//------------------------------------------------------------------------------------- // DirectXTexPMAlpha.cpp // // DirectX Texture Library - Premultiplied alpha operations // // THIS CODE AND INFORMATION IS PROVIDED "AS IS" WITHOUT WARRANTY OF // ANY KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING BUT NOT LIMITED TO // THE IMPLIED WARRANTIES OF MERCHANTABILITY AND/OR FITNESS FOR A // PARTICULAR PURPOSE. // // Copyright (c) Microsoft Corporation. All rights reserved. // // http://go.microsoft.com/fwlink/?LinkId=248926 //------------------------------------------------------------------------------------- #include "directxtexp.h" using namespace DirectX; namespace { //--------------------------------------------------------------------------------- // NonPremultiplied alpha -> Premultiplied alpha HRESULT PremultiplyAlpha_(const Image& srcImage, const Image& destImage) { assert(srcImage.width == destImage.width); assert(srcImage.height == destImage.height); ScopedAlignedArrayXMVECTOR scanline(reinterpret_cast(_aligned_malloc((sizeof(XMVECTOR)*srcImage.width), 16))); if (!scanline) return E_OUTOFMEMORY; const uint8_t *pSrc = srcImage.pixels; uint8_t *pDest = destImage.pixels; if (!pSrc || !pDest) return E_POINTER; for (size_t h = 0; h < srcImage.height; ++h) { if (!_LoadScanline(scanline.get(), srcImage.width, pSrc, srcImage.rowPitch, srcImage.format)) return E_FAIL; XMVECTOR* ptr = scanline.get(); for (size_t w = 0; w < srcImage.width; ++w) { XMVECTOR v = *ptr; XMVECTOR alpha = XMVectorSplatW(*ptr); alpha = XMVectorMultiply(v, alpha); *(ptr++) = XMVectorSelect(v, alpha, g_XMSelect1110); } if (!_StoreScanline(pDest, destImage.rowPitch, destImage.format, scanline.get(), srcImage.width)) return E_FAIL; pSrc += srcImage.rowPitch; pDest += destImage.rowPitch; } return S_OK; } HRESULT PremultiplyAlphaLinear(const Image& srcImage, DWORD flags, const Image& destImage) { assert(srcImage.width == destImage.width); assert(srcImage.height == destImage.height); static_assert(static_cast(TEX_PMALPHA_SRGB_IN) == static_cast(TEX_FILTER_SRGB_IN), "TEX_PMALHPA_SRGB* should match TEX_FILTER_SRGB*"); static_assert(static_cast(TEX_PMALPHA_SRGB_OUT) == static_cast(TEX_FILTER_SRGB_OUT), "TEX_PMALHPA_SRGB* should match TEX_FILTER_SRGB*"); static_assert(static_cast(TEX_PMALPHA_SRGB) == static_cast(TEX_FILTER_SRGB), "TEX_PMALHPA_SRGB* should match TEX_FILTER_SRGB*"); flags &= TEX_PMALPHA_SRGB; ScopedAlignedArrayXMVECTOR scanline(reinterpret_cast(_aligned_malloc((sizeof(XMVECTOR)*srcImage.width), 16))); if (!scanline) return E_OUTOFMEMORY; const uint8_t *pSrc = srcImage.pixels; uint8_t *pDest = destImage.pixels; if (!pSrc || !pDest) return E_POINTER; for (size_t h = 0; h < srcImage.height; ++h) { if (!_LoadScanlineLinear(scanline.get(), srcImage.width, pSrc, srcImage.rowPitch, srcImage.format, flags)) return E_FAIL; XMVECTOR* ptr = scanline.get(); for (size_t w = 0; w < srcImage.width; ++w) { XMVECTOR v = *ptr; XMVECTOR alpha = XMVectorSplatW(*ptr); alpha = XMVectorMultiply(v, alpha); *(ptr++) = XMVectorSelect(v, alpha, g_XMSelect1110); } if (!_StoreScanlineLinear(pDest, destImage.rowPitch, destImage.format, scanline.get(), srcImage.width, flags)) return E_FAIL; pSrc += srcImage.rowPitch; pDest += destImage.rowPitch; } return S_OK; } //--------------------------------------------------------------------------------- // Premultiplied alpha -> NonPremultiplied alpha (a.k.a. Straight alpha) HRESULT DemultiplyAlpha(const Image& srcImage, const Image& destImage) { assert(srcImage.width == destImage.width); assert(srcImage.height == destImage.height); ScopedAlignedArrayXMVECTOR scanline(reinterpret_cast(_aligned_malloc((sizeof(XMVECTOR)*srcImage.width), 16))); if (!scanline) return E_OUTOFMEMORY; const uint8_t *pSrc = srcImage.pixels; uint8_t *pDest = destImage.pixels; if (!pSrc || !pDest) return E_POINTER; for (size_t h = 0; h < srcImage.height; ++h) { if (!_LoadScanline(scanline.get(), srcImage.width, pSrc, srcImage.rowPitch, srcImage.format)) return E_FAIL; XMVECTOR* ptr = scanline.get(); for (size_t w = 0; w < srcImage.width; ++w) { XMVECTOR v = *ptr; XMVECTOR alpha = XMVectorSplatW(*ptr); alpha = XMVectorDivide(v, alpha); *(ptr++) = XMVectorSelect(v, alpha, g_XMSelect1110); } if (!_StoreScanline(pDest, destImage.rowPitch, destImage.format, scanline.get(), srcImage.width)) return E_FAIL; pSrc += srcImage.rowPitch; pDest += destImage.rowPitch; } return S_OK; } HRESULT DemultiplyAlphaLinear(const Image& srcImage, DWORD flags, const Image& destImage) { assert(srcImage.width == destImage.width); assert(srcImage.height == destImage.height); static_assert(static_cast(TEX_PMALPHA_SRGB_IN) == static_cast(TEX_FILTER_SRGB_IN), "TEX_PMALHPA_SRGB* should match TEX_FILTER_SRGB*"); static_assert(static_cast(TEX_PMALPHA_SRGB_OUT) == static_cast(TEX_FILTER_SRGB_OUT), "TEX_PMALHPA_SRGB* should match TEX_FILTER_SRGB*"); static_assert(static_cast(TEX_PMALPHA_SRGB) == static_cast(TEX_FILTER_SRGB), "TEX_PMALHPA_SRGB* should match TEX_FILTER_SRGB*"); flags &= TEX_PMALPHA_SRGB; ScopedAlignedArrayXMVECTOR scanline(reinterpret_cast(_aligned_malloc((sizeof(XMVECTOR)*srcImage.width), 16))); if (!scanline) return E_OUTOFMEMORY; const uint8_t *pSrc = srcImage.pixels; uint8_t *pDest = destImage.pixels; if (!pSrc || !pDest) return E_POINTER; for (size_t h = 0; h < srcImage.height; ++h) { if (!_LoadScanlineLinear(scanline.get(), srcImage.width, pSrc, srcImage.rowPitch, srcImage.format, flags)) return E_FAIL; XMVECTOR* ptr = scanline.get(); for (size_t w = 0; w < srcImage.width; ++w) { XMVECTOR v = *ptr; XMVECTOR alpha = XMVectorSplatW(*ptr); alpha = XMVectorDivide(v, alpha); *(ptr++) = XMVectorSelect(v, alpha, g_XMSelect1110); } if (!_StoreScanlineLinear(pDest, destImage.rowPitch, destImage.format, scanline.get(), srcImage.width, flags)) return E_FAIL; pSrc += srcImage.rowPitch; pDest += destImage.rowPitch; } return S_OK; } } //===================================================================================== // Entry-points //===================================================================================== //------------------------------------------------------------------------------------- // Converts to/from a premultiplied alpha version of the texture //------------------------------------------------------------------------------------- _Use_decl_annotations_ HRESULT DirectX::PremultiplyAlpha( const Image& srcImage, DWORD flags, ScratchImage& image) { if (!srcImage.pixels) return E_POINTER; if (IsCompressed(srcImage.format) || IsPlanar(srcImage.format) || IsPalettized(srcImage.format) || IsTypeless(srcImage.format) || !HasAlpha(srcImage.format)) return HRESULT_FROM_WIN32(ERROR_NOT_SUPPORTED); if ((srcImage.width > UINT32_MAX) || (srcImage.height > UINT32_MAX)) return E_INVALIDARG; HRESULT hr = image.Initialize2D(srcImage.format, srcImage.width, srcImage.height, 1, 1); if (FAILED(hr)) return hr; const Image *rimage = image.GetImage(0, 0, 0); if (!rimage) { image.Release(); return E_POINTER; } if (flags & TEX_PMALPHA_REVERSE) { hr = (flags & TEX_PMALPHA_IGNORE_SRGB) ? DemultiplyAlpha(srcImage, *rimage) : DemultiplyAlphaLinear(srcImage, flags, *rimage); } else { hr = (flags & TEX_PMALPHA_IGNORE_SRGB) ? PremultiplyAlpha_(srcImage, *rimage) : PremultiplyAlphaLinear(srcImage, flags, *rimage); } if (FAILED(hr)) { image.Release(); return hr; } return S_OK; } //------------------------------------------------------------------------------------- // Converts to/from a premultiplied alpha version of the texture (complex) //------------------------------------------------------------------------------------- _Use_decl_annotations_ HRESULT DirectX::PremultiplyAlpha( const Image* srcImages, size_t nimages, const TexMetadata& metadata, DWORD flags, ScratchImage& result) { if (!srcImages || !nimages) return E_INVALIDARG; if (IsCompressed(metadata.format) || IsPlanar(metadata.format) || IsPalettized(metadata.format) || IsTypeless(metadata.format) || !HasAlpha(metadata.format)) return HRESULT_FROM_WIN32(ERROR_NOT_SUPPORTED); if ((metadata.width > UINT32_MAX) || (metadata.height > UINT32_MAX)) return E_INVALIDARG; if (metadata.IsPMAlpha() != ((flags & TEX_PMALPHA_REVERSE) != 0)) return E_FAIL; TexMetadata mdata2 = metadata; mdata2.SetAlphaMode((flags & TEX_PMALPHA_REVERSE) ? TEX_ALPHA_MODE_STRAIGHT : TEX_ALPHA_MODE_PREMULTIPLIED); HRESULT hr = result.Initialize(mdata2); if (FAILED(hr)) return hr; if (nimages != result.GetImageCount()) { result.Release(); return E_FAIL; } const Image* dest = result.GetImages(); if (!dest) { result.Release(); return E_POINTER; } for (size_t index = 0; index < nimages; ++index) { const Image& src = srcImages[index]; if (src.format != metadata.format) { result.Release(); return E_FAIL; } if ((src.width > UINT32_MAX) || (src.height > UINT32_MAX)) return E_FAIL; const Image& dst = dest[index]; assert(dst.format == metadata.format); if (src.width != dst.width || src.height != dst.height) { result.Release(); return E_FAIL; } if (flags & TEX_PMALPHA_REVERSE) { hr = (flags & TEX_PMALPHA_IGNORE_SRGB) ? DemultiplyAlpha(src, dst) : DemultiplyAlphaLinear(src, flags, dst); } else { hr = (flags & TEX_PMALPHA_IGNORE_SRGB) ? PremultiplyAlpha_(src, dst) : PremultiplyAlphaLinear(src, flags, dst); } if (FAILED(hr)) { result.Release(); return hr; } } return S_OK; }