yuzu/src/video_core/textures/decoders.cpp

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// Copyright 2018 yuzu Emulator Project
// Licensed under GPLv2 or any later version
// Refer to the license.txt file included.
#include <cmath>
#include <cstring>
#include "common/alignment.h"
#include "common/assert.h"
#include "core/memory.h"
#include "video_core/gpu.h"
#include "video_core/textures/decoders.h"
#include "video_core/textures/texture.h"
namespace Tegra::Texture {
/**
* This table represents the internal swizzle of a gob,
* in format 16 bytes x 2 sector packing.
* Calculates the offset of an (x, y) position within a swizzled texture.
* Taken from the Tegra X1 Technical Reference Manual. pages 1187-1188
*/
template <std::size_t N, std::size_t M, u32 Align>
struct alignas(64) SwizzleTable {
static_assert(M * Align == 64, "Swizzle Table does not align to GOB");
constexpr SwizzleTable() {
for (u32 y = 0; y < N; ++y) {
for (u32 x = 0; x < M; ++x) {
const u32 x2 = x * Align;
values[y][x] = static_cast<u16>(((x2 % 64) / 32) * 256 + ((y % 8) / 2) * 64 +
((x2 % 32) / 16) * 32 + (y % 2) * 16 + (x2 % 16));
}
}
}
const std::array<u16, M>& operator[](std::size_t index) const {
return values[index];
}
std::array<std::array<u16, M>, N> values{};
};
constexpr auto legacy_swizzle_table = SwizzleTable<8, 64, 1>();
constexpr auto fast_swizzle_table = SwizzleTable<8, 4, 16>();
static void LegacySwizzleData(u32 width, u32 height, u32 bytes_per_pixel, u32 out_bytes_per_pixel,
u8* swizzled_data, u8* unswizzled_data, bool unswizzle,
u32 block_height) {
std::array<u8*, 2> data_ptrs;
const std::size_t stride = width * bytes_per_pixel;
const std::size_t gobs_in_x = 64;
const std::size_t gobs_in_y = 8;
const std::size_t gobs_size = gobs_in_x * gobs_in_y;
const std::size_t image_width_in_gobs{(stride + gobs_in_x - 1) / gobs_in_x};
for (std::size_t y = 0; y < height; ++y) {
const std::size_t gob_y_address =
(y / (gobs_in_y * block_height)) * gobs_size * block_height * image_width_in_gobs +
(y % (gobs_in_y * block_height) / gobs_in_y) * gobs_size;
const auto& table = legacy_swizzle_table[y % gobs_in_y];
for (std::size_t x = 0; x < width; ++x) {
const std::size_t gob_address =
gob_y_address + (x * bytes_per_pixel / gobs_in_x) * gobs_size * block_height;
const std::size_t x2 = x * bytes_per_pixel;
const std::size_t swizzle_offset = gob_address + table[x2 % gobs_in_x];
const std::size_t pixel_index = (x + y * width) * out_bytes_per_pixel;
data_ptrs[unswizzle] = swizzled_data + swizzle_offset;
data_ptrs[!unswizzle] = unswizzled_data + pixel_index;
std::memcpy(data_ptrs[0], data_ptrs[1], bytes_per_pixel);
}
}
}
static void FastSwizzleData(u32 width, u32 height, u32 bytes_per_pixel, u32 out_bytes_per_pixel,
u8* swizzled_data, u8* unswizzled_data, bool unswizzle,
u32 block_height) {
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std::array<u8*, 2> data_ptrs;
const std::size_t stride{width * bytes_per_pixel};
const std::size_t gobs_in_x = 64;
const std::size_t gobs_in_y = 8;
const std::size_t gobs_size = gobs_in_x * gobs_in_y;
const std::size_t image_width_in_gobs{(stride + gobs_in_x - 1) / gobs_in_x};
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const std::size_t copy_size{16};
for (std::size_t y = 0; y < height; ++y) {
const std::size_t initial_gob =
(y / (gobs_in_y * block_height)) * gobs_size * block_height * image_width_in_gobs +
(y % (gobs_in_y * block_height) / gobs_in_y) * gobs_size;
const std::size_t pixel_base{y * width * out_bytes_per_pixel};
const auto& table = fast_swizzle_table[y % gobs_in_y];
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for (std::size_t xb = 0; xb < stride; xb += copy_size) {
const std::size_t gob_address{initial_gob +
(xb / gobs_in_x) * gobs_size * block_height};
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const std::size_t swizzle_offset{gob_address + table[(xb / 16) % 4]};
const std::size_t out_x = xb * out_bytes_per_pixel / bytes_per_pixel;
const std::size_t pixel_index{out_x + pixel_base};
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data_ptrs[unswizzle] = swizzled_data + swizzle_offset;
data_ptrs[!unswizzle] = unswizzled_data + pixel_index;
std::memcpy(data_ptrs[0], data_ptrs[1], copy_size);
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}
}
}
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void Precise3DProcessGobs(u8* swizzled_data, u8* unswizzled_data, bool unswizzle, const u32 x_start,
const u32 y_start, const u32 z_start, const u32 x_end, const u32 y_end,
const u32 z_end, const u32 tile_offset, const u32 xy_block_size,
const u32 layer_z, const u32 stride_x, const u32 bytes_per_pixel,
const u32 out_bytes_per_pixel) {
std::array<u8*, 2> data_ptrs;
u32 z_adress = tile_offset;
const u32 gob_size = 64 * 8 * 1;
for (u32 z = z_start; z < z_end; z++) {
u32 y_adress = z_adress;
u32 pixel_base = layer_z * z + y_start * stride_x;
for (u32 y = y_start; y < y_end; y++) {
const auto& table = legacy_swizzle_table[y % 8];
for (u32 x = x_start; x < x_end; x++) {
const u32 swizzle_offset{y_adress + table[x * bytes_per_pixel % 64]};
const u32 pixel_index{x * out_bytes_per_pixel + pixel_base};
data_ptrs[unswizzle] = swizzled_data + swizzle_offset;
data_ptrs[!unswizzle] = unswizzled_data + pixel_index;
std::memcpy(data_ptrs[0], data_ptrs[1], bytes_per_pixel);
}
pixel_base += stride_x;
if ((y + 1) % 8 == 0)
y_adress += gob_size;
}
z_adress += xy_block_size;
}
}
void Precise3DSwizzledData(u8* swizzled_data, u8* unswizzled_data, bool unswizzle, u32 width,
u32 height, u32 depth, u32 bytes_per_pixel, u32 out_bytes_per_pixel,
u32 block_height, u32 block_depth) {
auto div_ceil = [](u32 x, u32 y) { return ((x + y - 1) / y); };
const u32 stride_x = width * out_bytes_per_pixel;
const u32 layer_z = height * stride_x;
const u32 gob_x_bytes = 64;
const u32 gob_elements_x = gob_x_bytes / bytes_per_pixel;
const u32 gob_elements_y = 8;
const u32 gob_elements_z = 1;
const u32 block_x_elements = gob_elements_x;
const u32 block_y_elements = gob_elements_y * block_height;
const u32 block_z_elements = gob_elements_z * block_depth;
const u32 blocks_on_x = div_ceil(width, block_x_elements);
const u32 blocks_on_y = div_ceil(height, block_y_elements);
const u32 blocks_on_z = div_ceil(depth, block_z_elements);
const u32 blocks = blocks_on_x * blocks_on_y * blocks_on_z;
const u32 gob_size = gob_x_bytes * gob_elements_y * gob_elements_z;
const u32 xy_block_size = gob_size * block_height;
const u32 block_size = xy_block_size * block_depth;
u32 tile_offset = 0;
for (u32 zb = 0; zb < blocks_on_z; zb++) {
const u32 z_start = zb * block_z_elements;
const u32 z_end = std::min(depth, z_start + block_z_elements);
for (u32 yb = 0; yb < blocks_on_y; yb++) {
const u32 y_start = yb * block_y_elements;
const u32 y_end = std::min(height, y_start + block_y_elements);
for (u32 xb = 0; xb < blocks_on_x; xb++) {
const u32 x_start = xb * block_x_elements;
const u32 x_end = std::min(width, x_start + block_x_elements);
Precise3DProcessGobs(swizzled_data, unswizzled_data, unswizzle, x_start, y_start,
z_start, x_end, y_end, z_end, tile_offset, xy_block_size, layer_z,
stride_x, bytes_per_pixel, out_bytes_per_pixel);
tile_offset += block_size;
}
}
}
}
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void Fast3DProcessGobs(u8* swizzled_data, u8* unswizzled_data, bool unswizzle, const u32 x_start,
const u32 y_start, const u32 z_start, const u32 x_end, const u32 y_end,
const u32 z_end, const u32 tile_offset, const u32 xy_block_size,
const u32 layer_z, const u32 stride_x, const u32 bytes_per_pixel,
const u32 out_bytes_per_pixel) {
std::array<u8*, 2> data_ptrs;
u32 z_adress = tile_offset;
const u32 x_startb = x_start * bytes_per_pixel;
const u32 x_endb = x_end * bytes_per_pixel;
const u32 copy_size = 16;
const u32 gob_size = 64 * 8 * 1;
for (u32 z = z_start; z < z_end; z++) {
u32 y_adress = z_adress;
u32 pixel_base = layer_z * z + y_start * stride_x;
for (u32 y = y_start; y < y_end; y++) {
const auto& table = fast_swizzle_table[y % 8];
for (u32 xb = x_startb; xb < x_endb; xb += copy_size) {
const u32 swizzle_offset{y_adress + table[(xb / 16) % 4]};
const u32 out_x = xb * out_bytes_per_pixel / bytes_per_pixel;
const u32 pixel_index{out_x + pixel_base};
data_ptrs[unswizzle] = swizzled_data + swizzle_offset;
data_ptrs[!unswizzle] = unswizzled_data + pixel_index;
std::memcpy(data_ptrs[0], data_ptrs[1], copy_size);
}
pixel_base += stride_x;
if ((y + 1) % 8 == 0)
y_adress += gob_size;
}
z_adress += xy_block_size;
}
}
void Fast3DSwizzledData(u8* swizzled_data, u8* unswizzled_data, bool unswizzle, u32 width,
u32 height, u32 depth, u32 bytes_per_pixel, u32 out_bytes_per_pixel,
u32 block_height, u32 block_depth) {
auto div_ceil = [](u32 x, u32 y) { return ((x + y - 1) / y); };
const u32 stride_x = width * out_bytes_per_pixel;
const u32 layer_z = height * stride_x;
const u32 gob_x_bytes = 64;
const u32 gob_elements_x = gob_x_bytes / bytes_per_pixel;
const u32 gob_elements_y = 8;
const u32 gob_elements_z = 1;
const u32 block_x_elements = gob_elements_x;
const u32 block_y_elements = gob_elements_y * block_height;
const u32 block_z_elements = gob_elements_z * block_depth;
const u32 blocks_on_x = div_ceil(width, block_x_elements);
const u32 blocks_on_y = div_ceil(height, block_y_elements);
const u32 blocks_on_z = div_ceil(depth, block_z_elements);
const u32 blocks = blocks_on_x * blocks_on_y * blocks_on_z;
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const u32 gob_size = gob_x_bytes * gob_elements_y * gob_elements_z;
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const u32 xy_block_size = gob_size * block_height;
const u32 block_size = xy_block_size * block_depth;
u32 tile_offset = 0;
for (u32 zb = 0; zb < blocks_on_z; zb++) {
const u32 z_start = zb * block_z_elements;
const u32 z_end = std::min(depth, z_start + block_z_elements);
for (u32 yb = 0; yb < blocks_on_y; yb++) {
const u32 y_start = yb * block_y_elements;
const u32 y_end = std::min(height, y_start + block_y_elements);
for (u32 xb = 0; xb < blocks_on_x; xb++) {
const u32 x_start = xb * block_x_elements;
const u32 x_end = std::min(width, x_start + block_x_elements);
Fast3DProcessGobs(swizzled_data, unswizzled_data, unswizzle, x_start, y_start,
z_start, x_end, y_end, z_end, tile_offset, xy_block_size, layer_z,
stride_x, bytes_per_pixel, out_bytes_per_pixel);
tile_offset += block_size;
}
}
}
}
void CopySwizzledData(u32 width, u32 height, u32 bytes_per_pixel, u32 out_bytes_per_pixel,
u8* swizzled_data, u8* unswizzled_data, bool unswizzle, u32 block_height) {
if (bytes_per_pixel % 3 != 0 && (width * bytes_per_pixel) % 16 == 0) {
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Fast3DSwizzledData(swizzled_data, unswizzled_data, unswizzle, width, height, 1U,
bytes_per_pixel, out_bytes_per_pixel, block_height, 1U);
} else {
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Precise3DSwizzledData(swizzled_data, unswizzled_data, unswizzle, width, height, 1U,
bytes_per_pixel, out_bytes_per_pixel, block_height, 1U);
}
}
u32 BytesPerPixel(TextureFormat format) {
switch (format) {
case TextureFormat::DXT1:
case TextureFormat::DXN1:
// In this case a 'pixel' actually refers to a 4x4 tile.
return 8;
case TextureFormat::DXT23:
case TextureFormat::DXT45:
case TextureFormat::DXN2:
case TextureFormat::BC7U:
case TextureFormat::BC6H_UF16:
case TextureFormat::BC6H_SF16:
// In this case a 'pixel' actually refers to a 4x4 tile.
return 16;
case TextureFormat::R32_G32_B32:
return 12;
case TextureFormat::ASTC_2D_4X4:
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case TextureFormat::ASTC_2D_8X8:
case TextureFormat::A8R8G8B8:
case TextureFormat::A2B10G10R10:
case TextureFormat::BF10GF11RF11:
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case TextureFormat::R32:
case TextureFormat::R16_G16:
return 4;
case TextureFormat::A1B5G5R5:
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case TextureFormat::B5G6R5:
case TextureFormat::G8R8:
case TextureFormat::R16:
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return 2;
case TextureFormat::R8:
return 1;
case TextureFormat::R16_G16_B16_A16:
return 8;
case TextureFormat::R32_G32_B32_A32:
return 16;
case TextureFormat::R32_G32:
return 8;
default:
UNIMPLEMENTED_MSG("Format not implemented");
break;
}
}
std::vector<u8> UnswizzleTexture(VAddr address, u32 tile_size, u32 bytes_per_pixel, u32 width,
u32 height, u32 block_height) {
std::vector<u8> unswizzled_data(width * height * bytes_per_pixel);
CopySwizzledData(width / tile_size, height / tile_size, bytes_per_pixel, bytes_per_pixel,
Memory::GetPointer(address), unswizzled_data.data(), true, block_height);
return unswizzled_data;
}
std::vector<u8> DecodeTexture(const std::vector<u8>& texture_data, TextureFormat format, u32 width,
u32 height) {
std::vector<u8> rgba_data;
// TODO(Subv): Implement.
switch (format) {
case TextureFormat::DXT1:
case TextureFormat::DXT23:
case TextureFormat::DXT45:
case TextureFormat::DXN1:
case TextureFormat::DXN2:
case TextureFormat::BC7U:
case TextureFormat::BC6H_UF16:
case TextureFormat::BC6H_SF16:
case TextureFormat::ASTC_2D_4X4:
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case TextureFormat::ASTC_2D_8X8:
case TextureFormat::A8R8G8B8:
case TextureFormat::A2B10G10R10:
case TextureFormat::A1B5G5R5:
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case TextureFormat::B5G6R5:
case TextureFormat::R8:
case TextureFormat::G8R8:
case TextureFormat::BF10GF11RF11:
case TextureFormat::R32_G32_B32_A32:
case TextureFormat::R32_G32:
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case TextureFormat::R32:
case TextureFormat::R16:
case TextureFormat::R16_G16:
case TextureFormat::R32_G32_B32:
// TODO(Subv): For the time being just forward the same data without any decoding.
rgba_data = texture_data;
break;
default:
UNIMPLEMENTED_MSG("Format not implemented");
break;
}
return rgba_data;
}
std::size_t CalculateSize(bool tiled, u32 bytes_per_pixel, u32 width, u32 height, u32 depth,
u32 block_height, u32 block_depth) {
if (tiled) {
const u32 gobs_in_x = 64 / bytes_per_pixel;
const u32 gobs_in_y = 8;
const u32 gobs_in_z = 1;
const u32 aligned_width = Common::AlignUp(width, gobs_in_x);
const u32 aligned_height = Common::AlignUp(height, gobs_in_y * block_height);
const u32 aligned_depth = Common::AlignUp(depth, gobs_in_z * block_depth);
return aligned_width * aligned_height * aligned_depth * bytes_per_pixel;
} else {
return width * height * depth * bytes_per_pixel;
}
}
} // namespace Tegra::Texture