src/core/SkGlyph.cpp - skia - Git at Google

 /*
  * Copyright 2018 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/core/SkGlyph.h"

 #include "src/core/SkArenaAlloc.h"
 #include "src/core/SkScalerContext.h"
 #include "src/pathops/SkPathOpsCubic.h"
 #include "src/pathops/SkPathOpsQuad.h"

 constexpr SkIPoint SkPackedGlyphID::kXYFieldMask;

 SkMask SkGlyph::mask() const {
     // getMetrics had to be called.
     SkASSERT(fMaskFormat != MASK_FORMAT_UNKNOWN);

     SkMask mask;
     mask.fImage = (uint8_t*)fImage;
     mask.fBounds.setXYWH(fLeft, fTop, fWidth, fHeight);
     mask.fRowBytes = this->rowBytes();
     mask.fFormat = static_cast<SkMask::Format>(fMaskFormat);
     return mask;
 }

 SkMask SkGlyph::mask(SkPoint position) const {
     SkMask answer = this->mask();
     answer.fBounds.offset(SkScalarFloorToInt(position.x()), SkScalarFloorToInt(position.y()));
     return answer;
 }

 void SkGlyph::zeroMetrics() {
     fAdvanceX = 0;
     fAdvanceY = 0;
     fWidth    = 0;
     fHeight   = 0;
     fTop      = 0;
     fLeft     = 0;
 }

 static size_t bits_to_bytes(size_t bits) {
     return (bits + 7) >> 3;
 }

 static size_t format_alignment(SkMask::Format format) {
     switch (format) {
         case SkMask::kBW_Format:
         case SkMask::kA8_Format:
         case SkMask::k3D_Format:
         case SkMask::kSDF_Format:
             return alignof(uint8_t);
         case SkMask::kARGB32_Format:
             return alignof(uint32_t);
         case SkMask::kLCD16_Format:
             return alignof(uint16_t);
         default:
             SK_ABORT("Unknown mask format.");
             break;
     }
     return 0;
 }

 static size_t format_rowbytes(int width, SkMask::Format format) {
     return format == SkMask::kBW_Format ? bits_to_bytes(width)
                                         : width * format_alignment(format);
 }

 size_t SkGlyph::formatAlignment() const {
     return format_alignment(this->maskFormat());
 }

 size_t SkGlyph::allocImage(SkArenaAlloc* alloc) {
     SkASSERT(!this->isEmpty());
     auto size = this->imageSize();
     fImage = alloc->makeBytesAlignedTo(size, this->formatAlignment());

     return size;
 }

 bool SkGlyph::setImage(SkArenaAlloc* alloc, SkScalerContext* scalerContext) {
     if (!this->setImageHasBeenCalled()) {
         // It used to be that getImage() could change the fMaskFormat. Extra checking to make
         // sure there are no regressions.
         SkDEBUGCODE(SkMask::Format oldFormat = this->maskFormat());
         this->allocImage(alloc);
         scalerContext->getImage(*this);
         SkASSERT(oldFormat == this->maskFormat());
         return true;
     }
     return false;
 }

 bool SkGlyph::setImage(SkArenaAlloc* alloc, const void* image) {
     if (!this->setImageHasBeenCalled()) {
         this->allocImage(alloc);
         memcpy(fImage, image, this->imageSize());
         return true;
     }
     return false;
 }

 bool SkGlyph::setMetricsAndImage(SkArenaAlloc* alloc, const SkGlyph& from) {
     if (fImage == nullptr) {
         fAdvanceX = from.fAdvanceX;
         fAdvanceY = from.fAdvanceY;
         fWidth = from.fWidth;
         fHeight = from.fHeight;
         fTop = from.fTop;
         fLeft = from.fLeft;
         fForceBW = from.fForceBW;
         fMaskFormat = from.fMaskFormat;

         // From glyph may not have an image because the glyph is too large.
         return from.fImage != nullptr && this->setImage(alloc, from.image());
     }
     return false;
 }

 size_t SkGlyph::rowBytes() const {
     return format_rowbytes(fWidth, (SkMask::Format)fMaskFormat);
 }

 size_t SkGlyph::rowBytesUsingFormat(SkMask::Format format) const {
     return format_rowbytes(fWidth, format);
 }

 size_t SkGlyph::imageSize() const {
     if (this->isEmpty() || this->imageTooLarge()) { return 0; }

     size_t size = this->rowBytes() * fHeight;

     if (fMaskFormat == SkMask::k3D_Format) {
         size *= 3;
     }

     return size;
 }

 void SkGlyph::installPath(SkArenaAlloc* alloc, const SkPath* path) {
     SkASSERT(fPathData == nullptr);
     SkASSERT(!this->setPathHasBeenCalled());
     fPathData = alloc->make<SkGlyph::PathData>();
     if (path != nullptr) {
         fPathData->fPath = *path;
         fPathData->fPath.updateBoundsCache();
         fPathData->fPath.getGenerationID();
         fPathData->fHasPath = true;
     }
 }

 bool SkGlyph::setPath(SkArenaAlloc* alloc, SkScalerContext* scalerContext) {
     if (!this->setPathHasBeenCalled()) {
         SkPath path;
         if (scalerContext->getPath(this->getPackedID(), &path)) {
             this->installPath(alloc, &path);
         } else {
             this->installPath(alloc, nullptr);
         }
         return this->path() != nullptr;
     }

     return false;
 }

 bool SkGlyph::setPath(SkArenaAlloc* alloc, const SkPath* path) {
     if (!this->setPathHasBeenCalled()) {
         this->installPath(alloc, path);
         return this->path() != nullptr;
     }
     return false;
 }

 const SkPath* SkGlyph::path() const {
     // setPath must have been called previously.
     SkASSERT(this->setPathHasBeenCalled());
     if (fPathData->fHasPath) {
         return &fPathData->fPath;
     }
     return nullptr;
 }

 static std::tuple<SkScalar, SkScalar> calculate_path_gap(
         SkScalar topOffset, SkScalar bottomOffset, const SkPath& path) {

     // Left and Right of an ever expanding gap around the path.
     SkScalar left  = SK_ScalarMax,
              right = SK_ScalarMin;
     auto expandGap = [&left, &right](SkScalar v) {
         left  = std::min(left, v);
         right = std::max(right, v);
     };

     // Handle all the different verbs for the path.
     SkPoint pts[4];
     auto addLine = [&expandGap, &pts](SkScalar offset) {
         SkScalar t = sk_ieee_float_divide(offset - pts[0].fY, pts[1].fY - pts[0].fY);
         if (0 <= t && t < 1) {   // this handles divide by zero above
             expandGap(pts[0].fX + t * (pts[1].fX - pts[0].fX));
         }
     };

     auto addQuad = [&expandGap, &pts](SkScalar offset) {
         SkDQuad quad;
         quad.set(pts);
         double roots[2];
         int count = quad.horizontalIntersect(offset, roots);
         while (--count >= 0) {
             expandGap(quad.ptAtT(roots[count]).asSkPoint().fX);
         }
     };

     auto addCubic = [&expandGap, &pts](SkScalar offset) {
         SkDCubic cubic;
         cubic.set(pts);
         double roots[3];
         int count = cubic.horizontalIntersect(offset, roots);
         while (--count >= 0) {
             expandGap(cubic.ptAtT(roots[count]).asSkPoint().fX);
         }
     };

     // Handle when a verb's points are in the gap between top and bottom.
     auto addPts = [&expandGap, &pts, topOffset, bottomOffset](int ptCount) {
         for (int i = 0; i < ptCount; ++i) {
             if (topOffset < pts[i].fY && pts[i].fY < bottomOffset) {
                 expandGap(pts[i].fX);
             }
         }
     };

     SkPath::Iter iter(path, false);
     SkPath::Verb verb;
     while (SkPath::kDone_Verb != (verb = iter.next(pts))) {
         switch (verb) {
             case SkPath::kMove_Verb: {
                 break;
             }
             case SkPath::kLine_Verb: {
                 addLine(topOffset);
                 addLine(bottomOffset);
                 addPts(2);
                 break;
             }
             case SkPath::kQuad_Verb: {
                 SkScalar quadTop = std::min(std::min(pts[0].fY, pts[1].fY), pts[2].fY);
                 if (bottomOffset < quadTop) { break; }
                 SkScalar quadBottom = std::max(std::max(pts[0].fY, pts[1].fY), pts[2].fY);
                 if (topOffset > quadBottom) { break; }
                 addQuad(topOffset);
                 addQuad(bottomOffset);
                 addPts(3);
                 break;
             }
             case SkPath::kConic_Verb: {
                 SkASSERT(0);  // no support for text composed of conics
                 break;
             }
             case SkPath::kCubic_Verb: {
                 SkScalar quadTop =
                         std::min(std::min(std::min(pts[0].fY, pts[1].fY), pts[2].fY), pts[3].fY);
                 if (bottomOffset < quadTop) { break; }
                 SkScalar quadBottom =
                         std::max(std::max(std::max(pts[0].fY, pts[1].fY), pts[2].fY), pts[3].fY);
                 if (topOffset > quadBottom) { break; }
                 addCubic(topOffset);
                 addCubic(bottomOffset);
                 addPts(4);
                 break;
             }
             case SkPath::kClose_Verb: {
                 break;
             }
             default: {
                 SkASSERT(0);
                 break;
             }
         }
     }

     return std::tie(left, right);
 }

 void SkGlyph::ensureIntercepts(const SkScalar* bounds, SkScalar scale, SkScalar xPos,
                                SkScalar* array, int* count, SkArenaAlloc* alloc) {

     auto offsetResults = [scale, xPos](
             const SkGlyph::Intercept* intercept,SkScalar* array, int* count) {
         if (array) {
             array += *count;
             for (int index = 0; index < 2; index++) {
                 *array++ = intercept->fInterval[index] * scale + xPos;
             }
         }
         *count += 2;
     };

     const SkGlyph::Intercept* match =
             [this](const SkScalar bounds[2]) -> const SkGlyph::Intercept* {
                 if (!fPathData) {
                     return nullptr;
                 }
                 const SkGlyph::Intercept* intercept = fPathData->fIntercept;
                 while (intercept) {
                     if (bounds[0] == intercept->fBounds[0] && bounds[1] == intercept->fBounds[1]) {
                         return intercept;
                     }
                     intercept = intercept->fNext;
                 }
                 return nullptr;
             }(bounds);

     if (match) {
         if (match->fInterval[0] < match->fInterval[1]) {
             offsetResults(match, array, count);
         }
         return;
     }

     SkGlyph::Intercept* intercept = alloc->make<SkGlyph::Intercept>();
     intercept->fNext = fPathData->fIntercept;
     intercept->fBounds[0] = bounds[0];
     intercept->fBounds[1] = bounds[1];
     intercept->fInterval[0] = SK_ScalarMax;
     intercept->fInterval[1] = SK_ScalarMin;
     fPathData->fIntercept = intercept;
     const SkPath* path = &(fPathData->fPath);
     const SkRect& pathBounds = path->getBounds();
     if (pathBounds.fBottom < bounds[0] || bounds[1] < pathBounds.fTop) {
         return;
     }

     std::tie(intercept->fInterval[0], intercept->fInterval[1])
             = calculate_path_gap(bounds[0], bounds[1], *path);

     if (intercept->fInterval[0] >= intercept->fInterval[1]) {
         intercept->fInterval[0] = SK_ScalarMax;
         intercept->fInterval[1] = SK_ScalarMin;
         return;
     }
     offsetResults(intercept, array, count);
 }
	/*
	* Copyright 2018 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/core/SkGlyph.h"

	#include "src/core/SkArenaAlloc.h"
	#include "src/core/SkScalerContext.h"
	#include "src/pathops/SkPathOpsCubic.h"
	#include "src/pathops/SkPathOpsQuad.h"

	constexpr SkIPoint SkPackedGlyphID::kXYFieldMask;

	SkMask SkGlyph::mask() const {
	// getMetrics had to be called.
	SkASSERT(fMaskFormat != MASK_FORMAT_UNKNOWN);

	SkMask mask;
	mask.fImage = (uint8_t*)fImage;
	mask.fBounds.setXYWH(fLeft, fTop, fWidth, fHeight);
	mask.fRowBytes = this->rowBytes();
	mask.fFormat = static_cast<SkMask::Format>(fMaskFormat);
	return mask;
	}

	SkMask SkGlyph::mask(SkPoint position) const {
	SkMask answer = this->mask();
	answer.fBounds.offset(SkScalarFloorToInt(position.x()), SkScalarFloorToInt(position.y()));
	return answer;
	}

	void SkGlyph::zeroMetrics() {
	fAdvanceX = 0;
	fAdvanceY = 0;
	fWidth = 0;
	fHeight = 0;
	fTop = 0;
	fLeft = 0;
	}

	static size_t bits_to_bytes(size_t bits) {
	return (bits + 7) >> 3;
	}

	static size_t format_alignment(SkMask::Format format) {
	switch (format) {
	case SkMask::kBW_Format:
	case SkMask::kA8_Format:
	case SkMask::k3D_Format:
	case SkMask::kSDF_Format:
	return alignof(uint8_t);
	case SkMask::kARGB32_Format:
	return alignof(uint32_t);
	case SkMask::kLCD16_Format:
	return alignof(uint16_t);
	default:
	SK_ABORT("Unknown mask format.");
	break;
	}
	return 0;
	}

	static size_t format_rowbytes(int width, SkMask::Format format) {
	return format == SkMask::kBW_Format ? bits_to_bytes(width)
	: width * format_alignment(format);
	}

	size_t SkGlyph::formatAlignment() const {
	return format_alignment(this->maskFormat());
	}

	size_t SkGlyph::allocImage(SkArenaAlloc* alloc) {
	SkASSERT(!this->isEmpty());
	auto size = this->imageSize();
	fImage = alloc->makeBytesAlignedTo(size, this->formatAlignment());

	return size;
	}

	bool SkGlyph::setImage(SkArenaAlloc* alloc, SkScalerContext* scalerContext) {
	if (!this->setImageHasBeenCalled()) {
	// It used to be that getImage() could change the fMaskFormat. Extra checking to make
	// sure there are no regressions.
	SkDEBUGCODE(SkMask::Format oldFormat = this->maskFormat());
	this->allocImage(alloc);
	scalerContext->getImage(*this);
	SkASSERT(oldFormat == this->maskFormat());
	return true;
	}
	return false;
	}

	bool SkGlyph::setImage(SkArenaAlloc* alloc, const void* image) {
	if (!this->setImageHasBeenCalled()) {
	this->allocImage(alloc);
	memcpy(fImage, image, this->imageSize());
	return true;
	}
	return false;
	}

	bool SkGlyph::setMetricsAndImage(SkArenaAlloc* alloc, const SkGlyph& from) {
	if (fImage == nullptr) {
	fAdvanceX = from.fAdvanceX;
	fAdvanceY = from.fAdvanceY;
	fWidth = from.fWidth;
	fHeight = from.fHeight;
	fTop = from.fTop;
	fLeft = from.fLeft;
	fForceBW = from.fForceBW;
	fMaskFormat = from.fMaskFormat;

	// From glyph may not have an image because the glyph is too large.
	return from.fImage != nullptr && this->setImage(alloc, from.image());
	}
	return false;
	}

	size_t SkGlyph::rowBytes() const {
	return format_rowbytes(fWidth, (SkMask::Format)fMaskFormat);
	}

	size_t SkGlyph::rowBytesUsingFormat(SkMask::Format format) const {
	return format_rowbytes(fWidth, format);
	}

	size_t SkGlyph::imageSize() const {
	if (this->isEmpty() \|\| this->imageTooLarge()) { return 0; }

	size_t size = this->rowBytes() * fHeight;

	if (fMaskFormat == SkMask::k3D_Format) {
	size *= 3;
	}

	return size;
	}

	void SkGlyph::installPath(SkArenaAlloc* alloc, const SkPath* path) {
	SkASSERT(fPathData == nullptr);
	SkASSERT(!this->setPathHasBeenCalled());
	fPathData = alloc->make<SkGlyph::PathData>();
	if (path != nullptr) {
	fPathData->fPath = *path;
	fPathData->fPath.updateBoundsCache();
	fPathData->fPath.getGenerationID();
	fPathData->fHasPath = true;
	}
	}

	bool SkGlyph::setPath(SkArenaAlloc* alloc, SkScalerContext* scalerContext) {
	if (!this->setPathHasBeenCalled()) {
	SkPath path;
	if (scalerContext->getPath(this->getPackedID(), &path)) {
	this->installPath(alloc, &path);
	} else {
	this->installPath(alloc, nullptr);
	}
	return this->path() != nullptr;
	}

	return false;
	}

	bool SkGlyph::setPath(SkArenaAlloc* alloc, const SkPath* path) {
	if (!this->setPathHasBeenCalled()) {
	this->installPath(alloc, path);
	return this->path() != nullptr;
	}
	return false;
	}

	const SkPath* SkGlyph::path() const {
	// setPath must have been called previously.
	SkASSERT(this->setPathHasBeenCalled());
	if (fPathData->fHasPath) {
	return &fPathData->fPath;
	}
	return nullptr;
	}

	static std::tuple<SkScalar, SkScalar> calculate_path_gap(
	SkScalar topOffset, SkScalar bottomOffset, const SkPath& path) {

	// Left and Right of an ever expanding gap around the path.
	SkScalar left = SK_ScalarMax,
	right = SK_ScalarMin;
	auto expandGap = [&left, &right](SkScalar v) {
	left = std::min(left, v);
	right = std::max(right, v);
	};

	// Handle all the different verbs for the path.
	SkPoint pts[4];
	auto addLine = [&expandGap, &pts](SkScalar offset) {
	SkScalar t = sk_ieee_float_divide(offset - pts[0].fY, pts[1].fY - pts[0].fY);
	if (0 <= t && t < 1) { // this handles divide by zero above
	expandGap(pts[0].fX + t * (pts[1].fX - pts[0].fX));
	}
	};

	auto addQuad = [&expandGap, &pts](SkScalar offset) {
	SkDQuad quad;
	quad.set(pts);
	double roots[2];
	int count = quad.horizontalIntersect(offset, roots);
	while (--count >= 0) {
	expandGap(quad.ptAtT(roots[count]).asSkPoint().fX);
	}
	};

	auto addCubic = [&expandGap, &pts](SkScalar offset) {
	SkDCubic cubic;
	cubic.set(pts);
	double roots[3];
	int count = cubic.horizontalIntersect(offset, roots);
	while (--count >= 0) {
	expandGap(cubic.ptAtT(roots[count]).asSkPoint().fX);
	}
	};

	// Handle when a verb's points are in the gap between top and bottom.
	auto addPts = [&expandGap, &pts, topOffset, bottomOffset](int ptCount) {
	for (int i = 0; i < ptCount; ++i) {
	if (topOffset < pts[i].fY && pts[i].fY < bottomOffset) {
	expandGap(pts[i].fX);
	}
	}
	};

	SkPath::Iter iter(path, false);
	SkPath::Verb verb;
	while (SkPath::kDone_Verb != (verb = iter.next(pts))) {
	switch (verb) {
	case SkPath::kMove_Verb: {
	break;
	}
	case SkPath::kLine_Verb: {
	addLine(topOffset);
	addLine(bottomOffset);
	addPts(2);
	break;
	}
	case SkPath::kQuad_Verb: {
	SkScalar quadTop = std::min(std::min(pts[0].fY, pts[1].fY), pts[2].fY);
	if (bottomOffset < quadTop) { break; }
	SkScalar quadBottom = std::max(std::max(pts[0].fY, pts[1].fY), pts[2].fY);
	if (topOffset > quadBottom) { break; }
	addQuad(topOffset);
	addQuad(bottomOffset);
	addPts(3);
	break;
	}
	case SkPath::kConic_Verb: {
	SkASSERT(0); // no support for text composed of conics
	break;
	}
	case SkPath::kCubic_Verb: {
	SkScalar quadTop =
	std::min(std::min(std::min(pts[0].fY, pts[1].fY), pts[2].fY), pts[3].fY);
	if (bottomOffset < quadTop) { break; }
	SkScalar quadBottom =
	std::max(std::max(std::max(pts[0].fY, pts[1].fY), pts[2].fY), pts[3].fY);
	if (topOffset > quadBottom) { break; }
	addCubic(topOffset);
	addCubic(bottomOffset);
	addPts(4);
	break;
	}
	case SkPath::kClose_Verb: {
	break;
	}
	default: {
	SkASSERT(0);
	break;
	}
	}
	}

	return std::tie(left, right);
	}

	void SkGlyph::ensureIntercepts(const SkScalar* bounds, SkScalar scale, SkScalar xPos,
	SkScalar* array, int* count, SkArenaAlloc* alloc) {

	auto offsetResults = [scale, xPos](
	const SkGlyph::Intercept* intercept,SkScalar* array, int* count) {
	if (array) {
	array += *count;
	for (int index = 0; index < 2; index++) {
	array++ = intercept->fInterval[index] scale + xPos;
	}
	}
	*count += 2;
	};

	const SkGlyph::Intercept* match =
	[this](const SkScalar bounds[2]) -> const SkGlyph::Intercept* {
	if (!fPathData) {
	return nullptr;
	}
	const SkGlyph::Intercept* intercept = fPathData->fIntercept;
	while (intercept) {
	if (bounds[0] == intercept->fBounds[0] && bounds[1] == intercept->fBounds[1]) {
	return intercept;
	}
	intercept = intercept->fNext;
	}
	return nullptr;
	}(bounds);

	if (match) {
	if (match->fInterval[0] < match->fInterval[1]) {
	offsetResults(match, array, count);
	}
	return;
	}

	SkGlyph::Intercept* intercept = alloc->make<SkGlyph::Intercept>();
	intercept->fNext = fPathData->fIntercept;
	intercept->fBounds[0] = bounds[0];
	intercept->fBounds[1] = bounds[1];
	intercept->fInterval[0] = SK_ScalarMax;
	intercept->fInterval[1] = SK_ScalarMin;
	fPathData->fIntercept = intercept;
	const SkPath* path = &(fPathData->fPath);
	const SkRect& pathBounds = path->getBounds();
	if (pathBounds.fBottom < bounds[0] \|\| bounds[1] < pathBounds.fTop) {
	return;
	}

	std::tie(intercept->fInterval[0], intercept->fInterval[1])
	= calculate_path_gap(bounds[0], bounds[1], *path);

	if (intercept->fInterval[0] >= intercept->fInterval[1]) {
	intercept->fInterval[0] = SK_ScalarMax;
	intercept->fInterval[1] = SK_ScalarMin;
	return;
	}
	offsetResults(intercept, array, count);
	}