gecko-dev/build/clang-plugin/VariableUsageHelpers.cpp
Sylvestre Ledru 0d4a611a04 Bug 1410472 - clang-plugin follows the LLVM coding style for real r=mystor
MozReview-Commit-ID: AXrQEjWzxvg

--HG--
extra : rebase_source : bf972fbb22648af2edbb756eb899ebddf8444dbc
2017-10-20 19:11:50 +02:00

272 lines
9.4 KiB
C++

#include "VariableUsageHelpers.h"
#include "Utils.h"
std::vector<const Stmt *> getUsageAsRvalue(const ValueDecl *ValueDeclaration,
const FunctionDecl *FuncDecl) {
std::vector<const Stmt *> UsageStatements;
// We check the function declaration has a body.
auto Body = FuncDecl->getBody();
if (!Body) {
return std::vector<const Stmt *>();
}
// We build a Control Flow Graph (CFG) fron the body of the function
// declaration.
std::unique_ptr<CFG> StatementCFG = CFG::buildCFG(
FuncDecl, Body, &FuncDecl->getASTContext(), CFG::BuildOptions());
// We iterate through all the CFGBlocks, which basically means that we go over
// all the possible branches of the code and therefore cover all statements.
for (auto &Block : *StatementCFG) {
// We iterate through all the statements of the block.
for (auto &BlockItem : *Block) {
Optional<CFGStmt> CFGStatement = BlockItem.getAs<CFGStmt>();
if (!CFGStatement) {
continue;
}
// FIXME: Right now this function/if chain is very basic and only covers
// the cases we need for escapesFunction()
if (auto BinOp = dyn_cast<BinaryOperator>(CFGStatement->getStmt())) {
// We only care about assignments.
if (BinOp->getOpcode() != BO_Assign) {
continue;
}
// We want our declaration to be used on the right hand side of the
// assignment.
auto DeclRef = dyn_cast<DeclRefExpr>(IgnoreTrivials(BinOp->getRHS()));
if (!DeclRef) {
continue;
}
if (DeclRef->getDecl() != ValueDeclaration) {
continue;
}
} else if (auto Return = dyn_cast<ReturnStmt>(CFGStatement->getStmt())) {
// We want our declaration to be used as the expression of the return
// statement.
auto DeclRef = dyn_cast_or_null<DeclRefExpr>(
IgnoreTrivials(Return->getRetValue()));
if (!DeclRef) {
continue;
}
if (DeclRef->getDecl() != ValueDeclaration) {
continue;
}
} else {
continue;
}
// We didn't early-continue, so we add the statement to the list.
UsageStatements.push_back(CFGStatement->getStmt());
}
}
return UsageStatements;
}
// We declare our EscapesFunctionError enum to be an error code enum.
namespace std {
template <> struct is_error_code_enum<EscapesFunctionError> : true_type {};
} // namespace std
// We define the EscapesFunctionErrorCategory which contains the error messages
// corresponding to each enum variant.
namespace {
struct EscapesFunctionErrorCategory : std::error_category {
const char *name() const noexcept override;
std::string message(int ev) const override;
};
const char *EscapesFunctionErrorCategory::name() const noexcept {
return "escapes function";
}
std::string EscapesFunctionErrorCategory::message(int ev) const {
switch (static_cast<EscapesFunctionError>(ev)) {
case EscapesFunctionError::ConstructorDeclNotFound:
return "constructor declaration not found";
case EscapesFunctionError::FunctionDeclNotFound:
return "function declaration not found";
case EscapesFunctionError::FunctionIsBuiltin:
return "function is builtin";
case EscapesFunctionError::FunctionIsVariadic:
return "function is variadic";
case EscapesFunctionError::ExprNotInCall:
return "expression is not in call";
case EscapesFunctionError::NoParamForArg:
return "no parameter for argument";
case EscapesFunctionError::ArgAndParamNotPointers:
return "argument and parameter are not pointers";
}
}
const EscapesFunctionErrorCategory TheEscapesFunctionErrorCategory{};
} // namespace
std::error_code make_error_code(EscapesFunctionError e) {
return {static_cast<int>(e), TheEscapesFunctionErrorCategory};
}
ErrorOr<std::tuple<const Stmt *, const Decl *>>
escapesFunction(const Expr *Arg, const CXXConstructExpr *Construct) {
// We get the function declaration corresponding to the call.
auto CtorDecl = Construct->getConstructor();
if (!CtorDecl) {
return EscapesFunctionError::ConstructorDeclNotFound;
}
return escapesFunction(Arg, CtorDecl, Construct->getArgs(),
Construct->getNumArgs());
}
ErrorOr<std::tuple<const Stmt *, const Decl *>>
escapesFunction(const Expr *Arg, const CallExpr *Call) {
// We get the function declaration corresponding to the call.
auto FuncDecl = Call->getDirectCallee();
if (!FuncDecl) {
return EscapesFunctionError::FunctionDeclNotFound;
}
return escapesFunction(Arg, FuncDecl, Call->getArgs(), Call->getNumArgs());
}
ErrorOr<std::tuple<const Stmt *, const Decl *>>
escapesFunction(const Expr *Arg, const CXXOperatorCallExpr *OpCall) {
// We get the function declaration corresponding to the operator call.
auto FuncDecl = OpCall->getDirectCallee();
if (!FuncDecl) {
return EscapesFunctionError::FunctionDeclNotFound;
}
auto Args = OpCall->getArgs();
auto NumArgs = OpCall->getNumArgs();
// If this is an infix binary operator defined as a one-param method, we
// remove the first argument as it is inserted explicitly and creates a
// mismatch with the parameters of the method declaration.
if (isInfixBinaryOp(OpCall) && FuncDecl->getNumParams() == 1) {
Args++;
NumArgs--;
}
return escapesFunction(Arg, FuncDecl, Args, NumArgs);
}
ErrorOr<std::tuple<const Stmt *, const Decl *>>
escapesFunction(const Expr *Arg, const FunctionDecl *FuncDecl,
const Expr *const *Arguments, unsigned NumArgs) {
if (!NumArgs) {
return std::make_tuple((const Stmt *)nullptr, (const Decl *)nullptr);
}
if (FuncDecl->getBuiltinID() != 0 ||
ASTIsInSystemHeader(FuncDecl->getASTContext(), *FuncDecl)) {
return EscapesFunctionError::FunctionIsBuiltin;
}
// FIXME: should probably be handled at some point, but it's too annoying
// for now.
if (FuncDecl->isVariadic()) {
return EscapesFunctionError::FunctionIsVariadic;
}
// We find the argument number corresponding to the Arg expression.
unsigned ArgNum = 0;
for (unsigned i = 0; i < NumArgs; i++) {
if (IgnoreTrivials(Arg) == IgnoreTrivials(Arguments[i])) {
break;
}
++ArgNum;
}
// If we don't find it, we early-return NoneType.
if (ArgNum >= NumArgs) {
return EscapesFunctionError::ExprNotInCall;
}
// Now we get the associated parameter.
if (ArgNum >= FuncDecl->getNumParams()) {
return EscapesFunctionError::NoParamForArg;
}
auto Param = FuncDecl->getParamDecl(ArgNum);
// We want both the argument and the parameter to be of pointer type.
// FIXME: this is enough for the DanglingOnTemporaryChecker, because the
// analysed methods only return pointers, but more cases should probably be
// handled when we want to use this function more broadly.
if ((!Arg->getType().getNonReferenceType()->isPointerType() &&
Arg->getType().getNonReferenceType()->isBuiltinType()) ||
(!Param->getType().getNonReferenceType()->isPointerType() &&
Param->getType().getNonReferenceType()->isBuiltinType())) {
return EscapesFunctionError::ArgAndParamNotPointers;
}
// We retrieve the usages of the parameter in the function.
auto Usages = getUsageAsRvalue(Param, FuncDecl);
// For each usage, we check if it doesn't allow the parameter to escape the
// function scope.
for (auto Usage : Usages) {
// In the case of an assignment.
if (auto BinOp = dyn_cast<BinaryOperator>(Usage)) {
// We retrieve the declaration the parameter is assigned to.
auto DeclRef = dyn_cast<DeclRefExpr>(BinOp->getLHS());
if (!DeclRef) {
continue;
}
if (auto ParamDeclaration = dyn_cast<ParmVarDecl>(DeclRef->getDecl())) {
// This is the case where the parameter escapes through another
// parameter.
// FIXME: for now we only care about references because we only detect
// trivial LHS with just a DeclRefExpr, and not more complex cases like:
// void func(Type* param1, Type** param2) {
// *param2 = param1;
// }
// This should be fixed when we have better/more helper functions to
// help deal with this kind of lvalue expressions.
if (!ParamDeclaration->getType()->isReferenceType()) {
continue;
}
return std::make_tuple(Usage, (const Decl *)ParamDeclaration);
} else if (auto VarDeclaration = dyn_cast<VarDecl>(DeclRef->getDecl())) {
// This is the case where the parameter escapes through a global/static
// variable.
if (!VarDeclaration->hasGlobalStorage()) {
continue;
}
return std::make_tuple(Usage, (const Decl *)VarDeclaration);
} else if (auto FieldDeclaration =
dyn_cast<FieldDecl>(DeclRef->getDecl())) {
// This is the case where the parameter escapes through a field.
return std::make_tuple(Usage, (const Decl *)FieldDeclaration);
}
} else if (isa<ReturnStmt>(Usage)) {
// This is the case where the parameter escapes through the return value
// of the function.
if (!FuncDecl->getReturnType()->isPointerType() &&
!FuncDecl->getReturnType()->isReferenceType()) {
continue;
}
return std::make_tuple(Usage, (const Decl *)FuncDecl);
}
}
// No early-return, this means that we haven't found any case of funciton
// escaping and that therefore the parameter remains in the function scope.
return std::make_tuple((const Stmt *)nullptr, (const Decl *)nullptr);
}