/* * Copyright 2013 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkPathOpsDebug.h" #include "SkPath.h" #include "SkString.h" #include "SkThread.h" #if DEBUG_VALIDATE extern bool FLAGS_runFail; #endif #if DEBUG_SORT int SkPathOpsDebug::gSortCountDefault = SK_MaxS32; int SkPathOpsDebug::gSortCount; #endif #if DEBUG_ACTIVE_OP const char* SkPathOpsDebug::kPathOpStr[] = {"diff", "sect", "union", "xor"}; #endif #if defined SK_DEBUG || !FORCE_RELEASE const char* SkPathOpsDebug::kLVerbStr[] = {"", "line", "quad", "cubic"}; #if defined(SK_DEBUG) || !FORCE_RELEASE int SkPathOpsDebug::gContourID = 0; int SkPathOpsDebug::gSegmentID = 0; #endif bool SkPathOpsDebug::ChaseContains(const SkTDArray<SkOpSpanBase* >& chaseArray, const SkOpSpanBase* span) { for (int index = 0; index < chaseArray.count(); ++index) { const SkOpSpanBase* entry = chaseArray[index]; if (entry == span) { return true; } } return false; } void SkPathOpsDebug::MathematicaIze(char* str, size_t bufferLen) { size_t len = strlen(str); bool num = false; for (size_t idx = 0; idx < len; ++idx) { if (num && str[idx] == 'e') { if (len + 2 >= bufferLen) { return; } memmove(&str[idx + 2], &str[idx + 1], len - idx); str[idx] = '*'; str[idx + 1] = '^'; ++len; } num = str[idx] >= '0' && str[idx] <= '9'; } } bool SkPathOpsDebug::ValidWind(int wind) { return wind > SK_MinS32 + 0xFFFF && wind < SK_MaxS32 - 0xFFFF; } void SkPathOpsDebug::WindingPrintf(int wind) { if (wind == SK_MinS32) { SkDebugf("?"); } else { SkDebugf("%d", wind); } } #endif // defined SK_DEBUG || !FORCE_RELEASE #if DEBUG_SHOW_TEST_NAME void* SkPathOpsDebug::CreateNameStr() { return SkNEW_ARRAY(char, DEBUG_FILENAME_STRING_LENGTH); } void SkPathOpsDebug::DeleteNameStr(void* v) { SkDELETE_ARRAY(reinterpret_cast<char* >(v)); } void SkPathOpsDebug::BumpTestName(char* test) { char* num = test + strlen(test); while (num[-1] >= '0' && num[-1] <= '9') { --num; } if (num[0] == '\0') { return; } int dec = atoi(num); if (dec == 0) { return; } ++dec; SK_SNPRINTF(num, DEBUG_FILENAME_STRING_LENGTH - (num - test), "%d", dec); } #endif static void show_function_header(const char* functionName) { SkDebugf("\nstatic void %s(skiatest::Reporter* reporter, const char* filename) {\n", functionName); if (strcmp("skphealth_com76", functionName) == 0) { SkDebugf("found it\n"); } } static const char* gOpStrs[] = { "kDifference_SkPathOp", "kIntersect_SkPathOp", "kUnion_SkPathOp", "kXor_PathOp", "kReverseDifference_SkPathOp", }; const char* SkPathOpsDebug::OpStr(SkPathOp op) { return gOpStrs[op]; } static void show_op(SkPathOp op, const char* pathOne, const char* pathTwo) { SkDebugf(" testPathOp(reporter, %s, %s, %s, filename);\n", pathOne, pathTwo, gOpStrs[op]); SkDebugf("}\n"); } SK_DECLARE_STATIC_MUTEX(gTestMutex); void SkPathOpsDebug::ShowPath(const SkPath& a, const SkPath& b, SkPathOp shapeOp, const char* testName) { SkAutoMutexAcquire ac(gTestMutex); show_function_header(testName); ShowOnePath(a, "path", true); ShowOnePath(b, "pathB", true); show_op(shapeOp, "path", "pathB"); } #include "SkPathOpsCubic.h" #include "SkPathOpsQuad.h" SkDCubic SkDQuad::debugToCubic() const { SkDCubic cubic; cubic[0] = fPts[0]; cubic[2] = fPts[1]; cubic[3] = fPts[2]; cubic[1].fX = (cubic[0].fX + cubic[2].fX * 2) / 3; cubic[1].fY = (cubic[0].fY + cubic[2].fY * 2) / 3; cubic[2].fX = (cubic[3].fX + cubic[2].fX * 2) / 3; cubic[2].fY = (cubic[3].fY + cubic[2].fY * 2) / 3; return cubic; } #include "SkOpAngle.h" #include "SkOpCoincidence.h" #include "SkOpSegment.h" SkOpAngle* SkOpSegment::debugLastAngle() { SkOpAngle* result = NULL; SkOpSpan* span = this->head(); do { if (span->toAngle()) { SkASSERT(!result); result = span->toAngle(); } } while ((span = span->next()->upCastable())); SkASSERT(result); return result; } void SkOpSegment::debugReset() { this->init(this->fPts, this->fWeight, this->contour(), this->verb()); } #if DEBUG_ACTIVE_SPANS void SkOpSegment::debugShowActiveSpans() const { debugValidate(); if (done()) { return; } int lastId = -1; double lastT = -1; const SkOpSpan* span = &fHead; do { if (span->done()) { continue; } if (lastId == this->debugID() && lastT == span->t()) { continue; } lastId = this->debugID(); lastT = span->t(); SkDebugf("%s id=%d", __FUNCTION__, this->debugID()); SkDebugf(" (%1.9g,%1.9g", fPts[0].fX, fPts[0].fY); for (int vIndex = 1; vIndex <= SkPathOpsVerbToPoints(fVerb); ++vIndex) { SkDebugf(" %1.9g,%1.9g", fPts[vIndex].fX, fPts[vIndex].fY); } if (SkPath::kConic_Verb == fVerb) { SkDebugf(" %1.9gf", fWeight); } const SkOpPtT* ptT = span->ptT(); SkDebugf(") t=%1.9g (%1.9g,%1.9g)", ptT->fT, ptT->fPt.fX, ptT->fPt.fY); SkDebugf(" tEnd=%1.9g", span->next()->t()); if (span->windSum() == SK_MinS32) { SkDebugf(" windSum=?"); } else { SkDebugf(" windSum=%d", span->windSum()); } if (span->oppValue() && span->oppSum() == SK_MinS32) { SkDebugf(" oppSum=?"); } else if (span->oppValue() || span->oppSum() != SK_MinS32) { SkDebugf(" oppSum=%d", span->oppSum()); } SkDebugf(" windValue=%d", span->windValue()); if (span->oppValue() || span->oppSum() != SK_MinS32) { SkDebugf(" oppValue=%d", span->oppValue()); } SkDebugf("\n"); } while ((span = span->next()->upCastable())); } #endif #if DEBUG_MARK_DONE void SkOpSegment::debugShowNewWinding(const char* fun, const SkOpSpan* span, int winding) { const SkPoint& pt = span->ptT()->fPt; SkDebugf("%s id=%d", fun, this->debugID()); SkDebugf(" (%1.9g,%1.9g", fPts[0].fX, fPts[0].fY); for (int vIndex = 1; vIndex <= SkPathOpsVerbToPoints(fVerb); ++vIndex) { SkDebugf(" %1.9g,%1.9g", fPts[vIndex].fX, fPts[vIndex].fY); } SkDebugf(") t=%1.9g [%d] (%1.9g,%1.9g) tEnd=%1.9g newWindSum=", span->t(), span->debugID(), pt.fX, pt.fY, span->next()->t()); if (winding == SK_MinS32) { SkDebugf("?"); } else { SkDebugf("%d", winding); } SkDebugf(" windSum="); if (span->windSum() == SK_MinS32) { SkDebugf("?"); } else { SkDebugf("%d", span->windSum()); } SkDebugf(" windValue=%d\n", span->windValue()); } void SkOpSegment::debugShowNewWinding(const char* fun, const SkOpSpan* span, int winding, int oppWinding) { const SkPoint& pt = span->ptT()->fPt; SkDebugf("%s id=%d", fun, this->debugID()); SkDebugf(" (%1.9g,%1.9g", fPts[0].fX, fPts[0].fY); for (int vIndex = 1; vIndex <= SkPathOpsVerbToPoints(fVerb); ++vIndex) { SkDebugf(" %1.9g,%1.9g", fPts[vIndex].fX, fPts[vIndex].fY); } SkDebugf(") t=%1.9g [%d] (%1.9g,%1.9g) tEnd=%1.9g newWindSum=", span->t(), span->debugID(), pt.fX, pt.fY, span->next()->t(), winding, oppWinding); if (winding == SK_MinS32) { SkDebugf("?"); } else { SkDebugf("%d", winding); } SkDebugf(" newOppSum="); if (oppWinding == SK_MinS32) { SkDebugf("?"); } else { SkDebugf("%d", oppWinding); } SkDebugf(" oppSum="); if (span->oppSum() == SK_MinS32) { SkDebugf("?"); } else { SkDebugf("%d", span->oppSum()); } SkDebugf(" windSum="); if (span->windSum() == SK_MinS32) { SkDebugf("?"); } else { SkDebugf("%d", span->windSum()); } SkDebugf(" windValue=%d oppValue=%d\n", span->windValue(), span->oppValue()); } #endif #if DEBUG_ANGLE SkString SkOpAngle::debugPart() const { SkString result; switch (this->segment()->verb()) { case SkPath::kLine_Verb: result.printf(LINE_DEBUG_STR " id=%d", LINE_DEBUG_DATA(fCurvePart), this->segment()->debugID()); break; case SkPath::kQuad_Verb: result.printf(QUAD_DEBUG_STR " id=%d", QUAD_DEBUG_DATA(fCurvePart), this->segment()->debugID()); break; case SkPath::kConic_Verb: result.printf(CONIC_DEBUG_STR " id=%d", CONIC_DEBUG_DATA(fCurvePart, fCurvePart.fConic.fWeight), this->segment()->debugID()); break; case SkPath::kCubic_Verb: result.printf(CUBIC_DEBUG_STR " id=%d", CUBIC_DEBUG_DATA(fCurvePart), this->segment()->debugID()); break; default: SkASSERT(0); } return result; } #endif #if DEBUG_SORT void SkOpAngle::debugLoop() const { const SkOpAngle* first = this; const SkOpAngle* next = this; do { next->dumpOne(true); SkDebugf("\n"); next = next->fNext; } while (next && next != first); next = first; do { next->debugValidate(); next = next->fNext; } while (next && next != first); } #endif void SkOpAngle::debugValidate() const { #if DEBUG_VALIDATE const SkOpAngle* first = this; const SkOpAngle* next = this; int wind = 0; int opp = 0; int lastXor = -1; int lastOppXor = -1; do { if (next->unorderable()) { return; } const SkOpSpan* minSpan = next->start()->starter(next->end()); if (minSpan->windValue() == SK_MinS32) { return; } bool op = next->segment()->operand(); bool isXor = next->segment()->isXor(); bool oppXor = next->segment()->oppXor(); SkASSERT(!DEBUG_LIMIT_WIND_SUM || between(0, minSpan->windValue(), DEBUG_LIMIT_WIND_SUM)); SkASSERT(!DEBUG_LIMIT_WIND_SUM || between(-DEBUG_LIMIT_WIND_SUM, minSpan->oppValue(), DEBUG_LIMIT_WIND_SUM)); bool useXor = op ? oppXor : isXor; SkASSERT(lastXor == -1 || lastXor == (int) useXor); lastXor = (int) useXor; wind += next->debugSign() * (op ? minSpan->oppValue() : minSpan->windValue()); if (useXor) { wind &= 1; } useXor = op ? isXor : oppXor; SkASSERT(lastOppXor == -1 || lastOppXor == (int) useXor); lastOppXor = (int) useXor; opp += next->debugSign() * (op ? minSpan->windValue() : minSpan->oppValue()); if (useXor) { opp &= 1; } next = next->fNext; } while (next && next != first); SkASSERT(wind == 0 || !FLAGS_runFail); SkASSERT(opp == 0 || !FLAGS_runFail); #endif } void SkOpAngle::debugValidateNext() const { #if !FORCE_RELEASE const SkOpAngle* first = this; const SkOpAngle* next = first; SkTDArray<const SkOpAngle*>(angles); do { // SK_ALWAYSBREAK(next->fSegment->debugContains(next)); angles.push(next); next = next->next(); if (next == first) { break; } SK_ALWAYSBREAK(!angles.contains(next)); if (!next) { return; } } while (true); #endif } void SkOpCoincidence::debugShowCoincidence() const { SkCoincidentSpans* span = fHead; while (span) { SkDebugf("%s - id=%d t=%1.9g tEnd=%1.9g\n", __FUNCTION__, span->fCoinPtTStart->segment()->debugID(), span->fCoinPtTStart->fT, span->fCoinPtTEnd->fT); SkDebugf("%s + id=%d t=%1.9g tEnd=%1.9g\n", __FUNCTION__, span->fOppPtTStart->segment()->debugID(), span->fOppPtTStart->fT, span->fOppPtTEnd->fT); span = span->fNext; } } void SkOpSegment::debugValidate() const { #if DEBUG_VALIDATE const SkOpSpanBase* span = &fHead; double lastT = -1; const SkOpSpanBase* prev = NULL; int count = 0; int done = 0; do { if (!span->final()) { ++count; done += span->upCast()->done() ? 1 : 0; } SkASSERT(span->segment() == this); SkASSERT(!prev || prev->upCast()->next() == span); SkASSERT(!prev || prev == span->prev()); prev = span; double t = span->ptT()->fT; SkASSERT(lastT < t); lastT = t; span->debugValidate(); } while (!span->final() && (span = span->upCast()->next())); SkASSERT(count == fCount); SkASSERT(done == fDoneCount); SkASSERT(count >= fDoneCount); SkASSERT(span->final()); span->debugValidate(); #endif } bool SkOpSpanBase::debugCoinEndLoopCheck() const { int loop = 0; const SkOpSpanBase* next = this; SkOpSpanBase* nextCoin; do { nextCoin = next->fCoinEnd; SkASSERT(nextCoin == this || nextCoin->fCoinEnd != nextCoin); for (int check = 1; check < loop - 1; ++check) { const SkOpSpanBase* checkCoin = this->fCoinEnd; const SkOpSpanBase* innerCoin = checkCoin; for (int inner = check + 1; inner < loop; ++inner) { innerCoin = innerCoin->fCoinEnd; if (checkCoin == innerCoin) { SkDebugf("*** bad coincident end loop ***\n"); return false; } } } ++loop; } while ((next = nextCoin) && next != this); return true; } void SkOpSpanBase::debugValidate() const { #if DEBUG_VALIDATE const SkOpPtT* ptT = &fPtT; SkASSERT(ptT->span() == this); do { // SkASSERT(SkDPoint::RoughlyEqual(fPtT.fPt, ptT->fPt)); ptT->debugValidate(); ptT = ptT->next(); } while (ptT != &fPtT); SkASSERT(this->debugCoinEndLoopCheck()); if (!this->final()) { SkASSERT(this->upCast()->debugCoinLoopCheck()); } if (fFromAngle) { fFromAngle->debugValidate(); } if (!this->final() && this->upCast()->toAngle()) { this->upCast()->toAngle()->debugValidate(); } #endif } bool SkOpSpan::debugCoinLoopCheck() const { int loop = 0; const SkOpSpan* next = this; SkOpSpan* nextCoin; do { nextCoin = next->fCoincident; SkASSERT(nextCoin == this || nextCoin->fCoincident != nextCoin); for (int check = 1; check < loop - 1; ++check) { const SkOpSpan* checkCoin = this->fCoincident; const SkOpSpan* innerCoin = checkCoin; for (int inner = check + 1; inner < loop; ++inner) { innerCoin = innerCoin->fCoincident; if (checkCoin == innerCoin) { SkDebugf("*** bad coincident loop ***\n"); return false; } } } ++loop; } while ((next = nextCoin) && next != this); return true; } // called only by test code int SkIntersections::debugCoincidentUsed() const { if (!fIsCoincident[0]) { SkASSERT(!fIsCoincident[1]); return 0; } int count = 0; SkDEBUGCODE(int count2 = 0;) for (int index = 0; index < fUsed; ++index) { if (fIsCoincident[0] & (1 << index)) { ++count; } #ifdef SK_DEBUG if (fIsCoincident[1] & (1 << index)) { ++count2; } #endif } SkASSERT(count == count2); return count; } #include "SkOpContour.h" int SkOpPtT::debugLoopLimit(bool report) const { int loop = 0; const SkOpPtT* next = this; do { for (int check = 1; check < loop - 1; ++check) { const SkOpPtT* checkPtT = this->fNext; const SkOpPtT* innerPtT = checkPtT; for (int inner = check + 1; inner < loop; ++inner) { innerPtT = innerPtT->fNext; if (checkPtT == innerPtT) { if (report) { SkDebugf("*** bad ptT loop ***\n"); } return loop; } } } ++loop; } while ((next = next->fNext) && next != this); return 0; } void SkOpPtT::debugValidate() const { #if DEBUG_VALIDATE if (contour()->globalState()->phase() == SkOpGlobalState::kIntersecting) { return; } SkASSERT(fNext); SkASSERT(fNext != this); SkASSERT(fNext->fNext); SkASSERT(debugLoopLimit(false) == 0); #endif } static void output_scalar(SkScalar num) { if (num == (int) num) { SkDebugf("%d", (int) num); } else { SkString str; str.printf("%1.9g", num); int width = (int) str.size(); const char* cStr = str.c_str(); while (cStr[width - 1] == '0') { --width; } str.resize(width); SkDebugf("%sf", str.c_str()); } } static void output_points(const SkPoint* pts, int count) { for (int index = 0; index < count; ++index) { output_scalar(pts[index].fX); SkDebugf(", "); output_scalar(pts[index].fY); if (index + 1 < count) { SkDebugf(", "); } } } static void showPathContours(SkPath::RawIter& iter, const char* pathName) { uint8_t verb; SkPoint pts[4]; while ((verb = iter.next(pts)) != SkPath::kDone_Verb) { switch (verb) { case SkPath::kMove_Verb: SkDebugf(" %s.moveTo(", pathName); output_points(&pts[0], 1); SkDebugf(");\n"); continue; case SkPath::kLine_Verb: SkDebugf(" %s.lineTo(", pathName); output_points(&pts[1], 1); SkDebugf(");\n"); break; case SkPath::kQuad_Verb: SkDebugf(" %s.quadTo(", pathName); output_points(&pts[1], 2); SkDebugf(");\n"); break; case SkPath::kConic_Verb: SkDebugf(" %s.conicTo(", pathName); output_points(&pts[1], 2); SkDebugf(", %1.9gf);\n", iter.conicWeight()); break; case SkPath::kCubic_Verb: SkDebugf(" %s.cubicTo(", pathName); output_points(&pts[1], 3); SkDebugf(");\n"); break; case SkPath::kClose_Verb: SkDebugf(" %s.close();\n", pathName); break; default: SkDEBUGFAIL("bad verb"); return; } } } static const char* gFillTypeStr[] = { "kWinding_FillType", "kEvenOdd_FillType", "kInverseWinding_FillType", "kInverseEvenOdd_FillType" }; void SkPathOpsDebug::ShowOnePath(const SkPath& path, const char* name, bool includeDeclaration) { SkPath::RawIter iter(path); #define SUPPORT_RECT_CONTOUR_DETECTION 0 #if SUPPORT_RECT_CONTOUR_DETECTION int rectCount = path.isRectContours() ? path.rectContours(NULL, NULL) : 0; if (rectCount > 0) { SkTDArray<SkRect> rects; SkTDArray<SkPath::Direction> directions; rects.setCount(rectCount); directions.setCount(rectCount); path.rectContours(rects.begin(), directions.begin()); for (int contour = 0; contour < rectCount; ++contour) { const SkRect& rect = rects[contour]; SkDebugf("path.addRect(%1.9g, %1.9g, %1.9g, %1.9g, %s);\n", rect.fLeft, rect.fTop, rect.fRight, rect.fBottom, directions[contour] == SkPath::kCCW_Direction ? "SkPath::kCCW_Direction" : "SkPath::kCW_Direction"); } return; } #endif SkPath::FillType fillType = path.getFillType(); SkASSERT(fillType >= SkPath::kWinding_FillType && fillType <= SkPath::kInverseEvenOdd_FillType); if (includeDeclaration) { SkDebugf(" SkPath %s;\n", name); } SkDebugf(" %s.setFillType(SkPath::%s);\n", name, gFillTypeStr[fillType]); iter.setPath(path); showPathContours(iter, name); }