lib/Transforms/IPO/LowerSetJmp.cpp - llvm - Git at Google

 //===- LowerSetJmp.cpp - Code pertaining to lowering set/long jumps -------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file was developed by the LLVM research group and is distributed under
 // the University of Illinois Open Source License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 //  This file implements the lowering of setjmp and longjmp to use the
 //  LLVM invoke and unwind instructions as necessary.
 //
 //  Lowering of longjmp is fairly trivial. We replace the call with a
 //  call to the LLVM library function "__llvm_sjljeh_throw_longjmp()".
 //  This unwinds the stack for us calling all of the destructors for
 //  objects allocated on the stack.
 //
 //  At a setjmp call, the basic block is split and the setjmp removed.
 //  The calls in a function that have a setjmp are converted to invoke
 //  where the except part checks to see if it's a longjmp exception and,
 //  if so, if it's handled in the function. If it is, then it gets the
 //  value returned by the longjmp and goes to where the basic block was
 //  split. Invoke instructions are handled in a similar fashion with the
 //  original except block being executed if it isn't a longjmp except
 //  that is handled by that function.
 //
 //===----------------------------------------------------------------------===//

 //===----------------------------------------------------------------------===//
 // FIXME: This pass doesn't deal with PHI statements just yet. That is,
 // we expect this to occur before SSAification is done. This would seem
 // to make sense, but in general, it might be a good idea to make this
 // pass invokable via the "opt" command at will.
 //===----------------------------------------------------------------------===//

 #include "llvm/Transforms/IPO.h"
 #include "llvm/Constants.h"
 #include "llvm/DerivedTypes.h"
 #include "llvm/Instructions.h"
 #include "llvm/Intrinsics.h"
 #include "llvm/Module.h"
 #include "llvm/Pass.h"
 #include "llvm/Support/CFG.h"
 #include "llvm/Support/InstVisitor.h"
 #include "llvm/Transforms/Utils/Local.h"
 #include "llvm/ADT/DepthFirstIterator.h"
 #include "llvm/ADT/Statistic.h"
 #include "llvm/ADT/StringExtras.h"
 #include "llvm/ADT/VectorExtras.h"
 using namespace llvm;

 namespace {
   Statistic<> LongJmpsTransformed("lowersetjmp",
                                   "Number of longjmps transformed");
   Statistic<> SetJmpsTransformed("lowersetjmp",
                                  "Number of setjmps transformed");
   Statistic<> CallsTransformed("lowersetjmp",
                                "Number of calls invokified");
   Statistic<> InvokesTransformed("lowersetjmp",
                                  "Number of invokes modified");

   //===--------------------------------------------------------------------===//
   // LowerSetJmp pass implementation.
   class LowerSetJmp : public ModulePass,
                       public InstVisitor<LowerSetJmp> {
     // LLVM library functions...
     Function* InitSJMap;        // __llvm_sjljeh_init_setjmpmap
     Function* DestroySJMap;     // __llvm_sjljeh_destroy_setjmpmap
     Function* AddSJToMap;       // __llvm_sjljeh_add_setjmp_to_map
     Function* ThrowLongJmp;     // __llvm_sjljeh_throw_longjmp
     Function* TryCatchLJ;       // __llvm_sjljeh_try_catching_longjmp_exception
     Function* IsLJException;    // __llvm_sjljeh_is_longjmp_exception
     Function* GetLJValue;       // __llvm_sjljeh_get_longjmp_value

     typedef std::pair<SwitchInst*, CallInst*> SwitchValuePair;

     // Keep track of those basic blocks reachable via a depth-first search of
     // the CFG from a setjmp call. We only need to transform those "call" and
     // "invoke" instructions that are reachable from the setjmp call site.
     std::set<BasicBlock*> DFSBlocks;

     // The setjmp map is going to hold information about which setjmps
     // were called (each setjmp gets its own number) and with which
     // buffer it was called.
     std::map<Function*, AllocaInst*>            SJMap;

     // The rethrow basic block map holds the basic block to branch to if
     // the exception isn't handled in the current function and needs to
     // be rethrown.
     std::map<const Function*, BasicBlock*>      RethrowBBMap;

     // The preliminary basic block map holds a basic block that grabs the
     // exception and determines if it's handled by the current function.
     std::map<const Function*, BasicBlock*>      PrelimBBMap;

     // The switch/value map holds a switch inst/call inst pair. The
     // switch inst controls which handler (if any) gets called and the
     // value is the value returned to that handler by the call to
     // __llvm_sjljeh_get_longjmp_value.
     std::map<const Function*, SwitchValuePair>  SwitchValMap;

     // A map of which setjmps we've seen so far in a function.
     std::map<const Function*, unsigned>         SetJmpIDMap;

     AllocaInst*     GetSetJmpMap(Function* Func);
     BasicBlock*     GetRethrowBB(Function* Func);
     SwitchValuePair GetSJSwitch(Function* Func, BasicBlock* Rethrow);

     void TransformLongJmpCall(CallInst* Inst);
     void TransformSetJmpCall(CallInst* Inst);

     bool IsTransformableFunction(const std::string& Name);
   public:
     void visitCallInst(CallInst& CI);
     void visitInvokeInst(InvokeInst& II);
     void visitReturnInst(ReturnInst& RI);
     void visitUnwindInst(UnwindInst& UI);

     bool runOnModule(Module& M);
     bool doInitialization(Module& M);
   };

   RegisterOpt<LowerSetJmp> X("lowersetjmp", "Lower Set Jump");
 } // end anonymous namespace

 // run - Run the transformation on the program. We grab the function
 // prototypes for longjmp and setjmp. If they are used in the program,
 // then we can go directly to the places they're at and transform them.
 bool LowerSetJmp::runOnModule(Module& M) {
   bool Changed = false;

   // These are what the functions are called.
   Function* SetJmp = M.getNamedFunction("llvm.setjmp");
   Function* LongJmp = M.getNamedFunction("llvm.longjmp");

   // This program doesn't have longjmp and setjmp calls.
   if ((!LongJmp || LongJmp->use_empty()) &&
         (!SetJmp || SetJmp->use_empty())) return false;

   // Initialize some values and functions we'll need to transform the
   // setjmp/longjmp functions.
   doInitialization(M);

   if (SetJmp) {
     for (Value::use_iterator B = SetJmp->use_begin(), E = SetJmp->use_end();
          B != E; ++B) {
       BasicBlock* BB = cast<Instruction>(*B)->getParent();
       for (df_ext_iterator<BasicBlock*> I = df_ext_begin(BB, DFSBlocks),
              E = df_ext_end(BB, DFSBlocks); I != E; ++I)
         /* empty */;
     }

     while (!SetJmp->use_empty()) {
       assert(isa<CallInst>(SetJmp->use_back()) &&
              "User of setjmp intrinsic not a call?");
       TransformSetJmpCall(cast<CallInst>(SetJmp->use_back()));
       Changed = true;
     }
   }

   if (LongJmp)
     while (!LongJmp->use_empty()) {
       assert(isa<CallInst>(LongJmp->use_back()) &&
              "User of longjmp intrinsic not a call?");
       TransformLongJmpCall(cast<CallInst>(LongJmp->use_back()));
       Changed = true;
     }

   // Now go through the affected functions and convert calls and invokes
   // to new invokes...
   for (std::map<Function*, AllocaInst*>::iterator
       B = SJMap.begin(), E = SJMap.end(); B != E; ++B) {
     Function* F = B->first;
     for (Function::iterator BB = F->begin(), BE = F->end(); BB != BE; ++BB)
       for (BasicBlock::iterator IB = BB->begin(), IE = BB->end(); IB != IE; ) {
         visit(*IB++);
         if (IB != BB->end() && IB->getParent() != BB)
           break;  // The next instruction got moved to a different block!
       }
   }

   DFSBlocks.clear();
   SJMap.clear();
   RethrowBBMap.clear();
   PrelimBBMap.clear();
   SwitchValMap.clear();
   SetJmpIDMap.clear();

   return Changed;
 }

 // doInitialization - For the lower long/setjmp pass, this ensures that a
 // module contains a declaration for the intrisic functions we are going
 // to call to convert longjmp and setjmp calls.
 //
 // This function is always successful, unless it isn't.
 bool LowerSetJmp::doInitialization(Module& M)
 {
   const Type *SBPTy = PointerType::get(Type::SByteTy);
   const Type *SBPPTy = PointerType::get(SBPTy);

   // N.B. See llvm/runtime/GCCLibraries/libexception/SJLJ-Exception.h for
   // a description of the following library functions.

   // void __llvm_sjljeh_init_setjmpmap(void**)
   InitSJMap = M.getOrInsertFunction("__llvm_sjljeh_init_setjmpmap",
                                     Type::VoidTy, SBPPTy, (Type *)0);
   // void __llvm_sjljeh_destroy_setjmpmap(void**)
   DestroySJMap = M.getOrInsertFunction("__llvm_sjljeh_destroy_setjmpmap",
                                        Type::VoidTy, SBPPTy, (Type *)0);

   // void __llvm_sjljeh_add_setjmp_to_map(void**, void*, unsigned)
   AddSJToMap = M.getOrInsertFunction("__llvm_sjljeh_add_setjmp_to_map",
                                      Type::VoidTy, SBPPTy, SBPTy,
                                      Type::UIntTy, (Type *)0);

   // void __llvm_sjljeh_throw_longjmp(int*, int)
   ThrowLongJmp = M.getOrInsertFunction("__llvm_sjljeh_throw_longjmp",
                                        Type::VoidTy, SBPTy, Type::IntTy,
                                        (Type *)0);

   // unsigned __llvm_sjljeh_try_catching_longjmp_exception(void **)
   TryCatchLJ =
     M.getOrInsertFunction("__llvm_sjljeh_try_catching_longjmp_exception",
                           Type::UIntTy, SBPPTy, (Type *)0);

   // bool __llvm_sjljeh_is_longjmp_exception()
   IsLJException = M.getOrInsertFunction("__llvm_sjljeh_is_longjmp_exception",
                                         Type::BoolTy, (Type *)0);

   // int __llvm_sjljeh_get_longjmp_value()
   GetLJValue = M.getOrInsertFunction("__llvm_sjljeh_get_longjmp_value",
                                      Type::IntTy, (Type *)0);
   return true;
 }

 // IsTransformableFunction - Return true if the function name isn't one
 // of the ones we don't want transformed. Currently, don't transform any
 // "llvm.{setjmp,longjmp}" functions and none of the setjmp/longjmp error
 // handling functions (beginning with __llvm_sjljeh_...they don't throw
 // exceptions).
 bool LowerSetJmp::IsTransformableFunction(const std::string& Name) {
   std::string SJLJEh("__llvm_sjljeh");

   if (Name.size() > SJLJEh.size())
     return std::string(Name.begin(), Name.begin() + SJLJEh.size()) != SJLJEh;

   return true;
 }

 // TransformLongJmpCall - Transform a longjmp call into a call to the
 // internal __llvm_sjljeh_throw_longjmp function. It then takes care of
 // throwing the exception for us.
 void LowerSetJmp::TransformLongJmpCall(CallInst* Inst)
 {
   const Type* SBPTy = PointerType::get(Type::SByteTy);

   // Create the call to "__llvm_sjljeh_throw_longjmp". This takes the
   // same parameters as "longjmp", except that the buffer is cast to a
   // char*. It returns "void", so it doesn't need to replace any of
   // Inst's uses and doesn't get a name.
   CastInst* CI = new CastInst(Inst->getOperand(1), SBPTy, "LJBuf", Inst);
   new CallInst(ThrowLongJmp, make_vector<Value*>(CI, Inst->getOperand(2), 0),
                "", Inst);

   SwitchValuePair& SVP = SwitchValMap[Inst->getParent()->getParent()];

   // If the function has a setjmp call in it (they are transformed first)
   // we should branch to the basic block that determines if this longjmp
   // is applicable here. Otherwise, issue an unwind.
   if (SVP.first)
     new BranchInst(SVP.first->getParent(), Inst);
   else
     new UnwindInst(Inst);

   // Remove all insts after the branch/unwind inst.  Go from back to front to
   // avoid replaceAllUsesWith if possible.
   BasicBlock *BB = Inst->getParent();
   Instruction *Removed;
   do {
     Removed = &BB->back();
     // If the removed instructions have any users, replace them now.
     if (!Removed->use_empty())
       Removed->replaceAllUsesWith(UndefValue::get(Removed->getType()));
     Removed->eraseFromParent();
   } while (Removed != Inst);

   ++LongJmpsTransformed;
 }

 // GetSetJmpMap - Retrieve (create and initialize, if necessary) the
 // setjmp map. This map is going to hold information about which setjmps
 // were called (each setjmp gets its own number) and with which buffer it
 // was called. There can be only one!
 AllocaInst* LowerSetJmp::GetSetJmpMap(Function* Func)
 {
   if (SJMap[Func]) return SJMap[Func];

   // Insert the setjmp map initialization before the first instruction in
   // the function.
   Instruction* Inst = Func->getEntryBlock().begin();
   assert(Inst && "Couldn't find even ONE instruction in entry block!");

   // Fill in the alloca and call to initialize the SJ map.
   const Type *SBPTy = PointerType::get(Type::SByteTy);
   AllocaInst* Map = new AllocaInst(SBPTy, 0, "SJMap", Inst);
   new CallInst(InitSJMap, make_vector<Value*>(Map, 0), "", Inst);
   return SJMap[Func] = Map;
 }

 // GetRethrowBB - Only one rethrow basic block is needed per function.
 // If this is a longjmp exception but not handled in this block, this BB
 // performs the rethrow.
 BasicBlock* LowerSetJmp::GetRethrowBB(Function* Func)
 {
   if (RethrowBBMap[Func]) return RethrowBBMap[Func];

   // The basic block we're going to jump to if we need to rethrow the
   // exception.
   BasicBlock* Rethrow = new BasicBlock("RethrowExcept", Func);

   // Fill in the "Rethrow" BB with a call to rethrow the exception. This
   // is the last instruction in the BB since at this point the runtime
   // should exit this function and go to the next function.
   new UnwindInst(Rethrow);
   return RethrowBBMap[Func] = Rethrow;
 }

 // GetSJSwitch - Return the switch statement that controls which handler
 // (if any) gets called and the value returned to that handler.
 LowerSetJmp::SwitchValuePair LowerSetJmp::GetSJSwitch(Function* Func,
                                                       BasicBlock* Rethrow)
 {
   if (SwitchValMap[Func].first) return SwitchValMap[Func];

   BasicBlock* LongJmpPre = new BasicBlock("LongJmpBlkPre", Func);
   BasicBlock::InstListType& LongJmpPreIL = LongJmpPre->getInstList();

   // Keep track of the preliminary basic block for some of the other
   // transformations.
   PrelimBBMap[Func] = LongJmpPre;

   // Grab the exception.
   CallInst* Cond = new
     CallInst(IsLJException, std::vector<Value*>(), "IsLJExcept");
   LongJmpPreIL.push_back(Cond);

   // The "decision basic block" gets the number associated with the
   // setjmp call returning to switch on and the value returned by
   // longjmp.
   BasicBlock* DecisionBB = new BasicBlock("LJDecisionBB", Func);
   BasicBlock::InstListType& DecisionBBIL = DecisionBB->getInstList();

   new BranchInst(DecisionBB, Rethrow, Cond, LongJmpPre);

   // Fill in the "decision" basic block.
   CallInst* LJVal = new CallInst(GetLJValue, std::vector<Value*>(), "LJVal");
   DecisionBBIL.push_back(LJVal);
   CallInst* SJNum = new
     CallInst(TryCatchLJ, make_vector<Value*>(GetSetJmpMap(Func), 0), "SJNum");
   DecisionBBIL.push_back(SJNum);

   SwitchInst* SI = new SwitchInst(SJNum, Rethrow, 0, DecisionBB);
   return SwitchValMap[Func] = SwitchValuePair(SI, LJVal);
 }

 // TransformSetJmpCall - The setjmp call is a bit trickier to transform.
 // We're going to convert all setjmp calls to nops. Then all "call" and
 // "invoke" instructions in the function are converted to "invoke" where
 // the "except" branch is used when returning from a longjmp call.
 void LowerSetJmp::TransformSetJmpCall(CallInst* Inst)
 {
   BasicBlock* ABlock = Inst->getParent();
   Function* Func = ABlock->getParent();

   // Add this setjmp to the setjmp map.
   const Type* SBPTy = PointerType::get(Type::SByteTy);
   CastInst* BufPtr = new CastInst(Inst->getOperand(1), SBPTy, "SBJmpBuf", Inst);
   new CallInst(AddSJToMap,
                make_vector<Value*>(GetSetJmpMap(Func), BufPtr,
                                    ConstantUInt::get(Type::UIntTy,
                                                      SetJmpIDMap[Func]++), 0),
                "", Inst);

   // We are guaranteed that there are no values live across basic blocks
   // (because we are "not in SSA form" yet), but there can still be values live
   // in basic blocks.  Because of this, splitting the setjmp block can cause
   // values above the setjmp to not dominate uses which are after the setjmp
   // call.  For all of these occasions, we must spill the value to the stack.
   //
   std::set<Instruction*> InstrsAfterCall;

   // The call is probably very close to the end of the basic block, for the
   // common usage pattern of: 'if (setjmp(...))', so keep track of the
   // instructions after the call.
   for (BasicBlock::iterator I = ++BasicBlock::iterator(Inst), E = ABlock->end();
        I != E; ++I)
     InstrsAfterCall.insert(I);

   for (BasicBlock::iterator II = ABlock->begin();
        II != BasicBlock::iterator(Inst); ++II)
     // Loop over all of the uses of instruction.  If any of them are after the
     // call, "spill" the value to the stack.
     for (Value::use_iterator UI = II->use_begin(), E = II->use_end();
          UI != E; ++UI)
       if (cast<Instruction>(*UI)->getParent() != ABlock ||
           InstrsAfterCall.count(cast<Instruction>(*UI))) {
         DemoteRegToStack(*II);
         break;
       }
   InstrsAfterCall.clear();

   // Change the setjmp call into a branch statement. We'll remove the
   // setjmp call in a little bit. No worries.
   BasicBlock* SetJmpContBlock = ABlock->splitBasicBlock(Inst);
   assert(SetJmpContBlock && "Couldn't split setjmp BB!!");

   SetJmpContBlock->setName(ABlock->getName()+"SetJmpCont");

   // Add the SetJmpContBlock to the set of blocks reachable from a setjmp.
   DFSBlocks.insert(SetJmpContBlock);

   // This PHI node will be in the new block created from the
   // splitBasicBlock call.
   PHINode* PHI = new PHINode(Type::IntTy, "SetJmpReturn", Inst);

   // Coming from a call to setjmp, the return is 0.
   PHI->addIncoming(ConstantInt::getNullValue(Type::IntTy), ABlock);

   // Add the case for this setjmp's number...
   SwitchValuePair SVP = GetSJSwitch(Func, GetRethrowBB(Func));
   SVP.first->addCase(ConstantUInt::get(Type::UIntTy, SetJmpIDMap[Func] - 1),
                      SetJmpContBlock);

   // Value coming from the handling of the exception.
   PHI->addIncoming(SVP.second, SVP.second->getParent());

   // Replace all uses of this instruction with the PHI node created by
   // the eradication of setjmp.
   Inst->replaceAllUsesWith(PHI);
   Inst->getParent()->getInstList().erase(Inst);

   ++SetJmpsTransformed;
 }

 // visitCallInst - This converts all LLVM call instructions into invoke
 // instructions. The except part of the invoke goes to the "LongJmpBlkPre"
 // that grabs the exception and proceeds to determine if it's a longjmp
 // exception or not.
 void LowerSetJmp::visitCallInst(CallInst& CI)
 {
   if (CI.getCalledFunction())
     if (!IsTransformableFunction(CI.getCalledFunction()->getName()) ||
         CI.getCalledFunction()->isIntrinsic()) return;

   BasicBlock* OldBB = CI.getParent();

   // If not reachable from a setjmp call, don't transform.
   if (!DFSBlocks.count(OldBB)) return;

   BasicBlock* NewBB = OldBB->splitBasicBlock(CI);
   assert(NewBB && "Couldn't split BB of \"call\" instruction!!");
   DFSBlocks.insert(NewBB);
   NewBB->setName("Call2Invoke");

   Function* Func = OldBB->getParent();

   // Construct the new "invoke" instruction.
   TerminatorInst* Term = OldBB->getTerminator();
   std::vector<Value*> Params(CI.op_begin() + 1, CI.op_end());
   InvokeInst* II = new
     InvokeInst(CI.getCalledValue(), NewBB, PrelimBBMap[Func],
                Params, CI.getName(), Term);

   // Replace the old call inst with the invoke inst and remove the call.
   CI.replaceAllUsesWith(II);
   CI.getParent()->getInstList().erase(&CI);

   // The old terminator is useless now that we have the invoke inst.
   Term->getParent()->getInstList().erase(Term);
   ++CallsTransformed;
 }

 // visitInvokeInst - Converting the "invoke" instruction is fairly
 // straight-forward. The old exception part is replaced by a query asking
 // if this is a longjmp exception. If it is, then it goes to the longjmp
 // exception blocks. Otherwise, control is passed the old exception.
 void LowerSetJmp::visitInvokeInst(InvokeInst& II)
 {
   if (II.getCalledFunction())
     if (!IsTransformableFunction(II.getCalledFunction()->getName()) ||
         II.getCalledFunction()->isIntrinsic()) return;

   BasicBlock* BB = II.getParent();

   // If not reachable from a setjmp call, don't transform.
   if (!DFSBlocks.count(BB)) return;

   BasicBlock* NormalBB = II.getNormalDest();
   BasicBlock* ExceptBB = II.getUnwindDest();

   Function* Func = BB->getParent();
   BasicBlock* NewExceptBB = new BasicBlock("InvokeExcept", Func);
   BasicBlock::InstListType& InstList = NewExceptBB->getInstList();

   // If this is a longjmp exception, then branch to the preliminary BB of
   // the longjmp exception handling. Otherwise, go to the old exception.
   CallInst* IsLJExcept = new
     CallInst(IsLJException, std::vector<Value*>(), "IsLJExcept");
   InstList.push_back(IsLJExcept);

   new BranchInst(PrelimBBMap[Func], ExceptBB, IsLJExcept, NewExceptBB);

   II.setUnwindDest(NewExceptBB);
   ++InvokesTransformed;
 }

 // visitReturnInst - We want to destroy the setjmp map upon exit from the
 // function.
 void LowerSetJmp::visitReturnInst(ReturnInst &RI) {
   Function* Func = RI.getParent()->getParent();
   new CallInst(DestroySJMap, make_vector<Value*>(GetSetJmpMap(Func), 0),
                "", &RI);
 }

 // visitUnwindInst - We want to destroy the setjmp map upon exit from the
 // function.
 void LowerSetJmp::visitUnwindInst(UnwindInst &UI) {
   Function* Func = UI.getParent()->getParent();
   new CallInst(DestroySJMap, make_vector<Value*>(GetSetJmpMap(Func), 0),
                "", &UI);
 }

 ModulePass *llvm::createLowerSetJmpPass() {
   return new LowerSetJmp();
 }
	//===- LowerSetJmp.cpp - Code pertaining to lowering set/long jumps -------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file was developed by the LLVM research group and is distributed under
	// the University of Illinois Open Source License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements the lowering of setjmp and longjmp to use the
	// LLVM invoke and unwind instructions as necessary.
	//
	// Lowering of longjmp is fairly trivial. We replace the call with a
	// call to the LLVM library function "__llvm_sjljeh_throw_longjmp()".
	// This unwinds the stack for us calling all of the destructors for
	// objects allocated on the stack.
	//
	// At a setjmp call, the basic block is split and the setjmp removed.
	// The calls in a function that have a setjmp are converted to invoke
	// where the except part checks to see if it's a longjmp exception and,
	// if so, if it's handled in the function. If it is, then it gets the
	// value returned by the longjmp and goes to where the basic block was
	// split. Invoke instructions are handled in a similar fashion with the
	// original except block being executed if it isn't a longjmp except
	// that is handled by that function.
	//
	//===----------------------------------------------------------------------===//

	//===----------------------------------------------------------------------===//
	// FIXME: This pass doesn't deal with PHI statements just yet. That is,
	// we expect this to occur before SSAification is done. This would seem
	// to make sense, but in general, it might be a good idea to make this
	// pass invokable via the "opt" command at will.
	//===----------------------------------------------------------------------===//

	#include "llvm/Transforms/IPO.h"
	#include "llvm/Constants.h"
	#include "llvm/DerivedTypes.h"
	#include "llvm/Instructions.h"
	#include "llvm/Intrinsics.h"
	#include "llvm/Module.h"
	#include "llvm/Pass.h"
	#include "llvm/Support/CFG.h"
	#include "llvm/Support/InstVisitor.h"
	#include "llvm/Transforms/Utils/Local.h"
	#include "llvm/ADT/DepthFirstIterator.h"
	#include "llvm/ADT/Statistic.h"
	#include "llvm/ADT/StringExtras.h"
	#include "llvm/ADT/VectorExtras.h"
	using namespace llvm;

	namespace {
	Statistic<> LongJmpsTransformed("lowersetjmp",
	"Number of longjmps transformed");
	Statistic<> SetJmpsTransformed("lowersetjmp",
	"Number of setjmps transformed");
	Statistic<> CallsTransformed("lowersetjmp",
	"Number of calls invokified");
	Statistic<> InvokesTransformed("lowersetjmp",
	"Number of invokes modified");

	//===--------------------------------------------------------------------===//
	// LowerSetJmp pass implementation.
	class LowerSetJmp : public ModulePass,
	public InstVisitor<LowerSetJmp> {
	// LLVM library functions...
	Function* InitSJMap; // __llvm_sjljeh_init_setjmpmap
	Function* DestroySJMap; // __llvm_sjljeh_destroy_setjmpmap
	Function* AddSJToMap; // __llvm_sjljeh_add_setjmp_to_map
	Function* ThrowLongJmp; // __llvm_sjljeh_throw_longjmp
	Function* TryCatchLJ; // __llvm_sjljeh_try_catching_longjmp_exception
	Function* IsLJException; // __llvm_sjljeh_is_longjmp_exception
	Function* GetLJValue; // __llvm_sjljeh_get_longjmp_value

	typedef std::pair<SwitchInst, CallInst> SwitchValuePair;

	// Keep track of those basic blocks reachable via a depth-first search of
	// the CFG from a setjmp call. We only need to transform those "call" and
	// "invoke" instructions that are reachable from the setjmp call site.
	std::set<BasicBlock*> DFSBlocks;

	// The setjmp map is going to hold information about which setjmps
	// were called (each setjmp gets its own number) and with which
	// buffer it was called.
	std::map<Function, AllocaInst> SJMap;

	// The rethrow basic block map holds the basic block to branch to if
	// the exception isn't handled in the current function and needs to
	// be rethrown.
	std::map<const Function, BasicBlock> RethrowBBMap;

	// The preliminary basic block map holds a basic block that grabs the
	// exception and determines if it's handled by the current function.
	std::map<const Function, BasicBlock> PrelimBBMap;

	// The switch/value map holds a switch inst/call inst pair. The
	// switch inst controls which handler (if any) gets called and the
	// value is the value returned to that handler by the call to
	// __llvm_sjljeh_get_longjmp_value.
	std::map<const Function*, SwitchValuePair> SwitchValMap;

	// A map of which setjmps we've seen so far in a function.
	std::map<const Function*, unsigned> SetJmpIDMap;

	AllocaInst* GetSetJmpMap(Function* Func);
	BasicBlock* GetRethrowBB(Function* Func);
	SwitchValuePair GetSJSwitch(Function* Func, BasicBlock* Rethrow);

	void TransformLongJmpCall(CallInst* Inst);
	void TransformSetJmpCall(CallInst* Inst);

	bool IsTransformableFunction(const std::string& Name);
	public:
	void visitCallInst(CallInst& CI);
	void visitInvokeInst(InvokeInst& II);
	void visitReturnInst(ReturnInst& RI);
	void visitUnwindInst(UnwindInst& UI);

	bool runOnModule(Module& M);
	bool doInitialization(Module& M);
	};

	RegisterOpt<LowerSetJmp> X("lowersetjmp", "Lower Set Jump");
	} // end anonymous namespace

	// run - Run the transformation on the program. We grab the function
	// prototypes for longjmp and setjmp. If they are used in the program,
	// then we can go directly to the places they're at and transform them.
	bool LowerSetJmp::runOnModule(Module& M) {
	bool Changed = false;

	// These are what the functions are called.
	Function* SetJmp = M.getNamedFunction("llvm.setjmp");
	Function* LongJmp = M.getNamedFunction("llvm.longjmp");

	// This program doesn't have longjmp and setjmp calls.
	if ((!LongJmp \|\| LongJmp->use_empty()) &&
	(!SetJmp \|\| SetJmp->use_empty())) return false;

	// Initialize some values and functions we'll need to transform the
	// setjmp/longjmp functions.
	doInitialization(M);

	if (SetJmp) {
	for (Value::use_iterator B = SetJmp->use_begin(), E = SetJmp->use_end();
	B != E; ++B) {
	BasicBlock* BB = cast<Instruction>(*B)->getParent();
	for (df_ext_iterator<BasicBlock*> I = df_ext_begin(BB, DFSBlocks),
	E = df_ext_end(BB, DFSBlocks); I != E; ++I)
	/* empty */;
	}

	while (!SetJmp->use_empty()) {
	assert(isa<CallInst>(SetJmp->use_back()) &&
	"User of setjmp intrinsic not a call?");
	TransformSetJmpCall(cast<CallInst>(SetJmp->use_back()));
	Changed = true;
	}
	}

	if (LongJmp)
	while (!LongJmp->use_empty()) {
	assert(isa<CallInst>(LongJmp->use_back()) &&
	"User of longjmp intrinsic not a call?");
	TransformLongJmpCall(cast<CallInst>(LongJmp->use_back()));
	Changed = true;
	}

	// Now go through the affected functions and convert calls and invokes
	// to new invokes...
	for (std::map<Function, AllocaInst>::iterator
	B = SJMap.begin(), E = SJMap.end(); B != E; ++B) {
	Function* F = B->first;
	for (Function::iterator BB = F->begin(), BE = F->end(); BB != BE; ++BB)
	for (BasicBlock::iterator IB = BB->begin(), IE = BB->end(); IB != IE; ) {
	visit(*IB++);
	if (IB != BB->end() && IB->getParent() != BB)
	break; // The next instruction got moved to a different block!
	}
	}

	DFSBlocks.clear();
	SJMap.clear();
	RethrowBBMap.clear();
	PrelimBBMap.clear();
	SwitchValMap.clear();
	SetJmpIDMap.clear();

	return Changed;
	}

	// doInitialization - For the lower long/setjmp pass, this ensures that a
	// module contains a declaration for the intrisic functions we are going
	// to call to convert longjmp and setjmp calls.
	//
	// This function is always successful, unless it isn't.
	bool LowerSetJmp::doInitialization(Module& M)
	{
	const Type *SBPTy = PointerType::get(Type::SByteTy);
	const Type *SBPPTy = PointerType::get(SBPTy);

	// N.B. See llvm/runtime/GCCLibraries/libexception/SJLJ-Exception.h for
	// a description of the following library functions.

	// void __llvm_sjljeh_init_setjmpmap(void**)
	InitSJMap = M.getOrInsertFunction("__llvm_sjljeh_init_setjmpmap",
	Type::VoidTy, SBPPTy, (Type *)0);
	// void __llvm_sjljeh_destroy_setjmpmap(void**)
	DestroySJMap = M.getOrInsertFunction("__llvm_sjljeh_destroy_setjmpmap",
	Type::VoidTy, SBPPTy, (Type *)0);

	// void __llvm_sjljeh_add_setjmp_to_map(void*, void, unsigned)
	AddSJToMap = M.getOrInsertFunction("__llvm_sjljeh_add_setjmp_to_map",
	Type::VoidTy, SBPPTy, SBPTy,
	Type::UIntTy, (Type *)0);

	// void __llvm_sjljeh_throw_longjmp(int*, int)
	ThrowLongJmp = M.getOrInsertFunction("__llvm_sjljeh_throw_longjmp",
	Type::VoidTy, SBPTy, Type::IntTy,
	(Type *)0);

	// unsigned __llvm_sjljeh_try_catching_longjmp_exception(void **)
	TryCatchLJ =
	M.getOrInsertFunction("__llvm_sjljeh_try_catching_longjmp_exception",
	Type::UIntTy, SBPPTy, (Type *)0);

	// bool __llvm_sjljeh_is_longjmp_exception()
	IsLJException = M.getOrInsertFunction("__llvm_sjljeh_is_longjmp_exception",
	Type::BoolTy, (Type *)0);

	// int __llvm_sjljeh_get_longjmp_value()
	GetLJValue = M.getOrInsertFunction("__llvm_sjljeh_get_longjmp_value",
	Type::IntTy, (Type *)0);
	return true;
	}

	// IsTransformableFunction - Return true if the function name isn't one
	// of the ones we don't want transformed. Currently, don't transform any
	// "llvm.{setjmp,longjmp}" functions and none of the setjmp/longjmp error
	// handling functions (beginning with __llvm_sjljeh_...they don't throw
	// exceptions).
	bool LowerSetJmp::IsTransformableFunction(const std::string& Name) {
	std::string SJLJEh("__llvm_sjljeh");

	if (Name.size() > SJLJEh.size())
	return std::string(Name.begin(), Name.begin() + SJLJEh.size()) != SJLJEh;

	return true;
	}

	// TransformLongJmpCall - Transform a longjmp call into a call to the
	// internal __llvm_sjljeh_throw_longjmp function. It then takes care of
	// throwing the exception for us.
	void LowerSetJmp::TransformLongJmpCall(CallInst* Inst)
	{
	const Type* SBPTy = PointerType::get(Type::SByteTy);

	// Create the call to "__llvm_sjljeh_throw_longjmp". This takes the
	// same parameters as "longjmp", except that the buffer is cast to a
	// char*. It returns "void", so it doesn't need to replace any of
	// Inst's uses and doesn't get a name.
	CastInst* CI = new CastInst(Inst->getOperand(1), SBPTy, "LJBuf", Inst);
	new CallInst(ThrowLongJmp, make_vector<Value*>(CI, Inst->getOperand(2), 0),
	"", Inst);

	SwitchValuePair& SVP = SwitchValMap[Inst->getParent()->getParent()];

	// If the function has a setjmp call in it (they are transformed first)
	// we should branch to the basic block that determines if this longjmp
	// is applicable here. Otherwise, issue an unwind.
	if (SVP.first)
	new BranchInst(SVP.first->getParent(), Inst);
	else
	new UnwindInst(Inst);

	// Remove all insts after the branch/unwind inst. Go from back to front to
	// avoid replaceAllUsesWith if possible.
	BasicBlock *BB = Inst->getParent();
	Instruction *Removed;
	do {
	Removed = &BB->back();
	// If the removed instructions have any users, replace them now.
	if (!Removed->use_empty())
	Removed->replaceAllUsesWith(UndefValue::get(Removed->getType()));
	Removed->eraseFromParent();
	} while (Removed != Inst);

	++LongJmpsTransformed;
	}

	// GetSetJmpMap - Retrieve (create and initialize, if necessary) the
	// setjmp map. This map is going to hold information about which setjmps
	// were called (each setjmp gets its own number) and with which buffer it
	// was called. There can be only one!
	AllocaInst* LowerSetJmp::GetSetJmpMap(Function* Func)
	{
	if (SJMap[Func]) return SJMap[Func];

	// Insert the setjmp map initialization before the first instruction in
	// the function.
	Instruction* Inst = Func->getEntryBlock().begin();
	assert(Inst && "Couldn't find even ONE instruction in entry block!");

	// Fill in the alloca and call to initialize the SJ map.
	const Type *SBPTy = PointerType::get(Type::SByteTy);
	AllocaInst* Map = new AllocaInst(SBPTy, 0, "SJMap", Inst);
	new CallInst(InitSJMap, make_vector<Value*>(Map, 0), "", Inst);
	return SJMap[Func] = Map;
	}

	// GetRethrowBB - Only one rethrow basic block is needed per function.
	// If this is a longjmp exception but not handled in this block, this BB
	// performs the rethrow.
	BasicBlock* LowerSetJmp::GetRethrowBB(Function* Func)
	{
	if (RethrowBBMap[Func]) return RethrowBBMap[Func];

	// The basic block we're going to jump to if we need to rethrow the
	// exception.
	BasicBlock* Rethrow = new BasicBlock("RethrowExcept", Func);

	// Fill in the "Rethrow" BB with a call to rethrow the exception. This
	// is the last instruction in the BB since at this point the runtime
	// should exit this function and go to the next function.
	new UnwindInst(Rethrow);
	return RethrowBBMap[Func] = Rethrow;
	}

	// GetSJSwitch - Return the switch statement that controls which handler
	// (if any) gets called and the value returned to that handler.
	LowerSetJmp::SwitchValuePair LowerSetJmp::GetSJSwitch(Function* Func,
	BasicBlock* Rethrow)
	{
	if (SwitchValMap[Func].first) return SwitchValMap[Func];

	BasicBlock* LongJmpPre = new BasicBlock("LongJmpBlkPre", Func);
	BasicBlock::InstListType& LongJmpPreIL = LongJmpPre->getInstList();

	// Keep track of the preliminary basic block for some of the other
	// transformations.
	PrelimBBMap[Func] = LongJmpPre;

	// Grab the exception.
	CallInst* Cond = new
	CallInst(IsLJException, std::vector<Value*>(), "IsLJExcept");
	LongJmpPreIL.push_back(Cond);

	// The "decision basic block" gets the number associated with the
	// setjmp call returning to switch on and the value returned by
	// longjmp.
	BasicBlock* DecisionBB = new BasicBlock("LJDecisionBB", Func);
	BasicBlock::InstListType& DecisionBBIL = DecisionBB->getInstList();

	new BranchInst(DecisionBB, Rethrow, Cond, LongJmpPre);

	// Fill in the "decision" basic block.
	CallInst* LJVal = new CallInst(GetLJValue, std::vector<Value*>(), "LJVal");
	DecisionBBIL.push_back(LJVal);
	CallInst* SJNum = new
	CallInst(TryCatchLJ, make_vector<Value*>(GetSetJmpMap(Func), 0), "SJNum");
	DecisionBBIL.push_back(SJNum);

	SwitchInst* SI = new SwitchInst(SJNum, Rethrow, 0, DecisionBB);
	return SwitchValMap[Func] = SwitchValuePair(SI, LJVal);
	}

	// TransformSetJmpCall - The setjmp call is a bit trickier to transform.
	// We're going to convert all setjmp calls to nops. Then all "call" and
	// "invoke" instructions in the function are converted to "invoke" where
	// the "except" branch is used when returning from a longjmp call.
	void LowerSetJmp::TransformSetJmpCall(CallInst* Inst)
	{
	BasicBlock* ABlock = Inst->getParent();
	Function* Func = ABlock->getParent();

	// Add this setjmp to the setjmp map.
	const Type* SBPTy = PointerType::get(Type::SByteTy);
	CastInst* BufPtr = new CastInst(Inst->getOperand(1), SBPTy, "SBJmpBuf", Inst);
	new CallInst(AddSJToMap,
	make_vector<Value*>(GetSetJmpMap(Func), BufPtr,
	ConstantUInt::get(Type::UIntTy,
	SetJmpIDMap[Func]++), 0),
	"", Inst);

	// We are guaranteed that there are no values live across basic blocks
	// (because we are "not in SSA form" yet), but there can still be values live
	// in basic blocks. Because of this, splitting the setjmp block can cause
	// values above the setjmp to not dominate uses which are after the setjmp
	// call. For all of these occasions, we must spill the value to the stack.
	//
	std::set<Instruction*> InstrsAfterCall;

	// The call is probably very close to the end of the basic block, for the
	// common usage pattern of: 'if (setjmp(...))', so keep track of the
	// instructions after the call.
	for (BasicBlock::iterator I = ++BasicBlock::iterator(Inst), E = ABlock->end();
	I != E; ++I)
	InstrsAfterCall.insert(I);

	for (BasicBlock::iterator II = ABlock->begin();
	II != BasicBlock::iterator(Inst); ++II)
	// Loop over all of the uses of instruction. If any of them are after the
	// call, "spill" the value to the stack.
	for (Value::use_iterator UI = II->use_begin(), E = II->use_end();
	UI != E; ++UI)
	if (cast<Instruction>(*UI)->getParent() != ABlock \|\|
	InstrsAfterCall.count(cast<Instruction>(*UI))) {
	DemoteRegToStack(*II);
	break;
	}
	InstrsAfterCall.clear();

	// Change the setjmp call into a branch statement. We'll remove the
	// setjmp call in a little bit. No worries.
	BasicBlock* SetJmpContBlock = ABlock->splitBasicBlock(Inst);
	assert(SetJmpContBlock && "Couldn't split setjmp BB!!");

	SetJmpContBlock->setName(ABlock->getName()+"SetJmpCont");

	// Add the SetJmpContBlock to the set of blocks reachable from a setjmp.
	DFSBlocks.insert(SetJmpContBlock);

	// This PHI node will be in the new block created from the
	// splitBasicBlock call.
	PHINode* PHI = new PHINode(Type::IntTy, "SetJmpReturn", Inst);

	// Coming from a call to setjmp, the return is 0.
	PHI->addIncoming(ConstantInt::getNullValue(Type::IntTy), ABlock);

	// Add the case for this setjmp's number...
	SwitchValuePair SVP = GetSJSwitch(Func, GetRethrowBB(Func));
	SVP.first->addCase(ConstantUInt::get(Type::UIntTy, SetJmpIDMap[Func] - 1),
	SetJmpContBlock);

	// Value coming from the handling of the exception.
	PHI->addIncoming(SVP.second, SVP.second->getParent());

	// Replace all uses of this instruction with the PHI node created by
	// the eradication of setjmp.
	Inst->replaceAllUsesWith(PHI);
	Inst->getParent()->getInstList().erase(Inst);

	++SetJmpsTransformed;
	}

	// visitCallInst - This converts all LLVM call instructions into invoke
	// instructions. The except part of the invoke goes to the "LongJmpBlkPre"
	// that grabs the exception and proceeds to determine if it's a longjmp
	// exception or not.
	void LowerSetJmp::visitCallInst(CallInst& CI)
	{
	if (CI.getCalledFunction())
	if (!IsTransformableFunction(CI.getCalledFunction()->getName()) \|\|
	CI.getCalledFunction()->isIntrinsic()) return;

	BasicBlock* OldBB = CI.getParent();

	// If not reachable from a setjmp call, don't transform.
	if (!DFSBlocks.count(OldBB)) return;

	BasicBlock* NewBB = OldBB->splitBasicBlock(CI);
	assert(NewBB && "Couldn't split BB of \"call\" instruction!!");
	DFSBlocks.insert(NewBB);
	NewBB->setName("Call2Invoke");

	Function* Func = OldBB->getParent();

	// Construct the new "invoke" instruction.
	TerminatorInst* Term = OldBB->getTerminator();
	std::vector<Value*> Params(CI.op_begin() + 1, CI.op_end());
	InvokeInst* II = new
	InvokeInst(CI.getCalledValue(), NewBB, PrelimBBMap[Func],
	Params, CI.getName(), Term);

	// Replace the old call inst with the invoke inst and remove the call.
	CI.replaceAllUsesWith(II);
	CI.getParent()->getInstList().erase(&CI);

	// The old terminator is useless now that we have the invoke inst.
	Term->getParent()->getInstList().erase(Term);
	++CallsTransformed;
	}

	// visitInvokeInst - Converting the "invoke" instruction is fairly
	// straight-forward. The old exception part is replaced by a query asking
	// if this is a longjmp exception. If it is, then it goes to the longjmp
	// exception blocks. Otherwise, control is passed the old exception.
	void LowerSetJmp::visitInvokeInst(InvokeInst& II)
	{
	if (II.getCalledFunction())
	if (!IsTransformableFunction(II.getCalledFunction()->getName()) \|\|
	II.getCalledFunction()->isIntrinsic()) return;

	BasicBlock* BB = II.getParent();

	// If not reachable from a setjmp call, don't transform.
	if (!DFSBlocks.count(BB)) return;

	BasicBlock* NormalBB = II.getNormalDest();
	BasicBlock* ExceptBB = II.getUnwindDest();

	Function* Func = BB->getParent();
	BasicBlock* NewExceptBB = new BasicBlock("InvokeExcept", Func);
	BasicBlock::InstListType& InstList = NewExceptBB->getInstList();

	// If this is a longjmp exception, then branch to the preliminary BB of
	// the longjmp exception handling. Otherwise, go to the old exception.
	CallInst* IsLJExcept = new
	CallInst(IsLJException, std::vector<Value*>(), "IsLJExcept");
	InstList.push_back(IsLJExcept);

	new BranchInst(PrelimBBMap[Func], ExceptBB, IsLJExcept, NewExceptBB);

	II.setUnwindDest(NewExceptBB);
	++InvokesTransformed;
	}

	// visitReturnInst - We want to destroy the setjmp map upon exit from the
	// function.
	void LowerSetJmp::visitReturnInst(ReturnInst &RI) {
	Function* Func = RI.getParent()->getParent();
	new CallInst(DestroySJMap, make_vector<Value*>(GetSetJmpMap(Func), 0),
	"", &RI);
	}

	// visitUnwindInst - We want to destroy the setjmp map upon exit from the
	// function.
	void LowerSetJmp::visitUnwindInst(UnwindInst &UI) {
	Function* Func = UI.getParent()->getParent();
	new CallInst(DestroySJMap, make_vector<Value*>(GetSetJmpMap(Func), 0),
	"", &UI);
	}

	ModulePass *llvm::createLowerSetJmpPass() {
	return new LowerSetJmp();
	}