lib/Target/AArch64/AArch64BranchFixupPass.cpp - llvm - Git at Google

 //===-- AArch64BranchFixupPass.cpp - AArch64 branch fixup -----------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file contains a pass that fixes AArch64 branches which have ended up out
 // of range for their immediate operands.
 //
 //===----------------------------------------------------------------------===//

 #define DEBUG_TYPE "aarch64-branch-fixup"
 #include "AArch64.h"
 #include "AArch64InstrInfo.h"
 #include "Utils/AArch64BaseInfo.h"
 #include "llvm/CodeGen/MachineFunctionPass.h"
 #include "llvm/CodeGen/MachineInstrBuilder.h"
 #include "llvm/CodeGen/MachineRegisterInfo.h"
 #include "llvm/Support/Debug.h"
 #include "llvm/Support/Format.h"
 #include "llvm/Support/raw_ostream.h"
 #include "llvm/ADT/Statistic.h"
 using namespace llvm;

 STATISTIC(NumSplit,      "Number of uncond branches inserted");
 STATISTIC(NumCBrFixed,   "Number of cond branches fixed");

 /// Return the worst case padding that could result from unknown offset bits.
 /// This does not include alignment padding caused by known offset bits.
 ///
 /// @param LogAlign log2(alignment)
 /// @param KnownBits Number of known low offset bits.
 static inline unsigned UnknownPadding(unsigned LogAlign, unsigned KnownBits) {
   if (KnownBits < LogAlign)
     return (1u << LogAlign) - (1u << KnownBits);
   return 0;
 }

 namespace {
   /// Due to limited PC-relative displacements, conditional branches to distant
   /// blocks may need converting into an unconditional equivalent. For example:
   ///     tbz w1, #0, far_away
   /// becomes
   ///     tbnz w1, #0, skip
   ///     b far_away
   ///   skip:
   class AArch64BranchFixup : public MachineFunctionPass {
     /// Information about the offset and size of a single basic block.
     struct BasicBlockInfo {
       /// Distance from the beginning of the function to the beginning of this
       /// basic block.
       ///
       /// Offsets are computed assuming worst case padding before an aligned
       /// block. This means that subtracting basic block offsets always gives a
       /// conservative estimate of the real distance which may be smaller.
       ///
       /// Because worst case padding is used, the computed offset of an aligned
       /// block may not actually be aligned.
       unsigned Offset;

       /// Size of the basic block in bytes.  If the block contains inline
       /// assembly, this is a worst case estimate.
       ///
       /// The size does not include any alignment padding whether from the
       /// beginning of the block, or from an aligned jump table at the end.
       unsigned Size;

       /// The number of low bits in Offset that are known to be exact.  The
       /// remaining bits of Offset are an upper bound.
       uint8_t KnownBits;

       /// When non-zero, the block contains instructions (inline asm) of unknown
       /// size.  The real size may be smaller than Size bytes by a multiple of 1
       /// << Unalign.
       uint8_t Unalign;

       BasicBlockInfo() : Offset(0), Size(0), KnownBits(0), Unalign(0) {}

       /// Compute the number of known offset bits internally to this block.
       /// This number should be used to predict worst case padding when
       /// splitting the block.
       unsigned internalKnownBits() const {
         unsigned Bits = Unalign ? Unalign : KnownBits;
         // If the block size isn't a multiple of the known bits, assume the
         // worst case padding.
         if (Size & ((1u << Bits) - 1))
           Bits = CountTrailingZeros_32(Size);
         return Bits;
       }

       /// Compute the offset immediately following this block.  If LogAlign is
       /// specified, return the offset the successor block will get if it has
       /// this alignment.
       unsigned postOffset(unsigned LogAlign = 0) const {
         unsigned PO = Offset + Size;
         if (!LogAlign)
           return PO;
         // Add alignment padding from the terminator.
         return PO + UnknownPadding(LogAlign, internalKnownBits());
       }

       /// Compute the number of known low bits of postOffset.  If this block
       /// contains inline asm, the number of known bits drops to the
       /// instruction alignment.  An aligned terminator may increase the number
       /// of know bits.
       /// If LogAlign is given, also consider the alignment of the next block.
       unsigned postKnownBits(unsigned LogAlign = 0) const {
         return std::max(LogAlign, internalKnownBits());
       }
     };

     std::vector<BasicBlockInfo> BBInfo;

     /// One per immediate branch, keeping the machine instruction pointer,
     /// conditional or unconditional, the max displacement, and (if IsCond is
     /// true) the corresponding inverted branch opcode.
     struct ImmBranch {
       MachineInstr *MI;
       unsigned OffsetBits : 31;
       bool IsCond : 1;
       ImmBranch(MachineInstr *mi, unsigned offsetbits, bool cond)
         : MI(mi), OffsetBits(offsetbits), IsCond(cond) {}
     };

     /// Keep track of all the immediate branch instructions.
     ///
     std::vector<ImmBranch> ImmBranches;

     MachineFunction *MF;
     const AArch64InstrInfo *TII;
   public:
     static char ID;
     AArch64BranchFixup() : MachineFunctionPass(ID) {}

     virtual bool runOnMachineFunction(MachineFunction &MF);

     virtual const char *getPassName() const {
       return "AArch64 branch fixup pass";
     }

   private:
     void initializeFunctionInfo();
     MachineBasicBlock *splitBlockBeforeInstr(MachineInstr *MI);
     void adjustBBOffsetsAfter(MachineBasicBlock *BB);
     bool isBBInRange(MachineInstr *MI, MachineBasicBlock *BB,
                      unsigned OffsetBits);
     bool fixupImmediateBr(ImmBranch &Br);
     bool fixupConditionalBr(ImmBranch &Br);

     void computeBlockSize(MachineBasicBlock *MBB);
     unsigned getOffsetOf(MachineInstr *MI) const;
     void dumpBBs();
     void verify();
   };
   char AArch64BranchFixup::ID = 0;
 }

 /// check BBOffsets
 void AArch64BranchFixup::verify() {
 #ifndef NDEBUG
   for (MachineFunction::iterator MBBI = MF->begin(), E = MF->end();
        MBBI != E; ++MBBI) {
     MachineBasicBlock *MBB = MBBI;
     unsigned MBBId = MBB->getNumber();
     assert(!MBBId || BBInfo[MBBId - 1].postOffset() <= BBInfo[MBBId].Offset);
   }
 #endif
 }

 /// print block size and offset information - debugging
 void AArch64BranchFixup::dumpBBs() {
   DEBUG({
     for (unsigned J = 0, E = BBInfo.size(); J !=E; ++J) {
       const BasicBlockInfo &BBI = BBInfo[J];
       dbgs() << format("%08x BB#%u\t", BBI.Offset, J)
              << " kb=" << unsigned(BBI.KnownBits)
              << " ua=" << unsigned(BBI.Unalign)
              << format(" size=%#x\n", BBInfo[J].Size);
     }
   });
 }

 /// Returns an instance of the branch fixup pass.
 FunctionPass *llvm::createAArch64BranchFixupPass() {
   return new AArch64BranchFixup();
 }

 bool AArch64BranchFixup::runOnMachineFunction(MachineFunction &mf) {
   MF = &mf;
   DEBUG(dbgs() << "***** AArch64BranchFixup ******");
   TII = (const AArch64InstrInfo*)MF->getTarget().getInstrInfo();

   // This pass invalidates liveness information when it splits basic blocks.
   MF->getRegInfo().invalidateLiveness();

   // Renumber all of the machine basic blocks in the function, guaranteeing that
   // the numbers agree with the position of the block in the function.
   MF->RenumberBlocks();

   // Do the initial scan of the function, building up information about the
   // sizes of each block and location of each immediate branch.
   initializeFunctionInfo();

   // Iteratively fix up branches until there is no change.
   unsigned NoBRIters = 0;
   bool MadeChange = false;
   while (true) {
     DEBUG(dbgs() << "Beginning iteration #" << NoBRIters << '\n');
     bool BRChange = false;
     for (unsigned i = 0, e = ImmBranches.size(); i != e; ++i)
       BRChange |= fixupImmediateBr(ImmBranches[i]);
     if (BRChange && ++NoBRIters > 30)
       report_fatal_error("Branch Fix Up pass failed to converge!");
     DEBUG(dumpBBs());

     if (!BRChange)
       break;
     MadeChange = true;
   }

   // After a while, this might be made debug-only, but it is not expensive.
   verify();

   DEBUG(dbgs() << '\n'; dumpBBs());

   BBInfo.clear();
   ImmBranches.clear();

   return MadeChange;
 }

 /// Return true if the specified basic block can fallthrough into the block
 /// immediately after it.
 static bool BBHasFallthrough(MachineBasicBlock *MBB) {
   // Get the next machine basic block in the function.
   MachineFunction::iterator MBBI = MBB;
   // Can't fall off end of function.
   if (llvm::next(MBBI) == MBB->getParent()->end())
     return false;

   MachineBasicBlock *NextBB = llvm::next(MBBI);
   for (MachineBasicBlock::succ_iterator I = MBB->succ_begin(),
        E = MBB->succ_end(); I != E; ++I)
     if (*I == NextBB)
       return true;

   return false;
 }

 /// Do the initial scan of the function, building up information about the sizes
 /// of each block, and each immediate branch.
 void AArch64BranchFixup::initializeFunctionInfo() {
   BBInfo.clear();
   BBInfo.resize(MF->getNumBlockIDs());

   // First thing, compute the size of all basic blocks, and see if the function
   // has any inline assembly in it. If so, we have to be conservative about
   // alignment assumptions, as we don't know for sure the size of any
   // instructions in the inline assembly.
   for (MachineFunction::iterator I = MF->begin(), E = MF->end(); I != E; ++I)
     computeBlockSize(I);

   // The known bits of the entry block offset are determined by the function
   // alignment.
   BBInfo.front().KnownBits = MF->getAlignment();

   // Compute block offsets and known bits.
   adjustBBOffsetsAfter(MF->begin());

   // Now go back through the instructions and build up our data structures.
   for (MachineFunction::iterator MBBI = MF->begin(), E = MF->end();
        MBBI != E; ++MBBI) {
     MachineBasicBlock &MBB = *MBBI;

     for (MachineBasicBlock::iterator I = MBB.begin(), E = MBB.end();
          I != E; ++I) {
       if (I->isDebugValue())
         continue;

       int Opc = I->getOpcode();
       if (I->isBranch()) {
         bool IsCond = false;

         // The offsets encoded in instructions here scale by the instruction
         // size (4 bytes), effectively increasing their range by 2 bits.
         unsigned Bits = 0;
         switch (Opc) {
         default:
           continue;  // Ignore other JT branches
         case AArch64::TBZxii:
         case AArch64::TBZwii:
         case AArch64::TBNZxii:
         case AArch64::TBNZwii:
           IsCond = true;
           Bits = 14 + 2;
           break;
         case AArch64::Bcc:
         case AArch64::CBZx:
         case AArch64::CBZw:
         case AArch64::CBNZx:
         case AArch64::CBNZw:
           IsCond = true;
           Bits = 19 + 2;
           break;
         case AArch64::Bimm:
           Bits = 26 + 2;
           break;
         }

         // Record this immediate branch.
         ImmBranches.push_back(ImmBranch(I, Bits, IsCond));
       }
     }
   }
 }

 /// Compute the size and some alignment information for MBB.  This function
 /// updates BBInfo directly.
 void AArch64BranchFixup::computeBlockSize(MachineBasicBlock *MBB) {
   BasicBlockInfo &BBI = BBInfo[MBB->getNumber()];
   BBI.Size = 0;
   BBI.Unalign = 0;

   for (MachineBasicBlock::iterator I = MBB->begin(), E = MBB->end(); I != E;
        ++I) {
     BBI.Size += TII->getInstSizeInBytes(*I);
     // For inline asm, GetInstSizeInBytes returns a conservative estimate.
     // The actual size may be smaller, but still a multiple of the instr size.
     if (I->isInlineAsm())
       BBI.Unalign = 2;
   }
 }

 /// Return the current offset of the specified machine instruction from the
 /// start of the function.  This offset changes as stuff is moved around inside
 /// the function.
 unsigned AArch64BranchFixup::getOffsetOf(MachineInstr *MI) const {
   MachineBasicBlock *MBB = MI->getParent();

   // The offset is composed of two things: the sum of the sizes of all MBB's
   // before this instruction's block, and the offset from the start of the block
   // it is in.
   unsigned Offset = BBInfo[MBB->getNumber()].Offset;

   // Sum instructions before MI in MBB.
   for (MachineBasicBlock::iterator I = MBB->begin(); &*I != MI; ++I) {
     assert(I != MBB->end() && "Didn't find MI in its own basic block?");
     Offset += TII->getInstSizeInBytes(*I);
   }
   return Offset;
 }

 /// Split the basic block containing MI into two blocks, which are joined by
 /// an unconditional branch.  Update data structures and renumber blocks to
 /// account for this change and returns the newly created block.
 MachineBasicBlock *
 AArch64BranchFixup::splitBlockBeforeInstr(MachineInstr *MI) {
   MachineBasicBlock *OrigBB = MI->getParent();

   // Create a new MBB for the code after the OrigBB.
   MachineBasicBlock *NewBB =
     MF->CreateMachineBasicBlock(OrigBB->getBasicBlock());
   MachineFunction::iterator MBBI = OrigBB; ++MBBI;
   MF->insert(MBBI, NewBB);

   // Splice the instructions starting with MI over to NewBB.
   NewBB->splice(NewBB->end(), OrigBB, MI, OrigBB->end());

   // Add an unconditional branch from OrigBB to NewBB.
   // Note the new unconditional branch is not being recorded.
   // There doesn't seem to be meaningful DebugInfo available; this doesn't
   // correspond to anything in the source.
   BuildMI(OrigBB, DebugLoc(), TII->get(AArch64::Bimm)).addMBB(NewBB);
   ++NumSplit;

   // Update the CFG.  All succs of OrigBB are now succs of NewBB.
   NewBB->transferSuccessors(OrigBB);

   // OrigBB branches to NewBB.
   OrigBB->addSuccessor(NewBB);

   // Update internal data structures to account for the newly inserted MBB.
   MF->RenumberBlocks(NewBB);

   // Insert an entry into BBInfo to align it properly with the (newly
   // renumbered) block numbers.
   BBInfo.insert(BBInfo.begin() + NewBB->getNumber(), BasicBlockInfo());

   // Figure out how large the OrigBB is.  As the first half of the original
   // block, it cannot contain a tablejump.  The size includes
   // the new jump we added.  (It should be possible to do this without
   // recounting everything, but it's very confusing, and this is rarely
   // executed.)
   computeBlockSize(OrigBB);

   // Figure out how large the NewMBB is.  As the second half of the original
   // block, it may contain a tablejump.
   computeBlockSize(NewBB);

   // All BBOffsets following these blocks must be modified.
   adjustBBOffsetsAfter(OrigBB);

   return NewBB;
 }

 void AArch64BranchFixup::adjustBBOffsetsAfter(MachineBasicBlock *BB) {
   unsigned BBNum = BB->getNumber();
   for(unsigned i = BBNum + 1, e = MF->getNumBlockIDs(); i < e; ++i) {
     // Get the offset and known bits at the end of the layout predecessor.
     // Include the alignment of the current block.
     unsigned LogAlign = MF->getBlockNumbered(i)->getAlignment();
     unsigned Offset = BBInfo[i - 1].postOffset(LogAlign);
     unsigned KnownBits = BBInfo[i - 1].postKnownBits(LogAlign);

     // This is where block i begins.  Stop if the offset is already correct,
     // and we have updated 2 blocks.  This is the maximum number of blocks
     // changed before calling this function.
     if (i > BBNum + 2 &&
         BBInfo[i].Offset == Offset &&
         BBInfo[i].KnownBits == KnownBits)
       break;

     BBInfo[i].Offset = Offset;
     BBInfo[i].KnownBits = KnownBits;
   }
 }

 /// Returns true if the distance between specific MI and specific BB can fit in
 /// MI's displacement field.
 bool AArch64BranchFixup::isBBInRange(MachineInstr *MI,
                                      MachineBasicBlock *DestBB,
                                      unsigned OffsetBits) {
   int64_t BrOffset   = getOffsetOf(MI);
   int64_t DestOffset = BBInfo[DestBB->getNumber()].Offset;

   DEBUG(dbgs() << "Branch of destination BB#" << DestBB->getNumber()
                << " from BB#" << MI->getParent()->getNumber()
                << " bits available=" << OffsetBits
                << " from " << getOffsetOf(MI) << " to " << DestOffset
                << " offset " << int(DestOffset-BrOffset) << "\t" << *MI);

   return isIntN(OffsetBits, DestOffset - BrOffset);
 }

 /// Fix up an immediate branch whose destination is too far away to fit in its
 /// displacement field.
 bool AArch64BranchFixup::fixupImmediateBr(ImmBranch &Br) {
   MachineInstr *MI = Br.MI;
   MachineBasicBlock *DestBB = 0;
   for (unsigned i = 0, e = MI->getNumOperands(); i != e; ++i) {
     if (MI->getOperand(i).isMBB()) {
       DestBB = MI->getOperand(i).getMBB();
       break;
     }
   }
   assert(DestBB && "Branch with no destination BB?");

   // Check to see if the DestBB is already in-range.
   if (isBBInRange(MI, DestBB, Br.OffsetBits))
     return false;

   assert(Br.IsCond && "Only conditional branches should need fixup");
   return fixupConditionalBr(Br);
 }

 /// Fix up a conditional branch whose destination is too far away to fit in its
 /// displacement field. It is converted to an inverse conditional branch + an
 /// unconditional branch to the destination.
 bool
 AArch64BranchFixup::fixupConditionalBr(ImmBranch &Br) {
   MachineInstr *MI = Br.MI;
   MachineBasicBlock *MBB = MI->getParent();
   unsigned CondBrMBBOperand = 0;

   // The general idea is to add an unconditional branch to the destination and
   // invert the conditional branch to jump over it. Complications occur around
   // fallthrough and unreachable ends to the block.
   //   b.lt L1
   //   =>
   //   b.ge L2
   //   b   L1
   // L2:

   // First we invert the conditional branch, by creating a replacement if
   // necessary. This if statement contains all the special handling of different
   // branch types.
   if (MI->getOpcode() == AArch64::Bcc) {
     // The basic block is operand number 1 for Bcc
     CondBrMBBOperand = 1;

     A64CC::CondCodes CC = (A64CC::CondCodes)MI->getOperand(0).getImm();
     CC = A64InvertCondCode(CC);
     MI->getOperand(0).setImm(CC);
   } else {
     MachineInstrBuilder InvertedMI;
     int InvertedOpcode;
     switch (MI->getOpcode()) {
     default: llvm_unreachable("Unknown branch type");
     case AArch64::TBZxii: InvertedOpcode = AArch64::TBNZxii; break;
     case AArch64::TBZwii: InvertedOpcode = AArch64::TBNZwii; break;
     case AArch64::TBNZxii: InvertedOpcode = AArch64::TBZxii; break;
     case AArch64::TBNZwii: InvertedOpcode = AArch64::TBZwii; break;
     case AArch64::CBZx: InvertedOpcode = AArch64::CBNZx; break;
     case AArch64::CBZw: InvertedOpcode = AArch64::CBNZw; break;
     case AArch64::CBNZx: InvertedOpcode = AArch64::CBZx; break;
     case AArch64::CBNZw: InvertedOpcode = AArch64::CBZw; break;
     }

     InvertedMI = BuildMI(*MBB, MI, MI->getDebugLoc(), TII->get(InvertedOpcode));
     for (unsigned i = 0, e= MI->getNumOperands(); i != e; ++i) {
       InvertedMI.addOperand(MI->getOperand(i));
       if (MI->getOperand(i).isMBB())
         CondBrMBBOperand = i;
     }

     MI->eraseFromParent();
     MI = Br.MI = InvertedMI;
   }

   // If the branch is at the end of its MBB and that has a fall-through block,
   // direct the updated conditional branch to the fall-through
   // block. Otherwise, split the MBB before the next instruction.
   MachineInstr *BMI = &MBB->back();
   bool NeedSplit = (BMI != MI) || !BBHasFallthrough(MBB);

   ++NumCBrFixed;
   if (BMI != MI) {
     if (llvm::next(MachineBasicBlock::iterator(MI)) == prior(MBB->end()) &&
         BMI->getOpcode() == AArch64::Bimm) {
       // Last MI in the BB is an unconditional branch. We can swap destinations:
       // b.eq L1 (temporarily b.ne L1 after first change)
       // b   L2
       // =>
       // b.ne L2
       // b   L1
       MachineBasicBlock *NewDest = BMI->getOperand(0).getMBB();
       if (isBBInRange(MI, NewDest, Br.OffsetBits)) {
         DEBUG(dbgs() << "  Invert Bcc condition and swap its destination with "
                      << *BMI);
         MachineBasicBlock *DestBB = MI->getOperand(CondBrMBBOperand).getMBB();
         BMI->getOperand(0).setMBB(DestBB);
         MI->getOperand(CondBrMBBOperand).setMBB(NewDest);
         return true;
       }
     }
   }

   if (NeedSplit) {
     MachineBasicBlock::iterator MBBI = MI; ++MBBI;
     splitBlockBeforeInstr(MBBI);
     // No need for the branch to the next block. We're adding an unconditional
     // branch to the destination.
     int delta = TII->getInstSizeInBytes(MBB->back());
     BBInfo[MBB->getNumber()].Size -= delta;
     MBB->back().eraseFromParent();
     // BBInfo[SplitBB].Offset is wrong temporarily, fixed below
   }

   // After splitting and removing the unconditional branch from the original BB,
   // the structure is now:
   // oldbb:
   //   [things]
   //   b.invertedCC L1
   // splitbb/fallthroughbb:
   //   [old b L2/real continuation]
   //
   // We now have to change the conditional branch to point to splitbb and add an
   // unconditional branch after it to L1, giving the final structure:
   // oldbb:
   //   [things]
   //   b.invertedCC splitbb
   //   b L1
   // splitbb/fallthroughbb:
   //   [old b L2/real continuation]
   MachineBasicBlock *NextBB = llvm::next(MachineFunction::iterator(MBB));

   DEBUG(dbgs() << "  Insert B to BB#"
                << MI->getOperand(CondBrMBBOperand).getMBB()->getNumber()
                << " also invert condition and change dest. to BB#"
                << NextBB->getNumber() << "\n");

   // Insert a new unconditional branch and fixup the destination of the
   // conditional one.  Also update the ImmBranch as well as adding a new entry
   // for the new branch.
   BuildMI(MBB, DebugLoc(), TII->get(AArch64::Bimm))
     .addMBB(MI->getOperand(CondBrMBBOperand).getMBB());
   MI->getOperand(CondBrMBBOperand).setMBB(NextBB);

   BBInfo[MBB->getNumber()].Size += TII->getInstSizeInBytes(MBB->back());

   // 26 bits written down in Bimm, specifying a multiple of 4.
   unsigned OffsetBits = 26 + 2;
   ImmBranches.push_back(ImmBranch(&MBB->back(), OffsetBits, false));

   adjustBBOffsetsAfter(MBB);
   return true;
 }
	//===-- AArch64BranchFixupPass.cpp - AArch64 branch fixup -----------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file contains a pass that fixes AArch64 branches which have ended up out
	// of range for their immediate operands.
	//
	//===----------------------------------------------------------------------===//

	#define DEBUG_TYPE "aarch64-branch-fixup"
	#include "AArch64.h"
	#include "AArch64InstrInfo.h"
	#include "Utils/AArch64BaseInfo.h"
	#include "llvm/CodeGen/MachineFunctionPass.h"
	#include "llvm/CodeGen/MachineInstrBuilder.h"
	#include "llvm/CodeGen/MachineRegisterInfo.h"
	#include "llvm/Support/Debug.h"
	#include "llvm/Support/Format.h"
	#include "llvm/Support/raw_ostream.h"
	#include "llvm/ADT/Statistic.h"
	using namespace llvm;

	STATISTIC(NumSplit, "Number of uncond branches inserted");
	STATISTIC(NumCBrFixed, "Number of cond branches fixed");

	/// Return the worst case padding that could result from unknown offset bits.
	/// This does not include alignment padding caused by known offset bits.
	///
	/// @param LogAlign log2(alignment)
	/// @param KnownBits Number of known low offset bits.
	static inline unsigned UnknownPadding(unsigned LogAlign, unsigned KnownBits) {
	if (KnownBits < LogAlign)
	return (1u << LogAlign) - (1u << KnownBits);
	return 0;
	}

	namespace {
	/// Due to limited PC-relative displacements, conditional branches to distant
	/// blocks may need converting into an unconditional equivalent. For example:
	/// tbz w1, #0, far_away
	/// becomes
	/// tbnz w1, #0, skip
	/// b far_away
	/// skip:
	class AArch64BranchFixup : public MachineFunctionPass {
	/// Information about the offset and size of a single basic block.
	struct BasicBlockInfo {
	/// Distance from the beginning of the function to the beginning of this
	/// basic block.
	///
	/// Offsets are computed assuming worst case padding before an aligned
	/// block. This means that subtracting basic block offsets always gives a
	/// conservative estimate of the real distance which may be smaller.
	///
	/// Because worst case padding is used, the computed offset of an aligned
	/// block may not actually be aligned.
	unsigned Offset;

	/// Size of the basic block in bytes. If the block contains inline
	/// assembly, this is a worst case estimate.
	///
	/// The size does not include any alignment padding whether from the
	/// beginning of the block, or from an aligned jump table at the end.
	unsigned Size;

	/// The number of low bits in Offset that are known to be exact. The
	/// remaining bits of Offset are an upper bound.
	uint8_t KnownBits;

	/// When non-zero, the block contains instructions (inline asm) of unknown
	/// size. The real size may be smaller than Size bytes by a multiple of 1
	/// << Unalign.
	uint8_t Unalign;

	BasicBlockInfo() : Offset(0), Size(0), KnownBits(0), Unalign(0) {}

	/// Compute the number of known offset bits internally to this block.
	/// This number should be used to predict worst case padding when
	/// splitting the block.
	unsigned internalKnownBits() const {
	unsigned Bits = Unalign ? Unalign : KnownBits;
	// If the block size isn't a multiple of the known bits, assume the
	// worst case padding.
	if (Size & ((1u << Bits) - 1))
	Bits = CountTrailingZeros_32(Size);
	return Bits;
	}

	/// Compute the offset immediately following this block. If LogAlign is
	/// specified, return the offset the successor block will get if it has
	/// this alignment.
	unsigned postOffset(unsigned LogAlign = 0) const {
	unsigned PO = Offset + Size;
	if (!LogAlign)
	return PO;
	// Add alignment padding from the terminator.
	return PO + UnknownPadding(LogAlign, internalKnownBits());
	}

	/// Compute the number of known low bits of postOffset. If this block
	/// contains inline asm, the number of known bits drops to the
	/// instruction alignment. An aligned terminator may increase the number
	/// of know bits.
	/// If LogAlign is given, also consider the alignment of the next block.
	unsigned postKnownBits(unsigned LogAlign = 0) const {
	return std::max(LogAlign, internalKnownBits());
	}
	};

	std::vector<BasicBlockInfo> BBInfo;

	/// One per immediate branch, keeping the machine instruction pointer,
	/// conditional or unconditional, the max displacement, and (if IsCond is
	/// true) the corresponding inverted branch opcode.
	struct ImmBranch {
	MachineInstr *MI;
	unsigned OffsetBits : 31;
	bool IsCond : 1;
	ImmBranch(MachineInstr *mi, unsigned offsetbits, bool cond)
	: MI(mi), OffsetBits(offsetbits), IsCond(cond) {}
	};

	/// Keep track of all the immediate branch instructions.
	///
	std::vector<ImmBranch> ImmBranches;

	MachineFunction *MF;
	const AArch64InstrInfo *TII;
	public:
	static char ID;
	AArch64BranchFixup() : MachineFunctionPass(ID) {}

	virtual bool runOnMachineFunction(MachineFunction &MF);

	virtual const char *getPassName() const {
	return "AArch64 branch fixup pass";
	}

	private:
	void initializeFunctionInfo();
	MachineBasicBlock splitBlockBeforeInstr(MachineInstr MI);
	void adjustBBOffsetsAfter(MachineBasicBlock *BB);
	bool isBBInRange(MachineInstr MI, MachineBasicBlock BB,
	unsigned OffsetBits);
	bool fixupImmediateBr(ImmBranch &Br);
	bool fixupConditionalBr(ImmBranch &Br);

	void computeBlockSize(MachineBasicBlock *MBB);
	unsigned getOffsetOf(MachineInstr *MI) const;
	void dumpBBs();
	void verify();
	};
	char AArch64BranchFixup::ID = 0;
	}

	/// check BBOffsets
	void AArch64BranchFixup::verify() {
	#ifndef NDEBUG
	for (MachineFunction::iterator MBBI = MF->begin(), E = MF->end();
	MBBI != E; ++MBBI) {
	MachineBasicBlock *MBB = MBBI;
	unsigned MBBId = MBB->getNumber();
	assert(!MBBId \|\| BBInfo[MBBId - 1].postOffset() <= BBInfo[MBBId].Offset);
	}
	#endif
	}

	/// print block size and offset information - debugging
	void AArch64BranchFixup::dumpBBs() {
	DEBUG({
	for (unsigned J = 0, E = BBInfo.size(); J !=E; ++J) {
	const BasicBlockInfo &BBI = BBInfo[J];
	dbgs() << format("%08x BB#%u\t", BBI.Offset, J)
	<< " kb=" << unsigned(BBI.KnownBits)
	<< " ua=" << unsigned(BBI.Unalign)
	<< format(" size=%#x\n", BBInfo[J].Size);
	}
	});
	}

	/// Returns an instance of the branch fixup pass.
	FunctionPass *llvm::createAArch64BranchFixupPass() {
	return new AArch64BranchFixup();
	}

	bool AArch64BranchFixup::runOnMachineFunction(MachineFunction &mf) {
	MF = &mf;
	DEBUG(dbgs() << "*** AArch64BranchFixup ****");
	TII = (const AArch64InstrInfo*)MF->getTarget().getInstrInfo();

	// This pass invalidates liveness information when it splits basic blocks.
	MF->getRegInfo().invalidateLiveness();

	// Renumber all of the machine basic blocks in the function, guaranteeing that
	// the numbers agree with the position of the block in the function.
	MF->RenumberBlocks();

	// Do the initial scan of the function, building up information about the
	// sizes of each block and location of each immediate branch.
	initializeFunctionInfo();

	// Iteratively fix up branches until there is no change.
	unsigned NoBRIters = 0;
	bool MadeChange = false;
	while (true) {
	DEBUG(dbgs() << "Beginning iteration #" << NoBRIters << '\n');
	bool BRChange = false;
	for (unsigned i = 0, e = ImmBranches.size(); i != e; ++i)
	BRChange \|= fixupImmediateBr(ImmBranches[i]);
	if (BRChange && ++NoBRIters > 30)
	report_fatal_error("Branch Fix Up pass failed to converge!");
	DEBUG(dumpBBs());

	if (!BRChange)
	break;
	MadeChange = true;
	}

	// After a while, this might be made debug-only, but it is not expensive.
	verify();

	DEBUG(dbgs() << '\n'; dumpBBs());

	BBInfo.clear();
	ImmBranches.clear();

	return MadeChange;
	}

	/// Return true if the specified basic block can fallthrough into the block
	/// immediately after it.
	static bool BBHasFallthrough(MachineBasicBlock *MBB) {
	// Get the next machine basic block in the function.
	MachineFunction::iterator MBBI = MBB;
	// Can't fall off end of function.
	if (llvm::next(MBBI) == MBB->getParent()->end())
	return false;

	MachineBasicBlock *NextBB = llvm::next(MBBI);
	for (MachineBasicBlock::succ_iterator I = MBB->succ_begin(),
	E = MBB->succ_end(); I != E; ++I)
	if (*I == NextBB)
	return true;

	return false;
	}

	/// Do the initial scan of the function, building up information about the sizes
	/// of each block, and each immediate branch.
	void AArch64BranchFixup::initializeFunctionInfo() {
	BBInfo.clear();
	BBInfo.resize(MF->getNumBlockIDs());

	// First thing, compute the size of all basic blocks, and see if the function
	// has any inline assembly in it. If so, we have to be conservative about
	// alignment assumptions, as we don't know for sure the size of any
	// instructions in the inline assembly.
	for (MachineFunction::iterator I = MF->begin(), E = MF->end(); I != E; ++I)
	computeBlockSize(I);

	// The known bits of the entry block offset are determined by the function
	// alignment.
	BBInfo.front().KnownBits = MF->getAlignment();

	// Compute block offsets and known bits.
	adjustBBOffsetsAfter(MF->begin());

	// Now go back through the instructions and build up our data structures.
	for (MachineFunction::iterator MBBI = MF->begin(), E = MF->end();
	MBBI != E; ++MBBI) {
	MachineBasicBlock &MBB = *MBBI;

	for (MachineBasicBlock::iterator I = MBB.begin(), E = MBB.end();
	I != E; ++I) {
	if (I->isDebugValue())
	continue;

	int Opc = I->getOpcode();
	if (I->isBranch()) {
	bool IsCond = false;

	// The offsets encoded in instructions here scale by the instruction
	// size (4 bytes), effectively increasing their range by 2 bits.
	unsigned Bits = 0;
	switch (Opc) {
	default:
	continue; // Ignore other JT branches
	case AArch64::TBZxii:
	case AArch64::TBZwii:
	case AArch64::TBNZxii:
	case AArch64::TBNZwii:
	IsCond = true;
	Bits = 14 + 2;
	break;
	case AArch64::Bcc:
	case AArch64::CBZx:
	case AArch64::CBZw:
	case AArch64::CBNZx:
	case AArch64::CBNZw:
	IsCond = true;
	Bits = 19 + 2;
	break;
	case AArch64::Bimm:
	Bits = 26 + 2;
	break;
	}

	// Record this immediate branch.
	ImmBranches.push_back(ImmBranch(I, Bits, IsCond));
	}
	}
	}
	}

	/// Compute the size and some alignment information for MBB. This function
	/// updates BBInfo directly.
	void AArch64BranchFixup::computeBlockSize(MachineBasicBlock *MBB) {
	BasicBlockInfo &BBI = BBInfo[MBB->getNumber()];
	BBI.Size = 0;
	BBI.Unalign = 0;

	for (MachineBasicBlock::iterator I = MBB->begin(), E = MBB->end(); I != E;
	++I) {
	BBI.Size += TII->getInstSizeInBytes(*I);
	// For inline asm, GetInstSizeInBytes returns a conservative estimate.
	// The actual size may be smaller, but still a multiple of the instr size.
	if (I->isInlineAsm())
	BBI.Unalign = 2;
	}
	}

	/// Return the current offset of the specified machine instruction from the
	/// start of the function. This offset changes as stuff is moved around inside
	/// the function.
	unsigned AArch64BranchFixup::getOffsetOf(MachineInstr *MI) const {
	MachineBasicBlock *MBB = MI->getParent();

	// The offset is composed of two things: the sum of the sizes of all MBB's
	// before this instruction's block, and the offset from the start of the block
	// it is in.
	unsigned Offset = BBInfo[MBB->getNumber()].Offset;

	// Sum instructions before MI in MBB.
	for (MachineBasicBlock::iterator I = MBB->begin(); &*I != MI; ++I) {
	assert(I != MBB->end() && "Didn't find MI in its own basic block?");
	Offset += TII->getInstSizeInBytes(*I);
	}
	return Offset;
	}

	/// Split the basic block containing MI into two blocks, which are joined by
	/// an unconditional branch. Update data structures and renumber blocks to
	/// account for this change and returns the newly created block.
	MachineBasicBlock *
	AArch64BranchFixup::splitBlockBeforeInstr(MachineInstr *MI) {
	MachineBasicBlock *OrigBB = MI->getParent();

	// Create a new MBB for the code after the OrigBB.
	MachineBasicBlock *NewBB =
	MF->CreateMachineBasicBlock(OrigBB->getBasicBlock());
	MachineFunction::iterator MBBI = OrigBB; ++MBBI;
	MF->insert(MBBI, NewBB);

	// Splice the instructions starting with MI over to NewBB.
	NewBB->splice(NewBB->end(), OrigBB, MI, OrigBB->end());

	// Add an unconditional branch from OrigBB to NewBB.
	// Note the new unconditional branch is not being recorded.
	// There doesn't seem to be meaningful DebugInfo available; this doesn't
	// correspond to anything in the source.
	BuildMI(OrigBB, DebugLoc(), TII->get(AArch64::Bimm)).addMBB(NewBB);
	++NumSplit;

	// Update the CFG. All succs of OrigBB are now succs of NewBB.
	NewBB->transferSuccessors(OrigBB);

	// OrigBB branches to NewBB.
	OrigBB->addSuccessor(NewBB);

	// Update internal data structures to account for the newly inserted MBB.
	MF->RenumberBlocks(NewBB);

	// Insert an entry into BBInfo to align it properly with the (newly
	// renumbered) block numbers.
	BBInfo.insert(BBInfo.begin() + NewBB->getNumber(), BasicBlockInfo());

	// Figure out how large the OrigBB is. As the first half of the original
	// block, it cannot contain a tablejump. The size includes
	// the new jump we added. (It should be possible to do this without
	// recounting everything, but it's very confusing, and this is rarely
	// executed.)
	computeBlockSize(OrigBB);

	// Figure out how large the NewMBB is. As the second half of the original
	// block, it may contain a tablejump.
	computeBlockSize(NewBB);

	// All BBOffsets following these blocks must be modified.
	adjustBBOffsetsAfter(OrigBB);

	return NewBB;
	}

	void AArch64BranchFixup::adjustBBOffsetsAfter(MachineBasicBlock *BB) {
	unsigned BBNum = BB->getNumber();
	for(unsigned i = BBNum + 1, e = MF->getNumBlockIDs(); i < e; ++i) {
	// Get the offset and known bits at the end of the layout predecessor.
	// Include the alignment of the current block.
	unsigned LogAlign = MF->getBlockNumbered(i)->getAlignment();
	unsigned Offset = BBInfo[i - 1].postOffset(LogAlign);
	unsigned KnownBits = BBInfo[i - 1].postKnownBits(LogAlign);

	// This is where block i begins. Stop if the offset is already correct,
	// and we have updated 2 blocks. This is the maximum number of blocks
	// changed before calling this function.
	if (i > BBNum + 2 &&
	BBInfo[i].Offset == Offset &&
	BBInfo[i].KnownBits == KnownBits)
	break;

	BBInfo[i].Offset = Offset;
	BBInfo[i].KnownBits = KnownBits;
	}
	}

	/// Returns true if the distance between specific MI and specific BB can fit in
	/// MI's displacement field.
	bool AArch64BranchFixup::isBBInRange(MachineInstr *MI,
	MachineBasicBlock *DestBB,
	unsigned OffsetBits) {
	int64_t BrOffset = getOffsetOf(MI);
	int64_t DestOffset = BBInfo[DestBB->getNumber()].Offset;

	DEBUG(dbgs() << "Branch of destination BB#" << DestBB->getNumber()
	<< " from BB#" << MI->getParent()->getNumber()
	<< " bits available=" << OffsetBits
	<< " from " << getOffsetOf(MI) << " to " << DestOffset
	<< " offset " << int(DestOffset-BrOffset) << "\t" << *MI);

	return isIntN(OffsetBits, DestOffset - BrOffset);
	}

	/// Fix up an immediate branch whose destination is too far away to fit in its
	/// displacement field.
	bool AArch64BranchFixup::fixupImmediateBr(ImmBranch &Br) {
	MachineInstr *MI = Br.MI;
	MachineBasicBlock *DestBB = 0;
	for (unsigned i = 0, e = MI->getNumOperands(); i != e; ++i) {
	if (MI->getOperand(i).isMBB()) {
	DestBB = MI->getOperand(i).getMBB();
	break;
	}
	}
	assert(DestBB && "Branch with no destination BB?");

	// Check to see if the DestBB is already in-range.
	if (isBBInRange(MI, DestBB, Br.OffsetBits))
	return false;

	assert(Br.IsCond && "Only conditional branches should need fixup");
	return fixupConditionalBr(Br);
	}

	/// Fix up a conditional branch whose destination is too far away to fit in its
	/// displacement field. It is converted to an inverse conditional branch + an
	/// unconditional branch to the destination.
	bool
	AArch64BranchFixup::fixupConditionalBr(ImmBranch &Br) {
	MachineInstr *MI = Br.MI;
	MachineBasicBlock *MBB = MI->getParent();
	unsigned CondBrMBBOperand = 0;

	// The general idea is to add an unconditional branch to the destination and
	// invert the conditional branch to jump over it. Complications occur around
	// fallthrough and unreachable ends to the block.
	// b.lt L1
	// =>
	// b.ge L2
	// b L1
	// L2:

	// First we invert the conditional branch, by creating a replacement if
	// necessary. This if statement contains all the special handling of different
	// branch types.
	if (MI->getOpcode() == AArch64::Bcc) {
	// The basic block is operand number 1 for Bcc
	CondBrMBBOperand = 1;

	A64CC::CondCodes CC = (A64CC::CondCodes)MI->getOperand(0).getImm();
	CC = A64InvertCondCode(CC);
	MI->getOperand(0).setImm(CC);
	} else {
	MachineInstrBuilder InvertedMI;
	int InvertedOpcode;
	switch (MI->getOpcode()) {
	default: llvm_unreachable("Unknown branch type");
	case AArch64::TBZxii: InvertedOpcode = AArch64::TBNZxii; break;
	case AArch64::TBZwii: InvertedOpcode = AArch64::TBNZwii; break;
	case AArch64::TBNZxii: InvertedOpcode = AArch64::TBZxii; break;
	case AArch64::TBNZwii: InvertedOpcode = AArch64::TBZwii; break;
	case AArch64::CBZx: InvertedOpcode = AArch64::CBNZx; break;
	case AArch64::CBZw: InvertedOpcode = AArch64::CBNZw; break;
	case AArch64::CBNZx: InvertedOpcode = AArch64::CBZx; break;
	case AArch64::CBNZw: InvertedOpcode = AArch64::CBZw; break;
	}

	InvertedMI = BuildMI(*MBB, MI, MI->getDebugLoc(), TII->get(InvertedOpcode));
	for (unsigned i = 0, e= MI->getNumOperands(); i != e; ++i) {
	InvertedMI.addOperand(MI->getOperand(i));
	if (MI->getOperand(i).isMBB())
	CondBrMBBOperand = i;
	}

	MI->eraseFromParent();
	MI = Br.MI = InvertedMI;
	}

	// If the branch is at the end of its MBB and that has a fall-through block,
	// direct the updated conditional branch to the fall-through
	// block. Otherwise, split the MBB before the next instruction.
	MachineInstr *BMI = &MBB->back();
	bool NeedSplit = (BMI != MI) \|\| !BBHasFallthrough(MBB);

	++NumCBrFixed;
	if (BMI != MI) {
	if (llvm::next(MachineBasicBlock::iterator(MI)) == prior(MBB->end()) &&
	BMI->getOpcode() == AArch64::Bimm) {
	// Last MI in the BB is an unconditional branch. We can swap destinations:
	// b.eq L1 (temporarily b.ne L1 after first change)
	// b L2
	// =>
	// b.ne L2
	// b L1
	MachineBasicBlock *NewDest = BMI->getOperand(0).getMBB();
	if (isBBInRange(MI, NewDest, Br.OffsetBits)) {
	DEBUG(dbgs() << " Invert Bcc condition and swap its destination with "
	<< *BMI);
	MachineBasicBlock *DestBB = MI->getOperand(CondBrMBBOperand).getMBB();
	BMI->getOperand(0).setMBB(DestBB);
	MI->getOperand(CondBrMBBOperand).setMBB(NewDest);
	return true;
	}
	}
	}

	if (NeedSplit) {
	MachineBasicBlock::iterator MBBI = MI; ++MBBI;
	splitBlockBeforeInstr(MBBI);
	// No need for the branch to the next block. We're adding an unconditional
	// branch to the destination.
	int delta = TII->getInstSizeInBytes(MBB->back());
	BBInfo[MBB->getNumber()].Size -= delta;
	MBB->back().eraseFromParent();
	// BBInfo[SplitBB].Offset is wrong temporarily, fixed below
	}

	// After splitting and removing the unconditional branch from the original BB,
	// the structure is now:
	// oldbb:
	// [things]
	// b.invertedCC L1
	// splitbb/fallthroughbb:
	// [old b L2/real continuation]
	//
	// We now have to change the conditional branch to point to splitbb and add an
	// unconditional branch after it to L1, giving the final structure:
	// oldbb:
	// [things]
	// b.invertedCC splitbb
	// b L1
	// splitbb/fallthroughbb:
	// [old b L2/real continuation]
	MachineBasicBlock *NextBB = llvm::next(MachineFunction::iterator(MBB));

	DEBUG(dbgs() << " Insert B to BB#"
	<< MI->getOperand(CondBrMBBOperand).getMBB()->getNumber()
	<< " also invert condition and change dest. to BB#"
	<< NextBB->getNumber() << "\n");

	// Insert a new unconditional branch and fixup the destination of the
	// conditional one. Also update the ImmBranch as well as adding a new entry
	// for the new branch.
	BuildMI(MBB, DebugLoc(), TII->get(AArch64::Bimm))
	.addMBB(MI->getOperand(CondBrMBBOperand).getMBB());
	MI->getOperand(CondBrMBBOperand).setMBB(NextBB);

	BBInfo[MBB->getNumber()].Size += TII->getInstSizeInBytes(MBB->back());

	// 26 bits written down in Bimm, specifying a multiple of 4.
	unsigned OffsetBits = 26 + 2;
	ImmBranches.push_back(ImmBranch(&MBB->back(), OffsetBits, false));

	adjustBBOffsetsAfter(MBB);
	return true;
	}