/************************************************************************** * Copyright (c) 2007, Intel Corporation. * * This program is free software; you can redistribute it and/or modify it * under the terms and conditions of the GNU General Public License, * version 2, as published by the Free Software Foundation. * * This program is distributed in the hope it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for * more details. * * You should have received a copy of the GNU General Public License along with * this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin St - Fifth Floor, Boston, MA 02110-1301 USA. * **************************************************************************/ #include #include "psb_drv.h" #include "psb_reg.h" #include "mmu.h" /* * Code for the SGX MMU: */ /* * clflush on one processor only: * clflush should apparently flush the cache line on all processors in an * SMP system. */ /* * kmap atomic: * The usage of the slots must be completely encapsulated within a spinlock, and * no other functions that may be using the locks for other purposed may be * called from within the locked region. * Since the slots are per processor, this will guarantee that we are the only * user. */ /* * TODO: Inserting ptes from an interrupt handler: * This may be desirable for some SGX functionality where the GPU can fault in * needed pages. For that, we need to make an atomic insert_pages function, that * may fail. * If it fails, the caller need to insert the page using a workqueue function, * but on average it should be fast. */ static inline uint32_t psb_mmu_pt_index(uint32_t offset) { return (offset >> PSB_PTE_SHIFT) & 0x3FF; } static inline uint32_t psb_mmu_pd_index(uint32_t offset) { return offset >> PSB_PDE_SHIFT; } #if defined(CONFIG_X86) static inline void psb_clflush(void *addr) { __asm__ __volatile__("clflush (%0)\n" : : "r"(addr) : "memory"); } static inline void psb_mmu_clflush(struct psb_mmu_driver *driver, void *addr) { if (!driver->has_clflush) return; mb(); psb_clflush(addr); mb(); } #else static inline void psb_mmu_clflush(struct psb_mmu_driver *driver, void *addr) {; } #endif static void psb_mmu_flush_pd_locked(struct psb_mmu_driver *driver, int force) { struct drm_device *dev = driver->dev; struct drm_psb_private *dev_priv = dev->dev_private; if (atomic_read(&driver->needs_tlbflush) || force) { uint32_t val = PSB_RSGX32(PSB_CR_BIF_CTRL); PSB_WSGX32(val | _PSB_CB_CTRL_INVALDC, PSB_CR_BIF_CTRL); /* Make sure data cache is turned off before enabling it */ wmb(); PSB_WSGX32(val & ~_PSB_CB_CTRL_INVALDC, PSB_CR_BIF_CTRL); (void)PSB_RSGX32(PSB_CR_BIF_CTRL); if (driver->msvdx_mmu_invaldc) atomic_set(driver->msvdx_mmu_invaldc, 1); } atomic_set(&driver->needs_tlbflush, 0); } #if 0 static void psb_mmu_flush_pd(struct psb_mmu_driver *driver, int force) { down_write(&driver->sem); psb_mmu_flush_pd_locked(driver, force); up_write(&driver->sem); } #endif void psb_mmu_flush(struct psb_mmu_driver *driver) { struct drm_device *dev = driver->dev; struct drm_psb_private *dev_priv = dev->dev_private; uint32_t val; down_write(&driver->sem); val = PSB_RSGX32(PSB_CR_BIF_CTRL); if (atomic_read(&driver->needs_tlbflush)) PSB_WSGX32(val | _PSB_CB_CTRL_INVALDC, PSB_CR_BIF_CTRL); else PSB_WSGX32(val | _PSB_CB_CTRL_FLUSH, PSB_CR_BIF_CTRL); /* Make sure data cache is turned off and MMU is flushed before restoring bank interface control register */ wmb(); PSB_WSGX32(val & ~(_PSB_CB_CTRL_FLUSH | _PSB_CB_CTRL_INVALDC), PSB_CR_BIF_CTRL); (void)PSB_RSGX32(PSB_CR_BIF_CTRL); atomic_set(&driver->needs_tlbflush, 0); if (driver->msvdx_mmu_invaldc) atomic_set(driver->msvdx_mmu_invaldc, 1); up_write(&driver->sem); } void psb_mmu_set_pd_context(struct psb_mmu_pd *pd, int hw_context) { struct drm_device *dev = pd->driver->dev; struct drm_psb_private *dev_priv = dev->dev_private; uint32_t offset = (hw_context == 0) ? PSB_CR_BIF_DIR_LIST_BASE0 : PSB_CR_BIF_DIR_LIST_BASE1 + hw_context * 4; down_write(&pd->driver->sem); PSB_WSGX32(page_to_pfn(pd->p) << PAGE_SHIFT, offset); wmb(); psb_mmu_flush_pd_locked(pd->driver, 1); pd->hw_context = hw_context; up_write(&pd->driver->sem); } static inline unsigned long psb_pd_addr_end(unsigned long addr, unsigned long end) { addr = (addr + PSB_PDE_MASK + 1) & ~PSB_PDE_MASK; return (addr < end) ? addr : end; } static inline uint32_t psb_mmu_mask_pte(uint32_t pfn, int type) { uint32_t mask = PSB_PTE_VALID; if (type & PSB_MMU_CACHED_MEMORY) mask |= PSB_PTE_CACHED; if (type & PSB_MMU_RO_MEMORY) mask |= PSB_PTE_RO; if (type & PSB_MMU_WO_MEMORY) mask |= PSB_PTE_WO; return (pfn << PAGE_SHIFT) | mask; } struct psb_mmu_pd *psb_mmu_alloc_pd(struct psb_mmu_driver *driver, int trap_pagefaults, int invalid_type) { struct psb_mmu_pd *pd = kmalloc(sizeof(*pd), GFP_KERNEL); uint32_t *v; int i; if (!pd) return NULL; pd->p = alloc_page(GFP_DMA32); if (!pd->p) goto out_err1; pd->dummy_pt = alloc_page(GFP_DMA32); if (!pd->dummy_pt) goto out_err2; pd->dummy_page = alloc_page(GFP_DMA32); if (!pd->dummy_page) goto out_err3; if (!trap_pagefaults) { pd->invalid_pde = psb_mmu_mask_pte(page_to_pfn(pd->dummy_pt), invalid_type); pd->invalid_pte = psb_mmu_mask_pte(page_to_pfn(pd->dummy_page), invalid_type); } else { pd->invalid_pde = 0; pd->invalid_pte = 0; } v = kmap(pd->dummy_pt); for (i = 0; i < (PAGE_SIZE / sizeof(uint32_t)); ++i) v[i] = pd->invalid_pte; kunmap(pd->dummy_pt); v = kmap(pd->p); for (i = 0; i < (PAGE_SIZE / sizeof(uint32_t)); ++i) v[i] = pd->invalid_pde; kunmap(pd->p); clear_page(kmap(pd->dummy_page)); kunmap(pd->dummy_page); pd->tables = vmalloc_user(sizeof(struct psb_mmu_pt *) * 1024); if (!pd->tables) goto out_err4; pd->hw_context = -1; pd->pd_mask = PSB_PTE_VALID; pd->driver = driver; return pd; out_err4: __free_page(pd->dummy_page); out_err3: __free_page(pd->dummy_pt); out_err2: __free_page(pd->p); out_err1: kfree(pd); return NULL; } static void psb_mmu_free_pt(struct psb_mmu_pt *pt) { __free_page(pt->p); kfree(pt); } void psb_mmu_free_pagedir(struct psb_mmu_pd *pd) { struct psb_mmu_driver *driver = pd->driver; struct drm_device *dev = driver->dev; struct drm_psb_private *dev_priv = dev->dev_private; struct psb_mmu_pt *pt; int i; down_write(&driver->sem); if (pd->hw_context != -1) { PSB_WSGX32(0, PSB_CR_BIF_DIR_LIST_BASE0 + pd->hw_context * 4); psb_mmu_flush_pd_locked(driver, 1); } /* Should take the spinlock here, but we don't need to do that since we have the semaphore in write mode. */ for (i = 0; i < 1024; ++i) { pt = pd->tables[i]; if (pt) psb_mmu_free_pt(pt); } vfree(pd->tables); __free_page(pd->dummy_page); __free_page(pd->dummy_pt); __free_page(pd->p); kfree(pd); up_write(&driver->sem); } static struct psb_mmu_pt *psb_mmu_alloc_pt(struct psb_mmu_pd *pd) { struct psb_mmu_pt *pt = kmalloc(sizeof(*pt), GFP_KERNEL); void *v; uint32_t clflush_add = pd->driver->clflush_add >> PAGE_SHIFT; uint32_t clflush_count = PAGE_SIZE / clflush_add; spinlock_t *lock = &pd->driver->lock; uint8_t *clf; uint32_t *ptes; int i; if (!pt) return NULL; pt->p = alloc_page(GFP_DMA32); if (!pt->p) { kfree(pt); return NULL; } spin_lock(lock); v = kmap_atomic(pt->p); clf = (uint8_t *) v; ptes = (uint32_t *) v; for (i = 0; i < (PAGE_SIZE / sizeof(uint32_t)); ++i) *ptes++ = pd->invalid_pte; #if defined(CONFIG_X86) if (pd->driver->has_clflush && pd->hw_context != -1) { mb(); for (i = 0; i < clflush_count; ++i) { psb_clflush(clf); clf += clflush_add; } mb(); } #endif kunmap_atomic(v); spin_unlock(lock); pt->count = 0; pt->pd = pd; pt->index = 0; return pt; } struct psb_mmu_pt *psb_mmu_pt_alloc_map_lock(struct psb_mmu_pd *pd, unsigned long addr) { uint32_t index = psb_mmu_pd_index(addr); struct psb_mmu_pt *pt; uint32_t *v; spinlock_t *lock = &pd->driver->lock; spin_lock(lock); pt = pd->tables[index]; while (!pt) { spin_unlock(lock); pt = psb_mmu_alloc_pt(pd); if (!pt) return NULL; spin_lock(lock); if (pd->tables[index]) { spin_unlock(lock); psb_mmu_free_pt(pt); spin_lock(lock); pt = pd->tables[index]; continue; } v = kmap_atomic(pd->p); pd->tables[index] = pt; v[index] = (page_to_pfn(pt->p) << 12) | pd->pd_mask; pt->index = index; kunmap_atomic((void *) v); if (pd->hw_context != -1) { psb_mmu_clflush(pd->driver, (void *)&v[index]); atomic_set(&pd->driver->needs_tlbflush, 1); } } pt->v = kmap_atomic(pt->p); return pt; } static struct psb_mmu_pt *psb_mmu_pt_map_lock(struct psb_mmu_pd *pd, unsigned long addr) { uint32_t index = psb_mmu_pd_index(addr); struct psb_mmu_pt *pt; spinlock_t *lock = &pd->driver->lock; spin_lock(lock); pt = pd->tables[index]; if (!pt) { spin_unlock(lock); return NULL; } pt->v = kmap_atomic(pt->p); return pt; } static void psb_mmu_pt_unmap_unlock(struct psb_mmu_pt *pt) { struct psb_mmu_pd *pd = pt->pd; uint32_t *v; kunmap_atomic(pt->v); if (pt->count == 0) { v = kmap_atomic(pd->p); v[pt->index] = pd->invalid_pde; pd->tables[pt->index] = NULL; if (pd->hw_context != -1) { psb_mmu_clflush(pd->driver, (void *)&v[pt->index]); atomic_set(&pd->driver->needs_tlbflush, 1); } kunmap_atomic(v); spin_unlock(&pd->driver->lock); psb_mmu_free_pt(pt); return; } spin_unlock(&pd->driver->lock); } static inline void psb_mmu_set_pte(struct psb_mmu_pt *pt, unsigned long addr, uint32_t pte) { pt->v[psb_mmu_pt_index(addr)] = pte; } static inline void psb_mmu_invalidate_pte(struct psb_mmu_pt *pt, unsigned long addr) { pt->v[psb_mmu_pt_index(addr)] = pt->pd->invalid_pte; } struct psb_mmu_pd *psb_mmu_get_default_pd(struct psb_mmu_driver *driver) { struct psb_mmu_pd *pd; down_read(&driver->sem); pd = driver->default_pd; up_read(&driver->sem); return pd; } /* Returns the physical address of the PD shared by sgx/msvdx */ uint32_t psb_get_default_pd_addr(struct psb_mmu_driver *driver) { struct psb_mmu_pd *pd; pd = psb_mmu_get_default_pd(driver); return page_to_pfn(pd->p) << PAGE_SHIFT; } void psb_mmu_driver_takedown(struct psb_mmu_driver *driver) { struct drm_device *dev = driver->dev; struct drm_psb_private *dev_priv = dev->dev_private; PSB_WSGX32(driver->bif_ctrl, PSB_CR_BIF_CTRL); psb_mmu_free_pagedir(driver->default_pd); kfree(driver); } struct psb_mmu_driver *psb_mmu_driver_init(struct drm_device *dev, int trap_pagefaults, int invalid_type, atomic_t *msvdx_mmu_invaldc) { struct psb_mmu_driver *driver; struct drm_psb_private *dev_priv = dev->dev_private; driver = kmalloc(sizeof(*driver), GFP_KERNEL); if (!driver) return NULL; driver->dev = dev; driver->default_pd = psb_mmu_alloc_pd(driver, trap_pagefaults, invalid_type); if (!driver->default_pd) goto out_err1; spin_lock_init(&driver->lock); init_rwsem(&driver->sem); down_write(&driver->sem); atomic_set(&driver->needs_tlbflush, 1); driver->msvdx_mmu_invaldc = msvdx_mmu_invaldc; driver->bif_ctrl = PSB_RSGX32(PSB_CR_BIF_CTRL); PSB_WSGX32(driver->bif_ctrl | _PSB_CB_CTRL_CLEAR_FAULT, PSB_CR_BIF_CTRL); PSB_WSGX32(driver->bif_ctrl & ~_PSB_CB_CTRL_CLEAR_FAULT, PSB_CR_BIF_CTRL); driver->has_clflush = 0; #if defined(CONFIG_X86) if (boot_cpu_has(X86_FEATURE_CLFLUSH)) { uint32_t tfms, misc, cap0, cap4, clflush_size; /* * clflush size is determined at kernel setup for x86_64 but not * for i386. We have to do it here. */ cpuid(0x00000001, &tfms, &misc, &cap0, &cap4); clflush_size = ((misc >> 8) & 0xff) * 8; driver->has_clflush = 1; driver->clflush_add = PAGE_SIZE * clflush_size / sizeof(uint32_t); driver->clflush_mask = driver->clflush_add - 1; driver->clflush_mask = ~driver->clflush_mask; } #endif up_write(&driver->sem); return driver; out_err1: kfree(driver); return NULL; } #if defined(CONFIG_X86) static void psb_mmu_flush_ptes(struct psb_mmu_pd *pd, unsigned long address, uint32_t num_pages, uint32_t desired_tile_stride, uint32_t hw_tile_stride) { struct psb_mmu_pt *pt; uint32_t rows = 1; uint32_t i; unsigned long addr; unsigned long end; unsigned long next; unsigned long add; unsigned long row_add; unsigned long clflush_add = pd->driver->clflush_add; unsigned long clflush_mask = pd->driver->clflush_mask; if (!pd->driver->has_clflush) return; if (hw_tile_stride) rows = num_pages / desired_tile_stride; else desired_tile_stride = num_pages; add = desired_tile_stride << PAGE_SHIFT; row_add = hw_tile_stride << PAGE_SHIFT; mb(); for (i = 0; i < rows; ++i) { addr = address; end = addr + add; do { next = psb_pd_addr_end(addr, end); pt = psb_mmu_pt_map_lock(pd, addr); if (!pt) continue; do { psb_clflush(&pt->v[psb_mmu_pt_index(addr)]); } while (addr += clflush_add, (addr & clflush_mask) < next); psb_mmu_pt_unmap_unlock(pt); } while (addr = next, next != end); address += row_add; } mb(); } #else static void psb_mmu_flush_ptes(struct psb_mmu_pd *pd, unsigned long address, uint32_t num_pages, uint32_t desired_tile_stride, uint32_t hw_tile_stride) { drm_ttm_cache_flush(); } #endif void psb_mmu_remove_pfn_sequence(struct psb_mmu_pd *pd, unsigned long address, uint32_t num_pages) { struct psb_mmu_pt *pt; unsigned long addr; unsigned long end; unsigned long next; unsigned long f_address = address; down_read(&pd->driver->sem); addr = address; end = addr + (num_pages << PAGE_SHIFT); do { next = psb_pd_addr_end(addr, end); pt = psb_mmu_pt_alloc_map_lock(pd, addr); if (!pt) goto out; do { psb_mmu_invalidate_pte(pt, addr); --pt->count; } while (addr += PAGE_SIZE, addr < next); psb_mmu_pt_unmap_unlock(pt); } while (addr = next, next != end); out: if (pd->hw_context != -1) psb_mmu_flush_ptes(pd, f_address, num_pages, 1, 1); up_read(&pd->driver->sem); if (pd->hw_context != -1) psb_mmu_flush(pd->driver); return; } void psb_mmu_remove_pages(struct psb_mmu_pd *pd, unsigned long address, uint32_t num_pages, uint32_t desired_tile_stride, uint32_t hw_tile_stride) { struct psb_mmu_pt *pt; uint32_t rows = 1; uint32_t i; unsigned long addr; unsigned long end; unsigned long next; unsigned long add; unsigned long row_add; unsigned long f_address = address; if (hw_tile_stride) rows = num_pages / desired_tile_stride; else desired_tile_stride = num_pages; add = desired_tile_stride << PAGE_SHIFT; row_add = hw_tile_stride << PAGE_SHIFT; down_read(&pd->driver->sem); /* Make sure we only need to flush this processor's cache */ for (i = 0; i < rows; ++i) { addr = address; end = addr + add; do { next = psb_pd_addr_end(addr, end); pt = psb_mmu_pt_map_lock(pd, addr); if (!pt) continue; do { psb_mmu_invalidate_pte(pt, addr); --pt->count; } while (addr += PAGE_SIZE, addr < next); psb_mmu_pt_unmap_unlock(pt); } while (addr = next, next != end); address += row_add; } if (pd->hw_context != -1) psb_mmu_flush_ptes(pd, f_address, num_pages, desired_tile_stride, hw_tile_stride); up_read(&pd->driver->sem); if (pd->hw_context != -1) psb_mmu_flush(pd->driver); } int psb_mmu_insert_pfn_sequence(struct psb_mmu_pd *pd, uint32_t start_pfn, unsigned long address, uint32_t num_pages, int type) { struct psb_mmu_pt *pt; uint32_t pte; unsigned long addr; unsigned long end; unsigned long next; unsigned long f_address = address; int ret = -ENOMEM; down_read(&pd->driver->sem); addr = address; end = addr + (num_pages << PAGE_SHIFT); do { next = psb_pd_addr_end(addr, end); pt = psb_mmu_pt_alloc_map_lock(pd, addr); if (!pt) { ret = -ENOMEM; goto out; } do { pte = psb_mmu_mask_pte(start_pfn++, type); psb_mmu_set_pte(pt, addr, pte); pt->count++; } while (addr += PAGE_SIZE, addr < next); psb_mmu_pt_unmap_unlock(pt); } while (addr = next, next != end); ret = 0; out: if (pd->hw_context != -1) psb_mmu_flush_ptes(pd, f_address, num_pages, 1, 1); up_read(&pd->driver->sem); if (pd->hw_context != -1) psb_mmu_flush(pd->driver); return 0; } int psb_mmu_insert_pages(struct psb_mmu_pd *pd, struct page **pages, unsigned long address, uint32_t num_pages, uint32_t desired_tile_stride, uint32_t hw_tile_stride, int type) { struct psb_mmu_pt *pt; uint32_t rows = 1; uint32_t i; uint32_t pte; unsigned long addr; unsigned long end; unsigned long next; unsigned long add; unsigned long row_add; unsigned long f_address = address; int ret = -ENOMEM; if (hw_tile_stride) { if (num_pages % desired_tile_stride != 0) return -EINVAL; rows = num_pages / desired_tile_stride; } else { desired_tile_stride = num_pages; } add = desired_tile_stride << PAGE_SHIFT; row_add = hw_tile_stride << PAGE_SHIFT; down_read(&pd->driver->sem); for (i = 0; i < rows; ++i) { addr = address; end = addr + add; do { next = psb_pd_addr_end(addr, end); pt = psb_mmu_pt_alloc_map_lock(pd, addr); if (!pt) goto out; do { pte = psb_mmu_mask_pte(page_to_pfn(*pages++), type); psb_mmu_set_pte(pt, addr, pte); pt->count++; } while (addr += PAGE_SIZE, addr < next); psb_mmu_pt_unmap_unlock(pt); } while (addr = next, next != end); address += row_add; } ret = 0; out: if (pd->hw_context != -1) psb_mmu_flush_ptes(pd, f_address, num_pages, desired_tile_stride, hw_tile_stride); up_read(&pd->driver->sem); if (pd->hw_context != -1) psb_mmu_flush(pd->driver); return ret; } int psb_mmu_virtual_to_pfn(struct psb_mmu_pd *pd, uint32_t virtual, unsigned long *pfn) { int ret; struct psb_mmu_pt *pt; uint32_t tmp; spinlock_t *lock = &pd->driver->lock; down_read(&pd->driver->sem); pt = psb_mmu_pt_map_lock(pd, virtual); if (!pt) { uint32_t *v; spin_lock(lock); v = kmap_atomic(pd->p); tmp = v[psb_mmu_pd_index(virtual)]; kunmap_atomic(v); spin_unlock(lock); if (tmp != pd->invalid_pde || !(tmp & PSB_PTE_VALID) || !(pd->invalid_pte & PSB_PTE_VALID)) { ret = -EINVAL; goto out; } ret = 0; *pfn = pd->invalid_pte >> PAGE_SHIFT; goto out; } tmp = pt->v[psb_mmu_pt_index(virtual)]; if (!(tmp & PSB_PTE_VALID)) { ret = -EINVAL; } else { ret = 0; *pfn = tmp >> PAGE_SHIFT; } psb_mmu_pt_unmap_unlock(pt); out: up_read(&pd->driver->sem); return ret; }