include/core/SkPathMeasure.h - skia - Git at Google

 /*
  * Copyright 2006 The Android Open Source Project
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkPathMeasure_DEFINED
 #define SkPathMeasure_DEFINED

 #include "../private/SkTDArray.h"
 #include "SkPath.h"

 struct SkConic;

 class SK_API SkPathMeasure : SkNoncopyable {
 public:
     SkPathMeasure();
     /** Initialize the pathmeasure with the specified path. The path must remain valid
         for the lifetime of the measure object, or until setPath() is called with
         a different path (or null), since the measure object keeps a pointer to the
         path object (does not copy its data).

         resScale controls the precision of the measure. values > 1 increase the
         precision (and possible slow down the computation).
     */
     SkPathMeasure(const SkPath& path, bool forceClosed, SkScalar resScale = 1);
     ~SkPathMeasure();

     /** Reset the pathmeasure with the specified path. The path must remain valid
         for the lifetime of the measure object, or until setPath() is called with
         a different path (or null), since the measure object keeps a pointer to the
         path object (does not copy its data).
     */
     void setPath(const SkPath*, bool forceClosed);

     /** Return the total length of the current contour, or 0 if no path
         is associated (e.g. resetPath(null))
     */
     SkScalar getLength();

     /** Pins distance to 0 <= distance <= getLength(), and then computes
         the corresponding position and tangent.
         Returns false if there is no path, or a zero-length path was specified, in which case
         position and tangent are unchanged.
     */
     bool SK_WARN_UNUSED_RESULT getPosTan(SkScalar distance, SkPoint* position,
                                          SkVector* tangent);

     enum MatrixFlags {
         kGetPosition_MatrixFlag     = 0x01,
         kGetTangent_MatrixFlag      = 0x02,
         kGetPosAndTan_MatrixFlag    = kGetPosition_MatrixFlag | kGetTangent_MatrixFlag
     };

     /** Pins distance to 0 <= distance <= getLength(), and then computes
         the corresponding matrix (by calling getPosTan).
         Returns false if there is no path, or a zero-length path was specified, in which case
         matrix is unchanged.
     */
     bool SK_WARN_UNUSED_RESULT getMatrix(SkScalar distance, SkMatrix* matrix,
                                   MatrixFlags flags = kGetPosAndTan_MatrixFlag);

     /** Given a start and stop distance, return in dst the intervening segment(s).
         If the segment is zero-length, return false, else return true.
         startD and stopD are pinned to legal values (0..getLength()). If startD > stopD
         then return false (and leave dst untouched).
         Begin the segment with a moveTo if startWithMoveTo is true
     */
     bool getSegment(SkScalar startD, SkScalar stopD, SkPath* dst, bool startWithMoveTo);

     /** Return true if the current contour is closed()
     */
     bool isClosed();

     /** Move to the next contour in the path. Return true if one exists, or false if
         we're done with the path.
     */
     bool nextContour();

 #ifdef SK_DEBUG
     void    dump();
 #endif

 private:
     SkPath::Iter    fIter;
     const SkPath*   fPath;
     SkScalar        fTolerance;
     SkScalar        fLength;            // relative to the current contour
     int             fFirstPtIndex;      // relative to the current contour
     bool            fIsClosed;          // relative to the current contour
     bool            fForceClosed;

     struct Segment {
         SkScalar    fDistance;  // total distance up to this point
         unsigned    fPtIndex; // index into the fPts array
         unsigned    fTValue : 30;
         unsigned    fType : 2;  // actually the enum SkSegType
                                 // See SkPathMeasurePriv.h

         SkScalar getScalarT() const;
     };
     SkTDArray<Segment>  fSegments;
     SkTDArray<SkPoint>  fPts; // Points used to define the segments

     static const Segment* NextSegment(const Segment*);

     void     buildSegments();
     SkScalar compute_quad_segs(const SkPoint pts[3], SkScalar distance,
                                 int mint, int maxt, int ptIndex);
     SkScalar compute_conic_segs(const SkConic&, SkScalar distance,
                                 int mint, const SkPoint& minPt,
                                 int maxt, const SkPoint& maxPt, int ptIndex);
     SkScalar compute_cubic_segs(const SkPoint pts[3], SkScalar distance,
                                 int mint, int maxt, int ptIndex);
     const Segment* distanceToSegment(SkScalar distance, SkScalar* t);
     bool quad_too_curvy(const SkPoint pts[3]);
     bool conic_too_curvy(const SkPoint& firstPt, const SkPoint& midTPt,const SkPoint& lastPt);
     bool cheap_dist_exceeds_limit(const SkPoint& pt, SkScalar x, SkScalar y);
     bool cubic_too_curvy(const SkPoint pts[4]);
 };

 #endif
	/*
	* Copyright 2006 The Android Open Source Project
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkPathMeasure_DEFINED
	#define SkPathMeasure_DEFINED

	#include "../private/SkTDArray.h"
	#include "SkPath.h"

	struct SkConic;

	class SK_API SkPathMeasure : SkNoncopyable {
	public:
	SkPathMeasure();
	/** Initialize the pathmeasure with the specified path. The path must remain valid
	for the lifetime of the measure object, or until setPath() is called with
	a different path (or null), since the measure object keeps a pointer to the
	path object (does not copy its data).

	resScale controls the precision of the measure. values > 1 increase the
	precision (and possible slow down the computation).
	*/
	SkPathMeasure(const SkPath& path, bool forceClosed, SkScalar resScale = 1);
	~SkPathMeasure();

	/** Reset the pathmeasure with the specified path. The path must remain valid
	for the lifetime of the measure object, or until setPath() is called with
	a different path (or null), since the measure object keeps a pointer to the
	path object (does not copy its data).
	*/
	void setPath(const SkPath*, bool forceClosed);

	/** Return the total length of the current contour, or 0 if no path
	is associated (e.g. resetPath(null))
	*/
	SkScalar getLength();

	/** Pins distance to 0 <= distance <= getLength(), and then computes
	the corresponding position and tangent.
	Returns false if there is no path, or a zero-length path was specified, in which case
	position and tangent are unchanged.
	*/
	bool SK_WARN_UNUSED_RESULT getPosTan(SkScalar distance, SkPoint* position,
	SkVector* tangent);

	enum MatrixFlags {
	kGetPosition_MatrixFlag = 0x01,
	kGetTangent_MatrixFlag = 0x02,
	kGetPosAndTan_MatrixFlag = kGetPosition_MatrixFlag \| kGetTangent_MatrixFlag
	};

	/** Pins distance to 0 <= distance <= getLength(), and then computes
	the corresponding matrix (by calling getPosTan).
	Returns false if there is no path, or a zero-length path was specified, in which case
	matrix is unchanged.
	*/
	bool SK_WARN_UNUSED_RESULT getMatrix(SkScalar distance, SkMatrix* matrix,
	MatrixFlags flags = kGetPosAndTan_MatrixFlag);

	/** Given a start and stop distance, return in dst the intervening segment(s).
	If the segment is zero-length, return false, else return true.
	startD and stopD are pinned to legal values (0..getLength()). If startD > stopD
	then return false (and leave dst untouched).
	Begin the segment with a moveTo if startWithMoveTo is true
	*/
	bool getSegment(SkScalar startD, SkScalar stopD, SkPath* dst, bool startWithMoveTo);

	/** Return true if the current contour is closed()
	*/
	bool isClosed();

	/** Move to the next contour in the path. Return true if one exists, or false if
	we're done with the path.
	*/
	bool nextContour();

	#ifdef SK_DEBUG
	void dump();
	#endif

	private:
	SkPath::Iter fIter;
	const SkPath* fPath;
	SkScalar fTolerance;
	SkScalar fLength; // relative to the current contour
	int fFirstPtIndex; // relative to the current contour
	bool fIsClosed; // relative to the current contour
	bool fForceClosed;

	struct Segment {
	SkScalar fDistance; // total distance up to this point
	unsigned fPtIndex; // index into the fPts array
	unsigned fTValue : 30;
	unsigned fType : 2; // actually the enum SkSegType
	// See SkPathMeasurePriv.h

	SkScalar getScalarT() const;
	};
	SkTDArray<Segment> fSegments;
	SkTDArray<SkPoint> fPts; // Points used to define the segments

	static const Segment* NextSegment(const Segment*);

	void buildSegments();
	SkScalar compute_quad_segs(const SkPoint pts[3], SkScalar distance,
	int mint, int maxt, int ptIndex);
	SkScalar compute_conic_segs(const SkConic&, SkScalar distance,
	int mint, const SkPoint& minPt,
	int maxt, const SkPoint& maxPt, int ptIndex);
	SkScalar compute_cubic_segs(const SkPoint pts[3], SkScalar distance,
	int mint, int maxt, int ptIndex);
	const Segment* distanceToSegment(SkScalar distance, SkScalar* t);
	bool quad_too_curvy(const SkPoint pts[3]);
	bool conic_too_curvy(const SkPoint& firstPt, const SkPoint& midTPt,const SkPoint& lastPt);
	bool cheap_dist_exceeds_limit(const SkPoint& pt, SkScalar x, SkScalar y);
	bool cubic_too_curvy(const SkPoint pts[4]);
	};

	#endif