lib/CodeGen/EHScopeStack.h - platform/external/clang_35a - Git at Google

 //===-- EHScopeStack.h - Stack for cleanup IR generation --------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // These classes should be the minimum interface required for other parts of
 // CodeGen to emit cleanups.  The implementation is in CGCleanup.cpp and other
 // implemenentation details that are not widely needed are in CGCleanup.h.
 //
 //===----------------------------------------------------------------------===//

 #ifndef CLANG_CODEGEN_EHSCOPESTACK_H
 #define CLANG_CODEGEN_EHSCOPESTACK_H

 #include "clang/Basic/LLVM.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/IR/BasicBlock.h"
 #include "llvm/IR/Instructions.h"
 #include "llvm/IR/Value.h"

 namespace clang {
 namespace CodeGen {

 class CodeGenFunction;

 /// A branch fixup.  These are required when emitting a goto to a
 /// label which hasn't been emitted yet.  The goto is optimistically
 /// emitted as a branch to the basic block for the label, and (if it
 /// occurs in a scope with non-trivial cleanups) a fixup is added to
 /// the innermost cleanup.  When a (normal) cleanup is popped, any
 /// unresolved fixups in that scope are threaded through the cleanup.
 struct BranchFixup {
   /// The block containing the terminator which needs to be modified
   /// into a switch if this fixup is resolved into the current scope.
   /// If null, LatestBranch points directly to the destination.
   llvm::BasicBlock *OptimisticBranchBlock;

   /// The ultimate destination of the branch.
   ///
   /// This can be set to null to indicate that this fixup was
   /// successfully resolved.
   llvm::BasicBlock *Destination;

   /// The destination index value.
   unsigned DestinationIndex;

   /// The initial branch of the fixup.
   llvm::BranchInst *InitialBranch;
 };

 template <class T> struct InvariantValue {
   typedef T type;
   typedef T saved_type;
   static bool needsSaving(type value) { return false; }
   static saved_type save(CodeGenFunction &CGF, type value) { return value; }
   static type restore(CodeGenFunction &CGF, saved_type value) { return value; }
 };

 /// A metaprogramming class for ensuring that a value will dominate an
 /// arbitrary position in a function.
 template <class T> struct DominatingValue : InvariantValue<T> {};

 template <class T, bool mightBeInstruction =
             std::is_base_of<llvm::Value, T>::value &&
             !std::is_base_of<llvm::Constant, T>::value &&
             !std::is_base_of<llvm::BasicBlock, T>::value>
 struct DominatingPointer;
 template <class T> struct DominatingPointer<T,false> : InvariantValue<T*> {};
 // template <class T> struct DominatingPointer<T,true> at end of file

 template <class T> struct DominatingValue<T*> : DominatingPointer<T> {};

 enum CleanupKind {
   EHCleanup = 0x1,
   NormalCleanup = 0x2,
   NormalAndEHCleanup = EHCleanup | NormalCleanup,

   InactiveCleanup = 0x4,
   InactiveEHCleanup = EHCleanup | InactiveCleanup,
   InactiveNormalCleanup = NormalCleanup | InactiveCleanup,
   InactiveNormalAndEHCleanup = NormalAndEHCleanup | InactiveCleanup
 };

 /// A stack of scopes which respond to exceptions, including cleanups
 /// and catch blocks.
 class EHScopeStack {
 public:
   /// A saved depth on the scope stack.  This is necessary because
   /// pushing scopes onto the stack invalidates iterators.
   class stable_iterator {
     friend class EHScopeStack;

     /// Offset from StartOfData to EndOfBuffer.
     ptrdiff_t Size;

     stable_iterator(ptrdiff_t Size) : Size(Size) {}

   public:
     static stable_iterator invalid() { return stable_iterator(-1); }
     stable_iterator() : Size(-1) {}

     bool isValid() const { return Size >= 0; }

     /// Returns true if this scope encloses I.
     /// Returns false if I is invalid.
     /// This scope must be valid.
     bool encloses(stable_iterator I) const { return Size <= I.Size; }

     /// Returns true if this scope strictly encloses I: that is,
     /// if it encloses I and is not I.
     /// Returns false is I is invalid.
     /// This scope must be valid.
     bool strictlyEncloses(stable_iterator I) const { return Size < I.Size; }

     friend bool operator==(stable_iterator A, stable_iterator B) {
       return A.Size == B.Size;
     }
     friend bool operator!=(stable_iterator A, stable_iterator B) {
       return A.Size != B.Size;
     }
   };

   /// Information for lazily generating a cleanup.  Subclasses must be
   /// POD-like: cleanups will not be destructed, and they will be
   /// allocated on the cleanup stack and freely copied and moved
   /// around.
   ///
   /// Cleanup implementations should generally be declared in an
   /// anonymous namespace.
   class Cleanup {
     // Anchor the construction vtable.
     virtual void anchor();
   public:
     /// Generation flags.
     class Flags {
       enum {
         F_IsForEH             = 0x1,
         F_IsNormalCleanupKind = 0x2,
         F_IsEHCleanupKind     = 0x4
       };
       unsigned flags;

     public:
       Flags() : flags(0) {}

       /// isForEH - true if the current emission is for an EH cleanup.
       bool isForEHCleanup() const { return flags & F_IsForEH; }
       bool isForNormalCleanup() const { return !isForEHCleanup(); }
       void setIsForEHCleanup() { flags |= F_IsForEH; }

       bool isNormalCleanupKind() const { return flags & F_IsNormalCleanupKind; }
       void setIsNormalCleanupKind() { flags |= F_IsNormalCleanupKind; }

       /// isEHCleanupKind - true if the cleanup was pushed as an EH
       /// cleanup.
       bool isEHCleanupKind() const { return flags & F_IsEHCleanupKind; }
       void setIsEHCleanupKind() { flags |= F_IsEHCleanupKind; }
     };

     // Provide a virtual destructor to suppress a very common warning
     // that unfortunately cannot be suppressed without this.  Cleanups
     // should not rely on this destructor ever being called.
     virtual ~Cleanup() {}

     /// Emit the cleanup.  For normal cleanups, this is run in the
     /// same EH context as when the cleanup was pushed, i.e. the
     /// immediately-enclosing context of the cleanup scope.  For
     /// EH cleanups, this is run in a terminate context.
     ///
     // \param flags cleanup kind.
     virtual void Emit(CodeGenFunction &CGF, Flags flags) = 0;
   };

   /// ConditionalCleanupN stores the saved form of its N parameters,
   /// then restores them and performs the cleanup.
   template <class T, class A0>
   class ConditionalCleanup1 : public Cleanup {
     typedef typename DominatingValue<A0>::saved_type A0_saved;
     A0_saved a0_saved;

     void Emit(CodeGenFunction &CGF, Flags flags) override {
       A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
       T(a0).Emit(CGF, flags);
     }

   public:
     ConditionalCleanup1(A0_saved a0)
       : a0_saved(a0) {}
   };

   template <class T, class A0, class A1>
   class ConditionalCleanup2 : public Cleanup {
     typedef typename DominatingValue<A0>::saved_type A0_saved;
     typedef typename DominatingValue<A1>::saved_type A1_saved;
     A0_saved a0_saved;
     A1_saved a1_saved;

     void Emit(CodeGenFunction &CGF, Flags flags) override {
       A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
       A1 a1 = DominatingValue<A1>::restore(CGF, a1_saved);
       T(a0, a1).Emit(CGF, flags);
     }

   public:
     ConditionalCleanup2(A0_saved a0, A1_saved a1)
       : a0_saved(a0), a1_saved(a1) {}
   };

   template <class T, class A0, class A1, class A2>
   class ConditionalCleanup3 : public Cleanup {
     typedef typename DominatingValue<A0>::saved_type A0_saved;
     typedef typename DominatingValue<A1>::saved_type A1_saved;
     typedef typename DominatingValue<A2>::saved_type A2_saved;
     A0_saved a0_saved;
     A1_saved a1_saved;
     A2_saved a2_saved;

     void Emit(CodeGenFunction &CGF, Flags flags) override {
       A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
       A1 a1 = DominatingValue<A1>::restore(CGF, a1_saved);
       A2 a2 = DominatingValue<A2>::restore(CGF, a2_saved);
       T(a0, a1, a2).Emit(CGF, flags);
     }

   public:
     ConditionalCleanup3(A0_saved a0, A1_saved a1, A2_saved a2)
       : a0_saved(a0), a1_saved(a1), a2_saved(a2) {}
   };

   template <class T, class A0, class A1, class A2, class A3>
   class ConditionalCleanup4 : public Cleanup {
     typedef typename DominatingValue<A0>::saved_type A0_saved;
     typedef typename DominatingValue<A1>::saved_type A1_saved;
     typedef typename DominatingValue<A2>::saved_type A2_saved;
     typedef typename DominatingValue<A3>::saved_type A3_saved;
     A0_saved a0_saved;
     A1_saved a1_saved;
     A2_saved a2_saved;
     A3_saved a3_saved;

     void Emit(CodeGenFunction &CGF, Flags flags) override {
       A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
       A1 a1 = DominatingValue<A1>::restore(CGF, a1_saved);
       A2 a2 = DominatingValue<A2>::restore(CGF, a2_saved);
       A3 a3 = DominatingValue<A3>::restore(CGF, a3_saved);
       T(a0, a1, a2, a3).Emit(CGF, flags);
     }

   public:
     ConditionalCleanup4(A0_saved a0, A1_saved a1, A2_saved a2, A3_saved a3)
       : a0_saved(a0), a1_saved(a1), a2_saved(a2), a3_saved(a3) {}
   };

 private:
   // The implementation for this class is in CGException.h and
   // CGException.cpp; the definition is here because it's used as a
   // member of CodeGenFunction.

   /// The start of the scope-stack buffer, i.e. the allocated pointer
   /// for the buffer.  All of these pointers are either simultaneously
   /// null or simultaneously valid.
   char *StartOfBuffer;

   /// The end of the buffer.
   char *EndOfBuffer;

   /// The first valid entry in the buffer.
   char *StartOfData;

   /// The innermost normal cleanup on the stack.
   stable_iterator InnermostNormalCleanup;

   /// The innermost EH scope on the stack.
   stable_iterator InnermostEHScope;

   /// The current set of branch fixups.  A branch fixup is a jump to
   /// an as-yet unemitted label, i.e. a label for which we don't yet
   /// know the EH stack depth.  Whenever we pop a cleanup, we have
   /// to thread all the current branch fixups through it.
   ///
   /// Fixups are recorded as the Use of the respective branch or
   /// switch statement.  The use points to the final destination.
   /// When popping out of a cleanup, these uses are threaded through
   /// the cleanup and adjusted to point to the new cleanup.
   ///
   /// Note that branches are allowed to jump into protected scopes
   /// in certain situations;  e.g. the following code is legal:
   ///     struct A { ~A(); }; // trivial ctor, non-trivial dtor
   ///     goto foo;
   ///     A a;
   ///    foo:
   ///     bar();
   SmallVector<BranchFixup, 8> BranchFixups;

   char *allocate(size_t Size);

   void *pushCleanup(CleanupKind K, size_t DataSize);

 public:
   EHScopeStack() : StartOfBuffer(0), EndOfBuffer(0), StartOfData(0),
                    InnermostNormalCleanup(stable_end()),
                    InnermostEHScope(stable_end()) {}
   ~EHScopeStack() { delete[] StartOfBuffer; }

   // Variadic templates would make this not terrible.

   /// Push a lazily-created cleanup on the stack.
   template <class T>
   void pushCleanup(CleanupKind Kind) {
     void *Buffer = pushCleanup(Kind, sizeof(T));
     Cleanup *Obj = new(Buffer) T();
     (void) Obj;
   }

   /// Push a lazily-created cleanup on the stack.
   template <class T, class A0>
   void pushCleanup(CleanupKind Kind, A0 a0) {
     void *Buffer = pushCleanup(Kind, sizeof(T));
     Cleanup *Obj = new(Buffer) T(a0);
     (void) Obj;
   }

   /// Push a lazily-created cleanup on the stack.
   template <class T, class A0, class A1>
   void pushCleanup(CleanupKind Kind, A0 a0, A1 a1) {
     void *Buffer = pushCleanup(Kind, sizeof(T));
     Cleanup *Obj = new(Buffer) T(a0, a1);
     (void) Obj;
   }

   /// Push a lazily-created cleanup on the stack.
   template <class T, class A0, class A1, class A2>
   void pushCleanup(CleanupKind Kind, A0 a0, A1 a1, A2 a2) {
     void *Buffer = pushCleanup(Kind, sizeof(T));
     Cleanup *Obj = new(Buffer) T(a0, a1, a2);
     (void) Obj;
   }

   /// Push a lazily-created cleanup on the stack.
   template <class T, class A0, class A1, class A2, class A3>
   void pushCleanup(CleanupKind Kind, A0 a0, A1 a1, A2 a2, A3 a3) {
     void *Buffer = pushCleanup(Kind, sizeof(T));
     Cleanup *Obj = new(Buffer) T(a0, a1, a2, a3);
     (void) Obj;
   }

   /// Push a lazily-created cleanup on the stack.
   template <class T, class A0, class A1, class A2, class A3, class A4>
   void pushCleanup(CleanupKind Kind, A0 a0, A1 a1, A2 a2, A3 a3, A4 a4) {
     void *Buffer = pushCleanup(Kind, sizeof(T));
     Cleanup *Obj = new(Buffer) T(a0, a1, a2, a3, a4);
     (void) Obj;
   }

   // Feel free to add more variants of the following:

   /// Push a cleanup with non-constant storage requirements on the
   /// stack.  The cleanup type must provide an additional static method:
   ///   static size_t getExtraSize(size_t);
   /// The argument to this method will be the value N, which will also
   /// be passed as the first argument to the constructor.
   ///
   /// The data stored in the extra storage must obey the same
   /// restrictions as normal cleanup member data.
   ///
   /// The pointer returned from this method is valid until the cleanup
   /// stack is modified.
   template <class T, class A0, class A1, class A2>
   T *pushCleanupWithExtra(CleanupKind Kind, size_t N, A0 a0, A1 a1, A2 a2) {
     void *Buffer = pushCleanup(Kind, sizeof(T) + T::getExtraSize(N));
     return new (Buffer) T(N, a0, a1, a2);
   }

   void pushCopyOfCleanup(CleanupKind Kind, const void *Cleanup, size_t Size) {
     void *Buffer = pushCleanup(Kind, Size);
     std::memcpy(Buffer, Cleanup, Size);
   }

   /// Pops a cleanup scope off the stack.  This is private to CGCleanup.cpp.
   void popCleanup();

   /// Push a set of catch handlers on the stack.  The catch is
   /// uninitialized and will need to have the given number of handlers
   /// set on it.
   class EHCatchScope *pushCatch(unsigned NumHandlers);

   /// Pops a catch scope off the stack.  This is private to CGException.cpp.
   void popCatch();

   /// Push an exceptions filter on the stack.
   class EHFilterScope *pushFilter(unsigned NumFilters);

   /// Pops an exceptions filter off the stack.
   void popFilter();

   /// Push a terminate handler on the stack.
   void pushTerminate();

   /// Pops a terminate handler off the stack.
   void popTerminate();

   /// Determines whether the exception-scopes stack is empty.
   bool empty() const { return StartOfData == EndOfBuffer; }

   bool requiresLandingPad() const {
     return InnermostEHScope != stable_end();
   }

   /// Determines whether there are any normal cleanups on the stack.
   bool hasNormalCleanups() const {
     return InnermostNormalCleanup != stable_end();
   }

   /// Returns the innermost normal cleanup on the stack, or
   /// stable_end() if there are no normal cleanups.
   stable_iterator getInnermostNormalCleanup() const {
     return InnermostNormalCleanup;
   }
   stable_iterator getInnermostActiveNormalCleanup() const;

   stable_iterator getInnermostEHScope() const {
     return InnermostEHScope;
   }

   stable_iterator getInnermostActiveEHScope() const;

   /// An unstable reference to a scope-stack depth.  Invalidated by
   /// pushes but not pops.
   class iterator;

   /// Returns an iterator pointing to the innermost EH scope.
   iterator begin() const;

   /// Returns an iterator pointing to the outermost EH scope.
   iterator end() const;

   /// Create a stable reference to the top of the EH stack.  The
   /// returned reference is valid until that scope is popped off the
   /// stack.
   stable_iterator stable_begin() const {
     return stable_iterator(EndOfBuffer - StartOfData);
   }

   /// Create a stable reference to the bottom of the EH stack.
   static stable_iterator stable_end() {
     return stable_iterator(0);
   }

   /// Translates an iterator into a stable_iterator.
   stable_iterator stabilize(iterator it) const;

   /// Turn a stable reference to a scope depth into a unstable pointer
   /// to the EH stack.
   iterator find(stable_iterator save) const;

   /// Removes the cleanup pointed to by the given stable_iterator.
   void removeCleanup(stable_iterator save);

   /// Add a branch fixup to the current cleanup scope.
   BranchFixup &addBranchFixup() {
     assert(hasNormalCleanups() && "adding fixup in scope without cleanups");
     BranchFixups.push_back(BranchFixup());
     return BranchFixups.back();
   }

   unsigned getNumBranchFixups() const { return BranchFixups.size(); }
   BranchFixup &getBranchFixup(unsigned I) {
     assert(I < getNumBranchFixups());
     return BranchFixups[I];
   }

   /// Pops lazily-removed fixups from the end of the list.  This
   /// should only be called by procedures which have just popped a
   /// cleanup or resolved one or more fixups.
   void popNullFixups();

   /// Clears the branch-fixups list.  This should only be called by
   /// ResolveAllBranchFixups.
   void clearFixups() { BranchFixups.clear(); }
 };

 } // namespace CodeGen
 } // namespace clang

 #endif
	//===-- EHScopeStack.h - Stack for cleanup IR generation --------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// These classes should be the minimum interface required for other parts of
	// CodeGen to emit cleanups. The implementation is in CGCleanup.cpp and other
	// implemenentation details that are not widely needed are in CGCleanup.h.
	//
	//===----------------------------------------------------------------------===//

	#ifndef CLANG_CODEGEN_EHSCOPESTACK_H
	#define CLANG_CODEGEN_EHSCOPESTACK_H

	#include "clang/Basic/LLVM.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/IR/BasicBlock.h"
	#include "llvm/IR/Instructions.h"
	#include "llvm/IR/Value.h"

	namespace clang {
	namespace CodeGen {

	class CodeGenFunction;

	/// A branch fixup. These are required when emitting a goto to a
	/// label which hasn't been emitted yet. The goto is optimistically
	/// emitted as a branch to the basic block for the label, and (if it
	/// occurs in a scope with non-trivial cleanups) a fixup is added to
	/// the innermost cleanup. When a (normal) cleanup is popped, any
	/// unresolved fixups in that scope are threaded through the cleanup.
	struct BranchFixup {
	/// The block containing the terminator which needs to be modified
	/// into a switch if this fixup is resolved into the current scope.
	/// If null, LatestBranch points directly to the destination.
	llvm::BasicBlock *OptimisticBranchBlock;

	/// The ultimate destination of the branch.
	///
	/// This can be set to null to indicate that this fixup was
	/// successfully resolved.
	llvm::BasicBlock *Destination;

	/// The destination index value.
	unsigned DestinationIndex;

	/// The initial branch of the fixup.
	llvm::BranchInst *InitialBranch;
	};

	template <class T> struct InvariantValue {
	typedef T type;
	typedef T saved_type;
	static bool needsSaving(type value) { return false; }
	static saved_type save(CodeGenFunction &CGF, type value) { return value; }
	static type restore(CodeGenFunction &CGF, saved_type value) { return value; }
	};

	/// A metaprogramming class for ensuring that a value will dominate an
	/// arbitrary position in a function.
	template <class T> struct DominatingValue : InvariantValue<T> {};

	template <class T, bool mightBeInstruction =
	std::is_base_of<llvm::Value, T>::value &&
	!std::is_base_of<llvm::Constant, T>::value &&
	!std::is_base_of<llvm::BasicBlock, T>::value>
	struct DominatingPointer;
	template <class T> struct DominatingPointer<T,false> : InvariantValue<T*> {};
	// template <class T> struct DominatingPointer<T,true> at end of file

	template <class T> struct DominatingValue<T*> : DominatingPointer<T> {};

	enum CleanupKind {
	EHCleanup = 0x1,
	NormalCleanup = 0x2,
	NormalAndEHCleanup = EHCleanup \| NormalCleanup,

	InactiveCleanup = 0x4,
	InactiveEHCleanup = EHCleanup \| InactiveCleanup,
	InactiveNormalCleanup = NormalCleanup \| InactiveCleanup,
	InactiveNormalAndEHCleanup = NormalAndEHCleanup \| InactiveCleanup
	};

	/// A stack of scopes which respond to exceptions, including cleanups
	/// and catch blocks.
	class EHScopeStack {
	public:
	/// A saved depth on the scope stack. This is necessary because
	/// pushing scopes onto the stack invalidates iterators.
	class stable_iterator {
	friend class EHScopeStack;

	/// Offset from StartOfData to EndOfBuffer.
	ptrdiff_t Size;

	stable_iterator(ptrdiff_t Size) : Size(Size) {}

	public:
	static stable_iterator invalid() { return stable_iterator(-1); }
	stable_iterator() : Size(-1) {}

	bool isValid() const { return Size >= 0; }

	/// Returns true if this scope encloses I.
	/// Returns false if I is invalid.
	/// This scope must be valid.
	bool encloses(stable_iterator I) const { return Size <= I.Size; }

	/// Returns true if this scope strictly encloses I: that is,
	/// if it encloses I and is not I.
	/// Returns false is I is invalid.
	/// This scope must be valid.
	bool strictlyEncloses(stable_iterator I) const { return Size < I.Size; }

	friend bool operator==(stable_iterator A, stable_iterator B) {
	return A.Size == B.Size;
	}
	friend bool operator!=(stable_iterator A, stable_iterator B) {
	return A.Size != B.Size;
	}
	};

	/// Information for lazily generating a cleanup. Subclasses must be
	/// POD-like: cleanups will not be destructed, and they will be
	/// allocated on the cleanup stack and freely copied and moved
	/// around.
	///
	/// Cleanup implementations should generally be declared in an
	/// anonymous namespace.
	class Cleanup {
	// Anchor the construction vtable.
	virtual void anchor();
	public:
	/// Generation flags.
	class Flags {
	enum {
	F_IsForEH = 0x1,
	F_IsNormalCleanupKind = 0x2,
	F_IsEHCleanupKind = 0x4
	};
	unsigned flags;

	public:
	Flags() : flags(0) {}

	/// isForEH - true if the current emission is for an EH cleanup.
	bool isForEHCleanup() const { return flags & F_IsForEH; }
	bool isForNormalCleanup() const { return !isForEHCleanup(); }
	void setIsForEHCleanup() { flags \|= F_IsForEH; }

	bool isNormalCleanupKind() const { return flags & F_IsNormalCleanupKind; }
	void setIsNormalCleanupKind() { flags \|= F_IsNormalCleanupKind; }

	/// isEHCleanupKind - true if the cleanup was pushed as an EH
	/// cleanup.
	bool isEHCleanupKind() const { return flags & F_IsEHCleanupKind; }
	void setIsEHCleanupKind() { flags \|= F_IsEHCleanupKind; }
	};

	// Provide a virtual destructor to suppress a very common warning
	// that unfortunately cannot be suppressed without this. Cleanups
	// should not rely on this destructor ever being called.
	virtual ~Cleanup() {}

	/// Emit the cleanup. For normal cleanups, this is run in the
	/// same EH context as when the cleanup was pushed, i.e. the
	/// immediately-enclosing context of the cleanup scope. For
	/// EH cleanups, this is run in a terminate context.
	///
	// \param flags cleanup kind.
	virtual void Emit(CodeGenFunction &CGF, Flags flags) = 0;
	};

	/// ConditionalCleanupN stores the saved form of its N parameters,
	/// then restores them and performs the cleanup.
	template <class T, class A0>
	class ConditionalCleanup1 : public Cleanup {
	typedef typename DominatingValue<A0>::saved_type A0_saved;
	A0_saved a0_saved;

	void Emit(CodeGenFunction &CGF, Flags flags) override {
	A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
	T(a0).Emit(CGF, flags);
	}

	public:
	ConditionalCleanup1(A0_saved a0)
	: a0_saved(a0) {}
	};

	template <class T, class A0, class A1>
	class ConditionalCleanup2 : public Cleanup {
	typedef typename DominatingValue<A0>::saved_type A0_saved;
	typedef typename DominatingValue<A1>::saved_type A1_saved;
	A0_saved a0_saved;
	A1_saved a1_saved;

	void Emit(CodeGenFunction &CGF, Flags flags) override {
	A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
	A1 a1 = DominatingValue<A1>::restore(CGF, a1_saved);
	T(a0, a1).Emit(CGF, flags);
	}

	public:
	ConditionalCleanup2(A0_saved a0, A1_saved a1)
	: a0_saved(a0), a1_saved(a1) {}
	};

	template <class T, class A0, class A1, class A2>
	class ConditionalCleanup3 : public Cleanup {
	typedef typename DominatingValue<A0>::saved_type A0_saved;
	typedef typename DominatingValue<A1>::saved_type A1_saved;
	typedef typename DominatingValue<A2>::saved_type A2_saved;
	A0_saved a0_saved;
	A1_saved a1_saved;
	A2_saved a2_saved;

	void Emit(CodeGenFunction &CGF, Flags flags) override {
	A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
	A1 a1 = DominatingValue<A1>::restore(CGF, a1_saved);
	A2 a2 = DominatingValue<A2>::restore(CGF, a2_saved);
	T(a0, a1, a2).Emit(CGF, flags);
	}

	public:
	ConditionalCleanup3(A0_saved a0, A1_saved a1, A2_saved a2)
	: a0_saved(a0), a1_saved(a1), a2_saved(a2) {}
	};

	template <class T, class A0, class A1, class A2, class A3>
	class ConditionalCleanup4 : public Cleanup {
	typedef typename DominatingValue<A0>::saved_type A0_saved;
	typedef typename DominatingValue<A1>::saved_type A1_saved;
	typedef typename DominatingValue<A2>::saved_type A2_saved;
	typedef typename DominatingValue<A3>::saved_type A3_saved;
	A0_saved a0_saved;
	A1_saved a1_saved;
	A2_saved a2_saved;
	A3_saved a3_saved;

	void Emit(CodeGenFunction &CGF, Flags flags) override {
	A0 a0 = DominatingValue<A0>::restore(CGF, a0_saved);
	A1 a1 = DominatingValue<A1>::restore(CGF, a1_saved);
	A2 a2 = DominatingValue<A2>::restore(CGF, a2_saved);
	A3 a3 = DominatingValue<A3>::restore(CGF, a3_saved);
	T(a0, a1, a2, a3).Emit(CGF, flags);
	}

	public:
	ConditionalCleanup4(A0_saved a0, A1_saved a1, A2_saved a2, A3_saved a3)
	: a0_saved(a0), a1_saved(a1), a2_saved(a2), a3_saved(a3) {}
	};

	private:
	// The implementation for this class is in CGException.h and
	// CGException.cpp; the definition is here because it's used as a
	// member of CodeGenFunction.

	/// The start of the scope-stack buffer, i.e. the allocated pointer
	/// for the buffer. All of these pointers are either simultaneously
	/// null or simultaneously valid.
	char *StartOfBuffer;

	/// The end of the buffer.
	char *EndOfBuffer;

	/// The first valid entry in the buffer.
	char *StartOfData;

	/// The innermost normal cleanup on the stack.
	stable_iterator InnermostNormalCleanup;

	/// The innermost EH scope on the stack.
	stable_iterator InnermostEHScope;

	/// The current set of branch fixups. A branch fixup is a jump to
	/// an as-yet unemitted label, i.e. a label for which we don't yet
	/// know the EH stack depth. Whenever we pop a cleanup, we have
	/// to thread all the current branch fixups through it.
	///
	/// Fixups are recorded as the Use of the respective branch or
	/// switch statement. The use points to the final destination.
	/// When popping out of a cleanup, these uses are threaded through
	/// the cleanup and adjusted to point to the new cleanup.
	///
	/// Note that branches are allowed to jump into protected scopes
	/// in certain situations; e.g. the following code is legal:
	/// struct A { ~A(); }; // trivial ctor, non-trivial dtor
	/// goto foo;
	/// A a;
	/// foo:
	/// bar();
	SmallVector<BranchFixup, 8> BranchFixups;

	char *allocate(size_t Size);

	void *pushCleanup(CleanupKind K, size_t DataSize);

	public:
	EHScopeStack() : StartOfBuffer(0), EndOfBuffer(0), StartOfData(0),
	InnermostNormalCleanup(stable_end()),
	InnermostEHScope(stable_end()) {}
	~EHScopeStack() { delete[] StartOfBuffer; }

	// Variadic templates would make this not terrible.

	/// Push a lazily-created cleanup on the stack.
	template <class T>
	void pushCleanup(CleanupKind Kind) {
	void *Buffer = pushCleanup(Kind, sizeof(T));
	Cleanup *Obj = new(Buffer) T();
	(void) Obj;
	}

	/// Push a lazily-created cleanup on the stack.
	template <class T, class A0>
	void pushCleanup(CleanupKind Kind, A0 a0) {
	void *Buffer = pushCleanup(Kind, sizeof(T));
	Cleanup *Obj = new(Buffer) T(a0);
	(void) Obj;
	}

	/// Push a lazily-created cleanup on the stack.
	template <class T, class A0, class A1>
	void pushCleanup(CleanupKind Kind, A0 a0, A1 a1) {
	void *Buffer = pushCleanup(Kind, sizeof(T));
	Cleanup *Obj = new(Buffer) T(a0, a1);
	(void) Obj;
	}

	/// Push a lazily-created cleanup on the stack.
	template <class T, class A0, class A1, class A2>
	void pushCleanup(CleanupKind Kind, A0 a0, A1 a1, A2 a2) {
	void *Buffer = pushCleanup(Kind, sizeof(T));
	Cleanup *Obj = new(Buffer) T(a0, a1, a2);
	(void) Obj;
	}

	/// Push a lazily-created cleanup on the stack.
	template <class T, class A0, class A1, class A2, class A3>
	void pushCleanup(CleanupKind Kind, A0 a0, A1 a1, A2 a2, A3 a3) {
	void *Buffer = pushCleanup(Kind, sizeof(T));
	Cleanup *Obj = new(Buffer) T(a0, a1, a2, a3);
	(void) Obj;
	}

	/// Push a lazily-created cleanup on the stack.
	template <class T, class A0, class A1, class A2, class A3, class A4>
	void pushCleanup(CleanupKind Kind, A0 a0, A1 a1, A2 a2, A3 a3, A4 a4) {
	void *Buffer = pushCleanup(Kind, sizeof(T));
	Cleanup *Obj = new(Buffer) T(a0, a1, a2, a3, a4);
	(void) Obj;
	}

	// Feel free to add more variants of the following:

	/// Push a cleanup with non-constant storage requirements on the
	/// stack. The cleanup type must provide an additional static method:
	/// static size_t getExtraSize(size_t);
	/// The argument to this method will be the value N, which will also
	/// be passed as the first argument to the constructor.
	///
	/// The data stored in the extra storage must obey the same
	/// restrictions as normal cleanup member data.
	///
	/// The pointer returned from this method is valid until the cleanup
	/// stack is modified.
	template <class T, class A0, class A1, class A2>
	T *pushCleanupWithExtra(CleanupKind Kind, size_t N, A0 a0, A1 a1, A2 a2) {
	void *Buffer = pushCleanup(Kind, sizeof(T) + T::getExtraSize(N));
	return new (Buffer) T(N, a0, a1, a2);
	}

	void pushCopyOfCleanup(CleanupKind Kind, const void *Cleanup, size_t Size) {
	void *Buffer = pushCleanup(Kind, Size);
	std::memcpy(Buffer, Cleanup, Size);
	}

	/// Pops a cleanup scope off the stack. This is private to CGCleanup.cpp.
	void popCleanup();

	/// Push a set of catch handlers on the stack. The catch is
	/// uninitialized and will need to have the given number of handlers
	/// set on it.
	class EHCatchScope *pushCatch(unsigned NumHandlers);

	/// Pops a catch scope off the stack. This is private to CGException.cpp.
	void popCatch();

	/// Push an exceptions filter on the stack.
	class EHFilterScope *pushFilter(unsigned NumFilters);

	/// Pops an exceptions filter off the stack.
	void popFilter();

	/// Push a terminate handler on the stack.
	void pushTerminate();

	/// Pops a terminate handler off the stack.
	void popTerminate();

	/// Determines whether the exception-scopes stack is empty.
	bool empty() const { return StartOfData == EndOfBuffer; }

	bool requiresLandingPad() const {
	return InnermostEHScope != stable_end();
	}

	/// Determines whether there are any normal cleanups on the stack.
	bool hasNormalCleanups() const {
	return InnermostNormalCleanup != stable_end();
	}

	/// Returns the innermost normal cleanup on the stack, or
	/// stable_end() if there are no normal cleanups.
	stable_iterator getInnermostNormalCleanup() const {
	return InnermostNormalCleanup;
	}
	stable_iterator getInnermostActiveNormalCleanup() const;

	stable_iterator getInnermostEHScope() const {
	return InnermostEHScope;
	}

	stable_iterator getInnermostActiveEHScope() const;

	/// An unstable reference to a scope-stack depth. Invalidated by
	/// pushes but not pops.
	class iterator;

	/// Returns an iterator pointing to the innermost EH scope.
	iterator begin() const;

	/// Returns an iterator pointing to the outermost EH scope.
	iterator end() const;

	/// Create a stable reference to the top of the EH stack. The
	/// returned reference is valid until that scope is popped off the
	/// stack.
	stable_iterator stable_begin() const {
	return stable_iterator(EndOfBuffer - StartOfData);
	}

	/// Create a stable reference to the bottom of the EH stack.
	static stable_iterator stable_end() {
	return stable_iterator(0);
	}

	/// Translates an iterator into a stable_iterator.
	stable_iterator stabilize(iterator it) const;

	/// Turn a stable reference to a scope depth into a unstable pointer
	/// to the EH stack.
	iterator find(stable_iterator save) const;

	/// Removes the cleanup pointed to by the given stable_iterator.
	void removeCleanup(stable_iterator save);

	/// Add a branch fixup to the current cleanup scope.
	BranchFixup &addBranchFixup() {
	assert(hasNormalCleanups() && "adding fixup in scope without cleanups");
	BranchFixups.push_back(BranchFixup());
	return BranchFixups.back();
	}

	unsigned getNumBranchFixups() const { return BranchFixups.size(); }
	BranchFixup &getBranchFixup(unsigned I) {
	assert(I < getNumBranchFixups());
	return BranchFixups[I];
	}

	/// Pops lazily-removed fixups from the end of the list. This
	/// should only be called by procedures which have just popped a
	/// cleanup or resolved one or more fixups.
	void popNullFixups();

	/// Clears the branch-fixups list. This should only be called by
	/// ResolveAllBranchFixups.
	void clearFixups() { BranchFixups.clear(); }
	};

	} // namespace CodeGen
	} // namespace clang

	#endif