clang-tools-extra/clang-tidy/utils/ExprSequence.cpp - external/github.com/llvm/llvm-project.git - Git at Google

 //===---------- ExprSequence.cpp - clang-tidy -----------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "ExprSequence.h"

 namespace clang {
 namespace tidy {
 namespace utils {

 // Returns the Stmt nodes that are parents of 'S', skipping any potential
 // intermediate non-Stmt nodes.
 //
 // In almost all cases, this function returns a single parent or no parents at
 // all.
 //
 // The case that a Stmt has multiple parents is rare but does actually occur in
 // the parts of the AST that we're interested in. Specifically, InitListExpr
 // nodes cause ASTContext::getParent() to return multiple parents for certain
 // nodes in their subtree because RecursiveASTVisitor visits both the syntactic
 // and semantic forms of InitListExpr, and the parent-child relationships are
 // different between the two forms.
 static SmallVector<const Stmt *, 1> getParentStmts(const Stmt *S,
                                                    ASTContext *Context) {
   SmallVector<const Stmt *, 1> Result;

   ASTContext::DynTypedNodeList Parents = Context->getParents(*S);

   SmallVector<ast_type_traits::DynTypedNode, 1> NodesToProcess(Parents.begin(),
                                                                Parents.end());

   while (!NodesToProcess.empty()) {
     ast_type_traits::DynTypedNode Node = NodesToProcess.back();
     NodesToProcess.pop_back();

     if (const auto *S = Node.get<Stmt>()) {
       Result.push_back(S);
     } else {
       Parents = Context->getParents(Node);
       NodesToProcess.append(Parents.begin(), Parents.end());
     }
   }

   return Result;
 }

 namespace {
 bool isDescendantOrEqual(const Stmt *Descendant, const Stmt *Ancestor,
                          ASTContext *Context) {
   if (Descendant == Ancestor)
     return true;
   for (const Stmt *Parent : getParentStmts(Descendant, Context)) {
     if (isDescendantOrEqual(Parent, Ancestor, Context))
       return true;
   }

   return false;
 }
 }

 ExprSequence::ExprSequence(const CFG *TheCFG, const Stmt *Root,
                            ASTContext *TheContext)
     : Context(TheContext), Root(Root) {
   for (const auto &SyntheticStmt : TheCFG->synthetic_stmts()) {
     SyntheticStmtSourceMap[SyntheticStmt.first] = SyntheticStmt.second;
   }
 }

 bool ExprSequence::inSequence(const Stmt *Before, const Stmt *After) const {
   Before = resolveSyntheticStmt(Before);
   After = resolveSyntheticStmt(After);

   // If 'After' is in the subtree of the siblings that follow 'Before' in the
   // chain of successors, we know that 'After' is sequenced after 'Before'.
   for (const Stmt *Successor = getSequenceSuccessor(Before); Successor;
        Successor = getSequenceSuccessor(Successor)) {
     if (isDescendantOrEqual(After, Successor, Context))
       return true;
   }

   // If 'After' is a parent of 'Before' or is sequenced after one of these
   // parents, we know that it is sequenced after 'Before'.
   for (const Stmt *Parent : getParentStmts(Before, Context)) {
     if (Parent == After || inSequence(Parent, After))
       return true;
   }

   return false;
 }

 bool ExprSequence::potentiallyAfter(const Stmt *After,
                                     const Stmt *Before) const {
   return !inSequence(After, Before);
 }

 const Stmt *ExprSequence::getSequenceSuccessor(const Stmt *S) const {
   for (const Stmt *Parent : getParentStmts(S, Context)) {
     // If a statement has multiple parents, make sure we're using the parent
     // that lies within the sub-tree under Root.
     if (!isDescendantOrEqual(Parent, Root, Context))
       continue;

     if (const auto *BO = dyn_cast<BinaryOperator>(Parent)) {
       // Comma operator: Right-hand side is sequenced after the left-hand side.
       if (BO->getLHS() == S && BO->getOpcode() == BO_Comma)
         return BO->getRHS();
     } else if (const auto *InitList = dyn_cast<InitListExpr>(Parent)) {
       // Initializer list: Each initializer clause is sequenced after the
       // clauses that precede it.
       for (unsigned I = 1; I < InitList->getNumInits(); ++I) {
         if (InitList->getInit(I - 1) == S)
           return InitList->getInit(I);
       }
     } else if (const auto *Compound = dyn_cast<CompoundStmt>(Parent)) {
       // Compound statement: Each sub-statement is sequenced after the
       // statements that precede it.
       const Stmt *Previous = nullptr;
       for (const auto *Child : Compound->body()) {
         if (Previous == S)
           return Child;
         Previous = Child;
       }
     } else if (const auto *TheDeclStmt = dyn_cast<DeclStmt>(Parent)) {
       // Declaration: Every initializer expression is sequenced after the
       // initializer expressions that precede it.
       const Expr *PreviousInit = nullptr;
       for (const Decl *TheDecl : TheDeclStmt->decls()) {
         if (const auto *TheVarDecl = dyn_cast<VarDecl>(TheDecl)) {
           if (const Expr *Init = TheVarDecl->getInit()) {
             if (PreviousInit == S)
               return Init;
             PreviousInit = Init;
           }
         }
       }
     } else if (const auto *ForRange = dyn_cast<CXXForRangeStmt>(Parent)) {
       // Range-based for: Loop variable declaration is sequenced before the
       // body. (We need this rule because these get placed in the same
       // CFGBlock.)
       if (S == ForRange->getLoopVarStmt())
         return ForRange->getBody();
     } else if (const auto *TheIfStmt = dyn_cast<IfStmt>(Parent)) {
       // If statement:
       // - Sequence init statement before variable declaration, if present;
       //   before condition evaluation, otherwise.
       // - Sequence variable declaration (along with the expression used to
       //   initialize it) before the evaluation of the condition.
       if (S == TheIfStmt->getInit()) {
         if (TheIfStmt->getConditionVariableDeclStmt() != nullptr)
           return TheIfStmt->getConditionVariableDeclStmt();
         return TheIfStmt->getCond();
       }
       if (S == TheIfStmt->getConditionVariableDeclStmt())
         return TheIfStmt->getCond();
     } else if (const auto *TheSwitchStmt = dyn_cast<SwitchStmt>(Parent)) {
       // Ditto for switch statements.
       if (S == TheSwitchStmt->getInit()) {
         if (TheSwitchStmt->getConditionVariableDeclStmt() != nullptr)
           return TheSwitchStmt->getConditionVariableDeclStmt();
         return TheSwitchStmt->getCond();
       }
       if (S == TheSwitchStmt->getConditionVariableDeclStmt())
         return TheSwitchStmt->getCond();
     } else if (const auto *TheWhileStmt = dyn_cast<WhileStmt>(Parent)) {
       // While statement: Sequence variable declaration (along with the
       // expression used to initialize it) before the evaluation of the
       // condition.
       if (S == TheWhileStmt->getConditionVariableDeclStmt())
         return TheWhileStmt->getCond();
     }
   }

   return nullptr;
 }

 const Stmt *ExprSequence::resolveSyntheticStmt(const Stmt *S) const {
   if (SyntheticStmtSourceMap.count(S))
     return SyntheticStmtSourceMap.lookup(S);
   return S;
 }

 StmtToBlockMap::StmtToBlockMap(const CFG *TheCFG, ASTContext *TheContext)
     : Context(TheContext) {
   for (const auto *B : *TheCFG) {
     for (const auto &Elem : *B) {
       if (Optional<CFGStmt> S = Elem.getAs<CFGStmt>())
         Map[S->getStmt()] = B;
     }
   }
 }

 const CFGBlock *StmtToBlockMap::blockContainingStmt(const Stmt *S) const {
   while (!Map.count(S)) {
     SmallVector<const Stmt *, 1> Parents = getParentStmts(S, Context);
     if (Parents.empty())
       return nullptr;
     S = Parents[0];
   }

   return Map.lookup(S);
 }

 } // namespace utils
 } // namespace tidy
 } // namespace clang
	//===---------- ExprSequence.cpp - clang-tidy -----------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "ExprSequence.h"

	namespace clang {
	namespace tidy {
	namespace utils {

	// Returns the Stmt nodes that are parents of 'S', skipping any potential
	// intermediate non-Stmt nodes.
	//
	// In almost all cases, this function returns a single parent or no parents at
	// all.
	//
	// The case that a Stmt has multiple parents is rare but does actually occur in
	// the parts of the AST that we're interested in. Specifically, InitListExpr
	// nodes cause ASTContext::getParent() to return multiple parents for certain
	// nodes in their subtree because RecursiveASTVisitor visits both the syntactic
	// and semantic forms of InitListExpr, and the parent-child relationships are
	// different between the two forms.
	static SmallVector<const Stmt , 1> getParentStmts(const Stmt S,
	ASTContext *Context) {
	SmallVector<const Stmt *, 1> Result;

	ASTContext::DynTypedNodeList Parents = Context->getParents(*S);

	SmallVector<ast_type_traits::DynTypedNode, 1> NodesToProcess(Parents.begin(),
	Parents.end());

	while (!NodesToProcess.empty()) {
	ast_type_traits::DynTypedNode Node = NodesToProcess.back();
	NodesToProcess.pop_back();

	if (const auto *S = Node.get<Stmt>()) {
	Result.push_back(S);
	} else {
	Parents = Context->getParents(Node);
	NodesToProcess.append(Parents.begin(), Parents.end());
	}
	}

	return Result;
	}

	namespace {
	bool isDescendantOrEqual(const Stmt Descendant, const Stmt Ancestor,
	ASTContext *Context) {
	if (Descendant == Ancestor)
	return true;
	for (const Stmt *Parent : getParentStmts(Descendant, Context)) {
	if (isDescendantOrEqual(Parent, Ancestor, Context))
	return true;
	}

	return false;
	}
	}

	ExprSequence::ExprSequence(const CFG TheCFG, const Stmt Root,
	ASTContext *TheContext)
	: Context(TheContext), Root(Root) {
	for (const auto &SyntheticStmt : TheCFG->synthetic_stmts()) {
	SyntheticStmtSourceMap[SyntheticStmt.first] = SyntheticStmt.second;
	}
	}

	bool ExprSequence::inSequence(const Stmt Before, const Stmt After) const {
	Before = resolveSyntheticStmt(Before);
	After = resolveSyntheticStmt(After);

	// If 'After' is in the subtree of the siblings that follow 'Before' in the
	// chain of successors, we know that 'After' is sequenced after 'Before'.
	for (const Stmt *Successor = getSequenceSuccessor(Before); Successor;
	Successor = getSequenceSuccessor(Successor)) {
	if (isDescendantOrEqual(After, Successor, Context))
	return true;
	}

	// If 'After' is a parent of 'Before' or is sequenced after one of these
	// parents, we know that it is sequenced after 'Before'.
	for (const Stmt *Parent : getParentStmts(Before, Context)) {
	if (Parent == After \|\| inSequence(Parent, After))
	return true;
	}

	return false;
	}

	bool ExprSequence::potentiallyAfter(const Stmt *After,
	const Stmt *Before) const {
	return !inSequence(After, Before);
	}

	const Stmt ExprSequence::getSequenceSuccessor(const Stmt S) const {
	for (const Stmt *Parent : getParentStmts(S, Context)) {
	// If a statement has multiple parents, make sure we're using the parent
	// that lies within the sub-tree under Root.
	if (!isDescendantOrEqual(Parent, Root, Context))
	continue;

	if (const auto *BO = dyn_cast<BinaryOperator>(Parent)) {
	// Comma operator: Right-hand side is sequenced after the left-hand side.
	if (BO->getLHS() == S && BO->getOpcode() == BO_Comma)
	return BO->getRHS();
	} else if (const auto *InitList = dyn_cast<InitListExpr>(Parent)) {
	// Initializer list: Each initializer clause is sequenced after the
	// clauses that precede it.
	for (unsigned I = 1; I < InitList->getNumInits(); ++I) {
	if (InitList->getInit(I - 1) == S)
	return InitList->getInit(I);
	}
	} else if (const auto *Compound = dyn_cast<CompoundStmt>(Parent)) {
	// Compound statement: Each sub-statement is sequenced after the
	// statements that precede it.
	const Stmt *Previous = nullptr;
	for (const auto *Child : Compound->body()) {
	if (Previous == S)
	return Child;
	Previous = Child;
	}
	} else if (const auto *TheDeclStmt = dyn_cast<DeclStmt>(Parent)) {
	// Declaration: Every initializer expression is sequenced after the
	// initializer expressions that precede it.
	const Expr *PreviousInit = nullptr;
	for (const Decl *TheDecl : TheDeclStmt->decls()) {
	if (const auto *TheVarDecl = dyn_cast<VarDecl>(TheDecl)) {
	if (const Expr *Init = TheVarDecl->getInit()) {
	if (PreviousInit == S)
	return Init;
	PreviousInit = Init;
	}
	}
	}
	} else if (const auto *ForRange = dyn_cast<CXXForRangeStmt>(Parent)) {
	// Range-based for: Loop variable declaration is sequenced before the
	// body. (We need this rule because these get placed in the same
	// CFGBlock.)
	if (S == ForRange->getLoopVarStmt())
	return ForRange->getBody();
	} else if (const auto *TheIfStmt = dyn_cast<IfStmt>(Parent)) {
	// If statement:
	// - Sequence init statement before variable declaration, if present;
	// before condition evaluation, otherwise.
	// - Sequence variable declaration (along with the expression used to
	// initialize it) before the evaluation of the condition.
	if (S == TheIfStmt->getInit()) {
	if (TheIfStmt->getConditionVariableDeclStmt() != nullptr)
	return TheIfStmt->getConditionVariableDeclStmt();
	return TheIfStmt->getCond();
	}
	if (S == TheIfStmt->getConditionVariableDeclStmt())
	return TheIfStmt->getCond();
	} else if (const auto *TheSwitchStmt = dyn_cast<SwitchStmt>(Parent)) {
	// Ditto for switch statements.
	if (S == TheSwitchStmt->getInit()) {
	if (TheSwitchStmt->getConditionVariableDeclStmt() != nullptr)
	return TheSwitchStmt->getConditionVariableDeclStmt();
	return TheSwitchStmt->getCond();
	}
	if (S == TheSwitchStmt->getConditionVariableDeclStmt())
	return TheSwitchStmt->getCond();
	} else if (const auto *TheWhileStmt = dyn_cast<WhileStmt>(Parent)) {
	// While statement: Sequence variable declaration (along with the
	// expression used to initialize it) before the evaluation of the
	// condition.
	if (S == TheWhileStmt->getConditionVariableDeclStmt())
	return TheWhileStmt->getCond();
	}
	}

	return nullptr;
	}

	const Stmt ExprSequence::resolveSyntheticStmt(const Stmt S) const {
	if (SyntheticStmtSourceMap.count(S))
	return SyntheticStmtSourceMap.lookup(S);
	return S;
	}

	StmtToBlockMap::StmtToBlockMap(const CFG TheCFG, ASTContext TheContext)
	: Context(TheContext) {
	for (const auto B : TheCFG) {
	for (const auto &Elem : *B) {
	if (Optional<CFGStmt> S = Elem.getAs<CFGStmt>())
	Map[S->getStmt()] = B;
	}
	}
	}

	const CFGBlock StmtToBlockMap::blockContainingStmt(const Stmt S) const {
	while (!Map.count(S)) {
	SmallVector<const Stmt *, 1> Parents = getParentStmts(S, Context);
	if (Parents.empty())
	return nullptr;
	S = Parents[0];
	}

	return Map.lookup(S);
	}

	} // namespace utils
	} // namespace tidy
	} // namespace clang