blob: a4b5570d86b47c7dd312545dab40a233a6a14dda [file] [log] [blame]
// Copyright 2019 The SwiftShader Authors. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "SpirvShader.hpp"
#include "System/Types.hpp"
#include "Vulkan/VkDescriptorSetLayout.hpp"
#include "Vulkan/VkPipelineLayout.hpp"
#include <spirv/unified1/spirv.hpp>
namespace sw {
static vk::Format SpirvFormatToVulkanFormat(spv::ImageFormat format)
{
switch(format)
{
case spv::ImageFormatUnknown: return VK_FORMAT_UNDEFINED;
case spv::ImageFormatRgba32f: return VK_FORMAT_R32G32B32A32_SFLOAT;
case spv::ImageFormatRgba16f: return VK_FORMAT_R16G16B16A16_SFLOAT;
case spv::ImageFormatR32f: return VK_FORMAT_R32_SFLOAT;
case spv::ImageFormatRgba8: return VK_FORMAT_R8G8B8A8_UNORM;
case spv::ImageFormatRgba8Snorm: return VK_FORMAT_R8G8B8A8_SNORM;
case spv::ImageFormatRg32f: return VK_FORMAT_R32G32_SFLOAT;
case spv::ImageFormatRg16f: return VK_FORMAT_R16G16_SFLOAT;
case spv::ImageFormatR11fG11fB10f: return VK_FORMAT_B10G11R11_UFLOAT_PACK32;
case spv::ImageFormatR16f: return VK_FORMAT_R16_SFLOAT;
case spv::ImageFormatRgba16: return VK_FORMAT_R16G16B16A16_UNORM;
case spv::ImageFormatRgb10A2: return VK_FORMAT_A2B10G10R10_UNORM_PACK32;
case spv::ImageFormatRg16: return VK_FORMAT_R16G16_UNORM;
case spv::ImageFormatRg8: return VK_FORMAT_R8G8_UNORM;
case spv::ImageFormatR16: return VK_FORMAT_R16_UNORM;
case spv::ImageFormatR8: return VK_FORMAT_R8_UNORM;
case spv::ImageFormatRgba16Snorm: return VK_FORMAT_R16G16B16A16_SNORM;
case spv::ImageFormatRg16Snorm: return VK_FORMAT_R16G16_SNORM;
case spv::ImageFormatRg8Snorm: return VK_FORMAT_R8G8_SNORM;
case spv::ImageFormatR16Snorm: return VK_FORMAT_R16_SNORM;
case spv::ImageFormatR8Snorm: return VK_FORMAT_R8_SNORM;
case spv::ImageFormatRgba32i: return VK_FORMAT_R32G32B32A32_SINT;
case spv::ImageFormatRgba16i: return VK_FORMAT_R16G16B16A16_SINT;
case spv::ImageFormatRgba8i: return VK_FORMAT_R8G8B8A8_SINT;
case spv::ImageFormatR32i: return VK_FORMAT_R32_SINT;
case spv::ImageFormatRg32i: return VK_FORMAT_R32G32_SINT;
case spv::ImageFormatRg16i: return VK_FORMAT_R16G16_SINT;
case spv::ImageFormatRg8i: return VK_FORMAT_R8G8_SINT;
case spv::ImageFormatR16i: return VK_FORMAT_R16_SINT;
case spv::ImageFormatR8i: return VK_FORMAT_R8_SINT;
case spv::ImageFormatRgba32ui: return VK_FORMAT_R32G32B32A32_UINT;
case spv::ImageFormatRgba16ui: return VK_FORMAT_R16G16B16A16_UINT;
case spv::ImageFormatRgba8ui: return VK_FORMAT_R8G8B8A8_UINT;
case spv::ImageFormatR32ui: return VK_FORMAT_R32_UINT;
case spv::ImageFormatRgb10a2ui: return VK_FORMAT_A2B10G10R10_UINT_PACK32;
case spv::ImageFormatRg32ui: return VK_FORMAT_R32G32_UINT;
case spv::ImageFormatRg16ui: return VK_FORMAT_R16G16_UINT;
case spv::ImageFormatRg8ui: return VK_FORMAT_R8G8_UINT;
case spv::ImageFormatR16ui: return VK_FORMAT_R16_UINT;
case spv::ImageFormatR8ui: return VK_FORMAT_R8_UINT;
default:
UNSUPPORTED("SPIR-V ImageFormat %u", format);
return VK_FORMAT_UNDEFINED;
}
}
SpirvEmitter::ImageInstruction::ImageInstruction(InsnIterator insn, const Spirv &shader, const SpirvEmitter &state)
: ImageInstructionSignature(parseVariantAndMethod(insn))
, position(insn.distanceFrom(shader.begin()))
{
if(samplerMethod == Write)
{
imageId = insn.word(1);
coordinateId = insn.word(2);
texelId = insn.word(3);
}
else
{
resultTypeId = insn.resultTypeId(); // word(1)
resultId = insn.resultId(); // word(2)
if(samplerMethod == Fetch || samplerMethod == Read || samplerMethod == TexelPointer) // Samplerless
{
imageId = insn.word(3);
}
else
{
// sampledImageId is either the result of an OpSampledImage instruction or
// an externally combined sampler and image.
Object::ID sampledImageId = insn.word(3);
if(state.isSampledImage(sampledImageId)) // Result of an OpSampledImage instruction
{
const SampledImagePointer &sampledImage = state.getSampledImage(sampledImageId);
imageId = shader.getObject(sampledImageId).definition.word(3);
samplerId = sampledImage.samplerId;
}
else // Combined image/sampler
{
imageId = sampledImageId;
samplerId = sampledImageId;
}
}
coordinateId = insn.word(4);
}
// `imageId` can represent either a Sampled Image, a samplerless Image, or a pointer to an Image.
// To get to the OpTypeImage operands, traverse the OpTypeSampledImage or OpTypePointer.
const Type &imageObjectType = shader.getObjectType(imageId);
const Type &imageReferenceType = (imageObjectType.opcode() == spv::OpTypeSampledImage)
? shader.getType(imageObjectType.definition.word(2))
: imageObjectType;
const Type &imageType = ((imageReferenceType.opcode() == spv::OpTypePointer)
? shader.getType(imageReferenceType.element)
: imageReferenceType);
ASSERT(imageType.opcode() == spv::OpTypeImage);
dim = imageType.definition.word(3);
arrayed = imageType.definition.word(5);
imageFormat = imageType.definition.word(8);
const Object &coordinateObject = shader.getObject(coordinateId);
const Type &coordinateType = shader.getType(coordinateObject);
coordinates = coordinateType.componentCount - (isProj() ? 1 : 0);
if(samplerMethod == TexelPointer)
{
sampleId = insn.word(5);
sample = !shader.getObject(sampleId).isConstantZero();
}
if(isDref())
{
drefId = insn.word(5);
}
if(samplerMethod == Gather)
{
gatherComponent = !isDref() ? shader.getObject(insn.word(5)).constantValue[0] : 0;
}
uint32_t operandsIndex = getImageOperandsIndex(insn);
uint32_t imageOperands = (operandsIndex != 0) ? insn.word(operandsIndex) : 0; // The mask which indicates which operands are provided.
operandsIndex += 1; // Advance to the first actual operand <id> location.
if(imageOperands & spv::ImageOperandsBiasMask)
{
ASSERT(samplerMethod == Bias);
lodOrBiasId = insn.word(operandsIndex);
operandsIndex += 1;
imageOperands &= ~spv::ImageOperandsBiasMask;
}
if(imageOperands & spv::ImageOperandsLodMask)
{
ASSERT(samplerMethod == Lod || samplerMethod == Fetch);
lodOrBiasId = insn.word(operandsIndex);
operandsIndex += 1;
imageOperands &= ~spv::ImageOperandsLodMask;
}
if(imageOperands & spv::ImageOperandsGradMask)
{
ASSERT(samplerMethod == Grad);
gradDxId = insn.word(operandsIndex + 0);
gradDyId = insn.word(operandsIndex + 1);
operandsIndex += 2;
imageOperands &= ~spv::ImageOperandsGradMask;
grad = shader.getObjectType(gradDxId).componentCount;
}
if(imageOperands & spv::ImageOperandsConstOffsetMask)
{
offsetId = insn.word(operandsIndex);
operandsIndex += 1;
imageOperands &= ~spv::ImageOperandsConstOffsetMask;
offset = shader.getObjectType(offsetId).componentCount;
}
if(imageOperands & spv::ImageOperandsSampleMask)
{
ASSERT(samplerMethod == Fetch || samplerMethod == Read || samplerMethod == Write);
sampleId = insn.word(operandsIndex);
operandsIndex += 1;
imageOperands &= ~spv::ImageOperandsSampleMask;
sample = !shader.getObject(sampleId).isConstantZero();
}
// TODO(b/174475384)
if(imageOperands & spv::ImageOperandsZeroExtendMask)
{
ASSERT(samplerMethod == Read || samplerMethod == Write);
imageOperands &= ~spv::ImageOperandsZeroExtendMask;
}
else if(imageOperands & spv::ImageOperandsSignExtendMask)
{
ASSERT(samplerMethod == Read || samplerMethod == Write);
imageOperands &= ~spv::ImageOperandsSignExtendMask;
}
[[maybe_unused]] spv::Scope scope = spv::ScopeCrossDevice; // "Whilst the CrossDevice scope is defined in SPIR-V, it is disallowed in Vulkan."
if(imageOperands & spv::ImageOperandsMakeTexelAvailableMask)
{
scope = static_cast<spv::Scope>(insn.word(operandsIndex));
operandsIndex += 1;
imageOperands &= ~spv::ImageOperandsMakeTexelAvailableMask;
}
if(imageOperands & spv::ImageOperandsMakeTexelVisibleMask)
{
scope = static_cast<spv::Scope>(insn.word(operandsIndex));
operandsIndex += 1;
imageOperands &= ~spv::ImageOperandsMakeTexelVisibleMask;
}
if(imageOperands & spv::ImageOperandsNonPrivateTexelMask)
{
imageOperands &= ~spv::ImageOperandsNonPrivateTexelMask;
}
if(imageOperands & spv::ImageOperandsVolatileTexelMask)
{
UNIMPLEMENTED("b/176819536");
imageOperands &= ~spv::ImageOperandsVolatileTexelMask;
}
if(imageOperands & spv::ImageOperandsNontemporalMask)
{
// Hints that the accessed texels are not likely
// to be accessed again in the near future.
imageOperands &= ~spv::ImageOperandsNontemporalMask;
}
// There should be no remaining image operands.
if(imageOperands != 0)
{
UNSUPPORTED("Image operands 0x%08X", imageOperands);
}
}
SpirvEmitter::ImageInstructionSignature SpirvEmitter::ImageInstruction::parseVariantAndMethod(InsnIterator insn)
{
uint32_t imageOperands = getImageOperandsMask(insn);
bool bias = imageOperands & spv::ImageOperandsBiasMask;
bool grad = imageOperands & spv::ImageOperandsGradMask;
switch(insn.opcode())
{
case spv::OpImageSampleImplicitLod: return { None, bias ? Bias : Implicit };
case spv::OpImageSampleExplicitLod: return { None, grad ? Grad : Lod };
case spv::OpImageSampleDrefImplicitLod: return { Dref, bias ? Bias : Implicit };
case spv::OpImageSampleDrefExplicitLod: return { Dref, grad ? Grad : Lod };
case spv::OpImageSampleProjImplicitLod: return { Proj, bias ? Bias : Implicit };
case spv::OpImageSampleProjExplicitLod: return { Proj, grad ? Grad : Lod };
case spv::OpImageSampleProjDrefImplicitLod: return { ProjDref, bias ? Bias : Implicit };
case spv::OpImageSampleProjDrefExplicitLod: return { ProjDref, grad ? Grad : Lod };
case spv::OpImageGather: return { None, Gather };
case spv::OpImageDrefGather: return { Dref, Gather };
case spv::OpImageFetch: return { None, Fetch };
case spv::OpImageQueryLod: return { None, Query };
case spv::OpImageRead: return { None, Read };
case spv::OpImageWrite: return { None, Write };
case spv::OpImageTexelPointer: return { None, TexelPointer };
default:
ASSERT(false);
return { None, Implicit };
}
}
// Returns the instruction word index at which the Image Operands mask is located, or 0 if not present.
uint32_t SpirvEmitter::ImageInstruction::getImageOperandsIndex(InsnIterator insn)
{
switch(insn.opcode())
{
case spv::OpImageSampleImplicitLod:
case spv::OpImageSampleProjImplicitLod:
return insn.wordCount() > 5 ? 5 : 0; // Optional
case spv::OpImageSampleExplicitLod:
case spv::OpImageSampleProjExplicitLod:
return 5; // "Either Lod or Grad image operands must be present."
case spv::OpImageSampleDrefImplicitLod:
case spv::OpImageSampleProjDrefImplicitLod:
return insn.wordCount() > 6 ? 6 : 0; // Optional
case spv::OpImageSampleDrefExplicitLod:
case spv::OpImageSampleProjDrefExplicitLod:
return 6; // "Either Lod or Grad image operands must be present."
case spv::OpImageGather:
case spv::OpImageDrefGather:
return insn.wordCount() > 6 ? 6 : 0; // Optional
case spv::OpImageFetch:
return insn.wordCount() > 5 ? 5 : 0; // Optional
case spv::OpImageQueryLod:
ASSERT(insn.wordCount() == 5);
return 0; // No image operands.
case spv::OpImageRead:
return insn.wordCount() > 5 ? 5 : 0; // Optional
case spv::OpImageWrite:
return insn.wordCount() > 4 ? 4 : 0; // Optional
case spv::OpImageTexelPointer:
ASSERT(insn.wordCount() == 6);
return 0; // No image operands.
default:
ASSERT(false);
return 0;
}
}
uint32_t SpirvEmitter::ImageInstruction::getImageOperandsMask(InsnIterator insn)
{
uint32_t operandsIndex = getImageOperandsIndex(insn);
return (operandsIndex != 0) ? insn.word(operandsIndex) : 0;
}
void SpirvEmitter::EmitImageSample(const ImageInstruction &instruction)
{
auto &resultType = shader.getType(instruction.resultTypeId);
auto &result = createIntermediate(instruction.resultId, resultType.componentCount);
Array<SIMD::Float> out(4);
// TODO(b/153380916): When we're in a code path that is always executed,
// i.e. post-dominators of the entry block, we don't have to dynamically
// check whether any lanes are active, and can elide the jump.
If(AnyTrue(activeLaneMask()))
{
EmitImageSampleUnconditional(out, instruction);
}
for(auto i = 0u; i < resultType.componentCount; i++) { result.move(i, out[i]); }
}
void SpirvEmitter::EmitImageSampleUnconditional(Array<SIMD::Float> &out, const ImageInstruction &instruction) const
{
auto decorations = shader.GetDecorationsForId(instruction.imageId);
if(decorations.NonUniform)
{
SIMD::Int activeLaneMask = this->activeLaneMask();
SIMD::Pointer imagePointer = getImage(instruction.imageId);
// PerLane output
for(int laneIdx = 0; laneIdx < SIMD::Width; laneIdx++)
{
Array<SIMD::Float> laneOut(out.getArraySize());
If(Extract(activeLaneMask, laneIdx) != 0)
{
Pointer<Byte> imageDescriptor = imagePointer.getPointerForLane(laneIdx); // vk::SampledImageDescriptor*
Pointer<Byte> samplerDescriptor = getSamplerDescriptor(imageDescriptor, instruction, laneIdx);
Pointer<Byte> samplerFunction = lookupSamplerFunction(imageDescriptor, samplerDescriptor, instruction);
callSamplerFunction(samplerFunction, laneOut, imageDescriptor, instruction);
}
for(int outIdx = 0; outIdx < out.getArraySize(); outIdx++)
{
out[outIdx] = Insert(out[outIdx], Extract(laneOut[outIdx], laneIdx), laneIdx);
}
}
}
else
{
Pointer<Byte> imageDescriptor = getImage(instruction.imageId).getUniformPointer(); // vk::SampledImageDescriptor*
Pointer<Byte> samplerDescriptor = getSamplerDescriptor(imageDescriptor, instruction);
Pointer<Byte> samplerFunction = lookupSamplerFunction(imageDescriptor, samplerDescriptor, instruction);
callSamplerFunction(samplerFunction, out, imageDescriptor, instruction);
}
}
Pointer<Byte> SpirvEmitter::getSamplerDescriptor(Pointer<Byte> imageDescriptor, const ImageInstruction &instruction) const
{
return ((instruction.samplerId == instruction.imageId) || (instruction.samplerId == 0)) ? imageDescriptor : getImage(instruction.samplerId).getUniformPointer();
}
Pointer<Byte> SpirvEmitter::getSamplerDescriptor(Pointer<Byte> imageDescriptor, const ImageInstruction &instruction, int laneIdx) const
{
return ((instruction.samplerId == instruction.imageId) || (instruction.samplerId == 0)) ? imageDescriptor : getImage(instruction.samplerId).getPointerForLane(laneIdx);
}
Pointer<Byte> SpirvEmitter::lookupSamplerFunction(Pointer<Byte> imageDescriptor, Pointer<Byte> samplerDescriptor, const ImageInstruction &instruction) const
{
Int samplerId = (instruction.samplerId != 0) ? *Pointer<rr::Int>(samplerDescriptor + OFFSET(vk::SampledImageDescriptor, samplerId)) : Int(0);
auto &cache = routine->samplerCache.at(instruction.position);
Bool cacheHit = (cache.imageDescriptor == imageDescriptor) && (cache.samplerId == samplerId); // TODO(b/205566405): Skip sampler ID check for samplerless instructions.
If(!cacheHit)
{
rr::Int imageViewId = *Pointer<rr::Int>(imageDescriptor + OFFSET(vk::ImageDescriptor, imageViewId));
cache.function = Call(getImageSampler, routine->device, instruction.signature, samplerId, imageViewId);
cache.imageDescriptor = imageDescriptor;
cache.samplerId = samplerId;
}
return cache.function;
}
void SpirvEmitter::callSamplerFunction(Pointer<Byte> samplerFunction, Array<SIMD::Float> &out, Pointer<Byte> imageDescriptor, const ImageInstruction &instruction) const
{
Array<SIMD::Float> in(16); // Maximum 16 input parameter components.
auto coordinate = Operand(shader, *this, instruction.coordinateId);
uint32_t i = 0;
for(; i < instruction.coordinates; i++)
{
if(instruction.isProj())
{
in[i] = coordinate.Float(i) / coordinate.Float(instruction.coordinates); // TODO(b/129523279): Optimize using reciprocal.
}
else
{
in[i] = coordinate.Float(i);
}
}
if(instruction.isDref())
{
auto drefValue = Operand(shader, *this, instruction.drefId);
if(instruction.isProj())
{
in[i] = drefValue.Float(0) / coordinate.Float(instruction.coordinates); // TODO(b/129523279): Optimize using reciprocal.
}
else
{
in[i] = drefValue.Float(0);
}
i++;
}
if(instruction.lodOrBiasId != 0)
{
auto lodValue = Operand(shader, *this, instruction.lodOrBiasId);
in[i] = lodValue.Float(0);
i++;
}
else if(instruction.gradDxId != 0)
{
auto dxValue = Operand(shader, *this, instruction.gradDxId);
auto dyValue = Operand(shader, *this, instruction.gradDyId);
ASSERT(dxValue.componentCount == dxValue.componentCount);
for(uint32_t j = 0; j < dxValue.componentCount; j++, i++)
{
in[i] = dxValue.Float(j);
}
for(uint32_t j = 0; j < dxValue.componentCount; j++, i++)
{
in[i] = dyValue.Float(j);
}
}
else if(instruction.samplerMethod == Fetch)
{
// The instruction didn't provide a lod operand, but the sampler's Fetch
// function requires one to be present. If no lod is supplied, the default
// is zero.
in[i] = As<SIMD::Float>(SIMD::Int(0));
i++;
}
if(instruction.offsetId != 0)
{
auto offsetValue = Operand(shader, *this, instruction.offsetId);
for(uint32_t j = 0; j < offsetValue.componentCount; j++, i++)
{
in[i] = As<SIMD::Float>(offsetValue.Int(j)); // Integer values, but transfered as float.
}
}
if(instruction.sample)
{
auto sampleValue = Operand(shader, *this, instruction.sampleId);
in[i] = As<SIMD::Float>(sampleValue.Int(0));
}
Pointer<Byte> texture = imageDescriptor + OFFSET(vk::SampledImageDescriptor, texture); // sw::Texture*
Call<ImageSampler>(samplerFunction, texture, &in, &out, routine->constants);
}
void SpirvEmitter::EmitImageQuerySizeLod(InsnIterator insn)
{
auto &resultTy = shader.getType(insn.resultTypeId());
auto imageId = Object::ID(insn.word(3));
auto lodId = Object::ID(insn.word(4));
auto &dst = createIntermediate(insn.resultId(), resultTy.componentCount);
GetImageDimensions(resultTy, imageId, lodId, dst);
}
void SpirvEmitter::EmitImageQuerySize(InsnIterator insn)
{
auto &resultTy = shader.getType(insn.resultTypeId());
auto imageId = Object::ID(insn.word(3));
auto lodId = Object::ID(0);
auto &dst = createIntermediate(insn.resultId(), resultTy.componentCount);
GetImageDimensions(resultTy, imageId, lodId, dst);
}
void SpirvEmitter::GetImageDimensions(const Type &resultTy, Object::ID imageId, Object::ID lodId, Intermediate &dst) const
{
auto &image = shader.getObject(imageId);
auto &imageType = shader.getType(image);
ASSERT(imageType.definition.opcode() == spv::OpTypeImage);
bool isArrayed = imageType.definition.word(5) != 0;
uint32_t dimensions = resultTy.componentCount - (isArrayed ? 1 : 0);
const Spirv::DescriptorDecorations &d = shader.descriptorDecorations.at(imageId);
auto descriptorType = routine->pipelineLayout->getDescriptorType(d.DescriptorSet, d.Binding);
Pointer<Byte> descriptor = getPointer(imageId).getUniformPointer();
Int width;
Int height;
Int depth;
switch(descriptorType)
{
case VK_DESCRIPTOR_TYPE_STORAGE_IMAGE:
case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
width = *Pointer<Int>(descriptor + OFFSET(vk::StorageImageDescriptor, width));
height = *Pointer<Int>(descriptor + OFFSET(vk::StorageImageDescriptor, height));
depth = *Pointer<Int>(descriptor + OFFSET(vk::StorageImageDescriptor, depth));
break;
case VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER:
case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
width = *Pointer<Int>(descriptor + OFFSET(vk::SampledImageDescriptor, width));
height = *Pointer<Int>(descriptor + OFFSET(vk::SampledImageDescriptor, height));
depth = *Pointer<Int>(descriptor + OFFSET(vk::SampledImageDescriptor, depth));
break;
default:
UNREACHABLE("Image descriptorType: %d", int(descriptorType));
}
if(lodId != 0)
{
auto lodVal = Operand(shader, *this, lodId);
ASSERT(lodVal.componentCount == 1);
auto lod = lodVal.Int(0);
auto one = SIMD::Int(1);
if(dimensions >= 1) dst.move(0, Max(SIMD::Int(width) >> lod, one));
if(dimensions >= 2) dst.move(1, Max(SIMD::Int(height) >> lod, one));
if(dimensions >= 3) dst.move(2, Max(SIMD::Int(depth) >> lod, one));
}
else
{
if(dimensions >= 1) dst.move(0, SIMD::Int(width));
if(dimensions >= 2) dst.move(1, SIMD::Int(height));
if(dimensions >= 3) dst.move(2, SIMD::Int(depth));
}
if(isArrayed)
{
dst.move(dimensions, SIMD::Int(depth));
}
}
void SpirvEmitter::EmitImageQueryLevels(InsnIterator insn)
{
auto &resultTy = shader.getType(insn.resultTypeId());
ASSERT(resultTy.componentCount == 1);
auto imageId = Object::ID(insn.word(3));
const Spirv::DescriptorDecorations &d = shader.descriptorDecorations.at(imageId);
auto descriptorType = routine->pipelineLayout->getDescriptorType(d.DescriptorSet, d.Binding);
Pointer<Byte> descriptor = getPointer(imageId).getUniformPointer();
Int mipLevels = 0;
switch(descriptorType)
{
case VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER:
case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
mipLevels = *Pointer<Int>(descriptor + OFFSET(vk::SampledImageDescriptor, mipLevels)); // uint32_t
break;
default:
UNREACHABLE("Image descriptorType: %d", int(descriptorType));
}
auto &dst = createIntermediate(insn.resultId(), 1);
dst.move(0, SIMD::Int(mipLevels));
}
void SpirvEmitter::EmitImageQuerySamples(InsnIterator insn)
{
auto &resultTy = shader.getType(insn.resultTypeId());
ASSERT(resultTy.componentCount == 1);
auto imageId = Object::ID(insn.word(3));
auto imageTy = shader.getObjectType(imageId);
ASSERT(imageTy.definition.opcode() == spv::OpTypeImage);
ASSERT(imageTy.definition.word(3) == spv::Dim2D);
ASSERT(imageTy.definition.word(6 /* MS */) == 1);
const Spirv::DescriptorDecorations &d = shader.descriptorDecorations.at(imageId);
auto descriptorType = routine->pipelineLayout->getDescriptorType(d.DescriptorSet, d.Binding);
Pointer<Byte> descriptor = getPointer(imageId).getUniformPointer();
Int sampleCount = 0;
switch(descriptorType)
{
case VK_DESCRIPTOR_TYPE_STORAGE_IMAGE:
sampleCount = *Pointer<Int>(descriptor + OFFSET(vk::StorageImageDescriptor, sampleCount)); // uint32_t
break;
case VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER:
case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
sampleCount = *Pointer<Int>(descriptor + OFFSET(vk::SampledImageDescriptor, sampleCount)); // uint32_t
break;
default:
UNREACHABLE("Image descriptorType: %d", int(descriptorType));
}
auto &dst = createIntermediate(insn.resultId(), 1);
dst.move(0, SIMD::Int(sampleCount));
}
SpirvEmitter::TexelAddressData SpirvEmitter::setupTexelAddressData(SIMD::Int rowPitch, SIMD::Int slicePitch, SIMD::Int samplePitch, ImageInstructionSignature instruction, SIMD::Int coordinate[], SIMD::Int sample, vk::Format imageFormat, const SpirvRoutine *routine)
{
TexelAddressData data;
data.isArrayed = instruction.arrayed;
data.dim = static_cast<spv::Dim>(instruction.dim);
data.texelSize = imageFormat.bytes();
data.dims = instruction.coordinates - (data.isArrayed ? 1 : 0);
data.u = coordinate[0];
data.v = SIMD::Int(0);
if(data.dims > 1)
{
data.v = coordinate[1];
}
if(data.dim == spv::DimSubpassData)
{
data.u += routine->windowSpacePosition[0];
data.v += routine->windowSpacePosition[1];
}
data.ptrOffset = data.u * SIMD::Int(data.texelSize);
if(data.dims > 1)
{
data.ptrOffset += data.v * rowPitch;
}
data.w = 0;
if((data.dims > 2) || data.isArrayed)
{
if(data.dims > 2)
{
data.w += coordinate[2];
}
if(data.isArrayed)
{
data.w += coordinate[data.dims];
}
data.ptrOffset += data.w * slicePitch;
}
if(data.dim == spv::DimSubpassData)
{
// Multiview input attachment access is to the layer corresponding to the current view
data.ptrOffset += SIMD::Int(routine->layer) * slicePitch;
}
if(instruction.sample)
{
data.ptrOffset += sample * samplePitch;
}
return data;
}
SIMD::Pointer SpirvEmitter::GetNonUniformTexelAddress(ImageInstructionSignature instruction, SIMD::Pointer descriptor, SIMD::Int coordinate[], SIMD::Int sample, vk::Format imageFormat, OutOfBoundsBehavior outOfBoundsBehavior, SIMD::Int activeLaneMask, const SpirvRoutine *routine)
{
const bool useStencilAspect = (imageFormat == VK_FORMAT_S8_UINT);
auto rowPitch = (descriptor + (useStencilAspect
? OFFSET(vk::StorageImageDescriptor, stencilRowPitchBytes)
: OFFSET(vk::StorageImageDescriptor, rowPitchBytes)))
.Load<SIMD::Int>(outOfBoundsBehavior, activeLaneMask);
auto slicePitch = (descriptor + (useStencilAspect
? OFFSET(vk::StorageImageDescriptor, stencilSlicePitchBytes)
: OFFSET(vk::StorageImageDescriptor, slicePitchBytes)))
.Load<SIMD::Int>(outOfBoundsBehavior, activeLaneMask);
auto samplePitch = (descriptor + (useStencilAspect
? OFFSET(vk::StorageImageDescriptor, stencilSamplePitchBytes)
: OFFSET(vk::StorageImageDescriptor, samplePitchBytes)))
.Load<SIMD::Int>(outOfBoundsBehavior, activeLaneMask);
auto texelData = setupTexelAddressData(rowPitch, slicePitch, samplePitch, instruction, coordinate, sample, imageFormat, routine);
// If the out-of-bounds behavior is set to nullify, then each coordinate must be tested individually.
// Other out-of-bounds behaviors work properly by just comparing the offset against the total size.
if(outOfBoundsBehavior == OutOfBoundsBehavior::Nullify)
{
SIMD::UInt width = (descriptor + OFFSET(vk::StorageImageDescriptor, width)).Load<SIMD::Int>(outOfBoundsBehavior, activeLaneMask);
SIMD::Int oobMask = As<SIMD::Int>(CmpNLT(As<SIMD::UInt>(texelData.u), width));
if(texelData.dims > 1)
{
SIMD::UInt height = As<SIMD::UInt>((descriptor + OFFSET(vk::StorageImageDescriptor, height)).Load<SIMD::Int>(outOfBoundsBehavior, activeLaneMask));
oobMask |= As<SIMD::Int>(CmpNLT(As<SIMD::UInt>(texelData.v), height));
}
if((texelData.dims > 2) || texelData.isArrayed)
{
SIMD::UInt depth = As<SIMD::UInt>((descriptor + OFFSET(vk::StorageImageDescriptor, depth)).Load<SIMD::Int>(outOfBoundsBehavior, activeLaneMask));
if(texelData.dim == spv::DimCube) { depth *= 6; }
oobMask |= As<SIMD::Int>(CmpNLT(As<SIMD::UInt>(texelData.w), depth));
}
if(instruction.sample)
{
SIMD::UInt sampleCount = As<SIMD::UInt>((descriptor + OFFSET(vk::StorageImageDescriptor, sampleCount)).Load<SIMD::Int>(outOfBoundsBehavior, activeLaneMask));
oobMask |= As<SIMD::Int>(CmpNLT(As<SIMD::UInt>(sample), sampleCount));
}
constexpr int32_t OOB_OFFSET = 0x7FFFFFFF - 16; // SIMD pointer offsets are signed 32-bit, so this is the largest offset (for 16-byte texels).
static_assert(OOB_OFFSET >= vk::MAX_MEMORY_ALLOCATION_SIZE, "the largest offset must be guaranteed to be out-of-bounds");
texelData.ptrOffset = (texelData.ptrOffset & ~oobMask) | (oobMask & SIMD::Int(OOB_OFFSET)); // oob ? OOB_OFFSET : ptrOffset // TODO: IfThenElse()
}
std::vector<Pointer<Byte>> imageBase(SIMD::Width);
for(int i = 0; i < SIMD::Width; i++)
{
imageBase[i] = *Pointer<Pointer<Byte>>(descriptor.getPointerForLane(i) + (useStencilAspect
? OFFSET(vk::StorageImageDescriptor, stencilPtr)
: OFFSET(vk::StorageImageDescriptor, ptr)));
}
return SIMD::Pointer(imageBase) + texelData.ptrOffset;
}
SIMD::Pointer SpirvEmitter::GetTexelAddress(ImageInstructionSignature instruction, Pointer<Byte> descriptor, SIMD::Int coordinate[], SIMD::Int sample, vk::Format imageFormat, OutOfBoundsBehavior outOfBoundsBehavior, const SpirvRoutine *routine)
{
const bool useStencilAspect = (imageFormat == VK_FORMAT_S8_UINT);
auto rowPitch = SIMD::Int(*Pointer<Int>(descriptor + (useStencilAspect
? OFFSET(vk::StorageImageDescriptor, stencilRowPitchBytes)
: OFFSET(vk::StorageImageDescriptor, rowPitchBytes))));
auto slicePitch = SIMD::Int(
*Pointer<Int>(descriptor + (useStencilAspect
? OFFSET(vk::StorageImageDescriptor, stencilSlicePitchBytes)
: OFFSET(vk::StorageImageDescriptor, slicePitchBytes))));
auto samplePitch = SIMD::Int(
*Pointer<Int>(descriptor + (useStencilAspect
? OFFSET(vk::StorageImageDescriptor, stencilSamplePitchBytes)
: OFFSET(vk::StorageImageDescriptor, samplePitchBytes))));
auto texelData = setupTexelAddressData(rowPitch, slicePitch, samplePitch, instruction, coordinate, sample, imageFormat, routine);
// If the out-of-bounds behavior is set to nullify, then each coordinate must be tested individually.
// Other out-of-bounds behaviors work properly by just comparing the offset against the total size.
if(outOfBoundsBehavior == OutOfBoundsBehavior::Nullify)
{
SIMD::UInt width = *Pointer<UInt>(descriptor + OFFSET(vk::StorageImageDescriptor, width));
SIMD::Int oobMask = As<SIMD::Int>(CmpNLT(As<SIMD::UInt>(texelData.u), width));
if(texelData.dims > 1)
{
SIMD::UInt height = *Pointer<UInt>(descriptor + OFFSET(vk::StorageImageDescriptor, height));
oobMask |= As<SIMD::Int>(CmpNLT(As<SIMD::UInt>(texelData.v), height));
}
if((texelData.dims > 2) || texelData.isArrayed)
{
UInt depth = *Pointer<UInt>(descriptor + OFFSET(vk::StorageImageDescriptor, depth));
if(texelData.dim == spv::DimCube) { depth *= 6; }
oobMask |= As<SIMD::Int>(CmpNLT(As<SIMD::UInt>(texelData.w), SIMD::UInt(depth)));
}
if(instruction.sample)
{
SIMD::UInt sampleCount = *Pointer<UInt>(descriptor + OFFSET(vk::StorageImageDescriptor, sampleCount));
oobMask |= As<SIMD::Int>(CmpNLT(As<SIMD::UInt>(sample), sampleCount));
}
constexpr int32_t OOB_OFFSET = 0x7FFFFFFF - 16; // SIMD pointer offsets are signed 32-bit, so this is the largest offset (for 16-byte texels).
static_assert(OOB_OFFSET >= vk::MAX_MEMORY_ALLOCATION_SIZE, "the largest offset must be guaranteed to be out-of-bounds");
texelData.ptrOffset = (texelData.ptrOffset & ~oobMask) | (oobMask & SIMD::Int(OOB_OFFSET)); // oob ? OOB_OFFSET : ptrOffset // TODO: IfThenElse()
}
Pointer<Byte> imageBase = *Pointer<Pointer<Byte>>(descriptor + (useStencilAspect
? OFFSET(vk::StorageImageDescriptor, stencilPtr)
: OFFSET(vk::StorageImageDescriptor, ptr)));
Int imageSizeInBytes = *Pointer<Int>(descriptor + OFFSET(vk::StorageImageDescriptor, sizeInBytes));
return SIMD::Pointer(imageBase, imageSizeInBytes, texelData.ptrOffset);
}
void SpirvEmitter::EmitImageRead(const ImageInstruction &instruction)
{
auto &resultType = shader.getObjectType(instruction.resultId);
auto &image = shader.getObject(instruction.imageId);
auto &imageType = shader.getType(image);
ASSERT(imageType.definition.opcode() == spv::OpTypeImage);
auto dim = static_cast<spv::Dim>(instruction.dim);
auto coordinate = Operand(shader, *this, instruction.coordinateId);
const Spirv::DescriptorDecorations &d = shader.descriptorDecorations.at(instruction.imageId);
// For subpass data, format in the instruction is spv::ImageFormatUnknown. Get it from
// the renderpass data instead. In all other cases, we can use the format in the instruction.
vk::Format imageFormat = (dim == spv::DimSubpassData)
? shader.getInputAttachmentFormat(d.InputAttachmentIndex)
: SpirvFormatToVulkanFormat(static_cast<spv::ImageFormat>(instruction.imageFormat));
// Depth+Stencil image attachments select aspect based on the Sampled Type of the
// OpTypeImage. If float, then we want the depth aspect. If int, we want the stencil aspect.
bool useStencilAspect = (imageFormat == VK_FORMAT_D32_SFLOAT_S8_UINT &&
shader.getType(imageType.definition.word(2)).opcode() == spv::OpTypeInt);
if(useStencilAspect)
{
imageFormat = VK_FORMAT_S8_UINT;
}
auto &dst = createIntermediate(instruction.resultId, resultType.componentCount);
SIMD::Pointer ptr = getPointer(instruction.imageId);
SIMD::Int uvwa[4];
SIMD::Int sample;
const int texelSize = imageFormat.bytes();
// VK_EXT_image_robustness requires replacing out-of-bounds access with zero.
// TODO(b/162327166): Only perform bounds checks when VK_EXT_image_robustness is enabled.
auto robustness = OutOfBoundsBehavior::Nullify;
for(uint32_t i = 0; i < instruction.coordinates; i++)
{
uvwa[i] = coordinate.Int(i);
}
if(instruction.sample)
{
sample = Operand(shader, *this, instruction.sampleId).Int(0);
}
// Gather packed texel data. Texels larger than 4 bytes occupy multiple SIMD::Int elements.
// TODO(b/160531165): Provide gather abstractions for various element sizes.
SIMD::Int packed[4];
SIMD::Pointer texelPtr = ptr.isBasePlusOffset
? GetTexelAddress(instruction, ptr.getUniformPointer(), uvwa, sample, imageFormat, robustness, routine)
: GetNonUniformTexelAddress(instruction, ptr, uvwa, sample, imageFormat, robustness, activeLaneMask(), routine);
if(texelSize == 4 || texelSize == 8 || texelSize == 16)
{
for(auto i = 0; i < texelSize / 4; i++)
{
packed[i] = texelPtr.Load<SIMD::Int>(robustness, activeLaneMask());
texelPtr += sizeof(float);
}
}
else if(texelSize == 2)
{
SIMD::Int mask = activeLaneMask() & texelPtr.isInBounds(2, robustness);
for(int i = 0; i < SIMD::Width; i++)
{
If(Extract(mask, i) != 0)
{
packed[0] = Insert(packed[0], Int(*Pointer<Short>(texelPtr.getPointerForLane(i))), i);
}
}
}
else if(texelSize == 1)
{
SIMD::Int mask = activeLaneMask() & texelPtr.isInBounds(1, robustness);
for(int i = 0; i < SIMD::Width; i++)
{
If(Extract(mask, i) != 0)
{
packed[0] = Insert(packed[0], Int(*Pointer<Byte>(texelPtr.getPointerForLane(i))), i);
}
}
}
else
UNREACHABLE("texelSize: %d", int(texelSize));
// Format support requirements here come from two sources:
// - Minimum required set of formats for loads from storage images
// - Any format supported as a color or depth/stencil attachment, for input attachments
switch(imageFormat)
{
case VK_FORMAT_R32G32B32A32_SFLOAT:
case VK_FORMAT_R32G32B32A32_SINT:
case VK_FORMAT_R32G32B32A32_UINT:
dst.move(0, packed[0]);
dst.move(1, packed[1]);
dst.move(2, packed[2]);
dst.move(3, packed[3]);
break;
case VK_FORMAT_R32_SINT:
case VK_FORMAT_R32_UINT:
dst.move(0, packed[0]);
// Fill remaining channels with 0,0,1 (of the correct type)
dst.move(1, SIMD::Int(0));
dst.move(2, SIMD::Int(0));
dst.move(3, SIMD::Int(1));
break;
case VK_FORMAT_R32_SFLOAT:
case VK_FORMAT_D32_SFLOAT:
case VK_FORMAT_D32_SFLOAT_S8_UINT:
dst.move(0, packed[0]);
// Fill remaining channels with 0,0,1 (of the correct type)
dst.move(1, SIMD::Float(0.0f));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_D16_UNORM:
dst.move(0, SIMD::Float(packed[0] & SIMD::Int(0xFFFF)) * SIMD::Float(1.0f / 0xFFFF));
dst.move(1, SIMD::Float(0.0f));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R16G16B16A16_UNORM:
dst.move(0, SIMD::Float(packed[0] & SIMD::Int(0xFFFF)) * SIMD::Float(1.0f / 0xFFFF));
dst.move(1, SIMD::Float((packed[0] >> 16) & SIMD::Int(0xFFFF)) * SIMD::Float(1.0f / 0xFFFF));
dst.move(2, SIMD::Float(packed[1] & SIMD::Int(0xFFFF)) * SIMD::Float(1.0f / 0xFFFF));
dst.move(3, SIMD::Float((packed[1] >> 16) & SIMD::Int(0xFFFF)) * SIMD::Float(1.0f / 0xFFFF));
break;
case VK_FORMAT_R16G16B16A16_SNORM:
dst.move(0, Max(SIMD::Float((packed[0] << 16) & SIMD::Int(0xFFFF0000)) * SIMD::Float(1.0f / 0x7FFF0000), SIMD::Float(-1.0f)));
dst.move(1, Max(SIMD::Float(packed[0] & SIMD::Int(0xFFFF0000)) * SIMD::Float(1.0f / 0x7FFF0000), SIMD::Float(-1.0f)));
dst.move(2, Max(SIMD::Float((packed[1] << 16) & SIMD::Int(0xFFFF0000)) * SIMD::Float(1.0f / 0x7FFF0000), SIMD::Float(-1.0f)));
dst.move(3, Max(SIMD::Float(packed[1] & SIMD::Int(0xFFFF0000)) * SIMD::Float(1.0f / 0x7FFF0000), SIMD::Float(-1.0f)));
break;
case VK_FORMAT_R16G16B16A16_SINT:
dst.move(0, (packed[0] << 16) >> 16);
dst.move(1, packed[0] >> 16);
dst.move(2, (packed[1] << 16) >> 16);
dst.move(3, packed[1] >> 16);
break;
case VK_FORMAT_R16G16B16A16_UINT:
dst.move(0, packed[0] & SIMD::Int(0xFFFF));
dst.move(1, (packed[0] >> 16) & SIMD::Int(0xFFFF));
dst.move(2, packed[1] & SIMD::Int(0xFFFF));
dst.move(3, (packed[1] >> 16) & SIMD::Int(0xFFFF));
break;
case VK_FORMAT_R16G16B16A16_SFLOAT:
dst.move(0, halfToFloatBits(As<SIMD::UInt>(packed[0]) & SIMD::UInt(0x0000FFFF)));
dst.move(1, halfToFloatBits((As<SIMD::UInt>(packed[0]) & SIMD::UInt(0xFFFF0000)) >> 16));
dst.move(2, halfToFloatBits(As<SIMD::UInt>(packed[1]) & SIMD::UInt(0x0000FFFF)));
dst.move(3, halfToFloatBits((As<SIMD::UInt>(packed[1]) & SIMD::UInt(0xFFFF0000)) >> 16));
break;
case VK_FORMAT_R8G8B8A8_SNORM:
case VK_FORMAT_A8B8G8R8_SNORM_PACK32:
dst.move(0, Max(SIMD::Float((packed[0] << 24) & SIMD::Int(0xFF000000)) * SIMD::Float(1.0f / 0x7F000000), SIMD::Float(-1.0f)));
dst.move(1, Max(SIMD::Float((packed[0] << 16) & SIMD::Int(0xFF000000)) * SIMD::Float(1.0f / 0x7F000000), SIMD::Float(-1.0f)));
dst.move(2, Max(SIMD::Float((packed[0] << 8) & SIMD::Int(0xFF000000)) * SIMD::Float(1.0f / 0x7F000000), SIMD::Float(-1.0f)));
dst.move(3, Max(SIMD::Float((packed[0]) & SIMD::Int(0xFF000000)) * SIMD::Float(1.0f / 0x7F000000), SIMD::Float(-1.0f)));
break;
case VK_FORMAT_R8G8B8A8_UNORM:
case VK_FORMAT_A8B8G8R8_UNORM_PACK32:
dst.move(0, SIMD::Float(packed[0] & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
dst.move(1, SIMD::Float((packed[0] >> 8) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
dst.move(2, SIMD::Float((packed[0] >> 16) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
dst.move(3, SIMD::Float((packed[0] >> 24) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
break;
case VK_FORMAT_R8G8B8A8_SRGB:
case VK_FORMAT_A8B8G8R8_SRGB_PACK32:
dst.move(0, sRGBtoLinear(SIMD::Float(packed[0] & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF)));
dst.move(1, sRGBtoLinear(SIMD::Float((packed[0] >> 8) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF)));
dst.move(2, sRGBtoLinear(SIMD::Float((packed[0] >> 16) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF)));
dst.move(3, SIMD::Float((packed[0] >> 24) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
break;
case VK_FORMAT_B8G8R8A8_UNORM:
dst.move(0, SIMD::Float((packed[0] >> 16) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
dst.move(1, SIMD::Float((packed[0] >> 8) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
dst.move(2, SIMD::Float(packed[0] & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
dst.move(3, SIMD::Float((packed[0] >> 24) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
break;
case VK_FORMAT_B8G8R8A8_SRGB:
dst.move(0, sRGBtoLinear(SIMD::Float((packed[0] >> 16) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF)));
dst.move(1, sRGBtoLinear(SIMD::Float((packed[0] >> 8) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF)));
dst.move(2, sRGBtoLinear(SIMD::Float(packed[0] & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF)));
dst.move(3, SIMD::Float((packed[0] >> 24) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
break;
case VK_FORMAT_R8G8B8A8_UINT:
case VK_FORMAT_A8B8G8R8_UINT_PACK32:
dst.move(0, As<SIMD::UInt>(packed[0]) & SIMD::UInt(0xFF));
dst.move(1, (As<SIMD::UInt>(packed[0]) >> 8) & SIMD::UInt(0xFF));
dst.move(2, (As<SIMD::UInt>(packed[0]) >> 16) & SIMD::UInt(0xFF));
dst.move(3, (As<SIMD::UInt>(packed[0]) >> 24) & SIMD::UInt(0xFF));
break;
case VK_FORMAT_R8G8B8A8_SINT:
case VK_FORMAT_A8B8G8R8_SINT_PACK32:
dst.move(0, (packed[0] << 24) >> 24);
dst.move(1, (packed[0] << 16) >> 24);
dst.move(2, (packed[0] << 8) >> 24);
dst.move(3, packed[0] >> 24);
break;
case VK_FORMAT_R8_UNORM:
dst.move(0, SIMD::Float((packed[0] & SIMD::Int(0xFF))) * SIMD::Float(1.0f / 0xFF));
dst.move(1, SIMD::Float(0.0f));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R8_SNORM:
dst.move(0, Max(SIMD::Float((packed[0] << 24) & SIMD::Int(0xFF000000)) * SIMD::Float(1.0f / 0x7F000000), SIMD::Float(-1.0f)));
dst.move(1, SIMD::Float(0.0f));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R8_UINT:
case VK_FORMAT_S8_UINT:
dst.move(0, As<SIMD::UInt>(packed[0]) & SIMD::UInt(0xFF));
dst.move(1, SIMD::UInt(0));
dst.move(2, SIMD::UInt(0));
dst.move(3, SIMD::UInt(1));
break;
case VK_FORMAT_R8_SINT:
dst.move(0, (packed[0] << 24) >> 24);
dst.move(1, SIMD::Int(0));
dst.move(2, SIMD::Int(0));
dst.move(3, SIMD::Int(1));
break;
case VK_FORMAT_R8G8_UNORM:
dst.move(0, SIMD::Float(packed[0] & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
dst.move(1, SIMD::Float((packed[0] >> 8) & SIMD::Int(0xFF)) * SIMD::Float(1.0f / 0xFF));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R8G8_SNORM:
dst.move(0, Max(SIMD::Float((packed[0] << 24) & SIMD::Int(0xFF000000)) * SIMD::Float(1.0f / 0x7F000000), SIMD::Float(-1.0f)));
dst.move(1, Max(SIMD::Float((packed[0] << 16) & SIMD::Int(0xFF000000)) * SIMD::Float(1.0f / 0x7F000000), SIMD::Float(-1.0f)));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R8G8_UINT:
dst.move(0, As<SIMD::UInt>(packed[0]) & SIMD::UInt(0xFF));
dst.move(1, (As<SIMD::UInt>(packed[0]) >> 8) & SIMD::UInt(0xFF));
dst.move(2, SIMD::UInt(0));
dst.move(3, SIMD::UInt(1));
break;
case VK_FORMAT_R8G8_SINT:
dst.move(0, (packed[0] << 24) >> 24);
dst.move(1, (packed[0] << 16) >> 24);
dst.move(2, SIMD::Int(0));
dst.move(3, SIMD::Int(1));
break;
case VK_FORMAT_R16_SFLOAT:
dst.move(0, halfToFloatBits(As<SIMD::UInt>(packed[0]) & SIMD::UInt(0x0000FFFF)));
dst.move(1, SIMD::Float(0.0f));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R16_UNORM:
dst.move(0, SIMD::Float(packed[0] & SIMD::Int(0xFFFF)) * SIMD::Float(1.0f / 0xFFFF));
dst.move(1, SIMD::Float(0.0f));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R16_SNORM:
dst.move(0, Max(SIMD::Float((packed[0] << 16) & SIMD::Int(0xFFFF0000)) * SIMD::Float(1.0f / 0x7FFF0000), SIMD::Float(-1.0f)));
dst.move(1, SIMD::Float(0.0f));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R16_UINT:
dst.move(0, packed[0] & SIMD::Int(0xFFFF));
dst.move(1, SIMD::UInt(0));
dst.move(2, SIMD::UInt(0));
dst.move(3, SIMD::UInt(1));
break;
case VK_FORMAT_R16_SINT:
dst.move(0, (packed[0] << 16) >> 16);
dst.move(1, SIMD::Int(0));
dst.move(2, SIMD::Int(0));
dst.move(3, SIMD::Int(1));
break;
case VK_FORMAT_R16G16_SFLOAT:
dst.move(0, halfToFloatBits(As<SIMD::UInt>(packed[0]) & SIMD::UInt(0x0000FFFF)));
dst.move(1, halfToFloatBits((As<SIMD::UInt>(packed[0]) & SIMD::UInt(0xFFFF0000)) >> 16));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R16G16_UNORM:
dst.move(0, SIMD::Float(packed[0] & SIMD::Int(0xFFFF)) * SIMD::Float(1.0f / 0xFFFF));
dst.move(1, SIMD::Float(As<SIMD::UInt>(packed[0]) >> 16) * SIMD::Float(1.0f / 0xFFFF));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R16G16_SNORM:
dst.move(0, Max(SIMD::Float((packed[0] << 16) & SIMD::Int(0xFFFF0000)) * SIMD::Float(1.0f / 0x7FFF0000), SIMD::Float(-1.0f)));
dst.move(1, Max(SIMD::Float(packed[0] & SIMD::Int(0xFFFF0000)) * SIMD::Float(1.0f / 0x7FFF0000), SIMD::Float(-1.0f)));
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R16G16_UINT:
dst.move(0, packed[0] & SIMD::Int(0xFFFF));
dst.move(1, (packed[0] >> 16) & SIMD::Int(0xFFFF));
dst.move(2, SIMD::UInt(0));
dst.move(3, SIMD::UInt(1));
break;
case VK_FORMAT_R16G16_SINT:
dst.move(0, (packed[0] << 16) >> 16);
dst.move(1, packed[0] >> 16);
dst.move(2, SIMD::Int(0));
dst.move(3, SIMD::Int(1));
break;
case VK_FORMAT_R32G32_SINT:
case VK_FORMAT_R32G32_UINT:
dst.move(0, packed[0]);
dst.move(1, packed[1]);
dst.move(2, SIMD::Int(0));
dst.move(3, SIMD::Int(1));
break;
case VK_FORMAT_R32G32_SFLOAT:
dst.move(0, packed[0]);
dst.move(1, packed[1]);
dst.move(2, SIMD::Float(0.0f));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_A2B10G10R10_UINT_PACK32:
dst.move(0, packed[0] & SIMD::Int(0x3FF));
dst.move(1, (packed[0] >> 10) & SIMD::Int(0x3FF));
dst.move(2, (packed[0] >> 20) & SIMD::Int(0x3FF));
dst.move(3, (packed[0] >> 30) & SIMD::Int(0x3));
break;
case VK_FORMAT_A2R10G10B10_UINT_PACK32:
dst.move(2, packed[0] & SIMD::Int(0x3FF));
dst.move(1, (packed[0] >> 10) & SIMD::Int(0x3FF));
dst.move(0, (packed[0] >> 20) & SIMD::Int(0x3FF));
dst.move(3, (packed[0] >> 30) & SIMD::Int(0x3));
break;
case VK_FORMAT_A2B10G10R10_UNORM_PACK32:
dst.move(0, SIMD::Float((packed[0]) & SIMD::Int(0x3FF)) * SIMD::Float(1.0f / 0x3FF));
dst.move(1, SIMD::Float((packed[0] >> 10) & SIMD::Int(0x3FF)) * SIMD::Float(1.0f / 0x3FF));
dst.move(2, SIMD::Float((packed[0] >> 20) & SIMD::Int(0x3FF)) * SIMD::Float(1.0f / 0x3FF));
dst.move(3, SIMD::Float((packed[0] >> 30) & SIMD::Int(0x3)) * SIMD::Float(1.0f / 0x3));
break;
case VK_FORMAT_A2R10G10B10_UNORM_PACK32:
dst.move(2, SIMD::Float((packed[0]) & SIMD::Int(0x3FF)) * SIMD::Float(1.0f / 0x3FF));
dst.move(1, SIMD::Float((packed[0] >> 10) & SIMD::Int(0x3FF)) * SIMD::Float(1.0f / 0x3FF));
dst.move(0, SIMD::Float((packed[0] >> 20) & SIMD::Int(0x3FF)) * SIMD::Float(1.0f / 0x3FF));
dst.move(3, SIMD::Float((packed[0] >> 30) & SIMD::Int(0x3)) * SIMD::Float(1.0f / 0x3));
break;
case VK_FORMAT_R4G4B4A4_UNORM_PACK16:
dst.move(0, SIMD::Float((packed[0] >> 12) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(1, SIMD::Float((packed[0] >> 8) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(2, SIMD::Float((packed[0] >> 4) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(3, SIMD::Float((packed[0]) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
break;
case VK_FORMAT_B4G4R4A4_UNORM_PACK16:
dst.move(0, SIMD::Float((packed[0] >> 4) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(1, SIMD::Float((packed[0] >> 8) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(2, SIMD::Float((packed[0] >> 12) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(3, SIMD::Float((packed[0]) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
break;
case VK_FORMAT_A4R4G4B4_UNORM_PACK16:
dst.move(0, SIMD::Float((packed[0] >> 8) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(1, SIMD::Float((packed[0] >> 4) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(2, SIMD::Float((packed[0]) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(3, SIMD::Float((packed[0] >> 12) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
break;
case VK_FORMAT_A4B4G4R4_UNORM_PACK16:
dst.move(0, SIMD::Float((packed[0]) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(1, SIMD::Float((packed[0] >> 4) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(2, SIMD::Float((packed[0] >> 8) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
dst.move(3, SIMD::Float((packed[0] >> 12) & SIMD::Int(0xF)) * SIMD::Float(1.0f / 0xF));
break;
case VK_FORMAT_R5G6B5_UNORM_PACK16:
dst.move(0, SIMD::Float((packed[0] >> 11) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(1, SIMD::Float((packed[0] >> 5) & SIMD::Int(0x3F)) * SIMD::Float(1.0f / 0x3F));
dst.move(2, SIMD::Float((packed[0]) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_B5G6R5_UNORM_PACK16:
dst.move(0, SIMD::Float((packed[0]) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(1, SIMD::Float((packed[0] >> 5) & SIMD::Int(0x3F)) * SIMD::Float(1.0f / 0x3F));
dst.move(2, SIMD::Float((packed[0] >> 11) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(3, SIMD::Float(1.0f));
break;
case VK_FORMAT_R5G5B5A1_UNORM_PACK16:
dst.move(0, SIMD::Float((packed[0] >> 11) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(1, SIMD::Float((packed[0] >> 6) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(2, SIMD::Float((packed[0] >> 1) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(3, SIMD::Float((packed[0]) & SIMD::Int(0x1)));
break;
case VK_FORMAT_B5G5R5A1_UNORM_PACK16:
dst.move(0, SIMD::Float((packed[0] >> 1) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(1, SIMD::Float((packed[0] >> 6) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(2, SIMD::Float((packed[0] >> 11) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(3, SIMD::Float((packed[0]) & SIMD::Int(0x1)));
break;
case VK_FORMAT_A1R5G5B5_UNORM_PACK16:
dst.move(0, SIMD::Float((packed[0] >> 10) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(1, SIMD::Float((packed[0] >> 5) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(2, SIMD::Float((packed[0]) & SIMD::Int(0x1F)) * SIMD::Float(1.0f / 0x1F));
dst.move(3, SIMD::Float((packed[0] >> 15) & SIMD::Int(0x1)));
break;
case VK_FORMAT_B10G11R11_UFLOAT_PACK32:
dst.move(0, halfToFloatBits((packed[0] << 4) & SIMD::Int(0x7FF0)));
dst.move(1, halfToFloatBits((packed[0] >> 7) & SIMD::Int(0x7FF0)));
dst.move(2, halfToFloatBits((packed[0] >> 17) & SIMD::Int(0x7FE0)));
dst.move(3, SIMD::Float(1.0f));
break;
default:
UNSUPPORTED("VkFormat %d", int(imageFormat));
break;
}
}
void SpirvEmitter::EmitImageWrite(const ImageInstruction &instruction)
{
auto &image = shader.getObject(instruction.imageId);
auto &imageType = shader.getType(image);
ASSERT(imageType.definition.opcode() == spv::OpTypeImage);
ASSERT(static_cast<spv::Dim>(instruction.dim) != spv::DimSubpassData); // "Its Dim operand must not be SubpassData."
auto coordinate = Operand(shader, *this, instruction.coordinateId);
auto texel = Operand(shader, *this, instruction.texelId);
Array<SIMD::Int> coord(5); // uvwa & sample
uint32_t i = 0;
for(; i < instruction.coordinates; i++)
{
coord[i] = coordinate.Int(i);
}
if(instruction.sample)
{
coord[i] = Operand(shader, *this, instruction.sampleId).Int(0);
}
Array<SIMD::Int> texelAndMask(5);
texelAndMask[0] = texel.Int(0);
texelAndMask[1] = texel.Int(1);
texelAndMask[2] = texel.Int(2);
texelAndMask[3] = texel.Int(3);
texelAndMask[4] = activeStoresAndAtomicsMask();
vk::Format imageFormat = SpirvFormatToVulkanFormat(static_cast<spv::ImageFormat>(instruction.imageFormat));
SIMD::Pointer ptr = getPointer(instruction.imageId);
if(ptr.isBasePlusOffset)
{
Pointer<Byte> imageDescriptor = ptr.getUniformPointer(); // vk::StorageImageDescriptor* or vk::SampledImageDescriptor*
Pointer<Byte> samplerDescriptor = getSamplerDescriptor(imageDescriptor, instruction);
if(imageFormat == VK_FORMAT_UNDEFINED) // spv::ImageFormatUnknown
{
Pointer<Byte> samplerFunction = lookupSamplerFunction(imageDescriptor, samplerDescriptor, instruction);
Call<ImageSampler>(samplerFunction, imageDescriptor, &coord, &texelAndMask, routine->constants);
}
else
{
WriteImage(instruction, imageDescriptor, &coord, &texelAndMask, imageFormat);
}
}
else
{
for(int j = 0; j < SIMD::Width; j++)
{
SIMD::Int singleLaneMask = 0;
singleLaneMask = Insert(singleLaneMask, 0xffffffff, j);
texelAndMask[4] = activeStoresAndAtomicsMask() & singleLaneMask;
Pointer<Byte> imageDescriptor = ptr.getPointerForLane(j);
Pointer<Byte> samplerDescriptor = getSamplerDescriptor(imageDescriptor, instruction, j);
if(imageFormat == VK_FORMAT_UNDEFINED) // spv::ImageFormatUnknown
{
Pointer<Byte> samplerFunction = lookupSamplerFunction(imageDescriptor, samplerDescriptor, instruction);
Call<ImageSampler>(samplerFunction, imageDescriptor, &coord, &texelAndMask, routine->constants);
}
else
{
WriteImage(instruction, imageDescriptor, &coord, &texelAndMask, imageFormat);
}
}
}
}
void SpirvEmitter::WriteImage(ImageInstructionSignature instruction, Pointer<Byte> descriptor, const Pointer<SIMD::Int> &coord, const Pointer<SIMD::Int> &texelAndMask, vk::Format imageFormat)
{
SIMD::Int texel[4];
texel[0] = texelAndMask[0];
texel[1] = texelAndMask[1];
texel[2] = texelAndMask[2];
texel[3] = texelAndMask[3];
SIMD::Int mask = texelAndMask[4];
SIMD::Int packed[4];
switch(imageFormat)
{
case VK_FORMAT_R32G32B32A32_SFLOAT:
case VK_FORMAT_R32G32B32A32_SINT:
case VK_FORMAT_R32G32B32A32_UINT:
packed[0] = texel[0];
packed[1] = texel[1];
packed[2] = texel[2];
packed[3] = texel[3];
break;
case VK_FORMAT_R32_SFLOAT:
case VK_FORMAT_R32_SINT:
case VK_FORMAT_R32_UINT:
packed[0] = texel[0];
break;
case VK_FORMAT_R8G8B8A8_UNORM:
case VK_FORMAT_A8B8G8R8_UNORM_PACK32:
packed[0] = (SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) |
((SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[1]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) << 8) |
((SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[2]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) << 16) |
((SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[3]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) << 24);
break;
case VK_FORMAT_B8G8R8A8_UNORM:
packed[0] = (SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[2]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) |
((SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[1]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) << 8) |
((SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) << 16) |
((SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[3]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) << 24);
break;
case VK_FORMAT_B8G8R8A8_SRGB:
packed[0] = (SIMD::UInt(Round(Min(Max(linearToSRGB(As<SIMD::Float>(texel[2])), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) |
((SIMD::UInt(Round(Min(Max(linearToSRGB(As<SIMD::Float>(texel[1])), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) << 8) |
((SIMD::UInt(Round(Min(Max(linearToSRGB(As<SIMD::Float>(texel[0])), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) << 16) |
((SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[3]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(255.0f)))) << 24);
break;
case VK_FORMAT_R8G8B8A8_SNORM:
case VK_FORMAT_A8B8G8R8_SNORM_PACK32:
packed[0] = (SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(127.0f))) &
SIMD::Int(0xFF)) |
((SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[1]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(127.0f))) &
SIMD::Int(0xFF))
<< 8) |
((SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[2]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(127.0f))) &
SIMD::Int(0xFF))
<< 16) |
((SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[3]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(127.0f))) &
SIMD::Int(0xFF))
<< 24);
break;
case VK_FORMAT_R8G8B8A8_SINT:
case VK_FORMAT_R8G8B8A8_UINT:
case VK_FORMAT_A8B8G8R8_SINT_PACK32:
case VK_FORMAT_A8B8G8R8_UINT_PACK32:
packed[0] = (SIMD::UInt(As<SIMD::UInt>(texel[0]) & SIMD::UInt(0xff))) |
(SIMD::UInt(As<SIMD::UInt>(texel[1]) & SIMD::UInt(0xff)) << 8) |
(SIMD::UInt(As<SIMD::UInt>(texel[2]) & SIMD::UInt(0xff)) << 16) |
(SIMD::UInt(As<SIMD::UInt>(texel[3]) & SIMD::UInt(0xff)) << 24);
break;
case VK_FORMAT_R16G16B16A16_SFLOAT:
packed[0] = floatToHalfBits(As<SIMD::UInt>(texel[0]), false) | floatToHalfBits(As<SIMD::UInt>(texel[1]), true);
packed[1] = floatToHalfBits(As<SIMD::UInt>(texel[2]), false) | floatToHalfBits(As<SIMD::UInt>(texel[3]), true);
break;
case VK_FORMAT_R16G16B16A16_SINT:
case VK_FORMAT_R16G16B16A16_UINT:
packed[0] = SIMD::UInt(As<SIMD::UInt>(texel[0]) & SIMD::UInt(0xFFFF)) | (SIMD::UInt(As<SIMD::UInt>(texel[1]) & SIMD::UInt(0xFFFF)) << 16);
packed[1] = SIMD::UInt(As<SIMD::UInt>(texel[2]) & SIMD::UInt(0xFFFF)) | (SIMD::UInt(As<SIMD::UInt>(texel[3]) & SIMD::UInt(0xFFFF)) << 16);
break;
case VK_FORMAT_R32G32_SFLOAT:
case VK_FORMAT_R32G32_SINT:
case VK_FORMAT_R32G32_UINT:
packed[0] = texel[0];
packed[1] = texel[1];
break;
case VK_FORMAT_R16G16_SFLOAT:
packed[0] = floatToHalfBits(As<SIMD::UInt>(texel[0]), false) | floatToHalfBits(As<SIMD::UInt>(texel[1]), true);
break;
case VK_FORMAT_R16G16_SINT:
case VK_FORMAT_R16G16_UINT:
packed[0] = SIMD::UInt(As<SIMD::UInt>(texel[0]) & SIMD::UInt(0xFFFF)) | (SIMD::UInt(As<SIMD::UInt>(texel[1]) & SIMD::UInt(0xFFFF)) << 16);
break;
case VK_FORMAT_B10G11R11_UFLOAT_PACK32:
// Truncates instead of rounding. See b/147900455
packed[0] = ((floatToHalfBits(As<SIMD::UInt>(Max(As<SIMD::Float>(texel[0]), SIMD::Float(0.0f))), false) & SIMD::UInt(0x7FF0)) >> 4) |
((floatToHalfBits(As<SIMD::UInt>(Max(As<SIMD::Float>(texel[1]), SIMD::Float(0.0f))), false) & SIMD::UInt(0x7FF0)) << 7) |
((floatToHalfBits(As<SIMD::UInt>(Max(As<SIMD::Float>(texel[2]), SIMD::Float(0.0f))), false) & SIMD::UInt(0x7FE0)) << 17);
break;
case VK_FORMAT_R16_SFLOAT:
packed[0] = floatToHalfBits(As<SIMD::UInt>(texel[0]), false);
break;
case VK_FORMAT_R16G16B16A16_UNORM:
packed[0] = SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0xFFFF))) |
(SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[1]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0xFFFF))) << 16);
packed[1] = SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[2]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0xFFFF))) |
(SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[3]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0xFFFF))) << 16);
break;
case VK_FORMAT_A2B10G10R10_UNORM_PACK32:
packed[0] = (SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x3FF)))) |
((SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[1]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x3FF)))) << 10) |
((SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[2]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x3FF)))) << 20) |
((SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[3]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x3)))) << 30);
break;
case VK_FORMAT_R16G16_UNORM:
packed[0] = SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0xFFFF))) |
(SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[1]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0xFFFF))) << 16);
break;
case VK_FORMAT_R8G8_UNORM:
packed[0] = SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0xFF))) |
(SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[1]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0xFF))) << 8);
break;
case VK_FORMAT_R16_UNORM:
packed[0] = SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0xFFFF)));
break;
case VK_FORMAT_R8_UNORM:
packed[0] = SIMD::UInt(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(0.0f)), SIMD::Float(1.0f)) * SIMD::Float(0xFF)));
break;
case VK_FORMAT_R16G16B16A16_SNORM:
packed[0] = (SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x7FFF))) & SIMD::Int(0xFFFF)) |
(SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[1]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x7FFF))) << 16);
packed[1] = (SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[2]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x7FFF))) & SIMD::Int(0xFFFF)) |
(SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[3]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x7FFF))) << 16);
break;
case VK_FORMAT_R16G16_SNORM:
packed[0] = (SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x7FFF))) & SIMD::Int(0xFFFF)) |
(SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[1]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x7FFF))) << 16);
break;
case VK_FORMAT_R8G8_SNORM:
packed[0] = (SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x7F))) & SIMD::Int(0xFF)) |
(SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[1]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x7F))) << 8);
break;
case VK_FORMAT_R16_SNORM:
packed[0] = SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x7FFF)));
break;
case VK_FORMAT_R8_SNORM:
packed[0] = SIMD::Int(Round(Min(Max(As<SIMD::Float>(texel[0]), SIMD::Float(-1.0f)), SIMD::Float(1.0f)) * SIMD::Float(0x7F)));
break;
case VK_FORMAT_R8G8_SINT:
case VK_FORMAT_R8G8_UINT:
packed[0] = SIMD::UInt(As<SIMD::UInt>(texel[0]) & SIMD::UInt(0xFF)) | (SIMD::UInt(As<SIMD::UInt>(texel[1]) & SIMD::UInt(0xFF)) << 8);
break;
case VK_FORMAT_R16_SINT:
case VK_FORMAT_R16_UINT:
packed[0] = SIMD::UInt(As<SIMD::UInt>(texel[0]) & SIMD::UInt(0xFFFF));
break;
case VK_FORMAT_R8_SINT:
case VK_FORMAT_R8_UINT:
packed[0] = SIMD::UInt(As<SIMD::UInt>(texel[0]) & SIMD::UInt(0xFF));
break;
case VK_FORMAT_A2B10G10R10_UINT_PACK32:
packed[0] = (SIMD::UInt(As<SIMD::UInt>(texel[0]) & SIMD::UInt(0x3FF))) |
(SIMD::UInt(As<SIMD::UInt>(texel[1]) & SIMD::UInt(0x3FF)) << 10) |
(SIMD::UInt(As<SIMD::UInt>(texel[2]) & SIMD::UInt(0x3FF)) << 20) |
(SIMD::UInt(As<SIMD::UInt>(texel[3]) & SIMD::UInt(0x3)) << 30);
break;
default:
UNSUPPORTED("VkFormat %d", int(imageFormat));
break;
}
// "The integer texel coordinates are validated according to the same rules as for texel input coordinate
// validation. If the texel fails integer texel coordinate validation, then the write has no effect."
// - https://www.khronos.org/registry/vulkan/specs/1.2/html/chap16.html#textures-output-coordinate-validation
auto robustness = OutOfBoundsBehavior::Nullify;
// GetTexelAddress() only needs the SpirvRoutine* for SubpassData accesses (i.e. input attachments).
const SpirvRoutine *routine = nullptr;
SIMD::Int uvwa[4];
SIMD::Int sample;
uint32_t i = 0;
for(; i < instruction.coordinates; i++)
{
uvwa[i] = As<SIMD::Int>(coord[i]);
}
if(instruction.sample)
{
sample = As<SIMD::Int>(coord[i]);
}
auto texelPtr = GetTexelAddress(instruction, descriptor, uvwa, sample, imageFormat, robustness, routine);
const int texelSize = imageFormat.bytes();
// Scatter packed texel data.
// TODO(b/160531165): Provide scatter abstractions for various element sizes.
if(texelSize == 4 || texelSize == 8 || texelSize == 16)
{
for(auto i = 0; i < texelSize / 4; i++)
{
texelPtr.Store(packed[i], robustness, mask);
texelPtr += sizeof(float);
}
}
else if(texelSize == 2)
{
mask = mask & texelPtr.isInBounds(2, robustness);
for(int i = 0; i < SIMD::Width; i++)
{
If(Extract(mask, i) != 0)
{
*Pointer<Short>(texelPtr.getPointerForLane(i)) = Short(Extract(packed[0], i));
}
}
}
else if(texelSize == 1)
{
mask = mask & texelPtr.isInBounds(1, robustness);
for(int i = 0; i < SIMD::Width; i++)
{
If(Extract(mask, i) != 0)
{
*Pointer<Byte>(texelPtr.getPointerForLane(i)) = Byte(Extract(packed[0], i));
}
}
}
else
UNREACHABLE("texelSize: %d", int(texelSize));
}
void SpirvEmitter::EmitImageTexelPointer(const ImageInstruction &instruction)
{
auto coordinate = Operand(shader, *this, instruction.coordinateId);
SIMD::Pointer ptr = getPointer(instruction.imageId);
// VK_EXT_image_robustness requires checking for out-of-bounds accesses.
// TODO(b/162327166): Only perform bounds checks when VK_EXT_image_robustness is enabled.
auto robustness = OutOfBoundsBehavior::Nullify;
vk::Format imageFormat = SpirvFormatToVulkanFormat(static_cast<spv::ImageFormat>(instruction.imageFormat));
SIMD::Int uvwa[4];
for(uint32_t i = 0; i < instruction.coordinates; i++)
{
uvwa[i] = coordinate.Int(i);
}
SIMD::Int sample = Operand(shader, *this, instruction.sampleId).Int(0);
auto texelPtr = ptr.isBasePlusOffset
? GetTexelAddress(instruction, ptr.getUniformPointer(), uvwa, sample, imageFormat, robustness, routine)
: GetNonUniformTexelAddress(instruction, ptr, uvwa, sample, imageFormat, robustness, activeLaneMask(), routine);
createPointer(instruction.resultId, texelPtr);
}
void SpirvEmitter::EmitSampledImage(InsnIterator insn)
{
Object::ID resultId = insn.word(2);
Object::ID imageId = insn.word(3);
Object::ID samplerId = insn.word(4);
// Create a sampled image, containing both a sampler and an image
createSampledImage(resultId, { getPointer(imageId), samplerId });
}
void SpirvEmitter::EmitImage(InsnIterator insn)
{
Object::ID resultId = insn.word(2);
Object::ID imageId = insn.word(3);
// Extract the image from a sampled image.
createPointer(resultId, getImage(imageId));
}
} // namespace sw