// Copyright 2018 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 "VkImage.hpp" #include "VkBuffer.hpp" #include "VkDevice.hpp" #include "VkDeviceMemory.hpp" #include "Device/BC_Decoder.hpp" #include "Device/Blitter.hpp" #include "Device/ETC_Decoder.hpp" #include "Device/ASTC_Decoder.hpp" #ifdef __ANDROID__ # include "System/GrallocAndroid.hpp" #endif #include namespace { ETC_Decoder::InputType GetInputType(const vk::Format &format) { switch(format) { case VK_FORMAT_EAC_R11_UNORM_BLOCK: return ETC_Decoder::ETC_R_UNSIGNED; case VK_FORMAT_EAC_R11_SNORM_BLOCK: return ETC_Decoder::ETC_R_SIGNED; case VK_FORMAT_EAC_R11G11_UNORM_BLOCK: return ETC_Decoder::ETC_RG_UNSIGNED; case VK_FORMAT_EAC_R11G11_SNORM_BLOCK: return ETC_Decoder::ETC_RG_SIGNED; case VK_FORMAT_ETC2_R8G8B8_UNORM_BLOCK: case VK_FORMAT_ETC2_R8G8B8_SRGB_BLOCK: return ETC_Decoder::ETC_RGB; case VK_FORMAT_ETC2_R8G8B8A1_UNORM_BLOCK: case VK_FORMAT_ETC2_R8G8B8A1_SRGB_BLOCK: return ETC_Decoder::ETC_RGB_PUNCHTHROUGH_ALPHA; case VK_FORMAT_ETC2_R8G8B8A8_UNORM_BLOCK: case VK_FORMAT_ETC2_R8G8B8A8_SRGB_BLOCK: return ETC_Decoder::ETC_RGBA; default: UNSUPPORTED("format: %d", int(format)); return ETC_Decoder::ETC_RGBA; } } int GetBCn(const vk::Format &format) { switch(format) { case VK_FORMAT_BC1_RGB_UNORM_BLOCK: case VK_FORMAT_BC1_RGBA_UNORM_BLOCK: case VK_FORMAT_BC1_RGB_SRGB_BLOCK: case VK_FORMAT_BC1_RGBA_SRGB_BLOCK: return 1; case VK_FORMAT_BC2_UNORM_BLOCK: case VK_FORMAT_BC2_SRGB_BLOCK: return 2; case VK_FORMAT_BC3_UNORM_BLOCK: case VK_FORMAT_BC3_SRGB_BLOCK: return 3; case VK_FORMAT_BC4_UNORM_BLOCK: case VK_FORMAT_BC4_SNORM_BLOCK: return 4; case VK_FORMAT_BC5_UNORM_BLOCK: case VK_FORMAT_BC5_SNORM_BLOCK: return 5; default: UNSUPPORTED("format: %d", int(format)); return 0; } } // Returns true for BC1 if we have an RGB format, false for RGBA // Returns true for BC4 and BC5 if we have an unsigned format, false for signed // Ignored by BC2 and BC3 bool GetNoAlphaOrUnsigned(const vk::Format &format) { switch(format) { case VK_FORMAT_BC1_RGB_UNORM_BLOCK: case VK_FORMAT_BC1_RGB_SRGB_BLOCK: case VK_FORMAT_BC4_UNORM_BLOCK: case VK_FORMAT_BC5_UNORM_BLOCK: return true; case VK_FORMAT_BC1_RGBA_UNORM_BLOCK: case VK_FORMAT_BC1_RGBA_SRGB_BLOCK: case VK_FORMAT_BC2_UNORM_BLOCK: case VK_FORMAT_BC2_SRGB_BLOCK: case VK_FORMAT_BC3_UNORM_BLOCK: case VK_FORMAT_BC3_SRGB_BLOCK: case VK_FORMAT_BC4_SNORM_BLOCK: case VK_FORMAT_BC5_SNORM_BLOCK: return false; default: UNSUPPORTED("format: %d", int(format)); return false; } } } // anonymous namespace namespace vk { Image::Image(const VkImageCreateInfo *pCreateInfo, void *mem, Device *device) : device(device) , flags(pCreateInfo->flags) , imageType(pCreateInfo->imageType) , format(pCreateInfo->format) , extent(pCreateInfo->extent) , mipLevels(pCreateInfo->mipLevels) , arrayLayers(pCreateInfo->arrayLayers) , samples(pCreateInfo->samples) , tiling(pCreateInfo->tiling) , usage(pCreateInfo->usage) { if(format.isCompressed()) { VkImageCreateInfo compressedImageCreateInfo = *pCreateInfo; compressedImageCreateInfo.format = format.getDecompressedFormat(); decompressedImage = new(mem) Image(&compressedImageCreateInfo, nullptr, device); } const auto *nextInfo = reinterpret_cast(pCreateInfo->pNext); for(; nextInfo != nullptr; nextInfo = nextInfo->pNext) { if(nextInfo->sType == VK_STRUCTURE_TYPE_EXTERNAL_MEMORY_IMAGE_CREATE_INFO) { const auto *externalInfo = reinterpret_cast(nextInfo); supportedExternalMemoryHandleTypes = externalInfo->handleTypes; } } } void Image::destroy(const VkAllocationCallbacks *pAllocator) { if(decompressedImage) { vk::deallocate(decompressedImage, pAllocator); } } size_t Image::ComputeRequiredAllocationSize(const VkImageCreateInfo *pCreateInfo) { return Format(pCreateInfo->format).isCompressed() ? sizeof(Image) : 0; } const VkMemoryRequirements Image::getMemoryRequirements() const { VkMemoryRequirements memoryRequirements; memoryRequirements.alignment = vk::REQUIRED_MEMORY_ALIGNMENT; memoryRequirements.memoryTypeBits = vk::MEMORY_TYPE_GENERIC_BIT; memoryRequirements.size = getStorageSize(format.getAspects()) + (decompressedImage ? decompressedImage->getStorageSize(decompressedImage->format.getAspects()) : 0); return memoryRequirements; } bool Image::canBindToMemory(DeviceMemory *pDeviceMemory) const { return pDeviceMemory->checkExternalMemoryHandleType(supportedExternalMemoryHandleTypes); } void Image::bind(DeviceMemory *pDeviceMemory, VkDeviceSize pMemoryOffset) { deviceMemory = pDeviceMemory; memoryOffset = pMemoryOffset; if(decompressedImage) { decompressedImage->deviceMemory = deviceMemory; decompressedImage->memoryOffset = memoryOffset + getStorageSize(format.getAspects()); } } #ifdef __ANDROID__ VkResult Image::prepareForExternalUseANDROID() const { void *nativeBuffer = nullptr; VkExtent3D extent = getMipLevelExtent(VK_IMAGE_ASPECT_COLOR_BIT, 0); buffer_handle_t importedBufferHandle = nullptr; if(GrallocModule::getInstance()->import(backingMemory.nativeHandle, &importedBufferHandle) != 0) { return VK_ERROR_OUT_OF_DATE_KHR; } if(!importedBufferHandle) { return VK_ERROR_OUT_OF_DATE_KHR; } if(GrallocModule::getInstance()->lock(importedBufferHandle, GRALLOC_USAGE_SW_WRITE_OFTEN, 0, 0, extent.width, extent.height, &nativeBuffer) != 0) { return VK_ERROR_OUT_OF_DATE_KHR; } if(!nativeBuffer) { return VK_ERROR_OUT_OF_DATE_KHR; } int imageRowBytes = rowPitchBytes(VK_IMAGE_ASPECT_COLOR_BIT, 0); int bufferRowBytes = backingMemory.stride * getFormat().bytes(); ASSERT(imageRowBytes <= bufferRowBytes); uint8_t *srcBuffer = static_cast(deviceMemory->getOffsetPointer(0)); uint8_t *dstBuffer = static_cast(nativeBuffer); for(uint32_t i = 0; i < extent.height; i++) { memcpy(dstBuffer + (i * bufferRowBytes), srcBuffer + (i * imageRowBytes), imageRowBytes); } if(GrallocModule::getInstance()->unlock(importedBufferHandle) != 0) { return VK_ERROR_OUT_OF_DATE_KHR; } if (GrallocModule::getInstance()->release(importedBufferHandle) != 0) { return VK_ERROR_OUT_OF_DATE_KHR; } return VK_SUCCESS; } VkDeviceMemory Image::getExternalMemory() const { return backingMemory.externalMemory ? *deviceMemory : VkDeviceMemory{ VK_NULL_HANDLE }; } #endif void Image::getSubresourceLayout(const VkImageSubresource *pSubresource, VkSubresourceLayout *pLayout) const { // By spec, aspectMask has a single bit set. if(!((pSubresource->aspectMask == VK_IMAGE_ASPECT_COLOR_BIT) || (pSubresource->aspectMask == VK_IMAGE_ASPECT_DEPTH_BIT) || (pSubresource->aspectMask == VK_IMAGE_ASPECT_STENCIL_BIT) || (pSubresource->aspectMask == VK_IMAGE_ASPECT_PLANE_0_BIT) || (pSubresource->aspectMask == VK_IMAGE_ASPECT_PLANE_1_BIT) || (pSubresource->aspectMask == VK_IMAGE_ASPECT_PLANE_2_BIT))) { UNSUPPORTED("aspectMask %X", pSubresource->aspectMask); } auto aspect = static_cast(pSubresource->aspectMask); pLayout->offset = getMemoryOffset(aspect, pSubresource->mipLevel, pSubresource->arrayLayer); pLayout->size = getMultiSampledLevelSize(aspect, pSubresource->mipLevel); pLayout->rowPitch = rowPitchBytes(aspect, pSubresource->mipLevel); pLayout->depthPitch = slicePitchBytes(aspect, pSubresource->mipLevel); pLayout->arrayPitch = getLayerSize(aspect); } void Image::copyTo(Image *dstImage, const VkImageCopy ®ion) const { // Image copy does not perform any conversion, it simply copies memory from // an image to another image that has the same number of bytes per pixel. if(!((region.srcSubresource.aspectMask == VK_IMAGE_ASPECT_COLOR_BIT) || (region.srcSubresource.aspectMask == VK_IMAGE_ASPECT_DEPTH_BIT) || (region.srcSubresource.aspectMask == VK_IMAGE_ASPECT_STENCIL_BIT) || (region.srcSubresource.aspectMask == VK_IMAGE_ASPECT_PLANE_0_BIT) || (region.srcSubresource.aspectMask == VK_IMAGE_ASPECT_PLANE_1_BIT) || (region.srcSubresource.aspectMask == VK_IMAGE_ASPECT_PLANE_2_BIT))) { UNSUPPORTED("srcSubresource.aspectMask %X", region.srcSubresource.aspectMask); } if(!((region.dstSubresource.aspectMask == VK_IMAGE_ASPECT_COLOR_BIT) || (region.dstSubresource.aspectMask == VK_IMAGE_ASPECT_DEPTH_BIT) || (region.dstSubresource.aspectMask == VK_IMAGE_ASPECT_STENCIL_BIT) || (region.dstSubresource.aspectMask == VK_IMAGE_ASPECT_PLANE_0_BIT) || (region.dstSubresource.aspectMask == VK_IMAGE_ASPECT_PLANE_1_BIT) || (region.dstSubresource.aspectMask == VK_IMAGE_ASPECT_PLANE_2_BIT))) { UNSUPPORTED("dstSubresource.aspectMask %X", region.dstSubresource.aspectMask); } VkImageAspectFlagBits srcAspect = static_cast(region.srcSubresource.aspectMask); VkImageAspectFlagBits dstAspect = static_cast(region.dstSubresource.aspectMask); Format srcFormat = getFormat(srcAspect); Format dstFormat = dstImage->getFormat(dstAspect); if((samples > VK_SAMPLE_COUNT_1_BIT) && (imageType == VK_IMAGE_TYPE_2D) && !format.isUnnormalizedInteger()) { // Requires multisampling resolve VkImageBlit blitRegion; blitRegion.srcSubresource = region.srcSubresource; blitRegion.srcOffsets[0] = region.srcOffset; blitRegion.srcOffsets[1].x = blitRegion.srcOffsets[0].x + region.extent.width; blitRegion.srcOffsets[1].y = blitRegion.srcOffsets[0].y + region.extent.height; blitRegion.srcOffsets[1].z = blitRegion.srcOffsets[0].z + region.extent.depth; blitRegion.dstSubresource = region.dstSubresource; blitRegion.dstOffsets[0] = region.dstOffset; blitRegion.dstOffsets[1].x = blitRegion.dstOffsets[0].x + region.extent.width; blitRegion.dstOffsets[1].y = blitRegion.dstOffsets[0].y + region.extent.height; blitRegion.dstOffsets[1].z = blitRegion.dstOffsets[0].z + region.extent.depth; return device->getBlitter()->blit(this, dstImage, blitRegion, VK_FILTER_NEAREST); } int srcBytesPerBlock = srcFormat.bytesPerBlock(); ASSERT(srcBytesPerBlock == dstFormat.bytesPerBlock()); const uint8_t *srcMem = static_cast(getTexelPointer(region.srcOffset, region.srcSubresource)); uint8_t *dstMem = static_cast(dstImage->getTexelPointer(region.dstOffset, region.dstSubresource)); int srcRowPitchBytes = rowPitchBytes(srcAspect, region.srcSubresource.mipLevel); int srcSlicePitchBytes = slicePitchBytes(srcAspect, region.srcSubresource.mipLevel); int dstRowPitchBytes = dstImage->rowPitchBytes(dstAspect, region.dstSubresource.mipLevel); int dstSlicePitchBytes = dstImage->slicePitchBytes(dstAspect, region.dstSubresource.mipLevel); VkExtent3D srcExtent = getMipLevelExtent(srcAspect, region.srcSubresource.mipLevel); VkExtent3D dstExtent = dstImage->getMipLevelExtent(dstAspect, region.dstSubresource.mipLevel); VkExtent3D copyExtent = imageExtentInBlocks(region.extent, srcAspect); bool isSinglePlane = (copyExtent.depth == 1); bool isSingleLine = (copyExtent.height == 1) && isSinglePlane; // In order to copy multiple lines using a single memcpy call, we // have to make sure that we need to copy the entire line and that // both source and destination lines have the same length in bytes bool isEntireLine = (region.extent.width == srcExtent.width) && (region.extent.width == dstExtent.width) && // For non compressed formats, blockWidth is 1. For compressed // formats, rowPitchBytes returns the number of bytes for a row of // blocks, so we have to divide by the block height, which means: // srcRowPitchBytes / srcBlockWidth == dstRowPitchBytes / dstBlockWidth // And, to avoid potential non exact integer division, for example if a // block has 16 bytes and represents 5 lines, we change the equation to: // srcRowPitchBytes * dstBlockWidth == dstRowPitchBytes * srcBlockWidth ((srcRowPitchBytes * dstFormat.blockWidth()) == (dstRowPitchBytes * srcFormat.blockWidth())); // In order to copy multiple planes using a single memcpy call, we // have to make sure that we need to copy the entire plane and that // both source and destination planes have the same length in bytes bool isEntirePlane = isEntireLine && (copyExtent.height == srcExtent.height) && (copyExtent.height == dstExtent.height) && (srcSlicePitchBytes == dstSlicePitchBytes); if(isSingleLine) // Copy one line { size_t copySize = copyExtent.width * srcBytesPerBlock; ASSERT((srcMem + copySize) < end()); ASSERT((dstMem + copySize) < dstImage->end()); memcpy(dstMem, srcMem, copySize); } else if(isEntireLine && isSinglePlane) // Copy one plane { size_t copySize = copyExtent.height * srcRowPitchBytes; ASSERT((srcMem + copySize) < end()); ASSERT((dstMem + copySize) < dstImage->end()); memcpy(dstMem, srcMem, copySize); } else if(isEntirePlane) // Copy multiple planes { size_t copySize = copyExtent.depth * srcSlicePitchBytes; ASSERT((srcMem + copySize) < end()); ASSERT((dstMem + copySize) < dstImage->end()); memcpy(dstMem, srcMem, copySize); } else if(isEntireLine) // Copy plane by plane { size_t copySize = copyExtent.height * srcRowPitchBytes; for(uint32_t z = 0; z < copyExtent.depth; z++, dstMem += dstSlicePitchBytes, srcMem += srcSlicePitchBytes) { ASSERT((srcMem + copySize) < end()); ASSERT((dstMem + copySize) < dstImage->end()); memcpy(dstMem, srcMem, copySize); } } else // Copy line by line { size_t copySize = copyExtent.width * srcBytesPerBlock; for(uint32_t z = 0; z < copyExtent.depth; z++, dstMem += dstSlicePitchBytes, srcMem += srcSlicePitchBytes) { const uint8_t *srcSlice = srcMem; uint8_t *dstSlice = dstMem; for(uint32_t y = 0; y < copyExtent.height; y++, dstSlice += dstRowPitchBytes, srcSlice += srcRowPitchBytes) { ASSERT((srcSlice + copySize) < end()); ASSERT((dstSlice + copySize) < dstImage->end()); memcpy(dstSlice, srcSlice, copySize); } } } dstImage->prepareForSampling({ region.dstSubresource.aspectMask, region.dstSubresource.mipLevel, 1, region.dstSubresource.baseArrayLayer, region.dstSubresource.layerCount }); } void Image::copy(Buffer *buffer, const VkBufferImageCopy ®ion, bool bufferIsSource) { switch(region.imageSubresource.aspectMask) { case VK_IMAGE_ASPECT_COLOR_BIT: case VK_IMAGE_ASPECT_DEPTH_BIT: case VK_IMAGE_ASPECT_STENCIL_BIT: case VK_IMAGE_ASPECT_PLANE_0_BIT: case VK_IMAGE_ASPECT_PLANE_1_BIT: case VK_IMAGE_ASPECT_PLANE_2_BIT: break; default: UNSUPPORTED("aspectMask %x", int(region.imageSubresource.aspectMask)); break; } auto aspect = static_cast(region.imageSubresource.aspectMask); Format copyFormat = getFormat(aspect); VkExtent3D imageExtent = imageExtentInBlocks(region.imageExtent, aspect); VkExtent2D bufferExtent = bufferExtentInBlocks({ imageExtent.width, imageExtent.height }, region); int bytesPerBlock = copyFormat.bytesPerBlock(); int bufferRowPitchBytes = bufferExtent.width * bytesPerBlock; int bufferSlicePitchBytes = bufferExtent.height * bufferRowPitchBytes; uint8_t *bufferMemory = static_cast(buffer->getOffsetPointer(region.bufferOffset)); uint8_t *imageMemory = static_cast(getTexelPointer(region.imageOffset, region.imageSubresource)); uint8_t *srcMemory = bufferIsSource ? bufferMemory : imageMemory; uint8_t *dstMemory = bufferIsSource ? imageMemory : bufferMemory; int imageRowPitchBytes = rowPitchBytes(aspect, region.imageSubresource.mipLevel); int imageSlicePitchBytes = slicePitchBytes(aspect, region.imageSubresource.mipLevel); int srcSlicePitchBytes = bufferIsSource ? bufferSlicePitchBytes : imageSlicePitchBytes; int dstSlicePitchBytes = bufferIsSource ? imageSlicePitchBytes : bufferSlicePitchBytes; int srcRowPitchBytes = bufferIsSource ? bufferRowPitchBytes : imageRowPitchBytes; int dstRowPitchBytes = bufferIsSource ? imageRowPitchBytes : bufferRowPitchBytes; VkExtent3D mipLevelExtent = getMipLevelExtent(aspect, region.imageSubresource.mipLevel); bool isSinglePlane = (imageExtent.depth == 1); bool isSingleLine = (imageExtent.height == 1) && isSinglePlane; bool isEntireLine = (imageExtent.width == mipLevelExtent.width) && (imageRowPitchBytes == bufferRowPitchBytes); bool isEntirePlane = isEntireLine && (imageExtent.height == mipLevelExtent.height) && (imageSlicePitchBytes == bufferSlicePitchBytes); VkDeviceSize copySize = 0; VkDeviceSize bufferLayerSize = 0; if(isSingleLine) { copySize = imageExtent.width * bytesPerBlock; bufferLayerSize = copySize; } else if(isEntireLine && isSinglePlane) { copySize = imageExtent.height * imageRowPitchBytes; bufferLayerSize = copySize; } else if(isEntirePlane) { copySize = imageExtent.depth * imageSlicePitchBytes; // Copy multiple planes bufferLayerSize = copySize; } else if(isEntireLine) // Copy plane by plane { copySize = imageExtent.height * imageRowPitchBytes; bufferLayerSize = copySize * imageExtent.depth; } else // Copy line by line { copySize = imageExtent.width * bytesPerBlock; bufferLayerSize = copySize * imageExtent.depth * imageExtent.height; } VkDeviceSize imageLayerSize = getLayerSize(aspect); VkDeviceSize srcLayerSize = bufferIsSource ? bufferLayerSize : imageLayerSize; VkDeviceSize dstLayerSize = bufferIsSource ? imageLayerSize : bufferLayerSize; for(uint32_t i = 0; i < region.imageSubresource.layerCount; i++) { if(isSingleLine || (isEntireLine && isSinglePlane) || isEntirePlane) { ASSERT(((bufferIsSource ? dstMemory : srcMemory) + copySize) < end()); ASSERT(((bufferIsSource ? srcMemory : dstMemory) + copySize) < buffer->end()); memcpy(dstMemory, srcMemory, copySize); } else if(isEntireLine) // Copy plane by plane { uint8_t *srcPlaneMemory = srcMemory; uint8_t *dstPlaneMemory = dstMemory; for(uint32_t z = 0; z < imageExtent.depth; z++) { ASSERT(((bufferIsSource ? dstPlaneMemory : srcPlaneMemory) + copySize) < end()); ASSERT(((bufferIsSource ? srcPlaneMemory : dstPlaneMemory) + copySize) < buffer->end()); memcpy(dstPlaneMemory, srcPlaneMemory, copySize); srcPlaneMemory += srcSlicePitchBytes; dstPlaneMemory += dstSlicePitchBytes; } } else // Copy line by line { uint8_t *srcLayerMemory = srcMemory; uint8_t *dstLayerMemory = dstMemory; for(uint32_t z = 0; z < imageExtent.depth; z++) { uint8_t *srcPlaneMemory = srcLayerMemory; uint8_t *dstPlaneMemory = dstLayerMemory; for(uint32_t y = 0; y < imageExtent.height; y++) { ASSERT(((bufferIsSource ? dstPlaneMemory : srcPlaneMemory) + copySize) < end()); ASSERT(((bufferIsSource ? srcPlaneMemory : dstPlaneMemory) + copySize) < buffer->end()); memcpy(dstPlaneMemory, srcPlaneMemory, copySize); srcPlaneMemory += srcRowPitchBytes; dstPlaneMemory += dstRowPitchBytes; } srcLayerMemory += srcSlicePitchBytes; dstLayerMemory += dstSlicePitchBytes; } } srcMemory += srcLayerSize; dstMemory += dstLayerSize; } if(bufferIsSource) { prepareForSampling({ region.imageSubresource.aspectMask, region.imageSubresource.mipLevel, 1, region.imageSubresource.baseArrayLayer, region.imageSubresource.layerCount }); } } void Image::copyTo(Buffer *dstBuffer, const VkBufferImageCopy ®ion) { copy(dstBuffer, region, false); } void Image::copyFrom(Buffer *srcBuffer, const VkBufferImageCopy ®ion) { copy(srcBuffer, region, true); } void *Image::getTexelPointer(const VkOffset3D &offset, const VkImageSubresourceLayers &subresource) const { VkImageAspectFlagBits aspect = static_cast(subresource.aspectMask); return deviceMemory->getOffsetPointer(texelOffsetBytesInStorage(offset, subresource) + getMemoryOffset(aspect, subresource.mipLevel, subresource.baseArrayLayer)); } VkExtent3D Image::imageExtentInBlocks(const VkExtent3D &extent, VkImageAspectFlagBits aspect) const { VkExtent3D adjustedExtent = extent; Format usedFormat = getFormat(aspect); if(usedFormat.isCompressed()) { // When using a compressed format, we use the block as the base unit, instead of the texel int blockWidth = usedFormat.blockWidth(); int blockHeight = usedFormat.blockHeight(); // Mip level allocations will round up to the next block for compressed texture adjustedExtent.width = ((adjustedExtent.width + blockWidth - 1) / blockWidth); adjustedExtent.height = ((adjustedExtent.height + blockHeight - 1) / blockHeight); } return adjustedExtent; } VkOffset3D Image::imageOffsetInBlocks(const VkOffset3D &offset, VkImageAspectFlagBits aspect) const { VkOffset3D adjustedOffset = offset; Format usedFormat = getFormat(aspect); if(usedFormat.isCompressed()) { // When using a compressed format, we use the block as the base unit, instead of the texel int blockWidth = usedFormat.blockWidth(); int blockHeight = usedFormat.blockHeight(); ASSERT(((offset.x % blockWidth) == 0) && ((offset.y % blockHeight) == 0)); // We can't offset within a block adjustedOffset.x /= blockWidth; adjustedOffset.y /= blockHeight; } return adjustedOffset; } VkExtent2D Image::bufferExtentInBlocks(const VkExtent2D &extent, const VkBufferImageCopy ®ion) const { VkExtent2D adjustedExtent = extent; VkImageAspectFlagBits aspect = static_cast(region.imageSubresource.aspectMask); Format usedFormat = getFormat(aspect); if(region.bufferRowLength != 0) { adjustedExtent.width = region.bufferRowLength; if(usedFormat.isCompressed()) { int blockWidth = usedFormat.blockWidth(); ASSERT((adjustedExtent.width % blockWidth) == 0); adjustedExtent.width /= blockWidth; } } if(region.bufferImageHeight != 0) { adjustedExtent.height = region.bufferImageHeight; if(usedFormat.isCompressed()) { int blockHeight = usedFormat.blockHeight(); ASSERT((adjustedExtent.height % blockHeight) == 0); adjustedExtent.height /= blockHeight; } } return adjustedExtent; } int Image::borderSize() const { // We won't add a border to compressed cube textures, we'll add it when we decompress the texture return (isCube() && !format.isCompressed()) ? 1 : 0; } VkDeviceSize Image::texelOffsetBytesInStorage(const VkOffset3D &offset, const VkImageSubresourceLayers &subresource) const { VkImageAspectFlagBits aspect = static_cast(subresource.aspectMask); VkOffset3D adjustedOffset = imageOffsetInBlocks(offset, aspect); int border = borderSize(); return adjustedOffset.z * slicePitchBytes(aspect, subresource.mipLevel) + (adjustedOffset.y + border) * rowPitchBytes(aspect, subresource.mipLevel) + (adjustedOffset.x + border) * getFormat(aspect).bytesPerBlock(); } VkExtent3D Image::getMipLevelExtent(VkImageAspectFlagBits aspect, uint32_t mipLevel) const { VkExtent3D mipLevelExtent; mipLevelExtent.width = extent.width >> mipLevel; mipLevelExtent.height = extent.height >> mipLevel; mipLevelExtent.depth = extent.depth >> mipLevel; if(mipLevelExtent.width == 0) { mipLevelExtent.width = 1; } if(mipLevelExtent.height == 0) { mipLevelExtent.height = 1; } if(mipLevelExtent.depth == 0) { mipLevelExtent.depth = 1; } switch(aspect) { case VK_IMAGE_ASPECT_COLOR_BIT: case VK_IMAGE_ASPECT_DEPTH_BIT: case VK_IMAGE_ASPECT_STENCIL_BIT: case VK_IMAGE_ASPECT_PLANE_0_BIT: // Vulkan 1.1 Table 31. Plane Format Compatibility Table: plane 0 of all defined formats is full resolution. break; case VK_IMAGE_ASPECT_PLANE_1_BIT: case VK_IMAGE_ASPECT_PLANE_2_BIT: switch(format) { case VK_FORMAT_G8_B8_R8_3PLANE_420_UNORM: case VK_FORMAT_G8_B8R8_2PLANE_420_UNORM: ASSERT(mipLevelExtent.width % 2 == 0 && mipLevelExtent.height % 2 == 0); // Vulkan 1.1: "Images in this format must be defined with a width and height that is a multiple of two." // Vulkan 1.1 Table 31. Plane Format Compatibility Table: // Half-resolution U and V planes. mipLevelExtent.width /= 2; mipLevelExtent.height /= 2; break; default: UNSUPPORTED("format %d", int(format)); } break; default: UNSUPPORTED("aspect %x", int(aspect)); } return mipLevelExtent; } int Image::rowPitchBytes(VkImageAspectFlagBits aspect, uint32_t mipLevel) const { // Depth and Stencil pitch should be computed separately ASSERT((aspect & (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)) != (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)); VkExtent3D mipLevelExtent = getMipLevelExtent(aspect, mipLevel); Format usedFormat = getFormat(aspect); if(usedFormat.isCompressed()) { VkExtent3D extentInBlocks = imageExtentInBlocks(mipLevelExtent, aspect); return extentInBlocks.width * usedFormat.bytesPerBlock(); } return usedFormat.pitchB(mipLevelExtent.width, borderSize(), true); } int Image::slicePitchBytes(VkImageAspectFlagBits aspect, uint32_t mipLevel) const { // Depth and Stencil slice should be computed separately ASSERT((aspect & (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)) != (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)); VkExtent3D mipLevelExtent = getMipLevelExtent(aspect, mipLevel); Format usedFormat = getFormat(aspect); if(usedFormat.isCompressed()) { VkExtent3D extentInBlocks = imageExtentInBlocks(mipLevelExtent, aspect); return extentInBlocks.height * extentInBlocks.width * usedFormat.bytesPerBlock(); } return usedFormat.sliceB(mipLevelExtent.width, mipLevelExtent.height, borderSize(), true); } Format Image::getFormat(VkImageAspectFlagBits aspect) const { return format.getAspectFormat(aspect); } bool Image::isCube() const { return (flags & VK_IMAGE_CREATE_CUBE_COMPATIBLE_BIT) && (imageType == VK_IMAGE_TYPE_2D); } uint8_t *Image::end() const { return reinterpret_cast(deviceMemory->getOffsetPointer(deviceMemory->getCommittedMemoryInBytes() + 1)); } VkDeviceSize Image::getMemoryOffset(VkImageAspectFlagBits aspect) const { switch(format) { case VK_FORMAT_D16_UNORM_S8_UINT: case VK_FORMAT_D24_UNORM_S8_UINT: case VK_FORMAT_D32_SFLOAT_S8_UINT: if(aspect == VK_IMAGE_ASPECT_STENCIL_BIT) { // Offset by depth buffer to get to stencil buffer return memoryOffset + getStorageSize(VK_IMAGE_ASPECT_DEPTH_BIT); } break; case VK_FORMAT_G8_B8_R8_3PLANE_420_UNORM: if(aspect == VK_IMAGE_ASPECT_PLANE_2_BIT) { return memoryOffset + getStorageSize(VK_IMAGE_ASPECT_PLANE_1_BIT) + getStorageSize(VK_IMAGE_ASPECT_PLANE_0_BIT); } // Fall through to 2PLANE case: case VK_FORMAT_G8_B8R8_2PLANE_420_UNORM: if(aspect == VK_IMAGE_ASPECT_PLANE_1_BIT) { return memoryOffset + getStorageSize(VK_IMAGE_ASPECT_PLANE_0_BIT); } else { ASSERT(aspect == VK_IMAGE_ASPECT_PLANE_0_BIT); return memoryOffset; } break; default: break; } return memoryOffset; } VkDeviceSize Image::getMemoryOffset(VkImageAspectFlagBits aspect, uint32_t mipLevel) const { VkDeviceSize offset = getMemoryOffset(aspect); for(uint32_t i = 0; i < mipLevel; ++i) { offset += getMultiSampledLevelSize(aspect, i); } return offset; } VkDeviceSize Image::getMemoryOffset(VkImageAspectFlagBits aspect, uint32_t mipLevel, uint32_t layer) const { return layer * getLayerOffset(aspect, mipLevel) + getMemoryOffset(aspect, mipLevel); } VkDeviceSize Image::getMipLevelSize(VkImageAspectFlagBits aspect, uint32_t mipLevel) const { return getMipLevelExtent(aspect, mipLevel).depth * slicePitchBytes(aspect, mipLevel); } VkDeviceSize Image::getMultiSampledLevelSize(VkImageAspectFlagBits aspect, uint32_t mipLevel) const { return getMipLevelSize(aspect, mipLevel) * samples; } bool Image::is3DSlice() const { return ((imageType == VK_IMAGE_TYPE_3D) && (flags & VK_IMAGE_CREATE_2D_ARRAY_COMPATIBLE_BIT)); } VkDeviceSize Image::getLayerOffset(VkImageAspectFlagBits aspect, uint32_t mipLevel) const { if(is3DSlice()) { // When the VkImageSubresourceRange structure is used to select a subset of the slices of a 3D // image's mip level in order to create a 2D or 2D array image view of a 3D image created with // VK_IMAGE_CREATE_2D_ARRAY_COMPATIBLE_BIT, baseArrayLayer and layerCount specify the first // slice index and the number of slices to include in the created image view. ASSERT(samples == VK_SAMPLE_COUNT_1_BIT); // Offset to the proper slice of the 3D image's mip level return slicePitchBytes(aspect, mipLevel); } return getLayerSize(aspect); } VkDeviceSize Image::getLayerSize(VkImageAspectFlagBits aspect) const { VkDeviceSize layerSize = 0; for(uint32_t mipLevel = 0; mipLevel < mipLevels; ++mipLevel) { layerSize += getMultiSampledLevelSize(aspect, mipLevel); } return layerSize; } VkDeviceSize Image::getStorageSize(VkImageAspectFlags aspectMask) const { if((aspectMask & ~(VK_IMAGE_ASPECT_COLOR_BIT | VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT | VK_IMAGE_ASPECT_PLANE_0_BIT | VK_IMAGE_ASPECT_PLANE_1_BIT | VK_IMAGE_ASPECT_PLANE_2_BIT)) != 0) { UNSUPPORTED("aspectMask %x", int(aspectMask)); } VkDeviceSize storageSize = 0; if(aspectMask & VK_IMAGE_ASPECT_COLOR_BIT) storageSize += getLayerSize(VK_IMAGE_ASPECT_COLOR_BIT); if(aspectMask & VK_IMAGE_ASPECT_DEPTH_BIT) storageSize += getLayerSize(VK_IMAGE_ASPECT_DEPTH_BIT); if(aspectMask & VK_IMAGE_ASPECT_STENCIL_BIT) storageSize += getLayerSize(VK_IMAGE_ASPECT_STENCIL_BIT); if(aspectMask & VK_IMAGE_ASPECT_PLANE_0_BIT) storageSize += getLayerSize(VK_IMAGE_ASPECT_PLANE_0_BIT); if(aspectMask & VK_IMAGE_ASPECT_PLANE_1_BIT) storageSize += getLayerSize(VK_IMAGE_ASPECT_PLANE_1_BIT); if(aspectMask & VK_IMAGE_ASPECT_PLANE_2_BIT) storageSize += getLayerSize(VK_IMAGE_ASPECT_PLANE_2_BIT); return arrayLayers * storageSize; } const Image *Image::getSampledImage(const vk::Format &imageViewFormat) const { bool isImageViewCompressed = imageViewFormat.isCompressed(); if(decompressedImage && !isImageViewCompressed) { ASSERT(flags & VK_IMAGE_CREATE_BLOCK_TEXEL_VIEW_COMPATIBLE_BIT); ASSERT(format.bytesPerBlock() == imageViewFormat.bytesPerBlock()); } // If the ImageView's format is compressed, then we do need to decompress the image so that // it may be sampled properly by texture sampling functions, which don't support compressed // textures. If the ImageView's format is NOT compressed, then we reinterpret cast the // compressed image into the ImageView's format, so we must return the compressed image as is. return (decompressedImage && isImageViewCompressed) ? decompressedImage : this; } void Image::blit(Image *dstImage, const VkImageBlit ®ion, VkFilter filter) const { device->getBlitter()->blit(this, dstImage, region, filter); } void Image::blitToBuffer(VkImageSubresourceLayers subresource, VkOffset3D offset, VkExtent3D extent, uint8_t *dst, int bufferRowPitch, int bufferSlicePitch) const { device->getBlitter()->blitToBuffer(this, subresource, offset, extent, dst, bufferRowPitch, bufferSlicePitch); } void Image::resolve(Image *dstImage, const VkImageResolve ®ion) const { VkImageBlit blitRegion; blitRegion.srcOffsets[0] = blitRegion.srcOffsets[1] = region.srcOffset; blitRegion.srcOffsets[1].x += region.extent.width; blitRegion.srcOffsets[1].y += region.extent.height; blitRegion.srcOffsets[1].z += region.extent.depth; blitRegion.dstOffsets[0] = blitRegion.dstOffsets[1] = region.dstOffset; blitRegion.dstOffsets[1].x += region.extent.width; blitRegion.dstOffsets[1].y += region.extent.height; blitRegion.dstOffsets[1].z += region.extent.depth; blitRegion.srcSubresource = region.srcSubresource; blitRegion.dstSubresource = region.dstSubresource; device->getBlitter()->blit(this, dstImage, blitRegion, VK_FILTER_NEAREST); } VkFormat Image::getClearFormat() const { // Set the proper format for the clear value, as described here: // https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#clears-values if(format.isSignedUnnormalizedInteger()) { return VK_FORMAT_R32G32B32A32_SINT; } else if(format.isUnsignedUnnormalizedInteger()) { return VK_FORMAT_R32G32B32A32_UINT; } return VK_FORMAT_R32G32B32A32_SFLOAT; } uint32_t Image::getLastLayerIndex(const VkImageSubresourceRange &subresourceRange) const { return ((subresourceRange.layerCount == VK_REMAINING_ARRAY_LAYERS) ? arrayLayers : (subresourceRange.baseArrayLayer + subresourceRange.layerCount)) - 1; } uint32_t Image::getLastMipLevel(const VkImageSubresourceRange &subresourceRange) const { return ((subresourceRange.levelCount == VK_REMAINING_MIP_LEVELS) ? mipLevels : (subresourceRange.baseMipLevel + subresourceRange.levelCount)) - 1; } void Image::clear(void *pixelData, VkFormat pixelFormat, const vk::Format &viewFormat, const VkImageSubresourceRange &subresourceRange, const VkRect2D &renderArea) { device->getBlitter()->clear(pixelData, pixelFormat, this, viewFormat, subresourceRange, &renderArea); } void Image::clear(const VkClearColorValue &color, const VkImageSubresourceRange &subresourceRange) { ASSERT(subresourceRange.aspectMask == VK_IMAGE_ASPECT_COLOR_BIT); device->getBlitter()->clear((void *)color.float32, getClearFormat(), this, format, subresourceRange); } void Image::clear(const VkClearDepthStencilValue &color, const VkImageSubresourceRange &subresourceRange) { ASSERT((subresourceRange.aspectMask & ~(VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)) == 0); if(subresourceRange.aspectMask & VK_IMAGE_ASPECT_DEPTH_BIT) { VkImageSubresourceRange depthSubresourceRange = subresourceRange; depthSubresourceRange.aspectMask = VK_IMAGE_ASPECT_DEPTH_BIT; device->getBlitter()->clear((void *)(&color.depth), VK_FORMAT_D32_SFLOAT, this, format, depthSubresourceRange); } if(subresourceRange.aspectMask & VK_IMAGE_ASPECT_STENCIL_BIT) { VkImageSubresourceRange stencilSubresourceRange = subresourceRange; stencilSubresourceRange.aspectMask = VK_IMAGE_ASPECT_STENCIL_BIT; device->getBlitter()->clear((void *)(&color.stencil), VK_FORMAT_S8_UINT, this, format, stencilSubresourceRange); } } void Image::clear(const VkClearValue &clearValue, const vk::Format &viewFormat, const VkRect2D &renderArea, const VkImageSubresourceRange &subresourceRange) { ASSERT((subresourceRange.aspectMask == VK_IMAGE_ASPECT_COLOR_BIT) || (subresourceRange.aspectMask & (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT))); if(subresourceRange.aspectMask == VK_IMAGE_ASPECT_COLOR_BIT) { clear((void *)(clearValue.color.float32), getClearFormat(), viewFormat, subresourceRange, renderArea); } else { if(subresourceRange.aspectMask & VK_IMAGE_ASPECT_DEPTH_BIT) { VkImageSubresourceRange depthSubresourceRange = subresourceRange; depthSubresourceRange.aspectMask = VK_IMAGE_ASPECT_DEPTH_BIT; clear((void *)(&clearValue.depthStencil.depth), VK_FORMAT_D32_SFLOAT, viewFormat, depthSubresourceRange, renderArea); } if(subresourceRange.aspectMask & VK_IMAGE_ASPECT_STENCIL_BIT) { VkImageSubresourceRange stencilSubresourceRange = subresourceRange; stencilSubresourceRange.aspectMask = VK_IMAGE_ASPECT_STENCIL_BIT; clear((void *)(&clearValue.depthStencil.stencil), VK_FORMAT_S8_UINT, viewFormat, stencilSubresourceRange, renderArea); } } } void Image::prepareForSampling(const VkImageSubresourceRange &subresourceRange) { if(decompressedImage) { switch(format) { case VK_FORMAT_EAC_R11_UNORM_BLOCK: case VK_FORMAT_EAC_R11_SNORM_BLOCK: case VK_FORMAT_EAC_R11G11_UNORM_BLOCK: case VK_FORMAT_EAC_R11G11_SNORM_BLOCK: case VK_FORMAT_ETC2_R8G8B8_UNORM_BLOCK: case VK_FORMAT_ETC2_R8G8B8_SRGB_BLOCK: case VK_FORMAT_ETC2_R8G8B8A1_UNORM_BLOCK: case VK_FORMAT_ETC2_R8G8B8A1_SRGB_BLOCK: case VK_FORMAT_ETC2_R8G8B8A8_UNORM_BLOCK: case VK_FORMAT_ETC2_R8G8B8A8_SRGB_BLOCK: decodeETC2(subresourceRange); break; case VK_FORMAT_BC1_RGB_UNORM_BLOCK: case VK_FORMAT_BC1_RGB_SRGB_BLOCK: case VK_FORMAT_BC1_RGBA_UNORM_BLOCK: case VK_FORMAT_BC1_RGBA_SRGB_BLOCK: case VK_FORMAT_BC2_UNORM_BLOCK: case VK_FORMAT_BC2_SRGB_BLOCK: case VK_FORMAT_BC3_UNORM_BLOCK: case VK_FORMAT_BC3_SRGB_BLOCK: case VK_FORMAT_BC4_UNORM_BLOCK: case VK_FORMAT_BC4_SNORM_BLOCK: case VK_FORMAT_BC5_UNORM_BLOCK: case VK_FORMAT_BC5_SNORM_BLOCK: decodeBC(subresourceRange); break; case VK_FORMAT_ASTC_4x4_UNORM_BLOCK: case VK_FORMAT_ASTC_5x4_UNORM_BLOCK: case VK_FORMAT_ASTC_5x5_UNORM_BLOCK: case VK_FORMAT_ASTC_6x5_UNORM_BLOCK: case VK_FORMAT_ASTC_6x6_UNORM_BLOCK: case VK_FORMAT_ASTC_8x5_UNORM_BLOCK: case VK_FORMAT_ASTC_8x6_UNORM_BLOCK: case VK_FORMAT_ASTC_8x8_UNORM_BLOCK: case VK_FORMAT_ASTC_10x5_UNORM_BLOCK: case VK_FORMAT_ASTC_10x6_UNORM_BLOCK: case VK_FORMAT_ASTC_10x8_UNORM_BLOCK: case VK_FORMAT_ASTC_10x10_UNORM_BLOCK: case VK_FORMAT_ASTC_12x10_UNORM_BLOCK: case VK_FORMAT_ASTC_12x12_UNORM_BLOCK: case VK_FORMAT_ASTC_4x4_SRGB_BLOCK: case VK_FORMAT_ASTC_5x4_SRGB_BLOCK: case VK_FORMAT_ASTC_5x5_SRGB_BLOCK: case VK_FORMAT_ASTC_6x5_SRGB_BLOCK: case VK_FORMAT_ASTC_6x6_SRGB_BLOCK: case VK_FORMAT_ASTC_8x5_SRGB_BLOCK: case VK_FORMAT_ASTC_8x6_SRGB_BLOCK: case VK_FORMAT_ASTC_8x8_SRGB_BLOCK: case VK_FORMAT_ASTC_10x5_SRGB_BLOCK: case VK_FORMAT_ASTC_10x6_SRGB_BLOCK: case VK_FORMAT_ASTC_10x8_SRGB_BLOCK: case VK_FORMAT_ASTC_10x10_SRGB_BLOCK: case VK_FORMAT_ASTC_12x10_SRGB_BLOCK: case VK_FORMAT_ASTC_12x12_SRGB_BLOCK: case VK_FORMAT_ASTC_4x4_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_5x4_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_5x5_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_6x5_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_6x6_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_8x5_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_8x6_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_8x8_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_10x5_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_10x6_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_10x8_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_10x10_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_12x10_SFLOAT_BLOCK_EXT: case VK_FORMAT_ASTC_12x12_SFLOAT_BLOCK_EXT: decodeASTC(subresourceRange); break; default: break; } } if(isCube() && (arrayLayers >= 6)) { VkImageSubresourceLayers subresourceLayers = { subresourceRange.aspectMask, subresourceRange.baseMipLevel, subresourceRange.baseArrayLayer, 6 }; // Update the borders of all the groups of 6 layers that can be part of a cubemaps but don't // touch leftover layers that cannot be part of cubemaps. uint32_t lastMipLevel = getLastMipLevel(subresourceRange); for(; subresourceLayers.mipLevel <= lastMipLevel; subresourceLayers.mipLevel++) { for(subresourceLayers.baseArrayLayer = 0; subresourceLayers.baseArrayLayer < arrayLayers - 5; subresourceLayers.baseArrayLayer += 6) { device->getBlitter()->updateBorders(decompressedImage ? decompressedImage : this, subresourceLayers); } } } } void Image::decodeETC2(const VkImageSubresourceRange &subresourceRange) const { ASSERT(decompressedImage); ETC_Decoder::InputType inputType = GetInputType(format); uint32_t lastLayer = getLastLayerIndex(subresourceRange); uint32_t lastMipLevel = getLastMipLevel(subresourceRange); int bytes = decompressedImage->format.bytes(); bool fakeAlpha = (format == VK_FORMAT_ETC2_R8G8B8_UNORM_BLOCK) || (format == VK_FORMAT_ETC2_R8G8B8_SRGB_BLOCK); size_t sizeToWrite = 0; VkImageSubresourceLayers subresourceLayers = { subresourceRange.aspectMask, subresourceRange.baseMipLevel, subresourceRange.baseArrayLayer, 1 }; for(; subresourceLayers.baseArrayLayer <= lastLayer; subresourceLayers.baseArrayLayer++) { for(; subresourceLayers.mipLevel <= lastMipLevel; subresourceLayers.mipLevel++) { VkExtent3D mipLevelExtent = getMipLevelExtent(static_cast(subresourceLayers.aspectMask), subresourceLayers.mipLevel); int pitchB = decompressedImage->rowPitchBytes(VK_IMAGE_ASPECT_COLOR_BIT, subresourceLayers.mipLevel); if(fakeAlpha) { // To avoid overflow in case of cube textures, which are offset in memory to account for the border, // compute the size from the first pixel to the last pixel, excluding any padding or border before // the first pixel or after the last pixel. sizeToWrite = ((mipLevelExtent.height - 1) * pitchB) + (mipLevelExtent.width * bytes); } for(int32_t depth = 0; depth < static_cast(mipLevelExtent.depth); depth++) { uint8_t *source = static_cast(getTexelPointer({ 0, 0, depth }, subresourceLayers)); uint8_t *dest = static_cast(decompressedImage->getTexelPointer({ 0, 0, depth }, subresourceLayers)); if(fakeAlpha) { ASSERT((dest + sizeToWrite) < decompressedImage->end()); memset(dest, 0xFF, sizeToWrite); } ETC_Decoder::Decode(source, dest, mipLevelExtent.width, mipLevelExtent.height, mipLevelExtent.width, mipLevelExtent.height, pitchB, bytes, inputType); } } } } void Image::decodeBC(const VkImageSubresourceRange &subresourceRange) const { ASSERT(decompressedImage); int n = GetBCn(format); int noAlphaU = GetNoAlphaOrUnsigned(format); uint32_t lastLayer = getLastLayerIndex(subresourceRange); uint32_t lastMipLevel = getLastMipLevel(subresourceRange); int bytes = decompressedImage->format.bytes(); VkImageSubresourceLayers subresourceLayers = { subresourceRange.aspectMask, subresourceRange.baseMipLevel, subresourceRange.baseArrayLayer, 1 }; for(; subresourceLayers.baseArrayLayer <= lastLayer; subresourceLayers.baseArrayLayer++) { for(; subresourceLayers.mipLevel <= lastMipLevel; subresourceLayers.mipLevel++) { VkExtent3D mipLevelExtent = getMipLevelExtent(static_cast(subresourceLayers.aspectMask), subresourceLayers.mipLevel); int pitchB = decompressedImage->rowPitchBytes(VK_IMAGE_ASPECT_COLOR_BIT, subresourceLayers.mipLevel); for(int32_t depth = 0; depth < static_cast(mipLevelExtent.depth); depth++) { uint8_t *source = static_cast(getTexelPointer({ 0, 0, depth }, subresourceLayers)); uint8_t *dest = static_cast(decompressedImage->getTexelPointer({ 0, 0, depth }, subresourceLayers)); BC_Decoder::Decode(source, dest, mipLevelExtent.width, mipLevelExtent.height, mipLevelExtent.width, mipLevelExtent.height, pitchB, bytes, n, noAlphaU); } } } } void Image::decodeASTC(const VkImageSubresourceRange &subresourceRange) const { ASSERT(decompressedImage); int xBlockSize = format.blockWidth(); int yBlockSize = format.blockHeight(); int zBlockSize = 1; bool isUnsigned = format.isUnsignedComponent(0); uint32_t lastLayer = getLastLayerIndex(subresourceRange); uint32_t lastMipLevel = getLastMipLevel(subresourceRange); int bytes = decompressedImage->format.bytes(); VkImageSubresourceLayers subresourceLayers = { subresourceRange.aspectMask, subresourceRange.baseMipLevel, subresourceRange.baseArrayLayer, 1 }; for(; subresourceLayers.baseArrayLayer <= lastLayer; subresourceLayers.baseArrayLayer++) { for(; subresourceLayers.mipLevel <= lastMipLevel; subresourceLayers.mipLevel++) { VkExtent3D mipLevelExtent = getMipLevelExtent(static_cast(subresourceLayers.aspectMask), subresourceLayers.mipLevel); int xblocks = (mipLevelExtent.width + xBlockSize - 1) / xBlockSize; int yblocks = (mipLevelExtent.height + yBlockSize - 1) / yBlockSize; int zblocks = (zBlockSize > 1) ? (mipLevelExtent.depth + zBlockSize - 1) / zBlockSize : 1; if(xblocks <= 0 || yblocks <= 0 || zblocks <= 0) { continue; } int pitchB = decompressedImage->rowPitchBytes(VK_IMAGE_ASPECT_COLOR_BIT, subresourceLayers.mipLevel); int sliceB = decompressedImage->slicePitchBytes(VK_IMAGE_ASPECT_COLOR_BIT, subresourceLayers.mipLevel); for(int32_t depth = 0; depth < static_cast(mipLevelExtent.depth); depth++) { uint8_t *source = static_cast(getTexelPointer({ 0, 0, depth }, subresourceLayers)); uint8_t *dest = static_cast(decompressedImage->getTexelPointer({ 0, 0, depth }, subresourceLayers)); ASTC_Decoder::Decode(source, dest, mipLevelExtent.width, mipLevelExtent.height, mipLevelExtent.depth, bytes, pitchB, sliceB, xBlockSize, yBlockSize, zBlockSize, xblocks, yblocks, zblocks, isUnsigned); } } } } } // namespace vk