/* * Copyright 2006 The Android Open Source Project * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef SkMask_DEFINED #define SkMask_DEFINED #include "SkRect.h" /** \class SkMask SkMask is used to describe alpha bitmaps, either 1bit, 8bit, or the 3-channel 3D format. These are passed to SkMaskFilter objects. */ struct SkMask { enum Format { kBW_Format, //!< 1bit per pixel mask (e.g. monochrome) kA8_Format, //!< 8bits per pixel mask (e.g. antialiasing) k3D_Format, //!< 3 8bit per pixl planes: alpha, mul, add kARGB32_Format, //!< SkPMColor kLCD16_Format, //!< 565 alpha for r/g/b kLCD32_Format //!< 888 alpha for r/g/b }; enum { kCountMaskFormats = kLCD32_Format + 1 }; uint8_t* fImage; SkIRect fBounds; uint32_t fRowBytes; Format fFormat; /** Returns true if the mask is empty: i.e. it has an empty bounds. */ bool isEmpty() const { return fBounds.isEmpty(); } /** Return the byte size of the mask, assuming only 1 plane. Does not account for k3D_Format. For that, use computeTotalImageSize(). If there is an overflow of 32bits, then returns 0. */ size_t computeImageSize() const; /** Return the byte size of the mask, taking into account any extra planes (e.g. k3D_Format). If there is an overflow of 32bits, then returns 0. */ size_t computeTotalImageSize() const; /** Returns the address of the byte that holds the specified bit. Asserts that the mask is kBW_Format, and that x,y are in range. x,y are in the same coordiate space as fBounds. */ uint8_t* getAddr1(int x, int y) const { SkASSERT(kBW_Format == fFormat); SkASSERT(fBounds.contains(x, y)); SkASSERT(fImage != NULL); return fImage + ((x - fBounds.fLeft) >> 3) + (y - fBounds.fTop) * fRowBytes; } /** Returns the address of the specified byte. Asserts that the mask is kA8_Format, and that x,y are in range. x,y are in the same coordiate space as fBounds. */ uint8_t* getAddr8(int x, int y) const { SkASSERT(kA8_Format == fFormat); SkASSERT(fBounds.contains(x, y)); SkASSERT(fImage != NULL); return fImage + x - fBounds.fLeft + (y - fBounds.fTop) * fRowBytes; } /** * Return the address of the specified 16bit mask. In the debug build, * this asserts that the mask's format is kLCD16_Format, and that (x,y) * are contained in the mask's fBounds. */ uint16_t* getAddrLCD16(int x, int y) const { SkASSERT(kLCD16_Format == fFormat); SkASSERT(fBounds.contains(x, y)); SkASSERT(fImage != NULL); uint16_t* row = (uint16_t*)(fImage + (y - fBounds.fTop) * fRowBytes); return row + (x - fBounds.fLeft); } /** * Return the address of the specified 32bit mask. In the debug build, * this asserts that the mask's format is kLCD32_Format, and that (x,y) * are contained in the mask's fBounds. */ uint32_t* getAddrLCD32(int x, int y) const { SkASSERT(kLCD32_Format == fFormat); SkASSERT(fBounds.contains(x, y)); SkASSERT(fImage != NULL); uint32_t* row = (uint32_t*)(fImage + (y - fBounds.fTop) * fRowBytes); return row + (x - fBounds.fLeft); } /** * Returns the address of the specified pixel, computing the pixel-size * at runtime based on the mask format. This will be slightly slower than * using one of the routines where the format is implied by the name * e.g. getAddr8 or getAddrLCD32. * * x,y must be contained by the mask's bounds (this is asserted in the * debug build, but not checked in the release build.) * * This should not be called with kBW_Format, as it will give unspecified * results (and assert in the debug build). */ void* getAddr(int x, int y) const; static uint8_t* AllocImage(size_t bytes); static void FreeImage(void* image); enum CreateMode { kJustComputeBounds_CreateMode, //!< compute bounds and return kJustRenderImage_CreateMode, //!< render into preallocate mask kComputeBoundsAndRenderImage_CreateMode //!< compute bounds, alloc image and render into it }; }; #endif