/* * Cppcheck - A tool for static C/C++ code analysis * Copyright (C) 2007-2019 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 . */ //--------------------------------------------------------------------------- // Buffer overrun.. //--------------------------------------------------------------------------- #include "checkbufferoverrun.h" #include "astutils.h" #include "library.h" #include "mathlib.h" #include "settings.h" #include "symboldatabase.h" #include "token.h" #include "tokenize.h" #include "tokenlist.h" #include "utils.h" #include "valueflow.h" #include #include #include #include // std::accumulate #include #include #include //--------------------------------------------------------------------------- // Register this check class (by creating a static instance of it) namespace { CheckBufferOverrun instance; } //--------------------------------------------------------------------------- // CWE ids used: static const CWE CWE131(131U); // Incorrect Calculation of Buffer Size static const CWE CWE170(170U); // Improper Null Termination static const CWE CWE_ARRAY_INDEX_THEN_CHECK(398U); // Indicator of Poor Code Quality static const CWE CWE682(682U); // Incorrect Calculation static const CWE CWE758(758U); // Reliance on Undefined, Unspecified, or Implementation-Defined Behavior static const CWE CWE_POINTER_ARITHMETIC_OVERFLOW(758U); // Reliance on Undefined, Unspecified, or Implementation-Defined Behavior static const CWE CWE_BUFFER_UNDERRUN(786U); // Access of Memory Location Before Start of Buffer static const CWE CWE_BUFFER_OVERRUN(788U); // Access of Memory Location After End of Buffer //--------------------------------------------------------------------------- static const ValueFlow::Value *getBufferSizeValue(const Token *tok) { const std::list &tokenValues = tok->values(); const auto it = std::find_if(tokenValues.begin(), tokenValues.end(), std::mem_fn(&ValueFlow::Value::isBufferSizeValue)); return it == tokenValues.end() ? nullptr : &*it; } static int getMinFormatStringOutputLength(const std::vector ¶meters, nonneg int formatStringArgNr) { if (formatStringArgNr <= 0 || formatStringArgNr > parameters.size()) return 0; if (parameters[formatStringArgNr - 1]->tokType() != Token::eString) return 0; const std::string &formatString = parameters[formatStringArgNr - 1]->str(); bool percentCharFound = false; int outputStringSize = 0; bool handleNextParameter = false; std::string digits_string; bool i_d_x_f_found = false; int parameterLength = 0; int inputArgNr = formatStringArgNr; for (int i = 1; i + 1 < formatString.length(); ++i) { if (formatString[i] == '\\') { if (i < formatString.length() - 1 && formatString[i + 1] == '0') break; ++outputStringSize; ++i; continue; } if (percentCharFound) { switch (formatString[i]) { case 'f': case 'x': case 'X': case 'i': i_d_x_f_found = true; handleNextParameter = true; parameterLength = 1; // TODO break; case 'c': case 'e': case 'E': case 'g': case 'o': case 'u': case 'p': case 'n': handleNextParameter = true; parameterLength = 1; // TODO break; case 'd': i_d_x_f_found = true; parameterLength = 1; if (inputArgNr < parameters.size() && parameters[inputArgNr]->hasKnownIntValue()) parameterLength = MathLib::toString(parameters[inputArgNr]->getKnownIntValue()).length(); handleNextParameter = true; break; case 's': parameterLength = 0; if (inputArgNr < parameters.size() && parameters[inputArgNr]->tokType() == Token::eString) parameterLength = Token::getStrLength(parameters[inputArgNr]); handleNextParameter = true; break; } } if (formatString[i] == '%') percentCharFound = !percentCharFound; else if (percentCharFound) { digits_string.append(1, formatString[i]); } if (!percentCharFound) outputStringSize++; if (handleNextParameter) { int tempDigits = std::abs(std::atoi(digits_string.c_str())); if (i_d_x_f_found) tempDigits = std::max(tempDigits, 1); if (digits_string.find('.') != std::string::npos) { const std::string endStr = digits_string.substr(digits_string.find('.') + 1); const int maxLen = std::max(std::abs(std::atoi(endStr.c_str())), 1); if (formatString[i] == 's') { // For strings, the length after the dot "%.2s" will limit // the length of the string. if (parameterLength > maxLen) parameterLength = maxLen; } else { // For integers, the length after the dot "%.2d" can // increase required length if (tempDigits < maxLen) tempDigits = maxLen; } } if (tempDigits < parameterLength) outputStringSize += parameterLength; else outputStringSize += tempDigits; parameterLength = 0; digits_string.clear(); i_d_x_f_found = false; percentCharFound = false; handleNextParameter = false; ++inputArgNr; } } return outputStringSize; } //--------------------------------------------------------------------------- static bool getDimensionsEtc(const Token * const arrayToken, const Settings *settings, std::vector * const dimensions, ErrorPath * const errorPath, bool * const mightBeLarger) { const Token *array = arrayToken; while (Token::Match(array, ".|::")) array = array->astOperand2(); if (array->variable() && array->variable()->isArray() && !array->variable()->dimensions().empty()) { *dimensions = array->variable()->dimensions(); if (dimensions->size() >= 1 && ((*dimensions)[0].num <= 1 || !(*dimensions)[0].tok)) { visitAstNodes(arrayToken, [&](const Token *child) { if (child->originalName() == "->") { *mightBeLarger = true; return ChildrenToVisit::none; } return ChildrenToVisit::op1_and_op2; }); } } else if (const Token *stringLiteral = array->getValueTokenMinStrSize(settings)) { Dimension dim; dim.tok = nullptr; dim.num = Token::getStrArraySize(stringLiteral); dim.known = array->hasKnownValue(); dimensions->emplace_back(dim); } else if (array->valueType() && array->valueType()->pointer >= 1 && array->valueType()->isIntegral()) { const ValueFlow::Value *value = getBufferSizeValue(array); if (!value) return false; *errorPath = value->errorPath; Dimension dim; dim.known = value->isKnown(); dim.tok = nullptr; int typeSize = array->valueType()->typeSize(*settings); if (typeSize == 0) return false; dim.num = value->intvalue / array->valueType()->typeSize(*settings); dimensions->emplace_back(dim); } return !dimensions->empty(); } static std::vector getOverrunIndexValues(const Token *tok, const Token *arrayToken, const std::vector &dimensions, const std::vector &indexTokens) { const Token *array = arrayToken; while (Token::Match(array, ".|::")) array = array->astOperand2(); for (int cond = 0; cond < 2; cond++) { bool equal = false; bool overflow = false; bool allKnown = true; std::vector indexValues; for (int i = 0; i < dimensions.size() && i < indexTokens.size(); ++i) { const ValueFlow::Value *value = indexTokens[i]->getMaxValue(cond == 1); indexValues.push_back(value); if (!value) continue; if (!value->isKnown()) { if (!allKnown) continue; allKnown = false; } if (array->variable() && array->variable()->isArray() && dimensions[i].num == 0) continue; if (value->intvalue == dimensions[i].num) equal = true; else if (value->intvalue > dimensions[i].num) overflow = true; } if (equal && tok->str() != "[") continue; if (!overflow && equal) { const Token *parent = tok; while (Token::simpleMatch(parent, "[")) parent = parent->astParent(); if (!parent || parent->isUnaryOp("&")) continue; } if (overflow || equal) return indexValues; } return std::vector(); } void CheckBufferOverrun::arrayIndex() { for (const Token *tok = mTokenizer->tokens(); tok; tok = tok->next()) { if (tok->str() != "[") continue; const Token *array = tok->astOperand1(); while (Token::Match(array, ".|::")) array = array->astOperand2(); if (!array || ((!array->variable() || array->variable()->nameToken() == array) && array->tokType() != Token::eString)) continue; if (!array->scope()->isExecutable()) { // LHS in non-executable scope => This is just a definition const Token *parent = tok; while (parent && !Token::simpleMatch(parent->astParent(), "=")) parent = parent->astParent(); if (!parent || parent == parent->astParent()->astOperand1()) continue; } if (astIsContainer(array)) continue; std::vector indexTokens; for (const Token *tok2 = tok; tok2 && tok2->str() == "["; tok2 = tok2->link()->next()) { if (!tok2->astOperand2()) { indexTokens.clear(); break; } indexTokens.emplace_back(tok2->astOperand2()); } if (indexTokens.empty()) continue; std::vector dimensions; ErrorPath errorPath; bool mightBeLarger = false; if (!getDimensionsEtc(tok->astOperand1(), mSettings, &dimensions, &errorPath, &mightBeLarger)) continue; // Positive index if (!mightBeLarger) { // TODO check arrays with dim 1 also const std::vector &indexValues = getOverrunIndexValues(tok, tok->astOperand1(), dimensions, indexTokens); if (!indexValues.empty()) arrayIndexError(tok, dimensions, indexValues); } // Negative index bool neg = false; std::vector negativeIndexes; for (const Token * indexToken : indexTokens) { const ValueFlow::Value *negativeValue = indexToken->getValueLE(-1, mSettings); negativeIndexes.emplace_back(negativeValue); if (negativeValue) neg = true; } if (neg) { negativeIndexError(tok, dimensions, negativeIndexes); } } } static std::string stringifyIndexes(const std::string &array, const std::vector &indexValues) { if (indexValues.size() == 1) return MathLib::toString(indexValues[0]->intvalue); std::ostringstream ret; ret << array; for (const ValueFlow::Value *index : indexValues) { ret << "["; if (index) ret << index->intvalue; else ret << "*"; ret << "]"; } return ret.str(); } static std::string arrayIndexMessage(const Token *tok, const std::vector &dimensions, const std::vector &indexValues, const Token *condition) { auto add_dim = [](const std::string &s, const Dimension &dim) { return s + "[" + MathLib::toString(dim.num) + "]"; }; const std::string array = std::accumulate(dimensions.begin(), dimensions.end(), tok->astOperand1()->expressionString(), add_dim); std::ostringstream errmsg; if (condition) errmsg << ValueFlow::eitherTheConditionIsRedundant(condition) << " or the array '" + array + "' is accessed at index " << stringifyIndexes(tok->astOperand1()->expressionString(), indexValues) << ", which is out of bounds."; else errmsg << "Array '" << array << "' accessed at index " << stringifyIndexes(tok->astOperand1()->expressionString(), indexValues) << ", which is out of bounds."; return errmsg.str(); } void CheckBufferOverrun::arrayIndexError(const Token *tok, const std::vector &dimensions, const std::vector &indexes) { if (!tok) { reportError(tok, Severity::error, "arrayIndexOutOfBounds", "Array 'arr[16]' accessed at index 16, which is out of bounds.", CWE_BUFFER_OVERRUN, false); reportError(tok, Severity::warning, "arrayIndexOutOfBoundsCond", "Array 'arr[16]' accessed at index 16, which is out of bounds.", CWE_BUFFER_OVERRUN, false); return; } const Token *condition = nullptr; const ValueFlow::Value *index = nullptr; for (const ValueFlow::Value *indexValue: indexes) { if (!indexValue) continue; if (!indexValue->errorSeverity() && !mSettings->isEnabled(Settings::WARNING)) return; if (indexValue->condition) condition = indexValue->condition; if (!index || !indexValue->errorPath.empty()) index = indexValue; } reportError(getErrorPath(tok, index, "Array index out of bounds"), index->errorSeverity() ? Severity::error : Severity::warning, index->condition ? "arrayIndexOutOfBoundsCond" : "arrayIndexOutOfBounds", arrayIndexMessage(tok, dimensions, indexes, condition), CWE_BUFFER_OVERRUN, index->isInconclusive()); } void CheckBufferOverrun::negativeIndexError(const Token *tok, const std::vector &dimensions, const std::vector &indexes) { if (!tok) { reportError(tok, Severity::error, "negativeIndex", "Negative array index", CWE_BUFFER_UNDERRUN, false); return; } const Token *condition = nullptr; const ValueFlow::Value *negativeValue = nullptr; for (const ValueFlow::Value *indexValue: indexes) { if (!indexValue) continue; if (!indexValue->errorSeverity() && !mSettings->isEnabled(Settings::WARNING)) return; if (indexValue->condition) condition = indexValue->condition; if (!negativeValue || !indexValue->errorPath.empty()) negativeValue = indexValue; } reportError(getErrorPath(tok, negativeValue, "Negative array index"), negativeValue->errorSeverity() ? Severity::error : Severity::warning, "negativeIndex", arrayIndexMessage(tok, dimensions, indexes, condition), CWE_BUFFER_UNDERRUN, negativeValue->isInconclusive()); } //--------------------------------------------------------------------------- void CheckBufferOverrun::pointerArithmetic() { if (!mSettings->isEnabled(Settings::PORTABILITY)) return; for (const Token *tok = mTokenizer->tokens(); tok; tok = tok->next()) { if (!Token::Match(tok, "+|-")) continue; if (!tok->valueType() || tok->valueType()->pointer == 0) continue; if (!tok->astOperand1() || !tok->astOperand2()) continue; if (!tok->astOperand1()->valueType() || !tok->astOperand2()->valueType()) continue; const Token *arrayToken, *indexToken; if (tok->astOperand1()->valueType()->pointer > 0) { arrayToken = tok->astOperand1(); indexToken = tok->astOperand2(); } else { arrayToken = tok->astOperand2(); indexToken = tok->astOperand1(); } if (!indexToken || !indexToken->valueType() || indexToken->valueType()->pointer > 0 || !indexToken->valueType()->isIntegral()) continue; std::vector dimensions; ErrorPath errorPath; bool mightBeLarger = false; if (!getDimensionsEtc(arrayToken, mSettings, &dimensions, &errorPath, &mightBeLarger)) continue; if (tok->str() == "+") { // Positive index if (!mightBeLarger) { // TODO check arrays with dim 1 also const std::vector indexTokens{indexToken}; const std::vector &indexValues = getOverrunIndexValues(tok, arrayToken, dimensions, indexTokens); if (!indexValues.empty()) pointerArithmeticError(tok, indexToken, indexValues.front()); } if (const ValueFlow::Value *neg = indexToken->getValueLE(-1, mSettings)) pointerArithmeticError(tok, indexToken, neg); } else if (tok->str() == "-") { // TODO } } } void CheckBufferOverrun::pointerArithmeticError(const Token *tok, const Token *indexToken, const ValueFlow::Value *indexValue) { if (!tok) { reportError(tok, Severity::portability, "pointerOutOfBounds", "Pointer arithmetic overflow.", CWE_POINTER_ARITHMETIC_OVERFLOW, false); reportError(tok, Severity::portability, "pointerOutOfBoundsCond", "Pointer arithmetic overflow.", CWE_POINTER_ARITHMETIC_OVERFLOW, false); return; } std::string errmsg; if (indexValue->condition) errmsg = "Undefined behaviour, when '" + indexToken->expressionString() + "' is " + MathLib::toString(indexValue->intvalue) + " the pointer arithmetic '" + tok->expressionString() + "' is out of bounds."; else errmsg = "Undefined behaviour, pointer arithmetic '" + tok->expressionString() + "' is out of bounds."; reportError(getErrorPath(tok, indexValue, "Pointer arithmetic overflow"), Severity::portability, indexValue->condition ? "pointerOutOfBoundsCond" : "pointerOutOfBounds", errmsg, CWE_POINTER_ARITHMETIC_OVERFLOW, indexValue->isInconclusive()); } //--------------------------------------------------------------------------- ValueFlow::Value CheckBufferOverrun::getBufferSize(const Token *bufTok) const { if (!bufTok->valueType()) return ValueFlow::Value(-1); const Variable *var = bufTok->variable(); if (!var || var->dimensions().empty()) { const ValueFlow::Value *value = getBufferSizeValue(bufTok); if (value) return *value; } if (!var) return ValueFlow::Value(-1); MathLib::bigint dim = std::accumulate(var->dimensions().begin(), var->dimensions().end(), 1LL, [](MathLib::bigint i1, const Dimension &dim) { return i1 * dim.num; }); ValueFlow::Value v; v.setKnown(); v.valueType = ValueFlow::Value::ValueType::BUFFER_SIZE; if (var->isPointerArray()) v.intvalue = dim * mSettings->sizeof_pointer; else if (var->isPointer()) return ValueFlow::Value(-1); else { const MathLib::bigint typeSize = bufTok->valueType()->typeSize(*mSettings); v.intvalue = dim * typeSize; } return v; } //--------------------------------------------------------------------------- static bool checkBufferSize(const Token *ftok, const Library::ArgumentChecks::MinSize &minsize, const std::vector &args, const MathLib::bigint bufferSize, const Settings *settings) { const Token * const arg = (minsize.arg > 0 && minsize.arg - 1 < args.size()) ? args[minsize.arg - 1] : nullptr; const Token * const arg2 = (minsize.arg2 > 0 && minsize.arg2 - 1 < args.size()) ? args[minsize.arg2 - 1] : nullptr; switch (minsize.type) { case Library::ArgumentChecks::MinSize::Type::STRLEN: if (settings->library.isargformatstr(ftok, minsize.arg)) { return getMinFormatStringOutputLength(args, minsize.arg) < bufferSize; } else if (arg) { const Token *strtoken = arg->getValueTokenMaxStrLength(); if (strtoken) return Token::getStrLength(strtoken) < bufferSize; } break; case Library::ArgumentChecks::MinSize::Type::ARGVALUE: if (arg && arg->hasKnownIntValue()) return arg->getKnownIntValue() <= bufferSize; break; case Library::ArgumentChecks::MinSize::Type::SIZEOF: // TODO break; case Library::ArgumentChecks::MinSize::Type::MUL: if (arg && arg2 && arg->hasKnownIntValue() && arg2->hasKnownIntValue()) return (arg->getKnownIntValue() * arg2->getKnownIntValue()) <= bufferSize; break; case Library::ArgumentChecks::MinSize::Type::VALUE: return minsize.value <= bufferSize; case Library::ArgumentChecks::MinSize::Type::NONE: break; }; return true; } void CheckBufferOverrun::bufferOverflow() { const SymbolDatabase *symbolDatabase = mTokenizer->getSymbolDatabase(); for (const Scope * scope : symbolDatabase->functionScopes) { for (const Token *tok = scope->bodyStart; tok != scope->bodyEnd; tok = tok->next()) { if (!Token::Match(tok, "%name% (") || Token::simpleMatch(tok, ") {")) continue; if (!mSettings->library.hasminsize(tok)) continue; const std::vector args = getArguments(tok); for (int argnr = 0; argnr < args.size(); ++argnr) { if (!args[argnr]->valueType() || args[argnr]->valueType()->pointer == 0) continue; const std::vector *minsizes = mSettings->library.argminsizes(tok, argnr + 1); if (!minsizes || minsizes->empty()) continue; // Get buffer size.. const Token *argtok = args[argnr]; while (argtok && argtok->isCast()) argtok = argtok->astOperand2() ? argtok->astOperand2() : argtok->astOperand1(); while (Token::Match(argtok, ".|::")) argtok = argtok->astOperand2(); if (!argtok || !argtok->variable()) continue; if (argtok->valueType() && argtok->valueType()->pointer == 0) continue; // TODO: strcpy(buf+10, "hello"); const ValueFlow::Value bufferSize = getBufferSize(argtok); if (bufferSize.intvalue <= 1) continue; bool error = std::none_of(minsizes->begin(), minsizes->end(), [=](const Library::ArgumentChecks::MinSize &minsize) { return checkBufferSize(tok, minsize, args, bufferSize.intvalue, mSettings); }); if (error) bufferOverflowError(args[argnr], &bufferSize); } } } } void CheckBufferOverrun::bufferOverflowError(const Token *tok, const ValueFlow::Value *value) { reportError(getErrorPath(tok, value, "Buffer overrun"), Severity::error, "bufferAccessOutOfBounds", "Buffer is accessed out of bounds: " + (tok ? tok->expressionString() : "buf"), CWE_BUFFER_OVERRUN, false); } //--------------------------------------------------------------------------- void CheckBufferOverrun::arrayIndexThenCheck() { if (!mSettings->isEnabled(Settings::PORTABILITY)) return; const SymbolDatabase *symbolDatabase = mTokenizer->getSymbolDatabase(); for (const Scope * const scope : symbolDatabase->functionScopes) { for (const Token *tok = scope->bodyStart; tok && tok != scope->bodyEnd; tok = tok->next()) { if (Token::simpleMatch(tok, "sizeof (")) { tok = tok->linkAt(1); continue; } if (Token::Match(tok, "%name% [ %var% ]")) { tok = tok->next(); const int indexID = tok->next()->varId(); const std::string& indexName(tok->strAt(1)); // Iterate AST upwards const Token* tok2 = tok; const Token* tok3 = tok2; while (tok2->astParent() && tok2->tokType() != Token::eLogicalOp && tok2->str() != "?") { tok3 = tok2; tok2 = tok2->astParent(); } // Ensure that we ended at a logical operator and that we came from its left side if (tok2->tokType() != Token::eLogicalOp || tok2->astOperand1() != tok3) continue; // check if array index is ok // statement can be closed in parentheses, so "(| " is using if (Token::Match(tok2, "&& (| %varid% <|<=", indexID)) arrayIndexThenCheckError(tok, indexName); else if (Token::Match(tok2, "&& (| %any% >|>= %varid% !!+", indexID)) arrayIndexThenCheckError(tok, indexName); } } } } void CheckBufferOverrun::arrayIndexThenCheckError(const Token *tok, const std::string &indexName) { reportError(tok, Severity::style, "arrayIndexThenCheck", "$symbol:" + indexName + "\n" "Array index '$symbol' is used before limits check.\n" "Defensive programming: The variable '$symbol' is used as an array index before it " "is checked that is within limits. This can mean that the array might be accessed out of bounds. " "Reorder conditions such as '(a[i] && i < 10)' to '(i < 10 && a[i])'. That way the array will " "not be accessed if the index is out of limits.", CWE_ARRAY_INDEX_THEN_CHECK, false); } //--------------------------------------------------------------------------- void CheckBufferOverrun::stringNotZeroTerminated() { // this is currently 'inconclusive'. See TestBufferOverrun::terminateStrncpy3 if (!mSettings->isEnabled(Settings::WARNING) || !mSettings->inconclusive) return; const SymbolDatabase *symbolDatabase = mTokenizer->getSymbolDatabase(); for (const Scope * const scope : symbolDatabase->functionScopes) { for (const Token *tok = scope->bodyStart; tok && tok != scope->bodyEnd; tok = tok->next()) { if (!Token::simpleMatch(tok, "strncpy (")) continue; const std::vector args = getArguments(tok); if (args.size() != 3) continue; const Token *sizeToken = args[2]; if (!sizeToken->hasKnownIntValue()) continue; const ValueFlow::Value &bufferSize = getBufferSize(args[0]); if (bufferSize.intvalue < 0 || sizeToken->getKnownIntValue() < bufferSize.intvalue) continue; const Token *srcValue = args[1]->getValueTokenMaxStrLength(); if (srcValue && Token::getStrLength(srcValue) < sizeToken->getKnownIntValue()) continue; // Is the buffer zero terminated after the call? bool isZeroTerminated = false; for (const Token *tok2 = tok->next()->link(); tok2 != scope->bodyEnd; tok2 = tok2->next()) { if (!Token::simpleMatch(tok2, "] =")) continue; const Token *rhs = tok2->next()->astOperand2(); if (!rhs || !rhs->hasKnownIntValue() || rhs->getKnownIntValue() != 0) continue; if (isSameExpression(mTokenizer->isCPP(), false, args[0], tok2->link()->astOperand1(), mSettings->library, false, false)) isZeroTerminated = true; } if (isZeroTerminated) continue; // TODO: Locate unsafe string usage.. terminateStrncpyError(tok, args[0]->expressionString()); } } } void CheckBufferOverrun::terminateStrncpyError(const Token *tok, const std::string &varname) { const std::string shortMessage = "The buffer '$symbol' may not be null-terminated after the call to strncpy()."; reportError(tok, Severity::warning, "terminateStrncpy", "$symbol:" + varname + '\n' + shortMessage + '\n' + shortMessage + ' ' + "If the source string's size fits or exceeds the given size, strncpy() does not add a " "zero at the end of the buffer. This causes bugs later in the code if the code " "assumes buffer is null-terminated.", CWE170, true); } void CheckBufferOverrun::bufferNotZeroTerminatedError(const Token *tok, const std::string &varname, const std::string &function) { const std::string errmsg = "$symbol:" + varname + '\n' + "$symbol:" + function + '\n' + "The buffer '" + varname + "' is not null-terminated after the call to " + function + "().\n" "The buffer '" + varname + "' is not null-terminated after the call to " + function + "(). " "This will cause bugs later in the code if the code assumes the buffer is null-terminated."; reportError(tok, Severity::warning, "bufferNotZeroTerminated", errmsg, CWE170, true); } //--------------------------------------------------------------------------- // CTU.. //--------------------------------------------------------------------------- std::string CheckBufferOverrun::MyFileInfo::toString() const { std::string xml; if (!unsafeArrayIndex.empty()) xml = " \n" + CTU::toString(unsafeArrayIndex) + " \n"; if (!unsafePointerArith.empty()) xml += " \n" + CTU::toString(unsafePointerArith) + " \n"; return xml; } bool CheckBufferOverrun::isCtuUnsafeBufferUsage(const Check *check, const Token *argtok, MathLib::bigint *offset, int type) { const CheckBufferOverrun *c = dynamic_cast(check); if (!c) return false; if (!argtok->valueType() || argtok->valueType()->typeSize(*c->mSettings) == 0) return false; const Token *indexTok = nullptr; if (type == 1 && Token::Match(argtok, "%name% [") && argtok->astParent() == argtok->next() && !Token::simpleMatch(argtok->linkAt(1), "] [")) indexTok = argtok->next()->astOperand2(); else if (type == 2 && Token::simpleMatch(argtok->astParent(), "+")) indexTok = (argtok == argtok->astParent()->astOperand1()) ? argtok->astParent()->astOperand2() : argtok->astParent()->astOperand1(); if (!indexTok) return false; if (!indexTok->hasKnownIntValue()) return false; if (!offset) return false; *offset = indexTok->getKnownIntValue() * argtok->valueType()->typeSize(*c->mSettings); return true; } bool CheckBufferOverrun::isCtuUnsafeArrayIndex(const Check *check, const Token *argtok, MathLib::bigint *offset) { return CheckBufferOverrun::isCtuUnsafeBufferUsage(check, argtok, offset, 1); } bool CheckBufferOverrun::isCtuUnsafePointerArith(const Check *check, const Token *argtok, MathLib::bigint *offset) { return CheckBufferOverrun::isCtuUnsafeBufferUsage(check, argtok, offset, 2); } /** @brief Parse current TU and extract file info */ Check::FileInfo *CheckBufferOverrun::getFileInfo(const Tokenizer *tokenizer, const Settings *settings) const { CheckBufferOverrun checkBufferOverrun(tokenizer, settings, nullptr); MyFileInfo *fileInfo = new MyFileInfo; fileInfo->unsafeArrayIndex = CTU::getUnsafeUsage(tokenizer, settings, &checkBufferOverrun, isCtuUnsafeArrayIndex); fileInfo->unsafePointerArith = CTU::getUnsafeUsage(tokenizer, settings, &checkBufferOverrun, isCtuUnsafePointerArith); if (fileInfo->unsafeArrayIndex.empty() && fileInfo->unsafePointerArith.empty()) { delete fileInfo; return nullptr; } return fileInfo; } Check::FileInfo * CheckBufferOverrun::loadFileInfoFromXml(const tinyxml2::XMLElement *xmlElement) const { const std::string arrayIndex("array-index"); const std::string pointerArith("pointer-arith"); MyFileInfo *fileInfo = new MyFileInfo; for (const tinyxml2::XMLElement *e = xmlElement->FirstChildElement(); e; e = e->NextSiblingElement()) { if (e->Name() == arrayIndex) fileInfo->unsafeArrayIndex = CTU::loadUnsafeUsageListFromXml(e); else if (e->Name() == pointerArith) fileInfo->unsafePointerArith = CTU::loadUnsafeUsageListFromXml(e); } if (fileInfo->unsafeArrayIndex.empty() && fileInfo->unsafePointerArith.empty()) { delete fileInfo; return nullptr; } return fileInfo; } /** @brief Analyse all file infos for all TU */ bool CheckBufferOverrun::analyseWholeProgram(const CTU::FileInfo *ctu, const std::list &fileInfo, const Settings& settings, ErrorLogger &errorLogger) { if (!ctu) return false; bool foundErrors = false; (void)settings; // This argument is unused const std::map> callsMap = ctu->getCallsMap(); for (Check::FileInfo *fi1 : fileInfo) { const MyFileInfo *fi = dynamic_cast(fi1); if (!fi) continue; for (const CTU::FileInfo::UnsafeUsage &unsafeUsage : fi->unsafeArrayIndex) foundErrors |= analyseWholeProgram1(ctu, callsMap, unsafeUsage, 1, errorLogger); for (const CTU::FileInfo::UnsafeUsage &unsafeUsage : fi->unsafePointerArith) foundErrors |= analyseWholeProgram1(ctu, callsMap, unsafeUsage, 2, errorLogger); } return foundErrors; } bool CheckBufferOverrun::analyseWholeProgram1(const CTU::FileInfo *ctu, const std::map> &callsMap, const CTU::FileInfo::UnsafeUsage &unsafeUsage, int type, ErrorLogger &errorLogger) { const CTU::FileInfo::FunctionCall *functionCall = nullptr; const std::list &locationList = ctu->getErrorPath(CTU::FileInfo::InvalidValueType::bufferOverflow, unsafeUsage, callsMap, "Using argument ARG", &functionCall, false); if (locationList.empty()) return false; const char *errorId = nullptr; std::string errmsg; CWE cwe(0); if (type == 1) { errorId = "ctuArrayIndex"; if (unsafeUsage.value > 0) errmsg = "Array index out of bounds; '" + unsafeUsage.myArgumentName + "' buffer size is " + MathLib::toString(functionCall->callArgValue) + " and it is accessed at offset " + MathLib::toString(unsafeUsage.value) + "."; else errmsg = "Array index out of bounds; buffer '" + unsafeUsage.myArgumentName + "' is accessed at offset " + MathLib::toString(unsafeUsage.value) + "."; cwe = (unsafeUsage.value > 0) ? CWE_BUFFER_OVERRUN : CWE_BUFFER_UNDERRUN; } else { errorId = "ctuPointerArith"; errmsg = "Pointer arithmetic overflow; '" + unsafeUsage.myArgumentName + "' buffer size is " + MathLib::toString(functionCall->callArgValue); cwe = CWE_POINTER_ARITHMETIC_OVERFLOW; } const ErrorLogger::ErrorMessage errorMessage(locationList, emptyString, Severity::error, errmsg, errorId, cwe, false); errorLogger.reportErr(errorMessage); return true; } void CheckBufferOverrun::objectIndex() { const SymbolDatabase *symbolDatabase = mTokenizer->getSymbolDatabase(); for (const Scope *functionScope : symbolDatabase->functionScopes) { for (const Token *tok = functionScope->bodyStart; tok != functionScope->bodyEnd; tok = tok->next()) { if (!Token::simpleMatch(tok, "[")) continue; const Token *obj = tok->astOperand1(); const Token *idx = tok->astOperand2(); if (!idx || !obj) continue; if (idx->hasKnownIntValue() && idx->getKnownIntValue() == 0) continue; ValueFlow::Value v = getLifetimeObjValue(obj); if (!v.isLocalLifetimeValue()) continue; if (v.lifetimeKind != ValueFlow::Value::LifetimeKind::Address) continue; const Variable *var = v.tokvalue->variable(); if (var->isReference()) continue; if (var->isRValueReference()) continue; if (var->isArray()) continue; if (var->isPointer()) continue; objectIndexError(tok, &v, idx->hasKnownIntValue()); } } } void CheckBufferOverrun::objectIndexError(const Token *tok, const ValueFlow::Value *v, bool known) { ErrorPath errorPath; std::string name; if (v) { name = v->tokvalue->variable()->name(); errorPath = v->errorPath; } errorPath.emplace_back(tok, ""); std::string verb = known ? "is" : "might be"; reportError(errorPath, known ? Severity::error : Severity::warning, "objectIndex", "The address of local variable '" + name + "' " + verb + " accessed at non-zero index.", CWE758, false); }