/* * Copyright 2018 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "fuzz/Fuzz.h" #include "fuzz/FuzzCommon.h" // We don't always want to test NaNs and infinities. static void fuzz_nice_float(Fuzz* fuzz, float* f) { float v; fuzz->next(&v); constexpr float kLimit = 1.0e35f; // FLT_MAX? *f = (v == v && v <= kLimit && v >= -kLimit) ? v : 0.0f; } template static void fuzz_nice_float(Fuzz* fuzz, float* f, Args... rest) { fuzz_nice_float(fuzz, f); fuzz_nice_float(fuzz, rest...); } static void fuzz_nice_rect(Fuzz* fuzz, SkRect* r) { fuzz_nice_float(fuzz, &r->fLeft, &r->fTop, &r->fRight, &r->fBottom); r->sort(); } // allows some float values for path points void FuzzNicePath(Fuzz* fuzz, SkPath* path, int maxOps) { if (maxOps <= 0 || fuzz->exhausted() || path->countPoints() > 100000) { return; } uint8_t fillType; fuzz->nextRange(&fillType, 0, (uint8_t)SkPathFillType::kInverseEvenOdd); path->setFillType((SkPathFillType)fillType); uint8_t numOps; fuzz->nextRange(&numOps, 0, maxOps); for (uint8_t i = 0; i < numOps; ++i) { // When we start adding the path to itself, the fuzzer can make an // exponentially long path, which causes timeouts. if (path->countPoints() > 100000) { return; } // How many items in the switch statement below. constexpr uint8_t PATH_OPERATIONS = 32; uint8_t op; fuzz->nextRange(&op, 0, PATH_OPERATIONS); bool test; SkPath p; SkMatrix m; SkRRect rr; SkRect r; SkPathDirection dir; unsigned int ui; SkScalar a, b, c, d, e, f; switch (op) { case 0: fuzz_nice_float(fuzz, &a, &b); path->moveTo(a, b); break; case 1: fuzz_nice_float(fuzz, &a, &b); path->rMoveTo(a, b); break; case 2: fuzz_nice_float(fuzz, &a, &b); path->lineTo(a, b); break; case 3: fuzz_nice_float(fuzz, &a, &b); path->rLineTo(a, b); break; case 4: fuzz_nice_float(fuzz, &a, &b, &c, &d); path->quadTo(a, b, c, d); break; case 5: fuzz_nice_float(fuzz, &a, &b, &c, &d); path->rQuadTo(a, b, c, d); break; case 6: fuzz_nice_float(fuzz, &a, &b, &c, &d, &e); path->conicTo(a, b, c, d, e); break; case 7: fuzz_nice_float(fuzz, &a, &b, &c, &d, &e); path->rConicTo(a, b, c, d, e); break; case 8: fuzz_nice_float(fuzz, &a, &b, &c, &d, &e, &f); path->cubicTo(a, b, c, d, e, f); break; case 9: fuzz_nice_float(fuzz, &a, &b, &c, &d, &e, &f); path->rCubicTo(a, b, c, d, e, f); break; case 10: fuzz_nice_float(fuzz, &a, &b, &c, &d, &e); path->arcTo(a, b, c, d, e); break; case 11: fuzz_nice_float(fuzz, &a, &b); fuzz_nice_rect(fuzz, &r); fuzz->next(&test); path->arcTo(r, a, b, test); break; case 12: path->close(); break; case 13: fuzz_nice_rect(fuzz, &r); fuzz->nextRange(&ui, 0, 1); dir = static_cast(ui); path->addRect(r, dir); break; case 14: fuzz->nextRange(&ui, 0, 1); dir = static_cast(ui); fuzz_nice_rect(fuzz, &r); fuzz->next(&ui); path->addRect(r, dir, ui); break; case 15: fuzz->nextRange(&ui, 0, 1); dir = static_cast(ui); fuzz_nice_rect(fuzz, &r); path->addOval(r, dir); break; case 16: fuzz->nextRange(&ui, 0, 1); dir = static_cast(ui); fuzz_nice_rect(fuzz, &r); fuzz->next(&ui); path->addOval(r, dir, ui); break; case 17: fuzz->nextRange(&ui, 0, 1); dir = static_cast(ui); fuzz_nice_float(fuzz, &a, &b, &c); path->addCircle(a, b, c, dir); break; case 18: fuzz_nice_rect(fuzz, &r); fuzz_nice_float(fuzz, &a, &b); path->addArc(r, a, b); break; case 19: fuzz_nice_float(fuzz, &a, &b); fuzz_nice_rect(fuzz, &r); fuzz->nextRange(&ui, 0, 1); dir = static_cast(ui); path->addRoundRect(r, a, b, dir); break; case 20: FuzzNiceRRect(fuzz, &rr); fuzz->nextRange(&ui, 0, 1); dir = static_cast(ui); path->addRRect(rr, dir); break; case 21: fuzz->nextRange(&ui, 0, 1); dir = static_cast(ui); FuzzNiceRRect(fuzz, &rr); path->addRRect(rr, dir, ui); break; case 22: { fuzz->nextRange(&ui, 0, 1); SkPath::AddPathMode mode = static_cast(ui); FuzzNiceMatrix(fuzz, &m); FuzzNicePath(fuzz, &p, maxOps-1); path->addPath(p, m, mode); break; } case 23: { fuzz->nextRange(&ui, 0, 1); SkPath::AddPathMode mode = static_cast(ui); FuzzNiceMatrix(fuzz, &m); path->addPath(*path, m, mode); break; } case 24: FuzzNicePath(fuzz, &p, maxOps-1); path->reverseAddPath(p); break; case 25: path->addPath(*path); break; case 26: path->reverseAddPath(*path); break; case 27: fuzz_nice_float(fuzz, &a, &b); path->offset(a, b, path); break; case 28: FuzzNicePath(fuzz, &p, maxOps-1); fuzz_nice_float(fuzz, &a, &b); p.offset(a, b, path); break; case 29: FuzzNiceMatrix(fuzz, &m); path->transform(m, path); break; case 30: FuzzNicePath(fuzz, &p, maxOps-1); FuzzNiceMatrix(fuzz, &m); p.transform(m, path); break; case 31: fuzz_nice_float(fuzz, &a, &b); path->setLastPt(a, b); break; default: SkASSERT(false); break; } SkASSERTF( path->isValid(), "path->isValid() failed at op %d, case %d", i, op); } } // allows all float values for path points void FuzzEvilPath(Fuzz* fuzz, SkPath* path, int last_verb) { while (!fuzz->exhausted()) { // Use a uint8_t to conserve bytes. This makes our "fuzzed bytes footprint" // smaller, which leads to more efficient fuzzing. uint8_t operation; fuzz->next(&operation); SkScalar a,b,c,d,e,f; switch (operation % (last_verb + 1)) { case SkPath::Verb::kMove_Verb: fuzz->next(&a, &b); path->moveTo(a, b); break; case SkPath::Verb::kLine_Verb: fuzz->next(&a, &b); path->lineTo(a, b); break; case SkPath::Verb::kQuad_Verb: fuzz->next(&a, &b, &c, &d); path->quadTo(a, b, c, d); break; case SkPath::Verb::kConic_Verb: fuzz->next(&a, &b, &c, &d, &e); path->conicTo(a, b, c, d, e); break; case SkPath::Verb::kCubic_Verb: fuzz->next(&a, &b, &c, &d, &e, &f); path->cubicTo(a, b, c, d, e, f); break; case SkPath::Verb::kClose_Verb: path->close(); break; case SkPath::Verb::kDone_Verb: // In this case, simply exit. return; } } } void FuzzNiceRRect(Fuzz* fuzz, SkRRect* rr) { SkRect r; fuzz_nice_rect(fuzz, &r); SkVector radii[4]; for (SkVector& vec : radii) { fuzz->nextRange(&vec.fX, 0.0f, 1.0f); vec.fX *= 0.5f * r.width(); fuzz->nextRange(&vec.fY, 0.0f, 1.0f); vec.fY *= 0.5f * r.height(); } rr->setRectRadii(r, radii); SkASSERT(rr->isValid()); } void FuzzNiceMatrix(Fuzz* fuzz, SkMatrix* m) { constexpr int kArrayLength = 9; SkScalar buffer[kArrayLength]; int matrixType; fuzz->nextRange(&matrixType, 0, 4); switch (matrixType) { case 0: // identity *m = SkMatrix::I(); return; case 1: // translate fuzz->nextRange(&buffer[0], -4000.0f, 4000.0f); fuzz->nextRange(&buffer[1], -4000.0f, 4000.0f); *m = SkMatrix::Translate(buffer[0], buffer[1]); return; case 2: // translate + scale fuzz->nextRange(&buffer[0], -400.0f, 400.0f); fuzz->nextRange(&buffer[1], -400.0f, 400.0f); fuzz->nextRange(&buffer[2], -4000.0f, 4000.0f); fuzz->nextRange(&buffer[3], -4000.0f, 4000.0f); *m = SkMatrix::Scale(buffer[0], buffer[1]); m->postTranslate(buffer[2], buffer[3]); return; case 3: // affine fuzz->nextN(buffer, 6); m->setAffine(buffer); return; case 4: // perspective fuzz->nextN(buffer, kArrayLength); m->set9(buffer); return; default: SkASSERT(false); return; } } void FuzzNiceRegion(Fuzz* fuzz, SkRegion* region, int maxN) { uint8_t N; fuzz->nextRange(&N, 0, maxN); for (uint8_t i = 0; i < N; ++i) { SkIRect r; SkRegion::Op op; // Avoid the sentinal value used by Region. fuzz->nextRange(&r.fLeft, -2147483646, 2147483646); fuzz->nextRange(&r.fTop, -2147483646, 2147483646); fuzz->nextRange(&r.fRight, -2147483646, 2147483646); fuzz->nextRange(&r.fBottom, -2147483646, 2147483646); r.sort(); fuzz->nextRange(&op, 0, SkRegion::kLastOp); if (!region->op(r, op)) { return; } } }