src/core/SkStroke.cpp - platform/external/skia - Git at Google

 /*
  * Copyright (C) 2006-2008 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "SkStrokerPriv.h"
 #include "SkGeometry.h"
 #include "SkPath.h"

 #define kMaxQuadSubdivide   5
 #define kMaxCubicSubdivide  4

 static inline bool degenerate_vector(const SkVector& v) {
     return SkScalarNearlyZero(v.fX) && SkScalarNearlyZero(v.fY);
 }

 static inline bool degenerate_line(const SkPoint& a, const SkPoint& b,
                                    SkScalar tolerance = SK_ScalarNearlyZero) {
     return SkScalarNearlyZero(a.fX - b.fX, tolerance) &&
             SkScalarNearlyZero(a.fY - b.fY, tolerance);
 }

 static inline bool normals_too_curvy(const SkVector& norm0, SkVector& norm1) {
     /*  root2/2 is a 45-degree angle
         make this constant bigger for more subdivisions (but not >= 1)
     */
     static const SkScalar kFlatEnoughNormalDotProd =
                                             SK_ScalarSqrt2/2 + SK_Scalar1/10;

     SkASSERT(kFlatEnoughNormalDotProd > 0 &&
              kFlatEnoughNormalDotProd < SK_Scalar1);

     return SkPoint::DotProduct(norm0, norm1) <= kFlatEnoughNormalDotProd;
 }

 static inline bool normals_too_pinchy(const SkVector& norm0, SkVector& norm1) {
     static const SkScalar kTooPinchyNormalDotProd = -SK_Scalar1 * 999 / 1000;

     return SkPoint::DotProduct(norm0, norm1) <= kTooPinchyNormalDotProd;
 }

 static bool set_normal_unitnormal(const SkPoint& before, const SkPoint& after,
                                   SkScalar radius,
                                   SkVector* normal, SkVector* unitNormal) {
     if (!unitNormal->setNormalize(after.fX - before.fX, after.fY - before.fY)) {
         return false;
     }
     unitNormal->rotateCCW();
     unitNormal->scale(radius, normal);
     return true;
 }

 static bool set_normal_unitnormal(const SkVector& vec,
                                   SkScalar radius,
                                   SkVector* normal, SkVector* unitNormal) {
     if (!unitNormal->setNormalize(vec.fX, vec.fY)) {
         return false;
     }
     unitNormal->rotateCCW();
     unitNormal->scale(radius, normal);
     return true;
 }

 ///////////////////////////////////////////////////////////////////////////////

 class SkPathStroker {
 public:
     SkPathStroker(SkScalar radius, SkScalar miterLimit, SkPaint::Cap cap,
                   SkPaint::Join join);

     void moveTo(const SkPoint&);
     void lineTo(const SkPoint&);
     void quadTo(const SkPoint&, const SkPoint&);
     void cubicTo(const SkPoint&, const SkPoint&, const SkPoint&);
     void close(bool isLine) { this->finishContour(true, isLine); }

     void done(SkPath* dst, bool isLine) {
         this->finishContour(false, isLine);
         fOuter.addPath(fExtra);
         dst->swap(fOuter);
     }

 private:
     SkScalar    fRadius;
     SkScalar    fInvMiterLimit;

     SkVector    fFirstNormal, fPrevNormal, fFirstUnitNormal, fPrevUnitNormal;
     SkPoint     fFirstPt, fPrevPt;  // on original path
     SkPoint     fFirstOuterPt;
     int         fSegmentCount;
     bool        fPrevIsLine;

     SkStrokerPriv::CapProc  fCapper;
     SkStrokerPriv::JoinProc fJoiner;

     SkPath  fInner, fOuter; // outer is our working answer, inner is temp
     SkPath  fExtra;         // added as extra complete contours

     void    finishContour(bool close, bool isLine);
     void    preJoinTo(const SkPoint&, SkVector* normal, SkVector* unitNormal,
                       bool isLine);
     void    postJoinTo(const SkPoint&, const SkVector& normal,
                        const SkVector& unitNormal);

     void    line_to(const SkPoint& currPt, const SkVector& normal);
     void    quad_to(const SkPoint pts[3],
                     const SkVector& normalAB, const SkVector& unitNormalAB,
                     SkVector* normalBC, SkVector* unitNormalBC,
                     int subDivide);
     void    cubic_to(const SkPoint pts[4],
                     const SkVector& normalAB, const SkVector& unitNormalAB,
                     SkVector* normalCD, SkVector* unitNormalCD,
                     int subDivide);
 };

 ///////////////////////////////////////////////////////////////////////////////

 void SkPathStroker::preJoinTo(const SkPoint& currPt, SkVector* normal,
                               SkVector* unitNormal, bool currIsLine) {
     SkASSERT(fSegmentCount >= 0);

     SkScalar    prevX = fPrevPt.fX;
     SkScalar    prevY = fPrevPt.fY;

     SkAssertResult(set_normal_unitnormal(fPrevPt, currPt, fRadius, normal,
                                          unitNormal));

     if (fSegmentCount == 0) {
         fFirstNormal = *normal;
         fFirstUnitNormal = *unitNormal;
         fFirstOuterPt.set(prevX + normal->fX, prevY + normal->fY);

         fOuter.moveTo(fFirstOuterPt.fX, fFirstOuterPt.fY);
         fInner.moveTo(prevX - normal->fX, prevY - normal->fY);
     } else {    // we have a previous segment
         fJoiner(&fOuter, &fInner, fPrevUnitNormal, fPrevPt, *unitNormal,
                 fRadius, fInvMiterLimit, fPrevIsLine, currIsLine);
     }
     fPrevIsLine = currIsLine;
 }

 void SkPathStroker::postJoinTo(const SkPoint& currPt, const SkVector& normal,
                                const SkVector& unitNormal) {
     fPrevPt = currPt;
     fPrevUnitNormal = unitNormal;
     fPrevNormal = normal;
     fSegmentCount += 1;
 }

 void SkPathStroker::finishContour(bool close, bool currIsLine) {
     if (fSegmentCount > 0) {
         SkPoint pt;

         if (close) {
             fJoiner(&fOuter, &fInner, fPrevUnitNormal, fPrevPt,
                     fFirstUnitNormal, fRadius, fInvMiterLimit,
                     fPrevIsLine, currIsLine);
             fOuter.close();
             // now add fInner as its own contour
             fInner.getLastPt(&pt);
             fOuter.moveTo(pt.fX, pt.fY);
             fOuter.reversePathTo(fInner);
             fOuter.close();
         } else {    // add caps to start and end
             // cap the end
             fInner.getLastPt(&pt);
             fCapper(&fOuter, fPrevPt, fPrevNormal, pt,
                     currIsLine ? &fInner : NULL);
             fOuter.reversePathTo(fInner);
             // cap the start
             fCapper(&fOuter, fFirstPt, -fFirstNormal, fFirstOuterPt,
                     fPrevIsLine ? &fInner : NULL);
             fOuter.close();
         }
     }
     fInner.reset();
     fSegmentCount = -1;
 }

 ///////////////////////////////////////////////////////////////////////////////

 SkPathStroker::SkPathStroker(SkScalar radius, SkScalar miterLimit,
                              SkPaint::Cap cap, SkPaint::Join join)
         : fRadius(radius) {

     /*  This is only used when join is miter_join, but we initialize it here
         so that it is always defined, to fis valgrind warnings.
     */
     fInvMiterLimit = 0;

     if (join == SkPaint::kMiter_Join) {
         if (miterLimit <= SK_Scalar1) {
             join = SkPaint::kBevel_Join;
         } else {
             fInvMiterLimit = SkScalarInvert(miterLimit);
         }
     }
     fCapper = SkStrokerPriv::CapFactory(cap);
     fJoiner = SkStrokerPriv::JoinFactory(join);
     fSegmentCount = -1;
     fPrevIsLine = false;
 }

 void SkPathStroker::moveTo(const SkPoint& pt) {
     if (fSegmentCount > 0) {
         this->finishContour(false, false);
     }
     fSegmentCount = 0;
     fFirstPt = fPrevPt = pt;
 }

 void SkPathStroker::line_to(const SkPoint& currPt, const SkVector& normal) {
     fOuter.lineTo(currPt.fX + normal.fX, currPt.fY + normal.fY);
     fInner.lineTo(currPt.fX - normal.fX, currPt.fY - normal.fY);
 }

 void SkPathStroker::lineTo(const SkPoint& currPt) {
     if (degenerate_line(fPrevPt, currPt)) {
         return;
     }
     SkVector    normal, unitNormal;

     this->preJoinTo(currPt, &normal, &unitNormal, true);
     this->line_to(currPt, normal);
     this->postJoinTo(currPt, normal, unitNormal);
 }

 void SkPathStroker::quad_to(const SkPoint pts[3],
                       const SkVector& normalAB, const SkVector& unitNormalAB,
                       SkVector* normalBC, SkVector* unitNormalBC,
                       int subDivide) {
     if (!set_normal_unitnormal(pts[1], pts[2], fRadius,
                                normalBC, unitNormalBC)) {
         // pts[1] nearly equals pts[2], so just draw a line to pts[2]
         this->line_to(pts[2], normalAB);
         *normalBC = normalAB;
         *unitNormalBC = unitNormalAB;
         return;
     }

     if (--subDivide >= 0 && normals_too_curvy(unitNormalAB, *unitNormalBC)) {
         SkPoint     tmp[5];
         SkVector    norm, unit;

         SkChopQuadAtHalf(pts, tmp);
         this->quad_to(&tmp[0], normalAB, unitNormalAB, &norm, &unit, subDivide);
         this->quad_to(&tmp[2], norm, unit, normalBC, unitNormalBC, subDivide);
     } else {
         SkVector    normalB, unitB;
         SkAssertResult(set_normal_unitnormal(pts[0], pts[2], fRadius,
                                              &normalB, &unitB));

         fOuter.quadTo(  pts[1].fX + normalB.fX, pts[1].fY + normalB.fY,
                         pts[2].fX + normalBC->fX, pts[2].fY + normalBC->fY);
         fInner.quadTo(  pts[1].fX - normalB.fX, pts[1].fY - normalB.fY,
                         pts[2].fX - normalBC->fX, pts[2].fY - normalBC->fY);
     }
 }

 void SkPathStroker::cubic_to(const SkPoint pts[4],
                       const SkVector& normalAB, const SkVector& unitNormalAB,
                       SkVector* normalCD, SkVector* unitNormalCD,
                       int subDivide) {
     SkVector    ab = pts[1] - pts[0];
     SkVector    cd = pts[3] - pts[2];
     SkVector    normalBC, unitNormalBC;

     bool    degenerateAB = degenerate_vector(ab);
     bool    degenerateCD = degenerate_vector(cd);

     if (degenerateAB && degenerateCD) {
 DRAW_LINE:
         this->line_to(pts[3], normalAB);
         *normalCD = normalAB;
         *unitNormalCD = unitNormalAB;
         return;
     }

     if (degenerateAB) {
         ab = pts[2] - pts[0];
         degenerateAB = degenerate_vector(ab);
     }
     if (degenerateCD) {
         cd = pts[3] - pts[1];
         degenerateCD = degenerate_vector(cd);
     }
     if (degenerateAB || degenerateCD) {
         goto DRAW_LINE;
     }
     SkAssertResult(set_normal_unitnormal(cd, fRadius, normalCD, unitNormalCD));
     bool degenerateBC = !set_normal_unitnormal(pts[1], pts[2], fRadius,
                                                &normalBC, &unitNormalBC);

     if (degenerateBC || normals_too_curvy(unitNormalAB, unitNormalBC) ||
              normals_too_curvy(unitNormalBC, *unitNormalCD)) {
         // subdivide if we can
         if (--subDivide < 0) {
             goto DRAW_LINE;
         }
         SkPoint     tmp[7];
         SkVector    norm, unit, dummy, unitDummy;

         SkChopCubicAtHalf(pts, tmp);
         this->cubic_to(&tmp[0], normalAB, unitNormalAB, &norm, &unit,
                        subDivide);
         // we use dummys since we already have a valid (and more accurate)
         // normals for CD
         this->cubic_to(&tmp[3], norm, unit, &dummy, &unitDummy, subDivide);
     } else {
         SkVector    normalB, normalC;

         // need normals to inset/outset the off-curve pts B and C

         if (0) {    // this is normal to the line between our adjacent pts
             normalB = pts[2] - pts[0];
             normalB.rotateCCW();
             SkAssertResult(normalB.setLength(fRadius));

             normalC = pts[3] - pts[1];
             normalC.rotateCCW();
             SkAssertResult(normalC.setLength(fRadius));
         } else {    // miter-join
             SkVector    unitBC = pts[2] - pts[1];
             unitBC.normalize();
             unitBC.rotateCCW();

             normalB = unitNormalAB + unitBC;
             normalC = *unitNormalCD + unitBC;

             SkScalar dot = SkPoint::DotProduct(unitNormalAB, unitBC);
             SkAssertResult(normalB.setLength(SkScalarDiv(fRadius,
                                         SkScalarSqrt((SK_Scalar1 + dot)/2))));
             dot = SkPoint::DotProduct(*unitNormalCD, unitBC);
             SkAssertResult(normalC.setLength(SkScalarDiv(fRadius,
                                         SkScalarSqrt((SK_Scalar1 + dot)/2))));
         }

         fOuter.cubicTo( pts[1].fX + normalB.fX, pts[1].fY + normalB.fY,
                         pts[2].fX + normalC.fX, pts[2].fY + normalC.fY,
                         pts[3].fX + normalCD->fX, pts[3].fY + normalCD->fY);

         fInner.cubicTo( pts[1].fX - normalB.fX, pts[1].fY - normalB.fY,
                         pts[2].fX - normalC.fX, pts[2].fY - normalC.fY,
                         pts[3].fX - normalCD->fX, pts[3].fY - normalCD->fY);
     }
 }

 void SkPathStroker::quadTo(const SkPoint& pt1, const SkPoint& pt2) {
     bool    degenerateAB = degenerate_line(fPrevPt, pt1);
     bool    degenerateBC = degenerate_line(pt1, pt2);

     if (degenerateAB | degenerateBC) {
         if (degenerateAB ^ degenerateBC) {
             this->lineTo(pt2);
         }
         return;
     }

     SkVector    normalAB, unitAB, normalBC, unitBC;

     this->preJoinTo(pt1, &normalAB, &unitAB, false);

     {
         SkPoint pts[3], tmp[5];
         pts[0] = fPrevPt;
         pts[1] = pt1;
         pts[2] = pt2;

         if (SkChopQuadAtMaxCurvature(pts, tmp) == 2) {
             unitBC.setNormalize(pts[2].fX - pts[1].fX, pts[2].fY - pts[1].fY);
             unitBC.rotateCCW();
             if (normals_too_pinchy(unitAB, unitBC)) {
                 normalBC = unitBC;
                 normalBC.scale(fRadius);

                 fOuter.lineTo(tmp[2].fX + normalAB.fX, tmp[2].fY + normalAB.fY);
                 fOuter.lineTo(tmp[2].fX + normalBC.fX, tmp[2].fY + normalBC.fY);
                 fOuter.lineTo(tmp[4].fX + normalBC.fX, tmp[4].fY + normalBC.fY);

                 fInner.lineTo(tmp[2].fX - normalAB.fX, tmp[2].fY - normalAB.fY);
                 fInner.lineTo(tmp[2].fX - normalBC.fX, tmp[2].fY - normalBC.fY);
                 fInner.lineTo(tmp[4].fX - normalBC.fX, tmp[4].fY - normalBC.fY);

                 fExtra.addCircle(tmp[2].fX, tmp[2].fY, fRadius,
                                  SkPath::kCW_Direction);
             } else {
                 this->quad_to(&tmp[0], normalAB, unitAB, &normalBC, &unitBC,
                               kMaxQuadSubdivide);
                 SkVector n = normalBC;
                 SkVector u = unitBC;
                 this->quad_to(&tmp[2], n, u, &normalBC, &unitBC,
                               kMaxQuadSubdivide);
             }
         } else {
             this->quad_to(pts, normalAB, unitAB, &normalBC, &unitBC,
                           kMaxQuadSubdivide);
         }
     }

     this->postJoinTo(pt2, normalBC, unitBC);
 }

 void SkPathStroker::cubicTo(const SkPoint& pt1, const SkPoint& pt2,
                             const SkPoint& pt3) {
     bool    degenerateAB = degenerate_line(fPrevPt, pt1);
     bool    degenerateBC = degenerate_line(pt1, pt2);
     bool    degenerateCD = degenerate_line(pt2, pt3);

     if (degenerateAB + degenerateBC + degenerateCD >= 2) {
         this->lineTo(pt3);
         return;
     }

     SkVector    normalAB, unitAB, normalCD, unitCD;

     // find the first tangent (which might be pt1 or pt2
     {
         const SkPoint*  nextPt = &pt1;
         if (degenerateAB)
             nextPt = &pt2;
         this->preJoinTo(*nextPt, &normalAB, &unitAB, false);
     }

     {
         SkPoint pts[4], tmp[13];
         int         i, count;
         SkVector    n, u;
         SkScalar    tValues[3];

         pts[0] = fPrevPt;
         pts[1] = pt1;
         pts[2] = pt2;
         pts[3] = pt3;

 #if 1
         count = SkChopCubicAtMaxCurvature(pts, tmp, tValues);
 #else
         count = 1;
         memcpy(tmp, pts, 4 * sizeof(SkPoint));
 #endif
         n = normalAB;
         u = unitAB;
         for (i = 0; i < count; i++) {
             this->cubic_to(&tmp[i * 3], n, u, &normalCD, &unitCD,
                            kMaxCubicSubdivide);
             if (i == count - 1) {
                 break;
             }
             n = normalCD;
             u = unitCD;

         }

         // check for too pinchy
         for (i = 1; i < count; i++) {
             SkPoint p;
             SkVector    v, c;

             SkEvalCubicAt(pts, tValues[i - 1], &p, &v, &c);

             SkScalar    dot = SkPoint::DotProduct(c, c);
             v.scale(SkScalarInvert(dot));

             if (SkScalarNearlyZero(v.fX) && SkScalarNearlyZero(v.fY)) {
                 fExtra.addCircle(p.fX, p.fY, fRadius, SkPath::kCW_Direction);
             }
         }

     }

     this->postJoinTo(pt3, normalCD, unitCD);
 }

 ///////////////////////////////////////////////////////////////////////////////
 ///////////////////////////////////////////////////////////////////////////////

 #include "SkPaint.h"

 SkStroke::SkStroke() {
     fWidth      = SK_DefaultStrokeWidth;
     fMiterLimit = SK_DefaultMiterLimit;
     fCap        = SkPaint::kDefault_Cap;
     fJoin       = SkPaint::kDefault_Join;
     fDoFill     = false;
 }

 SkStroke::SkStroke(const SkPaint& p) {
     fWidth      = p.getStrokeWidth();
     fMiterLimit = p.getStrokeMiter();
     fCap        = (uint8_t)p.getStrokeCap();
     fJoin       = (uint8_t)p.getStrokeJoin();
     fDoFill     = SkToU8(p.getStyle() == SkPaint::kStrokeAndFill_Style);
 }

 SkStroke::SkStroke(const SkPaint& p, SkScalar width) {
     fWidth      = width;
     fMiterLimit = p.getStrokeMiter();
     fCap        = (uint8_t)p.getStrokeCap();
     fJoin       = (uint8_t)p.getStrokeJoin();
     fDoFill     = SkToU8(p.getStyle() == SkPaint::kStrokeAndFill_Style);
 }

 void SkStroke::setWidth(SkScalar width) {
     SkASSERT(width >= 0);
     fWidth = width;
 }

 void SkStroke::setMiterLimit(SkScalar miterLimit) {
     SkASSERT(miterLimit >= 0);
     fMiterLimit = miterLimit;
 }

 void SkStroke::setCap(SkPaint::Cap cap) {
     SkASSERT((unsigned)cap < SkPaint::kCapCount);
     fCap = SkToU8(cap);
 }

 void SkStroke::setJoin(SkPaint::Join join) {
     SkASSERT((unsigned)join < SkPaint::kJoinCount);
     fJoin = SkToU8(join);
 }

 ///////////////////////////////////////////////////////////////////////////////

 #ifdef SK_SCALAR_IS_FIXED
     /*  return non-zero if the path is too big, and should be shrunk to avoid
         overflows during intermediate calculations. Note that we compute the
         bounds for this. If we had a custom callback/walker for paths, we could
         perhaps go faster by using that, and just perform the abs | in that
         routine
     */
     static int needs_to_shrink(const SkPath& path) {
         const SkRect& r = path.getBounds();
         SkFixed mask = SkAbs32(r.fLeft);
         mask |= SkAbs32(r.fTop);
         mask |= SkAbs32(r.fRight);
         mask |= SkAbs32(r.fBottom);
         // we need the top 3 bits clear (after abs) to avoid overflow
         return mask >> 29;
     }

     static void identity_proc(SkPoint pts[], int count) {}
     static void shift_down_2_proc(SkPoint pts[], int count) {
         for (int i = 0; i < count; i++) {
             pts->fX >>= 2;
             pts->fY >>= 2;
             pts += 1;
         }
     }
     #define APPLY_PROC(proc, pts, count)    proc(pts, count)
 #else   // float does need any of this
     #define APPLY_PROC(proc, pts, count)
 #endif

 void SkStroke::strokePath(const SkPath& src, SkPath* dst) const {
     SkASSERT(&src != NULL && dst != NULL);

     SkScalar radius = SkScalarHalf(fWidth);

     dst->reset();
     if (radius <= 0) {
         return;
     }

 #ifdef SK_SCALAR_IS_FIXED
     void (*proc)(SkPoint pts[], int count) = identity_proc;
     if (needs_to_shrink(src)) {
         proc = shift_down_2_proc;
         radius >>= 2;
         if (radius == 0) {
             return;
         }
     }
 #endif

     SkPathStroker   stroker(radius, fMiterLimit, this->getCap(),
                             this->getJoin());

     SkPath::Iter    iter(src, false);
     SkPoint         pts[4];
     SkPath::Verb    verb, lastSegment = SkPath::kMove_Verb;

     while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {
         switch (verb) {
             case SkPath::kMove_Verb:
                 APPLY_PROC(proc, &pts[0], 1);
                 stroker.moveTo(pts[0]);
                 break;
             case SkPath::kLine_Verb:
                 APPLY_PROC(proc, &pts[1], 1);
                 stroker.lineTo(pts[1]);
                 lastSegment = verb;
                 break;
             case SkPath::kQuad_Verb:
                 APPLY_PROC(proc, &pts[1], 2);
                 stroker.quadTo(pts[1], pts[2]);
                 lastSegment = verb;
                 break;
             case SkPath::kCubic_Verb:
                 APPLY_PROC(proc, &pts[1], 3);
                 stroker.cubicTo(pts[1], pts[2], pts[3]);
                 lastSegment = verb;
                 break;
             case SkPath::kClose_Verb:
                 stroker.close(lastSegment == SkPath::kLine_Verb);
                 break;
             default:
                 break;
         }
     }
     stroker.done(dst, lastSegment == SkPath::kLine_Verb);

 #ifdef SK_SCALAR_IS_FIXED
     // undo our previous down_shift
     if (shift_down_2_proc == proc) {
         // need a real shift methid on path. antialias paths could use this too
         SkMatrix matrix;
         matrix.setScale(SkIntToScalar(4), SkIntToScalar(4));
         dst->transform(matrix);
     }
 #endif

     if (fDoFill) {
         dst->addPath(src);
     } else {
         if (src.countPoints() == 2) {
             dst->setIsConvex(true);
         }
     }
 }

 void SkStroke::strokeLine(const SkPoint& p0, const SkPoint& p1,
                           SkPath* dst) const {
     SkPath  tmp;

     tmp.moveTo(p0);
     tmp.lineTo(p1);
     this->strokePath(tmp, dst);
 }
	/*
	* Copyright (C) 2006-2008 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "SkStrokerPriv.h"
	#include "SkGeometry.h"
	#include "SkPath.h"

	#define kMaxQuadSubdivide 5
	#define kMaxCubicSubdivide 4

	static inline bool degenerate_vector(const SkVector& v) {
	return SkScalarNearlyZero(v.fX) && SkScalarNearlyZero(v.fY);
	}

	static inline bool degenerate_line(const SkPoint& a, const SkPoint& b,
	SkScalar tolerance = SK_ScalarNearlyZero) {
	return SkScalarNearlyZero(a.fX - b.fX, tolerance) &&
	SkScalarNearlyZero(a.fY - b.fY, tolerance);
	}

	static inline bool normals_too_curvy(const SkVector& norm0, SkVector& norm1) {
	/* root2/2 is a 45-degree angle
	make this constant bigger for more subdivisions (but not >= 1)
	*/
	static const SkScalar kFlatEnoughNormalDotProd =
	SK_ScalarSqrt2/2 + SK_Scalar1/10;

	SkASSERT(kFlatEnoughNormalDotProd > 0 &&
	kFlatEnoughNormalDotProd < SK_Scalar1);

	return SkPoint::DotProduct(norm0, norm1) <= kFlatEnoughNormalDotProd;
	}

	static inline bool normals_too_pinchy(const SkVector& norm0, SkVector& norm1) {
	static const SkScalar kTooPinchyNormalDotProd = -SK_Scalar1 * 999 / 1000;

	return SkPoint::DotProduct(norm0, norm1) <= kTooPinchyNormalDotProd;
	}

	static bool set_normal_unitnormal(const SkPoint& before, const SkPoint& after,
	SkScalar radius,
	SkVector* normal, SkVector* unitNormal) {
	if (!unitNormal->setNormalize(after.fX - before.fX, after.fY - before.fY)) {
	return false;
	}
	unitNormal->rotateCCW();
	unitNormal->scale(radius, normal);
	return true;
	}

	static bool set_normal_unitnormal(const SkVector& vec,
	SkScalar radius,
	SkVector* normal, SkVector* unitNormal) {
	if (!unitNormal->setNormalize(vec.fX, vec.fY)) {
	return false;
	}
	unitNormal->rotateCCW();
	unitNormal->scale(radius, normal);
	return true;
	}

	///////////////////////////////////////////////////////////////////////////////

	class SkPathStroker {
	public:
	SkPathStroker(SkScalar radius, SkScalar miterLimit, SkPaint::Cap cap,
	SkPaint::Join join);

	void moveTo(const SkPoint&);
	void lineTo(const SkPoint&);
	void quadTo(const SkPoint&, const SkPoint&);
	void cubicTo(const SkPoint&, const SkPoint&, const SkPoint&);
	void close(bool isLine) { this->finishContour(true, isLine); }

	void done(SkPath* dst, bool isLine) {
	this->finishContour(false, isLine);
	fOuter.addPath(fExtra);
	dst->swap(fOuter);
	}

	private:
	SkScalar fRadius;
	SkScalar fInvMiterLimit;

	SkVector fFirstNormal, fPrevNormal, fFirstUnitNormal, fPrevUnitNormal;
	SkPoint fFirstPt, fPrevPt; // on original path
	SkPoint fFirstOuterPt;
	int fSegmentCount;
	bool fPrevIsLine;

	SkStrokerPriv::CapProc fCapper;
	SkStrokerPriv::JoinProc fJoiner;

	SkPath fInner, fOuter; // outer is our working answer, inner is temp
	SkPath fExtra; // added as extra complete contours

	void finishContour(bool close, bool isLine);
	void preJoinTo(const SkPoint&, SkVector* normal, SkVector* unitNormal,
	bool isLine);
	void postJoinTo(const SkPoint&, const SkVector& normal,
	const SkVector& unitNormal);

	void line_to(const SkPoint& currPt, const SkVector& normal);
	void quad_to(const SkPoint pts[3],
	const SkVector& normalAB, const SkVector& unitNormalAB,
	SkVector* normalBC, SkVector* unitNormalBC,
	int subDivide);
	void cubic_to(const SkPoint pts[4],
	const SkVector& normalAB, const SkVector& unitNormalAB,
	SkVector* normalCD, SkVector* unitNormalCD,
	int subDivide);
	};

	///////////////////////////////////////////////////////////////////////////////

	void SkPathStroker::preJoinTo(const SkPoint& currPt, SkVector* normal,
	SkVector* unitNormal, bool currIsLine) {
	SkASSERT(fSegmentCount >= 0);

	SkScalar prevX = fPrevPt.fX;
	SkScalar prevY = fPrevPt.fY;

	SkAssertResult(set_normal_unitnormal(fPrevPt, currPt, fRadius, normal,
	unitNormal));

	if (fSegmentCount == 0) {
	fFirstNormal = *normal;
	fFirstUnitNormal = *unitNormal;
	fFirstOuterPt.set(prevX + normal->fX, prevY + normal->fY);

	fOuter.moveTo(fFirstOuterPt.fX, fFirstOuterPt.fY);
	fInner.moveTo(prevX - normal->fX, prevY - normal->fY);
	} else { // we have a previous segment
	fJoiner(&fOuter, &fInner, fPrevUnitNormal, fPrevPt, *unitNormal,
	fRadius, fInvMiterLimit, fPrevIsLine, currIsLine);
	}
	fPrevIsLine = currIsLine;
	}

	void SkPathStroker::postJoinTo(const SkPoint& currPt, const SkVector& normal,
	const SkVector& unitNormal) {
	fPrevPt = currPt;
	fPrevUnitNormal = unitNormal;
	fPrevNormal = normal;
	fSegmentCount += 1;
	}

	void SkPathStroker::finishContour(bool close, bool currIsLine) {
	if (fSegmentCount > 0) {
	SkPoint pt;

	if (close) {
	fJoiner(&fOuter, &fInner, fPrevUnitNormal, fPrevPt,
	fFirstUnitNormal, fRadius, fInvMiterLimit,
	fPrevIsLine, currIsLine);
	fOuter.close();
	// now add fInner as its own contour
	fInner.getLastPt(&pt);
	fOuter.moveTo(pt.fX, pt.fY);
	fOuter.reversePathTo(fInner);
	fOuter.close();
	} else { // add caps to start and end
	// cap the end
	fInner.getLastPt(&pt);
	fCapper(&fOuter, fPrevPt, fPrevNormal, pt,
	currIsLine ? &fInner : NULL);
	fOuter.reversePathTo(fInner);
	// cap the start
	fCapper(&fOuter, fFirstPt, -fFirstNormal, fFirstOuterPt,
	fPrevIsLine ? &fInner : NULL);
	fOuter.close();
	}
	}
	fInner.reset();
	fSegmentCount = -1;
	}

	///////////////////////////////////////////////////////////////////////////////

	SkPathStroker::SkPathStroker(SkScalar radius, SkScalar miterLimit,
	SkPaint::Cap cap, SkPaint::Join join)
	: fRadius(radius) {

	/* This is only used when join is miter_join, but we initialize it here
	so that it is always defined, to fis valgrind warnings.
	*/
	fInvMiterLimit = 0;

	if (join == SkPaint::kMiter_Join) {
	if (miterLimit <= SK_Scalar1) {
	join = SkPaint::kBevel_Join;
	} else {
	fInvMiterLimit = SkScalarInvert(miterLimit);
	}
	}
	fCapper = SkStrokerPriv::CapFactory(cap);
	fJoiner = SkStrokerPriv::JoinFactory(join);
	fSegmentCount = -1;
	fPrevIsLine = false;
	}

	void SkPathStroker::moveTo(const SkPoint& pt) {
	if (fSegmentCount > 0) {
	this->finishContour(false, false);
	}
	fSegmentCount = 0;
	fFirstPt = fPrevPt = pt;
	}

	void SkPathStroker::line_to(const SkPoint& currPt, const SkVector& normal) {
	fOuter.lineTo(currPt.fX + normal.fX, currPt.fY + normal.fY);
	fInner.lineTo(currPt.fX - normal.fX, currPt.fY - normal.fY);
	}

	void SkPathStroker::lineTo(const SkPoint& currPt) {
	if (degenerate_line(fPrevPt, currPt)) {
	return;
	}
	SkVector normal, unitNormal;

	this->preJoinTo(currPt, &normal, &unitNormal, true);
	this->line_to(currPt, normal);
	this->postJoinTo(currPt, normal, unitNormal);
	}

	void SkPathStroker::quad_to(const SkPoint pts[3],
	const SkVector& normalAB, const SkVector& unitNormalAB,
	SkVector* normalBC, SkVector* unitNormalBC,
	int subDivide) {
	if (!set_normal_unitnormal(pts[1], pts[2], fRadius,
	normalBC, unitNormalBC)) {
	// pts[1] nearly equals pts[2], so just draw a line to pts[2]
	this->line_to(pts[2], normalAB);
	*normalBC = normalAB;
	*unitNormalBC = unitNormalAB;
	return;
	}

	if (--subDivide >= 0 && normals_too_curvy(unitNormalAB, *unitNormalBC)) {
	SkPoint tmp[5];
	SkVector norm, unit;

	SkChopQuadAtHalf(pts, tmp);
	this->quad_to(&tmp[0], normalAB, unitNormalAB, &norm, &unit, subDivide);
	this->quad_to(&tmp[2], norm, unit, normalBC, unitNormalBC, subDivide);
	} else {
	SkVector normalB, unitB;
	SkAssertResult(set_normal_unitnormal(pts[0], pts[2], fRadius,
	&normalB, &unitB));

	fOuter.quadTo( pts[1].fX + normalB.fX, pts[1].fY + normalB.fY,
	pts[2].fX + normalBC->fX, pts[2].fY + normalBC->fY);
	fInner.quadTo( pts[1].fX - normalB.fX, pts[1].fY - normalB.fY,
	pts[2].fX - normalBC->fX, pts[2].fY - normalBC->fY);
	}
	}

	void SkPathStroker::cubic_to(const SkPoint pts[4],
	const SkVector& normalAB, const SkVector& unitNormalAB,
	SkVector* normalCD, SkVector* unitNormalCD,
	int subDivide) {
	SkVector ab = pts[1] - pts[0];
	SkVector cd = pts[3] - pts[2];
	SkVector normalBC, unitNormalBC;

	bool degenerateAB = degenerate_vector(ab);
	bool degenerateCD = degenerate_vector(cd);

	if (degenerateAB && degenerateCD) {
	DRAW_LINE:
	this->line_to(pts[3], normalAB);
	*normalCD = normalAB;
	*unitNormalCD = unitNormalAB;
	return;
	}

	if (degenerateAB) {
	ab = pts[2] - pts[0];
	degenerateAB = degenerate_vector(ab);
	}
	if (degenerateCD) {
	cd = pts[3] - pts[1];
	degenerateCD = degenerate_vector(cd);
	}
	if (degenerateAB \|\| degenerateCD) {
	goto DRAW_LINE;
	}
	SkAssertResult(set_normal_unitnormal(cd, fRadius, normalCD, unitNormalCD));
	bool degenerateBC = !set_normal_unitnormal(pts[1], pts[2], fRadius,
	&normalBC, &unitNormalBC);

	if (degenerateBC \|\| normals_too_curvy(unitNormalAB, unitNormalBC) \|\|
	normals_too_curvy(unitNormalBC, *unitNormalCD)) {
	// subdivide if we can
	if (--subDivide < 0) {
	goto DRAW_LINE;
	}
	SkPoint tmp[7];
	SkVector norm, unit, dummy, unitDummy;

	SkChopCubicAtHalf(pts, tmp);
	this->cubic_to(&tmp[0], normalAB, unitNormalAB, &norm, &unit,
	subDivide);
	// we use dummys since we already have a valid (and more accurate)
	// normals for CD
	this->cubic_to(&tmp[3], norm, unit, &dummy, &unitDummy, subDivide);
	} else {
	SkVector normalB, normalC;

	// need normals to inset/outset the off-curve pts B and C

	if (0) { // this is normal to the line between our adjacent pts
	normalB = pts[2] - pts[0];
	normalB.rotateCCW();
	SkAssertResult(normalB.setLength(fRadius));

	normalC = pts[3] - pts[1];
	normalC.rotateCCW();
	SkAssertResult(normalC.setLength(fRadius));
	} else { // miter-join
	SkVector unitBC = pts[2] - pts[1];
	unitBC.normalize();
	unitBC.rotateCCW();

	normalB = unitNormalAB + unitBC;
	normalC = *unitNormalCD + unitBC;

	SkScalar dot = SkPoint::DotProduct(unitNormalAB, unitBC);
	SkAssertResult(normalB.setLength(SkScalarDiv(fRadius,
	SkScalarSqrt((SK_Scalar1 + dot)/2))));
	dot = SkPoint::DotProduct(*unitNormalCD, unitBC);
	SkAssertResult(normalC.setLength(SkScalarDiv(fRadius,
	SkScalarSqrt((SK_Scalar1 + dot)/2))));
	}

	fOuter.cubicTo( pts[1].fX + normalB.fX, pts[1].fY + normalB.fY,
	pts[2].fX + normalC.fX, pts[2].fY + normalC.fY,
	pts[3].fX + normalCD->fX, pts[3].fY + normalCD->fY);

	fInner.cubicTo( pts[1].fX - normalB.fX, pts[1].fY - normalB.fY,
	pts[2].fX - normalC.fX, pts[2].fY - normalC.fY,
	pts[3].fX - normalCD->fX, pts[3].fY - normalCD->fY);
	}
	}

	void SkPathStroker::quadTo(const SkPoint& pt1, const SkPoint& pt2) {
	bool degenerateAB = degenerate_line(fPrevPt, pt1);
	bool degenerateBC = degenerate_line(pt1, pt2);

	if (degenerateAB \| degenerateBC) {
	if (degenerateAB ^ degenerateBC) {
	this->lineTo(pt2);
	}
	return;
	}

	SkVector normalAB, unitAB, normalBC, unitBC;

	this->preJoinTo(pt1, &normalAB, &unitAB, false);

	{
	SkPoint pts[3], tmp[5];
	pts[0] = fPrevPt;
	pts[1] = pt1;
	pts[2] = pt2;

	if (SkChopQuadAtMaxCurvature(pts, tmp) == 2) {
	unitBC.setNormalize(pts[2].fX - pts[1].fX, pts[2].fY - pts[1].fY);
	unitBC.rotateCCW();
	if (normals_too_pinchy(unitAB, unitBC)) {
	normalBC = unitBC;
	normalBC.scale(fRadius);

	fOuter.lineTo(tmp[2].fX + normalAB.fX, tmp[2].fY + normalAB.fY);
	fOuter.lineTo(tmp[2].fX + normalBC.fX, tmp[2].fY + normalBC.fY);
	fOuter.lineTo(tmp[4].fX + normalBC.fX, tmp[4].fY + normalBC.fY);

	fInner.lineTo(tmp[2].fX - normalAB.fX, tmp[2].fY - normalAB.fY);
	fInner.lineTo(tmp[2].fX - normalBC.fX, tmp[2].fY - normalBC.fY);
	fInner.lineTo(tmp[4].fX - normalBC.fX, tmp[4].fY - normalBC.fY);

	fExtra.addCircle(tmp[2].fX, tmp[2].fY, fRadius,
	SkPath::kCW_Direction);
	} else {
	this->quad_to(&tmp[0], normalAB, unitAB, &normalBC, &unitBC,
	kMaxQuadSubdivide);
	SkVector n = normalBC;
	SkVector u = unitBC;
	this->quad_to(&tmp[2], n, u, &normalBC, &unitBC,
	kMaxQuadSubdivide);
	}
	} else {
	this->quad_to(pts, normalAB, unitAB, &normalBC, &unitBC,
	kMaxQuadSubdivide);
	}
	}

	this->postJoinTo(pt2, normalBC, unitBC);
	}

	void SkPathStroker::cubicTo(const SkPoint& pt1, const SkPoint& pt2,
	const SkPoint& pt3) {
	bool degenerateAB = degenerate_line(fPrevPt, pt1);
	bool degenerateBC = degenerate_line(pt1, pt2);
	bool degenerateCD = degenerate_line(pt2, pt3);

	if (degenerateAB + degenerateBC + degenerateCD >= 2) {
	this->lineTo(pt3);
	return;
	}

	SkVector normalAB, unitAB, normalCD, unitCD;

	// find the first tangent (which might be pt1 or pt2
	{
	const SkPoint* nextPt = &pt1;
	if (degenerateAB)
	nextPt = &pt2;
	this->preJoinTo(*nextPt, &normalAB, &unitAB, false);
	}

	{
	SkPoint pts[4], tmp[13];
	int i, count;
	SkVector n, u;
	SkScalar tValues[3];

	pts[0] = fPrevPt;
	pts[1] = pt1;
	pts[2] = pt2;
	pts[3] = pt3;

	#if 1
	count = SkChopCubicAtMaxCurvature(pts, tmp, tValues);
	#else
	count = 1;
	memcpy(tmp, pts, 4 * sizeof(SkPoint));
	#endif
	n = normalAB;
	u = unitAB;
	for (i = 0; i < count; i++) {
	this->cubic_to(&tmp[i * 3], n, u, &normalCD, &unitCD,
	kMaxCubicSubdivide);
	if (i == count - 1) {
	break;
	}
	n = normalCD;
	u = unitCD;

	}

	// check for too pinchy
	for (i = 1; i < count; i++) {
	SkPoint p;
	SkVector v, c;

	SkEvalCubicAt(pts, tValues[i - 1], &p, &v, &c);

	SkScalar dot = SkPoint::DotProduct(c, c);
	v.scale(SkScalarInvert(dot));

	if (SkScalarNearlyZero(v.fX) && SkScalarNearlyZero(v.fY)) {
	fExtra.addCircle(p.fX, p.fY, fRadius, SkPath::kCW_Direction);
	}
	}

	}

	this->postJoinTo(pt3, normalCD, unitCD);
	}

	///////////////////////////////////////////////////////////////////////////////
	///////////////////////////////////////////////////////////////////////////////

	#include "SkPaint.h"

	SkStroke::SkStroke() {
	fWidth = SK_DefaultStrokeWidth;
	fMiterLimit = SK_DefaultMiterLimit;
	fCap = SkPaint::kDefault_Cap;
	fJoin = SkPaint::kDefault_Join;
	fDoFill = false;
	}

	SkStroke::SkStroke(const SkPaint& p) {
	fWidth = p.getStrokeWidth();
	fMiterLimit = p.getStrokeMiter();
	fCap = (uint8_t)p.getStrokeCap();
	fJoin = (uint8_t)p.getStrokeJoin();
	fDoFill = SkToU8(p.getStyle() == SkPaint::kStrokeAndFill_Style);
	}

	SkStroke::SkStroke(const SkPaint& p, SkScalar width) {
	fWidth = width;
	fMiterLimit = p.getStrokeMiter();
	fCap = (uint8_t)p.getStrokeCap();
	fJoin = (uint8_t)p.getStrokeJoin();
	fDoFill = SkToU8(p.getStyle() == SkPaint::kStrokeAndFill_Style);
	}

	void SkStroke::setWidth(SkScalar width) {
	SkASSERT(width >= 0);
	fWidth = width;
	}

	void SkStroke::setMiterLimit(SkScalar miterLimit) {
	SkASSERT(miterLimit >= 0);
	fMiterLimit = miterLimit;
	}

	void SkStroke::setCap(SkPaint::Cap cap) {
	SkASSERT((unsigned)cap < SkPaint::kCapCount);
	fCap = SkToU8(cap);
	}

	void SkStroke::setJoin(SkPaint::Join join) {
	SkASSERT((unsigned)join < SkPaint::kJoinCount);
	fJoin = SkToU8(join);
	}

	///////////////////////////////////////////////////////////////////////////////

	#ifdef SK_SCALAR_IS_FIXED
	/* return non-zero if the path is too big, and should be shrunk to avoid
	overflows during intermediate calculations. Note that we compute the
	bounds for this. If we had a custom callback/walker for paths, we could
	perhaps go faster by using that, and just perform the abs \| in that
	routine
	*/
	static int needs_to_shrink(const SkPath& path) {
	const SkRect& r = path.getBounds();
	SkFixed mask = SkAbs32(r.fLeft);
	mask \|= SkAbs32(r.fTop);
	mask \|= SkAbs32(r.fRight);
	mask \|= SkAbs32(r.fBottom);
	// we need the top 3 bits clear (after abs) to avoid overflow
	return mask >> 29;
	}

	static void identity_proc(SkPoint pts[], int count) {}
	static void shift_down_2_proc(SkPoint pts[], int count) {
	for (int i = 0; i < count; i++) {
	pts->fX >>= 2;
	pts->fY >>= 2;
	pts += 1;
	}
	}
	#define APPLY_PROC(proc, pts, count) proc(pts, count)
	#else // float does need any of this
	#define APPLY_PROC(proc, pts, count)
	#endif

	void SkStroke::strokePath(const SkPath& src, SkPath* dst) const {
	SkASSERT(&src != NULL && dst != NULL);

	SkScalar radius = SkScalarHalf(fWidth);

	dst->reset();
	if (radius <= 0) {
	return;
	}

	#ifdef SK_SCALAR_IS_FIXED
	void (*proc)(SkPoint pts[], int count) = identity_proc;
	if (needs_to_shrink(src)) {
	proc = shift_down_2_proc;
	radius >>= 2;
	if (radius == 0) {
	return;
	}
	}
	#endif

	SkPathStroker stroker(radius, fMiterLimit, this->getCap(),
	this->getJoin());

	SkPath::Iter iter(src, false);
	SkPoint pts[4];
	SkPath::Verb verb, lastSegment = SkPath::kMove_Verb;

	while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {
	switch (verb) {
	case SkPath::kMove_Verb:
	APPLY_PROC(proc, &pts[0], 1);
	stroker.moveTo(pts[0]);
	break;
	case SkPath::kLine_Verb:
	APPLY_PROC(proc, &pts[1], 1);
	stroker.lineTo(pts[1]);
	lastSegment = verb;
	break;
	case SkPath::kQuad_Verb:
	APPLY_PROC(proc, &pts[1], 2);
	stroker.quadTo(pts[1], pts[2]);
	lastSegment = verb;
	break;
	case SkPath::kCubic_Verb:
	APPLY_PROC(proc, &pts[1], 3);
	stroker.cubicTo(pts[1], pts[2], pts[3]);
	lastSegment = verb;
	break;
	case SkPath::kClose_Verb:
	stroker.close(lastSegment == SkPath::kLine_Verb);
	break;
	default:
	break;
	}
	}
	stroker.done(dst, lastSegment == SkPath::kLine_Verb);

	#ifdef SK_SCALAR_IS_FIXED
	// undo our previous down_shift
	if (shift_down_2_proc == proc) {
	// need a real shift methid on path. antialias paths could use this too
	SkMatrix matrix;
	matrix.setScale(SkIntToScalar(4), SkIntToScalar(4));
	dst->transform(matrix);
	}
	#endif

	if (fDoFill) {
	dst->addPath(src);
	} else {
	if (src.countPoints() == 2) {
	dst->setIsConvex(true);
	}
	}
	}

	void SkStroke::strokeLine(const SkPoint& p0, const SkPoint& p1,
	SkPath* dst) const {
	SkPath tmp;

	tmp.moveTo(p0);
	tmp.lineTo(p1);
	this->strokePath(tmp, dst);
	}