/* * Copyright © 2016 Red Hat. * Copyright © 2016 Bas Nieuwenhuizen * * based in part on anv driver which is: * Copyright © 2015 Intel Corporation * * 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. */ #include "radv_debug.h" #include "radv_private.h" #include "vk_format.h" #include "vk_util.h" #include "radv_radeon_winsys.h" #include "sid.h" #include "util/debug.h" #include "util/u_atomic.h" static unsigned radv_choose_tiling(struct radv_device *device, const VkImageCreateInfo *pCreateInfo, VkFormat format) { if (pCreateInfo->tiling == VK_IMAGE_TILING_LINEAR) { assert(pCreateInfo->samples <= 1); return RADEON_SURF_MODE_LINEAR_ALIGNED; } if (!vk_format_is_compressed(format) && !vk_format_is_depth_or_stencil(format) && device->physical_device->rad_info.chip_class <= GFX8) { /* this causes hangs in some VK CTS tests on GFX9. */ /* Textures with a very small height are recommended to be linear. */ if (pCreateInfo->imageType == VK_IMAGE_TYPE_1D || /* Only very thin and long 2D textures should benefit from * linear_aligned. */ (pCreateInfo->extent.width > 8 && pCreateInfo->extent.height <= 2)) return RADEON_SURF_MODE_LINEAR_ALIGNED; } /* MSAA resources must be 2D tiled. */ if (pCreateInfo->samples > 1) return RADEON_SURF_MODE_2D; return RADEON_SURF_MODE_2D; } static bool radv_use_tc_compat_htile_for_image(struct radv_device *device, const VkImageCreateInfo *pCreateInfo, VkFormat format) { /* TC-compat HTILE is only available for GFX8+. */ if (device->physical_device->rad_info.chip_class < GFX8) return false; if ((pCreateInfo->usage & VK_IMAGE_USAGE_STORAGE_BIT)) return false; if (pCreateInfo->tiling == VK_IMAGE_TILING_LINEAR) return false; if (pCreateInfo->mipLevels > 1) return false; /* Do not enable TC-compatible HTILE if the image isn't readable by a * shader because no texture fetches will happen. */ if (!(pCreateInfo->usage & (VK_IMAGE_USAGE_SAMPLED_BIT | VK_IMAGE_USAGE_INPUT_ATTACHMENT_BIT | VK_IMAGE_USAGE_TRANSFER_SRC_BIT))) return false; /* FIXME: for some reason TC compat with 2/4/8 samples breaks some cts * tests - disable for now. On GFX10 D32_SFLOAT is affected as well. */ if (pCreateInfo->samples >= 2 && (format == VK_FORMAT_D32_SFLOAT_S8_UINT || (format == VK_FORMAT_D32_SFLOAT && device->physical_device->rad_info.chip_class == GFX10))) return false; /* GFX9 supports both 32-bit and 16-bit depth surfaces, while GFX8 only * supports 32-bit. Though, it's possible to enable TC-compat for * 16-bit depth surfaces if no Z planes are compressed. */ if (format != VK_FORMAT_D32_SFLOAT_S8_UINT && format != VK_FORMAT_D32_SFLOAT && format != VK_FORMAT_D16_UNORM) return false; if (pCreateInfo->flags & VK_IMAGE_CREATE_MUTABLE_FORMAT_BIT) { const struct VkImageFormatListCreateInfo *format_list = (const struct VkImageFormatListCreateInfo *) vk_find_struct_const(pCreateInfo->pNext, IMAGE_FORMAT_LIST_CREATE_INFO); /* We have to ignore the existence of the list if viewFormatCount = 0 */ if (format_list && format_list->viewFormatCount) { /* compatibility is transitive, so we only need to check * one format with everything else. */ for (unsigned i = 0; i < format_list->viewFormatCount; ++i) { if (format_list->pViewFormats[i] == VK_FORMAT_UNDEFINED) continue; if (format != format_list->pViewFormats[i]) return false; } } else { return false; } } return true; } static bool radv_surface_has_scanout(struct radv_device *device, const struct radv_image_create_info *info) { if (info->bo_metadata) { if (device->physical_device->rad_info.chip_class >= GFX9) return info->bo_metadata->u.gfx9.scanout; else return info->bo_metadata->u.legacy.scanout; } return info->scanout; } static bool radv_use_dcc_for_image(struct radv_device *device, const struct radv_image *image, const VkImageCreateInfo *pCreateInfo, VkFormat format) { bool dcc_compatible_formats; bool blendable; /* DCC (Delta Color Compression) is only available for GFX8+. */ if (device->physical_device->rad_info.chip_class < GFX8) return false; if (device->instance->debug_flags & RADV_DEBUG_NO_DCC) return false; if (image->shareable) return false; /* TODO: Enable DCC for storage images. */ if ((pCreateInfo->usage & VK_IMAGE_USAGE_STORAGE_BIT)) return false; if (pCreateInfo->tiling == VK_IMAGE_TILING_LINEAR) return false; if (vk_format_is_subsampled(format) || vk_format_get_plane_count(format) > 1) return false; /* TODO: Enable DCC for mipmaps on GFX9+. */ if ((pCreateInfo->arrayLayers > 1 || pCreateInfo->mipLevels > 1) && device->physical_device->rad_info.chip_class >= GFX9) return false; /* Do not enable DCC for mipmapped arrays because performance is worse. */ if (pCreateInfo->arrayLayers > 1 && pCreateInfo->mipLevels > 1) return false; /* FIXME: DCC for MSAA with 4x and 8x samples doesn't work yet, while * 2x can be enabled with an option. */ if (pCreateInfo->samples > 2 || (pCreateInfo->samples == 2 && !device->physical_device->dcc_msaa_allowed)) return false; /* Determine if the formats are DCC compatible. */ dcc_compatible_formats = radv_is_colorbuffer_format_supported(format, &blendable); if (pCreateInfo->flags & VK_IMAGE_CREATE_MUTABLE_FORMAT_BIT) { const struct VkImageFormatListCreateInfo *format_list = (const struct VkImageFormatListCreateInfo *) vk_find_struct_const(pCreateInfo->pNext, IMAGE_FORMAT_LIST_CREATE_INFO); /* We have to ignore the existence of the list if viewFormatCount = 0 */ if (format_list && format_list->viewFormatCount) { /* compatibility is transitive, so we only need to check * one format with everything else. */ for (unsigned i = 0; i < format_list->viewFormatCount; ++i) { if (format_list->pViewFormats[i] == VK_FORMAT_UNDEFINED) continue; if (!radv_dcc_formats_compatible(format, format_list->pViewFormats[i])) dcc_compatible_formats = false; } } else { dcc_compatible_formats = false; } } if (!dcc_compatible_formats) return false; return true; } static bool radv_use_tc_compat_cmask_for_image(struct radv_device *device, struct radv_image *image) { if (!(device->instance->perftest_flags & RADV_PERFTEST_TC_COMPAT_CMASK)) return false; /* TC-compat CMASK is only available for GFX8+. */ if (device->physical_device->rad_info.chip_class < GFX8) return false; if (image->usage & VK_IMAGE_USAGE_STORAGE_BIT) return false; if (radv_image_has_dcc(image)) return false; if (!radv_image_has_cmask(image)) return false; return true; } static uint32_t si_get_bo_metadata_word1(const struct radv_device *device) { return (ATI_VENDOR_ID << 16) | device->physical_device->rad_info.pci_id; } static bool radv_is_valid_opaque_metadata(const struct radv_device *device, const struct radeon_bo_metadata *md) { if (md->metadata[0] != 1 || md->metadata[1] != si_get_bo_metadata_word1(device)) return false; if (md->size_metadata < 40) return false; return true; } static void radv_patch_surface_from_metadata(struct radv_device *device, struct radeon_surf *surface, const struct radeon_bo_metadata *md) { surface->flags = RADEON_SURF_CLR(surface->flags, MODE); if (device->physical_device->rad_info.chip_class >= GFX9) { if (md->u.gfx9.swizzle_mode > 0) surface->flags |= RADEON_SURF_SET(RADEON_SURF_MODE_2D, MODE); else surface->flags |= RADEON_SURF_SET(RADEON_SURF_MODE_LINEAR_ALIGNED, MODE); surface->u.gfx9.surf.swizzle_mode = md->u.gfx9.swizzle_mode; } else { surface->u.legacy.pipe_config = md->u.legacy.pipe_config; surface->u.legacy.bankw = md->u.legacy.bankw; surface->u.legacy.bankh = md->u.legacy.bankh; surface->u.legacy.tile_split = md->u.legacy.tile_split; surface->u.legacy.mtilea = md->u.legacy.mtilea; surface->u.legacy.num_banks = md->u.legacy.num_banks; if (md->u.legacy.macrotile == RADEON_LAYOUT_TILED) surface->flags |= RADEON_SURF_SET(RADEON_SURF_MODE_2D, MODE); else if (md->u.legacy.microtile == RADEON_LAYOUT_TILED) surface->flags |= RADEON_SURF_SET(RADEON_SURF_MODE_1D, MODE); else surface->flags |= RADEON_SURF_SET(RADEON_SURF_MODE_LINEAR_ALIGNED, MODE); } } static VkResult radv_patch_image_dimensions(struct radv_device *device, struct radv_image *image, const struct radv_image_create_info *create_info, struct ac_surf_info *image_info) { unsigned width = image->info.width; unsigned height = image->info.height; /* * minigbm sometimes allocates bigger images which is going to result in * weird strides and other properties. Lets be lenient where possible and * fail it on GFX10 (as we cannot cope there). * * Example hack: https://chromium-review.googlesource.com/c/chromiumos/platform/minigbm/+/1457777/ */ if (create_info->bo_metadata && radv_is_valid_opaque_metadata(device, create_info->bo_metadata)) { const struct radeon_bo_metadata *md = create_info->bo_metadata; if (device->physical_device->rad_info.chip_class >= GFX10) { width = G_00A004_WIDTH_LO(md->metadata[3]) + (G_00A008_WIDTH_HI(md->metadata[4]) << 2) + 1; height = S_00A008_HEIGHT(md->metadata[4]) + 1; } else { width = G_008F18_WIDTH(md->metadata[4]) + 1; height = G_008F18_HEIGHT(md->metadata[4]) + 1; } } if (image->info.width == width && image->info.height == height) return VK_SUCCESS; if (width < image->info.width || height < image->info.height) { fprintf(stderr, "The imported image has smaller dimensions than the internal\n" "dimensions. Using it is going to fail badly, so we reject\n" "this import.\n" "(internal dimensions: %d x %d, external dimensions: %d x %d)\n", image->info.width, image->info.height, width, height); return VK_ERROR_INVALID_EXTERNAL_HANDLE; } else if (device->physical_device->rad_info.chip_class >= GFX10) { fprintf(stderr, "Tried to import an image with inconsistent width on GFX10.\n" "As GFX10 has no separate stride fields we cannot cope with\n" "an inconsistency in width and will fail this import.\n" "(internal dimensions: %d x %d, external dimensions: %d x %d)\n", image->info.width, image->info.height, width, height); return VK_ERROR_INVALID_EXTERNAL_HANDLE; } else { fprintf(stderr, "Tried to import an image with inconsistent width on pre-GFX10.\n" "As GFX10 has no separate stride fields we cannot cope with\n" "an inconsistency and would fail on GFX10.\n" "(internal dimensions: %d x %d, external dimensions: %d x %d)\n", image->info.width, image->info.height, width, height); } image_info->width = width; image_info->height = height; return VK_SUCCESS; } static VkResult radv_patch_image_from_extra_info(struct radv_device *device, struct radv_image *image, const struct radv_image_create_info *create_info, struct ac_surf_info *image_info) { VkResult result = radv_patch_image_dimensions(device, image, create_info, image_info); if (result != VK_SUCCESS) return result; for (unsigned plane = 0; plane < image->plane_count; ++plane) { if (create_info->bo_metadata) { radv_patch_surface_from_metadata(device, &image->planes[plane].surface, create_info->bo_metadata); } if (radv_surface_has_scanout(device, create_info)) { image->planes[plane].surface.flags |= RADEON_SURF_SCANOUT; image->planes[plane].surface.flags |= RADEON_SURF_DISABLE_DCC; image->info.surf_index = NULL; } } return VK_SUCCESS; } static int radv_init_surface(struct radv_device *device, const struct radv_image *image, struct radeon_surf *surface, unsigned plane_id, const VkImageCreateInfo *pCreateInfo, VkFormat image_format) { unsigned array_mode = radv_choose_tiling(device, pCreateInfo, image_format); VkFormat format = vk_format_get_plane_format(image_format, plane_id); const struct vk_format_description *desc = vk_format_description(format); bool is_depth, is_stencil; is_depth = vk_format_has_depth(desc); is_stencil = vk_format_has_stencil(desc); surface->blk_w = vk_format_get_blockwidth(format); surface->blk_h = vk_format_get_blockheight(format); surface->bpe = vk_format_get_blocksize(vk_format_depth_only(format)); /* align byte per element on dword */ if (surface->bpe == 3) { surface->bpe = 4; } surface->flags = RADEON_SURF_SET(array_mode, MODE); switch (pCreateInfo->imageType){ case VK_IMAGE_TYPE_1D: if (pCreateInfo->arrayLayers > 1) surface->flags |= RADEON_SURF_SET(RADEON_SURF_TYPE_1D_ARRAY, TYPE); else surface->flags |= RADEON_SURF_SET(RADEON_SURF_TYPE_1D, TYPE); break; case VK_IMAGE_TYPE_2D: if (pCreateInfo->arrayLayers > 1) surface->flags |= RADEON_SURF_SET(RADEON_SURF_TYPE_2D_ARRAY, TYPE); else surface->flags |= RADEON_SURF_SET(RADEON_SURF_TYPE_2D, TYPE); break; case VK_IMAGE_TYPE_3D: surface->flags |= RADEON_SURF_SET(RADEON_SURF_TYPE_3D, TYPE); break; default: unreachable("unhandled image type"); } if (is_depth) { surface->flags |= RADEON_SURF_ZBUFFER; if (radv_use_tc_compat_htile_for_image(device, pCreateInfo, image_format)) surface->flags |= RADEON_SURF_TC_COMPATIBLE_HTILE; } if (is_stencil) surface->flags |= RADEON_SURF_SBUFFER; if (device->physical_device->rad_info.chip_class >= GFX9 && pCreateInfo->imageType == VK_IMAGE_TYPE_3D && vk_format_get_blocksizebits(image_format) == 128 && vk_format_is_compressed(image_format)) surface->flags |= RADEON_SURF_NO_RENDER_TARGET; surface->flags |= RADEON_SURF_OPTIMIZE_FOR_SPACE; if (!radv_use_dcc_for_image(device, image, pCreateInfo, image_format)) surface->flags |= RADEON_SURF_DISABLE_DCC; return 0; } static inline unsigned si_tile_mode_index(const struct radv_image_plane *plane, unsigned level, bool stencil) { if (stencil) return plane->surface.u.legacy.stencil_tiling_index[level]; else return plane->surface.u.legacy.tiling_index[level]; } static unsigned radv_map_swizzle(unsigned swizzle) { switch (swizzle) { case VK_SWIZZLE_Y: return V_008F0C_SQ_SEL_Y; case VK_SWIZZLE_Z: return V_008F0C_SQ_SEL_Z; case VK_SWIZZLE_W: return V_008F0C_SQ_SEL_W; case VK_SWIZZLE_0: return V_008F0C_SQ_SEL_0; case VK_SWIZZLE_1: return V_008F0C_SQ_SEL_1; default: /* VK_SWIZZLE_X */ return V_008F0C_SQ_SEL_X; } } static void radv_make_buffer_descriptor(struct radv_device *device, struct radv_buffer *buffer, VkFormat vk_format, unsigned offset, unsigned range, uint32_t *state) { const struct vk_format_description *desc; unsigned stride; uint64_t gpu_address = radv_buffer_get_va(buffer->bo); uint64_t va = gpu_address + buffer->offset; unsigned num_format, data_format; int first_non_void; desc = vk_format_description(vk_format); first_non_void = vk_format_get_first_non_void_channel(vk_format); stride = desc->block.bits / 8; va += offset; state[0] = va; state[1] = S_008F04_BASE_ADDRESS_HI(va >> 32) | S_008F04_STRIDE(stride); if (device->physical_device->rad_info.chip_class != GFX8 && stride) { range /= stride; } state[2] = range; state[3] = S_008F0C_DST_SEL_X(radv_map_swizzle(desc->swizzle[0])) | S_008F0C_DST_SEL_Y(radv_map_swizzle(desc->swizzle[1])) | S_008F0C_DST_SEL_Z(radv_map_swizzle(desc->swizzle[2])) | S_008F0C_DST_SEL_W(radv_map_swizzle(desc->swizzle[3])); if (device->physical_device->rad_info.chip_class >= GFX10) { const struct gfx10_format *fmt = &gfx10_format_table[vk_format]; /* OOB_SELECT chooses the out-of-bounds check: * - 0: (index >= NUM_RECORDS) || (offset >= STRIDE) * - 1: index >= NUM_RECORDS * - 2: NUM_RECORDS == 0 * - 3: if SWIZZLE_ENABLE == 0: offset >= NUM_RECORDS * else: swizzle_address >= NUM_RECORDS */ state[3] |= S_008F0C_FORMAT(fmt->img_format) | S_008F0C_OOB_SELECT(V_008F0C_OOB_SELECT_STRUCTURED_WITH_OFFSET) | S_008F0C_RESOURCE_LEVEL(1); } else { num_format = radv_translate_buffer_numformat(desc, first_non_void); data_format = radv_translate_buffer_dataformat(desc, first_non_void); assert(data_format != V_008F0C_BUF_DATA_FORMAT_INVALID); assert(num_format != ~0); state[3] |= S_008F0C_NUM_FORMAT(num_format) | S_008F0C_DATA_FORMAT(data_format); } } static void si_set_mutable_tex_desc_fields(struct radv_device *device, struct radv_image *image, const struct legacy_surf_level *base_level_info, unsigned plane_id, unsigned base_level, unsigned first_level, unsigned block_width, bool is_stencil, bool is_storage_image, bool disable_compression, uint32_t *state) { struct radv_image_plane *plane = &image->planes[plane_id]; uint64_t gpu_address = image->bo ? radv_buffer_get_va(image->bo) + image->offset : 0; uint64_t va = gpu_address + plane->offset; enum chip_class chip_class = device->physical_device->rad_info.chip_class; uint64_t meta_va = 0; if (chip_class >= GFX9) { if (is_stencil) va += plane->surface.u.gfx9.stencil_offset; else va += plane->surface.u.gfx9.surf_offset; } else va += base_level_info->offset; state[0] = va >> 8; if (chip_class >= GFX9 || base_level_info->mode == RADEON_SURF_MODE_2D) state[0] |= plane->surface.tile_swizzle; state[1] &= C_008F14_BASE_ADDRESS_HI; state[1] |= S_008F14_BASE_ADDRESS_HI(va >> 40); if (chip_class >= GFX8) { state[6] &= C_008F28_COMPRESSION_EN; state[7] = 0; if (!disable_compression && radv_dcc_enabled(image, first_level)) { meta_va = gpu_address + image->dcc_offset; if (chip_class <= GFX8) meta_va += base_level_info->dcc_offset; unsigned dcc_tile_swizzle = plane->surface.tile_swizzle << 8; dcc_tile_swizzle &= plane->surface.dcc_alignment - 1; meta_va |= dcc_tile_swizzle; } else if (!disable_compression && radv_image_is_tc_compat_htile(image)) { meta_va = gpu_address + image->htile_offset; } if (meta_va) { state[6] |= S_008F28_COMPRESSION_EN(1); if (chip_class <= GFX9) state[7] = meta_va >> 8; } } if (chip_class >= GFX10) { state[3] &= C_00A00C_SW_MODE; if (is_stencil) { state[3] |= S_00A00C_SW_MODE(plane->surface.u.gfx9.stencil.swizzle_mode); } else { state[3] |= S_00A00C_SW_MODE(plane->surface.u.gfx9.surf.swizzle_mode); } state[6] &= C_00A018_META_DATA_ADDRESS_LO & C_00A018_META_PIPE_ALIGNED; if (meta_va) { struct gfx9_surf_meta_flags meta; if (image->dcc_offset) meta = plane->surface.u.gfx9.dcc; else meta = plane->surface.u.gfx9.htile; state[6] |= S_00A018_META_PIPE_ALIGNED(meta.pipe_aligned) | S_00A018_META_DATA_ADDRESS_LO(meta_va >> 8); } state[7] = meta_va >> 16; } else if (chip_class == GFX9) { state[3] &= C_008F1C_SW_MODE; state[4] &= C_008F20_PITCH; if (is_stencil) { state[3] |= S_008F1C_SW_MODE(plane->surface.u.gfx9.stencil.swizzle_mode); state[4] |= S_008F20_PITCH(plane->surface.u.gfx9.stencil.epitch); } else { state[3] |= S_008F1C_SW_MODE(plane->surface.u.gfx9.surf.swizzle_mode); state[4] |= S_008F20_PITCH(plane->surface.u.gfx9.surf.epitch); } state[5] &= C_008F24_META_DATA_ADDRESS & C_008F24_META_PIPE_ALIGNED & C_008F24_META_RB_ALIGNED; if (meta_va) { struct gfx9_surf_meta_flags meta; if (image->dcc_offset) meta = plane->surface.u.gfx9.dcc; else meta = plane->surface.u.gfx9.htile; state[5] |= S_008F24_META_DATA_ADDRESS(meta_va >> 40) | S_008F24_META_PIPE_ALIGNED(meta.pipe_aligned) | S_008F24_META_RB_ALIGNED(meta.rb_aligned); } } else { /* GFX6-GFX8 */ unsigned pitch = base_level_info->nblk_x * block_width; unsigned index = si_tile_mode_index(plane, base_level, is_stencil); state[3] &= C_008F1C_TILING_INDEX; state[3] |= S_008F1C_TILING_INDEX(index); state[4] &= C_008F20_PITCH; state[4] |= S_008F20_PITCH(pitch - 1); } } static unsigned radv_tex_dim(VkImageType image_type, VkImageViewType view_type, unsigned nr_layers, unsigned nr_samples, bool is_storage_image, bool gfx9) { if (view_type == VK_IMAGE_VIEW_TYPE_CUBE || view_type == VK_IMAGE_VIEW_TYPE_CUBE_ARRAY) return is_storage_image ? V_008F1C_SQ_RSRC_IMG_2D_ARRAY : V_008F1C_SQ_RSRC_IMG_CUBE; /* GFX9 allocates 1D textures as 2D. */ if (gfx9 && image_type == VK_IMAGE_TYPE_1D) image_type = VK_IMAGE_TYPE_2D; switch (image_type) { case VK_IMAGE_TYPE_1D: return nr_layers > 1 ? V_008F1C_SQ_RSRC_IMG_1D_ARRAY : V_008F1C_SQ_RSRC_IMG_1D; case VK_IMAGE_TYPE_2D: if (nr_samples > 1) return nr_layers > 1 ? V_008F1C_SQ_RSRC_IMG_2D_MSAA_ARRAY : V_008F1C_SQ_RSRC_IMG_2D_MSAA; else return nr_layers > 1 ? V_008F1C_SQ_RSRC_IMG_2D_ARRAY : V_008F1C_SQ_RSRC_IMG_2D; case VK_IMAGE_TYPE_3D: if (view_type == VK_IMAGE_VIEW_TYPE_3D) return V_008F1C_SQ_RSRC_IMG_3D; else return V_008F1C_SQ_RSRC_IMG_2D_ARRAY; default: unreachable("illegal image type"); } } static unsigned gfx9_border_color_swizzle(const enum vk_swizzle swizzle[4]) { unsigned bc_swizzle = V_008F20_BC_SWIZZLE_XYZW; if (swizzle[3] == VK_SWIZZLE_X) { /* For the pre-defined border color values (white, opaque * black, transparent black), the only thing that matters is * that the alpha channel winds up in the correct place * (because the RGB channels are all the same) so either of * these enumerations will work. */ if (swizzle[2] == VK_SWIZZLE_Y) bc_swizzle = V_008F20_BC_SWIZZLE_WZYX; else bc_swizzle = V_008F20_BC_SWIZZLE_WXYZ; } else if (swizzle[0] == VK_SWIZZLE_X) { if (swizzle[1] == VK_SWIZZLE_Y) bc_swizzle = V_008F20_BC_SWIZZLE_XYZW; else bc_swizzle = V_008F20_BC_SWIZZLE_XWYZ; } else if (swizzle[1] == VK_SWIZZLE_X) { bc_swizzle = V_008F20_BC_SWIZZLE_YXWZ; } else if (swizzle[2] == VK_SWIZZLE_X) { bc_swizzle = V_008F20_BC_SWIZZLE_ZYXW; } return bc_swizzle; } bool vi_alpha_is_on_msb(struct radv_device *device, VkFormat format) { const struct vk_format_description *desc = vk_format_description(format); if (device->physical_device->rad_info.chip_class >= GFX10 && desc->nr_channels == 1) return desc->swizzle[3] == VK_SWIZZLE_X; return radv_translate_colorswap(format, false) <= 1; } /** * Build the sampler view descriptor for a texture (GFX10). */ static void gfx10_make_texture_descriptor(struct radv_device *device, struct radv_image *image, bool is_storage_image, VkImageViewType view_type, VkFormat vk_format, const VkComponentMapping *mapping, unsigned first_level, unsigned last_level, unsigned first_layer, unsigned last_layer, unsigned width, unsigned height, unsigned depth, uint32_t *state, uint32_t *fmask_state) { const struct vk_format_description *desc; enum vk_swizzle swizzle[4]; unsigned img_format; unsigned type; desc = vk_format_description(vk_format); img_format = gfx10_format_table[vk_format].img_format; if (desc->colorspace == VK_FORMAT_COLORSPACE_ZS) { const unsigned char swizzle_xxxx[4] = {0, 0, 0, 0}; vk_format_compose_swizzles(mapping, swizzle_xxxx, swizzle); } else { vk_format_compose_swizzles(mapping, desc->swizzle, swizzle); } type = radv_tex_dim(image->type, view_type, image->info.array_size, image->info.samples, is_storage_image, device->physical_device->rad_info.chip_class == GFX9); if (type == V_008F1C_SQ_RSRC_IMG_1D_ARRAY) { height = 1; depth = image->info.array_size; } else if (type == V_008F1C_SQ_RSRC_IMG_2D_ARRAY || type == V_008F1C_SQ_RSRC_IMG_2D_MSAA_ARRAY) { if (view_type != VK_IMAGE_VIEW_TYPE_3D) depth = image->info.array_size; } else if (type == V_008F1C_SQ_RSRC_IMG_CUBE) depth = image->info.array_size / 6; state[0] = 0; state[1] = S_00A004_FORMAT(img_format) | S_00A004_WIDTH_LO(width - 1); state[2] = S_00A008_WIDTH_HI((width - 1) >> 2) | S_00A008_HEIGHT(height - 1) | S_00A008_RESOURCE_LEVEL(1); state[3] = S_00A00C_DST_SEL_X(radv_map_swizzle(swizzle[0])) | S_00A00C_DST_SEL_Y(radv_map_swizzle(swizzle[1])) | S_00A00C_DST_SEL_Z(radv_map_swizzle(swizzle[2])) | S_00A00C_DST_SEL_W(radv_map_swizzle(swizzle[3])) | S_00A00C_BASE_LEVEL(image->info.samples > 1 ? 0 : first_level) | S_00A00C_LAST_LEVEL(image->info.samples > 1 ? util_logbase2(image->info.samples) : last_level) | S_00A00C_BC_SWIZZLE(gfx9_border_color_swizzle(swizzle)) | S_00A00C_TYPE(type); /* Depth is the the last accessible layer on gfx9+. The hw doesn't need * to know the total number of layers. */ state[4] = S_00A010_DEPTH(type == V_008F1C_SQ_RSRC_IMG_3D ? depth - 1 : last_layer) | S_00A010_BASE_ARRAY(first_layer); state[5] = S_00A014_ARRAY_PITCH(0) | S_00A014_MAX_MIP(image->info.samples > 1 ? util_logbase2(image->info.samples) : image->info.levels - 1) | S_00A014_PERF_MOD(4); state[6] = 0; state[7] = 0; if (radv_dcc_enabled(image, first_level)) { state[6] |= S_00A018_MAX_UNCOMPRESSED_BLOCK_SIZE(V_028C78_MAX_BLOCK_SIZE_256B) | S_00A018_MAX_COMPRESSED_BLOCK_SIZE(V_028C78_MAX_BLOCK_SIZE_128B) | S_00A018_ALPHA_IS_ON_MSB(vi_alpha_is_on_msb(device, vk_format)); } /* Initialize the sampler view for FMASK. */ if (radv_image_has_fmask(image)) { uint64_t gpu_address = radv_buffer_get_va(image->bo); uint32_t format; uint64_t va; assert(image->plane_count == 1); va = gpu_address + image->offset + image->fmask_offset; switch (image->info.samples) { case 2: format = V_008F0C_IMG_FORMAT_FMASK8_S2_F2; break; case 4: format = V_008F0C_IMG_FORMAT_FMASK8_S4_F4; break; case 8: format = V_008F0C_IMG_FORMAT_FMASK32_S8_F8; break; default: unreachable("invalid nr_samples"); } fmask_state[0] = (va >> 8) | image->planes[0].surface.fmask_tile_swizzle; fmask_state[1] = S_00A004_BASE_ADDRESS_HI(va >> 40) | S_00A004_FORMAT(format) | S_00A004_WIDTH_LO(width - 1); fmask_state[2] = S_00A008_WIDTH_HI((width - 1) >> 2) | S_00A008_HEIGHT(height - 1) | S_00A008_RESOURCE_LEVEL(1); fmask_state[3] = S_00A00C_DST_SEL_X(V_008F1C_SQ_SEL_X) | S_00A00C_DST_SEL_Y(V_008F1C_SQ_SEL_X) | S_00A00C_DST_SEL_Z(V_008F1C_SQ_SEL_X) | S_00A00C_DST_SEL_W(V_008F1C_SQ_SEL_X) | S_00A00C_SW_MODE(image->planes[0].surface.u.gfx9.fmask.swizzle_mode) | S_00A00C_TYPE(radv_tex_dim(image->type, view_type, image->info.array_size, 0, false, false)); fmask_state[4] = S_00A010_DEPTH(last_layer) | S_00A010_BASE_ARRAY(first_layer); fmask_state[5] = 0; fmask_state[6] = S_00A018_META_PIPE_ALIGNED(image->planes[0].surface.u.gfx9.cmask.pipe_aligned); fmask_state[7] = 0; } else if (fmask_state) memset(fmask_state, 0, 8 * 4); } /** * Build the sampler view descriptor for a texture (SI-GFX9) */ static void si_make_texture_descriptor(struct radv_device *device, struct radv_image *image, bool is_storage_image, VkImageViewType view_type, VkFormat vk_format, const VkComponentMapping *mapping, unsigned first_level, unsigned last_level, unsigned first_layer, unsigned last_layer, unsigned width, unsigned height, unsigned depth, uint32_t *state, uint32_t *fmask_state) { const struct vk_format_description *desc; enum vk_swizzle swizzle[4]; int first_non_void; unsigned num_format, data_format, type; desc = vk_format_description(vk_format); if (desc->colorspace == VK_FORMAT_COLORSPACE_ZS) { const unsigned char swizzle_xxxx[4] = {0, 0, 0, 0}; vk_format_compose_swizzles(mapping, swizzle_xxxx, swizzle); } else { vk_format_compose_swizzles(mapping, desc->swizzle, swizzle); } first_non_void = vk_format_get_first_non_void_channel(vk_format); num_format = radv_translate_tex_numformat(vk_format, desc, first_non_void); if (num_format == ~0) { num_format = 0; } data_format = radv_translate_tex_dataformat(vk_format, desc, first_non_void); if (data_format == ~0) { data_format = 0; } /* S8 with either Z16 or Z32 HTILE need a special format. */ if (device->physical_device->rad_info.chip_class == GFX9 && vk_format == VK_FORMAT_S8_UINT && radv_image_is_tc_compat_htile(image)) { if (image->vk_format == VK_FORMAT_D32_SFLOAT_S8_UINT) data_format = V_008F14_IMG_DATA_FORMAT_S8_32; else if (image->vk_format == VK_FORMAT_D16_UNORM_S8_UINT) data_format = V_008F14_IMG_DATA_FORMAT_S8_16; } type = radv_tex_dim(image->type, view_type, image->info.array_size, image->info.samples, is_storage_image, device->physical_device->rad_info.chip_class == GFX9); if (type == V_008F1C_SQ_RSRC_IMG_1D_ARRAY) { height = 1; depth = image->info.array_size; } else if (type == V_008F1C_SQ_RSRC_IMG_2D_ARRAY || type == V_008F1C_SQ_RSRC_IMG_2D_MSAA_ARRAY) { if (view_type != VK_IMAGE_VIEW_TYPE_3D) depth = image->info.array_size; } else if (type == V_008F1C_SQ_RSRC_IMG_CUBE) depth = image->info.array_size / 6; state[0] = 0; state[1] = (S_008F14_DATA_FORMAT(data_format) | S_008F14_NUM_FORMAT(num_format)); state[2] = (S_008F18_WIDTH(width - 1) | S_008F18_HEIGHT(height - 1) | S_008F18_PERF_MOD(4)); state[3] = (S_008F1C_DST_SEL_X(radv_map_swizzle(swizzle[0])) | S_008F1C_DST_SEL_Y(radv_map_swizzle(swizzle[1])) | S_008F1C_DST_SEL_Z(radv_map_swizzle(swizzle[2])) | S_008F1C_DST_SEL_W(radv_map_swizzle(swizzle[3])) | S_008F1C_BASE_LEVEL(image->info.samples > 1 ? 0 : first_level) | S_008F1C_LAST_LEVEL(image->info.samples > 1 ? util_logbase2(image->info.samples) : last_level) | S_008F1C_TYPE(type)); state[4] = 0; state[5] = S_008F24_BASE_ARRAY(first_layer); state[6] = 0; state[7] = 0; if (device->physical_device->rad_info.chip_class == GFX9) { unsigned bc_swizzle = gfx9_border_color_swizzle(swizzle); /* Depth is the last accessible layer on Gfx9. * The hw doesn't need to know the total number of layers. */ if (type == V_008F1C_SQ_RSRC_IMG_3D) state[4] |= S_008F20_DEPTH(depth - 1); else state[4] |= S_008F20_DEPTH(last_layer); state[4] |= S_008F20_BC_SWIZZLE(bc_swizzle); state[5] |= S_008F24_MAX_MIP(image->info.samples > 1 ? util_logbase2(image->info.samples) : image->info.levels - 1); } else { state[3] |= S_008F1C_POW2_PAD(image->info.levels > 1); state[4] |= S_008F20_DEPTH(depth - 1); state[5] |= S_008F24_LAST_ARRAY(last_layer); } if (image->dcc_offset) { state[6] = S_008F28_ALPHA_IS_ON_MSB(vi_alpha_is_on_msb(device, vk_format)); } else { /* The last dword is unused by hw. The shader uses it to clear * bits in the first dword of sampler state. */ if (device->physical_device->rad_info.chip_class <= GFX7 && image->info.samples <= 1) { if (first_level == last_level) state[7] = C_008F30_MAX_ANISO_RATIO; else state[7] = 0xffffffff; } } /* Initialize the sampler view for FMASK. */ if (radv_image_has_fmask(image)) { uint32_t fmask_format, num_format; uint64_t gpu_address = radv_buffer_get_va(image->bo); uint64_t va; assert(image->plane_count == 1); va = gpu_address + image->offset + image->fmask_offset; if (device->physical_device->rad_info.chip_class == GFX9) { fmask_format = V_008F14_IMG_DATA_FORMAT_FMASK; switch (image->info.samples) { case 2: num_format = V_008F14_IMG_FMASK_8_2_2; break; case 4: num_format = V_008F14_IMG_FMASK_8_4_4; break; case 8: num_format = V_008F14_IMG_FMASK_32_8_8; break; default: unreachable("invalid nr_samples"); } } else { switch (image->info.samples) { case 2: fmask_format = V_008F14_IMG_DATA_FORMAT_FMASK8_S2_F2; break; case 4: fmask_format = V_008F14_IMG_DATA_FORMAT_FMASK8_S4_F4; break; case 8: fmask_format = V_008F14_IMG_DATA_FORMAT_FMASK32_S8_F8; break; default: assert(0); fmask_format = V_008F14_IMG_DATA_FORMAT_INVALID; } num_format = V_008F14_IMG_NUM_FORMAT_UINT; } fmask_state[0] = va >> 8; fmask_state[0] |= image->planes[0].surface.fmask_tile_swizzle; fmask_state[1] = S_008F14_BASE_ADDRESS_HI(va >> 40) | S_008F14_DATA_FORMAT(fmask_format) | S_008F14_NUM_FORMAT(num_format); fmask_state[2] = S_008F18_WIDTH(width - 1) | S_008F18_HEIGHT(height - 1); fmask_state[3] = S_008F1C_DST_SEL_X(V_008F1C_SQ_SEL_X) | S_008F1C_DST_SEL_Y(V_008F1C_SQ_SEL_X) | S_008F1C_DST_SEL_Z(V_008F1C_SQ_SEL_X) | S_008F1C_DST_SEL_W(V_008F1C_SQ_SEL_X) | S_008F1C_TYPE(radv_tex_dim(image->type, view_type, image->info.array_size, 0, false, false)); fmask_state[4] = 0; fmask_state[5] = S_008F24_BASE_ARRAY(first_layer); fmask_state[6] = 0; fmask_state[7] = 0; if (device->physical_device->rad_info.chip_class == GFX9) { fmask_state[3] |= S_008F1C_SW_MODE(image->planes[0].surface.u.gfx9.fmask.swizzle_mode); fmask_state[4] |= S_008F20_DEPTH(last_layer) | S_008F20_PITCH(image->planes[0].surface.u.gfx9.fmask.epitch); fmask_state[5] |= S_008F24_META_PIPE_ALIGNED(image->planes[0].surface.u.gfx9.cmask.pipe_aligned) | S_008F24_META_RB_ALIGNED(image->planes[0].surface.u.gfx9.cmask.rb_aligned); if (radv_image_is_tc_compat_cmask(image)) { va = gpu_address + image->offset + image->cmask_offset; fmask_state[5] |= S_008F24_META_DATA_ADDRESS(va >> 40); fmask_state[6] |= S_008F28_COMPRESSION_EN(1); fmask_state[7] |= va >> 8; } } else { fmask_state[3] |= S_008F1C_TILING_INDEX(image->planes[0].surface.u.legacy.fmask.tiling_index); fmask_state[4] |= S_008F20_DEPTH(depth - 1) | S_008F20_PITCH(image->planes[0].surface.u.legacy.fmask.pitch_in_pixels - 1); fmask_state[5] |= S_008F24_LAST_ARRAY(last_layer); if (radv_image_is_tc_compat_cmask(image)) { va = gpu_address + image->offset + image->cmask_offset; fmask_state[6] |= S_008F28_COMPRESSION_EN(1); fmask_state[7] |= va >> 8; } } } else if (fmask_state) memset(fmask_state, 0, 8 * 4); } static void radv_make_texture_descriptor(struct radv_device *device, struct radv_image *image, bool is_storage_image, VkImageViewType view_type, VkFormat vk_format, const VkComponentMapping *mapping, unsigned first_level, unsigned last_level, unsigned first_layer, unsigned last_layer, unsigned width, unsigned height, unsigned depth, uint32_t *state, uint32_t *fmask_state) { if (device->physical_device->rad_info.chip_class >= GFX10) { gfx10_make_texture_descriptor(device, image, is_storage_image, view_type, vk_format, mapping, first_level, last_level, first_layer, last_layer, width, height, depth, state, fmask_state); } else { si_make_texture_descriptor(device, image, is_storage_image, view_type, vk_format, mapping, first_level, last_level, first_layer, last_layer, width, height, depth, state, fmask_state); } } static void radv_query_opaque_metadata(struct radv_device *device, struct radv_image *image, struct radeon_bo_metadata *md) { static const VkComponentMapping fixedmapping; uint32_t desc[8], i; assert(image->plane_count == 1); /* Metadata image format format version 1: * [0] = 1 (metadata format identifier) * [1] = (VENDOR_ID << 16) | PCI_ID * [2:9] = image descriptor for the whole resource * [2] is always 0, because the base address is cleared * [9] is the DCC offset bits [39:8] from the beginning of * the buffer * [10:10+LAST_LEVEL] = mipmap level offset bits [39:8] for each level */ md->metadata[0] = 1; /* metadata image format version 1 */ /* TILE_MODE_INDEX is ambiguous without a PCI ID. */ md->metadata[1] = si_get_bo_metadata_word1(device); radv_make_texture_descriptor(device, image, false, (VkImageViewType)image->type, image->vk_format, &fixedmapping, 0, image->info.levels - 1, 0, image->info.array_size - 1, image->info.width, image->info.height, image->info.depth, desc, NULL); si_set_mutable_tex_desc_fields(device, image, &image->planes[0].surface.u.legacy.level[0], 0, 0, 0, image->planes[0].surface.blk_w, false, false, false, desc); /* Clear the base address and set the relative DCC offset. */ desc[0] = 0; desc[1] &= C_008F14_BASE_ADDRESS_HI; desc[7] = image->dcc_offset >> 8; /* Dwords [2:9] contain the image descriptor. */ memcpy(&md->metadata[2], desc, sizeof(desc)); /* Dwords [10:..] contain the mipmap level offsets. */ if (device->physical_device->rad_info.chip_class <= GFX8) { for (i = 0; i <= image->info.levels - 1; i++) md->metadata[10+i] = image->planes[0].surface.u.legacy.level[i].offset >> 8; md->size_metadata = (11 + image->info.levels - 1) * 4; } else md->size_metadata = 10 * 4; } void radv_init_metadata(struct radv_device *device, struct radv_image *image, struct radeon_bo_metadata *metadata) { struct radeon_surf *surface = &image->planes[0].surface; memset(metadata, 0, sizeof(*metadata)); if (device->physical_device->rad_info.chip_class >= GFX9) { metadata->u.gfx9.swizzle_mode = surface->u.gfx9.surf.swizzle_mode; metadata->u.gfx9.scanout = (surface->flags & RADEON_SURF_SCANOUT) != 0; } else { metadata->u.legacy.microtile = surface->u.legacy.level[0].mode >= RADEON_SURF_MODE_1D ? RADEON_LAYOUT_TILED : RADEON_LAYOUT_LINEAR; metadata->u.legacy.macrotile = surface->u.legacy.level[0].mode >= RADEON_SURF_MODE_2D ? RADEON_LAYOUT_TILED : RADEON_LAYOUT_LINEAR; metadata->u.legacy.pipe_config = surface->u.legacy.pipe_config; metadata->u.legacy.bankw = surface->u.legacy.bankw; metadata->u.legacy.bankh = surface->u.legacy.bankh; metadata->u.legacy.tile_split = surface->u.legacy.tile_split; metadata->u.legacy.mtilea = surface->u.legacy.mtilea; metadata->u.legacy.num_banks = surface->u.legacy.num_banks; metadata->u.legacy.stride = surface->u.legacy.level[0].nblk_x * surface->bpe; metadata->u.legacy.scanout = (surface->flags & RADEON_SURF_SCANOUT) != 0; } radv_query_opaque_metadata(device, image, metadata); } void radv_image_override_offset_stride(struct radv_device *device, struct radv_image *image, uint64_t offset, uint32_t stride) { struct radeon_surf *surface = &image->planes[0].surface; unsigned bpe = vk_format_get_blocksizebits(image->vk_format) / 8; if (device->physical_device->rad_info.chip_class >= GFX9) { if (stride) { surface->u.gfx9.surf_pitch = stride; surface->u.gfx9.surf_slice_size = (uint64_t)stride * surface->u.gfx9.surf_height * bpe; } surface->u.gfx9.surf_offset = offset; } else { surface->u.legacy.level[0].nblk_x = stride; surface->u.legacy.level[0].slice_size_dw = ((uint64_t)stride * surface->u.legacy.level[0].nblk_y * bpe) / 4; if (offset) { for (unsigned i = 0; i < ARRAY_SIZE(surface->u.legacy.level); ++i) surface->u.legacy.level[i].offset += offset; } } } static void radv_image_alloc_fmask(struct radv_device *device, struct radv_image *image) { unsigned fmask_alignment = image->planes[0].surface.fmask_alignment; image->fmask_offset = align64(image->size, fmask_alignment); image->size = image->fmask_offset + image->planes[0].surface.fmask_size; image->alignment = MAX2(image->alignment, fmask_alignment); } static void radv_image_alloc_cmask(struct radv_device *device, struct radv_image *image) { unsigned cmask_alignment = image->planes[0].surface.cmask_alignment; unsigned cmask_size = image->planes[0].surface.cmask_size; uint32_t clear_value_size = 0; if (!cmask_size) return; assert(cmask_alignment); image->cmask_offset = align64(image->size, cmask_alignment); /* + 8 for storing the clear values */ if (!image->clear_value_offset) { image->clear_value_offset = image->cmask_offset + cmask_size; clear_value_size = 8; } image->size = image->cmask_offset + cmask_size + clear_value_size; image->alignment = MAX2(image->alignment, cmask_alignment); } static void radv_image_alloc_dcc(struct radv_image *image) { assert(image->plane_count == 1); image->dcc_offset = align64(image->size, image->planes[0].surface.dcc_alignment); /* + 24 for storing the clear values + fce pred + dcc pred for each mip */ image->clear_value_offset = image->dcc_offset + image->planes[0].surface.dcc_size; image->fce_pred_offset = image->clear_value_offset + 8 * image->info.levels; image->dcc_pred_offset = image->clear_value_offset + 16 * image->info.levels; image->size = image->dcc_offset + image->planes[0].surface.dcc_size + 24 * image->info.levels; image->alignment = MAX2(image->alignment, image->planes[0].surface.dcc_alignment); } static void radv_image_alloc_htile(struct radv_device *device, struct radv_image *image) { image->htile_offset = align64(image->size, image->planes[0].surface.htile_alignment); /* + 8 for storing the clear values */ image->clear_value_offset = image->htile_offset + image->planes[0].surface.htile_size; image->size = image->clear_value_offset + image->info.levels * 8; if (radv_image_is_tc_compat_htile(image) && device->physical_device->rad_info.has_tc_compat_zrange_bug) { /* Metadata for the TC-compatible HTILE hardware bug which * have to be fixed by updating ZRANGE_PRECISION when doing * fast depth clears to 0.0f. */ image->tc_compat_zrange_offset = image->size; image->size = image->tc_compat_zrange_offset + image->info.levels * 4; } image->alignment = align64(image->alignment, image->planes[0].surface.htile_alignment); } static inline bool radv_image_can_enable_dcc_or_cmask(struct radv_image *image) { if (image->info.samples <= 1 && image->info.width * image->info.height <= 512 * 512) { /* Do not enable CMASK or DCC for small surfaces where the cost * of the eliminate pass can be higher than the benefit of fast * clear. RadeonSI does this, but the image threshold is * different. */ return false; } return image->usage & VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT && (image->exclusive || image->queue_family_mask == 1); } static inline bool radv_image_can_enable_dcc(struct radv_device *device, struct radv_image *image) { if (!radv_image_can_enable_dcc_or_cmask(image) || !radv_image_has_dcc(image)) return false; /* On GFX8, DCC layers can be interleaved and it's currently only * enabled if slice size is equal to the per slice fast clear size * because the driver assumes that portions of multiple layers are * contiguous during fast clears. */ if (image->info.array_size > 1) { const struct legacy_surf_level *surf_level = &image->planes[0].surface.u.legacy.level[0]; assert(device->physical_device->rad_info.chip_class == GFX8); if (image->planes[0].surface.dcc_slice_size != surf_level->dcc_fast_clear_size) return false; } return true; } static inline bool radv_image_can_enable_cmask(struct radv_image *image) { if (image->planes[0].surface.bpe > 8 && image->info.samples == 1) { /* Do not enable CMASK for non-MSAA images (fast color clear) * because 128 bit formats are not supported, but FMASK might * still be used. */ return false; } return radv_image_can_enable_dcc_or_cmask(image) && image->info.levels == 1 && image->info.depth == 1 && !image->planes[0].surface.is_linear; } static inline bool radv_image_can_enable_fmask(struct radv_image *image) { return image->info.samples > 1 && image->usage & VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT; } static inline bool radv_image_can_enable_htile(struct radv_image *image) { return radv_image_has_htile(image) && image->info.levels == 1 && image->info.width * image->info.height >= 8 * 8; } static void radv_image_disable_dcc(struct radv_image *image) { for (unsigned i = 0; i < image->plane_count; ++i) image->planes[i].surface.dcc_size = 0; } static void radv_image_disable_htile(struct radv_image *image) { for (unsigned i = 0; i < image->plane_count; ++i) image->planes[i].surface.htile_size = 0; } VkResult radv_image_create_layout(struct radv_device *device, struct radv_image_create_info create_info, struct radv_image *image) { /* Check that we did not initialize things earlier */ assert(!image->planes[0].surface.surf_size); /* Clear the pCreateInfo pointer so we catch issues in the delayed case when we test in the * common internal case. */ create_info.vk_info = NULL; struct ac_surf_info image_info = image->info; VkResult result = radv_patch_image_from_extra_info(device, image, &create_info, &image_info); if (result != VK_SUCCESS) return result; image->size = 0; image->alignment = 1; for (unsigned plane = 0; plane < image->plane_count; ++plane) { struct ac_surf_info info = image_info; if (plane) { const struct vk_format_description *desc = vk_format_description(image->vk_format); assert(info.width % desc->width_divisor == 0); assert(info.height % desc->height_divisor == 0); info.width /= desc->width_divisor; info.height /= desc->height_divisor; } device->ws->surface_init(device->ws, &info, &image->planes[plane].surface); image->planes[plane].offset = align(image->size, image->planes[plane].surface.surf_alignment); image->size = image->planes[plane].offset + image->planes[plane].surface.surf_size; image->alignment = image->planes[plane].surface.surf_alignment; image->planes[plane].format = vk_format_get_plane_format(image->vk_format, plane); } if (!create_info.no_metadata_planes) { /* Try to enable DCC first. */ if (radv_image_can_enable_dcc(device, image)) { radv_image_alloc_dcc(image); if (image->info.samples > 1) { /* CMASK should be enabled because DCC fast * clear with MSAA needs it. */ assert(radv_image_can_enable_cmask(image)); radv_image_alloc_cmask(device, image); } } else { /* When DCC cannot be enabled, try CMASK. */ radv_image_disable_dcc(image); if (radv_image_can_enable_cmask(image)) { radv_image_alloc_cmask(device, image); } } /* Try to enable FMASK for multisampled images. */ if (radv_image_can_enable_fmask(image)) { radv_image_alloc_fmask(device, image); if (radv_use_tc_compat_cmask_for_image(device, image)) image->tc_compatible_cmask = true; } else { /* Otherwise, try to enable HTILE for depth surfaces. */ if (radv_image_can_enable_htile(image) && !(device->instance->debug_flags & RADV_DEBUG_NO_HIZ)) { image->tc_compatible_htile = image->planes[0].surface.flags & RADEON_SURF_TC_COMPATIBLE_HTILE; radv_image_alloc_htile(device, image); } else { radv_image_disable_htile(image); } } } else { radv_image_disable_dcc(image); radv_image_disable_htile(image); } assert(image->planes[0].surface.surf_size); return VK_SUCCESS; } VkResult radv_image_create(VkDevice _device, const struct radv_image_create_info *create_info, const VkAllocationCallbacks* alloc, VkImage *pImage) { RADV_FROM_HANDLE(radv_device, device, _device); const VkImageCreateInfo *pCreateInfo = create_info->vk_info; struct radv_image *image = NULL; VkFormat format = radv_select_android_external_format(pCreateInfo->pNext, pCreateInfo->format); assert(pCreateInfo->sType == VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO); const unsigned plane_count = vk_format_get_plane_count(format); const size_t image_struct_size = sizeof(*image) + sizeof(struct radv_image_plane) * plane_count; radv_assert(pCreateInfo->mipLevels > 0); radv_assert(pCreateInfo->arrayLayers > 0); radv_assert(pCreateInfo->samples > 0); radv_assert(pCreateInfo->extent.width > 0); radv_assert(pCreateInfo->extent.height > 0); radv_assert(pCreateInfo->extent.depth > 0); image = vk_zalloc2(&device->alloc, alloc, image_struct_size, 8, VK_SYSTEM_ALLOCATION_SCOPE_OBJECT); if (!image) return vk_error(device->instance, VK_ERROR_OUT_OF_HOST_MEMORY); image->type = pCreateInfo->imageType; image->info.width = pCreateInfo->extent.width; image->info.height = pCreateInfo->extent.height; image->info.depth = pCreateInfo->extent.depth; image->info.samples = pCreateInfo->samples; image->info.storage_samples = pCreateInfo->samples; image->info.array_size = pCreateInfo->arrayLayers; image->info.levels = pCreateInfo->mipLevels; image->info.num_channels = vk_format_get_nr_components(format); image->vk_format = format; image->tiling = pCreateInfo->tiling; image->usage = pCreateInfo->usage; image->flags = pCreateInfo->flags; image->plane_count = plane_count; image->exclusive = pCreateInfo->sharingMode == VK_SHARING_MODE_EXCLUSIVE; if (pCreateInfo->sharingMode == VK_SHARING_MODE_CONCURRENT) { for (uint32_t i = 0; i < pCreateInfo->queueFamilyIndexCount; ++i) if (pCreateInfo->pQueueFamilyIndices[i] == VK_QUEUE_FAMILY_EXTERNAL || pCreateInfo->pQueueFamilyIndices[i] == VK_QUEUE_FAMILY_FOREIGN_EXT) image->queue_family_mask |= (1u << RADV_MAX_QUEUE_FAMILIES) - 1u; else image->queue_family_mask |= 1u << pCreateInfo->pQueueFamilyIndices[i]; } const VkExternalMemoryImageCreateInfo *external_info = vk_find_struct_const(pCreateInfo->pNext, EXTERNAL_MEMORY_IMAGE_CREATE_INFO) ; image->shareable = external_info; if (!vk_format_is_depth_or_stencil(format) && !image->shareable) { image->info.surf_index = &device->image_mrt_offset_counter; } for (unsigned plane = 0; plane < image->plane_count; ++plane) { radv_init_surface(device, image, &image->planes[plane].surface, plane, pCreateInfo, format); } bool delay_layout = external_info && (external_info->handleTypes & VK_EXTERNAL_MEMORY_HANDLE_TYPE_ANDROID_HARDWARE_BUFFER_BIT_ANDROID); if (delay_layout) { *pImage = radv_image_to_handle(image); assert (!(image->flags & VK_IMAGE_CREATE_SPARSE_BINDING_BIT)); return VK_SUCCESS; } ASSERTED VkResult result = radv_image_create_layout(device, *create_info, image); assert(result == VK_SUCCESS); if (image->flags & VK_IMAGE_CREATE_SPARSE_BINDING_BIT) { image->alignment = MAX2(image->alignment, 4096); image->size = align64(image->size, image->alignment); image->offset = 0; image->bo = device->ws->buffer_create(device->ws, image->size, image->alignment, 0, RADEON_FLAG_VIRTUAL, RADV_BO_PRIORITY_VIRTUAL); if (!image->bo) { vk_free2(&device->alloc, alloc, image); return vk_error(device->instance, VK_ERROR_OUT_OF_DEVICE_MEMORY); } } *pImage = radv_image_to_handle(image); return VK_SUCCESS; } static void radv_image_view_make_descriptor(struct radv_image_view *iview, struct radv_device *device, VkFormat vk_format, const VkComponentMapping *components, bool is_storage_image, bool disable_compression, unsigned plane_id, unsigned descriptor_plane_id) { struct radv_image *image = iview->image; struct radv_image_plane *plane = &image->planes[plane_id]; const struct vk_format_description *format_desc = vk_format_description(image->vk_format); bool is_stencil = iview->aspect_mask == VK_IMAGE_ASPECT_STENCIL_BIT; uint32_t blk_w; union radv_descriptor *descriptor; uint32_t hw_level = 0; if (is_storage_image) { descriptor = &iview->storage_descriptor; } else { descriptor = &iview->descriptor; } assert(vk_format_get_plane_count(vk_format) == 1); assert(plane->surface.blk_w % vk_format_get_blockwidth(plane->format) == 0); blk_w = plane->surface.blk_w / vk_format_get_blockwidth(plane->format) * vk_format_get_blockwidth(vk_format); if (device->physical_device->rad_info.chip_class >= GFX9) hw_level = iview->base_mip; radv_make_texture_descriptor(device, image, is_storage_image, iview->type, vk_format, components, hw_level, hw_level + iview->level_count - 1, iview->base_layer, iview->base_layer + iview->layer_count - 1, iview->extent.width / (plane_id ? format_desc->width_divisor : 1), iview->extent.height / (plane_id ? format_desc->height_divisor : 1), iview->extent.depth, descriptor->plane_descriptors[descriptor_plane_id], descriptor_plane_id ? NULL : descriptor->fmask_descriptor); const struct legacy_surf_level *base_level_info = NULL; if (device->physical_device->rad_info.chip_class <= GFX9) { if (is_stencil) base_level_info = &plane->surface.u.legacy.stencil_level[iview->base_mip]; else base_level_info = &plane->surface.u.legacy.level[iview->base_mip]; } si_set_mutable_tex_desc_fields(device, image, base_level_info, plane_id, iview->base_mip, iview->base_mip, blk_w, is_stencil, is_storage_image, is_storage_image || disable_compression, descriptor->plane_descriptors[descriptor_plane_id]); } static unsigned radv_plane_from_aspect(VkImageAspectFlags mask) { switch(mask) { case VK_IMAGE_ASPECT_PLANE_1_BIT: return 1; case VK_IMAGE_ASPECT_PLANE_2_BIT: return 2; default: return 0; } } VkFormat radv_get_aspect_format(struct radv_image *image, VkImageAspectFlags mask) { switch(mask) { case VK_IMAGE_ASPECT_PLANE_0_BIT: return image->planes[0].format; case VK_IMAGE_ASPECT_PLANE_1_BIT: return image->planes[1].format; case VK_IMAGE_ASPECT_PLANE_2_BIT: return image->planes[2].format; case VK_IMAGE_ASPECT_STENCIL_BIT: return vk_format_stencil_only(image->vk_format); case VK_IMAGE_ASPECT_DEPTH_BIT: return vk_format_depth_only(image->vk_format); case VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT: return vk_format_depth_only(image->vk_format); default: return image->vk_format; } } void radv_image_view_init(struct radv_image_view *iview, struct radv_device *device, const VkImageViewCreateInfo* pCreateInfo, const struct radv_image_view_extra_create_info* extra_create_info) { RADV_FROM_HANDLE(radv_image, image, pCreateInfo->image); const VkImageSubresourceRange *range = &pCreateInfo->subresourceRange; switch (image->type) { case VK_IMAGE_TYPE_1D: case VK_IMAGE_TYPE_2D: assert(range->baseArrayLayer + radv_get_layerCount(image, range) - 1 <= image->info.array_size); break; case VK_IMAGE_TYPE_3D: assert(range->baseArrayLayer + radv_get_layerCount(image, range) - 1 <= radv_minify(image->info.depth, range->baseMipLevel)); break; default: unreachable("bad VkImageType"); } iview->image = image; iview->bo = image->bo; iview->type = pCreateInfo->viewType; iview->plane_id = radv_plane_from_aspect(pCreateInfo->subresourceRange.aspectMask); iview->aspect_mask = pCreateInfo->subresourceRange.aspectMask; iview->multiple_planes = vk_format_get_plane_count(image->vk_format) > 1 && iview->aspect_mask == VK_IMAGE_ASPECT_COLOR_BIT; iview->vk_format = pCreateInfo->format; /* If the image has an Android external format, pCreateInfo->format will be * VK_FORMAT_UNDEFINED. */ if (iview->vk_format == VK_FORMAT_UNDEFINED) iview->vk_format = image->vk_format; if (iview->aspect_mask == VK_IMAGE_ASPECT_STENCIL_BIT) { iview->vk_format = vk_format_stencil_only(iview->vk_format); } else if (iview->aspect_mask == VK_IMAGE_ASPECT_DEPTH_BIT) { iview->vk_format = vk_format_depth_only(iview->vk_format); } if (device->physical_device->rad_info.chip_class >= GFX9) { iview->extent = (VkExtent3D) { .width = image->info.width, .height = image->info.height, .depth = image->info.depth, }; } else { iview->extent = (VkExtent3D) { .width = radv_minify(image->info.width , range->baseMipLevel), .height = radv_minify(image->info.height, range->baseMipLevel), .depth = radv_minify(image->info.depth , range->baseMipLevel), }; } if (iview->vk_format != image->planes[iview->plane_id].format) { unsigned view_bw = vk_format_get_blockwidth(iview->vk_format); unsigned view_bh = vk_format_get_blockheight(iview->vk_format); unsigned img_bw = vk_format_get_blockwidth(image->vk_format); unsigned img_bh = vk_format_get_blockheight(image->vk_format); iview->extent.width = round_up_u32(iview->extent.width * view_bw, img_bw); iview->extent.height = round_up_u32(iview->extent.height * view_bh, img_bh); /* Comment ported from amdvlk - * If we have the following image: * Uncompressed pixels Compressed block sizes (4x4) * mip0: 22 x 22 6 x 6 * mip1: 11 x 11 3 x 3 * mip2: 5 x 5 2 x 2 * mip3: 2 x 2 1 x 1 * mip4: 1 x 1 1 x 1 * * On GFX9 the descriptor is always programmed with the WIDTH and HEIGHT of the base level and the HW is * calculating the degradation of the block sizes down the mip-chain as follows (straight-up * divide-by-two integer math): * mip0: 6x6 * mip1: 3x3 * mip2: 1x1 * mip3: 1x1 * * This means that mip2 will be missing texels. * * Fix this by calculating the base mip's width and height, then convert that, and round it * back up to get the level 0 size. * Clamp the converted size between the original values, and next power of two, which * means we don't oversize the image. */ if (device->physical_device->rad_info.chip_class >= GFX9 && vk_format_is_compressed(image->vk_format) && !vk_format_is_compressed(iview->vk_format)) { unsigned lvl_width = radv_minify(image->info.width , range->baseMipLevel); unsigned lvl_height = radv_minify(image->info.height, range->baseMipLevel); lvl_width = round_up_u32(lvl_width * view_bw, img_bw); lvl_height = round_up_u32(lvl_height * view_bh, img_bh); lvl_width <<= range->baseMipLevel; lvl_height <<= range->baseMipLevel; iview->extent.width = CLAMP(lvl_width, iview->extent.width, iview->image->planes[0].surface.u.gfx9.surf_pitch); iview->extent.height = CLAMP(lvl_height, iview->extent.height, iview->image->planes[0].surface.u.gfx9.surf_height); } } iview->base_layer = range->baseArrayLayer; iview->layer_count = radv_get_layerCount(image, range); iview->base_mip = range->baseMipLevel; iview->level_count = radv_get_levelCount(image, range); bool disable_compression = extra_create_info ? extra_create_info->disable_compression: false; for (unsigned i = 0; i < (iview->multiple_planes ? vk_format_get_plane_count(image->vk_format) : 1); ++i) { VkFormat format = vk_format_get_plane_format(iview->vk_format, i); radv_image_view_make_descriptor(iview, device, format, &pCreateInfo->components, false, disable_compression, iview->plane_id + i, i); radv_image_view_make_descriptor(iview, device, format, &pCreateInfo->components, true, disable_compression, iview->plane_id + i, i); } } bool radv_layout_is_htile_compressed(const struct radv_image *image, VkImageLayout layout, bool in_render_loop, unsigned queue_mask) { if (radv_image_is_tc_compat_htile(image)) { if (layout == VK_IMAGE_LAYOUT_GENERAL && !in_render_loop && !(image->usage & VK_IMAGE_USAGE_STORAGE_BIT)) { /* It should be safe to enable TC-compat HTILE with * VK_IMAGE_LAYOUT_GENERAL if we are not in a render * loop and if the image doesn't have the storage bit * set. This improves performance for apps that use * GENERAL for the main depth pass because this allows * compression and this reduces the number of * decompressions from/to GENERAL. */ return true; } return layout != VK_IMAGE_LAYOUT_GENERAL; } return radv_image_has_htile(image) && (layout == VK_IMAGE_LAYOUT_DEPTH_STENCIL_ATTACHMENT_OPTIMAL || layout == VK_IMAGE_LAYOUT_DEPTH_ATTACHMENT_OPTIMAL_KHR || layout == VK_IMAGE_LAYOUT_STENCIL_ATTACHMENT_OPTIMAL_KHR || (layout == VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL && queue_mask == (1u << RADV_QUEUE_GENERAL))); } bool radv_layout_can_fast_clear(const struct radv_image *image, VkImageLayout layout, bool in_render_loop, unsigned queue_mask) { return layout == VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL; } bool radv_layout_dcc_compressed(const struct radv_device *device, const struct radv_image *image, VkImageLayout layout, bool in_render_loop, unsigned queue_mask) { /* Don't compress compute transfer dst, as image stores are not supported. */ if (layout == VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL && (queue_mask & (1u << RADV_QUEUE_COMPUTE))) return false; return radv_image_has_dcc(image) && layout != VK_IMAGE_LAYOUT_GENERAL; } unsigned radv_image_queue_family_mask(const struct radv_image *image, uint32_t family, uint32_t queue_family) { if (!image->exclusive) return image->queue_family_mask; if (family == VK_QUEUE_FAMILY_EXTERNAL || family == VK_QUEUE_FAMILY_FOREIGN_EXT) return (1u << RADV_MAX_QUEUE_FAMILIES) - 1u; if (family == VK_QUEUE_FAMILY_IGNORED) return 1u << queue_family; return 1u << family; } VkResult radv_CreateImage(VkDevice device, const VkImageCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkImage *pImage) { #ifdef ANDROID const VkNativeBufferANDROID *gralloc_info = vk_find_struct_const(pCreateInfo->pNext, NATIVE_BUFFER_ANDROID); if (gralloc_info) return radv_image_from_gralloc(device, pCreateInfo, gralloc_info, pAllocator, pImage); #endif const struct wsi_image_create_info *wsi_info = vk_find_struct_const(pCreateInfo->pNext, WSI_IMAGE_CREATE_INFO_MESA); bool scanout = wsi_info && wsi_info->scanout; return radv_image_create(device, &(struct radv_image_create_info) { .vk_info = pCreateInfo, .scanout = scanout, }, pAllocator, pImage); } void radv_DestroyImage(VkDevice _device, VkImage _image, const VkAllocationCallbacks *pAllocator) { RADV_FROM_HANDLE(radv_device, device, _device); RADV_FROM_HANDLE(radv_image, image, _image); if (!image) return; if (image->flags & VK_IMAGE_CREATE_SPARSE_BINDING_BIT) device->ws->buffer_destroy(image->bo); if (image->owned_memory != VK_NULL_HANDLE) radv_FreeMemory(_device, image->owned_memory, pAllocator); vk_free2(&device->alloc, pAllocator, image); } void radv_GetImageSubresourceLayout( VkDevice _device, VkImage _image, const VkImageSubresource* pSubresource, VkSubresourceLayout* pLayout) { RADV_FROM_HANDLE(radv_image, image, _image); RADV_FROM_HANDLE(radv_device, device, _device); int level = pSubresource->mipLevel; int layer = pSubresource->arrayLayer; unsigned plane_id = radv_plane_from_aspect(pSubresource->aspectMask); struct radv_image_plane *plane = &image->planes[plane_id]; struct radeon_surf *surface = &plane->surface; if (device->physical_device->rad_info.chip_class >= GFX9) { uint64_t level_offset = surface->is_linear ? surface->u.gfx9.offset[level] : 0; pLayout->offset = plane->offset + level_offset + surface->u.gfx9.surf_slice_size * layer; if (image->vk_format == VK_FORMAT_R32G32B32_UINT || image->vk_format == VK_FORMAT_R32G32B32_SINT || image->vk_format == VK_FORMAT_R32G32B32_SFLOAT) { /* Adjust the number of bytes between each row because * the pitch is actually the number of components per * row. */ pLayout->rowPitch = surface->u.gfx9.surf_pitch * surface->bpe / 3; } else { uint32_t pitch = surface->is_linear ? surface->u.gfx9.pitch[level] : surface->u.gfx9.surf_pitch; assert(util_is_power_of_two_nonzero(surface->bpe)); pLayout->rowPitch = pitch * surface->bpe; } pLayout->arrayPitch = surface->u.gfx9.surf_slice_size; pLayout->depthPitch = surface->u.gfx9.surf_slice_size; pLayout->size = surface->u.gfx9.surf_slice_size; if (image->type == VK_IMAGE_TYPE_3D) pLayout->size *= u_minify(image->info.depth, level); } else { pLayout->offset = plane->offset + surface->u.legacy.level[level].offset + (uint64_t)surface->u.legacy.level[level].slice_size_dw * 4 * layer; pLayout->rowPitch = surface->u.legacy.level[level].nblk_x * surface->bpe; pLayout->arrayPitch = (uint64_t)surface->u.legacy.level[level].slice_size_dw * 4; pLayout->depthPitch = (uint64_t)surface->u.legacy.level[level].slice_size_dw * 4; pLayout->size = (uint64_t)surface->u.legacy.level[level].slice_size_dw * 4; if (image->type == VK_IMAGE_TYPE_3D) pLayout->size *= u_minify(image->info.depth, level); } } VkResult radv_CreateImageView(VkDevice _device, const VkImageViewCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkImageView *pView) { RADV_FROM_HANDLE(radv_device, device, _device); struct radv_image_view *view; view = vk_alloc2(&device->alloc, pAllocator, sizeof(*view), 8, VK_SYSTEM_ALLOCATION_SCOPE_OBJECT); if (view == NULL) return vk_error(device->instance, VK_ERROR_OUT_OF_HOST_MEMORY); radv_image_view_init(view, device, pCreateInfo, NULL); *pView = radv_image_view_to_handle(view); return VK_SUCCESS; } void radv_DestroyImageView(VkDevice _device, VkImageView _iview, const VkAllocationCallbacks *pAllocator) { RADV_FROM_HANDLE(radv_device, device, _device); RADV_FROM_HANDLE(radv_image_view, iview, _iview); if (!iview) return; vk_free2(&device->alloc, pAllocator, iview); } void radv_buffer_view_init(struct radv_buffer_view *view, struct radv_device *device, const VkBufferViewCreateInfo* pCreateInfo) { RADV_FROM_HANDLE(radv_buffer, buffer, pCreateInfo->buffer); view->bo = buffer->bo; view->range = pCreateInfo->range == VK_WHOLE_SIZE ? buffer->size - pCreateInfo->offset : pCreateInfo->range; view->vk_format = pCreateInfo->format; radv_make_buffer_descriptor(device, buffer, view->vk_format, pCreateInfo->offset, view->range, view->state); } VkResult radv_CreateBufferView(VkDevice _device, const VkBufferViewCreateInfo *pCreateInfo, const VkAllocationCallbacks *pAllocator, VkBufferView *pView) { RADV_FROM_HANDLE(radv_device, device, _device); struct radv_buffer_view *view; view = vk_alloc2(&device->alloc, pAllocator, sizeof(*view), 8, VK_SYSTEM_ALLOCATION_SCOPE_OBJECT); if (!view) return vk_error(device->instance, VK_ERROR_OUT_OF_HOST_MEMORY); radv_buffer_view_init(view, device, pCreateInfo); *pView = radv_buffer_view_to_handle(view); return VK_SUCCESS; } void radv_DestroyBufferView(VkDevice _device, VkBufferView bufferView, const VkAllocationCallbacks *pAllocator) { RADV_FROM_HANDLE(radv_device, device, _device); RADV_FROM_HANDLE(radv_buffer_view, view, bufferView); if (!view) return; vk_free2(&device->alloc, pAllocator, view); }