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Ryujinx/src/Ryujinx.Graphics.Texture/LayoutConverter.cs
TSRBerry eb528ae0f0
Add workflow to automatically check code style issues for PRs (#4670) 
* Add workflow to perform automated checks for PRs

* Downgrade Microsoft.CodeAnalysis to 4.4.0

This is a workaround to fix issues with dotnet-format.
See:
- https://github.com/dotnet/format/issues/1805
- https://github.com/dotnet/format/issues/1800

* Adjust editorconfig to be more compatible with Ryujinx code-style

* Adjust .editorconfig line endings to match .gitattributes

* Disable 'prefer switch expression' rule

* Remove naming styles

These are the default rules, so we don't need to override them.

* Silence IDE0060 in .editorconfig

* Slightly adjust .editorconfig

* Add lost workflow changes

* Move .editorconfig comment to the top

* .editorconfig: private static readonly fields should be _lowerCamelCase

* .editorconfig: Remove alignment for declarations as well

* editorconfig: Add rule for local constants

* Disable CA1822 for HLE services

* Disable CA1822 for ViewModels

Bindings won't work with static members, but this issue is silently ignored.

* Run dotnet format for the whole solution

* Check result code of SDL_GetDisplayBounds

* Fix dotnet format style issues

* Add missing trailing commas

* Update Microsoft.CodeAnalysis.CSharp to 4.6.0

Skipping 4.5.0 since it breaks dotnet format

* Restore old default naming rules for dotnet format

* Add naming rule exception for CPU tests

* checks: Include all files before excluding paths

* Fix dotnet format issues

* Check dotnet format version

* checks: Run dotnet format with severity info again

* checks: Disable naming style rules until they won't crash the process anymore

* Remove unread private member

* checks: Attempt to run analyzers 3 times before giving up

* checks: Enable naming style rules again with the new retry logic
2023-07-24 18:35:04 +02:00

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using Ryujinx.Common;
using System;
using System.Runtime.Intrinsics;
using static Ryujinx.Graphics.Texture.BlockLinearConstants;
namespace Ryujinx.Graphics.Texture
{
public static class LayoutConverter
{
public const int HostStrideAlignment = 4;
public static void ConvertBlockLinearToLinear(
Span<byte> dst,
int width,
int height,
int stride,
int bytesPerPixel,
int gobBlocksInY,
ReadOnlySpan<byte> data)
{
int gobHeight = gobBlocksInY * GobHeight;
int strideTrunc = BitUtils.AlignDown(width * bytesPerPixel, 16);
int strideTrunc64 = BitUtils.AlignDown(width * bytesPerPixel, 64);
int xStart = strideTrunc / bytesPerPixel;
int outStrideGap = stride - width * bytesPerPixel;
int alignment = GobStride / bytesPerPixel;
int wAligned = BitUtils.AlignUp(width, alignment);
BlockLinearLayout layoutConverter = new(wAligned, height, gobBlocksInY, 1, bytesPerPixel);
unsafe bool Convert<T>(Span<byte> output, ReadOnlySpan<byte> data) where T : unmanaged
{
fixed (byte* outputPtr = output, dataPtr = data)
{
byte* outPtr = outputPtr;
for (int y = 0; y < height; y++)
{
layoutConverter.SetY(y);
for (int x = 0; x < strideTrunc64; x += 64, outPtr += 64)
{
byte* offset = dataPtr + layoutConverter.GetOffsetWithLineOffset64(x);
byte* offset2 = offset + 0x20;
byte* offset3 = offset + 0x100;
byte* offset4 = offset + 0x120;
Vector128<byte> value = *(Vector128<byte>*)offset;
Vector128<byte> value2 = *(Vector128<byte>*)offset2;
Vector128<byte> value3 = *(Vector128<byte>*)offset3;
Vector128<byte> value4 = *(Vector128<byte>*)offset4;
*(Vector128<byte>*)outPtr = value;
*(Vector128<byte>*)(outPtr + 16) = value2;
*(Vector128<byte>*)(outPtr + 32) = value3;
*(Vector128<byte>*)(outPtr + 48) = value4;
}
for (int x = strideTrunc64; x < strideTrunc; x += 16, outPtr += 16)
{
byte* offset = dataPtr + layoutConverter.GetOffsetWithLineOffset16(x);
*(Vector128<byte>*)outPtr = *(Vector128<byte>*)offset;
}
for (int x = xStart; x < width; x++, outPtr += bytesPerPixel)
{
byte* offset = dataPtr + layoutConverter.GetOffset(x);
*(T*)outPtr = *(T*)offset;
}
outPtr += outStrideGap;
}
}
return true;
}
bool _ = bytesPerPixel switch
{
1 => Convert<byte>(dst, data),
2 => Convert<ushort>(dst, data),
4 => Convert<uint>(dst, data),
8 => Convert<ulong>(dst, data),
12 => Convert<Bpp12Pixel>(dst, data),
16 => Convert<Vector128<byte>>(dst, data),
_ => throw new NotSupportedException($"Unable to convert ${bytesPerPixel} bpp pixel format."),
};
}
public static byte[] ConvertBlockLinearToLinear(
int width,
int height,
int depth,
int sliceDepth,
int levels,
int layers,
int blockWidth,
int blockHeight,
int bytesPerPixel,
int gobBlocksInY,
int gobBlocksInZ,
int gobBlocksInTileX,
SizeInfo sizeInfo,
ReadOnlySpan<byte> data)
{
int outSize = GetTextureSize(
width,
height,
sliceDepth,
levels,
layers,
blockWidth,
blockHeight,
bytesPerPixel);
byte[] output = new byte[outSize];
int outOffs = 0;
int mipGobBlocksInY = gobBlocksInY;
int mipGobBlocksInZ = gobBlocksInZ;
int gobWidth = (GobStride / bytesPerPixel) * gobBlocksInTileX;
int gobHeight = gobBlocksInY * GobHeight;
for (int level = 0; level < levels; level++)
{
int w = Math.Max(1, width >> level);
int h = Math.Max(1, height >> level);
int d = Math.Max(1, depth >> level);
w = BitUtils.DivRoundUp(w, blockWidth);
h = BitUtils.DivRoundUp(h, blockHeight);
while (h <= (mipGobBlocksInY >> 1) * GobHeight && mipGobBlocksInY != 1)
{
mipGobBlocksInY >>= 1;
}
if (level > 0 && d <= (mipGobBlocksInZ >> 1) && mipGobBlocksInZ != 1)
{
mipGobBlocksInZ >>= 1;
}
int strideTrunc = BitUtils.AlignDown(w * bytesPerPixel, 16);
int strideTrunc64 = BitUtils.AlignDown(w * bytesPerPixel, 64);
int xStart = strideTrunc / bytesPerPixel;
int stride = BitUtils.AlignUp(w * bytesPerPixel, HostStrideAlignment);
int outStrideGap = stride - w * bytesPerPixel;
int alignment = gobWidth;
if (d < gobBlocksInZ || w <= gobWidth || h <= gobHeight)
{
alignment = GobStride / bytesPerPixel;
}
int wAligned = BitUtils.AlignUp(w, alignment);
BlockLinearLayout layoutConverter = new(
wAligned,
h,
mipGobBlocksInY,
mipGobBlocksInZ,
bytesPerPixel);
int sd = Math.Max(1, sliceDepth >> level);
unsafe bool Convert<T>(Span<byte> output, ReadOnlySpan<byte> data) where T : unmanaged
{
fixed (byte* outputPtr = output, dataPtr = data)
{
byte* outPtr = outputPtr + outOffs;
for (int layer = 0; layer < layers; layer++)
{
byte* inBaseOffset = dataPtr + (layer * sizeInfo.LayerSize + sizeInfo.GetMipOffset(level));
for (int z = 0; z < sd; z++)
{
layoutConverter.SetZ(z);
for (int y = 0; y < h; y++)
{
layoutConverter.SetY(y);
for (int x = 0; x < strideTrunc64; x += 64, outPtr += 64)
{
byte* offset = inBaseOffset + layoutConverter.GetOffsetWithLineOffset64(x);
byte* offset2 = offset + 0x20;
byte* offset3 = offset + 0x100;
byte* offset4 = offset + 0x120;
Vector128<byte> value = *(Vector128<byte>*)offset;
Vector128<byte> value2 = *(Vector128<byte>*)offset2;
Vector128<byte> value3 = *(Vector128<byte>*)offset3;
Vector128<byte> value4 = *(Vector128<byte>*)offset4;
*(Vector128<byte>*)outPtr = value;
*(Vector128<byte>*)(outPtr + 16) = value2;
*(Vector128<byte>*)(outPtr + 32) = value3;
*(Vector128<byte>*)(outPtr + 48) = value4;
}
for (int x = strideTrunc64; x < strideTrunc; x += 16, outPtr += 16)
{
byte* offset = inBaseOffset + layoutConverter.GetOffsetWithLineOffset16(x);
*(Vector128<byte>*)outPtr = *(Vector128<byte>*)offset;
}
for (int x = xStart; x < w; x++, outPtr += bytesPerPixel)
{
byte* offset = inBaseOffset + layoutConverter.GetOffset(x);
*(T*)outPtr = *(T*)offset;
}
outPtr += outStrideGap;
}
}
}
outOffs += stride * h * d * layers;
}
return true;
}
bool _ = bytesPerPixel switch
{
1 => Convert<byte>(output, data),
2 => Convert<ushort>(output, data),
4 => Convert<uint>(output, data),
8 => Convert<ulong>(output, data),
12 => Convert<Bpp12Pixel>(output, data),
16 => Convert<Vector128<byte>>(output, data),
_ => throw new NotSupportedException($"Unable to convert ${bytesPerPixel} bpp pixel format."),
};
}
return output;
}
public static byte[] ConvertLinearStridedToLinear(
int width,
int height,
int blockWidth,
int blockHeight,
int lineSize,
int stride,
int bytesPerPixel,
ReadOnlySpan<byte> data)
{
int w = BitUtils.DivRoundUp(width, blockWidth);
int h = BitUtils.DivRoundUp(height, blockHeight);
int outStride = BitUtils.AlignUp(w * bytesPerPixel, HostStrideAlignment);
lineSize = Math.Min(lineSize, outStride);
byte[] output = new byte[h * outStride];
Span<byte> outSpan = output;
int outOffs = 0;
int inOffs = 0;
for (int y = 0; y < h; y++)
{
data.Slice(inOffs, lineSize).CopyTo(outSpan.Slice(outOffs, lineSize));
inOffs += stride;
outOffs += outStride;
}
return output;
}
public static void ConvertLinearToBlockLinear(
Span<byte> dst,
int width,
int height,
int stride,
int bytesPerPixel,
int gobBlocksInY,
ReadOnlySpan<byte> data)
{
int gobHeight = gobBlocksInY * GobHeight;
int strideTrunc = BitUtils.AlignDown(width * bytesPerPixel, 16);
int strideTrunc64 = BitUtils.AlignDown(width * bytesPerPixel, 64);
int xStart = strideTrunc / bytesPerPixel;
int inStrideGap = stride - width * bytesPerPixel;
int alignment = GobStride / bytesPerPixel;
int wAligned = BitUtils.AlignUp(width, alignment);
BlockLinearLayout layoutConverter = new(wAligned, height, gobBlocksInY, 1, bytesPerPixel);
unsafe bool Convert<T>(Span<byte> output, ReadOnlySpan<byte> data) where T : unmanaged
{
fixed (byte* outputPtr = output, dataPtr = data)
{
byte* inPtr = dataPtr;
for (int y = 0; y < height; y++)
{
layoutConverter.SetY(y);
for (int x = 0; x < strideTrunc64; x += 64, inPtr += 64)
{
byte* offset = outputPtr + layoutConverter.GetOffsetWithLineOffset64(x);
byte* offset2 = offset + 0x20;
byte* offset3 = offset + 0x100;
byte* offset4 = offset + 0x120;
Vector128<byte> value = *(Vector128<byte>*)inPtr;
Vector128<byte> value2 = *(Vector128<byte>*)(inPtr + 16);
Vector128<byte> value3 = *(Vector128<byte>*)(inPtr + 32);
Vector128<byte> value4 = *(Vector128<byte>*)(inPtr + 48);
*(Vector128<byte>*)offset = value;
*(Vector128<byte>*)offset2 = value2;
*(Vector128<byte>*)offset3 = value3;
*(Vector128<byte>*)offset4 = value4;
}
for (int x = strideTrunc64; x < strideTrunc; x += 16, inPtr += 16)
{
byte* offset = outputPtr + layoutConverter.GetOffsetWithLineOffset16(x);
*(Vector128<byte>*)offset = *(Vector128<byte>*)inPtr;
}
for (int x = xStart; x < width; x++, inPtr += bytesPerPixel)
{
byte* offset = outputPtr + layoutConverter.GetOffset(x);
*(T*)offset = *(T*)inPtr;
}
inPtr += inStrideGap;
}
}
return true;
}
bool _ = bytesPerPixel switch
{
1 => Convert<byte>(dst, data),
2 => Convert<ushort>(dst, data),
4 => Convert<uint>(dst, data),
8 => Convert<ulong>(dst, data),
12 => Convert<Bpp12Pixel>(dst, data),
16 => Convert<Vector128<byte>>(dst, data),
_ => throw new NotSupportedException($"Unable to convert ${bytesPerPixel} bpp pixel format."),
};
}
public static ReadOnlySpan<byte> ConvertLinearToBlockLinear(
Span<byte> output,
int width,
int height,
int depth,
int sliceDepth,
int levels,
int layers,
int blockWidth,
int blockHeight,
int bytesPerPixel,
int gobBlocksInY,
int gobBlocksInZ,
int gobBlocksInTileX,
SizeInfo sizeInfo,
ReadOnlySpan<byte> data)
{
if (output.Length == 0)
{
output = new byte[sizeInfo.TotalSize];
}
int inOffs = 0;
int mipGobBlocksInY = gobBlocksInY;
int mipGobBlocksInZ = gobBlocksInZ;
int gobWidth = (GobStride / bytesPerPixel) * gobBlocksInTileX;
int gobHeight = gobBlocksInY * GobHeight;
for (int level = 0; level < levels; level++)
{
int w = Math.Max(1, width >> level);
int h = Math.Max(1, height >> level);
int d = Math.Max(1, depth >> level);
w = BitUtils.DivRoundUp(w, blockWidth);
h = BitUtils.DivRoundUp(h, blockHeight);
while (h <= (mipGobBlocksInY >> 1) * GobHeight && mipGobBlocksInY != 1)
{
mipGobBlocksInY >>= 1;
}
if (level > 0 && d <= (mipGobBlocksInZ >> 1) && mipGobBlocksInZ != 1)
{
mipGobBlocksInZ >>= 1;
}
int strideTrunc = BitUtils.AlignDown(w * bytesPerPixel, 16);
int strideTrunc64 = BitUtils.AlignDown(w * bytesPerPixel, 64);
int xStart = strideTrunc / bytesPerPixel;
int stride = BitUtils.AlignUp(w * bytesPerPixel, HostStrideAlignment);
int inStrideGap = stride - w * bytesPerPixel;
int alignment = gobWidth;
if (d < gobBlocksInZ || w <= gobWidth || h <= gobHeight)
{
alignment = GobStride / bytesPerPixel;
}
int wAligned = BitUtils.AlignUp(w, alignment);
BlockLinearLayout layoutConverter = new(
wAligned,
h,
mipGobBlocksInY,
mipGobBlocksInZ,
bytesPerPixel);
int sd = Math.Max(1, sliceDepth >> level);
unsafe bool Convert<T>(Span<byte> output, ReadOnlySpan<byte> data) where T : unmanaged
{
fixed (byte* outputPtr = output, dataPtr = data)
{
byte* inPtr = dataPtr + inOffs;
for (int layer = 0; layer < layers; layer++)
{
byte* outBaseOffset = outputPtr + (layer * sizeInfo.LayerSize + sizeInfo.GetMipOffset(level));
for (int z = 0; z < sd; z++)
{
layoutConverter.SetZ(z);
for (int y = 0; y < h; y++)
{
layoutConverter.SetY(y);
for (int x = 0; x < strideTrunc64; x += 64, inPtr += 64)
{
byte* offset = outBaseOffset + layoutConverter.GetOffsetWithLineOffset64(x);
byte* offset2 = offset + 0x20;
byte* offset3 = offset + 0x100;
byte* offset4 = offset + 0x120;
Vector128<byte> value = *(Vector128<byte>*)inPtr;
Vector128<byte> value2 = *(Vector128<byte>*)(inPtr + 16);
Vector128<byte> value3 = *(Vector128<byte>*)(inPtr + 32);
Vector128<byte> value4 = *(Vector128<byte>*)(inPtr + 48);
*(Vector128<byte>*)offset = value;
*(Vector128<byte>*)offset2 = value2;
*(Vector128<byte>*)offset3 = value3;
*(Vector128<byte>*)offset4 = value4;
}
for (int x = strideTrunc64; x < strideTrunc; x += 16, inPtr += 16)
{
byte* offset = outBaseOffset + layoutConverter.GetOffsetWithLineOffset16(x);
*(Vector128<byte>*)offset = *(Vector128<byte>*)inPtr;
}
for (int x = xStart; x < w; x++, inPtr += bytesPerPixel)
{
byte* offset = outBaseOffset + layoutConverter.GetOffset(x);
*(T*)offset = *(T*)inPtr;
}
inPtr += inStrideGap;
}
}
}
inOffs += stride * h * d * layers;
}
return true;
}
bool _ = bytesPerPixel switch
{
1 => Convert<byte>(output, data),
2 => Convert<ushort>(output, data),
4 => Convert<uint>(output, data),
8 => Convert<ulong>(output, data),
12 => Convert<Bpp12Pixel>(output, data),
16 => Convert<Vector128<byte>>(output, data),
_ => throw new NotSupportedException($"Unable to convert ${bytesPerPixel} bpp pixel format."),
};
}
return output;
}
public static ReadOnlySpan<byte> ConvertLinearToLinearStrided(
Span<byte> output,
int width,
int height,
int blockWidth,
int blockHeight,
int stride,
int bytesPerPixel,
ReadOnlySpan<byte> data)
{
int w = BitUtils.DivRoundUp(width, blockWidth);
int h = BitUtils.DivRoundUp(height, blockHeight);
int inStride = BitUtils.AlignUp(w * bytesPerPixel, HostStrideAlignment);
int lineSize = width * bytesPerPixel;
if (inStride == stride)
{
if (output.Length != 0)
{
data.CopyTo(output);
return output;
}
else
{
return data;
}
}
if (output.Length == 0)
{
output = new byte[h * stride];
}
int inOffs = 0;
int outOffs = 0;
for (int y = 0; y < h; y++)
{
data.Slice(inOffs, lineSize).CopyTo(output.Slice(outOffs, lineSize));
inOffs += inStride;
outOffs += stride;
}
return output;
}
private static int GetTextureSize(
int width,
int height,
int depth,
int levels,
int layers,
int blockWidth,
int blockHeight,
int bytesPerPixel)
{
int layerSize = 0;
for (int level = 0; level < levels; level++)
{
int w = Math.Max(1, width >> level);
int h = Math.Max(1, height >> level);
int d = Math.Max(1, depth >> level);
w = BitUtils.DivRoundUp(w, blockWidth);
h = BitUtils.DivRoundUp(h, blockHeight);
int stride = BitUtils.AlignUp(w * bytesPerPixel, HostStrideAlignment);
layerSize += stride * h * d;
}
return layerSize * layers;
}
}
}
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