diff --git a/sys/riscv/riscv/pmap.c b/sys/riscv/riscv/pmap.c index 4baa4948e442..69eb36c2cd4c 100644 --- a/sys/riscv/riscv/pmap.c +++ b/sys/riscv/riscv/pmap.c @@ -1,5488 +1,5488 @@ /*- * 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. */ /*- * 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. */ /* * 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_pmap.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 #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) #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. */ CTASSERT((PMAP_MAPDEV_EARLY_SIZE & L2_OFFSET) == 0); static struct rwlock_padalign pvh_global_lock; static struct mtx_padalign allpmaps_lock; static int __read_frequently 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"); static SYSCTL_NODE(_vm_pmap, OID_AUTO, l1, CTLFLAG_RD | CTLFLAG_MPSAFE, 0, "L1 (1GB) page mapping counters"); static COUNTER_U64_DEFINE_EARLY(pmap_l1_demotions); SYSCTL_COUNTER_U64(_vm_pmap_l1, OID_AUTO, demotions, CTLFLAG_RD, &pmap_l1_demotions, "L1 (1GB) page demotions"); /* * 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_l1(pmap_t pmap, pd_entry_t *l1, 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 bool 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); static uint64_t pmap_satp_mode(void); #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) #define L1PTE_TO_PHYS(l1) \ ((((l1) & ~PTE_HI_MASK) >> PTE_PPN2_S) << L1_SHIFT) #define PTE_TO_VM_PAGE(pte) PHYS_TO_VM_PAGE(PTE_TO_PHYS(pte)) /* * Construct a page table entry of the specified level pointing to physical * address pa, with PTE bits 'bits'. * * A leaf PTE of any level must point to an address matching its alignment, * e.g. L2 pages must be 2MB aligned in memory. */ #define L1_PTE(pa, bits) ((((pa) >> L1_SHIFT) << PTE_PPN2_S) | (bits)) #define L2_PTE(pa, bits) ((((pa) >> L2_SHIFT) << PTE_PPN1_S) | (bits)) #define L3_PTE(pa, bits) ((((pa) >> L3_SHIFT) << PTE_PPN0_S) | (bits)) /* * Construct a page directory entry (PDE), pointing to next level entry at pa, * with PTE bits 'bits'. * * Unlike PTEs, page directory entries can point to any 4K-aligned physical * address. */ #define L0_PDE(pa, bits) L3_PTE(pa, bits) #define L1_PDE(pa, bits) L3_PTE(pa, bits) #define L2_PDE(pa, bits) L3_PTE(pa, bits) 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); } /* * Holds the PTE mode bits (defined in pte.h) for defining e.g. cacheability. * * The indices correspond to the VM_MEMATTR_* defines in riscv/include/vm.h. * * The array will be empty if no mode bits are supported by the CPU, e.g. when * lacking the Svpbmt extension. */ static __read_frequently pt_entry_t memattr_bits[VM_MEMATTR_TOTAL]; static __read_frequently pt_entry_t memattr_mask; static __inline pt_entry_t pmap_memattr_bits(vm_memattr_t mode) { KASSERT(pmap_is_valid_memattr(kernel_pmap, mode), ("invalid memory mode %u\n", mode)); return (memattr_bits[(int)mode]); } /* * This should only be used during pmap bootstrap e.g. by * pmap_create_pagetables(). */ static pt_entry_t * pmap_early_alloc_tables(vm_paddr_t *freemempos, int npages) { pt_entry_t *pt; pt = (pt_entry_t *)*freemempos; *freemempos += npages * PAGE_SIZE; bzero(pt, npages * PAGE_SIZE); return (pt); } /* * Construct the direct map -- a linear mapping of physical memory into * the kernel address space. * * We walk the list of physical memory segments (of arbitrary size and * address) mapping each appropriately using L2 and L1 superpages. * Consequently, the DMAP address space will have unmapped regions * corresponding to any holes between physical memory segments. * * The lowest usable physical address will always be mapped to * DMAP_MIN_ADDRESS. */ static vm_paddr_t pmap_bootstrap_dmap(pd_entry_t *l1, vm_paddr_t freemempos) { vm_paddr_t physmap[PHYS_AVAIL_ENTRIES]; vm_offset_t va; vm_paddr_t min_pa, max_pa, pa, endpa; pd_entry_t *l2; pt_entry_t memattr; u_int l1slot, l2slot; int physmap_idx; physmap_idx = physmem_avail(physmap, nitems(physmap)); min_pa = physmap[0]; max_pa = physmap[physmap_idx - 1]; printf("physmap_idx %u\n", physmap_idx); printf("min_pa %lx\n", min_pa); printf("max_pa %lx\n", max_pa); /* Set the limits of the DMAP region. */ dmap_phys_base = rounddown(min_pa, L1_SIZE); dmap_phys_max = max_pa; memattr = pmap_memattr_bits(VM_MEMATTR_DEFAULT); /* Walk the physmap table. */ l2 = NULL; l1slot = Ln_ENTRIES; /* sentinel value */ for (int idx = 0; idx < physmap_idx; idx += 2) { pa = rounddown(physmap[idx], L2_SIZE); endpa = physmap[idx + 1]; /* Virtual address for this range. */ va = PHYS_TO_DMAP(pa); /* Any 1GB possible for this range? */ if (roundup(pa, L1_SIZE) + L1_SIZE > endpa) goto l2end; /* Loop until the next 1GB boundary. */ while ((pa & L1_OFFSET) != 0) { if (l2 == NULL || pmap_l1_index(va) != l1slot) { /* Need to alloc another page table. */ l2 = pmap_early_alloc_tables(&freemempos, 1); /* Link it. */ l1slot = pmap_l1_index(va); pmap_store(&l1[l1slot], L1_PDE((vm_paddr_t)l2, PTE_V)); } /* map l2 pages */ l2slot = pmap_l2_index(va); pmap_store(&l2[l2slot], L2_PTE(pa, PTE_KERN | memattr)); pa += L2_SIZE; va += L2_SIZE; } /* Map what we can with 1GB superpages. */ while (pa + L1_SIZE - 1 < endpa) { /* map l1 pages */ l1slot = pmap_l1_index(va); pmap_store(&l1[l1slot], L1_PTE(pa, PTE_KERN | memattr)); pa += L1_SIZE; va += L1_SIZE; } l2end: while (pa < endpa) { if (l2 == NULL || pmap_l1_index(va) != l1slot) { /* Need to alloc another page table. */ l2 = pmap_early_alloc_tables(&freemempos, 1); /* Link it. */ l1slot = pmap_l1_index(va); pmap_store(&l1[l1slot], L1_PDE((vm_paddr_t)l2, PTE_V)); } /* map l2 pages */ l2slot = pmap_l2_index(va); pmap_store(&l2[l2slot], L2_PTE(pa, PTE_KERN | memattr)); pa += L2_SIZE; va += L2_SIZE; } } /* And finally, the limit on DMAP VA. */ dmap_max_addr = va; return (freemempos); } /* * Create a new set of pagetables to run the kernel with. * * An initial, temporary setup was created in locore.S, which serves well * enough to get us this far. It mapped kernstart -> KERNBASE, using 2MB * superpages, and created a 1GB identity map, which allows this function * to dereference physical addresses. * * The memory backing these page tables is allocated in the space * immediately following the kernel's preload area. Depending on the size * of this area, some, all, or none of these pages can be implicitly * mapped by the kernel's 2MB mappings. This memory will only ever be * accessed through the direct map, however. */ static vm_paddr_t pmap_create_pagetables(vm_paddr_t kernstart, vm_size_t kernlen, vm_paddr_t *root_pt_phys) { pt_entry_t *l0, *l1, *kern_l2, *kern_l3, *devmap_l3; pt_entry_t memattr; pd_entry_t *devmap_l2; vm_paddr_t kernend, freemempos, pa; int nkernl2, nkernl3, ndevmapl3; int i, slot; int mode; kernend = kernstart + kernlen; /* Static allocations begin after the kernel staging area. */ freemempos = roundup2(kernend, PAGE_SIZE); /* Detect Sv48 mode. */ mode = PMAP_MODE_SV39; TUNABLE_INT_FETCH("vm.pmap.mode", &mode); if (mode == PMAP_MODE_SV48 && (mmu_caps & MMU_SV48) != 0) { /* * Sv48 mode: allocate an L0 page table to be the root. The * layout of KVA is otherwise identical to Sv39. */ l0 = pmap_early_alloc_tables(&freemempos, 1); *root_pt_phys = (vm_paddr_t)l0; pmap_mode = PMAP_MODE_SV48; } else { l0 = NULL; } /* * Allocate an L1 page table. */ l1 = pmap_early_alloc_tables(&freemempos, 1); if (pmap_mode == PMAP_MODE_SV39) *root_pt_phys = (vm_paddr_t)l1; /* * Allocate a set of L2 page tables for KVA. Most likely, only 1 is * needed. */ nkernl2 = howmany(howmany(kernlen, L2_SIZE), Ln_ENTRIES); kern_l2 = pmap_early_alloc_tables(&freemempos, nkernl2); /* * Allocate an L2 page table for the static devmap, located at the end * of KVA. We can expect that the devmap will always be less than 1GB * in size. */ devmap_l2 = pmap_early_alloc_tables(&freemempos, 1); /* Allocate L3 page tables for the devmap. */ ndevmapl3 = howmany(howmany(PMAP_MAPDEV_EARLY_SIZE, L3_SIZE), Ln_ENTRIES); devmap_l3 = pmap_early_alloc_tables(&freemempos, ndevmapl3); /* * Allocate some L3 bootstrap pages, for early KVA allocations before * vm_mem_init() has run. For example, the message buffer. * * A somewhat arbitrary choice of 32MB. This should be more than enough * for any early allocations. There is no need to worry about waste, as * whatever is not used will be consumed by later calls to * pmap_growkernel(). */ nkernl3 = 16; kern_l3 = pmap_early_alloc_tables(&freemempos, nkernl3); /* Bootstrap the direct map. */ freemempos = pmap_bootstrap_dmap(l1, freemempos); /* Allocations are done. */ if (freemempos < roundup2(kernend, L2_SIZE)) freemempos = roundup2(kernend, L2_SIZE); /* Memory attributes for standard/main memory. */ memattr = pmap_memattr_bits(VM_MEMATTR_DEFAULT); /* * Map the kernel (and preloaded modules or data) using L2 superpages. * * kernstart is 2MB-aligned. This is enforced by loader(8) and required * by locore assembly. * * TODO: eventually, this should be done with proper permissions for * each segment, rather than mapping the entire kernel and preloaded * modules RWX. */ slot = pmap_l2_index(KERNBASE); for (pa = kernstart; pa < kernend; pa += L2_SIZE, slot++) { pmap_store(&kern_l2[slot], L2_PTE(pa, PTE_KERN | PTE_X | memattr)); } /* * Connect the L3 bootstrap pages to the kernel L2 table. The L3 PTEs * themselves are invalid. */ slot = pmap_l2_index(freemempos - kernstart + KERNBASE); for (i = 0; i < nkernl3; i++, slot++) { pa = (vm_paddr_t)kern_l3 + ptoa(i); pmap_store(&kern_l2[slot], L2_PDE(pa, PTE_V)); } /* Connect the L2 tables to the L1 table. */ slot = pmap_l1_index(KERNBASE); for (i = 0; i < nkernl2; i++, slot++) { pa = (vm_paddr_t)kern_l2 + ptoa(i); pmap_store(&l1[slot], L1_PDE(pa, PTE_V)); } /* Connect the L1 table to L0, if in use. */ if (pmap_mode == PMAP_MODE_SV48) { slot = pmap_l0_index(KERNBASE); pmap_store(&l0[slot], L0_PDE((vm_paddr_t)l1, PTE_V)); } /* * Connect the devmap L3 pages to the L2 table. The devmap PTEs * themselves are invalid. */ slot = pmap_l2_index(DEVMAP_MIN_VADDR); for (i = 0; i < ndevmapl3; i++, slot++) { pa = (vm_paddr_t)devmap_l3 + ptoa(i); pmap_store(&devmap_l2[slot], L2_PDE(pa, PTE_V)); } /* Connect the devmap L2 pages to the L1 table. */ slot = pmap_l1_index(DEVMAP_MIN_VADDR); pa = (vm_paddr_t)devmap_l2; pmap_store(&l1[slot], L1_PDE(pa, PTE_V)); /* Return the next position of free memory */ return (freemempos); } /* * Bootstrap the system enough to run with virtual memory. */ void pmap_bootstrap(vm_paddr_t kernstart, vm_size_t kernlen) { vm_paddr_t freemempos, pa; vm_paddr_t root_pt_phys; vm_offset_t freeva; vm_offset_t dpcpu, msgbufpv; pt_entry_t *pte; int i; printf("pmap_bootstrap %lx %lx\n", kernstart, kernlen); 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); /* * Set up the memory attribute bits. */ if (has_svpbmt) { memattr_bits[VM_MEMATTR_PMA] = PTE_MA_NONE; memattr_bits[VM_MEMATTR_UNCACHEABLE] = PTE_MA_NC; memattr_bits[VM_MEMATTR_DEVICE] = PTE_MA_IO; memattr_mask = PTE_MA_MASK; } /* Create a new set of pagetables to run the kernel in. */ freemempos = pmap_create_pagetables(kernstart, kernlen, &root_pt_phys); /* Switch to the newly created page tables. */ kernel_pmap->pm_stage = PM_STAGE1; kernel_pmap->pm_top = (pd_entry_t *)PHYS_TO_DMAP(root_pt_phys); kernel_pmap->pm_satp = atop(root_pt_phys) | pmap_satp_mode(); csr_write(satp, kernel_pmap->pm_satp); sfence_vma(); /* * Now, we need to make a few more static reservations from KVA. * * Set freeva to freemempos virtual address, and be sure to advance * them together. */ freeva = freemempos - kernstart + KERNBASE; #define reserve_space(var, pa, size) \ do { \ var = freeva; \ pa = freemempos; \ freeva += size; \ freemempos += size; \ } while (0) /* Allocate the dynamic per-cpu area. */ reserve_space(dpcpu, pa, DPCPU_SIZE); /* Map it. */ pte = pmap_l3(kernel_pmap, dpcpu); KASSERT(pte != NULL, ("Bootstrap pages missing")); for (i = 0; i < howmany(DPCPU_SIZE, PAGE_SIZE); i++) pmap_store(&pte[i], L3_PTE(pa + ptoa(i), PTE_KERN | pmap_memattr_bits(VM_MEMATTR_DEFAULT))); /* Now, it can be initialized. */ dpcpu_init((void *)dpcpu, 0); /* Allocate memory for the msgbuf, e.g. for /sbin/dmesg */ reserve_space(msgbufpv, pa, round_page(msgbufsize)); msgbufp = (void *)msgbufpv; /* Map it. */ pte = pmap_l3(kernel_pmap, msgbufpv); KASSERT(pte != NULL, ("Bootstrap pages missing")); for (i = 0; i < howmany(msgbufsize, PAGE_SIZE); i++) pmap_store(&pte[i], L3_PTE(pa + ptoa(i), PTE_KERN | pmap_memattr_bits(VM_MEMATTR_DEFAULT))); #undef reserve_space /* Mark the bounds of our available virtual address space */ virtual_avail = kernel_vm_end = freeva; virtual_end = DEVMAP_MIN_VADDR; /* Exclude the reserved physical memory from allocations. */ physmem_exclude_region(kernstart, freemempos - 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_DEFAULT; } /* * Initialize the pmap module. * * Called by vm_mem_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); 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_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) { m = PTE_TO_VM_PAGE(l3); if (!vm_page_wire_mapped(m)) m = NULL; } } PMAP_UNLOCK(pmap); return (m); } /* * Routine: pmap_kextract * Function: * Extract the physical page address associated with the given kernel * virtual address. */ 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); 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) { pt_entry_t entry; pt_entry_t *l3; pt_entry_t memattr; 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")); memattr = pmap_memattr_bits(mode); 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 |= memattr; 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. */ 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; vm_paddr_t 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 |= pmap_memattr_bits(m->md.pv_memattr); 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, bool 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 "all_l3e_PTE_A_set" is false, then "mpte" must * contain valid mappings with identical attributes except for PTE_A; * "mpte"'s valid field will be set to 1. * * If "promoted" and "all_l3e_PTE_A_set" are both true, then "mpte" must contain * valid mappings with identical attributes including PTE_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 all_l3e_PTE_A_set) { PMAP_LOCK_ASSERT(pmap, MA_OWNED); KASSERT(promoted || !all_l3e_PTE_A_set, ("a zero-filled PTP can't have PTE_A set in every PTE")); mpte->valid = promoted ? (all_l3e_PTE_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_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 bool 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) { 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); pdpg = PTE_TO_VM_PAGE(pmap_load(l1)); 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; l0 = pmap_l0(pmap, va); pdpg = PTE_TO_VM_PAGE(pmap_load(l0)); 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 = PTE_TO_VM_PAGE(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_stage = PM_STAGE1; 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_stage(pmap_t pmap, enum pmap_stage stage) { vm_paddr_t topphys; vm_page_t m; size_t i; /* * Top directory is 4 pages in hypervisor case. * Current address space layout makes 3 of them unused. */ if (stage == PM_STAGE1) m = vm_page_alloc_noobj(VM_ALLOC_WIRED | VM_ALLOC_ZERO | VM_ALLOC_WAITOK); else m = vm_page_alloc_noobj_contig(VM_ALLOC_WIRED | VM_ALLOC_ZERO, 4, 0, ~0ul, L2_SIZE, 0, VM_MEMATTR_DEFAULT); topphys = VM_PAGE_TO_PHYS(m); pmap->pm_top = (pd_entry_t *)PHYS_TO_DMAP(topphys); pmap->pm_satp = pmap_satp_mode() | (topphys >> PAGE_SHIFT); pmap->pm_stage = stage; bzero(&pmap->pm_stats, sizeof(pmap->pm_stats)); CPU_ZERO(&pmap->pm_active); if (stage == PM_STAGE2) goto finish; 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]; } finish: TAILQ_INIT(&pmap->pm_pvchunk); vm_radix_init(&pmap->pm_root); return (1); } int pmap_pinit(pmap_t pmap) { return (pmap_pinit_stage(pmap, PM_STAGE1)); } /* * 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 { pdpg = PTE_TO_VM_PAGE(pmap_load(l1)); 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 { pdpg = PTE_TO_VM_PAGE(pmap_load(l1)); 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; + vm_pindex_t pindex; 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 = PTE_TO_VM_PAGE(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); + pindex = pmap_l1_pindex(va); + l2pg = _pmap_alloc_l3(pmap, pindex, 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_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) { m = PTE_TO_VM_PAGE(pmap_load(l2)); 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; int npages; int i; 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->pm_stage == PM_STAGE2) goto finish; if (pmap_mode == PMAP_MODE_SV39) { mtx_lock(&allpmaps_lock); LIST_REMOVE(pmap, pm_list); mtx_unlock(&allpmaps_lock); } finish: npages = pmap->pm_stage == PM_STAGE2 ? 4 : 1; m = PHYS_TO_VM_PAGE(DMAP_TO_PHYS((vm_offset_t)pmap->pm_top)); for (i = 0; i < npages; i++) { vm_page_unwire_noq(m); vm_page_free(m); 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_NOFREE | VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (nkpg == NULL) panic("%s: no memory to grow kernel", __func__); nkpg->pindex = pmap_l1_pindex(kernel_vm_end); 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_NOFREE | VM_ALLOC_WIRED | VM_ALLOC_ZERO); if (nkpg == NULL) panic("%s: no memory to grow kernel", __func__); nkpg->pindex = pmap_l2_pindex(kernel_vm_end); 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 }; #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 /* * 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; } 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; 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); PV_STAT(atomic_add_int(&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; } 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 bool 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. */ PV_STAT(atomic_add_long(&pv_entry_allocs, Ln_ENTRIES - 1)); 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_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, Ln_ENTRIES - 1)); PV_STAT(atomic_add_int(&pv_entry_spare, -(Ln_ENTRIES - 1))); } #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 (vm_page_any_valid(ml3)) 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 = PTE_TO_VM_PAGE(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(vm_page_any_valid(ml3), ("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_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) { m = PTE_TO_VM_PAGE(old_l3); 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 ((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_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 ((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)) { m = PTE_TO_VM_PAGE(l2e); 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 = PTE_TO_VM_PAGE(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 (((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); } /* * Demote the specified L1 page to separate L2 pages. * Currently only used for DMAP entries. */ static bool pmap_demote_l1(pmap_t pmap, pd_entry_t *l1, vm_offset_t va) { vm_page_t m; pt_entry_t *l2, oldl1, newl2; pd_entry_t newl1; vm_paddr_t l2phys; PMAP_LOCK_ASSERT(pmap, MA_OWNED); oldl1 = pmap_load(l1); KASSERT((oldl1 & PTE_RWX) != 0, ("pmap_demote_l1: oldl1 is not a leaf PTE")); KASSERT((oldl1 & PTE_A) != 0, ("pmap_demote_l1: oldl1 is missing PTE_A")); KASSERT((oldl1 & (PTE_D | PTE_W)) != PTE_W, ("pmap_demote_l1: not dirty!")); KASSERT((oldl1 & PTE_SW_MANAGED) == 0, ("pmap_demote_l1: L1 table shouldn't be managed")); KASSERT(VIRT_IN_DMAP(va), ("pmap_demote_l1: is unsupported for non-DMAP va=%#lx", va)); /* Demoting L1 means we need to allocate a new page-table page. */ m = vm_page_alloc_noobj(VM_ALLOC_INTERRUPT | VM_ALLOC_WIRED); if (m == NULL) { CTR2(KTR_PMAP, "pmap_demote_l1: failure for va %#lx in pmap %p", va, pmap); return (false); } l2phys = VM_PAGE_TO_PHYS(m); l2 = (pt_entry_t *)PHYS_TO_DMAP(l2phys); /* * Create new entries, relying on the fact that only the low bits * (index) of the physical address are changing. */ newl2 = oldl1; for (int i = 0; i < Ln_ENTRIES; i++) pmap_store(&l2[i], newl2 | (i << PTE_PPN1_S)); /* * And update the L1 entry. * * NB: flushing the TLB is the responsibility of the caller. Cached * translations are still "correct" for demoted mappings until some * subset of the demoted range is modified. */ newl1 = ((l2phys / PAGE_SIZE) << PTE_PPN0_S) | PTE_V; pmap_store(l1, newl1); counter_u64_add(pmap_l1_demotions, 1); CTR2(KTR_PMAP, "pmap_demote_l1: success for va %#lx in pmap %p", va, pmap); return (true); } 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) { KASSERT((oldl2 & PTE_SW_WIRED) == 0, ("pmap_demote_l2_locked: page table page for a wired mapping is missing")); 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 (!vm_page_all_valid(mpte)) { 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 PTEs. */ 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 bool pmap_promote_l2(pmap_t pmap, pd_entry_t *l2, vm_offset_t va, vm_page_t ml3, struct rwlock **lockp) { pt_entry_t all_l3e_PTE_A, *firstl3, firstl3e, *l3, l3e; vm_paddr_t pa; PMAP_LOCK_ASSERT(pmap, MA_OWNED); if (!pmap_ps_enabled(pmap)) return (false); KASSERT((pmap_load(l2) & PTE_RWX) == 0, ("pmap_promote_l2: invalid l2 entry %p", l2)); /* * Examine the first L3E in the specified PTP. Abort if this L3E is * ineligible for promotion or does not map the first 4KB physical page * within a 2MB page. */ 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 (false); } /* * 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; } } /* * 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. */ all_l3e_PTE_A = firstl3e & PTE_A; pa += L2_SIZE - PAGE_SIZE; for (l3 = firstl3 + Ln_ENTRIES - 1; l3 > firstl3; 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 (false); } 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 (false); } all_l3e_PTE_A &= l3e; pa -= PAGE_SIZE; } /* * Unless all PTEs have PTE_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. */ firstl3e &= ~PTE_A | all_l3e_PTE_A; /* * Save the page table page in its current state until the L2 * mapping the superpage is demoted by pmap_demote_l2() or * destroyed by pmap_remove_l3(). */ if (ml3 == NULL) ml3 = PTE_TO_VM_PAGE(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, all_l3e_PTE_A != 0)) { CTR2(KTR_PMAP, "pmap_promote_l2: failure for va %#lx pmap %p", va, pmap); atomic_add_long(&pmap_l2_p_failures, 1); return (false); } 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); return (true); } #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 *l2, l2e; pt_entry_t new_l3, orig_l3; pt_entry_t *l3; pv_entry_t pv; vm_paddr_t opa, pa; vm_page_t mpte, om; pn_t 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; new_l3 |= pmap_memattr_bits(m->md.pv_memattr); /* * 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 = PTE_TO_VM_PAGE(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 { panic("pmap_enter: missing L3 table for kernel va %#lx", 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 && (m->flags & PG_FICTITIOUS) == 0 && vm_reserv_level_iffullpop(m) == 0) (void)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); } /* * 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 l2pg) { struct spglist free; 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); } } /* * 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 | pmap_memattr_bits(m->md.pv_memattr)); 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; vm_page_t uwptpg; 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 = PTE_TO_VM_PAGE(pmap_load(l2)); if (pmap_insert_pt_page(pmap, mt, false, false)) panic("pmap_enter_l2: trie insert failed"); } else KASSERT(pmap_load(l2) == 0, ("pmap_enter_l2: non-zero L2 entry %p", l2)); } /* * Allocate leaf ptpage for wired userspace pages. */ uwptpg = NULL; if ((new_l2 & PTE_SW_WIRED) != 0 && pmap != kernel_pmap) { uwptpg = vm_page_alloc_noobj(VM_ALLOC_WIRED); if (uwptpg == NULL) { pmap_abort_ptp(pmap, va, l2pg); return (KERN_RESOURCE_SHORTAGE); } uwptpg->pindex = pmap_l2_pindex(va); if (pmap_insert_pt_page(pmap, uwptpg, true, false)) { vm_page_unwire_noq(uwptpg); vm_page_free(uwptpg); pmap_abort_ptp(pmap, va, l2pg); return (KERN_RESOURCE_SHORTAGE); } pmap_resident_count_inc(pmap, 1); uwptpg->ref_count = Ln_ENTRIES; } 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)) { pmap_abort_ptp(pmap, va, l2pg); if (uwptpg != NULL) { mt = pmap_remove_pt_page(pmap, va); KASSERT(mt == uwptpg, ("removed pt page %p, expected %p", mt, uwptpg)); pmap_resident_count_dec(pmap, 1); uwptpg->ref_count = 1; vm_page_unwire_noq(uwptpg); vm_page_free(uwptpg); } 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; 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); l2 = NULL; 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); mpte = PTE_TO_VM_PAGE(pmap_load(l2)); 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--; 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) { SLIST_INIT(&free); if (pmap_unwire_ptp(pmap, va, mpte, &free)) vm_page_free_pages_toq(&free, false); } return (NULL); } /* * Increment counters */ pmap_resident_count_inc(pmap, 1); newl3 = ((VM_PAGE_TO_PHYS(m) / PAGE_SIZE) << PTE_PPN0_S) | PTE_V | PTE_R | pmap_memattr_bits(m->md.pv_memattr); 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); #if VM_NRESERVLEVEL > 0 /* * If both the PTP and the reservation are fully populated, then attempt * promotion. */ if ((prot & VM_PROT_NO_PROMOTE) == 0 && (mpte == NULL || mpte->ref_count == Ln_ENTRIES) && (m->flags & PG_FICTITIOUS) == 0 && vm_reserv_level_iffullpop(m) == 0) { if (l2 == NULL) l2 = pmap_l2(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_l2(pmap, l2, va, mpte, lockp)) mpte = NULL; } #endif 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. */ bool 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; bool 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(vm_page_any_valid(mpte), ("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 = PTE_TO_VM_PAGE(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, bool accessed, bool 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. */ bool 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. */ bool pmap_is_prefaultable(pmap_t pmap, vm_offset_t addr) { pt_entry_t *l3; bool 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. */ bool 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, ("%s: page %p is not managed", __func__, 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_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; vm_paddr_t phys; pd_entry_t *l1, l1e; pd_entry_t *l2, l2e; pt_entry_t *l3, l3e; pt_entry_t bits, mask; bool anychanged = false; int error = 0; 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); bits = pmap_memattr_bits(mode); mask = memattr_mask; /* First loop: perform PTE validation and demotions as necessary. */ 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) { /* * If the existing PTE has the correct attributes, then * no need to demote. */ if ((l1e & mask) == bits) { tmpva = (tmpva & ~L1_OFFSET) + L1_SIZE; continue; } /* * If the 1GB page fits in the remaining range, we * don't need to demote. */ if ((tmpva & L1_OFFSET) == 0 && tmpva + L1_SIZE <= base + size) { tmpva += L1_SIZE; continue; } if (!pmap_demote_l1(kernel_pmap, l1, tmpva)) return (EINVAL); } l2 = pmap_l1_to_l2(l1, tmpva); if (((l2e = pmap_load(l2)) & PTE_V) == 0) return (EINVAL); if ((l2e & PTE_RWX) != 0) { /* * If the existing PTE has the correct attributes, then * no need to demote. */ if ((l2e & mask) == bits) { tmpva = (tmpva & ~L2_OFFSET) + L2_SIZE; continue; } /* * If the 2MB page fits in the remaining range, we * don't need to demote. */ if ((tmpva & L2_OFFSET) == 0 && tmpva + L2_SIZE <= base + size) { tmpva += L2_SIZE; continue; } if (!pmap_demote_l2(kernel_pmap, l2, tmpva)) panic("l2 demotion failed"); } l3 = pmap_l2_to_l3(l2, tmpva); if (((l3e = pmap_load(l3)) & PTE_V) == 0) return (EINVAL); tmpva += PAGE_SIZE; } /* Second loop: perform PTE updates. */ for (tmpva = base; tmpva < base + size; ) { l1 = pmap_l1(kernel_pmap, tmpva); l1e = pmap_load(l1); if ((l1e & PTE_RWX) != 0) { /* Unchanged. */ if ((l1e & mask) == bits) { tmpva += L1_SIZE; continue; } l1e &= ~mask; l1e |= bits; pmap_store(l1, l1e); anychanged = true; /* Update corresponding DMAP entry */ phys = L1PTE_TO_PHYS(l1e); if (!VIRT_IN_DMAP(tmpva) && PHYS_IN_DMAP(phys)) { error = pmap_change_attr_locked( PHYS_TO_DMAP(phys), L1_SIZE, mode); if (error != 0) break; } tmpva += L1_SIZE; continue; } l2 = pmap_l1_to_l2(l1, tmpva); l2e = pmap_load(l2); if ((l2e & PTE_RWX) != 0) { /* Unchanged. */ if ((l2e & mask) == bits) { tmpva += L2_SIZE; continue; } l2e &= ~mask; l2e |= bits; pmap_store(l2, l2e); anychanged = true; /* Update corresponding DMAP entry */ phys = L2PTE_TO_PHYS(l2e); if (!VIRT_IN_DMAP(tmpva) && PHYS_IN_DMAP(phys)) { error = pmap_change_attr_locked( PHYS_TO_DMAP(phys), L2_SIZE, mode); if (error != 0) break; } tmpva += L2_SIZE; continue; } l3 = pmap_l2_to_l3(l2, tmpva); l3e = pmap_load(l3); /* Unchanged. */ if ((l3e & mask) == bits) { tmpva += PAGE_SIZE; continue; } l3e &= ~mask; l3e |= bits; pmap_store(l3, l3e); anychanged = true; phys = PTE_TO_PHYS(l3e); if (!VIRT_IN_DMAP(tmpva) && PHYS_IN_DMAP(phys)) { error = pmap_change_attr_locked(PHYS_TO_DMAP(phys), L3_SIZE, mode); if (error != 0) break; } tmpva += PAGE_SIZE; } if (anychanged) { pmap_invalidate_range(kernel_pmap, base, tmpva); if (mode == VM_MEMATTR_UNCACHEABLE) cpu_dcache_wbinv_range((void *)base, size); } return (error); } /* * 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"); } } } bool pmap_is_valid_memattr(pmap_t pmap __unused, vm_memattr_t mode) { return (mode >= VM_MEMATTR_DEFAULT && mode <= VM_MEMATTR_LAST); } 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) { char *mode; int i; if (eva <= range->sva) return; for (i = 0; i < nitems(memattr_bits); i++) if ((range->attrs & memattr_mask) == memattr_bits[i]) break; switch (i) { case VM_MEMATTR_PMA: mode = "PMA"; break; case VM_MEMATTR_UNCACHEABLE: mode = "NC "; break; case VM_MEMATTR_DEVICE: mode = "IO "; break; default: mode = "???"; break; } sbuf_printf(sb, "0x%016lx-0x%016lx r%c%c%c%c %s %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' : '-', mode, 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); attrs |= l1e & memattr_mask; } else if (l2e != 0) attrs |= l2e & PTE_G; if ((l2e & PTE_RWX) != 0) { attrs |= l2e & (PTE_RWX | PTE_U); attrs |= l2e & memattr_mask; } else if (l3e != 0) { attrs |= l3e & (PTE_RWX | PTE_U | PTE_G); attrs |= l3e & memattr_mask; } 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 *l1, 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"); l1 = pmap_l1(kernel_pmap, sva); l1e = pmap_load(l1); 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");