MWCC/compiler_and_linker/unsorted/Peephole.c

2754 lines
94 KiB
C

#include "compiler/Peephole.h"
#include "compiler/CompilerTools.h"
#include "compiler/InstrSelection.h"
#include "compiler/PCode.h"
#include "compiler/objects.h"
#include "compiler/types.h"
#include "compiler/Scheduler.h"
#include "compiler/PCodeUtilities.h"
#include "compiler/Alias.h"
#include "compiler/CParser.h"
typedef int (*PeepholeFunc)(PCode *instr, UInt32 *masks);
typedef struct Pattern {
struct Pattern *next;
PeepholeFunc func;
} Pattern;
typedef struct LiveRegs {
UInt32 x0;
UInt32 x4;
UInt32 x8;
UInt32 xC;
} LiveRegs;
static LiveRegs *liveregs[RegClassMax];
static Pattern *peepholepatterns[OPCODE_MAX];
static PCode **defininginstruction;
static void computeregisterusedefs(void) {
PCodeBlock *block;
PCode *instr;
PCodeArg *op;
int i;
RegClass rclass;
LiveRegs *lr;
UInt32 array1[RegClassMax];
UInt32 array2[RegClassMax];
for (block = pcbasicblocks; block; block = block->nextBlock) {
for (rclass = 0; rclass < RegClassMax; rclass++) {
array1[rclass] = 0;
array2[rclass] = 0;
}
for (instr = block->firstPCode; instr; instr = instr->nextPCode) {
for (op = instr->args, i = instr->argCount; i--; op++) {
if (
op->kind == PCOp_REGISTER &&
(op->data.reg.effect & EffectRead) &&
!((1 << op->data.reg.reg) & array2[op->arg])
)
array1[op->arg] |= 1 << op->data.reg.reg;
}
for (op = instr->args, i = instr->argCount; i--; op++) {
if (
op->kind == PCOp_REGISTER &&
(op->data.reg.effect & EffectWrite) &&
!((1 << op->data.reg.reg) & array1[op->arg])
)
array2[op->arg] |= 1 << op->data.reg.reg;
}
}
for (rclass = 0; rclass < RegClassMax; rclass++) {
lr = liveregs[rclass] + block->blockIndex;
lr->x0 = array1[rclass];
lr->x4 = array2[rclass];
if (rclass == RegClass_GPR) {
lr->x8 = 1 << 1;
lr->xC = 1 << 1;
} else {
lr->x8 = 0;
lr->xC = 0;
}
}
}
}
static void computeliveness(LiveRegs *lrarray, UInt32 x) {
PCodeBlock *block;
LiveRegs *lr;
PCLink *link;
UInt32 newC;
UInt32 new8;
int i;
int flag;
flag = 1;
while (flag) {
flag = 0;
i = pcblockcount;
while (i) {
if ((block = depthfirstordering[--i])) {
lr = lrarray + block->blockIndex;
newC = x;
for (link = block->successors; link; link = link->nextLink)
newC |= lrarray[link->block->blockIndex].x8;
lr->xC = newC;
new8 = lr->x0 | (lr->xC & ~lr->x4);
if (new8 != lr->x8) {
lr->x8 = new8;
flag = 1;
}
}
}
}
}
static void computeliveregisters(Object *func) {
Type *returntype;
RegClass rclass;
returntype = TYPE_FUNC(func->type)->functype;
for (rclass = 0; rclass < RegClassMax; rclass++)
liveregs[rclass] = lalloc(sizeof(LiveRegs) * pcblockcount);
computedepthfirstordering();
computeregisterusedefs();
if (TYPE_FITS_IN_REGISTER(returntype)) {
liveregs[RegClass_GPR][epilogue->blockIndex].x0 |= 1 << 3;
if (TYPE_IS_8BYTES(returntype))
liveregs[RegClass_GPR][epilogue->blockIndex].x0 |= 1 << 4;
} else if (IS_TYPE_FLOAT(returntype)) {
liveregs[RegClass_FPR][epilogue->blockIndex].x0 |= 1 << 1;
} else if (IS_TYPE_VECTOR(returntype)) {
liveregs[RegClass_VR][epilogue->blockIndex].x0 |= 1 << 2;
}
for (rclass = 0; rclass < RegClassMax; rclass++) {
if (rclass == RegClass_GPR)
computeliveness(liveregs[rclass], 2);
else
computeliveness(liveregs[rclass], 0);
}
}
static void computeinstructionpredecessors(PCodeBlock *block) {
PCode *nop;
RegClass rclass;
SInt32 i;
SInt32 defID;
SInt32 totalOps;
PCode *instr;
PCodeArg *op;
PCode *array[RegClassMax][32];
nop = makepcode(PC_NOP);
for (rclass = 0; rclass < RegClassMax; rclass++) {
for (i = 0; i < 32; i++) {
array[rclass][i] = nop;
}
}
totalOps = 0;
for (instr = block->firstPCode; instr; instr = instr->nextPCode)
totalOps += instr->argCount;
if (totalOps) {
defininginstruction = oalloc(sizeof(PCode *) * totalOps);
for (i = 0; i < totalOps; i++)
defininginstruction[i] = nop;
defID = 0;
for (instr = block->firstPCode; instr; instr = instr->nextPCode) {
instr->defID = defID;
for (i = 0, op = instr->args; i < instr->argCount; i++, op++) {
if (op->kind == PCOp_REGISTER && (op->data.reg.effect & EffectRead))
defininginstruction[defID + i] = array[op->arg][op->data.reg.reg];
}
for (i = 0, op = instr->args; i < instr->argCount; i++, op++) {
if (op->kind == PCOp_REGISTER && (op->data.reg.effect & EffectWrite))
array[op->arg][op->data.reg.reg] = instr;
}
defID += instr->argCount;
}
}
}
static int dead(PCode *instr, UInt32 *masks) {
int i;
PCodeArg *op;
if (instr->block->flags & (fIsProlog | fIsEpilogue))
return 0;
if (instr->flags & (fIsBranch | fIsWrite | fIsCall | fIsVolatile | fSideEffects))
return 0;
if (!instr->block->predecessors)
return 1;
for (op = instr->args, i = instr->argCount; i--; op++) {
if (
op->kind == PCOp_REGISTER &&
(op->data.reg.effect & EffectWrite) &&
((1 << op->data.reg.reg) & masks[op->arg])
)
return 0;
}
return 1;
}
static int definedbetween(PCode *start, PCode *end, PCodeArg *checkOp) {
PCode *instr;
PCodeArg *op;
int i;
for (instr = start->prevPCode; instr != end; instr = instr->prevPCode) {
for (op = instr->args, i = instr->argCount; i--; op++) {
if (PC_OP_IS_WRITE_REGISTER(op, checkOp->arg, checkOp->data.reg.reg))
return 1;
}
}
return 0;
}
static int usedbetween(PCode *start, PCode *end, PCodeArg *checkOp) {
PCode *instr;
PCodeArg *op;
int i;
for (instr = start->prevPCode; instr != end; instr = instr->prevPCode) {
for (op = instr->args, i = instr->argCount; i--; op++) {
if (PC_OP_IS_READ_REGISTER(op, checkOp->arg, checkOp->data.reg.reg))
return 1;
}
}
return 0;
}
static int isSPRlive(PCode *instr, int reg) {
PCode *scan;
PCodeArg *op;
int i;
for (scan = instr->nextPCode; scan; scan = scan->nextPCode) {
for (op = scan->args, i = scan->argCount; i--; op++) {
if (PC_OP_IS_READ_REGISTER(op, RegClass_SPR, reg))
return 1;
if (PC_OP_IS_WRITE_REGISTER(op, RegClass_SPR, reg))
return 0;
}
}
return 0;
}
static SInt32 extractedbits(PCode *instr) {
SInt32 a = instr->args[2].data.imm.value;
SInt32 b = instr->args[3].data.imm.value;
SInt32 c = instr->args[4].data.imm.value;
SInt32 val;
if (b <= c)
val = ((b > 31) ? 0 : (0xFFFFFFFFu >> b)) & ~(((c + 1) > 31) ? 0 : (0xFFFFFFFFu >> (c + 1)));
else
val = ((b > 31) ? 0 : (0xFFFFFFFFu >> b)) | ~(((c + 1) > 31) ? 0 : (0xFFFFFFFFu >> (c + 1)));
return ((UInt32) val >> a) | (val << (32 - a));
}
static int canmergemasks(SInt32 b1, SInt32 c1, SInt32 a, SInt32 b2, SInt32 c2, short *first, short *last) {
SInt32 val1;
SInt32 val2;
if (b1 <= c1)
val1 = ((b1 > 31) ? 0 : (0xFFFFFFFFu >> b1)) & ~(((c1 + 1) > 31) ? 0 : (0xFFFFFFFFu >> (c1 + 1)));
else
val1 = ((b1 > 31) ? 0 : (0xFFFFFFFFu >> b1)) | ~(((c1 + 1) > 31) ? 0 : (0xFFFFFFFFu >> (c1 + 1)));
if (b2 <= c2)
val2 = ((b2 > 31) ? 0 : (0xFFFFFFFFu >> b2)) & ~(((c2 + 1) > 31) ? 0 : (0xFFFFFFFFu >> (c2 + 1)));
else
val2 = ((b2 > 31) ? 0 : (0xFFFFFFFFu >> b2)) | ~(((c2 + 1) > 31) ? 0 : (0xFFFFFFFFu >> (c2 + 1)));
return ismaskconstant(val2 & ((val1 << a) | ((UInt32) val1 >> (32 - a))), first, last);
}
static int canuseupdatetest(PCodeBlock *block, PCode *instr, int count1, int count2, int count3, int count4, int count5) {
int i;
PCLink *link;
while (instr) {
if (++count1 > 17)
return 1;
switch (instr->op) {
case PC_DIVW:
case PC_DIVWU:
case PC_MULHW:
case PC_MULHWU:
case PC_MULLI:
case PC_MULLW:
return count3 == 0;
case PC_MTXER:
case PC_MTCTR:
case PC_MTLR:
case PC_MTCRF:
case PC_MTMSR:
case PC_MTSPR:
case PC_MFMSR:
case PC_MFSPR:
case PC_MFXER:
case PC_MFCTR:
case PC_MFLR:
case PC_MFCR:
case PC_ECIWX:
case PC_ECOWX:
case PC_DCBI:
case PC_ICBI:
case PC_MCRFS:
case PC_MCRXR:
case PC_MFTB:
case PC_MFSR:
case PC_MTSR:
case PC_MFSRIN:
case PC_MTSRIN:
case PC_MTFSB0:
case PC_MTFSB1:
case PC_MTFSFI:
case PC_SC:
case PC_TLBIA:
case PC_TLBIE:
case PC_TLBLD:
case PC_TLBLI:
case PC_TLBSYNC:
case PC_TW:
case PC_TRAP:
case PC_TWI:
case PC_MFROM:
case PC_DSA:
case PC_ESA:
return 1;
case PC_CRAND:
case PC_CRANDC:
case PC_CREQV:
case PC_CRNAND:
case PC_CRNOR:
case PC_CROR:
case PC_CRORC:
case PC_CRXOR:
case PC_MCRF:
if (++count5 > 1)
return 1;
}
if (instr->flags & (fIsRead | fIsWrite)) {
if (++count4 > 1)
return 1;
} else if (instr->flags & fIsBranch) {
if (++count2 > 2)
return 1;
for (i = 0; i < instr->argCount; i++) {
if (PC_OP_IS_ANY_REGISTER(&instr->args[i], RegClass_CRFIELD)) {
++count3;
break;
}
}
}
instr = instr->nextPCode;
}
if (block && block->successors) {
for (link = block->successors; link; link = link->nextLink) {
if (link->block && !canuseupdatetest(link->block, link->block->firstPCode, count1, count2, count3, count4, count5))
return 0;
}
}
return 1;
}
static int canuseupdate(PCode *instr) {
return canuseupdatetest(instr->block, instr->nextPCode, 0, 0, 0, 0, 0);
}
static int MR_Rx_Rx(PCode *instr, UInt32 *masks) {
if (
instr->args[0].data.reg.reg == instr->args[1].data.reg.reg &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit)
)
{
deletepcode(instr);
return 1;
}
return 0;
}
static int FMR_Fx_Fx(PCode *instr, UInt32 *masks) {
if (
instr->args[0].data.reg.reg == instr->args[1].data.reg.reg &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit)
)
{
deletepcode(instr);
return 1;
}
return 0;
}
static int VMR_Vx_Vx(PCode *instr, UInt32 *masks) {
if (
instr->args[0].data.reg.reg == instr->args[1].data.reg.reg &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit)
)
{
deletepcode(instr);
return 1;
}
return 0;
}
static int MR_MR(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
defInstr->op == PC_MR &&
instr->args[0].data.reg.reg == defInstr->args[1].data.reg.reg &&
!definedbetween(instr, defInstr, &instr->args[0]) &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit)
)
{
deletepcode(instr);
return 1;
}
return 0;
}
static int FMR_FMR(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
defInstr->op == PC_FMR &&
instr->args[0].data.reg.reg == defInstr->args[1].data.reg.reg &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
!definedbetween(instr, defInstr, &instr->args[0])
)
{
deletepcode(instr);
return 1;
}
return 0;
}
static int VMR_VMR(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
defInstr->op == PC_VMR &&
instr->args[0].data.reg.reg == defInstr->args[1].data.reg.reg &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
!definedbetween(instr, defInstr, &instr->args[0])
)
{
deletepcode(instr);
return 1;
}
return 0;
}
static int VMR_VMRP(PCode *instr, UInt32 *masks) {
PCode *prev = instr->prevPCode;
PCode *next = instr->nextPCode;
int prevFlag = 0;
int prevPermute = 0;
int nextFlag = 0;
int nextPermute = 0;
if (prev) {
prevFlag = (prev->flags & fOpTypeMask) == fOpTypeVR;
prevPermute = uses_vpermute_unit(prev);
}
if (next) {
nextFlag = (next->flags & fOpTypeMask) == fOpTypeVR;
nextPermute = uses_vpermute_unit(next);
}
if (prev) {
if (next) {
if (prevFlag && !prevPermute) {
if (nextFlag) {
if (!nextPermute) {
change_opcode(instr, PC_VMRP);
return 1;
}
} else {
change_opcode(instr, PC_VMRP);
return 1;
}
}
} else {
if (prevFlag && !prevPermute) {
change_opcode(instr, PC_VMRP);
return 1;
}
}
} else {
if (next && nextFlag && !nextPermute) {
change_opcode(instr, PC_VMRP);
return 1;
}
}
return 0;
}
static int MR_CMPI(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
PCodeArg op;
if (
instr->args[0].data.reg.reg == 0 &&
instr->args[2].data.imm.value == 0 &&
(PCODE_FLAG_SET_F(defInstr) & (fSideEffects | fCanSetRecordBit | fOpTypeGPR)) == (fCanSetRecordBit | fOpTypeGPR) &&
!usedbetween(instr, defInstr, &instr->args[0]) &&
!definedbetween(instr, defInstr, &instr->args[0])
)
{
if (defInstr->op == PC_ADDI) {
op.kind = PCOp_REGISTER;
op.arg = RegClass_SPR;
op.data.reg.reg = 0;
op.data.reg.effect = EffectRead | EffectWrite;
if (usedbetween(instr, defInstr, &op))
return 0;
}
pcsetrecordbit(defInstr);
deletepcode(instr);
return 1;
}
return 0;
}
static int EXTSB_RLWINM(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
defInstr->op == PC_EXTSB &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!(PCODE_FLAG_SET_F(defInstr) & fRecordBit) &&
!definedbetween(instr, defInstr, &defInstr->args[1]) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
(extractedbits(instr) & 0xFFFFFF00) == 0
)
{
instr->args[1].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
deletepcode(defInstr);
return 1;
}
return 0;
}
static int EXTSH_RLWINM(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
defInstr->op == PC_EXTSH &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!(PCODE_FLAG_SET_F(defInstr) & fRecordBit) &&
!definedbetween(instr, defInstr, &defInstr->args[1]) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
(extractedbits(instr) & 0xFFFF0000) == 0
)
{
instr->args[1].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
deletepcode(defInstr);
return 1;
}
return 0;
}
static int LBZ_RLWINM(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
(defInstr->op == PC_LBZ || defInstr->op == PC_LBZX) &&
instr->args[2].data.imm.value == 0 &&
instr->args[3].data.imm.value <= 24 &&
instr->args[4].data.imm.value == 31 &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
!definedbetween(instr, defInstr, &instr->args[0]) &&
!usedbetween(instr, defInstr, &instr->args[0])
)
{
defInstr->args[0].data.reg.reg = instr->args[0].data.reg.reg;
deletepcode(instr);
return 1;
}
return 0;
}
static int LHZ_RLWINM(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
(defInstr->op == PC_LHZ || defInstr->op == PC_LHZX) &&
instr->args[2].data.imm.value == 0 &&
instr->args[3].data.imm.value <= 16 &&
instr->args[4].data.imm.value == 31 &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
!definedbetween(instr, defInstr, &instr->args[0]) &&
!usedbetween(instr, defInstr, &instr->args[0])
)
{
defInstr->args[0].data.reg.reg = instr->args[0].data.reg.reg;
deletepcode(instr);
return 1;
}
return 0;
}
static int LHA_EXTSH(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
defInstr->op == PC_LHA &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
!definedbetween(instr, defInstr, &instr->args[0]) &&
!usedbetween(instr, defInstr, &instr->args[0])
)
{
defInstr->args[0].data.reg.reg = instr->args[0].data.reg.reg;
deletepcode(instr);
return 1;
}
if (
defInstr->op == PC_EXTSB &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit)
)
{
if (defInstr->args[0].data.reg.reg == defInstr->args[1].data.reg.reg) {
if (
!(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg)) &&
!usedbetween(instr, defInstr, &defInstr->args[0])
)
{
change_opcode(instr, PC_EXTSB);
deletepcode(defInstr);
return 1;
}
} else {
if (!definedbetween(instr, defInstr, &defInstr->args[1])) {
change_opcode(instr, PC_EXTSB);
instr->args[1] = defInstr->args[1];
} else {
change_opcode(instr, PC_MR);
}
return 1;
}
}
return 0;
}
static int ADDI_L_S(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
SInt32 addleft;
SInt32 addright;
if (defInstr->op == PC_ADDI && instr->args[2].kind == PCOp_IMMEDIATE) {
if (!PC_OP_IS_REGISTER(&instr->args[0], RegClass_GPR, instr->args[1].data.reg.reg)) {
if (
instr->args[2].data.imm.value == 0 &&
defInstr->args[0].data.reg.reg == defInstr->args[1].data.reg.reg &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
(!(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg)) || canuseupdate(instr))
)
{
if (!(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) {
instr->args[2] = defInstr->args[2];
} else {
instr->op++;
instr->args[1].data.reg.effect |= EffectWrite;
instr->args[2] = defInstr->args[2];
}
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
deletepcode(defInstr);
return 1;
}
addleft = 0x1FFFF;
addright = instr->args[2].data.imm.value;
if (defInstr->args[2].kind == PCOp_IMMEDIATE) {
addleft = defInstr->args[2].data.imm.value;
} else if (defInstr->args[2].kind == PCOp_MEMORY) {
if (defInstr->args[2].data.mem.obj->datatype == DLOCAL)
addleft = defInstr->args[2].data.mem.offset + defInstr->args[2].data.mem.obj->u.var.uid;
else if (addright == 0)
addleft = 0;
else
return 0;
}
if (!FITS_IN_SHORT(addleft + addright))
return 0;
if (
!(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg)) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
!definedbetween(instr, defInstr, &defInstr->args[1])
)
{
instr->args[1].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
if (defInstr->args[2].kind == PCOp_MEMORY) {
instr->args[2] = defInstr->args[2];
instr->args[2].data.mem.offset += addright;
if (instr->flags & (fIsRead | fIsWrite | fPCodeFlag20000 | fPCodeFlag40000)) {
instr->alias = make_alias(
instr->args[2].data.mem.obj,
instr->args[2].data.mem.offset,
nbytes_loaded_or_stored_by(instr)
);
}
} else {
instr->args[2].data.imm.value = addleft + addright;
}
deletepcode(defInstr);
return 1;
}
if (
instr->args[1].data.reg.reg != defInstr->args[1].data.reg.reg &&
!definedbetween(instr, defInstr, &defInstr->args[1])
)
{
if (defInstr->args[2].kind == PCOp_MEMORY && defInstr->args[2].data.mem.obj->datatype != DLOCAL)
return 0;
instr->args[1].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
if (defInstr->args[2].kind == PCOp_MEMORY) {
instr->args[2] = defInstr->args[2];
instr->args[2].data.mem.offset += addright;
if (instr->flags & (fIsRead | fIsWrite | fPCodeFlag20000 | fPCodeFlag40000)) {
instr->alias = make_alias(
instr->args[2].data.mem.obj,
instr->args[2].data.mem.offset,
nbytes_loaded_or_stored_by(instr)
);
}
} else {
instr->args[2].data.imm.value = addleft + addright;
}
return 1;
}
}
} else {
if (
defInstr->op == PC_MR &&
PC_OP_IS_ANY_REGISTER(&defInstr->args[1], RegClass_GPR) &&
defInstr->args[1].data.reg.reg != 0 &&
!definedbetween(instr, defInstr, &defInstr->args[1])
)
{
instr->args[1].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
}
}
return 0;
}
static int ADDI_LU_SU(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
instr->args[2].kind == PCOp_IMMEDIATE &&
defInstr->args[2].kind == PCOp_IMMEDIATE &&
defInstr->op == PC_ADDI &&
defInstr->args[0].data.reg.reg == defInstr->args[1].data.reg.reg &&
!(instr->args[0].arg == instr->args[1].arg && instr->args[0].data.reg.reg == instr->args[1].data.reg.reg) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
FITS_IN_SHORT(instr->args[2].data.imm.value + defInstr->args[2].data.imm.value)
)
{
if ((instr->args[2].data.imm.value + defInstr->args[2].data.imm.value) == 0) {
instr->op--;
instr->args[1].data.reg.effect &= ~EffectWrite;
instr->args[2].data.imm.value = 0;
} else {
instr->args[2].data.imm.value += defInstr->args[2].data.imm.value;
}
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
deletepcode(defInstr);
return 1;
}
return 0;
}
static int L_S_ADDI(PCode *instr, UInt32 *masks) {
PCode *scan;
PCodeArg *op;
int i;
short reg;
if (instr->args[2].kind != PCOp_IMMEDIATE)
return 0;
reg = instr->args[1].data.reg.reg;
if (!canuseupdate(instr))
return 0;
for (scan = instr->nextPCode; scan; scan = scan->nextPCode) {
for (op = scan->args, i = scan->argCount; i--; op++) {
if (PC_OP_IS_READ_REGISTER(op, RegClass_GPR, reg))
return 0;
if (PC_OP_IS_WRITE_REGISTER(op, RegClass_GPR, reg)) {
if (scan->op != PC_ADDI)
return 0;
if (scan->args[2].kind != PCOp_IMMEDIATE)
return 0;
if (
instr->args[2].data.imm.value == scan->args[2].data.imm.value &&
scan->args[0].data.reg.reg == scan->args[1].data.reg.reg &&
!(instr->args[0].arg == instr->args[1].arg && instr->args[0].data.reg.reg == instr->args[1].data.reg.reg)
)
{
if (!(masks[RegClass_GPR] & (1 << scan->args[0].data.reg.reg))) {
instr->args[2] = scan->args[2];
} else {
instr->op++;
instr->args[1].data.reg.effect |= EffectWrite;
instr->args[2] = scan->args[2];
}
change_opcode(scan, PC_NOP);
change_num_operands(scan, 0);
deletepcode(scan);
return 1;
}
return 0;
}
}
}
return 0;
}
static int LI_CMP_BC(PCode *instr, UInt32 *masks) {
PCode *defInstr;
PCode *defInstr2;
PCLink *link;
PCLink **ptr;
if (instr->args[1].data.imm.value == 2) {
defInstr = defininginstruction[instr->defID];
if ((defInstr->op == PC_CMPLI || defInstr->op == PC_CMPI) && defInstr->args[0].data.reg.reg == 0) {
defInstr2 = defininginstruction[defInstr->defID + 1];
if (
defInstr2->op == PC_LI &&
defInstr2->args[1].kind == PCOp_IMMEDIATE &&
(instr->op == PC_BT) == (defInstr2->args[1].data.imm.value == defInstr->args[2].data.imm.value)
)
{
change_opcode(instr, PC_B);
instr->args[0] = instr->args[2];
change_num_operands(instr, 1);
defininginstruction[instr->defID] = defininginstruction[instr->defID + 1];
for (ptr = &instr->block->successors; (link = *ptr); ptr = &link->nextLink) {
if (link->block == instr->block->nextBlock) {
*ptr = link->nextLink;
break;
}
}
for (ptr = &instr->block->nextBlock->predecessors; (link = *ptr); ptr = &link->nextLink) {
if (link->block == instr->block) {
*ptr = link->nextLink;
break;
}
}
}
}
}
return 0;
}
static int RLWINM_CMPLI_BC(PCode *instr, UInt32 *masks) {
PCode *defInstr;
PCode *defInstr2;
if (instr->args[1].data.imm.value == 2) {
defInstr = defininginstruction[instr->defID];
if (defInstr->op == PC_CMPLI && defInstr->args[0].data.reg.reg == 0 && defInstr->args[2].data.imm.value == 0) {
defInstr2 = defininginstruction[defInstr->defID + 1];
if (
(PCODE_FLAG_SET_F(defInstr2) & (fSideEffects | fCanSetRecordBit | fOpTypeGPR)) == (fCanSetRecordBit | fOpTypeGPR) &&
!usedbetween(defInstr, defInstr2, &defInstr->args[0]) &&
!definedbetween(defInstr, defInstr2, &defInstr->args[0])
)
{
pcsetrecordbit(defInstr2);
defininginstruction[instr->defID] = defininginstruction[defInstr->defID + 1];
deletepcode(defInstr);
return 1;
}
}
}
return 0;
}
static int LBZ_EXTSB_CMPI_BC(PCode *instr, UInt32 *masks) {
PCode *defInstr;
PCode *defInstr2;
if (instr->args[1].data.imm.value == 2) {
defInstr = defininginstruction[instr->defID];
if (
(
(defInstr->op == PC_CMPI || defInstr->op == PC_CMPLI) &&
defInstr->args[2].data.imm.value >= 0 &&
defInstr->args[2].data.imm.value <= 127
)
||
(
(defInstr->op == PC_EXTSB || defInstr->op == PC_EXTSH) &&
(PCODE_FLAG_SET_F(defInstr) & fRecordBit)
)
)
{
defInstr2 = defininginstruction[defInstr->defID + 1];
if (
defInstr2->op == PC_EXTSB &&
defininginstruction[defInstr2->defID + 1]->op == PC_LBZ &&
!(masks[RegClass_GPR] & (1 << defInstr2->args[0].data.reg.reg)) &&
!usedbetween(instr, defInstr, &defInstr2->args[0]) &&
!usedbetween(defInstr, defInstr2, &defInstr2->args[0]) &&
!definedbetween(defInstr, defInstr2, &defInstr2->args[1])
)
{
defInstr->args[1].data.reg.reg = defInstr2->args[1].data.reg.reg;
defininginstruction[defInstr->defID + 1] = defininginstruction[defInstr2->defID + 1];
deletepcode(defInstr2);
return 1;
}
}
}
return 0;
}
static int FRSP_STFS(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID];
if (
defInstr->op == PC_FRSP &&
!(masks[RegClass_FPR] & (1 << defInstr->args[0].data.reg.reg)) &&
!(PCODE_FLAG_SET_F(defInstr) & fRecordBit) &&
!definedbetween(instr, defInstr, &defInstr->args[1]) &&
!usedbetween(instr, defInstr, &defInstr->args[0])
)
{
instr->args[0].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID] = defininginstruction[defInstr->defID + 1];
deletepcode(defInstr);
return 1;
}
return 0;
}
static int NOT_AND(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 2];
if (
defInstr->op == PC_NOT &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!(PCODE_FLAG_SET_F(defInstr) & fRecordBit) &&
!definedbetween(instr, defInstr, &defInstr->args[1]) &&
!usedbetween(instr, defInstr, &defInstr->args[0])
)
{
instr->args[2].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 2] = defininginstruction[defInstr->defID + 1];
change_opcode(instr, PC_ANDC);
deletepcode(defInstr);
return 1;
}
return 0;
}
static int LI_MR(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
defInstr->op == PC_LI &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
!usedbetween(instr, defInstr, &defInstr->args[0])
)
{
change_opcode(instr, PC_LI);
instr->args[1] = defInstr->args[1];
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
deletepcode(defInstr);
return 1;
}
return 0;
}
static int VSPLTIS_VMR(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
short opcode = defInstr->op;
if (
(opcode == PC_VSPLTISB || opcode == PC_VSPLTISH || opcode == PC_VSPLTISW) &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_VR] & (1 << defInstr->args[0].data.reg.reg))) &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
!usedbetween(instr, defInstr, &defInstr->args[0])
)
{
change_opcode(instr, opcode);
instr->args[1] = defInstr->args[1];
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
deletepcode(defInstr);
return 1;
}
return 0;
}
static int L_MR(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
(defInstr->flags & fIsRead) &&
!(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg)) &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
!usedbetween(instr, defInstr, &instr->args[0]) &&
!definedbetween(instr, defInstr, &instr->args[0])
)
{
defInstr->args[0].data.reg.reg = instr->args[0].data.reg.reg;
deletepcode(instr);
return 1;
}
return 0;
}
static int L_FMR(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
(defInstr->flags & fIsRead) &&
!(masks[RegClass_FPR] & (1 << defInstr->args[0].data.reg.reg)) &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
!usedbetween(instr, defInstr, &instr->args[0]) &&
!definedbetween(instr, defInstr, &instr->args[0])
)
{
defInstr->args[0].data.reg.reg = instr->args[0].data.reg.reg;
deletepcode(instr);
return 1;
}
return 0;
}
static int L_S(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID];
SInt32 isIndexed;
SInt32 isFloat;
SInt32 isVector;
PCode *scan;
SInt32 loadSize;
SInt32 defInstrOffset;
SInt32 scanOffset;
SInt32 storeSize;
if (PCODE_FLAG_SET_F(instr) & (fIsVolatile | fSideEffects | fUpdatesPtr))
return 0;
if (PCODE_FLAG_SET_F(defInstr) & (fIsVolatile | fSideEffects | fUpdatesPtr))
return 0;
if (
(defInstr->flags & fIsRead) &&
PC_OP_IS_REGISTER(&defInstr->args[1], RegClass_GPR, instr->args[1].data.reg.reg) &&
defInstr->args[2].kind == instr->args[2].kind &&
!definedbetween(instr, defInstr, &instr->args[1])
)
{
if (instr->args[2].kind == PCOp_IMMEDIATE) {
if (instr->args[2].data.imm.value != defInstr->args[2].data.imm.value)
return 0;
} else if (instr->args[2].kind == PCOp_MEMORY) {
if (instr->args[2].data.mem.offset != defInstr->args[2].data.mem.offset ||
instr->args[2].data.mem.obj != defInstr->args[2].data.mem.obj)
return 0;
} else if (instr->args[2].kind == PCOp_REGISTER && instr->args[2].arg == RegClass_GPR) {
if (instr->args[2].data.reg.reg != defInstr->args[2].data.reg.reg ||
definedbetween(instr, defInstr, &instr->args[2]))
return 0;
} else {
return 0;
}
isIndexed = 0;
isFloat = 0;
isVector = 0;
switch (defInstr->op) {
case PC_LBZX:
isIndexed = 1;
case PC_LBZ:
loadSize = 1;
break;
case PC_LHZX:
case PC_LHAX:
isIndexed = 1;
case PC_LHZ:
case PC_LHA:
loadSize = 2;
break;
case PC_LWZX:
isIndexed = 1;
case PC_LWZ:
loadSize = 4;
break;
case PC_LFSX:
isIndexed = 1;
case PC_LFS:
isFloat = 1;
loadSize = 4;
break;
case PC_LFDX:
isIndexed = 1;
case PC_LFD:
isFloat = 1;
loadSize = 8;
break;
case PC_LVX:
case PC_LVXL:
isIndexed = 1;
isVector = 1;
loadSize = 16;
break;
default:
return 0;
}
switch (instr->op) {
case PC_STBX:
if (!isIndexed) return 0;
case PC_STB:
if (isFloat) return 0;
if (loadSize != 1) return 0;
break;
case PC_STHX:
if (!isIndexed) return 0;
case PC_STH:
if (isFloat) return 0;
if (loadSize != 2) return 0;
break;
case PC_STWX:
if (!isIndexed) return 0;
case PC_STW:
if (isFloat) return 0;
if (loadSize != 4) return 0;
break;
case PC_STFSX:
if (!isIndexed) return 0;
case PC_STFS:
if (!isFloat) return 0;
if (loadSize != 4) return 0;
break;
case PC_STFDX:
if (!isIndexed) return 0;
case PC_STFD:
if (!isFloat) return 0;
if (loadSize != 8) return 0;
break;
case PC_STVX:
case PC_STVXL:
if (!isIndexed) return 0;
if (!isVector) return 0;
if (loadSize != 16) return 0;
break;
default:
return 0;
}
for (scan = instr->prevPCode; scan && scan != defInstr; scan = scan->prevPCode) {
if (scan->flags & fIsWrite) {
if (scan->args[1].data.reg.reg != instr->args[1].data.reg.reg)
return 0;
if (scan->args[2].kind != defInstr->args[2].kind)
return 0;
if (scan->args[2].kind == PCOp_MEMORY) {
if (instr->args[2].data.mem.obj == scan->args[2].data.mem.obj) {
if (instr->args[2].data.mem.offset == defInstr->args[2].data.mem.offset)
return 0;
defInstrOffset = defInstr->args[2].data.mem.offset;
scanOffset = scan->args[2].data.mem.offset;
}
} else if (scan->args[2].kind == PCOp_IMMEDIATE) {
if (instr->args[1].data.reg.reg != scan->args[1].data.reg.reg)
return 0;
if (instr->args[2].data.imm.value == scan->args[2].data.imm.value)
return 0;
defInstrOffset = defInstr->args[2].data.imm.value;
scanOffset = scan->args[2].data.imm.value;
} else {
return 0;
}
switch (scan->op) {
case PC_STB:
case PC_STBX:
storeSize = 1;
break;
case PC_STH:
case PC_STHX:
storeSize = 2;
break;
case PC_STW:
case PC_STWX:
case PC_STFS:
case PC_STFSX:
storeSize = 4;
break;
case PC_STFD:
case PC_STFDX:
storeSize = 8;
break;
case PC_STVX:
case PC_STVXL:
storeSize = 16;
break;
default:
return 0;
}
if (defInstrOffset > scanOffset) {
if ((scanOffset + storeSize) > defInstrOffset)
return 0;
} else {
if ((defInstrOffset + loadSize) > scanOffset)
return 0;
}
}
}
deletepcode(instr);
return 1;
}
return 0;
}
static int RLWINM_RLWINM(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
short start;
short end;
if (
defInstr->op == PC_RLWINM &&
!(PCODE_FLAG_SET_F(defInstr) & fRecordBit) &&
!definedbetween(instr, defInstr, &defInstr->args[1]) &&
!(
defInstr->args[0].data.reg.reg == defInstr->args[1].data.reg.reg &&
(
(defInstr->args[0].data.reg.reg != instr->args[0].data.reg.reg && (masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) ||
usedbetween(instr, defInstr, &defInstr->args[0])
)
) &&
canmergemasks(
defInstr->args[3].data.imm.value,
defInstr->args[4].data.imm.value,
instr->args[2].data.imm.value,
instr->args[3].data.imm.value,
instr->args[4].data.imm.value,
&start, &end)
)
{
if (instr->op == PC_RLWIMI) {
if (instr->args[0].data.reg.reg == defInstr->args[0].data.reg.reg)
return 0;
if (start != instr->args[3].data.imm.value || end != instr->args[4].data.imm.value)
return 0;
}
instr->args[1].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
instr->args[2].data.imm.value = (instr->args[2].data.imm.value + defInstr->args[2].data.imm.value) & 31;
instr->args[3].data.imm.value = start;
instr->args[4].data.imm.value = end;
if (
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!usedbetween(instr, defInstr, &defInstr->args[0])
)
deletepcode(defInstr);
return 1;
}
if (
defInstr->op == PC_MR &&
instr->op == PC_RLWINM &&
!definedbetween(instr, defInstr, &defInstr->args[1])
)
{
instr->args[1].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
if (
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!(PCODE_FLAG_SET_F(defInstr) & fRecordBit) &&
!usedbetween(instr, defInstr, &defInstr->args[0])
)
deletepcode(defInstr);
return 1;
}
return 0;
}
static int MULLI_MULLI(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
defInstr->op == PC_MULLI &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!(PCODE_FLAG_SET_F(defInstr) & fRecordBit) &&
!definedbetween(instr, defInstr, &defInstr->args[1]) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
FITS_IN_SHORT(instr->args[2].data.imm.value * defInstr->args[2].data.imm.value)
)
{
instr->args[1].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
instr->args[2].data.imm.value *= defInstr->args[2].data.imm.value;
deletepcode(defInstr);
return 1;
}
return 0;
}
static int ADDI_ADDI(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
defInstr->op == PC_ADDI &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!(PCODE_FLAG_SET_F(defInstr) & fRecordBit) &&
!definedbetween(instr, defInstr, &defInstr->args[1]) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
instr->args[2].kind == PCOp_IMMEDIATE &&
defInstr->args[2].kind == PCOp_IMMEDIATE &&
FITS_IN_SHORT(instr->args[2].data.imm.value + defInstr->args[2].data.imm.value)
)
{
instr->args[1].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
instr->args[2].data.imm.value += defInstr->args[2].data.imm.value;
deletepcode(defInstr);
return 1;
}
return 0;
}
static int SRAWI_SRAWI(PCode *instr, UInt32 *masks) {
PCode *defInstr = defininginstruction[instr->defID + 1];
if (
defInstr->op == PC_SRAWI &&
(defInstr->args[0].data.reg.reg == instr->args[0].data.reg.reg || !(masks[RegClass_GPR] & (1 << defInstr->args[0].data.reg.reg))) &&
!(PCODE_FLAG_SET_F(defInstr) & fRecordBit) &&
!definedbetween(instr, defInstr, &defInstr->args[1]) &&
!usedbetween(instr, defInstr, &defInstr->args[0]) &&
instr->args[2].kind == PCOp_IMMEDIATE &&
defInstr->args[2].kind == PCOp_IMMEDIATE &&
(instr->args[2].data.imm.value + defInstr->args[2].data.imm.value) < 32 &&
(instr->args[2].data.imm.value + defInstr->args[2].data.imm.value) > 0
)
{
instr->args[1].data.reg.reg = defInstr->args[1].data.reg.reg;
defininginstruction[instr->defID + 1] = defininginstruction[defInstr->defID + 1];
instr->args[2].data.imm.value += defInstr->args[2].data.imm.value;
deletepcode(defInstr);
return 1;
}
return 0;
}
static int MR_ADDI(PCode *instr, UInt32 *masks) {
PCode *prev = instr->prevPCode;
PCode *next = instr->nextPCode;
int prevFlag = 0;
int nextFlag = 0;
if (copts.cpu == CPU_PPC603e) {
if (prev)
prevFlag = (prev->flags & fOpTypeMask) == fOpTypeGPR;
if (next)
nextFlag = (next->flags & fOpTypeMask) == fOpTypeGPR;
if (
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
instr->argCount >= 2 &&
instr->args[1].data.reg.reg != 0 &&
(prevFlag || nextFlag)
)
{
change_opcode(instr, PC_ADDI);
instr->args[2].kind = PCOp_IMMEDIATE;
instr->args[2].data.imm.value = 0;
instr->args[2].data.imm.obj = NULL;
change_num_operands(instr, 3);
}
}
return 0;
}
static int rotatedefinedusedtest(UInt32 *masks, PCode *instr, PCode *a, PCode *b, PCode *subfic) {
PCode *scan;
PCodeArg *op;
int i;
int reg1;
int reg2;
if (
(masks[RegClass_GPR] & (1 << subfic->args[0].data.reg.reg)) &&
subfic->args[0].data.reg.reg != instr->args[0].data.reg.reg &&
subfic->args[0].data.reg.reg != a->args[2].data.reg.reg
)
return 1;
for (scan = instr->block->firstPCode; scan != instr->block->lastPCode; scan = scan->nextPCode) {
if (scan == a) break;
if (scan == b) break;
if (scan == subfic) break;
}
reg1 = a->args[1].data.reg.reg;
reg2 = subfic->args[1].data.reg.reg;
while (scan != instr) {
for (op = instr->args, i = instr->argCount; i--; op++) {
if (
op->kind == PCOp_REGISTER &&
op->arg == RegClass_GPR &&
(
(
(op->data.reg.reg == reg1 || op->data.reg.reg == reg2) &&
(op->data.reg.effect & EffectWrite)
)
||
(
op->data.reg.reg == subfic->args[0].data.reg.reg && (op->data.reg.effect & EffectRead)
)
) &&
scan != a &&
scan != b &&
scan != subfic
)
return 1;
}
scan = scan->nextPCode;
}
return 0;
}
static int SRW_SUBFIC_RLW_OR(PCode *instr, UInt32 *masks) {
PCode *subfic;
PCode *defInstr1 = defininginstruction[instr->defID + 1];
PCode *defInstr2 = defininginstruction[instr->defID + 2];
if (PCODE_FLAG_SET_F(instr) & fRecordBit)
return 0;
if (
(masks[RegClass_GPR] & (1 << instr->args[1].data.reg.reg)) &&
instr->args[1].data.reg.reg != instr->args[0].data.reg.reg
)
return 0;
if (
(masks[RegClass_GPR] & (1 << instr->args[2].data.reg.reg)) &&
instr->args[1].data.reg.reg != instr->args[0].data.reg.reg
)
return 0;
if (defInstr1->op != PC_SRW && defInstr1->op != PC_SLW)
return 0;
if (defInstr2->op != PC_SRW && defInstr2->op != PC_SLW)
return 0;
if (usedbetween(instr, defInstr1, &defInstr1->args[0]))
return 0;
if (usedbetween(instr, defInstr2, &defInstr2->args[0]))
return 0;
if (
defInstr1->op == PC_SRW && defInstr2->op == PC_SLW &&
defInstr1->args[1].data.reg.reg == defInstr2->args[1].data.reg.reg
)
{
subfic = defininginstruction[defInstr1->defID + 2];
if (
subfic->op == PC_SUBFIC &&
subfic->args[1].data.reg.reg == defInstr2->args[2].data.reg.reg &&
subfic->args[2].data.imm.value == 32
)
{
if (rotatedefinedusedtest(masks, instr, defInstr2, defInstr1, subfic))
return 0;
change_opcode(instr, PC_RLWNM);
instr->args[1] = defInstr1->args[1];
defininginstruction[instr->defID + 1] = defininginstruction[defInstr1->defID + 1];
instr->args[2] = defInstr2->args[2];
defininginstruction[instr->defID + 2] = defininginstruction[defInstr2->defID + 2];
instr->args[3].kind = PCOp_IMMEDIATE;
instr->args[3].data.imm.value = 0;
instr->args[3].data.imm.obj = NULL;
instr->args[4].kind = PCOp_IMMEDIATE;
instr->args[4].data.imm.value = 31;
instr->args[4].data.imm.obj = NULL;
deletepcode(defInstr1);
deletepcode(defInstr2);
deletepcode(subfic);
return 1;
}
subfic = defininginstruction[defInstr2->defID + 2];
if (
subfic->op == PC_SUBFIC &&
subfic->args[1].data.reg.reg == defInstr1->args[2].data.reg.reg &&
subfic->args[2].data.imm.value == 32
)
{
if (rotatedefinedusedtest(masks, instr, defInstr2, defInstr1, subfic))
return 0;
change_opcode(instr, PC_RLWNM);
instr->args[1] = defInstr1->args[1];
defininginstruction[instr->defID + 1] = defininginstruction[defInstr1->defID + 1];
instr->args[2] = defInstr2->args[2];
defininginstruction[instr->defID + 2] = defininginstruction[defInstr2->defID + 2];
instr->args[3].kind = PCOp_IMMEDIATE;
instr->args[3].data.imm.value = 0;
instr->args[3].data.imm.obj = NULL;
instr->args[4].kind = PCOp_IMMEDIATE;
instr->args[4].data.imm.value = 31;
instr->args[4].data.imm.obj = NULL;
deletepcode(defInstr1);
deletepcode(defInstr2);
return 1;
}
} else if (
defInstr1->op == PC_SLW && defInstr2->op == PC_SRW &&
defInstr1->args[1].data.reg.reg == defInstr2->args[1].data.reg.reg
)
{
subfic = defininginstruction[defInstr1->defID + 2];
if (
subfic->op == PC_SUBFIC &&
subfic->args[1].data.reg.reg == defInstr2->args[2].data.reg.reg &&
subfic->args[2].data.imm.value == 32
)
{
if (rotatedefinedusedtest(masks, instr, defInstr1, defInstr2, subfic))
return 0;
change_opcode(instr, PC_RLWNM);
instr->args[1] = defInstr1->args[1];
defininginstruction[instr->defID + 1] = defininginstruction[defInstr1->defID + 1];
instr->args[2] = defInstr1->args[2];
defininginstruction[instr->defID + 2] = defininginstruction[defInstr1->defID + 2];
instr->args[3].kind = PCOp_IMMEDIATE;
instr->args[3].data.imm.value = 0;
instr->args[3].data.imm.obj = NULL;
instr->args[4].kind = PCOp_IMMEDIATE;
instr->args[4].data.imm.value = 31;
instr->args[4].data.imm.obj = NULL;
deletepcode(defInstr1);
deletepcode(defInstr2);
return 1;
}
subfic = defininginstruction[defInstr2->defID + 2];
if (
subfic->op == PC_SUBFIC &&
subfic->args[1].data.reg.reg == defInstr1->args[2].data.reg.reg &&
subfic->args[2].data.imm.value == 32
)
{
if (rotatedefinedusedtest(masks, instr, defInstr1, defInstr2, subfic))
return 0;
change_opcode(instr, PC_RLWNM);
instr->args[1] = defInstr1->args[1];
defininginstruction[instr->defID + 1] = defininginstruction[defInstr1->defID + 1];
instr->args[2] = defInstr1->args[2];
defininginstruction[instr->defID + 2] = defininginstruction[defInstr1->defID + 2];
instr->args[3].kind = PCOp_IMMEDIATE;
instr->args[3].data.imm.value = 0;
instr->args[3].data.imm.obj = NULL;
instr->args[4].kind = PCOp_IMMEDIATE;
instr->args[4].data.imm.value = 31;
instr->args[4].data.imm.obj = NULL;
deletepcode(defInstr1);
deletepcode(defInstr2);
deletepcode(subfic);
return 1;
}
}
return 0;
}
static int RLWINM_RLWIMI_STW(PCode *instr, UInt32 *masks) {
PCode *newInstr;
Boolean isZeroOffset;
int flags;
PCode *scan;
int i;
PCode *array[4];
flags = 0;
isZeroOffset = 0;
if (instr->op == PC_STW && instr->args[2].kind == PCOp_IMMEDIATE && instr->args[2].data.imm.value == 0)
isZeroOffset = 1;
scan = instr;
for (i = 0; i < 4; i++) {
if (scan->op == PC_RLWINM)
array[i] = defininginstruction[scan->defID + 1];
else
array[i] = defininginstruction[scan->defID];
scan = array[i];
if (array[0]->args[1].data.reg.reg != scan->args[1].data.reg.reg)
return 0;
if (i < 3) {
if (scan->op != PC_RLWIMI)
return 0;
} else {
if (scan->op != PC_RLWINM)
return 0;
}
if (scan->args[2].data.imm.value == 8) {
if (scan->args[3].data.imm.value == 24 && scan->args[4].data.imm.value == 31) {
if (flags & 1)
return 0;
flags |= 1;
} else if (scan->args[3].data.imm.value == 8 && scan->args[4].data.imm.value == 15) {
if (flags & 4)
return 0;
flags |= 4;
} else {
return 0;
}
} else if (scan->args[2].data.imm.value == 24) {
if (scan->args[3].data.imm.value == 0 && scan->args[4].data.imm.value == 7) {
if (flags & 8)
return 0;
flags |= 8;
} else if (scan->args[3].data.imm.value == 16 && scan->args[4].data.imm.value == 23) {
if (flags & 2)
return 0;
flags |= 2;
} else {
return 0;
}
} else {
return 0;
}
}
if (definedbetween(instr, array[3], &array[0]->args[1]))
return 0;
if (instr->op == PC_STWX) {
change_opcode(instr, PC_STWBRX);
instr->args[0] = array[0]->args[1];
defininginstruction[instr->defID] = defininginstruction[array[3]->defID + 1];
return 1;
}
if (instr->op == PC_STW) {
if (!isZeroOffset) {
if (masks[RegClass_GPR] & (1 << array[0]->args[0].data.reg.reg))
return 0;
if (usedbetween(array[2], array[3], &array[0]->args[0]))
return 0;
if (usedbetween(array[1], array[2], &array[0]->args[0]))
return 0;
if (usedbetween(array[0], array[1], &array[0]->args[0]))
return 0;
if (usedbetween(instr, array[0], &array[0]->args[0]))
return 0;
}
defininginstruction[instr->defID] = defininginstruction[array[3]->defID + 1];
if (!isZeroOffset) {
newInstr = makepcode(PC_STWBRX, array[3]->args[1].data.reg.reg, 0, instr->args[0].data.reg.reg);
newInstr->alias = instr->alias;
change_opcode(instr, PC_ADDI);
insertpcodeafter(instr, newInstr);
masks[RegClass_GPR] |= 1 << newInstr->args[0].data.reg.reg;
masks[RegClass_GPR] |= 1 << newInstr->args[2].data.reg.reg;
instr->args[0].data.reg.effect &= ~EffectRead;
instr->args[0].data.reg.effect |= EffectWrite;
defininginstruction[instr->defID] = instr;
deletepcode(array[0]);
deletepcode(array[1]);
deletepcode(array[2]);
deletepcode(array[3]);
} else {
change_opcode(instr, PC_STWBRX);
instr->args[0] = array[0]->args[1];
instr->args[2] = instr->args[1];
defininginstruction[instr->defID + 2] = defininginstruction[instr->defID + 1];
instr->args[1].kind = PCOp_REGISTER;
instr->args[1].arg = RegClass_GPR;
instr->args[1].data.reg.reg = 0;
instr->args[1].data.reg.effect = 0;
}
return 1;
}
return 0;
}
static int RLWINM_RLWIMI_STH(PCode *instr, UInt32 *masks) {
PCode *newInstr;
Boolean isZeroOffset;
int flags;
PCode *scan;
int i;
PCode *array[2];
flags = 0;
isZeroOffset = 0;
if (instr->op == PC_STH && instr->args[2].kind == PCOp_IMMEDIATE && instr->args[2].data.imm.value == 0)
isZeroOffset = 1;
scan = instr;
for (i = 0; i < 2; i++) {
if (scan->op == PC_RLWINM)
array[i] = defininginstruction[scan->defID + 1];
else
array[i] = defininginstruction[scan->defID];
scan = array[i];
if (array[0]->args[1].data.reg.reg != scan->args[1].data.reg.reg)
return 0;
if (i < 1) {
if (scan->op != PC_RLWIMI)
return 0;
} else {
if (scan->op != PC_RLWINM)
return 0;
}
if (scan->args[2].data.imm.value == 8) {
if (scan->args[3].data.imm.value == 16 && scan->args[4].data.imm.value == 23) {
if (flags & 2)
return 0;
flags |= 2;
} else {
return 0;
}
} else if (scan->args[2].data.imm.value == 24) {
if (scan->args[3].data.imm.value == 24 && scan->args[4].data.imm.value == 31) {
if (flags & 1)
return 0;
flags |= 1;
} else {
return 0;
}
} else {
return 0;
}
}
if (definedbetween(instr, array[1], &array[0]->args[1]))
return 0;
if (instr->op == PC_STHX) {
change_opcode(instr, PC_STHBRX);
instr->args[0] = array[0]->args[1];
defininginstruction[instr->defID] = defininginstruction[array[1]->defID + 1];
return 1;
}
if (instr->op == PC_STH) {
if (!isZeroOffset) {
if (masks[RegClass_GPR] & (1 << array[0]->args[0].data.reg.reg))
return 0;
if (usedbetween(array[0], array[1], &array[0]->args[0]))
return 0;
if (usedbetween(instr, array[0], &array[0]->args[0]))
return 0;
}
defininginstruction[instr->defID] = defininginstruction[array[1]->defID + 1];
if (!isZeroOffset) {
newInstr = makepcode(PC_STHBRX, array[1]->args[1].data.reg.reg, 0, instr->args[0].data.reg.reg);
newInstr->alias = instr->alias;
change_opcode(instr, PC_ADDI);
instr->args[0].data.reg.effect &= ~EffectRead;
instr->args[0].data.reg.effect |= EffectWrite;
defininginstruction[instr->defID] = instr;
insertpcodeafter(instr, newInstr);
masks[RegClass_GPR] |= 1 << newInstr->args[0].data.reg.reg;
masks[RegClass_GPR] |= 1 << newInstr->args[2].data.reg.reg;
deletepcode(array[0]);
deletepcode(array[1]);
} else {
change_opcode(instr, PC_STHBRX);
instr->args[0] = array[0]->args[1];
instr->args[2] = instr->args[1];
defininginstruction[instr->defID + 2] = defininginstruction[instr->defID + 1];
instr->args[1].kind = PCOp_REGISTER;
instr->args[1].arg = RegClass_GPR;
instr->args[1].data.reg.reg = 0;
instr->args[1].data.reg.effect = 0;
}
return 1;
}
return 0;
}
static void peepholeoptimizeblock(PCodeBlock *block) {
RegClass rclass;
PCode *instr;
PCodeArg *op;
int i;
Pattern *pattern;
UInt32 masks[RegClassMax];
for (rclass = 0; rclass < RegClassMax; rclass++)
masks[rclass] = liveregs[rclass][block->blockIndex].xC;
for (instr = block->lastPCode; instr; instr = instr->prevPCode) {
if (dead(instr, masks)) {
deletepcode(instr);
} else {
pattern = peepholepatterns[instr->op];
while (pattern) {
if (pattern->func(instr, masks)) {
if (!instr->block)
break;
pattern = peepholepatterns[instr->op];
} else {
pattern = pattern->next;
}
}
if (instr->block) {
for (op = instr->args, i = instr->argCount; i--; op++) {
if (op->kind == PCOp_REGISTER && (op->data.reg.effect & EffectWrite))
masks[op->arg] &= ~(1 << op->data.reg.reg);
}
for (op = instr->args, i = instr->argCount; i--; op++) {
if (op->kind == PCOp_REGISTER && (op->data.reg.effect & EffectRead))
masks[op->arg] |= 1 << op->data.reg.reg;
}
}
}
}
}
static SInt32 computepossiblemask(PCode *instr, short reg) {
SInt32 mask;
SInt32 val;
PCodeArg *op;
int i;
mask = 0xFFFFFFFF;
while (instr) {
for (op = instr->args, i = instr->argCount; i--; op++) {
if (PC_OP_IS_WRITE_REGISTER(op, RegClass_GPR, reg)) {
switch (instr->op) {
case PC_LBZ:
case PC_LBZU:
case PC_LBZX:
case PC_LBZUX:
mask = 0xFF;
break;
case PC_LHZ:
case PC_LHZU:
case PC_LHZX:
case PC_LHZUX:
mask = 0xFFFF;
break;
case PC_LI:
mask = instr->args[1].data.imm.value;
break;
case PC_SRAWI:
mask = computepossiblemask(instr->prevPCode, instr->args[1].data.reg.reg) >> instr->args[2].data.imm.value;
break;
case PC_RLWINM:
val = computepossiblemask(instr->prevPCode, instr->args[1].data.reg.reg);
mask = (val << instr->args[2].data.imm.value) | ((UInt32) val >> (32 - instr->args[2].data.imm.value));
if (instr->args[3].data.imm.value <= instr->args[4].data.imm.value)
val = ((instr->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> instr->args[3].data.imm.value)) & ~(((instr->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (instr->args[4].data.imm.value + 1)));
else
val = ((instr->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> instr->args[3].data.imm.value)) | ~(((instr->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (instr->args[4].data.imm.value + 1)));
mask &= val;
break;
case PC_RLWIMI:
val = computepossiblemask(instr->prevPCode, instr->args[1].data.reg.reg);
mask = (val << instr->args[2].data.imm.value) | ((UInt32) val >> (32 - instr->args[2].data.imm.value));
if (instr->args[3].data.imm.value <= instr->args[4].data.imm.value)
val = ((instr->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> instr->args[3].data.imm.value)) & ~(((instr->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (instr->args[4].data.imm.value + 1)));
else
val = ((instr->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> instr->args[3].data.imm.value)) | ~(((instr->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (instr->args[4].data.imm.value + 1)));
mask &= val;
mask |= computepossiblemask(instr->prevPCode, instr->args[0].data.reg.reg);
break;
case PC_OR:
mask = computepossiblemask(instr->prevPCode, instr->args[1].data.reg.reg) |
computepossiblemask(instr->prevPCode, instr->args[2].data.reg.reg);
break;
case PC_ORI:
mask = instr->args[2].data.imm.value |
computepossiblemask(instr->prevPCode, instr->args[1].data.reg.reg);
break;
case PC_AND:
mask = computepossiblemask(instr->prevPCode, instr->args[1].data.reg.reg) &
computepossiblemask(instr->prevPCode, instr->args[2].data.reg.reg);
break;
case PC_ANDI:
mask = instr->args[2].data.imm.value &
computepossiblemask(instr->prevPCode, instr->args[1].data.reg.reg);
break;
case PC_MR:
mask = computepossiblemask(instr->prevPCode, instr->args[1].data.reg.reg);
break;
}
return mask;
}
}
instr = instr->prevPCode;
}
return mask;
}
static UInt32 fillmaskholes(UInt32 mask) {
UInt32 oneBit;
UInt32 allBits;
UInt32 result;
oneBit = 1;
allBits = 0xFFFFFFFF;
result = 0;
if ((mask & 1) && (mask & 0x80000000)) {
result = 0xFFFFFFFF;
while ((mask & oneBit) == 1) {
oneBit <<= 1;
}
while ((mask & oneBit) == 0) {
result &= ~oneBit;
oneBit <<= 1;
}
return result;
} else {
while ((mask & oneBit) == 0 && (mask & allBits) != 0) {
oneBit <<= 1;
allBits <<= 1;
}
while ((mask & allBits) != 0) {
result |= oneBit;
oneBit <<= 1;
allBits <<= 1;
}
return result;
}
}
static int canuseinsert(PCode *instr1, PCode *instr2, short reg) {
if (computepossiblemask(instr2, reg) & fillmaskholes(computepossiblemask(instr1, instr1->args[0].data.reg.reg)))
return 0;
return 1;
}
static PCode *find_def_backwords(PCode *instr, short reg) {
int i;
while (instr) {
for (i = 0; i < instr->argCount; i++) {
if (PC_OP_IS_WRITE_REGISTER(&instr->args[i], RegClass_GPR, reg))
return instr;
}
instr = instr->prevPCode;
}
return NULL;
}
static void adjustforward(PCodeBlock *block) {
PCode *instr;
PCode *scan;
PCode *tmp;
PCodeArg *op;
int i;
short opcode;
short reg0;
short reg1;
SInt32 valA;
SInt32 valB;
instr = block->firstPCode;
while (instr) {
if (instr->op == PC_RLWINM) {
SInt32 val2;
SInt32 val3;
SInt32 val4;
short start;
short end;
short flag1 = 0;
short flag2 = 0;
reg0 = instr->args[0].data.reg.reg;
reg1 = instr->args[1].data.reg.reg;
val2 = instr->args[2].data.imm.value;
val3 = instr->args[3].data.imm.value;
val4 = instr->args[4].data.imm.value;
for (scan = instr->nextPCode; scan; scan = scan->nextPCode) {
opcode = scan->op;
if (opcode == PC_RLWINM && scan->args[1].data.reg.reg == reg0) {
if (
scan->args[3].data.imm.value == val3 &&
scan->args[4].data.imm.value == val4 &&
scan->args[2].data.imm.value == 0
)
{
if (PCODE_FLAG_SET_F(scan) & fRecordBit) {
if (!flag1) {
pcsetrecordbit(instr);
change_opcode(scan, PC_MR);
scan->flags &= ~fRecordBit;
scan->flags |= fIsMove;
change_num_operands(scan, 2);
} else {
change_opcode(scan, PC_MR);
scan->args[2] = scan->args[5];
change_num_operands(scan, 3);
}
} else {
change_opcode(scan, PC_MR);
change_num_operands(scan, 2);
}
}
else if (
reg0 != reg1 &&
!flag2 &&
canmergemasks(
val3,
val4,
scan->args[2].data.imm.value,
scan->args[3].data.imm.value,
scan->args[4].data.imm.value,
&start, &end)
)
{
scan->args[1].data.reg.reg = reg1;
scan->args[2].data.imm.value = (scan->args[2].data.imm.value + instr->args[2].data.imm.value) & 31;
scan->args[3].data.imm.value = start;
scan->args[4].data.imm.value = end;
}
}
else if (
opcode == PC_SRAWI &&
scan->args[1].data.reg.reg == reg0 &&
reg0 != reg1 &&
instr->args[2].data.imm.value == 0 &&
!(computepossiblemask(instr, reg0) & 0x80000000) &&
!flag2 &&
canmergemasks(val3, val4, 32 - scan->args[2].data.imm.value, scan->args[2].data.imm.value, 31, &start, &end) &&
!isSPRlive(scan, 0)
)
{
insertpcodeafter(scan, makepcode(
PC_RLWINM, scan->args[0].data.reg.reg, reg1,
32 - scan->args[2].data.imm.value, start, end
));
if (PCODE_FLAG_SET_F(scan) & fRecordBit)
pcsetrecordbit(scan->nextPCode);
deletepcode(scan);
}
else if (
opcode == PC_OR &&
!flag2 &&
reg0 != reg1 &&
!(PCODE_FLAG_SET_F(scan) & fRecordBit) &&
!(PCODE_FLAG_SET_F(instr) & fRecordBit) &&
scan->args[0].data.reg.reg != instr->args[1].data.reg.reg
)
{
if (scan->args[1].data.reg.reg == reg0 && canuseinsert(instr, scan, scan->args[2].data.reg.reg)) {
op = &scan->args[2];
tmp = find_def_backwords(scan->prevPCode, scan->args[2].data.reg.reg);
if (tmp->op == PC_RLWINM && tmp->args[2].data.imm.value == 0) {
if (instr->args[3].data.imm.value <= instr->args[4].data.imm.value)
valA = ((instr->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> instr->args[3].data.imm.value)) & ~(((instr->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (instr->args[4].data.imm.value + 1)));
else
valA = ((instr->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> instr->args[3].data.imm.value)) | ~(((instr->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (instr->args[4].data.imm.value + 1)));
if (tmp->args[3].data.imm.value <= tmp->args[4].data.imm.value)
valB = ((tmp->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> tmp->args[3].data.imm.value)) & ~(((tmp->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (tmp->args[4].data.imm.value + 1)));
else
valB = ((tmp->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> tmp->args[3].data.imm.value)) | ~(((tmp->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (tmp->args[4].data.imm.value + 1)));
if (valA == ~valB)
op = &tmp->args[1];
}
change_opcode(scan, PC_MR);
scan->args[1] = *op;
change_num_operands(scan, 2);
tmp = copypcode(instr);
change_opcode(tmp, PC_RLWIMI);
tmp->args[0] = scan->args[0];
tmp->args[0].data.reg.effect |= EffectRead;
if (ismaskconstant(fillmaskholes(computepossiblemask(instr, instr->args[0].data.reg.reg)), &start, &end)) {
tmp->args[3].data.imm.value = start;
tmp->args[4].data.imm.value = end;
}
insertpcodeafter(scan, tmp);
break;
}
if (
scan->args[2].data.reg.reg == reg0 &&
canuseinsert(instr, scan, scan->args[1].data.reg.reg)
)
{
op = &scan->args[1];
tmp = find_def_backwords(scan->prevPCode, scan->args[1].data.reg.reg);
if (tmp->op == PC_RLWINM && tmp->args[2].data.imm.value == 0) {
if (instr->args[3].data.imm.value <= instr->args[4].data.imm.value)
valA = ((instr->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> instr->args[3].data.imm.value)) & ~(((instr->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (instr->args[4].data.imm.value + 1)));
else
valA = ((instr->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> instr->args[3].data.imm.value)) | ~(((instr->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (instr->args[4].data.imm.value + 1)));
if (tmp->args[3].data.imm.value <= tmp->args[4].data.imm.value)
valB = ((tmp->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> tmp->args[3].data.imm.value)) & ~(((tmp->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (tmp->args[4].data.imm.value + 1)));
else
valB = ((tmp->args[3].data.imm.value > 31) ? 0 : (0xFFFFFFFFu >> tmp->args[3].data.imm.value)) | ~(((tmp->args[4].data.imm.value + 1) > 31) ? 0 : (0xFFFFFFFFu >> (tmp->args[4].data.imm.value + 1)));
if (valA == ~valB)
op = &tmp->args[1];
}
change_opcode(scan, PC_MR);
scan->args[1] = *op;
change_num_operands(scan, 2);
tmp = copypcode(instr);
change_opcode(tmp, PC_RLWIMI);
tmp->args[0] = scan->args[0];
tmp->args[0].data.reg.effect |= EffectRead;
if (ismaskconstant(fillmaskholes(computepossiblemask(instr, instr->args[0].data.reg.reg)), &start, &end)) {
tmp->args[3].data.imm.value = start;
tmp->args[4].data.imm.value = end;
}
insertpcodeafter(scan, tmp);
break;
}
}
else if (
!flag2 &&
reg0 != reg1 &&
val4 == 31 &&
instr->args[2].data.imm.value == 0 &&
(
((opcode == PC_STB || opcode == PC_STBX) && val3 <= 24) ||
((opcode == PC_STH || opcode == PC_STHX) && val3 <= 16)
) &&
scan->args[0].data.reg.reg == reg0
)
{
scan->args[0].data.reg.reg = reg1;
}
else if (
opcode == PC_EXTSH &&
scan->args[1].data.reg.reg == reg0 &&
val2 == 0 &&
val3 > 16 &&
val3 < val4
)
{
change_opcode(scan, PC_MR);
if ((PCODE_FLAG_SET_F(scan) & fRecordBit) && !flag1) {
pcsetrecordbit(instr);
scan->flags &= ~fRecordBit;
scan->flags |= fIsMove;
change_num_operands(scan, 2);
}
}
else if (
opcode == PC_EXTSB &&
scan->args[1].data.reg.reg == reg0 &&
val2 == 0 &&
val3 > 24 &&
val3 < val4
)
{
change_opcode(scan, PC_MR);
if ((PCODE_FLAG_SET_F(scan) & fRecordBit) && !flag1) {
pcsetrecordbit(instr);
scan->flags &= ~fRecordBit;
scan->flags |= fIsMove;
change_num_operands(scan, 2);
}
}
for (op = scan->args, i = scan->argCount; i--; op++) {
if (PC_OP_IS_WRITE_REGISTER(op, RegClass_GPR, reg0)) {
scan = block->lastPCode;
break;
}
if (PC_OP_IS_WRITE_REGISTER(op, RegClass_GPR, reg1))
flag2 = 1;
if (PC_OP_IS_REGISTER(op, RegClass_CRFIELD, 0))
flag1 = 1;
}
}
} else if (
instr->op == PC_EXTSB &&
(reg0 = instr->args[0].data.reg.reg) != (reg1 = instr->args[1].data.reg.reg)
)
{
short flag = 0;
for (scan = instr->nextPCode; scan; scan = scan->nextPCode) {
if (
(scan->op >= PC_STB && scan->op <= PC_STBUX) &&
scan->args[0].data.reg.reg == reg0
)
{
scan->args[0].data.reg.reg = reg1;
}
else if (
(scan->op == PC_EXTSH || scan->op == PC_EXTSB) &&
scan->args[1].data.reg.reg == reg0
)
{
change_opcode(scan, PC_MR);
if ((PCODE_FLAG_SET_F(scan) & fRecordBit) && !flag) {
pcsetrecordbit(instr);
scan->flags &= ~fRecordBit;
scan->flags |= fIsMove;
change_num_operands(scan, 2);
}
}
for (op = instr->args, i = instr->argCount; i--; op++) {
if (
PC_OP_IS_WRITE_ANY_REGISTER(op, RegClass_GPR) &&
(op->data.reg.reg == reg0 || op->data.reg.reg == reg1)
)
{
scan = block->lastPCode;
break;
}
if (PC_OP_IS_REGISTER(op, RegClass_CRFIELD, 0))
flag = 1;
}
}
} else if (
instr->op == PC_EXTSH &&
(reg0 = instr->args[0].data.reg.reg) != (reg1 = instr->args[1].data.reg.reg)
)
{
short flag = 0;
for (scan = instr->nextPCode; scan; scan = scan->nextPCode) {
if (
((scan->op >= PC_STB && scan->op <= PC_STBUX) || (scan->op >= PC_STH && scan->op <= PC_STHUX)) &&
scan->args[0].data.reg.reg == reg0
)
{
scan->args[0].data.reg.reg = reg1;
}
else if (scan->op == PC_EXTSH && scan->args[1].data.reg.reg == reg0)
{
change_opcode(scan, PC_MR);
if ((PCODE_FLAG_SET_F(scan) & fRecordBit) && !flag) {
pcsetrecordbit(instr);
scan->flags &= ~fRecordBit;
scan->flags |= fIsMove;
change_num_operands(scan, 2);
}
}
for (op = instr->args, i = instr->argCount; i--; op++) {
if (
PC_OP_IS_WRITE_ANY_REGISTER(op, RegClass_GPR) &&
(op->data.reg.reg == reg0 || op->data.reg.reg == reg1)
)
{
scan = block->lastPCode;
break;
}
if (PC_OP_IS_REGISTER(op, RegClass_CRFIELD, 0))
flag = 1;
}
}
} else if (
instr->op == PC_ADDI &&
(reg0 = instr->args[0].data.reg.reg) == (reg1 = instr->args[1].data.reg.reg) &&
instr->args[2].kind == PCOp_IMMEDIATE
)
{
Boolean flag1 = 0;
Boolean flag2 = 0;
SInt32 val2 = instr->args[2].data.imm.value;
for (scan = instr->nextPCode; scan; scan = scan->nextPCode) {
if ((scan->flags & fIsWrite) && scan->args[0].data.reg.reg == reg0)
break;
if (
(scan->flags & (fIsRead | fIsWrite)) &&
scan->args[1].data.reg.reg == reg0 &&
scan->args[2].kind == PCOp_IMMEDIATE &&
FITS_IN_SHORT(val2 + scan->args[2].data.imm.value)
)
{
scan->args[2].data.imm.value += val2;
tmp = instr->prevPCode;
if (
(scan->flags & fIsRead) &&
scan->args[0].data.reg.reg == reg0 &&
scan->args[0].kind == PCOp_REGISTER &&
scan->args[0].arg == RegClass_GPR
)
{
deletepcode(instr);
} else {
deletepcode(instr);
insertpcodeafter(scan, instr);
}
instr = tmp;
break;
}
if (
scan->op == PC_ADDI &&
scan->args[1].data.reg.reg == reg0 &&
scan->args[2].kind == PCOp_IMMEDIATE &&
FITS_IN_SHORT(val2 + scan->args[2].data.imm.value)
)
{
scan->args[2].data.imm.value += val2;
tmp = instr->prevPCode;
if (scan->args[0].data.reg.reg == reg0) {
deletepcode(instr);
} else {
deletepcode(instr);
insertpcodeafter(scan, instr);
}
instr = tmp;
break;
}
if (scan->flags & (fIsBranch | fIsCall)) {
if (flag1 && scan->prevPCode != instr) {
tmp = instr->prevPCode;
deletepcode(instr);
insertpcodebefore(scan, instr);
instr = tmp;
}
break;
}
for (op = scan->args, i = scan->argCount; i--; op++) {
if (PC_OP_IS_R_OR_W_REGISTER(op, RegClass_GPR, reg0)) {
if (flag1 && scan->prevPCode != instr) {
tmp = instr->prevPCode;
deletepcode(instr);
insertpcodebefore(scan, instr);
instr = tmp;
}
flag2 = 1;
break;
}
}
if (flag2)
break;
if (scan->op != PC_ADDI)
flag1 = 1;
if (flag1 && !scan->nextPCode) {
tmp = instr->prevPCode;
deletepcode(instr);
appendpcode(block, instr);
instr = tmp;
break;
}
}
}
if (instr)
instr = instr->nextPCode;
else
instr = block->firstPCode;
}
}
static void installpattern(Opcode opcode, PeepholeFunc func) {
Pattern *pattern = lalloc(sizeof(Pattern));
pattern->func = func;
pattern->next = peepholepatterns[opcode];
peepholepatterns[opcode] = pattern;
}
static void installpeepholepatterns(void) {
int i;
for (i = 0; i < OPCODE_MAX; i++)
peepholepatterns[i] = NULL;
installpattern(PC_AND, NOT_AND);
installpattern(PC_MR, LI_MR);
installpattern(PC_MR, L_MR);
installpattern(PC_FMR, L_FMR);
installpattern(PC_MR, MR_MR);
installpattern(PC_MR, MR_Rx_Rx);
installpattern(PC_FMR, FMR_FMR);
installpattern(PC_FMR, FMR_Fx_Fx);
installpattern(PC_VMR, VMR_VMRP);
installpattern(PC_VMR, VMR_VMR);
installpattern(PC_VMR, VMR_Vx_Vx);
installpattern(PC_VMR, VSPLTIS_VMR);
installpattern(PC_CMPI, MR_CMPI);
installpattern(PC_RLWIMI, RLWINM_RLWINM);
installpattern(PC_RLWINM, RLWINM_RLWINM);
installpattern(PC_RLWINM, EXTSB_RLWINM);
installpattern(PC_RLWINM, EXTSH_RLWINM);
installpattern(PC_RLWINM, LBZ_RLWINM);
installpattern(PC_RLWINM, LHZ_RLWINM);
installpattern(PC_EXTSH, LHA_EXTSH);
installpattern(PC_STW, RLWINM_RLWIMI_STW);
installpattern(PC_STWX, RLWINM_RLWIMI_STW);
installpattern(PC_STH, RLWINM_RLWIMI_STH);
installpattern(PC_STHX, RLWINM_RLWIMI_STH);
installpattern(PC_LBZ, ADDI_L_S);
installpattern(PC_LHZ, ADDI_L_S);
installpattern(PC_LHA, ADDI_L_S);
installpattern(PC_LWZ, ADDI_L_S);
installpattern(PC_STB, ADDI_L_S);
installpattern(PC_STH, ADDI_L_S);
installpattern(PC_STW, ADDI_L_S);
installpattern(PC_LFS, ADDI_L_S);
installpattern(PC_LFD, ADDI_L_S);
installpattern(PC_STFS, ADDI_L_S);
installpattern(PC_STFD, ADDI_L_S);
installpattern(PC_LBZU, ADDI_LU_SU);
installpattern(PC_LHZU, ADDI_LU_SU);
installpattern(PC_LHAU, ADDI_LU_SU);
installpattern(PC_LWZU, ADDI_LU_SU);
installpattern(PC_STBU, ADDI_LU_SU);
installpattern(PC_STHU, ADDI_LU_SU);
installpattern(PC_STWU, ADDI_LU_SU);
installpattern(PC_LFSU, ADDI_LU_SU);
installpattern(PC_LFDU, ADDI_LU_SU);
installpattern(PC_STFSU, ADDI_LU_SU);
installpattern(PC_STFDU, ADDI_LU_SU);
installpattern(PC_LBZ, L_S_ADDI);
installpattern(PC_LHZ, L_S_ADDI);
installpattern(PC_LHA, L_S_ADDI);
installpattern(PC_LWZ, L_S_ADDI);
installpattern(PC_STB, L_S_ADDI);
installpattern(PC_STH, L_S_ADDI);
installpattern(PC_STW, L_S_ADDI);
installpattern(PC_LFS, L_S_ADDI);
installpattern(PC_LFD, L_S_ADDI);
installpattern(PC_STFS, L_S_ADDI);
installpattern(PC_STFD, L_S_ADDI);
installpattern(PC_STB, L_S);
installpattern(PC_STH, L_S);
installpattern(PC_STW, L_S);
installpattern(PC_STFS, L_S);
installpattern(PC_STFD, L_S);
installpattern(PC_STBX, L_S);
installpattern(PC_STHX, L_S);
installpattern(PC_STWX, L_S);
installpattern(PC_STFSX, L_S);
installpattern(PC_STFDX, L_S);
installpattern(PC_BT, LBZ_EXTSB_CMPI_BC);
installpattern(PC_BF, LBZ_EXTSB_CMPI_BC);
installpattern(PC_BT, RLWINM_CMPLI_BC);
installpattern(PC_BF, RLWINM_CMPLI_BC);
installpattern(PC_BT, LI_CMP_BC);
installpattern(PC_BF, LI_CMP_BC);
installpattern(PC_RLWINM, RLWINM_RLWINM);
installpattern(PC_MULLI, MULLI_MULLI);
installpattern(PC_ADDI, ADDI_ADDI);
installpattern(PC_SRAWI, SRAWI_SRAWI);
installpattern(PC_MR, MR_ADDI);
installpattern(PC_OR, SRW_SUBFIC_RLW_OR);
}
void peepholeoptimizeforward(Object *func) {
PCodeBlock *block;
for (block = pcbasicblocks; block; block = block->nextBlock) {
if (block->pcodeCount >= 2)
adjustforward(block);
}
}
void peepholemergeblocks(Object *func, Boolean flag) {
PCodeBlock *block;
PCodeBlock *next;
Boolean flag2;
PCode *instr;
PCode *nextinstr;
PCLink *link;
PCLink *link2;
for (block = pcbasicblocks; block; block = block->nextBlock) {
flag2 = 0;
next = block->nextBlock;
if (!flag) {
flag2 = next && (next->flags & fIsEpilogue);
if (block->flags & fIsProlog)
continue;
}
if (block->pcodeCount > 0) {
for (instr = block->firstPCode; instr; instr = instr->nextPCode) {
if (instr->flags & (fIsCall | fSideEffects))
break;
}
if (instr)
continue;
instr = block->lastPCode;
if (instr && instr->op == PC_B) {
if (instr->args[0].kind == PCOp_LABEL && instr->args[0].data.label.label->block == next)
deletepcode(instr);
else
continue;
}
instr = block->lastPCode;
if (instr && (instr->flags & fIsBranch) && instr->op != PC_B)
continue;
while (
block->successors->block == next &&
block->successors->nextLink == NULL &&
next->predecessors->block == block &&
next->predecessors->nextLink == NULL &&
!flag2 &&
!(next->flags & fPCBlockFlag8000) &&
(block->pcodeCount + next->pcodeCount) <= 100
)
{
if (next->pcodeCount > 0) {
for (instr = next->firstPCode; instr; instr = nextinstr) {
nextinstr = instr->nextPCode;
if (instr->flags & (fIsCall | fSideEffects))
break;
deletepcode(instr);
if (instr->op != PC_B) {
appendpcode(block, instr);
} else if (instr->args[0].kind == PCOp_LABEL) {
if (instr->args[0].data.label.label->block != next->nextBlock)
appendpcode(block, instr);
} else {
appendpcode(block, instr);
}
}
}
if (next->pcodeCount != 0)
break;
if (next == epilogue)
break;
block->successors = next->successors;
for (link = block->successors; link; link = link->nextLink) {
for (link2 = link->block->predecessors; link2; link2 = link2->nextLink) {
if (link2->block == next) {
link2->block = block;
break;
}
}
}
block->nextBlock = next->nextBlock;
if (block->nextBlock)
block->nextBlock->prevBlock = block;
next->flags |= fDeleted;
next = block->nextBlock;
if (!flag)
flag2 = next && (next->flags & fIsEpilogue);
}
}
}
}
void peepholeoptimizepcode(Object *func) {
PCodeBlock *block;
installpeepholepatterns();
computeliveregisters(func);
for (block = pcbasicblocks; block; block = block->nextBlock) {
if (block->pcodeCount >= 1) {
computeinstructionpredecessors(block);
peepholeoptimizeblock(block);
freeoheap();
}
}
}