/* * Copyright 2016 Advanced Micro Devices, Inc. * All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. * */ /* This file implements randomized SDMA texture blit tests. */ #include "si_pipe.h" #include "util/u_surface.h" #include "util/rand_xor.h" static uint64_t seed_xorshift128plus[2]; #define RAND_NUM_SIZE 8 /* The GPU blits are emulated on the CPU using these CPU textures. */ struct cpu_texture { uint8_t *ptr; uint64_t size; uint64_t layer_stride; unsigned stride; }; static void alloc_cpu_texture(struct cpu_texture *tex, struct pipe_resource *templ, int bpp) { tex->stride = align(templ->width0 * bpp, RAND_NUM_SIZE); tex->layer_stride = (uint64_t)tex->stride * templ->height0; tex->size = tex->layer_stride * templ->array_size; tex->ptr = malloc(tex->size); assert(tex->ptr); } static void set_random_pixels(struct pipe_context *ctx, struct pipe_resource *tex, struct cpu_texture *cpu) { struct pipe_transfer *t; uint8_t *map; int x,y,z; map = pipe_transfer_map_3d(ctx, tex, 0, PIPE_TRANSFER_WRITE, 0, 0, 0, tex->width0, tex->height0, tex->array_size, &t); assert(map); for (z = 0; z < tex->array_size; z++) { for (y = 0; y < tex->height0; y++) { uint64_t *ptr = (uint64_t*) (map + t->layer_stride*z + t->stride*y); uint64_t *ptr_cpu = (uint64_t*) (cpu->ptr + cpu->layer_stride*z + cpu->stride*y); unsigned size = cpu->stride / RAND_NUM_SIZE; assert(t->stride % RAND_NUM_SIZE == 0); assert(cpu->stride % RAND_NUM_SIZE == 0); for (x = 0; x < size; x++) { *ptr++ = *ptr_cpu++ = rand_xorshift128plus(seed_xorshift128plus); } } } pipe_transfer_unmap(ctx, t); } static bool compare_textures(struct pipe_context *ctx, struct pipe_resource *tex, struct cpu_texture *cpu, int bpp) { struct pipe_transfer *t; uint8_t *map; int y,z; bool pass = true; map = pipe_transfer_map_3d(ctx, tex, 0, PIPE_TRANSFER_READ, 0, 0, 0, tex->width0, tex->height0, tex->array_size, &t); assert(map); for (z = 0; z < tex->array_size; z++) { for (y = 0; y < tex->height0; y++) { uint8_t *ptr = map + t->layer_stride*z + t->stride*y; uint8_t *cpu_ptr = cpu->ptr + cpu->layer_stride*z + cpu->stride*y; if (memcmp(ptr, cpu_ptr, tex->width0 * bpp)) { pass = false; goto done; } } } done: pipe_transfer_unmap(ctx, t); return pass; } static enum pipe_format get_format_from_bpp(int bpp) { switch (bpp) { case 1: return PIPE_FORMAT_R8_UINT; case 2: return PIPE_FORMAT_R16_UINT; case 4: return PIPE_FORMAT_R32_UINT; case 8: return PIPE_FORMAT_R32G32_UINT; case 16: return PIPE_FORMAT_R32G32B32A32_UINT; default: assert(0); return PIPE_FORMAT_NONE; } } static const char *array_mode_to_string(struct si_screen *sscreen, struct radeon_surf *surf) { if (sscreen->info.chip_class >= GFX9) { switch (surf->u.gfx9.surf.swizzle_mode) { case 0: return " LINEAR"; case 21: return " 4KB_S_X"; case 22: return " 4KB_D_X"; case 25: return "64KB_S_X"; case 26: return "64KB_D_X"; default: printf("Unhandled swizzle mode = %u\n", surf->u.gfx9.surf.swizzle_mode); return " UNKNOWN"; } } else { switch (surf->u.legacy.level[0].mode) { case RADEON_SURF_MODE_LINEAR_ALIGNED: return "LINEAR_ALIGNED"; case RADEON_SURF_MODE_1D: return "1D_TILED_THIN1"; case RADEON_SURF_MODE_2D: return "2D_TILED_THIN1"; default: assert(0); return " UNKNOWN"; } } } static unsigned generate_max_tex_side(unsigned max_tex_side) { switch (rand() % 4) { case 0: /* Try to hit large sizes in 1/4 of the cases. */ return max_tex_side; case 1: /* Try to hit 1D tiling in 1/4 of the cases. */ return 128; default: /* Try to hit common sizes in 2/4 of the cases. */ return 2048; } } void si_test_dma(struct si_screen *sscreen) { struct pipe_screen *screen = &sscreen->b; struct pipe_context *ctx = screen->context_create(screen, NULL, 0); struct si_context *sctx = (struct si_context*)ctx; uint64_t max_alloc_size; unsigned i, iterations, num_partial_copies, max_levels, max_tex_side; unsigned num_pass = 0, num_fail = 0; max_levels = screen->get_param(screen, PIPE_CAP_MAX_TEXTURE_2D_LEVELS); max_tex_side = 1 << (max_levels - 1); /* Max 128 MB allowed for both textures. */ max_alloc_size = 128 * 1024 * 1024; /* the seed for random test parameters */ srand(0x9b47d95b); /* the seed for random pixel data */ s_rand_xorshift128plus(seed_xorshift128plus, false); iterations = 1000000000; /* just kill it when you are bored */ num_partial_copies = 30; /* These parameters are randomly generated per test: * - whether to do one whole-surface copy or N partial copies per test * - which tiling modes to use (LINEAR_ALIGNED, 1D, 2D) * - which texture dimensions to use * - whether to use VRAM (all tiling modes) and GTT (staging, linear * only) allocations * - random initial pixels in src * - generate random subrectangle copies for partial blits */ for (i = 0; i < iterations; i++) { struct pipe_resource tsrc = {}, tdst = {}, *src, *dst; struct si_texture *sdst; struct si_texture *ssrc; struct cpu_texture src_cpu, dst_cpu; unsigned bpp, max_width, max_height, max_depth, j, num; unsigned gfx_blits = 0, dma_blits = 0, max_tex_side_gen; unsigned max_tex_layers; bool pass; bool do_partial_copies = rand() & 1; /* generate a random test case */ tsrc.target = tdst.target = PIPE_TEXTURE_2D_ARRAY; tsrc.depth0 = tdst.depth0 = 1; bpp = 1 << (rand() % 5); tsrc.format = tdst.format = get_format_from_bpp(bpp); max_tex_side_gen = generate_max_tex_side(max_tex_side); max_tex_layers = rand() % 4 ? 1 : 5; tsrc.width0 = (rand() % max_tex_side_gen) + 1; tsrc.height0 = (rand() % max_tex_side_gen) + 1; tsrc.array_size = (rand() % max_tex_layers) + 1; /* Have a 1/4 chance of getting power-of-two dimensions. */ if (rand() % 4 == 0) { tsrc.width0 = util_next_power_of_two(tsrc.width0); tsrc.height0 = util_next_power_of_two(tsrc.height0); } if (!do_partial_copies) { /* whole-surface copies only, same dimensions */ tdst = tsrc; } else { max_tex_side_gen = generate_max_tex_side(max_tex_side); max_tex_layers = rand() % 4 ? 1 : 5; /* many partial copies, dimensions can be different */ tdst.width0 = (rand() % max_tex_side_gen) + 1; tdst.height0 = (rand() % max_tex_side_gen) + 1; tdst.array_size = (rand() % max_tex_layers) + 1; /* Have a 1/4 chance of getting power-of-two dimensions. */ if (rand() % 4 == 0) { tdst.width0 = util_next_power_of_two(tdst.width0); tdst.height0 = util_next_power_of_two(tdst.height0); } } /* check texture sizes */ if ((uint64_t)tsrc.width0 * tsrc.height0 * tsrc.array_size * bpp + (uint64_t)tdst.width0 * tdst.height0 * tdst.array_size * bpp > max_alloc_size) { /* too large, try again */ i--; continue; } /* VRAM + the tiling mode depends on dimensions (3/4 of cases), * or GTT + linear only (1/4 of cases) */ tsrc.usage = rand() % 4 ? PIPE_USAGE_DEFAULT : PIPE_USAGE_STAGING; tdst.usage = rand() % 4 ? PIPE_USAGE_DEFAULT : PIPE_USAGE_STAGING; /* Allocate textures (both the GPU and CPU copies). * The CPU will emulate what the GPU should be doing. */ src = screen->resource_create(screen, &tsrc); dst = screen->resource_create(screen, &tdst); assert(src); assert(dst); sdst = (struct si_texture*)dst; ssrc = (struct si_texture*)src; alloc_cpu_texture(&src_cpu, &tsrc, bpp); alloc_cpu_texture(&dst_cpu, &tdst, bpp); printf("%4u: dst = (%5u x %5u x %u, %s), " " src = (%5u x %5u x %u, %s), bpp = %2u, ", i, tdst.width0, tdst.height0, tdst.array_size, array_mode_to_string(sscreen, &sdst->surface), tsrc.width0, tsrc.height0, tsrc.array_size, array_mode_to_string(sscreen, &ssrc->surface), bpp); fflush(stdout); /* set src pixels */ set_random_pixels(ctx, src, &src_cpu); /* clear dst pixels */ uint32_t zero = 0; si_clear_buffer(sctx, dst, 0, sdst->surface.surf_size, &zero, 4, SI_COHERENCY_SHADER); memset(dst_cpu.ptr, 0, dst_cpu.layer_stride * tdst.array_size); /* preparation */ max_width = MIN2(tsrc.width0, tdst.width0); max_height = MIN2(tsrc.height0, tdst.height0); max_depth = MIN2(tsrc.array_size, tdst.array_size); num = do_partial_copies ? num_partial_copies : 1; for (j = 0; j < num; j++) { int width, height, depth; int srcx, srcy, srcz, dstx, dsty, dstz; struct pipe_box box; unsigned old_num_draw_calls = sctx->num_draw_calls; unsigned old_num_dma_calls = sctx->num_dma_calls; if (!do_partial_copies) { /* copy whole src to dst */ width = max_width; height = max_height; depth = max_depth; srcx = srcy = srcz = dstx = dsty = dstz = 0; } else { /* random sub-rectangle copies from src to dst */ depth = (rand() % max_depth) + 1; srcz = rand() % (tsrc.array_size - depth + 1); dstz = rand() % (tdst.array_size - depth + 1); /* special code path to hit the tiled partial copies */ if (!ssrc->surface.is_linear && !sdst->surface.is_linear && rand() & 1) { if (max_width < 8 || max_height < 8) continue; width = ((rand() % (max_width / 8)) + 1) * 8; height = ((rand() % (max_height / 8)) + 1) * 8; srcx = rand() % (tsrc.width0 - width + 1) & ~0x7; srcy = rand() % (tsrc.height0 - height + 1) & ~0x7; dstx = rand() % (tdst.width0 - width + 1) & ~0x7; dsty = rand() % (tdst.height0 - height + 1) & ~0x7; } else { /* just make sure that it doesn't divide by zero */ assert(max_width > 0 && max_height > 0); width = (rand() % max_width) + 1; height = (rand() % max_height) + 1; srcx = rand() % (tsrc.width0 - width + 1); srcy = rand() % (tsrc.height0 - height + 1); dstx = rand() % (tdst.width0 - width + 1); dsty = rand() % (tdst.height0 - height + 1); } /* special code path to hit out-of-bounds reads in L2T */ if (ssrc->surface.is_linear && !sdst->surface.is_linear && rand() % 4 == 0) { srcx = 0; srcy = 0; srcz = 0; } } /* GPU copy */ u_box_3d(srcx, srcy, srcz, width, height, depth, &box); sctx->dma_copy(ctx, dst, 0, dstx, dsty, dstz, src, 0, &box); /* See which engine was used. */ gfx_blits += sctx->num_draw_calls > old_num_draw_calls; dma_blits += sctx->num_dma_calls > old_num_dma_calls; /* CPU copy */ util_copy_box(dst_cpu.ptr, tdst.format, dst_cpu.stride, dst_cpu.layer_stride, dstx, dsty, dstz, width, height, depth, src_cpu.ptr, src_cpu.stride, src_cpu.layer_stride, srcx, srcy, srcz); } pass = compare_textures(ctx, dst, &dst_cpu, bpp); if (pass) num_pass++; else num_fail++; printf("BLITs: GFX = %2u, DMA = %2u, %s [%u/%u]\n", gfx_blits, dma_blits, pass ? "pass" : "fail", num_pass, num_pass+num_fail); /* cleanup */ pipe_resource_reference(&src, NULL); pipe_resource_reference(&dst, NULL); free(src_cpu.ptr); free(dst_cpu.ptr); } ctx->destroy(ctx); exit(0); }