src/utils/win/SkDWriteGeometrySink.cpp - skia - Git at Google

 /*
  * Copyright 2012 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "include/core/SkTypes.h"
 #if defined(SK_BUILD_FOR_WIN)

 #include "include/core/SkPath.h"
 #include "src/utils/SkFloatUtils.h"
 #include "src/utils/win/SkDWriteGeometrySink.h"
 #include "src/utils/win/SkObjBase.h"

 #include <dwrite.h>
 #include <d2d1.h>

 SkDWriteGeometrySink::SkDWriteGeometrySink(SkPath* path)
     : fRefCount{1}, fPath{path}, fStarted{false}, fCurrent{0,0} {}

 SkDWriteGeometrySink::~SkDWriteGeometrySink() { }

 SK_STDMETHODIMP SkDWriteGeometrySink::QueryInterface(REFIID iid, void **object) {
     if (nullptr == object) {
         return E_INVALIDARG;
     }
     if (iid == __uuidof(IUnknown) || iid == __uuidof(IDWriteGeometrySink)) {
         *object = static_cast<IDWriteGeometrySink*>(this);
         this->AddRef();
         return S_OK;
     } else {
         *object = nullptr;
         return E_NOINTERFACE;
     }
 }

 SK_STDMETHODIMP_(ULONG) SkDWriteGeometrySink::AddRef(void) {
     return static_cast<ULONG>(InterlockedIncrement(&fRefCount));
 }

 SK_STDMETHODIMP_(ULONG) SkDWriteGeometrySink::Release(void) {
     ULONG res = static_cast<ULONG>(InterlockedDecrement(&fRefCount));
     if (0 == res) {
         delete this;
     }
     return res;
 }

 SK_STDMETHODIMP_(void) SkDWriteGeometrySink::SetFillMode(D2D1_FILL_MODE fillMode) {
     switch (fillMode) {
     case D2D1_FILL_MODE_ALTERNATE:
         fPath->setFillType(SkPathFillType::kEvenOdd);
         break;
     case D2D1_FILL_MODE_WINDING:
         fPath->setFillType(SkPathFillType::kWinding);
         break;
     default:
         SkDEBUGFAIL("Unknown D2D1_FILL_MODE.");
         break;
     }
 }

 SK_STDMETHODIMP_(void) SkDWriteGeometrySink::SetSegmentFlags(D2D1_PATH_SEGMENT vertexFlags) {
     if (vertexFlags == D2D1_PATH_SEGMENT_NONE || vertexFlags == D2D1_PATH_SEGMENT_FORCE_ROUND_LINE_JOIN) {
         SkDEBUGFAIL("Invalid D2D1_PATH_SEGMENT value.");
     }
 }

 SK_STDMETHODIMP_(void) SkDWriteGeometrySink::BeginFigure(D2D1_POINT_2F startPoint, D2D1_FIGURE_BEGIN figureBegin) {
     if (figureBegin == D2D1_FIGURE_BEGIN_HOLLOW) {
         SkDEBUGFAIL("Invalid D2D1_FIGURE_BEGIN value.");
     }
     fStarted = false;
     fCurrent = startPoint;
 }

 SK_STDMETHODIMP_(void) SkDWriteGeometrySink::AddLines(const D2D1_POINT_2F *points, UINT pointsCount) {
     for (const D2D1_POINT_2F *end = &points[pointsCount]; points < end; ++points) {
         if (this->currentIsNot(*points)) {
             this->goingTo(*points);
             fPath->lineTo(points->x, points->y);
         }
     }
 }

 static bool approximately_equal(float a, float b) {
     const SkFloatingPoint<float, 10> lhs(a), rhs(b);
     return lhs.AlmostEquals(rhs);
 }

 typedef struct {
     float x;
     float y;
 } Cubic[4], Point;

 static bool check_quadratic(const Cubic& cubic, Point& quadraticP1) {
     float dx10 = cubic[1].x - cubic[0].x;
     float dx23 = cubic[2].x - cubic[3].x;
     float midX = cubic[0].x + dx10 * 3 / 2;
     //NOTE: !approximately_equal(midX - cubic[3].x, dx23 * 3 / 2)
     //does not work as subnormals get in between the left side and 0.
     if (!approximately_equal(midX, (dx23 * 3 / 2) + cubic[3].x)) {
         return false;
     }
     float dy10 = cubic[1].y - cubic[0].y;
     float dy23 = cubic[2].y - cubic[3].y;
     float midY = cubic[0].y + dy10 * 3 / 2;
     if (!approximately_equal(midY, (dy23 * 3 / 2) + cubic[3].y)) {
         return false;
     }
     quadraticP1 = {midX, midY};
     return true;
 }

 SK_STDMETHODIMP_(void) SkDWriteGeometrySink::AddBeziers(const D2D1_BEZIER_SEGMENT *beziers, UINT beziersCount) {
     for (const D2D1_BEZIER_SEGMENT *end = &beziers[beziersCount]; beziers < end; ++beziers) {
         if (this->currentIsNot(beziers->point1) ||
             this->currentIsNot(beziers->point2) ||
             this->currentIsNot(beziers->point3))
         {
             Cubic cubic = { {        fCurrent.x,        fCurrent.y },
                             { beziers->point1.x, beziers->point1.y },
                             { beziers->point2.x, beziers->point2.y },
                             { beziers->point3.x, beziers->point3.y }, };
             this->goingTo(beziers->point3);
             Point quadraticP1;
             if (check_quadratic(cubic, quadraticP1)) {
                 fPath->quadTo(    quadraticP1.x,     quadraticP1.y,
                               beziers->point3.x, beziers->point3.y);
             } else {
                 fPath->cubicTo(beziers->point1.x, beziers->point1.y,
                                beziers->point2.x, beziers->point2.y,
                                beziers->point3.x, beziers->point3.y);
             }
         }
     }
 }

 SK_STDMETHODIMP_(void) SkDWriteGeometrySink::EndFigure(D2D1_FIGURE_END figureEnd) {
     if (fStarted) {
         fPath->close();
     }
 }

 SK_STDMETHODIMP SkDWriteGeometrySink::Close() {
     return S_OK;
 }

 HRESULT SkDWriteGeometrySink::Create(SkPath* path, IDWriteGeometrySink** geometryToPath) {
     *geometryToPath = new SkDWriteGeometrySink(path);
     return S_OK;
 }

 #endif//defined(SK_BUILD_FOR_WIN)
	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "include/core/SkTypes.h"
	#if defined(SK_BUILD_FOR_WIN)

	#include "include/core/SkPath.h"
	#include "src/utils/SkFloatUtils.h"
	#include "src/utils/win/SkDWriteGeometrySink.h"
	#include "src/utils/win/SkObjBase.h"

	#include <dwrite.h>
	#include <d2d1.h>

	SkDWriteGeometrySink::SkDWriteGeometrySink(SkPath* path)
	: fRefCount{1}, fPath{path}, fStarted{false}, fCurrent{0,0} {}

	SkDWriteGeometrySink::~SkDWriteGeometrySink() { }

	SK_STDMETHODIMP SkDWriteGeometrySink::QueryInterface(REFIID iid, void **object) {
	if (nullptr == object) {
	return E_INVALIDARG;
	}
	if (iid == __uuidof(IUnknown) \|\| iid == __uuidof(IDWriteGeometrySink)) {
	object = static_cast<IDWriteGeometrySink>(this);
	this->AddRef();
	return S_OK;
	} else {
	*object = nullptr;
	return E_NOINTERFACE;
	}
	}

	SK_STDMETHODIMP_(ULONG) SkDWriteGeometrySink::AddRef(void) {
	return static_cast<ULONG>(InterlockedIncrement(&fRefCount));
	}

	SK_STDMETHODIMP_(ULONG) SkDWriteGeometrySink::Release(void) {
	ULONG res = static_cast<ULONG>(InterlockedDecrement(&fRefCount));
	if (0 == res) {
	delete this;
	}
	return res;
	}

	SK_STDMETHODIMP_(void) SkDWriteGeometrySink::SetFillMode(D2D1_FILL_MODE fillMode) {
	switch (fillMode) {
	case D2D1_FILL_MODE_ALTERNATE:
	fPath->setFillType(SkPathFillType::kEvenOdd);
	break;
	case D2D1_FILL_MODE_WINDING:
	fPath->setFillType(SkPathFillType::kWinding);
	break;
	default:
	SkDEBUGFAIL("Unknown D2D1_FILL_MODE.");
	break;
	}
	}

	SK_STDMETHODIMP_(void) SkDWriteGeometrySink::SetSegmentFlags(D2D1_PATH_SEGMENT vertexFlags) {
	if (vertexFlags == D2D1_PATH_SEGMENT_NONE \|\| vertexFlags == D2D1_PATH_SEGMENT_FORCE_ROUND_LINE_JOIN) {
	SkDEBUGFAIL("Invalid D2D1_PATH_SEGMENT value.");
	}
	}

	SK_STDMETHODIMP_(void) SkDWriteGeometrySink::BeginFigure(D2D1_POINT_2F startPoint, D2D1_FIGURE_BEGIN figureBegin) {
	if (figureBegin == D2D1_FIGURE_BEGIN_HOLLOW) {
	SkDEBUGFAIL("Invalid D2D1_FIGURE_BEGIN value.");
	}
	fStarted = false;
	fCurrent = startPoint;
	}

	SK_STDMETHODIMP_(void) SkDWriteGeometrySink::AddLines(const D2D1_POINT_2F *points, UINT pointsCount) {
	for (const D2D1_POINT_2F *end = &points[pointsCount]; points < end; ++points) {
	if (this->currentIsNot(*points)) {
	this->goingTo(*points);
	fPath->lineTo(points->x, points->y);
	}
	}
	}

	static bool approximately_equal(float a, float b) {
	const SkFloatingPoint<float, 10> lhs(a), rhs(b);
	return lhs.AlmostEquals(rhs);
	}

	typedef struct {
	float x;
	float y;
	} Cubic[4], Point;

	static bool check_quadratic(const Cubic& cubic, Point& quadraticP1) {
	float dx10 = cubic[1].x - cubic[0].x;
	float dx23 = cubic[2].x - cubic[3].x;
	float midX = cubic[0].x + dx10 * 3 / 2;
	//NOTE: !approximately_equal(midX - cubic[3].x, dx23 * 3 / 2)
	//does not work as subnormals get in between the left side and 0.
	if (!approximately_equal(midX, (dx23 * 3 / 2) + cubic[3].x)) {
	return false;
	}
	float dy10 = cubic[1].y - cubic[0].y;
	float dy23 = cubic[2].y - cubic[3].y;
	float midY = cubic[0].y + dy10 * 3 / 2;
	if (!approximately_equal(midY, (dy23 * 3 / 2) + cubic[3].y)) {
	return false;
	}
	quadraticP1 = {midX, midY};
	return true;
	}

	SK_STDMETHODIMP_(void) SkDWriteGeometrySink::AddBeziers(const D2D1_BEZIER_SEGMENT *beziers, UINT beziersCount) {
	for (const D2D1_BEZIER_SEGMENT *end = &beziers[beziersCount]; beziers < end; ++beziers) {
	if (this->currentIsNot(beziers->point1) \|\|
	this->currentIsNot(beziers->point2) \|\|
	this->currentIsNot(beziers->point3))
	{
	Cubic cubic = { { fCurrent.x, fCurrent.y },
	{ beziers->point1.x, beziers->point1.y },
	{ beziers->point2.x, beziers->point2.y },
	{ beziers->point3.x, beziers->point3.y }, };
	this->goingTo(beziers->point3);
	Point quadraticP1;
	if (check_quadratic(cubic, quadraticP1)) {
	fPath->quadTo( quadraticP1.x, quadraticP1.y,
	beziers->point3.x, beziers->point3.y);
	} else {
	fPath->cubicTo(beziers->point1.x, beziers->point1.y,
	beziers->point2.x, beziers->point2.y,
	beziers->point3.x, beziers->point3.y);
	}
	}
	}
	}

	SK_STDMETHODIMP_(void) SkDWriteGeometrySink::EndFigure(D2D1_FIGURE_END figureEnd) {
	if (fStarted) {
	fPath->close();
	}
	}

	SK_STDMETHODIMP SkDWriteGeometrySink::Close() {
	return S_OK;
	}

	HRESULT SkDWriteGeometrySink::Create(SkPath* path, IDWriteGeometrySink** geometryToPath) {
	*geometryToPath = new SkDWriteGeometrySink(path);
	return S_OK;
	}

	#endif//defined(SK_BUILD_FOR_WIN)