llvm-project/clang-tools-extra/clang-tidy/modernize/UseAutoCheck.cpp

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//===--- UseAutoCheck.cpp - clang-tidy-------------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "UseAutoCheck.h"
#include "clang/AST/ASTContext.h"
#include "clang/ASTMatchers/ASTMatchers.h"
#include "clang/ASTMatchers/ASTMatchFinder.h"
using namespace clang;
using namespace clang::ast_matchers;
using namespace clang::ast_matchers::internal;
namespace clang {
namespace tidy {
namespace modernize {
namespace {
const char IteratorDeclStmtId[] = "iterator_decl";
const char DeclWithNewId[] = "decl_new";
/// \brief Matches variable declarations that have explicit initializers that
/// are not initializer lists.
///
/// Given
/// \code
/// iterator I = Container.begin();
/// MyType A(42);
/// MyType B{2};
/// MyType C;
/// \endcode
///
/// varDecl(hasWrittenNonListInitializer()) maches \c I and \c A but not \c B
/// or \c C.
AST_MATCHER(VarDecl, hasWrittenNonListInitializer) {
const Expr *Init = Node.getAnyInitializer();
if (!Init)
return false;
// The following test is based on DeclPrinter::VisitVarDecl() to find if an
// initializer is implicit or not.
if (const auto *Construct = dyn_cast<CXXConstructExpr>(Init)) {
return !Construct->isListInitialization() && Construct->getNumArgs() > 0 &&
!Construct->getArg(0)->isDefaultArgument();
}
return Node.getInitStyle() != VarDecl::ListInit;
}
/// \brief Matches QualTypes that are type sugar for QualTypes that match \c
/// SugarMatcher.
///
/// Given
/// \code
/// class C {};
/// typedef C my_type;
/// typedef my_type my_other_type;
/// \endcode
///
/// qualType(isSugarFor(recordType(hasDeclaration(namedDecl(hasName("C"))))))
/// matches \c my_type and \c my_other_type.
AST_MATCHER_P(QualType, isSugarFor, Matcher<QualType>, SugarMatcher) {
QualType QT = Node;
while (true) {
if (SugarMatcher.matches(QT, Finder, Builder))
return true;
QualType NewQT = QT.getSingleStepDesugaredType(Finder->getASTContext());
if (NewQT == QT)
return false;
QT = NewQT;
}
}
/// \brief Matches named declarations that have one of the standard iterator
/// names: iterator, reverse_iterator, const_iterator, const_reverse_iterator.
///
/// Given
/// \code
/// iterator I;
/// const_iterator CI;
/// \endcode
///
/// namedDecl(hasStdIteratorName()) matches \c I and \c CI.
AST_MATCHER(NamedDecl, hasStdIteratorName) {
static const char *const IteratorNames[] = {"iterator", "reverse_iterator",
"const_iterator",
"const_reverse_iterator"};
for (const char *Name : IteratorNames) {
if (hasName(Name).matches(Node, Finder, Builder))
return true;
}
return false;
}
/// \brief Matches named declarations that have one of the standard container
/// names.
///
/// Given
/// \code
/// class vector {};
/// class forward_list {};
/// class my_ver{};
/// \endcode
///
/// recordDecl(hasStdContainerName()) matches \c vector and \c forward_list
/// but not \c my_vec.
AST_MATCHER(NamedDecl, hasStdContainerName) {
static const char *const ContainerNames[] = {"array", "deque",
"forward_list", "list",
"vector",
"map", "multimap",
"set", "multiset",
"unordered_map",
"unordered_multimap",
"unordered_set",
"unordered_multiset",
"queue", "priority_queue",
"stack"};
for (const char *Name : ContainerNames) {
if (hasName(Name).matches(Node, Finder, Builder))
return true;
}
return false;
}
/// Matches declarations whose declaration context is the C++ standard library
/// namespace std.
///
/// Note that inline namespaces are silently ignored during the lookup since
/// both libstdc++ and libc++ are known to use them for versioning purposes.
///
/// Given:
/// \code
/// namespace ns {
/// struct my_type {};
/// using namespace std;
/// }
///
/// using std::vector;
/// using ns:my_type;
/// using ns::list;
/// \code
///
/// usingDecl(hasAnyUsingShadowDecl(hasTargetDecl(isFromStdNamespace())))
/// matches "using std::vector" and "using ns::list".
AST_MATCHER(Decl, isFromStdNamespace) {
const DeclContext *D = Node.getDeclContext();
while (D->isInlineNamespace())
D = D->getParent();
if (!D->isNamespace() || !D->getParent()->isTranslationUnit())
return false;
const IdentifierInfo *Info = cast<NamespaceDecl>(D)->getIdentifier();
return (Info && Info->isStr("std"));
}
/// \brief Returns a DeclarationMatcher that matches standard iterators nested
/// inside records with a standard container name.
DeclarationMatcher standardIterator() {
return allOf(
namedDecl(hasStdIteratorName()),
hasDeclContext(recordDecl(hasStdContainerName(), isFromStdNamespace())));
}
/// \brief Returns a TypeMatcher that matches typedefs for standard iterators
/// inside records with a standard container name.
TypeMatcher typedefIterator() {
return typedefType(hasDeclaration(standardIterator()));
}
/// \brief Returns a TypeMatcher that matches records named for standard
/// iterators nested inside records named for standard containers.
TypeMatcher nestedIterator() {
return recordType(hasDeclaration(standardIterator()));
}
/// \brief Returns a TypeMatcher that matches types declared with using
/// declarations and which name standard iterators for standard containers.
TypeMatcher iteratorFromUsingDeclaration() {
auto HasIteratorDecl = hasDeclaration(namedDecl(hasStdIteratorName()));
// Types resulting from using declarations are represented by elaboratedType.
return elaboratedType(allOf(
// Unwrap the nested name specifier to test for one of the standard
// containers.
hasQualifier(specifiesType(templateSpecializationType(hasDeclaration(
namedDecl(hasStdContainerName(), isFromStdNamespace()))))),
// the named type is what comes after the final '::' in the type. It
// should name one of the standard iterator names.
namesType(
anyOf(typedefType(HasIteratorDecl), recordType(HasIteratorDecl)))));
}
/// \brief This matcher returns declaration statements that contain variable
/// declarations with written non-list initializer for standard iterators.
StatementMatcher makeIteratorDeclMatcher() {
return declStmt(
// At least one varDecl should be a child of the declStmt to ensure
// it's a declaration list and avoid matching other declarations,
// e.g. using directives.
has(varDecl()),
unless(has(varDecl(anyOf(
unless(hasWrittenNonListInitializer()), hasType(autoType()),
unless(hasType(
isSugarFor(anyOf(typedefIterator(), nestedIterator(),
iteratorFromUsingDeclaration())))))))))
.bind(IteratorDeclStmtId);
}
StatementMatcher makeDeclWithNewMatcher() {
return declStmt(
has(varDecl()),
unless(has(varDecl(anyOf(
unless(hasInitializer(ignoringParenImpCasts(cxxNewExpr()))),
// Skip declarations that are already using auto.
anyOf(hasType(autoType()),
hasType(pointerType(pointee(autoType())))),
// FIXME: TypeLoc information is not reliable where CV
// qualifiers are concerned so these types can't be
// handled for now.
hasType(pointerType(
pointee(hasCanonicalType(hasLocalQualifiers())))),
// FIXME: Handle function pointers. For now we ignore them
// because the replacement replaces the entire type
// specifier source range which includes the identifier.
hasType(pointsTo(
pointsTo(parenType(innerType(functionType()))))))))))
.bind(DeclWithNewId);
}
} // namespace
void UseAutoCheck::registerMatchers(MatchFinder *Finder) {
// Only register the matchers for C++; the functionality currently does not
// provide any benefit to other languages, despite being benign.
if (getLangOpts().CPlusPlus) {
Finder->addMatcher(makeIteratorDeclMatcher(), this);
Finder->addMatcher(makeDeclWithNewMatcher(), this);
}
}
void UseAutoCheck::replaceIterators(const DeclStmt *D, ASTContext *Context) {
for (const auto *Dec : D->decls()) {
const auto *V = cast<VarDecl>(Dec);
const Expr *ExprInit = V->getInit();
// Skip expressions with cleanups from the intializer expression.
if (const auto *E = dyn_cast<ExprWithCleanups>(ExprInit))
ExprInit = E->getSubExpr();
const auto *Construct = dyn_cast<CXXConstructExpr>(ExprInit);
if (!Construct)
continue;
// Ensure that the constructor receives a single argument.
if (Construct->getNumArgs() != 1)
return;
// Drill down to the as-written initializer.
const Expr *E = (*Construct->arg_begin())->IgnoreParenImpCasts();
if (E != E->IgnoreConversionOperator()) {
// We hit a conversion operator. Early-out now as they imply an implicit
// conversion from a different type. Could also mean an explicit
// conversion from the same type but that's pretty rare.
return;
}
if (const auto *NestedConstruct = dyn_cast<CXXConstructExpr>(E)) {
// If we ran into an implicit conversion contructor, can't convert.
//
// FIXME: The following only checks if the constructor can be used
// implicitly, not if it actually was. Cases where the converting
// constructor was used explicitly won't get converted.
if (NestedConstruct->getConstructor()->isConvertingConstructor(false))
return;
}
if (!Context->hasSameType(V->getType(), E->getType()))
return;
}
// Get the type location using the first declaration.
const auto *V = cast<VarDecl>(*D->decl_begin());
// WARNING: TypeLoc::getSourceRange() will include the identifier for things
// like function pointers. Not a concern since this action only works with
// iterators but something to keep in mind in the future.
SourceRange Range(V->getTypeSourceInfo()->getTypeLoc().getSourceRange());
diag(Range.getBegin(), "use auto when declaring iterators")
<< FixItHint::CreateReplacement(Range, "auto");
}
void UseAutoCheck::replaceNew(const DeclStmt *D, ASTContext *Context) {
const auto *FirstDecl = dyn_cast<VarDecl>(*D->decl_begin());
// Ensure that there is at least one VarDecl within the DeclStmt.
if (!FirstDecl)
return;
const QualType FirstDeclType = FirstDecl->getType().getCanonicalType();
std::vector<SourceLocation> StarLocations;
for (const auto *Dec : D->decls()) {
const auto *V = cast<VarDecl>(Dec);
// Ensure that every DeclStmt child is a VarDecl.
if (!V)
return;
const auto *NewExpr = cast<CXXNewExpr>(V->getInit()->IgnoreParenImpCasts());
// Ensure that every VarDecl has a CXXNewExpr initializer.
if (!NewExpr)
return;
// If VarDecl and Initializer have mismatching unqualified types.
if (!Context->hasSameUnqualifiedType(V->getType(), NewExpr->getType()))
return;
// Remove explicitly written '*' from declarations where there's more than
// one declaration in the declaration list.
if (Dec == *D->decl_begin())
continue;
// All subsequent declarations should match the same non-decorated type.
if (FirstDeclType != V->getType().getCanonicalType())
return;
auto Q = V->getTypeSourceInfo()->getTypeLoc().getAs<PointerTypeLoc>();
while (!Q.isNull()) {
StarLocations.push_back(Q.getStarLoc());
Q = Q.getNextTypeLoc().getAs<PointerTypeLoc>();
}
}
// FIXME: There is, however, one case we can address: when the VarDecl pointee
// is the same as the initializer, just more CV-qualified. However, TypeLoc
// information is not reliable where CV qualifiers are concerned so we can't
// do anything about this case for now.
SourceRange Range(
FirstDecl->getTypeSourceInfo()->getTypeLoc().getSourceRange());
auto Diag = diag(Range.getBegin(), "use auto when initializing with new"
" to avoid duplicating the type name");
// Space after 'auto' to handle cases where the '*' in the pointer type is
// next to the identifier. This avoids changing 'int *p' into 'autop'.
Diag << FixItHint::CreateReplacement(Range, "auto ");
// Remove '*' from declarations using the saved star locations.
for (const auto &Loc : StarLocations) {
Diag << FixItHint::CreateReplacement(Loc, "");
}
}
void UseAutoCheck::check(const MatchFinder::MatchResult &Result) {
if (const auto *Decl = Result.Nodes.getNodeAs<DeclStmt>(IteratorDeclStmtId)) {
replaceIterators(Decl, Result.Context);
} else if (const auto *Decl =
Result.Nodes.getNodeAs<DeclStmt>(DeclWithNewId)) {
replaceNew(Decl, Result.Context);
} else {
llvm_unreachable("Bad Callback. No node provided.");
}
}
} // namespace modernize
} // namespace tidy
} // namespace clang