src/utils/SkPolyUtils.h - platform/external/skia - Gitiles

 /*
  * Copyright 2017 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkOffsetPolygon_DEFINED
 #define SkOffsetPolygon_DEFINED

 #include <functional>

 #include "include/core/SkPoint.h"
 #include "include/private/SkTDArray.h"

 struct SkRect;

 /**
  * Generates a polygon that is inset a constant from the boundary of a given convex polygon.
  *
  * @param inputPolygonVerts  Array of points representing the vertices of the original polygon.
  *  It should be convex and have no coincident points.
  * @param inputPolygonSize  Number of vertices in the original polygon.
  * @param inset  How far we wish to inset the polygon. This should be a positive value.
  * @param insetPolygon  The resulting inset polygon, if any.
  * @return true if an inset polygon exists, false otherwise.
  */
 bool SkInsetConvexPolygon(const SkPoint* inputPolygonVerts, int inputPolygonSize,
                           SkScalar inset, SkTDArray<SkPoint>* insetPolygon);

 /**
  * Generates a simple polygon (if possible) that is offset a constant distance from the boundary
  * of a given simple polygon.
  * The input polygon must be simple and have no coincident vertices or collinear edges.
  *
  * @param inputPolygonVerts  Array of points representing the vertices of the original polygon.
  * @param inputPolygonSize  Number of vertices in the original polygon.
  * @param bounds Bounding rectangle for the original polygon.
  * @param offset How far we wish to offset the polygon.
  *   Positive values indicate insetting, negative values outsetting.
  * @param offsetPolgon  The resulting offset polygon, if any.
  * @param polygonIndices  The indices of the original polygon that map to the new one.
  * @return true if an offset simple polygon exists, false otherwise.
  */
 bool SkOffsetSimplePolygon(const SkPoint* inputPolygonVerts, int inputPolygonSize,
                            const SkRect& bounds, SkScalar offset, SkTDArray<SkPoint>* offsetPolygon,
                            SkTDArray<int>* polygonIndices = nullptr);

 /**
  * Compute the number of points needed for a circular join when offsetting a vertex.
  * The lengths of offset0 and offset1 don't have to equal |offset| -- only the direction matters.
  * The segment lengths will be approximately four pixels.
  *
  * @param offset0  Starting offset vector direction.
  * @param offset1  Ending offset vector direction.
  * @param offset  Offset value (can be negative).
  * @param rotSin  Sine of rotation delta per step.
  * @param rotCos  Cosine of rotation delta per step.
  * @param n  Number of steps to fill out the arc.
  * @return true for success, false otherwise
  */
 bool SkComputeRadialSteps(const SkVector& offset0, const SkVector& offset1, SkScalar offset,
                           SkScalar* rotSin, SkScalar* rotCos, int* n);

 /**
  * Determine winding direction for a polygon.
  * The input polygon must be simple or the result will be meaningless.
  *
  * @param polygonVerts  Array of points representing the vertices of the polygon.
  * @param polygonSize  Number of vertices in the polygon.
  * @return 1 for cw, -1 for ccw, and 0 if zero signed area (either degenerate or self-intersecting).
  *         The y-axis is assumed to be pointing down.
  */
 int SkGetPolygonWinding(const SkPoint* polygonVerts, int polygonSize);

 /**
  * Determine whether a polygon is convex or not.
  *
  * @param polygonVerts  Array of points representing the vertices of the polygon.
  * @param polygonSize  Number of vertices in the polygon.
  * @return true if the polygon is convex, false otherwise.
  */
 bool SkIsConvexPolygon(const SkPoint* polygonVerts, int polygonSize);

 /**
  * Determine whether a polygon is simple (i.e., not self-intersecting) or not.
  * The input polygon must have no coincident vertices or the test will fail.
  *
  * @param polygonVerts  Array of points representing the vertices of the polygon.
  * @param polygonSize  Number of vertices in the polygon.
  * @return true if the polygon is simple, false otherwise.
  */
  bool SkIsSimplePolygon(const SkPoint* polygonVerts, int polygonSize);

  /**
   * Compute indices to triangulate the given polygon.
   * The input polygon must be simple (i.e. it is not self-intersecting)
   * and have no coincident vertices or collinear edges.
   *
   * @param polygonVerts  Array of points representing the vertices of the polygon.
   * @param indexMap Mapping from index in the given array to the final index in the triangulation.
   * @param polygonSize  Number of vertices in the polygon.
   * @param triangleIndices  Indices of the resulting triangulation.
   * @return true if successful, false otherwise.
   */
  bool SkTriangulateSimplePolygon(const SkPoint* polygonVerts, uint16_t* indexMap, int polygonSize,
                                  SkTDArray<uint16_t>* triangleIndices);

 // Experiment: doesn't handle really big floats (returns false), always returns true for count <= 3
 bool SkIsPolyConvex_experimental(const SkPoint[], int count);

 #endif
	/*
	* Copyright 2017 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkOffsetPolygon_DEFINED
	#define SkOffsetPolygon_DEFINED

	#include <functional>

	#include "include/core/SkPoint.h"
	#include "include/private/SkTDArray.h"

	struct SkRect;

	/**
	* Generates a polygon that is inset a constant from the boundary of a given convex polygon.
	*
	* @param inputPolygonVerts Array of points representing the vertices of the original polygon.
	* It should be convex and have no coincident points.
	* @param inputPolygonSize Number of vertices in the original polygon.
	* @param inset How far we wish to inset the polygon. This should be a positive value.
	* @param insetPolygon The resulting inset polygon, if any.
	* @return true if an inset polygon exists, false otherwise.
	*/
	bool SkInsetConvexPolygon(const SkPoint* inputPolygonVerts, int inputPolygonSize,
	SkScalar inset, SkTDArray<SkPoint>* insetPolygon);

	/**
	* Generates a simple polygon (if possible) that is offset a constant distance from the boundary
	* of a given simple polygon.
	* The input polygon must be simple and have no coincident vertices or collinear edges.
	*
	* @param inputPolygonVerts Array of points representing the vertices of the original polygon.
	* @param inputPolygonSize Number of vertices in the original polygon.
	* @param bounds Bounding rectangle for the original polygon.
	* @param offset How far we wish to offset the polygon.
	* Positive values indicate insetting, negative values outsetting.
	* @param offsetPolgon The resulting offset polygon, if any.
	* @param polygonIndices The indices of the original polygon that map to the new one.
	* @return true if an offset simple polygon exists, false otherwise.
	*/
	bool SkOffsetSimplePolygon(const SkPoint* inputPolygonVerts, int inputPolygonSize,
	const SkRect& bounds, SkScalar offset, SkTDArray<SkPoint>* offsetPolygon,
	SkTDArray<int>* polygonIndices = nullptr);

	/**
	* Compute the number of points needed for a circular join when offsetting a vertex.
	* The lengths of offset0 and offset1 don't have to equal \|offset\| -- only the direction matters.
	* The segment lengths will be approximately four pixels.
	*
	* @param offset0 Starting offset vector direction.
	* @param offset1 Ending offset vector direction.
	* @param offset Offset value (can be negative).
	* @param rotSin Sine of rotation delta per step.
	* @param rotCos Cosine of rotation delta per step.
	* @param n Number of steps to fill out the arc.
	* @return true for success, false otherwise
	*/
	bool SkComputeRadialSteps(const SkVector& offset0, const SkVector& offset1, SkScalar offset,
	SkScalar* rotSin, SkScalar* rotCos, int* n);

	/**
	* Determine winding direction for a polygon.
	* The input polygon must be simple or the result will be meaningless.
	*
	* @param polygonVerts Array of points representing the vertices of the polygon.
	* @param polygonSize Number of vertices in the polygon.
	* @return 1 for cw, -1 for ccw, and 0 if zero signed area (either degenerate or self-intersecting).
	* The y-axis is assumed to be pointing down.
	*/
	int SkGetPolygonWinding(const SkPoint* polygonVerts, int polygonSize);

	/**
	* Determine whether a polygon is convex or not.
	*
	* @param polygonVerts Array of points representing the vertices of the polygon.
	* @param polygonSize Number of vertices in the polygon.
	* @return true if the polygon is convex, false otherwise.
	*/
	bool SkIsConvexPolygon(const SkPoint* polygonVerts, int polygonSize);

	/**
	* Determine whether a polygon is simple (i.e., not self-intersecting) or not.
	* The input polygon must have no coincident vertices or the test will fail.
	*
	* @param polygonVerts Array of points representing the vertices of the polygon.
	* @param polygonSize Number of vertices in the polygon.
	* @return true if the polygon is simple, false otherwise.
	*/
	bool SkIsSimplePolygon(const SkPoint* polygonVerts, int polygonSize);

	/**
	* Compute indices to triangulate the given polygon.
	* The input polygon must be simple (i.e. it is not self-intersecting)
	* and have no coincident vertices or collinear edges.
	*
	* @param polygonVerts Array of points representing the vertices of the polygon.
	* @param indexMap Mapping from index in the given array to the final index in the triangulation.
	* @param polygonSize Number of vertices in the polygon.
	* @param triangleIndices Indices of the resulting triangulation.
	* @return true if successful, false otherwise.
	*/
	bool SkTriangulateSimplePolygon(const SkPoint* polygonVerts, uint16_t* indexMap, int polygonSize,
	SkTDArray<uint16_t>* triangleIndices);

	// Experiment: doesn't handle really big floats (returns false), always returns true for count <= 3
	bool SkIsPolyConvex_experimental(const SkPoint[], int count);

	#endif