/* * Copyright 2016 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef SkEncodedInfo_DEFINED #define SkEncodedInfo_DEFINED #include "SkImageInfo.h" class SkColorSpace; struct SkEncodedInfo { public: enum Alpha { kOpaque_Alpha, kUnpremul_Alpha, // Each pixel is either fully opaque or fully transparent. // There is no difference between requesting kPremul or kUnpremul. kBinary_Alpha, }; /* * We strive to make the number of components per pixel obvious through * our naming conventions. * Ex: kRGB has 3 components. kRGBA has 4 components. * * This sometimes results in redundant Alpha and Color information. * Ex: kRGB images must also be kOpaque. */ enum Color { // PNG, WBMP kGray_Color, // PNG kGrayAlpha_Color, // PNG, GIF, BMP kPalette_Color, // PNG, RAW kRGB_Color, kRGBA_Color, // BMP kBGR_Color, kBGRX_Color, kBGRA_Color, // JPEG, WEBP kYUV_Color, // WEBP kYUVA_Color, // JPEG // Photoshop actually writes inverted CMYK data into JPEGs, where zero // represents 100% ink coverage. For this reason, we treat CMYK JPEGs // as having inverted CMYK. libjpeg-turbo warns that this may break // other applications, but the CMYK JPEGs we see on the web expect to // be treated as inverted CMYK. kInvertedCMYK_Color, kYCCK_Color, }; static SkEncodedInfo Make(Color color, Alpha alpha, int bitsPerComponent) { SkASSERT(1 == bitsPerComponent || 2 == bitsPerComponent || 4 == bitsPerComponent || 8 == bitsPerComponent || 16 == bitsPerComponent); switch (color) { case kGray_Color: SkASSERT(kOpaque_Alpha == alpha); break; case kGrayAlpha_Color: SkASSERT(kOpaque_Alpha != alpha); break; case kPalette_Color: SkASSERT(16 != bitsPerComponent); break; case kRGB_Color: case kBGR_Color: case kBGRX_Color: SkASSERT(kOpaque_Alpha == alpha); SkASSERT(bitsPerComponent >= 8); break; case kYUV_Color: case kInvertedCMYK_Color: case kYCCK_Color: SkASSERT(kOpaque_Alpha == alpha); SkASSERT(8 == bitsPerComponent); break; case kRGBA_Color: SkASSERT(kOpaque_Alpha != alpha); SkASSERT(bitsPerComponent >= 8); break; case kBGRA_Color: case kYUVA_Color: SkASSERT(kOpaque_Alpha != alpha); SkASSERT(8 == bitsPerComponent); break; default: SkASSERT(false); break; } return SkEncodedInfo(color, alpha, bitsPerComponent); } /* * Returns an SkImageInfo with Skia color and alpha types that are the * closest possible match to the encoded info. */ SkImageInfo makeImageInfo(int width, int height, sk_sp colorSpace) const { auto ct = kGray_Color == fColor ? kGray_8_SkColorType : kN32_SkColorType ; auto alpha = kOpaque_Alpha == fAlpha ? kOpaque_SkAlphaType : kUnpremul_SkAlphaType; return SkImageInfo::Make(width, height, ct, alpha, std::move(colorSpace)); } Color color() const { return fColor; } Alpha alpha() const { return fAlpha; } bool opaque() const { return fAlpha == kOpaque_Alpha; } uint8_t bitsPerComponent() const { return fBitsPerComponent; } uint8_t bitsPerPixel() const { switch (fColor) { case kGray_Color: return fBitsPerComponent; case kGrayAlpha_Color: return 2 * fBitsPerComponent; case kPalette_Color: return fBitsPerComponent; case kRGB_Color: case kBGR_Color: case kYUV_Color: return 3 * fBitsPerComponent; case kRGBA_Color: case kBGRA_Color: case kBGRX_Color: case kYUVA_Color: case kInvertedCMYK_Color: case kYCCK_Color: return 4 * fBitsPerComponent; default: SkASSERT(false); return 0; } } private: SkEncodedInfo(Color color, Alpha alpha, uint8_t bitsPerComponent) : fColor(color) , fAlpha(alpha) , fBitsPerComponent(bitsPerComponent) {} Color fColor; Alpha fAlpha; uint8_t fBitsPerComponent; }; #endif