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//== GenericTaintChecker.cpp ----------------------------------- -*- C++ -*--=// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This checker defines the attack surface for generic taint propagation. // // The taint information produced by it might be useful to other checkers. For // example, checkers should report errors which involve tainted data more // aggressively, even if the involved symbols are under constrained. // //===----------------------------------------------------------------------===// #include "ClangSACheckers.h" #include "clang/StaticAnalyzer/Core/Checker.h" #include "clang/StaticAnalyzer/Core/CheckerManager.h" #include "clang/StaticAnalyzer/Core/PathSensitive/CheckerContext.h" #include "clang/StaticAnalyzer/Core/PathSensitive/ProgramStateTrait.h" #include "clang/StaticAnalyzer/Core/BugReporter/BugType.h" #include "clang/Basic/Builtins.h" #include <climits> using namespace clang; using namespace ento; namespace { class GenericTaintChecker : public Checker< check::PostStmt<CallExpr>, check::PreStmt<CallExpr> > { public: static void *getTag() { static int Tag; return &Tag; } void checkPostStmt(const CallExpr *CE, CheckerContext &C) const; void checkPostStmt(const DeclRefExpr *DRE, CheckerContext &C) const; void checkPreStmt(const CallExpr *CE, CheckerContext &C) const; private: static const unsigned InvalidArgIndex = UINT_MAX; /// Denotes the return vale. static const unsigned ReturnValueIndex = UINT_MAX - 1; mutable OwningPtr<BugType> BT; inline void initBugType() const { if (!BT) BT.reset(new BugType("Use of Untrusted Data", "Untrusted Data")); } /// \brief Catch taint related bugs. Check if tainted data is passed to a /// system call etc. bool checkPre(const CallExpr *CE, CheckerContext &C) const; /// \brief Add taint sources on a pre-visit. void addSourcesPre(const CallExpr *CE, CheckerContext &C) const; /// \brief Propagate taint generated at pre-visit. bool propagateFromPre(const CallExpr *CE, CheckerContext &C) const; /// \brief Add taint sources on a post visit. void addSourcesPost(const CallExpr *CE, CheckerContext &C) const; /// Check if the region the expression evaluates to is the standard input, /// and thus, is tainted. static bool isStdin(const Expr *E, CheckerContext &C); /// \brief Given a pointer argument, get the symbol of the value it contains /// (points to). static SymbolRef getPointedToSymbol(CheckerContext &C, const Expr *Arg); /// Functions defining the attack surface. typedef ProgramStateRef (GenericTaintChecker::*FnCheck)(const CallExpr *, CheckerContext &C) const; ProgramStateRef postScanf(const CallExpr *CE, CheckerContext &C) const; ProgramStateRef postSocket(const CallExpr *CE, CheckerContext &C) const; ProgramStateRef postRetTaint(const CallExpr *CE, CheckerContext &C) const; /// Taint the scanned input if the file is tainted. ProgramStateRef preFscanf(const CallExpr *CE, CheckerContext &C) const; /// Check for CWE-134: Uncontrolled Format String. static const char MsgUncontrolledFormatString[]; bool checkUncontrolledFormatString(const CallExpr *CE, CheckerContext &C) const; /// Check for: /// CERT/STR02-C. "Sanitize data passed to complex subsystems" /// CWE-78, "Failure to Sanitize Data into an OS Command" static const char MsgSanitizeSystemArgs[]; bool checkSystemCall(const CallExpr *CE, StringRef Name, CheckerContext &C) const; /// Check if tainted data is used as a buffer size ins strn.. functions, /// and allocators. static const char MsgTaintedBufferSize[]; bool checkTaintedBufferSize(const CallExpr *CE, const FunctionDecl *FDecl, CheckerContext &C) const; /// Generate a report if the expression is tainted or points to tainted data. bool generateReportIfTainted(const Expr *E, const char Msg[], CheckerContext &C) const; typedef llvm::SmallVector<unsigned, 2> ArgVector; /// \brief A struct used to specify taint propagation rules for a function. /// /// If any of the possible taint source arguments is tainted, all of the /// destination arguments should also be tainted. Use InvalidArgIndex in the /// src list to specify that all of the arguments can introduce taint. Use /// InvalidArgIndex in the dst arguments to signify that all the non-const /// pointer and reference arguments might be tainted on return. If /// ReturnValueIndex is added to the dst list, the return value will be /// tainted. struct TaintPropagationRule { /// List of arguments which can be taint sources and should be checked. ArgVector SrcArgs; /// List of arguments which should be tainted on function return. ArgVector DstArgs; // TODO: Check if using other data structures would be more optimal. TaintPropagationRule() {} TaintPropagationRule(unsigned SArg, unsigned DArg, bool TaintRet = false) { SrcArgs.push_back(SArg); DstArgs.push_back(DArg); if (TaintRet) DstArgs.push_back(ReturnValueIndex); } TaintPropagationRule(unsigned SArg1, unsigned SArg2, unsigned DArg, bool TaintRet = false) { SrcArgs.push_back(SArg1); SrcArgs.push_back(SArg2); DstArgs.push_back(DArg); if (TaintRet) DstArgs.push_back(ReturnValueIndex); } /// Get the propagation rule for a given function. static TaintPropagationRule getTaintPropagationRule(const FunctionDecl *FDecl, StringRef Name, CheckerContext &C); inline void addSrcArg(unsigned A) { SrcArgs.push_back(A); } inline void addDstArg(unsigned A) { DstArgs.push_back(A); } inline bool isNull() const { return SrcArgs.empty(); } inline bool isDestinationArgument(unsigned ArgNum) const { return (std::find(DstArgs.begin(), DstArgs.end(), ArgNum) != DstArgs.end()); } static inline bool isTaintedOrPointsToTainted(const Expr *E, ProgramStateRef State, CheckerContext &C) { return (State->isTainted(E, C.getLocationContext()) || isStdin(E, C) || (E->getType().getTypePtr()->isPointerType() && State->isTainted(getPointedToSymbol(C, E)))); } /// \brief Pre-process a function which propagates taint according to the /// taint rule. ProgramStateRef process(const CallExpr *CE, CheckerContext &C) const; }; }; const unsigned GenericTaintChecker::ReturnValueIndex; const unsigned GenericTaintChecker::InvalidArgIndex; const char GenericTaintChecker::MsgUncontrolledFormatString[] = "Untrusted data is used as a format string " "(CWE-134: Uncontrolled Format String)"; const char GenericTaintChecker::MsgSanitizeSystemArgs[] = "Untrusted data is passed to a system call " "(CERT/STR02-C. Sanitize data passed to complex subsystems)"; const char GenericTaintChecker::MsgTaintedBufferSize[] = "Untrusted data is used to specify the buffer size " "(CERT/STR31-C. Guarantee that storage for strings has sufficient space for " "character data and the null terminator)"; } // end of anonymous namespace /// A set which is used to pass information from call pre-visit instruction /// to the call post-visit. The values are unsigned integers, which are either /// ReturnValueIndex, or indexes of the pointer/reference argument, which /// points to data, which should be tainted on return. namespace { struct TaintArgsOnPostVisit{}; } namespace clang { namespace ento { template<> struct ProgramStateTrait<TaintArgsOnPostVisit> : public ProgramStatePartialTrait<llvm::ImmutableSet<unsigned> > { static void *GDMIndex() { return GenericTaintChecker::getTag(); } }; }} GenericTaintChecker::TaintPropagationRule GenericTaintChecker::TaintPropagationRule::getTaintPropagationRule( const FunctionDecl *FDecl, StringRef Name, CheckerContext &C) { // TODO: Currently, we might loose precision here: we always mark a return // value as tainted even if it's just a pointer, pointing to tainted data. // Check for exact name match for functions without builtin substitutes. TaintPropagationRule Rule = llvm::StringSwitch<TaintPropagationRule>(Name) .Case("atoi", TaintPropagationRule(0, ReturnValueIndex)) .Case("atol", TaintPropagationRule(0, ReturnValueIndex)) .Case("atoll", TaintPropagationRule(0, ReturnValueIndex)) .Case("getc", TaintPropagationRule(0, ReturnValueIndex)) .Case("fgetc", TaintPropagationRule(0, ReturnValueIndex)) .Case("getc_unlocked", TaintPropagationRule(0, ReturnValueIndex)) .Case("getw", TaintPropagationRule(0, ReturnValueIndex)) .Case("toupper", TaintPropagationRule(0, ReturnValueIndex)) .Case("tolower", TaintPropagationRule(0, ReturnValueIndex)) .Case("strchr", TaintPropagationRule(0, ReturnValueIndex)) .Case("strrchr", TaintPropagationRule(0, ReturnValueIndex)) .Case("read", TaintPropagationRule(0, 2, 1, true)) .Case("pread", TaintPropagationRule(InvalidArgIndex, 1, true)) .Case("gets", TaintPropagationRule(InvalidArgIndex, 0, true)) .Case("fgets", TaintPropagationRule(2, 0, true)) .Case("getline", TaintPropagationRule(2, 0)) .Case("getdelim", TaintPropagationRule(3, 0)) .Case("fgetln", TaintPropagationRule(0, ReturnValueIndex)) .Default(TaintPropagationRule()); if (!Rule.isNull()) return Rule; // Check if it's one of the memory setting/copying functions. // This check is specialized but faster then calling isCLibraryFunction. unsigned BId = 0; if ( (BId = FDecl->getMemoryFunctionKind()) ) switch(BId) { case Builtin::BImemcpy: case Builtin::BImemmove: case Builtin::BIstrncpy: case Builtin::BIstrncat: return TaintPropagationRule(1, 2, 0, true); case Builtin::BIstrlcpy: case Builtin::BIstrlcat: return TaintPropagationRule(1, 2, 0, false); case Builtin::BIstrndup: return TaintPropagationRule(0, 1, ReturnValueIndex); default: break; }; // Process all other functions which could be defined as builtins. if (Rule.isNull()) { if (C.isCLibraryFunction(FDecl, "snprintf") || C.isCLibraryFunction(FDecl, "sprintf")) return TaintPropagationRule(InvalidArgIndex, 0, true); else if (C.isCLibraryFunction(FDecl, "strcpy") || C.isCLibraryFunction(FDecl, "stpcpy") || C.isCLibraryFunction(FDecl, "strcat")) return TaintPropagationRule(1, 0, true); else if (C.isCLibraryFunction(FDecl, "bcopy")) return TaintPropagationRule(0, 2, 1, false); else if (C.isCLibraryFunction(FDecl, "strdup") || C.isCLibraryFunction(FDecl, "strdupa")) return TaintPropagationRule(0, ReturnValueIndex); else if (C.isCLibraryFunction(FDecl, "wcsdup")) return TaintPropagationRule(0, ReturnValueIndex); } // Skipping the following functions, since they might be used for cleansing // or smart memory copy: // - memccpy - copying untill hitting a special character. return TaintPropagationRule(); } void GenericTaintChecker::checkPreStmt(const CallExpr *CE, CheckerContext &C) const { // Check for errors first. if (checkPre(CE, C)) return; // Add taint second. addSourcesPre(CE, C); } void GenericTaintChecker::checkPostStmt(const CallExpr *CE, CheckerContext &C) const { if (propagateFromPre(CE, C)) return; addSourcesPost(CE, C); } void GenericTaintChecker::addSourcesPre(const CallExpr *CE, CheckerContext &C) const { ProgramStateRef State = 0; const FunctionDecl *FDecl = C.getCalleeDecl(CE); StringRef Name = C.getCalleeName(FDecl); if (Name.empty()) return; // First, try generating a propagation rule for this function. TaintPropagationRule Rule = TaintPropagationRule::getTaintPropagationRule(FDecl, Name, C); if (!Rule.isNull()) { State = Rule.process(CE, C); if (!State) return; C.addTransition(State); return; } // Otherwise, check if we have custom pre-processing implemented. FnCheck evalFunction = llvm::StringSwitch<FnCheck>(Name) .Case("fscanf", &GenericTaintChecker::preFscanf) .Default(0); // Check and evaluate the call. if (evalFunction) State = (this->*evalFunction)(CE, C); if (!State) return; C.addTransition(State); } bool GenericTaintChecker::propagateFromPre(const CallExpr *CE, CheckerContext &C) const { ProgramStateRef State = C.getState(); // Depending on what was tainted at pre-visit, we determined a set of // arguments which should be tainted after the function returns. These are // stored in the state as TaintArgsOnPostVisit set. llvm::ImmutableSet<unsigned> TaintArgs = State->get<TaintArgsOnPostVisit>(); if (TaintArgs.isEmpty()) return false; for (llvm::ImmutableSet<unsigned>::iterator I = TaintArgs.begin(), E = TaintArgs.end(); I != E; ++I) { unsigned ArgNum = *I; // Special handling for the tainted return value. if (ArgNum == ReturnValueIndex) { State = State->addTaint(CE, C.getLocationContext()); continue; } // The arguments are pointer arguments. The data they are pointing at is // tainted after the call. if (CE->getNumArgs() < (ArgNum + 1)) return false; const Expr* Arg = CE->getArg(ArgNum); SymbolRef Sym = getPointedToSymbol(C, Arg); if (Sym) State = State->addTaint(Sym); } // Clear up the taint info from the state. State = State->remove<TaintArgsOnPostVisit>(); if (State != C.getState()) { C.addTransition(State); return true; } return false; } void GenericTaintChecker::addSourcesPost(const CallExpr *CE, CheckerContext &C) const { // Define the attack surface. // Set the evaluation function by switching on the callee name. StringRef Name = C.getCalleeName(CE); if (Name.empty()) return; FnCheck evalFunction = llvm::StringSwitch<FnCheck>(Name) .Case("scanf", &GenericTaintChecker::postScanf) // TODO: Add support for vfscanf & family. .Case("getchar", &GenericTaintChecker::postRetTaint) .Case("getchar_unlocked", &GenericTaintChecker::postRetTaint) .Case("getenv", &GenericTaintChecker::postRetTaint) .Case("fopen", &GenericTaintChecker::postRetTaint) .Case("fdopen", &GenericTaintChecker::postRetTaint) .Case("freopen", &GenericTaintChecker::postRetTaint) .Case("getch", &GenericTaintChecker::postRetTaint) .Case("wgetch", &GenericTaintChecker::postRetTaint) .Case("socket", &GenericTaintChecker::postSocket) .Default(0); // If the callee isn't defined, it is not of security concern. // Check and evaluate the call. ProgramStateRef State = 0; if (evalFunction) State = (this->*evalFunction)(CE, C); if (!State) return; C.addTransition(State); } bool GenericTaintChecker::checkPre(const CallExpr *CE, CheckerContext &C) const{ if (checkUncontrolledFormatString(CE, C)) return true; const FunctionDecl *FDecl = C.getCalleeDecl(CE); StringRef Name = C.getCalleeName(FDecl); if (Name.empty()) return false; if (checkSystemCall(CE, Name, C)) return true; if (checkTaintedBufferSize(CE, FDecl, C)) return true; return false; } SymbolRef GenericTaintChecker::getPointedToSymbol(CheckerContext &C, const Expr* Arg) { ProgramStateRef State = C.getState(); SVal AddrVal = State->getSVal(Arg->IgnoreParens(), C.getLocationContext()); if (AddrVal.isUnknownOrUndef()) return 0; Loc *AddrLoc = dyn_cast<Loc>(&AddrVal); if (!AddrLoc) return 0; const PointerType *ArgTy = dyn_cast<PointerType>(Arg->getType().getCanonicalType().getTypePtr()); SVal Val = State->getSVal(*AddrLoc, ArgTy ? ArgTy->getPointeeType(): QualType()); return Val.getAsSymbol(); } ProgramStateRef GenericTaintChecker::TaintPropagationRule::process(const CallExpr *CE, CheckerContext &C) const { ProgramStateRef State = C.getState(); // Check for taint in arguments. bool IsTainted = false; for (ArgVector::const_iterator I = SrcArgs.begin(), E = SrcArgs.end(); I != E; ++I) { unsigned ArgNum = *I; if (ArgNum == InvalidArgIndex) { // Check if any of the arguments is tainted, but skip the // destination arguments. for (unsigned int i = 0; i < CE->getNumArgs(); ++i) { if (isDestinationArgument(i)) continue; if ((IsTainted = isTaintedOrPointsToTainted(CE->getArg(i), State, C))) break; } break; } if (CE->getNumArgs() < (ArgNum + 1)) return State; if ((IsTainted = isTaintedOrPointsToTainted(CE->getArg(ArgNum), State, C))) break; } if (!IsTainted) return State; // Mark the arguments which should be tainted after the function returns. for (ArgVector::const_iterator I = DstArgs.begin(), E = DstArgs.end(); I != E; ++I) { unsigned ArgNum = *I; // Should we mark all arguments as tainted? if (ArgNum == InvalidArgIndex) { // For all pointer and references that were passed in: // If they are not pointing to const data, mark data as tainted. // TODO: So far we are just going one level down; ideally we'd need to // recurse here. for (unsigned int i = 0; i < CE->getNumArgs(); ++i) { const Expr *Arg = CE->getArg(i); // Process pointer argument. const Type *ArgTy = Arg->getType().getTypePtr(); QualType PType = ArgTy->getPointeeType(); if ((!PType.isNull() && !PType.isConstQualified()) || (ArgTy->isReferenceType() && !Arg->getType().isConstQualified())) State = State->add<TaintArgsOnPostVisit>(i); } continue; } // Should mark the return value? if (ArgNum == ReturnValueIndex) { State = State->add<TaintArgsOnPostVisit>(ReturnValueIndex); continue; } // Mark the given argument. assert(ArgNum < CE->getNumArgs()); State = State->add<TaintArgsOnPostVisit>(ArgNum); } return State; } // If argument 0 (file descriptor) is tainted, all arguments except for arg 0 // and arg 1 should get taint. ProgramStateRef GenericTaintChecker::preFscanf(const CallExpr *CE, CheckerContext &C) const { assert(CE->getNumArgs() >= 2); ProgramStateRef State = C.getState(); // Check is the file descriptor is tainted. if (State->isTainted(CE->getArg(0), C.getLocationContext()) || isStdin(CE->getArg(0), C)) { // All arguments except for the first two should get taint. for (unsigned int i = 2; i < CE->getNumArgs(); ++i) State = State->add<TaintArgsOnPostVisit>(i); return State; } return 0; } // If argument 0(protocol domain) is network, the return value should get taint. ProgramStateRef GenericTaintChecker::postSocket(const CallExpr *CE, CheckerContext &C) const { ProgramStateRef State = C.getState(); if (CE->getNumArgs() < 3) return State; SourceLocation DomLoc = CE->getArg(0)->getExprLoc(); StringRef DomName = C.getMacroNameOrSpelling(DomLoc); // White list the internal communication protocols. if (DomName.equals("AF_SYSTEM") || DomName.equals("AF_LOCAL") || DomName.equals("AF_UNIX") || DomName.equals("AF_RESERVED_36")) return State; State = State->addTaint(CE, C.getLocationContext()); return State; } ProgramStateRef GenericTaintChecker::postScanf(const CallExpr *CE, CheckerContext &C) const { ProgramStateRef State = C.getState(); if (CE->getNumArgs() < 2) return State; SVal x = State->getSVal(CE->getArg(1), C.getLocationContext()); // All arguments except for the very first one should get taint. for (unsigned int i = 1; i < CE->getNumArgs(); ++i) { // The arguments are pointer arguments. The data they are pointing at is // tainted after the call. const Expr* Arg = CE->getArg(i); SymbolRef Sym = getPointedToSymbol(C, Arg); if (Sym) State = State->addTaint(Sym); } return State; } ProgramStateRef GenericTaintChecker::postRetTaint(const CallExpr *CE, CheckerContext &C) const { return C.getState()->addTaint(CE, C.getLocationContext()); } bool GenericTaintChecker::isStdin(const Expr *E, CheckerContext &C) { ProgramStateRef State = C.getState(); SVal Val = State->getSVal(E, C.getLocationContext()); // stdin is a pointer, so it would be a region. const MemRegion *MemReg = Val.getAsRegion(); // The region should be symbolic, we do not know it's value. const SymbolicRegion *SymReg = dyn_cast_or_null<SymbolicRegion>(MemReg); if (!SymReg) return false; // Get it's symbol and find the declaration region it's pointing to. const SymbolRegionValue *Sm =dyn_cast<SymbolRegionValue>(SymReg->getSymbol()); if (!Sm) return false; const DeclRegion *DeclReg = dyn_cast_or_null<DeclRegion>(Sm->getRegion()); if (!DeclReg) return false; // This region corresponds to a declaration, find out if it's a global/extern // variable named stdin with the proper type. if (const VarDecl *D = dyn_cast_or_null<VarDecl>(DeclReg->getDecl())) { D = D->getCanonicalDecl(); if ((D->getName().find("stdin") != StringRef::npos) && D->isExternC()) if (const PointerType * PtrTy = dyn_cast<PointerType>(D->getType().getTypePtr())) if (PtrTy->getPointeeType() == C.getASTContext().getFILEType()) return true; } return false; } static bool getPrintfFormatArgumentNum(const CallExpr *CE, const CheckerContext &C, unsigned int &ArgNum) { // Find if the function contains a format string argument. // Handles: fprintf, printf, sprintf, snprintf, vfprintf, vprintf, vsprintf, // vsnprintf, syslog, custom annotated functions. const FunctionDecl *FDecl = C.getCalleeDecl(CE); if (!FDecl) return false; for (specific_attr_iterator<FormatAttr> i = FDecl->specific_attr_begin<FormatAttr>(), e = FDecl->specific_attr_end<FormatAttr>(); i != e ; ++i) { const FormatAttr *Format = *i; ArgNum = Format->getFormatIdx() - 1; if ((Format->getType() == "printf") && CE->getNumArgs() > ArgNum) return true; } // Or if a function is named setproctitle (this is a heuristic). if (C.getCalleeName(CE).find("setproctitle") != StringRef::npos) { ArgNum = 0; return true; } return false; } bool GenericTaintChecker::generateReportIfTainted(const Expr *E, const char Msg[], CheckerContext &C) const { assert(E); // Check for taint. ProgramStateRef State = C.getState(); if (!State->isTainted(getPointedToSymbol(C, E)) && !State->isTainted(E, C.getLocationContext())) return false; // Generate diagnostic. if (ExplodedNode *N = C.addTransition()) { initBugType(); BugReport *report = new BugReport(*BT, Msg, N); report->addRange(E->getSourceRange()); C.EmitReport(report); return true; } return false; } bool GenericTaintChecker::checkUncontrolledFormatString(const CallExpr *CE, CheckerContext &C) const{ // Check if the function contains a format string argument. unsigned int ArgNum = 0; if (!getPrintfFormatArgumentNum(CE, C, ArgNum)) return false; // If either the format string content or the pointer itself are tainted, warn. if (generateReportIfTainted(CE->getArg(ArgNum), MsgUncontrolledFormatString, C)) return true; return false; } bool GenericTaintChecker::checkSystemCall(const CallExpr *CE, StringRef Name, CheckerContext &C) const { // TODO: It might make sense to run this check on demand. In some cases, // we should check if the environment has been cleansed here. We also might // need to know if the user was reset before these calls(seteuid). unsigned ArgNum = llvm::StringSwitch<unsigned>(Name) .Case("system", 0) .Case("popen", 0) .Case("execl", 0) .Case("execle", 0) .Case("execlp", 0) .Case("execv", 0) .Case("execvp", 0) .Case("execvP", 0) .Case("execve", 0) .Case("dlopen", 0) .Default(UINT_MAX); if (ArgNum == UINT_MAX || CE->getNumArgs() < (ArgNum + 1)) return false; if (generateReportIfTainted(CE->getArg(ArgNum), MsgSanitizeSystemArgs, C)) return true; return false; } // TODO: Should this check be a part of the CString checker? // If yes, should taint be a global setting? bool GenericTaintChecker::checkTaintedBufferSize(const CallExpr *CE, const FunctionDecl *FDecl, CheckerContext &C) const { // If the function has a buffer size argument, set ArgNum. unsigned ArgNum = InvalidArgIndex; unsigned BId = 0; if ( (BId = FDecl->getMemoryFunctionKind()) ) switch(BId) { case Builtin::BImemcpy: case Builtin::BImemmove: case Builtin::BIstrncpy: ArgNum = 2; break; case Builtin::BIstrndup: ArgNum = 1; break; default: break; }; if (ArgNum == InvalidArgIndex) { if (C.isCLibraryFunction(FDecl, "malloc") || C.isCLibraryFunction(FDecl, "calloc") || C.isCLibraryFunction(FDecl, "alloca")) ArgNum = 0; else if (C.isCLibraryFunction(FDecl, "memccpy")) ArgNum = 3; else if (C.isCLibraryFunction(FDecl, "realloc")) ArgNum = 1; else if (C.isCLibraryFunction(FDecl, "bcopy")) ArgNum = 2; } if (ArgNum != InvalidArgIndex && CE->getNumArgs() > ArgNum && generateReportIfTainted(CE->getArg(ArgNum), MsgTaintedBufferSize, C)) return true; return false; } void ento::registerGenericTaintChecker(CheckerManager &mgr) { mgr.registerChecker<GenericTaintChecker>(); }