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skia / skia / b6b7e7b6c8de74acb9dbb5b636634e20a27bcdaa / . / src / ports / SkFontHost_FreeType_common.cpp
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/*
* Copyright 2006-2012 The Android Open Source Project
* Copyright 2012 Mozilla Foundation
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "include/core/SkBitmap.h"
#include "include/core/SkCanvas.h"
#include "include/core/SkColor.h"
#include "include/core/SkPath.h"
#include "include/private/SkColorData.h"
#include "include/private/SkTo.h"
#include "src/core/SkFDot6.h"
#include "src/ports/SkFontHost_FreeType_common.h"
#include <utility>
#include <ft2build.h>
#include FT_FREETYPE_H
#include FT_BITMAP_H
#ifdef FT_COLOR_H
# include FT_COLOR_H
#endif
#include FT_IMAGE_H
#include FT_OUTLINE_H
// In the past, FT_GlyphSlot_Own_Bitmap was defined in this header file.
#include FT_SYNTHESIS_H
// FT_LOAD_COLOR and the corresponding FT_Pixel_Mode::FT_PIXEL_MODE_BGRA
// were introduced in FreeType 2.5.0.
// The following may be removed once FreeType 2.5.0 is required to build.
#ifndef FT_LOAD_COLOR
# define FT_LOAD_COLOR ( 1L << 20 )
# define FT_PIXEL_MODE_BGRA 7
#endif
#ifdef SK_DEBUG
const char* SkTraceFtrGetError(int e) {
switch ((FT_Error)e) {
#undef FTERRORS_H_
#define FT_ERRORDEF( e, v, s ) case v: return s;
#define FT_ERROR_START_LIST
#define FT_ERROR_END_LIST
#include FT_ERRORS_H
#undef FT_ERRORDEF
#undef FT_ERROR_START_LIST
#undef FT_ERROR_END_LIST
default: return "";
}
}
#endif // SK_DEBUG
namespace {
FT_Pixel_Mode compute_pixel_mode(SkMask::Format format) {
switch (format) {
case SkMask::kBW_Format:
return FT_PIXEL_MODE_MONO;
case SkMask::kA8_Format:
default:
return FT_PIXEL_MODE_GRAY;
}
}
///////////////////////////////////////////////////////////////////////////////
uint16_t packTriple(U8CPU r, U8CPU g, U8CPU b) {
#ifdef SK_SHOW_TEXT_BLIT_COVERAGE
r = SkTMax(r, (U8CPU)0x40);
g = SkTMax(g, (U8CPU)0x40);
b = SkTMax(b, (U8CPU)0x40);
#endif
return SkPack888ToRGB16(r, g, b);
}
uint16_t grayToRGB16(U8CPU gray) {
#ifdef SK_SHOW_TEXT_BLIT_COVERAGE
gray = SkTMax(gray, (U8CPU)0x40);
#endif
return SkPack888ToRGB16(gray, gray, gray);
}
int bittst(const uint8_t data[], int bitOffset) {
SkASSERT(bitOffset >= 0);
int lowBit = data[bitOffset >> 3] >> (~bitOffset & 7);
return lowBit & 1;
}
/**
* Copies a FT_Bitmap into an SkMask with the same dimensions.
*
* FT_PIXEL_MODE_MONO
* FT_PIXEL_MODE_GRAY
* FT_PIXEL_MODE_LCD
* FT_PIXEL_MODE_LCD_V
*/
template<bool APPLY_PREBLEND>
void copyFT2LCD16(const FT_Bitmap& bitmap, const SkMask& mask, int lcdIsBGR,
const uint8_t* tableR, const uint8_t* tableG, const uint8_t* tableB)
{
SkASSERT(SkMask::kLCD16_Format == mask.fFormat);
if (FT_PIXEL_MODE_LCD != bitmap.pixel_mode) {
SkASSERT(mask.fBounds.width() == static_cast<int>(bitmap.width));
}
if (FT_PIXEL_MODE_LCD_V != bitmap.pixel_mode) {
SkASSERT(mask.fBounds.height() == static_cast<int>(bitmap.rows));
}
const uint8_t* src = bitmap.buffer;
uint16_t* dst = reinterpret_cast<uint16_t*>(mask.fImage);
const size_t dstRB = mask.fRowBytes;
const int width = mask.fBounds.width();
const int height = mask.fBounds.height();
switch (bitmap.pixel_mode) {
case FT_PIXEL_MODE_MONO:
for (int y = height; y --> 0;) {
for (int x = 0; x < width; ++x) {
dst[x] = -bittst(src, x);
}
dst = (uint16_t*)((char*)dst + dstRB);
src += bitmap.pitch;
}
break;
case FT_PIXEL_MODE_GRAY:
for (int y = height; y --> 0;) {
for (int x = 0; x < width; ++x) {
dst[x] = grayToRGB16(src[x]);
}
dst = (uint16_t*)((char*)dst + dstRB);
src += bitmap.pitch;
}
break;
case FT_PIXEL_MODE_LCD:
SkASSERT(3 * mask.fBounds.width() == static_cast<int>(bitmap.width));
for (int y = height; y --> 0;) {
const uint8_t* triple = src;
if (lcdIsBGR) {
for (int x = 0; x < width; x++) {
dst[x] = packTriple(sk_apply_lut_if<APPLY_PREBLEND>(triple[2], tableR),
sk_apply_lut_if<APPLY_PREBLEND>(triple[1], tableG),
sk_apply_lut_if<APPLY_PREBLEND>(triple[0], tableB));
triple += 3;
}
} else {
for (int x = 0; x < width; x++) {
dst[x] = packTriple(sk_apply_lut_if<APPLY_PREBLEND>(triple[0], tableR),
sk_apply_lut_if<APPLY_PREBLEND>(triple[1], tableG),
sk_apply_lut_if<APPLY_PREBLEND>(triple[2], tableB));
triple += 3;
}
}
src += bitmap.pitch;
dst = (uint16_t*)((char*)dst + dstRB);
}
break;
case FT_PIXEL_MODE_LCD_V:
SkASSERT(3 * mask.fBounds.height() == static_cast<int>(bitmap.rows));
for (int y = height; y --> 0;) {
const uint8_t* srcR = src;
const uint8_t* srcG = srcR + bitmap.pitch;
const uint8_t* srcB = srcG + bitmap.pitch;
if (lcdIsBGR) {
using std::swap;
swap(srcR, srcB);
}
for (int x = 0; x < width; x++) {
dst[x] = packTriple(sk_apply_lut_if<APPLY_PREBLEND>(*srcR++, tableR),
sk_apply_lut_if<APPLY_PREBLEND>(*srcG++, tableG),
sk_apply_lut_if<APPLY_PREBLEND>(*srcB++, tableB));
}
src += 3 * bitmap.pitch;
dst = (uint16_t*)((char*)dst + dstRB);
}
break;
default:
SkDEBUGF("FT_Pixel_Mode %d", bitmap.pixel_mode);
SkDEBUGFAIL("unsupported FT_Pixel_Mode for LCD16");
break;
}
}
/**
* Copies a FT_Bitmap into an SkMask with the same dimensions.
*
* Yes, No, Never Requested, Never Produced
*
* kBW kA8 k3D kARGB32 kLCD16
* FT_PIXEL_MODE_MONO Y Y NR N Y
* FT_PIXEL_MODE_GRAY N Y NR N Y
* FT_PIXEL_MODE_GRAY2 NP NP NR NP NP
* FT_PIXEL_MODE_GRAY4 NP NP NR NP NP
* FT_PIXEL_MODE_LCD NP NP NR NP NP
* FT_PIXEL_MODE_LCD_V NP NP NR NP NP
* FT_PIXEL_MODE_BGRA N N NR Y N
*
* TODO: All of these N need to be Y or otherwise ruled out.
*/
void copyFTBitmap(const FT_Bitmap& srcFTBitmap, SkMask& dstMask) {
SkASSERTF(dstMask.fBounds.width() == static_cast<int>(srcFTBitmap.width),
"dstMask.fBounds.width() = %d\n"
"static_cast<int>(srcFTBitmap.width) = %d",
dstMask.fBounds.width(),
static_cast<int>(srcFTBitmap.width)
);
SkASSERTF(dstMask.fBounds.height() == static_cast<int>(srcFTBitmap.rows),
"dstMask.fBounds.height() = %d\n"
"static_cast<int>(srcFTBitmap.rows) = %d",
dstMask.fBounds.height(),
static_cast<int>(srcFTBitmap.rows)
);
const uint8_t* src = reinterpret_cast<const uint8_t*>(srcFTBitmap.buffer);
const FT_Pixel_Mode srcFormat = static_cast<FT_Pixel_Mode>(srcFTBitmap.pixel_mode);
// FT_Bitmap::pitch is an int and allowed to be negative.
const int srcPitch = srcFTBitmap.pitch;
const size_t srcRowBytes = SkTAbs(srcPitch);
uint8_t* dst = dstMask.fImage;
const SkMask::Format dstFormat = static_cast<SkMask::Format>(dstMask.fFormat);
const size_t dstRowBytes = dstMask.fRowBytes;
const size_t width = srcFTBitmap.width;
const size_t height = srcFTBitmap.rows;
if (SkMask::kLCD16_Format == dstFormat) {
copyFT2LCD16<false>(srcFTBitmap, dstMask, false, nullptr, nullptr, nullptr);
return;
}
if ((FT_PIXEL_MODE_MONO == srcFormat && SkMask::kBW_Format == dstFormat) ||
(FT_PIXEL_MODE_GRAY == srcFormat && SkMask::kA8_Format == dstFormat))
{
size_t commonRowBytes = SkTMin(srcRowBytes, dstRowBytes);
for (size_t y = height; y --> 0;) {
memcpy(dst, src, commonRowBytes);
src += srcPitch;
dst += dstRowBytes;
}
} else if (FT_PIXEL_MODE_MONO == srcFormat && SkMask::kA8_Format == dstFormat) {
for (size_t y = height; y --> 0;) {
uint8_t byte = 0;
int bits = 0;
const uint8_t* src_row = src;
uint8_t* dst_row = dst;
for (size_t x = width; x --> 0;) {
if (0 == bits) {
byte = *src_row++;
bits = 8;
}
*dst_row++ = byte & 0x80 ? 0xff : 0x00;
bits--;
byte <<= 1;
}
src += srcPitch;
dst += dstRowBytes;
}
} else if (FT_PIXEL_MODE_BGRA == srcFormat && SkMask::kARGB32_Format == dstFormat) {
// FT_PIXEL_MODE_BGRA is pre-multiplied.
for (size_t y = height; y --> 0;) {
const uint8_t* src_row = src;
SkPMColor* dst_row = reinterpret_cast<SkPMColor*>(dst);
for (size_t x = 0; x < width; ++x) {
uint8_t b = *src_row++;
uint8_t g = *src_row++;
uint8_t r = *src_row++;
uint8_t a = *src_row++;
*dst_row++ = SkPackARGB32(a, r, g, b);
#ifdef SK_SHOW_TEXT_BLIT_COVERAGE
*(dst_row-1) = SkFourByteInterp256(*(dst_row-1), SK_ColorWHITE, 0x40);
#endif
}
src += srcPitch;
dst += dstRowBytes;
}
} else {
SkDEBUGF("FT_Pixel_Mode %d, SkMask::Format %d\n", srcFormat, dstFormat);
SkDEBUGFAIL("unsupported combination of FT_Pixel_Mode and SkMask::Format");
}
}
inline int convert_8_to_1(unsigned byte) {
SkASSERT(byte <= 0xFF);
// Arbitrary decision that making the cutoff at 1/4 instead of 1/2 in general looks better.
return (byte >> 6) != 0;
}
uint8_t pack_8_to_1(const uint8_t alpha[8]) {
unsigned bits = 0;
for (int i = 0; i < 8; ++i) {
bits <<= 1;
bits |= convert_8_to_1(alpha[i]);
}
return SkToU8(bits);
}
void packA8ToA1(const SkMask& mask, const uint8_t* src, size_t srcRB) {
const int height = mask.fBounds.height();
const int width = mask.fBounds.width();
const int octs = width >> 3;
const int leftOverBits = width & 7;
uint8_t* dst = mask.fImage;
const int dstPad = mask.fRowBytes - SkAlign8(width)/8;
SkASSERT(dstPad >= 0);
const int srcPad = srcRB - width;
SkASSERT(srcPad >= 0);
for (int y = 0; y < height; ++y) {
for (int i = 0; i < octs; ++i) {
*dst++ = pack_8_to_1(src);
src += 8;
}
if (leftOverBits > 0) {
unsigned bits = 0;
int shift = 7;
for (int i = 0; i < leftOverBits; ++i, --shift) {
bits |= convert_8_to_1(*src++) << shift;
}
*dst++ = bits;
}
src += srcPad;
dst += dstPad;
}
}
inline SkMask::Format SkMaskFormat_for_SkColorType(SkColorType colorType) {
switch (colorType) {
case kAlpha_8_SkColorType:
return SkMask::kA8_Format;
case kN32_SkColorType:
return SkMask::kARGB32_Format;
default:
SkDEBUGFAIL("unsupported SkBitmap::Config");
return SkMask::kA8_Format;
}
}
inline SkColorType SkColorType_for_FTPixelMode(FT_Pixel_Mode pixel_mode) {
switch (pixel_mode) {
case FT_PIXEL_MODE_MONO:
case FT_PIXEL_MODE_GRAY:
return kAlpha_8_SkColorType;
case FT_PIXEL_MODE_BGRA:
return kN32_SkColorType;
default:
SkDEBUGFAIL("unsupported FT_PIXEL_MODE");
return kAlpha_8_SkColorType;
}
}
inline SkColorType SkColorType_for_SkMaskFormat(SkMask::Format format) {
switch (format) {
case SkMask::kBW_Format:
case SkMask::kA8_Format:
case SkMask::kLCD16_Format:
return kAlpha_8_SkColorType;
case SkMask::kARGB32_Format:
return kN32_SkColorType;
default:
SkDEBUGFAIL("unsupported destination SkBitmap::Config");
return kAlpha_8_SkColorType;
}
}
} // namespace
void SkScalerContext_FreeType_Base::generateGlyphImage(
FT_Face face,
const SkGlyph& glyph,
const SkMatrix& bitmapTransform)
{
const bool doBGR = SkToBool(fRec.fFlags & SkScalerContext::kLCD_BGROrder_Flag);
const bool doVert = SkToBool(fRec.fFlags & SkScalerContext::kLCD_Vertical_Flag);
switch ( face->glyph->format ) {
case FT_GLYPH_FORMAT_OUTLINE: {
FT_Outline* outline = &face->glyph->outline;
int dx = 0, dy = 0;
if (this->isSubpixel()) {
dx = SkFixedToFDot6(glyph.getSubXFixed());
dy = SkFixedToFDot6(glyph.getSubYFixed());
// negate dy since freetype-y-goes-up and skia-y-goes-down
dy = -dy;
}
memset(glyph.fImage, 0, glyph.rowBytes() * glyph.fHeight);
#ifdef FT_COLOR_H
if (SkMask::kARGB32_Format == glyph.fMaskFormat) {
SkBitmap dstBitmap;
// TODO: mark this as sRGB when the blits will be sRGB.
dstBitmap.setInfo(SkImageInfo::Make(glyph.fWidth, glyph.fHeight,
kN32_SkColorType,
kPremul_SkAlphaType),
glyph.rowBytes());
dstBitmap.setPixels(glyph.fImage);
// Scale unscaledBitmap into dstBitmap.
SkCanvas canvas(dstBitmap);
#ifdef SK_SHOW_TEXT_BLIT_COVERAGE
canvas.clear(0x33FF0000);
#else
canvas.clear(SK_ColorTRANSPARENT);
#endif
canvas.translate(-glyph.fLeft, -glyph.fTop);
if (this->isSubpixel()) {
canvas.translate(SkFixedToScalar(glyph.getSubXFixed()),
SkFixedToScalar(glyph.getSubYFixed()));
}
SkPaint paint;
paint.setAntiAlias(true);
FT_Color *palette;
FT_Error err = FT_Palette_Select(face, 0, &palette);
if (err) {
SK_TRACEFTR(err, "Could not get palette from %s fontFace.", face->family_name);
return;
}
FT_LayerIterator layerIterator;
layerIterator.p = NULL;
FT_Bool haveLayers = false;
FT_UInt layerGlyphIndex;
FT_UInt layerColorIndex;
while (FT_Get_Color_Glyph_Layer(face, glyph.getGlyphID(), &layerGlyphIndex,
&layerColorIndex,
&layerIterator)) {
haveLayers = true;
if (layerColorIndex == 0xFFFF) {
paint.setColor(SK_ColorBLACK);
} else {
SkColor color = SkColorSetARGB(palette[layerColorIndex].alpha,
palette[layerColorIndex].red,
palette[layerColorIndex].green,
palette[layerColorIndex].blue);
paint.setColor(color);
}
SkPath path;
if (this->generateFacePath(face, layerGlyphIndex, &path)) {
canvas.drawPath(path, paint);
}
}
if (!haveLayers) {
SK_TRACEFTR(err, "Could not get layers from %s fontFace.", face->family_name);
return;
}
} else
#endif
if (SkMask::kLCD16_Format == glyph.fMaskFormat) {
FT_Outline_Translate(outline, dx, dy);
FT_Error err = FT_Render_Glyph(face->glyph, doVert ? FT_RENDER_MODE_LCD_V :
FT_RENDER_MODE_LCD);
if (err) {
SK_TRACEFTR(err, "Could not render glyph %x.", face->glyph);
return;
}
SkMask mask = glyph.mask();
#ifdef SK_SHOW_TEXT_BLIT_COVERAGE
memset(mask.fImage, 0x80, mask.fBounds.height() * mask.fRowBytes);
#endif
FT_GlyphSlotRec& ftGlyph = *face->glyph;
if (!SkIRect::Intersects(mask.fBounds,
SkIRect::MakeXYWH( ftGlyph.bitmap_left,
-ftGlyph.bitmap_top,
ftGlyph.bitmap.width,
ftGlyph.bitmap.rows)))
{
return;
}
// If the FT_Bitmap extent is larger, discard bits of the bitmap outside the mask.
// If the SkMask extent is larger, shrink mask to fit bitmap (clearing discarded).
unsigned char* origBuffer = ftGlyph.bitmap.buffer;
// First align the top left (origin).
if (-ftGlyph.bitmap_top < mask.fBounds.fTop) {
int32_t topDiff = mask.fBounds.fTop - (-ftGlyph.bitmap_top);
ftGlyph.bitmap.buffer += ftGlyph.bitmap.pitch * topDiff;
ftGlyph.bitmap.rows -= topDiff;
ftGlyph.bitmap_top = -mask.fBounds.fTop;
}
if (ftGlyph.bitmap_left < mask.fBounds.fLeft) {
int32_t leftDiff = mask.fBounds.fLeft - ftGlyph.bitmap_left;
ftGlyph.bitmap.buffer += leftDiff;
ftGlyph.bitmap.width -= leftDiff;
ftGlyph.bitmap_left = mask.fBounds.fLeft;
}
if (mask.fBounds.fTop < -ftGlyph.bitmap_top) {
mask.fImage += mask.fRowBytes * (-ftGlyph.bitmap_top - mask.fBounds.fTop);
mask.fBounds.fTop = -ftGlyph.bitmap_top;
}
if (mask.fBounds.fLeft < ftGlyph.bitmap_left) {
mask.fImage += sizeof(uint16_t) * (ftGlyph.bitmap_left - mask.fBounds.fLeft);
mask.fBounds.fLeft = ftGlyph.bitmap_left;
}
// Origins aligned, clean up the width and height.
int ftVertScale = (doVert ? 3 : 1);
int ftHoriScale = (doVert ? 1 : 3);
if (mask.fBounds.height() * ftVertScale < SkToInt(ftGlyph.bitmap.rows)) {
ftGlyph.bitmap.rows = mask.fBounds.height() * ftVertScale;
}
if (mask.fBounds.width() * ftHoriScale < SkToInt(ftGlyph.bitmap.width)) {
ftGlyph.bitmap.width = mask.fBounds.width() * ftHoriScale;
}
if (SkToInt(ftGlyph.bitmap.rows) < mask.fBounds.height() * ftVertScale) {
mask.fBounds.fBottom = mask.fBounds.fTop + ftGlyph.bitmap.rows / ftVertScale;
}
if (SkToInt(ftGlyph.bitmap.width) < mask.fBounds.width() * ftHoriScale) {
mask.fBounds.fRight = mask.fBounds.fLeft + ftGlyph.bitmap.width / ftHoriScale;
}
if (fPreBlend.isApplicable()) {
copyFT2LCD16<true>(ftGlyph.bitmap, mask, doBGR,
fPreBlend.fR, fPreBlend.fG, fPreBlend.fB);
} else {
copyFT2LCD16<false>(ftGlyph.bitmap, mask, doBGR,
fPreBlend.fR, fPreBlend.fG, fPreBlend.fB);
}
// Restore the buffer pointer so FreeType can properly free it.
ftGlyph.bitmap.buffer = origBuffer;
} else {
FT_BBox bbox;
FT_Bitmap target;
FT_Outline_Get_CBox(outline, &bbox);
/*
what we really want to do for subpixel is
offset(dx, dy)
compute_bounds
offset(bbox & !63)
but that is two calls to offset, so we do the following, which
achieves the same thing with only one offset call.
*/
FT_Outline_Translate(outline, dx - ((bbox.xMin + dx) & ~63),
dy - ((bbox.yMin + dy) & ~63));
target.width = glyph.fWidth;
target.rows = glyph.fHeight;
target.pitch = glyph.rowBytes();
target.buffer = reinterpret_cast<uint8_t*>(glyph.fImage);
target.pixel_mode = compute_pixel_mode( (SkMask::Format)glyph.fMaskFormat);
target.num_grays = 256;
FT_Outline_Get_Bitmap(face->glyph->library, outline, &target);
#ifdef SK_SHOW_TEXT_BLIT_COVERAGE
for (int y = 0; y < glyph.fHeight; ++y) {
for (int x = 0; x < glyph.fWidth; ++x) {
uint8_t& a = ((uint8_t*)glyph.fImage)[(glyph.rowBytes() * y) + x];
a = SkTMax<uint8_t>(a, 0x20);
}
}
#endif
}
} break;
case FT_GLYPH_FORMAT_BITMAP: {
FT_Pixel_Mode pixel_mode = static_cast<FT_Pixel_Mode>(face->glyph->bitmap.pixel_mode);
SkMask::Format maskFormat = static_cast<SkMask::Format>(glyph.fMaskFormat);
// Assume that the other formats do not exist.
SkASSERT(FT_PIXEL_MODE_MONO == pixel_mode ||
FT_PIXEL_MODE_GRAY == pixel_mode ||
FT_PIXEL_MODE_BGRA == pixel_mode);
// These are the only formats this ScalerContext should request.
SkASSERT(SkMask::kBW_Format == maskFormat ||
SkMask::kA8_Format == maskFormat ||
SkMask::kARGB32_Format == maskFormat ||
SkMask::kLCD16_Format == maskFormat);
// If no scaling needed, directly copy glyph bitmap.
if (bitmapTransform.isIdentity()) {
SkMask dstMask = glyph.mask();
copyFTBitmap(face->glyph->bitmap, dstMask);
break;
}
// Otherwise, scale the bitmap.
// Copy the FT_Bitmap into an SkBitmap (either A8 or ARGB)
SkBitmap unscaledBitmap;
// TODO: mark this as sRGB when the blits will be sRGB.
unscaledBitmap.allocPixels(SkImageInfo::Make(face->glyph->bitmap.width,
face->glyph->bitmap.rows,
SkColorType_for_FTPixelMode(pixel_mode),
kPremul_SkAlphaType));
SkMask unscaledBitmapAlias;
unscaledBitmapAlias.fImage = reinterpret_cast<uint8_t*>(unscaledBitmap.getPixels());
unscaledBitmapAlias.fBounds.setWH(unscaledBitmap.width(), unscaledBitmap.height());
unscaledBitmapAlias.fRowBytes = unscaledBitmap.rowBytes();
unscaledBitmapAlias.fFormat = SkMaskFormat_for_SkColorType(unscaledBitmap.colorType());
copyFTBitmap(face->glyph->bitmap, unscaledBitmapAlias);
// Wrap the glyph's mask in a bitmap, unless the glyph's mask is BW or LCD.
// BW requires an A8 target for resizing, which can then be down sampled.
// LCD should use a 4x A8 target, which will then be down sampled.
// For simplicity, LCD uses A8 and is replicated.
int bitmapRowBytes = 0;
if (SkMask::kBW_Format != maskFormat && SkMask::kLCD16_Format != maskFormat) {
bitmapRowBytes = glyph.rowBytes();
}
SkBitmap dstBitmap;
// TODO: mark this as sRGB when the blits will be sRGB.
dstBitmap.setInfo(SkImageInfo::Make(glyph.fWidth, glyph.fHeight,
SkColorType_for_SkMaskFormat(maskFormat),
kPremul_SkAlphaType),
bitmapRowBytes);
if (SkMask::kBW_Format == maskFormat || SkMask::kLCD16_Format == maskFormat) {
dstBitmap.allocPixels();
} else {
dstBitmap.setPixels(glyph.fImage);
}
// Scale unscaledBitmap into dstBitmap.
SkCanvas canvas(dstBitmap);
#ifdef SK_SHOW_TEXT_BLIT_COVERAGE
canvas.clear(0x33FF0000);
#else
canvas.clear(SK_ColorTRANSPARENT);
#endif
canvas.translate(-glyph.fLeft, -glyph.fTop);
canvas.concat(bitmapTransform);
canvas.translate(face->glyph->bitmap_left, -face->glyph->bitmap_top);
SkPaint paint;
// Using kMedium FilterQuality will cause mipmaps to be generated. Use
// kLow when the results will be roughly the same in order to avoid
// the mipmap generation cost.
// See skbug.com/6967
if (bitmapTransform.getMinScale() < 0.5) {
paint.setFilterQuality(kMedium_SkFilterQuality);
} else {
paint.setFilterQuality(kLow_SkFilterQuality);
}
canvas.drawBitmap(unscaledBitmap, 0, 0, &paint);
// If the destination is BW or LCD, convert from A8.
if (SkMask::kBW_Format == maskFormat) {
// Copy the A8 dstBitmap into the A1 glyph.fImage.
SkMask dstMask = glyph.mask();
packA8ToA1(dstMask, dstBitmap.getAddr8(0, 0), dstBitmap.rowBytes());
} else if (SkMask::kLCD16_Format == maskFormat) {
// Copy the A8 dstBitmap into the LCD16 glyph.fImage.
uint8_t* src = dstBitmap.getAddr8(0, 0);
uint16_t* dst = reinterpret_cast<uint16_t*>(glyph.fImage);
for (int y = dstBitmap.height(); y --> 0;) {
for (int x = 0; x < dstBitmap.width(); ++x) {
dst[x] = grayToRGB16(src[x]);
}
dst = (uint16_t*)((char*)dst + glyph.rowBytes());
src += dstBitmap.rowBytes();
}
}
} break;
default:
SkDEBUGFAIL("unknown glyph format");
memset(glyph.fImage, 0, glyph.rowBytes() * glyph.fHeight);
return;
}
// We used to always do this pre-USE_COLOR_LUMINANCE, but with colorlum,
// it is optional
#if defined(SK_GAMMA_APPLY_TO_A8)
if (SkMask::kA8_Format == glyph.fMaskFormat && fPreBlend.isApplicable()) {
uint8_t* SK_RESTRICT dst = (uint8_t*)glyph.fImage;
unsigned rowBytes = glyph.rowBytes();
for (int y = glyph.fHeight - 1; y >= 0; --y) {
for (int x = glyph.fWidth - 1; x >= 0; --x) {
dst[x] = fPreBlend.fG[dst[x]];
}
dst += rowBytes;
}
}
#endif
}
///////////////////////////////////////////////////////////////////////////////
namespace {
int move_proc(const FT_Vector* pt, void* ctx) {
SkPath* path = (SkPath*)ctx;
path->close(); // to close the previous contour (if any)
path->moveTo(SkFDot6ToScalar(pt->x), -SkFDot6ToScalar(pt->y));
return 0;
}
int line_proc(const FT_Vector* pt, void* ctx) {
SkPath* path = (SkPath*)ctx;
path->lineTo(SkFDot6ToScalar(pt->x), -SkFDot6ToScalar(pt->y));
return 0;
}
int quad_proc(const FT_Vector* pt0, const FT_Vector* pt1, void* ctx) {
SkPath* path = (SkPath*)ctx;
path->quadTo(SkFDot6ToScalar(pt0->x), -SkFDot6ToScalar(pt0->y),
SkFDot6ToScalar(pt1->x), -SkFDot6ToScalar(pt1->y));
return 0;
}
int cubic_proc(const FT_Vector* pt0, const FT_Vector* pt1, const FT_Vector* pt2, void* ctx) {
SkPath* path = (SkPath*)ctx;
path->cubicTo(SkFDot6ToScalar(pt0->x), -SkFDot6ToScalar(pt0->y),
SkFDot6ToScalar(pt1->x), -SkFDot6ToScalar(pt1->y),
SkFDot6ToScalar(pt2->x), -SkFDot6ToScalar(pt2->y));
return 0;
}
} // namespace
bool SkScalerContext_FreeType_Base::generateGlyphPath(FT_Face face, SkPath* path) {
FT_Outline_Funcs funcs;
funcs.move_to = move_proc;
funcs.line_to = line_proc;
funcs.conic_to = quad_proc;
funcs.cubic_to = cubic_proc;
funcs.shift = 0;
funcs.delta = 0;
FT_Error err = FT_Outline_Decompose(&face->glyph->outline, &funcs, path);
if (err != 0) {
path->reset();
return false;
}
path->close();
return true;
}
bool SkScalerContext_FreeType_Base::generateFacePath(FT_Face face, SkGlyphID glyphID, SkPath* path) {
uint32_t flags = 0; //fLoadGlyphFlags;
flags |= FT_LOAD_NO_BITMAP; // ignore embedded bitmaps so we're sure to get the outline
flags &= ~FT_LOAD_RENDER; // don't scan convert (we just want the outline)
FT_Error err = FT_Load_Glyph(face, glyphID, flags);
if (err != 0) {
path->reset();
return false;
}
if (!generateGlyphPath(face, path)) {
path->reset();
return false;
}
return true;
}