Index: stable/10/sys/dev/ntb/ntb_hw/ntb_hw.c =================================================================== --- stable/10/sys/dev/ntb/ntb_hw/ntb_hw.c (revision 304393) +++ stable/10/sys/dev/ntb/ntb_hw/ntb_hw.c (revision 304394) @@ -1,3227 +1,3237 @@ /*- * Copyright (c) 2016 Alexander Motin * Copyright (C) 2013 Intel Corporation * Copyright (C) 2015 EMC Corporation * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /* * The Non-Transparent Bridge (NTB) is a device that allows you to connect * two or more systems using a PCI-e links, providing remote memory access. * * This module contains a driver for NTB hardware in Intel Xeon/Atom CPUs. * * NOTE: Much of the code in this module is shared with Linux. Any patches may * be picked up and redistributed in Linux with a dual GPL/BSD license. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "ntb_regs.h" #include "../ntb.h" #define MAX_MSIX_INTERRUPTS MAX(XEON_DB_COUNT, ATOM_DB_COUNT) #define NTB_HB_TIMEOUT 1 /* second */ #define ATOM_LINK_RECOVERY_TIME 500 /* ms */ #define BAR_HIGH_MASK (~((1ull << 12) - 1)) #define NTB_MSIX_VER_GUARD 0xaabbccdd #define NTB_MSIX_RECEIVED 0xe0f0e0f0 /* * PCI constants could be somewhere more generic, but aren't defined/used in * pci.c. */ #define PCI_MSIX_ENTRY_SIZE 16 #define PCI_MSIX_ENTRY_LOWER_ADDR 0 #define PCI_MSIX_ENTRY_UPPER_ADDR 4 #define PCI_MSIX_ENTRY_DATA 8 enum ntb_device_type { NTB_XEON, NTB_ATOM }; /* ntb_conn_type are hardware numbers, cannot change. */ enum ntb_conn_type { NTB_CONN_TRANSPARENT = 0, NTB_CONN_B2B = 1, NTB_CONN_RP = 2, }; enum ntb_b2b_direction { NTB_DEV_USD = 0, NTB_DEV_DSD = 1, }; enum ntb_bar { NTB_CONFIG_BAR = 0, NTB_B2B_BAR_1, NTB_B2B_BAR_2, NTB_B2B_BAR_3, NTB_MAX_BARS }; enum { NTB_MSIX_GUARD = 0, NTB_MSIX_DATA0, NTB_MSIX_DATA1, NTB_MSIX_DATA2, NTB_MSIX_OFS0, NTB_MSIX_OFS1, NTB_MSIX_OFS2, NTB_MSIX_DONE, NTB_MAX_MSIX_SPAD }; /* Device features and workarounds */ #define HAS_FEATURE(ntb, feature) \ (((ntb)->features & (feature)) != 0) struct ntb_hw_info { uint32_t device_id; const char *desc; enum ntb_device_type type; uint32_t features; }; struct ntb_pci_bar_info { bus_space_tag_t pci_bus_tag; bus_space_handle_t pci_bus_handle; int pci_resource_id; struct resource *pci_resource; vm_paddr_t pbase; caddr_t vbase; vm_size_t size; vm_memattr_t map_mode; /* Configuration register offsets */ uint32_t psz_off; uint32_t ssz_off; uint32_t pbarxlat_off; }; struct ntb_int_info { struct resource *res; int rid; void *tag; }; struct ntb_vec { struct ntb_softc *ntb; uint32_t num; unsigned masked; }; struct ntb_reg { uint32_t ntb_ctl; uint32_t lnk_sta; uint8_t db_size; unsigned mw_bar[NTB_MAX_BARS]; }; struct ntb_alt_reg { uint32_t db_bell; uint32_t db_mask; uint32_t spad; }; struct ntb_xlat_reg { uint32_t bar0_base; uint32_t bar2_base; uint32_t bar4_base; uint32_t bar5_base; uint32_t bar2_xlat; uint32_t bar4_xlat; uint32_t bar5_xlat; uint32_t bar2_limit; uint32_t bar4_limit; uint32_t bar5_limit; }; struct ntb_b2b_addr { uint64_t bar0_addr; uint64_t bar2_addr64; uint64_t bar4_addr64; uint64_t bar4_addr32; uint64_t bar5_addr32; }; struct ntb_msix_data { uint32_t nmd_ofs; uint32_t nmd_data; }; struct ntb_softc { device_t device; enum ntb_device_type type; uint32_t features; struct ntb_pci_bar_info bar_info[NTB_MAX_BARS]; struct ntb_int_info int_info[MAX_MSIX_INTERRUPTS]; uint32_t allocated_interrupts; struct ntb_msix_data peer_msix_data[XEON_NONLINK_DB_MSIX_BITS]; struct ntb_msix_data msix_data[XEON_NONLINK_DB_MSIX_BITS]; bool peer_msix_good; bool peer_msix_done; struct ntb_pci_bar_info *peer_lapic_bar; struct callout peer_msix_work; struct callout heartbeat_timer; struct callout lr_timer; void *ntb_ctx; const struct ntb_ctx_ops *ctx_ops; struct ntb_vec *msix_vec; struct rmlock ctx_lock; uint32_t ppd; enum ntb_conn_type conn_type; enum ntb_b2b_direction dev_type; /* Offset of peer bar0 in B2B BAR */ uint64_t b2b_off; /* Memory window used to access peer bar0 */ #define B2B_MW_DISABLED UINT8_MAX uint8_t b2b_mw_idx; uint32_t msix_xlat; uint8_t msix_mw_idx; uint8_t mw_count; uint8_t spad_count; uint8_t db_count; uint8_t db_vec_count; uint8_t db_vec_shift; /* Protects local db_mask. */ #define DB_MASK_LOCK(sc) mtx_lock_spin(&(sc)->db_mask_lock) #define DB_MASK_UNLOCK(sc) mtx_unlock_spin(&(sc)->db_mask_lock) #define DB_MASK_ASSERT(sc,f) mtx_assert(&(sc)->db_mask_lock, (f)) struct mtx db_mask_lock; volatile uint32_t ntb_ctl; volatile uint32_t lnk_sta; uint64_t db_valid_mask; uint64_t db_link_mask; uint64_t db_mask; uint64_t fake_db_bell; /* NTB_SB01BASE_LOCKUP*/ int last_ts; /* ticks @ last irq */ const struct ntb_reg *reg; const struct ntb_alt_reg *self_reg; const struct ntb_alt_reg *peer_reg; const struct ntb_xlat_reg *xlat_reg; }; #ifdef __i386__ static __inline uint64_t bus_space_read_8(bus_space_tag_t tag, bus_space_handle_t handle, bus_size_t offset) { return (bus_space_read_4(tag, handle, offset) | ((uint64_t)bus_space_read_4(tag, handle, offset + 4)) << 32); } static __inline void bus_space_write_8(bus_space_tag_t tag, bus_space_handle_t handle, bus_size_t offset, uint64_t val) { bus_space_write_4(tag, handle, offset, val); bus_space_write_4(tag, handle, offset + 4, val >> 32); } #endif #define ntb_bar_read(SIZE, bar, offset) \ bus_space_read_ ## SIZE (ntb->bar_info[(bar)].pci_bus_tag, \ ntb->bar_info[(bar)].pci_bus_handle, (offset)) #define ntb_bar_write(SIZE, bar, offset, val) \ bus_space_write_ ## SIZE (ntb->bar_info[(bar)].pci_bus_tag, \ ntb->bar_info[(bar)].pci_bus_handle, (offset), (val)) #define ntb_reg_read(SIZE, offset) ntb_bar_read(SIZE, NTB_CONFIG_BAR, offset) #define ntb_reg_write(SIZE, offset, val) \ ntb_bar_write(SIZE, NTB_CONFIG_BAR, offset, val) #define ntb_mw_read(SIZE, offset) \ ntb_bar_read(SIZE, ntb_mw_to_bar(ntb, ntb->b2b_mw_idx), offset) #define ntb_mw_write(SIZE, offset, val) \ ntb_bar_write(SIZE, ntb_mw_to_bar(ntb, ntb->b2b_mw_idx), \ offset, val) static int ntb_probe(device_t device); static int ntb_attach(device_t device); static int ntb_detach(device_t device); static uint64_t ntb_db_valid_mask(device_t dev); static void ntb_spad_clear(device_t dev); static uint64_t ntb_db_vector_mask(device_t dev, uint32_t vector); static bool ntb_link_is_up(device_t dev, enum ntb_speed *speed, enum ntb_width *width); static int ntb_link_enable(device_t dev, enum ntb_speed speed, enum ntb_width width); static int ntb_link_disable(device_t dev); static int ntb_spad_read(device_t dev, unsigned int idx, uint32_t *val); static int ntb_peer_spad_write(device_t dev, unsigned int idx, uint32_t val); static unsigned ntb_user_mw_to_idx(struct ntb_softc *, unsigned uidx); static inline enum ntb_bar ntb_mw_to_bar(struct ntb_softc *, unsigned mw); static inline bool bar_is_64bit(struct ntb_softc *, enum ntb_bar); static inline void bar_get_xlat_params(struct ntb_softc *, enum ntb_bar, uint32_t *base, uint32_t *xlat, uint32_t *lmt); static int ntb_map_pci_bars(struct ntb_softc *ntb); static int ntb_mw_set_wc_internal(struct ntb_softc *, unsigned idx, vm_memattr_t); static void print_map_success(struct ntb_softc *, struct ntb_pci_bar_info *, const char *); static int map_mmr_bar(struct ntb_softc *ntb, struct ntb_pci_bar_info *bar); static int map_memory_window_bar(struct ntb_softc *ntb, struct ntb_pci_bar_info *bar); static void ntb_unmap_pci_bar(struct ntb_softc *ntb); static int ntb_remap_msix(device_t, uint32_t desired, uint32_t avail); static int ntb_init_isr(struct ntb_softc *ntb); static int ntb_setup_legacy_interrupt(struct ntb_softc *ntb); static int ntb_setup_msix(struct ntb_softc *ntb, uint32_t num_vectors); static void ntb_teardown_interrupts(struct ntb_softc *ntb); static inline uint64_t ntb_vec_mask(struct ntb_softc *, uint64_t db_vector); static void ntb_interrupt(struct ntb_softc *, uint32_t vec); static void ndev_vec_isr(void *arg); static void ndev_irq_isr(void *arg); static inline uint64_t db_ioread(struct ntb_softc *, uint64_t regoff); static inline void db_iowrite(struct ntb_softc *, uint64_t regoff, uint64_t); static inline void db_iowrite_raw(struct ntb_softc *, uint64_t regoff, uint64_t); static int ntb_create_msix_vec(struct ntb_softc *ntb, uint32_t num_vectors); static void ntb_free_msix_vec(struct ntb_softc *ntb); static void ntb_get_msix_info(struct ntb_softc *ntb); static void ntb_exchange_msix(void *); static struct ntb_hw_info *ntb_get_device_info(uint32_t device_id); static void ntb_detect_max_mw(struct ntb_softc *ntb); static int ntb_detect_xeon(struct ntb_softc *ntb); static int ntb_detect_atom(struct ntb_softc *ntb); static int ntb_xeon_init_dev(struct ntb_softc *ntb); static int ntb_atom_init_dev(struct ntb_softc *ntb); static void ntb_teardown_xeon(struct ntb_softc *ntb); static void configure_atom_secondary_side_bars(struct ntb_softc *ntb); static void xeon_reset_sbar_size(struct ntb_softc *, enum ntb_bar idx, enum ntb_bar regbar); static void xeon_set_sbar_base_and_limit(struct ntb_softc *, uint64_t base_addr, enum ntb_bar idx, enum ntb_bar regbar); static void xeon_set_pbar_xlat(struct ntb_softc *, uint64_t base_addr, enum ntb_bar idx); static int xeon_setup_b2b_mw(struct ntb_softc *, const struct ntb_b2b_addr *addr, const struct ntb_b2b_addr *peer_addr); static inline bool link_is_up(struct ntb_softc *ntb); static inline bool _xeon_link_is_up(struct ntb_softc *ntb); static inline bool atom_link_is_err(struct ntb_softc *ntb); static inline enum ntb_speed ntb_link_sta_speed(struct ntb_softc *); static inline enum ntb_width ntb_link_sta_width(struct ntb_softc *); static void atom_link_hb(void *arg); static void ntb_link_event(device_t dev); static void ntb_db_event(device_t dev, uint32_t vec); static void recover_atom_link(void *arg); static bool ntb_poll_link(struct ntb_softc *ntb); static void save_bar_parameters(struct ntb_pci_bar_info *bar); static void ntb_sysctl_init(struct ntb_softc *); static int sysctl_handle_features(SYSCTL_HANDLER_ARGS); static int sysctl_handle_link_admin(SYSCTL_HANDLER_ARGS); static int sysctl_handle_link_status_human(SYSCTL_HANDLER_ARGS); static int sysctl_handle_link_status(SYSCTL_HANDLER_ARGS); static int sysctl_handle_register(SYSCTL_HANDLER_ARGS); static unsigned g_ntb_hw_debug_level; TUNABLE_INT("hw.ntb.debug_level", &g_ntb_hw_debug_level); SYSCTL_UINT(_hw_ntb, OID_AUTO, debug_level, CTLFLAG_RWTUN, &g_ntb_hw_debug_level, 0, "ntb_hw log level -- higher is more verbose"); #define ntb_printf(lvl, ...) do { \ if ((lvl) <= g_ntb_hw_debug_level) { \ device_printf(ntb->device, __VA_ARGS__); \ } \ } while (0) #define _NTB_PAT_UC 0 #define _NTB_PAT_WC 1 #define _NTB_PAT_WT 4 #define _NTB_PAT_WP 5 #define _NTB_PAT_WB 6 #define _NTB_PAT_UCM 7 static unsigned g_ntb_mw_pat = _NTB_PAT_UC; TUNABLE_INT("hw.ntb.default_mw_pat", &g_ntb_mw_pat); SYSCTL_UINT(_hw_ntb, OID_AUTO, default_mw_pat, CTLFLAG_RDTUN, &g_ntb_mw_pat, 0, "Configure the default memory window cache flags (PAT): " "UC: " __XSTRING(_NTB_PAT_UC) ", " "WC: " __XSTRING(_NTB_PAT_WC) ", " "WT: " __XSTRING(_NTB_PAT_WT) ", " "WP: " __XSTRING(_NTB_PAT_WP) ", " "WB: " __XSTRING(_NTB_PAT_WB) ", " "UC-: " __XSTRING(_NTB_PAT_UCM)); static inline vm_memattr_t ntb_pat_flags(void) { switch (g_ntb_mw_pat) { case _NTB_PAT_WC: return (VM_MEMATTR_WRITE_COMBINING); case _NTB_PAT_WT: return (VM_MEMATTR_WRITE_THROUGH); case _NTB_PAT_WP: return (VM_MEMATTR_WRITE_PROTECTED); case _NTB_PAT_WB: return (VM_MEMATTR_WRITE_BACK); case _NTB_PAT_UCM: return (VM_MEMATTR_WEAK_UNCACHEABLE); case _NTB_PAT_UC: /* FALLTHROUGH */ default: return (VM_MEMATTR_UNCACHEABLE); } } /* * Well, this obviously doesn't belong here, but it doesn't seem to exist * anywhere better yet. */ static inline const char * ntb_vm_memattr_to_str(vm_memattr_t pat) { switch (pat) { case VM_MEMATTR_WRITE_COMBINING: return ("WRITE_COMBINING"); case VM_MEMATTR_WRITE_THROUGH: return ("WRITE_THROUGH"); case VM_MEMATTR_WRITE_PROTECTED: return ("WRITE_PROTECTED"); case VM_MEMATTR_WRITE_BACK: return ("WRITE_BACK"); case VM_MEMATTR_WEAK_UNCACHEABLE: return ("UNCACHED"); case VM_MEMATTR_UNCACHEABLE: return ("UNCACHEABLE"); default: return ("UNKNOWN"); } } -static int g_ntb_msix_idx = 0; +static int g_ntb_msix_idx = 1; TUNABLE_INT("hw.ntb.msix_mw_idx", &g_ntb_msix_idx); SYSCTL_INT(_hw_ntb, OID_AUTO, msix_mw_idx, CTLFLAG_RDTUN, &g_ntb_msix_idx, 0, "Use this memory window to access the peer MSIX message complex on " "certain Xeon-based NTB systems, as a workaround for a hardware errata. " "Like b2b_mw_idx, negative values index from the last available memory " "window. (Applies on Xeon platforms with SB01BASE_LOCKUP errata.)"); static int g_ntb_mw_idx = -1; TUNABLE_INT("hw.ntb.b2b_mw_idx", &g_ntb_mw_idx); SYSCTL_INT(_hw_ntb, OID_AUTO, b2b_mw_idx, CTLFLAG_RDTUN, &g_ntb_mw_idx, 0, "Use this memory window to access the peer NTB registers. A " "non-negative value starts from the first MW index; a negative value " "starts from the last MW index. The default is -1, i.e., the last " "available memory window. Both sides of the NTB MUST set the same " "value here! (Applies on Xeon platforms with SDOORBELL_LOCKUP errata.)"); /* Hardware owns the low 16 bits of features. */ #define NTB_BAR_SIZE_4K (1 << 0) #define NTB_SDOORBELL_LOCKUP (1 << 1) #define NTB_SB01BASE_LOCKUP (1 << 2) #define NTB_B2BDOORBELL_BIT14 (1 << 3) /* Software/configuration owns the top 16 bits. */ #define NTB_SPLIT_BAR (1ull << 16) #define NTB_FEATURES_STR \ "\20\21SPLIT_BAR4\04B2B_DOORBELL_BIT14\03SB01BASE_LOCKUP" \ "\02SDOORBELL_LOCKUP\01BAR_SIZE_4K" static struct ntb_hw_info pci_ids[] = { /* XXX: PS/SS IDs left out until they are supported. */ { 0x0C4E8086, "BWD Atom Processor S1200 Non-Transparent Bridge B2B", NTB_ATOM, 0 }, { 0x37258086, "JSF Xeon C35xx/C55xx Non-Transparent Bridge B2B", NTB_XEON, NTB_SDOORBELL_LOCKUP | NTB_B2BDOORBELL_BIT14 }, { 0x3C0D8086, "SNB Xeon E5/Core i7 Non-Transparent Bridge B2B", NTB_XEON, NTB_SDOORBELL_LOCKUP | NTB_B2BDOORBELL_BIT14 }, { 0x0E0D8086, "IVT Xeon E5 V2 Non-Transparent Bridge B2B", NTB_XEON, NTB_SDOORBELL_LOCKUP | NTB_B2BDOORBELL_BIT14 | NTB_SB01BASE_LOCKUP | NTB_BAR_SIZE_4K }, { 0x2F0D8086, "HSX Xeon E5 V3 Non-Transparent Bridge B2B", NTB_XEON, NTB_SDOORBELL_LOCKUP | NTB_B2BDOORBELL_BIT14 | NTB_SB01BASE_LOCKUP }, { 0x6F0D8086, "BDX Xeon E5 V4 Non-Transparent Bridge B2B", NTB_XEON, NTB_SDOORBELL_LOCKUP | NTB_B2BDOORBELL_BIT14 | NTB_SB01BASE_LOCKUP }, { 0x00000000, NULL, NTB_ATOM, 0 } }; static const struct ntb_reg atom_reg = { .ntb_ctl = ATOM_NTBCNTL_OFFSET, .lnk_sta = ATOM_LINK_STATUS_OFFSET, .db_size = sizeof(uint64_t), .mw_bar = { NTB_B2B_BAR_1, NTB_B2B_BAR_2 }, }; static const struct ntb_alt_reg atom_pri_reg = { .db_bell = ATOM_PDOORBELL_OFFSET, .db_mask = ATOM_PDBMSK_OFFSET, .spad = ATOM_SPAD_OFFSET, }; static const struct ntb_alt_reg atom_b2b_reg = { .db_bell = ATOM_B2B_DOORBELL_OFFSET, .spad = ATOM_B2B_SPAD_OFFSET, }; static const struct ntb_xlat_reg atom_sec_xlat = { #if 0 /* "FIXME" says the Linux driver. */ .bar0_base = ATOM_SBAR0BASE_OFFSET, .bar2_base = ATOM_SBAR2BASE_OFFSET, .bar4_base = ATOM_SBAR4BASE_OFFSET, .bar2_limit = ATOM_SBAR2LMT_OFFSET, .bar4_limit = ATOM_SBAR4LMT_OFFSET, #endif .bar2_xlat = ATOM_SBAR2XLAT_OFFSET, .bar4_xlat = ATOM_SBAR4XLAT_OFFSET, }; static const struct ntb_reg xeon_reg = { .ntb_ctl = XEON_NTBCNTL_OFFSET, .lnk_sta = XEON_LINK_STATUS_OFFSET, .db_size = sizeof(uint16_t), .mw_bar = { NTB_B2B_BAR_1, NTB_B2B_BAR_2, NTB_B2B_BAR_3 }, }; static const struct ntb_alt_reg xeon_pri_reg = { .db_bell = XEON_PDOORBELL_OFFSET, .db_mask = XEON_PDBMSK_OFFSET, .spad = XEON_SPAD_OFFSET, }; static const struct ntb_alt_reg xeon_b2b_reg = { .db_bell = XEON_B2B_DOORBELL_OFFSET, .spad = XEON_B2B_SPAD_OFFSET, }; static const struct ntb_xlat_reg xeon_sec_xlat = { .bar0_base = XEON_SBAR0BASE_OFFSET, .bar2_base = XEON_SBAR2BASE_OFFSET, .bar4_base = XEON_SBAR4BASE_OFFSET, .bar5_base = XEON_SBAR5BASE_OFFSET, .bar2_limit = XEON_SBAR2LMT_OFFSET, .bar4_limit = XEON_SBAR4LMT_OFFSET, .bar5_limit = XEON_SBAR5LMT_OFFSET, .bar2_xlat = XEON_SBAR2XLAT_OFFSET, .bar4_xlat = XEON_SBAR4XLAT_OFFSET, .bar5_xlat = XEON_SBAR5XLAT_OFFSET, }; static struct ntb_b2b_addr xeon_b2b_usd_addr = { .bar0_addr = XEON_B2B_BAR0_ADDR, .bar2_addr64 = XEON_B2B_BAR2_ADDR64, .bar4_addr64 = XEON_B2B_BAR4_ADDR64, .bar4_addr32 = XEON_B2B_BAR4_ADDR32, .bar5_addr32 = XEON_B2B_BAR5_ADDR32, }; static struct ntb_b2b_addr xeon_b2b_dsd_addr = { .bar0_addr = XEON_B2B_BAR0_ADDR, .bar2_addr64 = XEON_B2B_BAR2_ADDR64, .bar4_addr64 = XEON_B2B_BAR4_ADDR64, .bar4_addr32 = XEON_B2B_BAR4_ADDR32, .bar5_addr32 = XEON_B2B_BAR5_ADDR32, }; SYSCTL_NODE(_hw_ntb, OID_AUTO, xeon_b2b, CTLFLAG_RW, 0, "B2B MW segment overrides -- MUST be the same on both sides"); TUNABLE_QUAD("hw.ntb.usd_bar2_addr64", &xeon_b2b_usd_addr.bar2_addr64); SYSCTL_UQUAD(_hw_ntb_xeon_b2b, OID_AUTO, usd_bar2_addr64, CTLFLAG_RDTUN, &xeon_b2b_usd_addr.bar2_addr64, 0, "If using B2B topology on Xeon " "hardware, use this 64-bit address on the bus between the NTB devices for " "the window at BAR2, on the upstream side of the link. MUST be the same " "address on both sides."); TUNABLE_QUAD("hw.ntb.usd_bar4_addr64", &xeon_b2b_usd_addr.bar4_addr64); SYSCTL_UQUAD(_hw_ntb_xeon_b2b, OID_AUTO, usd_bar4_addr64, CTLFLAG_RDTUN, &xeon_b2b_usd_addr.bar4_addr64, 0, "See usd_bar2_addr64, but BAR4."); TUNABLE_QUAD("hw.ntb.usd_bar4_addr32", &xeon_b2b_usd_addr.bar4_addr32); SYSCTL_UQUAD(_hw_ntb_xeon_b2b, OID_AUTO, usd_bar4_addr32, CTLFLAG_RDTUN, &xeon_b2b_usd_addr.bar4_addr32, 0, "See usd_bar2_addr64, but BAR4 " "(split-BAR mode)."); TUNABLE_QUAD("hw.ntb.usd_bar5_addr32", &xeon_b2b_usd_addr.bar5_addr32); SYSCTL_UQUAD(_hw_ntb_xeon_b2b, OID_AUTO, usd_bar5_addr32, CTLFLAG_RDTUN, &xeon_b2b_usd_addr.bar5_addr32, 0, "See usd_bar2_addr64, but BAR5 " "(split-BAR mode)."); TUNABLE_QUAD("hw.ntb.dsd_bar2_addr64", &xeon_b2b_dsd_addr.bar2_addr64); SYSCTL_UQUAD(_hw_ntb_xeon_b2b, OID_AUTO, dsd_bar2_addr64, CTLFLAG_RDTUN, &xeon_b2b_dsd_addr.bar2_addr64, 0, "If using B2B topology on Xeon " "hardware, use this 64-bit address on the bus between the NTB devices for " "the window at BAR2, on the downstream side of the link. MUST be the same" " address on both sides."); TUNABLE_QUAD("hw.ntb.dsd_bar4_addr64", &xeon_b2b_dsd_addr.bar4_addr64); SYSCTL_UQUAD(_hw_ntb_xeon_b2b, OID_AUTO, dsd_bar4_addr64, CTLFLAG_RDTUN, &xeon_b2b_dsd_addr.bar4_addr64, 0, "See dsd_bar2_addr64, but BAR4."); TUNABLE_QUAD("hw.ntb.dsd_bar4_addr32", &xeon_b2b_dsd_addr.bar4_addr32); SYSCTL_UQUAD(_hw_ntb_xeon_b2b, OID_AUTO, dsd_bar4_addr32, CTLFLAG_RDTUN, &xeon_b2b_dsd_addr.bar4_addr32, 0, "See dsd_bar2_addr64, but BAR4 " "(split-BAR mode)."); TUNABLE_QUAD("hw.ntb.dsd_bar5_addr32", &xeon_b2b_dsd_addr.bar5_addr32); SYSCTL_UQUAD(_hw_ntb_xeon_b2b, OID_AUTO, dsd_bar5_addr32, CTLFLAG_RDTUN, &xeon_b2b_dsd_addr.bar5_addr32, 0, "See dsd_bar2_addr64, but BAR5 " "(split-BAR mode)."); /* * OS <-> Driver interface structures */ MALLOC_DEFINE(M_NTB, "ntb_hw", "ntb_hw driver memory allocations"); SYSCTL_NODE(_hw, OID_AUTO, ntb, CTLFLAG_RW, 0, "NTB sysctls"); /* * OS <-> Driver linkage functions */ static int ntb_probe(device_t device) { struct ntb_hw_info *p; p = ntb_get_device_info(pci_get_devid(device)); if (p == NULL) return (ENXIO); device_set_desc(device, p->desc); return (0); } static int ntb_attach(device_t device) { struct ntb_softc *ntb; struct ntb_hw_info *p; int error; ntb = device_get_softc(device); p = ntb_get_device_info(pci_get_devid(device)); ntb->device = device; ntb->type = p->type; ntb->features = p->features; ntb->b2b_mw_idx = B2B_MW_DISABLED; ntb->msix_mw_idx = B2B_MW_DISABLED; /* Heartbeat timer for NTB_ATOM since there is no link interrupt */ callout_init(&ntb->heartbeat_timer, CALLOUT_MPSAFE); callout_init(&ntb->lr_timer, CALLOUT_MPSAFE); callout_init(&ntb->peer_msix_work, 1); mtx_init(&ntb->db_mask_lock, "ntb hw bits", NULL, MTX_SPIN); rm_init(&ntb->ctx_lock, "ntb ctx"); if (ntb->type == NTB_ATOM) error = ntb_detect_atom(ntb); else error = ntb_detect_xeon(ntb); if (error != 0) goto out; ntb_detect_max_mw(ntb); pci_enable_busmaster(ntb->device); error = ntb_map_pci_bars(ntb); if (error != 0) goto out; if (ntb->type == NTB_ATOM) error = ntb_atom_init_dev(ntb); else error = ntb_xeon_init_dev(ntb); if (error != 0) goto out; ntb_spad_clear(device); ntb_poll_link(ntb); ntb_sysctl_init(ntb); /* Attach children to this controller */ device_add_child(device, NULL, -1); bus_generic_attach(device); out: if (error != 0) ntb_detach(device); return (error); } static int ntb_detach(device_t device) { struct ntb_softc *ntb; ntb = device_get_softc(device); /* Detach & delete all children */ device_delete_children(device); if (ntb->self_reg != NULL) { DB_MASK_LOCK(ntb); db_iowrite(ntb, ntb->self_reg->db_mask, ntb->db_valid_mask); DB_MASK_UNLOCK(ntb); } callout_drain(&ntb->heartbeat_timer); callout_drain(&ntb->lr_timer); callout_drain(&ntb->peer_msix_work); pci_disable_busmaster(ntb->device); if (ntb->type == NTB_XEON) ntb_teardown_xeon(ntb); ntb_teardown_interrupts(ntb); mtx_destroy(&ntb->db_mask_lock); rm_destroy(&ntb->ctx_lock); ntb_unmap_pci_bar(ntb); return (0); } /* * Driver internal routines */ static inline enum ntb_bar ntb_mw_to_bar(struct ntb_softc *ntb, unsigned mw) { KASSERT(mw < ntb->mw_count, ("%s: mw:%u > count:%u", __func__, mw, (unsigned)ntb->mw_count)); KASSERT(ntb->reg->mw_bar[mw] != 0, ("invalid mw")); return (ntb->reg->mw_bar[mw]); } static inline bool bar_is_64bit(struct ntb_softc *ntb, enum ntb_bar bar) { /* XXX This assertion could be stronger. */ KASSERT(bar < NTB_MAX_BARS, ("bogus bar")); return (bar < NTB_B2B_BAR_2 || !HAS_FEATURE(ntb, NTB_SPLIT_BAR)); } static inline void bar_get_xlat_params(struct ntb_softc *ntb, enum ntb_bar bar, uint32_t *base, uint32_t *xlat, uint32_t *lmt) { uint32_t basev, lmtv, xlatv; switch (bar) { case NTB_B2B_BAR_1: basev = ntb->xlat_reg->bar2_base; lmtv = ntb->xlat_reg->bar2_limit; xlatv = ntb->xlat_reg->bar2_xlat; break; case NTB_B2B_BAR_2: basev = ntb->xlat_reg->bar4_base; lmtv = ntb->xlat_reg->bar4_limit; xlatv = ntb->xlat_reg->bar4_xlat; break; case NTB_B2B_BAR_3: basev = ntb->xlat_reg->bar5_base; lmtv = ntb->xlat_reg->bar5_limit; xlatv = ntb->xlat_reg->bar5_xlat; break; default: KASSERT(bar >= NTB_B2B_BAR_1 && bar < NTB_MAX_BARS, ("bad bar")); basev = lmtv = xlatv = 0; break; } if (base != NULL) *base = basev; if (xlat != NULL) *xlat = xlatv; if (lmt != NULL) *lmt = lmtv; } static int ntb_map_pci_bars(struct ntb_softc *ntb) { int rc; ntb->bar_info[NTB_CONFIG_BAR].pci_resource_id = PCIR_BAR(0); rc = map_mmr_bar(ntb, &ntb->bar_info[NTB_CONFIG_BAR]); if (rc != 0) goto out; ntb->bar_info[NTB_B2B_BAR_1].pci_resource_id = PCIR_BAR(2); rc = map_memory_window_bar(ntb, &ntb->bar_info[NTB_B2B_BAR_1]); if (rc != 0) goto out; ntb->bar_info[NTB_B2B_BAR_1].psz_off = XEON_PBAR23SZ_OFFSET; ntb->bar_info[NTB_B2B_BAR_1].ssz_off = XEON_SBAR23SZ_OFFSET; ntb->bar_info[NTB_B2B_BAR_1].pbarxlat_off = XEON_PBAR2XLAT_OFFSET; ntb->bar_info[NTB_B2B_BAR_2].pci_resource_id = PCIR_BAR(4); rc = map_memory_window_bar(ntb, &ntb->bar_info[NTB_B2B_BAR_2]); if (rc != 0) goto out; ntb->bar_info[NTB_B2B_BAR_2].psz_off = XEON_PBAR4SZ_OFFSET; ntb->bar_info[NTB_B2B_BAR_2].ssz_off = XEON_SBAR4SZ_OFFSET; ntb->bar_info[NTB_B2B_BAR_2].pbarxlat_off = XEON_PBAR4XLAT_OFFSET; if (!HAS_FEATURE(ntb, NTB_SPLIT_BAR)) goto out; ntb->bar_info[NTB_B2B_BAR_3].pci_resource_id = PCIR_BAR(5); rc = map_memory_window_bar(ntb, &ntb->bar_info[NTB_B2B_BAR_3]); ntb->bar_info[NTB_B2B_BAR_3].psz_off = XEON_PBAR5SZ_OFFSET; ntb->bar_info[NTB_B2B_BAR_3].ssz_off = XEON_SBAR5SZ_OFFSET; ntb->bar_info[NTB_B2B_BAR_3].pbarxlat_off = XEON_PBAR5XLAT_OFFSET; out: if (rc != 0) device_printf(ntb->device, "unable to allocate pci resource\n"); return (rc); } static void print_map_success(struct ntb_softc *ntb, struct ntb_pci_bar_info *bar, const char *kind) { device_printf(ntb->device, "Mapped BAR%d v:[%p-%p] p:[%p-%p] (0x%jx bytes) (%s)\n", PCI_RID2BAR(bar->pci_resource_id), bar->vbase, (char *)bar->vbase + bar->size - 1, (void *)bar->pbase, (void *)(bar->pbase + bar->size - 1), (uintmax_t)bar->size, kind); } static int map_mmr_bar(struct ntb_softc *ntb, struct ntb_pci_bar_info *bar) { bar->pci_resource = bus_alloc_resource_any(ntb->device, SYS_RES_MEMORY, &bar->pci_resource_id, RF_ACTIVE); if (bar->pci_resource == NULL) return (ENXIO); save_bar_parameters(bar); bar->map_mode = VM_MEMATTR_UNCACHEABLE; print_map_success(ntb, bar, "mmr"); return (0); } static int map_memory_window_bar(struct ntb_softc *ntb, struct ntb_pci_bar_info *bar) { int rc; vm_memattr_t mapmode; uint8_t bar_size_bits = 0; bar->pci_resource = bus_alloc_resource_any(ntb->device, SYS_RES_MEMORY, &bar->pci_resource_id, RF_ACTIVE); if (bar->pci_resource == NULL) return (ENXIO); save_bar_parameters(bar); /* * Ivytown NTB BAR sizes are misreported by the hardware due to a * hardware issue. To work around this, query the size it should be * configured to by the device and modify the resource to correspond to * this new size. The BIOS on systems with this problem is required to * provide enough address space to allow the driver to make this change * safely. * * Ideally I could have just specified the size when I allocated the * resource like: * bus_alloc_resource(ntb->device, * SYS_RES_MEMORY, &bar->pci_resource_id, 0ul, ~0ul, * 1ul << bar_size_bits, RF_ACTIVE); * but the PCI driver does not honor the size in this call, so we have * to modify it after the fact. */ if (HAS_FEATURE(ntb, NTB_BAR_SIZE_4K)) { if (bar->pci_resource_id == PCIR_BAR(2)) bar_size_bits = pci_read_config(ntb->device, XEON_PBAR23SZ_OFFSET, 1); else bar_size_bits = pci_read_config(ntb->device, XEON_PBAR45SZ_OFFSET, 1); rc = bus_adjust_resource(ntb->device, SYS_RES_MEMORY, bar->pci_resource, bar->pbase, bar->pbase + (1ul << bar_size_bits) - 1); if (rc != 0) { device_printf(ntb->device, "unable to resize bar\n"); return (rc); } save_bar_parameters(bar); } bar->map_mode = VM_MEMATTR_UNCACHEABLE; print_map_success(ntb, bar, "mw"); /* * Optionally, mark MW BARs as anything other than UC to improve * performance. */ mapmode = ntb_pat_flags(); if (mapmode == bar->map_mode) return (0); rc = pmap_change_attr((vm_offset_t)bar->vbase, bar->size, mapmode); if (rc == 0) { bar->map_mode = mapmode; device_printf(ntb->device, "Marked BAR%d v:[%p-%p] p:[%p-%p] as " "%s.\n", PCI_RID2BAR(bar->pci_resource_id), bar->vbase, (char *)bar->vbase + bar->size - 1, (void *)bar->pbase, (void *)(bar->pbase + bar->size - 1), ntb_vm_memattr_to_str(mapmode)); } else device_printf(ntb->device, "Unable to mark BAR%d v:[%p-%p] p:[%p-%p] as " "%s: %d\n", PCI_RID2BAR(bar->pci_resource_id), bar->vbase, (char *)bar->vbase + bar->size - 1, (void *)bar->pbase, (void *)(bar->pbase + bar->size - 1), ntb_vm_memattr_to_str(mapmode), rc); /* Proceed anyway */ return (0); } static void ntb_unmap_pci_bar(struct ntb_softc *ntb) { struct ntb_pci_bar_info *current_bar; int i; for (i = 0; i < NTB_MAX_BARS; i++) { current_bar = &ntb->bar_info[i]; if (current_bar->pci_resource != NULL) bus_release_resource(ntb->device, SYS_RES_MEMORY, current_bar->pci_resource_id, current_bar->pci_resource); } } static int ntb_setup_msix(struct ntb_softc *ntb, uint32_t num_vectors) { uint32_t i; int rc; for (i = 0; i < num_vectors; i++) { ntb->int_info[i].rid = i + 1; ntb->int_info[i].res = bus_alloc_resource_any(ntb->device, SYS_RES_IRQ, &ntb->int_info[i].rid, RF_ACTIVE); if (ntb->int_info[i].res == NULL) { device_printf(ntb->device, "bus_alloc_resource failed\n"); return (ENOMEM); } ntb->int_info[i].tag = NULL; ntb->allocated_interrupts++; rc = bus_setup_intr(ntb->device, ntb->int_info[i].res, INTR_MPSAFE | INTR_TYPE_MISC, NULL, ndev_vec_isr, &ntb->msix_vec[i], &ntb->int_info[i].tag); if (rc != 0) { device_printf(ntb->device, "bus_setup_intr failed\n"); return (ENXIO); } } return (0); } /* * The Linux NTB driver drops from MSI-X to legacy INTx if a unique vector * cannot be allocated for each MSI-X message. JHB seems to think remapping * should be okay. This tunable should enable us to test that hypothesis * when someone gets their hands on some Xeon hardware. */ static int ntb_force_remap_mode; TUNABLE_INT("hw.ntb.force_remap_mode", &ntb_force_remap_mode); SYSCTL_INT(_hw_ntb, OID_AUTO, force_remap_mode, CTLFLAG_RDTUN, &ntb_force_remap_mode, 0, "If enabled, force MSI-X messages to be remapped" " to a smaller number of ithreads, even if the desired number are " "available"); /* * In case it is NOT ok, give consumers an abort button. */ static int ntb_prefer_intx; TUNABLE_INT("hw.ntb.prefer_intx_to_remap", &ntb_prefer_intx); SYSCTL_INT(_hw_ntb, OID_AUTO, prefer_intx_to_remap, CTLFLAG_RDTUN, &ntb_prefer_intx, 0, "If enabled, prefer to use legacy INTx mode rather " "than remapping MSI-X messages over available slots (match Linux driver " "behavior)"); /* * Remap the desired number of MSI-X messages to available ithreads in a simple * round-robin fashion. */ static int ntb_remap_msix(device_t dev, uint32_t desired, uint32_t avail) { u_int *vectors; uint32_t i; int rc; if (ntb_prefer_intx != 0) return (ENXIO); vectors = malloc(desired * sizeof(*vectors), M_NTB, M_ZERO | M_WAITOK); for (i = 0; i < desired; i++) vectors[i] = (i % avail) + 1; rc = pci_remap_msix(dev, desired, vectors); free(vectors, M_NTB); return (rc); } static int ntb_init_isr(struct ntb_softc *ntb) { uint32_t desired_vectors, num_vectors; int rc; ntb->allocated_interrupts = 0; ntb->last_ts = ticks; /* * Mask all doorbell interrupts. (Except link events!) */ DB_MASK_LOCK(ntb); ntb->db_mask = ntb->db_valid_mask; db_iowrite(ntb, ntb->self_reg->db_mask, ntb->db_mask); DB_MASK_UNLOCK(ntb); num_vectors = desired_vectors = MIN(pci_msix_count(ntb->device), ntb->db_count); if (desired_vectors >= 1) { rc = pci_alloc_msix(ntb->device, &num_vectors); if (ntb_force_remap_mode != 0 && rc == 0 && num_vectors == desired_vectors) num_vectors--; if (rc == 0 && num_vectors < desired_vectors) { rc = ntb_remap_msix(ntb->device, desired_vectors, num_vectors); if (rc == 0) num_vectors = desired_vectors; else pci_release_msi(ntb->device); } if (rc != 0) num_vectors = 1; } else num_vectors = 1; if (ntb->type == NTB_XEON && num_vectors < ntb->db_vec_count) { if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) { device_printf(ntb->device, "Errata workaround does not support MSI or INTX\n"); return (EINVAL); } ntb->db_vec_count = 1; ntb->db_vec_shift = XEON_DB_TOTAL_SHIFT; rc = ntb_setup_legacy_interrupt(ntb); } else { if (num_vectors - 1 != XEON_NONLINK_DB_MSIX_BITS && HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) { device_printf(ntb->device, "Errata workaround expects %d doorbell bits\n", XEON_NONLINK_DB_MSIX_BITS); return (EINVAL); } ntb_create_msix_vec(ntb, num_vectors); rc = ntb_setup_msix(ntb, num_vectors); if (rc == 0 && HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) ntb_get_msix_info(ntb); } if (rc != 0) { device_printf(ntb->device, "Error allocating interrupts: %d\n", rc); ntb_free_msix_vec(ntb); } return (rc); } static int ntb_setup_legacy_interrupt(struct ntb_softc *ntb) { int rc; ntb->int_info[0].rid = 0; ntb->int_info[0].res = bus_alloc_resource_any(ntb->device, SYS_RES_IRQ, &ntb->int_info[0].rid, RF_SHAREABLE|RF_ACTIVE); if (ntb->int_info[0].res == NULL) { device_printf(ntb->device, "bus_alloc_resource failed\n"); return (ENOMEM); } ntb->int_info[0].tag = NULL; ntb->allocated_interrupts = 1; rc = bus_setup_intr(ntb->device, ntb->int_info[0].res, INTR_MPSAFE | INTR_TYPE_MISC, NULL, ndev_irq_isr, ntb, &ntb->int_info[0].tag); if (rc != 0) { device_printf(ntb->device, "bus_setup_intr failed\n"); return (ENXIO); } return (0); } static void ntb_teardown_interrupts(struct ntb_softc *ntb) { struct ntb_int_info *current_int; int i; for (i = 0; i < ntb->allocated_interrupts; i++) { current_int = &ntb->int_info[i]; if (current_int->tag != NULL) bus_teardown_intr(ntb->device, current_int->res, current_int->tag); if (current_int->res != NULL) bus_release_resource(ntb->device, SYS_RES_IRQ, rman_get_rid(current_int->res), current_int->res); } ntb_free_msix_vec(ntb); pci_release_msi(ntb->device); } /* * Doorbell register and mask are 64-bit on Atom, 16-bit on Xeon. Abstract it * out to make code clearer. */ static inline uint64_t db_ioread(struct ntb_softc *ntb, uint64_t regoff) { if (ntb->type == NTB_ATOM) return (ntb_reg_read(8, regoff)); KASSERT(ntb->type == NTB_XEON, ("bad ntb type")); return (ntb_reg_read(2, regoff)); } static inline void db_iowrite(struct ntb_softc *ntb, uint64_t regoff, uint64_t val) { KASSERT((val & ~ntb->db_valid_mask) == 0, ("%s: Invalid bits 0x%jx (valid: 0x%jx)", __func__, (uintmax_t)(val & ~ntb->db_valid_mask), (uintmax_t)ntb->db_valid_mask)); if (regoff == ntb->self_reg->db_mask) DB_MASK_ASSERT(ntb, MA_OWNED); db_iowrite_raw(ntb, regoff, val); } static inline void db_iowrite_raw(struct ntb_softc *ntb, uint64_t regoff, uint64_t val) { if (ntb->type == NTB_ATOM) { ntb_reg_write(8, regoff, val); return; } KASSERT(ntb->type == NTB_XEON, ("bad ntb type")); ntb_reg_write(2, regoff, (uint16_t)val); } static void ntb_db_set_mask(device_t dev, uint64_t bits) { struct ntb_softc *ntb = device_get_softc(dev); DB_MASK_LOCK(ntb); ntb->db_mask |= bits; if (!HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) db_iowrite(ntb, ntb->self_reg->db_mask, ntb->db_mask); DB_MASK_UNLOCK(ntb); } static void ntb_db_clear_mask(device_t dev, uint64_t bits) { struct ntb_softc *ntb = device_get_softc(dev); uint64_t ibits; int i; KASSERT((bits & ~ntb->db_valid_mask) == 0, ("%s: Invalid bits 0x%jx (valid: 0x%jx)", __func__, (uintmax_t)(bits & ~ntb->db_valid_mask), (uintmax_t)ntb->db_valid_mask)); DB_MASK_LOCK(ntb); ibits = ntb->fake_db_bell & ntb->db_mask & bits; ntb->db_mask &= ~bits; if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) { /* Simulate fake interrupts if unmasked DB bits are set. */ for (i = 0; i < XEON_NONLINK_DB_MSIX_BITS; i++) { if ((ibits & ntb_db_vector_mask(dev, i)) != 0) swi_sched(ntb->int_info[i].tag, 0); } } else { db_iowrite(ntb, ntb->self_reg->db_mask, ntb->db_mask); } DB_MASK_UNLOCK(ntb); } static uint64_t ntb_db_read(device_t dev) { struct ntb_softc *ntb = device_get_softc(dev); if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) return (ntb->fake_db_bell); return (db_ioread(ntb, ntb->self_reg->db_bell)); } static void ntb_db_clear(device_t dev, uint64_t bits) { struct ntb_softc *ntb = device_get_softc(dev); KASSERT((bits & ~ntb->db_valid_mask) == 0, ("%s: Invalid bits 0x%jx (valid: 0x%jx)", __func__, (uintmax_t)(bits & ~ntb->db_valid_mask), (uintmax_t)ntb->db_valid_mask)); if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) { DB_MASK_LOCK(ntb); ntb->fake_db_bell &= ~bits; DB_MASK_UNLOCK(ntb); return; } db_iowrite(ntb, ntb->self_reg->db_bell, bits); } static inline uint64_t ntb_vec_mask(struct ntb_softc *ntb, uint64_t db_vector) { uint64_t shift, mask; if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) { /* * Remap vectors in custom way to make at least first * three doorbells to not generate stray events. * This breaks Linux compatibility (if one existed) * when more then one DB is used (not by if_ntb). */ if (db_vector < XEON_NONLINK_DB_MSIX_BITS - 1) return (1 << db_vector); if (db_vector == XEON_NONLINK_DB_MSIX_BITS - 1) return (0x7ffc); } shift = ntb->db_vec_shift; mask = (1ull << shift) - 1; return (mask << (shift * db_vector)); } static void ntb_interrupt(struct ntb_softc *ntb, uint32_t vec) { uint64_t vec_mask; ntb->last_ts = ticks; vec_mask = ntb_vec_mask(ntb, vec); if ((vec_mask & ntb->db_link_mask) != 0) { if (ntb_poll_link(ntb)) ntb_link_event(ntb->device); } if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP) && (vec_mask & ntb->db_link_mask) == 0) { DB_MASK_LOCK(ntb); /* Do not report same DB events again if not cleared yet. */ vec_mask &= ~ntb->fake_db_bell; /* Update our internal doorbell register. */ ntb->fake_db_bell |= vec_mask; /* Do not report masked DB events. */ vec_mask &= ~ntb->db_mask; DB_MASK_UNLOCK(ntb); } if ((vec_mask & ntb->db_valid_mask) != 0) ntb_db_event(ntb->device, vec); } static void ndev_vec_isr(void *arg) { struct ntb_vec *nvec = arg; ntb_interrupt(nvec->ntb, nvec->num); } static void ndev_irq_isr(void *arg) { /* If we couldn't set up MSI-X, we only have the one vector. */ ntb_interrupt(arg, 0); } static int ntb_create_msix_vec(struct ntb_softc *ntb, uint32_t num_vectors) { uint32_t i; ntb->msix_vec = malloc(num_vectors * sizeof(*ntb->msix_vec), M_NTB, M_ZERO | M_WAITOK); for (i = 0; i < num_vectors; i++) { ntb->msix_vec[i].num = i; ntb->msix_vec[i].ntb = ntb; } return (0); } static void ntb_free_msix_vec(struct ntb_softc *ntb) { if (ntb->msix_vec == NULL) return; free(ntb->msix_vec, M_NTB); ntb->msix_vec = NULL; } static void ntb_get_msix_info(struct ntb_softc *ntb) { struct pci_devinfo *dinfo; struct pcicfg_msix *msix; uint32_t laddr, data, i, offset; dinfo = device_get_ivars(ntb->device); msix = &dinfo->cfg.msix; CTASSERT(XEON_NONLINK_DB_MSIX_BITS == nitems(ntb->msix_data)); for (i = 0; i < XEON_NONLINK_DB_MSIX_BITS; i++) { offset = msix->msix_table_offset + i * PCI_MSIX_ENTRY_SIZE; laddr = bus_read_4(msix->msix_table_res, offset + PCI_MSIX_ENTRY_LOWER_ADDR); ntb_printf(2, "local MSIX addr(%u): 0x%x\n", i, laddr); KASSERT((laddr & MSI_INTEL_ADDR_BASE) == MSI_INTEL_ADDR_BASE, ("local MSIX addr 0x%x not in MSI base 0x%x", laddr, MSI_INTEL_ADDR_BASE)); ntb->msix_data[i].nmd_ofs = laddr; data = bus_read_4(msix->msix_table_res, offset + PCI_MSIX_ENTRY_DATA); ntb_printf(2, "local MSIX data(%u): 0x%x\n", i, data); ntb->msix_data[i].nmd_data = data; } } static struct ntb_hw_info * ntb_get_device_info(uint32_t device_id) { struct ntb_hw_info *ep = pci_ids; while (ep->device_id) { if (ep->device_id == device_id) return (ep); ++ep; } return (NULL); } static void ntb_teardown_xeon(struct ntb_softc *ntb) { if (ntb->reg != NULL) ntb_link_disable(ntb->device); } static void ntb_detect_max_mw(struct ntb_softc *ntb) { if (ntb->type == NTB_ATOM) { ntb->mw_count = ATOM_MW_COUNT; return; } if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) ntb->mw_count = XEON_HSX_SPLIT_MW_COUNT; else ntb->mw_count = XEON_SNB_MW_COUNT; } static int ntb_detect_xeon(struct ntb_softc *ntb) { uint8_t ppd, conn_type; ppd = pci_read_config(ntb->device, NTB_PPD_OFFSET, 1); ntb->ppd = ppd; if ((ppd & XEON_PPD_DEV_TYPE) != 0) ntb->dev_type = NTB_DEV_DSD; else ntb->dev_type = NTB_DEV_USD; if ((ppd & XEON_PPD_SPLIT_BAR) != 0) ntb->features |= NTB_SPLIT_BAR; + + if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP) && + !HAS_FEATURE(ntb, NTB_SPLIT_BAR)) { + device_printf(ntb->device, + "Can not apply SB01BASE_LOCKUP workaround " + "with split BARs disabled!\n"); + device_printf(ntb->device, + "Expect system hangs under heavy NTB traffic!\n"); + ntb->features &= ~NTB_SB01BASE_LOCKUP; + } /* * SDOORBELL errata workaround gets in the way of SB01BASE_LOCKUP * errata workaround; only do one at a time. */ if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) ntb->features &= ~NTB_SDOORBELL_LOCKUP; conn_type = ppd & XEON_PPD_CONN_TYPE; switch (conn_type) { case NTB_CONN_B2B: ntb->conn_type = conn_type; break; case NTB_CONN_RP: case NTB_CONN_TRANSPARENT: default: device_printf(ntb->device, "Unsupported connection type: %u\n", (unsigned)conn_type); return (ENXIO); } return (0); } static int ntb_detect_atom(struct ntb_softc *ntb) { uint32_t ppd, conn_type; ppd = pci_read_config(ntb->device, NTB_PPD_OFFSET, 4); ntb->ppd = ppd; if ((ppd & ATOM_PPD_DEV_TYPE) != 0) ntb->dev_type = NTB_DEV_DSD; else ntb->dev_type = NTB_DEV_USD; conn_type = (ppd & ATOM_PPD_CONN_TYPE) >> 8; switch (conn_type) { case NTB_CONN_B2B: ntb->conn_type = conn_type; break; default: device_printf(ntb->device, "Unsupported NTB configuration\n"); return (ENXIO); } return (0); } static int ntb_xeon_init_dev(struct ntb_softc *ntb) { int rc; ntb->spad_count = XEON_SPAD_COUNT; ntb->db_count = XEON_DB_COUNT; ntb->db_link_mask = XEON_DB_LINK_BIT; ntb->db_vec_count = XEON_DB_MSIX_VECTOR_COUNT; ntb->db_vec_shift = XEON_DB_MSIX_VECTOR_SHIFT; if (ntb->conn_type != NTB_CONN_B2B) { device_printf(ntb->device, "Connection type %d not supported\n", ntb->conn_type); return (ENXIO); } ntb->reg = &xeon_reg; ntb->self_reg = &xeon_pri_reg; ntb->peer_reg = &xeon_b2b_reg; ntb->xlat_reg = &xeon_sec_xlat; if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) { ntb->fake_db_bell = 0; ntb->msix_mw_idx = (ntb->mw_count + g_ntb_msix_idx) % ntb->mw_count; ntb_printf(2, "Setting up MSIX mw idx %d means %u\n", g_ntb_msix_idx, ntb->msix_mw_idx); rc = ntb_mw_set_wc_internal(ntb, ntb->msix_mw_idx, VM_MEMATTR_UNCACHEABLE); KASSERT(rc == 0, ("shouldn't fail")); } else if (HAS_FEATURE(ntb, NTB_SDOORBELL_LOCKUP)) { /* * There is a Xeon hardware errata related to writes to SDOORBELL or * B2BDOORBELL in conjunction with inbound access to NTB MMIO space, * which may hang the system. To workaround this, use a memory * window to access the interrupt and scratch pad registers on the * remote system. */ ntb->b2b_mw_idx = (ntb->mw_count + g_ntb_mw_idx) % ntb->mw_count; ntb_printf(2, "Setting up b2b mw idx %d means %u\n", g_ntb_mw_idx, ntb->b2b_mw_idx); rc = ntb_mw_set_wc_internal(ntb, ntb->b2b_mw_idx, VM_MEMATTR_UNCACHEABLE); KASSERT(rc == 0, ("shouldn't fail")); } else if (HAS_FEATURE(ntb, NTB_B2BDOORBELL_BIT14)) /* * HW Errata on bit 14 of b2bdoorbell register. Writes will not be * mirrored to the remote system. Shrink the number of bits by one, * since bit 14 is the last bit. * * On REGS_THRU_MW errata mode, we don't use the b2bdoorbell register * anyway. Nor for non-B2B connection types. */ ntb->db_count = XEON_DB_COUNT - 1; ntb->db_valid_mask = (1ull << ntb->db_count) - 1; if (ntb->dev_type == NTB_DEV_USD) rc = xeon_setup_b2b_mw(ntb, &xeon_b2b_dsd_addr, &xeon_b2b_usd_addr); else rc = xeon_setup_b2b_mw(ntb, &xeon_b2b_usd_addr, &xeon_b2b_dsd_addr); if (rc != 0) return (rc); /* Enable Bus Master and Memory Space on the secondary side */ ntb_reg_write(2, XEON_SPCICMD_OFFSET, PCIM_CMD_MEMEN | PCIM_CMD_BUSMASTEREN); /* * Mask all doorbell interrupts. */ DB_MASK_LOCK(ntb); ntb->db_mask = ntb->db_valid_mask; db_iowrite(ntb, ntb->self_reg->db_mask, ntb->db_mask); DB_MASK_UNLOCK(ntb); rc = ntb_init_isr(ntb); return (rc); } static int ntb_atom_init_dev(struct ntb_softc *ntb) { int error; KASSERT(ntb->conn_type == NTB_CONN_B2B, ("Unsupported NTB configuration (%d)\n", ntb->conn_type)); ntb->spad_count = ATOM_SPAD_COUNT; ntb->db_count = ATOM_DB_COUNT; ntb->db_vec_count = ATOM_DB_MSIX_VECTOR_COUNT; ntb->db_vec_shift = ATOM_DB_MSIX_VECTOR_SHIFT; ntb->db_valid_mask = (1ull << ntb->db_count) - 1; ntb->reg = &atom_reg; ntb->self_reg = &atom_pri_reg; ntb->peer_reg = &atom_b2b_reg; ntb->xlat_reg = &atom_sec_xlat; /* * FIXME - MSI-X bug on early Atom HW, remove once internal issue is * resolved. Mask transaction layer internal parity errors. */ pci_write_config(ntb->device, 0xFC, 0x4, 4); configure_atom_secondary_side_bars(ntb); /* Enable Bus Master and Memory Space on the secondary side */ ntb_reg_write(2, ATOM_SPCICMD_OFFSET, PCIM_CMD_MEMEN | PCIM_CMD_BUSMASTEREN); error = ntb_init_isr(ntb); if (error != 0) return (error); /* Initiate PCI-E link training */ ntb_link_enable(ntb->device, NTB_SPEED_AUTO, NTB_WIDTH_AUTO); callout_reset(&ntb->heartbeat_timer, 0, atom_link_hb, ntb); return (0); } /* XXX: Linux driver doesn't seem to do any of this for Atom. */ static void configure_atom_secondary_side_bars(struct ntb_softc *ntb) { if (ntb->dev_type == NTB_DEV_USD) { ntb_reg_write(8, ATOM_PBAR2XLAT_OFFSET, XEON_B2B_BAR2_ADDR64); ntb_reg_write(8, ATOM_PBAR4XLAT_OFFSET, XEON_B2B_BAR4_ADDR64); ntb_reg_write(8, ATOM_MBAR23_OFFSET, XEON_B2B_BAR2_ADDR64); ntb_reg_write(8, ATOM_MBAR45_OFFSET, XEON_B2B_BAR4_ADDR64); } else { ntb_reg_write(8, ATOM_PBAR2XLAT_OFFSET, XEON_B2B_BAR2_ADDR64); ntb_reg_write(8, ATOM_PBAR4XLAT_OFFSET, XEON_B2B_BAR4_ADDR64); ntb_reg_write(8, ATOM_MBAR23_OFFSET, XEON_B2B_BAR2_ADDR64); ntb_reg_write(8, ATOM_MBAR45_OFFSET, XEON_B2B_BAR4_ADDR64); } } /* * When working around Xeon SDOORBELL errata by remapping remote registers in a * MW, limit the B2B MW to half a MW. By sharing a MW, half the shared MW * remains for use by a higher layer. * * Will only be used if working around SDOORBELL errata and the BIOS-configured * MW size is sufficiently large. */ static unsigned int ntb_b2b_mw_share; TUNABLE_INT("hw.ntb.b2b_mw_share", &ntb_b2b_mw_share); SYSCTL_UINT(_hw_ntb, OID_AUTO, b2b_mw_share, CTLFLAG_RDTUN, &ntb_b2b_mw_share, 0, "If enabled (non-zero), prefer to share half of the B2B peer register " "MW with higher level consumers. Both sides of the NTB MUST set the same " "value here."); static void xeon_reset_sbar_size(struct ntb_softc *ntb, enum ntb_bar idx, enum ntb_bar regbar) { struct ntb_pci_bar_info *bar; uint8_t bar_sz; if (!HAS_FEATURE(ntb, NTB_SPLIT_BAR) && idx >= NTB_B2B_BAR_3) return; bar = &ntb->bar_info[idx]; bar_sz = pci_read_config(ntb->device, bar->psz_off, 1); if (idx == regbar) { if (ntb->b2b_off != 0) bar_sz--; else bar_sz = 0; } pci_write_config(ntb->device, bar->ssz_off, bar_sz, 1); bar_sz = pci_read_config(ntb->device, bar->ssz_off, 1); (void)bar_sz; } static void xeon_set_sbar_base_and_limit(struct ntb_softc *ntb, uint64_t bar_addr, enum ntb_bar idx, enum ntb_bar regbar) { uint64_t reg_val; uint32_t base_reg, lmt_reg; bar_get_xlat_params(ntb, idx, &base_reg, NULL, &lmt_reg); if (idx == regbar) { if (ntb->b2b_off) bar_addr += ntb->b2b_off; else bar_addr = 0; } /* * Set limit registers first to avoid an errata where setting the base * registers locks the limit registers. */ if (!bar_is_64bit(ntb, idx)) { ntb_reg_write(4, lmt_reg, bar_addr); reg_val = ntb_reg_read(4, lmt_reg); (void)reg_val; ntb_reg_write(4, base_reg, bar_addr); reg_val = ntb_reg_read(4, base_reg); (void)reg_val; } else { ntb_reg_write(8, lmt_reg, bar_addr); reg_val = ntb_reg_read(8, lmt_reg); (void)reg_val; ntb_reg_write(8, base_reg, bar_addr); reg_val = ntb_reg_read(8, base_reg); (void)reg_val; } } static void xeon_set_pbar_xlat(struct ntb_softc *ntb, uint64_t base_addr, enum ntb_bar idx) { struct ntb_pci_bar_info *bar; bar = &ntb->bar_info[idx]; if (HAS_FEATURE(ntb, NTB_SPLIT_BAR) && idx >= NTB_B2B_BAR_2) { ntb_reg_write(4, bar->pbarxlat_off, base_addr); base_addr = ntb_reg_read(4, bar->pbarxlat_off); } else { ntb_reg_write(8, bar->pbarxlat_off, base_addr); base_addr = ntb_reg_read(8, bar->pbarxlat_off); } (void)base_addr; } static int xeon_setup_b2b_mw(struct ntb_softc *ntb, const struct ntb_b2b_addr *addr, const struct ntb_b2b_addr *peer_addr) { struct ntb_pci_bar_info *b2b_bar; vm_size_t bar_size; uint64_t bar_addr; enum ntb_bar b2b_bar_num, i; if (ntb->b2b_mw_idx == B2B_MW_DISABLED) { b2b_bar = NULL; b2b_bar_num = NTB_CONFIG_BAR; ntb->b2b_off = 0; } else { b2b_bar_num = ntb_mw_to_bar(ntb, ntb->b2b_mw_idx); KASSERT(b2b_bar_num > 0 && b2b_bar_num < NTB_MAX_BARS, ("invalid b2b mw bar")); b2b_bar = &ntb->bar_info[b2b_bar_num]; bar_size = b2b_bar->size; if (ntb_b2b_mw_share != 0 && (bar_size >> 1) >= XEON_B2B_MIN_SIZE) ntb->b2b_off = bar_size >> 1; else if (bar_size >= XEON_B2B_MIN_SIZE) { ntb->b2b_off = 0; } else { device_printf(ntb->device, "B2B bar size is too small!\n"); return (EIO); } } /* * Reset the secondary bar sizes to match the primary bar sizes. * (Except, disable or halve the size of the B2B secondary bar.) */ for (i = NTB_B2B_BAR_1; i < NTB_MAX_BARS; i++) xeon_reset_sbar_size(ntb, i, b2b_bar_num); bar_addr = 0; if (b2b_bar_num == NTB_CONFIG_BAR) bar_addr = addr->bar0_addr; else if (b2b_bar_num == NTB_B2B_BAR_1) bar_addr = addr->bar2_addr64; else if (b2b_bar_num == NTB_B2B_BAR_2 && !HAS_FEATURE(ntb, NTB_SPLIT_BAR)) bar_addr = addr->bar4_addr64; else if (b2b_bar_num == NTB_B2B_BAR_2) bar_addr = addr->bar4_addr32; else if (b2b_bar_num == NTB_B2B_BAR_3) bar_addr = addr->bar5_addr32; else KASSERT(false, ("invalid bar")); ntb_reg_write(8, XEON_SBAR0BASE_OFFSET, bar_addr); /* * Other SBARs are normally hit by the PBAR xlat, except for the b2b * register BAR. The B2B BAR is either disabled above or configured * half-size. It starts at PBAR xlat + offset. * * Also set up incoming BAR limits == base (zero length window). */ xeon_set_sbar_base_and_limit(ntb, addr->bar2_addr64, NTB_B2B_BAR_1, b2b_bar_num); if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) { xeon_set_sbar_base_and_limit(ntb, addr->bar4_addr32, NTB_B2B_BAR_2, b2b_bar_num); xeon_set_sbar_base_and_limit(ntb, addr->bar5_addr32, NTB_B2B_BAR_3, b2b_bar_num); } else xeon_set_sbar_base_and_limit(ntb, addr->bar4_addr64, NTB_B2B_BAR_2, b2b_bar_num); /* Zero incoming translation addrs */ ntb_reg_write(8, XEON_SBAR2XLAT_OFFSET, 0); ntb_reg_write(8, XEON_SBAR4XLAT_OFFSET, 0); if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) { size_t size, xlatoffset; enum ntb_bar bar_num; bar_num = ntb_mw_to_bar(ntb, ntb->msix_mw_idx); switch (bar_num) { case NTB_B2B_BAR_1: size = 8; xlatoffset = XEON_SBAR2XLAT_OFFSET; break; case NTB_B2B_BAR_2: xlatoffset = XEON_SBAR4XLAT_OFFSET; if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) size = 4; else size = 8; break; case NTB_B2B_BAR_3: xlatoffset = XEON_SBAR5XLAT_OFFSET; size = 4; break; default: KASSERT(false, ("Bogus msix mw idx: %u", ntb->msix_mw_idx)); return (EINVAL); } /* * We point the chosen MSIX MW BAR xlat to remote LAPIC for * workaround */ if (size == 4) { ntb_reg_write(4, xlatoffset, MSI_INTEL_ADDR_BASE); ntb->msix_xlat = ntb_reg_read(4, xlatoffset); } else { ntb_reg_write(8, xlatoffset, MSI_INTEL_ADDR_BASE); ntb->msix_xlat = ntb_reg_read(8, xlatoffset); } ntb->peer_lapic_bar = &ntb->bar_info[bar_num]; } (void)ntb_reg_read(8, XEON_SBAR2XLAT_OFFSET); (void)ntb_reg_read(8, XEON_SBAR4XLAT_OFFSET); /* Zero outgoing translation limits (whole bar size windows) */ ntb_reg_write(8, XEON_PBAR2LMT_OFFSET, 0); ntb_reg_write(8, XEON_PBAR4LMT_OFFSET, 0); /* Set outgoing translation offsets */ xeon_set_pbar_xlat(ntb, peer_addr->bar2_addr64, NTB_B2B_BAR_1); if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) { xeon_set_pbar_xlat(ntb, peer_addr->bar4_addr32, NTB_B2B_BAR_2); xeon_set_pbar_xlat(ntb, peer_addr->bar5_addr32, NTB_B2B_BAR_3); } else xeon_set_pbar_xlat(ntb, peer_addr->bar4_addr64, NTB_B2B_BAR_2); /* Set the translation offset for B2B registers */ bar_addr = 0; if (b2b_bar_num == NTB_CONFIG_BAR) bar_addr = peer_addr->bar0_addr; else if (b2b_bar_num == NTB_B2B_BAR_1) bar_addr = peer_addr->bar2_addr64; else if (b2b_bar_num == NTB_B2B_BAR_2 && !HAS_FEATURE(ntb, NTB_SPLIT_BAR)) bar_addr = peer_addr->bar4_addr64; else if (b2b_bar_num == NTB_B2B_BAR_2) bar_addr = peer_addr->bar4_addr32; else if (b2b_bar_num == NTB_B2B_BAR_3) bar_addr = peer_addr->bar5_addr32; else KASSERT(false, ("invalid bar")); /* * B2B_XLAT_OFFSET is a 64-bit register but can only be written 32 bits * at a time. */ ntb_reg_write(4, XEON_B2B_XLAT_OFFSETL, bar_addr & 0xffffffff); ntb_reg_write(4, XEON_B2B_XLAT_OFFSETU, bar_addr >> 32); return (0); } static inline bool _xeon_link_is_up(struct ntb_softc *ntb) { if (ntb->conn_type == NTB_CONN_TRANSPARENT) return (true); return ((ntb->lnk_sta & NTB_LINK_STATUS_ACTIVE) != 0); } static inline bool link_is_up(struct ntb_softc *ntb) { if (ntb->type == NTB_XEON) return (_xeon_link_is_up(ntb) && (ntb->peer_msix_good || !HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP))); KASSERT(ntb->type == NTB_ATOM, ("ntb type")); return ((ntb->ntb_ctl & ATOM_CNTL_LINK_DOWN) == 0); } static inline bool atom_link_is_err(struct ntb_softc *ntb) { uint32_t status; KASSERT(ntb->type == NTB_ATOM, ("ntb type")); status = ntb_reg_read(4, ATOM_LTSSMSTATEJMP_OFFSET); if ((status & ATOM_LTSSMSTATEJMP_FORCEDETECT) != 0) return (true); status = ntb_reg_read(4, ATOM_IBSTERRRCRVSTS0_OFFSET); return ((status & ATOM_IBIST_ERR_OFLOW) != 0); } /* Atom does not have link status interrupt, poll on that platform */ static void atom_link_hb(void *arg) { struct ntb_softc *ntb = arg; sbintime_t timo, poll_ts; timo = NTB_HB_TIMEOUT * hz; poll_ts = ntb->last_ts + timo; /* * Delay polling the link status if an interrupt was received, unless * the cached link status says the link is down. */ if ((sbintime_t)ticks - poll_ts < 0 && link_is_up(ntb)) { timo = poll_ts - ticks; goto out; } if (ntb_poll_link(ntb)) ntb_link_event(ntb->device); if (!link_is_up(ntb) && atom_link_is_err(ntb)) { /* Link is down with error, proceed with recovery */ callout_reset(&ntb->lr_timer, 0, recover_atom_link, ntb); return; } out: callout_reset(&ntb->heartbeat_timer, timo, atom_link_hb, ntb); } static void atom_perform_link_restart(struct ntb_softc *ntb) { uint32_t status; /* Driver resets the NTB ModPhy lanes - magic! */ ntb_reg_write(1, ATOM_MODPHY_PCSREG6, 0xe0); ntb_reg_write(1, ATOM_MODPHY_PCSREG4, 0x40); ntb_reg_write(1, ATOM_MODPHY_PCSREG4, 0x60); ntb_reg_write(1, ATOM_MODPHY_PCSREG6, 0x60); /* Driver waits 100ms to allow the NTB ModPhy to settle */ pause("ModPhy", hz / 10); /* Clear AER Errors, write to clear */ status = ntb_reg_read(4, ATOM_ERRCORSTS_OFFSET); status &= PCIM_AER_COR_REPLAY_ROLLOVER; ntb_reg_write(4, ATOM_ERRCORSTS_OFFSET, status); /* Clear unexpected electrical idle event in LTSSM, write to clear */ status = ntb_reg_read(4, ATOM_LTSSMERRSTS0_OFFSET); status |= ATOM_LTSSMERRSTS0_UNEXPECTEDEI; ntb_reg_write(4, ATOM_LTSSMERRSTS0_OFFSET, status); /* Clear DeSkew Buffer error, write to clear */ status = ntb_reg_read(4, ATOM_DESKEWSTS_OFFSET); status |= ATOM_DESKEWSTS_DBERR; ntb_reg_write(4, ATOM_DESKEWSTS_OFFSET, status); status = ntb_reg_read(4, ATOM_IBSTERRRCRVSTS0_OFFSET); status &= ATOM_IBIST_ERR_OFLOW; ntb_reg_write(4, ATOM_IBSTERRRCRVSTS0_OFFSET, status); /* Releases the NTB state machine to allow the link to retrain */ status = ntb_reg_read(4, ATOM_LTSSMSTATEJMP_OFFSET); status &= ~ATOM_LTSSMSTATEJMP_FORCEDETECT; ntb_reg_write(4, ATOM_LTSSMSTATEJMP_OFFSET, status); } static int ntb_set_ctx(device_t dev, void *ctx, const struct ntb_ctx_ops *ops) { struct ntb_softc *ntb = device_get_softc(dev); if (ctx == NULL || ops == NULL) return (EINVAL); rm_wlock(&ntb->ctx_lock); if (ntb->ctx_ops != NULL) { rm_wunlock(&ntb->ctx_lock); return (EINVAL); } ntb->ntb_ctx = ctx; ntb->ctx_ops = ops; rm_wunlock(&ntb->ctx_lock); return (0); } /* * It is expected that this will only be used from contexts where the ctx_lock * is not needed to protect ntb_ctx lifetime. */ static void * ntb_get_ctx(device_t dev, const struct ntb_ctx_ops **ops) { struct ntb_softc *ntb = device_get_softc(dev); KASSERT(ntb->ntb_ctx != NULL && ntb->ctx_ops != NULL, ("bogus")); if (ops != NULL) *ops = ntb->ctx_ops; return (ntb->ntb_ctx); } static void ntb_clear_ctx(device_t dev) { struct ntb_softc *ntb = device_get_softc(dev); rm_wlock(&ntb->ctx_lock); ntb->ntb_ctx = NULL; ntb->ctx_ops = NULL; rm_wunlock(&ntb->ctx_lock); } /* * ntb_link_event() - notify driver context of a change in link status * @ntb: NTB device context * * Notify the driver context that the link status may have changed. The driver * should call ntb_link_is_up() to get the current status. */ static void ntb_link_event(device_t dev) { struct ntb_softc *ntb = device_get_softc(dev); struct rm_priotracker ctx_tracker; rm_rlock(&ntb->ctx_lock, &ctx_tracker); if (ntb->ctx_ops != NULL && ntb->ctx_ops->link_event != NULL) ntb->ctx_ops->link_event(ntb->ntb_ctx); rm_runlock(&ntb->ctx_lock, &ctx_tracker); } /* * ntb_db_event() - notify driver context of a doorbell event * @ntb: NTB device context * @vector: Interrupt vector number * * Notify the driver context of a doorbell event. If hardware supports * multiple interrupt vectors for doorbells, the vector number indicates which * vector received the interrupt. The vector number is relative to the first * vector used for doorbells, starting at zero, and must be less than * ntb_db_vector_count(). The driver may call ntb_db_read() to check which * doorbell bits need service, and ntb_db_vector_mask() to determine which of * those bits are associated with the vector number. */ static void ntb_db_event(device_t dev, uint32_t vec) { struct ntb_softc *ntb = device_get_softc(dev); struct rm_priotracker ctx_tracker; rm_rlock(&ntb->ctx_lock, &ctx_tracker); if (ntb->ctx_ops != NULL && ntb->ctx_ops->db_event != NULL) ntb->ctx_ops->db_event(ntb->ntb_ctx, vec); rm_runlock(&ntb->ctx_lock, &ctx_tracker); } static int ntb_link_enable(device_t dev, enum ntb_speed speed __unused, enum ntb_width width __unused) { struct ntb_softc *ntb = device_get_softc(dev); uint32_t cntl; ntb_printf(2, "%s\n", __func__); if (ntb->type == NTB_ATOM) { pci_write_config(ntb->device, NTB_PPD_OFFSET, ntb->ppd | ATOM_PPD_INIT_LINK, 4); return (0); } if (ntb->conn_type == NTB_CONN_TRANSPARENT) { ntb_link_event(dev); return (0); } cntl = ntb_reg_read(4, ntb->reg->ntb_ctl); cntl &= ~(NTB_CNTL_LINK_DISABLE | NTB_CNTL_CFG_LOCK); cntl |= NTB_CNTL_P2S_BAR23_SNOOP | NTB_CNTL_S2P_BAR23_SNOOP; cntl |= NTB_CNTL_P2S_BAR4_SNOOP | NTB_CNTL_S2P_BAR4_SNOOP; if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) cntl |= NTB_CNTL_P2S_BAR5_SNOOP | NTB_CNTL_S2P_BAR5_SNOOP; ntb_reg_write(4, ntb->reg->ntb_ctl, cntl); return (0); } static int ntb_link_disable(device_t dev) { struct ntb_softc *ntb = device_get_softc(dev); uint32_t cntl; ntb_printf(2, "%s\n", __func__); if (ntb->conn_type == NTB_CONN_TRANSPARENT) { ntb_link_event(dev); return (0); } cntl = ntb_reg_read(4, ntb->reg->ntb_ctl); cntl &= ~(NTB_CNTL_P2S_BAR23_SNOOP | NTB_CNTL_S2P_BAR23_SNOOP); cntl &= ~(NTB_CNTL_P2S_BAR4_SNOOP | NTB_CNTL_S2P_BAR4_SNOOP); if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) cntl &= ~(NTB_CNTL_P2S_BAR5_SNOOP | NTB_CNTL_S2P_BAR5_SNOOP); cntl |= NTB_CNTL_LINK_DISABLE | NTB_CNTL_CFG_LOCK; ntb_reg_write(4, ntb->reg->ntb_ctl, cntl); return (0); } static bool ntb_link_enabled(device_t dev) { struct ntb_softc *ntb = device_get_softc(dev); uint32_t cntl; if (ntb->type == NTB_ATOM) { cntl = pci_read_config(ntb->device, NTB_PPD_OFFSET, 4); return ((cntl & ATOM_PPD_INIT_LINK) != 0); } if (ntb->conn_type == NTB_CONN_TRANSPARENT) return (true); cntl = ntb_reg_read(4, ntb->reg->ntb_ctl); return ((cntl & NTB_CNTL_LINK_DISABLE) == 0); } static void recover_atom_link(void *arg) { struct ntb_softc *ntb = arg; unsigned speed, width, oldspeed, oldwidth; uint32_t status32; atom_perform_link_restart(ntb); /* * There is a potential race between the 2 NTB devices recovering at * the same time. If the times are the same, the link will not recover * and the driver will be stuck in this loop forever. Add a random * interval to the recovery time to prevent this race. */ status32 = arc4random() % ATOM_LINK_RECOVERY_TIME; pause("Link", (ATOM_LINK_RECOVERY_TIME + status32) * hz / 1000); if (atom_link_is_err(ntb)) goto retry; status32 = ntb_reg_read(4, ntb->reg->ntb_ctl); if ((status32 & ATOM_CNTL_LINK_DOWN) != 0) goto out; status32 = ntb_reg_read(4, ntb->reg->lnk_sta); width = NTB_LNK_STA_WIDTH(status32); speed = status32 & NTB_LINK_SPEED_MASK; oldwidth = NTB_LNK_STA_WIDTH(ntb->lnk_sta); oldspeed = ntb->lnk_sta & NTB_LINK_SPEED_MASK; if (oldwidth != width || oldspeed != speed) goto retry; out: callout_reset(&ntb->heartbeat_timer, NTB_HB_TIMEOUT * hz, atom_link_hb, ntb); return; retry: callout_reset(&ntb->lr_timer, NTB_HB_TIMEOUT * hz, recover_atom_link, ntb); } /* * Polls the HW link status register(s); returns true if something has changed. */ static bool ntb_poll_link(struct ntb_softc *ntb) { uint32_t ntb_cntl; uint16_t reg_val; if (ntb->type == NTB_ATOM) { ntb_cntl = ntb_reg_read(4, ntb->reg->ntb_ctl); if (ntb_cntl == ntb->ntb_ctl) return (false); ntb->ntb_ctl = ntb_cntl; ntb->lnk_sta = ntb_reg_read(4, ntb->reg->lnk_sta); } else { db_iowrite_raw(ntb, ntb->self_reg->db_bell, ntb->db_link_mask); reg_val = pci_read_config(ntb->device, ntb->reg->lnk_sta, 2); if (reg_val == ntb->lnk_sta) return (false); ntb->lnk_sta = reg_val; if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) { if (_xeon_link_is_up(ntb)) { if (!ntb->peer_msix_good) { callout_reset(&ntb->peer_msix_work, 0, ntb_exchange_msix, ntb); return (false); } } else { ntb->peer_msix_good = false; ntb->peer_msix_done = false; } } } return (true); } static inline enum ntb_speed ntb_link_sta_speed(struct ntb_softc *ntb) { if (!link_is_up(ntb)) return (NTB_SPEED_NONE); return (ntb->lnk_sta & NTB_LINK_SPEED_MASK); } static inline enum ntb_width ntb_link_sta_width(struct ntb_softc *ntb) { if (!link_is_up(ntb)) return (NTB_WIDTH_NONE); return (NTB_LNK_STA_WIDTH(ntb->lnk_sta)); } SYSCTL_NODE(_hw_ntb, OID_AUTO, debug_info, CTLFLAG_RW, 0, "Driver state, statistics, and HW registers"); #define NTB_REGSZ_MASK (3ul << 30) #define NTB_REG_64 (1ul << 30) #define NTB_REG_32 (2ul << 30) #define NTB_REG_16 (3ul << 30) #define NTB_REG_8 (0ul << 30) #define NTB_DB_READ (1ul << 29) #define NTB_PCI_REG (1ul << 28) #define NTB_REGFLAGS_MASK (NTB_REGSZ_MASK | NTB_DB_READ | NTB_PCI_REG) static void ntb_sysctl_init(struct ntb_softc *ntb) { struct sysctl_oid_list *globals, *tree_par, *regpar, *statpar, *errpar; struct sysctl_ctx_list *ctx; struct sysctl_oid *tree, *tmptree; ctx = device_get_sysctl_ctx(ntb->device); globals = SYSCTL_CHILDREN(device_get_sysctl_tree(ntb->device)); SYSCTL_ADD_PROC(ctx, globals, OID_AUTO, "link_status", CTLFLAG_RD | CTLTYPE_STRING, ntb, 0, sysctl_handle_link_status_human, "A", "Link status (human readable)"); SYSCTL_ADD_PROC(ctx, globals, OID_AUTO, "active", CTLFLAG_RD | CTLTYPE_UINT, ntb, 0, sysctl_handle_link_status, "IU", "Link status (1=active, 0=inactive)"); SYSCTL_ADD_PROC(ctx, globals, OID_AUTO, "admin_up", CTLFLAG_RW | CTLTYPE_UINT, ntb, 0, sysctl_handle_link_admin, "IU", "Set/get interface status (1=UP, 0=DOWN)"); tree = SYSCTL_ADD_NODE(ctx, globals, OID_AUTO, "debug_info", CTLFLAG_RD, NULL, "Driver state, statistics, and HW registers"); tree_par = SYSCTL_CHILDREN(tree); SYSCTL_ADD_UINT(ctx, tree_par, OID_AUTO, "conn_type", CTLFLAG_RD, &ntb->conn_type, 0, "0 - Transparent; 1 - B2B; 2 - Root Port"); SYSCTL_ADD_UINT(ctx, tree_par, OID_AUTO, "dev_type", CTLFLAG_RD, &ntb->dev_type, 0, "0 - USD; 1 - DSD"); SYSCTL_ADD_UINT(ctx, tree_par, OID_AUTO, "ppd", CTLFLAG_RD, &ntb->ppd, 0, "Raw PPD register (cached)"); if (ntb->b2b_mw_idx != B2B_MW_DISABLED) { #ifdef notyet SYSCTL_ADD_U8(ctx, tree_par, OID_AUTO, "b2b_idx", CTLFLAG_RD, &ntb->b2b_mw_idx, 0, "Index of the MW used for B2B remote register access"); #endif SYSCTL_ADD_UQUAD(ctx, tree_par, OID_AUTO, "b2b_off", CTLFLAG_RD, &ntb->b2b_off, "If non-zero, offset of B2B register region in shared MW"); } SYSCTL_ADD_PROC(ctx, tree_par, OID_AUTO, "features", CTLFLAG_RD | CTLTYPE_STRING, ntb, 0, sysctl_handle_features, "A", "Features/errata of this NTB device"); SYSCTL_ADD_UINT(ctx, tree_par, OID_AUTO, "ntb_ctl", CTLFLAG_RD, __DEVOLATILE(uint32_t *, &ntb->ntb_ctl), 0, "NTB CTL register (cached)"); SYSCTL_ADD_UINT(ctx, tree_par, OID_AUTO, "lnk_sta", CTLFLAG_RD, __DEVOLATILE(uint32_t *, &ntb->lnk_sta), 0, "LNK STA register (cached)"); #ifdef notyet SYSCTL_ADD_U8(ctx, tree_par, OID_AUTO, "mw_count", CTLFLAG_RD, &ntb->mw_count, 0, "MW count"); SYSCTL_ADD_U8(ctx, tree_par, OID_AUTO, "spad_count", CTLFLAG_RD, &ntb->spad_count, 0, "Scratchpad count"); SYSCTL_ADD_U8(ctx, tree_par, OID_AUTO, "db_count", CTLFLAG_RD, &ntb->db_count, 0, "Doorbell count"); SYSCTL_ADD_U8(ctx, tree_par, OID_AUTO, "db_vec_count", CTLFLAG_RD, &ntb->db_vec_count, 0, "Doorbell vector count"); SYSCTL_ADD_U8(ctx, tree_par, OID_AUTO, "db_vec_shift", CTLFLAG_RD, &ntb->db_vec_shift, 0, "Doorbell vector shift"); #endif SYSCTL_ADD_UQUAD(ctx, tree_par, OID_AUTO, "db_valid_mask", CTLFLAG_RD, &ntb->db_valid_mask, "Doorbell valid mask"); SYSCTL_ADD_UQUAD(ctx, tree_par, OID_AUTO, "db_link_mask", CTLFLAG_RD, &ntb->db_link_mask, "Doorbell link mask"); SYSCTL_ADD_UQUAD(ctx, tree_par, OID_AUTO, "db_mask", CTLFLAG_RD, &ntb->db_mask, "Doorbell mask (cached)"); tmptree = SYSCTL_ADD_NODE(ctx, tree_par, OID_AUTO, "registers", CTLFLAG_RD, NULL, "Raw HW registers (big-endian)"); regpar = SYSCTL_CHILDREN(tmptree); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "ntbcntl", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | ntb->reg->ntb_ctl, sysctl_handle_register, "IU", "NTB Control register"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "lnkcap", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | 0x19c, sysctl_handle_register, "IU", "NTB Link Capabilities"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "lnkcon", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | 0x1a0, sysctl_handle_register, "IU", "NTB Link Control register"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "db_mask", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | NTB_DB_READ | ntb->self_reg->db_mask, sysctl_handle_register, "QU", "Doorbell mask register"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "db_bell", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | NTB_DB_READ | ntb->self_reg->db_bell, sysctl_handle_register, "QU", "Doorbell register"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "incoming_xlat23", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | ntb->xlat_reg->bar2_xlat, sysctl_handle_register, "QU", "Incoming XLAT23 register"); if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) { SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "incoming_xlat4", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | ntb->xlat_reg->bar4_xlat, sysctl_handle_register, "IU", "Incoming XLAT4 register"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "incoming_xlat5", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | ntb->xlat_reg->bar5_xlat, sysctl_handle_register, "IU", "Incoming XLAT5 register"); } else { SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "incoming_xlat45", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | ntb->xlat_reg->bar4_xlat, sysctl_handle_register, "QU", "Incoming XLAT45 register"); } SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "incoming_lmt23", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | ntb->xlat_reg->bar2_limit, sysctl_handle_register, "QU", "Incoming LMT23 register"); if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) { SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "incoming_lmt4", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | ntb->xlat_reg->bar4_limit, sysctl_handle_register, "IU", "Incoming LMT4 register"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "incoming_lmt5", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | ntb->xlat_reg->bar5_limit, sysctl_handle_register, "IU", "Incoming LMT5 register"); } else { SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "incoming_lmt45", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | ntb->xlat_reg->bar4_limit, sysctl_handle_register, "QU", "Incoming LMT45 register"); } if (ntb->type == NTB_ATOM) return; tmptree = SYSCTL_ADD_NODE(ctx, regpar, OID_AUTO, "xeon_stats", CTLFLAG_RD, NULL, "Xeon HW statistics"); statpar = SYSCTL_CHILDREN(tmptree); SYSCTL_ADD_PROC(ctx, statpar, OID_AUTO, "upstream_mem_miss", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_16 | XEON_USMEMMISS_OFFSET, sysctl_handle_register, "SU", "Upstream Memory Miss"); tmptree = SYSCTL_ADD_NODE(ctx, regpar, OID_AUTO, "xeon_hw_err", CTLFLAG_RD, NULL, "Xeon HW errors"); errpar = SYSCTL_CHILDREN(tmptree); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "ppd", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_8 | NTB_PCI_REG | NTB_PPD_OFFSET, sysctl_handle_register, "CU", "PPD"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "pbar23_sz", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_8 | NTB_PCI_REG | XEON_PBAR23SZ_OFFSET, sysctl_handle_register, "CU", "PBAR23 SZ (log2)"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "pbar4_sz", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_8 | NTB_PCI_REG | XEON_PBAR4SZ_OFFSET, sysctl_handle_register, "CU", "PBAR4 SZ (log2)"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "pbar5_sz", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_8 | NTB_PCI_REG | XEON_PBAR5SZ_OFFSET, sysctl_handle_register, "CU", "PBAR5 SZ (log2)"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "sbar23_sz", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_8 | NTB_PCI_REG | XEON_SBAR23SZ_OFFSET, sysctl_handle_register, "CU", "SBAR23 SZ (log2)"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "sbar4_sz", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_8 | NTB_PCI_REG | XEON_SBAR4SZ_OFFSET, sysctl_handle_register, "CU", "SBAR4 SZ (log2)"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "sbar5_sz", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_8 | NTB_PCI_REG | XEON_SBAR5SZ_OFFSET, sysctl_handle_register, "CU", "SBAR5 SZ (log2)"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "devsts", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_16 | NTB_PCI_REG | XEON_DEVSTS_OFFSET, sysctl_handle_register, "SU", "DEVSTS"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "lnksts", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_16 | NTB_PCI_REG | XEON_LINK_STATUS_OFFSET, sysctl_handle_register, "SU", "LNKSTS"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "slnksts", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_16 | NTB_PCI_REG | XEON_SLINK_STATUS_OFFSET, sysctl_handle_register, "SU", "SLNKSTS"); SYSCTL_ADD_PROC(ctx, errpar, OID_AUTO, "uncerrsts", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | NTB_PCI_REG | XEON_UNCERRSTS_OFFSET, sysctl_handle_register, "IU", "UNCERRSTS"); SYSCTL_ADD_PROC(ctx, errpar, OID_AUTO, "corerrsts", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | NTB_PCI_REG | XEON_CORERRSTS_OFFSET, sysctl_handle_register, "IU", "CORERRSTS"); if (ntb->conn_type != NTB_CONN_B2B) return; SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "outgoing_xlat23", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | ntb->bar_info[NTB_B2B_BAR_1].pbarxlat_off, sysctl_handle_register, "QU", "Outgoing XLAT23 register"); if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) { SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "outgoing_xlat4", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | ntb->bar_info[NTB_B2B_BAR_2].pbarxlat_off, sysctl_handle_register, "IU", "Outgoing XLAT4 register"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "outgoing_xlat5", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | ntb->bar_info[NTB_B2B_BAR_3].pbarxlat_off, sysctl_handle_register, "IU", "Outgoing XLAT5 register"); } else { SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "outgoing_xlat45", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | ntb->bar_info[NTB_B2B_BAR_2].pbarxlat_off, sysctl_handle_register, "QU", "Outgoing XLAT45 register"); } SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "outgoing_lmt23", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | XEON_PBAR2LMT_OFFSET, sysctl_handle_register, "QU", "Outgoing LMT23 register"); if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) { SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "outgoing_lmt4", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | XEON_PBAR4LMT_OFFSET, sysctl_handle_register, "IU", "Outgoing LMT4 register"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "outgoing_lmt5", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | XEON_PBAR5LMT_OFFSET, sysctl_handle_register, "IU", "Outgoing LMT5 register"); } else { SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "outgoing_lmt45", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | XEON_PBAR4LMT_OFFSET, sysctl_handle_register, "QU", "Outgoing LMT45 register"); } SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "sbar01_base", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | ntb->xlat_reg->bar0_base, sysctl_handle_register, "QU", "Secondary BAR01 base register"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "sbar23_base", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | ntb->xlat_reg->bar2_base, sysctl_handle_register, "QU", "Secondary BAR23 base register"); if (HAS_FEATURE(ntb, NTB_SPLIT_BAR)) { SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "sbar4_base", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | ntb->xlat_reg->bar4_base, sysctl_handle_register, "IU", "Secondary BAR4 base register"); SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "sbar5_base", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_32 | ntb->xlat_reg->bar5_base, sysctl_handle_register, "IU", "Secondary BAR5 base register"); } else { SYSCTL_ADD_PROC(ctx, regpar, OID_AUTO, "sbar45_base", CTLFLAG_RD | CTLTYPE_OPAQUE, ntb, NTB_REG_64 | ntb->xlat_reg->bar4_base, sysctl_handle_register, "QU", "Secondary BAR45 base register"); } } static int sysctl_handle_features(SYSCTL_HANDLER_ARGS) { struct ntb_softc *ntb = arg1; struct sbuf sb; int error; sbuf_new_for_sysctl(&sb, NULL, 256, req); sbuf_printf(&sb, "%b", ntb->features, NTB_FEATURES_STR); error = sbuf_finish(&sb); sbuf_delete(&sb); if (error || !req->newptr) return (error); return (EINVAL); } static int sysctl_handle_link_admin(SYSCTL_HANDLER_ARGS) { struct ntb_softc *ntb = arg1; unsigned old, new; int error; old = ntb_link_enabled(ntb->device); error = SYSCTL_OUT(req, &old, sizeof(old)); if (error != 0 || req->newptr == NULL) return (error); error = SYSCTL_IN(req, &new, sizeof(new)); if (error != 0) return (error); ntb_printf(0, "Admin set interface state to '%sabled'\n", (new != 0)? "en" : "dis"); if (new != 0) error = ntb_link_enable(ntb->device, NTB_SPEED_AUTO, NTB_WIDTH_AUTO); else error = ntb_link_disable(ntb->device); return (error); } static int sysctl_handle_link_status_human(SYSCTL_HANDLER_ARGS) { struct ntb_softc *ntb = arg1; struct sbuf sb; enum ntb_speed speed; enum ntb_width width; int error; sbuf_new_for_sysctl(&sb, NULL, 32, req); if (ntb_link_is_up(ntb->device, &speed, &width)) sbuf_printf(&sb, "up / PCIe Gen %u / Width x%u", (unsigned)speed, (unsigned)width); else sbuf_printf(&sb, "down"); error = sbuf_finish(&sb); sbuf_delete(&sb); if (error || !req->newptr) return (error); return (EINVAL); } static int sysctl_handle_link_status(SYSCTL_HANDLER_ARGS) { struct ntb_softc *ntb = arg1; unsigned res; int error; res = ntb_link_is_up(ntb->device, NULL, NULL); error = SYSCTL_OUT(req, &res, sizeof(res)); if (error || !req->newptr) return (error); return (EINVAL); } static int sysctl_handle_register(SYSCTL_HANDLER_ARGS) { struct ntb_softc *ntb; const void *outp; uintptr_t sz; uint64_t umv; char be[sizeof(umv)]; size_t outsz; uint32_t reg; bool db, pci; int error; ntb = arg1; reg = arg2 & ~NTB_REGFLAGS_MASK; sz = arg2 & NTB_REGSZ_MASK; db = (arg2 & NTB_DB_READ) != 0; pci = (arg2 & NTB_PCI_REG) != 0; KASSERT(!(db && pci), ("bogus")); if (db) { KASSERT(sz == NTB_REG_64, ("bogus")); umv = db_ioread(ntb, reg); outsz = sizeof(uint64_t); } else { switch (sz) { case NTB_REG_64: if (pci) umv = pci_read_config(ntb->device, reg, 8); else umv = ntb_reg_read(8, reg); outsz = sizeof(uint64_t); break; case NTB_REG_32: if (pci) umv = pci_read_config(ntb->device, reg, 4); else umv = ntb_reg_read(4, reg); outsz = sizeof(uint32_t); break; case NTB_REG_16: if (pci) umv = pci_read_config(ntb->device, reg, 2); else umv = ntb_reg_read(2, reg); outsz = sizeof(uint16_t); break; case NTB_REG_8: if (pci) umv = pci_read_config(ntb->device, reg, 1); else umv = ntb_reg_read(1, reg); outsz = sizeof(uint8_t); break; default: panic("bogus"); break; } } /* Encode bigendian so that sysctl -x is legible. */ be64enc(be, umv); outp = ((char *)be) + sizeof(umv) - outsz; error = SYSCTL_OUT(req, outp, outsz); if (error || !req->newptr) return (error); return (EINVAL); } static unsigned ntb_user_mw_to_idx(struct ntb_softc *ntb, unsigned uidx) { if ((ntb->b2b_mw_idx != B2B_MW_DISABLED && ntb->b2b_off == 0 && uidx >= ntb->b2b_mw_idx) || (ntb->msix_mw_idx != B2B_MW_DISABLED && uidx >= ntb->msix_mw_idx)) uidx++; if ((ntb->b2b_mw_idx != B2B_MW_DISABLED && ntb->b2b_off == 0 && uidx >= ntb->b2b_mw_idx) && (ntb->msix_mw_idx != B2B_MW_DISABLED && uidx >= ntb->msix_mw_idx)) uidx++; return (uidx); } static void ntb_exchange_msix(void *ctx) { struct ntb_softc *ntb; uint32_t val; unsigned i; ntb = ctx; if (ntb->peer_msix_good) goto msix_good; if (ntb->peer_msix_done) goto msix_done; for (i = 0; i < XEON_NONLINK_DB_MSIX_BITS; i++) { ntb_peer_spad_write(ntb->device, NTB_MSIX_DATA0 + i, ntb->msix_data[i].nmd_data); ntb_peer_spad_write(ntb->device, NTB_MSIX_OFS0 + i, ntb->msix_data[i].nmd_ofs - ntb->msix_xlat); } ntb_peer_spad_write(ntb->device, NTB_MSIX_GUARD, NTB_MSIX_VER_GUARD); ntb_spad_read(ntb->device, NTB_MSIX_GUARD, &val); if (val != NTB_MSIX_VER_GUARD) goto reschedule; for (i = 0; i < XEON_NONLINK_DB_MSIX_BITS; i++) { ntb_spad_read(ntb->device, NTB_MSIX_DATA0 + i, &val); ntb_printf(2, "remote MSIX data(%u): 0x%x\n", i, val); ntb->peer_msix_data[i].nmd_data = val; ntb_spad_read(ntb->device, NTB_MSIX_OFS0 + i, &val); ntb_printf(2, "remote MSIX addr(%u): 0x%x\n", i, val); ntb->peer_msix_data[i].nmd_ofs = val; } ntb->peer_msix_done = true; msix_done: ntb_peer_spad_write(ntb->device, NTB_MSIX_DONE, NTB_MSIX_RECEIVED); ntb_spad_read(ntb->device, NTB_MSIX_DONE, &val); if (val != NTB_MSIX_RECEIVED) goto reschedule; ntb->peer_msix_good = true; /* Give peer time to see our NTB_MSIX_RECEIVED. */ goto reschedule; msix_good: ntb_poll_link(ntb); ntb_link_event(ntb->device); return; reschedule: ntb->lnk_sta = pci_read_config(ntb->device, ntb->reg->lnk_sta, 2); if (_xeon_link_is_up(ntb)) { callout_reset(&ntb->peer_msix_work, hz * (ntb->peer_msix_good ? 2 : 1) / 100, ntb_exchange_msix, ntb); } else ntb_spad_clear(ntb->device); } /* * Public API to the rest of the OS */ static uint8_t ntb_spad_count(device_t dev) { struct ntb_softc *ntb = device_get_softc(dev); return (ntb->spad_count); } static uint8_t ntb_mw_count(device_t dev) { struct ntb_softc *ntb = device_get_softc(dev); uint8_t res; res = ntb->mw_count; if (ntb->b2b_mw_idx != B2B_MW_DISABLED && ntb->b2b_off == 0) res--; if (ntb->msix_mw_idx != B2B_MW_DISABLED) res--; return (res); } static int ntb_spad_write(device_t dev, unsigned int idx, uint32_t val) { struct ntb_softc *ntb = device_get_softc(dev); if (idx >= ntb->spad_count) return (EINVAL); ntb_reg_write(4, ntb->self_reg->spad + idx * 4, val); return (0); } /* * Zeros the local scratchpad. */ static void ntb_spad_clear(device_t dev) { struct ntb_softc *ntb = device_get_softc(dev); unsigned i; for (i = 0; i < ntb->spad_count; i++) ntb_spad_write(dev, i, 0); } static int ntb_spad_read(device_t dev, unsigned int idx, uint32_t *val) { struct ntb_softc *ntb = device_get_softc(dev); if (idx >= ntb->spad_count) return (EINVAL); *val = ntb_reg_read(4, ntb->self_reg->spad + idx * 4); return (0); } static int ntb_peer_spad_write(device_t dev, unsigned int idx, uint32_t val) { struct ntb_softc *ntb = device_get_softc(dev); if (idx >= ntb->spad_count) return (EINVAL); if (HAS_FEATURE(ntb, NTB_SDOORBELL_LOCKUP)) ntb_mw_write(4, XEON_SPAD_OFFSET + idx * 4, val); else ntb_reg_write(4, ntb->peer_reg->spad + idx * 4, val); return (0); } static int ntb_peer_spad_read(device_t dev, unsigned int idx, uint32_t *val) { struct ntb_softc *ntb = device_get_softc(dev); if (idx >= ntb->spad_count) return (EINVAL); if (HAS_FEATURE(ntb, NTB_SDOORBELL_LOCKUP)) *val = ntb_mw_read(4, XEON_SPAD_OFFSET + idx * 4); else *val = ntb_reg_read(4, ntb->peer_reg->spad + idx * 4); return (0); } static int ntb_mw_get_range(device_t dev, unsigned mw_idx, vm_paddr_t *base, caddr_t *vbase, size_t *size, size_t *align, size_t *align_size, bus_addr_t *plimit) { struct ntb_softc *ntb = device_get_softc(dev); struct ntb_pci_bar_info *bar; bus_addr_t limit; size_t bar_b2b_off; enum ntb_bar bar_num; if (mw_idx >= ntb_mw_count(dev)) return (EINVAL); mw_idx = ntb_user_mw_to_idx(ntb, mw_idx); bar_num = ntb_mw_to_bar(ntb, mw_idx); bar = &ntb->bar_info[bar_num]; bar_b2b_off = 0; if (mw_idx == ntb->b2b_mw_idx) { KASSERT(ntb->b2b_off != 0, ("user shouldn't get non-shared b2b mw")); bar_b2b_off = ntb->b2b_off; } if (bar_is_64bit(ntb, bar_num)) limit = BUS_SPACE_MAXADDR; else limit = BUS_SPACE_MAXADDR_32BIT; if (base != NULL) *base = bar->pbase + bar_b2b_off; if (vbase != NULL) *vbase = bar->vbase + bar_b2b_off; if (size != NULL) *size = bar->size - bar_b2b_off; if (align != NULL) *align = bar->size; if (align_size != NULL) *align_size = 1; if (plimit != NULL) *plimit = limit; return (0); } static int ntb_mw_set_trans(device_t dev, unsigned idx, bus_addr_t addr, size_t size) { struct ntb_softc *ntb = device_get_softc(dev); struct ntb_pci_bar_info *bar; uint64_t base, limit, reg_val; size_t bar_size, mw_size; uint32_t base_reg, xlat_reg, limit_reg; enum ntb_bar bar_num; if (idx >= ntb_mw_count(dev)) return (EINVAL); idx = ntb_user_mw_to_idx(ntb, idx); bar_num = ntb_mw_to_bar(ntb, idx); bar = &ntb->bar_info[bar_num]; bar_size = bar->size; if (idx == ntb->b2b_mw_idx) mw_size = bar_size - ntb->b2b_off; else mw_size = bar_size; /* Hardware requires that addr is aligned to bar size */ if ((addr & (bar_size - 1)) != 0) return (EINVAL); if (size > mw_size) return (EINVAL); bar_get_xlat_params(ntb, bar_num, &base_reg, &xlat_reg, &limit_reg); limit = 0; if (bar_is_64bit(ntb, bar_num)) { base = ntb_reg_read(8, base_reg) & BAR_HIGH_MASK; if (limit_reg != 0 && size != mw_size) limit = base + size; /* Set and verify translation address */ ntb_reg_write(8, xlat_reg, addr); reg_val = ntb_reg_read(8, xlat_reg) & BAR_HIGH_MASK; if (reg_val != addr) { ntb_reg_write(8, xlat_reg, 0); return (EIO); } /* Set and verify the limit */ ntb_reg_write(8, limit_reg, limit); reg_val = ntb_reg_read(8, limit_reg) & BAR_HIGH_MASK; if (reg_val != limit) { ntb_reg_write(8, limit_reg, base); ntb_reg_write(8, xlat_reg, 0); return (EIO); } } else { /* Configure 32-bit (split) BAR MW */ if ((addr & UINT32_MAX) != addr) return (ERANGE); if (((addr + size) & UINT32_MAX) != (addr + size)) return (ERANGE); base = ntb_reg_read(4, base_reg) & BAR_HIGH_MASK; if (limit_reg != 0 && size != mw_size) limit = base + size; /* Set and verify translation address */ ntb_reg_write(4, xlat_reg, addr); reg_val = ntb_reg_read(4, xlat_reg) & BAR_HIGH_MASK; if (reg_val != addr) { ntb_reg_write(4, xlat_reg, 0); return (EIO); } /* Set and verify the limit */ ntb_reg_write(4, limit_reg, limit); reg_val = ntb_reg_read(4, limit_reg) & BAR_HIGH_MASK; if (reg_val != limit) { ntb_reg_write(4, limit_reg, base); ntb_reg_write(4, xlat_reg, 0); return (EIO); } } return (0); } static int ntb_mw_clear_trans(device_t dev, unsigned mw_idx) { return (ntb_mw_set_trans(dev, mw_idx, 0, 0)); } static int ntb_mw_get_wc(device_t dev, unsigned idx, vm_memattr_t *mode) { struct ntb_softc *ntb = device_get_softc(dev); struct ntb_pci_bar_info *bar; if (idx >= ntb_mw_count(dev)) return (EINVAL); idx = ntb_user_mw_to_idx(ntb, idx); bar = &ntb->bar_info[ntb_mw_to_bar(ntb, idx)]; *mode = bar->map_mode; return (0); } static int ntb_mw_set_wc(device_t dev, unsigned idx, vm_memattr_t mode) { struct ntb_softc *ntb = device_get_softc(dev); if (idx >= ntb_mw_count(dev)) return (EINVAL); idx = ntb_user_mw_to_idx(ntb, idx); return (ntb_mw_set_wc_internal(ntb, idx, mode)); } static int ntb_mw_set_wc_internal(struct ntb_softc *ntb, unsigned idx, vm_memattr_t mode) { struct ntb_pci_bar_info *bar; int rc; bar = &ntb->bar_info[ntb_mw_to_bar(ntb, idx)]; if (bar->map_mode == mode) return (0); rc = pmap_change_attr((vm_offset_t)bar->vbase, bar->size, mode); if (rc == 0) bar->map_mode = mode; return (rc); } static void ntb_peer_db_set(device_t dev, uint64_t bit) { struct ntb_softc *ntb = device_get_softc(dev); if (HAS_FEATURE(ntb, NTB_SB01BASE_LOCKUP)) { struct ntb_pci_bar_info *lapic; unsigned i; lapic = ntb->peer_lapic_bar; for (i = 0; i < XEON_NONLINK_DB_MSIX_BITS; i++) { if ((bit & ntb_db_vector_mask(dev, i)) != 0) bus_space_write_4(lapic->pci_bus_tag, lapic->pci_bus_handle, ntb->peer_msix_data[i].nmd_ofs, ntb->peer_msix_data[i].nmd_data); } return; } if (HAS_FEATURE(ntb, NTB_SDOORBELL_LOCKUP)) { ntb_mw_write(2, XEON_PDOORBELL_OFFSET, bit); return; } db_iowrite(ntb, ntb->peer_reg->db_bell, bit); } static int ntb_peer_db_addr(device_t dev, bus_addr_t *db_addr, vm_size_t *db_size) { struct ntb_softc *ntb = device_get_softc(dev); struct ntb_pci_bar_info *bar; uint64_t regoff; KASSERT((db_addr != NULL && db_size != NULL), ("must be non-NULL")); if (!HAS_FEATURE(ntb, NTB_SDOORBELL_LOCKUP)) { bar = &ntb->bar_info[NTB_CONFIG_BAR]; regoff = ntb->peer_reg->db_bell; } else { KASSERT(ntb->b2b_mw_idx != B2B_MW_DISABLED, ("invalid b2b idx")); bar = &ntb->bar_info[ntb_mw_to_bar(ntb, ntb->b2b_mw_idx)]; regoff = XEON_PDOORBELL_OFFSET; } KASSERT(bar->pci_bus_tag != X86_BUS_SPACE_IO, ("uh oh")); /* HACK: Specific to current x86 bus implementation. */ *db_addr = ((uint64_t)bar->pci_bus_handle + regoff); *db_size = ntb->reg->db_size; return (0); } static uint64_t ntb_db_valid_mask(device_t dev) { struct ntb_softc *ntb = device_get_softc(dev); return (ntb->db_valid_mask); } static int ntb_db_vector_count(device_t dev) { struct ntb_softc *ntb = device_get_softc(dev); return (ntb->db_vec_count); } static uint64_t ntb_db_vector_mask(device_t dev, uint32_t vector) { struct ntb_softc *ntb = device_get_softc(dev); if (vector > ntb->db_vec_count) return (0); return (ntb->db_valid_mask & ntb_vec_mask(ntb, vector)); } static bool ntb_link_is_up(device_t dev, enum ntb_speed *speed, enum ntb_width *width) { struct ntb_softc *ntb = device_get_softc(dev); if (speed != NULL) *speed = ntb_link_sta_speed(ntb); if (width != NULL) *width = ntb_link_sta_width(ntb); return (link_is_up(ntb)); } static void save_bar_parameters(struct ntb_pci_bar_info *bar) { bar->pci_bus_tag = rman_get_bustag(bar->pci_resource); bar->pci_bus_handle = rman_get_bushandle(bar->pci_resource); bar->pbase = rman_get_start(bar->pci_resource); bar->size = rman_get_size(bar->pci_resource); bar->vbase = rman_get_virtual(bar->pci_resource); } static device_method_t ntb_intel_methods[] = { /* Device interface */ DEVMETHOD(device_probe, ntb_probe), DEVMETHOD(device_attach, ntb_attach), DEVMETHOD(device_detach, ntb_detach), /* NTB interface */ DEVMETHOD(ntb_link_is_up, ntb_link_is_up), DEVMETHOD(ntb_link_enable, ntb_link_enable), DEVMETHOD(ntb_link_disable, ntb_link_disable), DEVMETHOD(ntb_link_enabled, ntb_link_enabled), DEVMETHOD(ntb_set_ctx, ntb_set_ctx), DEVMETHOD(ntb_get_ctx, ntb_get_ctx), DEVMETHOD(ntb_clear_ctx, ntb_clear_ctx), DEVMETHOD(ntb_mw_count, ntb_mw_count), DEVMETHOD(ntb_mw_get_range, ntb_mw_get_range), DEVMETHOD(ntb_mw_set_trans, ntb_mw_set_trans), DEVMETHOD(ntb_mw_clear_trans, ntb_mw_clear_trans), DEVMETHOD(ntb_mw_get_wc, ntb_mw_get_wc), DEVMETHOD(ntb_mw_set_wc, ntb_mw_set_wc), DEVMETHOD(ntb_spad_count, ntb_spad_count), DEVMETHOD(ntb_spad_clear, ntb_spad_clear), DEVMETHOD(ntb_spad_write, ntb_spad_write), DEVMETHOD(ntb_spad_read, ntb_spad_read), DEVMETHOD(ntb_peer_spad_write, ntb_peer_spad_write), DEVMETHOD(ntb_peer_spad_read, ntb_peer_spad_read), DEVMETHOD(ntb_db_valid_mask, ntb_db_valid_mask), DEVMETHOD(ntb_db_vector_count, ntb_db_vector_count), DEVMETHOD(ntb_db_vector_mask, ntb_db_vector_mask), DEVMETHOD(ntb_db_clear, ntb_db_clear), DEVMETHOD(ntb_db_clear_mask, ntb_db_clear_mask), DEVMETHOD(ntb_db_read, ntb_db_read), DEVMETHOD(ntb_db_set_mask, ntb_db_set_mask), DEVMETHOD(ntb_peer_db_addr, ntb_peer_db_addr), DEVMETHOD(ntb_peer_db_set, ntb_peer_db_set), DEVMETHOD_END }; static DEFINE_CLASS_0(ntb_hw, ntb_intel_driver, ntb_intel_methods, sizeof(struct ntb_softc)); DRIVER_MODULE(ntb_intel, pci, ntb_intel_driver, ntb_hw_devclass, NULL, NULL); MODULE_DEPEND(ntb_intel, ntb, 1, 1, 1); MODULE_VERSION(ntb_intel, 1); Index: stable/10 =================================================================== --- stable/10 (revision 304393) +++ stable/10 (revision 304394) Property changes on: stable/10 ___________________________________________________________________ Modified: svn:mergeinfo ## -0,0 +0,1 ## Merged /head:r302508