/* * 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; 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