llvm-6502/lib/Target/SparcV9/RegAlloc/PhyRegAlloc.cpp
2003-07-02 01:24:00 +00:00

1224 lines
45 KiB
C++

//===-- PhyRegAlloc.cpp ---------------------------------------------------===//
//
// Register allocation for LLVM.
//
//===----------------------------------------------------------------------===//
#include "llvm/CodeGen/RegisterAllocation.h"
#include "RegAllocCommon.h"
#include "RegClass.h"
#include "llvm/CodeGen/IGNode.h"
#include "llvm/CodeGen/PhyRegAlloc.h"
#include "llvm/CodeGen/MachineInstrBuilder.h"
#include "llvm/CodeGen/MachineInstrAnnot.h"
#include "llvm/CodeGen/MachineFunction.h"
#include "llvm/CodeGen/MachineFunctionInfo.h"
#include "llvm/CodeGen/FunctionLiveVarInfo.h"
#include "llvm/Analysis/LoopInfo.h"
#include "llvm/Target/TargetMachine.h"
#include "llvm/Target/TargetFrameInfo.h"
#include "llvm/Target/TargetInstrInfo.h"
#include "llvm/Function.h"
#include "llvm/Type.h"
#include "llvm/iOther.h"
#include "Support/STLExtras.h"
#include "Support/CommandLine.h"
#include <math.h>
using std::cerr;
using std::vector;
RegAllocDebugLevel_t DEBUG_RA;
static cl::opt<RegAllocDebugLevel_t, true>
DRA_opt("dregalloc", cl::Hidden, cl::location(DEBUG_RA),
cl::desc("enable register allocation debugging information"),
cl::values(
clEnumValN(RA_DEBUG_None , "n", "disable debug output"),
clEnumValN(RA_DEBUG_Results, "y", "debug output for allocation results"),
clEnumValN(RA_DEBUG_Coloring, "c", "debug output for graph coloring step"),
clEnumValN(RA_DEBUG_Interference,"ig","debug output for interference graphs"),
clEnumValN(RA_DEBUG_LiveRanges , "lr","debug output for live ranges"),
clEnumValN(RA_DEBUG_Verbose, "v", "extra debug output"),
0));
//----------------------------------------------------------------------------
// RegisterAllocation pass front end...
//----------------------------------------------------------------------------
namespace {
class RegisterAllocator : public FunctionPass {
TargetMachine &Target;
public:
inline RegisterAllocator(TargetMachine &T) : Target(T) {}
const char *getPassName() const { return "Register Allocation"; }
bool runOnFunction(Function &F) {
if (DEBUG_RA)
cerr << "\n********* Function "<< F.getName() << " ***********\n";
PhyRegAlloc PRA(&F, Target, &getAnalysis<FunctionLiveVarInfo>(),
&getAnalysis<LoopInfo>());
PRA.allocateRegisters();
if (DEBUG_RA) cerr << "\nRegister allocation complete!\n";
return false;
}
virtual void getAnalysisUsage(AnalysisUsage &AU) const {
AU.addRequired<LoopInfo>();
AU.addRequired<FunctionLiveVarInfo>();
}
};
}
Pass *getRegisterAllocator(TargetMachine &T) {
return new RegisterAllocator(T);
}
//----------------------------------------------------------------------------
// Constructor: Init local composite objects and create register classes.
//----------------------------------------------------------------------------
PhyRegAlloc::PhyRegAlloc(Function *F, const TargetMachine& tm,
FunctionLiveVarInfo *Lvi, LoopInfo *LDC)
: TM(tm), Fn(F), MF(MachineFunction::get(F)), LVI(Lvi),
LRI(F, tm, RegClassList), MRI(tm.getRegInfo()),
NumOfRegClasses(MRI.getNumOfRegClasses()), LoopDepthCalc(LDC) {
// create each RegisterClass and put in RegClassList
//
for (unsigned rc=0; rc != NumOfRegClasses; rc++)
RegClassList.push_back(new RegClass(F, MRI.getMachineRegClass(rc),
&ResColList));
}
//----------------------------------------------------------------------------
// Destructor: Deletes register classes
//----------------------------------------------------------------------------
PhyRegAlloc::~PhyRegAlloc() {
for ( unsigned rc=0; rc < NumOfRegClasses; rc++)
delete RegClassList[rc];
AddedInstrMap.clear();
}
//----------------------------------------------------------------------------
// This method initally creates interference graphs (one in each reg class)
// and IGNodeList (one in each IG). The actual nodes will be pushed later.
//----------------------------------------------------------------------------
void PhyRegAlloc::createIGNodeListsAndIGs() {
if (DEBUG_RA >= RA_DEBUG_LiveRanges) cerr << "Creating LR lists ...\n";
// hash map iterator
LiveRangeMapType::const_iterator HMI = LRI.getLiveRangeMap()->begin();
// hash map end
LiveRangeMapType::const_iterator HMIEnd = LRI.getLiveRangeMap()->end();
for (; HMI != HMIEnd ; ++HMI ) {
if (HMI->first) {
LiveRange *L = HMI->second; // get the LiveRange
if (!L) {
if (DEBUG_RA)
cerr << "\n**** ?!?WARNING: NULL LIVE RANGE FOUND FOR: "
<< RAV(HMI->first) << "****\n";
continue;
}
// if the Value * is not null, and LR is not yet written to the IGNodeList
if (!(L->getUserIGNode()) ) {
RegClass *const RC = // RegClass of first value in the LR
RegClassList[ L->getRegClass()->getID() ];
RC->addLRToIG(L); // add this LR to an IG
}
}
}
// init RegClassList
for ( unsigned rc=0; rc < NumOfRegClasses ; rc++)
RegClassList[rc]->createInterferenceGraph();
if (DEBUG_RA >= RA_DEBUG_LiveRanges) cerr << "LRLists Created!\n";
}
//----------------------------------------------------------------------------
// This method will add all interferences at for a given instruction.
// Interence occurs only if the LR of Def (Inst or Arg) is of the same reg
// class as that of live var. The live var passed to this function is the
// LVset AFTER the instruction
//----------------------------------------------------------------------------
void PhyRegAlloc::addInterference(const Value *Def,
const ValueSet *LVSet,
bool isCallInst) {
ValueSet::const_iterator LIt = LVSet->begin();
// get the live range of instruction
//
const LiveRange *const LROfDef = LRI.getLiveRangeForValue( Def );
IGNode *const IGNodeOfDef = LROfDef->getUserIGNode();
assert( IGNodeOfDef );
RegClass *const RCOfDef = LROfDef->getRegClass();
// for each live var in live variable set
//
for ( ; LIt != LVSet->end(); ++LIt) {
if (DEBUG_RA >= RA_DEBUG_Verbose)
cerr << "< Def=" << RAV(Def) << ", Lvar=" << RAV(*LIt) << "> ";
// get the live range corresponding to live var
//
LiveRange *LROfVar = LRI.getLiveRangeForValue(*LIt);
// LROfVar can be null if it is a const since a const
// doesn't have a dominating def - see Assumptions above
//
if (LROfVar)
if (LROfDef != LROfVar) // do not set interf for same LR
if (RCOfDef == LROfVar->getRegClass()) // 2 reg classes are the same
RCOfDef->setInterference( LROfDef, LROfVar);
}
}
//----------------------------------------------------------------------------
// For a call instruction, this method sets the CallInterference flag in
// the LR of each variable live int the Live Variable Set live after the
// call instruction (except the return value of the call instruction - since
// the return value does not interfere with that call itself).
//----------------------------------------------------------------------------
void PhyRegAlloc::setCallInterferences(const MachineInstr *MInst,
const ValueSet *LVSetAft) {
if (DEBUG_RA >= RA_DEBUG_Interference)
cerr << "\n For call inst: " << *MInst;
// for each live var in live variable set after machine inst
//
for (ValueSet::const_iterator LIt = LVSetAft->begin(), LEnd = LVSetAft->end();
LIt != LEnd; ++LIt) {
// get the live range corresponding to live var
//
LiveRange *const LR = LRI.getLiveRangeForValue(*LIt );
// LR can be null if it is a const since a const
// doesn't have a dominating def - see Assumptions above
//
if (LR ) {
if (DEBUG_RA >= RA_DEBUG_Interference) {
cerr << "\n\tLR after Call: ";
printSet(*LR);
}
LR->setCallInterference();
if (DEBUG_RA >= RA_DEBUG_Interference) {
cerr << "\n ++After adding call interference for LR: " ;
printSet(*LR);
}
}
}
// Now find the LR of the return value of the call
// We do this because, we look at the LV set *after* the instruction
// to determine, which LRs must be saved across calls. The return value
// of the call is live in this set - but it does not interfere with call
// (i.e., we can allocate a volatile register to the return value)
//
CallArgsDescriptor* argDesc = CallArgsDescriptor::get(MInst);
if (const Value *RetVal = argDesc->getReturnValue()) {
LiveRange *RetValLR = LRI.getLiveRangeForValue( RetVal );
assert( RetValLR && "No LR for RetValue of call");
RetValLR->clearCallInterference();
}
// If the CALL is an indirect call, find the LR of the function pointer.
// That has a call interference because it conflicts with outgoing args.
if (const Value *AddrVal = argDesc->getIndirectFuncPtr()) {
LiveRange *AddrValLR = LRI.getLiveRangeForValue( AddrVal );
assert( AddrValLR && "No LR for indirect addr val of call");
AddrValLR->setCallInterference();
}
}
//----------------------------------------------------------------------------
// This method will walk thru code and create interferences in the IG of
// each RegClass. Also, this method calculates the spill cost of each
// Live Range (it is done in this method to save another pass over the code).
//----------------------------------------------------------------------------
void PhyRegAlloc::buildInterferenceGraphs()
{
if (DEBUG_RA >= RA_DEBUG_Interference)
cerr << "Creating interference graphs ...\n";
unsigned BBLoopDepthCost;
for (MachineFunction::iterator BBI = MF.begin(), BBE = MF.end();
BBI != BBE; ++BBI) {
const MachineBasicBlock &MBB = *BBI;
const BasicBlock *BB = MBB.getBasicBlock();
// find the 10^(loop_depth) of this BB
//
BBLoopDepthCost = (unsigned)pow(10.0, LoopDepthCalc->getLoopDepth(BB));
// get the iterator for machine instructions
//
MachineBasicBlock::const_iterator MII = MBB.begin();
// iterate over all the machine instructions in BB
//
for ( ; MII != MBB.end(); ++MII) {
const MachineInstr *MInst = *MII;
// get the LV set after the instruction
//
const ValueSet &LVSetAI = LVI->getLiveVarSetAfterMInst(MInst, BB);
bool isCallInst = TM.getInstrInfo().isCall(MInst->getOpCode());
if (isCallInst ) {
// set the isCallInterference flag of each live range wich extends
// accross this call instruction. This information is used by graph
// coloring algo to avoid allocating volatile colors to live ranges
// that span across calls (since they have to be saved/restored)
//
setCallInterferences(MInst, &LVSetAI);
}
// iterate over all MI operands to find defs
//
for (MachineInstr::const_val_op_iterator OpI = MInst->begin(),
OpE = MInst->end(); OpI != OpE; ++OpI) {
if (OpI.isDefOnly() || OpI.isDefAndUse()) // create a new LR since def
addInterference(*OpI, &LVSetAI, isCallInst);
// Calculate the spill cost of each live range
//
LiveRange *LR = LRI.getLiveRangeForValue(*OpI);
if (LR) LR->addSpillCost(BBLoopDepthCost);
}
// if there are multiple defs in this instruction e.g. in SETX
//
if (TM.getInstrInfo().isPseudoInstr(MInst->getOpCode()))
addInterf4PseudoInstr(MInst);
// Also add interference for any implicit definitions in a machine
// instr (currently, only calls have this).
//
unsigned NumOfImpRefs = MInst->getNumImplicitRefs();
for (unsigned z=0; z < NumOfImpRefs; z++)
if (MInst->getImplicitOp(z).opIsDefOnly() ||
MInst->getImplicitOp(z).opIsDefAndUse())
addInterference( MInst->getImplicitRef(z), &LVSetAI, isCallInst );
} // for all machine instructions in BB
} // for all BBs in function
// add interferences for function arguments. Since there are no explict
// defs in the function for args, we have to add them manually
//
addInterferencesForArgs();
if (DEBUG_RA >= RA_DEBUG_Interference)
cerr << "Interference graphs calculated!\n";
}
//--------------------------------------------------------------------------
// Pseudo instructions will be exapnded to multiple instructions by the
// assembler. Consequently, all the opernds must get distinct registers.
// Therefore, we mark all operands of a pseudo instruction as they interfere
// with one another.
//--------------------------------------------------------------------------
void PhyRegAlloc::addInterf4PseudoInstr(const MachineInstr *MInst) {
bool setInterf = false;
// iterate over MI operands to find defs
//
for (MachineInstr::const_val_op_iterator It1 = MInst->begin(),
ItE = MInst->end(); It1 != ItE; ++It1) {
const LiveRange *LROfOp1 = LRI.getLiveRangeForValue(*It1);
assert((LROfOp1 || !It1.isUseOnly())&& "No LR for Def in PSEUDO insruction");
MachineInstr::const_val_op_iterator It2 = It1;
for (++It2; It2 != ItE; ++It2) {
const LiveRange *LROfOp2 = LRI.getLiveRangeForValue(*It2);
if (LROfOp2) {
RegClass *RCOfOp1 = LROfOp1->getRegClass();
RegClass *RCOfOp2 = LROfOp2->getRegClass();
if (RCOfOp1 == RCOfOp2 ){
RCOfOp1->setInterference( LROfOp1, LROfOp2 );
setInterf = true;
}
} // if Op2 has a LR
} // for all other defs in machine instr
} // for all operands in an instruction
if (!setInterf && MInst->getNumOperands() > 2) {
cerr << "\nInterf not set for any operand in pseudo instr:\n";
cerr << *MInst;
assert(0 && "Interf not set for pseudo instr with > 2 operands" );
}
}
//----------------------------------------------------------------------------
// This method will add interferences for incoming arguments to a function.
//----------------------------------------------------------------------------
void PhyRegAlloc::addInterferencesForArgs() {
// get the InSet of root BB
const ValueSet &InSet = LVI->getInSetOfBB(&Fn->front());
for (Function::const_aiterator AI = Fn->abegin(); AI != Fn->aend(); ++AI) {
// add interferences between args and LVars at start
addInterference(AI, &InSet, false);
if (DEBUG_RA >= RA_DEBUG_Interference)
cerr << " - %% adding interference for argument " << RAV(AI) << "\n";
}
}
//----------------------------------------------------------------------------
// This method is called after register allocation is complete to set the
// allocated reisters in the machine code. This code will add register numbers
// to MachineOperands that contain a Value. Also it calls target specific
// methods to produce caller saving instructions. At the end, it adds all
// additional instructions produced by the register allocator to the
// instruction stream.
//----------------------------------------------------------------------------
//-----------------------------
// Utility functions used below
//-----------------------------
inline void
InsertBefore(MachineInstr* newMI,
MachineBasicBlock& MBB,
MachineBasicBlock::iterator& MII)
{
MII = MBB.insert(MII, newMI);
++MII;
}
inline void
InsertAfter(MachineInstr* newMI,
MachineBasicBlock& MBB,
MachineBasicBlock::iterator& MII)
{
++MII; // insert before the next instruction
MII = MBB.insert(MII, newMI);
}
inline void
DeleteInstruction(MachineBasicBlock& MBB,
MachineBasicBlock::iterator& MII)
{
MII = MBB.erase(MII);
}
inline void
SubstituteInPlace(MachineInstr* newMI,
MachineBasicBlock& MBB,
MachineBasicBlock::iterator MII)
{
*MII = newMI;
}
inline void
PrependInstructions(vector<MachineInstr *> &IBef,
MachineBasicBlock& MBB,
MachineBasicBlock::iterator& MII,
const std::string& msg)
{
if (!IBef.empty())
{
MachineInstr* OrigMI = *MII;
std::vector<MachineInstr *>::iterator AdIt;
for (AdIt = IBef.begin(); AdIt != IBef.end() ; ++AdIt)
{
if (DEBUG_RA) {
if (OrigMI) cerr << "For MInst:\n " << *OrigMI;
cerr << msg << "PREPENDed instr:\n " << **AdIt << "\n";
}
InsertBefore(*AdIt, MBB, MII);
}
}
}
inline void
AppendInstructions(std::vector<MachineInstr *> &IAft,
MachineBasicBlock& MBB,
MachineBasicBlock::iterator& MII,
const std::string& msg)
{
if (!IAft.empty())
{
MachineInstr* OrigMI = *MII;
std::vector<MachineInstr *>::iterator AdIt;
for ( AdIt = IAft.begin(); AdIt != IAft.end() ; ++AdIt )
{
if (DEBUG_RA) {
if (OrigMI) cerr << "For MInst:\n " << *OrigMI;
cerr << msg << "APPENDed instr:\n " << **AdIt << "\n";
}
InsertAfter(*AdIt, MBB, MII);
}
}
}
void PhyRegAlloc::updateInstruction(MachineInstr* MInst, BasicBlock* BB)
{
unsigned Opcode = MInst->getOpCode();
// Reset tmp stack positions so they can be reused for each machine instr.
MF.getInfo()->popAllTempValues();
// First, set the registers for operands in the machine instruction
// if a register was successfully allocated. Do this first because we
// will need to know which registers are already used by this instr'n.
//
for (unsigned OpNum=0; OpNum < MInst->getNumOperands(); ++OpNum)
{
MachineOperand& Op = MInst->getOperand(OpNum);
if (Op.getType() == MachineOperand::MO_VirtualRegister ||
Op.getType() == MachineOperand::MO_CCRegister)
{
const Value *const Val = Op.getVRegValue();
if (const LiveRange* LR = LRI.getLiveRangeForValue(Val))
if (LR->hasColor())
MInst->SetRegForOperand(OpNum,
MRI.getUnifiedRegNum(LR->getRegClass()->getID(),
LR->getColor()));
}
} // for each operand
// Mark that the operands have been updated. setRelRegsUsedByThisInst()
// is called to find registers used by each MachineInst, and it should not
// be used for an instruction until this is done. This flag just serves
// as a sanity check.
OperandsColoredMap[MInst] = true;
// Now insert special instructions (if necessary) for call/return
// instructions. Do this before inserting spill code since some
// registers must be used by outgoing call arguments or the return value
// of a call, and spill code should not use those registers.
//
if (TM.getInstrInfo().isCall(Opcode) ||
TM.getInstrInfo().isReturn(Opcode)) {
AddedInstrns &AI = AddedInstrMap[MInst];
if (TM.getInstrInfo().isCall(Opcode))
MRI.colorCallArgs(MInst, LRI, &AI, *this, BB);
else if (TM.getInstrInfo().isReturn(Opcode))
MRI.colorRetValue(MInst, LRI, &AI);
}
// Now insert spill code for remaining operands not allocated to
// registers. This must be done even for call return instructions
// since those are not handled by the special code above.
for (unsigned OpNum=0; OpNum < MInst->getNumOperands(); ++OpNum)
{
MachineOperand& Op = MInst->getOperand(OpNum);
if (Op.getType() == MachineOperand::MO_VirtualRegister ||
Op.getType() == MachineOperand::MO_CCRegister)
{
const Value* Val = Op.getVRegValue();
if (const LiveRange *LR = LRI.getLiveRangeForValue(Val))
if (! LR->hasColor())
insertCode4SpilledLR(LR, MInst, BB, OpNum);
}
} // for each operand
}
void PhyRegAlloc::updateMachineCode()
{
// Insert any instructions needed at method entry
MachineBasicBlock::iterator MII = MF.front().begin();
PrependInstructions(AddedInstrAtEntry.InstrnsBefore, MF.front(), MII,
"At function entry: \n");
assert(AddedInstrAtEntry.InstrnsAfter.empty() &&
"InstrsAfter should be unnecessary since we are just inserting at "
"the function entry point here.");
for (MachineFunction::iterator BBI = MF.begin(), BBE = MF.end();
BBI != BBE; ++BBI) {
MachineBasicBlock &MBB = *BBI;
// Iterate over all machine instructions in BB and mark operands with
// their assigned registers or insert spill code, as appropriate.
// Also, fix operands of call/return instructions.
//
for (MachineBasicBlock::iterator MII = MBB.begin(); MII != MBB.end(); ++MII)
if (!TM.getInstrInfo().isDummyPhiInstr((*MII)->getOpCode())) // ignore Phis
updateInstruction(*MII, MBB.getBasicBlock());
// Now, move code out of delay slots of branches and returns if needed.
// (Also, move "after" code from calls to the last delay slot instruction.)
// Moving code out of delay slots is needed in 2 situations:
// (1) If this is a branch and it needs instructions inserted after it,
// move any existing instructions out of the delay slot so that the
// instructions can go into the delay slot. This only supports the
// case that #instrsAfter <= #delay slots.
//
// (2) If any instruction in the delay slot needs
// instructions inserted, move it out of the delay slot and before the
// branch because putting code before or after it would be VERY BAD!
//
// If the annul bit of the branch is set, neither of these is legal!
// If so, we need to handle spill differently but annulling is not yet used.
//
for (MachineBasicBlock::iterator MII = MBB.begin();
MII != MBB.end(); ++MII)
if (unsigned delaySlots =
TM.getInstrInfo().getNumDelaySlots((*MII)->getOpCode()))
{
assert(delaySlots==1 && "Not handling multiple delay slots!");
MachineInstr *MInst = *MII;
MachineInstr *MDelayInst = *(MII+1);
// Check the 2 conditions above:
// (1) Does a branch need instructions added after it?
// (2) O/w does delay slot instr. need instrns before or after?
bool isBranch = (TM.getInstrInfo().isBranch((*MII)->getOpCode()) ||
TM.getInstrInfo().isReturn((*MII)->getOpCode()));
bool cond1 = isBranch && AddedInstrMap[MInst].InstrnsAfter.size() > 0;
bool cond2 = (AddedInstrMap.count(MDelayInst) ||
AddedInstrMap[MDelayInst].InstrnsAfter.size() > 0);
if (cond1 || cond2)
{
// Move delay slot instrn before the preceding branch.
// InsertBefore() modifies MII to point to the branch again.
assert(((*MII)->getOpCodeFlags() & AnnulFlag) == 0 &&
"FIXME: Annul bit must be turned off here!");
InsertBefore(MDelayInst, MBB, MII);
// In case (1), delete it and don't replace with anything!
// Otherwise (i.e., case (2) only) replace it with a NOP.
if (cond1) {
assert(AddedInstrMap[MInst].InstrnsAfter.size() <= delaySlots &&
"Cannot put more than #delaySlots spill instrns after "
"branch or return! Need to handle spill differently.");
DeleteInstruction(MBB, MII); // MII now points to next inst.
}
else {
MachineInstr* nopI =BuildMI(TM.getInstrInfo().getNOPOpCode(),1);
SubstituteInPlace(nopI, MBB, MII+1); // replace with NOP
}
}
// If this is not a branch or return (probably a call),
// the Instrnsafter, if any, must really go after the last
// delay slot. Move the InstrAfter to the instr. in that slot.
// We must do this after the previous code because the instructions
// in delay slots may get moved out by that code.
//
if (!isBranch)
move2DelayedInstr(MInst, *(MII+delaySlots));
}
// Finally iterate over all instructions in BB and insert before/after
//
for (MachineBasicBlock::iterator MII = MBB.begin();
MII != MBB.end(); ++MII) {
MachineInstr *MInst = *MII;
unsigned Opcode = MInst->getOpCode();
// do not process Phis
if (TM.getInstrInfo().isDummyPhiInstr(Opcode))
continue;
// Now add instructions that the register allocator inserts before/after
// this machine instructions (done only for calls/rets/incoming args)
// We do this here, to ensure that spill for an instruction is inserted
// closest as possible to an instruction (see above insertCode4Spill...)
// If there are instructions to be added, *before* this machine
// instruction, add them now.
//
if (AddedInstrMap.count(MInst)) {
PrependInstructions(AddedInstrMap[MInst].InstrnsBefore, MBB, MII,"");
}
// If there are instructions to be added *after* this machine
// instruction, add them now. All cases with delay slots have been
// c
if (!AddedInstrMap[MInst].InstrnsAfter.empty()) {
AppendInstructions(AddedInstrMap[MInst].InstrnsAfter, MBB, MII,"");
}
} // for each machine instruction
}
}
//----------------------------------------------------------------------------
// This method inserts spill code for AN operand whose LR was spilled.
// This method may be called several times for a single machine instruction
// if it contains many spilled operands. Each time it is called, it finds
// a register which is not live at that instruction and also which is not
// used by other spilled operands of the same instruction. Then it uses
// this register temporarily to accomodate the spilled value.
//----------------------------------------------------------------------------
void PhyRegAlloc::insertCode4SpilledLR(const LiveRange *LR,
MachineInstr *MInst,
const BasicBlock *BB,
const unsigned OpNum) {
assert((! TM.getInstrInfo().isCall(MInst->getOpCode()) || OpNum == 0) &&
"Outgoing arg of a call must be handled elsewhere (func arg ok)");
assert(! TM.getInstrInfo().isReturn(MInst->getOpCode()) &&
"Return value of a ret must be handled elsewhere");
MachineOperand& Op = MInst->getOperand(OpNum);
bool isDef = Op.opIsDefOnly();
bool isDefAndUse = Op.opIsDefAndUse();
unsigned RegType = MRI.getRegType(LR);
int SpillOff = LR->getSpillOffFromFP();
RegClass *RC = LR->getRegClass();
const ValueSet &LVSetBef = LVI->getLiveVarSetBeforeMInst(MInst, BB);
MF.getInfo()->pushTempValue(MRI.getSpilledRegSize(RegType) );
vector<MachineInstr*> MIBef, MIAft;
vector<MachineInstr*> AdIMid;
// Choose a register to hold the spilled value. This may insert code
// before and after MInst to free up the value. If so, this code should
// be first and last in the spill sequence before/after MInst.
int TmpRegU = getUsableUniRegAtMI(RegType, &LVSetBef, MInst, MIBef, MIAft);
// Set the operand first so that it this register does not get used
// as a scratch register for later calls to getUsableUniRegAtMI below
MInst->SetRegForOperand(OpNum, TmpRegU);
// get the added instructions for this instruction
AddedInstrns &AI = AddedInstrMap[MInst];
// We may need a scratch register to copy the spilled value to/from memory.
// This may itself have to insert code to free up a scratch register.
// Any such code should go before (after) the spill code for a load (store).
// The scratch reg is not marked as used because it is only used
// for the copy and not used across MInst.
int scratchRegType = -1;
int scratchReg = -1;
if (MRI.regTypeNeedsScratchReg(RegType, scratchRegType))
{
scratchReg = getUsableUniRegAtMI(scratchRegType, &LVSetBef,
MInst, MIBef, MIAft);
assert(scratchReg != MRI.getInvalidRegNum());
}
if (!isDef || isDefAndUse) {
// for a USE, we have to load the value of LR from stack to a TmpReg
// and use the TmpReg as one operand of instruction
// actual loading instruction(s)
MRI.cpMem2RegMI(AdIMid, MRI.getFramePointer(), SpillOff, TmpRegU, RegType,
scratchReg);
// the actual load should be after the instructions to free up TmpRegU
MIBef.insert(MIBef.end(), AdIMid.begin(), AdIMid.end());
AdIMid.clear();
}
if (isDef) { // if this is a Def
// for a DEF, we have to store the value produced by this instruction
// on the stack position allocated for this LR
// actual storing instruction(s)
MRI.cpReg2MemMI(AdIMid, TmpRegU, MRI.getFramePointer(), SpillOff, RegType,
scratchReg);
MIAft.insert(MIAft.begin(), AdIMid.begin(), AdIMid.end());
} // if !DEF
// Finally, insert the entire spill code sequences before/after MInst
AI.InstrnsBefore.insert(AI.InstrnsBefore.end(), MIBef.begin(), MIBef.end());
AI.InstrnsAfter.insert(AI.InstrnsAfter.begin(), MIAft.begin(), MIAft.end());
if (DEBUG_RA) {
cerr << "\nFor Inst:\n " << *MInst;
cerr << "SPILLED LR# " << LR->getUserIGNode()->getIndex();
cerr << "; added Instructions:";
for_each(MIBef.begin(), MIBef.end(), std::mem_fun(&MachineInstr::dump));
for_each(MIAft.begin(), MIAft.end(), std::mem_fun(&MachineInstr::dump));
}
}
//----------------------------------------------------------------------------
// We can use the following method to get a temporary register to be used
// BEFORE any given machine instruction. If there is a register available,
// this method will simply return that register and set MIBef = MIAft = NULL.
// Otherwise, it will return a register and MIAft and MIBef will contain
// two instructions used to free up this returned register.
// Returned register number is the UNIFIED register number
//----------------------------------------------------------------------------
int PhyRegAlloc::getUsableUniRegAtMI(const int RegType,
const ValueSet *LVSetBef,
MachineInstr *MInst,
std::vector<MachineInstr*>& MIBef,
std::vector<MachineInstr*>& MIAft) {
RegClass* RC = getRegClassByID(MRI.getRegClassIDOfRegType(RegType));
int RegU = getUnusedUniRegAtMI(RC, MInst, LVSetBef);
if (RegU == -1) {
// we couldn't find an unused register. Generate code to free up a reg by
// saving it on stack and restoring after the instruction
int TmpOff = MF.getInfo()->pushTempValue(MRI.getSpilledRegSize(RegType));
RegU = getUniRegNotUsedByThisInst(RC, MInst);
// Check if we need a scratch register to copy this register to memory.
int scratchRegType = -1;
if (MRI.regTypeNeedsScratchReg(RegType, scratchRegType))
{
int scratchReg = getUsableUniRegAtMI(scratchRegType, LVSetBef,
MInst, MIBef, MIAft);
assert(scratchReg != MRI.getInvalidRegNum());
// We may as well hold the value in the scratch register instead
// of copying it to memory and back. But we have to mark the
// register as used by this instruction, so it does not get used
// as a scratch reg. by another operand or anyone else.
MInst->insertUsedReg(scratchReg);
MRI.cpReg2RegMI(MIBef, RegU, scratchReg, RegType);
MRI.cpReg2RegMI(MIAft, scratchReg, RegU, RegType);
}
else
{ // the register can be copied directly to/from memory so do it.
MRI.cpReg2MemMI(MIBef, RegU, MRI.getFramePointer(), TmpOff, RegType);
MRI.cpMem2RegMI(MIAft, MRI.getFramePointer(), TmpOff, RegU, RegType);
}
}
return RegU;
}
//----------------------------------------------------------------------------
// This method is called to get a new unused register that can be used to
// accomodate a spilled value.
// This method may be called several times for a single machine instruction
// if it contains many spilled operands. Each time it is called, it finds
// a register which is not live at that instruction and also which is not
// used by other spilled operands of the same instruction.
// Return register number is relative to the register class. NOT
// unified number
//----------------------------------------------------------------------------
int PhyRegAlloc::getUnusedUniRegAtMI(RegClass *RC,
const MachineInstr *MInst,
const ValueSet *LVSetBef) {
unsigned NumAvailRegs = RC->getNumOfAvailRegs();
std::vector<bool> &IsColorUsedArr = RC->getIsColorUsedArr();
for (unsigned i=0; i < NumAvailRegs; i++) // Reset array
IsColorUsedArr[i] = false;
ValueSet::const_iterator LIt = LVSetBef->begin();
// for each live var in live variable set after machine inst
for ( ; LIt != LVSetBef->end(); ++LIt) {
// get the live range corresponding to live var
LiveRange *const LRofLV = LRI.getLiveRangeForValue(*LIt );
// LR can be null if it is a const since a const
// doesn't have a dominating def - see Assumptions above
if (LRofLV && LRofLV->getRegClass() == RC && LRofLV->hasColor() )
IsColorUsedArr[ LRofLV->getColor() ] = true;
}
// It is possible that one operand of this MInst was already spilled
// and it received some register temporarily. If that's the case,
// it is recorded in machine operand. We must skip such registers.
//
setRelRegsUsedByThisInst(RC, MInst);
for (unsigned c=0; c < NumAvailRegs; c++) // find first unused color
if (!IsColorUsedArr[c])
return MRI.getUnifiedRegNum(RC->getID(), c);
return -1;
}
//----------------------------------------------------------------------------
// Get any other register in a register class, other than what is used
// by operands of a machine instruction. Returns the unified reg number.
//----------------------------------------------------------------------------
int PhyRegAlloc::getUniRegNotUsedByThisInst(RegClass *RC,
const MachineInstr *MInst) {
vector<bool> &IsColorUsedArr = RC->getIsColorUsedArr();
unsigned NumAvailRegs = RC->getNumOfAvailRegs();
for (unsigned i=0; i < NumAvailRegs ; i++) // Reset array
IsColorUsedArr[i] = false;
setRelRegsUsedByThisInst(RC, MInst);
for (unsigned c=0; c < RC->getNumOfAvailRegs(); c++)// find first unused color
if (!IsColorUsedArr[c])
return MRI.getUnifiedRegNum(RC->getID(), c);
assert(0 && "FATAL: No free register could be found in reg class!!");
return 0;
}
//----------------------------------------------------------------------------
// This method modifies the IsColorUsedArr of the register class passed to it.
// It sets the bits corresponding to the registers used by this machine
// instructions. Both explicit and implicit operands are set.
//----------------------------------------------------------------------------
void PhyRegAlloc::setRelRegsUsedByThisInst(RegClass *RC,
const MachineInstr *MInst )
{
assert(OperandsColoredMap[MInst] == true &&
"Illegal to call setRelRegsUsedByThisInst() until colored operands "
"are marked for an instruction.");
vector<bool> &IsColorUsedArr = RC->getIsColorUsedArr();
// Add the registers already marked as used by the instruction.
// This should include any scratch registers that are used to save
// values across the instruction (e.g., for saving state register values).
const std::set<int> &regsUsed = MInst->getRegsUsed();
for (std::set<int>::iterator I=regsUsed.begin(), E=regsUsed.end(); I != E; ++I)
{
int i = *I;
unsigned classId = 0;
int classRegNum = MRI.getClassRegNum(i, classId);
if (RC->getID() == classId)
{
assert(classRegNum < (int) IsColorUsedArr.size() &&
"Illegal register number for this reg class?");
IsColorUsedArr[classRegNum] = true;
}
}
// If there are implicit references, mark their allocated regs as well
//
for (unsigned z=0; z < MInst->getNumImplicitRefs(); z++)
if (const LiveRange*
LRofImpRef = LRI.getLiveRangeForValue(MInst->getImplicitRef(z)))
if (LRofImpRef->hasColor())
// this implicit reference is in a LR that received a color
IsColorUsedArr[LRofImpRef->getColor()] = true;
}
//----------------------------------------------------------------------------
// If there are delay slots for an instruction, the instructions
// added after it must really go after the delayed instruction(s).
// So, we move the InstrAfter of that instruction to the
// corresponding delayed instruction using the following method.
//----------------------------------------------------------------------------
void PhyRegAlloc::move2DelayedInstr(const MachineInstr *OrigMI,
const MachineInstr *DelayedMI)
{
// "added after" instructions of the original instr
std::vector<MachineInstr *> &OrigAft = AddedInstrMap[OrigMI].InstrnsAfter;
// "added after" instructions of the delayed instr
std::vector<MachineInstr *> &DelayedAft =AddedInstrMap[DelayedMI].InstrnsAfter;
// go thru all the "added after instructions" of the original instruction
// and append them to the "added after instructions" of the delayed
// instructions
DelayedAft.insert(DelayedAft.end(), OrigAft.begin(), OrigAft.end());
// empty the "added after instructions" of the original instruction
OrigAft.clear();
}
//----------------------------------------------------------------------------
// This method prints the code with registers after register allocation is
// complete.
//----------------------------------------------------------------------------
void PhyRegAlloc::printMachineCode()
{
cerr << "\n;************** Function " << Fn->getName()
<< " *****************\n";
for (MachineFunction::iterator BBI = MF.begin(), BBE = MF.end();
BBI != BBE; ++BBI) {
cerr << "\n"; printLabel(BBI->getBasicBlock()); cerr << ": ";
// get the iterator for machine instructions
MachineBasicBlock& MBB = *BBI;
MachineBasicBlock::iterator MII = MBB.begin();
// iterate over all the machine instructions in BB
for ( ; MII != MBB.end(); ++MII) {
MachineInstr *MInst = *MII;
cerr << "\n\t";
cerr << TM.getInstrInfo().getName(MInst->getOpCode());
for (unsigned OpNum=0; OpNum < MInst->getNumOperands(); ++OpNum) {
MachineOperand& Op = MInst->getOperand(OpNum);
if (Op.getType() == MachineOperand::MO_VirtualRegister ||
Op.getType() == MachineOperand::MO_CCRegister /*||
Op.getType() == MachineOperand::MO_PCRelativeDisp*/ ) {
const Value *const Val = Op.getVRegValue () ;
// ****this code is temporary till NULL Values are fixed
if (! Val ) {
cerr << "\t<*NULL*>";
continue;
}
// if a label or a constant
if (isa<BasicBlock>(Val)) {
cerr << "\t"; printLabel( Op.getVRegValue () );
} else {
// else it must be a register value
const int RegNum = Op.getAllocatedRegNum();
cerr << "\t" << "%" << MRI.getUnifiedRegName( RegNum );
if (Val->hasName() )
cerr << "(" << Val->getName() << ")";
else
cerr << "(" << Val << ")";
if (Op.opIsDefOnly() || Op.opIsDefAndUse())
cerr << "*";
const LiveRange *LROfVal = LRI.getLiveRangeForValue(Val);
if (LROfVal )
if (LROfVal->hasSpillOffset() )
cerr << "$";
}
}
else if (Op.getType() == MachineOperand::MO_MachineRegister) {
cerr << "\t" << "%" << MRI.getUnifiedRegName(Op.getMachineRegNum());
}
else
cerr << "\t" << Op; // use dump field
}
unsigned NumOfImpRefs = MInst->getNumImplicitRefs();
if (NumOfImpRefs > 0) {
cerr << "\tImplicit:";
for (unsigned z=0; z < NumOfImpRefs; z++)
cerr << RAV(MInst->getImplicitRef(z)) << "\t";
}
} // for all machine instructions
cerr << "\n";
} // for all BBs
cerr << "\n";
}
//----------------------------------------------------------------------------
//----------------------------------------------------------------------------
void PhyRegAlloc::colorIncomingArgs()
{
MRI.colorMethodArgs(Fn, LRI, &AddedInstrAtEntry);
}
//----------------------------------------------------------------------------
// Used to generate a label for a basic block
//----------------------------------------------------------------------------
void PhyRegAlloc::printLabel(const Value *Val) {
if (Val->hasName())
cerr << Val->getName();
else
cerr << "Label" << Val;
}
//----------------------------------------------------------------------------
// This method calls setSugColorUsable method of each live range. This
// will determine whether the suggested color of LR is really usable.
// A suggested color is not usable when the suggested color is volatile
// AND when there are call interferences
//----------------------------------------------------------------------------
void PhyRegAlloc::markUnusableSugColors()
{
// hash map iterator
LiveRangeMapType::const_iterator HMI = (LRI.getLiveRangeMap())->begin();
LiveRangeMapType::const_iterator HMIEnd = (LRI.getLiveRangeMap())->end();
for (; HMI != HMIEnd ; ++HMI ) {
if (HMI->first) {
LiveRange *L = HMI->second; // get the LiveRange
if (L) {
if (L->hasSuggestedColor()) {
int RCID = L->getRegClass()->getID();
if (MRI.isRegVolatile( RCID, L->getSuggestedColor()) &&
L->isCallInterference() )
L->setSuggestedColorUsable( false );
else
L->setSuggestedColorUsable( true );
}
} // if L->hasSuggestedColor()
}
} // for all LR's in hash map
}
//----------------------------------------------------------------------------
// The following method will set the stack offsets of the live ranges that
// are decided to be spillled. This must be called just after coloring the
// LRs using the graph coloring algo. For each live range that is spilled,
// this method allocate a new spill position on the stack.
//----------------------------------------------------------------------------
void PhyRegAlloc::allocateStackSpace4SpilledLRs() {
if (DEBUG_RA) cerr << "\nSetting LR stack offsets for spills...\n";
LiveRangeMapType::const_iterator HMI = LRI.getLiveRangeMap()->begin();
LiveRangeMapType::const_iterator HMIEnd = LRI.getLiveRangeMap()->end();
for ( ; HMI != HMIEnd ; ++HMI) {
if (HMI->first && HMI->second) {
LiveRange *L = HMI->second; // get the LiveRange
if (!L->hasColor()) { // NOTE: ** allocating the size of long Type **
int stackOffset = MF.getInfo()->allocateSpilledValue(Type::LongTy);
L->setSpillOffFromFP(stackOffset);
if (DEBUG_RA)
cerr << " LR# " << L->getUserIGNode()->getIndex()
<< ": stack-offset = " << stackOffset << "\n";
}
}
} // for all LR's in hash map
}
//----------------------------------------------------------------------------
// The entry pont to Register Allocation
//----------------------------------------------------------------------------
void PhyRegAlloc::allocateRegisters()
{
// make sure that we put all register classes into the RegClassList
// before we call constructLiveRanges (now done in the constructor of
// PhyRegAlloc class).
//
LRI.constructLiveRanges(); // create LR info
if (DEBUG_RA >= RA_DEBUG_LiveRanges)
LRI.printLiveRanges();
createIGNodeListsAndIGs(); // create IGNode list and IGs
buildInterferenceGraphs(); // build IGs in all reg classes
if (DEBUG_RA >= RA_DEBUG_LiveRanges) {
// print all LRs in all reg classes
for ( unsigned rc=0; rc < NumOfRegClasses ; rc++)
RegClassList[rc]->printIGNodeList();
// print IGs in all register classes
for ( unsigned rc=0; rc < NumOfRegClasses ; rc++)
RegClassList[rc]->printIG();
}
LRI.coalesceLRs(); // coalesce all live ranges
if (DEBUG_RA >= RA_DEBUG_LiveRanges) {
// print all LRs in all reg classes
for (unsigned rc=0; rc < NumOfRegClasses; rc++)
RegClassList[rc]->printIGNodeList();
// print IGs in all register classes
for (unsigned rc=0; rc < NumOfRegClasses; rc++)
RegClassList[rc]->printIG();
}
// mark un-usable suggested color before graph coloring algorithm.
// When this is done, the graph coloring algo will not reserve
// suggested color unnecessarily - they can be used by another LR
//
markUnusableSugColors();
// color all register classes using the graph coloring algo
for (unsigned rc=0; rc < NumOfRegClasses ; rc++)
RegClassList[rc]->colorAllRegs();
// Atter graph coloring, if some LRs did not receive a color (i.e, spilled)
// a poistion for such spilled LRs
//
allocateStackSpace4SpilledLRs();
// Reset the temp. area on the stack before use by the first instruction.
// This will also happen after updating each instruction.
MF.getInfo()->popAllTempValues();
// color incoming args - if the correct color was not received
// insert code to copy to the correct register
//
colorIncomingArgs();
// Now update the machine code with register names and add any
// additional code inserted by the register allocator to the instruction
// stream
//
updateMachineCode();
if (DEBUG_RA) {
cerr << "\n**** Machine Code After Register Allocation:\n\n";
MF.dump();
}
}