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//===--- ScopeInfo.h - Information about a semantic context -----*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file defines FunctionScopeInfo and its subclasses, which contain
// information about a single function, block, lambda, or method body.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_CLANG_SEMA_SCOPE_INFO_H
#define LLVM_CLANG_SEMA_SCOPE_INFO_H
#include "clang/AST/Type.h"
#include "clang/Basic/PartialDiagnostic.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/SmallVector.h"
namespace clang {
class Decl;
class BlockDecl;
class CXXMethodDecl;
class ObjCPropertyDecl;
class IdentifierInfo;
class LabelDecl;
class ReturnStmt;
class Scope;
class SwitchStmt;
class VarDecl;
class DeclRefExpr;
class ObjCIvarRefExpr;
class ObjCPropertyRefExpr;
class ObjCMessageExpr;
namespace sema {
/// \brief Contains information about the compound statement currently being
/// parsed.
class CompoundScopeInfo {
public:
CompoundScopeInfo()
: HasEmptyLoopBodies(false) { }
/// \brief Whether this compound stamement contains `for' or `while' loops
/// with empty bodies.
bool HasEmptyLoopBodies;
void setHasEmptyLoopBodies() {
HasEmptyLoopBodies = true;
}
};
class PossiblyUnreachableDiag {
public:
PartialDiagnostic PD;
SourceLocation Loc;
const Stmt *stmt;
PossiblyUnreachableDiag(const PartialDiagnostic &PD, SourceLocation Loc,
const Stmt *stmt)
: PD(PD), Loc(Loc), stmt(stmt) {}
};
/// \brief Retains information about a function, method, or block that is
/// currently being parsed.
class FunctionScopeInfo {
protected:
enum ScopeKind {
SK_Function,
SK_Block,
SK_Lambda
};
public:
/// \brief What kind of scope we are describing.
///
ScopeKind Kind;
/// \brief Whether this function contains a VLA, \@try, try, C++
/// initializer, or anything else that can't be jumped past.
bool HasBranchProtectedScope;
/// \brief Whether this function contains any switches or direct gotos.
bool HasBranchIntoScope;
/// \brief Whether this function contains any indirect gotos.
bool HasIndirectGoto;
/// \brief Whether a statement was dropped because it was invalid.
bool HasDroppedStmt;
/// A flag that is set when parsing a method that must call super's
/// implementation, such as \c -dealloc, \c -finalize, or any method marked
/// with \c __attribute__((objc_requires_super)).
bool ObjCShouldCallSuper;
/// \brief Used to determine if errors occurred in this function or block.
DiagnosticErrorTrap ErrorTrap;
/// SwitchStack - This is the current set of active switch statements in the
/// block.
SmallVector<SwitchStmt*, 8> SwitchStack;
/// \brief The list of return statements that occur within the function or
/// block, if there is any chance of applying the named return value
/// optimization, or if we need to infer a return type.
SmallVector<ReturnStmt*, 4> Returns;
/// \brief The stack of currently active compound stamement scopes in the
/// function.
SmallVector<CompoundScopeInfo, 4> CompoundScopes;
/// \brief A list of PartialDiagnostics created but delayed within the
/// current function scope. These diagnostics are vetted for reachability
/// prior to being emitted.
SmallVector<PossiblyUnreachableDiag, 4> PossiblyUnreachableDiags;
public:
/// Represents a simple identification of a weak object.
///
/// Part of the implementation of -Wrepeated-use-of-weak.
///
/// This is used to determine if two weak accesses refer to the same object.
/// Here are some examples of how various accesses are "profiled":
///
/// Access Expression | "Base" Decl | "Property" Decl
/// :---------------: | :-----------------: | :------------------------------:
/// self.property | self (VarDecl) | property (ObjCPropertyDecl)
/// self.implicitProp | self (VarDecl) | -implicitProp (ObjCMethodDecl)
/// self->ivar.prop | ivar (ObjCIvarDecl) | prop (ObjCPropertyDecl)
/// cxxObj.obj.prop | obj (FieldDecl) | prop (ObjCPropertyDecl)
/// [self foo].prop | 0 (unknown) | prop (ObjCPropertyDecl)
/// self.prop1.prop2 | prop1 (ObjCPropertyDecl) | prop2 (ObjCPropertyDecl)
/// MyClass.prop | MyClass (ObjCInterfaceDecl) | -prop (ObjCMethodDecl)
/// weakVar | 0 (known) | weakVar (VarDecl)
/// self->weakIvar | self (VarDecl) | weakIvar (ObjCIvarDecl)
///
/// Objects are identified with only two Decls to make it reasonably fast to
/// compare them.
class WeakObjectProfileTy {
/// The base object decl, as described in the class documentation.
///
/// The extra flag is "true" if the Base and Property are enough to uniquely
/// identify the object in memory.
///
/// \sa isExactProfile()
typedef llvm::PointerIntPair<const NamedDecl *, 1, bool> BaseInfoTy;
BaseInfoTy Base;
/// The "property" decl, as described in the class documentation.
///
/// Note that this may not actually be an ObjCPropertyDecl, e.g. in the
/// case of "implicit" properties (regular methods accessed via dot syntax).
const NamedDecl *Property;
/// Used to find the proper base profile for a given base expression.
static BaseInfoTy getBaseInfo(const Expr *BaseE);
// For use in DenseMap.
friend class DenseMapInfo;
inline WeakObjectProfileTy();
static inline WeakObjectProfileTy getSentinel();
public:
WeakObjectProfileTy(const ObjCPropertyRefExpr *RE);
WeakObjectProfileTy(const Expr *Base, const ObjCPropertyDecl *Property);
WeakObjectProfileTy(const DeclRefExpr *RE);
WeakObjectProfileTy(const ObjCIvarRefExpr *RE);
const NamedDecl *getBase() const { return Base.getPointer(); }
const NamedDecl *getProperty() const { return Property; }
/// Returns true if the object base specifies a known object in memory,
/// rather than, say, an instance variable or property of another object.
///
/// Note that this ignores the effects of aliasing; that is, \c foo.bar is
/// considered an exact profile if \c foo is a local variable, even if
/// another variable \c foo2 refers to the same object as \c foo.
///
/// For increased precision, accesses with base variables that are
/// properties or ivars of 'self' (e.g. self.prop1.prop2) are considered to
/// be exact, though this is not true for arbitrary variables
/// (foo.prop1.prop2).
bool isExactProfile() const {
return Base.getInt();
}
bool operator==(const WeakObjectProfileTy &Other) const {
return Base == Other.Base && Property == Other.Property;
}
// For use in DenseMap.
// We can't specialize the usual llvm::DenseMapInfo at the end of the file
// because by that point the DenseMap in FunctionScopeInfo has already been
// instantiated.
class DenseMapInfo {
public:
static inline WeakObjectProfileTy getEmptyKey() {
return WeakObjectProfileTy();
}
static inline WeakObjectProfileTy getTombstoneKey() {
return WeakObjectProfileTy::getSentinel();
}
static unsigned getHashValue(const WeakObjectProfileTy &Val) {
typedef std::pair<BaseInfoTy, const NamedDecl *> Pair;
return llvm::DenseMapInfo<Pair>::getHashValue(Pair(Val.Base,
Val.Property));
}
static bool isEqual(const WeakObjectProfileTy &LHS,
const WeakObjectProfileTy &RHS) {
return LHS == RHS;
}
};
};
/// Represents a single use of a weak object.
///
/// Stores both the expression and whether the access is potentially unsafe
/// (i.e. it could potentially be warned about).
///
/// Part of the implementation of -Wrepeated-use-of-weak.
class WeakUseTy {
llvm::PointerIntPair<const Expr *, 1, bool> Rep;
public:
WeakUseTy(const Expr *Use, bool IsRead) : Rep(Use, IsRead) {}
const Expr *getUseExpr() const { return Rep.getPointer(); }
bool isUnsafe() const { return Rep.getInt(); }
void markSafe() { Rep.setInt(false); }
bool operator==(const WeakUseTy &Other) const {
return Rep == Other.Rep;
}
};
/// Used to collect uses of a particular weak object in a function body.
///
/// Part of the implementation of -Wrepeated-use-of-weak.
typedef SmallVector<WeakUseTy, 4> WeakUseVector;
/// Used to collect all uses of weak objects in a function body.
///
/// Part of the implementation of -Wrepeated-use-of-weak.
typedef llvm::SmallDenseMap<WeakObjectProfileTy, WeakUseVector, 8,
WeakObjectProfileTy::DenseMapInfo>
WeakObjectUseMap;
private:
/// Used to collect all uses of weak objects in this function body.
///
/// Part of the implementation of -Wrepeated-use-of-weak.
WeakObjectUseMap WeakObjectUses;
public:
/// Record that a weak object was accessed.
///
/// Part of the implementation of -Wrepeated-use-of-weak.
template <typename ExprT>
inline void recordUseOfWeak(const ExprT *E, bool IsRead = true);
void recordUseOfWeak(const ObjCMessageExpr *Msg,
const ObjCPropertyDecl *Prop);
/// Record that a given expression is a "safe" access of a weak object (e.g.
/// assigning it to a strong variable.)
///
/// Part of the implementation of -Wrepeated-use-of-weak.
void markSafeWeakUse(const Expr *E);
const WeakObjectUseMap &getWeakObjectUses() const {
return WeakObjectUses;
}
void setHasBranchIntoScope() {
HasBranchIntoScope = true;
}
void setHasBranchProtectedScope() {
HasBranchProtectedScope = true;
}
void setHasIndirectGoto() {
HasIndirectGoto = true;
}
void setHasDroppedStmt() {
HasDroppedStmt = true;
}
bool NeedsScopeChecking() const {
return !HasDroppedStmt &&
(HasIndirectGoto ||
(HasBranchProtectedScope && HasBranchIntoScope));
}
FunctionScopeInfo(DiagnosticsEngine &Diag)
: Kind(SK_Function),
HasBranchProtectedScope(false),
HasBranchIntoScope(false),
HasIndirectGoto(false),
HasDroppedStmt(false),
ObjCShouldCallSuper(false),
ErrorTrap(Diag) { }
virtual ~FunctionScopeInfo();
/// \brief Clear out the information in this function scope, making it
/// suitable for reuse.
void Clear();
};
class CapturingScopeInfo : public FunctionScopeInfo {
public:
enum ImplicitCaptureStyle {
ImpCap_None, ImpCap_LambdaByval, ImpCap_LambdaByref, ImpCap_Block
};
ImplicitCaptureStyle ImpCaptureStyle;
class Capture {
// There are two categories of capture: capturing 'this', and capturing
// local variables. There are three ways to capture a local variable:
// capture by copy in the C++11 sense, capture by reference
// in the C++11 sense, and __block capture. Lambdas explicitly specify
// capture by copy or capture by reference. For blocks, __block capture
// applies to variables with that annotation, variables of reference type
// are captured by reference, and other variables are captured by copy.
enum CaptureKind {
Cap_This, Cap_ByCopy, Cap_ByRef, Cap_Block
};
// The variable being captured (if we are not capturing 'this'),
// and misc bits descibing the capture.
llvm::PointerIntPair<VarDecl*, 2, CaptureKind> VarAndKind;
// Expression to initialize a field of the given type, and whether this
// is a nested capture; the expression is only required if we are
// capturing ByVal and the variable's type has a non-trivial
// copy constructor.
llvm::PointerIntPair<Expr*, 1, bool> CopyExprAndNested;
/// \brief The source location at which the first capture occurred..
SourceLocation Loc;
/// \brief The location of the ellipsis that expands a parameter pack.
SourceLocation EllipsisLoc;
/// \brief The type as it was captured, which is in effect the type of the
/// non-static data member that would hold the capture.
QualType CaptureType;
public:
Capture(VarDecl *Var, bool block, bool byRef, bool isNested,
SourceLocation Loc, SourceLocation EllipsisLoc,
QualType CaptureType, Expr *Cpy)
: VarAndKind(Var, block ? Cap_Block : byRef ? Cap_ByRef : Cap_ByCopy),
CopyExprAndNested(Cpy, isNested), Loc(Loc), EllipsisLoc(EllipsisLoc),
CaptureType(CaptureType){}
enum IsThisCapture { ThisCapture };
Capture(IsThisCapture, bool isNested, SourceLocation Loc,
QualType CaptureType, Expr *Cpy)
: VarAndKind(0, Cap_This), CopyExprAndNested(Cpy, isNested), Loc(Loc),
EllipsisLoc(), CaptureType(CaptureType) { }
bool isThisCapture() const { return VarAndKind.getInt() == Cap_This; }
bool isVariableCapture() const { return !isThisCapture(); }
bool isCopyCapture() const { return VarAndKind.getInt() == Cap_ByCopy; }
bool isReferenceCapture() const { return VarAndKind.getInt() == Cap_ByRef; }
bool isBlockCapture() const { return VarAndKind.getInt() == Cap_Block; }
bool isNested() { return CopyExprAndNested.getInt(); }
VarDecl *getVariable() const {
return VarAndKind.getPointer();
}
/// \brief Retrieve the location at which this variable was captured.
SourceLocation getLocation() const { return Loc; }
/// \brief Retrieve the source location of the ellipsis, whose presence
/// indicates that the capture is a pack expansion.
SourceLocation getEllipsisLoc() const { return EllipsisLoc; }
/// \brief Retrieve the capture type for this capture, which is effectively
/// the type of the non-static data member in the lambda/block structure
/// that would store this capture.
QualType getCaptureType() const { return CaptureType; }
Expr *getCopyExpr() const {
return CopyExprAndNested.getPointer();
}
};
CapturingScopeInfo(DiagnosticsEngine &Diag, ImplicitCaptureStyle Style)
: FunctionScopeInfo(Diag), ImpCaptureStyle(Style), CXXThisCaptureIndex(0),
HasImplicitReturnType(false)
{}
/// CaptureMap - A map of captured variables to (index+1) into Captures.
llvm::DenseMap<VarDecl*, unsigned> CaptureMap;
/// CXXThisCaptureIndex - The (index+1) of the capture of 'this';
/// zero if 'this' is not captured.
unsigned CXXThisCaptureIndex;
/// Captures - The captures.
SmallVector<Capture, 4> Captures;
/// \brief - Whether the target type of return statements in this context
/// is deduced (e.g. a lambda or block with omitted return type).
bool HasImplicitReturnType;
/// ReturnType - The target type of return statements in this context,
/// or null if unknown.
QualType ReturnType;
void addCapture(VarDecl *Var, bool isBlock, bool isByref, bool isNested,
SourceLocation Loc, SourceLocation EllipsisLoc,
QualType CaptureType, Expr *Cpy) {
Captures.push_back(Capture(Var, isBlock, isByref, isNested, Loc,
EllipsisLoc, CaptureType, Cpy));
CaptureMap[Var] = Captures.size();
}
void addThisCapture(bool isNested, SourceLocation Loc, QualType CaptureType,
Expr *Cpy);
/// \brief Determine whether the C++ 'this' is captured.
bool isCXXThisCaptured() const { return CXXThisCaptureIndex != 0; }
/// \brief Retrieve the capture of C++ 'this', if it has been captured.
Capture &getCXXThisCapture() {
assert(isCXXThisCaptured() && "this has not been captured");
return Captures[CXXThisCaptureIndex - 1];
}
/// \brief Determine whether the given variable has been captured.
bool isCaptured(VarDecl *Var) const {
return CaptureMap.count(Var);
}
/// \brief Retrieve the capture of the given variable, if it has been
/// captured already.
Capture &getCapture(VarDecl *Var) {
assert(isCaptured(Var) && "Variable has not been captured");
return Captures[CaptureMap[Var] - 1];
}
const Capture &getCapture(VarDecl *Var) const {
llvm::DenseMap<VarDecl*, unsigned>::const_iterator Known
= CaptureMap.find(Var);
assert(Known != CaptureMap.end() && "Variable has not been captured");
return Captures[Known->second - 1];
}
static bool classof(const FunctionScopeInfo *FSI) {
return FSI->Kind == SK_Block || FSI->Kind == SK_Lambda;
}
};
/// \brief Retains information about a block that is currently being parsed.
class BlockScopeInfo : public CapturingScopeInfo {
public:
BlockDecl *TheDecl;
/// TheScope - This is the scope for the block itself, which contains
/// arguments etc.
Scope *TheScope;
/// BlockType - The function type of the block, if one was given.
/// Its return type may be BuiltinType::Dependent.
QualType FunctionType;
BlockScopeInfo(DiagnosticsEngine &Diag, Scope *BlockScope, BlockDecl *Block)
: CapturingScopeInfo(Diag, ImpCap_Block), TheDecl(Block),
TheScope(BlockScope)
{
Kind = SK_Block;
}
virtual ~BlockScopeInfo();
static bool classof(const FunctionScopeInfo *FSI) {
return FSI->Kind == SK_Block;
}
};
class LambdaScopeInfo : public CapturingScopeInfo {
public:
/// \brief The class that describes the lambda.
CXXRecordDecl *Lambda;
/// \brief The class that describes the lambda.
CXXMethodDecl *CallOperator;
/// \brief Source range covering the lambda introducer [...].
SourceRange IntroducerRange;
/// \brief The number of captures in the \c Captures list that are
/// explicit captures.
unsigned NumExplicitCaptures;
/// \brief Whether this is a mutable lambda.
bool Mutable;
/// \brief Whether the (empty) parameter list is explicit.
bool ExplicitParams;
/// \brief Whether any of the capture expressions requires cleanups.
bool ExprNeedsCleanups;
/// \brief Whether the lambda contains an unexpanded parameter pack.
bool ContainsUnexpandedParameterPack;
/// \brief Variables used to index into by-copy array captures.
SmallVector<VarDecl *, 4> ArrayIndexVars;
/// \brief Offsets into the ArrayIndexVars array at which each capture starts
/// its list of array index variables.
SmallVector<unsigned, 4> ArrayIndexStarts;
LambdaScopeInfo(DiagnosticsEngine &Diag, CXXRecordDecl *Lambda,
CXXMethodDecl *CallOperator)
: CapturingScopeInfo(Diag, ImpCap_None), Lambda(Lambda),
CallOperator(CallOperator), NumExplicitCaptures(0), Mutable(false),
ExprNeedsCleanups(false), ContainsUnexpandedParameterPack(false)
{
Kind = SK_Lambda;
}
virtual ~LambdaScopeInfo();
/// \brief Note when
void finishedExplicitCaptures() {
NumExplicitCaptures = Captures.size();
}
static bool classof(const FunctionScopeInfo *FSI) {
return FSI->Kind == SK_Lambda;
}
};
FunctionScopeInfo::WeakObjectProfileTy::WeakObjectProfileTy()
: Base(0, false), Property(0) {}
FunctionScopeInfo::WeakObjectProfileTy
FunctionScopeInfo::WeakObjectProfileTy::getSentinel() {
FunctionScopeInfo::WeakObjectProfileTy Result;
Result.Base.setInt(true);
return Result;
}
template <typename ExprT>
void FunctionScopeInfo::recordUseOfWeak(const ExprT *E, bool IsRead) {
assert(E);
WeakUseVector &Uses = WeakObjectUses[WeakObjectProfileTy(E)];
Uses.push_back(WeakUseTy(E, IsRead));
}
inline void
CapturingScopeInfo::addThisCapture(bool isNested, SourceLocation Loc,
QualType CaptureType, Expr *Cpy) {
Captures.push_back(Capture(Capture::ThisCapture, isNested, Loc, CaptureType,
Cpy));
CXXThisCaptureIndex = Captures.size();
if (LambdaScopeInfo *LSI = dyn_cast<LambdaScopeInfo>(this))
LSI->ArrayIndexStarts.push_back(LSI->ArrayIndexVars.size());
}
} // end namespace sema
} // end namespace clang
#endif
|