Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Matthew Auld | 2533 | 95.87% | 1 | 25.00% |
Chris Wilson | 103 | 3.90% | 2 | 50.00% |
Pankaj Bharadiya | 6 | 0.23% | 1 | 25.00% |
Total | 2642 | 4 |
// SPDX-License-Identifier: MIT /* * Copyright © 2020 Intel Corporation */ #include <linux/slab.h> /* fault-inject.h is not standalone! */ #include <linux/fault-inject.h> #include "i915_trace.h" #include "intel_gt.h" #include "intel_gtt.h" void stash_init(struct pagestash *stash) { pagevec_init(&stash->pvec); spin_lock_init(&stash->lock); } static struct page *stash_pop_page(struct pagestash *stash) { struct page *page = NULL; spin_lock(&stash->lock); if (likely(stash->pvec.nr)) page = stash->pvec.pages[--stash->pvec.nr]; spin_unlock(&stash->lock); return page; } static void stash_push_pagevec(struct pagestash *stash, struct pagevec *pvec) { unsigned int nr; spin_lock_nested(&stash->lock, SINGLE_DEPTH_NESTING); nr = min_t(typeof(nr), pvec->nr, pagevec_space(&stash->pvec)); memcpy(stash->pvec.pages + stash->pvec.nr, pvec->pages + pvec->nr - nr, sizeof(pvec->pages[0]) * nr); stash->pvec.nr += nr; spin_unlock(&stash->lock); pvec->nr -= nr; } static struct page *vm_alloc_page(struct i915_address_space *vm, gfp_t gfp) { struct pagevec stack; struct page *page; if (I915_SELFTEST_ONLY(should_fail(&vm->fault_attr, 1))) i915_gem_shrink_all(vm->i915); page = stash_pop_page(&vm->free_pages); if (page) return page; if (!vm->pt_kmap_wc) return alloc_page(gfp); /* Look in our global stash of WC pages... */ page = stash_pop_page(&vm->i915->mm.wc_stash); if (page) return page; /* * Otherwise batch allocate pages to amortize cost of set_pages_wc. * * We have to be careful as page allocation may trigger the shrinker * (via direct reclaim) which will fill up the WC stash underneath us. * So we add our WB pages into a temporary pvec on the stack and merge * them into the WC stash after all the allocations are complete. */ pagevec_init(&stack); do { struct page *page; page = alloc_page(gfp); if (unlikely(!page)) break; stack.pages[stack.nr++] = page; } while (pagevec_space(&stack)); if (stack.nr && !set_pages_array_wc(stack.pages, stack.nr)) { page = stack.pages[--stack.nr]; /* Merge spare WC pages to the global stash */ if (stack.nr) stash_push_pagevec(&vm->i915->mm.wc_stash, &stack); /* Push any surplus WC pages onto the local VM stash */ if (stack.nr) stash_push_pagevec(&vm->free_pages, &stack); } /* Return unwanted leftovers */ if (unlikely(stack.nr)) { WARN_ON_ONCE(set_pages_array_wb(stack.pages, stack.nr)); __pagevec_release(&stack); } return page; } static void vm_free_pages_release(struct i915_address_space *vm, bool immediate) { struct pagevec *pvec = &vm->free_pages.pvec; struct pagevec stack; lockdep_assert_held(&vm->free_pages.lock); GEM_BUG_ON(!pagevec_count(pvec)); if (vm->pt_kmap_wc) { /* * When we use WC, first fill up the global stash and then * only if full immediately free the overflow. */ stash_push_pagevec(&vm->i915->mm.wc_stash, pvec); /* * As we have made some room in the VM's free_pages, * we can wait for it to fill again. Unless we are * inside i915_address_space_fini() and must * immediately release the pages! */ if (pvec->nr <= (immediate ? 0 : PAGEVEC_SIZE - 1)) return; /* * We have to drop the lock to allow ourselves to sleep, * so take a copy of the pvec and clear the stash for * others to use it as we sleep. */ stack = *pvec; pagevec_reinit(pvec); spin_unlock(&vm->free_pages.lock); pvec = &stack; set_pages_array_wb(pvec->pages, pvec->nr); spin_lock(&vm->free_pages.lock); } __pagevec_release(pvec); } static void vm_free_page(struct i915_address_space *vm, struct page *page) { /* * On !llc, we need to change the pages back to WB. We only do so * in bulk, so we rarely need to change the page attributes here, * but doing so requires a stop_machine() from deep inside arch/x86/mm. * To make detection of the possible sleep more likely, use an * unconditional might_sleep() for everybody. */ might_sleep(); spin_lock(&vm->free_pages.lock); while (!pagevec_space(&vm->free_pages.pvec)) vm_free_pages_release(vm, false); GEM_BUG_ON(pagevec_count(&vm->free_pages.pvec) >= PAGEVEC_SIZE); pagevec_add(&vm->free_pages.pvec, page); spin_unlock(&vm->free_pages.lock); } void __i915_vm_close(struct i915_address_space *vm) { struct i915_vma *vma, *vn; if (!atomic_dec_and_mutex_lock(&vm->open, &vm->mutex)) return; list_for_each_entry_safe(vma, vn, &vm->bound_list, vm_link) { struct drm_i915_gem_object *obj = vma->obj; /* Keep the obj (and hence the vma) alive as _we_ destroy it */ if (!kref_get_unless_zero(&obj->base.refcount)) continue; atomic_and(~I915_VMA_PIN_MASK, &vma->flags); WARN_ON(__i915_vma_unbind(vma)); __i915_vma_put(vma); i915_gem_object_put(obj); } GEM_BUG_ON(!list_empty(&vm->bound_list)); mutex_unlock(&vm->mutex); } void i915_address_space_fini(struct i915_address_space *vm) { spin_lock(&vm->free_pages.lock); if (pagevec_count(&vm->free_pages.pvec)) vm_free_pages_release(vm, true); GEM_BUG_ON(pagevec_count(&vm->free_pages.pvec)); spin_unlock(&vm->free_pages.lock); drm_mm_takedown(&vm->mm); mutex_destroy(&vm->mutex); } static void __i915_vm_release(struct work_struct *work) { struct i915_address_space *vm = container_of(work, struct i915_address_space, rcu.work); vm->cleanup(vm); i915_address_space_fini(vm); kfree(vm); } void i915_vm_release(struct kref *kref) { struct i915_address_space *vm = container_of(kref, struct i915_address_space, ref); GEM_BUG_ON(i915_is_ggtt(vm)); trace_i915_ppgtt_release(vm); queue_rcu_work(vm->i915->wq, &vm->rcu); } void i915_address_space_init(struct i915_address_space *vm, int subclass) { kref_init(&vm->ref); INIT_RCU_WORK(&vm->rcu, __i915_vm_release); atomic_set(&vm->open, 1); /* * The vm->mutex must be reclaim safe (for use in the shrinker). * Do a dummy acquire now under fs_reclaim so that any allocation * attempt holding the lock is immediately reported by lockdep. */ mutex_init(&vm->mutex); lockdep_set_subclass(&vm->mutex, subclass); i915_gem_shrinker_taints_mutex(vm->i915, &vm->mutex); GEM_BUG_ON(!vm->total); drm_mm_init(&vm->mm, 0, vm->total); vm->mm.head_node.color = I915_COLOR_UNEVICTABLE; stash_init(&vm->free_pages); INIT_LIST_HEAD(&vm->bound_list); } void clear_pages(struct i915_vma *vma) { GEM_BUG_ON(!vma->pages); if (vma->pages != vma->obj->mm.pages) { sg_free_table(vma->pages); kfree(vma->pages); } vma->pages = NULL; memset(&vma->page_sizes, 0, sizeof(vma->page_sizes)); } static int __setup_page_dma(struct i915_address_space *vm, struct i915_page_dma *p, gfp_t gfp) { p->page = vm_alloc_page(vm, gfp | I915_GFP_ALLOW_FAIL); if (unlikely(!p->page)) return -ENOMEM; p->daddr = dma_map_page_attrs(vm->dma, p->page, 0, PAGE_SIZE, PCI_DMA_BIDIRECTIONAL, DMA_ATTR_SKIP_CPU_SYNC | DMA_ATTR_NO_WARN); if (unlikely(dma_mapping_error(vm->dma, p->daddr))) { vm_free_page(vm, p->page); return -ENOMEM; } return 0; } int setup_page_dma(struct i915_address_space *vm, struct i915_page_dma *p) { return __setup_page_dma(vm, p, __GFP_HIGHMEM); } void cleanup_page_dma(struct i915_address_space *vm, struct i915_page_dma *p) { dma_unmap_page(vm->dma, p->daddr, PAGE_SIZE, PCI_DMA_BIDIRECTIONAL); vm_free_page(vm, p->page); } void fill_page_dma(const struct i915_page_dma *p, const u64 val, unsigned int count) { kunmap_atomic(memset64(kmap_atomic(p->page), val, count)); } static void poison_scratch_page(struct page *page, unsigned long size) { if (!IS_ENABLED(CONFIG_DRM_I915_DEBUG_GEM)) return; GEM_BUG_ON(!IS_ALIGNED(size, PAGE_SIZE)); do { void *vaddr; vaddr = kmap(page); memset(vaddr, POISON_FREE, PAGE_SIZE); kunmap(page); page = pfn_to_page(page_to_pfn(page) + 1); size -= PAGE_SIZE; } while (size); } int setup_scratch_page(struct i915_address_space *vm, gfp_t gfp) { unsigned long size; /* * In order to utilize 64K pages for an object with a size < 2M, we will * need to support a 64K scratch page, given that every 16th entry for a * page-table operating in 64K mode must point to a properly aligned 64K * region, including any PTEs which happen to point to scratch. * * This is only relevant for the 48b PPGTT where we support * huge-gtt-pages, see also i915_vma_insert(). However, as we share the * scratch (read-only) between all vm, we create one 64k scratch page * for all. */ size = I915_GTT_PAGE_SIZE_4K; if (i915_vm_is_4lvl(vm) && HAS_PAGE_SIZES(vm->i915, I915_GTT_PAGE_SIZE_64K)) { size = I915_GTT_PAGE_SIZE_64K; gfp |= __GFP_NOWARN; } gfp |= __GFP_ZERO | __GFP_RETRY_MAYFAIL; do { unsigned int order = get_order(size); struct page *page; dma_addr_t addr; page = alloc_pages(gfp, order); if (unlikely(!page)) goto skip; /* * Use a non-zero scratch page for debugging. * * We want a value that should be reasonably obvious * to spot in the error state, while also causing a GPU hang * if executed. We prefer using a clear page in production, so * should it ever be accidentally used, the effect should be * fairly benign. */ poison_scratch_page(page, size); addr = dma_map_page_attrs(vm->dma, page, 0, size, PCI_DMA_BIDIRECTIONAL, DMA_ATTR_SKIP_CPU_SYNC | DMA_ATTR_NO_WARN); if (unlikely(dma_mapping_error(vm->dma, addr))) goto free_page; if (unlikely(!IS_ALIGNED(addr, size))) goto unmap_page; vm->scratch[0].base.page = page; vm->scratch[0].base.daddr = addr; vm->scratch_order = order; return 0; unmap_page: dma_unmap_page(vm->dma, addr, size, PCI_DMA_BIDIRECTIONAL); free_page: __free_pages(page, order); skip: if (size == I915_GTT_PAGE_SIZE_4K) return -ENOMEM; size = I915_GTT_PAGE_SIZE_4K; gfp &= ~__GFP_NOWARN; } while (1); } void cleanup_scratch_page(struct i915_address_space *vm) { struct i915_page_dma *p = px_base(&vm->scratch[0]); unsigned int order = vm->scratch_order; dma_unmap_page(vm->dma, p->daddr, BIT(order) << PAGE_SHIFT, PCI_DMA_BIDIRECTIONAL); __free_pages(p->page, order); } void free_scratch(struct i915_address_space *vm) { int i; if (!px_dma(&vm->scratch[0])) /* set to 0 on clones */ return; for (i = 1; i <= vm->top; i++) { if (!px_dma(&vm->scratch[i])) break; cleanup_page_dma(vm, px_base(&vm->scratch[i])); } cleanup_scratch_page(vm); } void gtt_write_workarounds(struct intel_gt *gt) { struct drm_i915_private *i915 = gt->i915; struct intel_uncore *uncore = gt->uncore; /* * This function is for gtt related workarounds. This function is * called on driver load and after a GPU reset, so you can place * workarounds here even if they get overwritten by GPU reset. */ /* WaIncreaseDefaultTLBEntries:chv,bdw,skl,bxt,kbl,glk,cfl,cnl,icl */ if (IS_BROADWELL(i915)) intel_uncore_write(uncore, GEN8_L3_LRA_1_GPGPU, GEN8_L3_LRA_1_GPGPU_DEFAULT_VALUE_BDW); else if (IS_CHERRYVIEW(i915)) intel_uncore_write(uncore, GEN8_L3_LRA_1_GPGPU, GEN8_L3_LRA_1_GPGPU_DEFAULT_VALUE_CHV); else if (IS_GEN9_LP(i915)) intel_uncore_write(uncore, GEN8_L3_LRA_1_GPGPU, GEN9_L3_LRA_1_GPGPU_DEFAULT_VALUE_BXT); else if (INTEL_GEN(i915) >= 9 && INTEL_GEN(i915) <= 11) intel_uncore_write(uncore, GEN8_L3_LRA_1_GPGPU, GEN9_L3_LRA_1_GPGPU_DEFAULT_VALUE_SKL); /* * To support 64K PTEs we need to first enable the use of the * Intermediate-Page-Size(IPS) bit of the PDE field via some magical * mmio, otherwise the page-walker will simply ignore the IPS bit. This * shouldn't be needed after GEN10. * * 64K pages were first introduced from BDW+, although technically they * only *work* from gen9+. For pre-BDW we instead have the option for * 32K pages, but we don't currently have any support for it in our * driver. */ if (HAS_PAGE_SIZES(i915, I915_GTT_PAGE_SIZE_64K) && INTEL_GEN(i915) <= 10) intel_uncore_rmw(uncore, GEN8_GAMW_ECO_DEV_RW_IA, 0, GAMW_ECO_ENABLE_64K_IPS_FIELD); if (IS_GEN_RANGE(i915, 8, 11)) { bool can_use_gtt_cache = true; /* * According to the BSpec if we use 2M/1G pages then we also * need to disable the GTT cache. At least on BDW we can see * visual corruption when using 2M pages, and not disabling the * GTT cache. */ if (HAS_PAGE_SIZES(i915, I915_GTT_PAGE_SIZE_2M)) can_use_gtt_cache = false; /* WaGttCachingOffByDefault */ intel_uncore_write(uncore, HSW_GTT_CACHE_EN, can_use_gtt_cache ? GTT_CACHE_EN_ALL : 0); drm_WARN_ON_ONCE(&i915->drm, can_use_gtt_cache && intel_uncore_read(uncore, HSW_GTT_CACHE_EN) == 0); } } static void tgl_setup_private_ppat(struct intel_uncore *uncore) { /* TGL doesn't support LLC or AGE settings */ intel_uncore_write(uncore, GEN12_PAT_INDEX(0), GEN8_PPAT_WB); intel_uncore_write(uncore, GEN12_PAT_INDEX(1), GEN8_PPAT_WC); intel_uncore_write(uncore, GEN12_PAT_INDEX(2), GEN8_PPAT_WT); intel_uncore_write(uncore, GEN12_PAT_INDEX(3), GEN8_PPAT_UC); intel_uncore_write(uncore, GEN12_PAT_INDEX(4), GEN8_PPAT_WB); intel_uncore_write(uncore, GEN12_PAT_INDEX(5), GEN8_PPAT_WB); intel_uncore_write(uncore, GEN12_PAT_INDEX(6), GEN8_PPAT_WB); intel_uncore_write(uncore, GEN12_PAT_INDEX(7), GEN8_PPAT_WB); } static void cnl_setup_private_ppat(struct intel_uncore *uncore) { intel_uncore_write(uncore, GEN10_PAT_INDEX(0), GEN8_PPAT_WB | GEN8_PPAT_LLC); intel_uncore_write(uncore, GEN10_PAT_INDEX(1), GEN8_PPAT_WC | GEN8_PPAT_LLCELLC); intel_uncore_write(uncore, GEN10_PAT_INDEX(2), GEN8_PPAT_WT | GEN8_PPAT_LLCELLC); intel_uncore_write(uncore, GEN10_PAT_INDEX(3), GEN8_PPAT_UC); intel_uncore_write(uncore, GEN10_PAT_INDEX(4), GEN8_PPAT_WB | GEN8_PPAT_LLCELLC | GEN8_PPAT_AGE(0)); intel_uncore_write(uncore, GEN10_PAT_INDEX(5), GEN8_PPAT_WB | GEN8_PPAT_LLCELLC | GEN8_PPAT_AGE(1)); intel_uncore_write(uncore, GEN10_PAT_INDEX(6), GEN8_PPAT_WB | GEN8_PPAT_LLCELLC | GEN8_PPAT_AGE(2)); intel_uncore_write(uncore, GEN10_PAT_INDEX(7), GEN8_PPAT_WB | GEN8_PPAT_LLCELLC | GEN8_PPAT_AGE(3)); } /* * The GGTT and PPGTT need a private PPAT setup in order to handle cacheability * bits. When using advanced contexts each context stores its own PAT, but * writing this data shouldn't be harmful even in those cases. */ static void bdw_setup_private_ppat(struct intel_uncore *uncore) { u64 pat; pat = GEN8_PPAT(0, GEN8_PPAT_WB | GEN8_PPAT_LLC) | /* for normal objects, no eLLC */ GEN8_PPAT(1, GEN8_PPAT_WC | GEN8_PPAT_LLCELLC) | /* for something pointing to ptes? */ GEN8_PPAT(2, GEN8_PPAT_WT | GEN8_PPAT_LLCELLC) | /* for scanout with eLLC */ GEN8_PPAT(3, GEN8_PPAT_UC) | /* Uncached objects, mostly for scanout */ GEN8_PPAT(4, GEN8_PPAT_WB | GEN8_PPAT_LLCELLC | GEN8_PPAT_AGE(0)) | GEN8_PPAT(5, GEN8_PPAT_WB | GEN8_PPAT_LLCELLC | GEN8_PPAT_AGE(1)) | GEN8_PPAT(6, GEN8_PPAT_WB | GEN8_PPAT_LLCELLC | GEN8_PPAT_AGE(2)) | GEN8_PPAT(7, GEN8_PPAT_WB | GEN8_PPAT_LLCELLC | GEN8_PPAT_AGE(3)); intel_uncore_write(uncore, GEN8_PRIVATE_PAT_LO, lower_32_bits(pat)); intel_uncore_write(uncore, GEN8_PRIVATE_PAT_HI, upper_32_bits(pat)); } static void chv_setup_private_ppat(struct intel_uncore *uncore) { u64 pat; /* * Map WB on BDW to snooped on CHV. * * Only the snoop bit has meaning for CHV, the rest is * ignored. * * The hardware will never snoop for certain types of accesses: * - CPU GTT (GMADR->GGTT->no snoop->memory) * - PPGTT page tables * - some other special cycles * * As with BDW, we also need to consider the following for GT accesses: * "For GGTT, there is NO pat_sel[2:0] from the entry, * so RTL will always use the value corresponding to * pat_sel = 000". * Which means we must set the snoop bit in PAT entry 0 * in order to keep the global status page working. */ pat = GEN8_PPAT(0, CHV_PPAT_SNOOP) | GEN8_PPAT(1, 0) | GEN8_PPAT(2, 0) | GEN8_PPAT(3, 0) | GEN8_PPAT(4, CHV_PPAT_SNOOP) | GEN8_PPAT(5, CHV_PPAT_SNOOP) | GEN8_PPAT(6, CHV_PPAT_SNOOP) | GEN8_PPAT(7, CHV_PPAT_SNOOP); intel_uncore_write(uncore, GEN8_PRIVATE_PAT_LO, lower_32_bits(pat)); intel_uncore_write(uncore, GEN8_PRIVATE_PAT_HI, upper_32_bits(pat)); } void setup_private_pat(struct intel_uncore *uncore) { struct drm_i915_private *i915 = uncore->i915; GEM_BUG_ON(INTEL_GEN(i915) < 8); if (INTEL_GEN(i915) >= 12) tgl_setup_private_ppat(uncore); else if (INTEL_GEN(i915) >= 10) cnl_setup_private_ppat(uncore); else if (IS_CHERRYVIEW(i915) || IS_GEN9_LP(i915)) chv_setup_private_ppat(uncore); else bdw_setup_private_ppat(uncore); } #if IS_ENABLED(CONFIG_DRM_I915_SELFTEST) #include "selftests/mock_gtt.c" #endif
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