lib/CodeGen/CGCleanup.h - clang - Git at Google

 //===-- CGCleanup.h - Classes for cleanups 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 support the generation of LLVM IR for cleanups.
 //
 //===----------------------------------------------------------------------===//

 #ifndef CLANG_CODEGEN_CGCLEANUP_H
 #define CLANG_CODEGEN_CGCLEANUP_H

 /// EHScopeStack is defined in CodeGenFunction.h, but its
 /// implementation is in this file and in CGCleanup.cpp.
 #include "CodeGenFunction.h"

 namespace llvm {
   class Value;
   class BasicBlock;
 }

 namespace clang {
 namespace CodeGen {

 /// A protected scope for zero-cost EH handling.
 class EHScope {
   llvm::BasicBlock *CachedLandingPad;

   unsigned K : 2;

 protected:
   enum { BitsRemaining = 30 };

 public:
   enum Kind { Cleanup, Catch, Terminate, Filter };

   EHScope(Kind K) : CachedLandingPad(0), K(K) {}

   Kind getKind() const { return static_cast<Kind>(K); }

   llvm::BasicBlock *getCachedLandingPad() const {
     return CachedLandingPad;
   }

   void setCachedLandingPad(llvm::BasicBlock *Block) {
     CachedLandingPad = Block;
   }
 };

 /// A scope which attempts to handle some, possibly all, types of
 /// exceptions.
 ///
 /// Objective C @finally blocks are represented using a cleanup scope
 /// after the catch scope.
 class EHCatchScope : public EHScope {
   unsigned NumHandlers : BitsRemaining;

   // In effect, we have a flexible array member
   //   Handler Handlers[0];
   // But that's only standard in C99, not C++, so we have to do
   // annoying pointer arithmetic instead.

 public:
   struct Handler {
     /// A type info value, or null (C++ null, not an LLVM null pointer)
     /// for a catch-all.
     llvm::Value *Type;

     /// The catch handler for this type.
     llvm::BasicBlock *Block;

     /// The unwind destination index for this handler.
     unsigned Index;
   };

 private:
   friend class EHScopeStack;

   Handler *getHandlers() {
     return reinterpret_cast<Handler*>(this+1);
   }

   const Handler *getHandlers() const {
     return reinterpret_cast<const Handler*>(this+1);
   }

 public:
   static size_t getSizeForNumHandlers(unsigned N) {
     return sizeof(EHCatchScope) + N * sizeof(Handler);
   }

   EHCatchScope(unsigned NumHandlers)
     : EHScope(Catch), NumHandlers(NumHandlers) {
   }

   unsigned getNumHandlers() const {
     return NumHandlers;
   }

   void setCatchAllHandler(unsigned I, llvm::BasicBlock *Block) {
     setHandler(I, /*catchall*/ 0, Block);
   }

   void setHandler(unsigned I, llvm::Value *Type, llvm::BasicBlock *Block) {
     assert(I < getNumHandlers());
     getHandlers()[I].Type = Type;
     getHandlers()[I].Block = Block;
   }

   const Handler &getHandler(unsigned I) const {
     assert(I < getNumHandlers());
     return getHandlers()[I];
   }

   typedef const Handler *iterator;
   iterator begin() const { return getHandlers(); }
   iterator end() const { return getHandlers() + getNumHandlers(); }

   static bool classof(const EHScope *Scope) {
     return Scope->getKind() == Catch;
   }
 };

 /// A cleanup scope which generates the cleanup blocks lazily.
 class EHCleanupScope : public EHScope {
   /// Whether this cleanup needs to be run along normal edges.
   bool IsNormalCleanup : 1;

   /// Whether this cleanup needs to be run along exception edges.
   bool IsEHCleanup : 1;

   /// Whether this cleanup is currently active.
   bool IsActive : 1;

   /// Whether the normal cleanup should test the activation flag.
   bool TestFlagInNormalCleanup : 1;

   /// Whether the EH cleanup should test the activation flag.
   bool TestFlagInEHCleanup : 1;

   /// The amount of extra storage needed by the Cleanup.
   /// Always a multiple of the scope-stack alignment.
   unsigned CleanupSize : 12;

   /// The number of fixups required by enclosing scopes (not including
   /// this one).  If this is the top cleanup scope, all the fixups
   /// from this index onwards belong to this scope.
   unsigned FixupDepth : BitsRemaining - 17; // currently 13

   /// The nearest normal cleanup scope enclosing this one.
   EHScopeStack::stable_iterator EnclosingNormal;

   /// The nearest EH cleanup scope enclosing this one.
   EHScopeStack::stable_iterator EnclosingEH;

   /// The dual entry/exit block along the normal edge.  This is lazily
   /// created if needed before the cleanup is popped.
   llvm::BasicBlock *NormalBlock;

   /// The dual entry/exit block along the EH edge.  This is lazily
   /// created if needed before the cleanup is popped.
   llvm::BasicBlock *EHBlock;

   /// An optional i1 variable indicating whether this cleanup has been
   /// activated yet.
   llvm::AllocaInst *ActiveFlag;

   /// Extra information required for cleanups that have resolved
   /// branches through them.  This has to be allocated on the side
   /// because everything on the cleanup stack has be trivially
   /// movable.
   struct ExtInfo {
     /// The destinations of normal branch-afters and branch-throughs.
     llvm::SmallPtrSet<llvm::BasicBlock*, 4> Branches;

     /// Normal branch-afters.
     llvm::SmallVector<std::pair<llvm::BasicBlock*,llvm::ConstantInt*>, 4>
       BranchAfters;

     /// The destinations of EH branch-afters and branch-throughs.
     /// TODO: optimize for the extremely common case of a single
     /// branch-through.
     llvm::SmallPtrSet<llvm::BasicBlock*, 4> EHBranches;

     /// EH branch-afters.
     llvm::SmallVector<std::pair<llvm::BasicBlock*,llvm::ConstantInt*>, 4>
     EHBranchAfters;
   };
   mutable struct ExtInfo *ExtInfo;

   struct ExtInfo &getExtInfo() {
     if (!ExtInfo) ExtInfo = new struct ExtInfo();
     return *ExtInfo;
   }

   const struct ExtInfo &getExtInfo() const {
     if (!ExtInfo) ExtInfo = new struct ExtInfo();
     return *ExtInfo;
   }

 public:
   /// Gets the size required for a lazy cleanup scope with the given
   /// cleanup-data requirements.
   static size_t getSizeForCleanupSize(size_t Size) {
     return sizeof(EHCleanupScope) + Size;
   }

   size_t getAllocatedSize() const {
     return sizeof(EHCleanupScope) + CleanupSize;
   }

   EHCleanupScope(bool IsNormal, bool IsEH, bool IsActive,
                  unsigned CleanupSize, unsigned FixupDepth,
                  EHScopeStack::stable_iterator EnclosingNormal,
                  EHScopeStack::stable_iterator EnclosingEH)
     : EHScope(EHScope::Cleanup),
       IsNormalCleanup(IsNormal), IsEHCleanup(IsEH), IsActive(IsActive),
       TestFlagInNormalCleanup(false), TestFlagInEHCleanup(false),
       CleanupSize(CleanupSize), FixupDepth(FixupDepth),
       EnclosingNormal(EnclosingNormal), EnclosingEH(EnclosingEH),
       NormalBlock(0), EHBlock(0), ActiveFlag(0), ExtInfo(0)
   {
     assert(this->CleanupSize == CleanupSize && "cleanup size overflow");
   }

   ~EHCleanupScope() {
     delete ExtInfo;
   }

   bool isNormalCleanup() const { return IsNormalCleanup; }
   llvm::BasicBlock *getNormalBlock() const { return NormalBlock; }
   void setNormalBlock(llvm::BasicBlock *BB) { NormalBlock = BB; }

   bool isEHCleanup() const { return IsEHCleanup; }
   llvm::BasicBlock *getEHBlock() const { return EHBlock; }
   void setEHBlock(llvm::BasicBlock *BB) { EHBlock = BB; }

   bool isActive() const { return IsActive; }
   void setActive(bool A) { IsActive = A; }

   llvm::AllocaInst *getActiveFlag() const { return ActiveFlag; }
   void setActiveFlag(llvm::AllocaInst *Var) { ActiveFlag = Var; }

   void setTestFlagInNormalCleanup() { TestFlagInNormalCleanup = true; }
   bool shouldTestFlagInNormalCleanup() const { return TestFlagInNormalCleanup; }

   void setTestFlagInEHCleanup() { TestFlagInEHCleanup = true; }
   bool shouldTestFlagInEHCleanup() const { return TestFlagInEHCleanup; }

   unsigned getFixupDepth() const { return FixupDepth; }
   EHScopeStack::stable_iterator getEnclosingNormalCleanup() const {
     return EnclosingNormal;
   }
   EHScopeStack::stable_iterator getEnclosingEHCleanup() const {
     return EnclosingEH;
   }

   size_t getCleanupSize() const { return CleanupSize; }
   void *getCleanupBuffer() { return this + 1; }

   EHScopeStack::Cleanup *getCleanup() {
     return reinterpret_cast<EHScopeStack::Cleanup*>(getCleanupBuffer());
   }

   /// True if this cleanup scope has any branch-afters or branch-throughs.
   bool hasBranches() const { return ExtInfo && !ExtInfo->Branches.empty(); }

   /// Add a branch-after to this cleanup scope.  A branch-after is a
   /// branch from a point protected by this (normal) cleanup to a
   /// point in the normal cleanup scope immediately containing it.
   /// For example,
   ///   for (;;) { A a; break; }
   /// contains a branch-after.
   ///
   /// Branch-afters each have their own destination out of the
   /// cleanup, guaranteed distinct from anything else threaded through
   /// it.  Therefore branch-afters usually force a switch after the
   /// cleanup.
   void addBranchAfter(llvm::ConstantInt *Index,
                       llvm::BasicBlock *Block) {
     struct ExtInfo &ExtInfo = getExtInfo();
     if (ExtInfo.Branches.insert(Block))
       ExtInfo.BranchAfters.push_back(std::make_pair(Block, Index));
   }

   /// Return the number of unique branch-afters on this scope.
   unsigned getNumBranchAfters() const {
     return ExtInfo ? ExtInfo->BranchAfters.size() : 0;
   }

   llvm::BasicBlock *getBranchAfterBlock(unsigned I) const {
     assert(I < getNumBranchAfters());
     return ExtInfo->BranchAfters[I].first;
   }

   llvm::ConstantInt *getBranchAfterIndex(unsigned I) const {
     assert(I < getNumBranchAfters());
     return ExtInfo->BranchAfters[I].second;
   }

   /// Add a branch-through to this cleanup scope.  A branch-through is
   /// a branch from a scope protected by this (normal) cleanup to an
   /// enclosing scope other than the immediately-enclosing normal
   /// cleanup scope.
   ///
   /// In the following example, the branch through B's scope is a
   /// branch-through, while the branch through A's scope is a
   /// branch-after:
   ///   for (;;) { A a; B b; break; }
   ///
   /// All branch-throughs have a common destination out of the
   /// cleanup, one possibly shared with the fall-through.  Therefore
   /// branch-throughs usually don't force a switch after the cleanup.
   ///
   /// \return true if the branch-through was new to this scope
   bool addBranchThrough(llvm::BasicBlock *Block) {
     return getExtInfo().Branches.insert(Block);
   }

   /// Determines if this cleanup scope has any branch throughs.
   bool hasBranchThroughs() const {
     if (!ExtInfo) return false;
     return (ExtInfo->BranchAfters.size() != ExtInfo->Branches.size());
   }

   // Same stuff, only for EH branches instead of normal branches.
   // It's quite possible that we could find a better representation
   // for this.

   bool hasEHBranches() const { return ExtInfo && !ExtInfo->EHBranches.empty(); }
   void addEHBranchAfter(llvm::ConstantInt *Index,
                         llvm::BasicBlock *Block) {
     struct ExtInfo &ExtInfo = getExtInfo();
     if (ExtInfo.EHBranches.insert(Block))
       ExtInfo.EHBranchAfters.push_back(std::make_pair(Block, Index));
   }

   unsigned getNumEHBranchAfters() const {
     return ExtInfo ? ExtInfo->EHBranchAfters.size() : 0;
   }

   llvm::BasicBlock *getEHBranchAfterBlock(unsigned I) const {
     assert(I < getNumEHBranchAfters());
     return ExtInfo->EHBranchAfters[I].first;
   }

   llvm::ConstantInt *getEHBranchAfterIndex(unsigned I) const {
     assert(I < getNumEHBranchAfters());
     return ExtInfo->EHBranchAfters[I].second;
   }

   bool addEHBranchThrough(llvm::BasicBlock *Block) {
     return getExtInfo().EHBranches.insert(Block);
   }

   bool hasEHBranchThroughs() const {
     if (!ExtInfo) return false;
     return (ExtInfo->EHBranchAfters.size() != ExtInfo->EHBranches.size());
   }

   static bool classof(const EHScope *Scope) {
     return (Scope->getKind() == Cleanup);
   }
 };

 /// An exceptions scope which filters exceptions thrown through it.
 /// Only exceptions matching the filter types will be permitted to be
 /// thrown.
 ///
 /// This is used to implement C++ exception specifications.
 class EHFilterScope : public EHScope {
   unsigned NumFilters : BitsRemaining;

   // Essentially ends in a flexible array member:
   // llvm::Value *FilterTypes[0];

   llvm::Value **getFilters() {
     return reinterpret_cast<llvm::Value**>(this+1);
   }

   llvm::Value * const *getFilters() const {
     return reinterpret_cast<llvm::Value* const *>(this+1);
   }

 public:
   EHFilterScope(unsigned NumFilters) :
     EHScope(Filter), NumFilters(NumFilters) {}

   static size_t getSizeForNumFilters(unsigned NumFilters) {
     return sizeof(EHFilterScope) + NumFilters * sizeof(llvm::Value*);
   }

   unsigned getNumFilters() const { return NumFilters; }

   void setFilter(unsigned I, llvm::Value *FilterValue) {
     assert(I < getNumFilters());
     getFilters()[I] = FilterValue;
   }

   llvm::Value *getFilter(unsigned I) const {
     assert(I < getNumFilters());
     return getFilters()[I];
   }

   static bool classof(const EHScope *Scope) {
     return Scope->getKind() == Filter;
   }
 };

 /// An exceptions scope which calls std::terminate if any exception
 /// reaches it.
 class EHTerminateScope : public EHScope {
   unsigned DestIndex : BitsRemaining;
 public:
   EHTerminateScope(unsigned Index) : EHScope(Terminate), DestIndex(Index) {}
   static size_t getSize() { return sizeof(EHTerminateScope); }

   unsigned getDestIndex() const { return DestIndex; }

   static bool classof(const EHScope *Scope) {
     return Scope->getKind() == Terminate;
   }
 };

 /// A non-stable pointer into the scope stack.
 class EHScopeStack::iterator {
   char *Ptr;

   friend class EHScopeStack;
   explicit iterator(char *Ptr) : Ptr(Ptr) {}

 public:
   iterator() : Ptr(0) {}

   EHScope *get() const {
     return reinterpret_cast<EHScope*>(Ptr);
   }

   EHScope *operator->() const { return get(); }
   EHScope &operator*() const { return *get(); }

   iterator &operator++() {
     switch (get()->getKind()) {
     case EHScope::Catch:
       Ptr += EHCatchScope::getSizeForNumHandlers(
           static_cast<const EHCatchScope*>(get())->getNumHandlers());
       break;

     case EHScope::Filter:
       Ptr += EHFilterScope::getSizeForNumFilters(
           static_cast<const EHFilterScope*>(get())->getNumFilters());
       break;

     case EHScope::Cleanup:
       Ptr += static_cast<const EHCleanupScope*>(get())
         ->getAllocatedSize();
       break;

     case EHScope::Terminate:
       Ptr += EHTerminateScope::getSize();
       break;
     }

     return *this;
   }

   iterator next() {
     iterator copy = *this;
     ++copy;
     return copy;
   }

   iterator operator++(int) {
     iterator copy = *this;
     operator++();
     return copy;
   }

   bool encloses(iterator other) const { return Ptr >= other.Ptr; }
   bool strictlyEncloses(iterator other) const { return Ptr > other.Ptr; }

   bool operator==(iterator other) const { return Ptr == other.Ptr; }
   bool operator!=(iterator other) const { return Ptr != other.Ptr; }
 };

 inline EHScopeStack::iterator EHScopeStack::begin() const {
   return iterator(StartOfData);
 }

 inline EHScopeStack::iterator EHScopeStack::end() const {
   return iterator(EndOfBuffer);
 }

 inline void EHScopeStack::popCatch() {
   assert(!empty() && "popping exception stack when not empty");

   assert(isa<EHCatchScope>(*begin()));
   StartOfData += EHCatchScope::getSizeForNumHandlers(
                           cast<EHCatchScope>(*begin()).getNumHandlers());

   if (empty()) NextEHDestIndex = FirstEHDestIndex;

   assert(CatchDepth > 0 && "mismatched catch/terminate push/pop");
   CatchDepth--;
 }

 inline void EHScopeStack::popTerminate() {
   assert(!empty() && "popping exception stack when not empty");

   assert(isa<EHTerminateScope>(*begin()));
   StartOfData += EHTerminateScope::getSize();

   if (empty()) NextEHDestIndex = FirstEHDestIndex;

   assert(CatchDepth > 0 && "mismatched catch/terminate push/pop");
   CatchDepth--;
 }

 inline EHScopeStack::iterator EHScopeStack::find(stable_iterator sp) const {
   assert(sp.isValid() && "finding invalid savepoint");
   assert(sp.Size <= stable_begin().Size && "finding savepoint after pop");
   return iterator(EndOfBuffer - sp.Size);
 }

 inline EHScopeStack::stable_iterator
 EHScopeStack::stabilize(iterator ir) const {
   assert(StartOfData <= ir.Ptr && ir.Ptr <= EndOfBuffer);
   return stable_iterator(EndOfBuffer - ir.Ptr);
 }

 inline EHScopeStack::stable_iterator
 EHScopeStack::getInnermostActiveNormalCleanup() const {
   for (EHScopeStack::stable_iterator
          I = getInnermostNormalCleanup(), E = stable_end(); I != E; ) {
     EHCleanupScope &S = cast<EHCleanupScope>(*find(I));
     if (S.isActive()) return I;
     I = S.getEnclosingNormalCleanup();
   }
   return stable_end();
 }

 inline EHScopeStack::stable_iterator
 EHScopeStack::getInnermostActiveEHCleanup() const {
   for (EHScopeStack::stable_iterator
          I = getInnermostEHCleanup(), E = stable_end(); I != E; ) {
     EHCleanupScope &S = cast<EHCleanupScope>(*find(I));
     if (S.isActive()) return I;
     I = S.getEnclosingEHCleanup();
   }
   return stable_end();
 }

 }
 }

 #endif
	//===-- CGCleanup.h - Classes for cleanups 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 support the generation of LLVM IR for cleanups.
	//
	//===----------------------------------------------------------------------===//

	#ifndef CLANG_CODEGEN_CGCLEANUP_H
	#define CLANG_CODEGEN_CGCLEANUP_H

	/// EHScopeStack is defined in CodeGenFunction.h, but its
	/// implementation is in this file and in CGCleanup.cpp.
	#include "CodeGenFunction.h"

	namespace llvm {
	class Value;
	class BasicBlock;
	}

	namespace clang {
	namespace CodeGen {

	/// A protected scope for zero-cost EH handling.
	class EHScope {
	llvm::BasicBlock *CachedLandingPad;

	unsigned K : 2;

	protected:
	enum { BitsRemaining = 30 };

	public:
	enum Kind { Cleanup, Catch, Terminate, Filter };

	EHScope(Kind K) : CachedLandingPad(0), K(K) {}

	Kind getKind() const { return static_cast<Kind>(K); }

	llvm::BasicBlock *getCachedLandingPad() const {
	return CachedLandingPad;
	}

	void setCachedLandingPad(llvm::BasicBlock *Block) {
	CachedLandingPad = Block;
	}
	};

	/// A scope which attempts to handle some, possibly all, types of
	/// exceptions.
	///
	/// Objective C @finally blocks are represented using a cleanup scope
	/// after the catch scope.
	class EHCatchScope : public EHScope {
	unsigned NumHandlers : BitsRemaining;

	// In effect, we have a flexible array member
	// Handler Handlers[0];
	// But that's only standard in C99, not C++, so we have to do
	// annoying pointer arithmetic instead.

	public:
	struct Handler {
	/// A type info value, or null (C++ null, not an LLVM null pointer)
	/// for a catch-all.
	llvm::Value *Type;

	/// The catch handler for this type.
	llvm::BasicBlock *Block;

	/// The unwind destination index for this handler.
	unsigned Index;
	};

	private:
	friend class EHScopeStack;

	Handler *getHandlers() {
	return reinterpret_cast<Handler*>(this+1);
	}

	const Handler *getHandlers() const {
	return reinterpret_cast<const Handler*>(this+1);
	}

	public:
	static size_t getSizeForNumHandlers(unsigned N) {
	return sizeof(EHCatchScope) + N * sizeof(Handler);
	}

	EHCatchScope(unsigned NumHandlers)
	: EHScope(Catch), NumHandlers(NumHandlers) {
	}

	unsigned getNumHandlers() const {
	return NumHandlers;
	}

	void setCatchAllHandler(unsigned I, llvm::BasicBlock *Block) {
	setHandler(I, /catchall/ 0, Block);
	}

	void setHandler(unsigned I, llvm::Value Type, llvm::BasicBlock Block) {
	assert(I < getNumHandlers());
	getHandlers()[I].Type = Type;
	getHandlers()[I].Block = Block;
	}

	const Handler &getHandler(unsigned I) const {
	assert(I < getNumHandlers());
	return getHandlers()[I];
	}

	typedef const Handler *iterator;
	iterator begin() const { return getHandlers(); }
	iterator end() const { return getHandlers() + getNumHandlers(); }

	static bool classof(const EHScope *Scope) {
	return Scope->getKind() == Catch;
	}
	};

	/// A cleanup scope which generates the cleanup blocks lazily.
	class EHCleanupScope : public EHScope {
	/// Whether this cleanup needs to be run along normal edges.
	bool IsNormalCleanup : 1;

	/// Whether this cleanup needs to be run along exception edges.
	bool IsEHCleanup : 1;

	/// Whether this cleanup is currently active.
	bool IsActive : 1;

	/// Whether the normal cleanup should test the activation flag.
	bool TestFlagInNormalCleanup : 1;

	/// Whether the EH cleanup should test the activation flag.
	bool TestFlagInEHCleanup : 1;

	/// The amount of extra storage needed by the Cleanup.
	/// Always a multiple of the scope-stack alignment.
	unsigned CleanupSize : 12;

	/// The number of fixups required by enclosing scopes (not including
	/// this one). If this is the top cleanup scope, all the fixups
	/// from this index onwards belong to this scope.
	unsigned FixupDepth : BitsRemaining - 17; // currently 13

	/// The nearest normal cleanup scope enclosing this one.
	EHScopeStack::stable_iterator EnclosingNormal;

	/// The nearest EH cleanup scope enclosing this one.
	EHScopeStack::stable_iterator EnclosingEH;

	/// The dual entry/exit block along the normal edge. This is lazily
	/// created if needed before the cleanup is popped.
	llvm::BasicBlock *NormalBlock;

	/// The dual entry/exit block along the EH edge. This is lazily
	/// created if needed before the cleanup is popped.
	llvm::BasicBlock *EHBlock;

	/// An optional i1 variable indicating whether this cleanup has been
	/// activated yet.
	llvm::AllocaInst *ActiveFlag;

	/// Extra information required for cleanups that have resolved
	/// branches through them. This has to be allocated on the side
	/// because everything on the cleanup stack has be trivially
	/// movable.
	struct ExtInfo {
	/// The destinations of normal branch-afters and branch-throughs.
	llvm::SmallPtrSet<llvm::BasicBlock*, 4> Branches;

	/// Normal branch-afters.
	llvm::SmallVector<std::pair<llvm::BasicBlock,llvm::ConstantInt>, 4>
	BranchAfters;

	/// The destinations of EH branch-afters and branch-throughs.
	/// TODO: optimize for the extremely common case of a single
	/// branch-through.
	llvm::SmallPtrSet<llvm::BasicBlock*, 4> EHBranches;

	/// EH branch-afters.
	llvm::SmallVector<std::pair<llvm::BasicBlock,llvm::ConstantInt>, 4>
	EHBranchAfters;
	};
	mutable struct ExtInfo *ExtInfo;

	struct ExtInfo &getExtInfo() {
	if (!ExtInfo) ExtInfo = new struct ExtInfo();
	return *ExtInfo;
	}

	const struct ExtInfo &getExtInfo() const {
	if (!ExtInfo) ExtInfo = new struct ExtInfo();
	return *ExtInfo;
	}

	public:
	/// Gets the size required for a lazy cleanup scope with the given
	/// cleanup-data requirements.
	static size_t getSizeForCleanupSize(size_t Size) {
	return sizeof(EHCleanupScope) + Size;
	}

	size_t getAllocatedSize() const {
	return sizeof(EHCleanupScope) + CleanupSize;
	}

	EHCleanupScope(bool IsNormal, bool IsEH, bool IsActive,
	unsigned CleanupSize, unsigned FixupDepth,
	EHScopeStack::stable_iterator EnclosingNormal,
	EHScopeStack::stable_iterator EnclosingEH)
	: EHScope(EHScope::Cleanup),
	IsNormalCleanup(IsNormal), IsEHCleanup(IsEH), IsActive(IsActive),
	TestFlagInNormalCleanup(false), TestFlagInEHCleanup(false),
	CleanupSize(CleanupSize), FixupDepth(FixupDepth),
	EnclosingNormal(EnclosingNormal), EnclosingEH(EnclosingEH),
	NormalBlock(0), EHBlock(0), ActiveFlag(0), ExtInfo(0)
	{
	assert(this->CleanupSize == CleanupSize && "cleanup size overflow");
	}

	~EHCleanupScope() {
	delete ExtInfo;
	}

	bool isNormalCleanup() const { return IsNormalCleanup; }
	llvm::BasicBlock *getNormalBlock() const { return NormalBlock; }
	void setNormalBlock(llvm::BasicBlock *BB) { NormalBlock = BB; }

	bool isEHCleanup() const { return IsEHCleanup; }
	llvm::BasicBlock *getEHBlock() const { return EHBlock; }
	void setEHBlock(llvm::BasicBlock *BB) { EHBlock = BB; }

	bool isActive() const { return IsActive; }
	void setActive(bool A) { IsActive = A; }

	llvm::AllocaInst *getActiveFlag() const { return ActiveFlag; }
	void setActiveFlag(llvm::AllocaInst *Var) { ActiveFlag = Var; }

	void setTestFlagInNormalCleanup() { TestFlagInNormalCleanup = true; }
	bool shouldTestFlagInNormalCleanup() const { return TestFlagInNormalCleanup; }

	void setTestFlagInEHCleanup() { TestFlagInEHCleanup = true; }
	bool shouldTestFlagInEHCleanup() const { return TestFlagInEHCleanup; }

	unsigned getFixupDepth() const { return FixupDepth; }
	EHScopeStack::stable_iterator getEnclosingNormalCleanup() const {
	return EnclosingNormal;
	}
	EHScopeStack::stable_iterator getEnclosingEHCleanup() const {
	return EnclosingEH;
	}

	size_t getCleanupSize() const { return CleanupSize; }
	void *getCleanupBuffer() { return this + 1; }

	EHScopeStack::Cleanup *getCleanup() {
	return reinterpret_cast<EHScopeStack::Cleanup*>(getCleanupBuffer());
	}

	/// True if this cleanup scope has any branch-afters or branch-throughs.
	bool hasBranches() const { return ExtInfo && !ExtInfo->Branches.empty(); }

	/// Add a branch-after to this cleanup scope. A branch-after is a
	/// branch from a point protected by this (normal) cleanup to a
	/// point in the normal cleanup scope immediately containing it.
	/// For example,
	/// for (;;) { A a; break; }
	/// contains a branch-after.
	///
	/// Branch-afters each have their own destination out of the
	/// cleanup, guaranteed distinct from anything else threaded through
	/// it. Therefore branch-afters usually force a switch after the
	/// cleanup.
	void addBranchAfter(llvm::ConstantInt *Index,
	llvm::BasicBlock *Block) {
	struct ExtInfo &ExtInfo = getExtInfo();
	if (ExtInfo.Branches.insert(Block))
	ExtInfo.BranchAfters.push_back(std::make_pair(Block, Index));
	}

	/// Return the number of unique branch-afters on this scope.
	unsigned getNumBranchAfters() const {
	return ExtInfo ? ExtInfo->BranchAfters.size() : 0;
	}

	llvm::BasicBlock *getBranchAfterBlock(unsigned I) const {
	assert(I < getNumBranchAfters());
	return ExtInfo->BranchAfters[I].first;
	}

	llvm::ConstantInt *getBranchAfterIndex(unsigned I) const {
	assert(I < getNumBranchAfters());
	return ExtInfo->BranchAfters[I].second;
	}

	/// Add a branch-through to this cleanup scope. A branch-through is
	/// a branch from a scope protected by this (normal) cleanup to an
	/// enclosing scope other than the immediately-enclosing normal
	/// cleanup scope.
	///
	/// In the following example, the branch through B's scope is a
	/// branch-through, while the branch through A's scope is a
	/// branch-after:
	/// for (;;) { A a; B b; break; }
	///
	/// All branch-throughs have a common destination out of the
	/// cleanup, one possibly shared with the fall-through. Therefore
	/// branch-throughs usually don't force a switch after the cleanup.
	///
	/// \return true if the branch-through was new to this scope
	bool addBranchThrough(llvm::BasicBlock *Block) {
	return getExtInfo().Branches.insert(Block);
	}

	/// Determines if this cleanup scope has any branch throughs.
	bool hasBranchThroughs() const {
	if (!ExtInfo) return false;
	return (ExtInfo->BranchAfters.size() != ExtInfo->Branches.size());
	}

	// Same stuff, only for EH branches instead of normal branches.
	// It's quite possible that we could find a better representation
	// for this.

	bool hasEHBranches() const { return ExtInfo && !ExtInfo->EHBranches.empty(); }
	void addEHBranchAfter(llvm::ConstantInt *Index,
	llvm::BasicBlock *Block) {
	struct ExtInfo &ExtInfo = getExtInfo();
	if (ExtInfo.EHBranches.insert(Block))
	ExtInfo.EHBranchAfters.push_back(std::make_pair(Block, Index));
	}

	unsigned getNumEHBranchAfters() const {
	return ExtInfo ? ExtInfo->EHBranchAfters.size() : 0;
	}

	llvm::BasicBlock *getEHBranchAfterBlock(unsigned I) const {
	assert(I < getNumEHBranchAfters());
	return ExtInfo->EHBranchAfters[I].first;
	}

	llvm::ConstantInt *getEHBranchAfterIndex(unsigned I) const {
	assert(I < getNumEHBranchAfters());
	return ExtInfo->EHBranchAfters[I].second;
	}

	bool addEHBranchThrough(llvm::BasicBlock *Block) {
	return getExtInfo().EHBranches.insert(Block);
	}

	bool hasEHBranchThroughs() const {
	if (!ExtInfo) return false;
	return (ExtInfo->EHBranchAfters.size() != ExtInfo->EHBranches.size());
	}

	static bool classof(const EHScope *Scope) {
	return (Scope->getKind() == Cleanup);
	}
	};

	/// An exceptions scope which filters exceptions thrown through it.
	/// Only exceptions matching the filter types will be permitted to be
	/// thrown.
	///
	/// This is used to implement C++ exception specifications.
	class EHFilterScope : public EHScope {
	unsigned NumFilters : BitsRemaining;

	// Essentially ends in a flexible array member:
	// llvm::Value *FilterTypes[0];

	llvm::Value **getFilters() {
	return reinterpret_cast<llvm::Value**>(this+1);
	}

	llvm::Value * const *getFilters() const {
	return reinterpret_cast<llvm::Value* const *>(this+1);
	}

	public:
	EHFilterScope(unsigned NumFilters) :
	EHScope(Filter), NumFilters(NumFilters) {}

	static size_t getSizeForNumFilters(unsigned NumFilters) {
	return sizeof(EHFilterScope) + NumFilters * sizeof(llvm::Value*);
	}

	unsigned getNumFilters() const { return NumFilters; }

	void setFilter(unsigned I, llvm::Value *FilterValue) {
	assert(I < getNumFilters());
	getFilters()[I] = FilterValue;
	}

	llvm::Value *getFilter(unsigned I) const {
	assert(I < getNumFilters());
	return getFilters()[I];
	}

	static bool classof(const EHScope *Scope) {
	return Scope->getKind() == Filter;
	}
	};

	/// An exceptions scope which calls std::terminate if any exception
	/// reaches it.
	class EHTerminateScope : public EHScope {
	unsigned DestIndex : BitsRemaining;
	public:
	EHTerminateScope(unsigned Index) : EHScope(Terminate), DestIndex(Index) {}
	static size_t getSize() { return sizeof(EHTerminateScope); }

	unsigned getDestIndex() const { return DestIndex; }

	static bool classof(const EHScope *Scope) {
	return Scope->getKind() == Terminate;
	}
	};

	/// A non-stable pointer into the scope stack.
	class EHScopeStack::iterator {
	char *Ptr;

	friend class EHScopeStack;
	explicit iterator(char *Ptr) : Ptr(Ptr) {}

	public:
	iterator() : Ptr(0) {}

	EHScope *get() const {
	return reinterpret_cast<EHScope*>(Ptr);
	}

	EHScope *operator->() const { return get(); }
	EHScope &operator() const { return get(); }

	iterator &operator++() {
	switch (get()->getKind()) {
	case EHScope::Catch:
	Ptr += EHCatchScope::getSizeForNumHandlers(
	static_cast<const EHCatchScope*>(get())->getNumHandlers());
	break;

	case EHScope::Filter:
	Ptr += EHFilterScope::getSizeForNumFilters(
	static_cast<const EHFilterScope*>(get())->getNumFilters());
	break;

	case EHScope::Cleanup:
	Ptr += static_cast<const EHCleanupScope*>(get())
	->getAllocatedSize();
	break;

	case EHScope::Terminate:
	Ptr += EHTerminateScope::getSize();
	break;
	}

	return *this;
	}

	iterator next() {
	iterator copy = *this;
	++copy;
	return copy;
	}

	iterator operator++(int) {
	iterator copy = *this;
	operator++();
	return copy;
	}

	bool encloses(iterator other) const { return Ptr >= other.Ptr; }
	bool strictlyEncloses(iterator other) const { return Ptr > other.Ptr; }

	bool operator==(iterator other) const { return Ptr == other.Ptr; }
	bool operator!=(iterator other) const { return Ptr != other.Ptr; }
	};

	inline EHScopeStack::iterator EHScopeStack::begin() const {
	return iterator(StartOfData);
	}

	inline EHScopeStack::iterator EHScopeStack::end() const {
	return iterator(EndOfBuffer);
	}

	inline void EHScopeStack::popCatch() {
	assert(!empty() && "popping exception stack when not empty");

	assert(isa<EHCatchScope>(*begin()));
	StartOfData += EHCatchScope::getSizeForNumHandlers(
	cast<EHCatchScope>(*begin()).getNumHandlers());

	if (empty()) NextEHDestIndex = FirstEHDestIndex;

	assert(CatchDepth > 0 && "mismatched catch/terminate push/pop");
	CatchDepth--;
	}

	inline void EHScopeStack::popTerminate() {
	assert(!empty() && "popping exception stack when not empty");

	assert(isa<EHTerminateScope>(*begin()));
	StartOfData += EHTerminateScope::getSize();

	if (empty()) NextEHDestIndex = FirstEHDestIndex;

	assert(CatchDepth > 0 && "mismatched catch/terminate push/pop");
	CatchDepth--;
	}

	inline EHScopeStack::iterator EHScopeStack::find(stable_iterator sp) const {
	assert(sp.isValid() && "finding invalid savepoint");
	assert(sp.Size <= stable_begin().Size && "finding savepoint after pop");
	return iterator(EndOfBuffer - sp.Size);
	}

	inline EHScopeStack::stable_iterator
	EHScopeStack::stabilize(iterator ir) const {
	assert(StartOfData <= ir.Ptr && ir.Ptr <= EndOfBuffer);
	return stable_iterator(EndOfBuffer - ir.Ptr);
	}

	inline EHScopeStack::stable_iterator
	EHScopeStack::getInnermostActiveNormalCleanup() const {
	for (EHScopeStack::stable_iterator
	I = getInnermostNormalCleanup(), E = stable_end(); I != E; ) {
	EHCleanupScope &S = cast<EHCleanupScope>(*find(I));
	if (S.isActive()) return I;
	I = S.getEnclosingNormalCleanup();
	}
	return stable_end();
	}

	inline EHScopeStack::stable_iterator
	EHScopeStack::getInnermostActiveEHCleanup() const {
	for (EHScopeStack::stable_iterator
	I = getInnermostEHCleanup(), E = stable_end(); I != E; ) {
	EHCleanupScope &S = cast<EHCleanupScope>(*find(I));
	if (S.isActive()) return I;
	I = S.getEnclosingEHCleanup();
	}
	return stable_end();
	}

	}
	}

	#endif