FreeBSD/Linux Kernel Cross Reference
sys/x86/iommu/intel_utils.c

     /*-
      * Copyright (c) 2013 The FreeBSD Foundation
      * All rights reserved.
      *
      * This software was developed by Konstantin Belousov <kib@FreeBSD.org>
      * under sponsorship from the FreeBSD Foundation.
      *
      * Redistribution and use in source and binary forms, with or without
      * modification, are permitted provided that the following conditions
     * are met:
     * 1. Redistributions of source code must retain the above copyright
     *    notice, this list of conditions and the following disclaimer.
     * 2. Redistributions in binary form must reproduce the above copyright
     *    notice, this list of conditions and the following disclaimer in the
     *    documentation and/or other materials provided with the distribution.
     *
     * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
     * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
     * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
     * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
     * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
     * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
     * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
     * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
     * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
     * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
     * SUCH DAMAGE.
     */
    
    #include <sys/cdefs.h>
    __FBSDID("$FreeBSD$");
    
    #include <sys/param.h>
    #include <sys/bus.h>
    #include <sys/kernel.h>
    #include <sys/lock.h>
    #include <sys/malloc.h>
    #include <sys/memdesc.h>
    #include <sys/mutex.h>
    #include <sys/proc.h>
    #include <sys/queue.h>
    #include <sys/rman.h>
    #include <sys/rwlock.h>
    #include <sys/sched.h>
    #include <sys/sf_buf.h>
    #include <sys/sysctl.h>
    #include <sys/systm.h>
    #include <sys/taskqueue.h>
    #include <sys/tree.h>
    #include <dev/pci/pcivar.h>
    #include <vm/vm.h>
    #include <vm/vm_extern.h>
    #include <vm/vm_kern.h>
    #include <vm/vm_object.h>
    #include <vm/vm_page.h>
    #include <vm/vm_map.h>
    #include <vm/vm_pageout.h>
    #include <machine/bus.h>
    #include <machine/cpu.h>
    #include <x86/include/busdma_impl.h>
    #include <x86/iommu/intel_reg.h>
    #include <x86/iommu/busdma_dmar.h>
    #include <x86/iommu/intel_dmar.h>
    
    u_int
    dmar_nd2mask(u_int nd)
    {
            static const u_int masks[] = {
                    0x000f, /* nd == 0 */
                    0x002f, /* nd == 1 */
                    0x00ff, /* nd == 2 */
                    0x02ff, /* nd == 3 */
                    0x0fff, /* nd == 4 */
                    0x2fff, /* nd == 5 */
                    0xffff, /* nd == 6 */
                    0x0000, /* nd == 7 reserved */
            };
    
            KASSERT(nd <= 6, ("number of domains %d", nd));
            return (masks[nd]);
    }
    
    static const struct sagaw_bits_tag {
            int agaw;
            int cap;
            int awlvl;
            int pglvl;
    } sagaw_bits[] = {
            {.agaw = 30, .cap = DMAR_CAP_SAGAW_2LVL, .awlvl = DMAR_CTX2_AW_2LVL,
                .pglvl = 2},
            {.agaw = 39, .cap = DMAR_CAP_SAGAW_3LVL, .awlvl = DMAR_CTX2_AW_3LVL,
                .pglvl = 3},
            {.agaw = 48, .cap = DMAR_CAP_SAGAW_4LVL, .awlvl = DMAR_CTX2_AW_4LVL,
                .pglvl = 4},
            {.agaw = 57, .cap = DMAR_CAP_SAGAW_5LVL, .awlvl = DMAR_CTX2_AW_5LVL,
                .pglvl = 5},
            {.agaw = 64, .cap = DMAR_CAP_SAGAW_6LVL, .awlvl = DMAR_CTX2_AW_6LVL,
                .pglvl = 6}
    };
   #define SIZEOF_SAGAW_BITS (sizeof(sagaw_bits) / sizeof(sagaw_bits[0]))
   
   bool
   dmar_pglvl_supported(struct dmar_unit *unit, int pglvl)
   {
           int i;
   
           for (i = 0; i < SIZEOF_SAGAW_BITS; i++) {
                   if (sagaw_bits[i].pglvl != pglvl)
                           continue;
                   if ((DMAR_CAP_SAGAW(unit->hw_cap) & sagaw_bits[i].cap) != 0)
                           return (true);
           }
           return (false);
   }
   
   int
   ctx_set_agaw(struct dmar_ctx *ctx, int mgaw)
   {
           int sagaw, i;
   
           ctx->mgaw = mgaw;
           sagaw = DMAR_CAP_SAGAW(ctx->dmar->hw_cap);
           for (i = 0; i < SIZEOF_SAGAW_BITS; i++) {
                   if (sagaw_bits[i].agaw >= mgaw) {
                           ctx->agaw = sagaw_bits[i].agaw;
                           ctx->pglvl = sagaw_bits[i].pglvl;
                           ctx->awlvl = sagaw_bits[i].awlvl;
                           return (0);
                   }
           }
           device_printf(ctx->dmar->dev,
               "context request mgaw %d for pci%d:%d:%d:%d, "
               "no agaw found, sagaw %x\n", mgaw, ctx->dmar->segment, 
               pci_get_bus(ctx->ctx_tag.owner),
               pci_get_slot(ctx->ctx_tag.owner),
               pci_get_function(ctx->ctx_tag.owner), sagaw);
           return (EINVAL);
   }
   
   /*
    * Find a best fit mgaw for the given maxaddr:
    *   - if allow_less is false, must find sagaw which maps all requested
    *     addresses (used by identity mappings);
    *   - if allow_less is true, and no supported sagaw can map all requested
    *     address space, accept the biggest sagaw, whatever is it.
    */
   int
   dmar_maxaddr2mgaw(struct dmar_unit *unit, dmar_gaddr_t maxaddr, bool allow_less)
   {
           int i;
   
           for (i = 0; i < SIZEOF_SAGAW_BITS; i++) {
                   if ((1ULL << sagaw_bits[i].agaw) >= maxaddr &&
                       (DMAR_CAP_SAGAW(unit->hw_cap) & sagaw_bits[i].cap) != 0)
                           break;
           }
           if (allow_less && i == SIZEOF_SAGAW_BITS) {
                   do {
                           i--;
                   } while ((DMAR_CAP_SAGAW(unit->hw_cap) & sagaw_bits[i].cap)
                       == 0);
           }
           if (i < SIZEOF_SAGAW_BITS)
                   return (sagaw_bits[i].agaw);
           KASSERT(0, ("no mgaw for maxaddr %jx allow_less %d",
               (uintmax_t) maxaddr, allow_less));
           return (-1);
   }
   
   /*
    * Calculate the total amount of page table pages needed to map the
    * whole bus address space on the context with the selected agaw.
    */
   vm_pindex_t
   pglvl_max_pages(int pglvl)
   {
           vm_pindex_t res;
           int i;
   
           for (res = 0, i = pglvl; i > 0; i--) {
                   res *= DMAR_NPTEPG;
                   res++;
           }
           return (res);
   }
   
   /*
    * Return true if the page table level lvl supports the superpage for
    * the context ctx.
    */
   int
   ctx_is_sp_lvl(struct dmar_ctx *ctx, int lvl)
   {
           int alvl, cap_sps;
           static const int sagaw_sp[] = {
                   DMAR_CAP_SPS_2M,
                   DMAR_CAP_SPS_1G,
                   DMAR_CAP_SPS_512G,
                   DMAR_CAP_SPS_1T
           };
   
           alvl = ctx->pglvl - lvl - 1;
           cap_sps = DMAR_CAP_SPS(ctx->dmar->hw_cap);
           return (alvl < sizeof(sagaw_sp) / sizeof(sagaw_sp[0]) &&
               (sagaw_sp[alvl] & cap_sps) != 0);
   }
   
   dmar_gaddr_t
   pglvl_page_size(int total_pglvl, int lvl)
   {
           int rlvl;
           static const dmar_gaddr_t pg_sz[] = {
                   (dmar_gaddr_t)DMAR_PAGE_SIZE,
                   (dmar_gaddr_t)DMAR_PAGE_SIZE << DMAR_NPTEPGSHIFT,
                   (dmar_gaddr_t)DMAR_PAGE_SIZE << (2 * DMAR_NPTEPGSHIFT),
                   (dmar_gaddr_t)DMAR_PAGE_SIZE << (3 * DMAR_NPTEPGSHIFT),
                   (dmar_gaddr_t)DMAR_PAGE_SIZE << (4 * DMAR_NPTEPGSHIFT),
                   (dmar_gaddr_t)DMAR_PAGE_SIZE << (5 * DMAR_NPTEPGSHIFT)
           };
   
           KASSERT(lvl >= 0 && lvl < total_pglvl,
               ("total %d lvl %d", total_pglvl, lvl));
           rlvl = total_pglvl - lvl - 1;
           KASSERT(rlvl < sizeof(pg_sz) / sizeof(pg_sz[0]),
               ("sizeof pg_sz lvl %d", lvl));
           return (pg_sz[rlvl]);
   }
   
   dmar_gaddr_t
   ctx_page_size(struct dmar_ctx *ctx, int lvl)
   {
   
           return (pglvl_page_size(ctx->pglvl, lvl));
   }
   
   int
   calc_am(struct dmar_unit *unit, dmar_gaddr_t base, dmar_gaddr_t size,
       dmar_gaddr_t *isizep)
   {
           dmar_gaddr_t isize;
           int am;
   
           for (am = DMAR_CAP_MAMV(unit->hw_cap);; am--) {
                   isize = 1ULL << (am + DMAR_PAGE_SHIFT);
                   if ((base & (isize - 1)) == 0 && size >= isize)
                           break;
                   if (am == 0)
                           break;
           }
           *isizep = isize;
           return (am);
   }
   
   dmar_haddr_t dmar_high;
   int haw;
   int dmar_tbl_pagecnt;
   
   vm_page_t
   dmar_pgalloc(vm_object_t obj, vm_pindex_t idx, int flags)
   {
           vm_page_t m;
           int zeroed;
   
           zeroed = (flags & DMAR_PGF_ZERO) != 0 ? VM_ALLOC_ZERO : 0;
           for (;;) {
                   if ((flags & DMAR_PGF_OBJL) == 0)
                           VM_OBJECT_WLOCK(obj);
                   m = vm_page_lookup(obj, idx);
                   if ((flags & DMAR_PGF_NOALLOC) != 0 || m != NULL) {
                           if ((flags & DMAR_PGF_OBJL) == 0)
                                   VM_OBJECT_WUNLOCK(obj);
                           break;
                   }
                   m = vm_page_alloc_contig(obj, idx, VM_ALLOC_NOBUSY |
                       VM_ALLOC_SYSTEM | VM_ALLOC_NODUMP | zeroed, 1, 0,
                       dmar_high, PAGE_SIZE, 0, VM_MEMATTR_DEFAULT);
                   if ((flags & DMAR_PGF_OBJL) == 0)
                           VM_OBJECT_WUNLOCK(obj);
                   if (m != NULL) {
                           if (zeroed && (m->flags & PG_ZERO) == 0)
                                   pmap_zero_page(m);
                           atomic_add_int(&dmar_tbl_pagecnt, 1);
                           break;
                   }
                   if ((flags & DMAR_PGF_WAITOK) == 0)
                           break;
                   if ((flags & DMAR_PGF_OBJL) != 0)
                           VM_OBJECT_WUNLOCK(obj);
                   VM_WAIT;
                   if ((flags & DMAR_PGF_OBJL) != 0)
                           VM_OBJECT_WLOCK(obj);
           }
           return (m);
   }
   
   void
   dmar_pgfree(vm_object_t obj, vm_pindex_t idx, int flags)
   {
           vm_page_t m;
   
           if ((flags & DMAR_PGF_OBJL) == 0)
                   VM_OBJECT_WLOCK(obj);
           m = vm_page_lookup(obj, idx);
           if (m != NULL) {
                   vm_page_free(m);
                   atomic_subtract_int(&dmar_tbl_pagecnt, 1);
           }
           if ((flags & DMAR_PGF_OBJL) == 0)
                   VM_OBJECT_WUNLOCK(obj);
   }
   
   void *
   dmar_map_pgtbl(vm_object_t obj, vm_pindex_t idx, int flags,
       struct sf_buf **sf)
   {
           vm_page_t m;
           bool allocated;
   
           if ((flags & DMAR_PGF_OBJL) == 0)
                   VM_OBJECT_WLOCK(obj);
           m = vm_page_lookup(obj, idx);
           if (m == NULL && (flags & DMAR_PGF_ALLOC) != 0) {
                   m = dmar_pgalloc(obj, idx, flags | DMAR_PGF_OBJL);
                   allocated = true;
           } else
                   allocated = false;
           if (m == NULL) {
                   if ((flags & DMAR_PGF_OBJL) == 0)
                           VM_OBJECT_WUNLOCK(obj);
                   return (NULL);
           }
           /* Sleepable allocations cannot fail. */
           if ((flags & DMAR_PGF_WAITOK) != 0)
                   VM_OBJECT_WUNLOCK(obj);
           sched_pin();
           *sf = sf_buf_alloc(m, SFB_CPUPRIVATE | ((flags & DMAR_PGF_WAITOK)
               == 0 ? SFB_NOWAIT : 0));
           if (*sf == NULL) {
                   sched_unpin();
                   if (allocated) {
                           VM_OBJECT_ASSERT_WLOCKED(obj);
                           dmar_pgfree(obj, m->pindex, flags | DMAR_PGF_OBJL);
                   }
                   if ((flags & DMAR_PGF_OBJL) == 0)
                           VM_OBJECT_WUNLOCK(obj);
                   return (NULL);
           }
           if ((flags & (DMAR_PGF_WAITOK | DMAR_PGF_OBJL)) ==
               (DMAR_PGF_WAITOK | DMAR_PGF_OBJL))
                   VM_OBJECT_WLOCK(obj);
           else if ((flags & (DMAR_PGF_WAITOK | DMAR_PGF_OBJL)) == 0)
                   VM_OBJECT_WUNLOCK(obj);
           return ((void *)sf_buf_kva(*sf));
   }
   
   void
   dmar_unmap_pgtbl(struct sf_buf *sf)
   {
   
           sf_buf_free(sf);
           sched_unpin();
   }
   
   static void
   dmar_flush_transl_to_ram(struct dmar_unit *unit, void *dst, size_t sz)
   {
   
           if (DMAR_IS_COHERENT(unit))
                   return;
           /*
            * If DMAR does not snoop paging structures accesses, flush
            * CPU cache to memory.
            */
           pmap_invalidate_cache_range((uintptr_t)dst, (uintptr_t)dst + sz,
               TRUE);
   }
   
   void
   dmar_flush_pte_to_ram(struct dmar_unit *unit, dmar_pte_t *dst)
   {
   
           dmar_flush_transl_to_ram(unit, dst, sizeof(*dst));
   }
   
   void
   dmar_flush_ctx_to_ram(struct dmar_unit *unit, dmar_ctx_entry_t *dst)
   {
   
           dmar_flush_transl_to_ram(unit, dst, sizeof(*dst));
   }
   
   void
   dmar_flush_root_to_ram(struct dmar_unit *unit, dmar_root_entry_t *dst)
   {
   
           dmar_flush_transl_to_ram(unit, dst, sizeof(*dst));
   }
   
   /*
    * Load the root entry pointer into the hardware, busily waiting for
    * the completion.
    */
   int
   dmar_load_root_entry_ptr(struct dmar_unit *unit)
   {
           vm_page_t root_entry;
   
           /*
            * Access to the GCMD register must be serialized while the
            * command is submitted.
            */
           DMAR_ASSERT_LOCKED(unit);
   
           VM_OBJECT_RLOCK(unit->ctx_obj);
           root_entry = vm_page_lookup(unit->ctx_obj, 0);
           VM_OBJECT_RUNLOCK(unit->ctx_obj);
           dmar_write8(unit, DMAR_RTADDR_REG, VM_PAGE_TO_PHYS(root_entry));
           dmar_write4(unit, DMAR_GCMD_REG, unit->hw_gcmd | DMAR_GCMD_SRTP);
           /* XXXKIB should have a timeout */
           while ((dmar_read4(unit, DMAR_GSTS_REG) & DMAR_GSTS_RTPS) == 0)
                   cpu_spinwait();
           return (0);
   }
   
   /*
    * Globally invalidate the context entries cache, busily waiting for
    * the completion.
    */
   int
   dmar_inv_ctx_glob(struct dmar_unit *unit)
   {
   
           /*
            * Access to the CCMD register must be serialized while the
            * command is submitted.
            */
           DMAR_ASSERT_LOCKED(unit);
           KASSERT(!unit->qi_enabled, ("QI enabled"));
   
           /*
            * The DMAR_CCMD_ICC bit in the upper dword should be written
            * after the low dword write is completed.  Amd64
            * dmar_write8() does not have this issue, i386 dmar_write8()
            * writes the upper dword last.
            */
           dmar_write8(unit, DMAR_CCMD_REG, DMAR_CCMD_ICC | DMAR_CCMD_CIRG_GLOB);
           /* XXXKIB should have a timeout */
           while ((dmar_read4(unit, DMAR_CCMD_REG + 4) & DMAR_CCMD_ICC32) != 0)
                   cpu_spinwait();
           return (0);
   }
   
   /*
    * Globally invalidate the IOTLB, busily waiting for the completion.
    */
   int
   dmar_inv_iotlb_glob(struct dmar_unit *unit)
   {
           int reg;
   
           DMAR_ASSERT_LOCKED(unit);
           KASSERT(!unit->qi_enabled, ("QI enabled"));
   
           reg = 16 * DMAR_ECAP_IRO(unit->hw_ecap);
           /* See a comment about DMAR_CCMD_ICC in dmar_inv_ctx_glob. */
           dmar_write8(unit, reg + DMAR_IOTLB_REG_OFF, DMAR_IOTLB_IVT |
               DMAR_IOTLB_IIRG_GLB | DMAR_IOTLB_DR | DMAR_IOTLB_DW);
           /* XXXKIB should have a timeout */
           while ((dmar_read4(unit, reg + DMAR_IOTLB_REG_OFF + 4) &
               DMAR_IOTLB_IVT32) != 0)
                   cpu_spinwait();
           return (0);
   }
   
   /*
    * Flush the chipset write buffers.  See 11.1 "Write Buffer Flushing"
    * in the architecture specification.
    */
   int
   dmar_flush_write_bufs(struct dmar_unit *unit)
   {
   
           DMAR_ASSERT_LOCKED(unit);
   
           /*
            * DMAR_GCMD_WBF is only valid when CAP_RWBF is reported.
            */
           KASSERT((unit->hw_cap & DMAR_CAP_RWBF) != 0,
               ("dmar%d: no RWBF", unit->unit));
   
           dmar_write4(unit, DMAR_GCMD_REG, unit->hw_gcmd | DMAR_GCMD_WBF);
           /* XXXKIB should have a timeout */
           while ((dmar_read4(unit, DMAR_GSTS_REG) & DMAR_GSTS_WBFS) == 0)
                   cpu_spinwait();
           return (0);
   }
   
   int
   dmar_enable_translation(struct dmar_unit *unit)
   {
   
           DMAR_ASSERT_LOCKED(unit);
           unit->hw_gcmd |= DMAR_GCMD_TE;
           dmar_write4(unit, DMAR_GCMD_REG, unit->hw_gcmd);
           /* XXXKIB should have a timeout */
           while ((dmar_read4(unit, DMAR_GSTS_REG) & DMAR_GSTS_TES) == 0)
                   cpu_spinwait();
           return (0);
   }
   
   int
   dmar_disable_translation(struct dmar_unit *unit)
   {
   
           DMAR_ASSERT_LOCKED(unit);
           unit->hw_gcmd &= ~DMAR_GCMD_TE;
           dmar_write4(unit, DMAR_GCMD_REG, unit->hw_gcmd);
           /* XXXKIB should have a timeout */
           while ((dmar_read4(unit, DMAR_GSTS_REG) & DMAR_GSTS_TES) != 0)
                   cpu_spinwait();
           return (0);
   }
   
   #define BARRIER_F                               \
           u_int f_done, f_inproc, f_wakeup;       \
                                                   \
           f_done = 1 << (barrier_id * 3);         \
           f_inproc = 1 << (barrier_id * 3 + 1);   \
           f_wakeup = 1 << (barrier_id * 3 + 2)
   
   bool
   dmar_barrier_enter(struct dmar_unit *dmar, u_int barrier_id)
   {
           BARRIER_F;
   
           DMAR_LOCK(dmar);
           if ((dmar->barrier_flags & f_done) != 0) {
                   DMAR_UNLOCK(dmar);
                   return (false);
           }
   
           if ((dmar->barrier_flags & f_inproc) != 0) {
                   while ((dmar->barrier_flags & f_inproc) != 0) {
                           dmar->barrier_flags |= f_wakeup;
                           msleep(&dmar->barrier_flags, &dmar->lock, 0,
                               "dmarb", 0);
                   }
                   KASSERT((dmar->barrier_flags & f_done) != 0,
                       ("dmar%d barrier %d missing done", dmar->unit, barrier_id));
                   DMAR_UNLOCK(dmar);
                   return (false);
           }
   
           dmar->barrier_flags |= f_inproc;
           DMAR_UNLOCK(dmar);
           return (true);
   }
   
   void
   dmar_barrier_exit(struct dmar_unit *dmar, u_int barrier_id)
   {
           BARRIER_F;
   
           DMAR_ASSERT_LOCKED(dmar);
           KASSERT((dmar->barrier_flags & (f_done | f_inproc)) == f_inproc,
               ("dmar%d barrier %d missed entry", dmar->unit, barrier_id));
           dmar->barrier_flags |= f_done;
           if ((dmar->barrier_flags & f_wakeup) != 0)
                   wakeup(&dmar->barrier_flags);
           dmar->barrier_flags &= ~(f_inproc | f_wakeup);
           DMAR_UNLOCK(dmar);
   }
   
   int dmar_match_verbose;
   
   static SYSCTL_NODE(_hw, OID_AUTO, dmar, CTLFLAG_RD, NULL,
       "");
   SYSCTL_INT(_hw_dmar, OID_AUTO, tbl_pagecnt, CTLFLAG_RD | CTLFLAG_TUN,
       &dmar_tbl_pagecnt, 0,
       "Count of pages used for DMAR pagetables");
   SYSCTL_INT(_hw_dmar, OID_AUTO, match_verbose, CTLFLAG_RW | CTLFLAG_TUN,
       &dmar_match_verbose, 0,
       "Verbose matching of the PCI devices to DMAR paths");
   #ifdef INVARIANTS
   int dmar_check_free;
   SYSCTL_INT(_hw_dmar, OID_AUTO, check_free, CTLFLAG_RW | CTLFLAG_TUN,
       &dmar_check_free, 0,
       "Check the GPA RBtree for free_down and free_after validity");
   #endif
   

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