/* * Copyright 2016, 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 #include #include #include #include #include #include #include namespace { /* * Operators. */ static constexpr const char* kIncDecOps[] = { "++", "--" }; static constexpr const char* kIntUnaryOps[] = { "+", "-", "~" }; static constexpr const char* kFpUnaryOps[] = { "+", "-" }; static constexpr const char* kBoolBinOps[] = { "&&", "||", "&", "|", "^" }; // few less common static constexpr const char* kIntBinOps[] = { "+", "-", "*", "/", "%", ">>", ">>>", "<<", "&", "|", "^" }; static constexpr const char* kFpBinOps[] = { "+", "-", "*", "/" }; static constexpr const char* kBoolAssignOps[] = { "=", "&=" , "|=", "^=" }; // few less common static constexpr const char* kIntAssignOps[] = { "=", "+=", "-=", "*=", "/=", "%=", ">>=", ">>>=", "<<=", "&=", "|=", "^=" }; static constexpr const char* kFpAssignOps[] = { "=", "+=", "-=", "*=", "/=" }; static constexpr const char* kBoolRelOps[] = { "==", "!=" }; static constexpr const char* kRelOps[] = { "==", "!=", ">", ">=", "<", "<=" }; /* * Exceptions. */ static const char* kExceptionTypes[] = { "IllegalStateException", "NullPointerException", "IllegalArgumentException", "ArrayIndexOutOfBoundsException" }; /* * Version of JFuzz. Increase this each time changes are made to the program * to preserve the property that a given version of JFuzz yields the same * fuzzed program for a deterministic random seed. */ const char* VERSION = "1.5"; /* * Maximum number of array dimensions, together with corresponding maximum size * within each dimension (to keep memory/runtime requirements roughly the same). */ static const uint32_t kMaxDim = 10; static const uint32_t kMaxDimSize[kMaxDim + 1] = { 0, 1000, 32, 10, 6, 4, 3, 3, 2, 2, 2 }; /* * Utility function to return the number of elements in an array. */ template constexpr uint32_t countof(T const (&)[N]) { return N; } /** * A class that generates a random program that compiles correctly. The program * is generated using rules that generate various programming constructs. Each rule * has a fixed probability to "fire". Running a generated program yields deterministic * output, making it suited to test various modes of execution (e.g an interpreter vs. * an compiler or two different run times) for divergences. */ class JFuzz { public: JFuzz(FILE* out, uint32_t seed, uint32_t expr_depth, uint32_t stmt_length, uint32_t if_nest, uint32_t loop_nest, uint32_t try_nest) : out_(out), fuzz_random_engine_(seed), fuzz_seed_(seed), fuzz_expr_depth_(expr_depth), fuzz_stmt_length_(stmt_length), fuzz_if_nest_(if_nest), fuzz_loop_nest_(loop_nest), fuzz_try_nest_(try_nest), return_type_(randomType()), array_type_(randomType()), array_dim_(random1(kMaxDim)), array_size_(random1(kMaxDimSize[array_dim_])), indentation_(0), expr_depth_(0), stmt_length_(0), if_nest_(0), loop_nest_(0), switch_nest_(0), do_nest_(0), try_nest_(0), boolean_local_(0), int_local_(0), long_local_(0), float_local_(0), double_local_(0), in_inner_(false) { } ~JFuzz() { } void emitProgram() { emitHeader(); emitTestClassWithMain(); } private: // // Types. // // Current type of each expression during generation. enum Type { kBoolean, kInt, kLong, kFloat, kDouble }; // Test for an integral type. static bool isInteger(Type tp) { return tp == kInt || tp == kLong; } // Test for a floating-point type. static bool isFP(Type tp) { return tp == kFloat || tp == kDouble; } // Emit type. void emitType(Type tp) const { switch (tp) { case kBoolean: fputs("boolean", out_); break; case kInt: fputs("int", out_); break; case kLong: fputs("long", out_); break; case kFloat: fputs("float", out_); break; case kDouble: fputs("double", out_); break; } } // Emit type class. void emitTypeClass(Type tp) const { switch (tp) { case kBoolean: fputs("Boolean", out_); break; case kInt: fputs("Integer", out_); break; case kLong: fputs("Long", out_); break; case kFloat: fputs("Float", out_); break; case kDouble: fputs("Double", out_); break; } } // Return a random type. Type randomType() { switch (random1(5)) { case 1: return kBoolean; case 2: return kInt; case 3: return kLong; case 4: return kFloat; default: return kDouble; } } // Emits a random strong selected from an array of operator strings. template inline void emitOneOf(const char* const (&ops)[N]) { fputs(ops[random0(N)], out_); } // // Expressions. // // Emit an unary operator (same type in-out). void emitUnaryOp(Type tp) { if (tp == kBoolean) { fputc('!', out_); } else if (isInteger(tp)) { emitOneOf(kIntUnaryOps); } else { // isFP(tp) emitOneOf(kFpUnaryOps); } } // Emit a pre/post-increment/decrement operator (same type in-out). void emitIncDecOp(Type tp) { if (tp == kBoolean) { // Not applicable, just leave "as is". } else { // isInteger(tp) || isFP(tp) emitOneOf(kIncDecOps); } } // Emit a binary operator (same type in-out). void emitBinaryOp(Type tp) { if (tp == kBoolean) { emitOneOf(kBoolBinOps); } else if (isInteger(tp)) { emitOneOf(kIntBinOps); } else { // isFP(tp) emitOneOf(kFpBinOps); } } // Emit an assignment operator (same type in-out). void emitAssignmentOp(Type tp) { if (tp == kBoolean) { emitOneOf(kBoolAssignOps); } else if (isInteger(tp)) { emitOneOf(kIntAssignOps); } else { // isFP(tp) emitOneOf(kFpAssignOps); } } // Emit a relational operator (one type in, boolean out). void emitRelationalOp(Type tp) { if (tp == kBoolean) { emitOneOf(kBoolRelOps); } else { // isInteger(tp) || isFP(tp) emitOneOf(kRelOps); } } // Emit a type conversion operator sequence (out type given, new suitable in type picked). Type emitTypeConversionOp(Type tp) { if (tp == kInt) { switch (random1(5)) { case 1: fputs("(int)", out_); return kLong; case 2: fputs("(int)", out_); return kFloat; case 3: fputs("(int)", out_); return kDouble; // Narrowing-widening. case 4: fputs("(int)(byte)(int)", out_); return kInt; case 5: fputs("(int)(short)(int)", out_); return kInt; } } else if (tp == kLong) { switch (random1(6)) { case 1: /* implicit */ return kInt; case 2: fputs("(long)", out_); return kFloat; case 3: fputs("(long)", out_); return kDouble; // Narrowing-widening. case 4: fputs("(long)(byte)(long)", out_); return kLong; case 5: fputs("(long)(short)(long)", out_); return kLong; case 6: fputs("(long)(int)(long)", out_); return kLong; } } else if (tp == kFloat) { switch (random1(4)) { case 1: fputs("(float)", out_); return kInt; case 2: fputs("(float)", out_); return kLong; case 3: fputs("(float)", out_); return kDouble; // Narrowing-widening. case 4: fputs("(float)(int)(float)", out_); return kFloat; } } else if (tp == kDouble) { switch (random1(5)) { case 1: fputs("(double)", out_); return kInt; case 2: fputs("(double)", out_); return kLong; case 3: fputs("(double)", out_); return kFloat; // Narrowing-widening. case 4: fputs("(double)(int)(double)", out_); return kDouble; case 5: fputs("(double)(float)(double)", out_); return kDouble; } } return tp; // nothing suitable, just keep type } // Emit a type conversion (out type given, new suitable in type picked). void emitTypeConversion(Type tp) { if (tp == kBoolean) { Type tp = randomType(); emitExpression(tp); fputc(' ', out_); emitRelationalOp(tp); fputc(' ', out_); emitExpression(tp); } else { tp = emitTypeConversionOp(tp); fputc(' ', out_); emitExpression(tp); } } // Emit an unary intrinsic (out type given, new suitable in type picked). Type emitIntrinsic1(Type tp) { if (tp == kBoolean) { switch (random1(6)) { case 1: fputs("Float.isNaN", out_); return kFloat; case 2: fputs("Float.isFinite", out_); return kFloat; case 3: fputs("Float.isInfinite", out_); return kFloat; case 4: fputs("Double.isNaN", out_); return kDouble; case 5: fputs("Double.isFinite", out_); return kDouble; case 6: fputs("Double.isInfinite", out_); return kDouble; } } else if (isInteger(tp)) { const char* prefix = tp == kLong ? "Long" : "Integer"; switch (random1(13)) { case 1: fprintf(out_, "%s.highestOneBit", prefix); break; case 2: fprintf(out_, "%s.lowestOneBit", prefix); break; case 3: fprintf(out_, "%s.numberOfLeadingZeros", prefix); break; case 4: fprintf(out_, "%s.numberOfTrailingZeros", prefix); break; case 5: fprintf(out_, "%s.bitCount", prefix); break; case 6: fprintf(out_, "%s.signum", prefix); break; case 7: fprintf(out_, "%s.reverse", prefix); break; case 8: fprintf(out_, "%s.reverseBytes", prefix); break; case 9: fputs("Math.incrementExact", out_); break; case 10: fputs("Math.decrementExact", out_); break; case 11: fputs("Math.negateExact", out_); break; case 12: fputs("Math.abs", out_); break; case 13: fputs("Math.round", out_); return tp == kLong ? kDouble : kFloat; } } else { // isFP(tp) switch (random1(6)) { case 1: fputs("Math.abs", out_); break; case 2: fputs("Math.ulp", out_); break; case 3: fputs("Math.signum", out_); break; case 4: fputs("Math.nextUp", out_); break; case 5: fputs("Math.nextDown", out_); break; case 6: if (tp == kDouble) { fputs("Double.longBitsToDouble", out_); return kLong; } else { fputs("Float.intBitsToFloat", out_); return kInt; } } } return tp; // same type in-out } // Emit a binary intrinsic (out type given, new suitable in type picked). Type emitIntrinsic2(Type tp) { if (tp == kBoolean) { switch (random1(3)) { case 1: fputs("Boolean.logicalAnd", out_); break; case 2: fputs("Boolean.logicalOr", out_); break; case 3: fputs("Boolean.logicalXor", out_); break; } } else if (isInteger(tp)) { const char* prefix = tp == kLong ? "Long" : "Integer"; switch (random1(11)) { case 1: fprintf(out_, "%s.compare", prefix); break; case 2: fprintf(out_, "%s.sum", prefix); break; case 3: fprintf(out_, "%s.min", prefix); break; case 4: fprintf(out_, "%s.max", prefix); break; case 5: fputs("Math.min", out_); break; case 6: fputs("Math.max", out_); break; case 7: fputs("Math.floorDiv", out_); break; case 8: fputs("Math.floorMod", out_); break; case 9: fputs("Math.addExact", out_); break; case 10: fputs("Math.subtractExact", out_); break; case 11: fputs("Math.multiplyExact", out_); break; } } else { // isFP(tp) const char* prefix = tp == kDouble ? "Double" : "Float"; switch (random1(5)) { case 1: fprintf(out_, "%s.sum", prefix); break; case 2: fprintf(out_, "%s.min", prefix); break; case 3: fprintf(out_, "%s.max", prefix); break; case 4: fputs("Math.min", out_); break; case 5: fputs("Math.max", out_); break; } } return tp; // same type in-out } // Emit an intrinsic (out type given, new suitable in type picked). void emitIntrinsic(Type tp) { if (random1(2) == 1) { tp = emitIntrinsic1(tp); fputc('(', out_); emitExpression(tp); fputc(')', out_); } else { tp = emitIntrinsic2(tp); fputc('(', out_); emitExpression(tp); fputs(", ", out_); emitExpression(tp); fputc(')', out_); } } // Emit a method call (out type given). void emitMethodCall(Type tp) { if (tp != kBoolean && !in_inner_) { // Accept all numerical types (implicit conversion) and when not // declaring inner classes (to avoid infinite recursion). switch (random1(8)) { case 1: fputs("mA.a()", out_); break; case 2: fputs("mB.a()", out_); break; case 3: fputs("mB.x()", out_); break; case 4: fputs("mBX.x()", out_); break; case 5: fputs("mC.s()", out_); break; case 6: fputs("mC.c()", out_); break; case 7: fputs("mC.x()", out_); break; case 8: fputs("mCX.x()", out_); break; } } else { // Fall back to intrinsic. emitIntrinsic(tp); } } // Emit unboxing boxed object. void emitUnbox(Type tp) { fputc('(', out_); emitType(tp); fputs(") new ", out_); emitTypeClass(tp); fputc('(', out_); emitExpression(tp); fputc(')', out_); } // Emit miscellaneous constructs. void emitMisc(Type tp) { if (tp == kBoolean) { fprintf(out_, "this instanceof %s", in_inner_ ? "X" : "Test"); } else if (isInteger(tp)) { const char* prefix = tp == kLong ? "Long" : "Integer"; switch (random1(2)) { case 1: fprintf(out_, "%s.MIN_VALUE", prefix); break; case 2: fprintf(out_, "%s.MAX_VALUE", prefix); break; } } else { // isFP(tp) const char* prefix = tp == kDouble ? "Double" : "Float"; switch (random1(6)) { case 1: fprintf(out_, "%s.MIN_NORMAL", prefix); break; case 2: fprintf(out_, "%s.MIN_VALUE", prefix); break; case 3: fprintf(out_, "%s.MAX_VALUE", prefix); break; case 4: fprintf(out_, "%s.POSITIVE_INFINITY", prefix); break; case 5: fprintf(out_, "%s.NEGATIVE_INFINITY", prefix); break; case 6: fprintf(out_, "%s.NaN", prefix); break; } } } // Adjust local of given type and return adjusted value. uint32_t adjustLocal(Type tp, int32_t a) { switch (tp) { case kBoolean: boolean_local_ += a; return boolean_local_; case kInt: int_local_ += a; return int_local_; case kLong: long_local_ += a; return long_local_; case kFloat: float_local_ += a; return float_local_; default: double_local_ += a; return double_local_; } } // Emit an expression that is a strict upper bound for an array index. void emitUpperBound() { if (random1(8) == 1) { fputs("mArray.length", out_); } else if (random1(8) == 1) { fprintf(out_, "%u", random1(array_size_)); // random in range } else { fprintf(out_, "%u", array_size_); } } // Emit an array index, usually within proper range. void emitArrayIndex() { if (loop_nest_ > 0 && random1(2) == 1) { fprintf(out_, "i%u", random0(loop_nest_)); } else if (random1(8) == 1) { fputs("mArray.length - 1", out_); } else { fprintf(out_, "%u", random0(array_size_)); // random in range } // Introduce potential off by one errors with low probability. if (random1(100) == 1) { if (random1(2) == 1) { fputs(" - 1", out_); } else { fputs(" + 1", out_); } } } // Emit a literal. void emitLiteral(Type tp) { switch (tp) { case kBoolean: fputs(random1(2) == 1 ? "true" : "false", out_); break; case kInt: fprintf(out_, "%d", random()); break; case kLong: fprintf(out_, "%dL", random()); break; case kFloat: fprintf(out_, "%d.0f", random()); break; case kDouble: fprintf(out_, "%d.0", random()); break; } } // Emit array variable, if available. bool emitArrayVariable(Type tp) { if (tp == array_type_) { fputs("mArray", out_); for (uint32_t i = 0; i < array_dim_; i++) { fputc('[', out_); emitArrayIndex(); fputc(']', out_); } return true; } return false; } // Emit a local variable, if available. bool emitLocalVariable(Type tp) { uint32_t locals = adjustLocal(tp, 0); if (locals > 0) { uint32_t local = random0(locals); switch (tp) { case kBoolean: fprintf(out_, "lZ%u", local); break; case kInt: fprintf(out_, "lI%u", local); break; case kLong: fprintf(out_, "lJ%u", local); break; case kFloat: fprintf(out_, "lF%u", local); break; case kDouble: fprintf(out_, "lD%u", local); break; } return true; } return false; } // Emit a field variable. void emitFieldVariable(Type tp) { switch (tp) { case kBoolean:fputs("mZ", out_); break; case kInt: fputs("mI", out_); break; case kLong: fputs("mJ", out_); break; case kFloat: fputs("mF", out_); break; case kDouble: fputs("mD", out_); break; } } // Emit a variable. void emitVariable(Type tp) { switch (random1(4)) { case 1: if (emitArrayVariable(tp)) return; [[fallthrough]]; case 2: if (emitLocalVariable(tp)) return; [[fallthrough]]; default: emitFieldVariable(tp); break; } } // Emit an expression. void emitExpression(Type tp) { // Continuing expression becomes less likely as the depth grows. if (random1(expr_depth_ + 1) > fuzz_expr_depth_) { if (random1(2) == 1) { emitLiteral(tp); } else { emitVariable(tp); } return; } expr_depth_++; fputc('(', out_); switch (random1(12)) { // favor binary operations case 1: // Unary operator: ~ x emitUnaryOp(tp); fputc(' ', out_); emitExpression(tp); break; case 2: // Pre-increment: ++x emitIncDecOp(tp); emitVariable(tp); break; case 3: // Post-increment: x++ emitVariable(tp); emitIncDecOp(tp); break; case 4: // Ternary operator: b ? x : y emitExpression(kBoolean); fputs(" ? ", out_); emitExpression(tp); fputs(" : ", out_); emitExpression(tp); break; case 5: // Type conversion: (float) x emitTypeConversion(tp); break; case 6: // Intrinsic: foo(x) emitIntrinsic(tp); break; case 7: // Method call: mA.a() emitMethodCall(tp); break; case 8: // Emit unboxing boxed value: (int) Integer(x) emitUnbox(tp); break; case 9: // Miscellaneous constructs: a.length emitMisc(tp); break; default: // Binary operator: x + y emitExpression(tp); fputc(' ', out_); emitBinaryOp(tp); fputc(' ', out_); emitExpression(tp); break; } fputc(')', out_); --expr_depth_; } // // Statements. // // Emit current indentation. void emitIndentation() const { for (uint32_t i = 0; i < indentation_; i++) { fputc(' ', out_); } } // Emit a return statement. bool emitReturn(bool mustEmit) { // Only emit when we must, or with low probability inside ifs/loops, // but outside do-while to avoid confusing the may follow status. if (mustEmit || ((if_nest_ + loop_nest_) > 0 && do_nest_ == 0 && random1(10) == 1)) { fputs("return ", out_); emitExpression(return_type_); fputs(";\n", out_); return false; } // Fall back to assignment. return emitAssignment(); } // Emit a continue statement. bool emitContinue() { // Only emit with low probability inside loops. if (loop_nest_ > 0 && random1(10) == 1) { fputs("continue;\n", out_); return false; } // Fall back to assignment. return emitAssignment(); } // Emit a break statement. bool emitBreak() { // Only emit with low probability inside loops, but outside switches // to avoid confusing the may follow status. if (loop_nest_ > 0 && switch_nest_ == 0 && random1(10) == 1) { fputs("break;\n", out_); return false; } // Fall back to assignment. return emitAssignment(); } // Emit a new scope with a local variable declaration statement. bool emitScope() { Type tp = randomType(); fputs("{\n", out_); indentation_ += 2; emitIndentation(); emitType(tp); switch (tp) { case kBoolean: fprintf(out_, " lZ%u = ", boolean_local_); break; case kInt: fprintf(out_, " lI%u = ", int_local_); break; case kLong: fprintf(out_, " lJ%u = ", long_local_); break; case kFloat: fprintf(out_, " lF%u = ", float_local_); break; case kDouble: fprintf(out_, " lD%u = ", double_local_); break; } emitExpression(tp); fputs(";\n", out_); adjustLocal(tp, 1); // local now visible bool mayFollow = emitStatementList(); adjustLocal(tp, -1); // local no longer visible indentation_ -= 2; emitIndentation(); fputs("}\n", out_); return mayFollow; } // Emit one dimension of an array initializer, where parameter dim >= 1 // denotes the number of remaining dimensions that should be emitted. void emitArrayInitDim(int dim) { if (dim == 1) { // Last dimension: set of values. fputs("{ ", out_); for (uint32_t i = 0; i < array_size_; i++) { emitExpression(array_type_); fputs(", ", out_); } fputs("}", out_); } else { // Outer dimensions: set of sets. fputs("{\n", out_); indentation_ += 2; emitIndentation(); for (uint32_t i = 0; i < array_size_; i++) { emitArrayInitDim(dim - 1); if (i != array_size_ - 1) { fputs(",\n", out_); emitIndentation(); } } fputs(",\n", out_); indentation_ -= 2; emitIndentation(); fputs("}", out_); } } // Emit an array initializer of the following form. // { // type[]..[] tmp = { .. }; // mArray = tmp; // } bool emitArrayInit() { // Avoid elaborate array initializers. uint64_t p = pow(array_size_, array_dim_); if (p > 20) { return emitAssignment(); // fall back } fputs("{\n", out_); indentation_ += 2; emitIndentation(); emitType(array_type_); for (uint32_t i = 0; i < array_dim_; i++) { fputs("[]", out_); } fputs(" tmp = ", out_); emitArrayInitDim(array_dim_); fputs(";\n", out_); emitIndentation(); fputs("mArray = tmp;\n", out_); indentation_ -= 2; emitIndentation(); fputs("}\n", out_); return true; } // Emit a for loop. bool emitForLoop() { // Continuing loop nest becomes less likely as the depth grows. if (random1(loop_nest_ + 1) > fuzz_loop_nest_) { return emitAssignment(); // fall back } bool goesUp = random1(2) == 1; fprintf(out_, "for (int i%u = ", loop_nest_); if (goesUp) { fprintf(out_, "0; i%u < ", loop_nest_); emitUpperBound(); fprintf(out_, "; i%u++) {\n", loop_nest_); } else { emitUpperBound(); fprintf(out_, " - 1; i%d >= 0", loop_nest_); fprintf(out_, "; i%d--) {\n", loop_nest_); } ++loop_nest_; // now in loop indentation_ += 2; emitStatementList(); --loop_nest_; // no longer in loop indentation_ -= 2; emitIndentation(); fprintf(out_, "}\n"); return true; // loop-body does not block flow } // Emit while or do-while loop. bool emitDoLoop() { // Continuing loop nest becomes less likely as the depth grows. if (random1(loop_nest_ + 1) > fuzz_loop_nest_) { return emitAssignment(); // fall back } bool isWhile = random1(2) == 1; fputs("{\n", out_); indentation_ += 2; emitIndentation(); fprintf(out_, "int i%u = %d;\n", loop_nest_, isWhile ? -1 : 0); emitIndentation(); if (isWhile) { fprintf(out_, "while (++i%u < ", loop_nest_); emitUpperBound(); fputs(") {\n", out_); } else { fputs("do {\n", out_); do_nest_++; } ++loop_nest_; // now in loop indentation_ += 2; emitStatementList(); --loop_nest_; // no longer in loop indentation_ -= 2; emitIndentation(); if (isWhile) { fputs("}\n", out_); } else { fprintf(out_, "} while (++i%u < ", loop_nest_); emitUpperBound(); fputs(");\n", out_); --do_nest_; } indentation_ -= 2; emitIndentation(); fputs("}\n", out_); return true; // loop-body does not block flow } // Emit an if statement. bool emitIfStmt() { // Continuing if nest becomes less likely as the depth grows. if (random1(if_nest_ + 1) > fuzz_if_nest_) { return emitAssignment(); // fall back } fputs("if (", out_); emitExpression(kBoolean); fputs(") {\n", out_); ++if_nest_; // now in if indentation_ += 2; bool mayFollowTrue = emitStatementList(); indentation_ -= 2; emitIndentation(); fprintf(out_, "} else {\n"); indentation_ += 2; bool mayFollowFalse = emitStatementList(); --if_nest_; // no longer in if indentation_ -= 2; emitIndentation(); fprintf(out_, "}\n"); return mayFollowTrue || mayFollowFalse; } bool emitTry() { fputs("try {\n", out_); indentation_ += 2; bool mayFollow = emitStatementList(); indentation_ -= 2; emitIndentation(); fputc('}', out_); return mayFollow; } bool emitCatch() { uint32_t count = random1(countof(kExceptionTypes)); bool mayFollow = false; for (uint32_t i = 0; i < count; ++i) { fprintf(out_, " catch (%s ex%u_%u) {\n", kExceptionTypes[i], try_nest_, i); indentation_ += 2; mayFollow |= emitStatementList(); indentation_ -= 2; emitIndentation(); fputc('}', out_); } return mayFollow; } bool emitFinally() { fputs(" finally {\n", out_); indentation_ += 2; bool mayFollow = emitStatementList(); indentation_ -= 2; emitIndentation(); fputc('}', out_); return mayFollow; } // Emit a try-catch-finally block. bool emitTryCatchFinally() { // Apply a hard limit on the number of catch blocks. This is for // javac which fails if blocks within try-catch-finally are too // large (much less than you'd expect). if (try_nest_ > fuzz_try_nest_) { return emitAssignment(); // fall back } ++try_nest_; // Entering try-catch-finally bool mayFollow = emitTry(); switch (random0(3)) { case 0: // try..catch mayFollow |= emitCatch(); break; case 1: // try..finally mayFollow &= emitFinally(); break; case 2: // try..catch..finally // When determining whether code may follow, we observe that a // finally block always follows after try and catch // block. Code may only follow if the finally block permits // and either the try or catch block allows code to follow. mayFollow = (mayFollow | emitCatch()) & emitFinally(); break; } fputc('\n', out_); --try_nest_; // Leaving try-catch-finally return mayFollow; } // Emit a switch statement. bool emitSwitch() { // Continuing if nest becomes less likely as the depth grows. if (random1(if_nest_ + 1) > fuzz_if_nest_) { return emitAssignment(); // fall back } bool mayFollow = false; fputs("switch (", out_); emitArrayIndex(); // restrict its range fputs(") {\n", out_); ++if_nest_; ++switch_nest_; // now in switch indentation_ += 2; for (uint32_t i = 0; i < 2; i++) { emitIndentation(); if (i == 0) { fprintf(out_, "case %u: {\n", random0(array_size_)); } else { fprintf(out_, "default: {\n"); } indentation_ += 2; if (emitStatementList()) { // Must end with break. emitIndentation(); fputs("break;\n", out_); mayFollow = true; } indentation_ -= 2; emitIndentation(); fputs("}\n", out_); } --if_nest_; --switch_nest_; // no longer in switch indentation_ -= 2; emitIndentation(); fprintf(out_, "}\n"); return mayFollow; } bool emitNopCall() { fputs("nop();\n", out_); return true; } // Emit an assignment statement. bool emitAssignment() { Type tp = randomType(); emitVariable(tp); fputc(' ', out_); emitAssignmentOp(tp); fputc(' ', out_); emitExpression(tp); fputs(";\n", out_); return true; } // Emit a single statement. Returns true if statements may follow. bool emitStatement() { switch (random1(16)) { // favor assignments case 1: return emitReturn(false); break; case 2: return emitContinue(); break; case 3: return emitBreak(); break; case 4: return emitScope(); break; case 5: return emitArrayInit(); break; case 6: return emitForLoop(); break; case 7: return emitDoLoop(); break; case 8: return emitIfStmt(); break; case 9: return emitSwitch(); break; case 10: return emitTryCatchFinally(); break; case 11: return emitNopCall(); break; default: return emitAssignment(); break; } } // Emit a statement list. Returns true if statements may follow. bool emitStatementList() { while (stmt_length_ < 1000) { // avoid run-away stmt_length_++; emitIndentation(); if (!emitStatement()) { return false; // rest would be dead code } // Continuing this list becomes less likely as the total statement list grows. if (random1(stmt_length_) > fuzz_stmt_length_) { break; } } return true; } // Emit interface and class declarations. void emitClassDecls() { in_inner_ = true; fputs(" private interface X {\n", out_); fputs(" int x();\n", out_); fputs(" }\n\n", out_); fputs(" private class A {\n", out_); fputs(" public int a() {\n", out_); fputs(" return ", out_); emitExpression(kInt); fputs(";\n }\n", out_); fputs(" }\n\n", out_); fputs(" private class B extends A implements X {\n", out_); fputs(" public int a() {\n", out_); fputs(" return super.a() + ", out_); emitExpression(kInt); fputs(";\n }\n", out_); fputs(" public int x() {\n", out_); fputs(" return ", out_); emitExpression(kInt); fputs(";\n }\n", out_); fputs(" }\n\n", out_); fputs(" private static class C implements X {\n", out_); fputs(" public static int s() {\n", out_); fputs(" return ", out_); emitLiteral(kInt); fputs(";\n }\n", out_); fputs(" public int c() {\n", out_); fputs(" return ", out_); emitLiteral(kInt); fputs(";\n }\n", out_); fputs(" public int x() {\n", out_); fputs(" return ", out_); emitLiteral(kInt); fputs(";\n }\n", out_); fputs(" }\n\n", out_); in_inner_ = false; } // Emit field declarations. void emitFieldDecls() { fputs(" private A mA = new B();\n", out_); fputs(" private B mB = new B();\n", out_); fputs(" private X mBX = new B();\n", out_); fputs(" private C mC = new C();\n", out_); fputs(" private X mCX = new C();\n\n", out_); fputs(" private boolean mZ = false;\n", out_); fputs(" private int mI = 0;\n", out_); fputs(" private long mJ = 0;\n", out_); fputs(" private float mF = 0;\n", out_); fputs(" private double mD = 0;\n\n", out_); } // Emit array declaration. void emitArrayDecl() { fputs(" private ", out_); emitType(array_type_); for (uint32_t i = 0; i < array_dim_; i++) { fputs("[]", out_); } fputs(" mArray = new ", out_); emitType(array_type_); for (uint32_t i = 0; i < array_dim_; i++) { fprintf(out_, "[%d]", array_size_); } fputs(";\n\n", out_); } // Emit test constructor. void emitTestConstructor() { fputs(" private Test() {\n", out_); indentation_ += 2; emitIndentation(); emitType(array_type_); fputs(" a = ", out_); emitLiteral(array_type_); fputs(";\n", out_); for (uint32_t i = 0; i < array_dim_; i++) { emitIndentation(); fprintf(out_, "for (int i%u = 0; i%u < %u; i%u++) {\n", i, i, array_size_, i); indentation_ += 2; } emitIndentation(); fputs("mArray", out_); for (uint32_t i = 0; i < array_dim_; i++) { fprintf(out_, "[i%u]", i); } fputs(" = a;\n", out_); emitIndentation(); if (array_type_ == kBoolean) { fputs("a = !a;\n", out_); } else { fputs("a++;\n", out_); } for (uint32_t i = 0; i < array_dim_; i++) { indentation_ -= 2; emitIndentation(); fputs("}\n", out_); } indentation_ -= 2; fputs(" }\n\n", out_); } // Emit test method. void emitTestMethod() { fputs(" private ", out_); emitType(return_type_); fputs(" testMethod() {\n", out_); indentation_ += 2; if (emitStatementList()) { // Must end with return. emitIndentation(); emitReturn(true); } indentation_ -= 2; fputs(" }\n\n", out_); } // Emit main method driver. void emitMainMethod() { fputs(" public static void main(String[] args) {\n", out_); indentation_ += 2; fputs(" Test t = new Test();\n ", out_); emitType(return_type_); fputs(" r = ", out_); emitLiteral(return_type_); fputs(";\n", out_); fputs(" try {\n", out_); fputs(" r = t.testMethod();\n", out_); fputs(" } catch (Exception e) {\n", out_); fputs(" // Arithmetic, null pointer, index out of bounds, etc.\n", out_); fputs(" System.out.println(\"An exception was caught.\");\n", out_); fputs(" }\n", out_); fputs(" System.out.println(\"r = \" + r);\n", out_); fputs(" System.out.println(\"mZ = \" + t.mZ);\n", out_); fputs(" System.out.println(\"mI = \" + t.mI);\n", out_); fputs(" System.out.println(\"mJ = \" + t.mJ);\n", out_); fputs(" System.out.println(\"mF = \" + t.mF);\n", out_); fputs(" System.out.println(\"mD = \" + t.mD);\n", out_); fputs(" System.out.println(\"mArray = \" + ", out_); if (array_dim_ == 1) { fputs("Arrays.toString(t.mArray)", out_); } else { fputs("Arrays.deepToString(t.mArray)", out_); } fputs(");\n", out_); indentation_ -= 2; fputs(" }\n", out_); } // Emit a static void method. void emitStaticNopMethod() { fputs(" public static void nop() {}\n\n", out_); } // Emit program header. Emit command line options in the comments. void emitHeader() { fputs("\n/**\n * AOSP JFuzz Tester.\n", out_); fputs(" * Automatically generated program.\n", out_); fprintf(out_, " * jfuzz -s %u -d %u -l %u -i %u -n %u (version %s)\n */\n\n", fuzz_seed_, fuzz_expr_depth_, fuzz_stmt_length_, fuzz_if_nest_, fuzz_loop_nest_, VERSION); fputs("import java.util.Arrays;\n\n", out_); } // Emit single test class with main driver. void emitTestClassWithMain() { fputs("public class Test {\n\n", out_); indentation_ += 2; emitClassDecls(); emitFieldDecls(); emitArrayDecl(); emitTestConstructor(); emitTestMethod(); emitStaticNopMethod(); emitMainMethod(); indentation_ -= 2; fputs("}\n\n", out_); } // // Random integers. // // Return random integer. int32_t random() { return fuzz_random_engine_(); } // Return random integer in range [0,max). uint32_t random0(uint32_t max) { std::uniform_int_distribution gen(0, max - 1); return gen(fuzz_random_engine_); } // Return random integer in range [1,max]. uint32_t random1(uint32_t max) { std::uniform_int_distribution gen(1, max); return gen(fuzz_random_engine_); } // Fuzzing parameters. FILE* out_; std::mt19937 fuzz_random_engine_; const uint32_t fuzz_seed_; const uint32_t fuzz_expr_depth_; const uint32_t fuzz_stmt_length_; const uint32_t fuzz_if_nest_; const uint32_t fuzz_loop_nest_; const uint32_t fuzz_try_nest_; // Return and array setup. const Type return_type_; const Type array_type_; const uint32_t array_dim_; const uint32_t array_size_; // Current context. uint32_t indentation_; uint32_t expr_depth_; uint32_t stmt_length_; uint32_t if_nest_; uint32_t loop_nest_; uint32_t switch_nest_; uint32_t do_nest_; uint32_t try_nest_; uint32_t boolean_local_; uint32_t int_local_; uint32_t long_local_; uint32_t float_local_; uint32_t double_local_; bool in_inner_; }; } // anonymous namespace int32_t main(int32_t argc, char** argv) { // Time-based seed. struct timeval tp; gettimeofday(&tp, nullptr); // Defaults. uint32_t seed = (tp.tv_sec * 1000000 + tp.tv_usec); uint32_t expr_depth = 1; uint32_t stmt_length = 8; uint32_t if_nest = 2; uint32_t loop_nest = 3; uint32_t try_nest = 2; // Parse options. while (1) { int32_t option = getopt(argc, argv, "s:d:l:i:n:vh"); if (option < 0) { break; // done } switch (option) { case 's': seed = strtoul(optarg, nullptr, 0); // deterministic seed break; case 'd': expr_depth = strtoul(optarg, nullptr, 0); break; case 'l': stmt_length = strtoul(optarg, nullptr, 0); break; case 'i': if_nest = strtoul(optarg, nullptr, 0); break; case 'n': loop_nest = strtoul(optarg, nullptr, 0); break; case 't': try_nest = strtoul(optarg, nullptr, 0); break; case 'v': fprintf(stderr, "jfuzz version %s\n", VERSION); return 0; case 'h': default: fprintf(stderr, "usage: %s [-s seed] " "[-d expr-depth] [-l stmt-length] " "[-i if-nest] [-n loop-nest] [-t try-nest] [-v] [-h]\n", argv[0]); return 1; } } // Seed global random generator. srand(seed); // Generate fuzzed program. JFuzz fuzz(stdout, seed, expr_depth, stmt_length, if_nest, loop_nest, try_nest); fuzz.emitProgram(); return 0; }