src/effects/SkDashPathEffect.cpp - 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.
  */

 #include "include/effects/SkDashPathEffect.h"

 #include "include/core/SkFlattenable.h"
 #include "include/core/SkMatrix.h"
 #include "include/core/SkPaint.h"
 #include "include/core/SkPath.h"
 #include "include/core/SkPathEffect.h"
 #include "include/core/SkPoint.h"
 #include "include/core/SkRect.h"
 #include "include/core/SkStrokeRec.h"
 #include "include/private/base/SkAlign.h"
 #include "include/private/base/SkFloatingPoint.h"
 #include "include/private/base/SkMalloc.h"
 #include "include/private/base/SkTemplates.h"
 #include "include/private/base/SkTo.h"
 #include "src/core/SkReadBuffer.h"
 #include "src/core/SkWriteBuffer.h"
 #include "src/effects/SkDashImpl.h"
 #include "src/utils/SkDashPathPriv.h"

 #include <algorithm>
 #include <cstdint>
 #include <cstring>

 using namespace skia_private;

 SkDashImpl::SkDashImpl(const SkScalar intervals[], int count, SkScalar phase)
         : fPhase(0)
         , fInitialDashLength(-1)
         , fInitialDashIndex(0)
         , fIntervalLength(0) {
     SkASSERT(intervals);
     SkASSERT(count > 1 && SkIsAlign2(count));

     fIntervals = (SkScalar*)sk_malloc_throw(sizeof(SkScalar) * count);
     fCount = count;
     for (int i = 0; i < count; i++) {
         fIntervals[i] = intervals[i];
     }

     // set the internal data members
     SkDashPath::CalcDashParameters(phase, fIntervals, fCount,
             &fInitialDashLength, &fInitialDashIndex, &fIntervalLength, &fPhase);
 }

 SkDashImpl::~SkDashImpl() {
     sk_free(fIntervals);
 }

 bool SkDashImpl::onFilterPath(SkPath* dst, const SkPath& src, SkStrokeRec* rec,
                               const SkRect* cullRect, const SkMatrix&) const {
     return SkDashPath::InternalFilter(dst, src, rec, cullRect, fIntervals, fCount,
                                       fInitialDashLength, fInitialDashIndex, fIntervalLength,
                                       fPhase);
 }

 static void outset_for_stroke(SkRect* rect, const SkStrokeRec& rec) {
     SkScalar radius = SkScalarHalf(rec.getWidth());
     if (0 == radius) {
         radius = SK_Scalar1;    // hairlines
     }
     if (SkPaint::kMiter_Join == rec.getJoin()) {
         radius *= rec.getMiter();
     }
     rect->outset(radius, radius);
 }

 // Attempt to trim the line to minimally cover the cull rect (currently
 // only works for horizontal and vertical lines).
 // Return true if processing should continue; false otherwise.
 static bool cull_line(SkPoint* pts, const SkStrokeRec& rec,
                       const SkMatrix& ctm, const SkRect* cullRect,
                       const SkScalar intervalLength) {
     if (nullptr == cullRect) {
         SkASSERT(false); // Shouldn't ever occur in practice
         return false;
     }

     SkScalar dx = pts[1].x() - pts[0].x();
     SkScalar dy = pts[1].y() - pts[0].y();

     if ((dx && dy) || (!dx && !dy)) {
         return false;
     }

     SkRect bounds = *cullRect;
     outset_for_stroke(&bounds, rec);

     // cullRect is in device space while pts are in the local coordinate system
     // defined by the ctm. We want our answer in the local coordinate system.

     SkASSERT(ctm.rectStaysRect());
     SkMatrix inv;
     if (!ctm.invert(&inv)) {
         return false;
     }

     inv.mapRect(&bounds);

     if (dx) {
         SkASSERT(dx && !dy);
         SkScalar minX = pts[0].fX;
         SkScalar maxX = pts[1].fX;

         if (dx < 0) {
             using std::swap;
             swap(minX, maxX);
         }

         SkASSERT(minX < maxX);
         if (maxX <= bounds.fLeft || minX >= bounds.fRight) {
             return false;
         }

         // Now we actually perform the chop, removing the excess to the left and
         // right of the bounds (keeping our new line "in phase" with the dash,
         // hence the (mod intervalLength).

         if (minX < bounds.fLeft) {
             minX = bounds.fLeft - SkScalarMod(bounds.fLeft - minX, intervalLength);
         }
         if (maxX > bounds.fRight) {
             maxX = bounds.fRight + SkScalarMod(maxX - bounds.fRight, intervalLength);
         }

         SkASSERT(maxX > minX);
         if (dx < 0) {
             using std::swap;
             swap(minX, maxX);
         }
         pts[0].fX = minX;
         pts[1].fX = maxX;
     } else {
         SkASSERT(dy && !dx);
         SkScalar minY = pts[0].fY;
         SkScalar maxY = pts[1].fY;

         if (dy < 0) {
             using std::swap;
             swap(minY, maxY);
         }

         SkASSERT(minY < maxY);
         if (maxY <= bounds.fTop || minY >= bounds.fBottom) {
             return false;
         }

         // Now we actually perform the chop, removing the excess to the top and
         // bottom of the bounds (keeping our new line "in phase" with the dash,
         // hence the (mod intervalLength).

         if (minY < bounds.fTop) {
             minY = bounds.fTop - SkScalarMod(bounds.fTop - minY, intervalLength);
         }
         if (maxY > bounds.fBottom) {
             maxY = bounds.fBottom + SkScalarMod(maxY - bounds.fBottom, intervalLength);
         }

         SkASSERT(maxY > minY);
         if (dy < 0) {
             using std::swap;
             swap(minY, maxY);
         }
         pts[0].fY = minY;
         pts[1].fY = maxY;
     }

     return true;
 }

 // Currently asPoints is more restrictive then it needs to be. In the future
 // we need to:
 //      allow kRound_Cap capping (could allow rotations in the matrix with this)
 //      allow paths to be returned
 bool SkDashImpl::onAsPoints(PointData* results, const SkPath& src, const SkStrokeRec& rec,
                             const SkMatrix& matrix, const SkRect* cullRect) const {
     // width < 0 -> fill && width == 0 -> hairline so requiring width > 0 rules both out
     if (0 >= rec.getWidth()) {
         return false;
     }

     // TODO: this next test could be eased up. We could allow any number of
     // intervals as long as all the ons match and all the offs match.
     // Additionally, they do not necessarily need to be integers.
     // We cannot allow arbitrary intervals since we want the returned points
     // to be uniformly sized.
     if (fCount != 2 ||
         !SkScalarNearlyEqual(fIntervals[0], fIntervals[1]) ||
         !SkScalarIsInt(fIntervals[0]) ||
         !SkScalarIsInt(fIntervals[1])) {
         return false;
     }

     SkPoint pts[2];

     if (!src.isLine(pts)) {
         return false;
     }

     // TODO: this test could be eased up to allow circles
     if (SkPaint::kButt_Cap != rec.getCap()) {
         return false;
     }

     // TODO: this test could be eased up for circles. Rotations could be allowed.
     if (!matrix.rectStaysRect()) {
         return false;
     }

     // See if the line can be limited to something plausible.
     if (!cull_line(pts, rec, matrix, cullRect, fIntervalLength)) {
         return false;
     }

     SkScalar length = SkPoint::Distance(pts[1], pts[0]);

     SkVector tangent = pts[1] - pts[0];
     if (tangent.isZero()) {
         return false;
     }

     tangent.scale(SkScalarInvert(length));

     // TODO: make this test for horizontal & vertical lines more robust
     bool isXAxis = true;
     if (SkScalarNearlyEqual(SK_Scalar1, tangent.fX) ||
         SkScalarNearlyEqual(-SK_Scalar1, tangent.fX)) {
         results->fSize.set(SkScalarHalf(fIntervals[0]), SkScalarHalf(rec.getWidth()));
     } else if (SkScalarNearlyEqual(SK_Scalar1, tangent.fY) ||
                SkScalarNearlyEqual(-SK_Scalar1, tangent.fY)) {
         results->fSize.set(SkScalarHalf(rec.getWidth()), SkScalarHalf(fIntervals[0]));
         isXAxis = false;
     } else if (SkPaint::kRound_Cap != rec.getCap()) {
         // Angled lines don't have axis-aligned boxes.
         return false;
     }

     if (results) {
         results->fFlags = 0;
         SkScalar clampedInitialDashLength = std::min(length, fInitialDashLength);

         if (SkPaint::kRound_Cap == rec.getCap()) {
             results->fFlags |= PointData::kCircles_PointFlag;
         }

         results->fNumPoints = 0;
         SkScalar len2 = length;
         if (clampedInitialDashLength > 0 || 0 == fInitialDashIndex) {
             SkASSERT(len2 >= clampedInitialDashLength);
             if (0 == fInitialDashIndex) {
                 if (clampedInitialDashLength > 0) {
                     if (clampedInitialDashLength >= fIntervals[0]) {
                         ++results->fNumPoints;  // partial first dash
                     }
                     len2 -= clampedInitialDashLength;
                 }
                 len2 -= fIntervals[1];  // also skip first space
                 if (len2 < 0) {
                     len2 = 0;
                 }
             } else {
                 len2 -= clampedInitialDashLength; // skip initial partial empty
             }
         }
         // Too many midpoints can cause results->fNumPoints to overflow or
         // otherwise cause the results->fPoints allocation below to OOM.
         // Cap it to a sane value.
         SkScalar numIntervals = len2 / fIntervalLength;
         if (!SkIsFinite(numIntervals) || numIntervals > SkDashPath::kMaxDashCount) {
             return false;
         }
         int numMidPoints = SkScalarFloorToInt(numIntervals);
         results->fNumPoints += numMidPoints;
         len2 -= numMidPoints * fIntervalLength;
         bool partialLast = false;
         if (len2 > 0) {
             if (len2 < fIntervals[0]) {
                 partialLast = true;
             } else {
                 ++numMidPoints;
                 ++results->fNumPoints;
             }
         }

         results->fPoints = new SkPoint[results->fNumPoints];

         SkScalar    distance = 0;
         int         curPt = 0;

         if (clampedInitialDashLength > 0 || 0 == fInitialDashIndex) {
             SkASSERT(clampedInitialDashLength <= length);

             if (0 == fInitialDashIndex) {
                 if (clampedInitialDashLength > 0) {
                     // partial first block
                     SkASSERT(SkPaint::kRound_Cap != rec.getCap()); // can't handle partial circles
                     SkScalar x = pts[0].fX + tangent.fX * SkScalarHalf(clampedInitialDashLength);
                     SkScalar y = pts[0].fY + tangent.fY * SkScalarHalf(clampedInitialDashLength);
                     SkScalar halfWidth, halfHeight;
                     if (isXAxis) {
                         halfWidth = SkScalarHalf(clampedInitialDashLength);
                         halfHeight = SkScalarHalf(rec.getWidth());
                     } else {
                         halfWidth = SkScalarHalf(rec.getWidth());
                         halfHeight = SkScalarHalf(clampedInitialDashLength);
                     }
                     if (clampedInitialDashLength < fIntervals[0]) {
                         // This one will not be like the others
                         results->fFirst.addRect(x - halfWidth, y - halfHeight,
                                                 x + halfWidth, y + halfHeight);
                     } else {
                         SkASSERT(curPt < results->fNumPoints);
                         results->fPoints[curPt].set(x, y);
                         ++curPt;
                     }

                     distance += clampedInitialDashLength;
                 }

                 distance += fIntervals[1];  // skip over the next blank block too
             } else {
                 distance += clampedInitialDashLength;
             }
         }

         if (0 != numMidPoints) {
             distance += SkScalarHalf(fIntervals[0]);

             for (int i = 0; i < numMidPoints; ++i) {
                 SkScalar x = pts[0].fX + tangent.fX * distance;
                 SkScalar y = pts[0].fY + tangent.fY * distance;

                 SkASSERT(curPt < results->fNumPoints);
                 results->fPoints[curPt].set(x, y);
                 ++curPt;

                 distance += fIntervalLength;
             }

             distance -= SkScalarHalf(fIntervals[0]);
         }

         if (partialLast) {
             // partial final block
             SkASSERT(SkPaint::kRound_Cap != rec.getCap()); // can't handle partial circles
             SkScalar temp = length - distance;
             SkASSERT(temp < fIntervals[0]);
             SkScalar x = pts[0].fX + tangent.fX * (distance + SkScalarHalf(temp));
             SkScalar y = pts[0].fY + tangent.fY * (distance + SkScalarHalf(temp));
             SkScalar halfWidth, halfHeight;
             if (isXAxis) {
                 halfWidth = SkScalarHalf(temp);
                 halfHeight = SkScalarHalf(rec.getWidth());
             } else {
                 halfWidth = SkScalarHalf(rec.getWidth());
                 halfHeight = SkScalarHalf(temp);
             }
             results->fLast.addRect(x - halfWidth, y - halfHeight,
                                    x + halfWidth, y + halfHeight);
         }

         SkASSERT(curPt == results->fNumPoints);
     }

     return true;
 }

 SkPathEffect::DashType SkDashImpl::onAsADash(DashInfo* info) const {
     if (info) {
         if (info->fCount >= fCount && info->fIntervals) {
             memcpy(info->fIntervals, fIntervals, fCount * sizeof(SkScalar));
         }
         info->fCount = fCount;
         info->fPhase = fPhase;
     }
     return kDash_DashType;
 }

 void SkDashImpl::flatten(SkWriteBuffer& buffer) const {
     buffer.writeScalar(fPhase);
     buffer.writeScalarArray(fIntervals, fCount);
 }

 sk_sp<SkFlattenable> SkDashImpl::CreateProc(SkReadBuffer& buffer) {
     const SkScalar phase = buffer.readScalar();
     uint32_t count = buffer.getArrayCount();

     // Don't allocate gigantic buffers if there's not data for them.
     if (!buffer.validateCanReadN<SkScalar>(count)) {
         return nullptr;
     }

     AutoSTArray<32, SkScalar> intervals(count);
     if (buffer.readScalarArray(intervals.get(), count)) {
         return SkDashPathEffect::Make(intervals.get(), SkToInt(count), phase);
     }
     return nullptr;
 }

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

 sk_sp<SkPathEffect> SkDashPathEffect::Make(const SkScalar intervals[], int count, SkScalar phase) {
     if (!SkDashPath::ValidDashPath(phase, intervals, count)) {
         return nullptr;
     }
     return sk_sp<SkPathEffect>(new SkDashImpl(intervals, count, phase));
 }
	/*
	* 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.
	*/

	#include "include/effects/SkDashPathEffect.h"

	#include "include/core/SkFlattenable.h"
	#include "include/core/SkMatrix.h"
	#include "include/core/SkPaint.h"
	#include "include/core/SkPath.h"
	#include "include/core/SkPathEffect.h"
	#include "include/core/SkPoint.h"
	#include "include/core/SkRect.h"
	#include "include/core/SkStrokeRec.h"
	#include "include/private/base/SkAlign.h"
	#include "include/private/base/SkFloatingPoint.h"
	#include "include/private/base/SkMalloc.h"
	#include "include/private/base/SkTemplates.h"
	#include "include/private/base/SkTo.h"
	#include "src/core/SkReadBuffer.h"
	#include "src/core/SkWriteBuffer.h"
	#include "src/effects/SkDashImpl.h"
	#include "src/utils/SkDashPathPriv.h"

	#include <algorithm>
	#include <cstdint>
	#include <cstring>

	using namespace skia_private;

	SkDashImpl::SkDashImpl(const SkScalar intervals[], int count, SkScalar phase)
	: fPhase(0)
	, fInitialDashLength(-1)
	, fInitialDashIndex(0)
	, fIntervalLength(0) {
	SkASSERT(intervals);
	SkASSERT(count > 1 && SkIsAlign2(count));

	fIntervals = (SkScalar)sk_malloc_throw(sizeof(SkScalar) count);
	fCount = count;
	for (int i = 0; i < count; i++) {
	fIntervals[i] = intervals[i];
	}

	// set the internal data members
	SkDashPath::CalcDashParameters(phase, fIntervals, fCount,
	&fInitialDashLength, &fInitialDashIndex, &fIntervalLength, &fPhase);
	}

	SkDashImpl::~SkDashImpl() {
	sk_free(fIntervals);
	}

	bool SkDashImpl::onFilterPath(SkPath* dst, const SkPath& src, SkStrokeRec* rec,
	const SkRect* cullRect, const SkMatrix&) const {
	return SkDashPath::InternalFilter(dst, src, rec, cullRect, fIntervals, fCount,
	fInitialDashLength, fInitialDashIndex, fIntervalLength,
	fPhase);
	}

	static void outset_for_stroke(SkRect* rect, const SkStrokeRec& rec) {
	SkScalar radius = SkScalarHalf(rec.getWidth());
	if (0 == radius) {
	radius = SK_Scalar1; // hairlines
	}
	if (SkPaint::kMiter_Join == rec.getJoin()) {
	radius *= rec.getMiter();
	}
	rect->outset(radius, radius);
	}

	// Attempt to trim the line to minimally cover the cull rect (currently
	// only works for horizontal and vertical lines).
	// Return true if processing should continue; false otherwise.
	static bool cull_line(SkPoint* pts, const SkStrokeRec& rec,
	const SkMatrix& ctm, const SkRect* cullRect,
	const SkScalar intervalLength) {
	if (nullptr == cullRect) {
	SkASSERT(false); // Shouldn't ever occur in practice
	return false;
	}

	SkScalar dx = pts[1].x() - pts[0].x();
	SkScalar dy = pts[1].y() - pts[0].y();

	if ((dx && dy) \|\| (!dx && !dy)) {
	return false;
	}

	SkRect bounds = *cullRect;
	outset_for_stroke(&bounds, rec);

	// cullRect is in device space while pts are in the local coordinate system
	// defined by the ctm. We want our answer in the local coordinate system.

	SkASSERT(ctm.rectStaysRect());
	SkMatrix inv;
	if (!ctm.invert(&inv)) {
	return false;
	}

	inv.mapRect(&bounds);

	if (dx) {
	SkASSERT(dx && !dy);
	SkScalar minX = pts[0].fX;
	SkScalar maxX = pts[1].fX;

	if (dx < 0) {
	using std::swap;
	swap(minX, maxX);
	}

	SkASSERT(minX < maxX);
	if (maxX <= bounds.fLeft \|\| minX >= bounds.fRight) {
	return false;
	}

	// Now we actually perform the chop, removing the excess to the left and
	// right of the bounds (keeping our new line "in phase" with the dash,
	// hence the (mod intervalLength).

	if (minX < bounds.fLeft) {
	minX = bounds.fLeft - SkScalarMod(bounds.fLeft - minX, intervalLength);
	}
	if (maxX > bounds.fRight) {
	maxX = bounds.fRight + SkScalarMod(maxX - bounds.fRight, intervalLength);
	}

	SkASSERT(maxX > minX);
	if (dx < 0) {
	using std::swap;
	swap(minX, maxX);
	}
	pts[0].fX = minX;
	pts[1].fX = maxX;
	} else {
	SkASSERT(dy && !dx);
	SkScalar minY = pts[0].fY;
	SkScalar maxY = pts[1].fY;

	if (dy < 0) {
	using std::swap;
	swap(minY, maxY);
	}

	SkASSERT(minY < maxY);
	if (maxY <= bounds.fTop \|\| minY >= bounds.fBottom) {
	return false;
	}

	// Now we actually perform the chop, removing the excess to the top and
	// bottom of the bounds (keeping our new line "in phase" with the dash,
	// hence the (mod intervalLength).

	if (minY < bounds.fTop) {
	minY = bounds.fTop - SkScalarMod(bounds.fTop - minY, intervalLength);
	}
	if (maxY > bounds.fBottom) {
	maxY = bounds.fBottom + SkScalarMod(maxY - bounds.fBottom, intervalLength);
	}

	SkASSERT(maxY > minY);
	if (dy < 0) {
	using std::swap;
	swap(minY, maxY);
	}
	pts[0].fY = minY;
	pts[1].fY = maxY;
	}

	return true;
	}

	// Currently asPoints is more restrictive then it needs to be. In the future
	// we need to:
	// allow kRound_Cap capping (could allow rotations in the matrix with this)
	// allow paths to be returned
	bool SkDashImpl::onAsPoints(PointData* results, const SkPath& src, const SkStrokeRec& rec,
	const SkMatrix& matrix, const SkRect* cullRect) const {
	// width < 0 -> fill && width == 0 -> hairline so requiring width > 0 rules both out
	if (0 >= rec.getWidth()) {
	return false;
	}

	// TODO: this next test could be eased up. We could allow any number of
	// intervals as long as all the ons match and all the offs match.
	// Additionally, they do not necessarily need to be integers.
	// We cannot allow arbitrary intervals since we want the returned points
	// to be uniformly sized.
	if (fCount != 2 \|\|
	!SkScalarNearlyEqual(fIntervals[0], fIntervals[1]) \|\|
	!SkScalarIsInt(fIntervals[0]) \|\|
	!SkScalarIsInt(fIntervals[1])) {
	return false;
	}

	SkPoint pts[2];

	if (!src.isLine(pts)) {
	return false;
	}

	// TODO: this test could be eased up to allow circles
	if (SkPaint::kButt_Cap != rec.getCap()) {
	return false;
	}

	// TODO: this test could be eased up for circles. Rotations could be allowed.
	if (!matrix.rectStaysRect()) {
	return false;
	}

	// See if the line can be limited to something plausible.
	if (!cull_line(pts, rec, matrix, cullRect, fIntervalLength)) {
	return false;
	}

	SkScalar length = SkPoint::Distance(pts[1], pts[0]);

	SkVector tangent = pts[1] - pts[0];
	if (tangent.isZero()) {
	return false;
	}

	tangent.scale(SkScalarInvert(length));

	// TODO: make this test for horizontal & vertical lines more robust
	bool isXAxis = true;
	if (SkScalarNearlyEqual(SK_Scalar1, tangent.fX) \|\|
	SkScalarNearlyEqual(-SK_Scalar1, tangent.fX)) {
	results->fSize.set(SkScalarHalf(fIntervals[0]), SkScalarHalf(rec.getWidth()));
	} else if (SkScalarNearlyEqual(SK_Scalar1, tangent.fY) \|\|
	SkScalarNearlyEqual(-SK_Scalar1, tangent.fY)) {
	results->fSize.set(SkScalarHalf(rec.getWidth()), SkScalarHalf(fIntervals[0]));
	isXAxis = false;
	} else if (SkPaint::kRound_Cap != rec.getCap()) {
	// Angled lines don't have axis-aligned boxes.
	return false;
	}

	if (results) {
	results->fFlags = 0;
	SkScalar clampedInitialDashLength = std::min(length, fInitialDashLength);

	if (SkPaint::kRound_Cap == rec.getCap()) {
	results->fFlags \|= PointData::kCircles_PointFlag;
	}

	results->fNumPoints = 0;
	SkScalar len2 = length;
	if (clampedInitialDashLength > 0 \|\| 0 == fInitialDashIndex) {
	SkASSERT(len2 >= clampedInitialDashLength);
	if (0 == fInitialDashIndex) {
	if (clampedInitialDashLength > 0) {
	if (clampedInitialDashLength >= fIntervals[0]) {
	++results->fNumPoints; // partial first dash
	}
	len2 -= clampedInitialDashLength;
	}
	len2 -= fIntervals[1]; // also skip first space
	if (len2 < 0) {
	len2 = 0;
	}
	} else {
	len2 -= clampedInitialDashLength; // skip initial partial empty
	}
	}
	// Too many midpoints can cause results->fNumPoints to overflow or
	// otherwise cause the results->fPoints allocation below to OOM.
	// Cap it to a sane value.
	SkScalar numIntervals = len2 / fIntervalLength;
	if (!SkIsFinite(numIntervals) \|\| numIntervals > SkDashPath::kMaxDashCount) {
	return false;
	}
	int numMidPoints = SkScalarFloorToInt(numIntervals);
	results->fNumPoints += numMidPoints;
	len2 -= numMidPoints * fIntervalLength;
	bool partialLast = false;
	if (len2 > 0) {
	if (len2 < fIntervals[0]) {
	partialLast = true;
	} else {
	++numMidPoints;
	++results->fNumPoints;
	}
	}

	results->fPoints = new SkPoint[results->fNumPoints];

	SkScalar distance = 0;
	int curPt = 0;

	if (clampedInitialDashLength > 0 \|\| 0 == fInitialDashIndex) {
	SkASSERT(clampedInitialDashLength <= length);

	if (0 == fInitialDashIndex) {
	if (clampedInitialDashLength > 0) {
	// partial first block
	SkASSERT(SkPaint::kRound_Cap != rec.getCap()); // can't handle partial circles
	SkScalar x = pts[0].fX + tangent.fX * SkScalarHalf(clampedInitialDashLength);
	SkScalar y = pts[0].fY + tangent.fY * SkScalarHalf(clampedInitialDashLength);
	SkScalar halfWidth, halfHeight;
	if (isXAxis) {
	halfWidth = SkScalarHalf(clampedInitialDashLength);
	halfHeight = SkScalarHalf(rec.getWidth());
	} else {
	halfWidth = SkScalarHalf(rec.getWidth());
	halfHeight = SkScalarHalf(clampedInitialDashLength);
	}
	if (clampedInitialDashLength < fIntervals[0]) {
	// This one will not be like the others
	results->fFirst.addRect(x - halfWidth, y - halfHeight,
	x + halfWidth, y + halfHeight);
	} else {
	SkASSERT(curPt < results->fNumPoints);
	results->fPoints[curPt].set(x, y);
	++curPt;
	}

	distance += clampedInitialDashLength;
	}

	distance += fIntervals[1]; // skip over the next blank block too
	} else {
	distance += clampedInitialDashLength;
	}
	}

	if (0 != numMidPoints) {
	distance += SkScalarHalf(fIntervals[0]);

	for (int i = 0; i < numMidPoints; ++i) {
	SkScalar x = pts[0].fX + tangent.fX * distance;
	SkScalar y = pts[0].fY + tangent.fY * distance;

	SkASSERT(curPt < results->fNumPoints);
	results->fPoints[curPt].set(x, y);
	++curPt;

	distance += fIntervalLength;
	}

	distance -= SkScalarHalf(fIntervals[0]);
	}

	if (partialLast) {
	// partial final block
	SkASSERT(SkPaint::kRound_Cap != rec.getCap()); // can't handle partial circles
	SkScalar temp = length - distance;
	SkASSERT(temp < fIntervals[0]);
	SkScalar x = pts[0].fX + tangent.fX * (distance + SkScalarHalf(temp));
	SkScalar y = pts[0].fY + tangent.fY * (distance + SkScalarHalf(temp));
	SkScalar halfWidth, halfHeight;
	if (isXAxis) {
	halfWidth = SkScalarHalf(temp);
	halfHeight = SkScalarHalf(rec.getWidth());
	} else {
	halfWidth = SkScalarHalf(rec.getWidth());
	halfHeight = SkScalarHalf(temp);
	}
	results->fLast.addRect(x - halfWidth, y - halfHeight,
	x + halfWidth, y + halfHeight);
	}

	SkASSERT(curPt == results->fNumPoints);
	}

	return true;
	}

	SkPathEffect::DashType SkDashImpl::onAsADash(DashInfo* info) const {
	if (info) {
	if (info->fCount >= fCount && info->fIntervals) {
	memcpy(info->fIntervals, fIntervals, fCount * sizeof(SkScalar));
	}
	info->fCount = fCount;
	info->fPhase = fPhase;
	}
	return kDash_DashType;
	}

	void SkDashImpl::flatten(SkWriteBuffer& buffer) const {
	buffer.writeScalar(fPhase);
	buffer.writeScalarArray(fIntervals, fCount);
	}

	sk_sp<SkFlattenable> SkDashImpl::CreateProc(SkReadBuffer& buffer) {
	const SkScalar phase = buffer.readScalar();
	uint32_t count = buffer.getArrayCount();

	// Don't allocate gigantic buffers if there's not data for them.
	if (!buffer.validateCanReadN<SkScalar>(count)) {
	return nullptr;
	}

	AutoSTArray<32, SkScalar> intervals(count);
	if (buffer.readScalarArray(intervals.get(), count)) {
	return SkDashPathEffect::Make(intervals.get(), SkToInt(count), phase);
	}
	return nullptr;
	}

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

	sk_sp<SkPathEffect> SkDashPathEffect::Make(const SkScalar intervals[], int count, SkScalar phase) {
	if (!SkDashPath::ValidDashPath(phase, intervals, count)) {
	return nullptr;
	}
	return sk_sp<SkPathEffect>(new SkDashImpl(intervals, count, phase));
	}