lib/Parse/Scope.cpp - third_party/swift - Git at Google

 //===--- Scope.cpp - Scope Implementation ---------------------------------===//
 //
 // This source file is part of the Swift.org open source project
 //
 // Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors
 // Licensed under Apache License v2.0 with Runtime Library Exception
 //
 // See https://swift.org/LICENSE.txt for license information
 // See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
 //
 //===----------------------------------------------------------------------===//
 //
 //  This file implements semantic analysis for Swift declarations.
 //
 //===----------------------------------------------------------------------===//

 #include "swift/Parse/Scope.h"
 #include "swift/Parse/Parser.h"
 #include "llvm/ADT/Twine.h"

 using namespace swift;

 //===----------------------------------------------------------------------===//
 // Scope Implementation
 //===----------------------------------------------------------------------===//

 static bool isResolvableScope(ScopeKind SK) {
   switch (SK) {
   case ScopeKind::Extension:
   case ScopeKind::EnumBody:
   case ScopeKind::StructBody:
   case ScopeKind::ClassBody:
   case ScopeKind::ProtocolBody:
   case ScopeKind::TopLevel:
   case ScopeKind::InheritanceClause:
     return false;
   case ScopeKind::FunctionBody:
   case ScopeKind::Generics:
   case ScopeKind::Brace:
   case ScopeKind::ForeachVars:
   case ScopeKind::ClosureParams:
   case ScopeKind::CaseVars:
   case ScopeKind::CatchVars:
   case ScopeKind::IfVars:
   case ScopeKind::WhileVars:
     return true;
   }

   llvm_unreachable("Unhandled ScopeKind in switch.");
 }

 Scope::Scope(Parser *P, ScopeKind SC, bool isInactiveConfigBlock)
   : SI(P->getScopeInfo()),
     HTScope(SI.HT, SI.CurScope ? &SI.CurScope->HTScope : nullptr),
     PrevScope(SI.CurScope),
     PrevResolvableDepth(SI.ResolvableDepth),
     Kind(SC),
     IsInactiveConfigBlock(isInactiveConfigBlock) {
   assert(PrevScope || Kind == ScopeKind::TopLevel);

   if (SI.CurScope) {
     Depth = SI.CurScope->Depth + 1;
     IsInactiveConfigBlock |= SI.CurScope->IsInactiveConfigBlock;
   } else {
     Depth = 0;
   }
   SI.CurScope = this;
   if (!isResolvableScope(Kind))
     SI.ResolvableDepth = Depth + 1;
 }

 Scope::Scope(Parser *P, SavedScope &&SS):
     SI(P->getScopeInfo()),
     HTScope(std::move(SS.HTDetachedScope)),
     PrevScope(SI.CurScope),
     PrevResolvableDepth(SI.ResolvableDepth),
     Depth(SS.Depth),
     Kind(SS.Kind),
     IsInactiveConfigBlock(SS.IsInactiveConfigBlock) {

     SI.CurScope = this;
     if (!isResolvableScope(Kind))
       SI.ResolvableDepth = Depth + 1;
 }

 bool Scope::isResolvable() const {
   return isResolvableScope(Kind);
 }

 //===----------------------------------------------------------------------===//
 // ScopeInfo Implementation
 //===----------------------------------------------------------------------===//

 /// checkValidOverload - Check whether it is ok for D1 and D2 to be declared at
 /// the same scope.  This check is a transitive relationship, so if "D1 is a
 /// valid overload of D2" and "D2 is a valid overload of D3" then we know that
 /// D1/D3 are valid overloads and we don't have to check all permutations.
 static bool checkValidOverload(const ValueDecl *D1, const ValueDecl *D2,
                                Parser &P) {
   // Currently, there is no restriction on overloading.
   return false;
 }


 /// addToScope - Register the specified decl as being in the current lexical
 /// scope.
 void ScopeInfo::addToScope(ValueDecl *D, Parser &TheParser,
                            bool diagnoseRedefinitions) {
   if (!CurScope->isResolvable())
     return;

   assert(CurScope->getDepth() >= ResolvableDepth &&
          "inserting names into a non-resolvable scope");

   // If we have a shadowed variable definition, check to see if we have a
   // redefinition: two definitions in the same scope with the same name.
   ScopedHTTy::iterator EntryI = HT.begin(CurScope->HTScope, D->getFullName());

   // A redefinition is a hit in the scoped table at the same depth.
   if (EntryI != HT.end() && EntryI->first == CurScope->getDepth()) {
     ValueDecl *PrevDecl = EntryI->second;

     // If this is in a resolvable scope, diagnose redefinitions.  Later
     // phases will handle scopes like module-scope, etc.
     if (CurScope->getDepth() >= ResolvableDepth) {
       if (diagnoseRedefinitions) {
         return TheParser.diagnoseRedefinition(PrevDecl, D);
       }
       return;
     }

     // If this is at top-level scope, validate that the members of the overload
     // set all agree.

     // Check to see if D and PrevDecl are valid in the same overload set.
     if (checkValidOverload(D, PrevDecl, TheParser))
       return;

     // Note: we don't check whether all of the elements of the overload set have
     // different argument types.  This is checked later.
   }

   HT.insertIntoScope(CurScope->HTScope,
                      D->getFullName(),
                      std::make_pair(CurScope->getDepth(), D));
 }

 void ScopeInfo::dump() const {
 #ifndef NDEBUG
   // Dump out the current list of scopes.
   if (!CurScope->isResolvable())
     return;

   assert(CurScope->getDepth() >= ResolvableDepth &&
          "Attempting to dump a non-resolvable scope?!");

   llvm::dbgs() << "--- Dumping ScopeInfo ---\n";
   std::function<void(decltype(HT)::DebugVisitValueTy)> func =
       [&](const decltype(HT)::DebugVisitValueTy &iter) -> void {
     llvm::dbgs() << "DeclName: " << iter->getKey() << "\n"
                  << "KeyScopeID: " << iter->getValue().first << "\n"
                  << "Decl: ";
     iter->getValue().second->dumpRef(llvm::dbgs());
     llvm::dbgs() << "\n";
   };
   HT.debugVisit(std::move(func));
   llvm::dbgs() << "\n";
 #endif
 }
	//===--- Scope.cpp - Scope Implementation ---------------------------------===//
	//
	// This source file is part of the Swift.org open source project
	//
	// Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors
	// Licensed under Apache License v2.0 with Runtime Library Exception
	//
	// See https://swift.org/LICENSE.txt for license information
	// See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements semantic analysis for Swift declarations.
	//
	//===----------------------------------------------------------------------===//

	#include "swift/Parse/Scope.h"
	#include "swift/Parse/Parser.h"
	#include "llvm/ADT/Twine.h"

	using namespace swift;

	//===----------------------------------------------------------------------===//
	// Scope Implementation
	//===----------------------------------------------------------------------===//

	static bool isResolvableScope(ScopeKind SK) {
	switch (SK) {
	case ScopeKind::Extension:
	case ScopeKind::EnumBody:
	case ScopeKind::StructBody:
	case ScopeKind::ClassBody:
	case ScopeKind::ProtocolBody:
	case ScopeKind::TopLevel:
	case ScopeKind::InheritanceClause:
	return false;
	case ScopeKind::FunctionBody:
	case ScopeKind::Generics:
	case ScopeKind::Brace:
	case ScopeKind::ForeachVars:
	case ScopeKind::ClosureParams:
	case ScopeKind::CaseVars:
	case ScopeKind::CatchVars:
	case ScopeKind::IfVars:
	case ScopeKind::WhileVars:
	return true;
	}

	llvm_unreachable("Unhandled ScopeKind in switch.");
	}

	Scope::Scope(Parser *P, ScopeKind SC, bool isInactiveConfigBlock)
	: SI(P->getScopeInfo()),
	HTScope(SI.HT, SI.CurScope ? &SI.CurScope->HTScope : nullptr),
	PrevScope(SI.CurScope),
	PrevResolvableDepth(SI.ResolvableDepth),
	Kind(SC),
	IsInactiveConfigBlock(isInactiveConfigBlock) {
	assert(PrevScope \|\| Kind == ScopeKind::TopLevel);

	if (SI.CurScope) {
	Depth = SI.CurScope->Depth + 1;
	IsInactiveConfigBlock \|= SI.CurScope->IsInactiveConfigBlock;
	} else {
	Depth = 0;
	}
	SI.CurScope = this;
	if (!isResolvableScope(Kind))
	SI.ResolvableDepth = Depth + 1;
	}

	Scope::Scope(Parser *P, SavedScope &&SS):
	SI(P->getScopeInfo()),
	HTScope(std::move(SS.HTDetachedScope)),
	PrevScope(SI.CurScope),
	PrevResolvableDepth(SI.ResolvableDepth),
	Depth(SS.Depth),
	Kind(SS.Kind),
	IsInactiveConfigBlock(SS.IsInactiveConfigBlock) {

	SI.CurScope = this;
	if (!isResolvableScope(Kind))
	SI.ResolvableDepth = Depth + 1;
	}

	bool Scope::isResolvable() const {
	return isResolvableScope(Kind);
	}

	//===----------------------------------------------------------------------===//
	// ScopeInfo Implementation
	//===----------------------------------------------------------------------===//

	/// checkValidOverload - Check whether it is ok for D1 and D2 to be declared at
	/// the same scope. This check is a transitive relationship, so if "D1 is a
	/// valid overload of D2" and "D2 is a valid overload of D3" then we know that
	/// D1/D3 are valid overloads and we don't have to check all permutations.
	static bool checkValidOverload(const ValueDecl D1, const ValueDecl D2,
	Parser &P) {
	// Currently, there is no restriction on overloading.
	return false;
	}


	/// addToScope - Register the specified decl as being in the current lexical
	/// scope.
	void ScopeInfo::addToScope(ValueDecl *D, Parser &TheParser,
	bool diagnoseRedefinitions) {
	if (!CurScope->isResolvable())
	return;

	assert(CurScope->getDepth() >= ResolvableDepth &&
	"inserting names into a non-resolvable scope");

	// If we have a shadowed variable definition, check to see if we have a
	// redefinition: two definitions in the same scope with the same name.
	ScopedHTTy::iterator EntryI = HT.begin(CurScope->HTScope, D->getFullName());

	// A redefinition is a hit in the scoped table at the same depth.
	if (EntryI != HT.end() && EntryI->first == CurScope->getDepth()) {
	ValueDecl *PrevDecl = EntryI->second;

	// If this is in a resolvable scope, diagnose redefinitions. Later
	// phases will handle scopes like module-scope, etc.
	if (CurScope->getDepth() >= ResolvableDepth) {
	if (diagnoseRedefinitions) {
	return TheParser.diagnoseRedefinition(PrevDecl, D);
	}
	return;
	}

	// If this is at top-level scope, validate that the members of the overload
	// set all agree.

	// Check to see if D and PrevDecl are valid in the same overload set.
	if (checkValidOverload(D, PrevDecl, TheParser))
	return;

	// Note: we don't check whether all of the elements of the overload set have
	// different argument types. This is checked later.
	}

	HT.insertIntoScope(CurScope->HTScope,
	D->getFullName(),
	std::make_pair(CurScope->getDepth(), D));
	}

	void ScopeInfo::dump() const {
	#ifndef NDEBUG
	// Dump out the current list of scopes.
	if (!CurScope->isResolvable())
	return;

	assert(CurScope->getDepth() >= ResolvableDepth &&
	"Attempting to dump a non-resolvable scope?!");

	llvm::dbgs() << "--- Dumping ScopeInfo ---\n";
	std::function<void(decltype(HT)::DebugVisitValueTy)> func =
	[&](const decltype(HT)::DebugVisitValueTy &iter) -> void {
	llvm::dbgs() << "DeclName: " << iter->getKey() << "\n"
	<< "KeyScopeID: " << iter->getValue().first << "\n"
	<< "Decl: ";
	iter->getValue().second->dumpRef(llvm::dbgs());
	llvm::dbgs() << "\n";
	};
	HT.debugVisit(std::move(func));
	llvm::dbgs() << "\n";
	#endif
	}