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dawn / dawn / 42e76ba82a23adc059f33de300e4872ffc95e6d4 / . / src / dawn / native / Texture.cpp
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// Copyright 2017 The Dawn Authors
//
// 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 "dawn/native/Texture.h"
#include <algorithm>
#include "dawn/common/Assert.h"
#include "dawn/common/Constants.h"
#include "dawn/common/Math.h"
#include "dawn/native/Adapter.h"
#include "dawn/native/ChainUtils_autogen.h"
#include "dawn/native/Device.h"
#include "dawn/native/EnumMaskIterator.h"
#include "dawn/native/ObjectType_autogen.h"
#include "dawn/native/PassResourceUsage.h"
#include "dawn/native/ValidationUtils_autogen.h"
namespace dawn::native {
namespace {
MaybeError ValidateTextureViewFormatCompatibility(const DeviceBase* device,
const Format& format,
wgpu::TextureFormat viewFormatEnum) {
const Format* viewFormat;
DAWN_TRY_ASSIGN(viewFormat, device->GetInternalFormat(viewFormatEnum));
DAWN_INVALID_IF(!format.ViewCompatibleWith(*viewFormat),
"The texture view format (%s) is not texture view format compatible "
"with the texture format (%s).",
viewFormatEnum, format.format);
return {};
}
MaybeError ValidateCanViewTextureAs(const DeviceBase* device,
const TextureBase* texture,
const Format& viewFormat,
wgpu::TextureAspect aspect) {
const Format& format = texture->GetFormat();
if (aspect != wgpu::TextureAspect::All) {
wgpu::TextureFormat aspectFormat = format.GetAspectInfo(aspect).format;
if (viewFormat.format == aspectFormat) {
return {};
} else {
return DAWN_FORMAT_VALIDATION_ERROR(
"The view format (%s) is not compatible with %s of %s (%s).",
viewFormat.format, aspect, format.format, aspectFormat);
}
}
if (format.format == viewFormat.format) {
return {};
}
const FormatSet& compatibleViewFormats = texture->GetViewFormats();
if (compatibleViewFormats[viewFormat]) {
// Validation of this list is done on texture creation, so we don't need to
// handle the case where a format is in the list, but not compatible.
return {};
}
// |viewFormat| is not in the list. Check compatibility to generate an error message
// depending on whether it could be compatible, but needs to be explicitly listed,
// or it could never be compatible.
if (!format.ViewCompatibleWith(viewFormat)) {
// The view format isn't compatible with the format at all. Return an error
// that indicates this, in addition to reporting that it's missing from the
// list.
return DAWN_FORMAT_VALIDATION_ERROR(
"The texture view format (%s) is not compatible with the "
"texture format (%s)."
"The formats must be compatible, and the view format "
"must be passed in the list of view formats on texture creation.",
viewFormat.format, format.format);
} else {
// The view format is compatible, but not in the list.
return DAWN_FORMAT_VALIDATION_ERROR(
"%s was not created with the texture view format (%s) "
"in the list of compatible view formats.",
texture, viewFormat.format);
}
return {};
}
bool IsTextureViewDimensionCompatibleWithTextureDimension(
wgpu::TextureViewDimension textureViewDimension,
wgpu::TextureDimension textureDimension) {
switch (textureViewDimension) {
case wgpu::TextureViewDimension::e2D:
case wgpu::TextureViewDimension::e2DArray:
case wgpu::TextureViewDimension::Cube:
case wgpu::TextureViewDimension::CubeArray:
return textureDimension == wgpu::TextureDimension::e2D;
case wgpu::TextureViewDimension::e3D:
return textureDimension == wgpu::TextureDimension::e3D;
case wgpu::TextureViewDimension::e1D:
return textureDimension == wgpu::TextureDimension::e1D;
case wgpu::TextureViewDimension::Undefined:
UNREACHABLE();
}
}
bool IsArrayLayerValidForTextureViewDimension(
wgpu::TextureViewDimension textureViewDimension,
uint32_t textureViewArrayLayer) {
switch (textureViewDimension) {
case wgpu::TextureViewDimension::e2D:
case wgpu::TextureViewDimension::e3D:
return textureViewArrayLayer == 1u;
case wgpu::TextureViewDimension::e2DArray:
return true;
case wgpu::TextureViewDimension::Cube:
return textureViewArrayLayer == 6u;
case wgpu::TextureViewDimension::CubeArray:
return textureViewArrayLayer % 6 == 0;
case wgpu::TextureViewDimension::e1D:
return textureViewArrayLayer == 1u;
case wgpu::TextureViewDimension::Undefined:
UNREACHABLE();
}
}
MaybeError ValidateSampleCount(const TextureDescriptor* descriptor,
wgpu::TextureUsage usage,
const Format* format) {
DAWN_INVALID_IF(!IsValidSampleCount(descriptor->sampleCount),
"The sample count (%u) of the texture is not supported.",
descriptor->sampleCount);
if (descriptor->sampleCount > 1) {
DAWN_INVALID_IF(descriptor->mipLevelCount > 1,
"The mip level count (%u) of a multisampled texture is not 1.",
descriptor->mipLevelCount);
// Multisampled 1D and 3D textures are not supported in D3D12/Metal/Vulkan.
// Multisampled 2D array texture is not supported because on Metal it requires the
// version of macOS be greater than 10.14.
DAWN_INVALID_IF(descriptor->dimension != wgpu::TextureDimension::e2D,
"The dimension (%s) of a multisampled texture is not 2D.",
descriptor->dimension);
DAWN_INVALID_IF(descriptor->size.depthOrArrayLayers > 1,
"The depthOrArrayLayers (%u) of a multisampled texture is not 1.",
descriptor->size.depthOrArrayLayers);
DAWN_INVALID_IF(!format->supportsMultisample,
"The texture format (%s) does not support multisampling.",
format->format);
// Compressed formats are not renderable. They cannot support multisample.
ASSERT(!format->isCompressed);
DAWN_INVALID_IF(usage & wgpu::TextureUsage::StorageBinding,
"The sample count (%u) of a storage textures is not 1.",
descriptor->sampleCount);
}
return {};
}
MaybeError ValidateTextureViewDimensionCompatibility(
const TextureBase* texture,
const TextureViewDescriptor* descriptor) {
DAWN_INVALID_IF(
!IsArrayLayerValidForTextureViewDimension(descriptor->dimension,
descriptor->arrayLayerCount),
"The dimension (%s) of the texture view is not compatible with the layer count "
"(%u) of %s.",
descriptor->dimension, descriptor->arrayLayerCount, texture);
DAWN_INVALID_IF(
!IsTextureViewDimensionCompatibleWithTextureDimension(descriptor->dimension,
texture->GetDimension()),
"The dimension (%s) of the texture view is not compatible with the dimension (%s) "
"of %s.",
descriptor->dimension, texture->GetDimension(), texture);
DAWN_INVALID_IF(texture->GetSampleCount() > 1 &&
descriptor->dimension != wgpu::TextureViewDimension::e2D,
"The dimension (%s) of the multisampled texture view is not %s.",
descriptor->dimension, wgpu::TextureViewDimension::e2D);
switch (descriptor->dimension) {
case wgpu::TextureViewDimension::Cube:
case wgpu::TextureViewDimension::CubeArray:
DAWN_INVALID_IF(
texture->GetSize().width != texture->GetSize().height,
"A %s texture view is not compatible with %s because the texture's width "
"(%u) and height (%u) are not equal.",
descriptor->dimension, texture, texture->GetSize().width,
texture->GetSize().height);
break;
case wgpu::TextureViewDimension::e1D:
case wgpu::TextureViewDimension::e2D:
case wgpu::TextureViewDimension::e2DArray:
case wgpu::TextureViewDimension::e3D:
break;
case wgpu::TextureViewDimension::Undefined:
UNREACHABLE();
}
return {};
}
MaybeError ValidateTextureSize(const DeviceBase* device,
const TextureDescriptor* descriptor,
const Format* format) {
ASSERT(descriptor->size.width != 0 && descriptor->size.height != 0 &&
descriptor->size.depthOrArrayLayers != 0);
const CombinedLimits& limits = device->GetLimits();
Extent3D maxExtent;
switch (descriptor->dimension) {
case wgpu::TextureDimension::e1D:
maxExtent = {limits.v1.maxTextureDimension1D, 1, 1};
break;
case wgpu::TextureDimension::e2D:
maxExtent = {limits.v1.maxTextureDimension2D, limits.v1.maxTextureDimension2D,
limits.v1.maxTextureArrayLayers};
break;
case wgpu::TextureDimension::e3D:
maxExtent = {limits.v1.maxTextureDimension3D, limits.v1.maxTextureDimension3D,
limits.v1.maxTextureDimension3D};
break;
}
DAWN_INVALID_IF(descriptor->size.width > maxExtent.width ||
descriptor->size.height > maxExtent.height ||
descriptor->size.depthOrArrayLayers > maxExtent.depthOrArrayLayers,
"Texture size (%s) exceeded maximum texture size (%s).",
&descriptor->size, &maxExtent);
switch (descriptor->dimension) {
case wgpu::TextureDimension::e1D:
DAWN_INVALID_IF(
descriptor->mipLevelCount != 1,
"Texture mip level count (%u) is more than 1 when its dimension is %s.",
descriptor->mipLevelCount, wgpu::TextureDimension::e1D);
break;
case wgpu::TextureDimension::e2D: {
uint32_t maxMippedDimension =
std::max(descriptor->size.width, descriptor->size.height);
DAWN_INVALID_IF(
Log2(maxMippedDimension) + 1 < descriptor->mipLevelCount,
"Texture mip level count (%u) exceeds the maximum (%u) for its size (%s).",
descriptor->mipLevelCount, Log2(maxMippedDimension) + 1, &descriptor->size);
break;
}
case wgpu::TextureDimension::e3D: {
uint32_t maxMippedDimension = std::max(
descriptor->size.width,
std::max(descriptor->size.height, descriptor->size.depthOrArrayLayers));
DAWN_INVALID_IF(
Log2(maxMippedDimension) + 1 < descriptor->mipLevelCount,
"Texture mip level count (%u) exceeds the maximum (%u) for its size (%s).",
descriptor->mipLevelCount, Log2(maxMippedDimension) + 1, &descriptor->size);
break;
}
}
if (format->isCompressed) {
const TexelBlockInfo& blockInfo =
format->GetAspectInfo(wgpu::TextureAspect::All).block;
DAWN_INVALID_IF(
descriptor->size.width % blockInfo.width != 0 ||
descriptor->size.height % blockInfo.height != 0,
"The size (%s) of the texture is not a multiple of the block width (%u) and "
"height (%u) of the texture format (%s).",
&descriptor->size, blockInfo.width, blockInfo.height, format->format);
}
return {};
}
MaybeError ValidateTextureUsage(const TextureDescriptor* descriptor,
wgpu::TextureUsage usage,
const Format* format) {
DAWN_TRY(dawn::native::ValidateTextureUsage(usage));
DAWN_INVALID_IF(usage == wgpu::TextureUsage::None, "The texture usage must not be 0.");
constexpr wgpu::TextureUsage kValidCompressedUsages =
wgpu::TextureUsage::TextureBinding | wgpu::TextureUsage::CopySrc |
wgpu::TextureUsage::CopyDst;
DAWN_INVALID_IF(
format->isCompressed && !IsSubset(usage, kValidCompressedUsages),
"The texture usage (%s) is incompatible with the compressed texture format (%s).",
usage, format->format);
DAWN_INVALID_IF(
!format->isRenderable && (usage & wgpu::TextureUsage::RenderAttachment),
"The texture usage (%s) includes %s, which is incompatible with the non-renderable "
"format (%s).",
usage, wgpu::TextureUsage::RenderAttachment, format->format);
DAWN_INVALID_IF(
!format->supportsStorageUsage && (usage & wgpu::TextureUsage::StorageBinding),
"The texture usage (%s) includes %s, which is incompatible with the format (%s).",
usage, wgpu::TextureUsage::StorageBinding, format->format);
// Only allows simple readonly texture usages.
constexpr wgpu::TextureUsage kValidMultiPlanarUsages =
wgpu::TextureUsage::TextureBinding | wgpu::TextureUsage::CopySrc;
DAWN_INVALID_IF(
format->IsMultiPlanar() && !IsSubset(usage, kValidMultiPlanarUsages),
"The texture usage (%s) is incompatible with the multi-planar format (%s).", usage,
format->format);
return {};
}
} // anonymous namespace
MaybeError ValidateTextureDescriptor(const DeviceBase* device,
const TextureDescriptor* descriptor) {
DAWN_TRY(ValidateSingleSType(descriptor->nextInChain,
wgpu::SType::DawnTextureInternalUsageDescriptor));
const DawnTextureInternalUsageDescriptor* internalUsageDesc = nullptr;
FindInChain(descriptor->nextInChain, &internalUsageDesc);
DAWN_INVALID_IF(
internalUsageDesc != nullptr && !device->IsFeatureEnabled(Feature::DawnInternalUsages),
"The dawn-internal-usages feature is not enabled");
const Format* format;
DAWN_TRY_ASSIGN(format, device->GetInternalFormat(descriptor->format));
for (uint32_t i = 0; i < descriptor->viewFormatCount; ++i) {
DAWN_TRY_CONTEXT(
ValidateTextureViewFormatCompatibility(device, *format, descriptor->viewFormats[i]),
"validating viewFormats[%u]", i);
}
wgpu::TextureUsage usage = descriptor->usage;
if (internalUsageDesc != nullptr) {
usage |= internalUsageDesc->internalUsage;
}
DAWN_TRY(ValidateTextureUsage(descriptor, usage, format));
DAWN_TRY(ValidateTextureDimension(descriptor->dimension));
DAWN_TRY(ValidateSampleCount(descriptor, usage, format));
DAWN_INVALID_IF(descriptor->size.width == 0 || descriptor->size.height == 0 ||
descriptor->size.depthOrArrayLayers == 0 ||
descriptor->mipLevelCount == 0,
"The texture size (%s) or mipLevelCount (%u) is empty.", &descriptor->size,
descriptor->mipLevelCount);
DAWN_INVALID_IF(
descriptor->dimension != wgpu::TextureDimension::e2D && format->isCompressed,
"The dimension (%s) of a texture with a compressed format (%s) is not 2D.",
descriptor->dimension, format->format);
// Depth/stencil formats are valid for 2D textures only. Metal has this limit. And D3D12
// doesn't support depth/stencil formats on 3D textures.
DAWN_INVALID_IF(
descriptor->dimension != wgpu::TextureDimension::e2D &&
(format->aspects & (Aspect::Depth | Aspect::Stencil)) != 0,
"The dimension (%s) of a texture with a depth/stencil format (%s) is not 2D.",
descriptor->dimension, format->format);
DAWN_TRY(ValidateTextureSize(device, descriptor, format));
// TODO(crbug.com/dawn/838): Implement a workaround for this issue.
// Readbacks from the non-zero mip of a stencil texture may contain garbage data.
DAWN_INVALID_IF(
device->IsToggleEnabled(Toggle::DisallowUnsafeAPIs) && format->HasStencil() &&
descriptor->mipLevelCount > 1 &&
device->GetAdapter()->GetBackendType() == wgpu::BackendType::Metal,
"https://crbug.com/dawn/838: Stencil textures with more than one mip level are "
"disabled on Metal.");
DAWN_INVALID_IF(
device->IsToggleEnabled(Toggle::DisableR8RG8Mipmaps) && descriptor->mipLevelCount > 1 &&
(descriptor->format == wgpu::TextureFormat::R8Unorm ||
descriptor->format == wgpu::TextureFormat::RG8Unorm),
"https://crbug.com/dawn/1071: r8unorm and rg8unorm textures with more than one mip "
"level are disabled on Metal.");
return {};
}
MaybeError ValidateTextureViewDescriptor(const DeviceBase* device,
const TextureBase* texture,
const TextureViewDescriptor* descriptor) {
DAWN_INVALID_IF(descriptor->nextInChain != nullptr, "nextInChain must be nullptr.");
// Parent texture should have been already validated.
ASSERT(texture);
ASSERT(!texture->IsError());
DAWN_TRY(ValidateTextureViewDimension(descriptor->dimension));
DAWN_TRY(ValidateTextureFormat(descriptor->format));
DAWN_TRY(ValidateTextureAspect(descriptor->aspect));
const Format& format = texture->GetFormat();
const Format& viewFormat = device->GetValidInternalFormat(descriptor->format);
DAWN_INVALID_IF(
SelectFormatAspects(format, descriptor->aspect) == Aspect::None,
"Texture format (%s) does not have the texture view's selected aspect (%s).",
format.format, descriptor->aspect);
DAWN_INVALID_IF(descriptor->arrayLayerCount == 0 || descriptor->mipLevelCount == 0,
"The texture view's arrayLayerCount (%u) or mipLevelCount (%u) is zero.",
descriptor->arrayLayerCount, descriptor->mipLevelCount);
DAWN_INVALID_IF(
uint64_t(descriptor->baseArrayLayer) + uint64_t(descriptor->arrayLayerCount) >
uint64_t(texture->GetArrayLayers()),
"Texture view array layer range (baseArrayLayer: %u, arrayLayerCount: %u) exceeds the "
"texture's array layer count (%u).",
descriptor->baseArrayLayer, descriptor->arrayLayerCount, texture->GetArrayLayers());
DAWN_INVALID_IF(
uint64_t(descriptor->baseMipLevel) + uint64_t(descriptor->mipLevelCount) >
uint64_t(texture->GetNumMipLevels()),
"Texture view mip level range (baseMipLevel: %u, mipLevelCount: %u) exceeds the "
"texture's mip level count (%u).",
descriptor->baseMipLevel, descriptor->mipLevelCount, texture->GetNumMipLevels());
DAWN_TRY(ValidateCanViewTextureAs(device, texture, viewFormat, descriptor->aspect));
DAWN_TRY(ValidateTextureViewDimensionCompatibility(texture, descriptor));
return {};
}
TextureViewDescriptor GetTextureViewDescriptorWithDefaults(
const TextureBase* texture,
const TextureViewDescriptor* descriptor) {
ASSERT(texture);
TextureViewDescriptor desc = {};
if (descriptor) {
desc = *descriptor;
}
// The default value for the view dimension depends on the texture's dimension with a
// special case for 2DArray being chosen automatically if arrayLayerCount is unspecified.
if (desc.dimension == wgpu::TextureViewDimension::Undefined) {
switch (texture->GetDimension()) {
case wgpu::TextureDimension::e1D:
desc.dimension = wgpu::TextureViewDimension::e1D;
break;
case wgpu::TextureDimension::e2D:
desc.dimension = wgpu::TextureViewDimension::e2D;
break;
case wgpu::TextureDimension::e3D:
desc.dimension = wgpu::TextureViewDimension::e3D;
break;
}
}
if (desc.format == wgpu::TextureFormat::Undefined) {
const Format& format = texture->GetFormat();
Aspect aspects = SelectFormatAspects(format, desc.aspect);
if (HasOneBit(aspects)) {
desc.format = format.GetAspectInfo(aspects).format;
} else {
desc.format = format.format;
}
}
if (desc.arrayLayerCount == wgpu::kArrayLayerCountUndefined) {
switch (desc.dimension) {
case wgpu::TextureViewDimension::e1D:
case wgpu::TextureViewDimension::e2D:
case wgpu::TextureViewDimension::e3D:
desc.arrayLayerCount = 1;
break;
case wgpu::TextureViewDimension::Cube:
desc.arrayLayerCount = 6;
break;
case wgpu::TextureViewDimension::e2DArray:
case wgpu::TextureViewDimension::CubeArray:
desc.arrayLayerCount = texture->GetArrayLayers() - desc.baseArrayLayer;
break;
default:
// We don't put UNREACHABLE() here because we validate enums only after this
// function sets default values. Otherwise, the UNREACHABLE() will be hit.
break;
}
}
if (desc.mipLevelCount == wgpu::kMipLevelCountUndefined) {
desc.mipLevelCount = texture->GetNumMipLevels() - desc.baseMipLevel;
}
return desc;
}
// WebGPU only supports sample counts of 1 and 4. We could expand to more based on
// platform support, but it would probably be a feature.
bool IsValidSampleCount(uint32_t sampleCount) {
switch (sampleCount) {
case 1:
case 4:
return true;
default:
return false;
}
}
// TextureBase
TextureBase::TextureBase(DeviceBase* device,
const TextureDescriptor* descriptor,
TextureState state)
: ApiObjectBase(device, descriptor->label),
mDimension(descriptor->dimension),
mFormat(device->GetValidInternalFormat(descriptor->format)),
mSize(descriptor->size),
mMipLevelCount(descriptor->mipLevelCount),
mSampleCount(descriptor->sampleCount),
mUsage(descriptor->usage),
mInternalUsage(mUsage),
mState(state) {
uint32_t subresourceCount =
mMipLevelCount * GetArrayLayers() * GetAspectCount(mFormat.aspects);
mIsSubresourceContentInitializedAtIndex = std::vector<bool>(subresourceCount, false);
for (uint32_t i = 0; i < descriptor->viewFormatCount; ++i) {
if (descriptor->viewFormats[i] == descriptor->format) {
// Skip our own format, so the backends don't allocate the texture for
// reinterpretation if it's not needed.
continue;
}
mViewFormats[device->GetValidInternalFormat(descriptor->viewFormats[i])] = true;
}
const DawnTextureInternalUsageDescriptor* internalUsageDesc = nullptr;
FindInChain(descriptor->nextInChain, &internalUsageDesc);
if (internalUsageDesc != nullptr) {
mInternalUsage |= internalUsageDesc->internalUsage;
}
TrackInDevice();
}
static Format kUnusedFormat;
TextureBase::TextureBase(DeviceBase* device, TextureState state)
: ApiObjectBase(device, kLabelNotImplemented), mFormat(kUnusedFormat), mState(state) {
TrackInDevice();
}
TextureBase::TextureBase(DeviceBase* device, ObjectBase::ErrorTag tag)
: ApiObjectBase(device, tag), mFormat(kUnusedFormat) {
}
void TextureBase::DestroyImpl() {
mState = TextureState::Destroyed;
}
// static
TextureBase* TextureBase::MakeError(DeviceBase* device) {
return new TextureBase(device, ObjectBase::kError);
}
ObjectType TextureBase::GetType() const {
return ObjectType::Texture;
}
wgpu::TextureDimension TextureBase::GetDimension() const {
ASSERT(!IsError());
return mDimension;
}
const Format& TextureBase::GetFormat() const {
ASSERT(!IsError());
return mFormat;
}
const FormatSet& TextureBase::GetViewFormats() const {
ASSERT(!IsError());
return mViewFormats;
}
const Extent3D& TextureBase::GetSize() const {
ASSERT(!IsError());
return mSize;
}
uint32_t TextureBase::GetWidth() const {
ASSERT(!IsError());
return mSize.width;
}
uint32_t TextureBase::GetHeight() const {
ASSERT(!IsError());
return mSize.height;
}
uint32_t TextureBase::GetDepth() const {
ASSERT(!IsError());
ASSERT(mDimension == wgpu::TextureDimension::e3D);
return mSize.depthOrArrayLayers;
}
uint32_t TextureBase::GetArrayLayers() const {
ASSERT(!IsError());
if (mDimension == wgpu::TextureDimension::e3D) {
return 1;
}
return mSize.depthOrArrayLayers;
}
uint32_t TextureBase::GetNumMipLevels() const {
ASSERT(!IsError());
return mMipLevelCount;
}
SubresourceRange TextureBase::GetAllSubresources() const {
ASSERT(!IsError());
return {mFormat.aspects, {0, GetArrayLayers()}, {0, mMipLevelCount}};
}
uint32_t TextureBase::GetSampleCount() const {
ASSERT(!IsError());
return mSampleCount;
}
uint32_t TextureBase::GetSubresourceCount() const {
ASSERT(!IsError());
return static_cast<uint32_t>(mIsSubresourceContentInitializedAtIndex.size());
}
wgpu::TextureUsage TextureBase::GetUsage() const {
ASSERT(!IsError());
return mUsage;
}
wgpu::TextureUsage TextureBase::GetInternalUsage() const {
ASSERT(!IsError());
return mInternalUsage;
}
TextureBase::TextureState TextureBase::GetTextureState() const {
ASSERT(!IsError());
return mState;
}
uint32_t TextureBase::GetSubresourceIndex(uint32_t mipLevel,
uint32_t arraySlice,
Aspect aspect) const {
ASSERT(HasOneBit(aspect));
return mipLevel +
GetNumMipLevels() * (arraySlice + GetArrayLayers() * GetAspectIndex(aspect));
}
bool TextureBase::IsSubresourceContentInitialized(const SubresourceRange& range) const {
ASSERT(!IsError());
for (Aspect aspect : IterateEnumMask(range.aspects)) {
for (uint32_t arrayLayer = range.baseArrayLayer;
arrayLayer < range.baseArrayLayer + range.layerCount; ++arrayLayer) {
for (uint32_t mipLevel = range.baseMipLevel;
mipLevel < range.baseMipLevel + range.levelCount; ++mipLevel) {
uint32_t subresourceIndex = GetSubresourceIndex(mipLevel, arrayLayer, aspect);
ASSERT(subresourceIndex < mIsSubresourceContentInitializedAtIndex.size());
if (!mIsSubresourceContentInitializedAtIndex[subresourceIndex]) {
return false;
}
}
}
}
return true;
}
void TextureBase::SetIsSubresourceContentInitialized(bool isInitialized,
const SubresourceRange& range) {
ASSERT(!IsError());
for (Aspect aspect : IterateEnumMask(range.aspects)) {
for (uint32_t arrayLayer = range.baseArrayLayer;
arrayLayer < range.baseArrayLayer + range.layerCount; ++arrayLayer) {
for (uint32_t mipLevel = range.baseMipLevel;
mipLevel < range.baseMipLevel + range.levelCount; ++mipLevel) {
uint32_t subresourceIndex = GetSubresourceIndex(mipLevel, arrayLayer, aspect);
ASSERT(subresourceIndex < mIsSubresourceContentInitializedAtIndex.size());
mIsSubresourceContentInitializedAtIndex[subresourceIndex] = isInitialized;
}
}
}
}
MaybeError TextureBase::ValidateCanUseInSubmitNow() const {
ASSERT(!IsError());
DAWN_INVALID_IF(mState == TextureState::Destroyed, "Destroyed texture %s used in a submit.",
this);
return {};
}
bool TextureBase::IsMultisampledTexture() const {
ASSERT(!IsError());
return mSampleCount > 1;
}
Extent3D TextureBase::GetMipLevelVirtualSize(uint32_t level) const {
Extent3D extent = {std::max(mSize.width >> level, 1u), 1u, 1u};
if (mDimension == wgpu::TextureDimension::e1D) {
return extent;
}
extent.height = std::max(mSize.height >> level, 1u);
if (mDimension == wgpu::TextureDimension::e2D) {
return extent;
}
extent.depthOrArrayLayers = std::max(mSize.depthOrArrayLayers >> level, 1u);
return extent;
}
Extent3D TextureBase::GetMipLevelPhysicalSize(uint32_t level) const {
Extent3D extent = GetMipLevelVirtualSize(level);
// Compressed Textures will have paddings if their width or height is not a multiple of
// 4 at non-zero mipmap levels.
if (mFormat.isCompressed && level != 0) {
// If |level| is non-zero, then each dimension of |extent| is at most half of
// the max texture dimension. Computations here which add the block width/height
// to the extent cannot overflow.
const TexelBlockInfo& blockInfo = mFormat.GetAspectInfo(wgpu::TextureAspect::All).block;
extent.width = (extent.width + blockInfo.width - 1) / blockInfo.width * blockInfo.width;
extent.height =
(extent.height + blockInfo.height - 1) / blockInfo.height * blockInfo.height;
}
return extent;
}
Extent3D TextureBase::ClampToMipLevelVirtualSize(uint32_t level,
const Origin3D& origin,
const Extent3D& extent) const {
const Extent3D virtualSizeAtLevel = GetMipLevelVirtualSize(level);
ASSERT(origin.x <= virtualSizeAtLevel.width);
ASSERT(origin.y <= virtualSizeAtLevel.height);
uint32_t clampedCopyExtentWidth = (extent.width > virtualSizeAtLevel.width - origin.x)
? (virtualSizeAtLevel.width - origin.x)
: extent.width;
uint32_t clampedCopyExtentHeight = (extent.height > virtualSizeAtLevel.height - origin.y)
? (virtualSizeAtLevel.height - origin.y)
: extent.height;
return {clampedCopyExtentWidth, clampedCopyExtentHeight, extent.depthOrArrayLayers};
}
ResultOrError<Ref<TextureViewBase>> TextureBase::CreateView(
const TextureViewDescriptor* descriptor) {
return GetDevice()->CreateTextureView(this, descriptor);
}
TextureViewBase* TextureBase::APICreateView(const TextureViewDescriptor* descriptor) {
DeviceBase* device = GetDevice();
Ref<TextureViewBase> result;
if (device->ConsumedError(CreateView(descriptor), &result, "calling %s.CreateView(%s).",
this, descriptor)) {
return TextureViewBase::MakeError(device);
}
return result.Detach();
}
void TextureBase::APIDestroy() {
if (GetDevice()->ConsumedError(ValidateDestroy(), "calling %s.Destroy().", this)) {
return;
}
ASSERT(!IsError());
Destroy();
}
MaybeError TextureBase::ValidateDestroy() const {
DAWN_TRY(GetDevice()->ValidateObject(this));
return {};
}
// TextureViewBase
TextureViewBase::TextureViewBase(TextureBase* texture, const TextureViewDescriptor* descriptor)
: ApiObjectBase(texture->GetDevice(), descriptor->label),
mTexture(texture),
mFormat(GetDevice()->GetValidInternalFormat(descriptor->format)),
mDimension(descriptor->dimension),
mRange({ConvertViewAspect(mFormat, descriptor->aspect),
{descriptor->baseArrayLayer, descriptor->arrayLayerCount},
{descriptor->baseMipLevel, descriptor->mipLevelCount}}) {
TrackInDevice();
}
TextureViewBase::TextureViewBase(TextureBase* texture)
: ApiObjectBase(texture->GetDevice(), kLabelNotImplemented),
mTexture(texture),
mFormat(kUnusedFormat) {
TrackInDevice();
}
TextureViewBase::TextureViewBase(DeviceBase* device, ObjectBase::ErrorTag tag)
: ApiObjectBase(device, tag), mFormat(kUnusedFormat) {
}
void TextureViewBase::DestroyImpl() {
}
// static
TextureViewBase* TextureViewBase::MakeError(DeviceBase* device) {
return new TextureViewBase(device, ObjectBase::kError);
}
ObjectType TextureViewBase::GetType() const {
return ObjectType::TextureView;
}
const TextureBase* TextureViewBase::GetTexture() const {
ASSERT(!IsError());
return mTexture.Get();
}
TextureBase* TextureViewBase::GetTexture() {
ASSERT(!IsError());
return mTexture.Get();
}
Aspect TextureViewBase::GetAspects() const {
ASSERT(!IsError());
return mRange.aspects;
}
const Format& TextureViewBase::GetFormat() const {
ASSERT(!IsError());
return mFormat;
}
wgpu::TextureViewDimension TextureViewBase::GetDimension() const {
ASSERT(!IsError());
return mDimension;
}
uint32_t TextureViewBase::GetBaseMipLevel() const {
ASSERT(!IsError());
return mRange.baseMipLevel;
}
uint32_t TextureViewBase::GetLevelCount() const {
ASSERT(!IsError());
return mRange.levelCount;
}
uint32_t TextureViewBase::GetBaseArrayLayer() const {
ASSERT(!IsError());
return mRange.baseArrayLayer;
}
uint32_t TextureViewBase::GetLayerCount() const {
ASSERT(!IsError());
return mRange.layerCount;
}
const SubresourceRange& TextureViewBase::GetSubresourceRange() const {
ASSERT(!IsError());
return mRange;
}
} // namespace dawn::native