_OTHER; } if ((val & (MINCORE_MODIFIED_OTHER | MINCORE_REFERENCED_OTHER)) != (MINCORE_MODIFIED_OTHER | MINCORE_REFERENCED_OTHER) && (pte & (PG_MANAGED | PG_V)) == (PG_MANAGED | PG_V)) { *pap = pa; } out: PMAP_UNLOCK(pmap); return (val); } static uint64_t pmap_pcid_alloc(pmap_t pmap, struct pmap_pcid *pcidp) { uint32_t gen, new_gen, pcid_next; CRITICAL_ASSERT(curthread); gen = PCPU_GET(pcid_gen); if (pcidp->pm_pcid == PMAP_PCID_KERN) return (pti ? 0 : CR3_PCID_SAVE); if (pcidp->pm_gen == gen) return (CR3_PCID_SAVE); pcid_next = PCPU_GET(pcid_next); KASSERT((!pti && pcid_next <= PMAP_PCID_OVERMAX) || (pti && pcid_next <= PMAP_PCID_OVERMAX_KERN), ("cpu %d pcid_next %#x", PCPU_GET(cpuid), pcid_next)); if ((!pti && pcid_next == PMAP_PCID_OVERMAX) || (pti && pcid_next == PMAP_PCID_OVERMAX_KERN)) { new_gen = gen + 1; if (new_gen == 0) new_gen = 1; PCPU_SET(pcid_gen, new_gen); pcid_next = PMAP_PCID_KERN + 1; } else { new_gen = gen; } pcidp->pm_pcid = pcid_next; pcidp->pm_gen = new_gen; PCPU_SET(pcid_next, pcid_next + 1); return (0); } static uint64_t pmap_pcid_alloc_checked(pmap_t pmap, struct pmap_pcid *pcidp) { uint64_t cached; cached = pmap_pcid_alloc(pmap, pcidp); KASSERT(pcidp->pm_pcid < PMAP_PCID_OVERMAX, ("pmap %p cpu %d pcid %#x", pmap, PCPU_GET(cpuid), pcidp->pm_pcid)); KASSERT(pcidp->pm_pcid != PMAP_PCID_KERN || pmap == kernel_pmap, ("non-kernel pmap pmap %p cpu %d pcid %#x", pmap, PCPU_GET(cpuid), pcidp->pm_pcid)); return (cached); } static void pmap_activate_sw_pti_post(struct thread *td, pmap_t pmap) { PCPU_GET(tssp)->tss_rsp0 = pmap->pm_ucr3 != PMAP_NO_CR3 ? PCPU_GET(pti_rsp0) : (uintptr_t)td->td_md.md_stack_base; } static void pmap_activate_sw_pcid_pti(struct thread *td, pmap_t pmap, u_int cpuid) { pmap_t old_pmap; struct pmap_pcid *pcidp, *old_pcidp; uint64_t cached, cr3, kcr3, ucr3; KASSERT((read_rflags() & PSL_I) == 0, ("PCID needs interrupts disabled in pmap_activate_sw()")); /* See the comment in pmap_invalidate_page_pcid(). */ if (PCPU_GET(ucr3_load_mask) != PMAP_UCR3_NOMASK) { PCPU_SET(ucr3_load_mask, PMAP_UCR3_NOMASK); old_pmap = PCPU_GET(curpmap); MPASS(old_pmap->pm_ucr3 != PMAP_NO_CR3); old_pcidp = zpcpu_get_cpu(old_pmap->pm_pcidp, cpuid); old_pcidp->pm_gen = 0; } pcidp = zpcpu_get_cpu(pmap->pm_pcidp, cpuid); cached = pmap_pcid_alloc_checked(pmap, pcidp); cr3 = rcr3(); if ((cr3 & ~CR3_PCID_MASK) != pmap->pm_cr3) load_cr3(pmap->pm_cr3 | pcidp->pm_pcid); PCPU_SET(curpmap, pmap); kcr3 = pmap->pm_cr3 | pcidp->pm_pcid; ucr3 = pmap->pm_ucr3 | pcidp->pm_pcid | PMAP_PCID_USER_PT; if (!cached && pmap->pm_ucr3 != PMAP_NO_CR3) PCPU_SET(ucr3_load_mask, ~CR3_PCID_SAVE); PCPU_SET(kcr3, kcr3 | CR3_PCID_SAVE); PCPU_SET(ucr3, ucr3 | CR3_PCID_SAVE); if (cached) counter_u64_add(pcid_save_cnt, 1); pmap_activate_sw_pti_post(td, pmap); } static void pmap_activate_sw_pcid_nopti(struct thread *td __unused, pmap_t pmap, u_int cpuid) { struct pmap_pcid *pcidp; uint64_t cached, cr3; KASSERT((read_rflags() & PSL_I) == 0, ("PCID needs interrupts disabled in pmap_activate_sw()")); pcidp = zpcpu_get_cpu(pmap->pm_pcidp, cpuid); cached = pmap_pcid_alloc_checked(pmap, pcidp); cr3 = rcr3(); if (!cached || (cr3 & ~CR3_PCID_MASK) != pmap->pm_cr3) load_cr3(pmap->pm_cr3 | pcidp->pm_pcid | cached); PCPU_SET(curpmap, pmap); if (cached) counter_u64_add(pcid_save_cnt, 1); } static void pmap_activate_sw_nopcid_nopti(struct thread *td __unused, pmap_t pmap, u_int cpuid __unused) { load_cr3(pmap->pm_cr3); PCPU_SET(curpmap, pmap); } static void pmap_activate_sw_nopcid_pti(struct thread *td, pmap_t pmap, u_int cpuid __unused) { pmap_activate_sw_nopcid_nopti(td, pmap, cpuid); PCPU_SET(kcr3, pmap->pm_cr3); PCPU_SET(ucr3, pmap->pm_ucr3); pmap_activate_sw_pti_post(td, pmap); } DEFINE_IFUNC(static, void, pmap_activate_sw_mode, (struct thread *, pmap_t, u_int)) { if (pmap_pcid_enabled && pti) return (pmap_activate_sw_pcid_pti); else if (pmap_pcid_enabled && !pti) return (pmap_activate_sw_pcid_nopti); else if (!pmap_pcid_enabled && pti) return (pmap_activate_sw_nopcid_pti); else /* if (!pmap_pcid_enabled && !pti) */ return (pmap_activate_sw_nopcid_nopti); } void pmap_activate_sw(struct thread *td) { pmap_t oldpmap, pmap; u_int cpuid; oldpmap = PCPU_GET(curpmap); pmap = vmspace_pmap(td->td_proc->p_vmspace); if (oldpmap == pmap) { if (cpu_vendor_id != CPU_VENDOR_INTEL) mfence(); return; } cpuid = PCPU_GET(cpuid); #ifdef SMP CPU_SET_ATOMIC(cpuid, &pmap->pm_active); #else CPU_SET(cpuid, &pmap->pm_active); #endif pmap_activate_sw_mode(td, pmap, cpuid); #ifdef SMP CPU_CLR_ATOMIC(cpuid, &oldpmap->pm_active); #else CPU_CLR(cpuid, &oldpmap->pm_active); #endif } void pmap_activate(struct thread *td) { /* * invltlb_{invpcid,}_pcid_handler() is used to handle an * invalidate_all IPI, which checks for curpmap == * smp_tlb_pmap. The below sequence of operations has a * window where %CR3 is loaded with the new pmap's PML4 * address, but the curpmap value has not yet been updated. * This causes the invltlb IPI handler, which is called * between the updates, to execute as a NOP, which leaves * stale TLB entries. * * Note that the most common use of pmap_activate_sw(), from * a context switch, is immune to this race, because * interrupts are disabled (while the thread lock is owned), * so the IPI is delayed until after curpmap is updated. Protect * other callers in a similar way, by disabling interrupts * around the %cr3 register reload and curpmap assignment. */ spinlock_enter(); pmap_activate_sw(td); spinlock_exit(); } void pmap_activate_boot(pmap_t pmap) { uint64_t kcr3; u_int cpuid; /* * kernel_pmap must be never deactivated, and we ensure that * by never activating it at all. */ MPASS(pmap != kernel_pmap); cpuid = PCPU_GET(cpuid); #ifdef SMP CPU_SET_ATOMIC(cpuid, &pmap->pm_active); #else CPU_SET(cpuid, &pmap->pm_active); #endif PCPU_SET(curpmap, pmap); if (pti) { kcr3 = pmap->pm_cr3; if (pmap_pcid_enabled) kcr3 |= pmap_get_pcid(pmap) | CR3_PCID_SAVE; } else { kcr3 = PMAP_NO_CR3; } PCPU_SET(kcr3, kcr3); PCPU_SET(ucr3, PMAP_NO_CR3); } +void +pmap_active_cpus(pmap_t pmap, cpuset_t *res) +{ + *res = pmap->pm_active; +} + void pmap_sync_icache(pmap_t pm, vm_offset_t va, vm_size_t sz) { } /* * Increase the starting virtual address of the given mapping if a * different alignment might result in more superpage mappings. */ void pmap_align_superpage(vm_object_t object, vm_ooffset_t offset, vm_offset_t *addr, vm_size_t size) { vm_offset_t superpage_offset; if (size < NBPDR) return; if (object != NULL && (object->flags & OBJ_COLORED) != 0) offset += ptoa(object->pg_color); superpage_offset = offset & PDRMASK; if (size - ((NBPDR - superpage_offset) & PDRMASK) < NBPDR || (*addr & PDRMASK) == superpage_offset) return; if ((*addr & PDRMASK) < superpage_offset) *addr = (*addr & ~PDRMASK) + superpage_offset; else *addr = ((*addr + PDRMASK) & ~PDRMASK) + superpage_offset; } #ifdef INVARIANTS static unsigned long num_dirty_emulations; SYSCTL_ULONG(_vm_pmap, OID_AUTO, num_dirty_emulations, CTLFLAG_RW, &num_dirty_emulations, 0, NULL); static unsigned long num_accessed_emulations; SYSCTL_ULONG(_vm_pmap, OID_AUTO, num_accessed_emulations, CTLFLAG_RW, &num_accessed_emulations, 0, NULL); static unsigned long num_superpage_accessed_emulations; SYSCTL_ULONG(_vm_pmap, OID_AUTO, num_superpage_accessed_emulations, CTLFLAG_RW, &num_superpage_accessed_emulations, 0, NULL); static unsigned long ad_emulation_superpage_promotions; SYSCTL_ULONG(_vm_pmap, OID_AUTO, ad_emulation_superpage_promotions, CTLFLAG_RW, &ad_emulation_superpage_promotions, 0, NULL); #endif /* INVARIANTS */ int pmap_emulate_accessed_dirty(pmap_t pmap, vm_offset_t va, int ftype) { int rv; struct rwlock *lock; #if VM_NRESERVLEVEL > 0 vm_page_t m, mpte; #endif pd_entry_t *pde; pt_entry_t *pte, PG_A, PG_M, PG_RW, PG_V; KASSERT(ftype == VM_PROT_READ || ftype == VM_PROT_WRITE, ("pmap_emulate_accessed_dirty: invalid fault type %d", ftype)); if (!pmap_emulate_ad_bits(pmap)) return (-1); PG_A = pmap_accessed_bit(pmap); PG_M = pmap_modified_bit(pmap); PG_V = pmap_valid_bit(pmap); PG_RW = pmap_rw_bit(pmap); rv = -1; lock = NULL; PMAP_LOCK(pmap); pde = pmap_pde(pmap, va); if (pde == NULL || (*pde & PG_V) == 0) goto done; if ((*pde & PG_PS) != 0) { if (ftype == VM_PROT_READ) { #ifdef INVARIANTS atomic_add_long(&num_superpage_accessed_emulations, 1); #endif *pde |= PG_A; rv = 0; } goto done; } pte = pmap_pde_to_pte(pde, va); if ((*pte & PG_V) == 0) goto done; if (ftype == VM_PROT_WRITE) { if ((*pte & PG_RW) == 0) goto done; /* * Set the modified and accessed bits simultaneously. * * Intel EPT PTEs that do software emulation of A/D bits map * PG_A and PG_M to EPT_PG_READ and EPT_PG_WRITE respectively. * An EPT misconfiguration is triggered if the PTE is writable * but not readable (WR=10). This is avoided by setting PG_A * and PG_M simultaneously. */ *pte |= PG_M | PG_A; } else { *pte |= PG_A; } #if VM_NRESERVLEVEL > 0 /* try to promote the mapping */ if (va < VM_MAXUSER_ADDRESS) mpte = PHYS_TO_VM_PAGE(*pde & PG_FRAME); else mpte = NULL; m = PHYS_TO_VM_PAGE(*pte & PG_FRAME); if ((mpte == NULL || mpte->ref_count == NPTEPG) && (m->flags & PG_FICTITIOUS) == 0 && vm_reserv_level_iffullpop(m) == 0 && pmap_promote_pde(pmap, pde, va, mpte, &lock)) { #ifdef INVARIANTS atomic_add_long(&ad_emulation_superpage_promotions, 1); #endif } #endif #ifdef INVARIANTS if (ftype == VM_PROT_WRITE) atomic_add_long(&num_dirty_emulations, 1); else atomic_add_long(&num_accessed_emulations, 1); #endif rv = 0; /* success */ done: if (lock != NULL) rw_wunlock(lock); PMAP_UNLOCK(pmap); return (rv); } void pmap_get_mapping(pmap_t pmap, vm_offset_t va, uint64_t *ptr, int *num) { pml4_entry_t *pml4; pdp_entry_t *pdp; pd_entry_t *pde; pt_entry_t *pte, PG_V; int idx; idx = 0; PG_V = pmap_valid_bit(pmap); PMAP_LOCK(pmap); pml4 = pmap_pml4e(pmap, va); if (pml4 == NULL) goto done; ptr[idx++] = *pml4; if ((*pml4 & PG_V) == 0) goto done; pdp = pmap_pml4e_to_pdpe(pml4, va); ptr[idx++] = *pdp; if ((*pdp & PG_V) == 0 || (*pdp & PG_PS) != 0) goto done; pde = pmap_pdpe_to_pde(pdp, va); ptr[idx++] = *pde; if ((*pde & PG_V) == 0 || (*pde & PG_PS) != 0) goto done; pte = pmap_pde_to_pte(pde, va); ptr[idx++] = *pte; done: PMAP_UNLOCK(pmap); *num = idx; } /** * Get the kernel virtual address of a set of physical pages. If there are * physical addresses not covered by the DMAP perform a transient mapping * that will be removed when calling pmap_unmap_io_transient. * * \param page The pages the caller wishes to obtain the virtual * address on the kernel memory map. * \param vaddr On return contains the kernel virtual memory address * of the pages passed in the page parameter. * \param count Number of pages passed in. * \param can_fault true if the thread using the mapped pages can take * page faults, false otherwise. * * \returns true if the caller must call pmap_unmap_io_transient when * finished or false otherwise. * */ bool pmap_map_io_transient(vm_page_t page[], vm_offset_t vaddr[], int count, bool can_fault) { vm_paddr_t paddr; bool needs_mapping; pt_entry_t *pte; int cache_bits, error __unused, i; /* * Allocate any KVA space that we need, this is done in a separate * loop to prevent calling vmem_alloc while pinned. */ needs_mapping = false; for (i = 0; i < count; i++) { paddr = VM_PAGE_TO_PHYS(page[i]); if (__predict_false(paddr >= dmaplimit)) { error = vmem_alloc(kernel_arena, PAGE_SIZE, M_BESTFIT | M_WAITOK, &vaddr[i]); KASSERT(error == 0, ("vmem_alloc failed: %d", error)); needs_mapping = true; } else { vaddr[i] = PHYS_TO_DMAP(paddr); } } /* Exit early if everything is covered by the DMAP */ if (!needs_mapping) return (false); /* * NB: The sequence of updating a page table followed by accesses * to the corresponding pages used in the !DMAP case is subject to * the situation described in the "AMD64 Architecture Programmer's * Manual Volume 2: System Programming" rev. 3.23, "7.3.1 Special * Coherency Considerations". Therefore, issuing the INVLPG right * after modifying the PTE bits is crucial. */ if (!can_fault) sched_pin(); for (i = 0; i < count; i++) { paddr = VM_PAGE_TO_PHYS(page[i]); if (paddr >= dmaplimit) { if (can_fault) { /* * Slow path, since we can get page faults * while mappings are active don't pin the * thread to the CPU and instead add a global * mapping visible to all CPUs. */ pmap_qenter(vaddr[i], &page[i], 1); } else { pte = vtopte(vaddr[i]); cache_bits = pmap_cache_bits(kernel_pmap, page[i]->md.pat_mode, false); pte_store(pte, paddr | X86_PG_RW | X86_PG_V | cache_bits); pmap_invlpg(kernel_pmap, vaddr[i]); } } } return (needs_mapping); } void pmap_unmap_io_transient(vm_page_t page[], vm_offset_t vaddr[], int count, bool can_fault) { vm_paddr_t paddr; int i; if (!can_fault) sched_unpin(); for (i = 0; i < count; i++) { paddr = VM_PAGE_TO_PHYS(page[i]); if (paddr >= dmaplimit) { if (can_fault) pmap_qremove(vaddr[i], 1); vmem_free(kernel_arena, vaddr[i], PAGE_SIZE); } } } vm_offset_t pmap_quick_enter_page(vm_page_t m) { vm_paddr_t paddr; paddr = VM_PAGE_TO_PHYS(m); if (paddr < dmaplimit) return (PHYS_TO_DMAP(paddr)); mtx_lock_spin(&qframe_mtx); KASSERT(*vtopte(qframe) == 0, ("qframe busy")); /* * Since qframe is exclusively mapped by us, and we do not set * PG_G, we can use INVLPG here. */ invlpg(qframe); pte_store(vtopte(qframe), paddr | X86_PG_RW | X86_PG_V | X86_PG_A | X86_PG_M | pmap_cache_bits(kernel_pmap, m->md.pat_mode, 0)); return (qframe); } void pmap_quick_remove_page(vm_offset_t addr) { if (addr != qframe) return; pte_store(vtopte(qframe), 0); mtx_unlock_spin(&qframe_mtx); } /* * Pdp pages from the large map are managed differently from either * kernel or user page table pages. They are permanently allocated at * initialization time, and their reference count is permanently set to * zero. The pml4 entries pointing to those pages are copied into * each allocated pmap. * * In contrast, pd and pt pages are managed like user page table * pages. They are dynamically allocated, and their reference count * represents the number of valid entries within the page. */ static vm_page_t pmap_large_map_getptp_unlocked(void) { return (pmap_alloc_pt_page(kernel_pmap, 0, VM_ALLOC_ZERO)); } static vm_page_t pmap_large_map_getptp(void) { vm_page_t m; PMAP_LOCK_ASSERT(kernel_pmap, MA_OWNED); m = pmap_large_map_getptp_unlocked(); if (m == NULL) { PMAP_UNLOCK(kernel_pmap); vm_wait(NULL); PMAP_LOCK(kernel_pmap); /* Callers retry. */ } return (m); } static pdp_entry_t * pmap_large_map_pdpe(vm_offset_t va) { vm_pindex_t pml4_idx; vm_paddr_t mphys; pml4_idx = pmap_pml4e_index(va); KASSERT(LMSPML4I <= pml4_idx && pml4_idx < LMSPML4I + lm_ents, ("pmap_large_map_pdpe: va %#jx out of range idx %#jx LMSPML4I " "%#jx lm_ents %d", (uintmax_t)va, (uintmax_t)pml4_idx, LMSPML4I, lm_ents)); KASSERT((kernel_pml4[pml4_idx] & X86_PG_V) != 0, ("pmap_large_map_pdpe: invalid pml4 for va %#jx idx %#jx " "LMSPML4I %#jx lm_ents %d", (uintmax_t)va, (uintmax_t)pml4_idx, LMSPML4I, lm_ents)); mphys = kernel_pml4[pml4_idx] & PG_FRAME; return ((pdp_entry_t *)PHYS_TO_DMAP(mphys) + pmap_pdpe_index(va)); } static pd_entry_t * pmap_large_map_pde(vm_offset_t va) { pdp_entry_t *pdpe; vm_page_t m; vm_paddr_t mphys; retry: pdpe = pmap_large_map_pdpe(va); if (*pdpe == 0) { m = pmap_large_map_getptp(); if (m == NULL) goto retry; mphys = VM_PAGE_TO_PHYS(m); *pdpe = mphys | X86_PG_A | X86_PG_RW | X86_PG_V | pg_nx; } else { MPASS((*pdpe & X86_PG_PS) == 0); mphys = *pdpe & PG_FRAME; } return ((pd_entry_t *)PHYS_TO_DMAP(mphys) + pmap_pde_index(va)); } static pt_entry_t * pmap_large_map_pte(vm_offset_t va) { pd_entry_t *pde; vm_page_t m; vm_paddr_t mphys; retry: pde = pmap_large_map_pde(va); if (*pde == 0) { m = pmap_large_map_getptp(); if (m == NULL) goto retry; mphys = VM_PAGE_TO_PHYS(m); *pde = mphys | X86_PG_A | X86_PG_RW | X86_PG_V | pg_nx; PHYS_TO_VM_PAGE(DMAP_TO_PHYS((uintptr_t)pde))->ref_count++; } else { MPASS((*pde & X86_PG_PS) == 0); mphys = *pde & PG_FRAME; } return ((pt_entry_t *)PHYS_TO_DMAP(mphys) + pmap_pte_index(va)); } static vm_paddr_t pmap_large_map_kextract(vm_offset_t va) { pdp_entry_t *pdpe, pdp; pd_entry_t *pde, pd; pt_entry_t *pte, pt; KASSERT(PMAP_ADDRESS_IN_LARGEMAP(va), ("not largemap range %#lx", (u_long)va)); pdpe = pmap_large_map_pdpe(va); pdp = *pdpe; KASSERT((pdp & X86_PG_V) != 0, ("invalid pdp va %#lx pdpe %#lx pdp %#lx", va, (u_long)pdpe, pdp)); if ((pdp & X86_PG_PS) != 0) { KASSERT((amd_feature & AMDID_PAGE1GB) != 0, ("no 1G pages, va %#lx pdpe %#lx pdp %#lx", va, (u_long)pdpe, pdp)); return ((pdp & PG_PS_PDP_FRAME) | (va & PDPMASK)); } pde = pmap_pdpe_to_pde(pdpe, va); pd = *pde; KASSERT((pd & X86_PG_V) != 0, ("invalid pd va %#lx pde %#lx pd %#lx", va, (u_long)pde, pd)); if ((pd & X86_PG_PS) != 0) return ((pd & PG_PS_FRAME) | (va & PDRMASK)); pte = pmap_pde_to_pte(pde, va); pt = *pte; KASSERT((pt & X86_PG_V) != 0, ("invalid pte va %#lx pte %#lx pt %#lx", va, (u_long)pte, pt)); return ((pt & PG_FRAME) | (va & PAGE_MASK)); } static int pmap_large_map_getva(vm_size_t len, vm_offset_t align, vm_offset_t phase, vmem_addr_t *vmem_res) { /* * Large mappings are all but static. Consequently, there * is no point in waiting for an earlier allocation to be * freed. */ return (vmem_xalloc(large_vmem, len, align, phase, 0, VMEM_ADDR_MIN, VMEM_ADDR_MAX, M_NOWAIT | M_BESTFIT, vmem_res)); } int pmap_large_map(vm_paddr_t spa, vm_size_t len, void **addr, vm_memattr_t mattr) { pdp_entry_t *pdpe; pd_entry_t *pde; pt_entry_t *pte; vm_offset_t va, inc; vmem_addr_t vmem_res; vm_paddr_t pa; int error; if (len == 0 || spa + len < spa) return (EINVAL); /* See if DMAP can serve. */ if (spa + len <= dmaplimit) { va = PHYS_TO_DMAP(spa); *addr = (void *)va; return (pmap_change_attr(va, len, mattr)); } /* * No, allocate KVA. Fit the address with best possible * alignment for superpages. Fall back to worse align if * failed. */ error = ENOMEM; if ((amd_feature & AMDID_PAGE1GB) != 0 && rounddown2(spa + len, NBPDP) >= roundup2(spa, NBPDP) + NBPDP) error = pmap_large_map_getva(len, NBPDP, spa & PDPMASK, &vmem_res); if (error != 0 && rounddown2(spa + len, NBPDR) >= roundup2(spa, NBPDR) + NBPDR) error = pmap_large_map_getva(len, NBPDR, spa & PDRMASK, &vmem_res); if (error != 0) error = pmap_large_map_getva(len, PAGE_SIZE, 0, &vmem_res); if (error != 0) return (error); /* * Fill pagetable. PG_M is not pre-set, we scan modified bits * in the pagetable to minimize flushing. No need to * invalidate TLB, since we only update invalid entries. */ PMAP_LOCK(kernel_pmap); for (pa = spa, va = vmem_res; len > 0; pa += inc, va += inc, len -= inc) { if ((amd_feature & AMDID_PAGE1GB) != 0 && len >= NBPDP && (pa & PDPMASK) == 0 && (va & PDPMASK) == 0) { pdpe = pmap_large_map_pdpe(va); MPASS(*pdpe == 0); *pdpe = pa | pg_g | X86_PG_PS | X86_PG_RW | X86_PG_V | X86_PG_A | pg_nx | pmap_cache_bits(kernel_pmap, mattr, TRUE); inc = NBPDP; } else if (len >= NBPDR && (pa & PDRMASK) == 0 && (va & PDRMASK) == 0) { pde = pmap_large_map_pde(va); MPASS(*pde == 0); *pde = pa | pg_g | X86_PG_PS | X86_PG_RW | X86_PG_V | X86_PG_A | pg_nx | pmap_cache_bits(kernel_pmap, mattr, TRUE); PHYS_TO_VM_PAGE(DMAP_TO_PHYS((uintptr_t)pde))-> ref_count++; inc = NBPDR; } else { pte = pmap_large_map_pte(va); MPASS(*pte == 0); *pte = pa | pg_g | X86_PG_RW | X86_PG_V | X86_PG_A | pg_nx | pmap_cache_bits(kernel_pmap, mattr, FALSE); PHYS_TO_VM_PAGE(DMAP_TO_PHYS((uintptr_t)pte))-> ref_count++; inc = PAGE_SIZE; } } PMAP_UNLOCK(kernel_pmap); MPASS(len == 0); *addr = (void *)vmem_res; return (0); } void pmap_large_unmap(void *svaa, vm_size_t len) { vm_offset_t sva, va; vm_size_t inc; pdp_entry_t *pdpe, pdp; pd_entry_t *pde, pd; pt_entry_t *pte; vm_page_t m; struct spglist spgf; sva = (vm_offset_t)svaa; if (len == 0 || sva + len < sva || (sva >= DMAP_MIN_ADDRESS && sva + len <= DMAP_MIN_ADDRESS + dmaplimit)) return; SLIST_INIT(&spgf); KASSERT(PMAP_ADDRESS_IN_LARGEMAP(sva) && PMAP_ADDRESS_IN_LARGEMAP(sva + len - 1), ("not largemap range %#lx %#lx", (u_long)svaa, (u_long)svaa + len)); PMAP_LOCK(kernel_pmap); for (va = sva; va < sva + len; va += inc) { pdpe = pmap_large_map_pdpe(va); pdp = *pdpe; KASSERT((pdp & X86_PG_V) != 0, ("invalid pdp va %#lx pdpe %#lx pdp %#lx", va, (u_long)pdpe, pdp)); if ((pdp & X86_PG_PS) != 0) { KASSERT((amd_feature & AMDID_PAGE1GB) != 0, ("no 1G pages, va %#lx pdpe %#lx pdp %#lx", va, (u_long)pdpe, pdp)); KASSERT((va & PDPMASK) == 0, ("PDPMASK bit set, va %#lx pdpe %#lx pdp %#lx", va, (u_long)pdpe, pdp)); KASSERT(va + NBPDP <= sva + len, ("unmap covers partial 1GB page, sva %#lx va %#lx " "pdpe %#lx pdp %#lx len %#lx", sva, va, (u_long)pdpe, pdp, len)); *pdpe = 0; inc = NBPDP; continue; } pde = pmap_pdpe_to_pde(pdpe, va); pd = *pde; KASSERT((pd & X86_PG_V) != 0, ("invalid pd va %#lx pde %#lx pd %#lx", va, (u_long)pde, pd)); if ((pd & X86_PG_PS) != 0) { KASSERT((va & PDRMASK) == 0, ("PDRMASK bit set, va %#lx pde %#lx pd %#lx", va, (u_long)pde, pd)); KASSERT(va + NBPDR <= sva + len, ("unmap covers partial 2MB page, sva %#lx va %#lx " "pde %#lx pd %#lx len %#lx", sva, va, (u_long)pde, pd, len)); pde_store(pde, 0); inc = NBPDR; m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((vm_offset_t)pde)); m->ref_count--; if (m->ref_count == 0) { *pdpe = 0; SLIST_INSERT_HEAD(&spgf, m, plinks.s.ss); } continue; } pte = pmap_pde_to_pte(pde, va); KASSERT((*pte & X86_PG_V) != 0, ("invalid pte va %#lx pte %#lx pt %#lx", va, (u_long)pte, *pte)); pte_clear(pte); inc = PAGE_SIZE; m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((vm_offset_t)pte)); m->ref_count--; if (m->ref_count == 0) { *pde = 0; SLIST_INSERT_HEAD(&spgf, m, plinks.s.ss); m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((vm_offset_t)pde)); m->ref_count--; if (m->ref_count == 0) { *pdpe = 0; SLIST_INSERT_HEAD(&spgf, m, plinks.s.ss); } } } pmap_invalidate_range(kernel_pmap, sva, sva + len); PMAP_UNLOCK(kernel_pmap); vm_page_free_pages_toq(&spgf, false); vmem_free(large_vmem, sva, len); } static void pmap_large_map_wb_fence_mfence(void) { mfence(); } static void pmap_large_map_wb_fence_atomic(void) { atomic_thread_fence_seq_cst(); } static void pmap_large_map_wb_fence_nop(void) { } DEFINE_IFUNC(static, void, pmap_large_map_wb_fence, (void)) { if (cpu_vendor_id != CPU_VENDOR_INTEL) return (pmap_large_map_wb_fence_mfence); else if ((cpu_stdext_feature & (CPUID_STDEXT_CLWB | CPUID_STDEXT_CLFLUSHOPT)) == 0) return (pmap_large_map_wb_fence_atomic); else /* clflush is strongly enough ordered */ return (pmap_large_map_wb_fence_nop); } static void pmap_large_map_flush_range_clwb(vm_offset_t va, vm_size_t len) { for (; len > 0; len -= cpu_clflush_line_size, va += cpu_clflush_line_size) clwb(va); } static void pmap_large_map_flush_range_clflushopt(vm_offset_t va, vm_size_t len) { for (; len > 0; len -= cpu_clflush_line_size, va += cpu_clflush_line_size) clflushopt(va); } static void pmap_large_map_flush_range_clflush(vm_offset_t va, vm_size_t len) { for (; len > 0; len -= cpu_clflush_line_size, va += cpu_clflush_line_size) clflush(va); } static void pmap_large_map_flush_range_nop(vm_offset_t sva __unused, vm_size_t len __unused) { } DEFINE_IFUNC(static, void, pmap_large_map_flush_range, (vm_offset_t, vm_size_t)) { if ((cpu_stdext_feature & CPUID_STDEXT_CLWB) != 0) return (pmap_large_map_flush_range_clwb); else if ((cpu_stdext_feature & CPUID_STDEXT_CLFLUSHOPT) != 0) return (pmap_large_map_flush_range_clflushopt); else if ((cpu_feature & CPUID_CLFSH) != 0) return (pmap_large_map_flush_range_clflush); else return (pmap_large_map_flush_range_nop); } static void pmap_large_map_wb_large(vm_offset_t sva, vm_offset_t eva) { volatile u_long *pe; u_long p; vm_offset_t va; vm_size_t inc; bool seen_other; for (va = sva; va < eva; va += inc) { inc = 0; if ((amd_feature & AMDID_PAGE1GB) != 0) { pe = (volatile u_long *)pmap_large_map_pdpe(va); p = *pe; if ((p & X86_PG_PS) != 0) inc = NBPDP; } if (inc == 0) { pe = (volatile u_long *)pmap_large_map_pde(va); p = *pe; if ((p & X86_PG_PS) != 0) inc = NBPDR; } if (inc == 0) { pe = (volatile u_long *)pmap_large_map_pte(va); p = *pe; inc = PAGE_SIZE; } seen_other = false; for (;;) { if ((p & X86_PG_AVAIL1) != 0) { /* * Spin-wait for the end of a parallel * write-back. */ cpu_spinwait(); p = *pe; /* * If we saw other write-back * occuring, we cannot rely on PG_M to * indicate state of the cache. The * PG_M bit is cleared before the * flush to avoid ignoring new writes, * and writes which are relevant for * us might happen after. */ seen_other = true; continue; } if ((p & X86_PG_M) != 0 || seen_other) { if (!atomic_fcmpset_long(pe, &p, (p & ~X86_PG_M) | X86_PG_AVAIL1)) /* * If we saw PG_M without * PG_AVAIL1, and then on the * next attempt we do not * observe either PG_M or * PG_AVAIL1, the other * write-back started after us * and finished before us. We * can rely on it doing our * work. */ continue; pmap_large_map_flush_range(va, inc); atomic_clear_long(pe, X86_PG_AVAIL1); } break; } maybe_yield(); } } /* * Write-back cache lines for the given address range. * * Must be called only on the range or sub-range returned from * pmap_large_map(). Must not be called on the coalesced ranges. * * Does nothing on CPUs without CLWB, CLFLUSHOPT, or CLFLUSH * instructions support. */ void pmap_large_map_wb(void *svap, vm_size_t len) { vm_offset_t eva, sva; sva = (vm_offset_t)svap; eva = sva + len; pmap_large_map_wb_fence(); if (sva >= DMAP_MIN_ADDRESS && eva <= DMAP_MIN_ADDRESS + dmaplimit) { pmap_large_map_flush_range(sva, len); } else { KASSERT(sva >= LARGEMAP_MIN_ADDRESS && eva <= LARGEMAP_MIN_ADDRESS + lm_ents * NBPML4, ("pmap_large_map_wb: not largemap %#lx %#lx", sva, len)); pmap_large_map_wb_large(sva, eva); } pmap_large_map_wb_fence(); } static vm_page_t pmap_pti_alloc_page(void) { vm_page_t m; VM_OBJECT_ASSERT_WLOCKED(pti_obj); m = vm_page_grab(pti_obj, pti_pg_idx++, VM_ALLOC_WIRED | VM_ALLOC_ZERO); return (m); } static bool pmap_pti_free_page(vm_page_t m) { if (!vm_page_unwire_noq(m)) return (false); vm_page_xbusy_claim(m); vm_page_free_zero(m); return (true); } static void pmap_pti_init(void) { vm_page_t pml4_pg; pdp_entry_t *pdpe; vm_offset_t va; int i; if (!pti) return; pti_obj = vm_pager_allocate(OBJT_PHYS, NULL, 0, VM_PROT_ALL, 0, NULL); VM_OBJECT_WLOCK(pti_obj); pml4_pg = pmap_pti_alloc_page(); pti_pml4 = (pml4_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(pml4_pg)); for (va = VM_MIN_KERNEL_ADDRESS; va <= VM_MAX_KERNEL_ADDRESS && va >= VM_MIN_KERNEL_ADDRESS && va > NBPML4; va += NBPML4) { pdpe = pmap_pti_pdpe(va); pmap_pti_wire_pte(pdpe); } pmap_pti_add_kva_locked((vm_offset_t)&__pcpu[0], (vm_offset_t)&__pcpu[0] + sizeof(__pcpu[0]) * MAXCPU, false); pmap_pti_add_kva_locked((vm_offset_t)idt, (vm_offset_t)idt + sizeof(struct gate_descriptor) * NIDT, false); CPU_FOREACH(i) { /* Doublefault stack IST 1 */ va = __pcpu[i].pc_common_tss.tss_ist1 + sizeof(struct nmi_pcpu); pmap_pti_add_kva_locked(va - DBLFAULT_STACK_SIZE, va, false); /* NMI stack IST 2 */ va = __pcpu[i].pc_common_tss.tss_ist2 + sizeof(struct nmi_pcpu); pmap_pti_add_kva_locked(va - NMI_STACK_SIZE, va, false); /* MC# stack IST 3 */ va = __pcpu[i].pc_common_tss.tss_ist3 + sizeof(struct nmi_pcpu); pmap_pti_add_kva_locked(va - MCE_STACK_SIZE, va, false); /* DB# stack IST 4 */ va = __pcpu[i].pc_common_tss.tss_ist4 + sizeof(struct nmi_pcpu); pmap_pti_add_kva_locked(va - DBG_STACK_SIZE, va, false); } pmap_pti_add_kva_locked((vm_offset_t)KERNSTART, (vm_offset_t)etext, true); pti_finalized = true; VM_OBJECT_WUNLOCK(pti_obj); } static void pmap_cpu_init(void *arg __unused) { CPU_COPY(&all_cpus, &kernel_pmap->pm_active); pmap_pti_init(); } SYSINIT(pmap_cpu, SI_SUB_CPU + 1, SI_ORDER_ANY, pmap_cpu_init, NULL); static pdp_entry_t * pmap_pti_pdpe(vm_offset_t va) { pml4_entry_t *pml4e; pdp_entry_t *pdpe; vm_page_t m; vm_pindex_t pml4_idx; vm_paddr_t mphys; VM_OBJECT_ASSERT_WLOCKED(pti_obj); pml4_idx = pmap_pml4e_index(va); pml4e = &pti_pml4[pml4_idx]; m = NULL; if (*pml4e == 0) { if (pti_finalized) panic("pml4 alloc after finalization\n"); m = pmap_pti_alloc_page(); if (*pml4e != 0) { pmap_pti_free_page(m); mphys = *pml4e & ~PAGE_MASK; } else { mphys = VM_PAGE_TO_PHYS(m); *pml4e = mphys | X86_PG_RW | X86_PG_V; } } else { mphys = *pml4e & ~PAGE_MASK; } pdpe = (pdp_entry_t *)PHYS_TO_DMAP(mphys) + pmap_pdpe_index(va); return (pdpe); } static void pmap_pti_wire_pte(void *pte) { vm_page_t m; VM_OBJECT_ASSERT_WLOCKED(pti_obj); m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((uintptr_t)pte)); m->ref_count++; } static void pmap_pti_unwire_pde(void *pde, bool only_ref) { vm_page_t m; VM_OBJECT_ASSERT_WLOCKED(pti_obj); m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((uintptr_t)pde)); MPASS(only_ref || m->ref_count > 1); pmap_pti_free_page(m); } static void pmap_pti_unwire_pte(void *pte, vm_offset_t va) { vm_page_t m; pd_entry_t *pde; VM_OBJECT_ASSERT_WLOCKED(pti_obj); m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((uintptr_t)pte)); if (pmap_pti_free_page(m)) { pde = pmap_pti_pde(va); MPASS((*pde & (X86_PG_PS | X86_PG_V)) == X86_PG_V); *pde = 0; pmap_pti_unwire_pde(pde, false); } } static pd_entry_t * pmap_pti_pde(vm_offset_t va) { pdp_entry_t *pdpe; pd_entry_t *pde; vm_page_t m; vm_pindex_t pd_idx; vm_paddr_t mphys; VM_OBJECT_ASSERT_WLOCKED(pti_obj); pdpe = pmap_pti_pdpe(va); if (*pdpe == 0) { m = pmap_pti_alloc_page(); if (*pdpe != 0) { pmap_pti_free_page(m); MPASS((*pdpe & X86_PG_PS) == 0); mphys = *pdpe & ~PAGE_MASK; } else { mphys = VM_PAGE_TO_PHYS(m); *pdpe = mphys | X86_PG_RW | X86_PG_V; } } else { MPASS((*pdpe & X86_PG_PS) == 0); mphys = *pdpe & ~PAGE_MASK; } pde = (pd_entry_t *)PHYS_TO_DMAP(mphys); pd_idx = pmap_pde_index(va); pde += pd_idx; return (pde); } static pt_entry_t * pmap_pti_pte(vm_offset_t va, bool *unwire_pde) { pd_entry_t *pde; pt_entry_t *pte; vm_page_t m; vm_paddr_t mphys; VM_OBJECT_ASSERT_WLOCKED(pti_obj); pde = pmap_pti_pde(va); if (unwire_pde != NULL) { *unwire_pde = true; pmap_pti_wire_pte(pde); } if (*pde == 0) { m = pmap_pti_alloc_page(); if (*pde != 0) { pmap_pti_free_page(m); MPASS((*pde & X86_PG_PS) == 0); mphys = *pde & ~(PAGE_MASK | pg_nx); } else { mphys = VM_PAGE_TO_PHYS(m); *pde = mphys | X86_PG_RW | X86_PG_V; if (unwire_pde != NULL) *unwire_pde = false; } } else { MPASS((*pde & X86_PG_PS) == 0); mphys = *pde & ~(PAGE_MASK | pg_nx); } pte = (pt_entry_t *)PHYS_TO_DMAP(mphys); pte += pmap_pte_index(va); return (pte); } static void pmap_pti_add_kva_locked(vm_offset_t sva, vm_offset_t eva, bool exec) { vm_paddr_t pa; pd_entry_t *pde; pt_entry_t *pte, ptev; bool unwire_pde; VM_OBJECT_ASSERT_WLOCKED(pti_obj); sva = trunc_page(sva); MPASS(sva > VM_MAXUSER_ADDRESS); eva = round_page(eva); MPASS(sva < eva); for (; sva < eva; sva += PAGE_SIZE) { pte = pmap_pti_pte(sva, &unwire_pde); pa = pmap_kextract(sva); ptev = pa | X86_PG_RW | X86_PG_V | X86_PG_A | X86_PG_G | (exec ? 0 : pg_nx) | pmap_cache_bits(kernel_pmap, VM_MEMATTR_DEFAULT, FALSE); if (*pte == 0) { pte_store(pte, ptev); pmap_pti_wire_pte(pte); } else { KASSERT(!pti_finalized, ("pti overlap after fin %#lx %#lx %#lx", sva, *pte, ptev)); KASSERT(*pte == ptev, ("pti non-identical pte after fin %#lx %#lx %#lx", sva, *pte, ptev)); } if (unwire_pde) { pde = pmap_pti_pde(sva); pmap_pti_unwire_pde(pde, true); } } } void pmap_pti_add_kva(vm_offset_t sva, vm_offset_t eva, bool exec) { if (!pti) return; VM_OBJECT_WLOCK(pti_obj); pmap_pti_add_kva_locked(sva, eva, exec); VM_OBJECT_WUNLOCK(pti_obj); } void pmap_pti_remove_kva(vm_offset_t sva, vm_offset_t eva) { pt_entry_t *pte; vm_offset_t va; if (!pti) return; sva = rounddown2(sva, PAGE_SIZE); MPASS(sva > VM_MAXUSER_ADDRESS); eva = roundup2(eva, PAGE_SIZE); MPASS(sva < eva); VM_OBJECT_WLOCK(pti_obj); for (va = sva; va < eva; va += PAGE_SIZE) { pte = pmap_pti_pte(va, NULL); KASSERT((*pte & X86_PG_V) != 0, ("invalid pte va %#lx pte %#lx pt %#lx", va, (u_long)pte, *pte)); pte_clear(pte); pmap_pti_unwire_pte(pte, va); } pmap_invalidate_range(kernel_pmap, sva, eva); VM_OBJECT_WUNLOCK(pti_obj); } static void * pkru_dup_range(void *ctx __unused, void *data) { struct pmap_pkru_range *node, *new_node; new_node = uma_zalloc(pmap_pkru_ranges_zone, M_NOWAIT); if (new_node == NULL) return (NULL); node = data; memcpy(new_node, node, sizeof(*node)); return (new_node); } static void pkru_free_range(void *ctx __unused, void *node) { uma_zfree(pmap_pkru_ranges_zone, node); } static int pmap_pkru_assign(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, u_int keyidx, int flags) { struct pmap_pkru_range *ppr; int error; PMAP_LOCK_ASSERT(pmap, MA_OWNED); MPASS(pmap->pm_type == PT_X86); MPASS((cpu_stdext_feature2 & CPUID_STDEXT2_PKU) != 0); if ((flags & AMD64_PKRU_EXCL) != 0 && !rangeset_check_empty(&pmap->pm_pkru, sva, eva)) return (EBUSY); ppr = uma_zalloc(pmap_pkru_ranges_zone, M_NOWAIT); if (ppr == NULL) return (ENOMEM); ppr->pkru_keyidx = keyidx; ppr->pkru_flags = flags & AMD64_PKRU_PERSIST; error = rangeset_insert(&pmap->pm_pkru, sva, eva, ppr); if (error != 0) uma_zfree(pmap_pkru_ranges_zone, ppr); return (error); } static int pmap_pkru_deassign(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); MPASS(pmap->pm_type == PT_X86); MPASS((cpu_stdext_feature2 & CPUID_STDEXT2_PKU) != 0); return (rangeset_remove(&pmap->pm_pkru, sva, eva)); } static void pmap_pkru_deassign_all(pmap_t pmap) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); if (pmap->pm_type == PT_X86 && (cpu_stdext_feature2 & CPUID_STDEXT2_PKU) != 0) rangeset_remove_all(&pmap->pm_pkru); } static bool pmap_pkru_same(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { struct pmap_pkru_range *ppr, *prev_ppr; vm_offset_t va; PMAP_LOCK_ASSERT(pmap, MA_OWNED); if (pmap->pm_type != PT_X86 || (cpu_stdext_feature2 & CPUID_STDEXT2_PKU) == 0 || sva >= VM_MAXUSER_ADDRESS) return (true); MPASS(eva <= VM_MAXUSER_ADDRESS); for (va = sva; va < eva; prev_ppr = ppr) { ppr = rangeset_lookup(&pmap->pm_pkru, va); if (va == sva) prev_ppr = ppr; else if ((ppr == NULL) ^ (prev_ppr == NULL)) return (false); if (ppr == NULL) { va += PAGE_SIZE; continue; } if (prev_ppr->pkru_keyidx != ppr->pkru_keyidx) return (false); va = ppr->pkru_rs_el.re_end; } return (true); } static pt_entry_t pmap_pkru_get(pmap_t pmap, vm_offset_t va) { struct pmap_pkru_range *ppr; PMAP_LOCK_ASSERT(pmap, MA_OWNED); if (pmap->pm_type != PT_X86 || (cpu_stdext_feature2 & CPUID_STDEXT2_PKU) == 0 || va >= VM_MAXUSER_ADDRESS) return (0); ppr = rangeset_lookup(&pmap->pm_pkru, va); if (ppr != NULL) return (X86_PG_PKU(ppr->pkru_keyidx)); return (0); } static bool pred_pkru_on_remove(void *ctx __unused, void *r) { struct pmap_pkru_range *ppr; ppr = r; return ((ppr->pkru_flags & AMD64_PKRU_PERSIST) == 0); } static void pmap_pkru_on_remove(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); if (pmap->pm_type == PT_X86 && (cpu_stdext_feature2 & CPUID_STDEXT2_PKU) != 0) { rangeset_remove_pred(&pmap->pm_pkru, sva, eva, pred_pkru_on_remove); } } static int pmap_pkru_copy(pmap_t dst_pmap, pmap_t src_pmap) { PMAP_LOCK_ASSERT(dst_pmap, MA_OWNED); PMAP_LOCK_ASSERT(src_pmap, MA_OWNED); MPASS(dst_pmap->pm_type == PT_X86); MPASS(src_pmap->pm_type == PT_X86); MPASS((cpu_stdext_feature2 & CPUID_STDEXT2_PKU) != 0); if (src_pmap->pm_pkru.rs_data_ctx == NULL) return (0); return (rangeset_copy(&dst_pmap->pm_pkru, &src_pmap->pm_pkru)); } static void pmap_pkru_update_range(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, u_int keyidx) { pml4_entry_t *pml4e; pdp_entry_t *pdpe; pd_entry_t newpde, ptpaddr, *pde; pt_entry_t newpte, *ptep, pte; vm_offset_t va, va_next; bool changed; PMAP_LOCK_ASSERT(pmap, MA_OWNED); MPASS(pmap->pm_type == PT_X86); MPASS(keyidx <= PMAP_MAX_PKRU_IDX); for (changed = false, va = sva; va < eva; va = va_next) { pml4e = pmap_pml4e(pmap, va); if (pml4e == NULL || (*pml4e & X86_PG_V) == 0) { va_next = (va + NBPML4) & ~PML4MASK; if (va_next < va) va_next = eva; continue; } pdpe = pmap_pml4e_to_pdpe(pml4e, va); if ((*pdpe & X86_PG_V) == 0) { va_next = (va + NBPDP) & ~PDPMASK; if (va_next < va) va_next = eva; continue; } va_next = (va + NBPDR) & ~PDRMASK; if (va_next < va) va_next = eva; pde = pmap_pdpe_to_pde(pdpe, va); ptpaddr = *pde; if (ptpaddr == 0) continue; MPASS((ptpaddr & X86_PG_V) != 0); if ((ptpaddr & PG_PS) != 0) { if (va + NBPDR == va_next && eva >= va_next) { newpde = (ptpaddr & ~X86_PG_PKU_MASK) | X86_PG_PKU(keyidx); if (newpde != ptpaddr) { *pde = newpde; changed = true; } continue; } else if (!pmap_demote_pde(pmap, pde, va)) { continue; } } if (va_next > eva) va_next = eva; for (ptep = pmap_pde_to_pte(pde, va); va != va_next; ptep++, va += PAGE_SIZE) { pte = *ptep; if ((pte & X86_PG_V) == 0) continue; newpte = (pte & ~X86_PG_PKU_MASK) | X86_PG_PKU(keyidx); if (newpte != pte) { *ptep = newpte; changed = true; } } } if (changed) pmap_invalidate_range(pmap, sva, eva); } static int pmap_pkru_check_uargs(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, u_int keyidx, int flags) { if (pmap->pm_type != PT_X86 || keyidx > PMAP_MAX_PKRU_IDX || (flags & ~(AMD64_PKRU_PERSIST | AMD64_PKRU_EXCL)) != 0) return (EINVAL); if (eva <= sva || eva > VM_MAXUSER_ADDRESS) return (EFAULT); if ((cpu_stdext_feature2 & CPUID_STDEXT2_PKU) == 0) return (ENOTSUP); return (0); } int pmap_pkru_set(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, u_int keyidx, int flags) { int error; sva = trunc_page(sva); eva = round_page(eva); error = pmap_pkru_check_uargs(pmap, sva, eva, keyidx, flags); if (error != 0) return (error); for (;;) { PMAP_LOCK(pmap); error = pmap_pkru_assign(pmap, sva, eva, keyidx, flags); if (error == 0) pmap_pkru_update_range(pmap, sva, eva, keyidx); PMAP_UNLOCK(pmap); if (error != ENOMEM) break; vm_wait(NULL); } return (error); } int pmap_pkru_clear(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { int error; sva = trunc_page(sva); eva = round_page(eva); error = pmap_pkru_check_uargs(pmap, sva, eva, 0, 0); if (error != 0) return (error); for (;;) { PMAP_LOCK(pmap); error = pmap_pkru_deassign(pmap, sva, eva); if (error == 0) pmap_pkru_update_range(pmap, sva, eva, 0); PMAP_UNLOCK(pmap); if (error != ENOMEM) break; vm_wait(NULL); } return (error); } #if defined(KASAN) || defined(KMSAN) /* * Reserve enough memory to: * 1) allocate PDP pages for the shadow map(s), * 2) shadow the boot stack of KSTACK_PAGES pages, * so we need one PD page, one or two PT pages, and KSTACK_PAGES shadow pages * per shadow map. */ #ifdef KASAN #define SAN_EARLY_PAGES \ (NKASANPML4E + 1 + 2 + howmany(KSTACK_PAGES, KASAN_SHADOW_SCALE)) #else #define SAN_EARLY_PAGES \ (NKMSANSHADPML4E + NKMSANORIGPML4E + 2 * (1 + 2 + KSTACK_PAGES)) #endif static uint64_t __nosanitizeaddress __nosanitizememory pmap_san_enter_early_alloc_4k(uint64_t pabase) { static uint8_t data[PAGE_SIZE * SAN_EARLY_PAGES] __aligned(PAGE_SIZE); static size_t offset = 0; uint64_t pa; if (offset == sizeof(data)) { panic("%s: ran out of memory for the bootstrap shadow map", __func__); } pa = pabase + ((vm_offset_t)&data[offset] - KERNSTART); offset += PAGE_SIZE; return (pa); } /* * Map a shadow page, before the kernel has bootstrapped its page tables. This * is currently only used to shadow the temporary boot stack set up by locore. */ static void __nosanitizeaddress __nosanitizememory pmap_san_enter_early(vm_offset_t va) { static bool first = true; pml4_entry_t *pml4e; pdp_entry_t *pdpe; pd_entry_t *pde; pt_entry_t *pte; uint64_t cr3, pa, base; int i; base = amd64_loadaddr(); cr3 = rcr3(); if (first) { /* * If this the first call, we need to allocate new PML4Es for * the bootstrap shadow map(s). We don't know how the PML4 page * was initialized by the boot loader, so we can't simply test * whether the shadow map's PML4Es are zero. */ first = false; #ifdef KASAN for (i = 0; i < NKASANPML4E; i++) { pa = pmap_san_enter_early_alloc_4k(base); pml4e = (pml4_entry_t *)cr3 + pmap_pml4e_index(KASAN_MIN_ADDRESS + i * NBPML4); *pml4e = (pml4_entry_t)(pa | X86_PG_RW | X86_PG_V); } #else for (i = 0; i < NKMSANORIGPML4E; i++) { pa = pmap_san_enter_early_alloc_4k(base); pml4e = (pml4_entry_t *)cr3 + pmap_pml4e_index(KMSAN_ORIG_MIN_ADDRESS + i * NBPML4); *pml4e = (pml4_entry_t)(pa | X86_PG_RW | X86_PG_V); } for (i = 0; i < NKMSANSHADPML4E; i++) { pa = pmap_san_enter_early_alloc_4k(base); pml4e = (pml4_entry_t *)cr3 + pmap_pml4e_index(KMSAN_SHAD_MIN_ADDRESS + i * NBPML4); *pml4e = (pml4_entry_t)(pa | X86_PG_RW | X86_PG_V); } #endif } pml4e = (pml4_entry_t *)cr3 + pmap_pml4e_index(va); pdpe = (pdp_entry_t *)(*pml4e & PG_FRAME) + pmap_pdpe_index(va); if (*pdpe == 0) { pa = pmap_san_enter_early_alloc_4k(base); *pdpe = (pdp_entry_t)(pa | X86_PG_RW | X86_PG_V); } pde = (pd_entry_t *)(*pdpe & PG_FRAME) + pmap_pde_index(va); if (*pde == 0) { pa = pmap_san_enter_early_alloc_4k(base); *pde = (pd_entry_t)(pa | X86_PG_RW | X86_PG_V); } pte = (pt_entry_t *)(*pde & PG_FRAME) + pmap_pte_index(va); if (*pte != 0) panic("%s: PTE for %#lx is already initialized", __func__, va); pa = pmap_san_enter_early_alloc_4k(base); *pte = (pt_entry_t)(pa | X86_PG_A | X86_PG_M | X86_PG_RW | X86_PG_V); } static vm_page_t pmap_san_enter_alloc_4k(void) { vm_page_t m; m = vm_page_alloc_noobj(VM_ALLOC_INTERRUPT | VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (m == NULL) panic("%s: no memory to grow shadow map", __func__); return (m); } static vm_page_t pmap_san_enter_alloc_2m(void) { return (vm_page_alloc_noobj_contig(VM_ALLOC_WIRED | VM_ALLOC_ZERO, NPTEPG, 0, ~0ul, NBPDR, 0, VM_MEMATTR_DEFAULT)); } /* * Grow a shadow map by at least one 4KB page at the specified address. Use 2MB * pages when possible. */ void __nosanitizeaddress __nosanitizememory pmap_san_enter(vm_offset_t va) { pdp_entry_t *pdpe; pd_entry_t *pde; pt_entry_t *pte; vm_page_t m; if (kernphys == 0) { /* * We're creating a temporary shadow map for the boot stack. */ pmap_san_enter_early(va); return; } mtx_assert(&kernel_map->system_mtx, MA_OWNED); pdpe = pmap_pdpe(kernel_pmap, va); if ((*pdpe & X86_PG_V) == 0) { m = pmap_san_enter_alloc_4k(); *pdpe = (pdp_entry_t)(VM_PAGE_TO_PHYS(m) | X86_PG_RW | X86_PG_V | pg_nx); } pde = pmap_pdpe_to_pde(pdpe, va); if ((*pde & X86_PG_V) == 0) { m = pmap_san_enter_alloc_2m(); if (m != NULL) { *pde = (pd_entry_t)(VM_PAGE_TO_PHYS(m) | X86_PG_RW | X86_PG_PS | X86_PG_V | X86_PG_A | X86_PG_M | pg_nx); } else { m = pmap_san_enter_alloc_4k(); *pde = (pd_entry_t)(VM_PAGE_TO_PHYS(m) | X86_PG_RW | X86_PG_V | pg_nx); } } if ((*pde & X86_PG_PS) != 0) return; pte = pmap_pde_to_pte(pde, va); if ((*pte & X86_PG_V) != 0) return; m = pmap_san_enter_alloc_4k(); *pte = (pt_entry_t)(VM_PAGE_TO_PHYS(m) | X86_PG_RW | X86_PG_V | X86_PG_M | X86_PG_A | pg_nx); } #endif /* * Track a range of the kernel's virtual address space that is contiguous * in various mapping attributes. */ struct pmap_kernel_map_range { vm_offset_t sva; pt_entry_t attrs; int ptes; int pdes; int pdpes; }; static void sysctl_kmaps_dump(struct sbuf *sb, struct pmap_kernel_map_range *range, vm_offset_t eva) { const char *mode; int i, pat_idx; if (eva <= range->sva) return; pat_idx = pmap_pat_index(kernel_pmap, range->attrs, true); for (i = 0; i < PAT_INDEX_SIZE; i++) if (pat_index[i] == pat_idx) break; switch (i) { case PAT_WRITE_BACK: mode = "WB"; break; case PAT_WRITE_THROUGH: mode = "WT"; break; case PAT_UNCACHEABLE: mode = "UC"; break; case PAT_UNCACHED: mode = "U-"; break; case PAT_WRITE_PROTECTED: mode = "WP"; break; case PAT_WRITE_COMBINING: mode = "WC"; break; default: printf("%s: unknown PAT mode %#x for range 0x%016lx-0x%016lx\n", __func__, pat_idx, range->sva, eva); mode = "??"; break; } sbuf_printf(sb, "0x%016lx-0x%016lx r%c%c%c%c %s %d %d %d\n", range->sva, eva, (range->attrs & X86_PG_RW) != 0 ? 'w' : '-', (range->attrs & pg_nx) != 0 ? '-' : 'x', (range->attrs & X86_PG_U) != 0 ? 'u' : 's', (range->attrs & X86_PG_G) != 0 ? 'g' : '-', mode, range->pdpes, range->pdes, range->ptes); /* Reset to sentinel value. */ range->sva = la57 ? KV5ADDR(NPML5EPG - 1, NPML4EPG - 1, NPDPEPG - 1, NPDEPG - 1, NPTEPG - 1) : KV4ADDR(NPML4EPG - 1, NPDPEPG - 1, NPDEPG - 1, NPTEPG - 1); } /* * Determine whether the attributes specified by a page table entry match those * being tracked by the current range. This is not quite as simple as a direct * flag comparison since some PAT modes have multiple representations. */ static bool sysctl_kmaps_match(struct pmap_kernel_map_range *range, pt_entry_t attrs) { pt_entry_t diff, mask; mask = X86_PG_G | X86_PG_RW | X86_PG_U | X86_PG_PDE_CACHE | pg_nx; diff = (range->attrs ^ attrs) & mask; if (diff == 0) return (true); if ((diff & ~X86_PG_PDE_PAT) == 0 && pmap_pat_index(kernel_pmap, range->attrs, true) == pmap_pat_index(kernel_pmap, attrs, true)) return (true); return (false); } static void sysctl_kmaps_reinit(struct pmap_kernel_map_range *range, vm_offset_t va, pt_entry_t attrs) { memset(range, 0, sizeof(*range)); range->sva = va; range->attrs = attrs; } /* * Given a leaf PTE, derive the mapping's attributes. If they do not match * those of the current run, dump the address range and its attributes, and * begin a new run. */ static void sysctl_kmaps_check(struct sbuf *sb, struct pmap_kernel_map_range *range, vm_offset_t va, pml4_entry_t pml4e, pdp_entry_t pdpe, pd_entry_t pde, pt_entry_t pte) { pt_entry_t attrs; attrs = pml4e & (X86_PG_RW | X86_PG_U | pg_nx); attrs |= pdpe & pg_nx; attrs &= pg_nx | (pdpe & (X86_PG_RW | X86_PG_U)); if ((pdpe & PG_PS) != 0) { attrs |= pdpe & (X86_PG_G | X86_PG_PDE_CACHE); } else if (pde != 0) { attrs |= pde & pg_nx; attrs &= pg_nx | (pde & (X86_PG_RW | X86_PG_U)); } if ((pde & PG_PS) != 0) { attrs |= pde & (X86_PG_G | X86_PG_PDE_CACHE); } else if (pte != 0) { attrs |= pte & pg_nx; attrs &= pg_nx | (pte & (X86_PG_RW | X86_PG_U)); attrs |= pte & (X86_PG_G | X86_PG_PTE_CACHE); /* Canonicalize by always using the PDE PAT bit. */ if ((attrs & X86_PG_PTE_PAT) != 0) attrs ^= X86_PG_PDE_PAT | X86_PG_PTE_PAT; } if (range->sva > va || !sysctl_kmaps_match(range, attrs)) { sysctl_kmaps_dump(sb, range, va); sysctl_kmaps_reinit(range, va, attrs); } } static int sysctl_kmaps(SYSCTL_HANDLER_ARGS) { struct pmap_kernel_map_range range; struct sbuf sbuf, *sb; pml4_entry_t pml4e; pdp_entry_t *pdp, pdpe; pd_entry_t *pd, pde; pt_entry_t *pt, pte; vm_offset_t sva; vm_paddr_t pa; int error, i, j, k, l; error = sysctl_wire_old_buffer(req, 0); if (error != 0) return (error); sb = &sbuf; sbuf_new_for_sysctl(sb, NULL, PAGE_SIZE, req); /* Sentinel value. */ range.sva = la57 ? KV5ADDR(NPML5EPG - 1, NPML4EPG - 1, NPDPEPG - 1, NPDEPG - 1, NPTEPG - 1) : KV4ADDR(NPML4EPG - 1, NPDPEPG - 1, NPDEPG - 1, NPTEPG - 1); /* * Iterate over the kernel page tables without holding the kernel pmap * lock. Outside of the large map, kernel page table pages are never * freed, so at worst we will observe inconsistencies in the output. * Within the large map, ensure that PDP and PD page addresses are * valid before descending. */ for (sva = 0, i = pmap_pml4e_index(sva); i < NPML4EPG; i++) { switch (i) { case PML4PML4I: sbuf_printf(sb, "\nRecursive map:\n"); break; case DMPML4I: sbuf_printf(sb, "\nDirect map:\n"); break; #ifdef KASAN case KASANPML4I: sbuf_printf(sb, "\nKASAN shadow map:\n"); break; #endif #ifdef KMSAN case KMSANSHADPML4I: sbuf_printf(sb, "\nKMSAN shadow map:\n"); break; case KMSANORIGPML4I: sbuf_printf(sb, "\nKMSAN origin map:\n"); break; #endif case KPML4BASE: sbuf_printf(sb, "\nKernel map:\n"); break; case LMSPML4I: sbuf_printf(sb, "\nLarge map:\n"); break; } /* Convert to canonical form. */ if (sva == 1ul << 47) sva |= -1ul << 48; restart: pml4e = kernel_pml4[i]; if ((pml4e & X86_PG_V) == 0) { sva = rounddown2(sva, NBPML4); sysctl_kmaps_dump(sb, &range, sva); sva += NBPML4; continue; } pa = pml4e & PG_FRAME; pdp = (pdp_entry_t *)PHYS_TO_DMAP(pa); for (j = pmap_pdpe_index(sva); j < NPDPEPG; j++) { pdpe = pdp[j]; if ((pdpe & X86_PG_V) == 0) { sva = rounddown2(sva, NBPDP); sysctl_kmaps_dump(sb, &range, sva); sva += NBPDP; continue; } pa = pdpe & PG_FRAME; if ((pdpe & PG_PS) != 0) { sva = rounddown2(sva, NBPDP); sysctl_kmaps_check(sb, &range, sva, pml4e, pdpe, 0, 0); range.pdpes++; sva += NBPDP; continue; } if (PMAP_ADDRESS_IN_LARGEMAP(sva) && vm_phys_paddr_to_vm_page(pa) == NULL) { /* * Page table pages for the large map may be * freed. Validate the next-level address * before descending. */ goto restart; } pd = (pd_entry_t *)PHYS_TO_DMAP(pa); for (k = pmap_pde_index(sva); k < NPDEPG; k++) { pde = pd[k]; if ((pde & X86_PG_V) == 0) { sva = rounddown2(sva, NBPDR); sysctl_kmaps_dump(sb, &range, sva); sva += NBPDR; continue; } pa = pde & PG_FRAME; if ((pde & PG_PS) != 0) { sva = rounddown2(sva, NBPDR); sysctl_kmaps_check(sb, &range, sva, pml4e, pdpe, pde, 0); range.pdes++; sva += NBPDR; continue; } if (PMAP_ADDRESS_IN_LARGEMAP(sva) && vm_phys_paddr_to_vm_page(pa) == NULL) { /* * Page table pages for the large map * may be freed. Validate the * next-level address before descending. */ goto restart; } pt = (pt_entry_t *)PHYS_TO_DMAP(pa); for (l = pmap_pte_index(sva); l < NPTEPG; l++, sva += PAGE_SIZE) { pte = pt[l]; if ((pte & X86_PG_V) == 0) { sysctl_kmaps_dump(sb, &range, sva); continue; } sysctl_kmaps_check(sb, &range, sva, pml4e, pdpe, pde, pte); range.ptes++; } } } } error = sbuf_finish(sb); sbuf_delete(sb); return (error); } SYSCTL_OID(_vm_pmap, OID_AUTO, kernel_maps, CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE | CTLFLAG_SKIP, NULL, 0, sysctl_kmaps, "A", "Dump kernel address layout"); #ifdef DDB DB_SHOW_COMMAND(pte, pmap_print_pte) { pmap_t pmap; pml5_entry_t *pml5; pml4_entry_t *pml4; pdp_entry_t *pdp; pd_entry_t *pde; pt_entry_t *pte, PG_V; vm_offset_t va; if (!have_addr) { db_printf("show pte addr\n"); return; } va = (vm_offset_t)addr; if (kdb_thread != NULL) pmap = vmspace_pmap(kdb_thread->td_proc->p_vmspace); else pmap = PCPU_GET(curpmap); PG_V = pmap_valid_bit(pmap); db_printf("VA 0x%016lx", va); if (pmap_is_la57(pmap)) { pml5 = pmap_pml5e(pmap, va); db_printf(" pml5e 0x%016lx", *pml5); if ((*pml5 & PG_V) == 0) { db_printf("\n"); return; } pml4 = pmap_pml5e_to_pml4e(pml5, va); } else { pml4 = pmap_pml4e(pmap, va); } db_printf(" pml4e 0x%016lx", *pml4); if ((*pml4 & PG_V) == 0) { db_printf("\n"); return; } pdp = pmap_pml4e_to_pdpe(pml4, va); db_printf(" pdpe 0x%016lx", *pdp); if ((*pdp & PG_V) == 0 || (*pdp & PG_PS) != 0) { db_printf("\n"); return; } pde = pmap_pdpe_to_pde(pdp, va); db_printf(" pde 0x%016lx", *pde); if ((*pde & PG_V) == 0 || (*pde & PG_PS) != 0) { db_printf("\n"); return; } pte = pmap_pde_to_pte(pde, va); db_printf(" pte 0x%016lx\n", *pte); } DB_SHOW_COMMAND(phys2dmap, pmap_phys2dmap) { vm_paddr_t a; if (have_addr) { a = (vm_paddr_t)addr; db_printf("0x%jx\n", (uintmax_t)PHYS_TO_DMAP(a)); } else { db_printf("show phys2dmap addr\n"); } } static void ptpages_show_page(int level, int idx, vm_page_t pg) { db_printf("l %d i %d pg %p phys %#lx ref %x\n", level, idx, pg, VM_PAGE_TO_PHYS(pg), pg->ref_count); } static void ptpages_show_complain(int level, int idx, uint64_t pte) { db_printf("l %d i %d pte %#lx\n", level, idx, pte); } static void ptpages_show_pml4(vm_page_t pg4, int num_entries, uint64_t PG_V) { vm_page_t pg3, pg2, pg1; pml4_entry_t *pml4; pdp_entry_t *pdp; pd_entry_t *pd; int i4, i3, i2; pml4 = (pml4_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(pg4)); for (i4 = 0; i4 < num_entries; i4++) { if ((pml4[i4] & PG_V) == 0) continue; pg3 = PHYS_TO_VM_PAGE(pml4[i4] & PG_FRAME); if (pg3 == NULL) { ptpages_show_complain(3, i4, pml4[i4]); continue; } ptpages_show_page(3, i4, pg3); pdp = (pdp_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(pg3)); for (i3 = 0; i3 < NPDPEPG; i3++) { if ((pdp[i3] & PG_V) == 0) continue; pg2 = PHYS_TO_VM_PAGE(pdp[i3] & PG_FRAME); if (pg3 == NULL) { ptpages_show_complain(2, i3, pdp[i3]); continue; } ptpages_show_page(2, i3, pg2); pd = (pd_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(pg2)); for (i2 = 0; i2 < NPDEPG; i2++) { if ((pd[i2] & PG_V) == 0) continue; pg1 = PHYS_TO_VM_PAGE(pd[i2] & PG_FRAME); if (pg1 == NULL) { ptpages_show_complain(1, i2, pd[i2]); continue; } ptpages_show_page(1, i2, pg1); } } } } DB_SHOW_COMMAND(ptpages, pmap_ptpages) { pmap_t pmap; vm_page_t pg; pml5_entry_t *pml5; uint64_t PG_V; int i5; if (have_addr) pmap = (pmap_t)addr; else pmap = PCPU_GET(curpmap); PG_V = pmap_valid_bit(pmap); if (pmap_is_la57(pmap)) { pml5 = pmap->pm_pmltop; for (i5 = 0; i5 < NUPML5E; i5++) { if ((pml5[i5] & PG_V) == 0) continue; pg = PHYS_TO_VM_PAGE(pml5[i5] & PG_FRAME); if (pg == NULL) { ptpages_show_complain(4, i5, pml5[i5]); continue; } ptpages_show_page(4, i5, pg); ptpages_show_pml4(pg, NPML4EPG, PG_V); } } else { ptpages_show_pml4(PHYS_TO_VM_PAGE(DMAP_TO_PHYS( (vm_offset_t)pmap->pm_pmltop)), NUP4ML4E, PG_V); } } #endif diff --git a/sys/arm/arm/pmap-v6.c b/sys/arm/arm/pmap-v6.c index 5aa8eb169cad..719851432203 100644 --- a/sys/arm/arm/pmap-v6.c +++ b/sys/arm/arm/pmap-v6.c @@ -1,6935 +1,6941 @@ /*- * SPDX-License-Identifier: BSD-3-Clause AND BSD-2-Clause * * Copyright (c) 1991 Regents of the University of California. * Copyright (c) 1994 John S. Dyson * Copyright (c) 1994 David Greenman * Copyright (c) 2005-2010 Alan L. Cox * Copyright (c) 2014-2016 Svatopluk Kraus * Copyright (c) 2014-2016 Michal Meloun * All rights reserved. * * This code is derived from software contributed to Berkeley by * the Systems Programming Group of the University of Utah Computer * Science Department and William Jolitz of UUNET Technologies Inc. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * from: @(#)pmap.c 7.7 (Berkeley) 5/12/91 */ /*- * Copyright (c) 2003 Networks Associates Technology, Inc. * All rights reserved. * * This software was developed for the FreeBSD Project by Jake Burkholder, * Safeport Network Services, and Network Associates Laboratories, the * Security Research Division of Network Associates, Inc. under * DARPA/SPAWAR contract N66001-01-C-8035 ("CBOSS"), as part of the DARPA * CHATS research program. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include /* * Manages physical address maps. * * Since the information managed by this module is * also stored by the logical address mapping module, * this module may throw away valid virtual-to-physical * mappings at almost any time. However, invalidations * of virtual-to-physical mappings must be done as * requested. * * In order to cope with hardware architectures which * make virtual-to-physical map invalidates expensive, * this module may delay invalidate or reduced protection * operations until such time as they are actually * necessary. This module is given full information as * to which processors are currently using which maps, * and to when physical maps must be made correct. */ #include "opt_vm.h" #include "opt_pmap.h" #include "opt_ddb.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef DDB #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef SMP #include #endif #ifndef PMAP_SHPGPERPROC #define PMAP_SHPGPERPROC 200 #endif #ifndef DIAGNOSTIC #define PMAP_INLINE __inline #else #define PMAP_INLINE #endif #ifdef PMAP_DEBUG static void pmap_zero_page_check(vm_page_t m); void pmap_debug(int level); int pmap_pid_dump(int pid); #define PDEBUG(_lev_,_stat_) \ if (pmap_debug_level >= (_lev_)) \ ((_stat_)) #define dprintf printf int pmap_debug_level = 1; #else /* PMAP_DEBUG */ #define PDEBUG(_lev_,_stat_) /* Nothing */ #define dprintf(x, arg...) #endif /* PMAP_DEBUG */ /* * Level 2 page tables map definion ('max' is excluded). */ #define PT2V_MIN_ADDRESS ((vm_offset_t)PT2MAP) #define PT2V_MAX_ADDRESS ((vm_offset_t)PT2MAP + PT2MAP_SIZE) #define UPT2V_MIN_ADDRESS ((vm_offset_t)PT2MAP) #define UPT2V_MAX_ADDRESS \ ((vm_offset_t)(PT2MAP + (KERNBASE >> PT2MAP_SHIFT))) /* * Promotion to a 1MB (PTE1) page mapping requires that the corresponding * 4KB (PTE2) page mappings have identical settings for the following fields: */ #define PTE2_PROMOTE (PTE2_V | PTE2_A | PTE2_NM | PTE2_S | PTE2_NG | \ PTE2_NX | PTE2_RO | PTE2_U | PTE2_W | \ PTE2_ATTR_MASK) #define PTE1_PROMOTE (PTE1_V | PTE1_A | PTE1_NM | PTE1_S | PTE1_NG | \ PTE1_NX | PTE1_RO | PTE1_U | PTE1_W | \ PTE1_ATTR_MASK) #define ATTR_TO_L1(l2_attr) ((((l2_attr) & L2_TEX0) ? L1_S_TEX0 : 0) | \ (((l2_attr) & L2_C) ? L1_S_C : 0) | \ (((l2_attr) & L2_B) ? L1_S_B : 0) | \ (((l2_attr) & PTE2_A) ? PTE1_A : 0) | \ (((l2_attr) & PTE2_NM) ? PTE1_NM : 0) | \ (((l2_attr) & PTE2_S) ? PTE1_S : 0) | \ (((l2_attr) & PTE2_NG) ? PTE1_NG : 0) | \ (((l2_attr) & PTE2_NX) ? PTE1_NX : 0) | \ (((l2_attr) & PTE2_RO) ? PTE1_RO : 0) | \ (((l2_attr) & PTE2_U) ? PTE1_U : 0) | \ (((l2_attr) & PTE2_W) ? PTE1_W : 0)) #define ATTR_TO_L2(l1_attr) ((((l1_attr) & L1_S_TEX0) ? L2_TEX0 : 0) | \ (((l1_attr) & L1_S_C) ? L2_C : 0) | \ (((l1_attr) & L1_S_B) ? L2_B : 0) | \ (((l1_attr) & PTE1_A) ? PTE2_A : 0) | \ (((l1_attr) & PTE1_NM) ? PTE2_NM : 0) | \ (((l1_attr) & PTE1_S) ? PTE2_S : 0) | \ (((l1_attr) & PTE1_NG) ? PTE2_NG : 0) | \ (((l1_attr) & PTE1_NX) ? PTE2_NX : 0) | \ (((l1_attr) & PTE1_RO) ? PTE2_RO : 0) | \ (((l1_attr) & PTE1_U) ? PTE2_U : 0) | \ (((l1_attr) & PTE1_W) ? PTE2_W : 0)) /* * PTE2 descriptors creation macros. */ #define PTE2_ATTR_DEFAULT vm_memattr_to_pte2(VM_MEMATTR_DEFAULT) #define PTE2_ATTR_PT vm_memattr_to_pte2(pt_memattr) #define PTE2_KPT(pa) PTE2_KERN(pa, PTE2_AP_KRW, PTE2_ATTR_PT) #define PTE2_KPT_NG(pa) PTE2_KERN_NG(pa, PTE2_AP_KRW, PTE2_ATTR_PT) #define PTE2_KRW(pa) PTE2_KERN(pa, PTE2_AP_KRW, PTE2_ATTR_DEFAULT) #define PTE2_KRO(pa) PTE2_KERN(pa, PTE2_AP_KR, PTE2_ATTR_DEFAULT) #define PV_STATS #ifdef PV_STATS #define PV_STAT(x) do { x ; } while (0) #else #define PV_STAT(x) do { } while (0) #endif /* * The boot_pt1 is used temporary in very early boot stage as L1 page table. * We can init many things with no memory allocation thanks to its static * allocation and this brings two main advantages: * (1) other cores can be started very simply, * (2) various boot loaders can be supported as its arguments can be processed * in virtual address space and can be moved to safe location before * first allocation happened. * Only disadvantage is that boot_pt1 is used only in very early boot stage. * However, the table is uninitialized and so lays in bss. Therefore kernel * image size is not influenced. * * QQQ: In the future, maybe, boot_pt1 can be used for soft reset and * CPU suspend/resume game. */ extern pt1_entry_t boot_pt1[]; vm_paddr_t base_pt1; pt1_entry_t *kern_pt1; pt2_entry_t *kern_pt2tab; pt2_entry_t *PT2MAP; static uint32_t ttb_flags; static vm_memattr_t pt_memattr; ttb_entry_t pmap_kern_ttb; struct pmap kernel_pmap_store; LIST_HEAD(pmaplist, pmap); static struct pmaplist allpmaps; static struct mtx allpmaps_lock; vm_offset_t virtual_avail; /* VA of first avail page (after kernel bss) */ vm_offset_t virtual_end; /* VA of last avail page (end of kernel AS) */ static vm_offset_t kernel_vm_end_new; vm_offset_t kernel_vm_end = KERNBASE + NKPT2PG * NPT2_IN_PG * PTE1_SIZE; vm_offset_t vm_max_kernel_address; vm_paddr_t kernel_l1pa; static struct rwlock __aligned(CACHE_LINE_SIZE) pvh_global_lock; /* * Data for the pv entry allocation mechanism */ static TAILQ_HEAD(pch, pv_chunk) pv_chunks = TAILQ_HEAD_INITIALIZER(pv_chunks); static int pv_entry_count = 0, pv_entry_max = 0, pv_entry_high_water = 0; static struct md_page *pv_table; /* XXX: Is it used only the list in md_page? */ static int shpgperproc = PMAP_SHPGPERPROC; struct pv_chunk *pv_chunkbase; /* KVA block for pv_chunks */ int pv_maxchunks; /* How many chunks we have KVA for */ vm_offset_t pv_vafree; /* freelist stored in the PTE */ vm_paddr_t first_managed_pa; #define pa_to_pvh(pa) (&pv_table[pte1_index(pa - first_managed_pa)]) /* * All those kernel PT submaps that BSD is so fond of */ caddr_t _tmppt = 0; /* * Crashdump maps. */ static caddr_t crashdumpmap; static pt2_entry_t *PMAP1 = NULL, *PMAP2; static pt2_entry_t *PADDR1 = NULL, *PADDR2; #ifdef DDB static pt2_entry_t *PMAP3; static pt2_entry_t *PADDR3; static int PMAP3cpu __unused; /* for SMP only */ #endif #ifdef SMP static int PMAP1cpu; static int PMAP1changedcpu; SYSCTL_INT(_debug, OID_AUTO, PMAP1changedcpu, CTLFLAG_RD, &PMAP1changedcpu, 0, "Number of times pmap_pte2_quick changed CPU with same PMAP1"); #endif static int PMAP1changed; SYSCTL_INT(_debug, OID_AUTO, PMAP1changed, CTLFLAG_RD, &PMAP1changed, 0, "Number of times pmap_pte2_quick changed PMAP1"); static int PMAP1unchanged; SYSCTL_INT(_debug, OID_AUTO, PMAP1unchanged, CTLFLAG_RD, &PMAP1unchanged, 0, "Number of times pmap_pte2_quick didn't change PMAP1"); static struct mtx PMAP2mutex; /* * Internal flags for pmap_enter()'s helper functions. */ #define PMAP_ENTER_NORECLAIM 0x1000000 /* Don't reclaim PV entries. */ #define PMAP_ENTER_NOREPLACE 0x2000000 /* Don't replace mappings. */ static __inline void pt2_wirecount_init(vm_page_t m); static boolean_t pmap_demote_pte1(pmap_t pmap, pt1_entry_t *pte1p, vm_offset_t va); static int pmap_enter_pte1(pmap_t pmap, vm_offset_t va, pt1_entry_t pte1, u_int flags, vm_page_t m); void cache_icache_sync_fresh(vm_offset_t va, vm_paddr_t pa, vm_size_t size); /* * Function to set the debug level of the pmap code. */ #ifdef PMAP_DEBUG void pmap_debug(int level) { pmap_debug_level = level; dprintf("pmap_debug: level=%d\n", pmap_debug_level); } #endif /* PMAP_DEBUG */ /* * This table must corespond with memory attribute configuration in vm.h. * First entry is used for normal system mapping. * * Device memory is always marked as shared. * Normal memory is shared only in SMP . * Not outer shareable bits are not used yet. * Class 6 cannot be used on ARM11. */ #define TEXDEF_TYPE_SHIFT 0 #define TEXDEF_TYPE_MASK 0x3 #define TEXDEF_INNER_SHIFT 2 #define TEXDEF_INNER_MASK 0x3 #define TEXDEF_OUTER_SHIFT 4 #define TEXDEF_OUTER_MASK 0x3 #define TEXDEF_NOS_SHIFT 6 #define TEXDEF_NOS_MASK 0x1 #define TEX(t, i, o, s) \ ((t) << TEXDEF_TYPE_SHIFT) | \ ((i) << TEXDEF_INNER_SHIFT) | \ ((o) << TEXDEF_OUTER_SHIFT | \ ((s) << TEXDEF_NOS_SHIFT)) static uint32_t tex_class[8] = { /* type inner cache outer cache */ TEX(PRRR_MEM, NMRR_WB_WA, NMRR_WB_WA, 0), /* 0 - ATTR_WB_WA */ TEX(PRRR_MEM, NMRR_NC, NMRR_NC, 0), /* 1 - ATTR_NOCACHE */ TEX(PRRR_DEV, NMRR_NC, NMRR_NC, 0), /* 2 - ATTR_DEVICE */ TEX(PRRR_SO, NMRR_NC, NMRR_NC, 0), /* 3 - ATTR_SO */ TEX(PRRR_MEM, NMRR_WT, NMRR_WT, 0), /* 4 - ATTR_WT */ TEX(PRRR_MEM, NMRR_NC, NMRR_NC, 0), /* 5 - NOT USED YET */ TEX(PRRR_MEM, NMRR_NC, NMRR_NC, 0), /* 6 - NOT USED YET */ TEX(PRRR_MEM, NMRR_NC, NMRR_NC, 0), /* 7 - NOT USED YET */ }; #undef TEX static uint32_t pte2_attr_tab[8] = { PTE2_ATTR_WB_WA, /* 0 - VM_MEMATTR_WB_WA */ PTE2_ATTR_NOCACHE, /* 1 - VM_MEMATTR_NOCACHE */ PTE2_ATTR_DEVICE, /* 2 - VM_MEMATTR_DEVICE */ PTE2_ATTR_SO, /* 3 - VM_MEMATTR_SO */ PTE2_ATTR_WT, /* 4 - VM_MEMATTR_WRITE_THROUGH */ 0, /* 5 - NOT USED YET */ 0, /* 6 - NOT USED YET */ 0 /* 7 - NOT USED YET */ }; CTASSERT(VM_MEMATTR_WB_WA == 0); CTASSERT(VM_MEMATTR_NOCACHE == 1); CTASSERT(VM_MEMATTR_DEVICE == 2); CTASSERT(VM_MEMATTR_SO == 3); CTASSERT(VM_MEMATTR_WRITE_THROUGH == 4); #define VM_MEMATTR_END (VM_MEMATTR_WRITE_THROUGH + 1) boolean_t pmap_is_valid_memattr(pmap_t pmap __unused, vm_memattr_t mode) { return (mode >= 0 && mode < VM_MEMATTR_END); } static inline uint32_t vm_memattr_to_pte2(vm_memattr_t ma) { KASSERT((u_int)ma < VM_MEMATTR_END, ("%s: bad vm_memattr_t %d", __func__, ma)); return (pte2_attr_tab[(u_int)ma]); } static inline uint32_t vm_page_pte2_attr(vm_page_t m) { return (vm_memattr_to_pte2(m->md.pat_mode)); } /* * Convert TEX definition entry to TTB flags. */ static uint32_t encode_ttb_flags(int idx) { uint32_t inner, outer, nos, reg; inner = (tex_class[idx] >> TEXDEF_INNER_SHIFT) & TEXDEF_INNER_MASK; outer = (tex_class[idx] >> TEXDEF_OUTER_SHIFT) & TEXDEF_OUTER_MASK; nos = (tex_class[idx] >> TEXDEF_NOS_SHIFT) & TEXDEF_NOS_MASK; reg = nos << 5; reg |= outer << 3; if (cpuinfo.coherent_walk) reg |= (inner & 0x1) << 6; reg |= (inner & 0x2) >> 1; #ifdef SMP ARM_SMP_UP( reg |= 1 << 1, ); #endif return reg; } /* * Set TEX remapping registers in current CPU. */ void pmap_set_tex(void) { uint32_t prrr, nmrr; uint32_t type, inner, outer, nos; int i; #ifdef PMAP_PTE_NOCACHE /* XXX fixme */ if (cpuinfo.coherent_walk) { pt_memattr = VM_MEMATTR_WB_WA; ttb_flags = encode_ttb_flags(0); } else { pt_memattr = VM_MEMATTR_NOCACHE; ttb_flags = encode_ttb_flags(1); } #else pt_memattr = VM_MEMATTR_WB_WA; ttb_flags = encode_ttb_flags(0); #endif prrr = 0; nmrr = 0; /* Build remapping register from TEX classes. */ for (i = 0; i < 8; i++) { type = (tex_class[i] >> TEXDEF_TYPE_SHIFT) & TEXDEF_TYPE_MASK; inner = (tex_class[i] >> TEXDEF_INNER_SHIFT) & TEXDEF_INNER_MASK; outer = (tex_class[i] >> TEXDEF_OUTER_SHIFT) & TEXDEF_OUTER_MASK; nos = (tex_class[i] >> TEXDEF_NOS_SHIFT) & TEXDEF_NOS_MASK; prrr |= type << (i * 2); prrr |= nos << (i + 24); nmrr |= inner << (i * 2); nmrr |= outer << (i * 2 + 16); } /* Add shareable bits for device memory. */ prrr |= PRRR_DS0 | PRRR_DS1; /* Add shareable bits for normal memory in SMP case. */ #ifdef SMP ARM_SMP_UP( prrr |= PRRR_NS1, ); #endif cp15_prrr_set(prrr); cp15_nmrr_set(nmrr); /* Caches are disabled, so full TLB flush should be enough. */ tlb_flush_all_local(); } /* * Remap one vm_meattr class to another one. This can be useful as * workaround for SOC errata, e.g. if devices must be accessed using * SO memory class. * * !!! Please note that this function is absolutely last resort thing. * It should not be used under normal circumstances. !!! * * Usage rules: * - it shall be called after pmap_bootstrap_prepare() and before * cpu_mp_start() (thus only on boot CPU). In practice, it's expected * to be called from platform_attach() or platform_late_init(). * * - if remapping doesn't change caching mode, or until uncached class * is remapped to any kind of cached one, then no other restriction exists. * * - if pmap_remap_vm_attr() changes caching mode, but both (original and * remapped) remain cached, then caller is resposible for calling * of dcache_wbinv_poc_all(). * * - remapping of any kind of cached class to uncached is not permitted. */ void pmap_remap_vm_attr(vm_memattr_t old_attr, vm_memattr_t new_attr) { int old_idx, new_idx; /* Map VM memattrs to indexes to tex_class table. */ old_idx = PTE2_ATTR2IDX(pte2_attr_tab[(int)old_attr]); new_idx = PTE2_ATTR2IDX(pte2_attr_tab[(int)new_attr]); /* Replace TEX attribute and apply it. */ tex_class[old_idx] = tex_class[new_idx]; pmap_set_tex(); } /* * KERNBASE must be multiple of NPT2_IN_PG * PTE1_SIZE. In other words, * KERNBASE is mapped by first L2 page table in L2 page table page. It * meets same constrain due to PT2MAP being placed just under KERNBASE. */ CTASSERT((KERNBASE & (NPT2_IN_PG * PTE1_SIZE - 1)) == 0); CTASSERT((KERNBASE - VM_MAXUSER_ADDRESS) >= PT2MAP_SIZE); /* * In crazy dreams, PAGE_SIZE could be a multiple of PTE2_SIZE in general. * For now, anyhow, the following check must be fulfilled. */ CTASSERT(PAGE_SIZE == PTE2_SIZE); /* * We don't want to mess up MI code with all MMU and PMAP definitions, * so some things, which depend on other ones, are defined independently. * Now, it is time to check that we don't screw up something. */ CTASSERT(PDRSHIFT == PTE1_SHIFT); /* * Check L1 and L2 page table entries definitions consistency. */ CTASSERT(NB_IN_PT1 == (sizeof(pt1_entry_t) * NPTE1_IN_PT1)); CTASSERT(NB_IN_PT2 == (sizeof(pt2_entry_t) * NPTE2_IN_PT2)); /* * Check L2 page tables page consistency. */ CTASSERT(PAGE_SIZE == (NPT2_IN_PG * NB_IN_PT2)); CTASSERT((1 << PT2PG_SHIFT) == NPT2_IN_PG); /* * Check PT2TAB consistency. * PT2TAB_ENTRIES is defined as a division of NPTE1_IN_PT1 by NPT2_IN_PG. * This should be done without remainder. */ CTASSERT(NPTE1_IN_PT1 == (PT2TAB_ENTRIES * NPT2_IN_PG)); /* * A PT2MAP magic. * * All level 2 page tables (PT2s) are mapped continuously and accordingly * into PT2MAP address space. As PT2 size is less than PAGE_SIZE, this can * be done only if PAGE_SIZE is a multiple of PT2 size. All PT2s in one page * must be used together, but not necessary at once. The first PT2 in a page * must map things on correctly aligned address and the others must follow * in right order. */ #define NB_IN_PT2TAB (PT2TAB_ENTRIES * sizeof(pt2_entry_t)) #define NPT2_IN_PT2TAB (NB_IN_PT2TAB / NB_IN_PT2) #define NPG_IN_PT2TAB (NB_IN_PT2TAB / PAGE_SIZE) /* * Check PT2TAB consistency. * NPT2_IN_PT2TAB is defined as a division of NB_IN_PT2TAB by NB_IN_PT2. * NPG_IN_PT2TAB is defined as a division of NB_IN_PT2TAB by PAGE_SIZE. * The both should be done without remainder. */ CTASSERT(NB_IN_PT2TAB == (NPT2_IN_PT2TAB * NB_IN_PT2)); CTASSERT(NB_IN_PT2TAB == (NPG_IN_PT2TAB * PAGE_SIZE)); /* * The implementation was made general, however, with the assumption * bellow in mind. In case of another value of NPG_IN_PT2TAB, * the code should be once more rechecked. */ CTASSERT(NPG_IN_PT2TAB == 1); /* * Get offset of PT2 in a page * associated with given PT1 index. */ static __inline u_int page_pt2off(u_int pt1_idx) { return ((pt1_idx & PT2PG_MASK) * NB_IN_PT2); } /* * Get physical address of PT2 * associated with given PT2s page and PT1 index. */ static __inline vm_paddr_t page_pt2pa(vm_paddr_t pgpa, u_int pt1_idx) { return (pgpa + page_pt2off(pt1_idx)); } /* * Get first entry of PT2 * associated with given PT2s page and PT1 index. */ static __inline pt2_entry_t * page_pt2(vm_offset_t pgva, u_int pt1_idx) { return ((pt2_entry_t *)(pgva + page_pt2off(pt1_idx))); } /* * Get virtual address of PT2s page (mapped in PT2MAP) * which holds PT2 which holds entry which maps given virtual address. */ static __inline vm_offset_t pt2map_pt2pg(vm_offset_t va) { va &= ~(NPT2_IN_PG * PTE1_SIZE - 1); return ((vm_offset_t)pt2map_entry(va)); } /***************************************************************************** * * THREE pmap initialization milestones exist: * * locore.S * -> fundamental init (including MMU) in ASM * * initarm() * -> fundamental init continues in C * -> first available physical address is known * * pmap_bootstrap_prepare() -> FIRST PMAP MILESTONE (first epoch begins) * -> basic (safe) interface for physical address allocation is made * -> basic (safe) interface for virtual mapping is made * -> limited not SMP coherent work is possible * * -> more fundamental init continues in C * -> locks and some more things are available * -> all fundamental allocations and mappings are done * * pmap_bootstrap() -> SECOND PMAP MILESTONE (second epoch begins) * -> phys_avail[] and virtual_avail is set * -> control is passed to vm subsystem * -> physical and virtual address allocation are off limit * -> low level mapping functions, some SMP coherent, * are available, which cannot be used before vm subsystem * is being inited * * mi_startup() * -> vm subsystem is being inited * * pmap_init() -> THIRD PMAP MILESTONE (third epoch begins) * -> pmap is fully inited * *****************************************************************************/ /***************************************************************************** * * PMAP first stage initialization and utility functions * for pre-bootstrap epoch. * * After pmap_bootstrap_prepare() is called, the following functions * can be used: * * (1) strictly only for this stage functions for physical page allocations, * virtual space allocations, and mappings: * * vm_paddr_t pmap_preboot_get_pages(u_int num); * void pmap_preboot_map_pages(vm_paddr_t pa, vm_offset_t va, u_int num); * vm_offset_t pmap_preboot_reserve_pages(u_int num); * vm_offset_t pmap_preboot_get_vpages(u_int num); * void pmap_preboot_map_attr(vm_paddr_t pa, vm_offset_t va, vm_size_t size, * vm_prot_t prot, vm_memattr_t attr); * * (2) for all stages: * * vm_paddr_t pmap_kextract(vm_offset_t va); * * NOTE: This is not SMP coherent stage. * *****************************************************************************/ #define KERNEL_P2V(pa) \ ((vm_offset_t)((pa) - arm_physmem_kernaddr + KERNVIRTADDR)) #define KERNEL_V2P(va) \ ((vm_paddr_t)((va) - KERNVIRTADDR + arm_physmem_kernaddr)) static vm_paddr_t last_paddr; /* * Pre-bootstrap epoch page allocator. */ vm_paddr_t pmap_preboot_get_pages(u_int num) { vm_paddr_t ret; ret = last_paddr; last_paddr += num * PAGE_SIZE; return (ret); } /* * The fundamental initialization of PMAP stuff. * * Some things already happened in locore.S and some things could happen * before pmap_bootstrap_prepare() is called, so let's recall what is done: * 1. Caches are disabled. * 2. We are running on virtual addresses already with 'boot_pt1' * as L1 page table. * 3. So far, all virtual addresses can be converted to physical ones and * vice versa by the following macros: * KERNEL_P2V(pa) .... physical to virtual ones, * KERNEL_V2P(va) .... virtual to physical ones. * * What is done herein: * 1. The 'boot_pt1' is replaced by real kernel L1 page table 'kern_pt1'. * 2. PT2MAP magic is brought to live. * 3. Basic preboot functions for page allocations and mappings can be used. * 4. Everything is prepared for L1 cache enabling. * * Variations: * 1. To use second TTB register, so kernel and users page tables will be * separated. This way process forking - pmap_pinit() - could be faster, * it saves physical pages and KVA per a process, and it's simple change. * However, it will lead, due to hardware matter, to the following: * (a) 2G space for kernel and 2G space for users. * (b) 1G space for kernel in low addresses and 3G for users above it. * A question is: Is the case (b) really an option? Note that case (b) * does save neither physical memory and KVA. */ void pmap_bootstrap_prepare(vm_paddr_t last) { vm_paddr_t pt2pg_pa, pt2tab_pa, pa, size; vm_offset_t pt2pg_va; pt1_entry_t *pte1p; pt2_entry_t *pte2p; u_int i; uint32_t l1_attr; /* * Now, we are going to make real kernel mapping. Note that we are * already running on some mapping made in locore.S and we expect * that it's large enough to ensure nofault access to physical memory * allocated herein before switch. * * As kernel image and everything needed before are and will be mapped * by section mappings, we align last physical address to PTE1_SIZE. */ last_paddr = pte1_roundup(last); /* * Allocate and zero page(s) for kernel L1 page table. * * Note that it's first allocation on space which was PTE1_SIZE * aligned and as such base_pt1 is aligned to NB_IN_PT1 too. */ base_pt1 = pmap_preboot_get_pages(NPG_IN_PT1); kern_pt1 = (pt1_entry_t *)KERNEL_P2V(base_pt1); bzero((void*)kern_pt1, NB_IN_PT1); pte1_sync_range(kern_pt1, NB_IN_PT1); /* Allocate and zero page(s) for kernel PT2TAB. */ pt2tab_pa = pmap_preboot_get_pages(NPG_IN_PT2TAB); kern_pt2tab = (pt2_entry_t *)KERNEL_P2V(pt2tab_pa); bzero(kern_pt2tab, NB_IN_PT2TAB); pte2_sync_range(kern_pt2tab, NB_IN_PT2TAB); /* Allocate and zero page(s) for kernel L2 page tables. */ pt2pg_pa = pmap_preboot_get_pages(NKPT2PG); pt2pg_va = KERNEL_P2V(pt2pg_pa); size = NKPT2PG * PAGE_SIZE; bzero((void*)pt2pg_va, size); pte2_sync_range((pt2_entry_t *)pt2pg_va, size); /* * Add a physical memory segment (vm_phys_seg) corresponding to the * preallocated pages for kernel L2 page tables so that vm_page * structures representing these pages will be created. The vm_page * structures are required for promotion of the corresponding kernel * virtual addresses to section mappings. */ vm_phys_add_seg(pt2tab_pa, pmap_preboot_get_pages(0)); /* * Insert allocated L2 page table pages to PT2TAB and make * link to all PT2s in L1 page table. See how kernel_vm_end * is initialized. * * We play simple and safe. So every KVA will have underlaying * L2 page table, even kernel image mapped by sections. */ pte2p = kern_pt2tab_entry(KERNBASE); for (pa = pt2pg_pa; pa < pt2pg_pa + size; pa += PTE2_SIZE) pt2tab_store(pte2p++, PTE2_KPT(pa)); pte1p = kern_pte1(KERNBASE); for (pa = pt2pg_pa; pa < pt2pg_pa + size; pa += NB_IN_PT2) pte1_store(pte1p++, PTE1_LINK(pa)); /* Make section mappings for kernel. */ l1_attr = ATTR_TO_L1(PTE2_ATTR_DEFAULT); pte1p = kern_pte1(KERNBASE); for (pa = KERNEL_V2P(KERNBASE); pa < last; pa += PTE1_SIZE) pte1_store(pte1p++, PTE1_KERN(pa, PTE1_AP_KRW, l1_attr)); /* * Get free and aligned space for PT2MAP and make L1 page table links * to L2 page tables held in PT2TAB. * * Note that pages holding PT2s are stored in PT2TAB as pt2_entry_t * descriptors and PT2TAB page(s) itself is(are) used as PT2s. Thus * each entry in PT2TAB maps all PT2s in a page. This implies that * virtual address of PT2MAP must be aligned to NPT2_IN_PG * PTE1_SIZE. */ PT2MAP = (pt2_entry_t *)(KERNBASE - PT2MAP_SIZE); pte1p = kern_pte1((vm_offset_t)PT2MAP); for (pa = pt2tab_pa, i = 0; i < NPT2_IN_PT2TAB; i++, pa += NB_IN_PT2) { pte1_store(pte1p++, PTE1_LINK(pa)); } /* * Store PT2TAB in PT2TAB itself, i.e. self reference mapping. * Each pmap will hold own PT2TAB, so the mapping should be not global. */ pte2p = kern_pt2tab_entry((vm_offset_t)PT2MAP); for (pa = pt2tab_pa, i = 0; i < NPG_IN_PT2TAB; i++, pa += PTE2_SIZE) { pt2tab_store(pte2p++, PTE2_KPT_NG(pa)); } /* * Choose correct L2 page table and make mappings for allocations * made herein which replaces temporary locore.S mappings after a while. * Note that PT2MAP cannot be used until we switch to kern_pt1. * * Note, that these allocations started aligned on 1M section and * kernel PT1 was allocated first. Making of mappings must follow * order of physical allocations as we've used KERNEL_P2V() macro * for virtual addresses resolution. */ pte2p = kern_pt2tab_entry((vm_offset_t)kern_pt1); pt2pg_va = KERNEL_P2V(pte2_pa(pte2_load(pte2p))); pte2p = page_pt2(pt2pg_va, pte1_index((vm_offset_t)kern_pt1)); /* Make mapping for kernel L1 page table. */ for (pa = base_pt1, i = 0; i < NPG_IN_PT1; i++, pa += PTE2_SIZE) pte2_store(pte2p++, PTE2_KPT(pa)); /* Make mapping for kernel PT2TAB. */ for (pa = pt2tab_pa, i = 0; i < NPG_IN_PT2TAB; i++, pa += PTE2_SIZE) pte2_store(pte2p++, PTE2_KPT(pa)); /* Finally, switch from 'boot_pt1' to 'kern_pt1'. */ pmap_kern_ttb = base_pt1 | ttb_flags; cpuinfo_reinit_mmu(pmap_kern_ttb); /* * Initialize the first available KVA. As kernel image is mapped by * sections, we are leaving some gap behind. */ virtual_avail = (vm_offset_t)kern_pt2tab + NPG_IN_PT2TAB * PAGE_SIZE; } /* * Setup L2 page table page for given KVA. * Used in pre-bootstrap epoch. * * Note that we have allocated NKPT2PG pages for L2 page tables in advance * and used them for mapping KVA starting from KERNBASE. However, this is not * enough. Vectors and devices need L2 page tables too. Note that they are * even above VM_MAX_KERNEL_ADDRESS. */ static __inline vm_paddr_t pmap_preboot_pt2pg_setup(vm_offset_t va) { pt2_entry_t *pte2p, pte2; vm_paddr_t pt2pg_pa; /* Get associated entry in PT2TAB. */ pte2p = kern_pt2tab_entry(va); /* Just return, if PT2s page exists already. */ pte2 = pt2tab_load(pte2p); if (pte2_is_valid(pte2)) return (pte2_pa(pte2)); KASSERT(va >= VM_MAX_KERNEL_ADDRESS, ("%s: NKPT2PG too small", __func__)); /* * Allocate page for PT2s and insert it to PT2TAB. * In other words, map it into PT2MAP space. */ pt2pg_pa = pmap_preboot_get_pages(1); pt2tab_store(pte2p, PTE2_KPT(pt2pg_pa)); /* Zero all PT2s in allocated page. */ bzero((void*)pt2map_pt2pg(va), PAGE_SIZE); pte2_sync_range((pt2_entry_t *)pt2map_pt2pg(va), PAGE_SIZE); return (pt2pg_pa); } /* * Setup L2 page table for given KVA. * Used in pre-bootstrap epoch. */ static void pmap_preboot_pt2_setup(vm_offset_t va) { pt1_entry_t *pte1p; vm_paddr_t pt2pg_pa, pt2_pa; /* Setup PT2's page. */ pt2pg_pa = pmap_preboot_pt2pg_setup(va); pt2_pa = page_pt2pa(pt2pg_pa, pte1_index(va)); /* Insert PT2 to PT1. */ pte1p = kern_pte1(va); pte1_store(pte1p, PTE1_LINK(pt2_pa)); } /* * Get L2 page entry associated with given KVA. * Used in pre-bootstrap epoch. */ static __inline pt2_entry_t* pmap_preboot_vtopte2(vm_offset_t va) { pt1_entry_t *pte1p; /* Setup PT2 if needed. */ pte1p = kern_pte1(va); if (!pte1_is_valid(pte1_load(pte1p))) /* XXX - sections ?! */ pmap_preboot_pt2_setup(va); return (pt2map_entry(va)); } /* * Pre-bootstrap epoch page(s) mapping(s). */ void pmap_preboot_map_pages(vm_paddr_t pa, vm_offset_t va, u_int num) { u_int i; pt2_entry_t *pte2p; /* Map all the pages. */ for (i = 0; i < num; i++) { pte2p = pmap_preboot_vtopte2(va); pte2_store(pte2p, PTE2_KRW(pa)); va += PAGE_SIZE; pa += PAGE_SIZE; } } /* * Pre-bootstrap epoch virtual space alocator. */ vm_offset_t pmap_preboot_reserve_pages(u_int num) { u_int i; vm_offset_t start, va; pt2_entry_t *pte2p; /* Allocate virtual space. */ start = va = virtual_avail; virtual_avail += num * PAGE_SIZE; /* Zero the mapping. */ for (i = 0; i < num; i++) { pte2p = pmap_preboot_vtopte2(va); pte2_store(pte2p, 0); va += PAGE_SIZE; } return (start); } /* * Pre-bootstrap epoch page(s) allocation and mapping(s). */ vm_offset_t pmap_preboot_get_vpages(u_int num) { vm_paddr_t pa; vm_offset_t va; /* Allocate physical page(s). */ pa = pmap_preboot_get_pages(num); /* Allocate virtual space. */ va = virtual_avail; virtual_avail += num * PAGE_SIZE; /* Map and zero all. */ pmap_preboot_map_pages(pa, va, num); bzero((void *)va, num * PAGE_SIZE); return (va); } /* * Pre-bootstrap epoch page mapping(s) with attributes. */ void pmap_preboot_map_attr(vm_paddr_t pa, vm_offset_t va, vm_size_t size, vm_prot_t prot, vm_memattr_t attr) { u_int num; u_int l1_attr, l1_prot, l2_prot, l2_attr; pt1_entry_t *pte1p; pt2_entry_t *pte2p; l2_prot = prot & VM_PROT_WRITE ? PTE2_AP_KRW : PTE2_AP_KR; l2_prot |= (prot & VM_PROT_EXECUTE) ? PTE2_X : PTE2_NX; l2_attr = vm_memattr_to_pte2(attr); l1_prot = ATTR_TO_L1(l2_prot); l1_attr = ATTR_TO_L1(l2_attr); /* Map all the pages. */ num = round_page(size); while (num > 0) { if ((((va | pa) & PTE1_OFFSET) == 0) && (num >= PTE1_SIZE)) { pte1p = kern_pte1(va); pte1_store(pte1p, PTE1_KERN(pa, l1_prot, l1_attr)); va += PTE1_SIZE; pa += PTE1_SIZE; num -= PTE1_SIZE; } else { pte2p = pmap_preboot_vtopte2(va); pte2_store(pte2p, PTE2_KERN(pa, l2_prot, l2_attr)); va += PAGE_SIZE; pa += PAGE_SIZE; num -= PAGE_SIZE; } } } /* * Extract from the kernel page table the physical address * that is mapped by the given virtual address "va". */ vm_paddr_t pmap_kextract(vm_offset_t va) { vm_paddr_t pa; pt1_entry_t pte1; pt2_entry_t pte2; pte1 = pte1_load(kern_pte1(va)); if (pte1_is_section(pte1)) { pa = pte1_pa(pte1) | (va & PTE1_OFFSET); } else if (pte1_is_link(pte1)) { /* * We should beware of concurrent promotion that changes * pte1 at this point. However, it's not a problem as PT2 * page is preserved by promotion in PT2TAB. So even if * it happens, using of PT2MAP is still safe. * * QQQ: However, concurrent removing is a problem which * ends in abort on PT2MAP space. Locking must be used * to deal with this. */ pte2 = pte2_load(pt2map_entry(va)); pa = pte2_pa(pte2) | (va & PTE2_OFFSET); } else { panic("%s: va %#x pte1 %#x", __func__, va, pte1); } return (pa); } /* * Extract from the kernel page table the physical address * that is mapped by the given virtual address "va". Also * return L2 page table entry which maps the address. * * This is only intended to be used for panic dumps. */ vm_paddr_t pmap_dump_kextract(vm_offset_t va, pt2_entry_t *pte2p) { vm_paddr_t pa; pt1_entry_t pte1; pt2_entry_t pte2; pte1 = pte1_load(kern_pte1(va)); if (pte1_is_section(pte1)) { pa = pte1_pa(pte1) | (va & PTE1_OFFSET); pte2 = pa | ATTR_TO_L2(pte1) | PTE2_V; } else if (pte1_is_link(pte1)) { pte2 = pte2_load(pt2map_entry(va)); pa = pte2_pa(pte2); } else { pte2 = 0; pa = 0; } if (pte2p != NULL) *pte2p = pte2; return (pa); } /***************************************************************************** * * PMAP second stage initialization and utility functions * for bootstrap epoch. * * After pmap_bootstrap() is called, the following functions for * mappings can be used: * * void pmap_kenter(vm_offset_t va, vm_paddr_t pa); * void pmap_kremove(vm_offset_t va); * vm_offset_t pmap_map(vm_offset_t *virt, vm_paddr_t start, vm_paddr_t end, * int prot); * * NOTE: This is not SMP coherent stage. And physical page allocation is not * allowed during this stage. * *****************************************************************************/ /* * Initialize kernel PMAP locks and lists, kernel_pmap itself, and * reserve various virtual spaces for temporary mappings. */ void pmap_bootstrap(vm_offset_t firstaddr) { pt2_entry_t *unused __unused; struct pcpu *pc; /* * Initialize the kernel pmap (which is statically allocated). */ PMAP_LOCK_INIT(kernel_pmap); kernel_l1pa = (vm_paddr_t)kern_pt1; /* for libkvm */ kernel_pmap->pm_pt1 = kern_pt1; kernel_pmap->pm_pt2tab = kern_pt2tab; CPU_FILL(&kernel_pmap->pm_active); /* don't allow deactivation */ TAILQ_INIT(&kernel_pmap->pm_pvchunk); /* * Initialize the global pv list lock. */ rw_init(&pvh_global_lock, "pmap pv global"); LIST_INIT(&allpmaps); /* * Request a spin mutex so that changes to allpmaps cannot be * preempted by smp_rendezvous_cpus(). */ mtx_init(&allpmaps_lock, "allpmaps", NULL, MTX_SPIN); mtx_lock_spin(&allpmaps_lock); LIST_INSERT_HEAD(&allpmaps, kernel_pmap, pm_list); mtx_unlock_spin(&allpmaps_lock); /* * Reserve some special page table entries/VA space for temporary * mapping of pages. */ #define SYSMAP(c, p, v, n) do { \ v = (c)pmap_preboot_reserve_pages(n); \ p = pt2map_entry((vm_offset_t)v); \ } while (0) /* * Local CMAP1/CMAP2 are used for zeroing and copying pages. * Local CMAP2 is also used for data cache cleaning. */ pc = get_pcpu(); mtx_init(&pc->pc_cmap_lock, "SYSMAPS", NULL, MTX_DEF); SYSMAP(caddr_t, pc->pc_cmap1_pte2p, pc->pc_cmap1_addr, 1); SYSMAP(caddr_t, pc->pc_cmap2_pte2p, pc->pc_cmap2_addr, 1); SYSMAP(vm_offset_t, pc->pc_qmap_pte2p, pc->pc_qmap_addr, 1); /* * Crashdump maps. */ SYSMAP(caddr_t, unused, crashdumpmap, MAXDUMPPGS); /* * _tmppt is used for reading arbitrary physical pages via /dev/mem. */ SYSMAP(caddr_t, unused, _tmppt, 1); /* * PADDR1 and PADDR2 are used by pmap_pte2_quick() and pmap_pte2(), * respectively. PADDR3 is used by pmap_pte2_ddb(). */ SYSMAP(pt2_entry_t *, PMAP1, PADDR1, 1); SYSMAP(pt2_entry_t *, PMAP2, PADDR2, 1); #ifdef DDB SYSMAP(pt2_entry_t *, PMAP3, PADDR3, 1); #endif mtx_init(&PMAP2mutex, "PMAP2", NULL, MTX_DEF); /* * Note that in very short time in initarm(), we are going to * initialize phys_avail[] array and no further page allocation * can happen after that until vm subsystem will be initialized. */ kernel_vm_end_new = kernel_vm_end; virtual_end = vm_max_kernel_address; } static void pmap_init_reserved_pages(void) { struct pcpu *pc; vm_offset_t pages; int i; CPU_FOREACH(i) { pc = pcpu_find(i); /* * Skip if the mapping has already been initialized, * i.e. this is the BSP. */ if (pc->pc_cmap1_addr != 0) continue; mtx_init(&pc->pc_cmap_lock, "SYSMAPS", NULL, MTX_DEF); pages = kva_alloc(PAGE_SIZE * 3); if (pages == 0) panic("%s: unable to allocate KVA", __func__); pc->pc_cmap1_pte2p = pt2map_entry(pages); pc->pc_cmap2_pte2p = pt2map_entry(pages + PAGE_SIZE); pc->pc_qmap_pte2p = pt2map_entry(pages + (PAGE_SIZE * 2)); pc->pc_cmap1_addr = (caddr_t)pages; pc->pc_cmap2_addr = (caddr_t)(pages + PAGE_SIZE); pc->pc_qmap_addr = pages + (PAGE_SIZE * 2); } } SYSINIT(rpages_init, SI_SUB_CPU, SI_ORDER_ANY, pmap_init_reserved_pages, NULL); /* * The function can already be use in second initialization stage. * As such, the function DOES NOT call pmap_growkernel() where PT2 * allocation can happen. So if used, be sure that PT2 for given * virtual address is allocated already! * * Add a wired page to the kva. * Note: not SMP coherent. */ static __inline void pmap_kenter_prot_attr(vm_offset_t va, vm_paddr_t pa, uint32_t prot, uint32_t attr) { pt1_entry_t *pte1p; pt2_entry_t *pte2p; pte1p = kern_pte1(va); if (!pte1_is_valid(pte1_load(pte1p))) { /* XXX - sections ?! */ /* * This is a very low level function, so PT2 and particularly * PT2PG associated with given virtual address must be already * allocated. It's a pain mainly during pmap initialization * stage. However, called after pmap initialization with * virtual address not under kernel_vm_end will lead to * the same misery. */ if (!pte2_is_valid(pte2_load(kern_pt2tab_entry(va)))) panic("%s: kernel PT2 not allocated!", __func__); } pte2p = pt2map_entry(va); pte2_store(pte2p, PTE2_KERN(pa, prot, attr)); } PMAP_INLINE void pmap_kenter(vm_offset_t va, vm_paddr_t pa) { pmap_kenter_prot_attr(va, pa, PTE2_AP_KRW, PTE2_ATTR_DEFAULT); } /* * Remove a page from the kernel pagetables. * Note: not SMP coherent. */ PMAP_INLINE void pmap_kremove(vm_offset_t va) { pt1_entry_t *pte1p; pt2_entry_t *pte2p; pte1p = kern_pte1(va); if (pte1_is_section(pte1_load(pte1p))) { pte1_clear(pte1p); } else { pte2p = pt2map_entry(va); pte2_clear(pte2p); } } /* * Share new kernel PT2PG with all pmaps. * The caller is responsible for maintaining TLB consistency. */ static void pmap_kenter_pt2tab(vm_offset_t va, pt2_entry_t npte2) { pmap_t pmap; pt2_entry_t *pte2p; mtx_lock_spin(&allpmaps_lock); LIST_FOREACH(pmap, &allpmaps, pm_list) { pte2p = pmap_pt2tab_entry(pmap, va); pt2tab_store(pte2p, npte2); } mtx_unlock_spin(&allpmaps_lock); } /* * Share new kernel PTE1 with all pmaps. * The caller is responsible for maintaining TLB consistency. */ static void pmap_kenter_pte1(vm_offset_t va, pt1_entry_t npte1) { pmap_t pmap; pt1_entry_t *pte1p; mtx_lock_spin(&allpmaps_lock); LIST_FOREACH(pmap, &allpmaps, pm_list) { pte1p = pmap_pte1(pmap, va); pte1_store(pte1p, npte1); } mtx_unlock_spin(&allpmaps_lock); } /* * Used to map a range of physical addresses into kernel * virtual address space. * * The value passed in '*virt' is a suggested virtual address for * the mapping. Architectures which can support a direct-mapped * physical to virtual region can return the appropriate address * within that region, leaving '*virt' unchanged. Other * architectures should map the pages starting at '*virt' and * update '*virt' with the first usable address after the mapped * region. * * NOTE: Read the comments above pmap_kenter_prot_attr() as * the function is used herein! */ vm_offset_t pmap_map(vm_offset_t *virt, vm_paddr_t start, vm_paddr_t end, int prot) { vm_offset_t va, sva; vm_paddr_t pte1_offset; pt1_entry_t npte1; uint32_t l1prot, l2prot; uint32_t l1attr, l2attr; PDEBUG(1, printf("%s: virt = %#x, start = %#x, end = %#x (size = %#x)," " prot = %d\n", __func__, *virt, start, end, end - start, prot)); l2prot = (prot & VM_PROT_WRITE) ? PTE2_AP_KRW : PTE2_AP_KR; l2prot |= (prot & VM_PROT_EXECUTE) ? PTE2_X : PTE2_NX; l1prot = ATTR_TO_L1(l2prot); l2attr = PTE2_ATTR_DEFAULT; l1attr = ATTR_TO_L1(l2attr); va = *virt; /* * Does the physical address range's size and alignment permit at * least one section mapping to be created? */ pte1_offset = start & PTE1_OFFSET; if ((end - start) - ((PTE1_SIZE - pte1_offset) & PTE1_OFFSET) >= PTE1_SIZE) { /* * Increase the starting virtual address so that its alignment * does not preclude the use of section mappings. */ if ((va & PTE1_OFFSET) < pte1_offset) va = pte1_trunc(va) + pte1_offset; else if ((va & PTE1_OFFSET) > pte1_offset) va = pte1_roundup(va) + pte1_offset; } sva = va; while (start < end) { if ((start & PTE1_OFFSET) == 0 && end - start >= PTE1_SIZE) { KASSERT((va & PTE1_OFFSET) == 0, ("%s: misaligned va %#x", __func__, va)); npte1 = PTE1_KERN(start, l1prot, l1attr); pmap_kenter_pte1(va, npte1); va += PTE1_SIZE; start += PTE1_SIZE; } else { pmap_kenter_prot_attr(va, start, l2prot, l2attr); va += PAGE_SIZE; start += PAGE_SIZE; } } tlb_flush_range(sva, va - sva); *virt = va; return (sva); } /* * Make a temporary mapping for a physical address. * This is only intended to be used for panic dumps. */ void * pmap_kenter_temporary(vm_paddr_t pa, int i) { vm_offset_t va; /* QQQ: 'i' should be less or equal to MAXDUMPPGS. */ va = (vm_offset_t)crashdumpmap + (i * PAGE_SIZE); pmap_kenter(va, pa); tlb_flush_local(va); return ((void *)crashdumpmap); } /************************************* * * TLB & cache maintenance routines. * *************************************/ /* * We inline these within pmap.c for speed. */ PMAP_INLINE void pmap_tlb_flush(pmap_t pmap, vm_offset_t va) { if (pmap == kernel_pmap || !CPU_EMPTY(&pmap->pm_active)) tlb_flush(va); } PMAP_INLINE void pmap_tlb_flush_range(pmap_t pmap, vm_offset_t sva, vm_size_t size) { if (pmap == kernel_pmap || !CPU_EMPTY(&pmap->pm_active)) tlb_flush_range(sva, size); } /* * Abuse the pte2 nodes for unmapped kva to thread a kva freelist through. * Requirements: * - Must deal with pages in order to ensure that none of the PTE2_* bits * are ever set, PTE2_V in particular. * - Assumes we can write to pte2s without pte2_store() atomic ops. * - Assumes nothing will ever test these addresses for 0 to indicate * no mapping instead of correctly checking PTE2_V. * - Assumes a vm_offset_t will fit in a pte2 (true for arm). * Because PTE2_V is never set, there can be no mappings to invalidate. */ static vm_offset_t pmap_pte2list_alloc(vm_offset_t *head) { pt2_entry_t *pte2p; vm_offset_t va; va = *head; if (va == 0) panic("pmap_ptelist_alloc: exhausted ptelist KVA"); pte2p = pt2map_entry(va); *head = *pte2p; if (*head & PTE2_V) panic("%s: va with PTE2_V set!", __func__); *pte2p = 0; return (va); } static void pmap_pte2list_free(vm_offset_t *head, vm_offset_t va) { pt2_entry_t *pte2p; if (va & PTE2_V) panic("%s: freeing va with PTE2_V set!", __func__); pte2p = pt2map_entry(va); *pte2p = *head; /* virtual! PTE2_V is 0 though */ *head = va; } static void pmap_pte2list_init(vm_offset_t *head, void *base, int npages) { int i; vm_offset_t va; *head = 0; for (i = npages - 1; i >= 0; i--) { va = (vm_offset_t)base + i * PAGE_SIZE; pmap_pte2list_free(head, va); } } /***************************************************************************** * * PMAP third and final stage initialization. * * After pmap_init() is called, PMAP subsystem is fully initialized. * *****************************************************************************/ SYSCTL_NODE(_vm, OID_AUTO, pmap, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "VM/pmap parameters"); SYSCTL_INT(_vm_pmap, OID_AUTO, pv_entry_max, CTLFLAG_RD, &pv_entry_max, 0, "Max number of PV entries"); SYSCTL_INT(_vm_pmap, OID_AUTO, shpgperproc, CTLFLAG_RD, &shpgperproc, 0, "Page share factor per proc"); static u_long nkpt2pg = NKPT2PG; SYSCTL_ULONG(_vm_pmap, OID_AUTO, nkpt2pg, CTLFLAG_RD, &nkpt2pg, 0, "Pre-allocated pages for kernel PT2s"); static int sp_enabled = 1; SYSCTL_INT(_vm_pmap, OID_AUTO, sp_enabled, CTLFLAG_RDTUN | CTLFLAG_NOFETCH, &sp_enabled, 0, "Are large page mappings enabled?"); bool pmap_ps_enabled(pmap_t pmap __unused) { return (sp_enabled != 0); } static SYSCTL_NODE(_vm_pmap, OID_AUTO, pte1, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "1MB page mapping counters"); static u_long pmap_pte1_demotions; SYSCTL_ULONG(_vm_pmap_pte1, OID_AUTO, demotions, CTLFLAG_RD, &pmap_pte1_demotions, 0, "1MB page demotions"); static u_long pmap_pte1_mappings; SYSCTL_ULONG(_vm_pmap_pte1, OID_AUTO, mappings, CTLFLAG_RD, &pmap_pte1_mappings, 0, "1MB page mappings"); static u_long pmap_pte1_p_failures; SYSCTL_ULONG(_vm_pmap_pte1, OID_AUTO, p_failures, CTLFLAG_RD, &pmap_pte1_p_failures, 0, "1MB page promotion failures"); static u_long pmap_pte1_promotions; SYSCTL_ULONG(_vm_pmap_pte1, OID_AUTO, promotions, CTLFLAG_RD, &pmap_pte1_promotions, 0, "1MB page promotions"); static u_long pmap_pte1_kern_demotions; SYSCTL_ULONG(_vm_pmap_pte1, OID_AUTO, kern_demotions, CTLFLAG_RD, &pmap_pte1_kern_demotions, 0, "1MB page kernel demotions"); static u_long pmap_pte1_kern_promotions; SYSCTL_ULONG(_vm_pmap_pte1, OID_AUTO, kern_promotions, CTLFLAG_RD, &pmap_pte1_kern_promotions, 0, "1MB page kernel promotions"); static __inline ttb_entry_t pmap_ttb_get(pmap_t pmap) { return (vtophys(pmap->pm_pt1) | ttb_flags); } /* * Initialize a vm_page's machine-dependent fields. * * Variations: * 1. Pages for L2 page tables are always not managed. So, pv_list and * pt2_wirecount can share same physical space. However, proper * initialization on a page alloc for page tables and reinitialization * on the page free must be ensured. */ void pmap_page_init(vm_page_t m) { TAILQ_INIT(&m->md.pv_list); pt2_wirecount_init(m); m->md.pat_mode = VM_MEMATTR_DEFAULT; } /* * Virtualization for faster way how to zero whole page. */ static __inline void pagezero(void *page) { bzero(page, PAGE_SIZE); } /* * Zero L2 page table page. * Use same KVA as in pmap_zero_page(). */ static __inline vm_paddr_t pmap_pt2pg_zero(vm_page_t m) { pt2_entry_t *cmap2_pte2p; vm_paddr_t pa; struct pcpu *pc; pa = VM_PAGE_TO_PHYS(m); /* * XXX: For now, we map whole page even if it's already zero, * to sync it even if the sync is only DSB. */ sched_pin(); pc = get_pcpu(); cmap2_pte2p = pc->pc_cmap2_pte2p; mtx_lock(&pc->pc_cmap_lock); if (pte2_load(cmap2_pte2p) != 0) panic("%s: CMAP2 busy", __func__); pte2_store(cmap2_pte2p, PTE2_KERN_NG(pa, PTE2_AP_KRW, vm_page_pte2_attr(m))); /* Even VM_ALLOC_ZERO request is only advisory. */ if ((m->flags & PG_ZERO) == 0) pagezero(pc->pc_cmap2_addr); pte2_sync_range((pt2_entry_t *)pc->pc_cmap2_addr, PAGE_SIZE); pte2_clear(cmap2_pte2p); tlb_flush((vm_offset_t)pc->pc_cmap2_addr); /* * Unpin the thread before releasing the lock. Otherwise the thread * could be rescheduled while still bound to the current CPU, only * to unpin itself immediately upon resuming execution. */ sched_unpin(); mtx_unlock(&pc->pc_cmap_lock); return (pa); } /* * Init just allocated page as L2 page table(s) holder * and return its physical address. */ static __inline vm_paddr_t pmap_pt2pg_init(pmap_t pmap, vm_offset_t va, vm_page_t m) { vm_paddr_t pa; pt2_entry_t *pte2p; /* Check page attributes. */ if (m->md.pat_mode != pt_memattr) pmap_page_set_memattr(m, pt_memattr); /* Zero page and init wire counts. */ pa = pmap_pt2pg_zero(m); pt2_wirecount_init(m); /* * Map page to PT2MAP address space for given pmap. * Note that PT2MAP space is shared with all pmaps. */ if (pmap == kernel_pmap) pmap_kenter_pt2tab(va, PTE2_KPT(pa)); else { pte2p = pmap_pt2tab_entry(pmap, va); pt2tab_store(pte2p, PTE2_KPT_NG(pa)); } return (pa); } /* * Initialize the pmap module. * Called by vm_init, to initialize any structures that the pmap * system needs to map virtual memory. */ void pmap_init(void) { vm_size_t s; pt2_entry_t *pte2p, pte2; u_int i, pte1_idx, pv_npg; PDEBUG(1, printf("%s: phys_start = %#x\n", __func__, PHYSADDR)); /* * Initialize the vm page array entries for kernel pmap's * L2 page table pages allocated in advance. */ pte1_idx = pte1_index(KERNBASE - PT2MAP_SIZE); pte2p = kern_pt2tab_entry(KERNBASE - PT2MAP_SIZE); for (i = 0; i < nkpt2pg + NPG_IN_PT2TAB; i++, pte2p++) { vm_paddr_t pa; vm_page_t m; pte2 = pte2_load(pte2p); KASSERT(pte2_is_valid(pte2), ("%s: no valid entry", __func__)); pa = pte2_pa(pte2); m = PHYS_TO_VM_PAGE(pa); KASSERT(m >= vm_page_array && m < &vm_page_array[vm_page_array_size], ("%s: L2 page table page is out of range", __func__)); m->pindex = pte1_idx; m->phys_addr = pa; pte1_idx += NPT2_IN_PG; } /* * Initialize the address space (zone) for the pv entries. Set a * high water mark so that the system can recover from excessive * numbers of pv entries. */ TUNABLE_INT_FETCH("vm.pmap.shpgperproc", &shpgperproc); pv_entry_max = shpgperproc * maxproc + vm_cnt.v_page_count; TUNABLE_INT_FETCH("vm.pmap.pv_entries", &pv_entry_max); pv_entry_max = roundup(pv_entry_max, _NPCPV); pv_entry_high_water = 9 * (pv_entry_max / 10); /* * Are large page mappings enabled? */ TUNABLE_INT_FETCH("vm.pmap.sp_enabled", &sp_enabled); if (sp_enabled) { KASSERT(MAXPAGESIZES > 1 && pagesizes[1] == 0, ("%s: can't assign to pagesizes[1]", __func__)); pagesizes[1] = PTE1_SIZE; } /* * Calculate the size of the pv head table for sections. * Handle the possibility that "vm_phys_segs[...].end" is zero. * Note that the table is only for sections which could be promoted. */ first_managed_pa = pte1_trunc(vm_phys_segs[0].start); pv_npg = (pte1_trunc(vm_phys_segs[vm_phys_nsegs - 1].end - PAGE_SIZE) - first_managed_pa) / PTE1_SIZE + 1; /* * Allocate memory for the pv head table for sections. */ s = (vm_size_t)(pv_npg * sizeof(struct md_page)); s = round_page(s); pv_table = kmem_malloc(s, M_WAITOK | M_ZERO); for (i = 0; i < pv_npg; i++) TAILQ_INIT(&pv_table[i].pv_list); pv_maxchunks = MAX(pv_entry_max / _NPCPV, maxproc); pv_chunkbase = (struct pv_chunk *)kva_alloc(PAGE_SIZE * pv_maxchunks); if (pv_chunkbase == NULL) panic("%s: not enough kvm for pv chunks", __func__); pmap_pte2list_init(&pv_vafree, pv_chunkbase, pv_maxchunks); } /* * Add a list of wired pages to the kva * this routine is only used for temporary * kernel mappings that do not need to have * page modification or references recorded. * Note that old mappings are simply written * over. The page *must* be wired. * Note: SMP coherent. Uses a ranged shootdown IPI. */ void pmap_qenter(vm_offset_t sva, vm_page_t *ma, int count) { u_int anychanged; pt2_entry_t *epte2p, *pte2p, pte2; vm_page_t m; vm_paddr_t pa; anychanged = 0; pte2p = pt2map_entry(sva); epte2p = pte2p + count; while (pte2p < epte2p) { m = *ma++; pa = VM_PAGE_TO_PHYS(m); pte2 = pte2_load(pte2p); if ((pte2_pa(pte2) != pa) || (pte2_attr(pte2) != vm_page_pte2_attr(m))) { anychanged++; pte2_store(pte2p, PTE2_KERN(pa, PTE2_AP_KRW, vm_page_pte2_attr(m))); } pte2p++; } if (__predict_false(anychanged)) tlb_flush_range(sva, count * PAGE_SIZE); } /* * This routine tears out page mappings from the * kernel -- it is meant only for temporary mappings. * Note: SMP coherent. Uses a ranged shootdown IPI. */ void pmap_qremove(vm_offset_t sva, int count) { vm_offset_t va; va = sva; while (count-- > 0) { pmap_kremove(va); va += PAGE_SIZE; } tlb_flush_range(sva, va - sva); } /* * Are we current address space or kernel? */ static __inline int pmap_is_current(pmap_t pmap) { return (pmap == kernel_pmap || (pmap == vmspace_pmap(curthread->td_proc->p_vmspace))); } /* * If the given pmap is not the current or kernel pmap, the returned * pte2 must be released by passing it to pmap_pte2_release(). */ static pt2_entry_t * pmap_pte2(pmap_t pmap, vm_offset_t va) { pt1_entry_t pte1; vm_paddr_t pt2pg_pa; pte1 = pte1_load(pmap_pte1(pmap, va)); if (pte1_is_section(pte1)) panic("%s: attempt to map PTE1", __func__); if (pte1_is_link(pte1)) { /* Are we current address space or kernel? */ if (pmap_is_current(pmap)) return (pt2map_entry(va)); /* Note that L2 page table size is not equal to PAGE_SIZE. */ pt2pg_pa = trunc_page(pte1_link_pa(pte1)); mtx_lock(&PMAP2mutex); if (pte2_pa(pte2_load(PMAP2)) != pt2pg_pa) { pte2_store(PMAP2, PTE2_KPT(pt2pg_pa)); tlb_flush((vm_offset_t)PADDR2); } return (PADDR2 + (arm32_btop(va) & (NPTE2_IN_PG - 1))); } return (NULL); } /* * Releases a pte2 that was obtained from pmap_pte2(). * Be prepared for the pte2p being NULL. */ static __inline void pmap_pte2_release(pt2_entry_t *pte2p) { if ((pt2_entry_t *)(trunc_page((vm_offset_t)pte2p)) == PADDR2) { mtx_unlock(&PMAP2mutex); } } /* * Super fast pmap_pte2 routine best used when scanning * the pv lists. This eliminates many coarse-grained * invltlb calls. Note that many of the pv list * scans are across different pmaps. It is very wasteful * to do an entire tlb flush for checking a single mapping. * * If the given pmap is not the current pmap, pvh_global_lock * must be held and curthread pinned to a CPU. */ static pt2_entry_t * pmap_pte2_quick(pmap_t pmap, vm_offset_t va) { pt1_entry_t pte1; vm_paddr_t pt2pg_pa; pte1 = pte1_load(pmap_pte1(pmap, va)); if (pte1_is_section(pte1)) panic("%s: attempt to map PTE1", __func__); if (pte1_is_link(pte1)) { /* Are we current address space or kernel? */ if (pmap_is_current(pmap)) return (pt2map_entry(va)); rw_assert(&pvh_global_lock, RA_WLOCKED); KASSERT(curthread->td_pinned > 0, ("%s: curthread not pinned", __func__)); /* Note that L2 page table size is not equal to PAGE_SIZE. */ pt2pg_pa = trunc_page(pte1_link_pa(pte1)); if (pte2_pa(pte2_load(PMAP1)) != pt2pg_pa) { pte2_store(PMAP1, PTE2_KPT(pt2pg_pa)); #ifdef SMP PMAP1cpu = PCPU_GET(cpuid); #endif tlb_flush_local((vm_offset_t)PADDR1); PMAP1changed++; } else #ifdef SMP if (PMAP1cpu != PCPU_GET(cpuid)) { PMAP1cpu = PCPU_GET(cpuid); tlb_flush_local((vm_offset_t)PADDR1); PMAP1changedcpu++; } else #endif PMAP1unchanged++; return (PADDR1 + (arm32_btop(va) & (NPTE2_IN_PG - 1))); } return (NULL); } /* * Routine: pmap_extract * Function: * Extract the physical page address associated * with the given map/virtual_address pair. */ vm_paddr_t pmap_extract(pmap_t pmap, vm_offset_t va) { vm_paddr_t pa; pt1_entry_t pte1; pt2_entry_t *pte2p; PMAP_LOCK(pmap); pte1 = pte1_load(pmap_pte1(pmap, va)); if (pte1_is_section(pte1)) pa = pte1_pa(pte1) | (va & PTE1_OFFSET); else if (pte1_is_link(pte1)) { pte2p = pmap_pte2(pmap, va); pa = pte2_pa(pte2_load(pte2p)) | (va & PTE2_OFFSET); pmap_pte2_release(pte2p); } else pa = 0; PMAP_UNLOCK(pmap); return (pa); } /* * Routine: pmap_extract_and_hold * Function: * Atomically extract and hold the physical page * with the given pmap and virtual address pair * if that mapping permits the given protection. */ vm_page_t pmap_extract_and_hold(pmap_t pmap, vm_offset_t va, vm_prot_t prot) { vm_paddr_t pa; pt1_entry_t pte1; pt2_entry_t pte2, *pte2p; vm_page_t m; m = NULL; PMAP_LOCK(pmap); pte1 = pte1_load(pmap_pte1(pmap, va)); if (pte1_is_section(pte1)) { if (!(pte1 & PTE1_RO) || !(prot & VM_PROT_WRITE)) { pa = pte1_pa(pte1) | (va & PTE1_OFFSET); m = PHYS_TO_VM_PAGE(pa); if (!vm_page_wire_mapped(m)) m = NULL; } } else if (pte1_is_link(pte1)) { pte2p = pmap_pte2(pmap, va); pte2 = pte2_load(pte2p); pmap_pte2_release(pte2p); if (pte2_is_valid(pte2) && (!(pte2 & PTE2_RO) || !(prot & VM_PROT_WRITE))) { pa = pte2_pa(pte2); m = PHYS_TO_VM_PAGE(pa); if (!vm_page_wire_mapped(m)) m = NULL; } } PMAP_UNLOCK(pmap); return (m); } /* * Grow the number of kernel L2 page table entries, if needed. */ void pmap_growkernel(vm_offset_t addr) { vm_page_t m; vm_paddr_t pt2pg_pa, pt2_pa; pt1_entry_t pte1; pt2_entry_t pte2; PDEBUG(1, printf("%s: addr = %#x\n", __func__, addr)); /* * All the time kernel_vm_end is first KVA for which underlying * L2 page table is either not allocated or linked from L1 page table * (not considering sections). Except for two possible cases: * * (1) in the very beginning as long as pmap_growkernel() was * not called, it could be first unused KVA (which is not * rounded up to PTE1_SIZE), * * (2) when all KVA space is mapped and vm_map_max(kernel_map) * address is not rounded up to PTE1_SIZE. (For example, * it could be 0xFFFFFFFF.) */ kernel_vm_end = pte1_roundup(kernel_vm_end); mtx_assert(&kernel_map->system_mtx, MA_OWNED); addr = roundup2(addr, PTE1_SIZE); if (addr - 1 >= vm_map_max(kernel_map)) addr = vm_map_max(kernel_map); while (kernel_vm_end < addr) { pte1 = pte1_load(kern_pte1(kernel_vm_end)); if (pte1_is_valid(pte1)) { kernel_vm_end += PTE1_SIZE; if (kernel_vm_end - 1 >= vm_map_max(kernel_map)) { kernel_vm_end = vm_map_max(kernel_map); break; } continue; } /* * kernel_vm_end_new is used in pmap_pinit() when kernel * mappings are entered to new pmap all at once to avoid race * between pmap_kenter_pte1() and kernel_vm_end increase. * The same aplies to pmap_kenter_pt2tab(). */ kernel_vm_end_new = kernel_vm_end + PTE1_SIZE; pte2 = pt2tab_load(kern_pt2tab_entry(kernel_vm_end)); if (!pte2_is_valid(pte2)) { /* * Install new PT2s page into kernel PT2TAB. */ m = vm_page_alloc_noobj(VM_ALLOC_INTERRUPT | VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (m == NULL) panic("%s: no memory to grow kernel", __func__); m->pindex = pte1_index(kernel_vm_end) & ~PT2PG_MASK; /* * QQQ: To link all new L2 page tables from L1 page * table now and so pmap_kenter_pte1() them * at once together with pmap_kenter_pt2tab() * could be nice speed up. However, * pmap_growkernel() does not happen so often... * QQQ: The other TTBR is another option. */ pt2pg_pa = pmap_pt2pg_init(kernel_pmap, kernel_vm_end, m); } else pt2pg_pa = pte2_pa(pte2); pt2_pa = page_pt2pa(pt2pg_pa, pte1_index(kernel_vm_end)); pmap_kenter_pte1(kernel_vm_end, PTE1_LINK(pt2_pa)); kernel_vm_end = kernel_vm_end_new; if (kernel_vm_end - 1 >= vm_map_max(kernel_map)) { kernel_vm_end = vm_map_max(kernel_map); break; } } } static int kvm_size(SYSCTL_HANDLER_ARGS) { unsigned long ksize = vm_max_kernel_address - KERNBASE; return (sysctl_handle_long(oidp, &ksize, 0, req)); } SYSCTL_PROC(_vm, OID_AUTO, kvm_size, CTLTYPE_LONG | CTLFLAG_RD | CTLFLAG_NEEDGIANT, 0, 0, kvm_size, "IU", "Size of KVM"); static int kvm_free(SYSCTL_HANDLER_ARGS) { unsigned long kfree = vm_max_kernel_address - kernel_vm_end; return (sysctl_handle_long(oidp, &kfree, 0, req)); } SYSCTL_PROC(_vm, OID_AUTO, kvm_free, CTLTYPE_LONG | CTLFLAG_RD | CTLFLAG_NEEDGIANT, 0, 0, kvm_free, "IU", "Amount of KVM free"); /*********************************************** * * Pmap allocation/deallocation routines. * ***********************************************/ /* * Initialize the pmap for the swapper process. */ void pmap_pinit0(pmap_t pmap) { PDEBUG(1, printf("%s: pmap = %p\n", __func__, pmap)); PMAP_LOCK_INIT(pmap); /* * Kernel page table directory and pmap stuff around is already * initialized, we are using it right now and here. So, finish * only PMAP structures initialization for process0 ... * * Since the L1 page table and PT2TAB is shared with the kernel pmap, * which is already included in the list "allpmaps", this pmap does * not need to be inserted into that list. */ pmap->pm_pt1 = kern_pt1; pmap->pm_pt2tab = kern_pt2tab; CPU_ZERO(&pmap->pm_active); PCPU_SET(curpmap, pmap); TAILQ_INIT(&pmap->pm_pvchunk); bzero(&pmap->pm_stats, sizeof pmap->pm_stats); CPU_SET(0, &pmap->pm_active); } static __inline void pte1_copy_nosync(pt1_entry_t *spte1p, pt1_entry_t *dpte1p, vm_offset_t sva, vm_offset_t eva) { u_int idx, count; idx = pte1_index(sva); count = (pte1_index(eva) - idx + 1) * sizeof(pt1_entry_t); bcopy(spte1p + idx, dpte1p + idx, count); } static __inline void pt2tab_copy_nosync(pt2_entry_t *spte2p, pt2_entry_t *dpte2p, vm_offset_t sva, vm_offset_t eva) { u_int idx, count; idx = pt2tab_index(sva); count = (pt2tab_index(eva) - idx + 1) * sizeof(pt2_entry_t); bcopy(spte2p + idx, dpte2p + idx, count); } /* * Initialize a preallocated and zeroed pmap structure, * such as one in a vmspace structure. */ int pmap_pinit(pmap_t pmap) { pt1_entry_t *pte1p; pt2_entry_t *pte2p; vm_paddr_t pa, pt2tab_pa; u_int i; PDEBUG(6, printf("%s: pmap = %p, pm_pt1 = %p\n", __func__, pmap, pmap->pm_pt1)); /* * No need to allocate L2 page table space yet but we do need * a valid L1 page table and PT2TAB table. * * Install shared kernel mappings to these tables. It's a little * tricky as some parts of KVA are reserved for vectors, devices, * and whatever else. These parts are supposed to be above * vm_max_kernel_address. Thus two regions should be installed: * * (1) . * * QQQ: The second region should be stable enough to be installed * only once in time when the tables are allocated. * QQQ: Maybe copy of both regions at once could be faster ... * QQQ: Maybe the other TTBR is an option. * * Finally, install own PT2TAB table to these tables. */ if (pmap->pm_pt1 == NULL) { pmap->pm_pt1 = kmem_alloc_contig(NB_IN_PT1, M_NOWAIT | M_ZERO, 0, -1UL, NB_IN_PT1, 0, pt_memattr); if (pmap->pm_pt1 == NULL) return (0); } if (pmap->pm_pt2tab == NULL) { /* * QQQ: (1) PT2TAB must be contiguous. If PT2TAB is one page * only, what should be the only size for 32 bit systems, * then we could allocate it with vm_page_alloc() and all * the stuff needed as other L2 page table pages. * (2) Note that a process PT2TAB is special L2 page table * page. Its mapping in kernel_arena is permanent and can * be used no matter which process is current. Its mapping * in PT2MAP can be used only for current process. */ pmap->pm_pt2tab = kmem_alloc_attr(NB_IN_PT2TAB, M_NOWAIT | M_ZERO, 0, -1UL, pt_memattr); if (pmap->pm_pt2tab == NULL) { /* * QQQ: As struct pmap is allocated from UMA with * UMA_ZONE_NOFREE flag, it's important to leave * no allocation in pmap if initialization failed. */ kmem_free(pmap->pm_pt1, NB_IN_PT1); pmap->pm_pt1 = NULL; return (0); } /* * QQQ: Each L2 page table page vm_page_t has pindex set to * pte1 index of virtual address mapped by this page. * It's not valid for non kernel PT2TABs themselves. * The pindex of these pages can not be altered because * of the way how they are allocated now. However, it * should not be a problem. */ } mtx_lock_spin(&allpmaps_lock); /* * To avoid race with pmap_kenter_pte1() and pmap_kenter_pt2tab(), * kernel_vm_end_new is used here instead of kernel_vm_end. */ pte1_copy_nosync(kern_pt1, pmap->pm_pt1, KERNBASE, kernel_vm_end_new - 1); pte1_copy_nosync(kern_pt1, pmap->pm_pt1, vm_max_kernel_address, 0xFFFFFFFF); pt2tab_copy_nosync(kern_pt2tab, pmap->pm_pt2tab, KERNBASE, kernel_vm_end_new - 1); pt2tab_copy_nosync(kern_pt2tab, pmap->pm_pt2tab, vm_max_kernel_address, 0xFFFFFFFF); LIST_INSERT_HEAD(&allpmaps, pmap, pm_list); mtx_unlock_spin(&allpmaps_lock); /* * Store PT2MAP PT2 pages (a.k.a. PT2TAB) in PT2TAB itself. * I.e. self reference mapping. The PT2TAB is private, however mapped * into shared PT2MAP space, so the mapping should be not global. */ pt2tab_pa = vtophys(pmap->pm_pt2tab); pte2p = pmap_pt2tab_entry(pmap, (vm_offset_t)PT2MAP); for (pa = pt2tab_pa, i = 0; i < NPG_IN_PT2TAB; i++, pa += PTE2_SIZE) { pt2tab_store(pte2p++, PTE2_KPT_NG(pa)); } /* Insert PT2MAP PT2s into pmap PT1. */ pte1p = pmap_pte1(pmap, (vm_offset_t)PT2MAP); for (pa = pt2tab_pa, i = 0; i < NPT2_IN_PT2TAB; i++, pa += NB_IN_PT2) { pte1_store(pte1p++, PTE1_LINK(pa)); } /* * Now synchronize new mapping which was made above. */ pte1_sync_range(pmap->pm_pt1, NB_IN_PT1); pte2_sync_range(pmap->pm_pt2tab, NB_IN_PT2TAB); CPU_ZERO(&pmap->pm_active); TAILQ_INIT(&pmap->pm_pvchunk); bzero(&pmap->pm_stats, sizeof pmap->pm_stats); return (1); } #ifdef INVARIANTS static boolean_t pt2tab_user_is_empty(pt2_entry_t *tab) { u_int i, end; end = pt2tab_index(VM_MAXUSER_ADDRESS); for (i = 0; i < end; i++) if (tab[i] != 0) return (FALSE); return (TRUE); } #endif /* * Release any resources held by the given physical map. * Called when a pmap initialized by pmap_pinit is being released. * Should only be called if the map contains no valid mappings. */ void pmap_release(pmap_t pmap) { #ifdef INVARIANTS vm_offset_t start, end; #endif KASSERT(pmap->pm_stats.resident_count == 0, ("%s: pmap resident count %ld != 0", __func__, pmap->pm_stats.resident_count)); KASSERT(pt2tab_user_is_empty(pmap->pm_pt2tab), ("%s: has allocated user PT2(s)", __func__)); KASSERT(CPU_EMPTY(&pmap->pm_active), ("%s: pmap %p is active on some CPU(s)", __func__, pmap)); mtx_lock_spin(&allpmaps_lock); LIST_REMOVE(pmap, pm_list); mtx_unlock_spin(&allpmaps_lock); #ifdef INVARIANTS start = pte1_index(KERNBASE) * sizeof(pt1_entry_t); end = (pte1_index(0xFFFFFFFF) + 1) * sizeof(pt1_entry_t); bzero((char *)pmap->pm_pt1 + start, end - start); start = pt2tab_index(KERNBASE) * sizeof(pt2_entry_t); end = (pt2tab_index(0xFFFFFFFF) + 1) * sizeof(pt2_entry_t); bzero((char *)pmap->pm_pt2tab + start, end - start); #endif /* * We are leaving PT1 and PT2TAB allocated on released pmap, * so hopefully UMA vmspace_zone will always be inited with * UMA_ZONE_NOFREE flag. */ } /********************************************************* * * L2 table pages and their pages management routines. * *********************************************************/ /* * Virtual interface for L2 page table wire counting. * * Each L2 page table in a page has own counter which counts a number of * valid mappings in a table. Global page counter counts mappings in all * tables in a page plus a single itself mapping in PT2TAB. * * During a promotion we leave the associated L2 page table counter * untouched, so the table (strictly speaking a page which holds it) * is never freed if promoted. * * If a page m->ref_count == 1 then no valid mappings exist in any L2 page * table in the page and the page itself is only mapped in PT2TAB. */ static __inline void pt2_wirecount_init(vm_page_t m) { u_int i; /* * Note: A page m is allocated with VM_ALLOC_WIRED flag and * m->ref_count should be already set correctly. * So, there is no need to set it again herein. */ for (i = 0; i < NPT2_IN_PG; i++) m->md.pt2_wirecount[i] = 0; } static __inline void pt2_wirecount_inc(vm_page_t m, uint32_t pte1_idx) { /* * Note: A just modificated pte2 (i.e. already allocated) * is acquiring one extra reference which must be * explicitly cleared. It influences the KASSERTs herein. * All L2 page tables in a page always belong to the same * pmap, so we allow only one extra reference for the page. */ KASSERT(m->md.pt2_wirecount[pte1_idx & PT2PG_MASK] < (NPTE2_IN_PT2 + 1), ("%s: PT2 is overflowing ...", __func__)); KASSERT(m->ref_count <= (NPTE2_IN_PG + 1), ("%s: PT2PG is overflowing ...", __func__)); m->ref_count++; m->md.pt2_wirecount[pte1_idx & PT2PG_MASK]++; } static __inline void pt2_wirecount_dec(vm_page_t m, uint32_t pte1_idx) { KASSERT(m->md.pt2_wirecount[pte1_idx & PT2PG_MASK] != 0, ("%s: PT2 is underflowing ...", __func__)); KASSERT(m->ref_count > 1, ("%s: PT2PG is underflowing ...", __func__)); m->ref_count--; m->md.pt2_wirecount[pte1_idx & PT2PG_MASK]--; } static __inline void pt2_wirecount_set(vm_page_t m, uint32_t pte1_idx, uint16_t count) { KASSERT(count <= NPTE2_IN_PT2, ("%s: invalid count %u", __func__, count)); KASSERT(m->ref_count > m->md.pt2_wirecount[pte1_idx & PT2PG_MASK], ("%s: PT2PG corrupting (%u, %u) ...", __func__, m->ref_count, m->md.pt2_wirecount[pte1_idx & PT2PG_MASK])); m->ref_count -= m->md.pt2_wirecount[pte1_idx & PT2PG_MASK]; m->ref_count += count; m->md.pt2_wirecount[pte1_idx & PT2PG_MASK] = count; KASSERT(m->ref_count <= (NPTE2_IN_PG + 1), ("%s: PT2PG is overflowed (%u) ...", __func__, m->ref_count)); } static __inline uint32_t pt2_wirecount_get(vm_page_t m, uint32_t pte1_idx) { return (m->md.pt2_wirecount[pte1_idx & PT2PG_MASK]); } static __inline boolean_t pt2_is_empty(vm_page_t m, vm_offset_t va) { return (m->md.pt2_wirecount[pte1_index(va) & PT2PG_MASK] == 0); } static __inline boolean_t pt2_is_full(vm_page_t m, vm_offset_t va) { return (m->md.pt2_wirecount[pte1_index(va) & PT2PG_MASK] == NPTE2_IN_PT2); } static __inline boolean_t pt2pg_is_empty(vm_page_t m) { return (m->ref_count == 1); } /* * This routine is called if the L2 page table * is not mapped correctly. */ static vm_page_t _pmap_allocpte2(pmap_t pmap, vm_offset_t va, u_int flags) { uint32_t pte1_idx; pt1_entry_t *pte1p; pt2_entry_t pte2; vm_page_t m; vm_paddr_t pt2pg_pa, pt2_pa; pte1_idx = pte1_index(va); pte1p = pmap->pm_pt1 + pte1_idx; KASSERT(pte1_load(pte1p) == 0, ("%s: pm_pt1[%#x] is not zero: %#x", __func__, pte1_idx, pte1_load(pte1p))); pte2 = pt2tab_load(pmap_pt2tab_entry(pmap, va)); if (!pte2_is_valid(pte2)) { /* * Install new PT2s page into pmap PT2TAB. */ m = vm_page_alloc_noobj(VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (m == NULL) { if ((flags & PMAP_ENTER_NOSLEEP) == 0) { PMAP_UNLOCK(pmap); rw_wunlock(&pvh_global_lock); vm_wait(NULL); rw_wlock(&pvh_global_lock); PMAP_LOCK(pmap); } /* * Indicate the need to retry. While waiting, * the L2 page table page may have been allocated. */ return (NULL); } m->pindex = pte1_idx & ~PT2PG_MASK; pmap->pm_stats.resident_count++; pt2pg_pa = pmap_pt2pg_init(pmap, va, m); } else { pt2pg_pa = pte2_pa(pte2); m = PHYS_TO_VM_PAGE(pt2pg_pa); } pt2_wirecount_inc(m, pte1_idx); pt2_pa = page_pt2pa(pt2pg_pa, pte1_idx); pte1_store(pte1p, PTE1_LINK(pt2_pa)); return (m); } static vm_page_t pmap_allocpte2(pmap_t pmap, vm_offset_t va, u_int flags) { u_int pte1_idx; pt1_entry_t *pte1p, pte1; vm_page_t m; pte1_idx = pte1_index(va); retry: pte1p = pmap->pm_pt1 + pte1_idx; pte1 = pte1_load(pte1p); /* * This supports switching from a 1MB page to a * normal 4K page. */ if (pte1_is_section(pte1)) { (void)pmap_demote_pte1(pmap, pte1p, va); /* * Reload pte1 after demotion. * * Note: Demotion can even fail as either PT2 is not find for * the virtual address or PT2PG can not be allocated. */ pte1 = pte1_load(pte1p); } /* * If the L2 page table page is mapped, we just increment the * hold count, and activate it. */ if (pte1_is_link(pte1)) { m = PHYS_TO_VM_PAGE(pte1_link_pa(pte1)); pt2_wirecount_inc(m, pte1_idx); } else { /* * Here if the PT2 isn't mapped, or if it has * been deallocated. */ m = _pmap_allocpte2(pmap, va, flags); if (m == NULL && (flags & PMAP_ENTER_NOSLEEP) == 0) goto retry; } return (m); } /* * Schedule the specified unused L2 page table page to be freed. Specifically, * add the page to the specified list of pages that will be released to the * physical memory manager after the TLB has been updated. */ static __inline void pmap_add_delayed_free_list(vm_page_t m, struct spglist *free) { /* * Put page on a list so that it is released after * *ALL* TLB shootdown is done */ #ifdef PMAP_DEBUG pmap_zero_page_check(m); #endif m->flags |= PG_ZERO; SLIST_INSERT_HEAD(free, m, plinks.s.ss); } /* * Unwire L2 page tables page. */ static void pmap_unwire_pt2pg(pmap_t pmap, vm_offset_t va, vm_page_t m) { pt1_entry_t *pte1p, opte1 __unused; pt2_entry_t *pte2p; uint32_t i; KASSERT(pt2pg_is_empty(m), ("%s: pmap %p PT2PG %p wired", __func__, pmap, m)); /* * Unmap all L2 page tables in the page from L1 page table. * * QQQ: Individual L2 page tables (except the last one) can be unmapped * earlier. However, we are doing that this way. */ KASSERT(m->pindex == (pte1_index(va) & ~PT2PG_MASK), ("%s: pmap %p va %#x PT2PG %p bad index", __func__, pmap, va, m)); pte1p = pmap->pm_pt1 + m->pindex; for (i = 0; i < NPT2_IN_PG; i++, pte1p++) { KASSERT(m->md.pt2_wirecount[i] == 0, ("%s: pmap %p PT2 %u (PG %p) wired", __func__, pmap, i, m)); opte1 = pte1_load(pte1p); if (pte1_is_link(opte1)) { pte1_clear(pte1p); /* * Flush intermediate TLB cache. */ pmap_tlb_flush(pmap, (m->pindex + i) << PTE1_SHIFT); } #ifdef INVARIANTS else KASSERT((opte1 == 0) || pte1_is_section(opte1), ("%s: pmap %p va %#x bad pte1 %x at %u", __func__, pmap, va, opte1, i)); #endif } /* * Unmap the page from PT2TAB. */ pte2p = pmap_pt2tab_entry(pmap, va); (void)pt2tab_load_clear(pte2p); pmap_tlb_flush(pmap, pt2map_pt2pg(va)); m->ref_count = 0; pmap->pm_stats.resident_count--; /* * This barrier is so that the ordinary store unmapping * the L2 page table page is globally performed before TLB shoot- * down is begun. */ wmb(); vm_wire_sub(1); } /* * Decrements a L2 page table page's wire count, which is used to record the * number of valid page table entries within the page. If the wire count * drops to zero, then the page table page is unmapped. Returns TRUE if the * page table page was unmapped and FALSE otherwise. */ static __inline boolean_t pmap_unwire_pt2(pmap_t pmap, vm_offset_t va, vm_page_t m, struct spglist *free) { pt2_wirecount_dec(m, pte1_index(va)); if (pt2pg_is_empty(m)) { /* * QQQ: Wire count is zero, so whole page should be zero and * we can set PG_ZERO flag to it. * Note that when promotion is enabled, it takes some * more efforts. See pmap_unwire_pt2_all() below. */ pmap_unwire_pt2pg(pmap, va, m); pmap_add_delayed_free_list(m, free); return (TRUE); } else return (FALSE); } /* * Drop a L2 page table page's wire count at once, which is used to record * the number of valid L2 page table entries within the page. If the wire * count drops to zero, then the L2 page table page is unmapped. */ static __inline void pmap_unwire_pt2_all(pmap_t pmap, vm_offset_t va, vm_page_t m, struct spglist *free) { u_int pte1_idx = pte1_index(va); KASSERT(m->pindex == (pte1_idx & ~PT2PG_MASK), ("%s: PT2 page's pindex is wrong", __func__)); KASSERT(m->ref_count > pt2_wirecount_get(m, pte1_idx), ("%s: bad pt2 wire count %u > %u", __func__, m->ref_count, pt2_wirecount_get(m, pte1_idx))); /* * It's possible that the L2 page table was never used. * It happened in case that a section was created without promotion. */ if (pt2_is_full(m, va)) { pt2_wirecount_set(m, pte1_idx, 0); /* * QQQ: We clear L2 page table now, so when L2 page table page * is going to be freed, we can set it PG_ZERO flag ... * This function is called only on section mappings, so * hopefully it's not to big overload. * * XXX: If pmap is current, existing PT2MAP mapping could be * used for zeroing. */ pmap_zero_page_area(m, page_pt2off(pte1_idx), NB_IN_PT2); } #ifdef INVARIANTS else KASSERT(pt2_is_empty(m, va), ("%s: PT2 is not empty (%u)", __func__, pt2_wirecount_get(m, pte1_idx))); #endif if (pt2pg_is_empty(m)) { pmap_unwire_pt2pg(pmap, va, m); pmap_add_delayed_free_list(m, free); } } /* * After removing a L2 page table entry, this routine is used to * conditionally free the page, and manage the hold/wire counts. */ static boolean_t pmap_unuse_pt2(pmap_t pmap, vm_offset_t va, struct spglist *free) { pt1_entry_t pte1; vm_page_t mpte; if (va >= VM_MAXUSER_ADDRESS) return (FALSE); pte1 = pte1_load(pmap_pte1(pmap, va)); mpte = PHYS_TO_VM_PAGE(pte1_link_pa(pte1)); return (pmap_unwire_pt2(pmap, va, mpte, free)); } /************************************* * * Page management routines. * *************************************/ static const uint32_t pc_freemask[_NPCM] = { [0 ... _NPCM - 2] = PC_FREEN, [_NPCM - 1] = PC_FREEL }; SYSCTL_INT(_vm_pmap, OID_AUTO, pv_entry_count, CTLFLAG_RD, &pv_entry_count, 0, "Current number of pv entries"); #ifdef PV_STATS static int pc_chunk_count, pc_chunk_allocs, pc_chunk_frees, pc_chunk_tryfail; SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_count, CTLFLAG_RD, &pc_chunk_count, 0, "Current number of pv entry chunks"); SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_allocs, CTLFLAG_RD, &pc_chunk_allocs, 0, "Current number of pv entry chunks allocated"); SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_frees, CTLFLAG_RD, &pc_chunk_frees, 0, "Current number of pv entry chunks frees"); SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_tryfail, CTLFLAG_RD, &pc_chunk_tryfail, 0, "Number of times tried to get a chunk page but failed."); static long pv_entry_frees, pv_entry_allocs; static int pv_entry_spare; SYSCTL_LONG(_vm_pmap, OID_AUTO, pv_entry_frees, CTLFLAG_RD, &pv_entry_frees, 0, "Current number of pv entry frees"); SYSCTL_LONG(_vm_pmap, OID_AUTO, pv_entry_allocs, CTLFLAG_RD, &pv_entry_allocs, 0, "Current number of pv entry allocs"); SYSCTL_INT(_vm_pmap, OID_AUTO, pv_entry_spare, CTLFLAG_RD, &pv_entry_spare, 0, "Current number of spare pv entries"); #endif /* * Is given page managed? */ static __inline bool is_managed(vm_paddr_t pa) { vm_page_t m; m = PHYS_TO_VM_PAGE(pa); if (m == NULL) return (false); return ((m->oflags & VPO_UNMANAGED) == 0); } static __inline bool pte1_is_managed(pt1_entry_t pte1) { return (is_managed(pte1_pa(pte1))); } static __inline bool pte2_is_managed(pt2_entry_t pte2) { return (is_managed(pte2_pa(pte2))); } /* * We are in a serious low memory condition. Resort to * drastic measures to free some pages so we can allocate * another pv entry chunk. */ static vm_page_t pmap_pv_reclaim(pmap_t locked_pmap) { struct pch newtail; struct pv_chunk *pc; struct md_page *pvh; pt1_entry_t *pte1p; pmap_t pmap; pt2_entry_t *pte2p, tpte2; pv_entry_t pv; vm_offset_t va; vm_page_t m, m_pc; struct spglist free; uint32_t inuse; int bit, field, freed; PMAP_LOCK_ASSERT(locked_pmap, MA_OWNED); pmap = NULL; m_pc = NULL; SLIST_INIT(&free); TAILQ_INIT(&newtail); while ((pc = TAILQ_FIRST(&pv_chunks)) != NULL && (pv_vafree == 0 || SLIST_EMPTY(&free))) { TAILQ_REMOVE(&pv_chunks, pc, pc_lru); if (pmap != pc->pc_pmap) { if (pmap != NULL) { if (pmap != locked_pmap) PMAP_UNLOCK(pmap); } pmap = pc->pc_pmap; /* Avoid deadlock and lock recursion. */ if (pmap > locked_pmap) PMAP_LOCK(pmap); else if (pmap != locked_pmap && !PMAP_TRYLOCK(pmap)) { pmap = NULL; TAILQ_INSERT_TAIL(&newtail, pc, pc_lru); continue; } } /* * Destroy every non-wired, 4 KB page mapping in the chunk. */ freed = 0; for (field = 0; field < _NPCM; field++) { for (inuse = ~pc->pc_map[field] & pc_freemask[field]; inuse != 0; inuse &= ~(1UL << bit)) { bit = ffs(inuse) - 1; pv = &pc->pc_pventry[field * 32 + bit]; va = pv->pv_va; pte1p = pmap_pte1(pmap, va); if (pte1_is_section(pte1_load(pte1p))) continue; pte2p = pmap_pte2(pmap, va); tpte2 = pte2_load(pte2p); if ((tpte2 & PTE2_W) == 0) tpte2 = pte2_load_clear(pte2p); pmap_pte2_release(pte2p); if ((tpte2 & PTE2_W) != 0) continue; KASSERT(tpte2 != 0, ("pmap_pv_reclaim: pmap %p va %#x zero pte", pmap, va)); pmap_tlb_flush(pmap, va); m = PHYS_TO_VM_PAGE(pte2_pa(tpte2)); if (pte2_is_dirty(tpte2)) vm_page_dirty(m); if ((tpte2 & PTE2_A) != 0) vm_page_aflag_set(m, PGA_REFERENCED); TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); if (TAILQ_EMPTY(&m->md.pv_list) && (m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); if (TAILQ_EMPTY(&pvh->pv_list)) { vm_page_aflag_clear(m, PGA_WRITEABLE); } } pc->pc_map[field] |= 1UL << bit; pmap_unuse_pt2(pmap, va, &free); freed++; } } if (freed == 0) { TAILQ_INSERT_TAIL(&newtail, pc, pc_lru); continue; } /* Every freed mapping is for a 4 KB page. */ pmap->pm_stats.resident_count -= freed; PV_STAT(pv_entry_frees += freed); PV_STAT(pv_entry_spare += freed); pv_entry_count -= freed; TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); for (field = 0; field < _NPCM; field++) if (pc->pc_map[field] != pc_freemask[field]) { TAILQ_INSERT_HEAD(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&newtail, pc, pc_lru); /* * One freed pv entry in locked_pmap is * sufficient. */ if (pmap == locked_pmap) goto out; break; } if (field == _NPCM) { PV_STAT(pv_entry_spare -= _NPCPV); PV_STAT(pc_chunk_count--); PV_STAT(pc_chunk_frees++); /* Entire chunk is free; return it. */ m_pc = PHYS_TO_VM_PAGE(pmap_kextract((vm_offset_t)pc)); pmap_qremove((vm_offset_t)pc, 1); pmap_pte2list_free(&pv_vafree, (vm_offset_t)pc); break; } } out: TAILQ_CONCAT(&pv_chunks, &newtail, pc_lru); if (pmap != NULL) { if (pmap != locked_pmap) PMAP_UNLOCK(pmap); } if (m_pc == NULL && pv_vafree != 0 && SLIST_EMPTY(&free)) { m_pc = SLIST_FIRST(&free); SLIST_REMOVE_HEAD(&free, plinks.s.ss); /* Recycle a freed page table page. */ m_pc->ref_count = 1; vm_wire_add(1); } vm_page_free_pages_toq(&free, false); return (m_pc); } static void free_pv_chunk(struct pv_chunk *pc) { vm_page_t m; TAILQ_REMOVE(&pv_chunks, pc, pc_lru); PV_STAT(pv_entry_spare -= _NPCPV); PV_STAT(pc_chunk_count--); PV_STAT(pc_chunk_frees++); /* entire chunk is free, return it */ m = PHYS_TO_VM_PAGE(pmap_kextract((vm_offset_t)pc)); pmap_qremove((vm_offset_t)pc, 1); vm_page_unwire_noq(m); vm_page_free(m); pmap_pte2list_free(&pv_vafree, (vm_offset_t)pc); } /* * Free the pv_entry back to the free list. */ static void free_pv_entry(pmap_t pmap, pv_entry_t pv) { struct pv_chunk *pc; int idx, field, bit; rw_assert(&pvh_global_lock, RA_WLOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); PV_STAT(pv_entry_frees++); PV_STAT(pv_entry_spare++); pv_entry_count--; pc = pv_to_chunk(pv); idx = pv - &pc->pc_pventry[0]; field = idx / 32; bit = idx % 32; pc->pc_map[field] |= 1ul << bit; for (idx = 0; idx < _NPCM; idx++) if (pc->pc_map[idx] != pc_freemask[idx]) { /* * 98% of the time, pc is already at the head of the * list. If it isn't already, move it to the head. */ if (__predict_false(TAILQ_FIRST(&pmap->pm_pvchunk) != pc)) { TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_HEAD(&pmap->pm_pvchunk, pc, pc_list); } return; } TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); free_pv_chunk(pc); } /* * Get a new pv_entry, allocating a block from the system * when needed. */ static pv_entry_t get_pv_entry(pmap_t pmap, boolean_t try) { static const struct timeval printinterval = { 60, 0 }; static struct timeval lastprint; int bit, field; pv_entry_t pv; struct pv_chunk *pc; vm_page_t m; rw_assert(&pvh_global_lock, RA_WLOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); PV_STAT(pv_entry_allocs++); pv_entry_count++; if (pv_entry_count > pv_entry_high_water) if (ratecheck(&lastprint, &printinterval)) printf("Approaching the limit on PV entries, consider " "increasing either the vm.pmap.shpgperproc or the " "vm.pmap.pv_entries tunable.\n"); retry: pc = TAILQ_FIRST(&pmap->pm_pvchunk); if (pc != NULL) { for (field = 0; field < _NPCM; field++) { if (pc->pc_map[field]) { bit = ffs(pc->pc_map[field]) - 1; break; } } if (field < _NPCM) { pv = &pc->pc_pventry[field * 32 + bit]; pc->pc_map[field] &= ~(1ul << bit); /* If this was the last item, move it to tail */ for (field = 0; field < _NPCM; field++) if (pc->pc_map[field] != 0) { PV_STAT(pv_entry_spare--); return (pv); /* not full, return */ } TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&pmap->pm_pvchunk, pc, pc_list); PV_STAT(pv_entry_spare--); return (pv); } } /* * Access to the pte2list "pv_vafree" is synchronized by the pvh * global lock. If "pv_vafree" is currently non-empty, it will * remain non-empty until pmap_pte2list_alloc() completes. */ if (pv_vafree == 0 || (m = vm_page_alloc_noobj(VM_ALLOC_WIRED)) == NULL) { if (try) { pv_entry_count--; PV_STAT(pc_chunk_tryfail++); return (NULL); } m = pmap_pv_reclaim(pmap); if (m == NULL) goto retry; } PV_STAT(pc_chunk_count++); PV_STAT(pc_chunk_allocs++); pc = (struct pv_chunk *)pmap_pte2list_alloc(&pv_vafree); pmap_qenter((vm_offset_t)pc, &m, 1); pc->pc_pmap = pmap; pc->pc_map[0] = pc_freemask[0] & ~1ul; /* preallocated bit 0 */ for (field = 1; field < _NPCM; field++) pc->pc_map[field] = pc_freemask[field]; TAILQ_INSERT_TAIL(&pv_chunks, pc, pc_lru); pv = &pc->pc_pventry[0]; TAILQ_INSERT_HEAD(&pmap->pm_pvchunk, pc, pc_list); PV_STAT(pv_entry_spare += _NPCPV - 1); return (pv); } /* * Create a pv entry for page at pa for * (pmap, va). */ static void pmap_insert_entry(pmap_t pmap, vm_offset_t va, vm_page_t m) { pv_entry_t pv; rw_assert(&pvh_global_lock, RA_WLOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); pv = get_pv_entry(pmap, FALSE); pv->pv_va = va; TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); } static __inline pv_entry_t pmap_pvh_remove(struct md_page *pvh, pmap_t pmap, vm_offset_t va) { pv_entry_t pv; rw_assert(&pvh_global_lock, RA_WLOCKED); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { if (pmap == PV_PMAP(pv) && va == pv->pv_va) { TAILQ_REMOVE(&pvh->pv_list, pv, pv_next); break; } } return (pv); } static void pmap_pvh_free(struct md_page *pvh, pmap_t pmap, vm_offset_t va) { pv_entry_t pv; pv = pmap_pvh_remove(pvh, pmap, va); KASSERT(pv != NULL, ("pmap_pvh_free: pv not found")); free_pv_entry(pmap, pv); } static void pmap_remove_entry(pmap_t pmap, vm_page_t m, vm_offset_t va) { struct md_page *pvh; rw_assert(&pvh_global_lock, RA_WLOCKED); pmap_pvh_free(&m->md, pmap, va); if (TAILQ_EMPTY(&m->md.pv_list) && (m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); if (TAILQ_EMPTY(&pvh->pv_list)) vm_page_aflag_clear(m, PGA_WRITEABLE); } } static void pmap_pv_demote_pte1(pmap_t pmap, vm_offset_t va, vm_paddr_t pa) { struct md_page *pvh; pv_entry_t pv; vm_offset_t va_last; vm_page_t m; rw_assert(&pvh_global_lock, RA_WLOCKED); KASSERT((pa & PTE1_OFFSET) == 0, ("pmap_pv_demote_pte1: pa is not 1mpage aligned")); /* * Transfer the 1mpage's pv entry for this mapping to the first * page's pv list. */ pvh = pa_to_pvh(pa); va = pte1_trunc(va); pv = pmap_pvh_remove(pvh, pmap, va); KASSERT(pv != NULL, ("pmap_pv_demote_pte1: pv not found")); m = PHYS_TO_VM_PAGE(pa); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); /* Instantiate the remaining NPTE2_IN_PT2 - 1 pv entries. */ va_last = va + PTE1_SIZE - PAGE_SIZE; do { m++; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_pv_demote_pte1: page %p is not managed", m)); va += PAGE_SIZE; pmap_insert_entry(pmap, va, m); } while (va < va_last); } #if VM_NRESERVLEVEL > 0 static void pmap_pv_promote_pte1(pmap_t pmap, vm_offset_t va, vm_paddr_t pa) { struct md_page *pvh; pv_entry_t pv; vm_offset_t va_last; vm_page_t m; rw_assert(&pvh_global_lock, RA_WLOCKED); KASSERT((pa & PTE1_OFFSET) == 0, ("pmap_pv_promote_pte1: pa is not 1mpage aligned")); /* * Transfer the first page's pv entry for this mapping to the * 1mpage's pv list. Aside from avoiding the cost of a call * to get_pv_entry(), a transfer avoids the possibility that * get_pv_entry() calls pmap_pv_reclaim() and that pmap_pv_reclaim() * removes one of the mappings that is being promoted. */ m = PHYS_TO_VM_PAGE(pa); va = pte1_trunc(va); pv = pmap_pvh_remove(&m->md, pmap, va); KASSERT(pv != NULL, ("pmap_pv_promote_pte1: pv not found")); pvh = pa_to_pvh(pa); TAILQ_INSERT_TAIL(&pvh->pv_list, pv, pv_next); /* Free the remaining NPTE2_IN_PT2 - 1 pv entries. */ va_last = va + PTE1_SIZE - PAGE_SIZE; do { m++; va += PAGE_SIZE; pmap_pvh_free(&m->md, pmap, va); } while (va < va_last); } #endif /* * Conditionally create a pv entry. */ static boolean_t pmap_try_insert_pv_entry(pmap_t pmap, vm_offset_t va, vm_page_t m) { pv_entry_t pv; rw_assert(&pvh_global_lock, RA_WLOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); if (pv_entry_count < pv_entry_high_water && (pv = get_pv_entry(pmap, TRUE)) != NULL) { pv->pv_va = va; TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); return (TRUE); } else return (FALSE); } /* * Create the pv entries for each of the pages within a section. */ static bool pmap_pv_insert_pte1(pmap_t pmap, vm_offset_t va, pt1_entry_t pte1, u_int flags) { struct md_page *pvh; pv_entry_t pv; bool noreclaim; rw_assert(&pvh_global_lock, RA_WLOCKED); noreclaim = (flags & PMAP_ENTER_NORECLAIM) != 0; if ((noreclaim && pv_entry_count >= pv_entry_high_water) || (pv = get_pv_entry(pmap, noreclaim)) == NULL) return (false); pv->pv_va = va; pvh = pa_to_pvh(pte1_pa(pte1)); TAILQ_INSERT_TAIL(&pvh->pv_list, pv, pv_next); return (true); } static inline void pmap_tlb_flush_pte1(pmap_t pmap, vm_offset_t va, pt1_entry_t npte1) { /* Kill all the small mappings or the big one only. */ if (pte1_is_section(npte1)) pmap_tlb_flush_range(pmap, pte1_trunc(va), PTE1_SIZE); else pmap_tlb_flush(pmap, pte1_trunc(va)); } /* * Update kernel pte1 on all pmaps. * * The following function is called only on one cpu with disabled interrupts. * In SMP case, smp_rendezvous_cpus() is used to stop other cpus. This way * nobody can invoke explicit hardware table walk during the update of pte1. * Unsolicited hardware table walk can still happen, invoked by speculative * data or instruction prefetch or even by speculative hardware table walk. * * The break-before-make approach should be implemented here. However, it's * not so easy to do that for kernel mappings as it would be unhappy to unmap * itself unexpectedly but voluntarily. */ static void pmap_update_pte1_kernel(vm_offset_t va, pt1_entry_t npte1) { pmap_t pmap; pt1_entry_t *pte1p; /* * Get current pmap. Interrupts should be disabled here * so PCPU_GET() is done atomically. */ pmap = PCPU_GET(curpmap); if (pmap == NULL) pmap = kernel_pmap; /* * (1) Change pte1 on current pmap. * (2) Flush all obsolete TLB entries on current CPU. * (3) Change pte1 on all pmaps. * (4) Flush all obsolete TLB entries on all CPUs in SMP case. */ pte1p = pmap_pte1(pmap, va); pte1_store(pte1p, npte1); /* Kill all the small mappings or the big one only. */ if (pte1_is_section(npte1)) { pmap_pte1_kern_promotions++; tlb_flush_range_local(pte1_trunc(va), PTE1_SIZE); } else { pmap_pte1_kern_demotions++; tlb_flush_local(pte1_trunc(va)); } /* * In SMP case, this function is called when all cpus are at smp * rendezvous, so there is no need to use 'allpmaps_lock' lock here. * In UP case, the function is called with this lock locked. */ LIST_FOREACH(pmap, &allpmaps, pm_list) { pte1p = pmap_pte1(pmap, va); pte1_store(pte1p, npte1); } #ifdef SMP /* Kill all the small mappings or the big one only. */ if (pte1_is_section(npte1)) tlb_flush_range(pte1_trunc(va), PTE1_SIZE); else tlb_flush(pte1_trunc(va)); #endif } #ifdef SMP struct pte1_action { vm_offset_t va; pt1_entry_t npte1; u_int update; /* CPU that updates the PTE1 */ }; static void pmap_update_pte1_action(void *arg) { struct pte1_action *act = arg; if (act->update == PCPU_GET(cpuid)) pmap_update_pte1_kernel(act->va, act->npte1); } /* * Change pte1 on current pmap. * Note that kernel pte1 must be changed on all pmaps. * * According to the architecture reference manual published by ARM, * the behaviour is UNPREDICTABLE when two or more TLB entries map the same VA. * According to this manual, UNPREDICTABLE behaviours must never happen in * a viable system. In contrast, on x86 processors, it is not specified which * TLB entry mapping the virtual address will be used, but the MMU doesn't * generate a bogus translation the way it does on Cortex-A8 rev 2 (Beaglebone * Black). * * It's a problem when either promotion or demotion is being done. The pte1 * update and appropriate TLB flush must be done atomically in general. */ static void pmap_change_pte1(pmap_t pmap, pt1_entry_t *pte1p, vm_offset_t va, pt1_entry_t npte1) { if (pmap == kernel_pmap) { struct pte1_action act; sched_pin(); act.va = va; act.npte1 = npte1; act.update = PCPU_GET(cpuid); smp_rendezvous_cpus(all_cpus, smp_no_rendezvous_barrier, pmap_update_pte1_action, NULL, &act); sched_unpin(); } else { register_t cspr; /* * Use break-before-make approach for changing userland * mappings. It can cause L1 translation aborts on other * cores in SMP case. So, special treatment is implemented * in pmap_fault(). To reduce the likelihood that another core * will be affected by the broken mapping, disable interrupts * until the mapping change is completed. */ cspr = disable_interrupts(PSR_I | PSR_F); pte1_clear(pte1p); pmap_tlb_flush_pte1(pmap, va, npte1); pte1_store(pte1p, npte1); restore_interrupts(cspr); } } #else static void pmap_change_pte1(pmap_t pmap, pt1_entry_t *pte1p, vm_offset_t va, pt1_entry_t npte1) { if (pmap == kernel_pmap) { mtx_lock_spin(&allpmaps_lock); pmap_update_pte1_kernel(va, npte1); mtx_unlock_spin(&allpmaps_lock); } else { register_t cspr; /* * Use break-before-make approach for changing userland * mappings. It's absolutely safe in UP case when interrupts * are disabled. */ cspr = disable_interrupts(PSR_I | PSR_F); pte1_clear(pte1p); pmap_tlb_flush_pte1(pmap, va, npte1); pte1_store(pte1p, npte1); restore_interrupts(cspr); } } #endif #if VM_NRESERVLEVEL > 0 /* * Tries to promote the NPTE2_IN_PT2, contiguous 4KB page mappings that are * within a single page table page (PT2) to a single 1MB page mapping. * For promotion to occur, two conditions must be met: (1) the 4KB page * mappings must map aligned, contiguous physical memory and (2) the 4KB page * mappings must have identical characteristics. * * Managed (PG_MANAGED) mappings within the kernel address space are not * promoted. The reason is that kernel PTE1s are replicated in each pmap but * pmap_remove_write(), pmap_clear_modify(), and pmap_clear_reference() only * read the PTE1 from the kernel pmap. */ static void pmap_promote_pte1(pmap_t pmap, pt1_entry_t *pte1p, vm_offset_t va) { pt1_entry_t npte1; pt2_entry_t *fpte2p, fpte2, fpte2_fav; pt2_entry_t *pte2p, pte2; vm_offset_t pteva __unused; vm_page_t m __unused; PDEBUG(6, printf("%s(%p): try for va %#x pte1 %#x at %p\n", __func__, pmap, va, pte1_load(pte1p), pte1p)); PMAP_LOCK_ASSERT(pmap, MA_OWNED); /* * Examine the first PTE2 in the specified PT2. Abort if this PTE2 is * either invalid, unused, or does not map the first 4KB physical page * within a 1MB page. */ fpte2p = pmap_pte2_quick(pmap, pte1_trunc(va)); fpte2 = pte2_load(fpte2p); if ((fpte2 & ((PTE2_FRAME & PTE1_OFFSET) | PTE2_A | PTE2_V)) != (PTE2_A | PTE2_V)) { pmap_pte1_p_failures++; CTR3(KTR_PMAP, "%s: failure(1) for va %#x in pmap %p", __func__, va, pmap); return; } if (pte2_is_managed(fpte2) && pmap == kernel_pmap) { pmap_pte1_p_failures++; CTR3(KTR_PMAP, "%s: failure(2) for va %#x in pmap %p", __func__, va, pmap); return; } if ((fpte2 & (PTE2_NM | PTE2_RO)) == PTE2_NM) { /* * When page is not modified, PTE2_RO can be set without * a TLB invalidation. */ fpte2 |= PTE2_RO; pte2_store(fpte2p, fpte2); } /* * Examine each of the other PTE2s in the specified PT2. Abort if this * PTE2 maps an unexpected 4KB physical page or does not have identical * characteristics to the first PTE2. */ fpte2_fav = (fpte2 & (PTE2_FRAME | PTE2_A | PTE2_V)); fpte2_fav += PTE1_SIZE - PTE2_SIZE; /* examine from the end */ for (pte2p = fpte2p + NPTE2_IN_PT2 - 1; pte2p > fpte2p; pte2p--) { pte2 = pte2_load(pte2p); if ((pte2 & (PTE2_FRAME | PTE2_A | PTE2_V)) != fpte2_fav) { pmap_pte1_p_failures++; CTR3(KTR_PMAP, "%s: failure(3) for va %#x in pmap %p", __func__, va, pmap); return; } if ((pte2 & (PTE2_NM | PTE2_RO)) == PTE2_NM) { /* * When page is not modified, PTE2_RO can be set * without a TLB invalidation. See note above. */ pte2 |= PTE2_RO; pte2_store(pte2p, pte2); pteva = pte1_trunc(va) | (pte2 & PTE1_OFFSET & PTE2_FRAME); CTR3(KTR_PMAP, "%s: protect for va %#x in pmap %p", __func__, pteva, pmap); } if ((pte2 & PTE2_PROMOTE) != (fpte2 & PTE2_PROMOTE)) { pmap_pte1_p_failures++; CTR3(KTR_PMAP, "%s: failure(4) for va %#x in pmap %p", __func__, va, pmap); return; } fpte2_fav -= PTE2_SIZE; } /* * The page table page in its current state will stay in PT2TAB * until the PTE1 mapping the section is demoted by pmap_demote_pte1() * or destroyed by pmap_remove_pte1(). * * Note that L2 page table size is not equal to PAGE_SIZE. */ m = PHYS_TO_VM_PAGE(trunc_page(pte1_link_pa(pte1_load(pte1p)))); KASSERT(m >= vm_page_array && m < &vm_page_array[vm_page_array_size], ("%s: PT2 page is out of range", __func__)); KASSERT(m->pindex == (pte1_index(va) & ~PT2PG_MASK), ("%s: PT2 page's pindex is wrong", __func__)); /* * Get pte1 from pte2 format. */ npte1 = (fpte2 & PTE1_FRAME) | ATTR_TO_L1(fpte2) | PTE1_V; /* * Promote the pv entries. */ if (pte2_is_managed(fpte2)) pmap_pv_promote_pte1(pmap, va, pte1_pa(npte1)); /* * Promote the mappings. */ pmap_change_pte1(pmap, pte1p, va, npte1); pmap_pte1_promotions++; CTR3(KTR_PMAP, "%s: success for va %#x in pmap %p", __func__, va, pmap); PDEBUG(6, printf("%s(%p): success for va %#x pte1 %#x(%#x) at %p\n", __func__, pmap, va, npte1, pte1_load(pte1p), pte1p)); } #endif /* VM_NRESERVLEVEL > 0 */ /* * Zero L2 page table page. */ static __inline void pmap_clear_pt2(pt2_entry_t *fpte2p) { pt2_entry_t *pte2p; for (pte2p = fpte2p; pte2p < fpte2p + NPTE2_IN_PT2; pte2p++) pte2_clear(pte2p); } /* * Removes a 1MB page mapping from the kernel pmap. */ static void pmap_remove_kernel_pte1(pmap_t pmap, pt1_entry_t *pte1p, vm_offset_t va) { vm_page_t m; uint32_t pte1_idx; pt2_entry_t *fpte2p; vm_paddr_t pt2_pa; PMAP_LOCK_ASSERT(pmap, MA_OWNED); m = pmap_pt2_page(pmap, va); if (m == NULL) /* * QQQ: Is this function called only on promoted pte1? * We certainly do section mappings directly * (without promotion) in kernel !!! */ panic("%s: missing pt2 page", __func__); pte1_idx = pte1_index(va); /* * Initialize the L2 page table. */ fpte2p = page_pt2(pt2map_pt2pg(va), pte1_idx); pmap_clear_pt2(fpte2p); /* * Remove the mapping. */ pt2_pa = page_pt2pa(VM_PAGE_TO_PHYS(m), pte1_idx); pmap_kenter_pte1(va, PTE1_LINK(pt2_pa)); /* * QQQ: We do not need to invalidate PT2MAP mapping * as we did not change it. I.e. the L2 page table page * was and still is mapped the same way. */ } /* * Do the things to unmap a section in a process */ static void pmap_remove_pte1(pmap_t pmap, pt1_entry_t *pte1p, vm_offset_t sva, struct spglist *free) { pt1_entry_t opte1; struct md_page *pvh; vm_offset_t eva, va; vm_page_t m; PDEBUG(6, printf("%s(%p): va %#x pte1 %#x at %p\n", __func__, pmap, sva, pte1_load(pte1p), pte1p)); PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT((sva & PTE1_OFFSET) == 0, ("%s: sva is not 1mpage aligned", __func__)); /* * Clear and invalidate the mapping. It should occupy one and only TLB * entry. So, pmap_tlb_flush() called with aligned address should be * sufficient. */ opte1 = pte1_load_clear(pte1p); pmap_tlb_flush(pmap, sva); if (pte1_is_wired(opte1)) pmap->pm_stats.wired_count -= PTE1_SIZE / PAGE_SIZE; pmap->pm_stats.resident_count -= PTE1_SIZE / PAGE_SIZE; if (pte1_is_managed(opte1)) { pvh = pa_to_pvh(pte1_pa(opte1)); pmap_pvh_free(pvh, pmap, sva); eva = sva + PTE1_SIZE; for (va = sva, m = PHYS_TO_VM_PAGE(pte1_pa(opte1)); va < eva; va += PAGE_SIZE, m++) { if (pte1_is_dirty(opte1)) vm_page_dirty(m); if (opte1 & PTE1_A) vm_page_aflag_set(m, PGA_REFERENCED); if (TAILQ_EMPTY(&m->md.pv_list) && TAILQ_EMPTY(&pvh->pv_list)) vm_page_aflag_clear(m, PGA_WRITEABLE); } } if (pmap == kernel_pmap) { /* * L2 page table(s) can't be removed from kernel map as * kernel counts on it (stuff around pmap_growkernel()). */ pmap_remove_kernel_pte1(pmap, pte1p, sva); } else { /* * Get associated L2 page table page. * It's possible that the page was never allocated. */ m = pmap_pt2_page(pmap, sva); if (m != NULL) pmap_unwire_pt2_all(pmap, sva, m, free); } } /* * Fills L2 page table page with mappings to consecutive physical pages. */ static __inline void pmap_fill_pt2(pt2_entry_t *fpte2p, pt2_entry_t npte2) { pt2_entry_t *pte2p; for (pte2p = fpte2p; pte2p < fpte2p + NPTE2_IN_PT2; pte2p++) { pte2_store(pte2p, npte2); npte2 += PTE2_SIZE; } } /* * Tries to demote a 1MB page mapping. If demotion fails, the * 1MB page mapping is invalidated. */ static boolean_t pmap_demote_pte1(pmap_t pmap, pt1_entry_t *pte1p, vm_offset_t va) { pt1_entry_t opte1, npte1; pt2_entry_t *fpte2p, npte2; vm_paddr_t pt2pg_pa, pt2_pa; vm_page_t m; struct spglist free; uint32_t pte1_idx, isnew = 0; PDEBUG(6, printf("%s(%p): try for va %#x pte1 %#x at %p\n", __func__, pmap, va, pte1_load(pte1p), pte1p)); PMAP_LOCK_ASSERT(pmap, MA_OWNED); opte1 = pte1_load(pte1p); KASSERT(pte1_is_section(opte1), ("%s: opte1 not a section", __func__)); if ((opte1 & PTE1_A) == 0 || (m = pmap_pt2_page(pmap, va)) == NULL) { KASSERT(!pte1_is_wired(opte1), ("%s: PT2 page for a wired mapping is missing", __func__)); /* * Invalidate the 1MB page mapping and return * "failure" if the mapping was never accessed or the * allocation of the new page table page fails. */ if ((opte1 & PTE1_A) == 0 || (m = vm_page_alloc_noobj(VM_ALLOC_WIRED)) == NULL) { SLIST_INIT(&free); pmap_remove_pte1(pmap, pte1p, pte1_trunc(va), &free); vm_page_free_pages_toq(&free, false); CTR3(KTR_PMAP, "%s: failure for va %#x in pmap %p", __func__, va, pmap); return (FALSE); } m->pindex = pte1_index(va) & ~PT2PG_MASK; if (va < VM_MAXUSER_ADDRESS) pmap->pm_stats.resident_count++; isnew = 1; /* * We init all L2 page tables in the page even if * we are going to change everything for one L2 page * table in a while. */ pt2pg_pa = pmap_pt2pg_init(pmap, va, m); } else { if (va < VM_MAXUSER_ADDRESS) { if (pt2_is_empty(m, va)) isnew = 1; /* Demoting section w/o promotion. */ #ifdef INVARIANTS else KASSERT(pt2_is_full(m, va), ("%s: bad PT2 wire" " count %u", __func__, pt2_wirecount_get(m, pte1_index(va)))); #endif } } pt2pg_pa = VM_PAGE_TO_PHYS(m); pte1_idx = pte1_index(va); /* * If the pmap is current, then the PT2MAP can provide access to * the page table page (promoted L2 page tables are not unmapped). * Otherwise, temporarily map the L2 page table page (m) into * the kernel's address space at either PADDR1 or PADDR2. * * Note that L2 page table size is not equal to PAGE_SIZE. */ if (pmap_is_current(pmap)) fpte2p = page_pt2(pt2map_pt2pg(va), pte1_idx); else if (curthread->td_pinned > 0 && rw_wowned(&pvh_global_lock)) { if (pte2_pa(pte2_load(PMAP1)) != pt2pg_pa) { pte2_store(PMAP1, PTE2_KPT(pt2pg_pa)); #ifdef SMP PMAP1cpu = PCPU_GET(cpuid); #endif tlb_flush_local((vm_offset_t)PADDR1); PMAP1changed++; } else #ifdef SMP if (PMAP1cpu != PCPU_GET(cpuid)) { PMAP1cpu = PCPU_GET(cpuid); tlb_flush_local((vm_offset_t)PADDR1); PMAP1changedcpu++; } else #endif PMAP1unchanged++; fpte2p = page_pt2((vm_offset_t)PADDR1, pte1_idx); } else { mtx_lock(&PMAP2mutex); if (pte2_pa(pte2_load(PMAP2)) != pt2pg_pa) { pte2_store(PMAP2, PTE2_KPT(pt2pg_pa)); tlb_flush((vm_offset_t)PADDR2); } fpte2p = page_pt2((vm_offset_t)PADDR2, pte1_idx); } pt2_pa = page_pt2pa(pt2pg_pa, pte1_idx); npte1 = PTE1_LINK(pt2_pa); KASSERT((opte1 & PTE1_A) != 0, ("%s: opte1 is missing PTE1_A", __func__)); KASSERT((opte1 & (PTE1_NM | PTE1_RO)) != PTE1_NM, ("%s: opte1 has PTE1_NM", __func__)); /* * Get pte2 from pte1 format. */ npte2 = pte1_pa(opte1) | ATTR_TO_L2(opte1) | PTE2_V; /* * If the L2 page table page is new, initialize it. If the mapping * has changed attributes, update the page table entries. */ if (isnew != 0) { pt2_wirecount_set(m, pte1_idx, NPTE2_IN_PT2); pmap_fill_pt2(fpte2p, npte2); } else if ((pte2_load(fpte2p) & PTE2_PROMOTE) != (npte2 & PTE2_PROMOTE)) pmap_fill_pt2(fpte2p, npte2); KASSERT(pte2_pa(pte2_load(fpte2p)) == pte2_pa(npte2), ("%s: fpte2p and npte2 map different physical addresses", __func__)); if (fpte2p == PADDR2) mtx_unlock(&PMAP2mutex); /* * Demote the mapping. This pmap is locked. The old PTE1 has * PTE1_A set. If the old PTE1 has not PTE1_RO set, it also * has not PTE1_NM set. Thus, there is no danger of a race with * another processor changing the setting of PTE1_A and/or PTE1_NM * between the read above and the store below. */ pmap_change_pte1(pmap, pte1p, va, npte1); /* * Demote the pv entry. This depends on the earlier demotion * of the mapping. Specifically, the (re)creation of a per- * page pv entry might trigger the execution of pmap_pv_reclaim(), * which might reclaim a newly (re)created per-page pv entry * and destroy the associated mapping. In order to destroy * the mapping, the PTE1 must have already changed from mapping * the 1mpage to referencing the page table page. */ if (pte1_is_managed(opte1)) pmap_pv_demote_pte1(pmap, va, pte1_pa(opte1)); pmap_pte1_demotions++; CTR3(KTR_PMAP, "%s: success for va %#x in pmap %p", __func__, va, pmap); PDEBUG(6, printf("%s(%p): success for va %#x pte1 %#x(%#x) at %p\n", __func__, pmap, va, npte1, pte1_load(pte1p), pte1p)); return (TRUE); } /* * Insert the given physical page (p) at * the specified virtual address (v) in the * target physical map with the protection requested. * * If specified, the page will be wired down, meaning * that the related pte can not be reclaimed. * * NB: This is the only routine which MAY NOT lazy-evaluate * or lose information. That is, this routine must actually * insert this page into the given map NOW. */ int pmap_enter(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, u_int flags, int8_t psind) { pt1_entry_t *pte1p; pt2_entry_t *pte2p; pt2_entry_t npte2, opte2; pv_entry_t pv; vm_paddr_t opa, pa; vm_page_t mpte2, om; int rv; va = trunc_page(va); KASSERT(va <= vm_max_kernel_address, ("%s: toobig", __func__)); KASSERT(va < UPT2V_MIN_ADDRESS || va >= UPT2V_MAX_ADDRESS, ("%s: invalid to pmap_enter page table pages (va: 0x%x)", __func__, va)); KASSERT((m->oflags & VPO_UNMANAGED) != 0 || !VA_IS_CLEANMAP(va), ("%s: managed mapping within the clean submap", __func__)); if ((m->oflags & VPO_UNMANAGED) == 0) VM_PAGE_OBJECT_BUSY_ASSERT(m); KASSERT((flags & PMAP_ENTER_RESERVED) == 0, ("%s: flags %u has reserved bits set", __func__, flags)); pa = VM_PAGE_TO_PHYS(m); npte2 = PTE2(pa, PTE2_A, vm_page_pte2_attr(m)); if ((flags & VM_PROT_WRITE) == 0) npte2 |= PTE2_NM; if ((prot & VM_PROT_WRITE) == 0) npte2 |= PTE2_RO; KASSERT((npte2 & (PTE2_NM | PTE2_RO)) != PTE2_RO, ("%s: flags includes VM_PROT_WRITE but prot doesn't", __func__)); if ((prot & VM_PROT_EXECUTE) == 0) npte2 |= PTE2_NX; if ((flags & PMAP_ENTER_WIRED) != 0) npte2 |= PTE2_W; if (va < VM_MAXUSER_ADDRESS) npte2 |= PTE2_U; if (pmap != kernel_pmap) npte2 |= PTE2_NG; rw_wlock(&pvh_global_lock); PMAP_LOCK(pmap); sched_pin(); if (psind == 1) { /* Assert the required virtual and physical alignment. */ KASSERT((va & PTE1_OFFSET) == 0, ("%s: va unaligned", __func__)); KASSERT(m->psind > 0, ("%s: m->psind < psind", __func__)); rv = pmap_enter_pte1(pmap, va, PTE1_PA(pa) | ATTR_TO_L1(npte2) | PTE1_V, flags, m); goto out; } /* * In the case that a page table page is not * resident, we are creating it here. */ if (va < VM_MAXUSER_ADDRESS) { mpte2 = pmap_allocpte2(pmap, va, flags); if (mpte2 == NULL) { KASSERT((flags & PMAP_ENTER_NOSLEEP) != 0, ("pmap_allocpte2 failed with sleep allowed")); rv = KERN_RESOURCE_SHORTAGE; goto out; } } else mpte2 = NULL; pte1p = pmap_pte1(pmap, va); if (pte1_is_section(pte1_load(pte1p))) panic("%s: attempted on 1MB page", __func__); pte2p = pmap_pte2_quick(pmap, va); if (pte2p == NULL) panic("%s: invalid L1 page table entry va=%#x", __func__, va); om = NULL; opte2 = pte2_load(pte2p); opa = pte2_pa(opte2); /* * Mapping has not changed, must be protection or wiring change. */ if (pte2_is_valid(opte2) && (opa == pa)) { /* * Wiring change, just update stats. We don't worry about * wiring PT2 pages as they remain resident as long as there * are valid mappings in them. Hence, if a user page is wired, * the PT2 page will be also. */ if (pte2_is_wired(npte2) && !pte2_is_wired(opte2)) pmap->pm_stats.wired_count++; else if (!pte2_is_wired(npte2) && pte2_is_wired(opte2)) pmap->pm_stats.wired_count--; /* * Remove extra pte2 reference */ if (mpte2) pt2_wirecount_dec(mpte2, pte1_index(va)); if ((m->oflags & VPO_UNMANAGED) == 0) om = m; goto validate; } /* * QQQ: We think that changing physical address on writeable mapping * is not safe. Well, maybe on kernel address space with correct * locking, it can make a sense. However, we have no idea why * anyone should do that on user address space. Are we wrong? */ KASSERT((opa == 0) || (opa == pa) || !pte2_is_valid(opte2) || ((opte2 & PTE2_RO) != 0), ("%s: pmap %p va %#x(%#x) opa %#x pa %#x - gotcha %#x %#x!", __func__, pmap, va, opte2, opa, pa, flags, prot)); pv = NULL; /* * Mapping has changed, invalidate old range and fall through to * handle validating new mapping. */ if (opa) { if (pte2_is_wired(opte2)) pmap->pm_stats.wired_count--; om = PHYS_TO_VM_PAGE(opa); if (om != NULL && (om->oflags & VPO_UNMANAGED) != 0) om = NULL; if (om != NULL) pv = pmap_pvh_remove(&om->md, pmap, va); /* * Remove extra pte2 reference */ if (mpte2 != NULL) pt2_wirecount_dec(mpte2, va >> PTE1_SHIFT); } else pmap->pm_stats.resident_count++; /* * Enter on the PV list if part of our managed memory. */ if ((m->oflags & VPO_UNMANAGED) == 0) { if (pv == NULL) { pv = get_pv_entry(pmap, FALSE); pv->pv_va = va; } TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); } else if (pv != NULL) free_pv_entry(pmap, pv); /* * Increment counters */ if (pte2_is_wired(npte2)) pmap->pm_stats.wired_count++; validate: /* * Now validate mapping with desired protection/wiring. */ if (prot & VM_PROT_WRITE) { if ((m->oflags & VPO_UNMANAGED) == 0) vm_page_aflag_set(m, PGA_WRITEABLE); } /* * If the mapping or permission bits are different, we need * to update the pte2. * * QQQ: Think again and again what to do * if the mapping is going to be changed! */ if ((opte2 & ~(PTE2_NM | PTE2_A)) != (npte2 & ~(PTE2_NM | PTE2_A))) { /* * Sync icache if exec permission and attribute VM_MEMATTR_WB_WA * is set. Do it now, before the mapping is stored and made * valid for hardware table walk. If done later, there is a race * for other threads of current process in lazy loading case. * Don't do it for kernel memory which is mapped with exec * permission even if the memory isn't going to hold executable * code. The only time when icache sync is needed is after * kernel module is loaded and the relocation info is processed. * And it's done in elf_cpu_load_file(). * * QQQ: (1) Does it exist any better way where * or how to sync icache? * (2) Now, we do it on a page basis. */ if ((prot & VM_PROT_EXECUTE) && pmap != kernel_pmap && m->md.pat_mode == VM_MEMATTR_WB_WA && (opa != pa || (opte2 & PTE2_NX))) cache_icache_sync_fresh(va, pa, PAGE_SIZE); if (opte2 & PTE2_V) { /* Change mapping with break-before-make approach. */ opte2 = pte2_load_clear(pte2p); pmap_tlb_flush(pmap, va); pte2_store(pte2p, npte2); if (om != NULL) { KASSERT((om->oflags & VPO_UNMANAGED) == 0, ("%s: om %p unmanaged", __func__, om)); if ((opte2 & PTE2_A) != 0) vm_page_aflag_set(om, PGA_REFERENCED); if (pte2_is_dirty(opte2)) vm_page_dirty(om); if (TAILQ_EMPTY(&om->md.pv_list) && ((om->flags & PG_FICTITIOUS) != 0 || TAILQ_EMPTY(&pa_to_pvh(opa)->pv_list))) vm_page_aflag_clear(om, PGA_WRITEABLE); } } else pte2_store(pte2p, npte2); } #if 0 else { /* * QQQ: In time when both access and not mofified bits are * emulated by software, this should not happen. Some * analysis is need, if this really happen. Missing * tlb flush somewhere could be the reason. */ panic("%s: pmap %p va %#x opte2 %x npte2 %x !!", __func__, pmap, va, opte2, npte2); } #endif #if VM_NRESERVLEVEL > 0 /* * If both the L2 page table page and the reservation are fully * populated, then attempt promotion. */ if ((mpte2 == NULL || pt2_is_full(mpte2, va)) && sp_enabled && (m->flags & PG_FICTITIOUS) == 0 && vm_reserv_level_iffullpop(m) == 0) pmap_promote_pte1(pmap, pte1p, va); #endif rv = KERN_SUCCESS; out: sched_unpin(); rw_wunlock(&pvh_global_lock); PMAP_UNLOCK(pmap); return (rv); } /* * Do the things to unmap a page in a process. */ static int pmap_remove_pte2(pmap_t pmap, pt2_entry_t *pte2p, vm_offset_t va, struct spglist *free) { pt2_entry_t opte2; vm_page_t m; rw_assert(&pvh_global_lock, RA_WLOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); /* Clear and invalidate the mapping. */ opte2 = pte2_load_clear(pte2p); pmap_tlb_flush(pmap, va); KASSERT(pte2_is_valid(opte2), ("%s: pmap %p va %#x not link pte2 %#x", __func__, pmap, va, opte2)); if (opte2 & PTE2_W) pmap->pm_stats.wired_count -= 1; pmap->pm_stats.resident_count -= 1; if (pte2_is_managed(opte2)) { m = PHYS_TO_VM_PAGE(pte2_pa(opte2)); if (pte2_is_dirty(opte2)) vm_page_dirty(m); if (opte2 & PTE2_A) vm_page_aflag_set(m, PGA_REFERENCED); pmap_remove_entry(pmap, m, va); } return (pmap_unuse_pt2(pmap, va, free)); } /* * Remove a single page from a process address space. */ static void pmap_remove_page(pmap_t pmap, vm_offset_t va, struct spglist *free) { pt2_entry_t *pte2p; rw_assert(&pvh_global_lock, RA_WLOCKED); KASSERT(curthread->td_pinned > 0, ("%s: curthread not pinned", __func__)); PMAP_LOCK_ASSERT(pmap, MA_OWNED); if ((pte2p = pmap_pte2_quick(pmap, va)) == NULL || !pte2_is_valid(pte2_load(pte2p))) return; pmap_remove_pte2(pmap, pte2p, va, free); } /* * Remove the given range of addresses from the specified map. * * It is assumed that the start and end are properly * rounded to the page size. */ void pmap_remove(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { vm_offset_t nextva; pt1_entry_t *pte1p, pte1; pt2_entry_t *pte2p, pte2; struct spglist free; /* * Perform an unsynchronized read. This is, however, safe. */ if (pmap->pm_stats.resident_count == 0) return; SLIST_INIT(&free); rw_wlock(&pvh_global_lock); sched_pin(); PMAP_LOCK(pmap); /* * Special handling of removing one page. A very common * operation and easy to short circuit some code. */ if (sva + PAGE_SIZE == eva) { pte1 = pte1_load(pmap_pte1(pmap, sva)); if (pte1_is_link(pte1)) { pmap_remove_page(pmap, sva, &free); goto out; } } for (; sva < eva; sva = nextva) { /* * Calculate address for next L2 page table. */ nextva = pte1_trunc(sva + PTE1_SIZE); if (nextva < sva) nextva = eva; if (pmap->pm_stats.resident_count == 0) break; pte1p = pmap_pte1(pmap, sva); pte1 = pte1_load(pte1p); /* * Weed out invalid mappings. Note: we assume that the L1 page * table is always allocated, and in kernel virtual. */ if (pte1 == 0) continue; if (pte1_is_section(pte1)) { /* * Are we removing the entire large page? If not, * demote the mapping and fall through. */ if (sva + PTE1_SIZE == nextva && eva >= nextva) { pmap_remove_pte1(pmap, pte1p, sva, &free); continue; } else if (!pmap_demote_pte1(pmap, pte1p, sva)) { /* The large page mapping was destroyed. */ continue; } #ifdef INVARIANTS else { /* Update pte1 after demotion. */ pte1 = pte1_load(pte1p); } #endif } KASSERT(pte1_is_link(pte1), ("%s: pmap %p va %#x pte1 %#x at %p" " is not link", __func__, pmap, sva, pte1, pte1p)); /* * Limit our scan to either the end of the va represented * by the current L2 page table page, or to the end of the * range being removed. */ if (nextva > eva) nextva = eva; for (pte2p = pmap_pte2_quick(pmap, sva); sva != nextva; pte2p++, sva += PAGE_SIZE) { pte2 = pte2_load(pte2p); if (!pte2_is_valid(pte2)) continue; if (pmap_remove_pte2(pmap, pte2p, sva, &free)) break; } } out: sched_unpin(); rw_wunlock(&pvh_global_lock); PMAP_UNLOCK(pmap); vm_page_free_pages_toq(&free, false); } /* * Routine: pmap_remove_all * Function: * Removes this physical page from * all physical maps in which it resides. * Reflects back modify bits to the pager. * * Notes: * Original versions of this routine were very * inefficient because they iteratively called * pmap_remove (slow...) */ void pmap_remove_all(vm_page_t m) { struct md_page *pvh; pv_entry_t pv; pmap_t pmap; pt2_entry_t *pte2p, opte2; pt1_entry_t *pte1p; vm_offset_t va; struct spglist free; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("%s: page %p is not managed", __func__, m)); SLIST_INIT(&free); rw_wlock(&pvh_global_lock); sched_pin(); if ((m->flags & PG_FICTITIOUS) != 0) goto small_mappings; pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); while ((pv = TAILQ_FIRST(&pvh->pv_list)) != NULL) { va = pv->pv_va; pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pte1p = pmap_pte1(pmap, va); (void)pmap_demote_pte1(pmap, pte1p, va); PMAP_UNLOCK(pmap); } small_mappings: while ((pv = TAILQ_FIRST(&m->md.pv_list)) != NULL) { pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pmap->pm_stats.resident_count--; pte1p = pmap_pte1(pmap, pv->pv_va); KASSERT(!pte1_is_section(pte1_load(pte1p)), ("%s: found " "a 1mpage in page %p's pv list", __func__, m)); pte2p = pmap_pte2_quick(pmap, pv->pv_va); opte2 = pte2_load_clear(pte2p); pmap_tlb_flush(pmap, pv->pv_va); KASSERT(pte2_is_valid(opte2), ("%s: pmap %p va %x zero pte2", __func__, pmap, pv->pv_va)); if (pte2_is_wired(opte2)) pmap->pm_stats.wired_count--; if (opte2 & PTE2_A) vm_page_aflag_set(m, PGA_REFERENCED); /* * Update the vm_page_t clean and reference bits. */ if (pte2_is_dirty(opte2)) vm_page_dirty(m); pmap_unuse_pt2(pmap, pv->pv_va, &free); TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); free_pv_entry(pmap, pv); PMAP_UNLOCK(pmap); } vm_page_aflag_clear(m, PGA_WRITEABLE); sched_unpin(); rw_wunlock(&pvh_global_lock); vm_page_free_pages_toq(&free, false); } /* * Just subroutine for pmap_remove_pages() to reasonably satisfy * good coding style, a.k.a. 80 character line width limit hell. */ static __inline void pmap_remove_pte1_quick(pmap_t pmap, pt1_entry_t pte1, pv_entry_t pv, struct spglist *free) { vm_paddr_t pa; vm_page_t m, mt, mpt2pg; struct md_page *pvh; pa = pte1_pa(pte1); m = PHYS_TO_VM_PAGE(pa); KASSERT(m->phys_addr == pa, ("%s: vm_page_t %p addr mismatch %#x %#x", __func__, m, m->phys_addr, pa)); KASSERT((m->flags & PG_FICTITIOUS) != 0 || m < &vm_page_array[vm_page_array_size], ("%s: bad pte1 %#x", __func__, pte1)); if (pte1_is_dirty(pte1)) { for (mt = m; mt < &m[PTE1_SIZE / PAGE_SIZE]; mt++) vm_page_dirty(mt); } pmap->pm_stats.resident_count -= PTE1_SIZE / PAGE_SIZE; pvh = pa_to_pvh(pa); TAILQ_REMOVE(&pvh->pv_list, pv, pv_next); if (TAILQ_EMPTY(&pvh->pv_list)) { for (mt = m; mt < &m[PTE1_SIZE / PAGE_SIZE]; mt++) if (TAILQ_EMPTY(&mt->md.pv_list)) vm_page_aflag_clear(mt, PGA_WRITEABLE); } mpt2pg = pmap_pt2_page(pmap, pv->pv_va); if (mpt2pg != NULL) pmap_unwire_pt2_all(pmap, pv->pv_va, mpt2pg, free); } /* * Just subroutine for pmap_remove_pages() to reasonably satisfy * good coding style, a.k.a. 80 character line width limit hell. */ static __inline void pmap_remove_pte2_quick(pmap_t pmap, pt2_entry_t pte2, pv_entry_t pv, struct spglist *free) { vm_paddr_t pa; vm_page_t m; struct md_page *pvh; pa = pte2_pa(pte2); m = PHYS_TO_VM_PAGE(pa); KASSERT(m->phys_addr == pa, ("%s: vm_page_t %p addr mismatch %#x %#x", __func__, m, m->phys_addr, pa)); KASSERT((m->flags & PG_FICTITIOUS) != 0 || m < &vm_page_array[vm_page_array_size], ("%s: bad pte2 %#x", __func__, pte2)); if (pte2_is_dirty(pte2)) vm_page_dirty(m); pmap->pm_stats.resident_count--; TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); if (TAILQ_EMPTY(&m->md.pv_list) && (m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(pa); if (TAILQ_EMPTY(&pvh->pv_list)) vm_page_aflag_clear(m, PGA_WRITEABLE); } pmap_unuse_pt2(pmap, pv->pv_va, free); } /* * Remove all pages from specified address space this aids process * exit speeds. Also, this code is special cased for current process * only, but can have the more generic (and slightly slower) mode enabled. * This is much faster than pmap_remove in the case of running down * an entire address space. */ void pmap_remove_pages(pmap_t pmap) { pt1_entry_t *pte1p, pte1; pt2_entry_t *pte2p, pte2; pv_entry_t pv; struct pv_chunk *pc, *npc; struct spglist free; int field, idx; int32_t bit; uint32_t inuse, bitmask; boolean_t allfree; /* * Assert that the given pmap is only active on the current * CPU. Unfortunately, we cannot block another CPU from * activating the pmap while this function is executing. */ KASSERT(pmap == vmspace_pmap(curthread->td_proc->p_vmspace), ("%s: non-current pmap %p", __func__, pmap)); #if defined(SMP) && defined(INVARIANTS) { cpuset_t other_cpus; sched_pin(); other_cpus = pmap->pm_active; CPU_CLR(PCPU_GET(cpuid), &other_cpus); sched_unpin(); KASSERT(CPU_EMPTY(&other_cpus), ("%s: pmap %p active on other cpus", __func__, pmap)); } #endif SLIST_INIT(&free); rw_wlock(&pvh_global_lock); PMAP_LOCK(pmap); sched_pin(); TAILQ_FOREACH_SAFE(pc, &pmap->pm_pvchunk, pc_list, npc) { KASSERT(pc->pc_pmap == pmap, ("%s: wrong pmap %p %p", __func__, pmap, pc->pc_pmap)); allfree = TRUE; for (field = 0; field < _NPCM; field++) { inuse = (~(pc->pc_map[field])) & pc_freemask[field]; while (inuse != 0) { bit = ffs(inuse) - 1; bitmask = 1UL << bit; idx = field * 32 + bit; pv = &pc->pc_pventry[idx]; inuse &= ~bitmask; /* * Note that we cannot remove wired pages * from a process' mapping at this time */ pte1p = pmap_pte1(pmap, pv->pv_va); pte1 = pte1_load(pte1p); if (pte1_is_section(pte1)) { if (pte1_is_wired(pte1)) { allfree = FALSE; continue; } pte1_clear(pte1p); pmap_remove_pte1_quick(pmap, pte1, pv, &free); } else if (pte1_is_link(pte1)) { pte2p = pt2map_entry(pv->pv_va); pte2 = pte2_load(pte2p); if (!pte2_is_valid(pte2)) { printf("%s: pmap %p va %#x " "pte2 %#x\n", __func__, pmap, pv->pv_va, pte2); panic("bad pte2"); } if (pte2_is_wired(pte2)) { allfree = FALSE; continue; } pte2_clear(pte2p); pmap_remove_pte2_quick(pmap, pte2, pv, &free); } else { printf("%s: pmap %p va %#x pte1 %#x\n", __func__, pmap, pv->pv_va, pte1); panic("bad pte1"); } /* Mark free */ PV_STAT(pv_entry_frees++); PV_STAT(pv_entry_spare++); pv_entry_count--; pc->pc_map[field] |= bitmask; } } if (allfree) { TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); free_pv_chunk(pc); } } tlb_flush_all_ng_local(); sched_unpin(); rw_wunlock(&pvh_global_lock); PMAP_UNLOCK(pmap); vm_page_free_pages_toq(&free, false); } /* * This code makes some *MAJOR* assumptions: * 1. Current pmap & pmap exists. * 2. Not wired. * 3. Read access. * 4. No L2 page table pages. * but is *MUCH* faster than pmap_enter... */ static vm_page_t pmap_enter_quick_locked(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, vm_page_t mpt2pg) { pt2_entry_t *pte2p, pte2; vm_paddr_t pa; struct spglist free; uint32_t l2prot; KASSERT(!VA_IS_CLEANMAP(va) || (m->oflags & VPO_UNMANAGED) != 0, ("%s: managed mapping within the clean submap", __func__)); rw_assert(&pvh_global_lock, RA_WLOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); /* * In the case that a L2 page table page is not * resident, we are creating it here. */ if (va < VM_MAXUSER_ADDRESS) { u_int pte1_idx; pt1_entry_t pte1, *pte1p; vm_paddr_t pt2_pa; /* * Get L1 page table things. */ pte1_idx = pte1_index(va); pte1p = pmap_pte1(pmap, va); pte1 = pte1_load(pte1p); if (mpt2pg && (mpt2pg->pindex == (pte1_idx & ~PT2PG_MASK))) { /* * Each of NPT2_IN_PG L2 page tables on the page can * come here. Make sure that associated L1 page table * link is established. * * QQQ: It comes that we don't establish all links to * L2 page tables for newly allocated L2 page * tables page. */ KASSERT(!pte1_is_section(pte1), ("%s: pte1 %#x is section", __func__, pte1)); if (!pte1_is_link(pte1)) { pt2_pa = page_pt2pa(VM_PAGE_TO_PHYS(mpt2pg), pte1_idx); pte1_store(pte1p, PTE1_LINK(pt2_pa)); } pt2_wirecount_inc(mpt2pg, pte1_idx); } else { /* * If the L2 page table page is mapped, we just * increment the hold count, and activate it. */ if (pte1_is_section(pte1)) { return (NULL); } else if (pte1_is_link(pte1)) { mpt2pg = PHYS_TO_VM_PAGE(pte1_link_pa(pte1)); pt2_wirecount_inc(mpt2pg, pte1_idx); } else { mpt2pg = _pmap_allocpte2(pmap, va, PMAP_ENTER_NOSLEEP); if (mpt2pg == NULL) return (NULL); } } } else { mpt2pg = NULL; } /* * This call to pt2map_entry() makes the assumption that we are * entering the page into the current pmap. In order to support * quick entry into any pmap, one would likely use pmap_pte2_quick(). * But that isn't as quick as pt2map_entry(). */ pte2p = pt2map_entry(va); pte2 = pte2_load(pte2p); if (pte2_is_valid(pte2)) { if (mpt2pg != NULL) { /* * Remove extra pte2 reference */ pt2_wirecount_dec(mpt2pg, pte1_index(va)); mpt2pg = NULL; } return (NULL); } /* * Enter on the PV list if part of our managed memory. */ if ((m->oflags & VPO_UNMANAGED) == 0 && !pmap_try_insert_pv_entry(pmap, va, m)) { if (mpt2pg != NULL) { SLIST_INIT(&free); if (pmap_unwire_pt2(pmap, va, mpt2pg, &free)) { pmap_tlb_flush(pmap, va); vm_page_free_pages_toq(&free, false); } mpt2pg = NULL; } return (NULL); } /* * Increment counters */ pmap->pm_stats.resident_count++; /* * Now validate mapping with RO protection */ pa = VM_PAGE_TO_PHYS(m); l2prot = PTE2_RO | PTE2_NM; if (va < VM_MAXUSER_ADDRESS) l2prot |= PTE2_U | PTE2_NG; if ((prot & VM_PROT_EXECUTE) == 0) l2prot |= PTE2_NX; else if (m->md.pat_mode == VM_MEMATTR_WB_WA && pmap != kernel_pmap) { /* * Sync icache if exec permission and attribute VM_MEMATTR_WB_WA * is set. QQQ: For more info, see comments in pmap_enter(). */ cache_icache_sync_fresh(va, pa, PAGE_SIZE); } pte2_store(pte2p, PTE2(pa, l2prot, vm_page_pte2_attr(m))); return (mpt2pg); } void pmap_enter_quick(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot) { rw_wlock(&pvh_global_lock); PMAP_LOCK(pmap); (void)pmap_enter_quick_locked(pmap, va, m, prot, NULL); rw_wunlock(&pvh_global_lock); PMAP_UNLOCK(pmap); } /* * Tries to create a read- and/or execute-only 1 MB page mapping. Returns * true if successful. Returns false if (1) a mapping already exists at the * specified virtual address or (2) a PV entry cannot be allocated without * reclaiming another PV entry. */ static bool pmap_enter_1mpage(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot) { pt1_entry_t pte1; vm_paddr_t pa; PMAP_LOCK_ASSERT(pmap, MA_OWNED); pa = VM_PAGE_TO_PHYS(m); pte1 = PTE1(pa, PTE1_NM | PTE1_RO, ATTR_TO_L1(vm_page_pte2_attr(m))); if ((prot & VM_PROT_EXECUTE) == 0) pte1 |= PTE1_NX; if (va < VM_MAXUSER_ADDRESS) pte1 |= PTE1_U; if (pmap != kernel_pmap) pte1 |= PTE1_NG; return (pmap_enter_pte1(pmap, va, pte1, PMAP_ENTER_NOSLEEP | PMAP_ENTER_NOREPLACE | PMAP_ENTER_NORECLAIM, m) == KERN_SUCCESS); } /* * Tries to create the specified 1 MB page mapping. Returns KERN_SUCCESS if * the mapping was created, and either KERN_FAILURE or KERN_RESOURCE_SHORTAGE * otherwise. Returns KERN_FAILURE if PMAP_ENTER_NOREPLACE was specified and * a mapping already exists at the specified virtual address. Returns * KERN_RESOURCE_SHORTAGE if PMAP_ENTER_NORECLAIM was specified and PV entry * allocation failed. */ static int pmap_enter_pte1(pmap_t pmap, vm_offset_t va, pt1_entry_t pte1, u_int flags, vm_page_t m) { struct spglist free; pt1_entry_t opte1, *pte1p; pt2_entry_t pte2, *pte2p; vm_offset_t cur, end; vm_page_t mt; rw_assert(&pvh_global_lock, RA_WLOCKED); KASSERT((pte1 & (PTE1_NM | PTE1_RO)) == 0 || (pte1 & (PTE1_NM | PTE1_RO)) == (PTE1_NM | PTE1_RO), ("%s: pte1 has inconsistent NM and RO attributes", __func__)); PMAP_LOCK_ASSERT(pmap, MA_OWNED); pte1p = pmap_pte1(pmap, va); opte1 = pte1_load(pte1p); if (pte1_is_valid(opte1)) { if ((flags & PMAP_ENTER_NOREPLACE) != 0) { CTR3(KTR_PMAP, "%s: failure for va %#lx in pmap %p", __func__, va, pmap); return (KERN_FAILURE); } /* Break the existing mapping(s). */ SLIST_INIT(&free); if (pte1_is_section(opte1)) { /* * If the section resulted from a promotion, then a * reserved PT page could be freed. */ pmap_remove_pte1(pmap, pte1p, va, &free); } else { sched_pin(); end = va + PTE1_SIZE; for (cur = va, pte2p = pmap_pte2_quick(pmap, va); cur != end; cur += PAGE_SIZE, pte2p++) { pte2 = pte2_load(pte2p); if (!pte2_is_valid(pte2)) continue; if (pmap_remove_pte2(pmap, pte2p, cur, &free)) break; } sched_unpin(); } vm_page_free_pages_toq(&free, false); } if ((m->oflags & VPO_UNMANAGED) == 0) { /* * Abort this mapping if its PV entry could not be created. */ if (!pmap_pv_insert_pte1(pmap, va, pte1, flags)) { CTR3(KTR_PMAP, "%s: failure for va %#lx in pmap %p", __func__, va, pmap); return (KERN_RESOURCE_SHORTAGE); } if ((pte1 & PTE1_RO) == 0) { for (mt = m; mt < &m[PTE1_SIZE / PAGE_SIZE]; mt++) vm_page_aflag_set(mt, PGA_WRITEABLE); } } /* * Increment counters. */ if (pte1_is_wired(pte1)) pmap->pm_stats.wired_count += PTE1_SIZE / PAGE_SIZE; pmap->pm_stats.resident_count += PTE1_SIZE / PAGE_SIZE; /* * Sync icache if exec permission and attribute VM_MEMATTR_WB_WA * is set. QQQ: For more info, see comments in pmap_enter(). */ if ((pte1 & PTE1_NX) == 0 && m->md.pat_mode == VM_MEMATTR_WB_WA && pmap != kernel_pmap && (!pte1_is_section(opte1) || pte1_pa(opte1) != VM_PAGE_TO_PHYS(m) || (opte1 & PTE2_NX) != 0)) cache_icache_sync_fresh(va, VM_PAGE_TO_PHYS(m), PTE1_SIZE); /* * Map the section. */ pte1_store(pte1p, pte1); pmap_pte1_mappings++; CTR3(KTR_PMAP, "%s: success for va %#lx in pmap %p", __func__, va, pmap); return (KERN_SUCCESS); } /* * Maps a sequence of resident pages belonging to the same object. * The sequence begins with the given page m_start. This page is * mapped at the given virtual address start. Each subsequent page is * mapped at a virtual address that is offset from start by the same * amount as the page is offset from m_start within the object. The * last page in the sequence is the page with the largest offset from * m_start that can be mapped at a virtual address less than the given * virtual address end. Not every virtual page between start and end * is mapped; only those for which a resident page exists with the * corresponding offset from m_start are mapped. */ void pmap_enter_object(pmap_t pmap, vm_offset_t start, vm_offset_t end, vm_page_t m_start, vm_prot_t prot) { vm_offset_t va; vm_page_t m, mpt2pg; vm_pindex_t diff, psize; PDEBUG(6, printf("%s: pmap %p start %#x end %#x m %p prot %#x\n", __func__, pmap, start, end, m_start, prot)); VM_OBJECT_ASSERT_LOCKED(m_start->object); psize = atop(end - start); mpt2pg = NULL; m = m_start; rw_wlock(&pvh_global_lock); PMAP_LOCK(pmap); while (m != NULL && (diff = m->pindex - m_start->pindex) < psize) { va = start + ptoa(diff); if ((va & PTE1_OFFSET) == 0 && va + PTE1_SIZE <= end && m->psind == 1 && sp_enabled && pmap_enter_1mpage(pmap, va, m, prot)) m = &m[PTE1_SIZE / PAGE_SIZE - 1]; else mpt2pg = pmap_enter_quick_locked(pmap, va, m, prot, mpt2pg); m = TAILQ_NEXT(m, listq); } rw_wunlock(&pvh_global_lock); PMAP_UNLOCK(pmap); } /* * This code maps large physical mmap regions into the * processor address space. Note that some shortcuts * are taken, but the code works. */ void pmap_object_init_pt(pmap_t pmap, vm_offset_t addr, vm_object_t object, vm_pindex_t pindex, vm_size_t size) { pt1_entry_t *pte1p; vm_paddr_t pa, pte2_pa; vm_page_t p; vm_memattr_t pat_mode; u_int l1attr, l1prot; VM_OBJECT_ASSERT_WLOCKED(object); KASSERT(object->type == OBJT_DEVICE || object->type == OBJT_SG, ("%s: non-device object", __func__)); if ((addr & PTE1_OFFSET) == 0 && (size & PTE1_OFFSET) == 0) { if (!vm_object_populate(object, pindex, pindex + atop(size))) return; p = vm_page_lookup(object, pindex); KASSERT(p->valid == VM_PAGE_BITS_ALL, ("%s: invalid page %p", __func__, p)); pat_mode = p->md.pat_mode; /* * Abort the mapping if the first page is not physically * aligned to a 1MB page boundary. */ pte2_pa = VM_PAGE_TO_PHYS(p); if (pte2_pa & PTE1_OFFSET) return; /* * Skip the first page. Abort the mapping if the rest of * the pages are not physically contiguous or have differing * memory attributes. */ p = TAILQ_NEXT(p, listq); for (pa = pte2_pa + PAGE_SIZE; pa < pte2_pa + size; pa += PAGE_SIZE) { KASSERT(p->valid == VM_PAGE_BITS_ALL, ("%s: invalid page %p", __func__, p)); if (pa != VM_PAGE_TO_PHYS(p) || pat_mode != p->md.pat_mode) return; p = TAILQ_NEXT(p, listq); } /* * Map using 1MB pages. * * QQQ: Well, we are mapping a section, so same condition must * be hold like during promotion. It looks that only RW mapping * is done here, so readonly mapping must be done elsewhere. */ l1prot = PTE1_U | PTE1_NG | PTE1_RW | PTE1_M | PTE1_A; l1attr = ATTR_TO_L1(vm_memattr_to_pte2(pat_mode)); PMAP_LOCK(pmap); for (pa = pte2_pa; pa < pte2_pa + size; pa += PTE1_SIZE) { pte1p = pmap_pte1(pmap, addr); if (!pte1_is_valid(pte1_load(pte1p))) { pte1_store(pte1p, PTE1(pa, l1prot, l1attr)); pmap->pm_stats.resident_count += PTE1_SIZE / PAGE_SIZE; pmap_pte1_mappings++; } /* Else continue on if the PTE1 is already valid. */ addr += PTE1_SIZE; } PMAP_UNLOCK(pmap); } } /* * Do the things to protect a 1mpage in a process. */ static void pmap_protect_pte1(pmap_t pmap, pt1_entry_t *pte1p, vm_offset_t sva, vm_prot_t prot) { pt1_entry_t npte1, opte1; vm_offset_t eva, va; vm_page_t m; PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT((sva & PTE1_OFFSET) == 0, ("%s: sva is not 1mpage aligned", __func__)); opte1 = npte1 = pte1_load(pte1p); if (pte1_is_managed(opte1) && pte1_is_dirty(opte1)) { eva = sva + PTE1_SIZE; for (va = sva, m = PHYS_TO_VM_PAGE(pte1_pa(opte1)); va < eva; va += PAGE_SIZE, m++) vm_page_dirty(m); } if ((prot & VM_PROT_WRITE) == 0) npte1 |= PTE1_RO | PTE1_NM; if ((prot & VM_PROT_EXECUTE) == 0) npte1 |= PTE1_NX; /* * QQQ: Herein, execute permission is never set. * It only can be cleared. So, no icache * syncing is needed. */ if (npte1 != opte1) { pte1_store(pte1p, npte1); pmap_tlb_flush(pmap, sva); } } /* * Set the physical protection on the * specified range of this map as requested. */ void pmap_protect(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, vm_prot_t prot) { boolean_t pv_lists_locked; vm_offset_t nextva; pt1_entry_t *pte1p, pte1; pt2_entry_t *pte2p, opte2, npte2; KASSERT((prot & ~VM_PROT_ALL) == 0, ("invalid prot %x", prot)); if (prot == VM_PROT_NONE) { pmap_remove(pmap, sva, eva); return; } if ((prot & (VM_PROT_WRITE | VM_PROT_EXECUTE)) == (VM_PROT_WRITE | VM_PROT_EXECUTE)) return; if (pmap_is_current(pmap)) pv_lists_locked = FALSE; else { pv_lists_locked = TRUE; resume: rw_wlock(&pvh_global_lock); sched_pin(); } PMAP_LOCK(pmap); for (; sva < eva; sva = nextva) { /* * Calculate address for next L2 page table. */ nextva = pte1_trunc(sva + PTE1_SIZE); if (nextva < sva) nextva = eva; pte1p = pmap_pte1(pmap, sva); pte1 = pte1_load(pte1p); /* * Weed out invalid mappings. Note: we assume that L1 page * page table is always allocated, and in kernel virtual. */ if (pte1 == 0) continue; if (pte1_is_section(pte1)) { /* * Are we protecting the entire large page? If not, * demote the mapping and fall through. */ if (sva + PTE1_SIZE == nextva && eva >= nextva) { pmap_protect_pte1(pmap, pte1p, sva, prot); continue; } else { if (!pv_lists_locked) { pv_lists_locked = TRUE; if (!rw_try_wlock(&pvh_global_lock)) { PMAP_UNLOCK(pmap); goto resume; } sched_pin(); } if (!pmap_demote_pte1(pmap, pte1p, sva)) { /* * The large page mapping * was destroyed. */ continue; } #ifdef INVARIANTS else { /* Update pte1 after demotion */ pte1 = pte1_load(pte1p); } #endif } } KASSERT(pte1_is_link(pte1), ("%s: pmap %p va %#x pte1 %#x at %p" " is not link", __func__, pmap, sva, pte1, pte1p)); /* * Limit our scan to either the end of the va represented * by the current L2 page table page, or to the end of the * range being protected. */ if (nextva > eva) nextva = eva; for (pte2p = pmap_pte2_quick(pmap, sva); sva != nextva; pte2p++, sva += PAGE_SIZE) { vm_page_t m; opte2 = npte2 = pte2_load(pte2p); if (!pte2_is_valid(opte2)) continue; if ((prot & VM_PROT_WRITE) == 0) { if (pte2_is_managed(opte2) && pte2_is_dirty(opte2)) { m = PHYS_TO_VM_PAGE(pte2_pa(opte2)); vm_page_dirty(m); } npte2 |= PTE2_RO | PTE2_NM; } if ((prot & VM_PROT_EXECUTE) == 0) npte2 |= PTE2_NX; /* * QQQ: Herein, execute permission is never set. * It only can be cleared. So, no icache * syncing is needed. */ if (npte2 != opte2) { pte2_store(pte2p, npte2); pmap_tlb_flush(pmap, sva); } } } if (pv_lists_locked) { sched_unpin(); rw_wunlock(&pvh_global_lock); } PMAP_UNLOCK(pmap); } /* * pmap_pvh_wired_mappings: * * Return the updated number "count" of managed mappings that are wired. */ static int pmap_pvh_wired_mappings(struct md_page *pvh, int count) { pmap_t pmap; pt1_entry_t pte1; pt2_entry_t pte2; pv_entry_t pv; rw_assert(&pvh_global_lock, RA_WLOCKED); sched_pin(); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pte1 = pte1_load(pmap_pte1(pmap, pv->pv_va)); if (pte1_is_section(pte1)) { if (pte1_is_wired(pte1)) count++; } else { KASSERT(pte1_is_link(pte1), ("%s: pte1 %#x is not link", __func__, pte1)); pte2 = pte2_load(pmap_pte2_quick(pmap, pv->pv_va)); if (pte2_is_wired(pte2)) count++; } PMAP_UNLOCK(pmap); } sched_unpin(); return (count); } /* * pmap_page_wired_mappings: * * Return the number of managed mappings to the given physical page * that are wired. */ int pmap_page_wired_mappings(vm_page_t m) { int count; count = 0; if ((m->oflags & VPO_UNMANAGED) != 0) return (count); rw_wlock(&pvh_global_lock); count = pmap_pvh_wired_mappings(&m->md, count); if ((m->flags & PG_FICTITIOUS) == 0) { count = pmap_pvh_wired_mappings(pa_to_pvh(VM_PAGE_TO_PHYS(m)), count); } rw_wunlock(&pvh_global_lock); return (count); } /* * Returns TRUE if any of the given mappings were used to modify * physical memory. Otherwise, returns FALSE. Both page and 1mpage * mappings are supported. */ static boolean_t pmap_is_modified_pvh(struct md_page *pvh) { pv_entry_t pv; pt1_entry_t pte1; pt2_entry_t pte2; pmap_t pmap; boolean_t rv; rw_assert(&pvh_global_lock, RA_WLOCKED); rv = FALSE; sched_pin(); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pte1 = pte1_load(pmap_pte1(pmap, pv->pv_va)); if (pte1_is_section(pte1)) { rv = pte1_is_dirty(pte1); } else { KASSERT(pte1_is_link(pte1), ("%s: pte1 %#x is not link", __func__, pte1)); pte2 = pte2_load(pmap_pte2_quick(pmap, pv->pv_va)); rv = pte2_is_dirty(pte2); } PMAP_UNLOCK(pmap); if (rv) break; } sched_unpin(); return (rv); } /* * pmap_is_modified: * * Return whether or not the specified physical page was modified * in any physical maps. */ boolean_t pmap_is_modified(vm_page_t m) { boolean_t rv; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("%s: page %p is not managed", __func__, m)); /* * If the page is not busied then this check is racy. */ if (!pmap_page_is_write_mapped(m)) return (FALSE); rw_wlock(&pvh_global_lock); rv = pmap_is_modified_pvh(&m->md) || ((m->flags & PG_FICTITIOUS) == 0 && pmap_is_modified_pvh(pa_to_pvh(VM_PAGE_TO_PHYS(m)))); rw_wunlock(&pvh_global_lock); return (rv); } /* * pmap_is_prefaultable: * * Return whether or not the specified virtual address is eligible * for prefault. */ boolean_t pmap_is_prefaultable(pmap_t pmap, vm_offset_t addr) { pt1_entry_t pte1; pt2_entry_t pte2; boolean_t rv; rv = FALSE; PMAP_LOCK(pmap); pte1 = pte1_load(pmap_pte1(pmap, addr)); if (pte1_is_link(pte1)) { pte2 = pte2_load(pt2map_entry(addr)); rv = !pte2_is_valid(pte2) ; } PMAP_UNLOCK(pmap); return (rv); } /* * Returns TRUE if any of the given mappings were referenced and FALSE * otherwise. Both page and 1mpage mappings are supported. */ static boolean_t pmap_is_referenced_pvh(struct md_page *pvh) { pv_entry_t pv; pt1_entry_t pte1; pt2_entry_t pte2; pmap_t pmap; boolean_t rv; rw_assert(&pvh_global_lock, RA_WLOCKED); rv = FALSE; sched_pin(); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pte1 = pte1_load(pmap_pte1(pmap, pv->pv_va)); if (pte1_is_section(pte1)) { rv = (pte1 & (PTE1_A | PTE1_V)) == (PTE1_A | PTE1_V); } else { pte2 = pte2_load(pmap_pte2_quick(pmap, pv->pv_va)); rv = (pte2 & (PTE2_A | PTE2_V)) == (PTE2_A | PTE2_V); } PMAP_UNLOCK(pmap); if (rv) break; } sched_unpin(); return (rv); } /* * pmap_is_referenced: * * Return whether or not the specified physical page was referenced * in any physical maps. */ boolean_t pmap_is_referenced(vm_page_t m) { boolean_t rv; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("%s: page %p is not managed", __func__, m)); rw_wlock(&pvh_global_lock); rv = pmap_is_referenced_pvh(&m->md) || ((m->flags & PG_FICTITIOUS) == 0 && pmap_is_referenced_pvh(pa_to_pvh(VM_PAGE_TO_PHYS(m)))); rw_wunlock(&pvh_global_lock); return (rv); } /* * pmap_ts_referenced: * * Return a count of reference bits for a page, clearing those bits. * It is not necessary for every reference bit to be cleared, but it * is necessary that 0 only be returned when there are truly no * reference bits set. * * As an optimization, update the page's dirty field if a modified bit is * found while counting reference bits. This opportunistic update can be * performed at low cost and can eliminate the need for some future calls * to pmap_is_modified(). However, since this function stops after * finding PMAP_TS_REFERENCED_MAX reference bits, it may not detect some * dirty pages. Those dirty pages will only be detected by a future call * to pmap_is_modified(). */ int pmap_ts_referenced(vm_page_t m) { struct md_page *pvh; pv_entry_t pv, pvf; pmap_t pmap; pt1_entry_t *pte1p, opte1; pt2_entry_t *pte2p, opte2; vm_paddr_t pa; int rtval = 0; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("%s: page %p is not managed", __func__, m)); pa = VM_PAGE_TO_PHYS(m); pvh = pa_to_pvh(pa); rw_wlock(&pvh_global_lock); sched_pin(); if ((m->flags & PG_FICTITIOUS) != 0 || (pvf = TAILQ_FIRST(&pvh->pv_list)) == NULL) goto small_mappings; pv = pvf; do { pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pte1p = pmap_pte1(pmap, pv->pv_va); opte1 = pte1_load(pte1p); if (pte1_is_dirty(opte1)) { /* * Although "opte1" is mapping a 1MB page, because * this function is called at a 4KB page granularity, * we only update the 4KB page under test. */ vm_page_dirty(m); } if ((opte1 & PTE1_A) != 0) { /* * Since this reference bit is shared by 256 4KB pages, * it should not be cleared every time it is tested. * Apply a simple "hash" function on the physical page * number, the virtual section number, and the pmap * address to select one 4KB page out of the 256 * on which testing the reference bit will result * in clearing that bit. This function is designed * to avoid the selection of the same 4KB page * for every 1MB page mapping. * * On demotion, a mapping that hasn't been referenced * is simply destroyed. To avoid the possibility of a * subsequent page fault on a demoted wired mapping, * always leave its reference bit set. Moreover, * since the section is wired, the current state of * its reference bit won't affect page replacement. */ if ((((pa >> PAGE_SHIFT) ^ (pv->pv_va >> PTE1_SHIFT) ^ (uintptr_t)pmap) & (NPTE2_IN_PG - 1)) == 0 && !pte1_is_wired(opte1)) { pte1_clear_bit(pte1p, PTE1_A); pmap_tlb_flush(pmap, pv->pv_va); } rtval++; } PMAP_UNLOCK(pmap); /* Rotate the PV list if it has more than one entry. */ if (TAILQ_NEXT(pv, pv_next) != NULL) { TAILQ_REMOVE(&pvh->pv_list, pv, pv_next); TAILQ_INSERT_TAIL(&pvh->pv_list, pv, pv_next); } if (rtval >= PMAP_TS_REFERENCED_MAX) goto out; } while ((pv = TAILQ_FIRST(&pvh->pv_list)) != pvf); small_mappings: if ((pvf = TAILQ_FIRST(&m->md.pv_list)) == NULL) goto out; pv = pvf; do { pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pte1p = pmap_pte1(pmap, pv->pv_va); KASSERT(pte1_is_link(pte1_load(pte1p)), ("%s: not found a link in page %p's pv list", __func__, m)); pte2p = pmap_pte2_quick(pmap, pv->pv_va); opte2 = pte2_load(pte2p); if (pte2_is_dirty(opte2)) vm_page_dirty(m); if ((opte2 & PTE2_A) != 0) { pte2_clear_bit(pte2p, PTE2_A); pmap_tlb_flush(pmap, pv->pv_va); rtval++; } PMAP_UNLOCK(pmap); /* Rotate the PV list if it has more than one entry. */ if (TAILQ_NEXT(pv, pv_next) != NULL) { TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); } } while ((pv = TAILQ_FIRST(&m->md.pv_list)) != pvf && rtval < PMAP_TS_REFERENCED_MAX); out: sched_unpin(); rw_wunlock(&pvh_global_lock); return (rtval); } /* * Clear the wired attribute from the mappings for the specified range of * addresses in the given pmap. Every valid mapping within that range * must have the wired attribute set. In contrast, invalid mappings * cannot have the wired attribute set, so they are ignored. * * The wired attribute of the page table entry is not a hardware feature, * so there is no need to invalidate any TLB entries. */ void pmap_unwire(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { vm_offset_t nextva; pt1_entry_t *pte1p, pte1; pt2_entry_t *pte2p, pte2; boolean_t pv_lists_locked; if (pmap_is_current(pmap)) pv_lists_locked = FALSE; else { pv_lists_locked = TRUE; resume: rw_wlock(&pvh_global_lock); sched_pin(); } PMAP_LOCK(pmap); for (; sva < eva; sva = nextva) { nextva = pte1_trunc(sva + PTE1_SIZE); if (nextva < sva) nextva = eva; pte1p = pmap_pte1(pmap, sva); pte1 = pte1_load(pte1p); /* * Weed out invalid mappings. Note: we assume that L1 page * page table is always allocated, and in kernel virtual. */ if (pte1 == 0) continue; if (pte1_is_section(pte1)) { if (!pte1_is_wired(pte1)) panic("%s: pte1 %#x not wired", __func__, pte1); /* * Are we unwiring the entire large page? If not, * demote the mapping and fall through. */ if (sva + PTE1_SIZE == nextva && eva >= nextva) { pte1_clear_bit(pte1p, PTE1_W); pmap->pm_stats.wired_count -= PTE1_SIZE / PAGE_SIZE; continue; } else { if (!pv_lists_locked) { pv_lists_locked = TRUE; if (!rw_try_wlock(&pvh_global_lock)) { PMAP_UNLOCK(pmap); /* Repeat sva. */ goto resume; } sched_pin(); } if (!pmap_demote_pte1(pmap, pte1p, sva)) panic("%s: demotion failed", __func__); #ifdef INVARIANTS else { /* Update pte1 after demotion */ pte1 = pte1_load(pte1p); } #endif } } KASSERT(pte1_is_link(pte1), ("%s: pmap %p va %#x pte1 %#x at %p" " is not link", __func__, pmap, sva, pte1, pte1p)); /* * Limit our scan to either the end of the va represented * by the current L2 page table page, or to the end of the * range being protected. */ if (nextva > eva) nextva = eva; for (pte2p = pmap_pte2_quick(pmap, sva); sva != nextva; pte2p++, sva += PAGE_SIZE) { pte2 = pte2_load(pte2p); if (!pte2_is_valid(pte2)) continue; if (!pte2_is_wired(pte2)) panic("%s: pte2 %#x is missing PTE2_W", __func__, pte2); /* * PTE2_W must be cleared atomically. Although the pmap * lock synchronizes access to PTE2_W, another processor * could be changing PTE2_NM and/or PTE2_A concurrently. */ pte2_clear_bit(pte2p, PTE2_W); pmap->pm_stats.wired_count--; } } if (pv_lists_locked) { sched_unpin(); rw_wunlock(&pvh_global_lock); } PMAP_UNLOCK(pmap); } /* * Clear the write and modified bits in each of the given page's mappings. */ void pmap_remove_write(vm_page_t m) { struct md_page *pvh; pv_entry_t next_pv, pv; pmap_t pmap; pt1_entry_t *pte1p; pt2_entry_t *pte2p, opte2; vm_offset_t va; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("%s: page %p is not managed", __func__, m)); vm_page_assert_busied(m); if (!pmap_page_is_write_mapped(m)) return; rw_wlock(&pvh_global_lock); sched_pin(); if ((m->flags & PG_FICTITIOUS) != 0) goto small_mappings; pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); TAILQ_FOREACH_SAFE(pv, &pvh->pv_list, pv_next, next_pv) { va = pv->pv_va; pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pte1p = pmap_pte1(pmap, va); if (!(pte1_load(pte1p) & PTE1_RO)) (void)pmap_demote_pte1(pmap, pte1p, va); PMAP_UNLOCK(pmap); } small_mappings: TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pte1p = pmap_pte1(pmap, pv->pv_va); KASSERT(!pte1_is_section(pte1_load(pte1p)), ("%s: found" " a section in page %p's pv list", __func__, m)); pte2p = pmap_pte2_quick(pmap, pv->pv_va); opte2 = pte2_load(pte2p); if (!(opte2 & PTE2_RO)) { pte2_store(pte2p, opte2 | PTE2_RO | PTE2_NM); if (pte2_is_dirty(opte2)) vm_page_dirty(m); pmap_tlb_flush(pmap, pv->pv_va); } PMAP_UNLOCK(pmap); } vm_page_aflag_clear(m, PGA_WRITEABLE); sched_unpin(); rw_wunlock(&pvh_global_lock); } /* * Apply the given advice to the specified range of addresses within the * given pmap. Depending on the advice, clear the referenced and/or * modified flags in each mapping and set the mapped page's dirty field. */ void pmap_advise(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, int advice) { pt1_entry_t *pte1p, opte1; pt2_entry_t *pte2p, pte2; vm_offset_t pdnxt; vm_page_t m; boolean_t pv_lists_locked; if (advice != MADV_DONTNEED && advice != MADV_FREE) return; if (pmap_is_current(pmap)) pv_lists_locked = FALSE; else { pv_lists_locked = TRUE; resume: rw_wlock(&pvh_global_lock); sched_pin(); } PMAP_LOCK(pmap); for (; sva < eva; sva = pdnxt) { pdnxt = pte1_trunc(sva + PTE1_SIZE); if (pdnxt < sva) pdnxt = eva; pte1p = pmap_pte1(pmap, sva); opte1 = pte1_load(pte1p); if (!pte1_is_valid(opte1)) /* XXX */ continue; else if (pte1_is_section(opte1)) { if (!pte1_is_managed(opte1)) continue; if (!pv_lists_locked) { pv_lists_locked = TRUE; if (!rw_try_wlock(&pvh_global_lock)) { PMAP_UNLOCK(pmap); goto resume; } sched_pin(); } if (!pmap_demote_pte1(pmap, pte1p, sva)) { /* * The large page mapping was destroyed. */ continue; } /* * Unless the page mappings are wired, remove the * mapping to a single page so that a subsequent * access may repromote. Since the underlying L2 page * table is fully populated, this removal never * frees a L2 page table page. */ if (!pte1_is_wired(opte1)) { pte2p = pmap_pte2_quick(pmap, sva); KASSERT(pte2_is_valid(pte2_load(pte2p)), ("%s: invalid PTE2", __func__)); pmap_remove_pte2(pmap, pte2p, sva, NULL); } } if (pdnxt > eva) pdnxt = eva; for (pte2p = pmap_pte2_quick(pmap, sva); sva != pdnxt; pte2p++, sva += PAGE_SIZE) { pte2 = pte2_load(pte2p); if (!pte2_is_valid(pte2) || !pte2_is_managed(pte2)) continue; else if (pte2_is_dirty(pte2)) { if (advice == MADV_DONTNEED) { /* * Future calls to pmap_is_modified() * can be avoided by making the page * dirty now. */ m = PHYS_TO_VM_PAGE(pte2_pa(pte2)); vm_page_dirty(m); } pte2_set_bit(pte2p, PTE2_NM); pte2_clear_bit(pte2p, PTE2_A); } else if ((pte2 & PTE2_A) != 0) pte2_clear_bit(pte2p, PTE2_A); else continue; pmap_tlb_flush(pmap, sva); } } if (pv_lists_locked) { sched_unpin(); rw_wunlock(&pvh_global_lock); } PMAP_UNLOCK(pmap); } /* * Clear the modify bits on the specified physical page. */ void pmap_clear_modify(vm_page_t m) { struct md_page *pvh; pv_entry_t next_pv, pv; pmap_t pmap; pt1_entry_t *pte1p, opte1; pt2_entry_t *pte2p, opte2; vm_offset_t va; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("%s: page %p is not managed", __func__, m)); vm_page_assert_busied(m); if (!pmap_page_is_write_mapped(m)) return; rw_wlock(&pvh_global_lock); sched_pin(); if ((m->flags & PG_FICTITIOUS) != 0) goto small_mappings; pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); TAILQ_FOREACH_SAFE(pv, &pvh->pv_list, pv_next, next_pv) { va = pv->pv_va; pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pte1p = pmap_pte1(pmap, va); opte1 = pte1_load(pte1p); if (!(opte1 & PTE1_RO)) { if (pmap_demote_pte1(pmap, pte1p, va) && !pte1_is_wired(opte1)) { /* * Write protect the mapping to a * single page so that a subsequent * write access may repromote. */ va += VM_PAGE_TO_PHYS(m) - pte1_pa(opte1); pte2p = pmap_pte2_quick(pmap, va); opte2 = pte2_load(pte2p); if ((opte2 & PTE2_V)) { pte2_set_bit(pte2p, PTE2_NM | PTE2_RO); vm_page_dirty(m); pmap_tlb_flush(pmap, va); } } } PMAP_UNLOCK(pmap); } small_mappings: TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pte1p = pmap_pte1(pmap, pv->pv_va); KASSERT(!pte1_is_section(pte1_load(pte1p)), ("%s: found" " a section in page %p's pv list", __func__, m)); pte2p = pmap_pte2_quick(pmap, pv->pv_va); if (pte2_is_dirty(pte2_load(pte2p))) { pte2_set_bit(pte2p, PTE2_NM); pmap_tlb_flush(pmap, pv->pv_va); } PMAP_UNLOCK(pmap); } sched_unpin(); rw_wunlock(&pvh_global_lock); } /* * Sets the memory attribute for the specified page. */ void pmap_page_set_memattr(vm_page_t m, vm_memattr_t ma) { pt2_entry_t *cmap2_pte2p; vm_memattr_t oma; vm_paddr_t pa; struct pcpu *pc; oma = m->md.pat_mode; m->md.pat_mode = ma; CTR5(KTR_PMAP, "%s: page %p - 0x%08X oma: %d, ma: %d", __func__, m, VM_PAGE_TO_PHYS(m), oma, ma); if ((m->flags & PG_FICTITIOUS) != 0) return; #if 0 /* * If "m" is a normal page, flush it from the cache. * * First, try to find an existing mapping of the page by sf * buffer. sf_buf_invalidate_cache() modifies mapping and * flushes the cache. */ if (sf_buf_invalidate_cache(m, oma)) return; #endif /* * If page is not mapped by sf buffer, map the page * transient and do invalidation. */ if (ma != oma) { pa = VM_PAGE_TO_PHYS(m); sched_pin(); pc = get_pcpu(); cmap2_pte2p = pc->pc_cmap2_pte2p; mtx_lock(&pc->pc_cmap_lock); if (pte2_load(cmap2_pte2p) != 0) panic("%s: CMAP2 busy", __func__); pte2_store(cmap2_pte2p, PTE2_KERN_NG(pa, PTE2_AP_KRW, vm_memattr_to_pte2(ma))); dcache_wbinv_poc((vm_offset_t)pc->pc_cmap2_addr, pa, PAGE_SIZE); pte2_clear(cmap2_pte2p); tlb_flush((vm_offset_t)pc->pc_cmap2_addr); sched_unpin(); mtx_unlock(&pc->pc_cmap_lock); } } /* * Miscellaneous support routines follow */ /* * Returns TRUE if the given page is mapped individually or as part of * a 1mpage. Otherwise, returns FALSE. */ boolean_t pmap_page_is_mapped(vm_page_t m) { boolean_t rv; if ((m->oflags & VPO_UNMANAGED) != 0) return (FALSE); rw_wlock(&pvh_global_lock); rv = !TAILQ_EMPTY(&m->md.pv_list) || ((m->flags & PG_FICTITIOUS) == 0 && !TAILQ_EMPTY(&pa_to_pvh(VM_PAGE_TO_PHYS(m))->pv_list)); rw_wunlock(&pvh_global_lock); return (rv); } /* * Returns true if the pmap's pv is one of the first * 16 pvs linked to from this page. This count may * be changed upwards or downwards in the future; it * is only necessary that true be returned for a small * subset of pmaps for proper page aging. */ boolean_t pmap_page_exists_quick(pmap_t pmap, vm_page_t m) { struct md_page *pvh; pv_entry_t pv; int loops = 0; boolean_t rv; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("%s: page %p is not managed", __func__, m)); rv = FALSE; rw_wlock(&pvh_global_lock); TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { if (PV_PMAP(pv) == pmap) { rv = TRUE; break; } loops++; if (loops >= 16) break; } if (!rv && loops < 16 && (m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { if (PV_PMAP(pv) == pmap) { rv = TRUE; break; } loops++; if (loops >= 16) break; } } rw_wunlock(&pvh_global_lock); return (rv); } /* * pmap_zero_page zeros the specified hardware page by mapping * the page into KVM and using bzero to clear its contents. */ void pmap_zero_page(vm_page_t m) { pt2_entry_t *cmap2_pte2p; struct pcpu *pc; sched_pin(); pc = get_pcpu(); cmap2_pte2p = pc->pc_cmap2_pte2p; mtx_lock(&pc->pc_cmap_lock); if (pte2_load(cmap2_pte2p) != 0) panic("%s: CMAP2 busy", __func__); pte2_store(cmap2_pte2p, PTE2_KERN_NG(VM_PAGE_TO_PHYS(m), PTE2_AP_KRW, vm_page_pte2_attr(m))); pagezero(pc->pc_cmap2_addr); pte2_clear(cmap2_pte2p); tlb_flush((vm_offset_t)pc->pc_cmap2_addr); sched_unpin(); mtx_unlock(&pc->pc_cmap_lock); } /* * pmap_zero_page_area zeros the specified hardware page by mapping * the page into KVM and using bzero to clear its contents. * * off and size may not cover an area beyond a single hardware page. */ void pmap_zero_page_area(vm_page_t m, int off, int size) { pt2_entry_t *cmap2_pte2p; struct pcpu *pc; sched_pin(); pc = get_pcpu(); cmap2_pte2p = pc->pc_cmap2_pte2p; mtx_lock(&pc->pc_cmap_lock); if (pte2_load(cmap2_pte2p) != 0) panic("%s: CMAP2 busy", __func__); pte2_store(cmap2_pte2p, PTE2_KERN_NG(VM_PAGE_TO_PHYS(m), PTE2_AP_KRW, vm_page_pte2_attr(m))); if (off == 0 && size == PAGE_SIZE) pagezero(pc->pc_cmap2_addr); else bzero(pc->pc_cmap2_addr + off, size); pte2_clear(cmap2_pte2p); tlb_flush((vm_offset_t)pc->pc_cmap2_addr); sched_unpin(); mtx_unlock(&pc->pc_cmap_lock); } /* * pmap_copy_page copies the specified (machine independent) * page by mapping the page into virtual memory and using * bcopy to copy the page, one machine dependent page at a * time. */ void pmap_copy_page(vm_page_t src, vm_page_t dst) { pt2_entry_t *cmap1_pte2p, *cmap2_pte2p; struct pcpu *pc; sched_pin(); pc = get_pcpu(); cmap1_pte2p = pc->pc_cmap1_pte2p; cmap2_pte2p = pc->pc_cmap2_pte2p; mtx_lock(&pc->pc_cmap_lock); if (pte2_load(cmap1_pte2p) != 0) panic("%s: CMAP1 busy", __func__); if (pte2_load(cmap2_pte2p) != 0) panic("%s: CMAP2 busy", __func__); pte2_store(cmap1_pte2p, PTE2_KERN_NG(VM_PAGE_TO_PHYS(src), PTE2_AP_KR | PTE2_NM, vm_page_pte2_attr(src))); pte2_store(cmap2_pte2p, PTE2_KERN_NG(VM_PAGE_TO_PHYS(dst), PTE2_AP_KRW, vm_page_pte2_attr(dst))); bcopy(pc->pc_cmap1_addr, pc->pc_cmap2_addr, PAGE_SIZE); pte2_clear(cmap1_pte2p); tlb_flush((vm_offset_t)pc->pc_cmap1_addr); pte2_clear(cmap2_pte2p); tlb_flush((vm_offset_t)pc->pc_cmap2_addr); sched_unpin(); mtx_unlock(&pc->pc_cmap_lock); } int unmapped_buf_allowed = 1; void pmap_copy_pages(vm_page_t ma[], vm_offset_t a_offset, vm_page_t mb[], vm_offset_t b_offset, int xfersize) { pt2_entry_t *cmap1_pte2p, *cmap2_pte2p; vm_page_t a_pg, b_pg; char *a_cp, *b_cp; vm_offset_t a_pg_offset, b_pg_offset; struct pcpu *pc; int cnt; sched_pin(); pc = get_pcpu(); cmap1_pte2p = pc->pc_cmap1_pte2p; cmap2_pte2p = pc->pc_cmap2_pte2p; mtx_lock(&pc->pc_cmap_lock); if (pte2_load(cmap1_pte2p) != 0) panic("pmap_copy_pages: CMAP1 busy"); if (pte2_load(cmap2_pte2p) != 0) panic("pmap_copy_pages: CMAP2 busy"); while (xfersize > 0) { a_pg = ma[a_offset >> PAGE_SHIFT]; a_pg_offset = a_offset & PAGE_MASK; cnt = min(xfersize, PAGE_SIZE - a_pg_offset); b_pg = mb[b_offset >> PAGE_SHIFT]; b_pg_offset = b_offset & PAGE_MASK; cnt = min(cnt, PAGE_SIZE - b_pg_offset); pte2_store(cmap1_pte2p, PTE2_KERN_NG(VM_PAGE_TO_PHYS(a_pg), PTE2_AP_KR | PTE2_NM, vm_page_pte2_attr(a_pg))); tlb_flush_local((vm_offset_t)pc->pc_cmap1_addr); pte2_store(cmap2_pte2p, PTE2_KERN_NG(VM_PAGE_TO_PHYS(b_pg), PTE2_AP_KRW, vm_page_pte2_attr(b_pg))); tlb_flush_local((vm_offset_t)pc->pc_cmap2_addr); a_cp = pc->pc_cmap1_addr + a_pg_offset; b_cp = pc->pc_cmap2_addr + b_pg_offset; bcopy(a_cp, b_cp, cnt); a_offset += cnt; b_offset += cnt; xfersize -= cnt; } pte2_clear(cmap1_pte2p); tlb_flush((vm_offset_t)pc->pc_cmap1_addr); pte2_clear(cmap2_pte2p); tlb_flush((vm_offset_t)pc->pc_cmap2_addr); sched_unpin(); mtx_unlock(&pc->pc_cmap_lock); } vm_offset_t pmap_quick_enter_page(vm_page_t m) { struct pcpu *pc; pt2_entry_t *pte2p; critical_enter(); pc = get_pcpu(); pte2p = pc->pc_qmap_pte2p; KASSERT(pte2_load(pte2p) == 0, ("%s: PTE2 busy", __func__)); pte2_store(pte2p, PTE2_KERN_NG(VM_PAGE_TO_PHYS(m), PTE2_AP_KRW, vm_page_pte2_attr(m))); return (pc->pc_qmap_addr); } void pmap_quick_remove_page(vm_offset_t addr) { struct pcpu *pc; pt2_entry_t *pte2p; pc = get_pcpu(); pte2p = pc->pc_qmap_pte2p; KASSERT(addr == pc->pc_qmap_addr, ("%s: invalid address", __func__)); KASSERT(pte2_load(pte2p) != 0, ("%s: PTE2 not in use", __func__)); pte2_clear(pte2p); tlb_flush(pc->pc_qmap_addr); critical_exit(); } /* * Copy the range specified by src_addr/len * from the source map to the range dst_addr/len * in the destination map. * * This routine is only advisory and need not do anything. */ void pmap_copy(pmap_t dst_pmap, pmap_t src_pmap, vm_offset_t dst_addr, vm_size_t len, vm_offset_t src_addr) { struct spglist free; vm_offset_t addr; vm_offset_t end_addr = src_addr + len; vm_offset_t nextva; if (dst_addr != src_addr) return; if (!pmap_is_current(src_pmap)) return; rw_wlock(&pvh_global_lock); if (dst_pmap < src_pmap) { PMAP_LOCK(dst_pmap); PMAP_LOCK(src_pmap); } else { PMAP_LOCK(src_pmap); PMAP_LOCK(dst_pmap); } sched_pin(); for (addr = src_addr; addr < end_addr; addr = nextva) { pt2_entry_t *src_pte2p, *dst_pte2p; vm_page_t dst_mpt2pg, src_mpt2pg; pt1_entry_t src_pte1; u_int pte1_idx; KASSERT(addr < VM_MAXUSER_ADDRESS, ("%s: invalid to pmap_copy page tables", __func__)); nextva = pte1_trunc(addr + PTE1_SIZE); if (nextva < addr) nextva = end_addr; pte1_idx = pte1_index(addr); src_pte1 = src_pmap->pm_pt1[pte1_idx]; if (pte1_is_section(src_pte1)) { if ((addr & PTE1_OFFSET) != 0 || (addr + PTE1_SIZE) > end_addr) continue; if (dst_pmap->pm_pt1[pte1_idx] == 0 && (!pte1_is_managed(src_pte1) || pmap_pv_insert_pte1(dst_pmap, addr, src_pte1, PMAP_ENTER_NORECLAIM))) { dst_pmap->pm_pt1[pte1_idx] = src_pte1 & ~PTE1_W; dst_pmap->pm_stats.resident_count += PTE1_SIZE / PAGE_SIZE; pmap_pte1_mappings++; } continue; } else if (!pte1_is_link(src_pte1)) continue; src_mpt2pg = PHYS_TO_VM_PAGE(pte1_link_pa(src_pte1)); /* * We leave PT2s to be linked from PT1 even if they are not * referenced until all PT2s in a page are without reference. * * QQQ: It could be changed ... */ #if 0 /* single_pt2_link_is_cleared */ KASSERT(pt2_wirecount_get(src_mpt2pg, pte1_idx) > 0, ("%s: source page table page is unused", __func__)); #else if (pt2_wirecount_get(src_mpt2pg, pte1_idx) == 0) continue; #endif if (nextva > end_addr) nextva = end_addr; src_pte2p = pt2map_entry(addr); while (addr < nextva) { pt2_entry_t temp_pte2; temp_pte2 = pte2_load(src_pte2p); /* * we only virtual copy managed pages */ if (pte2_is_managed(temp_pte2)) { dst_mpt2pg = pmap_allocpte2(dst_pmap, addr, PMAP_ENTER_NOSLEEP); if (dst_mpt2pg == NULL) goto out; dst_pte2p = pmap_pte2_quick(dst_pmap, addr); if (!pte2_is_valid(pte2_load(dst_pte2p)) && pmap_try_insert_pv_entry(dst_pmap, addr, PHYS_TO_VM_PAGE(pte2_pa(temp_pte2)))) { /* * Clear the wired, modified, and * accessed (referenced) bits * during the copy. */ temp_pte2 &= ~(PTE2_W | PTE2_A); temp_pte2 |= PTE2_NM; pte2_store(dst_pte2p, temp_pte2); dst_pmap->pm_stats.resident_count++; } else { SLIST_INIT(&free); if (pmap_unwire_pt2(dst_pmap, addr, dst_mpt2pg, &free)) { pmap_tlb_flush(dst_pmap, addr); vm_page_free_pages_toq(&free, false); } goto out; } if (pt2_wirecount_get(dst_mpt2pg, pte1_idx) >= pt2_wirecount_get(src_mpt2pg, pte1_idx)) break; } addr += PAGE_SIZE; src_pte2p++; } } out: sched_unpin(); rw_wunlock(&pvh_global_lock); PMAP_UNLOCK(src_pmap); PMAP_UNLOCK(dst_pmap); } /* * Increase the starting virtual address of the given mapping if a * different alignment might result in more section mappings. */ void pmap_align_superpage(vm_object_t object, vm_ooffset_t offset, vm_offset_t *addr, vm_size_t size) { vm_offset_t pte1_offset; if (size < PTE1_SIZE) return; if (object != NULL && (object->flags & OBJ_COLORED) != 0) offset += ptoa(object->pg_color); pte1_offset = offset & PTE1_OFFSET; if (size - ((PTE1_SIZE - pte1_offset) & PTE1_OFFSET) < PTE1_SIZE || (*addr & PTE1_OFFSET) == pte1_offset) return; if ((*addr & PTE1_OFFSET) < pte1_offset) *addr = pte1_trunc(*addr) + pte1_offset; else *addr = pte1_roundup(*addr) + pte1_offset; } void pmap_activate(struct thread *td) { pmap_t pmap, oldpmap; u_int cpuid, ttb; PDEBUG(9, printf("%s: td = %08x\n", __func__, (uint32_t)td)); critical_enter(); pmap = vmspace_pmap(td->td_proc->p_vmspace); oldpmap = PCPU_GET(curpmap); cpuid = PCPU_GET(cpuid); #if defined(SMP) CPU_CLR_ATOMIC(cpuid, &oldpmap->pm_active); CPU_SET_ATOMIC(cpuid, &pmap->pm_active); #else CPU_CLR(cpuid, &oldpmap->pm_active); CPU_SET(cpuid, &pmap->pm_active); #endif ttb = pmap_ttb_get(pmap); /* * pmap_activate is for the current thread on the current cpu */ td->td_pcb->pcb_pagedir = ttb; cp15_ttbr_set(ttb); PCPU_SET(curpmap, pmap); critical_exit(); } +void +pmap_active_cpus(pmap_t pmap, cpuset_t *res) +{ + *res = pmap->pm_active; +} + /* * Perform the pmap work for mincore(2). If the page is not both referenced and * modified by this pmap, returns its physical address so that the caller can * find other mappings. */ int pmap_mincore(pmap_t pmap, vm_offset_t addr, vm_paddr_t *pap) { pt1_entry_t *pte1p, pte1; pt2_entry_t *pte2p, pte2; vm_paddr_t pa; bool managed; int val; PMAP_LOCK(pmap); pte1p = pmap_pte1(pmap, addr); pte1 = pte1_load(pte1p); if (pte1_is_section(pte1)) { pa = trunc_page(pte1_pa(pte1) | (addr & PTE1_OFFSET)); managed = pte1_is_managed(pte1); val = MINCORE_PSIND(1) | MINCORE_INCORE; if (pte1_is_dirty(pte1)) val |= MINCORE_MODIFIED | MINCORE_MODIFIED_OTHER; if (pte1 & PTE1_A) val |= MINCORE_REFERENCED | MINCORE_REFERENCED_OTHER; } else if (pte1_is_link(pte1)) { pte2p = pmap_pte2(pmap, addr); pte2 = pte2_load(pte2p); pmap_pte2_release(pte2p); pa = pte2_pa(pte2); managed = pte2_is_managed(pte2); val = MINCORE_INCORE; if (pte2_is_dirty(pte2)) val |= MINCORE_MODIFIED | MINCORE_MODIFIED_OTHER; if (pte2 & PTE2_A) val |= MINCORE_REFERENCED | MINCORE_REFERENCED_OTHER; } else { managed = false; val = 0; } if ((val & (MINCORE_MODIFIED_OTHER | MINCORE_REFERENCED_OTHER)) != (MINCORE_MODIFIED_OTHER | MINCORE_REFERENCED_OTHER) && managed) { *pap = pa; } PMAP_UNLOCK(pmap); return (val); } void pmap_kenter_device(vm_offset_t va, vm_size_t size, vm_paddr_t pa) { vm_offset_t sva; uint32_t l2attr; KASSERT((size & PAGE_MASK) == 0, ("%s: device mapping not page-sized", __func__)); sva = va; l2attr = vm_memattr_to_pte2(VM_MEMATTR_DEVICE); while (size != 0) { pmap_kenter_prot_attr(va, pa, PTE2_AP_KRW, l2attr); va += PAGE_SIZE; pa += PAGE_SIZE; size -= PAGE_SIZE; } tlb_flush_range(sva, va - sva); } void pmap_kremove_device(vm_offset_t va, vm_size_t size) { vm_offset_t sva; KASSERT((size & PAGE_MASK) == 0, ("%s: device mapping not page-sized", __func__)); sva = va; while (size != 0) { pmap_kremove(va); va += PAGE_SIZE; size -= PAGE_SIZE; } tlb_flush_range(sva, va - sva); } void pmap_set_pcb_pagedir(pmap_t pmap, struct pcb *pcb) { pcb->pcb_pagedir = pmap_ttb_get(pmap); } /* * Clean L1 data cache range by physical address. * The range must be within a single page. */ static void pmap_dcache_wb_pou(vm_paddr_t pa, vm_size_t size, uint32_t attr) { pt2_entry_t *cmap2_pte2p; struct pcpu *pc; KASSERT(((pa & PAGE_MASK) + size) <= PAGE_SIZE, ("%s: not on single page", __func__)); sched_pin(); pc = get_pcpu(); cmap2_pte2p = pc->pc_cmap2_pte2p; mtx_lock(&pc->pc_cmap_lock); if (pte2_load(cmap2_pte2p) != 0) panic("%s: CMAP2 busy", __func__); pte2_store(cmap2_pte2p, PTE2_KERN_NG(pa, PTE2_AP_KRW, attr)); dcache_wb_pou((vm_offset_t)pc->pc_cmap2_addr + (pa & PAGE_MASK), size); pte2_clear(cmap2_pte2p); tlb_flush((vm_offset_t)pc->pc_cmap2_addr); sched_unpin(); mtx_unlock(&pc->pc_cmap_lock); } /* * Sync instruction cache range which is not mapped yet. */ void cache_icache_sync_fresh(vm_offset_t va, vm_paddr_t pa, vm_size_t size) { uint32_t len, offset; vm_page_t m; /* Write back d-cache on given address range. */ offset = pa & PAGE_MASK; for ( ; size != 0; size -= len, pa += len, offset = 0) { len = min(PAGE_SIZE - offset, size); m = PHYS_TO_VM_PAGE(pa); KASSERT(m != NULL, ("%s: vm_page_t is null for %#x", __func__, pa)); pmap_dcache_wb_pou(pa, len, vm_page_pte2_attr(m)); } /* * I-cache is VIPT. Only way how to flush all virtual mappings * on given physical address is to invalidate all i-cache. */ icache_inv_all(); } void pmap_sync_icache(pmap_t pmap, vm_offset_t va, vm_size_t size) { /* Write back d-cache on given address range. */ if (va >= VM_MIN_KERNEL_ADDRESS) { dcache_wb_pou(va, size); } else { uint32_t len, offset; vm_paddr_t pa; vm_page_t m; offset = va & PAGE_MASK; for ( ; size != 0; size -= len, va += len, offset = 0) { pa = pmap_extract(pmap, va); /* offset is preserved */ len = min(PAGE_SIZE - offset, size); m = PHYS_TO_VM_PAGE(pa); KASSERT(m != NULL, ("%s: vm_page_t is null for %#x", __func__, pa)); pmap_dcache_wb_pou(pa, len, vm_page_pte2_attr(m)); } } /* * I-cache is VIPT. Only way how to flush all virtual mappings * on given physical address is to invalidate all i-cache. */ icache_inv_all(); } /* * The implementation of pmap_fault() uses IN_RANGE2() macro which * depends on the fact that given range size is a power of 2. */ CTASSERT(powerof2(NB_IN_PT1)); CTASSERT(powerof2(PT2MAP_SIZE)); #define IN_RANGE2(addr, start, size) \ ((vm_offset_t)(start) == ((vm_offset_t)(addr) & ~((size) - 1))) /* * Handle access and R/W emulation faults. */ int pmap_fault(pmap_t pmap, vm_offset_t far, uint32_t fsr, int idx, bool usermode) { pt1_entry_t *pte1p, pte1; pt2_entry_t *pte2p, pte2; if (pmap == NULL) pmap = kernel_pmap; /* * In kernel, we should never get abort with FAR which is in range of * pmap->pm_pt1 or PT2MAP address spaces. If it happens, stop here * and print out a useful abort message and even get to the debugger * otherwise it likely ends with never ending loop of aborts. */ if (__predict_false(IN_RANGE2(far, pmap->pm_pt1, NB_IN_PT1))) { /* * All L1 tables should always be mapped and present. * However, we check only current one herein. For user mode, * only permission abort from malicious user is not fatal. * And alignment abort as it may have higher priority. */ if (!usermode || (idx != FAULT_ALIGN && idx != FAULT_PERM_L2)) { CTR4(KTR_PMAP, "%s: pmap %#x pm_pt1 %#x far %#x", __func__, pmap, pmap->pm_pt1, far); panic("%s: pm_pt1 abort", __func__); } return (KERN_INVALID_ADDRESS); } if (__predict_false(IN_RANGE2(far, PT2MAP, PT2MAP_SIZE))) { /* * PT2MAP should be always mapped and present in current * L1 table. However, only existing L2 tables are mapped * in PT2MAP. For user mode, only L2 translation abort and * permission abort from malicious user is not fatal. * And alignment abort as it may have higher priority. */ if (!usermode || (idx != FAULT_ALIGN && idx != FAULT_TRAN_L2 && idx != FAULT_PERM_L2)) { CTR4(KTR_PMAP, "%s: pmap %#x PT2MAP %#x far %#x", __func__, pmap, PT2MAP, far); panic("%s: PT2MAP abort", __func__); } return (KERN_INVALID_ADDRESS); } /* * A pmap lock is used below for handling of access and R/W emulation * aborts. They were handled by atomic operations before so some * analysis of new situation is needed to answer the following question: * Is it safe to use the lock even for these aborts? * * There may happen two cases in general: * * (1) Aborts while the pmap lock is locked already - this should not * happen as pmap lock is not recursive. However, under pmap lock only * internal kernel data should be accessed and such data should be * mapped with A bit set and NM bit cleared. If double abort happens, * then a mapping of data which has caused it must be fixed. Further, * all new mappings are always made with A bit set and the bit can be * cleared only on managed mappings. * * (2) Aborts while another lock(s) is/are locked - this already can * happen. However, there is no difference here if it's either access or * R/W emulation abort, or if it's some other abort. */ PMAP_LOCK(pmap); #ifdef INVARIANTS pte1 = pte1_load(pmap_pte1(pmap, far)); if (pte1_is_link(pte1)) { /* * Check in advance that associated L2 page table is mapped into * PT2MAP space. Note that faulty access to not mapped L2 page * table is caught in more general check above where "far" is * checked that it does not lay in PT2MAP space. Note also that * L1 page table and PT2TAB always exist and are mapped. */ pte2 = pt2tab_load(pmap_pt2tab_entry(pmap, far)); if (!pte2_is_valid(pte2)) panic("%s: missing L2 page table (%p, %#x)", __func__, pmap, far); } #endif #ifdef SMP /* * Special treatment is due to break-before-make approach done when * pte1 is updated for userland mapping during section promotion or * demotion. If not caught here, pmap_enter() can find a section * mapping on faulting address. That is not allowed. */ if (idx == FAULT_TRAN_L1 && usermode && cp15_ats1cur_check(far) == 0) { PMAP_UNLOCK(pmap); return (KERN_SUCCESS); } #endif /* * Accesss bits for page and section. Note that the entry * is not in TLB yet, so TLB flush is not necessary. * * QQQ: This is hardware emulation, we do not call userret() * for aborts from user mode. */ if (idx == FAULT_ACCESS_L2) { pte1 = pte1_load(pmap_pte1(pmap, far)); if (pte1_is_link(pte1)) { /* L2 page table should exist and be mapped. */ pte2p = pt2map_entry(far); pte2 = pte2_load(pte2p); if (pte2_is_valid(pte2)) { pte2_store(pte2p, pte2 | PTE2_A); PMAP_UNLOCK(pmap); return (KERN_SUCCESS); } } else { /* * We got L2 access fault but PTE1 is not a link. * Probably some race happened, do nothing. */ CTR3(KTR_PMAP, "%s: FAULT_ACCESS_L2 - pmap %#x far %#x", __func__, pmap, far); PMAP_UNLOCK(pmap); return (KERN_SUCCESS); } } if (idx == FAULT_ACCESS_L1) { pte1p = pmap_pte1(pmap, far); pte1 = pte1_load(pte1p); if (pte1_is_section(pte1)) { pte1_store(pte1p, pte1 | PTE1_A); PMAP_UNLOCK(pmap); return (KERN_SUCCESS); } else { /* * We got L1 access fault but PTE1 is not section * mapping. Probably some race happened, do nothing. */ CTR3(KTR_PMAP, "%s: FAULT_ACCESS_L1 - pmap %#x far %#x", __func__, pmap, far); PMAP_UNLOCK(pmap); return (KERN_SUCCESS); } } /* * Handle modify bits for page and section. Note that the modify * bit is emulated by software. So PTEx_RO is software read only * bit and PTEx_NM flag is real hardware read only bit. * * QQQ: This is hardware emulation, we do not call userret() * for aborts from user mode. */ if ((fsr & FSR_WNR) && (idx == FAULT_PERM_L2)) { pte1 = pte1_load(pmap_pte1(pmap, far)); if (pte1_is_link(pte1)) { /* L2 page table should exist and be mapped. */ pte2p = pt2map_entry(far); pte2 = pte2_load(pte2p); if (pte2_is_valid(pte2) && !(pte2 & PTE2_RO) && (pte2 & PTE2_NM)) { pte2_store(pte2p, pte2 & ~PTE2_NM); tlb_flush(trunc_page(far)); PMAP_UNLOCK(pmap); return (KERN_SUCCESS); } } else { /* * We got L2 permission fault but PTE1 is not a link. * Probably some race happened, do nothing. */ CTR3(KTR_PMAP, "%s: FAULT_PERM_L2 - pmap %#x far %#x", __func__, pmap, far); PMAP_UNLOCK(pmap); return (KERN_SUCCESS); } } if ((fsr & FSR_WNR) && (idx == FAULT_PERM_L1)) { pte1p = pmap_pte1(pmap, far); pte1 = pte1_load(pte1p); if (pte1_is_section(pte1)) { if (!(pte1 & PTE1_RO) && (pte1 & PTE1_NM)) { pte1_store(pte1p, pte1 & ~PTE1_NM); tlb_flush(pte1_trunc(far)); PMAP_UNLOCK(pmap); return (KERN_SUCCESS); } } else { /* * We got L1 permission fault but PTE1 is not section * mapping. Probably some race happened, do nothing. */ CTR3(KTR_PMAP, "%s: FAULT_PERM_L1 - pmap %#x far %#x", __func__, pmap, far); PMAP_UNLOCK(pmap); return (KERN_SUCCESS); } } /* * QQQ: The previous code, mainly fast handling of access and * modify bits aborts, could be moved to ASM. Now we are * starting to deal with not fast aborts. */ PMAP_UNLOCK(pmap); return (KERN_FAILURE); } #if defined(PMAP_DEBUG) /* * Reusing of KVA used in pmap_zero_page function !!! */ static void pmap_zero_page_check(vm_page_t m) { pt2_entry_t *cmap2_pte2p; uint32_t *p, *end; struct pcpu *pc; sched_pin(); pc = get_pcpu(); cmap2_pte2p = pc->pc_cmap2_pte2p; mtx_lock(&pc->pc_cmap_lock); if (pte2_load(cmap2_pte2p) != 0) panic("%s: CMAP2 busy", __func__); pte2_store(cmap2_pte2p, PTE2_KERN_NG(VM_PAGE_TO_PHYS(m), PTE2_AP_KRW, vm_page_pte2_attr(m))); end = (uint32_t*)(pc->pc_cmap2_addr + PAGE_SIZE); for (p = (uint32_t*)pc->pc_cmap2_addr; p < end; p++) if (*p != 0) panic("%s: page %p not zero, va: %p", __func__, m, pc->pc_cmap2_addr); pte2_clear(cmap2_pte2p); tlb_flush((vm_offset_t)pc->pc_cmap2_addr); sched_unpin(); mtx_unlock(&pc->pc_cmap_lock); } int pmap_pid_dump(int pid) { pmap_t pmap; struct proc *p; int npte2 = 0; int i, j, index; sx_slock(&allproc_lock); FOREACH_PROC_IN_SYSTEM(p) { if (p->p_pid != pid || p->p_vmspace == NULL) continue; index = 0; pmap = vmspace_pmap(p->p_vmspace); for (i = 0; i < NPTE1_IN_PT1; i++) { pt1_entry_t pte1; pt2_entry_t *pte2p, pte2; vm_offset_t base, va; vm_paddr_t pa; vm_page_t m; base = i << PTE1_SHIFT; pte1 = pte1_load(&pmap->pm_pt1[i]); if (pte1_is_section(pte1)) { /* * QQQ: Do something here! */ } else if (pte1_is_link(pte1)) { for (j = 0; j < NPTE2_IN_PT2; j++) { va = base + (j << PAGE_SHIFT); if (va >= VM_MIN_KERNEL_ADDRESS) { if (index) { index = 0; printf("\n"); } sx_sunlock(&allproc_lock); return (npte2); } pte2p = pmap_pte2(pmap, va); pte2 = pte2_load(pte2p); pmap_pte2_release(pte2p); if (!pte2_is_valid(pte2)) continue; pa = pte2_pa(pte2); m = PHYS_TO_VM_PAGE(pa); printf("va: 0x%x, pa: 0x%x, w: %d, " "f: 0x%x", va, pa, m->ref_count, m->flags); npte2++; index++; if (index >= 2) { index = 0; printf("\n"); } else { printf(" "); } } } } } sx_sunlock(&allproc_lock); return (npte2); } #endif #ifdef DDB static pt2_entry_t * pmap_pte2_ddb(pmap_t pmap, vm_offset_t va) { pt1_entry_t pte1; vm_paddr_t pt2pg_pa; pte1 = pte1_load(pmap_pte1(pmap, va)); if (!pte1_is_link(pte1)) return (NULL); if (pmap_is_current(pmap)) return (pt2map_entry(va)); /* Note that L2 page table size is not equal to PAGE_SIZE. */ pt2pg_pa = trunc_page(pte1_link_pa(pte1)); if (pte2_pa(pte2_load(PMAP3)) != pt2pg_pa) { pte2_store(PMAP3, PTE2_KPT(pt2pg_pa)); #ifdef SMP PMAP3cpu = PCPU_GET(cpuid); #endif tlb_flush_local((vm_offset_t)PADDR3); } #ifdef SMP else if (PMAP3cpu != PCPU_GET(cpuid)) { PMAP3cpu = PCPU_GET(cpuid); tlb_flush_local((vm_offset_t)PADDR3); } #endif return (PADDR3 + (arm32_btop(va) & (NPTE2_IN_PG - 1))); } static void dump_pmap(pmap_t pmap) { printf("pmap %p\n", pmap); printf(" pm_pt1: %p\n", pmap->pm_pt1); printf(" pm_pt2tab: %p\n", pmap->pm_pt2tab); printf(" pm_active: 0x%08lX\n", pmap->pm_active.__bits[0]); } DB_SHOW_COMMAND(pmaps, pmap_list_pmaps) { pmap_t pmap; LIST_FOREACH(pmap, &allpmaps, pm_list) { dump_pmap(pmap); } } static int pte2_class(pt2_entry_t pte2) { int cls; cls = (pte2 >> 2) & 0x03; cls |= (pte2 >> 4) & 0x04; return (cls); } static void dump_section(pmap_t pmap, uint32_t pte1_idx) { } static void dump_link(pmap_t pmap, uint32_t pte1_idx, boolean_t invalid_ok) { uint32_t i; vm_offset_t va; pt2_entry_t *pte2p, pte2; vm_page_t m; va = pte1_idx << PTE1_SHIFT; pte2p = pmap_pte2_ddb(pmap, va); for (i = 0; i < NPTE2_IN_PT2; i++, pte2p++, va += PAGE_SIZE) { pte2 = pte2_load(pte2p); if (pte2 == 0) continue; if (!pte2_is_valid(pte2)) { printf(" 0x%08X: 0x%08X", va, pte2); if (!invalid_ok) printf(" - not valid !!!"); printf("\n"); continue; } m = PHYS_TO_VM_PAGE(pte2_pa(pte2)); printf(" 0x%08X: 0x%08X, TEX%d, s:%d, g:%d, m:%p", va , pte2, pte2_class(pte2), !!(pte2 & PTE2_S), !(pte2 & PTE2_NG), m); if (m != NULL) { printf(" v:%d w:%d f:0x%04X\n", m->valid, m->ref_count, m->flags); } else { printf("\n"); } } } static __inline boolean_t is_pv_chunk_space(vm_offset_t va) { if ((((vm_offset_t)pv_chunkbase) <= va) && (va < ((vm_offset_t)pv_chunkbase + PAGE_SIZE * pv_maxchunks))) return (TRUE); return (FALSE); } DB_SHOW_COMMAND(pmap, pmap_pmap_print) { /* XXX convert args. */ pmap_t pmap = (pmap_t)addr; pt1_entry_t pte1; pt2_entry_t pte2; vm_offset_t va, eva; vm_page_t m; uint32_t i; boolean_t invalid_ok, dump_link_ok, dump_pv_chunk; if (have_addr) { pmap_t pm; LIST_FOREACH(pm, &allpmaps, pm_list) if (pm == pmap) break; if (pm == NULL) { printf("given pmap %p is not in allpmaps list\n", pmap); return; } } else pmap = PCPU_GET(curpmap); eva = (modif[0] == 'u') ? VM_MAXUSER_ADDRESS : 0xFFFFFFFF; dump_pv_chunk = FALSE; /* XXX evaluate from modif[] */ printf("pmap: 0x%08X\n", (uint32_t)pmap); printf("PT2MAP: 0x%08X\n", (uint32_t)PT2MAP); printf("pt2tab: 0x%08X\n", (uint32_t)pmap->pm_pt2tab); for(i = 0; i < NPTE1_IN_PT1; i++) { pte1 = pte1_load(&pmap->pm_pt1[i]); if (pte1 == 0) continue; va = i << PTE1_SHIFT; if (va >= eva) break; if (pte1_is_section(pte1)) { printf("0x%08X: Section 0x%08X, s:%d g:%d\n", va, pte1, !!(pte1 & PTE1_S), !(pte1 & PTE1_NG)); dump_section(pmap, i); } else if (pte1_is_link(pte1)) { dump_link_ok = TRUE; invalid_ok = FALSE; pte2 = pte2_load(pmap_pt2tab_entry(pmap, va)); m = PHYS_TO_VM_PAGE(pte1_link_pa(pte1)); printf("0x%08X: Link 0x%08X, pt2tab: 0x%08X m: %p", va, pte1, pte2, m); if (is_pv_chunk_space(va)) { printf(" - pv_chunk space"); if (dump_pv_chunk) invalid_ok = TRUE; else dump_link_ok = FALSE; } else if (m != NULL) printf(" w:%d w2:%u", m->ref_count, pt2_wirecount_get(m, pte1_index(va))); if (pte2 == 0) printf(" !!! pt2tab entry is ZERO"); else if (pte2_pa(pte1) != pte2_pa(pte2)) printf(" !!! pt2tab entry is DIFFERENT - m: %p", PHYS_TO_VM_PAGE(pte2_pa(pte2))); printf("\n"); if (dump_link_ok) dump_link(pmap, i, invalid_ok); } else printf("0x%08X: Invalid entry 0x%08X\n", va, pte1); } } static void dump_pt2tab(pmap_t pmap) { uint32_t i; pt2_entry_t pte2; vm_offset_t va; vm_paddr_t pa; vm_page_t m; printf("PT2TAB:\n"); for (i = 0; i < PT2TAB_ENTRIES; i++) { pte2 = pte2_load(&pmap->pm_pt2tab[i]); if (!pte2_is_valid(pte2)) continue; va = i << PT2TAB_SHIFT; pa = pte2_pa(pte2); m = PHYS_TO_VM_PAGE(pa); printf(" 0x%08X: 0x%08X, TEX%d, s:%d, m:%p", va, pte2, pte2_class(pte2), !!(pte2 & PTE2_S), m); if (m != NULL) printf(" , w: %d, f: 0x%04X pidx: %lld", m->ref_count, m->flags, m->pindex); printf("\n"); } } DB_SHOW_COMMAND(pmap_pt2tab, pmap_pt2tab_print) { /* XXX convert args. */ pmap_t pmap = (pmap_t)addr; pt1_entry_t pte1; pt2_entry_t pte2; vm_offset_t va; uint32_t i, start; if (have_addr) { printf("supported only on current pmap\n"); return; } pmap = PCPU_GET(curpmap); printf("curpmap: 0x%08X\n", (uint32_t)pmap); printf("PT2MAP: 0x%08X\n", (uint32_t)PT2MAP); printf("pt2tab: 0x%08X\n", (uint32_t)pmap->pm_pt2tab); start = pte1_index((vm_offset_t)PT2MAP); for (i = start; i < (start + NPT2_IN_PT2TAB); i++) { pte1 = pte1_load(&pmap->pm_pt1[i]); if (pte1 == 0) continue; va = i << PTE1_SHIFT; if (pte1_is_section(pte1)) { printf("0x%08X: Section 0x%08X, s:%d\n", va, pte1, !!(pte1 & PTE1_S)); dump_section(pmap, i); } else if (pte1_is_link(pte1)) { pte2 = pte2_load(pmap_pt2tab_entry(pmap, va)); printf("0x%08X: Link 0x%08X, pt2tab: 0x%08X\n", va, pte1, pte2); if (pte2 == 0) printf(" !!! pt2tab entry is ZERO\n"); } else printf("0x%08X: Invalid entry 0x%08X\n", va, pte1); } dump_pt2tab(pmap); } #endif diff --git a/sys/arm64/include/pmap.h b/sys/arm64/include/pmap.h index fd8dc8d33f38..1789588210c3 100644 --- a/sys/arm64/include/pmap.h +++ b/sys/arm64/include/pmap.h @@ -1,204 +1,206 @@ /*- * Copyright (c) 1991 Regents of the University of California. * All rights reserved. * * This code is derived from software contributed to Berkeley by * the Systems Programming Group of the University of Utah Computer * Science Department and William Jolitz of UUNET Technologies Inc. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #ifdef __arm__ #include #else /* !__arm__ */ #ifndef _MACHINE_PMAP_H_ #define _MACHINE_PMAP_H_ #include #ifndef LOCORE #include #include #include #include #include #ifdef _KERNEL #define vtophys(va) pmap_kextract((vm_offset_t)(va)) #endif #define pmap_page_get_memattr(m) ((m)->md.pv_memattr) #define pmap_page_is_write_mapped(m) (((m)->a.flags & PGA_WRITEABLE) != 0) void pmap_page_set_memattr(vm_page_t m, vm_memattr_t ma); /* * Pmap stuff */ struct md_page { TAILQ_HEAD(,pv_entry) pv_list; int pv_gen; vm_memattr_t pv_memattr; }; /* * This structure is used to hold a virtual<->physical address * association and is used mostly by bootstrap code */ struct pv_addr { SLIST_ENTRY(pv_addr) pv_list; vm_offset_t pv_va; vm_paddr_t pv_pa; }; enum pmap_stage { PM_INVALID, PM_STAGE1, PM_STAGE2, }; struct pmap { struct mtx pm_mtx; struct pmap_statistics pm_stats; /* pmap statistics */ uint64_t pm_ttbr; vm_paddr_t pm_l0_paddr; pd_entry_t *pm_l0; TAILQ_HEAD(,pv_chunk) pm_pvchunk; /* list of mappings in pmap */ struct vm_radix pm_root; /* spare page table pages */ long pm_cookie; /* encodes the pmap's ASID */ struct asid_set *pm_asid_set; /* The ASID/VMID set to use */ enum pmap_stage pm_stage; int pm_levels; uint64_t pm_reserved[4]; }; typedef struct pmap *pmap_t; struct thread; #ifdef _KERNEL extern struct pmap kernel_pmap_store; #define kernel_pmap (&kernel_pmap_store) #define pmap_kernel() kernel_pmap #define PMAP_ASSERT_LOCKED(pmap) \ mtx_assert(&(pmap)->pm_mtx, MA_OWNED) #define PMAP_LOCK(pmap) mtx_lock(&(pmap)->pm_mtx) #define PMAP_LOCK_ASSERT(pmap, type) \ mtx_assert(&(pmap)->pm_mtx, (type)) #define PMAP_LOCK_DESTROY(pmap) mtx_destroy(&(pmap)->pm_mtx) #define PMAP_LOCK_INIT(pmap) mtx_init(&(pmap)->pm_mtx, "pmap", \ NULL, MTX_DEF | MTX_DUPOK) #define PMAP_OWNED(pmap) mtx_owned(&(pmap)->pm_mtx) #define PMAP_MTX(pmap) (&(pmap)->pm_mtx) #define PMAP_TRYLOCK(pmap) mtx_trylock(&(pmap)->pm_mtx) #define PMAP_UNLOCK(pmap) mtx_unlock(&(pmap)->pm_mtx) #define ASID_RESERVED_FOR_PID_0 0 #define ASID_RESERVED_FOR_EFI 1 #define ASID_FIRST_AVAILABLE (ASID_RESERVED_FOR_EFI + 1) #define ASID_TO_OPERAND(asid) ({ \ KASSERT((asid) != -1, ("invalid ASID")); \ (uint64_t)(asid) << TTBR_ASID_SHIFT; \ }) +#define PMAP_WANT_ACTIVE_CPUS_NAIVE + extern vm_offset_t virtual_avail; extern vm_offset_t virtual_end; /* * Macros to test if a mapping is mappable with an L1 Section mapping * or an L2 Large Page mapping. */ #define L1_MAPPABLE_P(va, pa, size) \ ((((va) | (pa)) & L1_OFFSET) == 0 && (size) >= L1_SIZE) #define pmap_vm_page_alloc_check(m) void pmap_activate_vm(pmap_t); void pmap_bootstrap(vm_paddr_t, vm_size_t); int pmap_change_attr(vm_offset_t va, vm_size_t size, int mode); int pmap_change_prot(vm_offset_t va, vm_size_t size, vm_prot_t prot); void pmap_kenter(vm_offset_t sva, vm_size_t size, vm_paddr_t pa, int mode); void pmap_kenter_device(vm_offset_t, vm_size_t, vm_paddr_t); bool pmap_klookup(vm_offset_t va, vm_paddr_t *pa); vm_paddr_t pmap_kextract(vm_offset_t va); void pmap_kremove(vm_offset_t); void pmap_kremove_device(vm_offset_t, vm_size_t); void *pmap_mapdev_attr(vm_paddr_t pa, vm_size_t size, vm_memattr_t ma); bool pmap_page_is_mapped(vm_page_t m); int pmap_pinit_stage(pmap_t, enum pmap_stage, int); bool pmap_ps_enabled(pmap_t pmap); uint64_t pmap_to_ttbr0(pmap_t pmap); void pmap_disable_promotion(vm_offset_t sva, vm_size_t size); void pmap_map_delete(pmap_t, vm_offset_t, vm_offset_t); void *pmap_mapdev(vm_paddr_t, vm_size_t); void *pmap_mapbios(vm_paddr_t, vm_size_t); void pmap_unmapdev(void *, vm_size_t); void pmap_unmapbios(void *, vm_size_t); bool pmap_map_io_transient(vm_page_t *, vm_offset_t *, int, bool); void pmap_unmap_io_transient(vm_page_t *, vm_offset_t *, int, bool); bool pmap_get_tables(pmap_t, vm_offset_t, pd_entry_t **, pd_entry_t **, pd_entry_t **, pt_entry_t **); int pmap_fault(pmap_t, uint64_t, uint64_t); struct pcb *pmap_switch(struct thread *); extern void (*pmap_clean_stage2_tlbi)(void); extern void (*pmap_invalidate_vpipt_icache)(void); extern void (*pmap_stage2_invalidate_range)(uint64_t, vm_offset_t, vm_offset_t, bool); extern void (*pmap_stage2_invalidate_all)(uint64_t); static inline int pmap_vmspace_copy(pmap_t dst_pmap __unused, pmap_t src_pmap __unused) { return (0); } #if defined(KASAN) || defined(KMSAN) struct arm64_bootparams; void pmap_bootstrap_san(vm_paddr_t); void pmap_san_enter(vm_offset_t); void pmap_san_bootstrap(struct arm64_bootparams *); #endif #endif /* _KERNEL */ #endif /* !LOCORE */ #endif /* !_MACHINE_PMAP_H_ */ #endif /* !__arm__ */ diff --git a/sys/i386/i386/pmap_base.c b/sys/i386/i386/pmap_base.c index b0c3413d1735..50229ee40caa 100644 --- a/sys/i386/i386/pmap_base.c +++ b/sys/i386/i386/pmap_base.c @@ -1,968 +1,974 @@ /*- * SPDX-License-Identifier: BSD-4-Clause * * Copyright (c) 1991 Regents of the University of California. * All rights reserved. * Copyright (c) 1994 John S. Dyson * All rights reserved. * Copyright (c) 1994 David Greenman * All rights reserved. * Copyright (c) 2005-2010 Alan L. Cox * All rights reserved. * * This code is derived from software contributed to Berkeley by * the Systems Programming Group of the University of Utah Computer * Science Department and William Jolitz of UUNET Technologies Inc. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * from: @(#)pmap.c 7.7 (Berkeley) 5/12/91 */ /*- * Copyright (c) 2003 Networks Associates Technology, Inc. * All rights reserved. * Copyright (c) 2018 The FreeBSD Foundation * All rights reserved. * * This software was developed for the FreeBSD Project by Jake Burkholder, * Safeport Network Services, and Network Associates Laboratories, the * Security Research Division of Network Associates, Inc. under * DARPA/SPAWAR contract N66001-01-C-8035 ("CBOSS"), as part of the DARPA * CHATS research program. * * Portions of this software were developed by * Konstantin Belousov under sponsorship from * the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include #include "opt_apic.h" #include "opt_cpu.h" #include "opt_pmap.h" #include "opt_smp.h" #include "opt_vm.h" #include #include #include #include #include #include #include #include #include #ifdef DEV_APIC #include #include #include #endif #include static SYSCTL_NODE(_vm, OID_AUTO, pmap, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "VM/pmap parameters"); #include #include #include #include #include vm_offset_t virtual_avail; /* VA of first avail page (after kernel bss) */ vm_offset_t virtual_end; /* VA of last avail page (end of kernel AS) */ int unmapped_buf_allowed = 1; int pti; u_long physfree; /* phys addr of next free page */ u_long vm86phystk; /* PA of vm86/bios stack */ u_long vm86paddr; /* address of vm86 region */ int vm86pa; /* phys addr of vm86 region */ u_long KERNend; /* phys addr end of kernel (just after bss) */ u_long KPTphys; /* phys addr of kernel page tables */ caddr_t ptvmmap = 0; vm_offset_t kernel_vm_end; int i386_pmap_VM_NFREEORDER; int i386_pmap_VM_LEVEL_0_ORDER; int i386_pmap_PDRSHIFT; int pat_works = 1; SYSCTL_INT(_vm_pmap, OID_AUTO, pat_works, CTLFLAG_RD, &pat_works, 0, "Is page attribute table fully functional?"); int pg_ps_enabled = 1; SYSCTL_INT(_vm_pmap, OID_AUTO, pg_ps_enabled, CTLFLAG_RDTUN | CTLFLAG_NOFETCH, &pg_ps_enabled, 0, "Are large page mappings enabled?"); int pv_entry_max = 0; SYSCTL_INT(_vm_pmap, OID_AUTO, pv_entry_max, CTLFLAG_RD, &pv_entry_max, 0, "Max number of PV entries"); int pv_entry_count = 0; SYSCTL_INT(_vm_pmap, OID_AUTO, pv_entry_count, CTLFLAG_RD, &pv_entry_count, 0, "Current number of pv entries"); #ifndef PMAP_SHPGPERPROC #define PMAP_SHPGPERPROC 200 #endif int shpgperproc = PMAP_SHPGPERPROC; SYSCTL_INT(_vm_pmap, OID_AUTO, shpgperproc, CTLFLAG_RD, &shpgperproc, 0, "Page share factor per proc"); static SYSCTL_NODE(_vm_pmap, OID_AUTO, pde, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "2/4MB page mapping counters"); u_long pmap_pde_demotions; SYSCTL_ULONG(_vm_pmap_pde, OID_AUTO, demotions, CTLFLAG_RD, &pmap_pde_demotions, 0, "2/4MB page demotions"); u_long pmap_pde_mappings; SYSCTL_ULONG(_vm_pmap_pde, OID_AUTO, mappings, CTLFLAG_RD, &pmap_pde_mappings, 0, "2/4MB page mappings"); u_long pmap_pde_p_failures; SYSCTL_ULONG(_vm_pmap_pde, OID_AUTO, p_failures, CTLFLAG_RD, &pmap_pde_p_failures, 0, "2/4MB page promotion failures"); u_long pmap_pde_promotions; SYSCTL_ULONG(_vm_pmap_pde, OID_AUTO, promotions, CTLFLAG_RD, &pmap_pde_promotions, 0, "2/4MB page promotions"); #ifdef SMP int PMAP1changedcpu; SYSCTL_INT(_debug, OID_AUTO, PMAP1changedcpu, CTLFLAG_RD, &PMAP1changedcpu, 0, "Number of times pmap_pte_quick changed CPU with same PMAP1"); #endif int PMAP1changed; SYSCTL_INT(_debug, OID_AUTO, PMAP1changed, CTLFLAG_RD, &PMAP1changed, 0, "Number of times pmap_pte_quick changed PMAP1"); int PMAP1unchanged; SYSCTL_INT(_debug, OID_AUTO, PMAP1unchanged, CTLFLAG_RD, &PMAP1unchanged, 0, "Number of times pmap_pte_quick didn't change PMAP1"); static int kvm_size(SYSCTL_HANDLER_ARGS) { unsigned long ksize; ksize = VM_MAX_KERNEL_ADDRESS - KERNBASE; return (sysctl_handle_long(oidp, &ksize, 0, req)); } SYSCTL_PROC(_vm, OID_AUTO, kvm_size, CTLTYPE_LONG | CTLFLAG_RD | CTLFLAG_MPSAFE, 0, 0, kvm_size, "IU", "Size of KVM"); static int kvm_free(SYSCTL_HANDLER_ARGS) { unsigned long kfree; kfree = VM_MAX_KERNEL_ADDRESS - kernel_vm_end; return (sysctl_handle_long(oidp, &kfree, 0, req)); } SYSCTL_PROC(_vm, OID_AUTO, kvm_free, CTLTYPE_LONG | CTLFLAG_RD | CTLFLAG_MPSAFE, 0, 0, kvm_free, "IU", "Amount of KVM free"); #ifdef PV_STATS int pc_chunk_count, pc_chunk_allocs, pc_chunk_frees, pc_chunk_tryfail; long pv_entry_frees, pv_entry_allocs; int pv_entry_spare; SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_count, CTLFLAG_RD, &pc_chunk_count, 0, "Current number of pv entry chunks"); SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_allocs, CTLFLAG_RD, &pc_chunk_allocs, 0, "Current number of pv entry chunks allocated"); SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_frees, CTLFLAG_RD, &pc_chunk_frees, 0, "Current number of pv entry chunks frees"); SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_tryfail, CTLFLAG_RD, &pc_chunk_tryfail, 0, "Number of times tried to get a chunk page but failed."); SYSCTL_LONG(_vm_pmap, OID_AUTO, pv_entry_frees, CTLFLAG_RD, &pv_entry_frees, 0, "Current number of pv entry frees"); SYSCTL_LONG(_vm_pmap, OID_AUTO, pv_entry_allocs, CTLFLAG_RD, &pv_entry_allocs, 0, "Current number of pv entry allocs"); SYSCTL_INT(_vm_pmap, OID_AUTO, pv_entry_spare, CTLFLAG_RD, &pv_entry_spare, 0, "Current number of spare pv entries"); #endif struct pmap kernel_pmap_store; static struct pmap_methods *pmap_methods_ptr; static int sysctl_kmaps(SYSCTL_HANDLER_ARGS) { return (pmap_methods_ptr->pm_sysctl_kmaps(oidp, arg1, arg2, req)); } SYSCTL_OID(_vm_pmap, OID_AUTO, kernel_maps, CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE | CTLFLAG_SKIP, NULL, 0, sysctl_kmaps, "A", "Dump kernel address layout"); /* * Initialize a vm_page's machine-dependent fields. */ void pmap_page_init(vm_page_t m) { TAILQ_INIT(&m->md.pv_list); m->md.pat_mode = PAT_WRITE_BACK; } void invltlb_glob(void) { invltlb(); } static void pmap_invalidate_cache_range_selfsnoop(vm_offset_t sva, vm_offset_t eva); static void pmap_invalidate_cache_range_all(vm_offset_t sva, vm_offset_t eva); void pmap_flush_page(vm_page_t m) { pmap_methods_ptr->pm_flush_page(m); } DEFINE_IFUNC(, void, pmap_invalidate_cache_range, (vm_offset_t, vm_offset_t)) { if ((cpu_feature & CPUID_SS) != 0) return (pmap_invalidate_cache_range_selfsnoop); if ((cpu_feature & CPUID_CLFSH) != 0) return (pmap_force_invalidate_cache_range); return (pmap_invalidate_cache_range_all); } #define PMAP_CLFLUSH_THRESHOLD (2 * 1024 * 1024) static void pmap_invalidate_cache_range_check_align(vm_offset_t sva, vm_offset_t eva) { KASSERT((sva & PAGE_MASK) == 0, ("pmap_invalidate_cache_range: sva not page-aligned")); KASSERT((eva & PAGE_MASK) == 0, ("pmap_invalidate_cache_range: eva not page-aligned")); } static void pmap_invalidate_cache_range_selfsnoop(vm_offset_t sva, vm_offset_t eva) { pmap_invalidate_cache_range_check_align(sva, eva); } void pmap_force_invalidate_cache_range(vm_offset_t sva, vm_offset_t eva) { sva &= ~(vm_offset_t)(cpu_clflush_line_size - 1); if (eva - sva >= PMAP_CLFLUSH_THRESHOLD) { /* * The supplied range is bigger than 2MB. * Globally invalidate cache. */ pmap_invalidate_cache(); return; } #ifdef DEV_APIC /* * XXX: Some CPUs fault, hang, or trash the local APIC * registers if we use CLFLUSH on the local APIC * range. The local APIC is always uncached, so we * don't need to flush for that range anyway. */ if (pmap_kextract(sva) == lapic_paddr) return; #endif if ((cpu_stdext_feature & CPUID_STDEXT_CLFLUSHOPT) != 0) { /* * Do per-cache line flush. Use the sfence * instruction to insure that previous stores are * included in the write-back. The processor * propagates flush to other processors in the cache * coherence domain. */ sfence(); for (; sva < eva; sva += cpu_clflush_line_size) clflushopt(sva); sfence(); } else { /* * Writes are ordered by CLFLUSH on Intel CPUs. */ if (cpu_vendor_id != CPU_VENDOR_INTEL) mfence(); for (; sva < eva; sva += cpu_clflush_line_size) clflush(sva); if (cpu_vendor_id != CPU_VENDOR_INTEL) mfence(); } } static void pmap_invalidate_cache_range_all(vm_offset_t sva, vm_offset_t eva) { pmap_invalidate_cache_range_check_align(sva, eva); pmap_invalidate_cache(); } void pmap_invalidate_cache_pages(vm_page_t *pages, int count) { int i; if (count >= PMAP_CLFLUSH_THRESHOLD / PAGE_SIZE || (cpu_feature & CPUID_CLFSH) == 0) { pmap_invalidate_cache(); } else { for (i = 0; i < count; i++) pmap_flush_page(pages[i]); } } void pmap_ksetrw(vm_offset_t va) { pmap_methods_ptr->pm_ksetrw(va); } void pmap_remap_lower(bool enable) { pmap_methods_ptr->pm_remap_lower(enable); } void pmap_remap_lowptdi(bool enable) { pmap_methods_ptr->pm_remap_lowptdi(enable); } void pmap_align_superpage(vm_object_t object, vm_ooffset_t offset, vm_offset_t *addr, vm_size_t size) { return (pmap_methods_ptr->pm_align_superpage(object, offset, addr, size)); } vm_offset_t pmap_quick_enter_page(vm_page_t m) { return (pmap_methods_ptr->pm_quick_enter_page(m)); } void pmap_quick_remove_page(vm_offset_t addr) { return (pmap_methods_ptr->pm_quick_remove_page(addr)); } void * pmap_trm_alloc(size_t size, int flags) { return (pmap_methods_ptr->pm_trm_alloc(size, flags)); } void pmap_trm_free(void *addr, size_t size) { pmap_methods_ptr->pm_trm_free(addr, size); } void pmap_sync_icache(pmap_t pm, vm_offset_t va, vm_size_t sz) { } vm_offset_t pmap_get_map_low(void) { return (pmap_methods_ptr->pm_get_map_low()); } vm_offset_t pmap_get_vm_maxuser_address(void) { return (pmap_methods_ptr->pm_get_vm_maxuser_address()); } vm_paddr_t pmap_kextract(vm_offset_t va) { return (pmap_methods_ptr->pm_kextract(va)); } vm_paddr_t pmap_pg_frame(vm_paddr_t pa) { return (pmap_methods_ptr->pm_pg_frame(pa)); } void pmap_sf_buf_map(struct sf_buf *sf) { pmap_methods_ptr->pm_sf_buf_map(sf); } void pmap_cp_slow0_map(vm_offset_t kaddr, int plen, vm_page_t *ma) { pmap_methods_ptr->pm_cp_slow0_map(kaddr, plen, ma); } u_int pmap_get_kcr3(void) { return (pmap_methods_ptr->pm_get_kcr3()); } u_int pmap_get_cr3(pmap_t pmap) { return (pmap_methods_ptr->pm_get_cr3(pmap)); } caddr_t pmap_cmap3(vm_paddr_t pa, u_int pte_flags) { return (pmap_methods_ptr->pm_cmap3(pa, pte_flags)); } void pmap_basemem_setup(u_int basemem) { pmap_methods_ptr->pm_basemem_setup(basemem); } void pmap_set_nx(void) { pmap_methods_ptr->pm_set_nx(); } void * pmap_bios16_enter(void) { return (pmap_methods_ptr->pm_bios16_enter()); } void pmap_bios16_leave(void *handle) { pmap_methods_ptr->pm_bios16_leave(handle); } void pmap_bootstrap(vm_paddr_t firstaddr) { pmap_methods_ptr->pm_bootstrap(firstaddr); } boolean_t pmap_is_valid_memattr(pmap_t pmap, vm_memattr_t mode) { return (pmap_methods_ptr->pm_is_valid_memattr(pmap, mode)); } int pmap_cache_bits(pmap_t pmap, int mode, boolean_t is_pde) { return (pmap_methods_ptr->pm_cache_bits(pmap, mode, is_pde)); } bool pmap_ps_enabled(pmap_t pmap) { return (pmap_methods_ptr->pm_ps_enabled(pmap)); } void pmap_pinit0(pmap_t pmap) { pmap_methods_ptr->pm_pinit0(pmap); } int pmap_pinit(pmap_t pmap) { return (pmap_methods_ptr->pm_pinit(pmap)); } void pmap_activate(struct thread *td) { pmap_methods_ptr->pm_activate(td); } void pmap_activate_boot(pmap_t pmap) { pmap_methods_ptr->pm_activate_boot(pmap); } void pmap_advise(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, int advice) { pmap_methods_ptr->pm_advise(pmap, sva, eva, advice); } void pmap_clear_modify(vm_page_t m) { pmap_methods_ptr->pm_clear_modify(m); } int pmap_change_attr(vm_offset_t va, vm_size_t size, int mode) { return (pmap_methods_ptr->pm_change_attr(va, size, mode)); } int pmap_mincore(pmap_t pmap, vm_offset_t addr, vm_paddr_t *pap) { return (pmap_methods_ptr->pm_mincore(pmap, addr, pap)); } void pmap_copy(pmap_t dst_pmap, pmap_t src_pmap, vm_offset_t dst_addr, vm_size_t len, vm_offset_t src_addr) { pmap_methods_ptr->pm_copy(dst_pmap, src_pmap, dst_addr, len, src_addr); } void pmap_copy_page(vm_page_t src, vm_page_t dst) { pmap_methods_ptr->pm_copy_page(src, dst); } void pmap_copy_pages(vm_page_t ma[], vm_offset_t a_offset, vm_page_t mb[], vm_offset_t b_offset, int xfersize) { pmap_methods_ptr->pm_copy_pages(ma, a_offset, mb, b_offset, xfersize); } void pmap_zero_page(vm_page_t m) { pmap_methods_ptr->pm_zero_page(m); } void pmap_zero_page_area(vm_page_t m, int off, int size) { pmap_methods_ptr->pm_zero_page_area(m, off, size); } int pmap_enter(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, u_int flags, int8_t psind) { return (pmap_methods_ptr->pm_enter(pmap, va, m, prot, flags, psind)); } void pmap_enter_object(pmap_t pmap, vm_offset_t start, vm_offset_t end, vm_page_t m_start, vm_prot_t prot) { pmap_methods_ptr->pm_enter_object(pmap, start, end, m_start, prot); } void pmap_enter_quick(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot) { pmap_methods_ptr->pm_enter_quick(pmap, va, m, prot); } void * pmap_kenter_temporary(vm_paddr_t pa, int i) { return (pmap_methods_ptr->pm_kenter_temporary(pa, i)); } void pmap_object_init_pt(pmap_t pmap, vm_offset_t addr, vm_object_t object, vm_pindex_t pindex, vm_size_t size) { pmap_methods_ptr->pm_object_init_pt(pmap, addr, object, pindex, size); } void pmap_unwire(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { pmap_methods_ptr->pm_unwire(pmap, sva, eva); } boolean_t pmap_page_exists_quick(pmap_t pmap, vm_page_t m) { return (pmap_methods_ptr->pm_page_exists_quick(pmap, m)); } int pmap_page_wired_mappings(vm_page_t m) { return (pmap_methods_ptr->pm_page_wired_mappings(m)); } boolean_t pmap_page_is_mapped(vm_page_t m) { return (pmap_methods_ptr->pm_page_is_mapped(m)); } void pmap_remove_pages(pmap_t pmap) { pmap_methods_ptr->pm_remove_pages(pmap); } boolean_t pmap_is_modified(vm_page_t m) { return (pmap_methods_ptr->pm_is_modified(m)); } boolean_t pmap_is_prefaultable(pmap_t pmap, vm_offset_t addr) { return (pmap_methods_ptr->pm_is_prefaultable(pmap, addr)); } boolean_t pmap_is_referenced(vm_page_t m) { return (pmap_methods_ptr->pm_is_referenced(m)); } void pmap_remove_write(vm_page_t m) { pmap_methods_ptr->pm_remove_write(m); } int pmap_ts_referenced(vm_page_t m) { return (pmap_methods_ptr->pm_ts_referenced(m)); } void * pmap_mapdev_attr(vm_paddr_t pa, vm_size_t size, int mode) { return (pmap_methods_ptr->pm_mapdev_attr(pa, size, mode, MAPDEV_SETATTR)); } void * pmap_mapdev(vm_paddr_t pa, vm_size_t size) { return (pmap_methods_ptr->pm_mapdev_attr(pa, size, PAT_UNCACHEABLE, MAPDEV_SETATTR)); } void * pmap_mapbios(vm_paddr_t pa, vm_size_t size) { return (pmap_methods_ptr->pm_mapdev_attr(pa, size, PAT_WRITE_BACK, 0)); } void pmap_unmapdev(void *p, vm_size_t size) { pmap_methods_ptr->pm_unmapdev(p, size); } void pmap_page_set_memattr(vm_page_t m, vm_memattr_t ma) { pmap_methods_ptr->pm_page_set_memattr(m, ma); } vm_paddr_t pmap_extract(pmap_t pmap, vm_offset_t va) { return (pmap_methods_ptr->pm_extract(pmap, va)); } vm_page_t pmap_extract_and_hold(pmap_t pmap, vm_offset_t va, vm_prot_t prot) { return (pmap_methods_ptr->pm_extract_and_hold(pmap, va, prot)); } vm_offset_t pmap_map(vm_offset_t *virt, vm_paddr_t start, vm_paddr_t end, int prot) { return (pmap_methods_ptr->pm_map(virt, start, end, prot)); } void pmap_qenter(vm_offset_t sva, vm_page_t *ma, int count) { pmap_methods_ptr->pm_qenter(sva, ma, count); } void pmap_qremove(vm_offset_t sva, int count) { pmap_methods_ptr->pm_qremove(sva, count); } void pmap_release(pmap_t pmap) { pmap_methods_ptr->pm_release(pmap); } void pmap_remove(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { pmap_methods_ptr->pm_remove(pmap, sva, eva); } void pmap_protect(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, vm_prot_t prot) { pmap_methods_ptr->pm_protect(pmap, sva, eva, prot); } void pmap_remove_all(vm_page_t m) { pmap_methods_ptr->pm_remove_all(m); } void pmap_init(void) { pmap_methods_ptr->pm_init(); } void pmap_init_pat(void) { pmap_methods_ptr->pm_init_pat(); } void pmap_growkernel(vm_offset_t addr) { pmap_methods_ptr->pm_growkernel(addr); } void pmap_invalidate_page(pmap_t pmap, vm_offset_t va) { pmap_methods_ptr->pm_invalidate_page(pmap, va); } void pmap_invalidate_range(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { pmap_methods_ptr->pm_invalidate_range(pmap, sva, eva); } void pmap_invalidate_all(pmap_t pmap) { pmap_methods_ptr->pm_invalidate_all(pmap); } void pmap_invalidate_cache(void) { pmap_methods_ptr->pm_invalidate_cache(); } void pmap_kenter(vm_offset_t va, vm_paddr_t pa) { pmap_methods_ptr->pm_kenter(va, pa); } void pmap_kremove(vm_offset_t va) { pmap_methods_ptr->pm_kremove(va); } +void +pmap_active_cpus(pmap_t pmap, cpuset_t *res) +{ + *res = pmap->pm_active; +} + extern struct pmap_methods pmap_pae_methods, pmap_nopae_methods; int pae_mode; SYSCTL_INT(_vm_pmap, OID_AUTO, pae_mode, CTLFLAG_RDTUN | CTLFLAG_NOFETCH, &pae_mode, 0, "PAE"); void pmap_cold(void) { init_static_kenv((char *)bootinfo.bi_envp, 0); pae_mode = (cpu_feature & CPUID_PAE) != 0; if (pae_mode) TUNABLE_INT_FETCH("vm.pmap.pae_mode", &pae_mode); if (pae_mode) { pmap_methods_ptr = &pmap_pae_methods; pmap_pae_cold(); } else { pmap_methods_ptr = &pmap_nopae_methods; pmap_nopae_cold(); } } diff --git a/sys/powerpc/powerpc/pmap_dispatch.c b/sys/powerpc/powerpc/pmap_dispatch.c index ebf81551fa07..3f1ac937433f 100644 --- a/sys/powerpc/powerpc/pmap_dispatch.c +++ b/sys/powerpc/powerpc/pmap_dispatch.c @@ -1,255 +1,261 @@ /*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright (c) 2005 Peter Grehan * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * */ #include /* * Dispatch MI pmap calls to the appropriate MMU implementation * through a previously registered kernel object. * * Before pmap_bootstrap() can be called, a CPU module must have * called pmap_mmu_install(). This may be called multiple times: * the highest priority call will be installed as the default * MMU handler when pmap_bootstrap() is called. * * It is required that mutex_init() be called before pmap_bootstrap(), * as the PMAP layer makes extensive use of mutexes. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include mmu_t mmu_obj; /* * pmap globals */ struct pmap kernel_pmap_store; vm_offset_t msgbuf_phys; vm_offset_t kernel_vm_end; vm_offset_t virtual_avail; vm_offset_t virtual_end; caddr_t crashdumpmap; int pmap_bootstrapped; /* Default level 0 reservations consist of 512 pages (2MB superpage). */ int vm_level_0_order = 9; SYSCTL_NODE(_vm, OID_AUTO, pmap, CTLFLAG_RD, 0, "VM/pmap parameters"); int superpages_enabled = 1; SYSCTL_INT(_vm_pmap, OID_AUTO, superpages_enabled, CTLFLAG_RDTUN, &superpages_enabled, 0, "Enable support for transparent superpages"); #ifdef AIM int pvo_vaddr_compare(struct pvo_entry *a, struct pvo_entry *b) { if (PVO_VADDR(a) < PVO_VADDR(b)) return (-1); else if (PVO_VADDR(a) > PVO_VADDR(b)) return (1); return (0); } RB_GENERATE(pvo_tree, pvo_entry, pvo_plink, pvo_vaddr_compare); #endif static int pmap_nomethod(void) { return (0); } #define DEFINE_PMAP_IFUNC(ret, func, args) \ DEFINE_IFUNC(, ret, pmap_##func, args) { \ pmap_##func##_t f; \ f = PMAP_RESOLVE_FUNC(func); \ return (f != NULL ? f : (pmap_##func##_t)pmap_nomethod);\ } #define DEFINE_DUMPSYS_IFUNC(ret, func, args) \ DEFINE_IFUNC(, ret, dumpsys_##func, args) { \ pmap_dumpsys_##func##_t f; \ f = PMAP_RESOLVE_FUNC(dumpsys_##func); \ return (f != NULL ? f : (pmap_dumpsys_##func##_t)pmap_nomethod);\ } DEFINE_PMAP_IFUNC(void, activate, (struct thread *)); DEFINE_PMAP_IFUNC(void, advise, (pmap_t, vm_offset_t, vm_offset_t, int)); DEFINE_PMAP_IFUNC(void, align_superpage, (vm_object_t, vm_ooffset_t, vm_offset_t *, vm_size_t)); DEFINE_PMAP_IFUNC(void, clear_modify, (vm_page_t)); DEFINE_PMAP_IFUNC(void, copy, (pmap_t, pmap_t, vm_offset_t, vm_size_t, vm_offset_t)); DEFINE_PMAP_IFUNC(int, enter, (pmap_t, vm_offset_t, vm_page_t, vm_prot_t, u_int, int8_t)); DEFINE_PMAP_IFUNC(void, enter_quick, (pmap_t, vm_offset_t, vm_page_t, vm_prot_t)); DEFINE_PMAP_IFUNC(void, enter_object, (pmap_t, vm_offset_t, vm_offset_t, vm_page_t, vm_prot_t)); DEFINE_PMAP_IFUNC(vm_paddr_t, extract, (pmap_t, vm_offset_t)); DEFINE_PMAP_IFUNC(vm_page_t, extract_and_hold, (pmap_t, vm_offset_t, vm_prot_t)); DEFINE_PMAP_IFUNC(void, kenter, (vm_offset_t, vm_paddr_t)); DEFINE_PMAP_IFUNC(void, kenter_attr, (vm_offset_t, vm_paddr_t, vm_memattr_t)); DEFINE_PMAP_IFUNC(vm_paddr_t, kextract, (vm_offset_t)); DEFINE_PMAP_IFUNC(void, kremove, (vm_offset_t)); DEFINE_PMAP_IFUNC(void, object_init_pt, (pmap_t, vm_offset_t, vm_object_t, vm_pindex_t, vm_size_t)); DEFINE_PMAP_IFUNC(boolean_t, is_modified, (vm_page_t)); DEFINE_PMAP_IFUNC(boolean_t, is_prefaultable, (pmap_t, vm_offset_t)); DEFINE_PMAP_IFUNC(boolean_t, is_referenced, (vm_page_t)); DEFINE_PMAP_IFUNC(boolean_t, page_exists_quick, (pmap_t, vm_page_t)); DEFINE_PMAP_IFUNC(void, page_init, (vm_page_t)); DEFINE_PMAP_IFUNC(boolean_t, page_is_mapped, (vm_page_t)); DEFINE_PMAP_IFUNC(int, page_wired_mappings, (vm_page_t)); DEFINE_PMAP_IFUNC(void, protect, (pmap_t, vm_offset_t, vm_offset_t, vm_prot_t)); DEFINE_PMAP_IFUNC(bool, ps_enabled, (pmap_t)); DEFINE_PMAP_IFUNC(void, qenter, (vm_offset_t, vm_page_t *, int)); DEFINE_PMAP_IFUNC(void, qremove, (vm_offset_t, int)); DEFINE_PMAP_IFUNC(vm_offset_t, quick_enter_page, (vm_page_t)); DEFINE_PMAP_IFUNC(void, quick_remove_page, (vm_offset_t)); DEFINE_PMAP_IFUNC(int, ts_referenced, (vm_page_t)); DEFINE_PMAP_IFUNC(void, release, (pmap_t)); DEFINE_PMAP_IFUNC(void, remove, (pmap_t, vm_offset_t, vm_offset_t)); DEFINE_PMAP_IFUNC(void, remove_all, (vm_page_t)); DEFINE_PMAP_IFUNC(void, remove_pages, (pmap_t)); DEFINE_PMAP_IFUNC(void, remove_write, (vm_page_t)); DEFINE_PMAP_IFUNC(void, unwire, (pmap_t, vm_offset_t, vm_offset_t)); DEFINE_PMAP_IFUNC(void, zero_page, (vm_page_t)); DEFINE_PMAP_IFUNC(void, zero_page_area, (vm_page_t, int, int)); DEFINE_PMAP_IFUNC(void, copy_page, (vm_page_t, vm_page_t)); DEFINE_PMAP_IFUNC(void, copy_pages, (vm_page_t ma[], vm_offset_t a_offset, vm_page_t mb[], vm_offset_t b_offset, int xfersize)); DEFINE_PMAP_IFUNC(void, growkernel, (vm_offset_t)); DEFINE_PMAP_IFUNC(void, init, (void)); DEFINE_PMAP_IFUNC(vm_offset_t, map, (vm_offset_t *, vm_paddr_t, vm_paddr_t, int)); DEFINE_PMAP_IFUNC(int, pinit, (pmap_t)); DEFINE_PMAP_IFUNC(void, pinit0, (pmap_t)); DEFINE_PMAP_IFUNC(int, mincore, (pmap_t, vm_offset_t, vm_paddr_t *)); DEFINE_PMAP_IFUNC(void, deactivate, (struct thread *)); DEFINE_PMAP_IFUNC(void, bootstrap, (vm_offset_t, vm_offset_t)); DEFINE_PMAP_IFUNC(void, cpu_bootstrap, (int)); DEFINE_PMAP_IFUNC(void *, mapdev, (vm_paddr_t, vm_size_t)); DEFINE_PMAP_IFUNC(void *, mapdev_attr, (vm_paddr_t, vm_size_t, vm_memattr_t)); DEFINE_PMAP_IFUNC(void, page_set_memattr, (vm_page_t, vm_memattr_t)); DEFINE_PMAP_IFUNC(void, unmapdev, (void *, vm_size_t)); DEFINE_PMAP_IFUNC(int, map_user_ptr, (pmap_t, volatile const void *, void **, size_t, size_t *)); DEFINE_PMAP_IFUNC(int, decode_kernel_ptr, (vm_offset_t, int *, vm_offset_t *)); DEFINE_PMAP_IFUNC(int, dev_direct_mapped, (vm_paddr_t, vm_size_t)); DEFINE_PMAP_IFUNC(void, sync_icache, (pmap_t, vm_offset_t, vm_size_t)); DEFINE_PMAP_IFUNC(int, change_attr, (vm_offset_t, vm_size_t, vm_memattr_t)); DEFINE_PMAP_IFUNC(void, page_array_startup, (long)); DEFINE_PMAP_IFUNC(void, tlbie_all, (void)); DEFINE_DUMPSYS_IFUNC(void, map_chunk, (vm_paddr_t, size_t, void **)); DEFINE_DUMPSYS_IFUNC(void, unmap_chunk, (vm_paddr_t, size_t, void *)); DEFINE_DUMPSYS_IFUNC(void, pa_init, (void)); DEFINE_DUMPSYS_IFUNC(size_t, scan_pmap, (struct bitset *)); DEFINE_DUMPSYS_IFUNC(void *, dump_pmap_init, (unsigned)); DEFINE_DUMPSYS_IFUNC(void *, dump_pmap, (void *, void *, u_long *)); /* * MMU install routines. Highest priority wins, equal priority also * overrides allowing last-set to win. */ SET_DECLARE(mmu_set, struct mmu_kobj); boolean_t pmap_mmu_install(char *name, int prio) { mmu_t *mmupp, mmup; static int curr_prio = 0; /* * Try and locate the MMU kobj corresponding to the name */ SET_FOREACH(mmupp, mmu_set) { mmup = *mmupp; if (mmup->name && !strcmp(mmup->name, name) && (prio >= curr_prio || mmu_obj == NULL)) { curr_prio = prio; mmu_obj = mmup; return (TRUE); } } return (FALSE); } /* MMU "pre-bootstrap" init, used to install extra resolvers, etc. */ void pmap_mmu_init(void) { if (mmu_obj->funcs->install != NULL) (mmu_obj->funcs->install)(); } const char * pmap_mmu_name(void) { return (mmu_obj->name); } int unmapped_buf_allowed; boolean_t pmap_is_valid_memattr(pmap_t pmap __unused, vm_memattr_t mode) { switch (mode) { case VM_MEMATTR_DEFAULT: case VM_MEMATTR_UNCACHEABLE: case VM_MEMATTR_CACHEABLE: case VM_MEMATTR_WRITE_COMBINING: case VM_MEMATTR_WRITE_BACK: case VM_MEMATTR_WRITE_THROUGH: case VM_MEMATTR_PREFETCHABLE: return (TRUE); default: return (FALSE); } } + +void +pmap_active_cpus(pmap_t pmap, cpuset_t *res) +{ + *res = pmap->pm_active; +} diff --git a/sys/riscv/riscv/pmap.c b/sys/riscv/riscv/pmap.c index 20e6ccd22b62..49ee54b37918 100644 --- a/sys/riscv/riscv/pmap.c +++ b/sys/riscv/riscv/pmap.c @@ -1,5028 +1,5034 @@ /*- * SPDX-License-Identifier: BSD-4-Clause * * Copyright (c) 1991 Regents of the University of California. * All rights reserved. * Copyright (c) 1994 John S. Dyson * All rights reserved. * Copyright (c) 1994 David Greenman * All rights reserved. * Copyright (c) 2003 Peter Wemm * All rights reserved. * Copyright (c) 2005-2010 Alan L. Cox * All rights reserved. * Copyright (c) 2014 Andrew Turner * All rights reserved. * Copyright (c) 2014 The FreeBSD Foundation * All rights reserved. * Copyright (c) 2015-2018 Ruslan Bukin * All rights reserved. * * This code is derived from software contributed to Berkeley by * the Systems Programming Group of the University of Utah Computer * Science Department and William Jolitz of UUNET Technologies Inc. * * Portions of this software were developed by Andrew Turner under * sponsorship from The FreeBSD Foundation. * * Portions of this software were developed by SRI International and the * University of Cambridge Computer Laboratory under DARPA/AFRL contract * FA8750-10-C-0237 ("CTSRD"), as part of the DARPA CRASH research programme. * * Portions of this software were developed by the University of Cambridge * Computer Laboratory as part of the CTSRD Project, with support from the * UK Higher Education Innovation Fund (HEIF). * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * from: @(#)pmap.c 7.7 (Berkeley) 5/12/91 */ /*- * Copyright (c) 2003 Networks Associates Technology, Inc. * All rights reserved. * * This software was developed for the FreeBSD Project by Jake Burkholder, * Safeport Network Services, and Network Associates Laboratories, the * Security Research Division of Network Associates, Inc. under * DARPA/SPAWAR contract N66001-01-C-8035 ("CBOSS"), as part of the DARPA * CHATS research program. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include /* * Manages physical address maps. * * Since the information managed by this module is * also stored by the logical address mapping module, * this module may throw away valid virtual-to-physical * mappings at almost any time. However, invalidations * of virtual-to-physical mappings must be done as * requested. * * In order to cope with hardware architectures which * make virtual-to-physical map invalidates expensive, * this module may delay invalidate or reduced protection * operations until such time as they are actually * necessary. This module is given full information as * to which processors are currently using which maps, * and to when physical maps must be made correct. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Boundary values for the page table page index space: * * L3 pages: [0, NUL2E) * L2 pages: [NUL2E, NUL2E + NUL1E) * L1 pages: [NUL2E + NUL1E, NUL2E + NUL1E + NUL0E) * * Note that these ranges are used in both SV39 and SV48 mode. In SV39 mode the * ranges are not fully populated since there are at most Ln_ENTRIES^2 L3 pages * in a set of page tables. */ #define NUL0E Ln_ENTRIES #define NUL1E (Ln_ENTRIES * NUL0E) #define NUL2E (Ln_ENTRIES * NUL1E) #if !defined(DIAGNOSTIC) #ifdef __GNUC_GNU_INLINE__ #define PMAP_INLINE __attribute__((__gnu_inline__)) inline #else #define PMAP_INLINE extern inline #endif #else #define PMAP_INLINE #endif #ifdef PV_STATS #define PV_STAT(x) do { x ; } while (0) #define __pv_stat_used #else #define PV_STAT(x) do { } while (0) #define __pv_stat_used __unused #endif #define pmap_l1_pindex(v) (NUL2E + ((v) >> L1_SHIFT)) #define pmap_l2_pindex(v) ((v) >> L2_SHIFT) #define pa_to_pvh(pa) (&pv_table[pa_index(pa)]) #define NPV_LIST_LOCKS MAXCPU #define PHYS_TO_PV_LIST_LOCK(pa) \ (&pv_list_locks[pmap_l2_pindex(pa) % NPV_LIST_LOCKS]) #define CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, pa) do { \ struct rwlock **_lockp = (lockp); \ struct rwlock *_new_lock; \ \ _new_lock = PHYS_TO_PV_LIST_LOCK(pa); \ if (_new_lock != *_lockp) { \ if (*_lockp != NULL) \ rw_wunlock(*_lockp); \ *_lockp = _new_lock; \ rw_wlock(*_lockp); \ } \ } while (0) #define CHANGE_PV_LIST_LOCK_TO_VM_PAGE(lockp, m) \ CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, VM_PAGE_TO_PHYS(m)) #define RELEASE_PV_LIST_LOCK(lockp) do { \ struct rwlock **_lockp = (lockp); \ \ if (*_lockp != NULL) { \ rw_wunlock(*_lockp); \ *_lockp = NULL; \ } \ } while (0) #define VM_PAGE_TO_PV_LIST_LOCK(m) \ PHYS_TO_PV_LIST_LOCK(VM_PAGE_TO_PHYS(m)) static SYSCTL_NODE(_vm, OID_AUTO, pmap, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "VM/pmap parameters"); /* The list of all the user pmaps */ LIST_HEAD(pmaplist, pmap); static struct pmaplist allpmaps = LIST_HEAD_INITIALIZER(); enum pmap_mode __read_frequently pmap_mode = PMAP_MODE_SV39; SYSCTL_INT(_vm_pmap, OID_AUTO, mode, CTLFLAG_RDTUN | CTLFLAG_NOFETCH, &pmap_mode, 0, "translation mode, 0 = SV39, 1 = SV48"); struct pmap kernel_pmap_store; vm_offset_t virtual_avail; /* VA of first avail page (after kernel bss) */ vm_offset_t virtual_end; /* VA of last avail page (end of kernel AS) */ vm_offset_t kernel_vm_end = 0; vm_paddr_t dmap_phys_base; /* The start of the dmap region */ vm_paddr_t dmap_phys_max; /* The limit of the dmap region */ vm_offset_t dmap_max_addr; /* The virtual address limit of the dmap */ /* This code assumes all L1 DMAP entries will be used */ CTASSERT((DMAP_MIN_ADDRESS & ~L1_OFFSET) == DMAP_MIN_ADDRESS); CTASSERT((DMAP_MAX_ADDRESS & ~L1_OFFSET) == DMAP_MAX_ADDRESS); /* * This code assumes that the early DEVMAP is L2_SIZE aligned and is fully * contained within a single L2 entry. The early DTB is mapped immediately * before the devmap L2 entry. */ CTASSERT((PMAP_MAPDEV_EARLY_SIZE & L2_OFFSET) == 0); CTASSERT((VM_EARLY_DTB_ADDRESS & L2_OFFSET) == 0); CTASSERT(VM_EARLY_DTB_ADDRESS < (VM_MAX_KERNEL_ADDRESS - PMAP_MAPDEV_EARLY_SIZE)); static struct rwlock_padalign pvh_global_lock; static struct mtx_padalign allpmaps_lock; static int superpages_enabled = 1; SYSCTL_INT(_vm_pmap, OID_AUTO, superpages_enabled, CTLFLAG_RDTUN, &superpages_enabled, 0, "Enable support for transparent superpages"); static SYSCTL_NODE(_vm_pmap, OID_AUTO, l2, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "2MB page mapping counters"); static u_long pmap_l2_demotions; SYSCTL_ULONG(_vm_pmap_l2, OID_AUTO, demotions, CTLFLAG_RD, &pmap_l2_demotions, 0, "2MB page demotions"); static u_long pmap_l2_mappings; SYSCTL_ULONG(_vm_pmap_l2, OID_AUTO, mappings, CTLFLAG_RD, &pmap_l2_mappings, 0, "2MB page mappings"); static u_long pmap_l2_p_failures; SYSCTL_ULONG(_vm_pmap_l2, OID_AUTO, p_failures, CTLFLAG_RD, &pmap_l2_p_failures, 0, "2MB page promotion failures"); static u_long pmap_l2_promotions; SYSCTL_ULONG(_vm_pmap_l2, OID_AUTO, promotions, CTLFLAG_RD, &pmap_l2_promotions, 0, "2MB page promotions"); /* * Data for the pv entry allocation mechanism */ static TAILQ_HEAD(pch, pv_chunk) pv_chunks = TAILQ_HEAD_INITIALIZER(pv_chunks); static struct mtx pv_chunks_mutex; static struct rwlock pv_list_locks[NPV_LIST_LOCKS]; static struct md_page *pv_table; static struct md_page pv_dummy; extern cpuset_t all_harts; /* * Internal flags for pmap_enter()'s helper functions. */ #define PMAP_ENTER_NORECLAIM 0x1000000 /* Don't reclaim PV entries. */ #define PMAP_ENTER_NOREPLACE 0x2000000 /* Don't replace mappings. */ static void free_pv_chunk(struct pv_chunk *pc); static void free_pv_entry(pmap_t pmap, pv_entry_t pv); static pv_entry_t get_pv_entry(pmap_t pmap, struct rwlock **lockp); static vm_page_t reclaim_pv_chunk(pmap_t locked_pmap, struct rwlock **lockp); static void pmap_pvh_free(struct md_page *pvh, pmap_t pmap, vm_offset_t va); static pv_entry_t pmap_pvh_remove(struct md_page *pvh, pmap_t pmap, vm_offset_t va); static bool pmap_demote_l2(pmap_t pmap, pd_entry_t *l2, vm_offset_t va); static bool pmap_demote_l2_locked(pmap_t pmap, pd_entry_t *l2, vm_offset_t va, struct rwlock **lockp); static int pmap_enter_l2(pmap_t pmap, vm_offset_t va, pd_entry_t new_l2, u_int flags, vm_page_t m, struct rwlock **lockp); static vm_page_t pmap_enter_quick_locked(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, vm_page_t mpte, struct rwlock **lockp); static int pmap_remove_l3(pmap_t pmap, pt_entry_t *l3, vm_offset_t sva, pd_entry_t ptepde, struct spglist *free, struct rwlock **lockp); static boolean_t pmap_try_insert_pv_entry(pmap_t pmap, vm_offset_t va, vm_page_t m, struct rwlock **lockp); static vm_page_t _pmap_alloc_l3(pmap_t pmap, vm_pindex_t ptepindex, struct rwlock **lockp); static void _pmap_unwire_ptp(pmap_t pmap, vm_offset_t va, vm_page_t m, struct spglist *free); static int pmap_unuse_pt(pmap_t, vm_offset_t, pd_entry_t, struct spglist *); static int pmap_change_attr_locked(vm_offset_t va, vm_size_t size, int mode); #define pmap_clear(pte) pmap_store(pte, 0) #define pmap_clear_bits(pte, bits) atomic_clear_64(pte, bits) #define pmap_load_store(pte, entry) atomic_swap_64(pte, entry) #define pmap_load_clear(pte) pmap_load_store(pte, 0) #define pmap_load(pte) atomic_load_64(pte) #define pmap_store(pte, entry) atomic_store_64(pte, entry) #define pmap_store_bits(pte, bits) atomic_set_64(pte, bits) /********************/ /* Inline functions */ /********************/ static __inline void pagecopy(void *s, void *d) { memcpy(d, s, PAGE_SIZE); } static __inline void pagezero(void *p) { bzero(p, PAGE_SIZE); } #define pmap_l0_index(va) (((va) >> L0_SHIFT) & Ln_ADDR_MASK) #define pmap_l1_index(va) (((va) >> L1_SHIFT) & Ln_ADDR_MASK) #define pmap_l2_index(va) (((va) >> L2_SHIFT) & Ln_ADDR_MASK) #define pmap_l3_index(va) (((va) >> L3_SHIFT) & Ln_ADDR_MASK) #define PTE_TO_PHYS(pte) \ ((((pte) & ~PTE_HI_MASK) >> PTE_PPN0_S) * PAGE_SIZE) #define L2PTE_TO_PHYS(l2) \ ((((l2) & ~PTE_HI_MASK) >> PTE_PPN1_S) << L2_SHIFT) static __inline pd_entry_t * pmap_l0(pmap_t pmap, vm_offset_t va) { KASSERT(pmap_mode != PMAP_MODE_SV39, ("%s: in SV39 mode", __func__)); KASSERT(VIRT_IS_VALID(va), ("%s: malformed virtual address %#lx", __func__, va)); return (&pmap->pm_top[pmap_l0_index(va)]); } static __inline pd_entry_t * pmap_l0_to_l1(pd_entry_t *l0, vm_offset_t va) { vm_paddr_t phys; pd_entry_t *l1; KASSERT(pmap_mode != PMAP_MODE_SV39, ("%s: in SV39 mode", __func__)); phys = PTE_TO_PHYS(pmap_load(l0)); l1 = (pd_entry_t *)PHYS_TO_DMAP(phys); return (&l1[pmap_l1_index(va)]); } static __inline pd_entry_t * pmap_l1(pmap_t pmap, vm_offset_t va) { pd_entry_t *l0; KASSERT(VIRT_IS_VALID(va), ("%s: malformed virtual address %#lx", __func__, va)); if (pmap_mode == PMAP_MODE_SV39) { return (&pmap->pm_top[pmap_l1_index(va)]); } else { l0 = pmap_l0(pmap, va); if ((pmap_load(l0) & PTE_V) == 0) return (NULL); if ((pmap_load(l0) & PTE_RX) != 0) return (NULL); return (pmap_l0_to_l1(l0, va)); } } static __inline pd_entry_t * pmap_l1_to_l2(pd_entry_t *l1, vm_offset_t va) { vm_paddr_t phys; pd_entry_t *l2; phys = PTE_TO_PHYS(pmap_load(l1)); l2 = (pd_entry_t *)PHYS_TO_DMAP(phys); return (&l2[pmap_l2_index(va)]); } static __inline pd_entry_t * pmap_l2(pmap_t pmap, vm_offset_t va) { pd_entry_t *l1; l1 = pmap_l1(pmap, va); if (l1 == NULL) return (NULL); if ((pmap_load(l1) & PTE_V) == 0) return (NULL); if ((pmap_load(l1) & PTE_RX) != 0) return (NULL); return (pmap_l1_to_l2(l1, va)); } static __inline pt_entry_t * pmap_l2_to_l3(pd_entry_t *l2, vm_offset_t va) { vm_paddr_t phys; pt_entry_t *l3; phys = PTE_TO_PHYS(pmap_load(l2)); l3 = (pd_entry_t *)PHYS_TO_DMAP(phys); return (&l3[pmap_l3_index(va)]); } static __inline pt_entry_t * pmap_l3(pmap_t pmap, vm_offset_t va) { pd_entry_t *l2; l2 = pmap_l2(pmap, va); if (l2 == NULL) return (NULL); if ((pmap_load(l2) & PTE_V) == 0) return (NULL); if ((pmap_load(l2) & PTE_RX) != 0) return (NULL); return (pmap_l2_to_l3(l2, va)); } static __inline void pmap_resident_count_inc(pmap_t pmap, int count) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); pmap->pm_stats.resident_count += count; } static __inline void pmap_resident_count_dec(pmap_t pmap, int count) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT(pmap->pm_stats.resident_count >= count, ("pmap %p resident count underflow %ld %d", pmap, pmap->pm_stats.resident_count, count)); pmap->pm_stats.resident_count -= count; } static void pmap_distribute_l1(struct pmap *pmap, vm_pindex_t l1index, pt_entry_t entry) { struct pmap *user_pmap; pd_entry_t *l1; /* * Distribute new kernel L1 entry to all the user pmaps. This is only * necessary with three-level paging configured: with four-level paging * the kernel's half of the top-level page table page is static and can * simply be copied at pmap initialization time. */ if (pmap != kernel_pmap || pmap_mode != PMAP_MODE_SV39) return; mtx_lock(&allpmaps_lock); LIST_FOREACH(user_pmap, &allpmaps, pm_list) { l1 = &user_pmap->pm_top[l1index]; pmap_store(l1, entry); } mtx_unlock(&allpmaps_lock); } static pt_entry_t * pmap_early_page_idx(vm_offset_t l1pt, vm_offset_t va, u_int *l1_slot, u_int *l2_slot) { pt_entry_t *l2; pd_entry_t *l1 __diagused; l1 = (pd_entry_t *)l1pt; *l1_slot = (va >> L1_SHIFT) & Ln_ADDR_MASK; /* Check locore has used a table L1 map */ KASSERT((l1[*l1_slot] & PTE_RX) == 0, ("Invalid bootstrap L1 table")); /* Find the address of the L2 table */ l2 = (pt_entry_t *)init_pt_va; *l2_slot = pmap_l2_index(va); return (l2); } static vm_paddr_t pmap_early_vtophys(vm_offset_t l1pt, vm_offset_t va) { u_int l1_slot, l2_slot; pt_entry_t *l2; vm_paddr_t ret; l2 = pmap_early_page_idx(l1pt, va, &l1_slot, &l2_slot); /* Check locore has used L2 superpages */ KASSERT((l2[l2_slot] & PTE_RX) != 0, ("Invalid bootstrap L2 table")); /* L2 is superpages */ ret = L2PTE_TO_PHYS(l2[l2_slot]); ret += (va & L2_OFFSET); return (ret); } static void pmap_bootstrap_dmap(vm_offset_t kern_l1, vm_paddr_t min_pa, vm_paddr_t max_pa) { vm_offset_t va; vm_paddr_t pa; pd_entry_t *l1; u_int l1_slot; pt_entry_t entry; pn_t pn; pa = dmap_phys_base = min_pa & ~L1_OFFSET; va = DMAP_MIN_ADDRESS; l1 = (pd_entry_t *)kern_l1; l1_slot = pmap_l1_index(DMAP_MIN_ADDRESS); for (; va < DMAP_MAX_ADDRESS && pa < max_pa; pa += L1_SIZE, va += L1_SIZE, l1_slot++) { KASSERT(l1_slot < Ln_ENTRIES, ("Invalid L1 index")); /* superpages */ pn = (pa / PAGE_SIZE); entry = PTE_KERN; entry |= (pn << PTE_PPN0_S); pmap_store(&l1[l1_slot], entry); } /* Set the upper limit of the DMAP region */ dmap_phys_max = pa; dmap_max_addr = va; sfence_vma(); } static vm_offset_t pmap_bootstrap_l3(vm_offset_t l1pt, vm_offset_t va, vm_offset_t l3_start) { vm_offset_t l3pt; pt_entry_t entry; pd_entry_t *l2; vm_paddr_t pa; u_int l2_slot; pn_t pn; KASSERT((va & L2_OFFSET) == 0, ("Invalid virtual address")); l2 = pmap_l2(kernel_pmap, va); l2 = (pd_entry_t *)((uintptr_t)l2 & ~(PAGE_SIZE - 1)); l2_slot = pmap_l2_index(va); l3pt = l3_start; for (; va < VM_MAX_KERNEL_ADDRESS; l2_slot++, va += L2_SIZE) { KASSERT(l2_slot < Ln_ENTRIES, ("Invalid L2 index")); pa = pmap_early_vtophys(l1pt, l3pt); pn = (pa / PAGE_SIZE); entry = (PTE_V); entry |= (pn << PTE_PPN0_S); pmap_store(&l2[l2_slot], entry); l3pt += PAGE_SIZE; } /* Clean the L2 page table */ memset((void *)l3_start, 0, l3pt - l3_start); return (l3pt); } /* * Bootstrap the system enough to run with virtual memory. */ void pmap_bootstrap(vm_offset_t l1pt, vm_paddr_t kernstart, vm_size_t kernlen) { vm_paddr_t physmap[PHYS_AVAIL_ENTRIES]; uint64_t satp; vm_offset_t dpcpu, freemempos, l0pv, msgbufpv; vm_paddr_t l0pa, l1pa, max_pa, min_pa, pa; pd_entry_t *l0p; pt_entry_t *l2p; u_int l1_slot, l2_slot; u_int physmap_idx; int i, mode; printf("pmap_bootstrap %lx %lx %lx\n", l1pt, kernstart, kernlen); /* Set this early so we can use the pagetable walking functions */ kernel_pmap_store.pm_top = (pd_entry_t *)l1pt; PMAP_LOCK_INIT(kernel_pmap); TAILQ_INIT(&kernel_pmap->pm_pvchunk); vm_radix_init(&kernel_pmap->pm_root); rw_init(&pvh_global_lock, "pmap pv global"); /* * Set the current CPU as active in the kernel pmap. Secondary cores * will add themselves later in init_secondary(). The SBI firmware * may rely on this mask being precise, so CPU_FILL() is not used. */ CPU_SET(PCPU_GET(hart), &kernel_pmap->pm_active); /* Assume the address we were loaded to is a valid physical address. */ min_pa = max_pa = kernstart; physmap_idx = physmem_avail(physmap, nitems(physmap)); physmap_idx /= 2; /* * Find the minimum physical address. physmap is sorted, * but may contain empty ranges. */ for (i = 0; i < physmap_idx * 2; i += 2) { if (physmap[i] == physmap[i + 1]) continue; if (physmap[i] <= min_pa) min_pa = physmap[i]; if (physmap[i + 1] > max_pa) max_pa = physmap[i + 1]; } printf("physmap_idx %u\n", physmap_idx); printf("min_pa %lx\n", min_pa); printf("max_pa %lx\n", max_pa); /* Create a direct map region early so we can use it for pa -> va */ pmap_bootstrap_dmap(l1pt, min_pa, max_pa); /* * Read the page table to find out what is already mapped. * This assumes we have mapped a block of memory from KERNBASE * using a single L1 entry. */ (void)pmap_early_page_idx(l1pt, KERNBASE, &l1_slot, &l2_slot); /* Sanity check the index, KERNBASE should be the first VA */ KASSERT(l2_slot == 0, ("The L2 index is non-zero")); freemempos = roundup2(KERNBASE + kernlen, PAGE_SIZE); /* Create the l3 tables for the early devmap */ freemempos = pmap_bootstrap_l3(l1pt, VM_MAX_KERNEL_ADDRESS - PMAP_MAPDEV_EARLY_SIZE, freemempos); /* * Invalidate the mapping we created for the DTB. At this point a copy * has been created, and we no longer need it. We want to avoid the * possibility of an aliased mapping in the future. */ l2p = pmap_l2(kernel_pmap, VM_EARLY_DTB_ADDRESS); if ((pmap_load(l2p) & PTE_V) != 0) pmap_clear(l2p); sfence_vma(); #define alloc_pages(var, np) \ (var) = freemempos; \ freemempos += (np * PAGE_SIZE); \ memset((char *)(var), 0, ((np) * PAGE_SIZE)); mode = 0; TUNABLE_INT_FETCH("vm.pmap.mode", &mode); if (mode == PMAP_MODE_SV48 && (mmu_caps & MMU_SV48) != 0) { /* * Enable SV48 mode: allocate an L0 page and set SV48 mode in * SATP. If the implementation does not provide SV48 mode, * the mode read back from the (WARL) SATP register will be * unchanged, and we continue in SV39 mode. */ alloc_pages(l0pv, 1); l0p = (void *)l0pv; l1pa = pmap_early_vtophys(l1pt, l1pt); l0p[pmap_l0_index(KERNBASE)] = PTE_V | PTE_A | PTE_D | ((l1pa >> PAGE_SHIFT) << PTE_PPN0_S); l0pa = pmap_early_vtophys(l1pt, l0pv); csr_write(satp, (l0pa >> PAGE_SHIFT) | SATP_MODE_SV48); satp = csr_read(satp); if ((satp & SATP_MODE_M) == SATP_MODE_SV48) { pmap_mode = PMAP_MODE_SV48; kernel_pmap_store.pm_top = l0p; } else { /* Mode didn't change, give the page back. */ freemempos -= PAGE_SIZE; } } /* Allocate dynamic per-cpu area. */ alloc_pages(dpcpu, DPCPU_SIZE / PAGE_SIZE); dpcpu_init((void *)dpcpu, 0); /* Allocate memory for the msgbuf, e.g. for /sbin/dmesg */ alloc_pages(msgbufpv, round_page(msgbufsize) / PAGE_SIZE); msgbufp = (void *)msgbufpv; virtual_avail = roundup2(freemempos, L2_SIZE); virtual_end = VM_MAX_KERNEL_ADDRESS - PMAP_MAPDEV_EARLY_SIZE; kernel_vm_end = virtual_avail; pa = pmap_early_vtophys(l1pt, freemempos); physmem_exclude_region(kernstart, pa - kernstart, EXFLAG_NOALLOC); } /* * Initialize a vm_page's machine-dependent fields. */ void pmap_page_init(vm_page_t m) { TAILQ_INIT(&m->md.pv_list); m->md.pv_memattr = VM_MEMATTR_WRITE_BACK; } /* * Initialize the pmap module. * Called by vm_init, to initialize any structures that the pmap * system needs to map virtual memory. */ void pmap_init(void) { vm_size_t s; int i, pv_npg; /* * Initialize the pv chunk and pmap list mutexes. */ mtx_init(&pv_chunks_mutex, "pmap pv chunk list", NULL, MTX_DEF); mtx_init(&allpmaps_lock, "allpmaps", NULL, MTX_DEF); /* * Initialize the pool of pv list locks. */ for (i = 0; i < NPV_LIST_LOCKS; i++) rw_init(&pv_list_locks[i], "pmap pv list"); /* * Calculate the size of the pv head table for superpages. */ pv_npg = howmany(vm_phys_segs[vm_phys_nsegs - 1].end, L2_SIZE); /* * Allocate memory for the pv head table for superpages. */ s = (vm_size_t)(pv_npg * sizeof(struct md_page)); s = round_page(s); pv_table = kmem_malloc(s, M_WAITOK | M_ZERO); for (i = 0; i < pv_npg; i++) TAILQ_INIT(&pv_table[i].pv_list); TAILQ_INIT(&pv_dummy.pv_list); if (superpages_enabled) pagesizes[1] = L2_SIZE; } #ifdef SMP /* * For SMP, these functions have to use IPIs for coherence. * * In general, the calling thread uses a plain fence to order the * writes to the page tables before invoking an SBI callback to invoke * sfence_vma() on remote CPUs. */ static void pmap_invalidate_page(pmap_t pmap, vm_offset_t va) { cpuset_t mask; sched_pin(); mask = pmap->pm_active; CPU_CLR(PCPU_GET(hart), &mask); fence(); if (!CPU_EMPTY(&mask) && smp_started) sbi_remote_sfence_vma(mask.__bits, va, 1); sfence_vma_page(va); sched_unpin(); } static void pmap_invalidate_range(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { cpuset_t mask; sched_pin(); mask = pmap->pm_active; CPU_CLR(PCPU_GET(hart), &mask); fence(); if (!CPU_EMPTY(&mask) && smp_started) sbi_remote_sfence_vma(mask.__bits, sva, eva - sva + 1); /* * Might consider a loop of sfence_vma_page() for a small * number of pages in the future. */ sfence_vma(); sched_unpin(); } static void pmap_invalidate_all(pmap_t pmap) { cpuset_t mask; sched_pin(); mask = pmap->pm_active; CPU_CLR(PCPU_GET(hart), &mask); /* * XXX: The SBI doc doesn't detail how to specify x0 as the * address to perform a global fence. BBL currently treats * all sfence_vma requests as global however. */ fence(); if (!CPU_EMPTY(&mask) && smp_started) sbi_remote_sfence_vma(mask.__bits, 0, 0); sfence_vma(); sched_unpin(); } #else /* * Normal, non-SMP, invalidation functions. * We inline these within pmap.c for speed. */ static __inline void pmap_invalidate_page(pmap_t pmap, vm_offset_t va) { sfence_vma_page(va); } static __inline void pmap_invalidate_range(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { /* * Might consider a loop of sfence_vma_page() for a small * number of pages in the future. */ sfence_vma(); } static __inline void pmap_invalidate_all(pmap_t pmap) { sfence_vma(); } #endif /* * Routine: pmap_extract * Function: * Extract the physical page address associated * with the given map/virtual_address pair. */ vm_paddr_t pmap_extract(pmap_t pmap, vm_offset_t va) { pd_entry_t *l2p, l2; pt_entry_t *l3p; vm_paddr_t pa; pa = 0; /* * Start with an L2 lookup, L1 superpages are currently not implemented. */ PMAP_LOCK(pmap); l2p = pmap_l2(pmap, va); if (l2p != NULL && ((l2 = pmap_load(l2p)) & PTE_V) != 0) { if ((l2 & PTE_RWX) == 0) { l3p = pmap_l2_to_l3(l2p, va); if (l3p != NULL) { pa = PTE_TO_PHYS(pmap_load(l3p)); pa |= (va & L3_OFFSET); } } else { /* L2 is a superpage mapping. */ pa = L2PTE_TO_PHYS(l2); pa |= (va & L2_OFFSET); } } PMAP_UNLOCK(pmap); return (pa); } /* * Routine: pmap_extract_and_hold * Function: * Atomically extract and hold the physical page * with the given pmap and virtual address pair * if that mapping permits the given protection. */ vm_page_t pmap_extract_and_hold(pmap_t pmap, vm_offset_t va, vm_prot_t prot) { pt_entry_t *l3p, l3; vm_paddr_t phys; vm_page_t m; m = NULL; PMAP_LOCK(pmap); l3p = pmap_l3(pmap, va); if (l3p != NULL && (l3 = pmap_load(l3p)) != 0) { if ((l3 & PTE_W) != 0 || (prot & VM_PROT_WRITE) == 0) { phys = PTE_TO_PHYS(l3); m = PHYS_TO_VM_PAGE(phys); if (!vm_page_wire_mapped(m)) m = NULL; } } PMAP_UNLOCK(pmap); return (m); } vm_paddr_t pmap_kextract(vm_offset_t va) { pd_entry_t *l2, l2e; pt_entry_t *l3; vm_paddr_t pa; if (va >= DMAP_MIN_ADDRESS && va < DMAP_MAX_ADDRESS) { pa = DMAP_TO_PHYS(va); } else { l2 = pmap_l2(kernel_pmap, va); if (l2 == NULL) panic("pmap_kextract: No l2"); l2e = pmap_load(l2); /* * Beware of concurrent promotion and demotion! We must * use l2e rather than loading from l2 multiple times to * ensure we see a consistent state, including the * implicit load in pmap_l2_to_l3. It is, however, safe * to use an old l2e because the L3 page is preserved by * promotion. */ if ((l2e & PTE_RX) != 0) { /* superpages */ pa = L2PTE_TO_PHYS(l2e); pa |= (va & L2_OFFSET); return (pa); } l3 = pmap_l2_to_l3(&l2e, va); if (l3 == NULL) panic("pmap_kextract: No l3..."); pa = PTE_TO_PHYS(pmap_load(l3)); pa |= (va & PAGE_MASK); } return (pa); } /*************************************************** * Low level mapping routines..... ***************************************************/ void pmap_kenter(vm_offset_t sva, vm_size_t size, vm_paddr_t pa, int mode __unused) { pt_entry_t entry; pt_entry_t *l3; vm_offset_t va; pn_t pn; KASSERT((pa & L3_OFFSET) == 0, ("pmap_kenter_device: Invalid physical address")); KASSERT((sva & L3_OFFSET) == 0, ("pmap_kenter_device: Invalid virtual address")); KASSERT((size & PAGE_MASK) == 0, ("pmap_kenter_device: Mapping is not page-sized")); va = sva; while (size != 0) { l3 = pmap_l3(kernel_pmap, va); KASSERT(l3 != NULL, ("Invalid page table, va: 0x%lx", va)); pn = (pa / PAGE_SIZE); entry = PTE_KERN; entry |= (pn << PTE_PPN0_S); pmap_store(l3, entry); va += PAGE_SIZE; pa += PAGE_SIZE; size -= PAGE_SIZE; } pmap_invalidate_range(kernel_pmap, sva, va); } void pmap_kenter_device(vm_offset_t sva, vm_size_t size, vm_paddr_t pa) { pmap_kenter(sva, size, pa, VM_MEMATTR_DEVICE); } /* * Remove a page from the kernel pagetables. * Note: not SMP coherent. */ PMAP_INLINE void pmap_kremove(vm_offset_t va) { pt_entry_t *l3; l3 = pmap_l3(kernel_pmap, va); KASSERT(l3 != NULL, ("pmap_kremove: Invalid address")); pmap_clear(l3); sfence_vma(); } void pmap_kremove_device(vm_offset_t sva, vm_size_t size) { pt_entry_t *l3; vm_offset_t va; KASSERT((sva & L3_OFFSET) == 0, ("pmap_kremove_device: Invalid virtual address")); KASSERT((size & PAGE_MASK) == 0, ("pmap_kremove_device: Mapping is not page-sized")); va = sva; while (size != 0) { l3 = pmap_l3(kernel_pmap, va); KASSERT(l3 != NULL, ("Invalid page table, va: 0x%lx", va)); pmap_clear(l3); va += PAGE_SIZE; size -= PAGE_SIZE; } pmap_invalidate_range(kernel_pmap, sva, va); } /* * Used to map a range of physical addresses into kernel * virtual address space. * * The value passed in '*virt' is a suggested virtual address for * the mapping. Architectures which can support a direct-mapped * physical to virtual region can return the appropriate address * within that region, leaving '*virt' unchanged. Other * architectures should map the pages starting at '*virt' and * update '*virt' with the first usable address after the mapped * region. */ vm_offset_t pmap_map(vm_offset_t *virt, vm_paddr_t start, vm_paddr_t end, int prot) { return PHYS_TO_DMAP(start); } /* * Add a list of wired pages to the kva * this routine is only used for temporary * kernel mappings that do not need to have * page modification or references recorded. * Note that old mappings are simply written * over. The page *must* be wired. * Note: SMP coherent. Uses a ranged shootdown IPI. */ void pmap_qenter(vm_offset_t sva, vm_page_t *ma, int count) { pt_entry_t *l3, pa; vm_offset_t va; vm_page_t m; pt_entry_t entry; pn_t pn; int i; va = sva; for (i = 0; i < count; i++) { m = ma[i]; pa = VM_PAGE_TO_PHYS(m); pn = (pa / PAGE_SIZE); l3 = pmap_l3(kernel_pmap, va); entry = PTE_KERN; entry |= (pn << PTE_PPN0_S); pmap_store(l3, entry); va += L3_SIZE; } pmap_invalidate_range(kernel_pmap, sva, va); } /* * This routine tears out page mappings from the * kernel -- it is meant only for temporary mappings. * Note: SMP coherent. Uses a ranged shootdown IPI. */ void pmap_qremove(vm_offset_t sva, int count) { pt_entry_t *l3; vm_offset_t va; KASSERT(sva >= VM_MIN_KERNEL_ADDRESS, ("usermode va %lx", sva)); for (va = sva; count-- > 0; va += PAGE_SIZE) { l3 = pmap_l3(kernel_pmap, va); KASSERT(l3 != NULL, ("pmap_kremove: Invalid address")); pmap_clear(l3); } pmap_invalidate_range(kernel_pmap, sva, va); } bool pmap_ps_enabled(pmap_t pmap __unused) { return (superpages_enabled); } /*************************************************** * Page table page management routines..... ***************************************************/ /* * Schedule the specified unused page table page to be freed. Specifically, * add the page to the specified list of pages that will be released to the * physical memory manager after the TLB has been updated. */ static __inline void pmap_add_delayed_free_list(vm_page_t m, struct spglist *free, boolean_t set_PG_ZERO) { if (set_PG_ZERO) m->flags |= PG_ZERO; else m->flags &= ~PG_ZERO; SLIST_INSERT_HEAD(free, m, plinks.s.ss); } /* * Inserts the specified page table page into the specified pmap's collection * of idle page table pages. Each of a pmap's page table pages is responsible * for mapping a distinct range of virtual addresses. The pmap's collection is * ordered by this virtual address range. * * If "promoted" is false, then the page table page "ml3" must be zero filled. */ static __inline int pmap_insert_pt_page(pmap_t pmap, vm_page_t ml3, bool promoted) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); ml3->valid = promoted ? VM_PAGE_BITS_ALL : 0; return (vm_radix_insert(&pmap->pm_root, ml3)); } /* * Removes the page table page mapping the specified virtual address from the * specified pmap's collection of idle page table pages, and returns it. * Otherwise, returns NULL if there is no page table page corresponding to the * specified virtual address. */ static __inline vm_page_t pmap_remove_pt_page(pmap_t pmap, vm_offset_t va) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); return (vm_radix_remove(&pmap->pm_root, pmap_l2_pindex(va))); } /* * Decrements a page table page's reference count, which is used to record the * number of valid page table entries within the page. If the reference count * drops to zero, then the page table page is unmapped. Returns TRUE if the * page table page was unmapped and FALSE otherwise. */ static inline boolean_t pmap_unwire_ptp(pmap_t pmap, vm_offset_t va, vm_page_t m, struct spglist *free) { KASSERT(m->ref_count > 0, ("%s: page %p ref count underflow", __func__, m)); --m->ref_count; if (m->ref_count == 0) { _pmap_unwire_ptp(pmap, va, m, free); return (TRUE); } else { return (FALSE); } } static void _pmap_unwire_ptp(pmap_t pmap, vm_offset_t va, vm_page_t m, struct spglist *free) { vm_paddr_t phys; PMAP_LOCK_ASSERT(pmap, MA_OWNED); if (m->pindex >= NUL2E + NUL1E) { pd_entry_t *l0; l0 = pmap_l0(pmap, va); pmap_clear(l0); } else if (m->pindex >= NUL2E) { pd_entry_t *l1; l1 = pmap_l1(pmap, va); pmap_clear(l1); pmap_distribute_l1(pmap, pmap_l1_index(va), 0); } else { pd_entry_t *l2; l2 = pmap_l2(pmap, va); pmap_clear(l2); } pmap_resident_count_dec(pmap, 1); if (m->pindex < NUL2E) { pd_entry_t *l1; vm_page_t pdpg; l1 = pmap_l1(pmap, va); phys = PTE_TO_PHYS(pmap_load(l1)); pdpg = PHYS_TO_VM_PAGE(phys); pmap_unwire_ptp(pmap, va, pdpg, free); } else if (m->pindex < NUL2E + NUL1E && pmap_mode != PMAP_MODE_SV39) { pd_entry_t *l0; vm_page_t pdpg; MPASS(pmap_mode != PMAP_MODE_SV39); l0 = pmap_l0(pmap, va); phys = PTE_TO_PHYS(pmap_load(l0)); pdpg = PHYS_TO_VM_PAGE(phys); pmap_unwire_ptp(pmap, va, pdpg, free); } pmap_invalidate_page(pmap, va); vm_wire_sub(1); /* * Put page on a list so that it is released after * *ALL* TLB shootdown is done */ pmap_add_delayed_free_list(m, free, TRUE); } /* * After removing a page table entry, this routine is used to * conditionally free the page, and manage the reference count. */ static int pmap_unuse_pt(pmap_t pmap, vm_offset_t va, pd_entry_t ptepde, struct spglist *free) { vm_page_t mpte; if (va >= VM_MAXUSER_ADDRESS) return (0); KASSERT(ptepde != 0, ("pmap_unuse_pt: ptepde != 0")); mpte = PHYS_TO_VM_PAGE(PTE_TO_PHYS(ptepde)); return (pmap_unwire_ptp(pmap, va, mpte, free)); } static uint64_t pmap_satp_mode(void) { return (pmap_mode == PMAP_MODE_SV39 ? SATP_MODE_SV39 : SATP_MODE_SV48); } void pmap_pinit0(pmap_t pmap) { PMAP_LOCK_INIT(pmap); bzero(&pmap->pm_stats, sizeof(pmap->pm_stats)); pmap->pm_top = kernel_pmap->pm_top; pmap->pm_satp = pmap_satp_mode() | (vtophys(pmap->pm_top) >> PAGE_SHIFT); CPU_ZERO(&pmap->pm_active); TAILQ_INIT(&pmap->pm_pvchunk); vm_radix_init(&pmap->pm_root); pmap_activate_boot(pmap); } int pmap_pinit(pmap_t pmap) { vm_paddr_t topphys; vm_page_t mtop; size_t i; mtop = vm_page_alloc_noobj(VM_ALLOC_WIRED | VM_ALLOC_ZERO | VM_ALLOC_WAITOK); topphys = VM_PAGE_TO_PHYS(mtop); pmap->pm_top = (pd_entry_t *)PHYS_TO_DMAP(topphys); pmap->pm_satp = pmap_satp_mode() | (topphys >> PAGE_SHIFT); bzero(&pmap->pm_stats, sizeof(pmap->pm_stats)); CPU_ZERO(&pmap->pm_active); if (pmap_mode == PMAP_MODE_SV39) { /* * Copy L1 entries from the kernel pmap. This must be done with * the allpmaps lock held to avoid races with * pmap_distribute_l1(). */ mtx_lock(&allpmaps_lock); LIST_INSERT_HEAD(&allpmaps, pmap, pm_list); for (i = pmap_l1_index(VM_MIN_KERNEL_ADDRESS); i < pmap_l1_index(VM_MAX_KERNEL_ADDRESS); i++) pmap->pm_top[i] = kernel_pmap->pm_top[i]; for (i = pmap_l1_index(DMAP_MIN_ADDRESS); i < pmap_l1_index(DMAP_MAX_ADDRESS); i++) pmap->pm_top[i] = kernel_pmap->pm_top[i]; mtx_unlock(&allpmaps_lock); } else { i = pmap_l0_index(VM_MIN_KERNEL_ADDRESS); pmap->pm_top[i] = kernel_pmap->pm_top[i]; } TAILQ_INIT(&pmap->pm_pvchunk); vm_radix_init(&pmap->pm_root); return (1); } /* * This routine is called if the desired page table page does not exist. * * If page table page allocation fails, this routine may sleep before * returning NULL. It sleeps only if a lock pointer was given. * * Note: If a page allocation fails at page table level two or three, * one or two pages may be held during the wait, only to be released * afterwards. This conservative approach is easily argued to avoid * race conditions. */ static vm_page_t _pmap_alloc_l3(pmap_t pmap, vm_pindex_t ptepindex, struct rwlock **lockp) { vm_page_t m, pdpg; pt_entry_t entry; vm_paddr_t phys; pn_t pn; PMAP_LOCK_ASSERT(pmap, MA_OWNED); /* * Allocate a page table page. */ m = vm_page_alloc_noobj(VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (m == NULL) { if (lockp != NULL) { RELEASE_PV_LIST_LOCK(lockp); PMAP_UNLOCK(pmap); rw_runlock(&pvh_global_lock); vm_wait(NULL); rw_rlock(&pvh_global_lock); PMAP_LOCK(pmap); } /* * Indicate the need to retry. While waiting, the page table * page may have been allocated. */ return (NULL); } m->pindex = ptepindex; /* * Map the pagetable page into the process address space, if * it isn't already there. */ pn = VM_PAGE_TO_PHYS(m) >> PAGE_SHIFT; if (ptepindex >= NUL2E + NUL1E) { pd_entry_t *l0; vm_pindex_t l0index; KASSERT(pmap_mode != PMAP_MODE_SV39, ("%s: pindex %#lx in SV39 mode", __func__, ptepindex)); KASSERT(ptepindex < NUL2E + NUL1E + NUL0E, ("%s: pindex %#lx out of range", __func__, ptepindex)); l0index = ptepindex - (NUL2E + NUL1E); l0 = &pmap->pm_top[l0index]; KASSERT((pmap_load(l0) & PTE_V) == 0, ("%s: L0 entry %#lx is valid", __func__, pmap_load(l0))); entry = PTE_V | (pn << PTE_PPN0_S); pmap_store(l0, entry); } else if (ptepindex >= NUL2E) { pd_entry_t *l0, *l1; vm_pindex_t l0index, l1index; l1index = ptepindex - NUL2E; if (pmap_mode == PMAP_MODE_SV39) { l1 = &pmap->pm_top[l1index]; } else { l0index = l1index >> Ln_ENTRIES_SHIFT; l0 = &pmap->pm_top[l0index]; if (pmap_load(l0) == 0) { /* Recurse to allocate the L1 page. */ if (_pmap_alloc_l3(pmap, NUL2E + NUL1E + l0index, lockp) == NULL) goto fail; phys = PTE_TO_PHYS(pmap_load(l0)); } else { phys = PTE_TO_PHYS(pmap_load(l0)); pdpg = PHYS_TO_VM_PAGE(phys); pdpg->ref_count++; } l1 = (pd_entry_t *)PHYS_TO_DMAP(phys); l1 = &l1[ptepindex & Ln_ADDR_MASK]; } KASSERT((pmap_load(l1) & PTE_V) == 0, ("%s: L1 entry %#lx is valid", __func__, pmap_load(l1))); entry = PTE_V | (pn << PTE_PPN0_S); pmap_store(l1, entry); pmap_distribute_l1(pmap, l1index, entry); } else { vm_pindex_t l0index, l1index; pd_entry_t *l0, *l1, *l2; l1index = ptepindex >> (L1_SHIFT - L2_SHIFT); if (pmap_mode == PMAP_MODE_SV39) { l1 = &pmap->pm_top[l1index]; if (pmap_load(l1) == 0) { /* recurse for allocating page dir */ if (_pmap_alloc_l3(pmap, NUL2E + l1index, lockp) == NULL) goto fail; } else { phys = PTE_TO_PHYS(pmap_load(l1)); pdpg = PHYS_TO_VM_PAGE(phys); pdpg->ref_count++; } } else { l0index = l1index >> Ln_ENTRIES_SHIFT; l0 = &pmap->pm_top[l0index]; if (pmap_load(l0) == 0) { /* Recurse to allocate the L1 entry. */ if (_pmap_alloc_l3(pmap, NUL2E + l1index, lockp) == NULL) goto fail; phys = PTE_TO_PHYS(pmap_load(l0)); l1 = (pd_entry_t *)PHYS_TO_DMAP(phys); l1 = &l1[l1index & Ln_ADDR_MASK]; } else { phys = PTE_TO_PHYS(pmap_load(l0)); l1 = (pd_entry_t *)PHYS_TO_DMAP(phys); l1 = &l1[l1index & Ln_ADDR_MASK]; if (pmap_load(l1) == 0) { /* Recurse to allocate the L2 page. */ if (_pmap_alloc_l3(pmap, NUL2E + l1index, lockp) == NULL) goto fail; } else { phys = PTE_TO_PHYS(pmap_load(l1)); pdpg = PHYS_TO_VM_PAGE(phys); pdpg->ref_count++; } } } phys = PTE_TO_PHYS(pmap_load(l1)); l2 = (pd_entry_t *)PHYS_TO_DMAP(phys); l2 = &l2[ptepindex & Ln_ADDR_MASK]; KASSERT((pmap_load(l2) & PTE_V) == 0, ("%s: L2 entry %#lx is valid", __func__, pmap_load(l2))); entry = PTE_V | (pn << PTE_PPN0_S); pmap_store(l2, entry); } pmap_resident_count_inc(pmap, 1); return (m); fail: vm_page_unwire_noq(m); vm_page_free_zero(m); return (NULL); } static vm_page_t pmap_alloc_l2(pmap_t pmap, vm_offset_t va, struct rwlock **lockp) { pd_entry_t *l1; vm_page_t l2pg; vm_pindex_t l2pindex; retry: l1 = pmap_l1(pmap, va); if (l1 != NULL && (pmap_load(l1) & PTE_V) != 0) { KASSERT((pmap_load(l1) & PTE_RWX) == 0, ("%s: L1 entry %#lx for VA %#lx is a leaf", __func__, pmap_load(l1), va)); /* Add a reference to the L2 page. */ l2pg = PHYS_TO_VM_PAGE(PTE_TO_PHYS(pmap_load(l1))); l2pg->ref_count++; } else { /* Allocate a L2 page. */ l2pindex = pmap_l2_pindex(va) >> Ln_ENTRIES_SHIFT; l2pg = _pmap_alloc_l3(pmap, NUL2E + l2pindex, lockp); if (l2pg == NULL && lockp != NULL) goto retry; } return (l2pg); } static vm_page_t pmap_alloc_l3(pmap_t pmap, vm_offset_t va, struct rwlock **lockp) { vm_pindex_t ptepindex; pd_entry_t *l2; vm_paddr_t phys; vm_page_t m; /* * Calculate pagetable page index */ ptepindex = pmap_l2_pindex(va); retry: /* * Get the page directory entry */ l2 = pmap_l2(pmap, va); /* * If the page table page is mapped, we just increment the * hold count, and activate it. */ if (l2 != NULL && pmap_load(l2) != 0) { phys = PTE_TO_PHYS(pmap_load(l2)); m = PHYS_TO_VM_PAGE(phys); m->ref_count++; } else { /* * Here if the pte page isn't mapped, or if it has been * deallocated. */ m = _pmap_alloc_l3(pmap, ptepindex, lockp); if (m == NULL && lockp != NULL) goto retry; } return (m); } /*************************************************** * Pmap allocation/deallocation routines. ***************************************************/ /* * Release any resources held by the given physical map. * Called when a pmap initialized by pmap_pinit is being released. * Should only be called if the map contains no valid mappings. */ void pmap_release(pmap_t pmap) { vm_page_t m; KASSERT(pmap->pm_stats.resident_count == 0, ("pmap_release: pmap resident count %ld != 0", pmap->pm_stats.resident_count)); KASSERT(CPU_EMPTY(&pmap->pm_active), ("releasing active pmap %p", pmap)); if (pmap_mode == PMAP_MODE_SV39) { mtx_lock(&allpmaps_lock); LIST_REMOVE(pmap, pm_list); mtx_unlock(&allpmaps_lock); } m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((vm_offset_t)pmap->pm_top)); vm_page_unwire_noq(m); vm_page_free(m); } static int kvm_size(SYSCTL_HANDLER_ARGS) { unsigned long ksize = VM_MAX_KERNEL_ADDRESS - VM_MIN_KERNEL_ADDRESS; return sysctl_handle_long(oidp, &ksize, 0, req); } SYSCTL_PROC(_vm, OID_AUTO, kvm_size, CTLTYPE_LONG | CTLFLAG_RD | CTLFLAG_MPSAFE, 0, 0, kvm_size, "LU", "Size of KVM"); static int kvm_free(SYSCTL_HANDLER_ARGS) { unsigned long kfree = VM_MAX_KERNEL_ADDRESS - kernel_vm_end; return sysctl_handle_long(oidp, &kfree, 0, req); } SYSCTL_PROC(_vm, OID_AUTO, kvm_free, CTLTYPE_LONG | CTLFLAG_RD | CTLFLAG_MPSAFE, 0, 0, kvm_free, "LU", "Amount of KVM free"); /* * grow the number of kernel page table entries, if needed */ void pmap_growkernel(vm_offset_t addr) { vm_paddr_t paddr; vm_page_t nkpg; pd_entry_t *l1, *l2; pt_entry_t entry; pn_t pn; mtx_assert(&kernel_map->system_mtx, MA_OWNED); addr = roundup2(addr, L2_SIZE); if (addr - 1 >= vm_map_max(kernel_map)) addr = vm_map_max(kernel_map); while (kernel_vm_end < addr) { l1 = pmap_l1(kernel_pmap, kernel_vm_end); if (pmap_load(l1) == 0) { /* We need a new PDP entry */ nkpg = vm_page_alloc_noobj(VM_ALLOC_INTERRUPT | VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (nkpg == NULL) panic("pmap_growkernel: no memory to grow kernel"); nkpg->pindex = kernel_vm_end >> L1_SHIFT; paddr = VM_PAGE_TO_PHYS(nkpg); pn = (paddr / PAGE_SIZE); entry = (PTE_V); entry |= (pn << PTE_PPN0_S); pmap_store(l1, entry); pmap_distribute_l1(kernel_pmap, pmap_l1_index(kernel_vm_end), entry); continue; /* try again */ } l2 = pmap_l1_to_l2(l1, kernel_vm_end); if ((pmap_load(l2) & PTE_V) != 0 && (pmap_load(l2) & PTE_RWX) == 0) { kernel_vm_end = (kernel_vm_end + L2_SIZE) & ~L2_OFFSET; if (kernel_vm_end - 1 >= vm_map_max(kernel_map)) { kernel_vm_end = vm_map_max(kernel_map); break; } continue; } nkpg = vm_page_alloc_noobj(VM_ALLOC_INTERRUPT | VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (nkpg == NULL) panic("pmap_growkernel: no memory to grow kernel"); nkpg->pindex = kernel_vm_end >> L2_SHIFT; paddr = VM_PAGE_TO_PHYS(nkpg); pn = (paddr / PAGE_SIZE); entry = (PTE_V); entry |= (pn << PTE_PPN0_S); pmap_store(l2, entry); pmap_invalidate_page(kernel_pmap, kernel_vm_end); kernel_vm_end = (kernel_vm_end + L2_SIZE) & ~L2_OFFSET; if (kernel_vm_end - 1 >= vm_map_max(kernel_map)) { kernel_vm_end = vm_map_max(kernel_map); break; } } } /*************************************************** * page management routines. ***************************************************/ static const uint64_t pc_freemask[_NPCM] = { [0 ... _NPCM - 2] = PC_FREEN, [_NPCM - 1] = PC_FREEL }; #if 0 #ifdef PV_STATS static int pc_chunk_count, pc_chunk_allocs, pc_chunk_frees, pc_chunk_tryfail; SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_count, CTLFLAG_RD, &pc_chunk_count, 0, "Current number of pv entry chunks"); SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_allocs, CTLFLAG_RD, &pc_chunk_allocs, 0, "Current number of pv entry chunks allocated"); SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_frees, CTLFLAG_RD, &pc_chunk_frees, 0, "Current number of pv entry chunks frees"); SYSCTL_INT(_vm_pmap, OID_AUTO, pc_chunk_tryfail, CTLFLAG_RD, &pc_chunk_tryfail, 0, "Number of times tried to get a chunk page but failed."); static long pv_entry_frees, pv_entry_allocs, pv_entry_count; static int pv_entry_spare; SYSCTL_LONG(_vm_pmap, OID_AUTO, pv_entry_frees, CTLFLAG_RD, &pv_entry_frees, 0, "Current number of pv entry frees"); SYSCTL_LONG(_vm_pmap, OID_AUTO, pv_entry_allocs, CTLFLAG_RD, &pv_entry_allocs, 0, "Current number of pv entry allocs"); SYSCTL_LONG(_vm_pmap, OID_AUTO, pv_entry_count, CTLFLAG_RD, &pv_entry_count, 0, "Current number of pv entries"); SYSCTL_INT(_vm_pmap, OID_AUTO, pv_entry_spare, CTLFLAG_RD, &pv_entry_spare, 0, "Current number of spare pv entries"); #endif #endif /* 0 */ /* * We are in a serious low memory condition. Resort to * drastic measures to free some pages so we can allocate * another pv entry chunk. * * Returns NULL if PV entries were reclaimed from the specified pmap. * * We do not, however, unmap 2mpages because subsequent accesses will * allocate per-page pv entries until repromotion occurs, thereby * exacerbating the shortage of free pv entries. */ static vm_page_t reclaim_pv_chunk(pmap_t locked_pmap, struct rwlock **lockp) { panic("RISCVTODO: reclaim_pv_chunk"); } /* * free the pv_entry back to the free list */ static void free_pv_entry(pmap_t pmap, pv_entry_t pv) { struct pv_chunk *pc; int idx, field, bit; rw_assert(&pvh_global_lock, RA_LOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); PV_STAT(atomic_add_long(&pv_entry_frees, 1)); PV_STAT(atomic_add_int(&pv_entry_spare, 1)); PV_STAT(atomic_subtract_long(&pv_entry_count, 1)); pc = pv_to_chunk(pv); idx = pv - &pc->pc_pventry[0]; field = idx / 64; bit = idx % 64; pc->pc_map[field] |= 1ul << bit; if (!pc_is_free(pc)) { /* 98% of the time, pc is already at the head of the list. */ if (__predict_false(pc != TAILQ_FIRST(&pmap->pm_pvchunk))) { TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_HEAD(&pmap->pm_pvchunk, pc, pc_list); } return; } TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); free_pv_chunk(pc); } static void free_pv_chunk(struct pv_chunk *pc) { vm_page_t m; mtx_lock(&pv_chunks_mutex); TAILQ_REMOVE(&pv_chunks, pc, pc_lru); mtx_unlock(&pv_chunks_mutex); PV_STAT(atomic_subtract_int(&pv_entry_spare, _NPCPV)); PV_STAT(atomic_subtract_int(&pc_chunk_count, 1)); PV_STAT(atomic_add_int(&pc_chunk_frees, 1)); /* entire chunk is free, return it */ m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((vm_offset_t)pc)); dump_drop_page(m->phys_addr); vm_page_unwire_noq(m); vm_page_free(m); } /* * Returns a new PV entry, allocating a new PV chunk from the system when * needed. If this PV chunk allocation fails and a PV list lock pointer was * given, a PV chunk is reclaimed from an arbitrary pmap. Otherwise, NULL is * returned. * * The given PV list lock may be released. */ static pv_entry_t get_pv_entry(pmap_t pmap, struct rwlock **lockp) { int bit, field; pv_entry_t pv; struct pv_chunk *pc; vm_page_t m; rw_assert(&pvh_global_lock, RA_LOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); PV_STAT(atomic_add_long(&pv_entry_allocs, 1)); retry: pc = TAILQ_FIRST(&pmap->pm_pvchunk); if (pc != NULL) { for (field = 0; field < _NPCM; field++) { if (pc->pc_map[field]) { bit = ffsl(pc->pc_map[field]) - 1; break; } } if (field < _NPCM) { pv = &pc->pc_pventry[field * 64 + bit]; pc->pc_map[field] &= ~(1ul << bit); /* If this was the last item, move it to tail */ if (pc_is_full(pc)) { TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&pmap->pm_pvchunk, pc, pc_list); } PV_STAT(atomic_add_long(&pv_entry_count, 1)); PV_STAT(atomic_subtract_int(&pv_entry_spare, 1)); return (pv); } } /* No free items, allocate another chunk */ m = vm_page_alloc_noobj(VM_ALLOC_WIRED); if (m == NULL) { if (lockp == NULL) { PV_STAT(pc_chunk_tryfail++); return (NULL); } m = reclaim_pv_chunk(pmap, lockp); if (m == NULL) goto retry; } PV_STAT(atomic_add_int(&pc_chunk_count, 1)); PV_STAT(atomic_add_int(&pc_chunk_allocs, 1)); dump_add_page(m->phys_addr); pc = (void *)PHYS_TO_DMAP(m->phys_addr); pc->pc_pmap = pmap; pc->pc_map[0] = PC_FREEN & ~1ul; /* preallocated bit 0 */ pc->pc_map[1] = PC_FREEN; pc->pc_map[2] = PC_FREEL; mtx_lock(&pv_chunks_mutex); TAILQ_INSERT_TAIL(&pv_chunks, pc, pc_lru); mtx_unlock(&pv_chunks_mutex); pv = &pc->pc_pventry[0]; TAILQ_INSERT_HEAD(&pmap->pm_pvchunk, pc, pc_list); PV_STAT(atomic_add_long(&pv_entry_count, 1)); PV_STAT(atomic_add_int(&pv_entry_spare, _NPCPV - 1)); return (pv); } /* * Ensure that the number of spare PV entries in the specified pmap meets or * exceeds the given count, "needed". * * The given PV list lock may be released. */ static void reserve_pv_entries(pmap_t pmap, int needed, struct rwlock **lockp) { struct pch new_tail; struct pv_chunk *pc; vm_page_t m; int avail, free; bool reclaimed; rw_assert(&pvh_global_lock, RA_LOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT(lockp != NULL, ("reserve_pv_entries: lockp is NULL")); /* * Newly allocated PV chunks must be stored in a private list until * the required number of PV chunks have been allocated. Otherwise, * reclaim_pv_chunk() could recycle one of these chunks. In * contrast, these chunks must be added to the pmap upon allocation. */ TAILQ_INIT(&new_tail); retry: avail = 0; TAILQ_FOREACH(pc, &pmap->pm_pvchunk, pc_list) { bit_count((bitstr_t *)pc->pc_map, 0, sizeof(pc->pc_map) * NBBY, &free); if (free == 0) break; avail += free; if (avail >= needed) break; } for (reclaimed = false; avail < needed; avail += _NPCPV) { m = vm_page_alloc_noobj(VM_ALLOC_WIRED); if (m == NULL) { m = reclaim_pv_chunk(pmap, lockp); if (m == NULL) goto retry; reclaimed = true; } /* XXX PV STATS */ #if 0 dump_add_page(m->phys_addr); #endif pc = (void *)PHYS_TO_DMAP(m->phys_addr); pc->pc_pmap = pmap; pc->pc_map[0] = PC_FREEN; pc->pc_map[1] = PC_FREEN; pc->pc_map[2] = PC_FREEL; TAILQ_INSERT_HEAD(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&new_tail, pc, pc_lru); /* * The reclaim might have freed a chunk from the current pmap. * If that chunk contained available entries, we need to * re-count the number of available entries. */ if (reclaimed) goto retry; } if (!TAILQ_EMPTY(&new_tail)) { mtx_lock(&pv_chunks_mutex); TAILQ_CONCAT(&pv_chunks, &new_tail, pc_lru); mtx_unlock(&pv_chunks_mutex); } } /* * First find and then remove the pv entry for the specified pmap and virtual * address from the specified pv list. Returns the pv entry if found and NULL * otherwise. This operation can be performed on pv lists for either 4KB or * 2MB page mappings. */ static __inline pv_entry_t pmap_pvh_remove(struct md_page *pvh, pmap_t pmap, vm_offset_t va) { pv_entry_t pv; rw_assert(&pvh_global_lock, RA_LOCKED); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { if (pmap == PV_PMAP(pv) && va == pv->pv_va) { TAILQ_REMOVE(&pvh->pv_list, pv, pv_next); pvh->pv_gen++; break; } } return (pv); } /* * First find and then destroy the pv entry for the specified pmap and virtual * address. This operation can be performed on pv lists for either 4KB or 2MB * page mappings. */ static void pmap_pvh_free(struct md_page *pvh, pmap_t pmap, vm_offset_t va) { pv_entry_t pv; pv = pmap_pvh_remove(pvh, pmap, va); KASSERT(pv != NULL, ("pmap_pvh_free: pv not found for %#lx", va)); free_pv_entry(pmap, pv); } /* * Conditionally create the PV entry for a 4KB page mapping if the required * memory can be allocated without resorting to reclamation. */ static boolean_t pmap_try_insert_pv_entry(pmap_t pmap, vm_offset_t va, vm_page_t m, struct rwlock **lockp) { pv_entry_t pv; rw_assert(&pvh_global_lock, RA_LOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); /* Pass NULL instead of the lock pointer to disable reclamation. */ if ((pv = get_pv_entry(pmap, NULL)) != NULL) { pv->pv_va = va; CHANGE_PV_LIST_LOCK_TO_VM_PAGE(lockp, m); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; return (TRUE); } else return (FALSE); } /* * After demotion from a 2MB page mapping to 512 4KB page mappings, * destroy the pv entry for the 2MB page mapping and reinstantiate the pv * entries for each of the 4KB page mappings. */ static void __unused pmap_pv_demote_l2(pmap_t pmap, vm_offset_t va, vm_paddr_t pa, struct rwlock **lockp) { struct md_page *pvh; struct pv_chunk *pc; pv_entry_t pv; vm_page_t m; vm_offset_t va_last; int bit, field; rw_assert(&pvh_global_lock, RA_LOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, pa); /* * Transfer the 2mpage's pv entry for this mapping to the first * page's pv list. Once this transfer begins, the pv list lock * must not be released until the last pv entry is reinstantiated. */ pvh = pa_to_pvh(pa); va &= ~L2_OFFSET; pv = pmap_pvh_remove(pvh, pmap, va); KASSERT(pv != NULL, ("pmap_pv_demote_l2: pv not found")); m = PHYS_TO_VM_PAGE(pa); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; /* Instantiate the remaining 511 pv entries. */ va_last = va + L2_SIZE - PAGE_SIZE; for (;;) { pc = TAILQ_FIRST(&pmap->pm_pvchunk); KASSERT(!pc_is_full(pc), ("pmap_pv_demote_l2: missing spare")); for (field = 0; field < _NPCM; field++) { while (pc->pc_map[field] != 0) { bit = ffsl(pc->pc_map[field]) - 1; pc->pc_map[field] &= ~(1ul << bit); pv = &pc->pc_pventry[field * 64 + bit]; va += PAGE_SIZE; pv->pv_va = va; m++; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_pv_demote_l2: page %p is not managed", m)); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; if (va == va_last) goto out; } } TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&pmap->pm_pvchunk, pc, pc_list); } out: if (pc_is_free(pc)) { TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); TAILQ_INSERT_TAIL(&pmap->pm_pvchunk, pc, pc_list); } /* XXX PV stats */ } #if VM_NRESERVLEVEL > 0 static void pmap_pv_promote_l2(pmap_t pmap, vm_offset_t va, vm_paddr_t pa, struct rwlock **lockp) { struct md_page *pvh; pv_entry_t pv; vm_page_t m; vm_offset_t va_last; rw_assert(&pvh_global_lock, RA_LOCKED); KASSERT((pa & L2_OFFSET) == 0, ("pmap_pv_promote_l2: misaligned pa %#lx", pa)); CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, pa); m = PHYS_TO_VM_PAGE(pa); va = va & ~L2_OFFSET; pv = pmap_pvh_remove(&m->md, pmap, va); KASSERT(pv != NULL, ("pmap_pv_promote_l2: pv for %#lx not found", va)); pvh = pa_to_pvh(pa); TAILQ_INSERT_TAIL(&pvh->pv_list, pv, pv_next); pvh->pv_gen++; va_last = va + L2_SIZE - PAGE_SIZE; do { m++; va += PAGE_SIZE; pmap_pvh_free(&m->md, pmap, va); } while (va < va_last); } #endif /* VM_NRESERVLEVEL > 0 */ /* * Create the PV entry for a 2MB page mapping. Always returns true unless the * flag PMAP_ENTER_NORECLAIM is specified. If that flag is specified, returns * false if the PV entry cannot be allocated without resorting to reclamation. */ static bool pmap_pv_insert_l2(pmap_t pmap, vm_offset_t va, pd_entry_t l2e, u_int flags, struct rwlock **lockp) { struct md_page *pvh; pv_entry_t pv; vm_paddr_t pa; PMAP_LOCK_ASSERT(pmap, MA_OWNED); /* Pass NULL instead of the lock pointer to disable reclamation. */ if ((pv = get_pv_entry(pmap, (flags & PMAP_ENTER_NORECLAIM) != 0 ? NULL : lockp)) == NULL) return (false); pv->pv_va = va; pa = PTE_TO_PHYS(l2e); CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, pa); pvh = pa_to_pvh(pa); TAILQ_INSERT_TAIL(&pvh->pv_list, pv, pv_next); pvh->pv_gen++; return (true); } static void pmap_remove_kernel_l2(pmap_t pmap, pt_entry_t *l2, vm_offset_t va) { pt_entry_t newl2, oldl2 __diagused; vm_page_t ml3; vm_paddr_t ml3pa; KASSERT(!VIRT_IN_DMAP(va), ("removing direct mapping of %#lx", va)); KASSERT(pmap == kernel_pmap, ("pmap %p is not kernel_pmap", pmap)); PMAP_LOCK_ASSERT(pmap, MA_OWNED); ml3 = pmap_remove_pt_page(pmap, va); if (ml3 == NULL) panic("pmap_remove_kernel_l2: Missing pt page"); ml3pa = VM_PAGE_TO_PHYS(ml3); newl2 = ml3pa | PTE_V; /* * If this page table page was unmapped by a promotion, then it * contains valid mappings. Zero it to invalidate those mappings. */ if (ml3->valid != 0) pagezero((void *)PHYS_TO_DMAP(ml3pa)); /* * Demote the mapping. */ oldl2 = pmap_load_store(l2, newl2); KASSERT(oldl2 == 0, ("%s: found existing mapping at %p: %#lx", __func__, l2, oldl2)); } /* * pmap_remove_l2: Do the things to unmap a level 2 superpage. */ static int pmap_remove_l2(pmap_t pmap, pt_entry_t *l2, vm_offset_t sva, pd_entry_t l1e, struct spglist *free, struct rwlock **lockp) { struct md_page *pvh; pt_entry_t oldl2; vm_offset_t eva, va; vm_page_t m, ml3; PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT((sva & L2_OFFSET) == 0, ("pmap_remove_l2: sva is not aligned")); oldl2 = pmap_load_clear(l2); KASSERT((oldl2 & PTE_RWX) != 0, ("pmap_remove_l2: L2e %lx is not a superpage mapping", oldl2)); /* * The sfence.vma documentation states that it is sufficient to specify * a single address within a superpage mapping. However, since we do * not perform any invalidation upon promotion, TLBs may still be * caching 4KB mappings within the superpage, so we must invalidate the * entire range. */ pmap_invalidate_range(pmap, sva, sva + L2_SIZE); if ((oldl2 & PTE_SW_WIRED) != 0) pmap->pm_stats.wired_count -= L2_SIZE / PAGE_SIZE; pmap_resident_count_dec(pmap, L2_SIZE / PAGE_SIZE); if ((oldl2 & PTE_SW_MANAGED) != 0) { CHANGE_PV_LIST_LOCK_TO_PHYS(lockp, PTE_TO_PHYS(oldl2)); pvh = pa_to_pvh(PTE_TO_PHYS(oldl2)); pmap_pvh_free(pvh, pmap, sva); eva = sva + L2_SIZE; for (va = sva, m = PHYS_TO_VM_PAGE(PTE_TO_PHYS(oldl2)); va < eva; va += PAGE_SIZE, m++) { if ((oldl2 & PTE_D) != 0) vm_page_dirty(m); if ((oldl2 & PTE_A) != 0) vm_page_aflag_set(m, PGA_REFERENCED); if (TAILQ_EMPTY(&m->md.pv_list) && TAILQ_EMPTY(&pvh->pv_list)) vm_page_aflag_clear(m, PGA_WRITEABLE); } } if (pmap == kernel_pmap) { pmap_remove_kernel_l2(pmap, l2, sva); } else { ml3 = pmap_remove_pt_page(pmap, sva); if (ml3 != NULL) { KASSERT(ml3->valid == VM_PAGE_BITS_ALL, ("pmap_remove_l2: l3 page not promoted")); pmap_resident_count_dec(pmap, 1); KASSERT(ml3->ref_count == Ln_ENTRIES, ("pmap_remove_l2: l3 page ref count error")); ml3->ref_count = 1; vm_page_unwire_noq(ml3); pmap_add_delayed_free_list(ml3, free, FALSE); } } return (pmap_unuse_pt(pmap, sva, l1e, free)); } /* * pmap_remove_l3: do the things to unmap a page in a process */ static int pmap_remove_l3(pmap_t pmap, pt_entry_t *l3, vm_offset_t va, pd_entry_t l2e, struct spglist *free, struct rwlock **lockp) { struct md_page *pvh; pt_entry_t old_l3; vm_paddr_t phys; vm_page_t m; PMAP_LOCK_ASSERT(pmap, MA_OWNED); old_l3 = pmap_load_clear(l3); pmap_invalidate_page(pmap, va); if (old_l3 & PTE_SW_WIRED) pmap->pm_stats.wired_count -= 1; pmap_resident_count_dec(pmap, 1); if (old_l3 & PTE_SW_MANAGED) { phys = PTE_TO_PHYS(old_l3); m = PHYS_TO_VM_PAGE(phys); if ((old_l3 & PTE_D) != 0) vm_page_dirty(m); if (old_l3 & PTE_A) vm_page_aflag_set(m, PGA_REFERENCED); CHANGE_PV_LIST_LOCK_TO_VM_PAGE(lockp, m); pmap_pvh_free(&m->md, pmap, va); if (TAILQ_EMPTY(&m->md.pv_list) && (m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); if (TAILQ_EMPTY(&pvh->pv_list)) vm_page_aflag_clear(m, PGA_WRITEABLE); } } return (pmap_unuse_pt(pmap, va, l2e, free)); } /* * Remove the given range of addresses from the specified map. * * It is assumed that the start and end are properly * rounded to the page size. */ void pmap_remove(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { struct spglist free; struct rwlock *lock; vm_offset_t va, va_next; pd_entry_t *l0, *l1, *l2, l2e; pt_entry_t *l3; /* * Perform an unsynchronized read. This is, however, safe. */ if (pmap->pm_stats.resident_count == 0) return; SLIST_INIT(&free); rw_rlock(&pvh_global_lock); PMAP_LOCK(pmap); lock = NULL; for (; sva < eva; sva = va_next) { if (pmap->pm_stats.resident_count == 0) break; if (pmap_mode == PMAP_MODE_SV48) { l0 = pmap_l0(pmap, sva); if (pmap_load(l0) == 0) { va_next = (sva + L0_SIZE) & ~L0_OFFSET; if (va_next < sva) va_next = eva; continue; } l1 = pmap_l0_to_l1(l0, sva); } else { l1 = pmap_l1(pmap, sva); } if (pmap_load(l1) == 0) { va_next = (sva + L1_SIZE) & ~L1_OFFSET; if (va_next < sva) va_next = eva; continue; } /* * Calculate index for next page table. */ va_next = (sva + L2_SIZE) & ~L2_OFFSET; if (va_next < sva) va_next = eva; l2 = pmap_l1_to_l2(l1, sva); if (l2 == NULL) continue; if ((l2e = pmap_load(l2)) == 0) continue; if ((l2e & PTE_RWX) != 0) { if (sva + L2_SIZE == va_next && eva >= va_next) { (void)pmap_remove_l2(pmap, l2, sva, pmap_load(l1), &free, &lock); continue; } else if (!pmap_demote_l2_locked(pmap, l2, sva, &lock)) { /* * The large page mapping was destroyed. */ continue; } l2e = pmap_load(l2); } /* * Limit our scan to either the end of the va represented * by the current page table page, or to the end of the * range being removed. */ if (va_next > eva) va_next = eva; va = va_next; for (l3 = pmap_l2_to_l3(l2, sva); sva != va_next; l3++, sva += L3_SIZE) { if (pmap_load(l3) == 0) { if (va != va_next) { pmap_invalidate_range(pmap, va, sva); va = va_next; } continue; } if (va == va_next) va = sva; if (pmap_remove_l3(pmap, l3, sva, l2e, &free, &lock)) { sva += L3_SIZE; break; } } if (va != va_next) pmap_invalidate_range(pmap, va, sva); } if (lock != NULL) rw_wunlock(lock); rw_runlock(&pvh_global_lock); PMAP_UNLOCK(pmap); vm_page_free_pages_toq(&free, false); } /* * Routine: pmap_remove_all * Function: * Removes this physical page from * all physical maps in which it resides. * Reflects back modify bits to the pager. * * Notes: * Original versions of this routine were very * inefficient because they iteratively called * pmap_remove (slow...) */ void pmap_remove_all(vm_page_t m) { struct spglist free; struct md_page *pvh; pmap_t pmap; pt_entry_t *l3, l3e; pd_entry_t *l2, l2e __diagused; pv_entry_t pv; vm_offset_t va; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_remove_all: page %p is not managed", m)); SLIST_INIT(&free); pvh = (m->flags & PG_FICTITIOUS) != 0 ? &pv_dummy : pa_to_pvh(VM_PAGE_TO_PHYS(m)); rw_wlock(&pvh_global_lock); while ((pv = TAILQ_FIRST(&pvh->pv_list)) != NULL) { pmap = PV_PMAP(pv); PMAP_LOCK(pmap); va = pv->pv_va; l2 = pmap_l2(pmap, va); (void)pmap_demote_l2(pmap, l2, va); PMAP_UNLOCK(pmap); } while ((pv = TAILQ_FIRST(&m->md.pv_list)) != NULL) { pmap = PV_PMAP(pv); PMAP_LOCK(pmap); pmap_resident_count_dec(pmap, 1); l2 = pmap_l2(pmap, pv->pv_va); KASSERT(l2 != NULL, ("pmap_remove_all: no l2 table found")); l2e = pmap_load(l2); KASSERT((l2e & PTE_RX) == 0, ("pmap_remove_all: found a superpage in %p's pv list", m)); l3 = pmap_l2_to_l3(l2, pv->pv_va); l3e = pmap_load_clear(l3); pmap_invalidate_page(pmap, pv->pv_va); if (l3e & PTE_SW_WIRED) pmap->pm_stats.wired_count--; if ((l3e & PTE_A) != 0) vm_page_aflag_set(m, PGA_REFERENCED); /* * Update the vm_page_t clean and reference bits. */ if ((l3e & PTE_D) != 0) vm_page_dirty(m); pmap_unuse_pt(pmap, pv->pv_va, pmap_load(l2), &free); TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; free_pv_entry(pmap, pv); PMAP_UNLOCK(pmap); } vm_page_aflag_clear(m, PGA_WRITEABLE); rw_wunlock(&pvh_global_lock); vm_page_free_pages_toq(&free, false); } /* * Set the physical protection on the * specified range of this map as requested. */ void pmap_protect(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, vm_prot_t prot) { pd_entry_t *l0, *l1, *l2, l2e; pt_entry_t *l3, l3e, mask; vm_page_t m, mt; vm_paddr_t pa; vm_offset_t va_next; bool anychanged, pv_lists_locked; if ((prot & VM_PROT_READ) == VM_PROT_NONE) { pmap_remove(pmap, sva, eva); return; } if ((prot & (VM_PROT_WRITE | VM_PROT_EXECUTE)) == (VM_PROT_WRITE | VM_PROT_EXECUTE)) return; anychanged = false; pv_lists_locked = false; mask = 0; if ((prot & VM_PROT_WRITE) == 0) mask |= PTE_W | PTE_D; if ((prot & VM_PROT_EXECUTE) == 0) mask |= PTE_X; resume: PMAP_LOCK(pmap); for (; sva < eva; sva = va_next) { if (pmap_mode == PMAP_MODE_SV48) { l0 = pmap_l0(pmap, sva); if (pmap_load(l0) == 0) { va_next = (sva + L0_SIZE) & ~L0_OFFSET; if (va_next < sva) va_next = eva; continue; } l1 = pmap_l0_to_l1(l0, sva); } else { l1 = pmap_l1(pmap, sva); } if (pmap_load(l1) == 0) { va_next = (sva + L1_SIZE) & ~L1_OFFSET; if (va_next < sva) va_next = eva; continue; } va_next = (sva + L2_SIZE) & ~L2_OFFSET; if (va_next < sva) va_next = eva; l2 = pmap_l1_to_l2(l1, sva); if (l2 == NULL || (l2e = pmap_load(l2)) == 0) continue; if ((l2e & PTE_RWX) != 0) { if (sva + L2_SIZE == va_next && eva >= va_next) { retryl2: if ((prot & VM_PROT_WRITE) == 0 && (l2e & (PTE_SW_MANAGED | PTE_D)) == (PTE_SW_MANAGED | PTE_D)) { pa = PTE_TO_PHYS(l2e); m = PHYS_TO_VM_PAGE(pa); for (mt = m; mt < &m[Ln_ENTRIES]; mt++) vm_page_dirty(mt); } if (!atomic_fcmpset_long(l2, &l2e, l2e & ~mask)) goto retryl2; anychanged = true; continue; } else { if (!pv_lists_locked) { pv_lists_locked = true; if (!rw_try_rlock(&pvh_global_lock)) { if (anychanged) pmap_invalidate_all( pmap); PMAP_UNLOCK(pmap); rw_rlock(&pvh_global_lock); goto resume; } } if (!pmap_demote_l2(pmap, l2, sva)) { /* * The large page mapping was destroyed. */ continue; } } } if (va_next > eva) va_next = eva; for (l3 = pmap_l2_to_l3(l2, sva); sva != va_next; l3++, sva += L3_SIZE) { l3e = pmap_load(l3); retryl3: if ((l3e & PTE_V) == 0) continue; if ((prot & VM_PROT_WRITE) == 0 && (l3e & (PTE_SW_MANAGED | PTE_D)) == (PTE_SW_MANAGED | PTE_D)) { m = PHYS_TO_VM_PAGE(PTE_TO_PHYS(l3e)); vm_page_dirty(m); } if (!atomic_fcmpset_long(l3, &l3e, l3e & ~mask)) goto retryl3; anychanged = true; } } if (anychanged) pmap_invalidate_all(pmap); if (pv_lists_locked) rw_runlock(&pvh_global_lock); PMAP_UNLOCK(pmap); } int pmap_fault(pmap_t pmap, vm_offset_t va, vm_prot_t ftype) { pd_entry_t *l2, l2e; pt_entry_t bits, *pte, oldpte; int rv; KASSERT(VIRT_IS_VALID(va), ("pmap_fault: invalid va %#lx", va)); rv = 0; PMAP_LOCK(pmap); l2 = pmap_l2(pmap, va); if (l2 == NULL || ((l2e = pmap_load(l2)) & PTE_V) == 0) goto done; if ((l2e & PTE_RWX) == 0) { pte = pmap_l2_to_l3(l2, va); if (pte == NULL || ((oldpte = pmap_load(pte)) & PTE_V) == 0) goto done; } else { pte = l2; oldpte = l2e; } if ((pmap != kernel_pmap && (oldpte & PTE_U) == 0) || (ftype == VM_PROT_WRITE && (oldpte & PTE_W) == 0) || (ftype == VM_PROT_EXECUTE && (oldpte & PTE_X) == 0) || (ftype == VM_PROT_READ && (oldpte & PTE_R) == 0)) goto done; bits = PTE_A; if (ftype == VM_PROT_WRITE) bits |= PTE_D; /* * Spurious faults can occur if the implementation caches invalid * entries in the TLB, or if simultaneous accesses on multiple CPUs * race with each other. */ if ((oldpte & bits) != bits) pmap_store_bits(pte, bits); sfence_vma(); rv = 1; done: PMAP_UNLOCK(pmap); return (rv); } static bool pmap_demote_l2(pmap_t pmap, pd_entry_t *l2, vm_offset_t va) { struct rwlock *lock; bool rv; lock = NULL; rv = pmap_demote_l2_locked(pmap, l2, va, &lock); if (lock != NULL) rw_wunlock(lock); return (rv); } /* * Tries to demote a 2MB page mapping. If demotion fails, the 2MB page * mapping is invalidated. */ static bool pmap_demote_l2_locked(pmap_t pmap, pd_entry_t *l2, vm_offset_t va, struct rwlock **lockp) { struct spglist free; vm_page_t mpte; pd_entry_t newl2, oldl2; pt_entry_t *firstl3, newl3; vm_paddr_t mptepa; int i; PMAP_LOCK_ASSERT(pmap, MA_OWNED); oldl2 = pmap_load(l2); KASSERT((oldl2 & PTE_RWX) != 0, ("pmap_demote_l2_locked: oldl2 is not a leaf entry")); if ((oldl2 & PTE_A) == 0 || (mpte = pmap_remove_pt_page(pmap, va)) == NULL) { if ((oldl2 & PTE_A) == 0 || (mpte = vm_page_alloc_noobj( (VIRT_IN_DMAP(va) ? VM_ALLOC_INTERRUPT : 0) | VM_ALLOC_WIRED)) == NULL) { SLIST_INIT(&free); (void)pmap_remove_l2(pmap, l2, va & ~L2_OFFSET, pmap_load(pmap_l1(pmap, va)), &free, lockp); vm_page_free_pages_toq(&free, true); CTR2(KTR_PMAP, "pmap_demote_l2_locked: " "failure for va %#lx in pmap %p", va, pmap); return (false); } mpte->pindex = pmap_l2_pindex(va); if (va < VM_MAXUSER_ADDRESS) { mpte->ref_count = Ln_ENTRIES; pmap_resident_count_inc(pmap, 1); } } mptepa = VM_PAGE_TO_PHYS(mpte); firstl3 = (pt_entry_t *)PHYS_TO_DMAP(mptepa); newl2 = ((mptepa / PAGE_SIZE) << PTE_PPN0_S) | PTE_V; KASSERT((oldl2 & PTE_A) != 0, ("pmap_demote_l2_locked: oldl2 is missing PTE_A")); KASSERT((oldl2 & (PTE_D | PTE_W)) != PTE_W, ("pmap_demote_l2_locked: oldl2 is missing PTE_D")); newl3 = oldl2; /* * If the page table page is not leftover from an earlier promotion, * initialize it. */ if (mpte->valid == 0) { for (i = 0; i < Ln_ENTRIES; i++) pmap_store(firstl3 + i, newl3 + (i << PTE_PPN0_S)); } KASSERT(PTE_TO_PHYS(pmap_load(firstl3)) == PTE_TO_PHYS(newl3), ("pmap_demote_l2_locked: firstl3 and newl3 map different physical " "addresses")); /* * If the mapping has changed attributes, update the page table * entries. */ if ((pmap_load(firstl3) & PTE_PROMOTE) != (newl3 & PTE_PROMOTE)) for (i = 0; i < Ln_ENTRIES; i++) pmap_store(firstl3 + i, newl3 + (i << PTE_PPN0_S)); /* * The spare PV entries must be reserved prior to demoting the * mapping, that is, prior to changing the L2 entry. Otherwise, the * state of the L2 entry and the PV lists will be inconsistent, which * can result in reclaim_pv_chunk() attempting to remove a PV entry from * the wrong PV list and pmap_pv_demote_l2() failing to find the * expected PV entry for the 2MB page mapping that is being demoted. */ if ((oldl2 & PTE_SW_MANAGED) != 0) reserve_pv_entries(pmap, Ln_ENTRIES - 1, lockp); /* * Demote the mapping. */ pmap_store(l2, newl2); /* * Demote the PV entry. */ if ((oldl2 & PTE_SW_MANAGED) != 0) pmap_pv_demote_l2(pmap, va, PTE_TO_PHYS(oldl2), lockp); atomic_add_long(&pmap_l2_demotions, 1); CTR2(KTR_PMAP, "pmap_demote_l2_locked: success for va %#lx in pmap %p", va, pmap); return (true); } #if VM_NRESERVLEVEL > 0 static void pmap_promote_l2(pmap_t pmap, pd_entry_t *l2, vm_offset_t va, vm_page_t ml3, struct rwlock **lockp) { pt_entry_t *firstl3, firstl3e, *l3, l3e; vm_paddr_t pa; PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT((pmap_load(l2) & PTE_RWX) == 0, ("pmap_promote_l2: invalid l2 entry %p", l2)); firstl3 = (pt_entry_t *)PHYS_TO_DMAP(PTE_TO_PHYS(pmap_load(l2))); firstl3e = pmap_load(firstl3); pa = PTE_TO_PHYS(firstl3e); if ((pa & L2_OFFSET) != 0) { CTR2(KTR_PMAP, "pmap_promote_l2: failure for va %#lx pmap %p", va, pmap); atomic_add_long(&pmap_l2_p_failures, 1); return; } /* * Downgrade a clean, writable mapping to read-only to ensure that the * hardware does not set PTE_D while we are comparing PTEs. * * Upon a write access to a clean mapping, the implementation will * either atomically check protections and set PTE_D, or raise a page * fault. In the latter case, the pmap lock provides atomicity. Thus, * we do not issue an sfence.vma here and instead rely on pmap_fault() * to do so lazily. */ while ((firstl3e & (PTE_W | PTE_D)) == PTE_W) { if (atomic_fcmpset_64(firstl3, &firstl3e, firstl3e & ~PTE_W)) { firstl3e &= ~PTE_W; break; } } pa += PAGE_SIZE; for (l3 = firstl3 + 1; l3 < firstl3 + Ln_ENTRIES; l3++) { l3e = pmap_load(l3); if (PTE_TO_PHYS(l3e) != pa) { CTR2(KTR_PMAP, "pmap_promote_l2: failure for va %#lx pmap %p", va, pmap); atomic_add_long(&pmap_l2_p_failures, 1); return; } while ((l3e & (PTE_W | PTE_D)) == PTE_W) { if (atomic_fcmpset_64(l3, &l3e, l3e & ~PTE_W)) { l3e &= ~PTE_W; break; } } if ((l3e & PTE_PROMOTE) != (firstl3e & PTE_PROMOTE)) { CTR2(KTR_PMAP, "pmap_promote_l2: failure for va %#lx pmap %p", va, pmap); atomic_add_long(&pmap_l2_p_failures, 1); return; } pa += PAGE_SIZE; } if (ml3 == NULL) ml3 = PHYS_TO_VM_PAGE(PTE_TO_PHYS(pmap_load(l2))); KASSERT(ml3->pindex == pmap_l2_pindex(va), ("pmap_promote_l2: page table page's pindex is wrong")); if (pmap_insert_pt_page(pmap, ml3, true)) { CTR2(KTR_PMAP, "pmap_promote_l2: failure for va %#lx pmap %p", va, pmap); atomic_add_long(&pmap_l2_p_failures, 1); return; } if ((firstl3e & PTE_SW_MANAGED) != 0) pmap_pv_promote_l2(pmap, va, PTE_TO_PHYS(firstl3e), lockp); pmap_store(l2, firstl3e); atomic_add_long(&pmap_l2_promotions, 1); CTR2(KTR_PMAP, "pmap_promote_l2: success for va %#lx in pmap %p", va, pmap); } #endif /* * Insert the given physical page (p) at * the specified virtual address (v) in the * target physical map with the protection requested. * * If specified, the page will be wired down, meaning * that the related pte can not be reclaimed. * * NB: This is the only routine which MAY NOT lazy-evaluate * or lose information. That is, this routine must actually * insert this page into the given map NOW. */ int pmap_enter(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, u_int flags, int8_t psind) { struct rwlock *lock; pd_entry_t *l1, *l2, l2e; pt_entry_t new_l3, orig_l3; pt_entry_t *l3; pv_entry_t pv; vm_paddr_t opa, pa, l2_pa, l3_pa; vm_page_t mpte, om, l2_m, l3_m; pt_entry_t entry; pn_t l2_pn, l3_pn, pn; int rv; bool nosleep; va = trunc_page(va); if ((m->oflags & VPO_UNMANAGED) == 0) VM_PAGE_OBJECT_BUSY_ASSERT(m); pa = VM_PAGE_TO_PHYS(m); pn = (pa / PAGE_SIZE); new_l3 = PTE_V | PTE_R | PTE_A; if (prot & VM_PROT_EXECUTE) new_l3 |= PTE_X; if (flags & VM_PROT_WRITE) new_l3 |= PTE_D; if (prot & VM_PROT_WRITE) new_l3 |= PTE_W; if (va < VM_MAX_USER_ADDRESS) new_l3 |= PTE_U; new_l3 |= (pn << PTE_PPN0_S); if ((flags & PMAP_ENTER_WIRED) != 0) new_l3 |= PTE_SW_WIRED; /* * Set modified bit gratuitously for writeable mappings if * the page is unmanaged. We do not want to take a fault * to do the dirty bit accounting for these mappings. */ if ((m->oflags & VPO_UNMANAGED) != 0) { if (prot & VM_PROT_WRITE) new_l3 |= PTE_D; } else new_l3 |= PTE_SW_MANAGED; CTR2(KTR_PMAP, "pmap_enter: %.16lx -> %.16lx", va, pa); lock = NULL; mpte = NULL; rw_rlock(&pvh_global_lock); PMAP_LOCK(pmap); if (psind == 1) { /* Assert the required virtual and physical alignment. */ KASSERT((va & L2_OFFSET) == 0, ("pmap_enter: va %#lx unaligned", va)); KASSERT(m->psind > 0, ("pmap_enter: m->psind < psind")); rv = pmap_enter_l2(pmap, va, new_l3, flags, m, &lock); goto out; } l2 = pmap_l2(pmap, va); if (l2 != NULL && ((l2e = pmap_load(l2)) & PTE_V) != 0 && ((l2e & PTE_RWX) == 0 || pmap_demote_l2_locked(pmap, l2, va, &lock))) { l3 = pmap_l2_to_l3(l2, va); if (va < VM_MAXUSER_ADDRESS) { mpte = PHYS_TO_VM_PAGE(PTE_TO_PHYS(pmap_load(l2))); mpte->ref_count++; } } else if (va < VM_MAXUSER_ADDRESS) { nosleep = (flags & PMAP_ENTER_NOSLEEP) != 0; mpte = pmap_alloc_l3(pmap, va, nosleep ? NULL : &lock); if (mpte == NULL && nosleep) { CTR0(KTR_PMAP, "pmap_enter: mpte == NULL"); if (lock != NULL) rw_wunlock(lock); rw_runlock(&pvh_global_lock); PMAP_UNLOCK(pmap); return (KERN_RESOURCE_SHORTAGE); } l3 = pmap_l3(pmap, va); } else { l3 = pmap_l3(pmap, va); /* TODO: This is not optimal, but should mostly work */ if (l3 == NULL) { if (l2 == NULL) { l2_m = vm_page_alloc_noobj(VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (l2_m == NULL) panic("pmap_enter: l2 pte_m == NULL"); l2_pa = VM_PAGE_TO_PHYS(l2_m); l2_pn = (l2_pa / PAGE_SIZE); l1 = pmap_l1(pmap, va); entry = (PTE_V); entry |= (l2_pn << PTE_PPN0_S); pmap_store(l1, entry); pmap_distribute_l1(pmap, pmap_l1_index(va), entry); l2 = pmap_l1_to_l2(l1, va); } l3_m = vm_page_alloc_noobj(VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (l3_m == NULL) panic("pmap_enter: l3 pte_m == NULL"); l3_pa = VM_PAGE_TO_PHYS(l3_m); l3_pn = (l3_pa / PAGE_SIZE); entry = (PTE_V); entry |= (l3_pn << PTE_PPN0_S); pmap_store(l2, entry); l3 = pmap_l2_to_l3(l2, va); } pmap_invalidate_page(pmap, va); } orig_l3 = pmap_load(l3); opa = PTE_TO_PHYS(orig_l3); pv = NULL; /* * Is the specified virtual address already mapped? */ if ((orig_l3 & PTE_V) != 0) { /* * Wiring change, just update stats. We don't worry about * wiring PT pages as they remain resident as long as there * are valid mappings in them. Hence, if a user page is wired, * the PT page will be also. */ if ((flags & PMAP_ENTER_WIRED) != 0 && (orig_l3 & PTE_SW_WIRED) == 0) pmap->pm_stats.wired_count++; else if ((flags & PMAP_ENTER_WIRED) == 0 && (orig_l3 & PTE_SW_WIRED) != 0) pmap->pm_stats.wired_count--; /* * Remove the extra PT page reference. */ if (mpte != NULL) { mpte->ref_count--; KASSERT(mpte->ref_count > 0, ("pmap_enter: missing reference to page table page," " va: 0x%lx", va)); } /* * Has the physical page changed? */ if (opa == pa) { /* * No, might be a protection or wiring change. */ if ((orig_l3 & PTE_SW_MANAGED) != 0 && (new_l3 & PTE_W) != 0) vm_page_aflag_set(m, PGA_WRITEABLE); goto validate; } /* * The physical page has changed. Temporarily invalidate * the mapping. This ensures that all threads sharing the * pmap keep a consistent view of the mapping, which is * necessary for the correct handling of COW faults. It * also permits reuse of the old mapping's PV entry, * avoiding an allocation. * * For consistency, handle unmanaged mappings the same way. */ orig_l3 = pmap_load_clear(l3); KASSERT(PTE_TO_PHYS(orig_l3) == opa, ("pmap_enter: unexpected pa update for %#lx", va)); if ((orig_l3 & PTE_SW_MANAGED) != 0) { om = PHYS_TO_VM_PAGE(opa); /* * The pmap lock is sufficient to synchronize with * concurrent calls to pmap_page_test_mappings() and * pmap_ts_referenced(). */ if ((orig_l3 & PTE_D) != 0) vm_page_dirty(om); if ((orig_l3 & PTE_A) != 0) vm_page_aflag_set(om, PGA_REFERENCED); CHANGE_PV_LIST_LOCK_TO_PHYS(&lock, opa); pv = pmap_pvh_remove(&om->md, pmap, va); KASSERT(pv != NULL, ("pmap_enter: no PV entry for %#lx", va)); if ((new_l3 & PTE_SW_MANAGED) == 0) free_pv_entry(pmap, pv); if ((om->a.flags & PGA_WRITEABLE) != 0 && TAILQ_EMPTY(&om->md.pv_list) && ((om->flags & PG_FICTITIOUS) != 0 || TAILQ_EMPTY(&pa_to_pvh(opa)->pv_list))) vm_page_aflag_clear(om, PGA_WRITEABLE); } pmap_invalidate_page(pmap, va); orig_l3 = 0; } else { /* * Increment the counters. */ if ((new_l3 & PTE_SW_WIRED) != 0) pmap->pm_stats.wired_count++; pmap_resident_count_inc(pmap, 1); } /* * Enter on the PV list if part of our managed memory. */ if ((new_l3 & PTE_SW_MANAGED) != 0) { if (pv == NULL) { pv = get_pv_entry(pmap, &lock); pv->pv_va = va; } CHANGE_PV_LIST_LOCK_TO_PHYS(&lock, pa); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; if ((new_l3 & PTE_W) != 0) vm_page_aflag_set(m, PGA_WRITEABLE); } validate: /* * Sync the i-cache on all harts before updating the PTE * if the new PTE is executable. */ if (prot & VM_PROT_EXECUTE) pmap_sync_icache(pmap, va, PAGE_SIZE); /* * Update the L3 entry. */ if (orig_l3 != 0) { orig_l3 = pmap_load_store(l3, new_l3); pmap_invalidate_page(pmap, va); KASSERT(PTE_TO_PHYS(orig_l3) == pa, ("pmap_enter: invalid update")); if ((orig_l3 & (PTE_D | PTE_SW_MANAGED)) == (PTE_D | PTE_SW_MANAGED)) vm_page_dirty(m); } else { pmap_store(l3, new_l3); } #if VM_NRESERVLEVEL > 0 if (mpte != NULL && mpte->ref_count == Ln_ENTRIES && pmap_ps_enabled(pmap) && (m->flags & PG_FICTITIOUS) == 0 && vm_reserv_level_iffullpop(m) == 0) pmap_promote_l2(pmap, l2, va, mpte, &lock); #endif rv = KERN_SUCCESS; out: if (lock != NULL) rw_wunlock(lock); rw_runlock(&pvh_global_lock); PMAP_UNLOCK(pmap); return (rv); } /* * Tries to create a read- and/or execute-only 2MB page mapping. Returns * KERN_SUCCESS if the mapping was created. Otherwise, returns an error * value. See pmap_enter_l2() for the possible error values when "no sleep", * "no replace", and "no reclaim" are specified. */ static int pmap_enter_2mpage(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, struct rwlock **lockp) { pd_entry_t new_l2; pn_t pn; PMAP_LOCK_ASSERT(pmap, MA_OWNED); pn = VM_PAGE_TO_PHYS(m) / PAGE_SIZE; new_l2 = (pd_entry_t)((pn << PTE_PPN0_S) | PTE_R | PTE_V); if ((m->oflags & VPO_UNMANAGED) == 0) new_l2 |= PTE_SW_MANAGED; if ((prot & VM_PROT_EXECUTE) != 0) new_l2 |= PTE_X; if (va < VM_MAXUSER_ADDRESS) new_l2 |= PTE_U; return (pmap_enter_l2(pmap, va, new_l2, PMAP_ENTER_NOSLEEP | PMAP_ENTER_NOREPLACE | PMAP_ENTER_NORECLAIM, NULL, lockp)); } /* * Returns true if every page table entry in the specified page table is * zero. */ static bool pmap_every_pte_zero(vm_paddr_t pa) { pt_entry_t *pt_end, *pte; KASSERT((pa & PAGE_MASK) == 0, ("pa is misaligned")); pte = (pt_entry_t *)PHYS_TO_DMAP(pa); for (pt_end = pte + Ln_ENTRIES; pte < pt_end; pte++) { if (*pte != 0) return (false); } return (true); } /* * Tries to create the specified 2MB page mapping. Returns KERN_SUCCESS if * the mapping was created, and one of KERN_FAILURE, KERN_NO_SPACE, or * KERN_RESOURCE_SHORTAGE otherwise. Returns KERN_FAILURE if * PMAP_ENTER_NOREPLACE was specified and a 4KB page mapping already exists * within the 2MB virtual address range starting at the specified virtual * address. Returns KERN_NO_SPACE if PMAP_ENTER_NOREPLACE was specified and a * 2MB page mapping already exists at the specified virtual address. Returns * KERN_RESOURCE_SHORTAGE if either (1) PMAP_ENTER_NOSLEEP was specified and a * page table page allocation failed or (2) PMAP_ENTER_NORECLAIM was specified * and a PV entry allocation failed. * * The parameter "m" is only used when creating a managed, writeable mapping. */ static int pmap_enter_l2(pmap_t pmap, vm_offset_t va, pd_entry_t new_l2, u_int flags, vm_page_t m, struct rwlock **lockp) { struct spglist free; pd_entry_t *l2, *l3, oldl2; vm_offset_t sva; vm_page_t l2pg, mt; PMAP_LOCK_ASSERT(pmap, MA_OWNED); if ((l2pg = pmap_alloc_l2(pmap, va, (flags & PMAP_ENTER_NOSLEEP) != 0 ? NULL : lockp)) == NULL) { CTR2(KTR_PMAP, "pmap_enter_l2: failed to allocate PT page" " for va %#lx in pmap %p", va, pmap); return (KERN_RESOURCE_SHORTAGE); } l2 = (pd_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(l2pg)); l2 = &l2[pmap_l2_index(va)]; if ((oldl2 = pmap_load(l2)) != 0) { KASSERT(l2pg->ref_count > 1, ("pmap_enter_l2: l2pg's ref count is too low")); if ((flags & PMAP_ENTER_NOREPLACE) != 0) { if ((oldl2 & PTE_RWX) != 0) { l2pg->ref_count--; CTR2(KTR_PMAP, "pmap_enter_l2: no space for va %#lx" " in pmap %p", va, pmap); return (KERN_NO_SPACE); } else if (va < VM_MAXUSER_ADDRESS || !pmap_every_pte_zero(L2PTE_TO_PHYS(oldl2))) { l2pg->ref_count--; CTR2(KTR_PMAP, "pmap_enter_l2:" " failed to replace existing mapping" " for va %#lx in pmap %p", va, pmap); return (KERN_FAILURE); } } SLIST_INIT(&free); if ((oldl2 & PTE_RWX) != 0) (void)pmap_remove_l2(pmap, l2, va, pmap_load(pmap_l1(pmap, va)), &free, lockp); else for (sva = va; sva < va + L2_SIZE; sva += PAGE_SIZE) { l3 = pmap_l2_to_l3(l2, sva); if ((pmap_load(l3) & PTE_V) != 0 && pmap_remove_l3(pmap, l3, sva, oldl2, &free, lockp) != 0) break; } vm_page_free_pages_toq(&free, true); if (va >= VM_MAXUSER_ADDRESS) { /* * Both pmap_remove_l2() and pmap_remove_l3() will * leave the kernel page table page zero filled. */ mt = PHYS_TO_VM_PAGE(PTE_TO_PHYS(pmap_load(l2))); if (pmap_insert_pt_page(pmap, mt, false)) panic("pmap_enter_l2: trie insert failed"); } else KASSERT(pmap_load(l2) == 0, ("pmap_enter_l2: non-zero L2 entry %p", l2)); } if ((new_l2 & PTE_SW_MANAGED) != 0) { /* * Abort this mapping if its PV entry could not be created. */ if (!pmap_pv_insert_l2(pmap, va, new_l2, flags, lockp)) { SLIST_INIT(&free); if (pmap_unwire_ptp(pmap, va, l2pg, &free)) { /* * Although "va" is not mapped, paging-structure * caches could nonetheless have entries that * refer to the freed page table pages. * Invalidate those entries. */ pmap_invalidate_page(pmap, va); vm_page_free_pages_toq(&free, true); } CTR2(KTR_PMAP, "pmap_enter_l2: failed to create PV entry" " for va %#lx in pmap %p", va, pmap); return (KERN_RESOURCE_SHORTAGE); } if ((new_l2 & PTE_W) != 0) for (mt = m; mt < &m[L2_SIZE / PAGE_SIZE]; mt++) vm_page_aflag_set(mt, PGA_WRITEABLE); } /* * Increment counters. */ if ((new_l2 & PTE_SW_WIRED) != 0) pmap->pm_stats.wired_count += L2_SIZE / PAGE_SIZE; pmap->pm_stats.resident_count += L2_SIZE / PAGE_SIZE; /* * Map the superpage. */ pmap_store(l2, new_l2); atomic_add_long(&pmap_l2_mappings, 1); CTR2(KTR_PMAP, "pmap_enter_l2: success for va %#lx in pmap %p", va, pmap); return (KERN_SUCCESS); } /* * Maps a sequence of resident pages belonging to the same object. * The sequence begins with the given page m_start. This page is * mapped at the given virtual address start. Each subsequent page is * mapped at a virtual address that is offset from start by the same * amount as the page is offset from m_start within the object. The * last page in the sequence is the page with the largest offset from * m_start that can be mapped at a virtual address less than the given * virtual address end. Not every virtual page between start and end * is mapped; only those for which a resident page exists with the * corresponding offset from m_start are mapped. */ void pmap_enter_object(pmap_t pmap, vm_offset_t start, vm_offset_t end, vm_page_t m_start, vm_prot_t prot) { struct rwlock *lock; vm_offset_t va; vm_page_t m, mpte; vm_pindex_t diff, psize; int rv; VM_OBJECT_ASSERT_LOCKED(m_start->object); psize = atop(end - start); mpte = NULL; m = m_start; lock = NULL; rw_rlock(&pvh_global_lock); PMAP_LOCK(pmap); while (m != NULL && (diff = m->pindex - m_start->pindex) < psize) { va = start + ptoa(diff); if ((va & L2_OFFSET) == 0 && va + L2_SIZE <= end && m->psind == 1 && pmap_ps_enabled(pmap) && ((rv = pmap_enter_2mpage(pmap, va, m, prot, &lock)) == KERN_SUCCESS || rv == KERN_NO_SPACE)) m = &m[L2_SIZE / PAGE_SIZE - 1]; else mpte = pmap_enter_quick_locked(pmap, va, m, prot, mpte, &lock); m = TAILQ_NEXT(m, listq); } if (lock != NULL) rw_wunlock(lock); rw_runlock(&pvh_global_lock); PMAP_UNLOCK(pmap); } /* * this code makes some *MAJOR* assumptions: * 1. Current pmap & pmap exists. * 2. Not wired. * 3. Read access. * 4. No page table pages. * but is *MUCH* faster than pmap_enter... */ void pmap_enter_quick(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot) { struct rwlock *lock; lock = NULL; rw_rlock(&pvh_global_lock); PMAP_LOCK(pmap); (void)pmap_enter_quick_locked(pmap, va, m, prot, NULL, &lock); if (lock != NULL) rw_wunlock(lock); rw_runlock(&pvh_global_lock); PMAP_UNLOCK(pmap); } static vm_page_t pmap_enter_quick_locked(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, vm_page_t mpte, struct rwlock **lockp) { struct spglist free; vm_paddr_t phys; pd_entry_t *l2; pt_entry_t *l3, newl3; KASSERT(!VA_IS_CLEANMAP(va) || (m->oflags & VPO_UNMANAGED) != 0, ("pmap_enter_quick_locked: managed mapping within the clean submap")); rw_assert(&pvh_global_lock, RA_LOCKED); PMAP_LOCK_ASSERT(pmap, MA_OWNED); CTR2(KTR_PMAP, "pmap_enter_quick_locked: %p %lx", pmap, va); /* * In the case that a page table page is not * resident, we are creating it here. */ if (va < VM_MAXUSER_ADDRESS) { vm_pindex_t l2pindex; /* * Calculate pagetable page index */ l2pindex = pmap_l2_pindex(va); if (mpte && (mpte->pindex == l2pindex)) { mpte->ref_count++; } else { /* * Get the l2 entry */ l2 = pmap_l2(pmap, va); /* * If the page table page is mapped, we just increment * the hold count, and activate it. Otherwise, we * attempt to allocate a page table page. If this * attempt fails, we don't retry. Instead, we give up. */ if (l2 != NULL && pmap_load(l2) != 0) { if ((pmap_load(l2) & PTE_RWX) != 0) return (NULL); phys = PTE_TO_PHYS(pmap_load(l2)); mpte = PHYS_TO_VM_PAGE(phys); mpte->ref_count++; } else { /* * Pass NULL instead of the PV list lock * pointer, because we don't intend to sleep. */ mpte = _pmap_alloc_l3(pmap, l2pindex, NULL); if (mpte == NULL) return (mpte); } } l3 = (pt_entry_t *)PHYS_TO_DMAP(VM_PAGE_TO_PHYS(mpte)); l3 = &l3[pmap_l3_index(va)]; } else { mpte = NULL; l3 = pmap_l3(kernel_pmap, va); } if (l3 == NULL) panic("pmap_enter_quick_locked: No l3"); if (pmap_load(l3) != 0) { if (mpte != NULL) { mpte->ref_count--; mpte = NULL; } return (mpte); } /* * Enter on the PV list if part of our managed memory. */ if ((m->oflags & VPO_UNMANAGED) == 0 && !pmap_try_insert_pv_entry(pmap, va, m, lockp)) { if (mpte != NULL) { SLIST_INIT(&free); if (pmap_unwire_ptp(pmap, va, mpte, &free)) { pmap_invalidate_page(pmap, va); vm_page_free_pages_toq(&free, false); } mpte = NULL; } return (mpte); } /* * Increment counters */ pmap_resident_count_inc(pmap, 1); newl3 = ((VM_PAGE_TO_PHYS(m) / PAGE_SIZE) << PTE_PPN0_S) | PTE_V | PTE_R; if ((prot & VM_PROT_EXECUTE) != 0) newl3 |= PTE_X; if ((m->oflags & VPO_UNMANAGED) == 0) newl3 |= PTE_SW_MANAGED; if (va < VM_MAX_USER_ADDRESS) newl3 |= PTE_U; /* * Sync the i-cache on all harts before updating the PTE * if the new PTE is executable. */ if (prot & VM_PROT_EXECUTE) pmap_sync_icache(pmap, va, PAGE_SIZE); pmap_store(l3, newl3); pmap_invalidate_page(pmap, va); return (mpte); } /* * This code maps large physical mmap regions into the * processor address space. Note that some shortcuts * are taken, but the code works. */ void pmap_object_init_pt(pmap_t pmap, vm_offset_t addr, vm_object_t object, vm_pindex_t pindex, vm_size_t size) { VM_OBJECT_ASSERT_WLOCKED(object); KASSERT(object->type == OBJT_DEVICE || object->type == OBJT_SG, ("pmap_object_init_pt: non-device object")); } /* * Clear the wired attribute from the mappings for the specified range of * addresses in the given pmap. Every valid mapping within that range * must have the wired attribute set. In contrast, invalid mappings * cannot have the wired attribute set, so they are ignored. * * The wired attribute of the page table entry is not a hardware feature, * so there is no need to invalidate any TLB entries. */ void pmap_unwire(pmap_t pmap, vm_offset_t sva, vm_offset_t eva) { vm_offset_t va_next; pd_entry_t *l0, *l1, *l2, l2e; pt_entry_t *l3, l3e; bool pv_lists_locked; pv_lists_locked = false; retry: PMAP_LOCK(pmap); for (; sva < eva; sva = va_next) { if (pmap_mode == PMAP_MODE_SV48) { l0 = pmap_l0(pmap, sva); if (pmap_load(l0) == 0) { va_next = (sva + L0_SIZE) & ~L0_OFFSET; if (va_next < sva) va_next = eva; continue; } l1 = pmap_l0_to_l1(l0, sva); } else { l1 = pmap_l1(pmap, sva); } if (pmap_load(l1) == 0) { va_next = (sva + L1_SIZE) & ~L1_OFFSET; if (va_next < sva) va_next = eva; continue; } va_next = (sva + L2_SIZE) & ~L2_OFFSET; if (va_next < sva) va_next = eva; l2 = pmap_l1_to_l2(l1, sva); if ((l2e = pmap_load(l2)) == 0) continue; if ((l2e & PTE_RWX) != 0) { if (sva + L2_SIZE == va_next && eva >= va_next) { if ((l2e & PTE_SW_WIRED) == 0) panic("pmap_unwire: l2 %#jx is missing " "PTE_SW_WIRED", (uintmax_t)l2e); pmap_clear_bits(l2, PTE_SW_WIRED); continue; } else { if (!pv_lists_locked) { pv_lists_locked = true; if (!rw_try_rlock(&pvh_global_lock)) { PMAP_UNLOCK(pmap); rw_rlock(&pvh_global_lock); /* Repeat sva. */ goto retry; } } if (!pmap_demote_l2(pmap, l2, sva)) panic("pmap_unwire: demotion failed"); } } if (va_next > eva) va_next = eva; for (l3 = pmap_l2_to_l3(l2, sva); sva != va_next; l3++, sva += L3_SIZE) { if ((l3e = pmap_load(l3)) == 0) continue; if ((l3e & PTE_SW_WIRED) == 0) panic("pmap_unwire: l3 %#jx is missing " "PTE_SW_WIRED", (uintmax_t)l3e); /* * PG_W must be cleared atomically. Although the pmap * lock synchronizes access to PG_W, another processor * could be setting PG_M and/or PG_A concurrently. */ pmap_clear_bits(l3, PTE_SW_WIRED); pmap->pm_stats.wired_count--; } } if (pv_lists_locked) rw_runlock(&pvh_global_lock); PMAP_UNLOCK(pmap); } /* * Copy the range specified by src_addr/len * from the source map to the range dst_addr/len * in the destination map. * * This routine is only advisory and need not do anything. */ void pmap_copy(pmap_t dst_pmap, pmap_t src_pmap, vm_offset_t dst_addr, vm_size_t len, vm_offset_t src_addr) { } /* * pmap_zero_page zeros the specified hardware page by mapping * the page into KVM and using bzero to clear its contents. */ void pmap_zero_page(vm_page_t m) { vm_offset_t va = PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m)); pagezero((void *)va); } /* * pmap_zero_page_area zeros the specified hardware page by mapping * the page into KVM and using bzero to clear its contents. * * off and size may not cover an area beyond a single hardware page. */ void pmap_zero_page_area(vm_page_t m, int off, int size) { vm_offset_t va = PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m)); if (off == 0 && size == PAGE_SIZE) pagezero((void *)va); else bzero((char *)va + off, size); } /* * pmap_copy_page copies the specified (machine independent) * page by mapping the page into virtual memory and using * bcopy to copy the page, one machine dependent page at a * time. */ void pmap_copy_page(vm_page_t msrc, vm_page_t mdst) { vm_offset_t src = PHYS_TO_DMAP(VM_PAGE_TO_PHYS(msrc)); vm_offset_t dst = PHYS_TO_DMAP(VM_PAGE_TO_PHYS(mdst)); pagecopy((void *)src, (void *)dst); } int unmapped_buf_allowed = 1; void pmap_copy_pages(vm_page_t ma[], vm_offset_t a_offset, vm_page_t mb[], vm_offset_t b_offset, int xfersize) { void *a_cp, *b_cp; vm_page_t m_a, m_b; vm_paddr_t p_a, p_b; vm_offset_t a_pg_offset, b_pg_offset; int cnt; while (xfersize > 0) { a_pg_offset = a_offset & PAGE_MASK; m_a = ma[a_offset >> PAGE_SHIFT]; p_a = m_a->phys_addr; b_pg_offset = b_offset & PAGE_MASK; m_b = mb[b_offset >> PAGE_SHIFT]; p_b = m_b->phys_addr; cnt = min(xfersize, PAGE_SIZE - a_pg_offset); cnt = min(cnt, PAGE_SIZE - b_pg_offset); if (__predict_false(!PHYS_IN_DMAP(p_a))) { panic("!DMAP a %lx", p_a); } else { a_cp = (char *)PHYS_TO_DMAP(p_a) + a_pg_offset; } if (__predict_false(!PHYS_IN_DMAP(p_b))) { panic("!DMAP b %lx", p_b); } else { b_cp = (char *)PHYS_TO_DMAP(p_b) + b_pg_offset; } bcopy(a_cp, b_cp, cnt); a_offset += cnt; b_offset += cnt; xfersize -= cnt; } } vm_offset_t pmap_quick_enter_page(vm_page_t m) { return (PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m))); } void pmap_quick_remove_page(vm_offset_t addr) { } /* * Returns true if the pmap's pv is one of the first * 16 pvs linked to from this page. This count may * be changed upwards or downwards in the future; it * is only necessary that true be returned for a small * subset of pmaps for proper page aging. */ boolean_t pmap_page_exists_quick(pmap_t pmap, vm_page_t m) { struct md_page *pvh; struct rwlock *lock; pv_entry_t pv; int loops = 0; boolean_t rv; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_page_exists_quick: page %p is not managed", m)); rv = FALSE; rw_rlock(&pvh_global_lock); lock = VM_PAGE_TO_PV_LIST_LOCK(m); rw_rlock(lock); TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { if (PV_PMAP(pv) == pmap) { rv = TRUE; break; } loops++; if (loops >= 16) break; } if (!rv && loops < 16 && (m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { if (PV_PMAP(pv) == pmap) { rv = TRUE; break; } loops++; if (loops >= 16) break; } } rw_runlock(lock); rw_runlock(&pvh_global_lock); return (rv); } /* * pmap_page_wired_mappings: * * Return the number of managed mappings to the given physical page * that are wired. */ int pmap_page_wired_mappings(vm_page_t m) { struct md_page *pvh; struct rwlock *lock; pmap_t pmap; pd_entry_t *l2; pt_entry_t *l3; pv_entry_t pv; int count, md_gen, pvh_gen; if ((m->oflags & VPO_UNMANAGED) != 0) return (0); rw_rlock(&pvh_global_lock); lock = VM_PAGE_TO_PV_LIST_LOCK(m); rw_rlock(lock); restart: count = 0; TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { md_gen = m->md.pv_gen; rw_runlock(lock); PMAP_LOCK(pmap); rw_rlock(lock); if (md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } l2 = pmap_l2(pmap, pv->pv_va); KASSERT((pmap_load(l2) & PTE_RWX) == 0, ("%s: found a 2mpage in page %p's pv list", __func__, m)); l3 = pmap_l2_to_l3(l2, pv->pv_va); if ((pmap_load(l3) & PTE_SW_WIRED) != 0) count++; PMAP_UNLOCK(pmap); } if ((m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { md_gen = m->md.pv_gen; pvh_gen = pvh->pv_gen; rw_runlock(lock); PMAP_LOCK(pmap); rw_rlock(lock); if (md_gen != m->md.pv_gen || pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } l2 = pmap_l2(pmap, pv->pv_va); if ((pmap_load(l2) & PTE_SW_WIRED) != 0) count++; PMAP_UNLOCK(pmap); } } rw_runlock(lock); rw_runlock(&pvh_global_lock); return (count); } /* * Returns true if the given page is mapped individually or as part of * a 2mpage. Otherwise, returns false. */ bool pmap_page_is_mapped(vm_page_t m) { struct rwlock *lock; bool rv; if ((m->oflags & VPO_UNMANAGED) != 0) return (false); lock = VM_PAGE_TO_PV_LIST_LOCK(m); rw_rlock(lock); rv = !TAILQ_EMPTY(&m->md.pv_list) || ((m->flags & PG_FICTITIOUS) == 0 && !TAILQ_EMPTY(&pa_to_pvh(VM_PAGE_TO_PHYS(m))->pv_list)); rw_runlock(lock); return (rv); } static void pmap_remove_pages_pv(pmap_t pmap, vm_page_t m, pv_entry_t pv, struct spglist *free, bool superpage) { struct md_page *pvh; vm_page_t mpte, mt; if (superpage) { pmap_resident_count_dec(pmap, Ln_ENTRIES); pvh = pa_to_pvh(m->phys_addr); TAILQ_REMOVE(&pvh->pv_list, pv, pv_next); pvh->pv_gen++; if (TAILQ_EMPTY(&pvh->pv_list)) { for (mt = m; mt < &m[Ln_ENTRIES]; mt++) if (TAILQ_EMPTY(&mt->md.pv_list) && (mt->a.flags & PGA_WRITEABLE) != 0) vm_page_aflag_clear(mt, PGA_WRITEABLE); } mpte = pmap_remove_pt_page(pmap, pv->pv_va); if (mpte != NULL) { KASSERT(mpte->valid == VM_PAGE_BITS_ALL, ("pmap_remove_pages: pte page not promoted")); pmap_resident_count_dec(pmap, 1); KASSERT(mpte->ref_count == Ln_ENTRIES, ("pmap_remove_pages: pte page ref count error")); mpte->ref_count = 0; pmap_add_delayed_free_list(mpte, free, FALSE); } } else { pmap_resident_count_dec(pmap, 1); TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; if (TAILQ_EMPTY(&m->md.pv_list) && (m->a.flags & PGA_WRITEABLE) != 0) { pvh = pa_to_pvh(m->phys_addr); if (TAILQ_EMPTY(&pvh->pv_list)) vm_page_aflag_clear(m, PGA_WRITEABLE); } } } /* * Destroy all managed, non-wired mappings in the given user-space * pmap. This pmap cannot be active on any processor besides the * caller. * * This function cannot be applied to the kernel pmap. Moreover, it * is not intended for general use. It is only to be used during * process termination. Consequently, it can be implemented in ways * that make it faster than pmap_remove(). First, it can more quickly * destroy mappings by iterating over the pmap's collection of PV * entries, rather than searching the page table. Second, it doesn't * have to test and clear the page table entries atomically, because * no processor is currently accessing the user address space. In * particular, a page table entry's dirty bit won't change state once * this function starts. */ void pmap_remove_pages(pmap_t pmap) { struct spglist free; pd_entry_t ptepde; pt_entry_t *pte, tpte; vm_page_t m, mt; pv_entry_t pv; struct pv_chunk *pc, *npc; struct rwlock *lock; int64_t bit; uint64_t inuse, bitmask; int allfree, field, freed __pv_stat_used, idx; bool superpage; lock = NULL; SLIST_INIT(&free); rw_rlock(&pvh_global_lock); PMAP_LOCK(pmap); TAILQ_FOREACH_SAFE(pc, &pmap->pm_pvchunk, pc_list, npc) { allfree = 1; freed = 0; for (field = 0; field < _NPCM; field++) { inuse = ~pc->pc_map[field] & pc_freemask[field]; while (inuse != 0) { bit = ffsl(inuse) - 1; bitmask = 1UL << bit; idx = field * 64 + bit; pv = &pc->pc_pventry[idx]; inuse &= ~bitmask; pte = pmap_l1(pmap, pv->pv_va); ptepde = pmap_load(pte); pte = pmap_l1_to_l2(pte, pv->pv_va); tpte = pmap_load(pte); KASSERT((tpte & PTE_V) != 0, ("L2 PTE is invalid... bogus PV entry? " "va=%#lx, pte=%#lx", pv->pv_va, tpte)); if ((tpte & PTE_RWX) != 0) { superpage = true; } else { ptepde = tpte; pte = pmap_l2_to_l3(pte, pv->pv_va); tpte = pmap_load(pte); superpage = false; } /* * We cannot remove wired pages from a * process' mapping at this time. */ if (tpte & PTE_SW_WIRED) { allfree = 0; continue; } m = PHYS_TO_VM_PAGE(PTE_TO_PHYS(tpte)); KASSERT((m->flags & PG_FICTITIOUS) != 0 || m < &vm_page_array[vm_page_array_size], ("pmap_remove_pages: bad pte %#jx", (uintmax_t)tpte)); pmap_clear(pte); /* * Update the vm_page_t clean/reference bits. */ if ((tpte & (PTE_D | PTE_W)) == (PTE_D | PTE_W)) { if (superpage) for (mt = m; mt < &m[Ln_ENTRIES]; mt++) vm_page_dirty(mt); else vm_page_dirty(m); } CHANGE_PV_LIST_LOCK_TO_VM_PAGE(&lock, m); /* Mark free */ pc->pc_map[field] |= bitmask; pmap_remove_pages_pv(pmap, m, pv, &free, superpage); pmap_unuse_pt(pmap, pv->pv_va, ptepde, &free); freed++; } } PV_STAT(atomic_add_long(&pv_entry_frees, freed)); PV_STAT(atomic_add_int(&pv_entry_spare, freed)); PV_STAT(atomic_subtract_long(&pv_entry_count, freed)); if (allfree) { TAILQ_REMOVE(&pmap->pm_pvchunk, pc, pc_list); free_pv_chunk(pc); } } if (lock != NULL) rw_wunlock(lock); pmap_invalidate_all(pmap); rw_runlock(&pvh_global_lock); PMAP_UNLOCK(pmap); vm_page_free_pages_toq(&free, false); } static bool pmap_page_test_mappings(vm_page_t m, boolean_t accessed, boolean_t modified) { struct md_page *pvh; struct rwlock *lock; pd_entry_t *l2; pt_entry_t *l3, mask; pv_entry_t pv; pmap_t pmap; int md_gen, pvh_gen; bool rv; mask = 0; if (modified) mask |= PTE_D; if (accessed) mask |= PTE_A; rv = FALSE; rw_rlock(&pvh_global_lock); lock = VM_PAGE_TO_PV_LIST_LOCK(m); rw_rlock(lock); restart: TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { md_gen = m->md.pv_gen; rw_runlock(lock); PMAP_LOCK(pmap); rw_rlock(lock); if (md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } l2 = pmap_l2(pmap, pv->pv_va); KASSERT((pmap_load(l2) & PTE_RWX) == 0, ("%s: found a 2mpage in page %p's pv list", __func__, m)); l3 = pmap_l2_to_l3(l2, pv->pv_va); rv = (pmap_load(l3) & mask) == mask; PMAP_UNLOCK(pmap); if (rv) goto out; } if ((m->flags & PG_FICTITIOUS) == 0) { pvh = pa_to_pvh(VM_PAGE_TO_PHYS(m)); TAILQ_FOREACH(pv, &pvh->pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { md_gen = m->md.pv_gen; pvh_gen = pvh->pv_gen; rw_runlock(lock); PMAP_LOCK(pmap); rw_rlock(lock); if (md_gen != m->md.pv_gen || pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } l2 = pmap_l2(pmap, pv->pv_va); rv = (pmap_load(l2) & mask) == mask; PMAP_UNLOCK(pmap); if (rv) goto out; } } out: rw_runlock(lock); rw_runlock(&pvh_global_lock); return (rv); } /* * pmap_is_modified: * * Return whether or not the specified physical page was modified * in any physical maps. */ boolean_t pmap_is_modified(vm_page_t m) { KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_is_modified: page %p is not managed", m)); /* * If the page is not busied then this check is racy. */ if (!pmap_page_is_write_mapped(m)) return (FALSE); return (pmap_page_test_mappings(m, FALSE, TRUE)); } /* * pmap_is_prefaultable: * * Return whether or not the specified virtual address is eligible * for prefault. */ boolean_t pmap_is_prefaultable(pmap_t pmap, vm_offset_t addr) { pt_entry_t *l3; boolean_t rv; /* * Return TRUE if and only if the L3 entry for the specified virtual * address is allocated but invalid. */ rv = FALSE; PMAP_LOCK(pmap); l3 = pmap_l3(pmap, addr); if (l3 != NULL && pmap_load(l3) == 0) { rv = TRUE; } PMAP_UNLOCK(pmap); return (rv); } /* * pmap_is_referenced: * * Return whether or not the specified physical page was referenced * in any physical maps. */ boolean_t pmap_is_referenced(vm_page_t m) { KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_is_referenced: page %p is not managed", m)); return (pmap_page_test_mappings(m, TRUE, FALSE)); } /* * Clear the write and modified bits in each of the given page's mappings. */ void pmap_remove_write(vm_page_t m) { struct md_page *pvh; struct rwlock *lock; pmap_t pmap; pd_entry_t *l2; pt_entry_t *l3, oldl3, newl3; pv_entry_t next_pv, pv; vm_offset_t va; int md_gen, pvh_gen; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_remove_write: page %p is not managed", m)); vm_page_assert_busied(m); if (!pmap_page_is_write_mapped(m)) return; lock = VM_PAGE_TO_PV_LIST_LOCK(m); pvh = (m->flags & PG_FICTITIOUS) != 0 ? &pv_dummy : pa_to_pvh(VM_PAGE_TO_PHYS(m)); rw_rlock(&pvh_global_lock); retry_pv_loop: rw_wlock(lock); TAILQ_FOREACH_SAFE(pv, &pvh->pv_list, pv_next, next_pv) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); rw_wunlock(lock); goto retry_pv_loop; } } va = pv->pv_va; l2 = pmap_l2(pmap, va); if ((pmap_load(l2) & PTE_W) != 0) (void)pmap_demote_l2_locked(pmap, l2, va, &lock); KASSERT(lock == VM_PAGE_TO_PV_LIST_LOCK(m), ("inconsistent pv lock %p %p for page %p", lock, VM_PAGE_TO_PV_LIST_LOCK(m), m)); PMAP_UNLOCK(pmap); } TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; md_gen = m->md.pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen || md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); rw_wunlock(lock); goto retry_pv_loop; } } l2 = pmap_l2(pmap, pv->pv_va); KASSERT((pmap_load(l2) & PTE_RWX) == 0, ("%s: found a 2mpage in page %p's pv list", __func__, m)); l3 = pmap_l2_to_l3(l2, pv->pv_va); oldl3 = pmap_load(l3); retry: if ((oldl3 & PTE_W) != 0) { newl3 = oldl3 & ~(PTE_D | PTE_W); if (!atomic_fcmpset_long(l3, &oldl3, newl3)) goto retry; if ((oldl3 & PTE_D) != 0) vm_page_dirty(m); pmap_invalidate_page(pmap, pv->pv_va); } PMAP_UNLOCK(pmap); } rw_wunlock(lock); vm_page_aflag_clear(m, PGA_WRITEABLE); rw_runlock(&pvh_global_lock); } /* * pmap_ts_referenced: * * Return a count of reference bits for a page, clearing those bits. * It is not necessary for every reference bit to be cleared, but it * is necessary that 0 only be returned when there are truly no * reference bits set. * * As an optimization, update the page's dirty field if a modified bit is * found while counting reference bits. This opportunistic update can be * performed at low cost and can eliminate the need for some future calls * to pmap_is_modified(). However, since this function stops after * finding PMAP_TS_REFERENCED_MAX reference bits, it may not detect some * dirty pages. Those dirty pages will only be detected by a future call * to pmap_is_modified(). */ int pmap_ts_referenced(vm_page_t m) { struct spglist free; struct md_page *pvh; struct rwlock *lock; pv_entry_t pv, pvf; pmap_t pmap; pd_entry_t *l2, l2e; pt_entry_t *l3, l3e; vm_paddr_t pa; vm_offset_t va; int cleared, md_gen, not_cleared, pvh_gen; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_ts_referenced: page %p is not managed", m)); SLIST_INIT(&free); cleared = 0; pa = VM_PAGE_TO_PHYS(m); pvh = (m->flags & PG_FICTITIOUS) != 0 ? &pv_dummy : pa_to_pvh(pa); lock = PHYS_TO_PV_LIST_LOCK(pa); rw_rlock(&pvh_global_lock); rw_wlock(lock); retry: not_cleared = 0; if ((pvf = TAILQ_FIRST(&pvh->pv_list)) == NULL) goto small_mappings; pv = pvf; do { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); goto retry; } } va = pv->pv_va; l2 = pmap_l2(pmap, va); l2e = pmap_load(l2); if ((l2e & (PTE_W | PTE_D)) == (PTE_W | PTE_D)) { /* * Although l2e is mapping a 2MB page, because * this function is called at a 4KB page granularity, * we only update the 4KB page under test. */ vm_page_dirty(m); } if ((l2e & PTE_A) != 0) { /* * Since this reference bit is shared by 512 4KB * pages, it should not be cleared every time it is * tested. Apply a simple "hash" function on the * physical page number, the virtual superpage number, * and the pmap address to select one 4KB page out of * the 512 on which testing the reference bit will * result in clearing that reference bit. This * function is designed to avoid the selection of the * same 4KB page for every 2MB page mapping. * * On demotion, a mapping that hasn't been referenced * is simply destroyed. To avoid the possibility of a * subsequent page fault on a demoted wired mapping, * always leave its reference bit set. Moreover, * since the superpage is wired, the current state of * its reference bit won't affect page replacement. */ if ((((pa >> PAGE_SHIFT) ^ (pv->pv_va >> L2_SHIFT) ^ (uintptr_t)pmap) & (Ln_ENTRIES - 1)) == 0 && (l2e & PTE_SW_WIRED) == 0) { pmap_clear_bits(l2, PTE_A); pmap_invalidate_page(pmap, va); cleared++; } else not_cleared++; } PMAP_UNLOCK(pmap); /* Rotate the PV list if it has more than one entry. */ if (pv != NULL && TAILQ_NEXT(pv, pv_next) != NULL) { TAILQ_REMOVE(&pvh->pv_list, pv, pv_next); TAILQ_INSERT_TAIL(&pvh->pv_list, pv, pv_next); pvh->pv_gen++; } if (cleared + not_cleared >= PMAP_TS_REFERENCED_MAX) goto out; } while ((pv = TAILQ_FIRST(&pvh->pv_list)) != pvf); small_mappings: if ((pvf = TAILQ_FIRST(&m->md.pv_list)) == NULL) goto out; pv = pvf; do { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; md_gen = m->md.pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen || md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); goto retry; } } l2 = pmap_l2(pmap, pv->pv_va); KASSERT((pmap_load(l2) & PTE_RX) == 0, ("pmap_ts_referenced: found an invalid l2 table")); l3 = pmap_l2_to_l3(l2, pv->pv_va); l3e = pmap_load(l3); if ((l3e & PTE_D) != 0) vm_page_dirty(m); if ((l3e & PTE_A) != 0) { if ((l3e & PTE_SW_WIRED) == 0) { /* * Wired pages cannot be paged out so * doing accessed bit emulation for * them is wasted effort. We do the * hard work for unwired pages only. */ pmap_clear_bits(l3, PTE_A); pmap_invalidate_page(pmap, pv->pv_va); cleared++; } else not_cleared++; } PMAP_UNLOCK(pmap); /* Rotate the PV list if it has more than one entry. */ if (pv != NULL && TAILQ_NEXT(pv, pv_next) != NULL) { TAILQ_REMOVE(&m->md.pv_list, pv, pv_next); TAILQ_INSERT_TAIL(&m->md.pv_list, pv, pv_next); m->md.pv_gen++; } } while ((pv = TAILQ_FIRST(&m->md.pv_list)) != pvf && cleared + not_cleared < PMAP_TS_REFERENCED_MAX); out: rw_wunlock(lock); rw_runlock(&pvh_global_lock); vm_page_free_pages_toq(&free, false); return (cleared + not_cleared); } /* * Apply the given advice to the specified range of addresses within the * given pmap. Depending on the advice, clear the referenced and/or * modified flags in each mapping and set the mapped page's dirty field. */ void pmap_advise(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, int advice) { } /* * Clear the modify bits on the specified physical page. */ void pmap_clear_modify(vm_page_t m) { struct md_page *pvh; struct rwlock *lock; pmap_t pmap; pv_entry_t next_pv, pv; pd_entry_t *l2, oldl2; pt_entry_t *l3; vm_offset_t va; int md_gen, pvh_gen; KASSERT((m->oflags & VPO_UNMANAGED) == 0, ("pmap_clear_modify: page %p is not managed", m)); vm_page_assert_busied(m); if (!pmap_page_is_write_mapped(m)) return; /* * If the page is not PGA_WRITEABLE, then no PTEs can have PG_M set. * If the object containing the page is locked and the page is not * exclusive busied, then PGA_WRITEABLE cannot be concurrently set. */ if ((m->a.flags & PGA_WRITEABLE) == 0) return; pvh = (m->flags & PG_FICTITIOUS) != 0 ? &pv_dummy : pa_to_pvh(VM_PAGE_TO_PHYS(m)); lock = VM_PAGE_TO_PV_LIST_LOCK(m); rw_rlock(&pvh_global_lock); rw_wlock(lock); restart: TAILQ_FOREACH_SAFE(pv, &pvh->pv_list, pv_next, next_pv) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { pvh_gen = pvh->pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } va = pv->pv_va; l2 = pmap_l2(pmap, va); oldl2 = pmap_load(l2); /* If oldl2 has PTE_W set, then it also has PTE_D set. */ if ((oldl2 & PTE_W) != 0 && pmap_demote_l2_locked(pmap, l2, va, &lock) && (oldl2 & PTE_SW_WIRED) == 0) { /* * Write protect the mapping to a single page so that * a subsequent write access may repromote. */ va += VM_PAGE_TO_PHYS(m) - PTE_TO_PHYS(oldl2); l3 = pmap_l2_to_l3(l2, va); pmap_clear_bits(l3, PTE_D | PTE_W); vm_page_dirty(m); pmap_invalidate_page(pmap, va); } PMAP_UNLOCK(pmap); } TAILQ_FOREACH(pv, &m->md.pv_list, pv_next) { pmap = PV_PMAP(pv); if (!PMAP_TRYLOCK(pmap)) { md_gen = m->md.pv_gen; pvh_gen = pvh->pv_gen; rw_wunlock(lock); PMAP_LOCK(pmap); rw_wlock(lock); if (pvh_gen != pvh->pv_gen || md_gen != m->md.pv_gen) { PMAP_UNLOCK(pmap); goto restart; } } l2 = pmap_l2(pmap, pv->pv_va); KASSERT((pmap_load(l2) & PTE_RWX) == 0, ("%s: found a 2mpage in page %p's pv list", __func__, m)); l3 = pmap_l2_to_l3(l2, pv->pv_va); if ((pmap_load(l3) & (PTE_D | PTE_W)) == (PTE_D | PTE_W)) { pmap_clear_bits(l3, PTE_D | PTE_W); pmap_invalidate_page(pmap, pv->pv_va); } PMAP_UNLOCK(pmap); } rw_wunlock(lock); rw_runlock(&pvh_global_lock); } void * pmap_mapbios(vm_paddr_t pa, vm_size_t size) { return ((void *)PHYS_TO_DMAP(pa)); } void pmap_unmapbios(void *p, vm_size_t size) { } /* * Sets the memory attribute for the specified page. */ void pmap_page_set_memattr(vm_page_t m, vm_memattr_t ma) { m->md.pv_memattr = ma; /* * If "m" is a normal page, update its direct mapping. This update * can be relied upon to perform any cache operations that are * required for data coherence. */ if ((m->flags & PG_FICTITIOUS) == 0 && pmap_change_attr(PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m)), PAGE_SIZE, m->md.pv_memattr) != 0) panic("memory attribute change on the direct map failed"); } /* * Changes the specified virtual address range's memory type to that given by * the parameter "mode". The specified virtual address range must be * completely contained within either the direct map or the kernel map. * * Returns zero if the change completed successfully, and either EINVAL or * ENOMEM if the change failed. Specifically, EINVAL is returned if some part * of the virtual address range was not mapped, and ENOMEM is returned if * there was insufficient memory available to complete the change. In the * latter case, the memory type may have been changed on some part of the * virtual address range. */ int pmap_change_attr(vm_offset_t va, vm_size_t size, int mode) { int error; PMAP_LOCK(kernel_pmap); error = pmap_change_attr_locked(va, size, mode); PMAP_UNLOCK(kernel_pmap); return (error); } static int pmap_change_attr_locked(vm_offset_t va, vm_size_t size, int mode) { vm_offset_t base, offset, tmpva; pd_entry_t *l1, l1e; pd_entry_t *l2, l2e; pt_entry_t *l3, l3e; PMAP_LOCK_ASSERT(kernel_pmap, MA_OWNED); base = trunc_page(va); offset = va & PAGE_MASK; size = round_page(offset + size); if (!VIRT_IN_DMAP(base) && !(base >= VM_MIN_KERNEL_ADDRESS && base < VM_MAX_KERNEL_ADDRESS)) return (EINVAL); for (tmpva = base; tmpva < base + size; ) { l1 = pmap_l1(kernel_pmap, tmpva); if (l1 == NULL || ((l1e = pmap_load(l1)) & PTE_V) == 0) return (EINVAL); if ((l1e & PTE_RWX) != 0) { /* * TODO: Demote if attributes don't match and there * isn't an L1 page left in the range, and update the * L1 entry if the attributes don't match but there is * an L1 page left in the range, once we support the * upcoming Svpbmt extension. */ tmpva = (tmpva & ~L1_OFFSET) + L1_SIZE; continue; } l2 = pmap_l1_to_l2(l1, tmpva); if (l2 == NULL || ((l2e = pmap_load(l2)) & PTE_V) == 0) return (EINVAL); if ((l2e & PTE_RWX) != 0) { /* * TODO: Demote if attributes don't match and there * isn't an L2 page left in the range, and update the * L2 entry if the attributes don't match but there is * an L2 page left in the range, once we support the * upcoming Svpbmt extension. */ tmpva = (tmpva & ~L2_OFFSET) + L2_SIZE; continue; } l3 = pmap_l2_to_l3(l2, tmpva); if (l3 == NULL || ((l3e = pmap_load(l3)) & PTE_V) == 0) return (EINVAL); /* * TODO: Update the L3 entry if the attributes don't match once * we support the upcoming Svpbmt extension. */ tmpva += PAGE_SIZE; } return (0); } /* * Perform the pmap work for mincore(2). If the page is not both referenced and * modified by this pmap, returns its physical address so that the caller can * find other mappings. */ int pmap_mincore(pmap_t pmap, vm_offset_t addr, vm_paddr_t *pap) { pt_entry_t *l2, *l3, tpte; vm_paddr_t pa; int val; bool managed; PMAP_LOCK(pmap); l2 = pmap_l2(pmap, addr); if (l2 != NULL && ((tpte = pmap_load(l2)) & PTE_V) != 0) { if ((tpte & PTE_RWX) != 0) { pa = PTE_TO_PHYS(tpte) | (addr & L2_OFFSET); val = MINCORE_INCORE | MINCORE_PSIND(1); } else { l3 = pmap_l2_to_l3(l2, addr); tpte = pmap_load(l3); if ((tpte & PTE_V) == 0) { PMAP_UNLOCK(pmap); return (0); } pa = PTE_TO_PHYS(tpte) | (addr & L3_OFFSET); val = MINCORE_INCORE; } if ((tpte & PTE_D) != 0) val |= MINCORE_MODIFIED | MINCORE_MODIFIED_OTHER; if ((tpte & PTE_A) != 0) val |= MINCORE_REFERENCED | MINCORE_REFERENCED_OTHER; managed = (tpte & PTE_SW_MANAGED) == PTE_SW_MANAGED; } else { managed = false; val = 0; } if ((val & (MINCORE_MODIFIED_OTHER | MINCORE_REFERENCED_OTHER)) != (MINCORE_MODIFIED_OTHER | MINCORE_REFERENCED_OTHER) && managed) { *pap = pa; } PMAP_UNLOCK(pmap); return (val); } void pmap_activate_sw(struct thread *td) { pmap_t oldpmap, pmap; u_int hart; oldpmap = PCPU_GET(curpmap); pmap = vmspace_pmap(td->td_proc->p_vmspace); if (pmap == oldpmap) return; csr_write(satp, pmap->pm_satp); hart = PCPU_GET(hart); #ifdef SMP CPU_SET_ATOMIC(hart, &pmap->pm_active); CPU_CLR_ATOMIC(hart, &oldpmap->pm_active); #else CPU_SET(hart, &pmap->pm_active); CPU_CLR(hart, &oldpmap->pm_active); #endif PCPU_SET(curpmap, pmap); sfence_vma(); } void pmap_activate(struct thread *td) { critical_enter(); pmap_activate_sw(td); critical_exit(); } void pmap_activate_boot(pmap_t pmap) { u_int hart; hart = PCPU_GET(hart); #ifdef SMP CPU_SET_ATOMIC(hart, &pmap->pm_active); #else CPU_SET(hart, &pmap->pm_active); #endif PCPU_SET(curpmap, pmap); } +void +pmap_active_cpus(pmap_t pmap, cpuset_t *res) +{ + *res = pmap->pm_active; +} + void pmap_sync_icache(pmap_t pmap, vm_offset_t va, vm_size_t sz) { cpuset_t mask; /* * From the RISC-V User-Level ISA V2.2: * * "To make a store to instruction memory visible to all * RISC-V harts, the writing hart has to execute a data FENCE * before requesting that all remote RISC-V harts execute a * FENCE.I." * * However, this is slightly misleading; we still need to * perform a FENCE.I for the local hart, as FENCE does nothing * for its icache. FENCE.I alone is also sufficient for the * local hart. */ sched_pin(); mask = all_harts; CPU_CLR(PCPU_GET(hart), &mask); fence_i(); if (!CPU_EMPTY(&mask) && smp_started) { fence(); sbi_remote_fence_i(mask.__bits); } sched_unpin(); } /* * Increase the starting virtual address of the given mapping if a * different alignment might result in more superpage mappings. */ void pmap_align_superpage(vm_object_t object, vm_ooffset_t offset, vm_offset_t *addr, vm_size_t size) { vm_offset_t superpage_offset; if (size < L2_SIZE) return; if (object != NULL && (object->flags & OBJ_COLORED) != 0) offset += ptoa(object->pg_color); superpage_offset = offset & L2_OFFSET; if (size - ((L2_SIZE - superpage_offset) & L2_OFFSET) < L2_SIZE || (*addr & L2_OFFSET) == superpage_offset) return; if ((*addr & L2_OFFSET) < superpage_offset) *addr = (*addr & ~L2_OFFSET) + superpage_offset; else *addr = ((*addr + L2_OFFSET) & ~L2_OFFSET) + superpage_offset; } /** * Get the kernel virtual address of a set of physical pages. If there are * physical addresses not covered by the DMAP perform a transient mapping * that will be removed when calling pmap_unmap_io_transient. * * \param page The pages the caller wishes to obtain the virtual * address on the kernel memory map. * \param vaddr On return contains the kernel virtual memory address * of the pages passed in the page parameter. * \param count Number of pages passed in. * \param can_fault true if the thread using the mapped pages can take * page faults, false otherwise. * * \returns true if the caller must call pmap_unmap_io_transient when * finished or false otherwise. * */ bool pmap_map_io_transient(vm_page_t page[], vm_offset_t vaddr[], int count, bool can_fault) { vm_paddr_t paddr; bool needs_mapping; int error __diagused, i; /* * Allocate any KVA space that we need, this is done in a separate * loop to prevent calling vmem_alloc while pinned. */ needs_mapping = false; for (i = 0; i < count; i++) { paddr = VM_PAGE_TO_PHYS(page[i]); if (__predict_false(paddr >= DMAP_MAX_PHYSADDR)) { error = vmem_alloc(kernel_arena, PAGE_SIZE, M_BESTFIT | M_WAITOK, &vaddr[i]); KASSERT(error == 0, ("vmem_alloc failed: %d", error)); needs_mapping = true; } else { vaddr[i] = PHYS_TO_DMAP(paddr); } } /* Exit early if everything is covered by the DMAP */ if (!needs_mapping) return (false); if (!can_fault) sched_pin(); for (i = 0; i < count; i++) { paddr = VM_PAGE_TO_PHYS(page[i]); if (paddr >= DMAP_MAX_PHYSADDR) { panic( "pmap_map_io_transient: TODO: Map out of DMAP data"); } } return (needs_mapping); } void pmap_unmap_io_transient(vm_page_t page[], vm_offset_t vaddr[], int count, bool can_fault) { vm_paddr_t paddr; int i; if (!can_fault) sched_unpin(); for (i = 0; i < count; i++) { paddr = VM_PAGE_TO_PHYS(page[i]); if (paddr >= DMAP_MAX_PHYSADDR) { panic("RISCVTODO: pmap_unmap_io_transient: Unmap data"); } } } boolean_t pmap_is_valid_memattr(pmap_t pmap __unused, vm_memattr_t mode) { return (mode >= VM_MEMATTR_DEVICE && mode <= VM_MEMATTR_WRITE_BACK); } bool pmap_get_tables(pmap_t pmap, vm_offset_t va, pd_entry_t **l1, pd_entry_t **l2, pt_entry_t **l3) { pd_entry_t *l1p, *l2p; /* Get l1 directory entry. */ l1p = pmap_l1(pmap, va); *l1 = l1p; if (l1p == NULL || (pmap_load(l1p) & PTE_V) == 0) return (false); if ((pmap_load(l1p) & PTE_RX) != 0) { *l2 = NULL; *l3 = NULL; return (true); } /* Get l2 directory entry. */ l2p = pmap_l1_to_l2(l1p, va); *l2 = l2p; if (l2p == NULL || (pmap_load(l2p) & PTE_V) == 0) return (false); if ((pmap_load(l2p) & PTE_RX) != 0) { *l3 = NULL; return (true); } /* Get l3 page table entry. */ *l3 = pmap_l2_to_l3(l2p, va); return (true); } /* * Track a range of the kernel's virtual address space that is contiguous * in various mapping attributes. */ struct pmap_kernel_map_range { vm_offset_t sva; pt_entry_t attrs; int l3pages; int l2pages; int l1pages; }; static void sysctl_kmaps_dump(struct sbuf *sb, struct pmap_kernel_map_range *range, vm_offset_t eva) { if (eva <= range->sva) return; sbuf_printf(sb, "0x%016lx-0x%016lx r%c%c%c%c %d %d %d\n", range->sva, eva, (range->attrs & PTE_W) == PTE_W ? 'w' : '-', (range->attrs & PTE_X) == PTE_X ? 'x' : '-', (range->attrs & PTE_U) == PTE_U ? 'u' : 's', (range->attrs & PTE_G) == PTE_G ? 'g' : '-', range->l1pages, range->l2pages, range->l3pages); /* Reset to sentinel value. */ range->sva = 0xfffffffffffffffful; } /* * Determine whether the attributes specified by a page table entry match those * being tracked by the current range. */ static bool sysctl_kmaps_match(struct pmap_kernel_map_range *range, pt_entry_t attrs) { return (range->attrs == attrs); } static void sysctl_kmaps_reinit(struct pmap_kernel_map_range *range, vm_offset_t va, pt_entry_t attrs) { memset(range, 0, sizeof(*range)); range->sva = va; range->attrs = attrs; } /* * Given a leaf PTE, derive the mapping's attributes. If they do not match * those of the current run, dump the address range and its attributes, and * begin a new run. */ static void sysctl_kmaps_check(struct sbuf *sb, struct pmap_kernel_map_range *range, vm_offset_t va, pd_entry_t l1e, pd_entry_t l2e, pt_entry_t l3e) { pt_entry_t attrs; /* The PTE global bit is inherited by lower levels. */ attrs = l1e & PTE_G; if ((l1e & PTE_RWX) != 0) attrs |= l1e & (PTE_RWX | PTE_U); else if (l2e != 0) attrs |= l2e & PTE_G; if ((l2e & PTE_RWX) != 0) attrs |= l2e & (PTE_RWX | PTE_U); else if (l3e != 0) attrs |= l3e & (PTE_RWX | PTE_U | PTE_G); if (range->sva > va || !sysctl_kmaps_match(range, attrs)) { sysctl_kmaps_dump(sb, range, va); sysctl_kmaps_reinit(range, va, attrs); } } static int sysctl_kmaps(SYSCTL_HANDLER_ARGS) { struct pmap_kernel_map_range range; struct sbuf sbuf, *sb; pd_entry_t l1e, *l2, l2e; pt_entry_t *l3, l3e; vm_offset_t sva; vm_paddr_t pa; int error, i, j, k; error = sysctl_wire_old_buffer(req, 0); if (error != 0) return (error); sb = &sbuf; sbuf_new_for_sysctl(sb, NULL, PAGE_SIZE, req); /* Sentinel value. */ range.sva = 0xfffffffffffffffful; /* * Iterate over the kernel page tables without holding the kernel pmap * lock. Kernel page table pages are never freed, so at worst we will * observe inconsistencies in the output. */ sva = VM_MIN_KERNEL_ADDRESS; for (i = pmap_l1_index(sva); i < Ln_ENTRIES; i++) { if (i == pmap_l1_index(DMAP_MIN_ADDRESS)) sbuf_printf(sb, "\nDirect map:\n"); else if (i == pmap_l1_index(VM_MIN_KERNEL_ADDRESS)) sbuf_printf(sb, "\nKernel map:\n"); l1e = kernel_pmap->pm_top[i]; if ((l1e & PTE_V) == 0) { sysctl_kmaps_dump(sb, &range, sva); sva += L1_SIZE; continue; } if ((l1e & PTE_RWX) != 0) { sysctl_kmaps_check(sb, &range, sva, l1e, 0, 0); range.l1pages++; sva += L1_SIZE; continue; } pa = PTE_TO_PHYS(l1e); l2 = (pd_entry_t *)PHYS_TO_DMAP(pa); for (j = pmap_l2_index(sva); j < Ln_ENTRIES; j++) { l2e = l2[j]; if ((l2e & PTE_V) == 0) { sysctl_kmaps_dump(sb, &range, sva); sva += L2_SIZE; continue; } if ((l2e & PTE_RWX) != 0) { sysctl_kmaps_check(sb, &range, sva, l1e, l2e, 0); range.l2pages++; sva += L2_SIZE; continue; } pa = PTE_TO_PHYS(l2e); l3 = (pd_entry_t *)PHYS_TO_DMAP(pa); for (k = pmap_l3_index(sva); k < Ln_ENTRIES; k++, sva += L3_SIZE) { l3e = l3[k]; if ((l3e & PTE_V) == 0) { sysctl_kmaps_dump(sb, &range, sva); continue; } sysctl_kmaps_check(sb, &range, sva, l1e, l2e, l3e); range.l3pages++; } } } error = sbuf_finish(sb); sbuf_delete(sb); return (error); } SYSCTL_OID(_vm_pmap, OID_AUTO, kernel_maps, CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE | CTLFLAG_SKIP, NULL, 0, sysctl_kmaps, "A", "Dump kernel address layout"); diff --git a/sys/vm/pmap.h b/sys/vm/pmap.h index 7272882132e0..65e909df9b8f 100644 --- a/sys/vm/pmap.h +++ b/sys/vm/pmap.h @@ -1,174 +1,176 @@ /*- * SPDX-License-Identifier: BSD-3-Clause * * Copyright (c) 1991, 1993 * The Regents of the University of California. All rights reserved. * * This code is derived from software contributed to Berkeley by * The Mach Operating System project at Carnegie-Mellon University. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * from: @(#)pmap.h 8.1 (Berkeley) 6/11/93 * * * Copyright (c) 1987, 1990 Carnegie-Mellon University. * All rights reserved. * * Author: Avadis Tevanian, Jr. * * Permission to use, copy, modify and distribute this software and * its documentation is hereby granted, provided that both the copyright * notice and this permission notice appear in all copies of the * software, derivative works or modified versions, and any portions * thereof, and that both notices appear in supporting documentation. * * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. * * Carnegie Mellon requests users of this software to return to * * Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU * School of Computer Science * Carnegie Mellon University * Pittsburgh PA 15213-3890 * * any improvements or extensions that they make and grant Carnegie the * rights to redistribute these changes. */ /* * Machine address mapping definitions -- machine-independent * section. [For machine-dependent section, see "machine/pmap.h".] */ #ifndef _PMAP_VM_ #define _PMAP_VM_ /* * Each machine dependent implementation is expected to * keep certain statistics. They may do this anyway they * so choose, but are expected to return the statistics * in the following structure. */ struct pmap_statistics { long resident_count; /* # of pages mapped (total) */ long wired_count; /* # of pages wired */ }; typedef struct pmap_statistics *pmap_statistics_t; /* * Each machine-dependent implementation is required to provide: * * vm_memattr_t pmap_page_get_memattr(vm_page_t); * boolean_t pmap_page_is_mapped(vm_page_t); * boolean_t pmap_page_is_write_mapped(vm_page_t); * void pmap_page_set_memattr(vm_page_t, vm_memattr_t); */ #include #ifdef _KERNEL +#include struct thread; /* * Updates to kernel_vm_end are synchronized by the kernel_map's system mutex. */ extern vm_offset_t kernel_vm_end; /* * Flags for pmap_enter(). The bits in the low-order byte are reserved * for the protection code (vm_prot_t) that describes the fault type. * Bits 24 through 31 are reserved for the pmap's internal use. */ #define PMAP_ENTER_NOSLEEP 0x00000100 #define PMAP_ENTER_WIRED 0x00000200 #define PMAP_ENTER_LARGEPAGE 0x00000400 #define PMAP_ENTER_RESERVED 0xFF000000 /* * Define the maximum number of machine-dependent reference bits that are * cleared by a call to pmap_ts_referenced(). This limit serves two purposes. * First, it bounds the cost of reference bit maintenance on widely shared * pages. Second, it prevents numeric overflow during maintenance of a * widely shared page's "act_count" field. An overflow could result in the * premature deactivation of the page. */ #define PMAP_TS_REFERENCED_MAX 5 void pmap_activate(struct thread *td); +void pmap_active_cpus(pmap_t pmap, cpuset_t *res); void pmap_advise(pmap_t pmap, vm_offset_t sva, vm_offset_t eva, int advice); void pmap_align_superpage(vm_object_t, vm_ooffset_t, vm_offset_t *, vm_size_t); void pmap_clear_modify(vm_page_t m); void pmap_copy(pmap_t, pmap_t, vm_offset_t, vm_size_t, vm_offset_t); void pmap_copy_page(vm_page_t, vm_page_t); void pmap_copy_pages(vm_page_t ma[], vm_offset_t a_offset, vm_page_t mb[], vm_offset_t b_offset, int xfersize); int pmap_enter(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot, u_int flags, int8_t psind); void pmap_enter_object(pmap_t pmap, vm_offset_t start, vm_offset_t end, vm_page_t m_start, vm_prot_t prot); void pmap_enter_quick(pmap_t pmap, vm_offset_t va, vm_page_t m, vm_prot_t prot); vm_paddr_t pmap_extract(pmap_t pmap, vm_offset_t va); vm_page_t pmap_extract_and_hold(pmap_t pmap, vm_offset_t va, vm_prot_t prot); void pmap_growkernel(vm_offset_t); void pmap_init(void); boolean_t pmap_is_modified(vm_page_t m); boolean_t pmap_is_prefaultable(pmap_t pmap, vm_offset_t va); boolean_t pmap_is_referenced(vm_page_t m); boolean_t pmap_is_valid_memattr(pmap_t, vm_memattr_t); vm_offset_t pmap_map(vm_offset_t *, vm_paddr_t, vm_paddr_t, int); int pmap_mincore(pmap_t pmap, vm_offset_t addr, vm_paddr_t *pap); void pmap_object_init_pt(pmap_t pmap, vm_offset_t addr, vm_object_t object, vm_pindex_t pindex, vm_size_t size); boolean_t pmap_page_exists_quick(pmap_t pmap, vm_page_t m); void pmap_page_init(vm_page_t m); int pmap_page_wired_mappings(vm_page_t m); int pmap_pinit(pmap_t); void pmap_pinit0(pmap_t); void pmap_protect(pmap_t, vm_offset_t, vm_offset_t, vm_prot_t); void pmap_qenter(vm_offset_t, vm_page_t *, int); void pmap_qremove(vm_offset_t, int); vm_offset_t pmap_quick_enter_page(vm_page_t); void pmap_quick_remove_page(vm_offset_t); void pmap_release(pmap_t); void pmap_remove(pmap_t, vm_offset_t, vm_offset_t); void pmap_remove_all(vm_page_t m); void pmap_remove_pages(pmap_t); void pmap_remove_write(vm_page_t m); void pmap_sync_icache(pmap_t, vm_offset_t, vm_size_t); int pmap_ts_referenced(vm_page_t m); void pmap_unwire(pmap_t pmap, vm_offset_t start, vm_offset_t end); void pmap_zero_page(vm_page_t); void pmap_zero_page_area(vm_page_t, int off, int size); #define pmap_resident_count(pm) ((pm)->pm_stats.resident_count) #define pmap_wired_count(pm) ((pm)->pm_stats.wired_count) #endif /* _KERNEL */ #endif /* _PMAP_VM_ */ diff --git a/sys/vm/vm_kern.c b/sys/vm/vm_kern.c index c3695b5c94eb..f94200d77c47 100644 --- a/sys/vm/vm_kern.c +++ b/sys/vm/vm_kern.c @@ -1,975 +1,1001 @@ /*- * SPDX-License-Identifier: (BSD-3-Clause AND MIT-CMU) * * Copyright (c) 1991, 1993 * The Regents of the University of California. All rights reserved. * * This code is derived from software contributed to Berkeley by * The Mach Operating System project at Carnegie-Mellon University. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * from: @(#)vm_kern.c 8.3 (Berkeley) 1/12/94 * * * Copyright (c) 1987, 1990 Carnegie-Mellon University. * All rights reserved. * * Authors: Avadis Tevanian, Jr., Michael Wayne Young * * Permission to use, copy, modify and distribute this software and * its documentation is hereby granted, provided that both the copyright * notice and this permission notice appear in all copies of the * software, derivative works or modified versions, and any portions * thereof, and that both notices appear in supporting documentation. * * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. * * Carnegie Mellon requests users of this software to return to * * Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU * School of Computer Science * Carnegie Mellon University * Pittsburgh PA 15213-3890 * * any improvements or extensions that they make and grant Carnegie the * rights to redistribute these changes. */ /* * Kernel memory management. */ #include #include "opt_vm.h" #include #include #include #include #include #include #include #include #include #include #include +#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include struct vm_map kernel_map_store; struct vm_map exec_map_store; struct vm_map pipe_map_store; const void *zero_region; CTASSERT((ZERO_REGION_SIZE & PAGE_MASK) == 0); /* NB: Used by kernel debuggers. */ const u_long vm_maxuser_address = VM_MAXUSER_ADDRESS; u_int exec_map_entry_size; u_int exec_map_entries; SYSCTL_ULONG(_vm, OID_AUTO, min_kernel_address, CTLFLAG_RD, SYSCTL_NULL_ULONG_PTR, VM_MIN_KERNEL_ADDRESS, "Min kernel address"); SYSCTL_ULONG(_vm, OID_AUTO, max_kernel_address, CTLFLAG_RD, #if defined(__arm__) &vm_max_kernel_address, 0, #else SYSCTL_NULL_ULONG_PTR, VM_MAX_KERNEL_ADDRESS, #endif "Max kernel address"); #if VM_NRESERVLEVEL > 0 #define KVA_QUANTUM_SHIFT (VM_LEVEL_0_ORDER + PAGE_SHIFT) #else /* On non-superpage architectures we want large import sizes. */ #define KVA_QUANTUM_SHIFT (8 + PAGE_SHIFT) #endif #define KVA_QUANTUM (1ul << KVA_QUANTUM_SHIFT) #define KVA_NUMA_IMPORT_QUANTUM (KVA_QUANTUM * 128) extern void uma_startup2(void); /* * kva_alloc: * * Allocate a virtual address range with no underlying object and * no initial mapping to physical memory. Any mapping from this * range to physical memory must be explicitly created prior to * its use, typically with pmap_qenter(). Any attempt to create * a mapping on demand through vm_fault() will result in a panic. */ vm_offset_t kva_alloc(vm_size_t size) { vm_offset_t addr; TSENTER(); size = round_page(size); if (vmem_alloc(kernel_arena, size, M_BESTFIT | M_NOWAIT, &addr)) return (0); TSEXIT(); return (addr); } /* * kva_free: * * Release a region of kernel virtual memory allocated * with kva_alloc, and return the physical pages * associated with that region. * * This routine may not block on kernel maps. */ void kva_free(vm_offset_t addr, vm_size_t size) { size = round_page(size); vmem_free(kernel_arena, addr, size); } /* * Update sanitizer shadow state to reflect a new allocation. Force inlining to * help make KMSAN origin tracking more precise. */ static __always_inline void kmem_alloc_san(vm_offset_t addr, vm_size_t size, vm_size_t asize, int flags) { if ((flags & M_ZERO) == 0) { kmsan_mark((void *)addr, asize, KMSAN_STATE_UNINIT); kmsan_orig((void *)addr, asize, KMSAN_TYPE_KMEM, KMSAN_RET_ADDR); } else { kmsan_mark((void *)addr, asize, KMSAN_STATE_INITED); } kasan_mark((void *)addr, size, asize, KASAN_KMEM_REDZONE); } static vm_page_t kmem_alloc_contig_pages(vm_object_t object, vm_pindex_t pindex, int domain, int pflags, u_long npages, vm_paddr_t low, vm_paddr_t high, u_long alignment, vm_paddr_t boundary, vm_memattr_t memattr) { vm_page_t m; int tries; bool wait, reclaim; VM_OBJECT_ASSERT_WLOCKED(object); wait = (pflags & VM_ALLOC_WAITOK) != 0; reclaim = (pflags & VM_ALLOC_NORECLAIM) == 0; pflags &= ~(VM_ALLOC_NOWAIT | VM_ALLOC_WAITOK | VM_ALLOC_WAITFAIL); pflags |= VM_ALLOC_NOWAIT; for (tries = wait ? 3 : 1;; tries--) { m = vm_page_alloc_contig_domain(object, pindex, domain, pflags, npages, low, high, alignment, boundary, memattr); if (m != NULL || tries == 0 || !reclaim) break; VM_OBJECT_WUNLOCK(object); if (!vm_page_reclaim_contig_domain(domain, pflags, npages, low, high, alignment, boundary) && wait) vm_wait_domain(domain); VM_OBJECT_WLOCK(object); } return (m); } /* * Allocates a region from the kernel address map and physical pages * within the specified address range to the kernel object. Creates a * wired mapping from this region to these pages, and returns the * region's starting virtual address. The allocated pages are not * necessarily physically contiguous. If M_ZERO is specified through the * given flags, then the pages are zeroed before they are mapped. */ static void * kmem_alloc_attr_domain(int domain, vm_size_t size, int flags, vm_paddr_t low, vm_paddr_t high, vm_memattr_t memattr) { vmem_t *vmem; vm_object_t object; vm_offset_t addr, i, offset; vm_page_t m; vm_size_t asize; int pflags; vm_prot_t prot; object = kernel_object; asize = round_page(size); vmem = vm_dom[domain].vmd_kernel_arena; if (vmem_alloc(vmem, asize, M_BESTFIT | flags, &addr)) return (0); offset = addr - VM_MIN_KERNEL_ADDRESS; pflags = malloc2vm_flags(flags) | VM_ALLOC_WIRED; prot = (flags & M_EXEC) != 0 ? VM_PROT_ALL : VM_PROT_RW; VM_OBJECT_WLOCK(object); for (i = 0; i < asize; i += PAGE_SIZE) { m = kmem_alloc_contig_pages(object, atop(offset + i), domain, pflags, 1, low, high, PAGE_SIZE, 0, memattr); if (m == NULL) { VM_OBJECT_WUNLOCK(object); kmem_unback(object, addr, i); vmem_free(vmem, addr, asize); return (0); } KASSERT(vm_page_domain(m) == domain, ("kmem_alloc_attr_domain: Domain mismatch %d != %d", vm_page_domain(m), domain)); if ((flags & M_ZERO) && (m->flags & PG_ZERO) == 0) pmap_zero_page(m); vm_page_valid(m); pmap_enter(kernel_pmap, addr + i, m, prot, prot | PMAP_ENTER_WIRED, 0); } VM_OBJECT_WUNLOCK(object); kmem_alloc_san(addr, size, asize, flags); return ((void *)addr); } void * kmem_alloc_attr(vm_size_t size, int flags, vm_paddr_t low, vm_paddr_t high, vm_memattr_t memattr) { return (kmem_alloc_attr_domainset(DOMAINSET_RR(), size, flags, low, high, memattr)); } void * kmem_alloc_attr_domainset(struct domainset *ds, vm_size_t size, int flags, vm_paddr_t low, vm_paddr_t high, vm_memattr_t memattr) { struct vm_domainset_iter di; void *addr; int domain; vm_domainset_iter_policy_init(&di, ds, &domain, &flags); do { addr = kmem_alloc_attr_domain(domain, size, flags, low, high, memattr); if (addr != NULL) break; } while (vm_domainset_iter_policy(&di, &domain) == 0); return (addr); } /* * Allocates a region from the kernel address map and physically * contiguous pages within the specified address range to the kernel * object. Creates a wired mapping from this region to these pages, and * returns the region's starting virtual address. If M_ZERO is specified * through the given flags, then the pages are zeroed before they are * mapped. */ static void * kmem_alloc_contig_domain(int domain, vm_size_t size, int flags, vm_paddr_t low, vm_paddr_t high, u_long alignment, vm_paddr_t boundary, vm_memattr_t memattr) { vmem_t *vmem; vm_object_t object; vm_offset_t addr, offset, tmp; vm_page_t end_m, m; vm_size_t asize; u_long npages; int pflags; object = kernel_object; asize = round_page(size); vmem = vm_dom[domain].vmd_kernel_arena; if (vmem_alloc(vmem, asize, flags | M_BESTFIT, &addr)) return (NULL); offset = addr - VM_MIN_KERNEL_ADDRESS; pflags = malloc2vm_flags(flags) | VM_ALLOC_WIRED; npages = atop(asize); VM_OBJECT_WLOCK(object); m = kmem_alloc_contig_pages(object, atop(offset), domain, pflags, npages, low, high, alignment, boundary, memattr); if (m == NULL) { VM_OBJECT_WUNLOCK(object); vmem_free(vmem, addr, asize); return (NULL); } KASSERT(vm_page_domain(m) == domain, ("kmem_alloc_contig_domain: Domain mismatch %d != %d", vm_page_domain(m), domain)); end_m = m + npages; tmp = addr; for (; m < end_m; m++) { if ((flags & M_ZERO) && (m->flags & PG_ZERO) == 0) pmap_zero_page(m); vm_page_valid(m); pmap_enter(kernel_pmap, tmp, m, VM_PROT_RW, VM_PROT_RW | PMAP_ENTER_WIRED, 0); tmp += PAGE_SIZE; } VM_OBJECT_WUNLOCK(object); kmem_alloc_san(addr, size, asize, flags); return ((void *)addr); } void * kmem_alloc_contig(vm_size_t size, int flags, vm_paddr_t low, vm_paddr_t high, u_long alignment, vm_paddr_t boundary, vm_memattr_t memattr) { return (kmem_alloc_contig_domainset(DOMAINSET_RR(), size, flags, low, high, alignment, boundary, memattr)); } void * kmem_alloc_contig_domainset(struct domainset *ds, vm_size_t size, int flags, vm_paddr_t low, vm_paddr_t high, u_long alignment, vm_paddr_t boundary, vm_memattr_t memattr) { struct vm_domainset_iter di; void *addr; int domain; vm_domainset_iter_policy_init(&di, ds, &domain, &flags); do { addr = kmem_alloc_contig_domain(domain, size, flags, low, high, alignment, boundary, memattr); if (addr != NULL) break; } while (vm_domainset_iter_policy(&di, &domain) == 0); return (addr); } /* * kmem_subinit: * * Initializes a map to manage a subrange * of the kernel virtual address space. * * Arguments are as follows: * * parent Map to take range from * min, max Returned endpoints of map * size Size of range to find * superpage_align Request that min is superpage aligned */ void kmem_subinit(vm_map_t map, vm_map_t parent, vm_offset_t *min, vm_offset_t *max, vm_size_t size, bool superpage_align) { int ret; size = round_page(size); *min = vm_map_min(parent); ret = vm_map_find(parent, NULL, 0, min, size, 0, superpage_align ? VMFS_SUPER_SPACE : VMFS_ANY_SPACE, VM_PROT_ALL, VM_PROT_ALL, MAP_ACC_NO_CHARGE); if (ret != KERN_SUCCESS) panic("kmem_subinit: bad status return of %d", ret); *max = *min + size; vm_map_init(map, vm_map_pmap(parent), *min, *max); if (vm_map_submap(parent, *min, *max, map) != KERN_SUCCESS) panic("kmem_subinit: unable to change range to submap"); } /* * kmem_malloc_domain: * * Allocate wired-down pages in the kernel's address space. */ static void * kmem_malloc_domain(int domain, vm_size_t size, int flags) { vmem_t *arena; vm_offset_t addr; vm_size_t asize; int rv; if (__predict_true((flags & M_EXEC) == 0)) arena = vm_dom[domain].vmd_kernel_arena; else arena = vm_dom[domain].vmd_kernel_rwx_arena; asize = round_page(size); if (vmem_alloc(arena, asize, flags | M_BESTFIT, &addr)) return (0); rv = kmem_back_domain(domain, kernel_object, addr, asize, flags); if (rv != KERN_SUCCESS) { vmem_free(arena, addr, asize); return (0); } kasan_mark((void *)addr, size, asize, KASAN_KMEM_REDZONE); return ((void *)addr); } void * kmem_malloc(vm_size_t size, int flags) { void * p; TSENTER(); p = kmem_malloc_domainset(DOMAINSET_RR(), size, flags); TSEXIT(); return (p); } void * kmem_malloc_domainset(struct domainset *ds, vm_size_t size, int flags) { struct vm_domainset_iter di; void *addr; int domain; vm_domainset_iter_policy_init(&di, ds, &domain, &flags); do { addr = kmem_malloc_domain(domain, size, flags); if (addr != NULL) break; } while (vm_domainset_iter_policy(&di, &domain) == 0); return (addr); } /* * kmem_back_domain: * * Allocate physical pages from the specified domain for the specified * virtual address range. */ int kmem_back_domain(int domain, vm_object_t object, vm_offset_t addr, vm_size_t size, int flags) { vm_offset_t offset, i; vm_page_t m, mpred; vm_prot_t prot; int pflags; KASSERT(object == kernel_object, ("kmem_back_domain: only supports kernel object.")); offset = addr - VM_MIN_KERNEL_ADDRESS; pflags = malloc2vm_flags(flags) | VM_ALLOC_WIRED; pflags &= ~(VM_ALLOC_NOWAIT | VM_ALLOC_WAITOK | VM_ALLOC_WAITFAIL); if (flags & M_WAITOK) pflags |= VM_ALLOC_WAITFAIL; prot = (flags & M_EXEC) != 0 ? VM_PROT_ALL : VM_PROT_RW; i = 0; VM_OBJECT_WLOCK(object); retry: mpred = vm_radix_lookup_le(&object->rtree, atop(offset + i)); for (; i < size; i += PAGE_SIZE, mpred = m) { m = vm_page_alloc_domain_after(object, atop(offset + i), domain, pflags, mpred); /* * Ran out of space, free everything up and return. Don't need * to lock page queues here as we know that the pages we got * aren't on any queues. */ if (m == NULL) { if ((flags & M_NOWAIT) == 0) goto retry; VM_OBJECT_WUNLOCK(object); kmem_unback(object, addr, i); return (KERN_NO_SPACE); } KASSERT(vm_page_domain(m) == domain, ("kmem_back_domain: Domain mismatch %d != %d", vm_page_domain(m), domain)); if (flags & M_ZERO && (m->flags & PG_ZERO) == 0) pmap_zero_page(m); KASSERT((m->oflags & VPO_UNMANAGED) != 0, ("kmem_malloc: page %p is managed", m)); vm_page_valid(m); pmap_enter(kernel_pmap, addr + i, m, prot, prot | PMAP_ENTER_WIRED, 0); if (__predict_false((prot & VM_PROT_EXECUTE) != 0)) m->oflags |= VPO_KMEM_EXEC; } VM_OBJECT_WUNLOCK(object); kmem_alloc_san(addr, size, size, flags); return (KERN_SUCCESS); } /* * kmem_back: * * Allocate physical pages for the specified virtual address range. */ int kmem_back(vm_object_t object, vm_offset_t addr, vm_size_t size, int flags) { vm_offset_t end, next, start; int domain, rv; KASSERT(object == kernel_object, ("kmem_back: only supports kernel object.")); for (start = addr, end = addr + size; addr < end; addr = next) { /* * We must ensure that pages backing a given large virtual page * all come from the same physical domain. */ if (vm_ndomains > 1) { domain = (addr >> KVA_QUANTUM_SHIFT) % vm_ndomains; while (VM_DOMAIN_EMPTY(domain)) domain++; next = roundup2(addr + 1, KVA_QUANTUM); if (next > end || next < start) next = end; } else { domain = 0; next = end; } rv = kmem_back_domain(domain, object, addr, next - addr, flags); if (rv != KERN_SUCCESS) { kmem_unback(object, start, addr - start); break; } } return (rv); } /* * kmem_unback: * * Unmap and free the physical pages underlying the specified virtual * address range. * * A physical page must exist within the specified object at each index * that is being unmapped. */ static struct vmem * _kmem_unback(vm_object_t object, vm_offset_t addr, vm_size_t size) { struct vmem *arena; vm_page_t m, next; vm_offset_t end, offset; int domain; KASSERT(object == kernel_object, ("kmem_unback: only supports kernel object.")); if (size == 0) return (NULL); pmap_remove(kernel_pmap, addr, addr + size); offset = addr - VM_MIN_KERNEL_ADDRESS; end = offset + size; VM_OBJECT_WLOCK(object); m = vm_page_lookup(object, atop(offset)); domain = vm_page_domain(m); if (__predict_true((m->oflags & VPO_KMEM_EXEC) == 0)) arena = vm_dom[domain].vmd_kernel_arena; else arena = vm_dom[domain].vmd_kernel_rwx_arena; for (; offset < end; offset += PAGE_SIZE, m = next) { next = vm_page_next(m); vm_page_xbusy_claim(m); vm_page_unwire_noq(m); vm_page_free(m); } VM_OBJECT_WUNLOCK(object); return (arena); } void kmem_unback(vm_object_t object, vm_offset_t addr, vm_size_t size) { (void)_kmem_unback(object, addr, size); } /* * kmem_free: * * Free memory allocated with kmem_malloc. The size must match the * original allocation. */ void kmem_free(void *addr, vm_size_t size) { struct vmem *arena; size = round_page(size); kasan_mark(addr, size, size, 0); arena = _kmem_unback(kernel_object, (uintptr_t)addr, size); if (arena != NULL) vmem_free(arena, (uintptr_t)addr, size); } /* * kmap_alloc_wait: * * Allocates pageable memory from a sub-map of the kernel. If the submap * has no room, the caller sleeps waiting for more memory in the submap. * * This routine may block. */ vm_offset_t kmap_alloc_wait(vm_map_t map, vm_size_t size) { vm_offset_t addr; size = round_page(size); if (!swap_reserve(size)) return (0); for (;;) { /* * To make this work for more than one map, use the map's lock * to lock out sleepers/wakers. */ vm_map_lock(map); addr = vm_map_findspace(map, vm_map_min(map), size); if (addr + size <= vm_map_max(map)) break; /* no space now; see if we can ever get space */ if (vm_map_max(map) - vm_map_min(map) < size) { vm_map_unlock(map); swap_release(size); return (0); } map->needs_wakeup = TRUE; vm_map_unlock_and_wait(map, 0); } vm_map_insert(map, NULL, 0, addr, addr + size, VM_PROT_RW, VM_PROT_RW, MAP_ACC_CHARGED); vm_map_unlock(map); return (addr); } /* * kmap_free_wakeup: * * Returns memory to a submap of the kernel, and wakes up any processes * waiting for memory in that map. */ void kmap_free_wakeup(vm_map_t map, vm_offset_t addr, vm_size_t size) { vm_map_lock(map); (void) vm_map_delete(map, trunc_page(addr), round_page(addr + size)); if (map->needs_wakeup) { map->needs_wakeup = FALSE; vm_map_wakeup(map); } vm_map_unlock(map); } void kmem_init_zero_region(void) { vm_offset_t addr, i; vm_page_t m; /* * Map a single physical page of zeros to a larger virtual range. * This requires less looping in places that want large amounts of * zeros, while not using much more physical resources. */ addr = kva_alloc(ZERO_REGION_SIZE); m = vm_page_alloc_noobj(VM_ALLOC_WIRED | VM_ALLOC_ZERO); for (i = 0; i < ZERO_REGION_SIZE; i += PAGE_SIZE) pmap_qenter(addr + i, &m, 1); pmap_protect(kernel_pmap, addr, addr + ZERO_REGION_SIZE, VM_PROT_READ); zero_region = (const void *)addr; } /* * Import KVA from the kernel map into the kernel arena. */ static int kva_import(void *unused, vmem_size_t size, int flags, vmem_addr_t *addrp) { vm_offset_t addr; int result; TSENTER(); KASSERT((size % KVA_QUANTUM) == 0, ("kva_import: Size %jd is not a multiple of %d", (intmax_t)size, (int)KVA_QUANTUM)); addr = vm_map_min(kernel_map); result = vm_map_find(kernel_map, NULL, 0, &addr, size, 0, VMFS_SUPER_SPACE, VM_PROT_ALL, VM_PROT_ALL, MAP_NOFAULT); if (result != KERN_SUCCESS) { TSEXIT(); return (ENOMEM); } *addrp = addr; TSEXIT(); return (0); } /* * Import KVA from a parent arena into a per-domain arena. Imports must be * KVA_QUANTUM-aligned and a multiple of KVA_QUANTUM in size. */ static int kva_import_domain(void *arena, vmem_size_t size, int flags, vmem_addr_t *addrp) { KASSERT((size % KVA_QUANTUM) == 0, ("kva_import_domain: Size %jd is not a multiple of %d", (intmax_t)size, (int)KVA_QUANTUM)); return (vmem_xalloc(arena, size, KVA_QUANTUM, 0, 0, VMEM_ADDR_MIN, VMEM_ADDR_MAX, flags, addrp)); } /* * kmem_init: * * Create the kernel map; insert a mapping covering kernel text, * data, bss, and all space allocated thus far (`boostrap' data). The * new map will thus map the range between VM_MIN_KERNEL_ADDRESS and * `start' as allocated, and the range between `start' and `end' as free. * Create the kernel vmem arena and its per-domain children. */ void kmem_init(vm_offset_t start, vm_offset_t end) { vm_size_t quantum; int domain; vm_map_init(kernel_map, kernel_pmap, VM_MIN_KERNEL_ADDRESS, end); kernel_map->system_map = 1; vm_map_lock(kernel_map); /* N.B.: cannot use kgdb to debug, starting with this assignment ... */ (void)vm_map_insert(kernel_map, NULL, 0, #ifdef __amd64__ KERNBASE, #else VM_MIN_KERNEL_ADDRESS, #endif start, VM_PROT_ALL, VM_PROT_ALL, MAP_NOFAULT); /* ... and ending with the completion of the above `insert' */ #ifdef __amd64__ /* * Mark KVA used for the page array as allocated. Other platforms * that handle vm_page_array allocation can simply adjust virtual_avail * instead. */ (void)vm_map_insert(kernel_map, NULL, 0, (vm_offset_t)vm_page_array, (vm_offset_t)vm_page_array + round_2mpage(vm_page_array_size * sizeof(struct vm_page)), VM_PROT_RW, VM_PROT_RW, MAP_NOFAULT); #endif vm_map_unlock(kernel_map); /* * Use a large import quantum on NUMA systems. This helps minimize * interleaving of superpages, reducing internal fragmentation within * the per-domain arenas. */ if (vm_ndomains > 1 && PMAP_HAS_DMAP) quantum = KVA_NUMA_IMPORT_QUANTUM; else quantum = KVA_QUANTUM; /* * Initialize the kernel_arena. This can grow on demand. */ vmem_init(kernel_arena, "kernel arena", 0, 0, PAGE_SIZE, 0, 0); vmem_set_import(kernel_arena, kva_import, NULL, NULL, quantum); for (domain = 0; domain < vm_ndomains; domain++) { /* * Initialize the per-domain arenas. These are used to color * the KVA space in a way that ensures that virtual large pages * are backed by memory from the same physical domain, * maximizing the potential for superpage promotion. */ vm_dom[domain].vmd_kernel_arena = vmem_create( "kernel arena domain", 0, 0, PAGE_SIZE, 0, M_WAITOK); vmem_set_import(vm_dom[domain].vmd_kernel_arena, kva_import_domain, NULL, kernel_arena, quantum); /* * In architectures with superpages, maintain separate arenas * for allocations with permissions that differ from the * "standard" read/write permissions used for kernel memory, * so as not to inhibit superpage promotion. * * Use the base import quantum since this arena is rarely used. */ #if VM_NRESERVLEVEL > 0 vm_dom[domain].vmd_kernel_rwx_arena = vmem_create( "kernel rwx arena domain", 0, 0, PAGE_SIZE, 0, M_WAITOK); vmem_set_import(vm_dom[domain].vmd_kernel_rwx_arena, kva_import_domain, (vmem_release_t *)vmem_xfree, kernel_arena, KVA_QUANTUM); #else vm_dom[domain].vmd_kernel_rwx_arena = vm_dom[domain].vmd_kernel_arena; #endif } /* * This must be the very first call so that the virtual address * space used for early allocations is properly marked used in * the map. */ uma_startup2(); } /* * kmem_bootstrap_free: * * Free pages backing preloaded data (e.g., kernel modules) to the * system. Currently only supported on platforms that create a * vm_phys segment for preloaded data. */ void kmem_bootstrap_free(vm_offset_t start, vm_size_t size) { #if defined(__i386__) || defined(__amd64__) struct vm_domain *vmd; vm_offset_t end, va; vm_paddr_t pa; vm_page_t m; end = trunc_page(start + size); start = round_page(start); #ifdef __amd64__ /* * Preloaded files do not have execute permissions by default on amd64. * Restore the default permissions to ensure that the direct map alias * is updated. */ pmap_change_prot(start, end - start, VM_PROT_RW); #endif for (va = start; va < end; va += PAGE_SIZE) { pa = pmap_kextract(va); m = PHYS_TO_VM_PAGE(pa); vmd = vm_pagequeue_domain(m); vm_domain_free_lock(vmd); vm_phys_free_pages(m, 0); vm_domain_free_unlock(vmd); vm_domain_freecnt_inc(vmd, 1); vm_cnt.v_page_count++; } pmap_remove(kernel_pmap, start, end); (void)vmem_add(kernel_arena, start, end - start, M_WAITOK); #endif } +#ifdef PMAP_WANT_ACTIVE_CPUS_NAIVE +void +pmap_active_cpus(pmap_t pmap, cpuset_t *res) +{ + struct thread *td; + struct proc *p; + struct vmspace *vm; + int c; + + CPU_ZERO(res); + CPU_FOREACH(c) { + td = cpuid_to_pcpu[c]->pc_curthread; + p = td->td_proc; + if (p == NULL) + continue; + vm = vmspace_acquire_ref(p); + if (vm == NULL) + continue; + if (pmap == vmspace_pmap(vm)) + CPU_SET(c, res); + vmspace_free(vm); + } +} +#endif + /* * Allow userspace to directly trigger the VM drain routine for testing * purposes. */ static int debug_vm_lowmem(SYSCTL_HANDLER_ARGS) { int error, i; i = 0; error = sysctl_handle_int(oidp, &i, 0, req); if (error != 0) return (error); if ((i & ~(VM_LOW_KMEM | VM_LOW_PAGES)) != 0) return (EINVAL); if (i != 0) EVENTHANDLER_INVOKE(vm_lowmem, i); return (0); } SYSCTL_PROC(_debug, OID_AUTO, vm_lowmem, CTLTYPE_INT | CTLFLAG_MPSAFE | CTLFLAG_RW, 0, 0, debug_vm_lowmem, "I", "set to trigger vm_lowmem event with given flags"); static int debug_uma_reclaim(SYSCTL_HANDLER_ARGS) { int error, i; i = 0; error = sysctl_handle_int(oidp, &i, 0, req); if (error != 0 || req->newptr == NULL) return (error); if (i != UMA_RECLAIM_TRIM && i != UMA_RECLAIM_DRAIN && i != UMA_RECLAIM_DRAIN_CPU) return (EINVAL); uma_reclaim(i); return (0); } SYSCTL_PROC(_debug, OID_AUTO, uma_reclaim, CTLTYPE_INT | CTLFLAG_MPSAFE | CTLFLAG_RW, 0, 0, debug_uma_reclaim, "I", "set to generate request to reclaim uma caches"); static int debug_uma_reclaim_domain(SYSCTL_HANDLER_ARGS) { int domain, error, request; request = 0; error = sysctl_handle_int(oidp, &request, 0, req); if (error != 0 || req->newptr == NULL) return (error); domain = request >> 4; request &= 0xf; if (request != UMA_RECLAIM_TRIM && request != UMA_RECLAIM_DRAIN && request != UMA_RECLAIM_DRAIN_CPU) return (EINVAL); if (domain < 0 || domain >= vm_ndomains) return (EINVAL); uma_reclaim_domain(request, domain); return (0); } SYSCTL_PROC(_debug, OID_AUTO, uma_reclaim_domain, CTLTYPE_INT | CTLFLAG_MPSAFE | CTLFLAG_RW, 0, 0, debug_uma_reclaim_domain, "I", "");