// SPDX-License-Identifier: MIT /* * Copyright © 2020-2022 Intel Corporation */ #include #include #include "tests/xe_kunit_helpers.h" #include "tests/xe_pci_test.h" #include "xe_pci.h" #include "xe_pm.h" static bool sanity_fence_failed(struct xe_device *xe, struct dma_fence *fence, const char *str, struct kunit *test) { long ret; if (IS_ERR(fence)) { KUNIT_FAIL(test, "Failed to create fence for %s: %li\n", str, PTR_ERR(fence)); return true; } if (!fence) return true; ret = dma_fence_wait_timeout(fence, false, 5 * HZ); if (ret <= 0) { KUNIT_FAIL(test, "Fence timed out for %s: %li\n", str, ret); return true; } return false; } static int run_sanity_job(struct xe_migrate *m, struct xe_device *xe, struct xe_bb *bb, u32 second_idx, const char *str, struct kunit *test) { u64 batch_base = xe_migrate_batch_base(m, xe->info.has_usm); struct xe_sched_job *job = xe_bb_create_migration_job(m->q, bb, batch_base, second_idx); struct dma_fence *fence; if (IS_ERR(job)) { KUNIT_FAIL(test, "Failed to allocate fake pt: %li\n", PTR_ERR(job)); return PTR_ERR(job); } xe_sched_job_arm(job); fence = dma_fence_get(&job->drm.s_fence->finished); xe_sched_job_push(job); if (sanity_fence_failed(xe, fence, str, test)) return -ETIMEDOUT; dma_fence_put(fence); kunit_info(test, "%s: Job completed\n", str); return 0; } #define check(_retval, _expected, str, _test) \ do { if ((_retval) != (_expected)) { \ KUNIT_FAIL(_test, "Sanity check failed: " str \ " expected %llx, got %llx\n", \ (u64)(_expected), (u64)(_retval)); \ } } while (0) static void test_copy(struct xe_migrate *m, struct xe_bo *bo, struct kunit *test, u32 region) { struct xe_device *xe = tile_to_xe(m->tile); u64 retval, expected = 0; bool big = bo->size >= SZ_2M; struct dma_fence *fence; const char *str = big ? "Copying big bo" : "Copying small bo"; int err; struct xe_bo *remote = xe_bo_create_locked(xe, m->tile, NULL, bo->size, ttm_bo_type_kernel, region | XE_BO_FLAG_NEEDS_CPU_ACCESS); if (IS_ERR(remote)) { KUNIT_FAIL(test, "Failed to allocate remote bo for %s: %pe\n", str, remote); return; } err = xe_bo_validate(remote, NULL, false); if (err) { KUNIT_FAIL(test, "Failed to validate system bo for %s: %i\n", str, err); goto out_unlock; } err = xe_bo_vmap(remote); if (err) { KUNIT_FAIL(test, "Failed to vmap system bo for %s: %i\n", str, err); goto out_unlock; } xe_map_memset(xe, &remote->vmap, 0, 0xd0, remote->size); fence = xe_migrate_clear(m, remote, remote->ttm.resource, XE_MIGRATE_CLEAR_FLAG_FULL); if (!sanity_fence_failed(xe, fence, big ? "Clearing remote big bo" : "Clearing remote small bo", test)) { retval = xe_map_rd(xe, &remote->vmap, 0, u64); check(retval, expected, "remote first offset should be cleared", test); retval = xe_map_rd(xe, &remote->vmap, remote->size - 8, u64); check(retval, expected, "remote last offset should be cleared", test); } dma_fence_put(fence); /* Try to copy 0xc0 from remote to vram with 2MB or 64KiB/4KiB pages */ xe_map_memset(xe, &remote->vmap, 0, 0xc0, remote->size); xe_map_memset(xe, &bo->vmap, 0, 0xd0, bo->size); expected = 0xc0c0c0c0c0c0c0c0; fence = xe_migrate_copy(m, remote, bo, remote->ttm.resource, bo->ttm.resource, false); if (!sanity_fence_failed(xe, fence, big ? "Copying big bo remote -> vram" : "Copying small bo remote -> vram", test)) { retval = xe_map_rd(xe, &bo->vmap, 0, u64); check(retval, expected, "remote -> vram bo first offset should be copied", test); retval = xe_map_rd(xe, &bo->vmap, bo->size - 8, u64); check(retval, expected, "remote -> vram bo offset should be copied", test); } dma_fence_put(fence); /* And other way around.. slightly hacky.. */ xe_map_memset(xe, &remote->vmap, 0, 0xd0, remote->size); xe_map_memset(xe, &bo->vmap, 0, 0xc0, bo->size); fence = xe_migrate_copy(m, bo, remote, bo->ttm.resource, remote->ttm.resource, false); if (!sanity_fence_failed(xe, fence, big ? "Copying big bo vram -> remote" : "Copying small bo vram -> remote", test)) { retval = xe_map_rd(xe, &remote->vmap, 0, u64); check(retval, expected, "vram -> remote bo first offset should be copied", test); retval = xe_map_rd(xe, &remote->vmap, bo->size - 8, u64); check(retval, expected, "vram -> remote bo last offset should be copied", test); } dma_fence_put(fence); xe_bo_vunmap(remote); out_unlock: xe_bo_unlock(remote); xe_bo_put(remote); } static void test_copy_sysmem(struct xe_migrate *m, struct xe_bo *bo, struct kunit *test) { test_copy(m, bo, test, XE_BO_FLAG_SYSTEM); } static void test_copy_vram(struct xe_migrate *m, struct xe_bo *bo, struct kunit *test) { u32 region; if (bo->ttm.resource->mem_type == XE_PL_SYSTEM) return; if (bo->ttm.resource->mem_type == XE_PL_VRAM0) region = XE_BO_FLAG_VRAM1; else region = XE_BO_FLAG_VRAM0; test_copy(m, bo, test, region); } static void xe_migrate_sanity_test(struct xe_migrate *m, struct kunit *test) { struct xe_tile *tile = m->tile; struct xe_device *xe = tile_to_xe(tile); struct xe_bo *pt, *bo = m->pt_bo, *big, *tiny; struct xe_res_cursor src_it; struct dma_fence *fence; u64 retval, expected; struct xe_bb *bb; int err; u8 id = tile->id; err = xe_bo_vmap(bo); if (err) { KUNIT_FAIL(test, "Failed to vmap our pagetables: %li\n", PTR_ERR(bo)); return; } big = xe_bo_create_pin_map(xe, tile, m->q->vm, SZ_4M, ttm_bo_type_kernel, XE_BO_FLAG_VRAM_IF_DGFX(tile) | XE_BO_FLAG_PINNED); if (IS_ERR(big)) { KUNIT_FAIL(test, "Failed to allocate bo: %li\n", PTR_ERR(big)); goto vunmap; } pt = xe_bo_create_pin_map(xe, tile, m->q->vm, XE_PAGE_SIZE, ttm_bo_type_kernel, XE_BO_FLAG_VRAM_IF_DGFX(tile) | XE_BO_FLAG_PINNED); if (IS_ERR(pt)) { KUNIT_FAIL(test, "Failed to allocate fake pt: %li\n", PTR_ERR(pt)); goto free_big; } tiny = xe_bo_create_pin_map(xe, tile, m->q->vm, 2 * SZ_4K, ttm_bo_type_kernel, XE_BO_FLAG_VRAM_IF_DGFX(tile) | XE_BO_FLAG_PINNED); if (IS_ERR(tiny)) { KUNIT_FAIL(test, "Failed to allocate fake pt: %li\n", PTR_ERR(pt)); goto free_pt; } bb = xe_bb_new(tile->primary_gt, 32, xe->info.has_usm); if (IS_ERR(bb)) { KUNIT_FAIL(test, "Failed to create batchbuffer: %li\n", PTR_ERR(bb)); goto free_tiny; } kunit_info(test, "Starting tests, top level PT addr: %lx, special pagetable base addr: %lx\n", (unsigned long)xe_bo_main_addr(m->q->vm->pt_root[id]->bo, XE_PAGE_SIZE), (unsigned long)xe_bo_main_addr(m->pt_bo, XE_PAGE_SIZE)); /* First part of the test, are we updating our pagetable bo with a new entry? */ xe_map_wr(xe, &bo->vmap, XE_PAGE_SIZE * (NUM_KERNEL_PDE - 1), u64, 0xdeaddeadbeefbeef); expected = m->q->vm->pt_ops->pte_encode_bo(pt, 0, xe->pat.idx[XE_CACHE_WB], 0); if (m->q->vm->flags & XE_VM_FLAG_64K) expected |= XE_PTE_PS64; if (xe_bo_is_vram(pt)) xe_res_first(pt->ttm.resource, 0, pt->size, &src_it); else xe_res_first_sg(xe_bo_sg(pt), 0, pt->size, &src_it); emit_pte(m, bb, NUM_KERNEL_PDE - 1, xe_bo_is_vram(pt), false, &src_it, XE_PAGE_SIZE, pt->ttm.resource); run_sanity_job(m, xe, bb, bb->len, "Writing PTE for our fake PT", test); retval = xe_map_rd(xe, &bo->vmap, XE_PAGE_SIZE * (NUM_KERNEL_PDE - 1), u64); check(retval, expected, "PTE entry write", test); /* Now try to write data to our newly mapped 'pagetable', see if it succeeds */ bb->len = 0; bb->cs[bb->len++] = MI_BATCH_BUFFER_END; xe_map_wr(xe, &pt->vmap, 0, u32, 0xdeaddead); expected = 0; emit_clear(tile->primary_gt, bb, xe_migrate_vm_addr(NUM_KERNEL_PDE - 1, 0), 4, 4, IS_DGFX(xe)); run_sanity_job(m, xe, bb, 1, "Writing to our newly mapped pagetable", test); retval = xe_map_rd(xe, &pt->vmap, 0, u32); check(retval, expected, "Write to PT after adding PTE", test); /* Sanity checks passed, try the full ones! */ /* Clear a small bo */ kunit_info(test, "Clearing small buffer object\n"); xe_map_memset(xe, &tiny->vmap, 0, 0x22, tiny->size); expected = 0; fence = xe_migrate_clear(m, tiny, tiny->ttm.resource, XE_MIGRATE_CLEAR_FLAG_FULL); if (sanity_fence_failed(xe, fence, "Clearing small bo", test)) goto out; dma_fence_put(fence); retval = xe_map_rd(xe, &tiny->vmap, 0, u32); check(retval, expected, "Command clear small first value", test); retval = xe_map_rd(xe, &tiny->vmap, tiny->size - 4, u32); check(retval, expected, "Command clear small last value", test); kunit_info(test, "Copying small buffer object to system\n"); test_copy_sysmem(m, tiny, test); if (xe->info.tile_count > 1) { kunit_info(test, "Copying small buffer object to other vram\n"); test_copy_vram(m, tiny, test); } /* Clear a big bo */ kunit_info(test, "Clearing big buffer object\n"); xe_map_memset(xe, &big->vmap, 0, 0x11, big->size); expected = 0; fence = xe_migrate_clear(m, big, big->ttm.resource, XE_MIGRATE_CLEAR_FLAG_FULL); if (sanity_fence_failed(xe, fence, "Clearing big bo", test)) goto out; dma_fence_put(fence); retval = xe_map_rd(xe, &big->vmap, 0, u32); check(retval, expected, "Command clear big first value", test); retval = xe_map_rd(xe, &big->vmap, big->size - 4, u32); check(retval, expected, "Command clear big last value", test); kunit_info(test, "Copying big buffer object to system\n"); test_copy_sysmem(m, big, test); if (xe->info.tile_count > 1) { kunit_info(test, "Copying big buffer object to other vram\n"); test_copy_vram(m, big, test); } out: xe_bb_free(bb, NULL); free_tiny: xe_bo_unpin(tiny); xe_bo_put(tiny); free_pt: xe_bo_unpin(pt); xe_bo_put(pt); free_big: xe_bo_unpin(big); xe_bo_put(big); vunmap: xe_bo_vunmap(m->pt_bo); } static int migrate_test_run_device(struct xe_device *xe) { struct kunit *test = kunit_get_current_test(); struct xe_tile *tile; int id; xe_pm_runtime_get(xe); for_each_tile(tile, xe, id) { struct xe_migrate *m = tile->migrate; kunit_info(test, "Testing tile id %d.\n", id); xe_vm_lock(m->q->vm, false); xe_migrate_sanity_test(m, test); xe_vm_unlock(m->q->vm); } xe_pm_runtime_put(xe); return 0; } static void xe_migrate_sanity_kunit(struct kunit *test) { struct xe_device *xe = test->priv; migrate_test_run_device(xe); } static struct dma_fence *blt_copy(struct xe_tile *tile, struct xe_bo *src_bo, struct xe_bo *dst_bo, bool copy_only_ccs, const char *str, struct kunit *test) { struct xe_gt *gt = tile->primary_gt; struct xe_migrate *m = tile->migrate; struct xe_device *xe = gt_to_xe(gt); struct dma_fence *fence = NULL; u64 size = src_bo->size; struct xe_res_cursor src_it, dst_it; struct ttm_resource *src = src_bo->ttm.resource, *dst = dst_bo->ttm.resource; u64 src_L0_ofs, dst_L0_ofs; u32 src_L0_pt, dst_L0_pt; u64 src_L0, dst_L0; int err; bool src_is_vram = mem_type_is_vram(src->mem_type); bool dst_is_vram = mem_type_is_vram(dst->mem_type); if (!src_is_vram) xe_res_first_sg(xe_bo_sg(src_bo), 0, size, &src_it); else xe_res_first(src, 0, size, &src_it); if (!dst_is_vram) xe_res_first_sg(xe_bo_sg(dst_bo), 0, size, &dst_it); else xe_res_first(dst, 0, size, &dst_it); while (size) { u32 batch_size = 2; /* arb_clear() + MI_BATCH_BUFFER_END */ struct xe_sched_job *job; struct xe_bb *bb; u32 flush_flags = 0; u32 update_idx; u32 avail_pts = max_mem_transfer_per_pass(xe) / LEVEL0_PAGE_TABLE_ENCODE_SIZE; u32 pte_flags; src_L0 = xe_migrate_res_sizes(m, &src_it); dst_L0 = xe_migrate_res_sizes(m, &dst_it); src_L0 = min(src_L0, dst_L0); pte_flags = src_is_vram ? (PTE_UPDATE_FLAG_IS_VRAM | PTE_UPDATE_FLAG_IS_COMP_PTE) : 0; batch_size += pte_update_size(m, pte_flags, src, &src_it, &src_L0, &src_L0_ofs, &src_L0_pt, 0, 0, avail_pts); pte_flags = dst_is_vram ? (PTE_UPDATE_FLAG_IS_VRAM | PTE_UPDATE_FLAG_IS_COMP_PTE) : 0; batch_size += pte_update_size(m, pte_flags, dst, &dst_it, &src_L0, &dst_L0_ofs, &dst_L0_pt, 0, avail_pts, avail_pts); /* Add copy commands size here */ batch_size += ((copy_only_ccs) ? 0 : EMIT_COPY_DW) + ((xe_device_has_flat_ccs(xe) && copy_only_ccs) ? EMIT_COPY_CCS_DW : 0); bb = xe_bb_new(gt, batch_size, xe->info.has_usm); if (IS_ERR(bb)) { err = PTR_ERR(bb); goto err_sync; } if (src_is_vram) xe_res_next(&src_it, src_L0); else emit_pte(m, bb, src_L0_pt, src_is_vram, false, &src_it, src_L0, src); if (dst_is_vram) xe_res_next(&dst_it, src_L0); else emit_pte(m, bb, dst_L0_pt, dst_is_vram, false, &dst_it, src_L0, dst); bb->cs[bb->len++] = MI_BATCH_BUFFER_END; update_idx = bb->len; if (!copy_only_ccs) emit_copy(gt, bb, src_L0_ofs, dst_L0_ofs, src_L0, XE_PAGE_SIZE); if (copy_only_ccs) flush_flags = xe_migrate_ccs_copy(m, bb, src_L0_ofs, src_is_vram, dst_L0_ofs, dst_is_vram, src_L0, dst_L0_ofs, copy_only_ccs); job = xe_bb_create_migration_job(m->q, bb, xe_migrate_batch_base(m, xe->info.has_usm), update_idx); if (IS_ERR(job)) { err = PTR_ERR(job); goto err; } xe_sched_job_add_migrate_flush(job, flush_flags); mutex_lock(&m->job_mutex); xe_sched_job_arm(job); dma_fence_put(fence); fence = dma_fence_get(&job->drm.s_fence->finished); xe_sched_job_push(job); dma_fence_put(m->fence); m->fence = dma_fence_get(fence); mutex_unlock(&m->job_mutex); xe_bb_free(bb, fence); size -= src_L0; continue; err: xe_bb_free(bb, NULL); err_sync: if (fence) { dma_fence_wait(fence, false); dma_fence_put(fence); } return ERR_PTR(err); } return fence; } static void test_migrate(struct xe_device *xe, struct xe_tile *tile, struct xe_bo *sys_bo, struct xe_bo *vram_bo, struct xe_bo *ccs_bo, struct kunit *test) { struct dma_fence *fence; u64 expected, retval; long timeout; long ret; expected = 0xd0d0d0d0d0d0d0d0; xe_map_memset(xe, &sys_bo->vmap, 0, 0xd0, sys_bo->size); fence = blt_copy(tile, sys_bo, vram_bo, false, "Blit copy from sysmem to vram", test); if (!sanity_fence_failed(xe, fence, "Blit copy from sysmem to vram", test)) { retval = xe_map_rd(xe, &vram_bo->vmap, 0, u64); if (retval == expected) KUNIT_FAIL(test, "Sanity check failed: VRAM must have compressed value\n"); } dma_fence_put(fence); kunit_info(test, "Evict vram buffer object\n"); ret = xe_bo_evict(vram_bo, true); if (ret) { KUNIT_FAIL(test, "Failed to evict bo.\n"); return; } ret = xe_bo_vmap(vram_bo); if (ret) { KUNIT_FAIL(test, "Failed to vmap vram bo: %li\n", ret); return; } retval = xe_map_rd(xe, &vram_bo->vmap, 0, u64); check(retval, expected, "Clear evicted vram data first value", test); retval = xe_map_rd(xe, &vram_bo->vmap, vram_bo->size - 8, u64); check(retval, expected, "Clear evicted vram data last value", test); fence = blt_copy(tile, vram_bo, ccs_bo, true, "Blit surf copy from vram to sysmem", test); if (!sanity_fence_failed(xe, fence, "Clear ccs buffer data", test)) { retval = xe_map_rd(xe, &ccs_bo->vmap, 0, u64); check(retval, 0, "Clear ccs data first value", test); retval = xe_map_rd(xe, &ccs_bo->vmap, ccs_bo->size - 8, u64); check(retval, 0, "Clear ccs data last value", test); } dma_fence_put(fence); kunit_info(test, "Restore vram buffer object\n"); ret = xe_bo_validate(vram_bo, NULL, false); if (ret) { KUNIT_FAIL(test, "Failed to validate vram bo for: %li\n", ret); return; } /* Sync all migration blits */ timeout = dma_resv_wait_timeout(vram_bo->ttm.base.resv, DMA_RESV_USAGE_KERNEL, true, 5 * HZ); if (timeout <= 0) { KUNIT_FAIL(test, "Failed to sync bo eviction.\n"); return; } ret = xe_bo_vmap(vram_bo); if (ret) { KUNIT_FAIL(test, "Failed to vmap vram bo: %li\n", ret); return; } retval = xe_map_rd(xe, &vram_bo->vmap, 0, u64); check(retval, expected, "Restored value must be equal to initial value", test); retval = xe_map_rd(xe, &vram_bo->vmap, vram_bo->size - 8, u64); check(retval, expected, "Restored value must be equal to initial value", test); fence = blt_copy(tile, vram_bo, ccs_bo, true, "Blit surf copy from vram to sysmem", test); if (!sanity_fence_failed(xe, fence, "Clear ccs buffer data", test)) { retval = xe_map_rd(xe, &ccs_bo->vmap, 0, u64); check(retval, 0, "Clear ccs data first value", test); retval = xe_map_rd(xe, &ccs_bo->vmap, ccs_bo->size - 8, u64); check(retval, 0, "Clear ccs data last value", test); } dma_fence_put(fence); } static void test_clear(struct xe_device *xe, struct xe_tile *tile, struct xe_bo *sys_bo, struct xe_bo *vram_bo, struct kunit *test) { struct dma_fence *fence; u64 expected, retval; expected = 0xd0d0d0d0d0d0d0d0; xe_map_memset(xe, &sys_bo->vmap, 0, 0xd0, sys_bo->size); fence = blt_copy(tile, sys_bo, vram_bo, false, "Blit copy from sysmem to vram", test); if (!sanity_fence_failed(xe, fence, "Blit copy from sysmem to vram", test)) { retval = xe_map_rd(xe, &vram_bo->vmap, 0, u64); if (retval == expected) KUNIT_FAIL(test, "Sanity check failed: VRAM must have compressed value\n"); } dma_fence_put(fence); fence = blt_copy(tile, vram_bo, sys_bo, false, "Blit copy from vram to sysmem", test); if (!sanity_fence_failed(xe, fence, "Blit copy from vram to sysmem", test)) { retval = xe_map_rd(xe, &sys_bo->vmap, 0, u64); check(retval, expected, "Decompressed value must be equal to initial value", test); retval = xe_map_rd(xe, &sys_bo->vmap, sys_bo->size - 8, u64); check(retval, expected, "Decompressed value must be equal to initial value", test); } dma_fence_put(fence); kunit_info(test, "Clear vram buffer object\n"); expected = 0x0000000000000000; fence = xe_migrate_clear(tile->migrate, vram_bo, vram_bo->ttm.resource, XE_MIGRATE_CLEAR_FLAG_FULL); if (sanity_fence_failed(xe, fence, "Clear vram_bo", test)) return; dma_fence_put(fence); fence = blt_copy(tile, vram_bo, sys_bo, false, "Blit copy from vram to sysmem", test); if (!sanity_fence_failed(xe, fence, "Clear main buffer data", test)) { retval = xe_map_rd(xe, &sys_bo->vmap, 0, u64); check(retval, expected, "Clear main buffer first value", test); retval = xe_map_rd(xe, &sys_bo->vmap, sys_bo->size - 8, u64); check(retval, expected, "Clear main buffer last value", test); } dma_fence_put(fence); fence = blt_copy(tile, vram_bo, sys_bo, true, "Blit surf copy from vram to sysmem", test); if (!sanity_fence_failed(xe, fence, "Clear ccs buffer data", test)) { retval = xe_map_rd(xe, &sys_bo->vmap, 0, u64); check(retval, expected, "Clear ccs data first value", test); retval = xe_map_rd(xe, &sys_bo->vmap, sys_bo->size - 8, u64); check(retval, expected, "Clear ccs data last value", test); } dma_fence_put(fence); } static void validate_ccs_test_run_tile(struct xe_device *xe, struct xe_tile *tile, struct kunit *test) { struct xe_bo *sys_bo, *vram_bo = NULL, *ccs_bo = NULL; unsigned int bo_flags = XE_BO_FLAG_VRAM_IF_DGFX(tile); long ret; sys_bo = xe_bo_create_user(xe, NULL, NULL, SZ_4M, DRM_XE_GEM_CPU_CACHING_WC, XE_BO_FLAG_SYSTEM | XE_BO_FLAG_NEEDS_CPU_ACCESS); if (IS_ERR(sys_bo)) { KUNIT_FAIL(test, "xe_bo_create() failed with err=%ld\n", PTR_ERR(sys_bo)); return; } xe_bo_lock(sys_bo, false); ret = xe_bo_validate(sys_bo, NULL, false); if (ret) { KUNIT_FAIL(test, "Failed to validate system bo for: %li\n", ret); goto free_sysbo; } ret = xe_bo_vmap(sys_bo); if (ret) { KUNIT_FAIL(test, "Failed to vmap system bo: %li\n", ret); goto free_sysbo; } xe_bo_unlock(sys_bo); ccs_bo = xe_bo_create_user(xe, NULL, NULL, SZ_4M, DRM_XE_GEM_CPU_CACHING_WC, bo_flags | XE_BO_FLAG_NEEDS_CPU_ACCESS); if (IS_ERR(ccs_bo)) { KUNIT_FAIL(test, "xe_bo_create() failed with err=%ld\n", PTR_ERR(ccs_bo)); return; } xe_bo_lock(ccs_bo, false); ret = xe_bo_validate(ccs_bo, NULL, false); if (ret) { KUNIT_FAIL(test, "Failed to validate system bo for: %li\n", ret); goto free_ccsbo; } ret = xe_bo_vmap(ccs_bo); if (ret) { KUNIT_FAIL(test, "Failed to vmap system bo: %li\n", ret); goto free_ccsbo; } xe_bo_unlock(ccs_bo); vram_bo = xe_bo_create_user(xe, NULL, NULL, SZ_4M, DRM_XE_GEM_CPU_CACHING_WC, bo_flags | XE_BO_FLAG_NEEDS_CPU_ACCESS); if (IS_ERR(vram_bo)) { KUNIT_FAIL(test, "xe_bo_create() failed with err=%ld\n", PTR_ERR(vram_bo)); return; } xe_bo_lock(vram_bo, false); ret = xe_bo_validate(vram_bo, NULL, false); if (ret) { KUNIT_FAIL(test, "Failed to validate vram bo for: %li\n", ret); goto free_vrambo; } ret = xe_bo_vmap(vram_bo); if (ret) { KUNIT_FAIL(test, "Failed to vmap vram bo: %li\n", ret); goto free_vrambo; } test_clear(xe, tile, sys_bo, vram_bo, test); test_migrate(xe, tile, sys_bo, vram_bo, ccs_bo, test); xe_bo_unlock(vram_bo); xe_bo_lock(vram_bo, false); xe_bo_vunmap(vram_bo); xe_bo_unlock(vram_bo); xe_bo_lock(ccs_bo, false); xe_bo_vunmap(ccs_bo); xe_bo_unlock(ccs_bo); xe_bo_lock(sys_bo, false); xe_bo_vunmap(sys_bo); xe_bo_unlock(sys_bo); free_vrambo: xe_bo_put(vram_bo); free_ccsbo: xe_bo_put(ccs_bo); free_sysbo: xe_bo_put(sys_bo); } static int validate_ccs_test_run_device(struct xe_device *xe) { struct kunit *test = kunit_get_current_test(); struct xe_tile *tile; int id; if (!xe_device_has_flat_ccs(xe)) { kunit_skip(test, "non-flat-ccs device\n"); return 0; } if (!(GRAPHICS_VER(xe) >= 20 && IS_DGFX(xe))) { kunit_skip(test, "non-xe2 discrete device\n"); return 0; } xe_pm_runtime_get(xe); for_each_tile(tile, xe, id) validate_ccs_test_run_tile(xe, tile, test); xe_pm_runtime_put(xe); return 0; } static void xe_validate_ccs_kunit(struct kunit *test) { struct xe_device *xe = test->priv; validate_ccs_test_run_device(xe); } static struct kunit_case xe_migrate_tests[] = { KUNIT_CASE_PARAM(xe_migrate_sanity_kunit, xe_pci_live_device_gen_param), KUNIT_CASE_PARAM(xe_validate_ccs_kunit, xe_pci_live_device_gen_param), {} }; VISIBLE_IF_KUNIT struct kunit_suite xe_migrate_test_suite = { .name = "xe_migrate", .test_cases = xe_migrate_tests, .init = xe_kunit_helper_xe_device_live_test_init, }; EXPORT_SYMBOL_IF_KUNIT(xe_migrate_test_suite);