llvm-project/clang/lib/Sema/SemaLookup.cpp

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//===--------------------- SemaLookup.cpp - Name Lookup ------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements name lookup for C, C++, Objective-C, and
// Objective-C++.
//
//===----------------------------------------------------------------------===//
#include "Sema.h"
#include "Lookup.h"
#include "clang/AST/ASTContext.h"
#include "clang/AST/CXXInheritance.h"
#include "clang/AST/Decl.h"
#include "clang/AST/DeclCXX.h"
#include "clang/AST/DeclObjC.h"
#include "clang/AST/DeclTemplate.h"
#include "clang/AST/Expr.h"
#include "clang/AST/ExprCXX.h"
#include "clang/Parse/DeclSpec.h"
#include "clang/Basic/Builtins.h"
#include "clang/Basic/LangOptions.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/Support/ErrorHandling.h"
#include <list>
#include <set>
#include <vector>
#include <iterator>
#include <utility>
#include <algorithm>
using namespace clang;
namespace {
class UnqualUsingEntry {
const DeclContext *Nominated;
const DeclContext *CommonAncestor;
public:
UnqualUsingEntry(const DeclContext *Nominated,
const DeclContext *CommonAncestor)
: Nominated(Nominated), CommonAncestor(CommonAncestor) {
}
const DeclContext *getCommonAncestor() const {
return CommonAncestor;
}
const DeclContext *getNominatedNamespace() const {
return Nominated;
}
// Sort by the pointer value of the common ancestor.
struct Comparator {
bool operator()(const UnqualUsingEntry &L, const UnqualUsingEntry &R) {
return L.getCommonAncestor() < R.getCommonAncestor();
}
bool operator()(const UnqualUsingEntry &E, const DeclContext *DC) {
return E.getCommonAncestor() < DC;
}
bool operator()(const DeclContext *DC, const UnqualUsingEntry &E) {
return DC < E.getCommonAncestor();
}
};
};
/// A collection of using directives, as used by C++ unqualified
/// lookup.
class UnqualUsingDirectiveSet {
typedef llvm::SmallVector<UnqualUsingEntry, 8> ListTy;
ListTy list;
llvm::SmallPtrSet<DeclContext*, 8> visited;
public:
UnqualUsingDirectiveSet() {}
void visitScopeChain(Scope *S, Scope *InnermostFileScope) {
// C++ [namespace.udir]p1:
// During unqualified name lookup, the names appear as if they
// were declared in the nearest enclosing namespace which contains
// both the using-directive and the nominated namespace.
DeclContext *InnermostFileDC
= static_cast<DeclContext*>(InnermostFileScope->getEntity());
assert(InnermostFileDC && InnermostFileDC->isFileContext());
for (; S; S = S->getParent()) {
if (DeclContext *Ctx = static_cast<DeclContext*>(S->getEntity())) {
DeclContext *EffectiveDC = (Ctx->isFileContext() ? Ctx : InnermostFileDC);
visit(Ctx, EffectiveDC);
} else {
Scope::udir_iterator I = S->using_directives_begin(),
End = S->using_directives_end();
for (; I != End; ++I)
visit(I->getAs<UsingDirectiveDecl>(), InnermostFileDC);
}
}
}
// Visits a context and collect all of its using directives
// recursively. Treats all using directives as if they were
// declared in the context.
//
// A given context is only every visited once, so it is important
// that contexts be visited from the inside out in order to get
// the effective DCs right.
void visit(DeclContext *DC, DeclContext *EffectiveDC) {
if (!visited.insert(DC))
return;
addUsingDirectives(DC, EffectiveDC);
}
// Visits a using directive and collects all of its using
// directives recursively. Treats all using directives as if they
// were declared in the effective DC.
void visit(UsingDirectiveDecl *UD, DeclContext *EffectiveDC) {
DeclContext *NS = UD->getNominatedNamespace();
if (!visited.insert(NS))
return;
addUsingDirective(UD, EffectiveDC);
addUsingDirectives(NS, EffectiveDC);
}
// Adds all the using directives in a context (and those nominated
// by its using directives, transitively) as if they appeared in
// the given effective context.
void addUsingDirectives(DeclContext *DC, DeclContext *EffectiveDC) {
llvm::SmallVector<DeclContext*,4> queue;
while (true) {
DeclContext::udir_iterator I, End;
for (llvm::tie(I, End) = DC->getUsingDirectives(); I != End; ++I) {
UsingDirectiveDecl *UD = *I;
DeclContext *NS = UD->getNominatedNamespace();
if (visited.insert(NS)) {
addUsingDirective(UD, EffectiveDC);
queue.push_back(NS);
}
}
if (queue.empty())
return;
DC = queue.back();
queue.pop_back();
}
}
// Add a using directive as if it had been declared in the given
// context. This helps implement C++ [namespace.udir]p3:
// The using-directive is transitive: if a scope contains a
// using-directive that nominates a second namespace that itself
// contains using-directives, the effect is as if the
// using-directives from the second namespace also appeared in
// the first.
void addUsingDirective(UsingDirectiveDecl *UD, DeclContext *EffectiveDC) {
// Find the common ancestor between the effective context and
// the nominated namespace.
DeclContext *Common = UD->getNominatedNamespace();
while (!Common->Encloses(EffectiveDC))
Common = Common->getParent();
Common = Common->getPrimaryContext();
list.push_back(UnqualUsingEntry(UD->getNominatedNamespace(), Common));
}
void done() {
std::sort(list.begin(), list.end(), UnqualUsingEntry::Comparator());
}
typedef ListTy::iterator iterator;
typedef ListTy::const_iterator const_iterator;
iterator begin() { return list.begin(); }
iterator end() { return list.end(); }
const_iterator begin() const { return list.begin(); }
const_iterator end() const { return list.end(); }
std::pair<const_iterator,const_iterator>
getNamespacesFor(DeclContext *DC) const {
return std::equal_range(begin(), end(), DC->getPrimaryContext(),
UnqualUsingEntry::Comparator());
}
};
}
static bool IsAcceptableIDNS(NamedDecl *D, unsigned IDNS) {
return D->isInIdentifierNamespace(IDNS);
}
static bool IsAcceptableOperatorName(NamedDecl *D, unsigned IDNS) {
return D->isInIdentifierNamespace(IDNS) &&
!D->getDeclContext()->isRecord();
}
static bool IsAcceptableNestedNameSpecifierName(NamedDecl *D, unsigned IDNS) {
// This lookup ignores everything that isn't a type.
// This is a fast check for the far most common case.
if (D->isInIdentifierNamespace(Decl::IDNS_Tag))
return true;
if (isa<UsingShadowDecl>(D))
D = cast<UsingShadowDecl>(D)->getTargetDecl();
return isa<TypeDecl>(D);
}
static bool IsAcceptableNamespaceName(NamedDecl *D, unsigned IDNS) {
// We don't need to look through using decls here because
// using decls aren't allowed to name namespaces.
return isa<NamespaceDecl>(D) || isa<NamespaceAliasDecl>(D);
}
/// Gets the default result filter for the given lookup.
static inline
LookupResult::ResultFilter getResultFilter(Sema::LookupNameKind NameKind) {
switch (NameKind) {
case Sema::LookupOrdinaryName:
case Sema::LookupTagName:
case Sema::LookupMemberName:
case Sema::LookupRedeclarationWithLinkage: // FIXME: check linkage, scoping
case Sema::LookupUsingDeclName:
case Sema::LookupObjCProtocolName:
case Sema::LookupObjCImplementationName:
return &IsAcceptableIDNS;
case Sema::LookupOperatorName:
return &IsAcceptableOperatorName;
case Sema::LookupNestedNameSpecifierName:
return &IsAcceptableNestedNameSpecifierName;
case Sema::LookupNamespaceName:
return &IsAcceptableNamespaceName;
}
llvm_unreachable("unkknown lookup kind");
return 0;
}
// Retrieve the set of identifier namespaces that correspond to a
// specific kind of name lookup.
static inline unsigned getIDNS(Sema::LookupNameKind NameKind,
bool CPlusPlus,
bool Redeclaration) {
unsigned IDNS = 0;
switch (NameKind) {
case Sema::LookupOrdinaryName:
case Sema::LookupOperatorName:
case Sema::LookupRedeclarationWithLinkage:
IDNS = Decl::IDNS_Ordinary;
if (CPlusPlus) {
IDNS |= Decl::IDNS_Tag | Decl::IDNS_Member;
if (Redeclaration) IDNS |= Decl::IDNS_TagFriend | Decl::IDNS_OrdinaryFriend;
}
break;
case Sema::LookupTagName:
IDNS = Decl::IDNS_Tag;
if (CPlusPlus && Redeclaration)
IDNS |= Decl::IDNS_TagFriend;
break;
case Sema::LookupMemberName:
IDNS = Decl::IDNS_Member;
if (CPlusPlus)
IDNS |= Decl::IDNS_Tag | Decl::IDNS_Ordinary;
break;
case Sema::LookupNestedNameSpecifierName:
case Sema::LookupNamespaceName:
IDNS = Decl::IDNS_Ordinary | Decl::IDNS_Tag | Decl::IDNS_Member;
break;
case Sema::LookupUsingDeclName:
IDNS = Decl::IDNS_Ordinary | Decl::IDNS_Tag
| Decl::IDNS_Member | Decl::IDNS_Using;
break;
case Sema::LookupObjCProtocolName:
IDNS = Decl::IDNS_ObjCProtocol;
break;
case Sema::LookupObjCImplementationName:
IDNS = Decl::IDNS_ObjCImplementation;
break;
}
return IDNS;
}
void LookupResult::configure() {
IDNS = getIDNS(LookupKind,
SemaRef.getLangOptions().CPlusPlus,
isForRedeclaration());
IsAcceptableFn = getResultFilter(LookupKind);
}
// Necessary because CXXBasePaths is not complete in Sema.h
void LookupResult::deletePaths(CXXBasePaths *Paths) {
delete Paths;
}
/// Resolves the result kind of this lookup.
void LookupResult::resolveKind() {
unsigned N = Decls.size();
// Fast case: no possible ambiguity.
if (N == 0) {
assert(ResultKind == NotFound || ResultKind == NotFoundInCurrentInstantiation);
return;
}
// If there's a single decl, we need to examine it to decide what
// kind of lookup this is.
if (N == 1) {
if (isa<FunctionTemplateDecl>(*Decls.begin()))
ResultKind = FoundOverloaded;
else if (isa<UnresolvedUsingValueDecl>(*Decls.begin()))
ResultKind = FoundUnresolvedValue;
return;
}
// Don't do any extra resolution if we've already resolved as ambiguous.
if (ResultKind == Ambiguous) return;
llvm::SmallPtrSet<NamedDecl*, 16> Unique;
bool Ambiguous = false;
bool HasTag = false, HasFunction = false, HasNonFunction = false;
bool HasFunctionTemplate = false, HasUnresolved = false;
unsigned UniqueTagIndex = 0;
unsigned I = 0;
while (I < N) {
NamedDecl *D = Decls[I]->getUnderlyingDecl();
D = cast<NamedDecl>(D->getCanonicalDecl());
if (!Unique.insert(D)) {
// If it's not unique, pull something off the back (and
// continue at this index).
Decls[I] = Decls[--N];
} else {
// Otherwise, do some decl type analysis and then continue.
if (isa<UnresolvedUsingValueDecl>(D)) {
HasUnresolved = true;
} else if (isa<TagDecl>(D)) {
if (HasTag)
Ambiguous = true;
UniqueTagIndex = I;
HasTag = true;
} else if (isa<FunctionTemplateDecl>(D)) {
HasFunction = true;
HasFunctionTemplate = true;
} else if (isa<FunctionDecl>(D)) {
HasFunction = true;
} else {
if (HasNonFunction)
Ambiguous = true;
HasNonFunction = true;
}
I++;
}
}
// C++ [basic.scope.hiding]p2:
// A class name or enumeration name can be hidden by the name of
// an object, function, or enumerator declared in the same
// scope. If a class or enumeration name and an object, function,
// or enumerator are declared in the same scope (in any order)
// with the same name, the class or enumeration name is hidden
// wherever the object, function, or enumerator name is visible.
// But it's still an error if there are distinct tag types found,
// even if they're not visible. (ref?)
if (HideTags && HasTag && !Ambiguous &&
(HasFunction || HasNonFunction || HasUnresolved))
Decls[UniqueTagIndex] = Decls[--N];
Decls.set_size(N);
if (HasNonFunction && (HasFunction || HasUnresolved))
Ambiguous = true;
if (Ambiguous)
setAmbiguous(LookupResult::AmbiguousReference);
else if (HasUnresolved)
ResultKind = LookupResult::FoundUnresolvedValue;
else if (N > 1 || HasFunctionTemplate)
ResultKind = LookupResult::FoundOverloaded;
else
ResultKind = LookupResult::Found;
}
void LookupResult::addDeclsFromBasePaths(const CXXBasePaths &P) {
CXXBasePaths::paths_iterator I, E;
DeclContext::lookup_iterator DI, DE;
for (I = P.begin(), E = P.end(); I != E; ++I)
for (llvm::tie(DI,DE) = I->Decls; DI != DE; ++DI)
addDecl(*DI);
}
void LookupResult::setAmbiguousBaseSubobjects(CXXBasePaths &P) {
Paths = new CXXBasePaths;
Paths->swap(P);
addDeclsFromBasePaths(*Paths);
resolveKind();
setAmbiguous(AmbiguousBaseSubobjects);
}
void LookupResult::setAmbiguousBaseSubobjectTypes(CXXBasePaths &P) {
Paths = new CXXBasePaths;
Paths->swap(P);
addDeclsFromBasePaths(*Paths);
resolveKind();
setAmbiguous(AmbiguousBaseSubobjectTypes);
}
void LookupResult::print(llvm::raw_ostream &Out) {
Out << Decls.size() << " result(s)";
if (isAmbiguous()) Out << ", ambiguous";
if (Paths) Out << ", base paths present";
for (iterator I = begin(), E = end(); I != E; ++I) {
Out << "\n";
(*I)->print(Out, 2);
}
}
// Adds all qualifying matches for a name within a decl context to the
// given lookup result. Returns true if any matches were found.
static bool LookupDirect(LookupResult &R, const DeclContext *DC) {
bool Found = false;
DeclContext::lookup_const_iterator I, E;
for (llvm::tie(I, E) = DC->lookup(R.getLookupName()); I != E; ++I) {
NamedDecl *D = *I;
if (R.isAcceptableDecl(D)) {
R.addDecl(D);
Found = true;
}
}
if (R.getLookupName().getNameKind()
!= DeclarationName::CXXConversionFunctionName ||
R.getLookupName().getCXXNameType()->isDependentType() ||
!isa<CXXRecordDecl>(DC))
return Found;
// C++ [temp.mem]p6:
// A specialization of a conversion function template is not found by
// name lookup. Instead, any conversion function templates visible in the
// context of the use are considered. [...]
const CXXRecordDecl *Record = cast<CXXRecordDecl>(DC);
if (!Record->isDefinition())
return Found;
const UnresolvedSetImpl *Unresolved = Record->getConversionFunctions();
for (UnresolvedSetImpl::iterator U = Unresolved->begin(),
UEnd = Unresolved->end(); U != UEnd; ++U) {
FunctionTemplateDecl *ConvTemplate = dyn_cast<FunctionTemplateDecl>(*U);
if (!ConvTemplate)
continue;
// When we're performing lookup for the purposes of redeclaration, just
// add the conversion function template. When we deduce template
// arguments for specializations, we'll end up unifying the return
// type of the new declaration with the type of the function template.
if (R.isForRedeclaration()) {
R.addDecl(ConvTemplate);
Found = true;
continue;
}
// C++ [temp.mem]p6:
// [...] For each such operator, if argument deduction succeeds
// (14.9.2.3), the resulting specialization is used as if found by
// name lookup.
//
// When referencing a conversion function for any purpose other than
// a redeclaration (such that we'll be building an expression with the
// result), perform template argument deduction and place the
// specialization into the result set. We do this to avoid forcing all
// callers to perform special deduction for conversion functions.
Sema::TemplateDeductionInfo Info(R.getSema().Context);
FunctionDecl *Specialization = 0;
const FunctionProtoType *ConvProto
= ConvTemplate->getTemplatedDecl()->getType()->getAs<FunctionProtoType>();
assert(ConvProto && "Nonsensical conversion function template type");
// Compute the type of the function that we would expect the conversion
// function to have, if it were to match the name given.
// FIXME: Calling convention!
QualType ExpectedType
= R.getSema().Context.getFunctionType(R.getLookupName().getCXXNameType(),
0, 0, ConvProto->isVariadic(),
ConvProto->getTypeQuals(),
false, false, 0, 0,
ConvProto->getNoReturnAttr());
// Perform template argument deduction against the type that we would
// expect the function to have.
if (R.getSema().DeduceTemplateArguments(ConvTemplate, 0, ExpectedType,
Specialization, Info)
== Sema::TDK_Success) {
R.addDecl(Specialization);
Found = true;
}
}
return Found;
}
// Performs C++ unqualified lookup into the given file context.
static bool
CppNamespaceLookup(LookupResult &R, ASTContext &Context, DeclContext *NS,
UnqualUsingDirectiveSet &UDirs) {
assert(NS && NS->isFileContext() && "CppNamespaceLookup() requires namespace!");
// Perform direct name lookup into the LookupCtx.
bool Found = LookupDirect(R, NS);
// Perform direct name lookup into the namespaces nominated by the
// using directives whose common ancestor is this namespace.
UnqualUsingDirectiveSet::const_iterator UI, UEnd;
llvm::tie(UI, UEnd) = UDirs.getNamespacesFor(NS);
for (; UI != UEnd; ++UI)
if (LookupDirect(R, UI->getNominatedNamespace()))
Found = true;
R.resolveKind();
return Found;
}
static bool isNamespaceOrTranslationUnitScope(Scope *S) {
if (DeclContext *Ctx = static_cast<DeclContext*>(S->getEntity()))
return Ctx->isFileContext();
return false;
}
// Find the next outer declaration context corresponding to this scope.
static DeclContext *findOuterContext(Scope *S) {
for (S = S->getParent(); S; S = S->getParent())
if (S->getEntity())
return static_cast<DeclContext *>(S->getEntity())->getPrimaryContext();
return 0;
}
bool Sema::CppLookupName(LookupResult &R, Scope *S) {
assert(getLangOptions().CPlusPlus && "Can perform only C++ lookup");
DeclarationName Name = R.getLookupName();
Scope *Initial = S;
IdentifierResolver::iterator
I = IdResolver.begin(Name),
IEnd = IdResolver.end();
// First we lookup local scope.
// We don't consider using-directives, as per 7.3.4.p1 [namespace.udir]
// ...During unqualified name lookup (3.4.1), the names appear as if
// they were declared in the nearest enclosing namespace which contains
// both the using-directive and the nominated namespace.
// [Note: in this context, "contains" means "contains directly or
// indirectly".
//
// For example:
// namespace A { int i; }
// void foo() {
// int i;
// {
// using namespace A;
// ++i; // finds local 'i', A::i appears at global scope
// }
// }
//
for (; S && !isNamespaceOrTranslationUnitScope(S); S = S->getParent()) {
// Check whether the IdResolver has anything in this scope.
bool Found = false;
for (; I != IEnd && S->isDeclScope(DeclPtrTy::make(*I)); ++I) {
if (R.isAcceptableDecl(*I)) {
Found = true;
R.addDecl(*I);
}
}
if (Found) {
R.resolveKind();
return true;
}
if (DeclContext *Ctx = static_cast<DeclContext*>(S->getEntity())) {
DeclContext *OuterCtx = findOuterContext(S);
for (; Ctx && Ctx->getPrimaryContext() != OuterCtx;
Ctx = Ctx->getLookupParent()) {
// We do not directly look into function or method contexts
// (since all local variables are found via the identifier
// changes) or in transparent contexts (since those entities
// will be found in the nearest enclosing non-transparent
// context).
if (Ctx->isFunctionOrMethod() || Ctx->isTransparentContext())
continue;
// Perform qualified name lookup into this context.
// FIXME: In some cases, we know that every name that could be found by
// this qualified name lookup will also be on the identifier chain. For
// example, inside a class without any base classes, we never need to
// perform qualified lookup because all of the members are on top of the
// identifier chain.
if (LookupQualifiedName(R, Ctx, /*InUnqualifiedLookup=*/true))
return true;
}
}
}
// Stop if we ran out of scopes.
// FIXME: This really, really shouldn't be happening.
if (!S) return false;
// Collect UsingDirectiveDecls in all scopes, and recursively all
// nominated namespaces by those using-directives.
//
2009-05-16 15:39:55 +08:00
// FIXME: Cache this sorted list in Scope structure, and DeclContext, so we
// don't build it for each lookup!
UnqualUsingDirectiveSet UDirs;
UDirs.visitScopeChain(Initial, S);
UDirs.done();
// Lookup namespace scope, and global scope.
// Unqualified name lookup in C++ requires looking into scopes
// that aren't strictly lexical, and therefore we walk through the
// context as well as walking through the scopes.
for (; S; S = S->getParent()) {
DeclContext *Ctx = static_cast<DeclContext *>(S->getEntity());
if (Ctx && Ctx->isTransparentContext())
continue;
// Check whether the IdResolver has anything in this scope.
bool Found = false;
for (; I != IEnd && S->isDeclScope(DeclPtrTy::make(*I)); ++I) {
if (R.isAcceptableDecl(*I)) {
// We found something. Look for anything else in our scope
// with this same name and in an acceptable identifier
// namespace, so that we can construct an overload set if we
// need to.
Found = true;
R.addDecl(*I);
}
}
if (Ctx) {
assert(Ctx->isFileContext() &&
"We should have been looking only at file context here already.");
// Look into context considering using-directives.
if (CppNamespaceLookup(R, Context, Ctx, UDirs))
Found = true;
}
if (Found) {
R.resolveKind();
return true;
}
if (R.isForRedeclaration() && Ctx && !Ctx->isTransparentContext())
return false;
}
return !R.empty();
}
/// @brief Perform unqualified name lookup starting from a given
/// scope.
///
/// Unqualified name lookup (C++ [basic.lookup.unqual], C99 6.2.1) is
/// used to find names within the current scope. For example, 'x' in
/// @code
/// int x;
/// int f() {
/// return x; // unqualified name look finds 'x' in the global scope
/// }
/// @endcode
///
/// Different lookup criteria can find different names. For example, a
/// particular scope can have both a struct and a function of the same
/// name, and each can be found by certain lookup criteria. For more
/// information about lookup criteria, see the documentation for the
/// class LookupCriteria.
///
/// @param S The scope from which unqualified name lookup will
/// begin. If the lookup criteria permits, name lookup may also search
/// in the parent scopes.
///
/// @param Name The name of the entity that we are searching for.
///
Implicitly declare certain C library functions (malloc, strcpy, memmove, etc.) when we perform name lookup on them. This ensures that we produce the correct signature for these functions, which has two practical impacts: 1) When we're supporting the "implicit function declaration" feature of C99, these functions will be implicitly declared with the right signature rather than as a function returning "int" with no prototype. See PR3541 for the reason why this is important (hint: GCC always predeclares these functions). 2) If users attempt to redeclare one of these library functions with an incompatible signature, we produce a hard error. This patch does a little bit of work to give reasonable error messages. For example, when we hit case #1 we complain that we're implicitly declaring this function with a specific signature, and then we give a note that asks the user to include the appropriate header (e.g., "please include <stdlib.h> or explicitly declare 'malloc'"). In case #2, we show the type of the implicit builtin that was incorrectly declared, so the user can see the problem. We could do better here: for example, when displaying this latter error message we say something like: 'strcpy' was implicitly declared here with type 'char *(char *, char const *)' but we should really print out a fake code line showing the declaration, like this: 'strcpy' was implicitly declared here as: char *strcpy(char *, char const *) This would also be good for printing built-in candidates with C++ operator overloading. The set of C library functions supported by this patch includes all functions from the C99 specification's <stdlib.h> and <string.h> that (a) are predefined by GCC and (b) have signatures that could cause codegen issues if they are treated as functions with no prototype returning and int. Future work could extend this set of functions to other C library functions that we know about. llvm-svn: 64504
2009-02-14 07:20:09 +08:00
/// @param Loc If provided, the source location where we're performing
/// name lookup. At present, this is only used to produce diagnostics when
Implicitly declare certain C library functions (malloc, strcpy, memmove, etc.) when we perform name lookup on them. This ensures that we produce the correct signature for these functions, which has two practical impacts: 1) When we're supporting the "implicit function declaration" feature of C99, these functions will be implicitly declared with the right signature rather than as a function returning "int" with no prototype. See PR3541 for the reason why this is important (hint: GCC always predeclares these functions). 2) If users attempt to redeclare one of these library functions with an incompatible signature, we produce a hard error. This patch does a little bit of work to give reasonable error messages. For example, when we hit case #1 we complain that we're implicitly declaring this function with a specific signature, and then we give a note that asks the user to include the appropriate header (e.g., "please include <stdlib.h> or explicitly declare 'malloc'"). In case #2, we show the type of the implicit builtin that was incorrectly declared, so the user can see the problem. We could do better here: for example, when displaying this latter error message we say something like: 'strcpy' was implicitly declared here with type 'char *(char *, char const *)' but we should really print out a fake code line showing the declaration, like this: 'strcpy' was implicitly declared here as: char *strcpy(char *, char const *) This would also be good for printing built-in candidates with C++ operator overloading. The set of C library functions supported by this patch includes all functions from the C99 specification's <stdlib.h> and <string.h> that (a) are predefined by GCC and (b) have signatures that could cause codegen issues if they are treated as functions with no prototype returning and int. Future work could extend this set of functions to other C library functions that we know about. llvm-svn: 64504
2009-02-14 07:20:09 +08:00
/// C library functions (like "malloc") are implicitly declared.
///
/// @returns The result of name lookup, which includes zero or more
/// declarations and possibly additional information used to diagnose
/// ambiguities.
bool Sema::LookupName(LookupResult &R, Scope *S, bool AllowBuiltinCreation) {
DeclarationName Name = R.getLookupName();
if (!Name) return false;
LookupNameKind NameKind = R.getLookupKind();
if (!getLangOptions().CPlusPlus) {
// Unqualified name lookup in C/Objective-C is purely lexical, so
// search in the declarations attached to the name.
if (NameKind == Sema::LookupRedeclarationWithLinkage) {
// Find the nearest non-transparent declaration scope.
while (!(S->getFlags() & Scope::DeclScope) ||
(S->getEntity() &&
static_cast<DeclContext *>(S->getEntity())
->isTransparentContext()))
S = S->getParent();
}
unsigned IDNS = R.getIdentifierNamespace();
// Scan up the scope chain looking for a decl that matches this
// identifier that is in the appropriate namespace. This search
// should not take long, as shadowing of names is uncommon, and
// deep shadowing is extremely uncommon.
bool LeftStartingScope = false;
for (IdentifierResolver::iterator I = IdResolver.begin(Name),
IEnd = IdResolver.end();
I != IEnd; ++I)
Initial implementation of function overloading in C. This commit adds a new attribute, "overloadable", that enables C++ function overloading in C. The attribute can only be added to function declarations, e.g., int *f(int) __attribute__((overloadable)); If the "overloadable" attribute exists on a function with a given name, *all* functions with that name (and in that scope) must have the "overloadable" attribute. Sets of overloaded functions with the "overloadable" attribute then follow the normal C++ rules for overloaded functions, e.g., overloads must have different parameter-type-lists from each other. When calling an overloaded function in C, we follow the same overloading rules as C++, with three extensions to the set of standard conversions: - A value of a given struct or union type T can be converted to the type T. This is just the identity conversion. (In C++, this would go through a copy constructor). - A value of pointer type T* can be converted to a value of type U* if T and U are compatible types. This conversion has Conversion rank (it's considered a pointer conversion in C). - A value of type T can be converted to a value of type U if T and U are compatible (and are not both pointer types). This conversion has Conversion rank (it's considered to be a new kind of conversion unique to C, a "compatible" conversion). Known defects (and, therefore, next steps): 1) The standard-conversion handling does not understand conversions involving _Complex or vector extensions, so it is likely to get these wrong. We need to add these conversions. 2) All overloadable functions with the same name will have the same linkage name, which means we'll get a collision in the linker (if not sooner). We'll need to mangle the names of these functions. llvm-svn: 64336
2009-02-12 07:02:49 +08:00
if ((*I)->isInIdentifierNamespace(IDNS)) {
if (NameKind == LookupRedeclarationWithLinkage) {
// Determine whether this (or a previous) declaration is
// out-of-scope.
if (!LeftStartingScope && !S->isDeclScope(DeclPtrTy::make(*I)))
LeftStartingScope = true;
// If we found something outside of our starting scope that
// does not have linkage, skip it.
if (LeftStartingScope && !((*I)->hasLinkage()))
continue;
}
R.addDecl(*I);
if ((*I)->getAttr<OverloadableAttr>()) {
Initial implementation of function overloading in C. This commit adds a new attribute, "overloadable", that enables C++ function overloading in C. The attribute can only be added to function declarations, e.g., int *f(int) __attribute__((overloadable)); If the "overloadable" attribute exists on a function with a given name, *all* functions with that name (and in that scope) must have the "overloadable" attribute. Sets of overloaded functions with the "overloadable" attribute then follow the normal C++ rules for overloaded functions, e.g., overloads must have different parameter-type-lists from each other. When calling an overloaded function in C, we follow the same overloading rules as C++, with three extensions to the set of standard conversions: - A value of a given struct or union type T can be converted to the type T. This is just the identity conversion. (In C++, this would go through a copy constructor). - A value of pointer type T* can be converted to a value of type U* if T and U are compatible types. This conversion has Conversion rank (it's considered a pointer conversion in C). - A value of type T can be converted to a value of type U if T and U are compatible (and are not both pointer types). This conversion has Conversion rank (it's considered to be a new kind of conversion unique to C, a "compatible" conversion). Known defects (and, therefore, next steps): 1) The standard-conversion handling does not understand conversions involving _Complex or vector extensions, so it is likely to get these wrong. We need to add these conversions. 2) All overloadable functions with the same name will have the same linkage name, which means we'll get a collision in the linker (if not sooner). We'll need to mangle the names of these functions. llvm-svn: 64336
2009-02-12 07:02:49 +08:00
// If this declaration has the "overloadable" attribute, we
// might have a set of overloaded functions.
// Figure out what scope the identifier is in.
while (!(S->getFlags() & Scope::DeclScope) ||
!S->isDeclScope(DeclPtrTy::make(*I)))
Initial implementation of function overloading in C. This commit adds a new attribute, "overloadable", that enables C++ function overloading in C. The attribute can only be added to function declarations, e.g., int *f(int) __attribute__((overloadable)); If the "overloadable" attribute exists on a function with a given name, *all* functions with that name (and in that scope) must have the "overloadable" attribute. Sets of overloaded functions with the "overloadable" attribute then follow the normal C++ rules for overloaded functions, e.g., overloads must have different parameter-type-lists from each other. When calling an overloaded function in C, we follow the same overloading rules as C++, with three extensions to the set of standard conversions: - A value of a given struct or union type T can be converted to the type T. This is just the identity conversion. (In C++, this would go through a copy constructor). - A value of pointer type T* can be converted to a value of type U* if T and U are compatible types. This conversion has Conversion rank (it's considered a pointer conversion in C). - A value of type T can be converted to a value of type U if T and U are compatible (and are not both pointer types). This conversion has Conversion rank (it's considered to be a new kind of conversion unique to C, a "compatible" conversion). Known defects (and, therefore, next steps): 1) The standard-conversion handling does not understand conversions involving _Complex or vector extensions, so it is likely to get these wrong. We need to add these conversions. 2) All overloadable functions with the same name will have the same linkage name, which means we'll get a collision in the linker (if not sooner). We'll need to mangle the names of these functions. llvm-svn: 64336
2009-02-12 07:02:49 +08:00
S = S->getParent();
// Find the last declaration in this scope (with the same
// name, naturally).
IdentifierResolver::iterator LastI = I;
for (++LastI; LastI != IEnd; ++LastI) {
if (!S->isDeclScope(DeclPtrTy::make(*LastI)))
Initial implementation of function overloading in C. This commit adds a new attribute, "overloadable", that enables C++ function overloading in C. The attribute can only be added to function declarations, e.g., int *f(int) __attribute__((overloadable)); If the "overloadable" attribute exists on a function with a given name, *all* functions with that name (and in that scope) must have the "overloadable" attribute. Sets of overloaded functions with the "overloadable" attribute then follow the normal C++ rules for overloaded functions, e.g., overloads must have different parameter-type-lists from each other. When calling an overloaded function in C, we follow the same overloading rules as C++, with three extensions to the set of standard conversions: - A value of a given struct or union type T can be converted to the type T. This is just the identity conversion. (In C++, this would go through a copy constructor). - A value of pointer type T* can be converted to a value of type U* if T and U are compatible types. This conversion has Conversion rank (it's considered a pointer conversion in C). - A value of type T can be converted to a value of type U if T and U are compatible (and are not both pointer types). This conversion has Conversion rank (it's considered to be a new kind of conversion unique to C, a "compatible" conversion). Known defects (and, therefore, next steps): 1) The standard-conversion handling does not understand conversions involving _Complex or vector extensions, so it is likely to get these wrong. We need to add these conversions. 2) All overloadable functions with the same name will have the same linkage name, which means we'll get a collision in the linker (if not sooner). We'll need to mangle the names of these functions. llvm-svn: 64336
2009-02-12 07:02:49 +08:00
break;
R.addDecl(*LastI);
Initial implementation of function overloading in C. This commit adds a new attribute, "overloadable", that enables C++ function overloading in C. The attribute can only be added to function declarations, e.g., int *f(int) __attribute__((overloadable)); If the "overloadable" attribute exists on a function with a given name, *all* functions with that name (and in that scope) must have the "overloadable" attribute. Sets of overloaded functions with the "overloadable" attribute then follow the normal C++ rules for overloaded functions, e.g., overloads must have different parameter-type-lists from each other. When calling an overloaded function in C, we follow the same overloading rules as C++, with three extensions to the set of standard conversions: - A value of a given struct or union type T can be converted to the type T. This is just the identity conversion. (In C++, this would go through a copy constructor). - A value of pointer type T* can be converted to a value of type U* if T and U are compatible types. This conversion has Conversion rank (it's considered a pointer conversion in C). - A value of type T can be converted to a value of type U if T and U are compatible (and are not both pointer types). This conversion has Conversion rank (it's considered to be a new kind of conversion unique to C, a "compatible" conversion). Known defects (and, therefore, next steps): 1) The standard-conversion handling does not understand conversions involving _Complex or vector extensions, so it is likely to get these wrong. We need to add these conversions. 2) All overloadable functions with the same name will have the same linkage name, which means we'll get a collision in the linker (if not sooner). We'll need to mangle the names of these functions. llvm-svn: 64336
2009-02-12 07:02:49 +08:00
}
}
R.resolveKind();
return true;
Initial implementation of function overloading in C. This commit adds a new attribute, "overloadable", that enables C++ function overloading in C. The attribute can only be added to function declarations, e.g., int *f(int) __attribute__((overloadable)); If the "overloadable" attribute exists on a function with a given name, *all* functions with that name (and in that scope) must have the "overloadable" attribute. Sets of overloaded functions with the "overloadable" attribute then follow the normal C++ rules for overloaded functions, e.g., overloads must have different parameter-type-lists from each other. When calling an overloaded function in C, we follow the same overloading rules as C++, with three extensions to the set of standard conversions: - A value of a given struct or union type T can be converted to the type T. This is just the identity conversion. (In C++, this would go through a copy constructor). - A value of pointer type T* can be converted to a value of type U* if T and U are compatible types. This conversion has Conversion rank (it's considered a pointer conversion in C). - A value of type T can be converted to a value of type U if T and U are compatible (and are not both pointer types). This conversion has Conversion rank (it's considered to be a new kind of conversion unique to C, a "compatible" conversion). Known defects (and, therefore, next steps): 1) The standard-conversion handling does not understand conversions involving _Complex or vector extensions, so it is likely to get these wrong. We need to add these conversions. 2) All overloadable functions with the same name will have the same linkage name, which means we'll get a collision in the linker (if not sooner). We'll need to mangle the names of these functions. llvm-svn: 64336
2009-02-12 07:02:49 +08:00
}
} else {
// Perform C++ unqualified name lookup.
if (CppLookupName(R, S))
return true;
}
// If we didn't find a use of this identifier, and if the identifier
// corresponds to a compiler builtin, create the decl object for the builtin
// now, injecting it into translation unit scope, and return it.
if (NameKind == LookupOrdinaryName ||
NameKind == LookupRedeclarationWithLinkage) {
IdentifierInfo *II = Name.getAsIdentifierInfo();
Implicitly declare certain C library functions (malloc, strcpy, memmove, etc.) when we perform name lookup on them. This ensures that we produce the correct signature for these functions, which has two practical impacts: 1) When we're supporting the "implicit function declaration" feature of C99, these functions will be implicitly declared with the right signature rather than as a function returning "int" with no prototype. See PR3541 for the reason why this is important (hint: GCC always predeclares these functions). 2) If users attempt to redeclare one of these library functions with an incompatible signature, we produce a hard error. This patch does a little bit of work to give reasonable error messages. For example, when we hit case #1 we complain that we're implicitly declaring this function with a specific signature, and then we give a note that asks the user to include the appropriate header (e.g., "please include <stdlib.h> or explicitly declare 'malloc'"). In case #2, we show the type of the implicit builtin that was incorrectly declared, so the user can see the problem. We could do better here: for example, when displaying this latter error message we say something like: 'strcpy' was implicitly declared here with type 'char *(char *, char const *)' but we should really print out a fake code line showing the declaration, like this: 'strcpy' was implicitly declared here as: char *strcpy(char *, char const *) This would also be good for printing built-in candidates with C++ operator overloading. The set of C library functions supported by this patch includes all functions from the C99 specification's <stdlib.h> and <string.h> that (a) are predefined by GCC and (b) have signatures that could cause codegen issues if they are treated as functions with no prototype returning and int. Future work could extend this set of functions to other C library functions that we know about. llvm-svn: 64504
2009-02-14 07:20:09 +08:00
if (II && AllowBuiltinCreation) {
// If this is a builtin on this (or all) targets, create the decl.
Implicitly declare certain C library functions (malloc, strcpy, memmove, etc.) when we perform name lookup on them. This ensures that we produce the correct signature for these functions, which has two practical impacts: 1) When we're supporting the "implicit function declaration" feature of C99, these functions will be implicitly declared with the right signature rather than as a function returning "int" with no prototype. See PR3541 for the reason why this is important (hint: GCC always predeclares these functions). 2) If users attempt to redeclare one of these library functions with an incompatible signature, we produce a hard error. This patch does a little bit of work to give reasonable error messages. For example, when we hit case #1 we complain that we're implicitly declaring this function with a specific signature, and then we give a note that asks the user to include the appropriate header (e.g., "please include <stdlib.h> or explicitly declare 'malloc'"). In case #2, we show the type of the implicit builtin that was incorrectly declared, so the user can see the problem. We could do better here: for example, when displaying this latter error message we say something like: 'strcpy' was implicitly declared here with type 'char *(char *, char const *)' but we should really print out a fake code line showing the declaration, like this: 'strcpy' was implicitly declared here as: char *strcpy(char *, char const *) This would also be good for printing built-in candidates with C++ operator overloading. The set of C library functions supported by this patch includes all functions from the C99 specification's <stdlib.h> and <string.h> that (a) are predefined by GCC and (b) have signatures that could cause codegen issues if they are treated as functions with no prototype returning and int. Future work could extend this set of functions to other C library functions that we know about. llvm-svn: 64504
2009-02-14 07:20:09 +08:00
if (unsigned BuiltinID = II->getBuiltinID()) {
// In C++, we don't have any predefined library functions like
// 'malloc'. Instead, we'll just error.
if (getLangOptions().CPlusPlus &&
Implicitly declare certain C library functions (malloc, strcpy, memmove, etc.) when we perform name lookup on them. This ensures that we produce the correct signature for these functions, which has two practical impacts: 1) When we're supporting the "implicit function declaration" feature of C99, these functions will be implicitly declared with the right signature rather than as a function returning "int" with no prototype. See PR3541 for the reason why this is important (hint: GCC always predeclares these functions). 2) If users attempt to redeclare one of these library functions with an incompatible signature, we produce a hard error. This patch does a little bit of work to give reasonable error messages. For example, when we hit case #1 we complain that we're implicitly declaring this function with a specific signature, and then we give a note that asks the user to include the appropriate header (e.g., "please include <stdlib.h> or explicitly declare 'malloc'"). In case #2, we show the type of the implicit builtin that was incorrectly declared, so the user can see the problem. We could do better here: for example, when displaying this latter error message we say something like: 'strcpy' was implicitly declared here with type 'char *(char *, char const *)' but we should really print out a fake code line showing the declaration, like this: 'strcpy' was implicitly declared here as: char *strcpy(char *, char const *) This would also be good for printing built-in candidates with C++ operator overloading. The set of C library functions supported by this patch includes all functions from the C99 specification's <stdlib.h> and <string.h> that (a) are predefined by GCC and (b) have signatures that could cause codegen issues if they are treated as functions with no prototype returning and int. Future work could extend this set of functions to other C library functions that we know about. llvm-svn: 64504
2009-02-14 07:20:09 +08:00
Context.BuiltinInfo.isPredefinedLibFunction(BuiltinID))
return false;
Implicitly declare certain C library functions (malloc, strcpy, memmove, etc.) when we perform name lookup on them. This ensures that we produce the correct signature for these functions, which has two practical impacts: 1) When we're supporting the "implicit function declaration" feature of C99, these functions will be implicitly declared with the right signature rather than as a function returning "int" with no prototype. See PR3541 for the reason why this is important (hint: GCC always predeclares these functions). 2) If users attempt to redeclare one of these library functions with an incompatible signature, we produce a hard error. This patch does a little bit of work to give reasonable error messages. For example, when we hit case #1 we complain that we're implicitly declaring this function with a specific signature, and then we give a note that asks the user to include the appropriate header (e.g., "please include <stdlib.h> or explicitly declare 'malloc'"). In case #2, we show the type of the implicit builtin that was incorrectly declared, so the user can see the problem. We could do better here: for example, when displaying this latter error message we say something like: 'strcpy' was implicitly declared here with type 'char *(char *, char const *)' but we should really print out a fake code line showing the declaration, like this: 'strcpy' was implicitly declared here as: char *strcpy(char *, char const *) This would also be good for printing built-in candidates with C++ operator overloading. The set of C library functions supported by this patch includes all functions from the C99 specification's <stdlib.h> and <string.h> that (a) are predefined by GCC and (b) have signatures that could cause codegen issues if they are treated as functions with no prototype returning and int. Future work could extend this set of functions to other C library functions that we know about. llvm-svn: 64504
2009-02-14 07:20:09 +08:00
NamedDecl *D = LazilyCreateBuiltin((IdentifierInfo *)II, BuiltinID,
S, R.isForRedeclaration(),
R.getNameLoc());
if (D) R.addDecl(D);
return (D != NULL);
Implicitly declare certain C library functions (malloc, strcpy, memmove, etc.) when we perform name lookup on them. This ensures that we produce the correct signature for these functions, which has two practical impacts: 1) When we're supporting the "implicit function declaration" feature of C99, these functions will be implicitly declared with the right signature rather than as a function returning "int" with no prototype. See PR3541 for the reason why this is important (hint: GCC always predeclares these functions). 2) If users attempt to redeclare one of these library functions with an incompatible signature, we produce a hard error. This patch does a little bit of work to give reasonable error messages. For example, when we hit case #1 we complain that we're implicitly declaring this function with a specific signature, and then we give a note that asks the user to include the appropriate header (e.g., "please include <stdlib.h> or explicitly declare 'malloc'"). In case #2, we show the type of the implicit builtin that was incorrectly declared, so the user can see the problem. We could do better here: for example, when displaying this latter error message we say something like: 'strcpy' was implicitly declared here with type 'char *(char *, char const *)' but we should really print out a fake code line showing the declaration, like this: 'strcpy' was implicitly declared here as: char *strcpy(char *, char const *) This would also be good for printing built-in candidates with C++ operator overloading. The set of C library functions supported by this patch includes all functions from the C99 specification's <stdlib.h> and <string.h> that (a) are predefined by GCC and (b) have signatures that could cause codegen issues if they are treated as functions with no prototype returning and int. Future work could extend this set of functions to other C library functions that we know about. llvm-svn: 64504
2009-02-14 07:20:09 +08:00
}
}
}
return false;
}
/// @brief Perform qualified name lookup in the namespaces nominated by
/// using directives by the given context.
///
/// C++98 [namespace.qual]p2:
/// Given X::m (where X is a user-declared namespace), or given ::m
/// (where X is the global namespace), let S be the set of all
/// declarations of m in X and in the transitive closure of all
/// namespaces nominated by using-directives in X and its used
/// namespaces, except that using-directives are ignored in any
/// namespace, including X, directly containing one or more
/// declarations of m. No namespace is searched more than once in
/// the lookup of a name. If S is the empty set, the program is
/// ill-formed. Otherwise, if S has exactly one member, or if the
/// context of the reference is a using-declaration
/// (namespace.udecl), S is the required set of declarations of
/// m. Otherwise if the use of m is not one that allows a unique
/// declaration to be chosen from S, the program is ill-formed.
/// C++98 [namespace.qual]p5:
/// During the lookup of a qualified namespace member name, if the
/// lookup finds more than one declaration of the member, and if one
/// declaration introduces a class name or enumeration name and the
/// other declarations either introduce the same object, the same
/// enumerator or a set of functions, the non-type name hides the
/// class or enumeration name if and only if the declarations are
/// from the same namespace; otherwise (the declarations are from
/// different namespaces), the program is ill-formed.
static bool LookupQualifiedNameInUsingDirectives(LookupResult &R,
DeclContext *StartDC) {
assert(StartDC->isFileContext() && "start context is not a file context");
DeclContext::udir_iterator I = StartDC->using_directives_begin();
DeclContext::udir_iterator E = StartDC->using_directives_end();
if (I == E) return false;
// We have at least added all these contexts to the queue.
llvm::DenseSet<DeclContext*> Visited;
Visited.insert(StartDC);
// We have not yet looked into these namespaces, much less added
// their "using-children" to the queue.
llvm::SmallVector<NamespaceDecl*, 8> Queue;
// We have already looked into the initial namespace; seed the queue
// with its using-children.
for (; I != E; ++I) {
NamespaceDecl *ND = (*I)->getNominatedNamespace()->getOriginalNamespace();
if (Visited.insert(ND).second)
Queue.push_back(ND);
}
// The easiest way to implement the restriction in [namespace.qual]p5
// is to check whether any of the individual results found a tag
// and, if so, to declare an ambiguity if the final result is not
// a tag.
bool FoundTag = false;
bool FoundNonTag = false;
LookupResult LocalR(LookupResult::Temporary, R);
bool Found = false;
while (!Queue.empty()) {
NamespaceDecl *ND = Queue.back();
Queue.pop_back();
// We go through some convolutions here to avoid copying results
// between LookupResults.
bool UseLocal = !R.empty();
LookupResult &DirectR = UseLocal ? LocalR : R;
bool FoundDirect = LookupDirect(DirectR, ND);
if (FoundDirect) {
// First do any local hiding.
DirectR.resolveKind();
// If the local result is a tag, remember that.
if (DirectR.isSingleTagDecl())
FoundTag = true;
else
FoundNonTag = true;
// Append the local results to the total results if necessary.
if (UseLocal) {
R.addAllDecls(LocalR);
LocalR.clear();
}
}
// If we find names in this namespace, ignore its using directives.
if (FoundDirect) {
Found = true;
continue;
}
for (llvm::tie(I,E) = ND->getUsingDirectives(); I != E; ++I) {
NamespaceDecl *Nom = (*I)->getNominatedNamespace();
if (Visited.insert(Nom).second)
Queue.push_back(Nom);
}
}
if (Found) {
if (FoundTag && FoundNonTag)
R.setAmbiguousQualifiedTagHiding();
else
R.resolveKind();
}
return Found;
}
/// \brief Perform qualified name lookup into a given context.
///
/// Qualified name lookup (C++ [basic.lookup.qual]) is used to find
/// names when the context of those names is explicit specified, e.g.,
/// "std::vector" or "x->member", or as part of unqualified name lookup.
///
/// Different lookup criteria can find different names. For example, a
/// particular scope can have both a struct and a function of the same
/// name, and each can be found by certain lookup criteria. For more
/// information about lookup criteria, see the documentation for the
/// class LookupCriteria.
///
/// \param R captures both the lookup criteria and any lookup results found.
///
/// \param LookupCtx The context in which qualified name lookup will
/// search. If the lookup criteria permits, name lookup may also search
/// in the parent contexts or (for C++ classes) base classes.
///
/// \param InUnqualifiedLookup true if this is qualified name lookup that
/// occurs as part of unqualified name lookup.
///
/// \returns true if lookup succeeded, false if it failed.
bool Sema::LookupQualifiedName(LookupResult &R, DeclContext *LookupCtx,
bool InUnqualifiedLookup) {
assert(LookupCtx && "Sema::LookupQualifiedName requires a lookup context");
if (!R.getLookupName())
return false;
// Make sure that the declaration context is complete.
assert((!isa<TagDecl>(LookupCtx) ||
LookupCtx->isDependentContext() ||
cast<TagDecl>(LookupCtx)->isDefinition() ||
Context.getTypeDeclType(cast<TagDecl>(LookupCtx))->getAs<TagType>()
->isBeingDefined()) &&
"Declaration context must already be complete!");
// Perform qualified name lookup into the LookupCtx.
if (LookupDirect(R, LookupCtx)) {
R.resolveKind();
if (isa<CXXRecordDecl>(LookupCtx))
R.setNamingClass(cast<CXXRecordDecl>(LookupCtx));
return true;
}
// Don't descend into implied contexts for redeclarations.
// C++98 [namespace.qual]p6:
// In a declaration for a namespace member in which the
// declarator-id is a qualified-id, given that the qualified-id
// for the namespace member has the form
// nested-name-specifier unqualified-id
// the unqualified-id shall name a member of the namespace
// designated by the nested-name-specifier.
// See also [class.mfct]p5 and [class.static.data]p2.
if (R.isForRedeclaration())
return false;
// If this is a namespace, look it up in the implied namespaces.
if (LookupCtx->isFileContext())
return LookupQualifiedNameInUsingDirectives(R, LookupCtx);
// If this isn't a C++ class, we aren't allowed to look into base
// classes, we're done.
CXXRecordDecl *LookupRec = dyn_cast<CXXRecordDecl>(LookupCtx);
if (!LookupRec)
return false;
// If we're performing qualified name lookup into a dependent class,
// then we are actually looking into a current instantiation. If we have any
// dependent base classes, then we either have to delay lookup until
// template instantiation time (at which point all bases will be available)
// or we have to fail.
if (!InUnqualifiedLookup && LookupRec->isDependentContext() &&
LookupRec->hasAnyDependentBases()) {
R.setNotFoundInCurrentInstantiation();
return false;
}
// Perform lookup into our base classes.
CXXBasePaths Paths;
Paths.setOrigin(LookupRec);
// Look for this member in our base classes
CXXRecordDecl::BaseMatchesCallback *BaseCallback = 0;
switch (R.getLookupKind()) {
case LookupOrdinaryName:
case LookupMemberName:
case LookupRedeclarationWithLinkage:
BaseCallback = &CXXRecordDecl::FindOrdinaryMember;
break;
case LookupTagName:
BaseCallback = &CXXRecordDecl::FindTagMember;
break;
case LookupUsingDeclName:
// This lookup is for redeclarations only.
case LookupOperatorName:
case LookupNamespaceName:
case LookupObjCProtocolName:
case LookupObjCImplementationName:
// These lookups will never find a member in a C++ class (or base class).
return false;
case LookupNestedNameSpecifierName:
BaseCallback = &CXXRecordDecl::FindNestedNameSpecifierMember;
break;
}
if (!LookupRec->lookupInBases(BaseCallback,
R.getLookupName().getAsOpaquePtr(), Paths))
return false;
R.setNamingClass(LookupRec);
// C++ [class.member.lookup]p2:
// [...] If the resulting set of declarations are not all from
// sub-objects of the same type, or the set has a nonstatic member
// and includes members from distinct sub-objects, there is an
// ambiguity and the program is ill-formed. Otherwise that set is
// the result of the lookup.
// FIXME: support using declarations!
QualType SubobjectType;
int SubobjectNumber = 0;
AccessSpecifier SubobjectAccess = AS_private;
for (CXXBasePaths::paths_iterator Path = Paths.begin(), PathEnd = Paths.end();
Path != PathEnd; ++Path) {
const CXXBasePathElement &PathElement = Path->back();
// Pick the best (i.e. most permissive i.e. numerically lowest) access
// across all paths.
SubobjectAccess = std::min(SubobjectAccess, Path->Access);
// Determine whether we're looking at a distinct sub-object or not.
if (SubobjectType.isNull()) {
// This is the first subobject we've looked at. Record its type.
SubobjectType = Context.getCanonicalType(PathElement.Base->getType());
SubobjectNumber = PathElement.SubobjectNumber;
} else if (SubobjectType
!= Context.getCanonicalType(PathElement.Base->getType())) {
// We found members of the given name in two subobjects of
// different types. This lookup is ambiguous.
R.setAmbiguousBaseSubobjectTypes(Paths);
return true;
} else if (SubobjectNumber != PathElement.SubobjectNumber) {
// We have a different subobject of the same type.
// C++ [class.member.lookup]p5:
// A static member, a nested type or an enumerator defined in
// a base class T can unambiguously be found even if an object
// has more than one base class subobject of type T.
Decl *FirstDecl = *Path->Decls.first;
if (isa<VarDecl>(FirstDecl) ||
isa<TypeDecl>(FirstDecl) ||
isa<EnumConstantDecl>(FirstDecl))
continue;
if (isa<CXXMethodDecl>(FirstDecl)) {
// Determine whether all of the methods are static.
bool AllMethodsAreStatic = true;
for (DeclContext::lookup_iterator Func = Path->Decls.first;
Func != Path->Decls.second; ++Func) {
if (!isa<CXXMethodDecl>(*Func)) {
assert(isa<TagDecl>(*Func) && "Non-function must be a tag decl");
break;
}
if (!cast<CXXMethodDecl>(*Func)->isStatic()) {
AllMethodsAreStatic = false;
break;
}
}
if (AllMethodsAreStatic)
continue;
}
// We have found a nonstatic member name in multiple, distinct
// subobjects. Name lookup is ambiguous.
R.setAmbiguousBaseSubobjects(Paths);
return true;
}
}
// Lookup in a base class succeeded; return these results.
DeclContext::lookup_iterator I, E;
for (llvm::tie(I,E) = Paths.front().Decls; I != E; ++I) {
NamedDecl *D = *I;
AccessSpecifier AS = CXXRecordDecl::MergeAccess(SubobjectAccess,
D->getAccess());
R.addDecl(D, AS);
}
R.resolveKind();
return true;
}
/// @brief Performs name lookup for a name that was parsed in the
/// source code, and may contain a C++ scope specifier.
///
/// This routine is a convenience routine meant to be called from
/// contexts that receive a name and an optional C++ scope specifier
/// (e.g., "N::M::x"). It will then perform either qualified or
/// unqualified name lookup (with LookupQualifiedName or LookupName,
/// respectively) on the given name and return those results.
///
/// @param S The scope from which unqualified name lookup will
/// begin.
///
/// @param SS An optional C++ scope-specifier, e.g., "::N::M".
///
/// @param Name The name of the entity that name lookup will
/// search for.
///
Implicitly declare certain C library functions (malloc, strcpy, memmove, etc.) when we perform name lookup on them. This ensures that we produce the correct signature for these functions, which has two practical impacts: 1) When we're supporting the "implicit function declaration" feature of C99, these functions will be implicitly declared with the right signature rather than as a function returning "int" with no prototype. See PR3541 for the reason why this is important (hint: GCC always predeclares these functions). 2) If users attempt to redeclare one of these library functions with an incompatible signature, we produce a hard error. This patch does a little bit of work to give reasonable error messages. For example, when we hit case #1 we complain that we're implicitly declaring this function with a specific signature, and then we give a note that asks the user to include the appropriate header (e.g., "please include <stdlib.h> or explicitly declare 'malloc'"). In case #2, we show the type of the implicit builtin that was incorrectly declared, so the user can see the problem. We could do better here: for example, when displaying this latter error message we say something like: 'strcpy' was implicitly declared here with type 'char *(char *, char const *)' but we should really print out a fake code line showing the declaration, like this: 'strcpy' was implicitly declared here as: char *strcpy(char *, char const *) This would also be good for printing built-in candidates with C++ operator overloading. The set of C library functions supported by this patch includes all functions from the C99 specification's <stdlib.h> and <string.h> that (a) are predefined by GCC and (b) have signatures that could cause codegen issues if they are treated as functions with no prototype returning and int. Future work could extend this set of functions to other C library functions that we know about. llvm-svn: 64504
2009-02-14 07:20:09 +08:00
/// @param Loc If provided, the source location where we're performing
/// name lookup. At present, this is only used to produce diagnostics when
Implicitly declare certain C library functions (malloc, strcpy, memmove, etc.) when we perform name lookup on them. This ensures that we produce the correct signature for these functions, which has two practical impacts: 1) When we're supporting the "implicit function declaration" feature of C99, these functions will be implicitly declared with the right signature rather than as a function returning "int" with no prototype. See PR3541 for the reason why this is important (hint: GCC always predeclares these functions). 2) If users attempt to redeclare one of these library functions with an incompatible signature, we produce a hard error. This patch does a little bit of work to give reasonable error messages. For example, when we hit case #1 we complain that we're implicitly declaring this function with a specific signature, and then we give a note that asks the user to include the appropriate header (e.g., "please include <stdlib.h> or explicitly declare 'malloc'"). In case #2, we show the type of the implicit builtin that was incorrectly declared, so the user can see the problem. We could do better here: for example, when displaying this latter error message we say something like: 'strcpy' was implicitly declared here with type 'char *(char *, char const *)' but we should really print out a fake code line showing the declaration, like this: 'strcpy' was implicitly declared here as: char *strcpy(char *, char const *) This would also be good for printing built-in candidates with C++ operator overloading. The set of C library functions supported by this patch includes all functions from the C99 specification's <stdlib.h> and <string.h> that (a) are predefined by GCC and (b) have signatures that could cause codegen issues if they are treated as functions with no prototype returning and int. Future work could extend this set of functions to other C library functions that we know about. llvm-svn: 64504
2009-02-14 07:20:09 +08:00
/// C library functions (like "malloc") are implicitly declared.
///
/// @param EnteringContext Indicates whether we are going to enter the
/// context of the scope-specifier SS (if present).
///
/// @returns True if any decls were found (but possibly ambiguous)
bool Sema::LookupParsedName(LookupResult &R, Scope *S, const CXXScopeSpec *SS,
bool AllowBuiltinCreation, bool EnteringContext) {
if (SS && SS->isInvalid()) {
// When the scope specifier is invalid, don't even look for
// anything.
return false;
}
if (SS && SS->isSet()) {
if (DeclContext *DC = computeDeclContext(*SS, EnteringContext)) {
// We have resolved the scope specifier to a particular declaration
// contex, and will perform name lookup in that context.
if (!DC->isDependentContext() && RequireCompleteDeclContext(*SS))
return false;
R.setContextRange(SS->getRange());
return LookupQualifiedName(R, DC);
2009-03-19 08:18:19 +08:00
}
// We could not resolve the scope specified to a specific declaration
// context, which means that SS refers to an unknown specialization.
// Name lookup can't find anything in this case.
return false;
}
// Perform unqualified name lookup starting in the given scope.
return LookupName(R, S, AllowBuiltinCreation);
}
/// @brief Produce a diagnostic describing the ambiguity that resulted
/// from name lookup.
///
/// @param Result The ambiguous name lookup result.
///
/// @param Name The name of the entity that name lookup was
/// searching for.
///
/// @param NameLoc The location of the name within the source code.
///
/// @param LookupRange A source range that provides more
/// source-location information concerning the lookup itself. For
/// example, this range might highlight a nested-name-specifier that
/// precedes the name.
///
/// @returns true
bool Sema::DiagnoseAmbiguousLookup(LookupResult &Result) {
assert(Result.isAmbiguous() && "Lookup result must be ambiguous");
DeclarationName Name = Result.getLookupName();
SourceLocation NameLoc = Result.getNameLoc();
SourceRange LookupRange = Result.getContextRange();
switch (Result.getAmbiguityKind()) {
case LookupResult::AmbiguousBaseSubobjects: {
CXXBasePaths *Paths = Result.getBasePaths();
QualType SubobjectType = Paths->front().back().Base->getType();
Diag(NameLoc, diag::err_ambiguous_member_multiple_subobjects)
<< Name << SubobjectType << getAmbiguousPathsDisplayString(*Paths)
<< LookupRange;
DeclContext::lookup_iterator Found = Paths->front().Decls.first;
while (isa<CXXMethodDecl>(*Found) &&
cast<CXXMethodDecl>(*Found)->isStatic())
++Found;
Diag((*Found)->getLocation(), diag::note_ambiguous_member_found);
return true;
}
case LookupResult::AmbiguousBaseSubobjectTypes: {
Diag(NameLoc, diag::err_ambiguous_member_multiple_subobject_types)
<< Name << LookupRange;
CXXBasePaths *Paths = Result.getBasePaths();
std::set<Decl *> DeclsPrinted;
for (CXXBasePaths::paths_iterator Path = Paths->begin(),
PathEnd = Paths->end();
Path != PathEnd; ++Path) {
Decl *D = *Path->Decls.first;
if (DeclsPrinted.insert(D).second)
Diag(D->getLocation(), diag::note_ambiguous_member_found);
}
return true;
}
case LookupResult::AmbiguousTagHiding: {
Diag(NameLoc, diag::err_ambiguous_tag_hiding) << Name << LookupRange;
llvm::SmallPtrSet<NamedDecl*,8> TagDecls;
LookupResult::iterator DI, DE = Result.end();
for (DI = Result.begin(); DI != DE; ++DI)
if (TagDecl *TD = dyn_cast<TagDecl>(*DI)) {
TagDecls.insert(TD);
Diag(TD->getLocation(), diag::note_hidden_tag);
}
for (DI = Result.begin(); DI != DE; ++DI)
if (!isa<TagDecl>(*DI))
Diag((*DI)->getLocation(), diag::note_hiding_object);
// For recovery purposes, go ahead and implement the hiding.
LookupResult::Filter F = Result.makeFilter();
while (F.hasNext()) {
if (TagDecls.count(F.next()))
F.erase();
}
F.done();
return true;
}
case LookupResult::AmbiguousReference: {
Diag(NameLoc, diag::err_ambiguous_reference) << Name << LookupRange;
LookupResult::iterator DI = Result.begin(), DE = Result.end();
for (; DI != DE; ++DI)
Diag((*DI)->getLocation(), diag::note_ambiguous_candidate) << *DI;
return true;
}
}
llvm_unreachable("unknown ambiguity kind");
return true;
}
static void
addAssociatedClassesAndNamespaces(QualType T,
ASTContext &Context,
Sema::AssociatedNamespaceSet &AssociatedNamespaces,
Sema::AssociatedClassSet &AssociatedClasses);
static void CollectNamespace(Sema::AssociatedNamespaceSet &Namespaces,
DeclContext *Ctx) {
if (Ctx->isFileContext())
Namespaces.insert(Ctx);
}
// \brief Add the associated classes and namespaces for argument-dependent
// lookup that involves a template argument (C++ [basic.lookup.koenig]p2).
static void
addAssociatedClassesAndNamespaces(const TemplateArgument &Arg,
ASTContext &Context,
Sema::AssociatedNamespaceSet &AssociatedNamespaces,
Sema::AssociatedClassSet &AssociatedClasses) {
// C++ [basic.lookup.koenig]p2, last bullet:
// -- [...] ;
switch (Arg.getKind()) {
case TemplateArgument::Null:
break;
case TemplateArgument::Type:
// [...] the namespaces and classes associated with the types of the
// template arguments provided for template type parameters (excluding
// template template parameters)
addAssociatedClassesAndNamespaces(Arg.getAsType(), Context,
AssociatedNamespaces,
AssociatedClasses);
break;
case TemplateArgument::Template: {
// [...] the namespaces in which any template template arguments are
// defined; and the classes in which any member templates used as
// template template arguments are defined.
TemplateName Template = Arg.getAsTemplate();
if (ClassTemplateDecl *ClassTemplate
= dyn_cast<ClassTemplateDecl>(Template.getAsTemplateDecl())) {
DeclContext *Ctx = ClassTemplate->getDeclContext();
if (CXXRecordDecl *EnclosingClass = dyn_cast<CXXRecordDecl>(Ctx))
AssociatedClasses.insert(EnclosingClass);
// Add the associated namespace for this class.
while (Ctx->isRecord())
Ctx = Ctx->getParent();
CollectNamespace(AssociatedNamespaces, Ctx);
}
break;
}
case TemplateArgument::Declaration:
case TemplateArgument::Integral:
case TemplateArgument::Expression:
// [Note: non-type template arguments do not contribute to the set of
// associated namespaces. ]
break;
case TemplateArgument::Pack:
for (TemplateArgument::pack_iterator P = Arg.pack_begin(),
PEnd = Arg.pack_end();
P != PEnd; ++P)
addAssociatedClassesAndNamespaces(*P, Context,
AssociatedNamespaces,
AssociatedClasses);
break;
}
}
// \brief Add the associated classes and namespaces for
// argument-dependent lookup with an argument of class type
// (C++ [basic.lookup.koenig]p2).
static void
addAssociatedClassesAndNamespaces(CXXRecordDecl *Class,
ASTContext &Context,
Sema::AssociatedNamespaceSet &AssociatedNamespaces,
Sema::AssociatedClassSet &AssociatedClasses) {
// C++ [basic.lookup.koenig]p2:
// [...]
// -- If T is a class type (including unions), its associated
// classes are: the class itself; the class of which it is a
// member, if any; and its direct and indirect base
// classes. Its associated namespaces are the namespaces in
// which its associated classes are defined.
// Add the class of which it is a member, if any.
DeclContext *Ctx = Class->getDeclContext();
if (CXXRecordDecl *EnclosingClass = dyn_cast<CXXRecordDecl>(Ctx))
AssociatedClasses.insert(EnclosingClass);
// Add the associated namespace for this class.
while (Ctx->isRecord())
Ctx = Ctx->getParent();
CollectNamespace(AssociatedNamespaces, Ctx);
// Add the class itself. If we've already seen this class, we don't
// need to visit base classes.
if (!AssociatedClasses.insert(Class))
return;
// -- If T is a template-id, its associated namespaces and classes are
// the namespace in which the template is defined; for member
// templates, the member templates class; the namespaces and classes
// associated with the types of the template arguments provided for
// template type parameters (excluding template template parameters); the
// namespaces in which any template template arguments are defined; and
// the classes in which any member templates used as template template
// arguments are defined. [Note: non-type template arguments do not
// contribute to the set of associated namespaces. ]
if (ClassTemplateSpecializationDecl *Spec
= dyn_cast<ClassTemplateSpecializationDecl>(Class)) {
DeclContext *Ctx = Spec->getSpecializedTemplate()->getDeclContext();
if (CXXRecordDecl *EnclosingClass = dyn_cast<CXXRecordDecl>(Ctx))
AssociatedClasses.insert(EnclosingClass);
// Add the associated namespace for this class.
while (Ctx->isRecord())
Ctx = Ctx->getParent();
CollectNamespace(AssociatedNamespaces, Ctx);
const TemplateArgumentList &TemplateArgs = Spec->getTemplateArgs();
for (unsigned I = 0, N = TemplateArgs.size(); I != N; ++I)
addAssociatedClassesAndNamespaces(TemplateArgs[I], Context,
AssociatedNamespaces,
AssociatedClasses);
}
// Only recurse into base classes for complete types.
if (!Class->hasDefinition()) {
// FIXME: we might need to instantiate templates here
return;
}
// Add direct and indirect base classes along with their associated
// namespaces.
llvm::SmallVector<CXXRecordDecl *, 32> Bases;
Bases.push_back(Class);
while (!Bases.empty()) {
// Pop this class off the stack.
Class = Bases.back();
Bases.pop_back();
// Visit the base classes.
for (CXXRecordDecl::base_class_iterator Base = Class->bases_begin(),
BaseEnd = Class->bases_end();
Base != BaseEnd; ++Base) {
const RecordType *BaseType = Base->getType()->getAs<RecordType>();
// In dependent contexts, we do ADL twice, and the first time around,
// the base type might be a dependent TemplateSpecializationType, or a
// TemplateTypeParmType. If that happens, simply ignore it.
// FIXME: If we want to support export, we probably need to add the
// namespace of the template in a TemplateSpecializationType, or even
// the classes and namespaces of known non-dependent arguments.
if (!BaseType)
continue;
CXXRecordDecl *BaseDecl = cast<CXXRecordDecl>(BaseType->getDecl());
if (AssociatedClasses.insert(BaseDecl)) {
// Find the associated namespace for this base class.
DeclContext *BaseCtx = BaseDecl->getDeclContext();
while (BaseCtx->isRecord())
BaseCtx = BaseCtx->getParent();
CollectNamespace(AssociatedNamespaces, BaseCtx);
// Make sure we visit the bases of this base class.
if (BaseDecl->bases_begin() != BaseDecl->bases_end())
Bases.push_back(BaseDecl);
}
}
}
}
// \brief Add the associated classes and namespaces for
// argument-dependent lookup with an argument of type T
// (C++ [basic.lookup.koenig]p2).
static void
addAssociatedClassesAndNamespaces(QualType T,
ASTContext &Context,
Sema::AssociatedNamespaceSet &AssociatedNamespaces,
Sema::AssociatedClassSet &AssociatedClasses) {
// C++ [basic.lookup.koenig]p2:
//
// For each argument type T in the function call, there is a set
// of zero or more associated namespaces and a set of zero or more
// associated classes to be considered. The sets of namespaces and
// classes is determined entirely by the types of the function
// arguments (and the namespace of any template template
// argument). Typedef names and using-declarations used to specify
// the types do not contribute to this set. The sets of namespaces
// and classes are determined in the following way:
T = Context.getCanonicalType(T).getUnqualifiedType();
// -- If T is a pointer to U or an array of U, its associated
// namespaces and classes are those associated with U.
//
// We handle this by unwrapping pointer and array types immediately,
// to avoid unnecessary recursion.
while (true) {
if (const PointerType *Ptr = T->getAs<PointerType>())
T = Ptr->getPointeeType();
else if (const ArrayType *Ptr = Context.getAsArrayType(T))
T = Ptr->getElementType();
else
break;
}
// -- If T is a fundamental type, its associated sets of
// namespaces and classes are both empty.
if (T->getAs<BuiltinType>())
return;
// -- If T is a class type (including unions), its associated
// classes are: the class itself; the class of which it is a
// member, if any; and its direct and indirect base
// classes. Its associated namespaces are the namespaces in
// which its associated classes are defined.
if (const RecordType *ClassType = T->getAs<RecordType>())
if (CXXRecordDecl *ClassDecl
= dyn_cast<CXXRecordDecl>(ClassType->getDecl())) {
addAssociatedClassesAndNamespaces(ClassDecl, Context,
AssociatedNamespaces,
AssociatedClasses);
return;
}
// -- If T is an enumeration type, its associated namespace is
// the namespace in which it is defined. If it is class
// member, its associated class is the members class; else
// it has no associated class.
if (const EnumType *EnumT = T->getAs<EnumType>()) {
EnumDecl *Enum = EnumT->getDecl();
DeclContext *Ctx = Enum->getDeclContext();
if (CXXRecordDecl *EnclosingClass = dyn_cast<CXXRecordDecl>(Ctx))
AssociatedClasses.insert(EnclosingClass);
// Add the associated namespace for this class.
while (Ctx->isRecord())
Ctx = Ctx->getParent();
CollectNamespace(AssociatedNamespaces, Ctx);
return;
}
// -- If T is a function type, its associated namespaces and
// classes are those associated with the function parameter
// types and those associated with the return type.
if (const FunctionType *FnType = T->getAs<FunctionType>()) {
// Return type
addAssociatedClassesAndNamespaces(FnType->getResultType(),
Context,
AssociatedNamespaces, AssociatedClasses);
const FunctionProtoType *Proto = dyn_cast<FunctionProtoType>(FnType);
if (!Proto)
return;
// Argument types
for (FunctionProtoType::arg_type_iterator Arg = Proto->arg_type_begin(),
ArgEnd = Proto->arg_type_end();
Arg != ArgEnd; ++Arg)
addAssociatedClassesAndNamespaces(*Arg, Context,
AssociatedNamespaces, AssociatedClasses);
return;
}
// -- If T is a pointer to a member function of a class X, its
// associated namespaces and classes are those associated
// with the function parameter types and return type,
// together with those associated with X.
//
// -- If T is a pointer to a data member of class X, its
// associated namespaces and classes are those associated
// with the member type together with those associated with
// X.
if (const MemberPointerType *MemberPtr = T->getAs<MemberPointerType>()) {
// Handle the type that the pointer to member points to.
addAssociatedClassesAndNamespaces(MemberPtr->getPointeeType(),
Context,
AssociatedNamespaces,
AssociatedClasses);
// Handle the class type into which this points.
if (const RecordType *Class = MemberPtr->getClass()->getAs<RecordType>())
addAssociatedClassesAndNamespaces(cast<CXXRecordDecl>(Class->getDecl()),
Context,
AssociatedNamespaces,
AssociatedClasses);
return;
}
// FIXME: What about block pointers?
// FIXME: What about Objective-C message sends?
}
/// \brief Find the associated classes and namespaces for
/// argument-dependent lookup for a call with the given set of
/// arguments.
///
/// This routine computes the sets of associated classes and associated
/// namespaces searched by argument-dependent lookup
/// (C++ [basic.lookup.argdep]) for a given set of arguments.
void
Sema::FindAssociatedClassesAndNamespaces(Expr **Args, unsigned NumArgs,
AssociatedNamespaceSet &AssociatedNamespaces,
AssociatedClassSet &AssociatedClasses) {
AssociatedNamespaces.clear();
AssociatedClasses.clear();
// C++ [basic.lookup.koenig]p2:
// For each argument type T in the function call, there is a set
// of zero or more associated namespaces and a set of zero or more
// associated classes to be considered. The sets of namespaces and
// classes is determined entirely by the types of the function
// arguments (and the namespace of any template template
// argument).
for (unsigned ArgIdx = 0; ArgIdx != NumArgs; ++ArgIdx) {
Expr *Arg = Args[ArgIdx];
if (Arg->getType() != Context.OverloadTy) {
addAssociatedClassesAndNamespaces(Arg->getType(), Context,
AssociatedNamespaces,
AssociatedClasses);
continue;
}
// [...] In addition, if the argument is the name or address of a
// set of overloaded functions and/or function templates, its
// associated classes and namespaces are the union of those
// associated with each of the members of the set: the namespace
// in which the function or function template is defined and the
// classes and namespaces associated with its (non-dependent)
// parameter types and return type.
Arg = Arg->IgnoreParens();
if (UnaryOperator *unaryOp = dyn_cast<UnaryOperator>(Arg))
if (unaryOp->getOpcode() == UnaryOperator::AddrOf)
Arg = unaryOp->getSubExpr();
// TODO: avoid the copies. This should be easy when the cases
// share a storage implementation.
llvm::SmallVector<NamedDecl*, 8> Functions;
if (UnresolvedLookupExpr *ULE = dyn_cast<UnresolvedLookupExpr>(Arg))
Functions.append(ULE->decls_begin(), ULE->decls_end());
else
continue;
for (llvm::SmallVectorImpl<NamedDecl*>::iterator I = Functions.begin(),
E = Functions.end(); I != E; ++I) {
// Look through any using declarations to find the underlying function.
NamedDecl *Fn = (*I)->getUnderlyingDecl();
FunctionDecl *FDecl = dyn_cast<FunctionDecl>(Fn);
if (!FDecl)
FDecl = cast<FunctionTemplateDecl>(Fn)->getTemplatedDecl();
// Add the classes and namespaces associated with the parameter
// types and return type of this function.
addAssociatedClassesAndNamespaces(FDecl->getType(), Context,
AssociatedNamespaces,
AssociatedClasses);
}
}
}
/// IsAcceptableNonMemberOperatorCandidate - Determine whether Fn is
/// an acceptable non-member overloaded operator for a call whose
/// arguments have types T1 (and, if non-empty, T2). This routine
/// implements the check in C++ [over.match.oper]p3b2 concerning
/// enumeration types.
static bool
IsAcceptableNonMemberOperatorCandidate(FunctionDecl *Fn,
QualType T1, QualType T2,
ASTContext &Context) {
if (T1->isDependentType() || (!T2.isNull() && T2->isDependentType()))
return true;
if (T1->isRecordType() || (!T2.isNull() && T2->isRecordType()))
return true;
const FunctionProtoType *Proto = Fn->getType()->getAs<FunctionProtoType>();
if (Proto->getNumArgs() < 1)
return false;
if (T1->isEnumeralType()) {
QualType ArgType = Proto->getArgType(0).getNonReferenceType();
if (Context.hasSameUnqualifiedType(T1, ArgType))
return true;
}
if (Proto->getNumArgs() < 2)
return false;
if (!T2.isNull() && T2->isEnumeralType()) {
QualType ArgType = Proto->getArgType(1).getNonReferenceType();
if (Context.hasSameUnqualifiedType(T2, ArgType))
return true;
}
return false;
}
NamedDecl *Sema::LookupSingleName(Scope *S, DeclarationName Name,
LookupNameKind NameKind,
RedeclarationKind Redecl) {
LookupResult R(*this, Name, SourceLocation(), NameKind, Redecl);
LookupName(R, S);
return R.getAsSingle<NamedDecl>();
}
/// \brief Find the protocol with the given name, if any.
ObjCProtocolDecl *Sema::LookupProtocol(IdentifierInfo *II) {
Decl *D = LookupSingleName(TUScope, II, LookupObjCProtocolName);
return cast_or_null<ObjCProtocolDecl>(D);
}
void Sema::LookupOverloadedOperatorName(OverloadedOperatorKind Op, Scope *S,
QualType T1, QualType T2,
UnresolvedSetImpl &Functions) {
// C++ [over.match.oper]p3:
// -- The set of non-member candidates is the result of the
// unqualified lookup of operator@ in the context of the
// expression according to the usual rules for name lookup in
// unqualified function calls (3.4.2) except that all member
// functions are ignored. However, if no operand has a class
// type, only those non-member functions in the lookup set
// that have a first parameter of type T1 or "reference to
// (possibly cv-qualified) T1", when T1 is an enumeration
// type, or (if there is a right operand) a second parameter
// of type T2 or "reference to (possibly cv-qualified) T2",
// when T2 is an enumeration type, are candidate functions.
DeclarationName OpName = Context.DeclarationNames.getCXXOperatorName(Op);
LookupResult Operators(*this, OpName, SourceLocation(), LookupOperatorName);
LookupName(Operators, S);
assert(!Operators.isAmbiguous() && "Operator lookup cannot be ambiguous");
if (Operators.empty())
return;
for (LookupResult::iterator Op = Operators.begin(), OpEnd = Operators.end();
Op != OpEnd; ++Op) {
if (FunctionDecl *FD = dyn_cast<FunctionDecl>(*Op)) {
if (IsAcceptableNonMemberOperatorCandidate(FD, T1, T2, Context))
Functions.addDecl(FD, Op.getAccess()); // FIXME: canonical FD
} else if (FunctionTemplateDecl *FunTmpl
= dyn_cast<FunctionTemplateDecl>(*Op)) {
// FIXME: friend operators?
// FIXME: do we need to check IsAcceptableNonMemberOperatorCandidate,
// later?
if (!FunTmpl->getDeclContext()->isRecord())
Functions.addDecl(FunTmpl, Op.getAccess());
}
}
}
void ADLResult::insert(NamedDecl *New) {
NamedDecl *&Old = Decls[cast<NamedDecl>(New->getCanonicalDecl())];
// If we haven't yet seen a decl for this key, or the last decl
// was exactly this one, we're done.
if (Old == 0 || Old == New) {
Old = New;
return;
}
// Otherwise, decide which is a more recent redeclaration.
FunctionDecl *OldFD, *NewFD;
if (isa<FunctionTemplateDecl>(New)) {
OldFD = cast<FunctionTemplateDecl>(Old)->getTemplatedDecl();
NewFD = cast<FunctionTemplateDecl>(New)->getTemplatedDecl();
} else {
OldFD = cast<FunctionDecl>(Old);
NewFD = cast<FunctionDecl>(New);
}
FunctionDecl *Cursor = NewFD;
while (true) {
Cursor = Cursor->getPreviousDeclaration();
// If we got to the end without finding OldFD, OldFD is the newer
// declaration; leave things as they are.
if (!Cursor) return;
// If we do find OldFD, then NewFD is newer.
if (Cursor == OldFD) break;
// Otherwise, keep looking.
}
Old = New;
}
void Sema::ArgumentDependentLookup(DeclarationName Name, bool Operator,
Expr **Args, unsigned NumArgs,
ADLResult &Result) {
// Find all of the associated namespaces and classes based on the
// arguments we have.
AssociatedNamespaceSet AssociatedNamespaces;
AssociatedClassSet AssociatedClasses;
FindAssociatedClassesAndNamespaces(Args, NumArgs,
AssociatedNamespaces,
AssociatedClasses);
QualType T1, T2;
if (Operator) {
T1 = Args[0]->getType();
if (NumArgs >= 2)
T2 = Args[1]->getType();
}
// C++ [basic.lookup.argdep]p3:
// Let X be the lookup set produced by unqualified lookup (3.4.1)
// and let Y be the lookup set produced by argument dependent
// lookup (defined as follows). If X contains [...] then Y is
// empty. Otherwise Y is the set of declarations found in the
// namespaces associated with the argument types as described
// below. The set of declarations found by the lookup of the name
// is the union of X and Y.
//
// Here, we compute Y and add its members to the overloaded
// candidate set.
for (AssociatedNamespaceSet::iterator NS = AssociatedNamespaces.begin(),
NSEnd = AssociatedNamespaces.end();
NS != NSEnd; ++NS) {
// When considering an associated namespace, the lookup is the
// same as the lookup performed when the associated namespace is
// used as a qualifier (3.4.3.2) except that:
//
// -- Any using-directives in the associated namespace are
// ignored.
//
// -- Any namespace-scope friend functions declared in
// associated classes are visible within their respective
// namespaces even if they are not visible during an ordinary
// lookup (11.4).
DeclContext::lookup_iterator I, E;
for (llvm::tie(I, E) = (*NS)->lookup(Name); I != E; ++I) {
NamedDecl *D = *I;
// If the only declaration here is an ordinary friend, consider
// it only if it was declared in an associated classes.
if (D->getIdentifierNamespace() == Decl::IDNS_OrdinaryFriend) {
DeclContext *LexDC = D->getLexicalDeclContext();
if (!AssociatedClasses.count(cast<CXXRecordDecl>(LexDC)))
continue;
}
if (isa<UsingShadowDecl>(D))
D = cast<UsingShadowDecl>(D)->getTargetDecl();
if (isa<FunctionDecl>(D)) {
if (Operator &&
!IsAcceptableNonMemberOperatorCandidate(cast<FunctionDecl>(D),
T1, T2, Context))
continue;
} else if (!isa<FunctionTemplateDecl>(D))
continue;
Result.insert(D);
}
}
}
//----------------------------------------------------------------------------
// Search for all visible declarations.
//----------------------------------------------------------------------------
VisibleDeclConsumer::~VisibleDeclConsumer() { }
namespace {
class ShadowContextRAII;
class VisibleDeclsRecord {
public:
/// \brief An entry in the shadow map, which is optimized to store a
/// single declaration (the common case) but can also store a list
/// of declarations.
class ShadowMapEntry {
typedef llvm::SmallVector<NamedDecl *, 4> DeclVector;
/// \brief Contains either the solitary NamedDecl * or a vector
/// of declarations.
llvm::PointerUnion<NamedDecl *, DeclVector*> DeclOrVector;
public:
ShadowMapEntry() : DeclOrVector() { }
void Add(NamedDecl *ND);
void Destroy();
// Iteration.
typedef NamedDecl **iterator;
iterator begin();
iterator end();
};
private:
/// \brief A mapping from declaration names to the declarations that have
/// this name within a particular scope.
typedef llvm::DenseMap<DeclarationName, ShadowMapEntry> ShadowMap;
/// \brief A list of shadow maps, which is used to model name hiding.
std::list<ShadowMap> ShadowMaps;
/// \brief The declaration contexts we have already visited.
llvm::SmallPtrSet<DeclContext *, 8> VisitedContexts;
friend class ShadowContextRAII;
public:
/// \brief Determine whether we have already visited this context
/// (and, if not, note that we are going to visit that context now).
bool visitedContext(DeclContext *Ctx) {
return !VisitedContexts.insert(Ctx);
}
/// \brief Determine whether the given declaration is hidden in the
/// current scope.
///
/// \returns the declaration that hides the given declaration, or
/// NULL if no such declaration exists.
NamedDecl *checkHidden(NamedDecl *ND);
/// \brief Add a declaration to the current shadow map.
void add(NamedDecl *ND) { ShadowMaps.back()[ND->getDeclName()].Add(ND); }
};
/// \brief RAII object that records when we've entered a shadow context.
class ShadowContextRAII {
VisibleDeclsRecord &Visible;
typedef VisibleDeclsRecord::ShadowMap ShadowMap;
public:
ShadowContextRAII(VisibleDeclsRecord &Visible) : Visible(Visible) {
Visible.ShadowMaps.push_back(ShadowMap());
}
~ShadowContextRAII() {
for (ShadowMap::iterator E = Visible.ShadowMaps.back().begin(),
EEnd = Visible.ShadowMaps.back().end();
E != EEnd;
++E)
E->second.Destroy();
Visible.ShadowMaps.pop_back();
}
};
} // end anonymous namespace
void VisibleDeclsRecord::ShadowMapEntry::Add(NamedDecl *ND) {
if (DeclOrVector.isNull()) {
// 0 - > 1 elements: just set the single element information.
DeclOrVector = ND;
return;
}
if (NamedDecl *PrevND = DeclOrVector.dyn_cast<NamedDecl *>()) {
// 1 -> 2 elements: create the vector of results and push in the
// existing declaration.
DeclVector *Vec = new DeclVector;
Vec->push_back(PrevND);
DeclOrVector = Vec;
}
// Add the new element to the end of the vector.
DeclOrVector.get<DeclVector*>()->push_back(ND);
}
void VisibleDeclsRecord::ShadowMapEntry::Destroy() {
if (DeclVector *Vec = DeclOrVector.dyn_cast<DeclVector *>()) {
delete Vec;
DeclOrVector = ((NamedDecl *)0);
}
}
VisibleDeclsRecord::ShadowMapEntry::iterator
VisibleDeclsRecord::ShadowMapEntry::begin() {
if (DeclOrVector.isNull())
return 0;
if (DeclOrVector.dyn_cast<NamedDecl *>())
return &reinterpret_cast<NamedDecl*&>(DeclOrVector);
return DeclOrVector.get<DeclVector *>()->begin();
}
VisibleDeclsRecord::ShadowMapEntry::iterator
VisibleDeclsRecord::ShadowMapEntry::end() {
if (DeclOrVector.isNull())
return 0;
if (DeclOrVector.dyn_cast<NamedDecl *>())
return &reinterpret_cast<NamedDecl*&>(DeclOrVector) + 1;
return DeclOrVector.get<DeclVector *>()->end();
}
NamedDecl *VisibleDeclsRecord::checkHidden(NamedDecl *ND) {
// Look through using declarations.
ND = ND->getUnderlyingDecl();
unsigned IDNS = ND->getIdentifierNamespace();
std::list<ShadowMap>::reverse_iterator SM = ShadowMaps.rbegin();
for (std::list<ShadowMap>::reverse_iterator SMEnd = ShadowMaps.rend();
SM != SMEnd; ++SM) {
ShadowMap::iterator Pos = SM->find(ND->getDeclName());
if (Pos == SM->end())
continue;
for (ShadowMapEntry::iterator I = Pos->second.begin(),
IEnd = Pos->second.end();
I != IEnd; ++I) {
// A tag declaration does not hide a non-tag declaration.
if ((*I)->getIdentifierNamespace() == Decl::IDNS_Tag &&
(IDNS & (Decl::IDNS_Member | Decl::IDNS_Ordinary |
Decl::IDNS_ObjCProtocol)))
continue;
// Protocols are in distinct namespaces from everything else.
if ((((*I)->getIdentifierNamespace() & Decl::IDNS_ObjCProtocol)
|| (IDNS & Decl::IDNS_ObjCProtocol)) &&
(*I)->getIdentifierNamespace() != IDNS)
continue;
// Functions and function templates in the same scope overload
// rather than hide. FIXME: Look for hiding based on function
// signatures!
if ((*I)->isFunctionOrFunctionTemplate() &&
ND->isFunctionOrFunctionTemplate() &&
SM == ShadowMaps.rbegin())
continue;
// We've found a declaration that hides this one.
return *I;
}
}
return 0;
}
static void LookupVisibleDecls(DeclContext *Ctx, LookupResult &Result,
bool QualifiedNameLookup,
bool InBaseClass,
VisibleDeclConsumer &Consumer,
VisibleDeclsRecord &Visited) {
if (!Ctx)
return;
// Make sure we don't visit the same context twice.
if (Visited.visitedContext(Ctx->getPrimaryContext()))
return;
// Enumerate all of the results in this context.
for (DeclContext *CurCtx = Ctx->getPrimaryContext(); CurCtx;
CurCtx = CurCtx->getNextContext()) {
for (DeclContext::decl_iterator D = CurCtx->decls_begin(),
DEnd = CurCtx->decls_end();
D != DEnd; ++D) {
if (NamedDecl *ND = dyn_cast<NamedDecl>(*D))
if (Result.isAcceptableDecl(ND)) {
Consumer.FoundDecl(ND, Visited.checkHidden(ND), InBaseClass);
Visited.add(ND);
}
// Visit transparent contexts inside this context.
if (DeclContext *InnerCtx = dyn_cast<DeclContext>(*D)) {
if (InnerCtx->isTransparentContext())
LookupVisibleDecls(InnerCtx, Result, QualifiedNameLookup, InBaseClass,
Consumer, Visited);
}
}
}
// Traverse using directives for qualified name lookup.
if (QualifiedNameLookup) {
ShadowContextRAII Shadow(Visited);
DeclContext::udir_iterator I, E;
for (llvm::tie(I, E) = Ctx->getUsingDirectives(); I != E; ++I) {
LookupVisibleDecls((*I)->getNominatedNamespace(), Result,
QualifiedNameLookup, InBaseClass, Consumer, Visited);
}
}
// Traverse the contexts of inherited C++ classes.
if (CXXRecordDecl *Record = dyn_cast<CXXRecordDecl>(Ctx)) {
if (!Record->hasDefinition())
return;
for (CXXRecordDecl::base_class_iterator B = Record->bases_begin(),
BEnd = Record->bases_end();
B != BEnd; ++B) {
QualType BaseType = B->getType();
// Don't look into dependent bases, because name lookup can't look
// there anyway.
if (BaseType->isDependentType())
continue;
const RecordType *Record = BaseType->getAs<RecordType>();
if (!Record)
continue;
// FIXME: It would be nice to be able to determine whether referencing
// a particular member would be ambiguous. For example, given
//
// struct A { int member; };
// struct B { int member; };
// struct C : A, B { };
//
// void f(C *c) { c->### }
//
// accessing 'member' would result in an ambiguity. However, we
// could be smart enough to qualify the member with the base
// class, e.g.,
//
// c->B::member
//
// or
//
// c->A::member
// Find results in this base class (and its bases).
ShadowContextRAII Shadow(Visited);
LookupVisibleDecls(Record->getDecl(), Result, QualifiedNameLookup,
true, Consumer, Visited);
}
}
// Traverse the contexts of Objective-C classes.
if (ObjCInterfaceDecl *IFace = dyn_cast<ObjCInterfaceDecl>(Ctx)) {
// Traverse categories.
for (ObjCCategoryDecl *Category = IFace->getCategoryList();
Category; Category = Category->getNextClassCategory()) {
ShadowContextRAII Shadow(Visited);
LookupVisibleDecls(Category, Result, QualifiedNameLookup, false,
Consumer, Visited);
}
// Traverse protocols.
for (ObjCInterfaceDecl::protocol_iterator I = IFace->protocol_begin(),
E = IFace->protocol_end(); I != E; ++I) {
ShadowContextRAII Shadow(Visited);
LookupVisibleDecls(*I, Result, QualifiedNameLookup, false, Consumer,
Visited);
}
// Traverse the superclass.
if (IFace->getSuperClass()) {
ShadowContextRAII Shadow(Visited);
LookupVisibleDecls(IFace->getSuperClass(), Result, QualifiedNameLookup,
true, Consumer, Visited);
}
} else if (ObjCProtocolDecl *Protocol = dyn_cast<ObjCProtocolDecl>(Ctx)) {
for (ObjCProtocolDecl::protocol_iterator I = Protocol->protocol_begin(),
E = Protocol->protocol_end(); I != E; ++I) {
ShadowContextRAII Shadow(Visited);
LookupVisibleDecls(*I, Result, QualifiedNameLookup, false, Consumer,
Visited);
}
} else if (ObjCCategoryDecl *Category = dyn_cast<ObjCCategoryDecl>(Ctx)) {
for (ObjCCategoryDecl::protocol_iterator I = Category->protocol_begin(),
E = Category->protocol_end(); I != E; ++I) {
ShadowContextRAII Shadow(Visited);
LookupVisibleDecls(*I, Result, QualifiedNameLookup, false, Consumer,
Visited);
}
}
}
static void LookupVisibleDecls(Scope *S, LookupResult &Result,
UnqualUsingDirectiveSet &UDirs,
VisibleDeclConsumer &Consumer,
VisibleDeclsRecord &Visited) {
if (!S)
return;
if (!S->getEntity() || !S->getParent() ||
((DeclContext *)S->getEntity())->isFunctionOrMethod()) {
// Walk through the declarations in this Scope.
for (Scope::decl_iterator D = S->decl_begin(), DEnd = S->decl_end();
D != DEnd; ++D) {
if (NamedDecl *ND = dyn_cast<NamedDecl>((Decl *)((*D).get())))
if (Result.isAcceptableDecl(ND)) {
Consumer.FoundDecl(ND, Visited.checkHidden(ND), false);
Visited.add(ND);
}
}
}
DeclContext *Entity = 0;
if (S->getEntity()) {
// Look into this scope's declaration context, along with any of its
// parent lookup contexts (e.g., enclosing classes), up to the point
// where we hit the context stored in the next outer scope.
Entity = (DeclContext *)S->getEntity();
DeclContext *OuterCtx = findOuterContext(S);
for (DeclContext *Ctx = Entity; Ctx && Ctx->getPrimaryContext() != OuterCtx;
Ctx = Ctx->getLookupParent()) {
if (ObjCMethodDecl *Method = dyn_cast<ObjCMethodDecl>(Ctx)) {
if (Method->isInstanceMethod()) {
// For instance methods, look for ivars in the method's interface.
LookupResult IvarResult(Result.getSema(), Result.getLookupName(),
Result.getNameLoc(), Sema::LookupMemberName);
if (ObjCInterfaceDecl *IFace = Method->getClassInterface())
LookupVisibleDecls(IFace, IvarResult, /*QualifiedNameLookup=*/false,
/*InBaseClass=*/false, Consumer, Visited);
}
// We've already performed all of the name lookup that we need
// to for Objective-C methods; the next context will be the
// outer scope.
break;
}
if (Ctx->isFunctionOrMethod())
continue;
LookupVisibleDecls(Ctx, Result, /*QualifiedNameLookup=*/false,
/*InBaseClass=*/false, Consumer, Visited);
}
} else if (!S->getParent()) {
// Look into the translation unit scope. We walk through the translation
// unit's declaration context, because the Scope itself won't have all of
// the declarations if we loaded a precompiled header.
// FIXME: We would like the translation unit's Scope object to point to the
// translation unit, so we don't need this special "if" branch. However,
// doing so would force the normal C++ name-lookup code to look into the
// translation unit decl when the IdentifierInfo chains would suffice.
// Once we fix that problem (which is part of a more general "don't look
// in DeclContexts unless we have to" optimization), we can eliminate this.
Entity = Result.getSema().Context.getTranslationUnitDecl();
LookupVisibleDecls(Entity, Result, /*QualifiedNameLookup=*/false,
/*InBaseClass=*/false, Consumer, Visited);
}
if (Entity) {
// Lookup visible declarations in any namespaces found by using
// directives.
UnqualUsingDirectiveSet::const_iterator UI, UEnd;
llvm::tie(UI, UEnd) = UDirs.getNamespacesFor(Entity);
for (; UI != UEnd; ++UI)
LookupVisibleDecls(const_cast<DeclContext *>(UI->getNominatedNamespace()),
Result, /*QualifiedNameLookup=*/false,
/*InBaseClass=*/false, Consumer, Visited);
}
// Lookup names in the parent scope.
ShadowContextRAII Shadow(Visited);
LookupVisibleDecls(S->getParent(), Result, UDirs, Consumer, Visited);
}
void Sema::LookupVisibleDecls(Scope *S, LookupNameKind Kind,
VisibleDeclConsumer &Consumer) {
// Determine the set of using directives available during
// unqualified name lookup.
Scope *Initial = S;
UnqualUsingDirectiveSet UDirs;
if (getLangOptions().CPlusPlus) {
// Find the first namespace or translation-unit scope.
while (S && !isNamespaceOrTranslationUnitScope(S))
S = S->getParent();
UDirs.visitScopeChain(Initial, S);
}
UDirs.done();
// Look for visible declarations.
LookupResult Result(*this, DeclarationName(), SourceLocation(), Kind);
VisibleDeclsRecord Visited;
ShadowContextRAII Shadow(Visited);
::LookupVisibleDecls(Initial, Result, UDirs, Consumer, Visited);
}
void Sema::LookupVisibleDecls(DeclContext *Ctx, LookupNameKind Kind,
VisibleDeclConsumer &Consumer) {
LookupResult Result(*this, DeclarationName(), SourceLocation(), Kind);
VisibleDeclsRecord Visited;
ShadowContextRAII Shadow(Visited);
::LookupVisibleDecls(Ctx, Result, /*QualifiedNameLookup=*/true,
/*InBaseClass=*/false, Consumer, Visited);
}
//----------------------------------------------------------------------------
// Typo correction
//----------------------------------------------------------------------------
namespace {
class TypoCorrectionConsumer : public VisibleDeclConsumer {
/// \brief The name written that is a typo in the source.
llvm::StringRef Typo;
/// \brief The results found that have the smallest edit distance
/// found (so far) with the typo name.
llvm::SmallVector<NamedDecl *, 4> BestResults;
/// \brief The best edit distance found so far.
unsigned BestEditDistance;
public:
explicit TypoCorrectionConsumer(IdentifierInfo *Typo)
: Typo(Typo->getName()) { }
virtual void FoundDecl(NamedDecl *ND, NamedDecl *Hiding, bool InBaseClass);
typedef llvm::SmallVector<NamedDecl *, 4>::const_iterator iterator;
iterator begin() const { return BestResults.begin(); }
iterator end() const { return BestResults.end(); }
bool empty() const { return BestResults.empty(); }
unsigned getBestEditDistance() const { return BestEditDistance; }
};
}
void TypoCorrectionConsumer::FoundDecl(NamedDecl *ND, NamedDecl *Hiding,
bool InBaseClass) {
// Don't consider hidden names for typo correction.
if (Hiding)
return;
// Only consider entities with identifiers for names, ignoring
// special names (constructors, overloaded operators, selectors,
// etc.).
IdentifierInfo *Name = ND->getIdentifier();
if (!Name)
return;
// Compute the edit distance between the typo and the name of this
// entity. If this edit distance is not worse than the best edit
// distance we've seen so far, add it to the list of results.
unsigned ED = Typo.edit_distance(Name->getName());
if (!BestResults.empty()) {
if (ED < BestEditDistance) {
// This result is better than any we've seen before; clear out
// the previous results.
BestResults.clear();
BestEditDistance = ED;
} else if (ED > BestEditDistance) {
// This result is worse than the best results we've seen so far;
// ignore it.
return;
}
} else
BestEditDistance = ED;
BestResults.push_back(ND);
}
/// \brief Try to "correct" a typo in the source code by finding
/// visible declarations whose names are similar to the name that was
/// present in the source code.
///
/// \param Res the \c LookupResult structure that contains the name
/// that was present in the source code along with the name-lookup
/// criteria used to search for the name. On success, this structure
/// will contain the results of name lookup.
///
/// \param S the scope in which name lookup occurs.
///
/// \param SS the nested-name-specifier that precedes the name we're
/// looking for, if present.
///
/// \param MemberContext if non-NULL, the context in which to look for
/// a member access expression.
///
/// \param EnteringContext whether we're entering the context described by
/// the nested-name-specifier SS.
///
/// \param OPT when non-NULL, the search for visible declarations will
/// also walk the protocols in the qualified interfaces of \p OPT.
///
/// \returns true if the typo was corrected, in which case the \p Res
/// structure will contain the results of name lookup for the
/// corrected name. Otherwise, returns false.
bool Sema::CorrectTypo(LookupResult &Res, Scope *S, const CXXScopeSpec *SS,
DeclContext *MemberContext, bool EnteringContext,
const ObjCObjectPointerType *OPT) {
if (Diags.hasFatalErrorOccurred())
return false;
// Provide a stop gap for files that are just seriously broken. Trying
// to correct all typos can turn into a HUGE performance penalty, causing
// some files to take minutes to get rejected by the parser.
// FIXME: Is this the right solution?
if (TyposCorrected == 20)
return false;
++TyposCorrected;
// We only attempt to correct typos for identifiers.
IdentifierInfo *Typo = Res.getLookupName().getAsIdentifierInfo();
if (!Typo)
return false;
// If the scope specifier itself was invalid, don't try to correct
// typos.
if (SS && SS->isInvalid())
return false;
// Never try to correct typos during template deduction or
// instantiation.
if (!ActiveTemplateInstantiations.empty())
return false;
TypoCorrectionConsumer Consumer(Typo);
if (MemberContext) {
LookupVisibleDecls(MemberContext, Res.getLookupKind(), Consumer);
// Look in qualified interfaces.
if (OPT) {
for (ObjCObjectPointerType::qual_iterator
I = OPT->qual_begin(), E = OPT->qual_end();
I != E; ++I)
LookupVisibleDecls(*I, Res.getLookupKind(), Consumer);
}
} else if (SS && SS->isSet()) {
DeclContext *DC = computeDeclContext(*SS, EnteringContext);
if (!DC)
return false;
LookupVisibleDecls(DC, Res.getLookupKind(), Consumer);
} else {
LookupVisibleDecls(S, Res.getLookupKind(), Consumer);
}
if (Consumer.empty())
return false;
// Only allow a single, closest name in the result set (it's okay to
// have overloads of that name, though).
TypoCorrectionConsumer::iterator I = Consumer.begin();
DeclarationName BestName = (*I)->getDeclName();
// If we've found an Objective-C ivar or property, don't perform
// name lookup again; we'll just return the result directly.
NamedDecl *FoundBest = 0;
if (isa<ObjCIvarDecl>(*I) || isa<ObjCPropertyDecl>(*I))
FoundBest = *I;
++I;
for(TypoCorrectionConsumer::iterator IEnd = Consumer.end(); I != IEnd; ++I) {
if (BestName != (*I)->getDeclName())
return false;
// FIXME: If there are both ivars and properties of the same name,
// don't return both because the callee can't handle two
// results. We really need to separate ivar lookup from property
// lookup to avoid this problem.
FoundBest = 0;
}
// BestName is the closest viable name to what the user
// typed. However, to make sure that we don't pick something that's
// way off, make sure that the user typed at least 3 characters for
// each correction.
unsigned ED = Consumer.getBestEditDistance();
if (ED == 0 || (BestName.getAsIdentifierInfo()->getName().size() / ED) < 3)
return false;
// Perform name lookup again with the name we chose, and declare
// success if we found something that was not ambiguous.
Res.clear();
Res.setLookupName(BestName);
// If we found an ivar or property, add that result; no further
// lookup is required.
if (FoundBest)
Res.addDecl(FoundBest);
// If we're looking into the context of a member, perform qualified
// name lookup on the best name.
else if (MemberContext)
LookupQualifiedName(Res, MemberContext);
// Perform lookup as if we had just parsed the best name.
else
LookupParsedName(Res, S, SS, /*AllowBuiltinCreation=*/false,
EnteringContext);
if (Res.isAmbiguous()) {
Res.suppressDiagnostics();
return false;
}
return Res.getResultKind() != LookupResult::NotFound;
}