/* * Cppcheck - A tool for static C/C++ code analysis * Copyright (C) 2007-2020 Cppcheck team. * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ /** * @brief This is the ExprEngine component in Cppcheck. Its job is to * convert the C/C++ code into expressions that the Z3 prover understands. * We can then ask Z3 prover for instance if variable "x" can be 123 and * the Z3 prover can tell us that. * * Overview * ======== * * The ExprEngine performs a "abstract execution" of each function. * - ExprEngine performs "forward" analysis only. It starts at the top * of the functions. * - There is a abstract program state `Data::memory`. * - The constraints are stored in the vector `Data::constraints`. * * Abstract program state * ====================== * * The map `Data::memory` contains the abstract values of all variables * that are used in the current function scope. * * Use `--debug-bug-hunting --verbose` to dump out `Data::memory`. * Example output: * 2:5: { x=$1 y=$2} * Explanation: * At line 2, column 5: The memory has two variables. Variable x has the * value $1. Variable y has the value $2. * * Different value names: * - Typical abstract value has name that starts with "$". The number is * just a incremented value. * - If a variable has a known value then the concrete value is written. * Example: `{ x=1 }`. * - For an uninitialized value the output says "?". For example: `{ a=? }` * - For buffers the output is something like `{ buf=($3,size=10,[:]=?,[$1]=$2) }` * The first item "$3" is the name of the buffer value. * The second item says that the size of this buffer is 10. * After that comes `[index]=value` items that show what values buffer items have: * `[:]=?` means that all items are uninitialized. * `[$1]=$2` means that the buffer item at index "$1" has value "$2". * * Abstract execution * ================== * * The function: * static void execute(const Token *start, const Token *end, Data &data) * * Perform abstract execution of the code from `start` to `end`. The * `data` is modified during the abstract execution. * * Each astTop token is executed. From that, operands are executed * recursively in the "execute.." functions. The result of an operand is * a abstract value. * * Branches * -------- * * Imagine: * code1 * if (x > 0) * code2 * else * code3 * code4 * * When "if" is reached.. the current `data` is branched into `thenData` * and `elseData`. * For "thenData" a constraint is added: x>0 * For "elseData" a constraint is added: !(x>0) * * Then analysis of `thenData` and `elseData` will continue separately, * by recursive execution. The "code4" block will be analysed both with * `thenData` and `elseData`. * * Z3 * == * * The ExprEngine will not execute Z3 unless a check wants it to. * * The abstract values and all their constraints is added to a Z3 solver * object and after that Z3 can tell us if some condition can be true. * * Z3 is a SMT solver: * https://en.wikipedia.org/wiki/Satisfiability_modulo_theories * * In SMT: * - all variables are "constant". A variable can not be changed or assigned. * - There is no "execution". The solver considers all equations simultaneously. * * Simple example (TestExpr::expr6): * * void f(unsigned char x) * { * unsigned char y = 8 - x;\n" * y > 1000; * } * * If a check wants to know if "y > 1000" can be true, ExprEngine will * generate this Z3 input: * * (declare-fun $1 () Int) * (assert (and (>= $1 0) (<= $1 255))) * (assert (> (- 8 $1) 1000)) * * A symbol "$1" is created. * assert that "$1" is a value 0-255. * assert that "8-$1" is greater than 1000. * * Z3 can now determine if these assertions are possible or not. In this * case these assertions are not possible, there is no value for $1 between * 0-255 that means that "8-$1" is greater than 1000. */ #include "exprengine.h" #include "astutils.h" #include "bughuntingchecks.h" #include "errorlogger.h" #include "settings.h" #include "symboldatabase.h" #include "tokenize.h" #include #include #include #ifdef USE_Z3 #include #include #define GET_VERSION_INT(A,B,C) ((A) * 10000 + (B) * 100 + (C)) #define Z3_VERSION_INT GET_VERSION_INT(Z3_MAJOR_VERSION, Z3_MINOR_VERSION, Z3_BUILD_NUMBER) #endif namespace { struct BugHuntingException { BugHuntingException(const Token *tok, const std::string &what) : tok(tok), what(what) {} const Token *tok; const std::string what; }; } std::string ExprEngine::str(int128_t value) { std::ostringstream ostr; #ifdef __GNUC__ if (value == (int)value) { ostr << (int) value; return ostr.str(); } if (value < 0) { ostr << "-"; value = -value; } uint64_t high = value >> 64; uint64_t low = value; if (high > 0) ostr << "h" << std::hex << high << "l"; ostr << std::hex << low; #else ostr << value; #endif return ostr.str(); } static ExprEngine::ValuePtr getValueRangeFromValueType(const std::string &name, const ValueType *vt, const cppcheck::Platform &platform); namespace { class TrackExecution { public: TrackExecution() : mDataIndex(0), mAbortLine(-1) {} int getNewDataIndex() { return mDataIndex++; } void symbolRange(const Token *tok, ExprEngine::ValuePtr value) { if (!tok || !value) return; if (tok->index() == 0) return; const std::string &symbolicExpression = value->getSymbolicExpression(); if (symbolicExpression[0] != '$') return; if (mSymbols.find(symbolicExpression) != mSymbols.end()) return; mSymbols.insert(symbolicExpression); mMap[tok].push_back(symbolicExpression + "=" + value->getRange()); } void state(const Token *tok, const std::string &s) { mMap[tok].push_back(s); } void print(std::ostream &out) { std::set> locations; for (auto it : mMap) { locations.insert(std::pair(it.first->linenr(), it.first->column())); } for (const std::pair &loc : locations) { int lineNumber = loc.first; int column = loc.second; for (auto &it : mMap) { const Token *tok = it.first; if (lineNumber != tok->linenr()) continue; if (column != tok->column()) continue; const std::vector &dumps = it.second; for (const std::string &dump : dumps) out << lineNumber << ":" << column << ": " << dump << "\n"; } } } void report(std::ostream &out, const Scope *functionScope) { int linenr = -1; std::string code; for (const Token *tok = functionScope->bodyStart->next(); tok != functionScope->bodyEnd; tok = tok->next()) { if (tok->linenr() > linenr) { if (!code.empty()) out << getStatus(linenr) << " " << code << std::endl; linenr = tok->linenr(); code.clear(); } code += " " + tok->str(); } out << getStatus(linenr) << " " << code << std::endl; } void setAbortLine(int linenr) { if (linenr > 0 && (mAbortLine == -1 || linenr < mAbortLine)) mAbortLine = linenr; } void addError(int linenr) { mErrors.insert(linenr); } bool isAllOk() const { return mErrors.empty(); } void addMissingContract(const std::string &f) { mMissingContracts.insert(f); } const std::set getMissingContracts() const { return mMissingContracts; } private: const char *getStatus(int linenr) const { if (mErrors.find(linenr) != mErrors.end()) return "ERROR"; if (mAbortLine > 0 && linenr >= mAbortLine) return "--"; return "ok"; } std::map> mMap; int mDataIndex; int mAbortLine; std::set mSymbols; std::set mErrors; std::set mMissingContracts; }; class Data : public ExprEngine::DataBase { public: Data(int *symbolValueIndex, ErrorLogger *errorLogger, const Tokenizer *tokenizer, const Settings *settings, const std::string ¤tFunction, const std::vector &callbacks, TrackExecution *trackExecution) : DataBase(currentFunction, settings) , symbolValueIndex(symbolValueIndex) , errorLogger(errorLogger) , tokenizer(tokenizer) , callbacks(callbacks) , recursion(0) , mTrackExecution(trackExecution) , mDataIndex(trackExecution->getNewDataIndex()) {} typedef std::map Memory; Memory memory; int * const symbolValueIndex; ErrorLogger *errorLogger; const Tokenizer * const tokenizer; const std::vector &callbacks; std::vector constraints; int recursion; ExprEngine::ValuePtr executeContract(const Function *function, ExprEngine::ValuePtr(*executeExpression)(const Token*, Data&)) { const auto it = settings->functionContracts.find(function->fullName()); if (it == settings->functionContracts.end()) return ExprEngine::ValuePtr(); const std::string &expects = it->second; TokenList tokenList(settings); std::istringstream istr(expects); tokenList.createTokens(istr); tokenList.createAst(); SymbolDatabase *symbolDatabase = const_cast(tokenizer->getSymbolDatabase()); for (Token *tok = tokenList.front(); tok; tok = tok->next()) { for (const Variable &arg: function->argumentList) { if (arg.name() == tok->str()) { tok->variable(&arg); tok->varId(arg.declarationId()); } } } symbolDatabase->setValueTypeInTokenList(false, tokenList.front()); return executeExpression(tokenList.front()->astTop(), *this); } void contractConstraints(const Function *function, ExprEngine::ValuePtr(*executeExpression)(const Token*, Data&)) { auto value = executeContract(function, executeExpression); if (value) constraints.push_back(value); } void assignValue(const Token *tok, unsigned int varId, ExprEngine::ValuePtr value) { if (varId == 0) return; mTrackExecution->symbolRange(tok, value); if (value) { if (auto arr = std::dynamic_pointer_cast(value)) { for (const auto &dim: arr->size) mTrackExecution->symbolRange(tok, dim); for (const auto &indexAndValue: arr->data) mTrackExecution->symbolRange(tok, indexAndValue.value); } else if (auto s = std::dynamic_pointer_cast(value)) { for (const auto &m: s->member) mTrackExecution->symbolRange(tok, m.second); } } memory[varId] = value; } void assignStructMember(const Token *tok, ExprEngine::StructValue *structVal, const std::string &memberName, ExprEngine::ValuePtr value) { mTrackExecution->symbolRange(tok, value); structVal->member[memberName] = value; } void functionCall() { // Remove values for global variables const SymbolDatabase *symbolDatabase = tokenizer->getSymbolDatabase(); for (std::map::iterator it = memory.begin(); it != memory.end();) { unsigned int varid = it->first; const Variable *var = symbolDatabase->getVariableFromVarId(varid); if (var && var->isGlobal()) it = memory.erase(it); else ++it; } } std::string getNewSymbolName() OVERRIDE { return "$" + std::to_string(++(*symbolValueIndex)); } std::shared_ptr getArrayValue(const Token *tok) { const Memory::iterator it = memory.find(tok->varId()); if (it != memory.end()) return std::dynamic_pointer_cast(it->second); if (tok->varId() == 0 || !tok->variable()) return std::shared_ptr(); auto val = std::make_shared(this, tok->variable()); assignValue(tok, tok->varId(), val); return val; } ExprEngine::ValuePtr getValue(unsigned int varId, const ValueType *valueType, const Token *tok) { const Memory::const_iterator it = memory.find(varId); if (it != memory.end()) return it->second; if (!valueType) return ExprEngine::ValuePtr(); ExprEngine::ValuePtr value = getValueRangeFromValueType(getNewSymbolName(), valueType, *settings); if (value) { if (tok->variable() && tok->variable()->nameToken()) addConstraints(value, tok->variable()->nameToken()); assignValue(tok, varId, value); } return value; } void trackCheckContract(const Token *tok, const std::string &solverOutput) { std::ostringstream os; os << "checkContract:{\n"; std::string line; std::istringstream istr(solverOutput); while (std::getline(istr, line)) os << " " << line << "\n"; os << "}"; mTrackExecution->state(tok, os.str()); } void trackProgramState(const Token *tok) { if (memory.empty()) return; const SymbolDatabase * const symbolDatabase = tokenizer->getSymbolDatabase(); std::ostringstream s; s << "{"; // << mDataIndex << ":"; for (auto mem : memory) { ExprEngine::ValuePtr value = mem.second; const Variable *var = symbolDatabase->getVariableFromVarId(mem.first); if (!var) continue; s << " " << var->name() << "="; if (!value) s << "(null)"; else if (value->name[0] == '$' && value->getSymbolicExpression() != value->name) s << "(" << value->name << "," << value->getSymbolicExpression() << ")"; else s << value->name; } s << "}"; mTrackExecution->state(tok, s.str()); } void addMissingContract(const std::string &f) { mTrackExecution->addMissingContract(f); } const std::set getMissingContracts() const { return mTrackExecution->getMissingContracts(); } ExprEngine::ValuePtr notValue(ExprEngine::ValuePtr v) { auto b = std::dynamic_pointer_cast(v); if (b) { std::string binop; if (b->binop == "==") binop = "!="; else if (b->binop == "!=") binop = "=="; else if (b->binop == ">=") binop = "<"; else if (b->binop == "<=") binop = ">"; else if (b->binop == ">") binop = "<="; else if (b->binop == "<") binop = ">="; if (!binop.empty()) return std::make_shared(binop, b->op1, b->op2); } auto zero = std::make_shared("0", 0, 0); return std::make_shared("==", v, zero); } void addConstraint(ExprEngine::ValuePtr condValue, bool trueCond) { if (!condValue) return; if (trueCond) constraints.push_back(condValue); else constraints.push_back(notValue(condValue)); } void addConstraint(ExprEngine::ValuePtr lhsValue, ExprEngine::ValuePtr rhsValue, bool equals) { if (!lhsValue || !rhsValue) return; constraints.push_back(std::make_shared(equals?"==":"!=", lhsValue, rhsValue)); } void addConstraints(ExprEngine::ValuePtr value, const Token *tok) { MathLib::bigint low; if (tok->getCppcheckAttribute(TokenImpl::CppcheckAttributes::Type::LOW, &low)) addConstraint(std::make_shared(">=", value, std::make_shared(std::to_string(low), low, low)), true); MathLib::bigint high; if (tok->getCppcheckAttribute(TokenImpl::CppcheckAttributes::Type::HIGH, &high)) addConstraint(std::make_shared("<=", value, std::make_shared(std::to_string(high), high, high)), true); } void reportError(const Token *tok, Severity::SeverityType severity, const char id[], const std::string &text, CWE cwe, bool inconclusive, bool incomplete, const std::string &functionName) OVERRIDE { if (errorPath.empty()) mTrackExecution->addError(tok->linenr()); ErrorPath e = errorPath; e.push_back(ErrorPathItem(tok, text)); ErrorMessage errmsg(e, &tokenizer->list, severity, id, text, cwe, inconclusive); errmsg.incomplete = incomplete; errmsg.function = functionName.empty() ? currentFunction : functionName; errorLogger->reportErr(errmsg); } private: TrackExecution * const mTrackExecution; const int mDataIndex; }; } #ifdef __clang__ // work around "undefined reference to `__muloti4'" linker error - see https://bugs.llvm.org/show_bug.cgi?id=16404 __attribute__((no_sanitize("undefined"))) #endif static ExprEngine::ValuePtr simplifyValue(ExprEngine::ValuePtr origValue) { auto b = std::dynamic_pointer_cast(origValue); if (!b) return origValue; if (!b->op1 || !b->op2) return origValue; auto intRange1 = std::dynamic_pointer_cast(b->op1); auto intRange2 = std::dynamic_pointer_cast(b->op2); if (intRange1 && intRange2 && intRange1->minValue == intRange1->maxValue && intRange2->minValue == intRange2->maxValue) { const std::string &binop = b->binop; int128_t v; if (binop == "+") v = intRange1->minValue + intRange2->minValue; else if (binop == "-") v = intRange1->minValue - intRange2->minValue; else if (binop == "*") v = intRange1->minValue * intRange2->minValue; else if (binop == "/" && intRange2->minValue != 0) v = intRange1->minValue / intRange2->minValue; else if (binop == "%" && intRange2->minValue != 0) v = intRange1->minValue % intRange2->minValue; else return origValue; return std::make_shared(ExprEngine::str(v), v, v); } return origValue; } static ExprEngine::ValuePtr translateUninitValueToRange(ExprEngine::ValuePtr value, const ::ValueType *valueType, Data &data) { if (!value) return value; if (value->type == ExprEngine::ValueType::UninitValue) { auto rangeValue = getValueRangeFromValueType(data.getNewSymbolName(), valueType, *data.settings); if (rangeValue) return rangeValue; } if (auto conditionalValue = std::dynamic_pointer_cast(value)) { if (conditionalValue->values.size() == 1 && conditionalValue->values[0].second && conditionalValue->values[0].second->type == ExprEngine::ValueType::UninitValue) { auto rangeValue = getValueRangeFromValueType(data.getNewSymbolName(), valueType, *data.settings); if (rangeValue) return rangeValue; } } return value; } static int128_t truncateInt(int128_t value, int bits, char sign) { value = value & (((int128_t)1 << bits) - 1); // Sign extension if (sign == 's' && value & (1ULL << (bits - 1))) value |= ~(((int128_t)1 << bits) - 1); return value; } ExprEngine::ArrayValue::ArrayValue(const std::string &name, ExprEngine::ValuePtr size, ExprEngine::ValuePtr value, bool pointer, bool nullPointer, bool uninitPointer) : Value(name, ExprEngine::ValueType::ArrayValue) , pointer(pointer), nullPointer(nullPointer), uninitPointer(uninitPointer) { this->size.push_back(size); assign(ExprEngine::ValuePtr(), value); } ExprEngine::ArrayValue::ArrayValue(DataBase *data, const Variable *var) : Value(data->getNewSymbolName(), ExprEngine::ValueType::ArrayValue) , pointer(var->isPointer()), nullPointer(var->isPointer()), uninitPointer(var->isPointer()) { if (var) { for (const auto &dim : var->dimensions()) { if (dim.known) size.push_back(std::make_shared(std::to_string(dim.num), dim.num, dim.num)); else size.push_back(std::make_shared(data->getNewSymbolName(), 1, ExprEngine::ArrayValue::MAXSIZE)); } } else { size.push_back(std::make_shared(data->getNewSymbolName(), 1, ExprEngine::ArrayValue::MAXSIZE)); } ValuePtr val; if (var && !var->isGlobal() && !var->isStatic()) val = std::make_shared(); else if (var && var->valueType()) { ::ValueType vt(*var->valueType()); vt.pointer = 0; val = getValueRangeFromValueType(data->getNewSymbolName(), &vt, *data->settings); } assign(ExprEngine::ValuePtr(), val); } std::string ExprEngine::ArrayValue::getRange() const { std::string r = getSymbolicExpression(); if (nullPointer) r += std::string(r.empty() ? "" : ",") + "null"; if (uninitPointer) r += std::string(r.empty() ? "" : ",") + "->?"; return r; } void ExprEngine::ArrayValue::assign(ExprEngine::ValuePtr index, ExprEngine::ValuePtr value) { if (!index) data.clear(); if (value) { ExprEngine::ArrayValue::IndexAndValue indexAndValue = {index, value}; data.push_back(indexAndValue); } } void ExprEngine::ArrayValue::clear() { data.clear(); ExprEngine::ArrayValue::IndexAndValue indexAndValue = { ExprEngine::ValuePtr(), std::make_shared("0", 0, 0) }; data.push_back(indexAndValue); } static bool isEqual(ExprEngine::ValuePtr v1, ExprEngine::ValuePtr v2) { if (!v1 || !v2) return !v1 && !v2; return v1->name == v2->name; } static bool isNonOverlapping(ExprEngine::ValuePtr v1, ExprEngine::ValuePtr v2) { if (!v1 || !v2) return false; // Don't know! auto intRange1 = std::dynamic_pointer_cast(v1); auto intRange2 = std::dynamic_pointer_cast(v2); if (intRange1 && intRange2 && (intRange1->minValue > intRange2->maxValue || intRange1->maxValue < intRange2->maxValue)) return true; return false; } ExprEngine::ConditionalValue::Vector ExprEngine::ArrayValue::read(ExprEngine::ValuePtr index) const { ExprEngine::ConditionalValue::Vector ret; if (!index) return ret; for (const auto &indexAndValue : data) { if (::isEqual(index, indexAndValue.index)) ret.clear(); if (isNonOverlapping(index, indexAndValue.index)) continue; // Array contains string literal data... if (!indexAndValue.index && indexAndValue.value->type == ExprEngine::ValueType::StringLiteralValue) { auto stringLiteral = std::dynamic_pointer_cast(indexAndValue.value); if (!stringLiteral) { ret.push_back(std::pair(indexAndValue.index, std::make_shared("", -128, 128))); continue; } if (auto i = std::dynamic_pointer_cast(index)) { if (i->minValue >= 0 && i->minValue == i->maxValue) { int c = 0; if (i->minValue < stringLiteral->size()) c = stringLiteral->string[i->minValue]; ret.push_back(std::pair(indexAndValue.index, std::make_shared(std::to_string(c), c, c))); continue; } } int cmin = 0, cmax = 0; for (char c : stringLiteral->string) { if (c < cmin) cmin = c; else if (c > cmax) cmax = c; } ret.push_back(std::pair(indexAndValue.index, std::make_shared("", cmin, cmax))); continue; } // Rename IntRange if (auto i = std::dynamic_pointer_cast(indexAndValue.value)) { ret.push_back(std::pair(indexAndValue.index, std::make_shared(indexAndValue.value->name + ":" + index->name, i->minValue, i->maxValue))); continue; } ret.push_back(std::pair(indexAndValue.index, indexAndValue.value)); } if (ret.size() == 1) ret[0].first = ExprEngine::ValuePtr(); else if (ret.size() == 2 && !ret[0].first) { ret[0].first = std::make_shared("!=", index, ret[1].first); ret[1].first = std::make_shared("==", index, ret[1].first); } else { // FIXME!! ret.clear(); } return ret; } std::string ExprEngine::ConditionalValue::getSymbolicExpression() const { std::ostringstream ostr; ostr << "{"; bool first = true; for (auto condvalue : values) { ValuePtr cond = condvalue.first; ValuePtr value = condvalue.second; if (!first) ostr << ","; first = false; ostr << "{" << (cond ? cond->getSymbolicExpression() : std::string("(null)")) << "," << value->getSymbolicExpression() << "}"; } ostr << "}"; return ostr.str(); } std::string ExprEngine::ArrayValue::getSymbolicExpression() const { std::ostringstream ostr; if (size.empty()) ostr << "(null)"; else { for (const auto &dim: size) ostr << "[" << (dim ? dim->name : std::string("(null)")) << "]"; } for (const auto &indexAndValue : data) { ostr << ",[" << (!indexAndValue.index ? std::string(":") : indexAndValue.index->name) << "]=" << indexAndValue.value->name; } return ostr.str(); } std::string ExprEngine::StructValue::getSymbolicExpression() const { std::ostringstream ostr; ostr << "{"; bool first = true; for (const auto& m: member) { const std::string &memberName = m.first; auto memberValue = m.second; if (!first) ostr << ","; first = false; ostr << memberName << "=" << (memberValue ? memberValue->getSymbolicExpression() : std::string("(null)")); } ostr << "}"; return ostr.str(); } std::string ExprEngine::IntegerTruncation::getSymbolicExpression() const { return sign + std::to_string(bits) + "(" + inputValue->getSymbolicExpression() + ")"; } #ifdef USE_Z3 struct ExprData { typedef std::map ValueExpr; typedef std::vector AssertionList; z3::context context; ValueExpr valueExpr; AssertionList assertionList; void addAssertions(z3::solver &solver) const { for (auto assertExpr : assertionList) solver.add(assertExpr); } z3::expr addInt(const std::string &name, int128_t minValue, int128_t maxValue) { z3::expr e = context.int_const(name.c_str()); valueExpr.emplace(name, e); if (minValue >= INT_MIN && maxValue <= INT_MAX) assertionList.push_back(e >= int(minValue) && e <= int(maxValue)); else if (maxValue <= INT_MAX) assertionList.push_back(e <= int(maxValue)); else if (minValue >= INT_MIN) assertionList.push_back(e >= int(minValue)); return e; } z3::expr addFloat(const std::string &name) { #if Z3_VERSION_INT >= GET_VERSION_INT(4,8,0) z3::expr e = context.fpa_const(name.c_str(), 11, 53); #else z3::expr e = context.real_const(name.c_str()); #endif valueExpr.emplace(name, e); return e; } z3::expr getExpr(const ExprEngine::BinOpResult *b) { auto op1 = getExpr(b->op1); auto op2 = getExpr(b->op2); if (b->binop == "+") return op1 + op2; if (b->binop == "-") return op1 - op2; if (b->binop == "*") return op1 * op2; if (b->binop == "/") return op1 / op2; if (b->binop == "%") #if Z3_VERSION_INT >= GET_VERSION_INT(4,8,5) return op1 % op2; #else return op1 - (op1 / op2) * op2; #endif if (b->binop == "==") return int_expr(op1) == int_expr(op2); if (b->binop == "!=") return op1 != op2; if (b->binop == ">=") return op1 >= op2; if (b->binop == "<=") return op1 <= op2; if (b->binop == ">") return op1 > op2; if (b->binop == "<") return op1 < op2; if (b->binop == "&&") return bool_expr(op1) && bool_expr(op2); if (b->binop == "||") return bool_expr(op1) || bool_expr(op2); if (b->binop == "<<") return op1 * z3::pw(context.int_val(2), op2); if (b->binop == ">>") return op1 / z3::pw(context.int_val(2), op2); throw BugHuntingException(nullptr, "Internal error: Unhandled operator " + b->binop); } z3::expr getExpr(ExprEngine::ValuePtr v) { if (!v) throw BugHuntingException(nullptr, "Can not solve expressions, operand value is null"); if (auto intRange = std::dynamic_pointer_cast(v)) { if (intRange->name[0] != '$') #if Z3_VERSION_INT >= GET_VERSION_INT(4,7,1) return context.int_val(int64_t(intRange->minValue)); #else return context.int_val((long long)(intRange->minValue)); #endif auto it = valueExpr.find(v->name); if (it != valueExpr.end()) return it->second; return addInt(v->name, intRange->minValue, intRange->maxValue); } if (auto floatRange = std::dynamic_pointer_cast(v)) { auto it = valueExpr.find(v->name); if (it != valueExpr.end()) return it->second; return addFloat(v->name); } if (auto b = std::dynamic_pointer_cast(v)) { return getExpr(b.get()); } if (auto c = std::dynamic_pointer_cast(v)) { if (c->values.empty()) throw BugHuntingException(nullptr, "ConditionalValue is empty"); if (c->values.size() == 1) return getExpr(c->values[0].second); return z3::ite(getExpr(c->values[1].first), getExpr(c->values[1].second), getExpr(c->values[0].second)); } if (auto integerTruncation = std::dynamic_pointer_cast(v)) { return getExpr(integerTruncation->inputValue); //return getExpr(integerTruncation->inputValue) & ((1 << integerTruncation->bits) - 1); } if (v->type == ExprEngine::ValueType::UninitValue) return context.int_val(0); throw BugHuntingException(nullptr, "Internal error: Unhandled value type"); } z3::expr getConstraintExpr(ExprEngine::ValuePtr v) { if (v->type == ExprEngine::ValueType::IntRange) return (getExpr(v) != 0); return bool_expr(getExpr(v)); } private: z3::expr bool_expr(z3::expr e) { if (e.is_bool()) return e; return e != 0; } z3::expr int_expr(z3::expr e) { if (e.is_bool()) return z3::ite(e, context.int_val(1), context.int_val(0)); return e; } }; #endif bool ExprEngine::IntRange::isEqual(DataBase *dataBase, int value) const { if (value < minValue || value > maxValue) return false; const Data *data = dynamic_cast(dataBase); if (data->constraints.empty()) return true; #ifdef USE_Z3 // Check the value against the constraints ExprData exprData; z3::solver solver(exprData.context); try { z3::expr e = exprData.addInt(name, minValue, maxValue); for (auto constraint : dynamic_cast(dataBase)->constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); solver.add(e == value); return solver.check() == z3::sat; } catch (const z3::exception &exception) { std::cerr << "z3: " << exception << std::endl; return true; // Safe option is to return true } #else // The value may or may not be in range return false; #endif } bool ExprEngine::IntRange::isGreaterThan(DataBase *dataBase, int value) const { if (maxValue <= value) return false; const Data *data = dynamic_cast(dataBase); if (data->constraints.empty()) return true; #ifdef USE_Z3 // Check the value against the constraints ExprData exprData; z3::solver solver(exprData.context); try { z3::expr e = exprData.addInt(name, minValue, maxValue); for (auto constraint : dynamic_cast(dataBase)->constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); solver.add(e > value); return solver.check() == z3::sat; } catch (const z3::exception &exception) { std::cerr << "z3: " << exception << std::endl; return true; // Safe option is to return true } #else // The value may or may not be in range return false; #endif } bool ExprEngine::IntRange::isLessThan(DataBase *dataBase, int value) const { if (minValue >= value) return false; const Data *data = dynamic_cast(dataBase); if (data->constraints.empty()) return true; #ifdef USE_Z3 // Check the value against the constraints ExprData exprData; z3::solver solver(exprData.context); try { z3::expr e = exprData.addInt(name, minValue, maxValue); for (auto constraint : dynamic_cast(dataBase)->constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); solver.add(e < value); return solver.check() == z3::sat; } catch (const z3::exception &exception) { std::cerr << "z3: " << exception << std::endl; return true; // Safe option is to return true } #else // The value may or may not be in range return false; #endif } bool ExprEngine::FloatRange::isEqual(DataBase *dataBase, int value) const { const Data *data = dynamic_cast(dataBase); if (data->constraints.empty()) return true; if (MathLib::isFloat(name)) { float f = MathLib::toDoubleNumber(name); return value >= f - 0.00001 && value <= f + 0.00001; } #ifdef USE_Z3 // Check the value against the constraints ExprData exprData; z3::solver solver(exprData.context); try { z3::expr e = exprData.addFloat(name); for (auto constraint : dynamic_cast(dataBase)->constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); solver.add(e >= value && e <= value); return solver.check() != z3::unsat; } catch (const z3::exception &exception) { std::cerr << "z3: " << exception << std::endl; return true; // Safe option is to return true } #else // The value may or may not be in range return false; #endif } bool ExprEngine::FloatRange::isGreaterThan(DataBase *dataBase, int value) const { if (value < minValue || value > maxValue) return false; const Data *data = dynamic_cast(dataBase); if (data->constraints.empty()) return true; if (MathLib::isFloat(name)) return value > MathLib::toDoubleNumber(name); #ifdef USE_Z3 // Check the value against the constraints ExprData exprData; z3::solver solver(exprData.context); try { z3::expr e = exprData.addFloat(name); for (auto constraint : dynamic_cast(dataBase)->constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); solver.add(e > value); return solver.check() == z3::sat; } catch (const z3::exception &exception) { std::cerr << "z3: " << exception << std::endl; return true; // Safe option is to return true } #else // The value may or may not be in range return false; #endif } bool ExprEngine::FloatRange::isLessThan(DataBase *dataBase, int value) const { if (value < minValue || value > maxValue) return false; const Data *data = dynamic_cast(dataBase); if (data->constraints.empty()) return true; if (MathLib::isFloat(name)) return value < MathLib::toDoubleNumber(name); #ifdef USE_Z3 // Check the value against the constraints ExprData exprData; z3::solver solver(exprData.context); try { z3::expr e = exprData.addFloat(name); for (auto constraint : dynamic_cast(dataBase)->constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); solver.add(e < value); return solver.check() == z3::sat; } catch (const z3::exception &exception) { std::cerr << "z3: " << exception << std::endl; return true; // Safe option is to return true } #else // The value may or may not be in range return false; #endif } bool ExprEngine::BinOpResult::isEqual(ExprEngine::DataBase *dataBase, int value) const { #ifdef USE_Z3 ExprData exprData; z3::solver solver(exprData.context); z3::expr e = exprData.getExpr(this); for (auto constraint : dynamic_cast(dataBase)->constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); solver.add(e == value); return solver.check() == z3::sat; #else (void)dataBase; (void)value; return false; #endif } bool ExprEngine::BinOpResult::isGreaterThan(ExprEngine::DataBase *dataBase, int value) const { #ifdef USE_Z3 try { ExprData exprData; z3::solver solver(exprData.context); z3::expr e = exprData.getExpr(this); for (auto constraint : dynamic_cast(dataBase)->constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); solver.add(e > value); return solver.check() == z3::sat; } catch (const z3::exception &exception) { std::cerr << "z3:" << exception << std::endl; return true; // Safe option is to return true } #else (void)dataBase; (void)value; return false; #endif } bool ExprEngine::BinOpResult::isLessThan(ExprEngine::DataBase *dataBase, int value) const { #ifdef USE_Z3 try { ExprData exprData; z3::solver solver(exprData.context); z3::expr e = exprData.getExpr(this); for (auto constraint : dynamic_cast(dataBase)->constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); solver.add(e < value); return solver.check() == z3::sat; } catch (const z3::exception &exception) { std::cerr << "z3:" << exception << std::endl; return true; // Safe option is to return true } #else (void)dataBase; (void)value; return false; #endif } std::string ExprEngine::BinOpResult::getExpr(ExprEngine::DataBase *dataBase) const { #ifdef USE_Z3 try { ExprData exprData; z3::solver solver(exprData.context); z3::expr e = exprData.getExpr(this); for (auto constraint : dynamic_cast(dataBase)->constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); solver.add(e); std::ostringstream os; os << solver; switch (solver.check()) { case z3::sat: os << "\nz3::sat\n"; break; case z3::unsat: os << "\nz3::unsat\n"; break; case z3::unknown: os << "\nz3::unknown\n"; break; } return os.str(); } catch (const z3::exception &exception) { std::ostringstream os; os << "\nz3:" << exception << "\n"; return os.str(); } #else (void)dataBase; return ""; #endif } // Todo: This is taken from ValueFlow and modified.. we should reuse it static int getIntBitsFromValueType(const ValueType *vt, const cppcheck::Platform &platform) { if (!vt) return 0; switch (vt->type) { case ValueType::Type::BOOL: return 1; case ValueType::Type::CHAR: return platform.char_bit; case ValueType::Type::SHORT: return platform.short_bit; case ValueType::Type::INT: return platform.int_bit; case ValueType::Type::LONG: return platform.long_bit; case ValueType::Type::LONGLONG: return platform.long_long_bit; default: return 0; } } static ExprEngine::ValuePtr getValueRangeFromValueType(const std::string &name, const ValueType *vt, const cppcheck::Platform &platform) { if (!vt || !(vt->isIntegral() || vt->isFloat()) || vt->pointer) return ExprEngine::ValuePtr(); int bits = getIntBitsFromValueType(vt, platform); if (bits == 1) { return std::make_shared(name, 0, 1); } else if (bits > 1) { if (vt->sign == ValueType::Sign::UNSIGNED) { return std::make_shared(name, 0, ((int128_t)1 << bits) - 1); } else { return std::make_shared(name, -((int128_t)1 << (bits - 1)), ((int128_t)1 << (bits - 1)) - 1); } } if (vt->isFloat()) return std::make_shared(name, -std::numeric_limits::infinity(), std::numeric_limits::infinity()); return ExprEngine::ValuePtr(); } static void call(const std::vector &callbacks, const Token *tok, ExprEngine::ValuePtr value, Data *dataBase) { if (value) { for (ExprEngine::Callback f : callbacks) { try { f(tok, *value, dataBase); } catch (const BugHuntingException &e) { throw BugHuntingException(tok, e.what); } } } } static ExprEngine::ValuePtr executeExpression(const Token *tok, Data &data); static ExprEngine::ValuePtr executeExpression1(const Token *tok, Data &data); static void execute(const Token *start, const Token *end, Data &data); static ExprEngine::ValuePtr calculateArrayIndex(const Token *tok, Data &data, const ExprEngine::ArrayValue &arrayValue) { int nr = 1; const Token *tok2 = tok; while (Token::simpleMatch(tok2->astOperand1(), "[")) { tok2 = tok2->astOperand1(); nr++; } ExprEngine::ValuePtr totalIndex; ExprEngine::ValuePtr dim; while (Token::simpleMatch(tok, "[")) { auto rawIndex = executeExpression(tok->astOperand2(), data); ExprEngine::ValuePtr index; if (dim) index = simplifyValue(std::make_shared("*", dim, rawIndex)); else index = rawIndex; if (!totalIndex) totalIndex = index; else totalIndex = simplifyValue(std::make_shared("+", index, totalIndex)); if (arrayValue.size.size() >= nr) { if (arrayValue.size[nr-1]) { if (!dim) dim = arrayValue.size[nr-1]; else dim = simplifyValue(std::make_shared("*", dim, arrayValue.size[nr-1])); } } nr--; tok = tok->astOperand1(); } return totalIndex; } static ExprEngine::ValuePtr executeReturn(const Token *tok, Data &data) { ExprEngine::ValuePtr retval = executeExpression(tok->astOperand1(), data); call(data.callbacks, tok, retval, &data); return retval; } static ExprEngine::ValuePtr truncateValue(ExprEngine::ValuePtr val, const ValueType *valueType, Data &data) { if (!valueType) return val; if (valueType->pointer != 0) return val; if (!valueType->isIntegral()) return val; // TODO int bits = getIntBitsFromValueType(valueType, *data.settings); if (bits == 0) // TODO return val; if (auto range = std::dynamic_pointer_cast(val)) { if (range->minValue == range->maxValue) { int128_t newValue = truncateInt(range->minValue, bits, valueType->sign == ValueType::Sign::SIGNED ? 's' : 'u'); if (newValue == range->minValue) return val; return std::make_shared(ExprEngine::str(newValue), newValue, newValue); } if (auto typeRange = getValueRangeFromValueType("", valueType, *data.settings)) { auto typeIntRange = std::dynamic_pointer_cast(typeRange); if (typeIntRange) { if (range->minValue >= typeIntRange->minValue && range->maxValue <= typeIntRange->maxValue) return val; } } return std::make_shared(data.getNewSymbolName(), val, bits, valueType->sign == ValueType::Sign::SIGNED ? 's' : 'u'); } // TODO return val; } static ExprEngine::ValuePtr executeAssign(const Token *tok, Data &data) { ExprEngine::ValuePtr rhsValue = executeExpression(tok->astOperand2(), data); if (!rhsValue) { const ValueType * const vt1 = tok->astOperand1() ? tok->astOperand1()->valueType() : nullptr; const ValueType * const vt2 = tok->astOperand2() ? tok->astOperand2()->valueType() : nullptr; if (vt1 && vt1->pointer == 0 && vt1->isIntegral()) rhsValue = getValueRangeFromValueType(data.getNewSymbolName(), vt1, *data.settings); else if (vt2 && vt2->container && vt2->container->stdStringLike) { auto size = std::make_shared(data.getNewSymbolName(), 0, ~0ULL); auto value = std::make_shared(data.getNewSymbolName(), -128, 127); rhsValue = std::make_shared(data.getNewSymbolName(), size, value, false, false, false); call(data.callbacks, tok->astOperand2(), rhsValue, &data); } } if (!rhsValue) throw BugHuntingException(tok, "Expression '" + tok->expressionString() + "'; Failed to evaluate RHS"); ExprEngine::ValuePtr assignValue; if (tok->str() == "=") assignValue = rhsValue; else { // "+=" => "+" std::string binop(tok->str()); binop = binop.substr(0, binop.size() - 1); ExprEngine::ValuePtr lhsValue = executeExpression(tok->astOperand1(), data); assignValue = simplifyValue(std::make_shared(binop, lhsValue, rhsValue)); } const Token *lhsToken = tok->astOperand1(); assignValue = truncateValue(assignValue, lhsToken->valueType(), data); call(data.callbacks, tok, assignValue, &data); if (lhsToken->varId() > 0) { data.assignValue(lhsToken, lhsToken->varId(), assignValue); } else if (lhsToken->str() == "[") { const Token *tok2 = lhsToken; while (Token::simpleMatch(tok2->astOperand1(), "[")) tok2 = tok2->astOperand1(); auto arrayValue = data.getArrayValue(tok2->astOperand1()); if (arrayValue) { // Is it array initialization? const Token *arrayInit = tok2->astOperand1(); if (arrayInit && arrayInit->variable() && arrayInit->variable()->nameToken() == arrayInit) { if (assignValue->type == ExprEngine::ValueType::StringLiteralValue) arrayValue->assign(ExprEngine::ValuePtr(), assignValue); } else { auto indexValue = calculateArrayIndex(lhsToken, data, *arrayValue); arrayValue->assign(indexValue, assignValue); } } } else if (lhsToken->isUnaryOp("*")) { auto pval = executeExpression(lhsToken->astOperand1(), data); if (pval && pval->type == ExprEngine::ValueType::AddressOfValue) { auto val = std::dynamic_pointer_cast(pval); if (val) data.assignValue(lhsToken, val->varId, assignValue); } else if (pval && pval->type == ExprEngine::ValueType::BinOpResult) { auto b = std::dynamic_pointer_cast(pval); if (b && b->binop == "+") { std::shared_ptr arr; ExprEngine::ValuePtr offset; if (b->op1->type == ExprEngine::ValueType::ArrayValue) { arr = std::dynamic_pointer_cast(b->op1); offset = b->op2; } else { arr = std::dynamic_pointer_cast(b->op2); offset = b->op1; } if (arr && offset) { arr->assign(offset, assignValue); } } } } else if (Token::Match(lhsToken, ". %name%")) { auto structVal = executeExpression(lhsToken->astOperand1(), data); if (structVal && structVal->type == ExprEngine::ValueType::StructValue) data.assignStructMember(tok, &*std::static_pointer_cast(structVal), lhsToken->strAt(1), assignValue); } return assignValue; } static ExprEngine::ValuePtr executeIncDec(const Token *tok, Data &data) { ExprEngine::ValuePtr beforeValue = executeExpression(tok->astOperand1(), data); ExprEngine::ValuePtr assignValue = simplifyValue(std::make_shared(tok->str().substr(0,1), beforeValue, std::make_shared("1", 1, 1))); if (tok->astOperand1()->varId() > 0) data.assignValue(tok->astOperand1(), tok->astOperand1()->varId(), assignValue); else throw BugHuntingException(tok, "Unhandled increment/decrement operand"); return (precedes(tok, tok->astOperand1())) ? assignValue : beforeValue; } #ifdef USE_Z3 static void checkContract(Data &data, const Token *tok, const Function *function, const std::vector &argValues) { ExprData exprData; z3::solver solver(exprData.context); try { // Invert contract, we want to know if the contract might not be met solver.add(z3::ite(exprData.getConstraintExpr(data.executeContract(function, executeExpression1)), exprData.context.bool_val(false), exprData.context.bool_val(true))); bool bailoutValue = false; for (nonneg int i = 0; i < argValues.size(); ++i) { const Variable *argvar = function->getArgumentVar(i); if (!argvar || !argvar->nameToken()) continue; ExprEngine::ValuePtr argValue = argValues[i]; if (!argValue || argValue->type == ExprEngine::ValueType::BailoutValue) { bailoutValue = true; break; } if (argValue && argValue->type == ExprEngine::ValueType::IntRange) { solver.add(exprData.getExpr(data.getValue(argvar->declarationId(), nullptr, nullptr)) == exprData.getExpr(argValue)); } } if (!bailoutValue) { for (auto constraint : data.constraints) solver.add(exprData.getConstraintExpr(constraint)); exprData.addAssertions(solver); // Log solver expressions for debugging/testing purposes std::ostringstream os; os << solver; data.trackCheckContract(tok, os.str()); } if (bailoutValue || solver.check() == z3::sat) { const char id[] = "bughuntingFunctionCall"; const auto contractIt = data.settings->functionContracts.find(function->fullName()); const std::string functionName = contractIt->first; const std::string functionExpects = contractIt->second; data.reportError(tok, Severity::SeverityType::error, id, "Function '" + function->name() + "' is called, can not determine that its contract '" + functionExpects + "' is always met.", CWE(0), false, bailoutValue, functionName); } } catch (const z3::exception &exception) { std::cerr << "z3: " << exception << std::endl; } catch (const BugHuntingException &e) { const char id[] = "internalErrorInExprEngine"; const auto contractIt = data.settings->functionContracts.find(function->fullName()); const std::string functionName = contractIt->first; const std::string functionExpects = contractIt->second; data.reportError(tok, Severity::SeverityType::error, id, "Function '" + function->name() + "' is called, can not determine that its contract '" + functionExpects + "' is always met.", CWE(0), false, true, functionName); } } #endif static ExprEngine::ValuePtr executeFunctionCall(const Token *tok, Data &data) { if (Token::simpleMatch(tok->previous(), "sizeof (")) { ExprEngine::ValuePtr retVal; if (tok->hasKnownIntValue()) { const MathLib::bigint value = tok->getKnownIntValue(); retVal = std::make_shared(std::to_string(value), value, value); } else { retVal = std::make_shared(data.getNewSymbolName(), 1, 0x7fffffff); } call(data.callbacks, tok, retVal, &data); return retVal; } std::vector argValues; for (const Token *argtok : getArguments(tok)) { auto val = executeExpression1(argtok, data); argValues.push_back(val); if (!argtok->valueType() || (argtok->valueType()->constness & 1) == 1) continue; if (auto arrayValue = std::dynamic_pointer_cast(val)) { ValueType vt(*argtok->valueType()); vt.pointer = 0; auto anyVal = getValueRangeFromValueType(data.getNewSymbolName(), &vt, *data.settings); arrayValue->assign(ExprEngine::ValuePtr(), anyVal); } else if (auto addressOf = std::dynamic_pointer_cast(val)) { ValueType vt(*argtok->valueType()); vt.pointer = 0; if (vt.isIntegral() && argtok->valueType()->pointer == 1) data.assignValue(argtok, addressOf->varId, getValueRangeFromValueType(data.getNewSymbolName(), &vt, *data.settings)); } } if (tok->astOperand1()->function()) { const Function *function = tok->astOperand1()->function(); const std::string &functionName = function->fullName(); const auto contractIt = data.settings->functionContracts.find(functionName); if (contractIt != data.settings->functionContracts.end()) { #ifdef USE_Z3 checkContract(data, tok, function, argValues); #endif } else if (!argValues.empty()) { bool bailout = false; for (const auto v: argValues) bailout |= (v && v->type == ExprEngine::ValueType::BailoutValue); if (!bailout) data.addMissingContract(functionName); } // Execute subfunction.. if (function->hasBody()) { const Scope *functionScope = function->functionScope; int argnr = 0; for (const Variable &arg: function->argumentList) { if (argnr < argValues.size()) data.assignValue(function->functionScope->bodyStart, arg.declarationId(), argValues[argnr]); // TODO default values! argnr++; } data.contractConstraints(function, executeExpression1); data.errorPath.push_back(ErrorPathItem(tok, "Calling " + function->name())); try { execute(functionScope->bodyStart, functionScope->bodyEnd, data); } catch (BugHuntingException &e) { e.tok = tok; throw e; } data.errorPath.pop_back(); } } auto val = getValueRangeFromValueType(data.getNewSymbolName(), tok->valueType(), *data.settings); call(data.callbacks, tok, val, &data); data.functionCall(); return val; } static ExprEngine::ValuePtr executeArrayIndex(const Token *tok, Data &data) { const Token *tok2 = tok; while (Token::simpleMatch(tok2->astOperand1(), "[")) tok2 = tok2->astOperand1(); auto arrayValue = data.getArrayValue(tok2->astOperand1()); if (arrayValue) { auto indexValue = calculateArrayIndex(tok, data, *arrayValue); auto conditionalValues = arrayValue->read(indexValue); for (auto value: conditionalValues) call(data.callbacks, tok, value.second, &data); if (conditionalValues.size() == 1 && !conditionalValues[0].first) return conditionalValues[0].second; return std::make_shared(data.getNewSymbolName(), conditionalValues); } // TODO: Pointer value.. executeExpression(tok->astOperand1(), data); executeExpression(tok->astOperand2(), data); return ExprEngine::ValuePtr(); } static ExprEngine::ValuePtr executeCast(const Token *tok, Data &data) { const Token *expr = tok->astOperand2() ? tok->astOperand2() : tok->astOperand1(); auto val = executeExpression(expr, data); if (expr->valueType() && expr->valueType()->type == ::ValueType::Type::VOID && expr->valueType()->pointer > 0) { if (!tok->valueType() || expr->valueType()->pointer < tok->valueType()->pointer) return std::make_shared(); ::ValueType vt(*tok->valueType()); vt.pointer = 0; auto range = getValueRangeFromValueType(data.getNewSymbolName(), &vt, *data.settings); if (tok->valueType()->pointer == 0) return range; bool uninitPointer = false, nullPointer = false; if (val && val->type == ExprEngine::ValueType::ArrayValue) { nullPointer = std::static_pointer_cast(val)->nullPointer; uninitPointer = std::static_pointer_cast(val)->uninitPointer; } auto bufferSize = std::make_shared(data.getNewSymbolName(), 1, ~0UL); return std::make_shared(data.getNewSymbolName(), bufferSize, range, true, nullPointer, uninitPointer); } if (val) { // TODO: Cast this.. call(data.callbacks, tok, val, &data); return val; } val = getValueRangeFromValueType(data.getNewSymbolName(), tok->valueType(), *data.settings); call(data.callbacks, tok, val, &data); return val; } static ExprEngine::ValuePtr executeDot(const Token *tok, Data &data) { if (!tok->astOperand1() || !tok->astOperand1()->varId()) { auto v = getValueRangeFromValueType(data.getNewSymbolName(), tok->valueType(), *data.settings); call(data.callbacks, tok, v, &data); return v; } std::shared_ptr structValue = std::dynamic_pointer_cast(data.getValue(tok->astOperand1()->varId(), nullptr, nullptr)); if (!structValue) { if (tok->originalName() == "->") { std::shared_ptr pointerValue = std::dynamic_pointer_cast(data.getValue(tok->astOperand1()->varId(), nullptr, nullptr)); if (pointerValue && pointerValue->pointer && !pointerValue->data.empty()) { call(data.callbacks, tok->astOperand1(), pointerValue, &data); auto indexValue = std::make_shared("0", 0, 0); ExprEngine::ValuePtr ret; for (auto val: pointerValue->read(indexValue)) { structValue = std::dynamic_pointer_cast(val.second); if (structValue) { auto memberValue = structValue->getValueOfMember(tok->astOperand2()->str()); call(data.callbacks, tok, memberValue, &data); if (!ret) ret = memberValue; } } return ret; } else { call(data.callbacks, tok->astOperand1(), data.getValue(tok->astOperand1()->varId(), nullptr, nullptr), &data); } } if (!structValue) { auto v = getValueRangeFromValueType(data.getNewSymbolName(), tok->valueType(), *data.settings); if (!v) v = std::make_shared(); call(data.callbacks, tok, v, &data); return v; } } call(data.callbacks, tok->astOperand1(), structValue, &data); ExprEngine::ValuePtr memberValue = structValue->getValueOfMember(tok->astOperand2()->str()); call(data.callbacks, tok, memberValue, &data); return memberValue; } static ExprEngine::ValuePtr executeBinaryOp(const Token *tok, Data &data) { ExprEngine::ValuePtr v1 = executeExpression(tok->astOperand1(), data); ExprEngine::ValuePtr v2; if (tok->str() == "?") { if (tok->astOperand1()->hasKnownIntValue()) { if (tok->astOperand1()->getKnownIntValue()) v2 = executeExpression(tok->astOperand2()->astOperand1(), data); else v2 = executeExpression(tok->astOperand2()->astOperand2(), data); call(data.callbacks, tok, v2, &data); return v2; } Data trueData(data); trueData.addConstraint(v1, true); auto trueValue = simplifyValue(executeExpression(tok->astOperand2()->astOperand1(), trueData)); Data falseData(data); falseData.addConstraint(v1, false); auto falseValue = simplifyValue(executeExpression(tok->astOperand2()->astOperand2(), falseData)); auto result = simplifyValue(std::make_shared("?", v1, std::make_shared(":", trueValue, falseValue))); call(data.callbacks, tok, result, &data); return result; } else if (tok->str() == "&&" || tok->str() == "||") { Data data2(data); data2.addConstraint(v1, tok->str() == "&&"); v2 = executeExpression(tok->astOperand2(), data2); } else { v2 = executeExpression(tok->astOperand2(), data); } if (v1 && v2) { auto result = simplifyValue(std::make_shared(tok->str(), v1, v2)); call(data.callbacks, tok, result, &data); return result; } if (tok->str() == "&&" && (v1 || v2)) { auto result = v1 ? v1 : v2; call(data.callbacks, tok, result, &data); return result; } return ExprEngine::ValuePtr(); } static ExprEngine::ValuePtr executeAddressOf(const Token *tok, Data &data) { auto addr = std::make_shared(data.getNewSymbolName(), tok->astOperand1()->varId()); call(data.callbacks, tok, addr, &data); return addr; } static ExprEngine::ValuePtr executeDeref(const Token *tok, Data &data) { ExprEngine::ValuePtr pval = executeExpression(tok->astOperand1(), data); if (!pval) { auto v = getValueRangeFromValueType(data.getNewSymbolName(), tok->valueType(), *data.settings); if (tok->astOperand1()->varId()) { pval = std::make_shared(data.getNewSymbolName(), ExprEngine::ValuePtr(), v, true, false, false); data.assignValue(tok->astOperand1(), tok->astOperand1()->varId(), pval); } call(data.callbacks, tok, v, &data); return v; } auto addressOf = std::dynamic_pointer_cast(pval); if (addressOf) { auto val = data.getValue(addressOf->varId, tok->valueType(), tok); call(data.callbacks, tok, val, &data); return val; } auto pointer = std::dynamic_pointer_cast(pval); if (pointer) { auto indexValue = std::make_shared("0", 0, 0); auto conditionalValues = pointer->read(indexValue); for (auto value: conditionalValues) call(data.callbacks, tok, value.second, &data); if (conditionalValues.size() == 1 && !conditionalValues[0].first) return conditionalValues[0].second; return std::make_shared(data.getNewSymbolName(), conditionalValues); } return ExprEngine::ValuePtr(); } static ExprEngine::ValuePtr executeVariable(const Token *tok, Data &data) { auto val = data.getValue(tok->varId(), tok->valueType(), tok); call(data.callbacks, tok, val, &data); return val; } static ExprEngine::ValuePtr executeKnownMacro(const Token *tok, Data &data) { auto val = std::make_shared(data.getNewSymbolName(), tok->getKnownIntValue(), tok->getKnownIntValue()); call(data.callbacks, tok, val, &data); return val; } static ExprEngine::ValuePtr executeNumber(const Token *tok, Data &data) { if (tok->valueType()->isFloat()) { long double value = MathLib::toDoubleNumber(tok->str()); auto v = std::make_shared(tok->str(), value, value); call(data.callbacks, tok, v, &data); return v; } int128_t value = MathLib::toLongNumber(tok->str()); auto v = std::make_shared(tok->str(), value, value); call(data.callbacks, tok, v, &data); return v; } static ExprEngine::ValuePtr executeStringLiteral(const Token *tok, Data &data) { std::string s = tok->str(); return std::make_shared(data.getNewSymbolName(), s.substr(1, s.size()-2)); } static ExprEngine::ValuePtr executeExpression1(const Token *tok, Data &data) { if (tok->str() == "return") return executeReturn(tok, data); if (tok->isAssignmentOp()) // TODO: Handle more operators return executeAssign(tok, data); if (tok->tokType() == Token::Type::eIncDecOp) return executeIncDec(tok, data); if (tok->astOperand1() && tok->astOperand2() && tok->str() == "[") return executeArrayIndex(tok, data); if (tok->str() == "(") { if (!tok->isCast()) return executeFunctionCall(tok, data); return executeCast(tok, data); } if (tok->str() == ".") return executeDot(tok, data); if (tok->str() == "::" && tok->hasKnownIntValue()) { // TODO handle :: better auto v = tok->getKnownIntValue(); return std::make_shared(std::to_string(v), v, v); } if (tok->astOperand1() && tok->astOperand2()) return executeBinaryOp(tok, data); if (tok->isUnaryOp("&") && Token::Match(tok->astOperand1(), "%var%")) return executeAddressOf(tok, data); if (tok->isUnaryOp("*")) return executeDeref(tok, data); if (tok->varId()) return executeVariable(tok, data); if (tok->isName() && tok->hasKnownIntValue()) return executeKnownMacro(tok, data); if (tok->isNumber() || tok->tokType() == Token::Type::eChar) return executeNumber(tok, data); if (tok->tokType() == Token::Type::eString) return executeStringLiteral(tok, data); return ExprEngine::ValuePtr(); } static ExprEngine::ValuePtr executeExpression(const Token *tok, Data &data) { return translateUninitValueToRange(executeExpression1(tok, data), tok->valueType(), data); } static ExprEngine::ValuePtr createVariableValue(const Variable &var, Data &data); static void execute(const Token *start, const Token *end, Data &data) { if (data.recursion > 20) // FIXME return; // Update data.recursion struct Recursion { Recursion(int *var, int value) : var(var), value(value) { *var = value + 1; } ~Recursion() { if (*var >= value) *var = value; } int *var; int value; }; Recursion updateRecursion(&data.recursion, data.recursion); for (const Token *tok = start; tok != end; tok = tok->next()) { if (Token::Match(tok, "[;{}]")) data.trackProgramState(tok); if (Token::simpleMatch(tok, "while (") && (tok->linkAt(1), ") ;") && tok->next()->astOperand1()->hasKnownIntValue() && tok->next()->astOperand1()->getKnownIntValue() == 0) { tok = tok->tokAt(4); continue; } if (tok->str() == "break") { const Scope *scope = tok->scope(); while (scope->type == Scope::eIf || scope->type == Scope::eElse) scope = scope->nestedIn; tok = scope->bodyEnd; if (!precedes(tok,end)) return; } if (Token::simpleMatch(tok, "try")) // TODO this is a bailout throw BugHuntingException(tok, "Unhandled:" + tok->str()); // Variable declaration.. if (tok->variable() && tok->variable()->nameToken() == tok) { if (Token::Match(tok, "%varid% ; %varid% =", tok->varId())) { // if variable is not used in assignment rhs then we do not need to create a "confusing" variable value.. bool foundInRhs = false; visitAstNodes(tok->tokAt(3)->astOperand2(), [&](const Token *rhs) { if (rhs->varId()==tok->varId()) { foundInRhs = true; return ChildrenToVisit::done; } return ChildrenToVisit::op1_and_op2; }); if (!foundInRhs) { tok = tok->tokAt(2); continue; } data.assignValue(tok, tok->varId(), createVariableValue(*tok->variable(), data)); } else if (tok->variable()->isArray()) { data.assignValue(tok, tok->varId(), std::make_shared(&data, tok->variable())); if (Token::Match(tok, "%name% [")) tok = tok->linkAt(1); } else if (Token::Match(tok, "%var% ;")) data.assignValue(tok, tok->varId(), createVariableValue(*tok->variable(), data)); } else if (!tok->astParent() && (tok->astOperand1() || tok->astOperand2())) { executeExpression(tok, data); if (Token::Match(tok, "throw|return")) return; } else if (Token::simpleMatch(tok, "if (")) { const Token *cond = tok->next()->astOperand2(); // TODO: C++17 condition const ExprEngine::ValuePtr condValue = executeExpression(cond, data); Data thenData(data); Data elseData(data); thenData.addConstraint(condValue, true); elseData.addConstraint(condValue, false); const Token *thenStart = tok->linkAt(1)->next(); const Token *thenEnd = thenStart->link(); const Token *exceptionToken = nullptr; std::string exceptionMessage; auto exec = [&](const Token *tok1, const Token *tok2, Data& data) { try { execute(tok1, tok2, data); } catch (BugHuntingException &e) { if (!exceptionToken || (e.tok && precedes(e.tok, exceptionToken))) { exceptionToken = e.tok; exceptionMessage = e.what; } } }; exec(thenStart->next(), end, thenData); if (Token::simpleMatch(thenEnd, "} else {")) { const Token *elseStart = thenEnd->tokAt(2); exec(elseStart->next(), end, elseData); } else { exec(thenEnd, end, elseData); } if (exceptionToken) throw BugHuntingException(exceptionToken, exceptionMessage); return; } else if (Token::simpleMatch(tok, "switch (")) { auto condValue = executeExpression(tok->next()->astOperand2(), data); // TODO: C++17 condition const Token *bodyStart = tok->linkAt(1)->next(); const Token *bodyEnd = bodyStart->link(); const Token *defaultStart = nullptr; Data defaultData(data); const Token *exceptionToken = nullptr; std::string exceptionMessage; auto exec = [&](const Token *tok1, const Token *tok2, Data& data) { try { execute(tok1, tok2, data); } catch (BugHuntingException &e) { if (!exceptionToken || (e.tok && precedes(e.tok, exceptionToken))) { exceptionToken = e.tok; exceptionMessage = e.what; } } }; for (const Token *tok2 = bodyStart->next(); tok2 != bodyEnd; tok2 = tok2->next()) { if (tok2->str() == "{") tok2 = tok2->link(); else if (Token::Match(tok2, "case %char%|%num% :")) { const MathLib::bigint caseValue1 = tok2->next()->getKnownIntValue(); auto caseValue = std::make_shared(MathLib::toString(caseValue1), caseValue1, caseValue1); Data caseData(data); caseData.addConstraint(condValue, caseValue, true); defaultData.addConstraint(condValue, caseValue, false); exec(tok2->tokAt(2), end, caseData); } else if (Token::Match(tok2, "case %name% :") && !Token::Match(tok2->tokAt(3), ";| case")) { Data caseData(data); exec(tok2->tokAt(2), end, caseData); } else if (Token::simpleMatch(tok2, "default :")) defaultStart = tok2; } exec(defaultStart ? defaultStart : bodyEnd, end, defaultData); if (exceptionToken) throw BugHuntingException(exceptionToken, exceptionMessage); return; } if (Token::Match(tok, "for|while (") && Token::simpleMatch(tok->linkAt(1), ") {")) { const Token *bodyStart = tok->linkAt(1)->next(); const Token *bodyEnd = bodyStart->link(); // TODO this is very rough code std::set changedVariables; for (const Token *tok2 = tok; tok2 != bodyEnd; tok2 = tok2->next()) { if (Token::Match(tok2, "%assign%")) { const Token *lhs = tok2->astOperand1(); while (Token::simpleMatch(lhs, "[")) lhs = lhs->astOperand1(); if (!lhs) throw BugHuntingException(tok2, "Unhandled assignment in loop"); if (Token::Match(lhs, ". %name% =|[") && lhs->astOperand1() && lhs->astOperand1()->valueType()) { const Token *structToken = lhs->astOperand1(); if (!structToken->valueType() || !structToken->varId()) throw BugHuntingException(tok2, "Unhandled assignment in loop"); const Scope *structScope = structToken->valueType()->typeScope; if (!structScope) throw BugHuntingException(tok2, "Unhandled assignment in loop"); const std::string &memberName = tok2->previous()->str(); ExprEngine::ValuePtr memberValue; for (const Variable &member : structScope->varlist) { if (memberName == member.name() && member.valueType()) { memberValue = createVariableValue(member, data); break; } } if (!memberValue) throw BugHuntingException(tok2, "Unhandled assignment in loop"); ExprEngine::ValuePtr structVal1 = data.getValue(structToken->varId(), structToken->valueType(), structToken); if (!structVal1) structVal1 = createVariableValue(*structToken->variable(), data); auto structVal = std::dynamic_pointer_cast(structVal1); if (!structVal) throw BugHuntingException(tok2, "Unhandled assignment in loop"); data.assignStructMember(tok2, &*structVal, memberName, memberValue); continue; } if (lhs->isUnaryOp("*") && lhs->astOperand1()->varId()) { const Token *varToken = tok2->astOperand1()->astOperand1(); ExprEngine::ValuePtr val = data.getValue(varToken->varId(), varToken->valueType(), varToken); if (val && val->type == ExprEngine::ValueType::ArrayValue) { // Try to assign "any" value auto arrayValue = std::dynamic_pointer_cast(val); arrayValue->assign(std::make_shared("0", 0, 0), std::make_shared()); continue; } } if (!lhs->variable()) throw BugHuntingException(tok2, "Unhandled assignment in loop"); // give variable "any" value int varid = lhs->varId(); if (changedVariables.find(varid) != changedVariables.end()) continue; changedVariables.insert(varid); auto oldValue = data.getValue(varid, nullptr, nullptr); if (oldValue && oldValue->isUninit()) call(data.callbacks, lhs, oldValue, &data); if (oldValue && oldValue->type == ExprEngine::ValueType::ArrayValue) { // Try to assign "any" value auto arrayValue = std::dynamic_pointer_cast(oldValue); arrayValue->assign(std::make_shared(data.getNewSymbolName(), 0, ~0ULL), std::make_shared()); continue; } data.assignValue(tok2, varid, getValueRangeFromValueType(data.getNewSymbolName(), lhs->valueType(), *data.settings)); continue; } else if (Token::Match(tok2, "++|--") && tok2->astOperand1() && tok2->astOperand1()->variable()) { // give variable "any" value const Token *vartok = tok2->astOperand1(); int varid = vartok->varId(); if (changedVariables.find(varid) != changedVariables.end()) continue; changedVariables.insert(varid); auto oldValue = data.getValue(varid, nullptr, nullptr); if (oldValue && oldValue->type == ExprEngine::ValueType::UninitValue) call(data.callbacks, tok2, oldValue, &data); data.assignValue(tok2, varid, getValueRangeFromValueType(data.getNewSymbolName(), vartok->valueType(), *data.settings)); } } } if (Token::simpleMatch(tok, "} else {")) tok = tok->linkAt(2); } } void ExprEngine::executeAllFunctions(ErrorLogger *errorLogger, const Tokenizer *tokenizer, const Settings *settings, const std::vector &callbacks, std::ostream &report) { const SymbolDatabase *symbolDatabase = tokenizer->getSymbolDatabase(); for (const Scope *functionScope : symbolDatabase->functionScopes) { try { executeFunction(functionScope, errorLogger, tokenizer, settings, callbacks, report); } catch (const BugHuntingException &e) { // FIXME.. there should not be exceptions std::string functionName = functionScope->function->name(); std::cout << "Verify: Aborted analysis of function '" << functionName << "':" << e.tok->linenr() << ": " << e.what << std::endl; } catch (const std::exception &e) { // FIXME.. there should not be exceptions std::string functionName = functionScope->function->name(); std::cout << "Verify: Aborted analysis of function '" << functionName << "': " << e.what() << std::endl; } } } static ExprEngine::ValuePtr createStructVal(const Scope *structScope, bool uninitData, Data &data) { if (!structScope) return ExprEngine::ValuePtr(); std::shared_ptr structValue = std::make_shared(data.getNewSymbolName()); auto uninitValue = std::make_shared(); for (const Variable &member : structScope->varlist) { if (uninitData) { if (member.isPointer()) { structValue->member[member.name()] = uninitValue; continue; } if (member.valueType() && member.valueType()->type >= ::ValueType::Type::CHAR) { structValue->member[member.name()] = uninitValue; continue; } } if (member.valueType() && member.valueType()->isIntegral()) { ExprEngine::ValuePtr memberValue = createVariableValue(member, data); if (memberValue) structValue->member[member.name()] = memberValue; } } return structValue; } static ExprEngine::ValuePtr createVariableValue(const Variable &var, Data &data) { if (!var.nameToken()) return ExprEngine::ValuePtr(); const ValueType *valueType = var.valueType(); if (!valueType || valueType->type == ValueType::Type::UNKNOWN_TYPE) valueType = var.nameToken()->valueType(); if (!valueType || valueType->type == ValueType::Type::UNKNOWN_TYPE) { // variable with unknown type if (var.isLocal() && var.isPointer() && !var.isArray()) return std::make_shared(); return ExprEngine::ValuePtr(); } if (valueType->pointer > 0) { if (var.isLocal()) return std::make_shared(); auto bufferSize = std::make_shared(data.getNewSymbolName(), 1, ~0UL); ExprEngine::ValuePtr pointerValue; if (valueType->type == ValueType::Type::RECORD) pointerValue = createStructVal(valueType->typeScope, var.isLocal() && !var.isStatic(), data); else { ValueType vt(*valueType); vt.pointer = 0; if (vt.constness & 1) pointerValue = getValueRangeFromValueType(data.getNewSymbolName(), &vt, *data.settings); else pointerValue = std::make_shared(); } return std::make_shared(data.getNewSymbolName(), bufferSize, pointerValue, true, true, var.isLocal() && !var.isStatic()); } if (var.isArray()) return std::make_shared(&data, &var); if (valueType->isIntegral() || valueType->isFloat()) { ExprEngine::ValuePtr value; if (var.isLocal() && !var.isStatic()) value = std::make_shared(); else value = getValueRangeFromValueType(data.getNewSymbolName(), valueType, *data.settings); data.addConstraints(value, var.nameToken()); return value; } if (valueType->type == ValueType::Type::RECORD) return createStructVal(valueType->typeScope, var.isLocal() && !var.isStatic(), data); if (valueType->smartPointerType) { auto structValue = createStructVal(valueType->smartPointerType->classScope, var.isLocal() && !var.isStatic(), data); auto size = std::make_shared(data.getNewSymbolName(), 1, ~0UL); return std::make_shared(data.getNewSymbolName(), size, structValue, true, true, false); } if (valueType->container) { ExprEngine::ValuePtr value; if (valueType->container->stdStringLike) value = std::make_shared(data.getNewSymbolName(), -128, 127); else if (valueType->containerTypeToken) { ValueType vt = ValueType::parseDecl(valueType->containerTypeToken, data.settings); value = getValueRangeFromValueType(data.getNewSymbolName(), &vt, *data.settings); } else return ExprEngine::ValuePtr(); auto bufferSize = std::make_shared(data.getNewSymbolName(), 0, ~0U); return std::make_shared(data.getNewSymbolName(), bufferSize, value, false, false, false); } return ExprEngine::ValuePtr(); } void ExprEngine::executeFunction(const Scope *functionScope, ErrorLogger *errorLogger, const Tokenizer *tokenizer, const Settings *settings, const std::vector &callbacks, std::ostream &report) { if (!functionScope->bodyStart) return; const Function *function = functionScope->function; if (!function) return; if (functionScope->bodyStart->fileIndex() > 0) // TODO.. what about functions in headers? return; const std::string currentFunction = function->fullName(); int symbolValueIndex = 0; TrackExecution trackExecution; Data data(&symbolValueIndex, errorLogger, tokenizer, settings, currentFunction, callbacks, &trackExecution); for (const Variable &arg : function->argumentList) data.assignValue(functionScope->bodyStart, arg.declarationId(), createVariableValue(arg, data)); data.contractConstraints(function, executeExpression1); try { execute(functionScope->bodyStart, functionScope->bodyEnd, data); } catch (BugHuntingException &e) { if (settings->debugBugHunting) report << "BugHuntingException tok.line:" << e.tok->linenr() << " what:" << e.what << "\n"; trackExecution.setAbortLine(e.tok->linenr()); auto bailoutValue = std::make_shared(); for (const Token *tok = e.tok; tok != functionScope->bodyEnd; tok = tok->next()) { if (Token::Match(tok, "return|throw|while|if|for (")) { tok = tok->next(); continue; } call(callbacks, tok, bailoutValue, &data); } } const bool bugHuntingReport = !settings->bugHuntingReport.empty(); if (settings->debugBugHunting && (settings->verbose || callbacks.empty() || !trackExecution.isAllOk())) { if (bugHuntingReport) report << "[debug]" << std::endl; trackExecution.print(report); if (!callbacks.empty()) { if (bugHuntingReport) report << "[details]" << std::endl; trackExecution.report(report, functionScope); } } // Write a report if (bugHuntingReport) { for (const std::string &f: trackExecution.getMissingContracts()) report << "[missing contract] " << f << std::endl; } } void ExprEngine::runChecks(ErrorLogger *errorLogger, const Tokenizer *tokenizer, const Settings *settings) { std::vector callbacks; addBughuntingChecks(&callbacks); std::ostringstream report; ExprEngine::executeAllFunctions(errorLogger, tokenizer, settings, callbacks, report); if (settings->bugHuntingReport.empty()) std::cout << report.str(); else if (errorLogger) errorLogger->bughuntingReport(report.str()); } static void dumpRecursive(ExprEngine::ValuePtr val) { if (!val) { std::cout << "NULL"; return; } switch (val->type) { case ExprEngine::ValueType::AddressOfValue: std::cout << "AddressOfValue(" << std::dynamic_pointer_cast(val)->varId << ")"; break; case ExprEngine::ValueType::ArrayValue: std::cout << "ArrayValue"; break; case ExprEngine::ValueType::BailoutValue: std::cout << "BailoutValue"; break; case ExprEngine::ValueType::BinOpResult: { auto b = std::dynamic_pointer_cast(val); std::cout << "("; dumpRecursive(b->op1); std::cout << " " << b->binop << " "; dumpRecursive(b->op2); std::cout << ")"; } break; case ExprEngine::ValueType::ConditionalValue: std::cout << "ConditionalValue"; break; case ExprEngine::ValueType::FloatRange: std::cout << "FloatRange"; break; case ExprEngine::ValueType::IntRange: std::cout << "IntRange"; break; case ExprEngine::ValueType::IntegerTruncation: std::cout << "IntegerTruncation("; dumpRecursive(std::dynamic_pointer_cast(val)->inputValue); std::cout << ")"; break; case ExprEngine::ValueType::StringLiteralValue: std::cout << "StringLiteralValue"; break; case ExprEngine::ValueType::StructValue: std::cout << "StructValue"; break; case ExprEngine::ValueType::UninitValue: std::cout << "UninitValue"; break; } } void ExprEngine::dump(ExprEngine::ValuePtr val) { dumpRecursive(val); std::cout << "\n"; }