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f736e1711cb4202a1fcf52a7064097caccfb003c
swift-mirror/lib/AST/Module.cpp
Doug Gregor f736e1711c Check operator declaration binding in the first pass for FuncDecls. 
This eliminates the pre-pass we were performing to bind the operator
decls, which was only a pre-pass because we used to bind unresolved
declaration references too early. In the process, fixed some bugs
(e.g., it wasn't checking methods at all) and improved the QoI with
Fix-Its and notes:

t.swift:2:6: error: prefix unary operator missing 'prefix' attribute
func ~~~(x : Float) {}
     ^
     [prefix] 
t.swift:1:17: note: prefix operator found here
operator prefix ~~~ {}
                ^



Swift SVN r7099
2013-08-09 21:01:47 +00:00

470 lines
17 KiB
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//===--- Module.cpp - Swift Language Module Implementation ----------------===//
//
// This source file is part of the Swift.org open source project
//
// Copyright (c) 2014 - 2015 Apple Inc. and the Swift project authors
// Licensed under Apache License v2.0 with Runtime Library Exception
//
// See http://swift.org/LICENSE.txt for license information
// See http://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
//
//===----------------------------------------------------------------------===//
//
// This file implements the Module class and subclasses.
//
//===----------------------------------------------------------------------===//
#include "swift/AST/Diagnostics.h"
#include "swift/AST/Module.h"
#include "swift/AST/ModuleLoader.h"
#include "swift/AST/NameLookup.h"
#include "swift/AST/AST.h"
#include "swift/AST/PrintOptions.h"
#include "clang/Basic/Module.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/DenseSet.h"
#include "llvm/ADT/TinyPtrVector.h"
#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/Support/raw_ostream.h"
using namespace swift;
//===----------------------------------------------------------------------===//
// Builtin Module Name lookup
//===----------------------------------------------------------------------===//
namespace {
/// BuiltinModuleCache - This is the type of the cache for the BuiltinModule.
/// This is lazily created on its first use an hangs off
/// Module::LookupCachePimpl.
class BuiltinModuleCache {
/// The cache of identifiers we've already looked up. We use a
/// single hashtable for both types and values as a minor
/// optimization; this prevents us from having both a builtin type
/// and a builtin value with the same name, but that's okay.
llvm::DenseMap<Identifier, ValueDecl*> Cache;
public:
void lookupValue(Identifier Name, NLKind LookupKind, BuiltinModule &M,
SmallVectorImpl<ValueDecl*> &Result);
};
} // end anonymous namespace.
static BuiltinModuleCache &getBuiltinCachePimpl(void *&Ptr) {
// FIXME: This leaks. Sticking this into ASTContext isn't enough because then
// the DenseMap will leak.
if (Ptr == 0)
Ptr = new BuiltinModuleCache();
return *(BuiltinModuleCache*)Ptr;
}
void BuiltinModuleCache::lookupValue(Identifier Name, NLKind LookupKind,
BuiltinModule &M,
SmallVectorImpl<ValueDecl*> &Result) {
// Only qualified lookup ever finds anything in the builtin module.
if (LookupKind != NLKind::QualifiedLookup) return;
ValueDecl *&Entry = Cache[Name];
if (Entry == 0)
if (Type Ty = getBuiltinType(M.Ctx, Name.str()))
Entry = new (M.Ctx) TypeAliasDecl(SourceLoc(), Name, SourceLoc(),
TypeLoc::withoutLoc(Ty),
M.Ctx.TheBuiltinModule,
MutableArrayRef<TypeLoc>());
if (Entry == 0)
Entry = getBuiltinValue(M.Ctx, Name);
if (Entry)
Result.push_back(Entry);
}
//===----------------------------------------------------------------------===//
// Normal Module Name Lookup
//===----------------------------------------------------------------------===//
namespace {
/// TUModuleCache - This is the type of the cache for the TranslationUnit.
/// This is lazily created on its first use an hangs off
/// Module::LookupCachePimpl.
class TUModuleCache {
llvm::DenseMap<Identifier, TinyPtrVector<ValueDecl*>> TopLevelValues;
void doPopulateCache(ArrayRef<Decl*> decls, bool onlyOperators);
public:
typedef Module::AccessPathTy AccessPathTy;
TUModuleCache(const TranslationUnit &TU);
void lookupValue(AccessPathTy AccessPath, Identifier Name,
NLKind LookupKind, TranslationUnit &TU,
SmallVectorImpl<ValueDecl*> &Result);
void lookupVisibleDecls(AccessPathTy AccessPath,
VisibleDeclConsumer &Consumer,
NLKind LookupKind,
const TranslationUnit &TU);
};
} // end anonymous namespace.
static TUModuleCache &getTUCachePimpl(void *&Ptr, const TranslationUnit &TU) {
// FIXME: This leaks. Sticking this into ASTContext isn't enough because then
// the DenseMap will leak.
if (Ptr == 0)
Ptr = new TUModuleCache(TU);
return *(TUModuleCache*)Ptr;
}
static void freeTUCachePimpl(void *&Ptr) {
delete (TUModuleCache*)Ptr;
Ptr = 0;
}
void TUModuleCache::doPopulateCache(ArrayRef<Decl*> decls, bool onlyOperators) {
for (Decl *D : decls) {
if (ValueDecl *VD = dyn_cast<ValueDecl>(D))
if (onlyOperators ? VD->getName().isOperator() : !VD->getName().empty())
TopLevelValues[VD->getName()].push_back(VD);
if (NominalTypeDecl *NTD = dyn_cast<NominalTypeDecl>(D))
doPopulateCache(NTD->getMembers(), true);
if (ExtensionDecl *ED = dyn_cast<ExtensionDecl>(D))
doPopulateCache(ED->getMembers(), true);
}
}
/// Populate our cache on the first name lookup.
TUModuleCache::TUModuleCache(const TranslationUnit &TU) {
doPopulateCache(TU.Decls, false);
}
void TUModuleCache::lookupValue(AccessPathTy AccessPath, Identifier Name,
NLKind LookupKind, TranslationUnit &TU,
SmallVectorImpl<ValueDecl*> &Result) {
assert(AccessPath.size() <= 1 && "can only refer to top-level decls");
// If this import is specific to some named type or decl ("import swift.int")
// then filter out any lookups that don't match.
if (AccessPath.size() == 1 && AccessPath.front().first != Name)
return;
auto I = TopLevelValues.find(Name);
if (I == TopLevelValues.end()) return;
Result.reserve(I->second.size());
for (ValueDecl *Elt : I->second)
Result.push_back(Elt);
}
void TUModuleCache::lookupVisibleDecls(AccessPathTy AccessPath,
VisibleDeclConsumer &Consumer,
NLKind LookupKind,
const TranslationUnit &TU) {
assert(AccessPath.size() <= 1 && "can only refer to top-level decls");
if (!AccessPath.empty()) {
auto I = TopLevelValues.find(AccessPath.front().first);
if (I == TopLevelValues.end()) return;
for (auto vd : I->second)
Consumer.foundDecl(vd);
return;
}
for (auto &tlv : TopLevelValues) {
for (ValueDecl *vd : tlv.second)
Consumer.foundDecl(vd);
}
}
//===----------------------------------------------------------------------===//
// Module Implementation
//===----------------------------------------------------------------------===//
/// lookupValue - Look up a (possibly overloaded) value set at top-level scope
/// (but with the specified access path, which may come from an import decl)
/// within the current module. This does a simple local lookup, not
/// recursively looking through imports.
void Module::lookupValue(AccessPathTy AccessPath, Identifier Name,
NLKind LookupKind,
SmallVectorImpl<ValueDecl*> &Result) {
if (BuiltinModule *BM = dyn_cast<BuiltinModule>(this)) {
assert(AccessPath.empty() && "builtin module's access path always empty!");
return getBuiltinCachePimpl(LookupCachePimpl)
.lookupValue(Name, LookupKind, *BM, Result);
}
if (auto TU = dyn_cast<TranslationUnit>(this)) {
// Look in the translation unit.
return getTUCachePimpl(LookupCachePimpl, *TU)
.lookupValue(AccessPath, Name, LookupKind, *TU, Result);
}
return cast<LoadedModule>(this)->lookupValue(AccessPath, Name, LookupKind,
Result);
}
/// lookupVisibleDecls - Find ValueDecls in the module and pass them to the
/// given consumer object.
void Module::lookupVisibleDecls(AccessPathTy AccessPath,
VisibleDeclConsumer &Consumer,
NLKind LookupKind) const {
if (auto BM = dyn_cast<BuiltinModule>(this)) {
// TODO Look through the Builtin module.
(void)BM;
return;
}
if (auto TU = dyn_cast<TranslationUnit>(this)) {
return getTUCachePimpl(LookupCachePimpl, *TU)
.lookupVisibleDecls(AccessPath, Consumer, LookupKind, *TU);
}
return cast<LoadedModule>(this)->lookupVisibleDecls(AccessPath, Consumer,
LookupKind);
}
namespace {
// Returns Nothing on error, Optional(nullptr) if no operator decl found, or
// Optional(decl) if decl was found.
template<typename OP_DECL>
Optional<OP_DECL *> lookupOperatorDeclForName(Module *M,
SourceLoc Loc,
Identifier Name,
llvm::StringMap<OP_DECL *> TranslationUnit::*OP_MAP)
{
if (auto loadedModule = dyn_cast<LoadedModule>(M))
return loadedModule->lookupOperator<OP_DECL>(Name);
auto *TU = dyn_cast<TranslationUnit>(M);
if (!TU)
return Nothing;
// Look for an operator declaration in the current module.
auto found = (TU->*OP_MAP).find(Name.get());
if (found != (TU->*OP_MAP).end())
return found->getValue()? Optional<OP_DECL *>(found->getValue()) : Nothing;
// Look for imported operator decls.
llvm::DenseSet<OP_DECL*> importedOperators;
for (auto &imported : TU->getImportedModules()) {
Optional<OP_DECL *> maybeOp
= lookupOperatorDeclForName(imported.first.second, Loc, Name, OP_MAP);
if (!maybeOp)
return Nothing;
if (OP_DECL *op = *maybeOp)
importedOperators.insert(op);
}
// If we found a single import, use it.
if (importedOperators.empty()) {
// Cache the mapping so we don't need to troll imports next time.
(TU->*OP_MAP)[Name.get()] = nullptr;
return Nothing;
}
if (importedOperators.size() == 1) {
// Cache the mapping so we don't need to troll imports next time.
OP_DECL *result = *importedOperators.begin();
(TU->*OP_MAP)[Name.get()] = result;
return result;
}
// Otherwise, check for conflicts.
auto i = importedOperators.begin(), end = importedOperators.end();
OP_DECL *first = *i;
for (++i; i != end; ++i) {
if ((*i)->conflictsWith(first)) {
if (Loc.isValid()) {
ASTContext &C = M->getASTContext();
C.Diags.diagnose(Loc, diag::ambiguous_operator_decls);
C.Diags.diagnose(first->getLoc(), diag::found_this_operator_decl);
C.Diags.diagnose((*i)->getLoc(), diag::found_this_operator_decl);
}
return Nothing;
}
}
// Cache the mapping so we don't need to troll imports next time.
(TU->*OP_MAP)[Name.get()] = first;
return first;
}
} // end anonymous namespace
Optional<PrefixOperatorDecl *> Module::lookupPrefixOperator(Identifier name,
SourceLoc diagLoc) {
return lookupOperatorDeclForName(this, diagLoc, name,
&TranslationUnit::PrefixOperators);
}
Optional<PostfixOperatorDecl *> Module::lookupPostfixOperator(Identifier name,
SourceLoc diagLoc) {
return lookupOperatorDeclForName(this, diagLoc, name,
&TranslationUnit::PostfixOperators);
}
Optional<InfixOperatorDecl *> Module::lookupInfixOperator(Identifier name,
SourceLoc diagLoc) {
return lookupOperatorDeclForName(this, diagLoc, name,
&TranslationUnit::InfixOperators);
}
void
Module::getReexportedModules(SmallVectorImpl<ImportedModule> &modules) const {
if (isa<BuiltinModule>(this))
return;
if (auto TU = dyn_cast<TranslationUnit>(this)) {
// A translation unit doesn't really re-export all of its imported modules,
// but for the purposes of lookup a TU is always top-level, so we want to
// look at regular imports as well as re-exports.
for (auto importPair : TU->getImportedModules())
modules.push_back(importPair.first);
return;
}
return cast<LoadedModule>(this)->getReexportedModules(modules);
}
namespace {
/// Arbitrarily orders ImportedModule records, for inclusion in sets and such.
class OrderImportedModules {
using ImportedModule = Module::ImportedModule;
using AccessPathTy = Module::AccessPathTy;
public:
bool operator()(const ImportedModule &lhs, const ImportedModule &rhs) {
if (lhs.second != rhs.second)
return std::less<const Module *>()(lhs.second, rhs.second);
if (lhs.first.data() != rhs.first.data())
return std::less<AccessPathTy::iterator>()(lhs.first.begin(),
rhs.first.begin());
return lhs.first.size() < rhs.first.size();
}
};
}
bool Module::isSameAccessPath(AccessPathTy lhs, AccessPathTy rhs) {
using AccessPathElem = std::pair<Identifier, SourceLoc>;
if (lhs.size() != rhs.size())
return false;
auto iters = std::mismatch(lhs.begin(), lhs.end(), rhs.begin(),
[](const AccessPathElem &lElem,
const AccessPathElem &rElem) {
return lElem.first == rElem.first;
});
return iters.first == lhs.end();
}
void Module::forAllVisibleModules(Optional<AccessPathTy> thisPath,
std::function<bool(ImportedModule)> fn) {
llvm::SmallSet<ImportedModule, 32, OrderImportedModules> visited;
SmallVector<ImportedModule, 32> queue;
AccessPathTy overridingPath;
if (thisPath.hasValue()) {
overridingPath = thisPath.getValue();
queue.push_back(ImportedModule(overridingPath, this));
} else {
visited.insert(ImportedModule({}, this));
getReexportedModules(queue);
}
while (!queue.empty()) {
auto next = queue.pop_back_val();
// Filter any whole-module imports, and skip specific-decl imports if the
// import path doesn't match exactly.
if (next.first.empty())
next.first = overridingPath;
else if (!overridingPath.empty() &&
!isSameAccessPath(next.first, overridingPath)) {
// If we ever allow importing non-top-level decls, it's possible the rule
// above isn't what we want.
assert(next.first.size() == 1 && "import of non-top-level decl");
continue;
}
if (!visited.insert(next))
continue;
if (!fn(next))
break;
next.second->getReexportedModules(queue);
}
}
//===----------------------------------------------------------------------===//
// TranslationUnit Implementation
//===----------------------------------------------------------------------===//
void TranslationUnit::print(raw_ostream &os) {
print(os, PrintOptions::printEverything());
}
void TranslationUnit::print(raw_ostream &os, const PrintOptions &options) {
for (auto decl : Decls) {
if (!decl->shouldPrintInContext())
continue;
decl->print(os, options);
os << "\n";
}
}
void TranslationUnit::clearLookupCache() {
freeTUCachePimpl(LookupCachePimpl);
}
//===----------------------------------------------------------------------===//
// LoadedModule Implementation
//===----------------------------------------------------------------------===//
void LoadedModule::lookupValue(AccessPathTy accessPath, Identifier name,
NLKind lookupKind,
SmallVectorImpl<ValueDecl*> &result) {
return getOwner().lookupValue(this, accessPath, name, lookupKind, result);
}
OperatorDecl *LoadedModule::lookupOperator(Identifier name, DeclKind fixity) {
return getOwner().lookupOperator(this, name, fixity);
}
template<>
PrefixOperatorDecl *
LoadedModule::lookupOperator<PrefixOperatorDecl>(Identifier name) {
auto result = lookupOperator(name, DeclKind::PrefixOperator);
return cast_or_null<PrefixOperatorDecl>(result);
}
template<>
PostfixOperatorDecl *
LoadedModule::lookupOperator<PostfixOperatorDecl>(Identifier name) {
auto result = lookupOperator(name, DeclKind::PostfixOperator);
return cast_or_null<PostfixOperatorDecl>(result);
}
template<>
InfixOperatorDecl *
LoadedModule::lookupOperator<InfixOperatorDecl>(Identifier name) {
auto result = lookupOperator(name, DeclKind::InfixOperator);
return cast_or_null<InfixOperatorDecl>(result);
}
void LoadedModule::getReexportedModules(
SmallVectorImpl<ImportedModule> &exports) const {
return getOwner().getReexportedModules(this, exports);
}
void LoadedModule::lookupVisibleDecls(AccessPathTy accessPath,
VisibleDeclConsumer &consumer,
NLKind lookupKind) const {
return getOwner().lookupVisibleDecls(this, accessPath, consumer, lookupKind);
}
//===----------------------------------------------------------------------===//
// ModuleLoader Implementation
//===----------------------------------------------------------------------===//
ModuleLoader::~ModuleLoader() {}
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