lib/Transforms/Utils/IntegerDivision.cpp - platform/external/llvm - Gitiles

 //===-- IntegerDivision.cpp - Expand integer division ---------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file contains an implementation of 32bit scalar integer division for
 // targets that don't have native support. It's largely derived from
 // compiler-rt's implementation of __udivsi3, but hand-tuned to reduce the
 // amount of control flow
 //
 //===----------------------------------------------------------------------===//

 #define DEBUG_TYPE "integer-division"
 #include "llvm/Function.h"
 #include "llvm/Instructions.h"
 #include "llvm/Intrinsics.h"
 #include "llvm/IRBuilder.h"
 #include "llvm/Transforms/Utils/IntegerDivision.h"

 using namespace llvm;

 // Generate code to divide two signed integers. Returns the quotient, rounded
 // towards 0. Builder's insert point should be pointing at the sdiv
 // instruction. This will generate a udiv in the process, and Builder's insert
 // point will be pointing at the udiv (if present, i.e. not folded), ready to be
 // expanded if the user wishes.
 static Value* GenerateSignedDivisionCode(Value* Dividend, Value* Divisor,
                                          IRBuilder<>& Builder) {
   // Implementation taken from compiler-rt's __divsi3

   ConstantInt* ThirtyOne = Builder.getInt32(31);

   // ;   %tmp    = ashr i32 %dividend, 31
   // ;   %tmp1   = ashr i32 %divisor, 31
   // ;   %tmp2   = xor i32 %tmp, %dividend
   // ;   %u_dvnd = sub nsw i32 %tmp2, %tmp
   // ;   %tmp3   = xor i32 %tmp1, %divisor
   // ;   %u_dvsr = sub nsw i32 %tmp3, %tmp1
   // ;   %q_sgn  = xor i32 %tmp1, %tmp
   // ;   %q_mag  = udiv i32 %u_dvnd, %u_dvsr
   // ;   %tmp4   = xor i32 %q_mag, %q_sgn
   // ;   %q      = sub i32 %tmp4, %q_sgn
   Value* Tmp    = Builder.CreateAShr(Dividend, ThirtyOne);
   Value* Tmp1   = Builder.CreateAShr(Divisor, ThirtyOne);
   Value* Tmp2   = Builder.CreateXor(Tmp, Dividend);
   Value* U_Dvnd = Builder.CreateSub(Tmp2, Tmp);
   Value* Tmp3   = Builder.CreateXor(Tmp1, Divisor);
   Value* U_Dvsr = Builder.CreateSub(Tmp3, Tmp1);
   Value* Q_Sgn  = Builder.CreateXor(Tmp1, Tmp);
   Value* Q_Mag  = Builder.CreateUDiv(U_Dvnd, U_Dvsr);
   Value* Tmp4   = Builder.CreateXor(Q_Mag, Q_Sgn);
   Value* Q      = Builder.CreateSub(Tmp4, Q_Sgn);

   if (Instruction* UDiv = dyn_cast<Instruction>(Q_Mag))
     Builder.SetInsertPoint(UDiv);

   return Q;
 }

 // Generates code to divide two unsigned scalar 32-bit integers. Returns the
 // quotient, rounded towards 0. Builder's insert point should be pointing at the
 // udiv instruction.
 static Value* GenerateUnsignedDivisionCode(Value* Dividend, Value* Divisor,
                                            IRBuilder<>& Builder) {
   // The basic algorithm can be found in the compiler-rt project's
   // implementation of __udivsi3.c. Here, we do a lower-level IR based approach
   // that's been hand-tuned to lessen the amount of control flow involved.

   // Some helper values
   IntegerType* I32Ty = Builder.getInt32Ty();

   ConstantInt* Zero      = Builder.getInt32(0);
   ConstantInt* One       = Builder.getInt32(1);
   ConstantInt* ThirtyOne = Builder.getInt32(31);
   ConstantInt* NegOne    = ConstantInt::getSigned(I32Ty, -1);
   ConstantInt* True      = Builder.getTrue();

   BasicBlock* IBB = Builder.GetInsertBlock();
   Function* F = IBB->getParent();
   Function* CTLZi32 = Intrinsic::getDeclaration(F->getParent(), Intrinsic::ctlz,
                                                 I32Ty);

   // Our CFG is going to look like:
   // +---------------------+
   // | special-cases       |
   // |   ...               |
   // +---------------------+
   //  |       |
   //  |   +----------+
   //  |   |  bb1     |
   //  |   |  ...     |
   //  |   +----------+
   //  |    |      |
   //  |    |  +------------+
   //  |    |  |  preheader |
   //  |    |  |  ...       |
   //  |    |  +------------+
   //  |    |      |
   //  |    |      |      +---+
   //  |    |      |      |   |
   //  |    |  +------------+ |
   //  |    |  |  do-while  | |
   //  |    |  |  ...       | |
   //  |    |  +------------+ |
   //  |    |      |      |   |
   //  |   +-----------+  +---+
   //  |   | loop-exit |
   //  |   |  ...      |
   //  |   +-----------+
   //  |     |
   // +-------+
   // | ...   |
   // | end   |
   // +-------+
   BasicBlock* SpecialCases = Builder.GetInsertBlock();
   SpecialCases->setName(Twine(SpecialCases->getName(), "_udiv-special-cases"));
   BasicBlock* End = SpecialCases->splitBasicBlock(Builder.GetInsertPoint(),
                                                   "udiv-end");
   BasicBlock* LoopExit  = BasicBlock::Create(Builder.getContext(),
                                              "udiv-loop-exit", F, End);
   BasicBlock* DoWhile   = BasicBlock::Create(Builder.getContext(),
                                              "udiv-do-while", F, End);
   BasicBlock* Preheader = BasicBlock::Create(Builder.getContext(),
                                              "udiv-preheader", F, End);
   BasicBlock* BB1       = BasicBlock::Create(Builder.getContext(),
                                              "udiv-bb1", F, End);

   // We'll be overwriting the terminator to insert our extra blocks
   SpecialCases->getTerminator()->eraseFromParent();

   // First off, check for special cases: dividend or divisor is zero, divisor
   // is greater than dividend, and divisor is 1.
   // ; special-cases:
   // ;   %ret0_1      = icmp eq i32 %divisor, 0
   // ;   %ret0_2      = icmp eq i32 %dividend, 0
   // ;   %ret0_3      = or i1 %ret0_1, %ret0_2
   // ;   %tmp0        = tail call i32 @llvm.ctlz.i32(i32 %divisor, i1 true)
   // ;   %tmp1        = tail call i32 @llvm.ctlz.i32(i32 %dividend, i1 true)
   // ;   %sr          = sub nsw i32 %tmp0, %tmp1
   // ;   %ret0_4      = icmp ugt i32 %sr, 31
   // ;   %ret0        = or i1 %ret0_3, %ret0_4
   // ;   %retDividend = icmp eq i32 %sr, 31
   // ;   %retVal      = select i1 %ret0, i32 0, i32 %dividend
   // ;   %earlyRet    = or i1 %ret0, %retDividend
   // ;   br i1 %earlyRet, label %end, label %bb1
   Builder.SetInsertPoint(SpecialCases);
   Value* Ret0_1      = Builder.CreateICmpEQ(Divisor, Zero);
   Value* Ret0_2      = Builder.CreateICmpEQ(Dividend, Zero);
   Value* Ret0_3      = Builder.CreateOr(Ret0_1, Ret0_2);
   Value* Tmp0        = Builder.CreateCall2(CTLZi32, Divisor, True);
   Value* Tmp1        = Builder.CreateCall2(CTLZi32, Dividend, True);
   Value* SR          = Builder.CreateSub(Tmp0, Tmp1);
   Value* Ret0_4      = Builder.CreateICmpUGT(SR, ThirtyOne);
   Value* Ret0        = Builder.CreateOr(Ret0_3, Ret0_4);
   Value* RetDividend = Builder.CreateICmpEQ(SR, ThirtyOne);
   Value* RetVal      = Builder.CreateSelect(Ret0, Zero, Dividend);
   Value* EarlyRet    = Builder.CreateOr(Ret0, RetDividend);
   Builder.CreateCondBr(EarlyRet, End, BB1);

   // ; bb1:                                             ; preds = %special-cases
   // ;   %sr_1     = add i32 %sr, 1
   // ;   %tmp2     = sub i32 31, %sr
   // ;   %q        = shl i32 %dividend, %tmp2
   // ;   %skipLoop = icmp eq i32 %sr_1, 0
   // ;   br i1 %skipLoop, label %loop-exit, label %preheader
   Builder.SetInsertPoint(BB1);
   Value* SR_1     = Builder.CreateAdd(SR, One);
   Value* Tmp2     = Builder.CreateSub(ThirtyOne, SR);
   Value* Q        = Builder.CreateShl(Dividend, Tmp2);
   Value* SkipLoop = Builder.CreateICmpEQ(SR_1, Zero);
   Builder.CreateCondBr(SkipLoop, LoopExit, Preheader);

   // ; preheader:                                           ; preds = %bb1
   // ;   %tmp3 = lshr i32 %dividend, %sr_1
   // ;   %tmp4 = add i32 %divisor, -1
   // ;   br label %do-while
   Builder.SetInsertPoint(Preheader);
   Value* Tmp3 = Builder.CreateLShr(Dividend, SR_1);
   Value* Tmp4 = Builder.CreateAdd(Divisor, NegOne);
   Builder.CreateBr(DoWhile);

   // ; do-while:                                 ; preds = %do-while, %preheader
   // ;   %carry_1 = phi i32 [ 0, %preheader ], [ %carry, %do-while ]
   // ;   %sr_3    = phi i32 [ %sr_1, %preheader ], [ %sr_2, %do-while ]
   // ;   %r_1     = phi i32 [ %tmp3, %preheader ], [ %r, %do-while ]
   // ;   %q_2     = phi i32 [ %q, %preheader ], [ %q_1, %do-while ]
   // ;   %tmp5  = shl i32 %r_1, 1
   // ;   %tmp6  = lshr i32 %q_2, 31
   // ;   %tmp7  = or i32 %tmp5, %tmp6
   // ;   %tmp8  = shl i32 %q_2, 1
   // ;   %q_1   = or i32 %carry_1, %tmp8
   // ;   %tmp9  = sub i32 %tmp4, %tmp7
   // ;   %tmp10 = ashr i32 %tmp9, 31
   // ;   %carry = and i32 %tmp10, 1
   // ;   %tmp11 = and i32 %tmp10, %divisor
   // ;   %r     = sub i32 %tmp7, %tmp11
   // ;   %sr_2  = add i32 %sr_3, -1
   // ;   %tmp12 = icmp eq i32 %sr_2, 0
   // ;   br i1 %tmp12, label %loop-exit, label %do-while
   Builder.SetInsertPoint(DoWhile);
   PHINode* Carry_1 = Builder.CreatePHI(I32Ty, 2);
   PHINode* SR_3    = Builder.CreatePHI(I32Ty, 2);
   PHINode* R_1     = Builder.CreatePHI(I32Ty, 2);
   PHINode* Q_2     = Builder.CreatePHI(I32Ty, 2);
   Value* Tmp5  = Builder.CreateShl(R_1, One);
   Value* Tmp6  = Builder.CreateLShr(Q_2, ThirtyOne);
   Value* Tmp7  = Builder.CreateOr(Tmp5, Tmp6);
   Value* Tmp8  = Builder.CreateShl(Q_2, One);
   Value* Q_1   = Builder.CreateOr(Carry_1, Tmp8);
   Value* Tmp9  = Builder.CreateSub(Tmp4, Tmp7);
   Value* Tmp10 = Builder.CreateAShr(Tmp9, 31);
   Value* Carry = Builder.CreateAnd(Tmp10, One);
   Value* Tmp11 = Builder.CreateAnd(Tmp10, Divisor);
   Value* R     = Builder.CreateSub(Tmp7, Tmp11);
   Value* SR_2  = Builder.CreateAdd(SR_3, NegOne);
   Value* Tmp12 = Builder.CreateICmpEQ(SR_2, Zero);
   Builder.CreateCondBr(Tmp12, LoopExit, DoWhile);

   // ; loop-exit:                                      ; preds = %do-while, %bb1
   // ;   %carry_2 = phi i32 [ 0, %bb1 ], [ %carry, %do-while ]
   // ;   %q_3     = phi i32 [ %q, %bb1 ], [ %q_1, %do-while ]
   // ;   %tmp13 = shl i32 %q_3, 1
   // ;   %q_4   = or i32 %carry_2, %tmp13
   // ;   br label %end
   Builder.SetInsertPoint(LoopExit);
   PHINode* Carry_2 = Builder.CreatePHI(I32Ty, 2);
   PHINode* Q_3     = Builder.CreatePHI(I32Ty, 2);
   Value* Tmp13 = Builder.CreateShl(Q_3, One);
   Value* Q_4   = Builder.CreateOr(Carry_2, Tmp13);
   Builder.CreateBr(End);

   // ; end:                                 ; preds = %loop-exit, %special-cases
   // ;   %q_5 = phi i32 [ %q_4, %loop-exit ], [ %retVal, %special-cases ]
   // ;   ret i32 %q_5
   Builder.SetInsertPoint(End, End->begin());
   PHINode* Q_5 = Builder.CreatePHI(I32Ty, 2);

   // Populate the Phis, since all values have now been created. Our Phis were:
   // ;   %carry_1 = phi i32 [ 0, %preheader ], [ %carry, %do-while ]
   Carry_1->addIncoming(Zero, Preheader);
   Carry_1->addIncoming(Carry, DoWhile);
   // ;   %sr_3 = phi i32 [ %sr_1, %preheader ], [ %sr_2, %do-while ]
   SR_3->addIncoming(SR_1, Preheader);
   SR_3->addIncoming(SR_2, DoWhile);
   // ;   %r_1 = phi i32 [ %tmp3, %preheader ], [ %r, %do-while ]
   R_1->addIncoming(Tmp3, Preheader);
   R_1->addIncoming(R, DoWhile);
   // ;   %q_2 = phi i32 [ %q, %preheader ], [ %q_1, %do-while ]
   Q_2->addIncoming(Q, Preheader);
   Q_2->addIncoming(Q_1, DoWhile);
   // ;   %carry_2 = phi i32 [ 0, %bb1 ], [ %carry, %do-while ]
   Carry_2->addIncoming(Zero, BB1);
   Carry_2->addIncoming(Carry, DoWhile);
   // ;   %q_3 = phi i32 [ %q, %bb1 ], [ %q_1, %do-while ]
   Q_3->addIncoming(Q, BB1);
   Q_3->addIncoming(Q_1, DoWhile);
   // ;   %q_5 = phi i32 [ %q_4, %loop-exit ], [ %retVal, %special-cases ]
   Q_5->addIncoming(Q_4, LoopExit);
   Q_5->addIncoming(RetVal, SpecialCases);

   return Q_5;
 }

 bool llvm::expandDivision(BinaryOperator* Div) {
   assert((Div->getOpcode() == Instruction::SDiv ||
           Div->getOpcode() == Instruction::UDiv) &&
          "Trying to expand division from a non-division function");

   IRBuilder<> Builder(Div);

   if (Div->getType()->isVectorTy())
     llvm_unreachable("Div over vectors not supported");

   // First prepare the sign if it's a signed division
   if (Div->getOpcode() == Instruction::SDiv) {
     // Lower the code to unsigned division, and reset Div to point to the udiv.
     Value* Quotient = GenerateSignedDivisionCode(Div->getOperand(0),
                                                 Div->getOperand(1), Builder);
     Div->replaceAllUsesWith(Quotient);
     Div->dropAllReferences();
     Div->eraseFromParent();

     // If we didn't actually generate a udiv instruction, we're done
     BinaryOperator* BO = dyn_cast<BinaryOperator>(Builder.GetInsertPoint());
     if (!BO || BO->getOpcode() != Instruction::UDiv)
       return true;

     Div = BO;
   }

   // Insert the unsigned division code
   Value* Quotient = GenerateUnsignedDivisionCode(Div->getOperand(0),
                                                  Div->getOperand(1),
                                                  Builder);
   Div->replaceAllUsesWith(Quotient);
   Div->dropAllReferences();
   Div->eraseFromParent();

   return true;
 }
	//===-- IntegerDivision.cpp - Expand integer division ---------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file contains an implementation of 32bit scalar integer division for
	// targets that don't have native support. It's largely derived from
	// compiler-rt's implementation of __udivsi3, but hand-tuned to reduce the
	// amount of control flow
	//
	//===----------------------------------------------------------------------===//

	#define DEBUG_TYPE "integer-division"
	#include "llvm/Function.h"
	#include "llvm/Instructions.h"
	#include "llvm/Intrinsics.h"
	#include "llvm/IRBuilder.h"
	#include "llvm/Transforms/Utils/IntegerDivision.h"

	using namespace llvm;

	// Generate code to divide two signed integers. Returns the quotient, rounded
	// towards 0. Builder's insert point should be pointing at the sdiv
	// instruction. This will generate a udiv in the process, and Builder's insert
	// point will be pointing at the udiv (if present, i.e. not folded), ready to be
	// expanded if the user wishes.
	static Value* GenerateSignedDivisionCode(Value* Dividend, Value* Divisor,
	IRBuilder<>& Builder) {
	// Implementation taken from compiler-rt's __divsi3

	ConstantInt* ThirtyOne = Builder.getInt32(31);

	// ; %tmp = ashr i32 %dividend, 31
	// ; %tmp1 = ashr i32 %divisor, 31
	// ; %tmp2 = xor i32 %tmp, %dividend
	// ; %u_dvnd = sub nsw i32 %tmp2, %tmp
	// ; %tmp3 = xor i32 %tmp1, %divisor
	// ; %u_dvsr = sub nsw i32 %tmp3, %tmp1
	// ; %q_sgn = xor i32 %tmp1, %tmp
	// ; %q_mag = udiv i32 %u_dvnd, %u_dvsr
	// ; %tmp4 = xor i32 %q_mag, %q_sgn
	// ; %q = sub i32 %tmp4, %q_sgn
	Value* Tmp = Builder.CreateAShr(Dividend, ThirtyOne);
	Value* Tmp1 = Builder.CreateAShr(Divisor, ThirtyOne);
	Value* Tmp2 = Builder.CreateXor(Tmp, Dividend);
	Value* U_Dvnd = Builder.CreateSub(Tmp2, Tmp);
	Value* Tmp3 = Builder.CreateXor(Tmp1, Divisor);
	Value* U_Dvsr = Builder.CreateSub(Tmp3, Tmp1);
	Value* Q_Sgn = Builder.CreateXor(Tmp1, Tmp);
	Value* Q_Mag = Builder.CreateUDiv(U_Dvnd, U_Dvsr);
	Value* Tmp4 = Builder.CreateXor(Q_Mag, Q_Sgn);
	Value* Q = Builder.CreateSub(Tmp4, Q_Sgn);

	if (Instruction* UDiv = dyn_cast<Instruction>(Q_Mag))
	Builder.SetInsertPoint(UDiv);

	return Q;
	}

	// Generates code to divide two unsigned scalar 32-bit integers. Returns the
	// quotient, rounded towards 0. Builder's insert point should be pointing at the
	// udiv instruction.
	static Value* GenerateUnsignedDivisionCode(Value* Dividend, Value* Divisor,
	IRBuilder<>& Builder) {
	// The basic algorithm can be found in the compiler-rt project's
	// implementation of __udivsi3.c. Here, we do a lower-level IR based approach
	// that's been hand-tuned to lessen the amount of control flow involved.

	// Some helper values
	IntegerType* I32Ty = Builder.getInt32Ty();

	ConstantInt* Zero = Builder.getInt32(0);
	ConstantInt* One = Builder.getInt32(1);
	ConstantInt* ThirtyOne = Builder.getInt32(31);
	ConstantInt* NegOne = ConstantInt::getSigned(I32Ty, -1);
	ConstantInt* True = Builder.getTrue();

	BasicBlock* IBB = Builder.GetInsertBlock();
	Function* F = IBB->getParent();
	Function* CTLZi32 = Intrinsic::getDeclaration(F->getParent(), Intrinsic::ctlz,
	I32Ty);

	// Our CFG is going to look like:
	// +---------------------+
	// \| special-cases \|
	// \| ... \|
	// +---------------------+
	// \| \|
	// \| +----------+
	// \| \| bb1 \|
	// \| \| ... \|
	// \| +----------+
	// \| \| \|
	// \| \| +------------+
	// \| \| \| preheader \|
	// \| \| \| ... \|
	// \| \| +------------+
	// \| \| \|
	// \| \| \| +---+
	// \| \| \| \| \|
	// \| \| +------------+ \|
	// \| \| \| do-while \| \|
	// \| \| \| ... \| \|
	// \| \| +------------+ \|
	// \| \| \| \| \|
	// \| +-----------+ +---+
	// \| \| loop-exit \|
	// \| \| ... \|
	// \| +-----------+
	// \| \|
	// +-------+
	// \| ... \|
	// \| end \|
	// +-------+
	BasicBlock* SpecialCases = Builder.GetInsertBlock();
	SpecialCases->setName(Twine(SpecialCases->getName(), "_udiv-special-cases"));
	BasicBlock* End = SpecialCases->splitBasicBlock(Builder.GetInsertPoint(),
	"udiv-end");
	BasicBlock* LoopExit = BasicBlock::Create(Builder.getContext(),
	"udiv-loop-exit", F, End);
	BasicBlock* DoWhile = BasicBlock::Create(Builder.getContext(),
	"udiv-do-while", F, End);
	BasicBlock* Preheader = BasicBlock::Create(Builder.getContext(),
	"udiv-preheader", F, End);
	BasicBlock* BB1 = BasicBlock::Create(Builder.getContext(),
	"udiv-bb1", F, End);

	// We'll be overwriting the terminator to insert our extra blocks
	SpecialCases->getTerminator()->eraseFromParent();

	// First off, check for special cases: dividend or divisor is zero, divisor
	// is greater than dividend, and divisor is 1.
	// ; special-cases:
	// ; %ret0_1 = icmp eq i32 %divisor, 0
	// ; %ret0_2 = icmp eq i32 %dividend, 0
	// ; %ret0_3 = or i1 %ret0_1, %ret0_2
	// ; %tmp0 = tail call i32 @llvm.ctlz.i32(i32 %divisor, i1 true)
	// ; %tmp1 = tail call i32 @llvm.ctlz.i32(i32 %dividend, i1 true)
	// ; %sr = sub nsw i32 %tmp0, %tmp1
	// ; %ret0_4 = icmp ugt i32 %sr, 31
	// ; %ret0 = or i1 %ret0_3, %ret0_4
	// ; %retDividend = icmp eq i32 %sr, 31
	// ; %retVal = select i1 %ret0, i32 0, i32 %dividend
	// ; %earlyRet = or i1 %ret0, %retDividend
	// ; br i1 %earlyRet, label %end, label %bb1
	Builder.SetInsertPoint(SpecialCases);
	Value* Ret0_1 = Builder.CreateICmpEQ(Divisor, Zero);
	Value* Ret0_2 = Builder.CreateICmpEQ(Dividend, Zero);
	Value* Ret0_3 = Builder.CreateOr(Ret0_1, Ret0_2);
	Value* Tmp0 = Builder.CreateCall2(CTLZi32, Divisor, True);
	Value* Tmp1 = Builder.CreateCall2(CTLZi32, Dividend, True);
	Value* SR = Builder.CreateSub(Tmp0, Tmp1);
	Value* Ret0_4 = Builder.CreateICmpUGT(SR, ThirtyOne);
	Value* Ret0 = Builder.CreateOr(Ret0_3, Ret0_4);
	Value* RetDividend = Builder.CreateICmpEQ(SR, ThirtyOne);
	Value* RetVal = Builder.CreateSelect(Ret0, Zero, Dividend);
	Value* EarlyRet = Builder.CreateOr(Ret0, RetDividend);
	Builder.CreateCondBr(EarlyRet, End, BB1);

	// ; bb1: ; preds = %special-cases
	// ; %sr_1 = add i32 %sr, 1
	// ; %tmp2 = sub i32 31, %sr
	// ; %q = shl i32 %dividend, %tmp2
	// ; %skipLoop = icmp eq i32 %sr_1, 0
	// ; br i1 %skipLoop, label %loop-exit, label %preheader
	Builder.SetInsertPoint(BB1);
	Value* SR_1 = Builder.CreateAdd(SR, One);
	Value* Tmp2 = Builder.CreateSub(ThirtyOne, SR);
	Value* Q = Builder.CreateShl(Dividend, Tmp2);
	Value* SkipLoop = Builder.CreateICmpEQ(SR_1, Zero);
	Builder.CreateCondBr(SkipLoop, LoopExit, Preheader);

	// ; preheader: ; preds = %bb1
	// ; %tmp3 = lshr i32 %dividend, %sr_1
	// ; %tmp4 = add i32 %divisor, -1
	// ; br label %do-while
	Builder.SetInsertPoint(Preheader);
	Value* Tmp3 = Builder.CreateLShr(Dividend, SR_1);
	Value* Tmp4 = Builder.CreateAdd(Divisor, NegOne);
	Builder.CreateBr(DoWhile);

	// ; do-while: ; preds = %do-while, %preheader
	// ; %carry_1 = phi i32 [ 0, %preheader ], [ %carry, %do-while ]
	// ; %sr_3 = phi i32 [ %sr_1, %preheader ], [ %sr_2, %do-while ]
	// ; %r_1 = phi i32 [ %tmp3, %preheader ], [ %r, %do-while ]
	// ; %q_2 = phi i32 [ %q, %preheader ], [ %q_1, %do-while ]
	// ; %tmp5 = shl i32 %r_1, 1
	// ; %tmp6 = lshr i32 %q_2, 31
	// ; %tmp7 = or i32 %tmp5, %tmp6
	// ; %tmp8 = shl i32 %q_2, 1
	// ; %q_1 = or i32 %carry_1, %tmp8
	// ; %tmp9 = sub i32 %tmp4, %tmp7
	// ; %tmp10 = ashr i32 %tmp9, 31
	// ; %carry = and i32 %tmp10, 1
	// ; %tmp11 = and i32 %tmp10, %divisor
	// ; %r = sub i32 %tmp7, %tmp11
	// ; %sr_2 = add i32 %sr_3, -1
	// ; %tmp12 = icmp eq i32 %sr_2, 0
	// ; br i1 %tmp12, label %loop-exit, label %do-while
	Builder.SetInsertPoint(DoWhile);
	PHINode* Carry_1 = Builder.CreatePHI(I32Ty, 2);
	PHINode* SR_3 = Builder.CreatePHI(I32Ty, 2);
	PHINode* R_1 = Builder.CreatePHI(I32Ty, 2);
	PHINode* Q_2 = Builder.CreatePHI(I32Ty, 2);
	Value* Tmp5 = Builder.CreateShl(R_1, One);
	Value* Tmp6 = Builder.CreateLShr(Q_2, ThirtyOne);
	Value* Tmp7 = Builder.CreateOr(Tmp5, Tmp6);
	Value* Tmp8 = Builder.CreateShl(Q_2, One);
	Value* Q_1 = Builder.CreateOr(Carry_1, Tmp8);
	Value* Tmp9 = Builder.CreateSub(Tmp4, Tmp7);
	Value* Tmp10 = Builder.CreateAShr(Tmp9, 31);
	Value* Carry = Builder.CreateAnd(Tmp10, One);
	Value* Tmp11 = Builder.CreateAnd(Tmp10, Divisor);
	Value* R = Builder.CreateSub(Tmp7, Tmp11);
	Value* SR_2 = Builder.CreateAdd(SR_3, NegOne);
	Value* Tmp12 = Builder.CreateICmpEQ(SR_2, Zero);
	Builder.CreateCondBr(Tmp12, LoopExit, DoWhile);

	// ; loop-exit: ; preds = %do-while, %bb1
	// ; %carry_2 = phi i32 [ 0, %bb1 ], [ %carry, %do-while ]
	// ; %q_3 = phi i32 [ %q, %bb1 ], [ %q_1, %do-while ]
	// ; %tmp13 = shl i32 %q_3, 1
	// ; %q_4 = or i32 %carry_2, %tmp13
	// ; br label %end
	Builder.SetInsertPoint(LoopExit);
	PHINode* Carry_2 = Builder.CreatePHI(I32Ty, 2);
	PHINode* Q_3 = Builder.CreatePHI(I32Ty, 2);
	Value* Tmp13 = Builder.CreateShl(Q_3, One);
	Value* Q_4 = Builder.CreateOr(Carry_2, Tmp13);
	Builder.CreateBr(End);

	// ; end: ; preds = %loop-exit, %special-cases
	// ; %q_5 = phi i32 [ %q_4, %loop-exit ], [ %retVal, %special-cases ]
	// ; ret i32 %q_5
	Builder.SetInsertPoint(End, End->begin());
	PHINode* Q_5 = Builder.CreatePHI(I32Ty, 2);

	// Populate the Phis, since all values have now been created. Our Phis were:
	// ; %carry_1 = phi i32 [ 0, %preheader ], [ %carry, %do-while ]
	Carry_1->addIncoming(Zero, Preheader);
	Carry_1->addIncoming(Carry, DoWhile);
	// ; %sr_3 = phi i32 [ %sr_1, %preheader ], [ %sr_2, %do-while ]
	SR_3->addIncoming(SR_1, Preheader);
	SR_3->addIncoming(SR_2, DoWhile);
	// ; %r_1 = phi i32 [ %tmp3, %preheader ], [ %r, %do-while ]
	R_1->addIncoming(Tmp3, Preheader);
	R_1->addIncoming(R, DoWhile);
	// ; %q_2 = phi i32 [ %q, %preheader ], [ %q_1, %do-while ]
	Q_2->addIncoming(Q, Preheader);
	Q_2->addIncoming(Q_1, DoWhile);
	// ; %carry_2 = phi i32 [ 0, %bb1 ], [ %carry, %do-while ]
	Carry_2->addIncoming(Zero, BB1);
	Carry_2->addIncoming(Carry, DoWhile);
	// ; %q_3 = phi i32 [ %q, %bb1 ], [ %q_1, %do-while ]
	Q_3->addIncoming(Q, BB1);
	Q_3->addIncoming(Q_1, DoWhile);
	// ; %q_5 = phi i32 [ %q_4, %loop-exit ], [ %retVal, %special-cases ]
	Q_5->addIncoming(Q_4, LoopExit);
	Q_5->addIncoming(RetVal, SpecialCases);

	return Q_5;
	}

	bool llvm::expandDivision(BinaryOperator* Div) {
	assert((Div->getOpcode() == Instruction::SDiv \|\|
	Div->getOpcode() == Instruction::UDiv) &&
	"Trying to expand division from a non-division function");

	IRBuilder<> Builder(Div);

	if (Div->getType()->isVectorTy())
	llvm_unreachable("Div over vectors not supported");

	// First prepare the sign if it's a signed division
	if (Div->getOpcode() == Instruction::SDiv) {
	// Lower the code to unsigned division, and reset Div to point to the udiv.
	Value* Quotient = GenerateSignedDivisionCode(Div->getOperand(0),
	Div->getOperand(1), Builder);
	Div->replaceAllUsesWith(Quotient);
	Div->dropAllReferences();
	Div->eraseFromParent();

	// If we didn't actually generate a udiv instruction, we're done
	BinaryOperator* BO = dyn_cast<BinaryOperator>(Builder.GetInsertPoint());
	if (!BO \|\| BO->getOpcode() != Instruction::UDiv)
	return true;

	Div = BO;
	}

	// Insert the unsigned division code
	Value* Quotient = GenerateUnsignedDivisionCode(Div->getOperand(0),
	Div->getOperand(1),
	Builder);
	Div->replaceAllUsesWith(Quotient);
	Div->dropAllReferences();
	Div->eraseFromParent();

	return true;
	}