third_party/skia_next/third_party/skia/src/gpu/geometry/GrPathUtils.h - cobalt - Git at Google

 /*
  * Copyright 2011 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrPathUtils_DEFINED
 #define GrPathUtils_DEFINED

 #include "include/core/SkRect.h"
 #include "include/private/SkTArray.h"
 #include "src/core/SkGeometry.h"
 #include "src/core/SkPathPriv.h"
 #include "src/gpu/BufferWriter.h"
 #include "src/gpu/GrVx.h"

 class SkMatrix;

 /**
  *  Utilities for evaluating paths.
  */
 namespace GrPathUtils {

 // When tessellating curved paths into linear segments, this defines the maximum distance in screen
 // space which a segment may deviate from the mathematically correct value. Above this value, the
 // segment will be subdivided.
 // This value was chosen to approximate the supersampling accuracy of the raster path (16 samples,
 // or one quarter pixel).
 static const SkScalar kDefaultTolerance = SkDoubleToScalar(0.25);

 // We guarantee that no quad or cubic will ever produce more than this many points
 static const int kMaxPointsPerCurve = 1 << 10;

 // Very small tolerances will be increased to a minimum threshold value, to avoid division problems
 // in subsequent math.
 SkScalar scaleToleranceToSrc(SkScalar devTol,
                              const SkMatrix& viewM,
                              const SkRect& pathBounds);

 // Returns the maximum number of vertices required when using a recursive chopping algorithm to
 // linearize the quadratic Bezier (e.g. generateQuadraticPoints below) to the given error tolerance.
 // This is a power of two and will not exceed kMaxPointsPerCurve.
 uint32_t quadraticPointCount(const SkPoint points[], SkScalar tol);

 // Returns the number of points actually written to 'points', will be <= to 'pointsLeft'
 uint32_t generateQuadraticPoints(const SkPoint& p0,
                                  const SkPoint& p1,
                                  const SkPoint& p2,
                                  SkScalar tolSqd,
                                  SkPoint** points,
                                  uint32_t pointsLeft);

 // Returns the maximum number of vertices required when using a recursive chopping algorithm to
 // linearize the cubic Bezier (e.g. generateQuadraticPoints below) to the given error tolerance.
 // This is a power of two and will not exceed kMaxPointsPerCurve.
 uint32_t cubicPointCount(const SkPoint points[], SkScalar tol);

 // Returns the number of points actually written to 'points', will be <= to 'pointsLeft'
 uint32_t generateCubicPoints(const SkPoint& p0,
                              const SkPoint& p1,
                              const SkPoint& p2,
                              const SkPoint& p3,
                              SkScalar tolSqd,
                              SkPoint** points,
                              uint32_t pointsLeft);

 // A 2x3 matrix that goes from the 2d space coordinates to UV space where u^2-v = 0 specifies the
 // quad. The matrix is determined by the control points of the quadratic.
 class QuadUVMatrix {
 public:
     QuadUVMatrix() {}
     // Initialize the matrix from the control pts
     QuadUVMatrix(const SkPoint controlPts[3]) { this->set(controlPts); }
     void set(const SkPoint controlPts[3]);

     /**
      * Applies the matrix to vertex positions to compute UV coords.
      *
      * vertices is a pointer to the first vertex.
      * vertexCount is the number of vertices.
      * stride is the size of each vertex.
      * uvOffset is the offset of the UV values within each vertex.
      */
     void apply(void* vertices, int vertexCount, size_t stride, size_t uvOffset) const {
         intptr_t xyPtr = reinterpret_cast<intptr_t>(vertices);
         intptr_t uvPtr = reinterpret_cast<intptr_t>(vertices) + uvOffset;
         float sx = fM[0];
         float kx = fM[1];
         float tx = fM[2];
         float ky = fM[3];
         float sy = fM[4];
         float ty = fM[5];
         for (int i = 0; i < vertexCount; ++i) {
             const SkPoint* xy = reinterpret_cast<const SkPoint*>(xyPtr);
             SkPoint* uv = reinterpret_cast<SkPoint*>(uvPtr);
             uv->fX = sx * xy->fX + kx * xy->fY + tx;
             uv->fY = ky * xy->fX + sy * xy->fY + ty;
             xyPtr += stride;
             uvPtr += stride;
         }
     }
 private:
     float fM[6];
 };

 // Input is 3 control points and a weight for a bezier conic. Calculates the three linear
 // functionals (K,L,M) that represent the implicit equation of the conic, k^2 - lm.
 //
 // Output: klm holds the linear functionals K,L,M as row vectors:
 //
 //     | ..K.. |   | x |      | k |
 //     | ..L.. | * | y |  ==  | l |
 //     | ..M.. |   | 1 |      | m |
 //
 void getConicKLM(const SkPoint p[3], const SkScalar weight, SkMatrix* klm);

 // Converts a cubic into a sequence of quads. If working in device space use tolScale = 1, otherwise
 // set based on stretchiness of the matrix. The result is sets of 3 points in quads. This will
 // preserve the starting and ending tangent vectors (modulo FP precision).
 void convertCubicToQuads(const SkPoint p[4],
                          SkScalar tolScale,
                          SkTArray<SkPoint, true>* quads);

 // When we approximate a cubic {a,b,c,d} with a quadratic we may have to ensure that the new control
 // point lies between the lines ab and cd. The convex path renderer requires this. It starts with a
 // path where all the control points taken together form a convex polygon. It relies on this
 // property and the quadratic approximation of cubics step cannot alter it. This variation enforces
 // this constraint. The cubic must be simple and dir must specify the orientation of the contour
 // containing the cubic.
 void convertCubicToQuadsConstrainToTangents(const SkPoint p[4],
                                             SkScalar tolScale,
                                             SkPathFirstDirection dir,
                                             SkTArray<SkPoint, true>* quads);

 // Converts the given line to a cubic bezier.
 // NOTE: This method interpolates at 1/3 and 2/3, but if suitable in context, the cubic
 // {p0, p0, p1, p1} may also work.
 inline void writeLineAsCubic(SkPoint startPt, SkPoint endPt, skgpu::VertexWriter* writer) {
     using grvx::float2; using skvx::bit_pun;
     float2 p0 = bit_pun<float2>(startPt);
     float2 p1 = bit_pun<float2>(endPt);
     float2 v = (p1 - p0) * (1/3.f);
     *writer << p0 << (p0 + v) << (p1 - v) << p1;
 }

 // Converts the given quadratic bezier to a cubic.
 inline void writeQuadAsCubic(const SkPoint p[3], skgpu::VertexWriter* writer) {
     using grvx::float2; using skvx::bit_pun;
     float2 p0 = bit_pun<float2>(p[0]);
     float2 p1 = bit_pun<float2>(p[1]);
     float2 p2 = bit_pun<float2>(p[2]);
     float2 c = p1 * (2/3.f);
     *writer << p0 << (p0*(1/3.f) + c) << (p2 * (1/3.f) + c) << p2;
 }
 inline void convertQuadToCubic(const SkPoint p[3], SkPoint out[4]) {
     skgpu::VertexWriter writer(out);
     writeQuadAsCubic(p, &writer);
 }

 // Finds 0, 1, or 2 T values at which to chop the given curve in order to guarantee the resulting
 // cubics are convex and rotate no more than 180 degrees.
 //
 //   - If the cubic is "serpentine", then the T values are any inflection points in [0 < T < 1].
 //   - If the cubic is linear, then the T values are any 180-degree cusp points in [0 < T < 1].
 //   - Otherwise the T value is the point at which rotation reaches 180 degrees, iff in [0 < T < 1].
 //
 // 'areCusps' is set to true if the chop point occurred at a cusp (within tolerance), or if the chop
 // point(s) occurred at 180-degree turnaround points on a degenerate flat line.
 int findCubicConvex180Chops(const SkPoint[], float T[2], bool* areCusps);

 // Returns true if the given conic (or quadratic) has a cusp point. The w value is not necessary in
 // determining this. If there is a cusp, it can be found at the midtangent.
 inline bool conicHasCusp(const SkPoint p[3]) {
     SkVector a = p[1] - p[0];
     SkVector b = p[2] - p[1];
     // A conic of any class can only have a cusp if it is a degenerate flat line with a 180 degree
     // turnarund. To detect this, the beginning and ending tangents must be parallel
     // (a.cross(b) == 0) and pointing in opposite directions (a.dot(b) < 0).
     return a.cross(b) == 0 && a.dot(b) < 0;
 }

 }  // namespace GrPathUtils

 #endif
	/*
	* Copyright 2011 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrPathUtils_DEFINED
	#define GrPathUtils_DEFINED

	#include "include/core/SkRect.h"
	#include "include/private/SkTArray.h"
	#include "src/core/SkGeometry.h"
	#include "src/core/SkPathPriv.h"
	#include "src/gpu/BufferWriter.h"
	#include "src/gpu/GrVx.h"

	class SkMatrix;

	/**
	* Utilities for evaluating paths.
	*/
	namespace GrPathUtils {

	// When tessellating curved paths into linear segments, this defines the maximum distance in screen
	// space which a segment may deviate from the mathematically correct value. Above this value, the
	// segment will be subdivided.
	// This value was chosen to approximate the supersampling accuracy of the raster path (16 samples,
	// or one quarter pixel).
	static const SkScalar kDefaultTolerance = SkDoubleToScalar(0.25);

	// We guarantee that no quad or cubic will ever produce more than this many points
	static const int kMaxPointsPerCurve = 1 << 10;

	// Very small tolerances will be increased to a minimum threshold value, to avoid division problems
	// in subsequent math.
	SkScalar scaleToleranceToSrc(SkScalar devTol,
	const SkMatrix& viewM,
	const SkRect& pathBounds);

	// Returns the maximum number of vertices required when using a recursive chopping algorithm to
	// linearize the quadratic Bezier (e.g. generateQuadraticPoints below) to the given error tolerance.
	// This is a power of two and will not exceed kMaxPointsPerCurve.
	uint32_t quadraticPointCount(const SkPoint points[], SkScalar tol);

	// Returns the number of points actually written to 'points', will be <= to 'pointsLeft'
	uint32_t generateQuadraticPoints(const SkPoint& p0,
	const SkPoint& p1,
	const SkPoint& p2,
	SkScalar tolSqd,
	SkPoint** points,
	uint32_t pointsLeft);

	// Returns the maximum number of vertices required when using a recursive chopping algorithm to
	// linearize the cubic Bezier (e.g. generateQuadraticPoints below) to the given error tolerance.
	// This is a power of two and will not exceed kMaxPointsPerCurve.
	uint32_t cubicPointCount(const SkPoint points[], SkScalar tol);

	// Returns the number of points actually written to 'points', will be <= to 'pointsLeft'
	uint32_t generateCubicPoints(const SkPoint& p0,
	const SkPoint& p1,
	const SkPoint& p2,
	const SkPoint& p3,
	SkScalar tolSqd,
	SkPoint** points,
	uint32_t pointsLeft);

	// A 2x3 matrix that goes from the 2d space coordinates to UV space where u^2-v = 0 specifies the
	// quad. The matrix is determined by the control points of the quadratic.
	class QuadUVMatrix {
	public:
	QuadUVMatrix() {}
	// Initialize the matrix from the control pts
	QuadUVMatrix(const SkPoint controlPts[3]) { this->set(controlPts); }
	void set(const SkPoint controlPts[3]);

	/**
	* Applies the matrix to vertex positions to compute UV coords.
	*
	* vertices is a pointer to the first vertex.
	* vertexCount is the number of vertices.
	* stride is the size of each vertex.
	* uvOffset is the offset of the UV values within each vertex.
	*/
	void apply(void* vertices, int vertexCount, size_t stride, size_t uvOffset) const {
	intptr_t xyPtr = reinterpret_cast<intptr_t>(vertices);
	intptr_t uvPtr = reinterpret_cast<intptr_t>(vertices) + uvOffset;
	float sx = fM[0];
	float kx = fM[1];
	float tx = fM[2];
	float ky = fM[3];
	float sy = fM[4];
	float ty = fM[5];
	for (int i = 0; i < vertexCount; ++i) {
	const SkPoint* xy = reinterpret_cast<const SkPoint*>(xyPtr);
	SkPoint* uv = reinterpret_cast<SkPoint*>(uvPtr);
	uv->fX = sx * xy->fX + kx * xy->fY + tx;
	uv->fY = ky * xy->fX + sy * xy->fY + ty;
	xyPtr += stride;
	uvPtr += stride;
	}
	}
	private:
	float fM[6];
	};

	// Input is 3 control points and a weight for a bezier conic. Calculates the three linear
	// functionals (K,L,M) that represent the implicit equation of the conic, k^2 - lm.
	//
	// Output: klm holds the linear functionals K,L,M as row vectors:
	//
	// \| ..K.. \| \| x \| \| k \|
	// \| ..L.. \| * \| y \| == \| l \|
	// \| ..M.. \| \| 1 \| \| m \|
	//
	void getConicKLM(const SkPoint p[3], const SkScalar weight, SkMatrix* klm);

	// Converts a cubic into a sequence of quads. If working in device space use tolScale = 1, otherwise
	// set based on stretchiness of the matrix. The result is sets of 3 points in quads. This will
	// preserve the starting and ending tangent vectors (modulo FP precision).
	void convertCubicToQuads(const SkPoint p[4],
	SkScalar tolScale,
	SkTArray<SkPoint, true>* quads);

	// When we approximate a cubic {a,b,c,d} with a quadratic we may have to ensure that the new control
	// point lies between the lines ab and cd. The convex path renderer requires this. It starts with a
	// path where all the control points taken together form a convex polygon. It relies on this
	// property and the quadratic approximation of cubics step cannot alter it. This variation enforces
	// this constraint. The cubic must be simple and dir must specify the orientation of the contour
	// containing the cubic.
	void convertCubicToQuadsConstrainToTangents(const SkPoint p[4],
	SkScalar tolScale,
	SkPathFirstDirection dir,
	SkTArray<SkPoint, true>* quads);

	// Converts the given line to a cubic bezier.
	// NOTE: This method interpolates at 1/3 and 2/3, but if suitable in context, the cubic
	// {p0, p0, p1, p1} may also work.
	inline void writeLineAsCubic(SkPoint startPt, SkPoint endPt, skgpu::VertexWriter* writer) {
	using grvx::float2; using skvx::bit_pun;
	float2 p0 = bit_pun<float2>(startPt);
	float2 p1 = bit_pun<float2>(endPt);
	float2 v = (p1 - p0) * (1/3.f);
	*writer << p0 << (p0 + v) << (p1 - v) << p1;
	}

	// Converts the given quadratic bezier to a cubic.
	inline void writeQuadAsCubic(const SkPoint p[3], skgpu::VertexWriter* writer) {
	using grvx::float2; using skvx::bit_pun;
	float2 p0 = bit_pun<float2>(p[0]);
	float2 p1 = bit_pun<float2>(p[1]);
	float2 p2 = bit_pun<float2>(p[2]);
	float2 c = p1 * (2/3.f);
	writer << p0 << (p0(1/3.f) + c) << (p2 * (1/3.f) + c) << p2;
	}
	inline void convertQuadToCubic(const SkPoint p[3], SkPoint out[4]) {
	skgpu::VertexWriter writer(out);
	writeQuadAsCubic(p, &writer);
	}

	// Finds 0, 1, or 2 T values at which to chop the given curve in order to guarantee the resulting
	// cubics are convex and rotate no more than 180 degrees.
	//
	// - If the cubic is "serpentine", then the T values are any inflection points in [0 < T < 1].
	// - If the cubic is linear, then the T values are any 180-degree cusp points in [0 < T < 1].
	// - Otherwise the T value is the point at which rotation reaches 180 degrees, iff in [0 < T < 1].
	//
	// 'areCusps' is set to true if the chop point occurred at a cusp (within tolerance), or if the chop
	// point(s) occurred at 180-degree turnaround points on a degenerate flat line.
	int findCubicConvex180Chops(const SkPoint[], float T[2], bool* areCusps);

	// Returns true if the given conic (or quadratic) has a cusp point. The w value is not necessary in
	// determining this. If there is a cusp, it can be found at the midtangent.
	inline bool conicHasCusp(const SkPoint p[3]) {
	SkVector a = p[1] - p[0];
	SkVector b = p[2] - p[1];
	// A conic of any class can only have a cusp if it is a degenerate flat line with a 180 degree
	// turnarund. To detect this, the beginning and ending tangents must be parallel
	// (a.cross(b) == 0) and pointing in opposite directions (a.dot(b) < 0).
	return a.cross(b) == 0 && a.dot(b) < 0;
	}

	} // namespace GrPathUtils

	#endif