Gitiles
Code Review Sign In
LeafOS / LeafOS-Project / android_art / 2acf36d8cfeb5ddb293904148aa70f25ef6d8845 / . / src / compiler / codegen / mips / Mips32 / Factory.cc
blob: 1162702f68dd6ff061757d3df422b60fd5eed9b5 [file] [log] [blame]
/*
* Copyright (C) 2012 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
namespace art {
/*
* This file contains codegen for the MIPS32 ISA and is intended to be
* includes by:
*
* Codegen-$(TARGET_ARCH_VARIANT).c
*
*/
static int coreRegs[] = {r_ZERO, r_AT, r_V0, r_V1, r_A0, r_A1, r_A2, r_A3,
r_T0, r_T1, r_T2, r_T3, r_T4, r_T5, r_T6, r_T7,
r_S0, r_S1, r_S2, r_S3, r_S4, r_S5, r_S6, r_S7, r_T8,
r_T9, r_K0, r_K1, r_GP, r_SP, r_FP, r_RA};
static int reservedRegs[] = {r_ZERO, r_AT, r_S0, r_S1, r_K0, r_K1, r_GP, r_SP,
r_RA};
static int coreTemps[] = {r_V0, r_V1, r_A0, r_A1, r_A2, r_A3, r_T0, r_T1, r_T2,
r_T3, r_T4, r_T5, r_T6, r_T7, r_T8, r_T9};
#ifdef __mips_hard_float
static int fpRegs[] = {r_F0, r_F1, r_F2, r_F3, r_F4, r_F5, r_F6, r_F7,
r_F8, r_F9, r_F10, r_F11, r_F12, r_F13, r_F14, r_F15};
static int fpTemps[] = {r_F0, r_F1, r_F2, r_F3, r_F4, r_F5, r_F6, r_F7,
r_F8, r_F9, r_F10, r_F11, r_F12, r_F13, r_F14, r_F15};
#endif
void genBarrier(CompilationUnit *cUnit);
void storePair(CompilationUnit *cUnit, int base, int lowReg,
int highReg);
void loadPair(CompilationUnit *cUnit, int base, int lowReg, int highReg);
LIR *loadWordDisp(CompilationUnit *cUnit, int rBase, int displacement,
int rDest);
LIR *storeWordDisp(CompilationUnit *cUnit, int rBase,
int displacement, int rSrc);
LIR *loadConstant(CompilationUnit *cUnit, int rDest, int value);
#ifdef __mips_hard_float
LIR *fpRegCopy(CompilationUnit *cUnit, int rDest, int rSrc)
{
int opcode;
/* must be both DOUBLE or both not DOUBLE */
DCHECK_EQ(DOUBLEREG(rDest),DOUBLEREG(rSrc));
if (DOUBLEREG(rDest)) {
opcode = kMipsFmovd;
} else {
if (SINGLEREG(rDest)) {
if (SINGLEREG(rSrc)) {
opcode = kMipsFmovs;
} else {
/* note the operands are swapped for the mtc1 instr */
int tOpnd = rSrc;
rSrc = rDest;
rDest = tOpnd;
opcode = kMipsMtc1;
}
} else {
DCHECK(SINGLEREG(rSrc));
opcode = kMipsMfc1;
}
}
LIR* res = rawLIR(cUnit, cUnit->currentDalvikOffset, opcode, rSrc, rDest);
if (!(cUnit->disableOpt & (1 << kSafeOptimizations)) && rDest == rSrc) {
res->flags.isNop = true;
}
return res;
}
#endif
/*
* Load a immediate using a shortcut if possible; otherwise
* grab from the per-translation literal pool. If target is
* a high register, build constant into a low register and copy.
*
* No additional register clobbering operation performed. Use this version when
* 1) rDest is freshly returned from oatAllocTemp or
* 2) The codegen is under fixed register usage
*/
LIR *loadConstantNoClobber(CompilationUnit *cUnit, int rDest,
int value)
{
LIR *res;
#ifdef __mips_hard_float
int rDestSave = rDest;
int isFpReg = FPREG(rDest);
if (isFpReg) {
DCHECK(SINGLEREG(rDest));
rDest = oatAllocTemp(cUnit);
}
#endif
/* See if the value can be constructed cheaply */
if (value == 0) {
res = newLIR2(cUnit, kMipsMove, rDest, r_ZERO);
} else if ((value > 0) && (value <= 65535)) {
res = newLIR3(cUnit, kMipsOri, rDest, r_ZERO, value);
} else if ((value < 0) && (value >= -32768)) {
res = newLIR3(cUnit, kMipsAddiu, rDest, r_ZERO, value);
} else {
res = newLIR2(cUnit, kMipsLui, rDest, value>>16);
if (value & 0xffff)
newLIR3(cUnit, kMipsOri, rDest, rDest, value);
}
#ifdef __mips_hard_float
if (isFpReg) {
newLIR2(cUnit, kMipsMtc1, rDest, rDestSave);
oatFreeTemp(cUnit, rDest);
}
#endif
return res;
}
LIR *opBranchUnconditional(CompilationUnit *cUnit, OpKind op)
{
DCHECK_EQ(op, kOpUncondBr);
return newLIR1(cUnit, kMipsB, 0 /* offset to be patched */ );
}
LIR *loadMultiple(CompilationUnit *cUnit, int rBase, int rMask);
LIR *opReg(CompilationUnit *cUnit, OpKind op, int rDestSrc)
{
MipsOpCode opcode = kMipsNop;
switch (op) {
case kOpBlx:
opcode = kMipsJalr;
break;
case kOpBx:
return newLIR1(cUnit, kMipsJr, rDestSrc);
break;
default:
LOG(FATAL) << "Bad case in opReg";
}
return newLIR2(cUnit, opcode, r_RA, rDestSrc);
}
LIR *opRegRegImm(CompilationUnit *cUnit, OpKind op, int rDest,
int rSrc1, int value);
LIR *opRegImm(CompilationUnit *cUnit, OpKind op, int rDestSrc1,
int value)
{
LIR *res;
bool neg = (value < 0);
int absValue = (neg) ? -value : value;
bool shortForm = (absValue & 0xff) == absValue;
MipsOpCode opcode = kMipsNop;
switch (op) {
case kOpAdd:
return opRegRegImm(cUnit, op, rDestSrc1, rDestSrc1, value);
break;
case kOpSub:
return opRegRegImm(cUnit, op, rDestSrc1, rDestSrc1, value);
break;
default:
LOG(FATAL) << "Bad case in opRegImm";
break;
}
if (shortForm)
res = newLIR2(cUnit, opcode, rDestSrc1, absValue);
else {
int rScratch = oatAllocTemp(cUnit);
res = loadConstant(cUnit, rScratch, value);
if (op == kOpCmp)
newLIR2(cUnit, opcode, rDestSrc1, rScratch);
else
newLIR3(cUnit, opcode, rDestSrc1, rDestSrc1, rScratch);
}
return res;
}
LIR *opRegRegReg(CompilationUnit *cUnit, OpKind op, int rDest,
int rSrc1, int rSrc2)
{
MipsOpCode opcode = kMipsNop;
switch (op) {
case kOpAdd:
opcode = kMipsAddu;
break;
case kOpSub:
opcode = kMipsSubu;
break;
case kOpAnd:
opcode = kMipsAnd;
break;
case kOpMul:
opcode = kMipsMul;
break;
case kOpOr:
opcode = kMipsOr;
break;
case kOpXor:
opcode = kMipsXor;
break;
case kOpLsl:
opcode = kMipsSllv;
break;
case kOpLsr:
opcode = kMipsSrlv;
break;
case kOpAsr:
opcode = kMipsSrav;
break;
case kOpAdc:
case kOpSbc:
LOG(FATAL) << "No carry bit on MIPS";
break;
default:
LOG(FATAL) << "bad case in opRegRegReg";
break;
}
return newLIR3(cUnit, opcode, rDest, rSrc1, rSrc2);
}
LIR *opRegRegImm(CompilationUnit *cUnit, OpKind op, int rDest,
int rSrc1, int value)
{
LIR *res;
MipsOpCode opcode = kMipsNop;
bool shortForm = true;
switch (op) {
case kOpAdd:
if (IS_SIMM16(value)) {
opcode = kMipsAddiu;
}
else {
shortForm = false;
opcode = kMipsAddu;
}
break;
case kOpSub:
if (IS_SIMM16((-value))) {
value = -value;
opcode = kMipsAddiu;
}
else {
shortForm = false;
opcode = kMipsSubu;
}
break;
case kOpLsl:
DCHECK(value >= 0 && value <= 31);
opcode = kMipsSll;
break;
case kOpLsr:
DCHECK(value >= 0 && value <= 31);
opcode = kMipsSrl;
break;
case kOpAsr:
DCHECK(value >= 0 && value <= 31);
opcode = kMipsSra;
break;
case kOpAnd:
if (IS_UIMM16((value))) {
opcode = kMipsAndi;
}
else {
shortForm = false;
opcode = kMipsAnd;
}
break;
case kOpOr:
if (IS_UIMM16((value))) {
opcode = kMipsOri;
}
else {
shortForm = false;
opcode = kMipsOr;
}
break;
case kOpXor:
if (IS_UIMM16((value))) {
opcode = kMipsXori;
}
else {
shortForm = false;
opcode = kMipsXor;
}
break;
case kOpMul:
shortForm = false;
opcode = kMipsMul;
break;
default:
LOG(FATAL) << "Bad case in opRegRegImm";
break;
}
if (shortForm)
res = newLIR3(cUnit, opcode, rDest, rSrc1, value);
else {
if (rDest != rSrc1) {
res = loadConstant(cUnit, rDest, value);
newLIR3(cUnit, opcode, rDest, rSrc1, rDest);
} else {
int rScratch = oatAllocTemp(cUnit);
res = loadConstant(cUnit, rScratch, value);
newLIR3(cUnit, opcode, rDest, rSrc1, rScratch);
}
}
return res;
}
LIR *opRegReg(CompilationUnit *cUnit, OpKind op, int rDestSrc1,
int rSrc2)
{
MipsOpCode opcode = kMipsNop;
LIR *res;
switch (op) {
case kOpMov:
opcode = kMipsMove;
break;
case kOpMvn:
return newLIR3(cUnit, kMipsNor, rDestSrc1, rSrc2, r_ZERO);
case kOpNeg:
return newLIR3(cUnit, kMipsSubu, rDestSrc1, r_ZERO, rSrc2);
case kOpAdd:
case kOpAnd:
case kOpMul:
case kOpOr:
case kOpSub:
case kOpXor:
return opRegRegReg(cUnit, op, rDestSrc1, rDestSrc1, rSrc2);
case kOp2Byte:
#if __mips_isa_rev>=2
res = newLIR2(cUnit, kMipsSeb, rDestSrc1, rSrc2);
#else
res = opRegRegImm(cUnit, kOpLsl, rDestSrc1, rSrc2, 24);
opRegRegImm(cUnit, kOpAsr, rDestSrc1, rDestSrc1, 24);
#endif
return res;
case kOp2Short:
#if __mips_isa_rev>=2
res = newLIR2(cUnit, kMipsSeh, rDestSrc1, rSrc2);
#else
res = opRegRegImm(cUnit, kOpLsl, rDestSrc1, rSrc2, 16);
opRegRegImm(cUnit, kOpAsr, rDestSrc1, rDestSrc1, 16);
#endif
return res;
case kOp2Char:
return newLIR3(cUnit, kMipsAndi, rDestSrc1, rSrc2, 0xFFFF);
default:
LOG(FATAL) << "Bad case in opRegReg";
break;
}
return newLIR2(cUnit, opcode, rDestSrc1, rSrc2);
}
LIR *loadConstantValueWide(CompilationUnit *cUnit, int rDestLo,
int rDestHi, int valLo, int valHi)
{
LIR *res;
res = loadConstantNoClobber(cUnit, rDestLo, valLo);
loadConstantNoClobber(cUnit, rDestHi, valHi);
return res;
}
/* Load value from base + scaled index. */
LIR *loadBaseIndexed(CompilationUnit *cUnit, int rBase,
int rIndex, int rDest, int scale, OpSize size)
{
LIR *first = NULL;
LIR *res;
MipsOpCode opcode = kMipsNop;
int tReg = oatAllocTemp(cUnit);
#ifdef __mips_hard_float
if (FPREG(rDest)) {
DCHECK(SINGLEREG(rDest));
DCHECK((size == kWord) || (size == kSingle));
size = kSingle;
} else {
if (size == kSingle)
size = kWord;
}
#endif
if (!scale) {
first = newLIR3(cUnit, kMipsAddu, tReg , rBase, rIndex);
} else {
first = opRegRegImm(cUnit, kOpLsl, tReg, rIndex, scale);
newLIR3(cUnit, kMipsAddu, tReg , rBase, tReg);
}
switch (size) {
#ifdef __mips_hard_float
case kSingle:
opcode = kMipsFlwc1;
break;
#endif
case kWord:
opcode = kMipsLw;
break;
case kUnsignedHalf:
opcode = kMipsLhu;
break;
case kSignedHalf:
opcode = kMipsLh;
break;
case kUnsignedByte:
opcode = kMipsLbu;
break;
case kSignedByte:
opcode = kMipsLb;
break;
default:
LOG(FATAL) << "Bad case in loadBaseIndexed";
}
res = newLIR3(cUnit, opcode, rDest, 0, tReg);
oatFreeTemp(cUnit, tReg);
return (first) ? first : res;
}
/* store value base base + scaled index. */
LIR *storeBaseIndexed(CompilationUnit *cUnit, int rBase,
int rIndex, int rSrc, int scale, OpSize size)
{
LIR *first = NULL;
LIR *res;
MipsOpCode opcode = kMipsNop;
int rNewIndex = rIndex;
int tReg = oatAllocTemp(cUnit);
#ifdef __mips_hard_float
if (FPREG(rSrc)) {
DCHECK(SINGLEREG(rSrc));
DCHECK((size == kWord) || (size == kSingle));
size = kSingle;
} else {
if (size == kSingle)
size = kWord;
}
#endif
if (!scale) {
first = newLIR3(cUnit, kMipsAddu, tReg , rBase, rIndex);
} else {
first = opRegRegImm(cUnit, kOpLsl, tReg, rIndex, scale);
newLIR3(cUnit, kMipsAddu, tReg , rBase, tReg);
}
switch (size) {
#ifdef __mips_hard_float
case kSingle:
opcode = kMipsFswc1;
break;
#endif
case kWord:
opcode = kMipsSw;
break;
case kUnsignedHalf:
case kSignedHalf:
opcode = kMipsSh;
break;
case kUnsignedByte:
case kSignedByte:
opcode = kMipsSb;
break;
default:
LOG(FATAL) << "Bad case in storeBaseIndexed";
}
res = newLIR3(cUnit, opcode, rSrc, 0, tReg);
oatFreeTemp(cUnit, rNewIndex);
return first;
}
LIR *loadMultiple(CompilationUnit *cUnit, int rBase, int rMask)
{
int i;
int loadCnt = 0;
LIR *res = NULL ;
genBarrier(cUnit);
for (i = 0; i < 8; i++, rMask >>= 1) {
if (rMask & 0x1) { /* map r0 to MIPS r_A0 */
newLIR3(cUnit, kMipsLw, i+r_A0, loadCnt*4, rBase);
loadCnt++;
}
}
if (loadCnt) {/* increment after */
newLIR3(cUnit, kMipsAddiu, rBase, rBase, loadCnt*4);
}
genBarrier(cUnit);
return res; /* NULL always returned which should be ok since no callers use it */
}
LIR *storeMultiple(CompilationUnit *cUnit, int rBase, int rMask)
{
int i;
int storeCnt = 0;
LIR *res = NULL ;
genBarrier(cUnit);
for (i = 0; i < 8; i++, rMask >>= 1) {
if (rMask & 0x1) { /* map r0 to MIPS r_A0 */
newLIR3(cUnit, kMipsSw, i+r_A0, storeCnt*4, rBase);
storeCnt++;
}
}
if (storeCnt) { /* increment after */
newLIR3(cUnit, kMipsAddiu, rBase, rBase, storeCnt*4);
}
genBarrier(cUnit);
return res; /* NULL always returned which should be ok since no callers use it */
}
LIR *loadBaseDispBody(CompilationUnit *cUnit, MIR *mir, int rBase,
int displacement, int rDest, int rDestHi,
OpSize size, int sReg)
/*
* Load value from base + displacement. Optionally perform null check
* on base (which must have an associated sReg and MIR). If not
* performing null check, incoming MIR can be null. IMPORTANT: this
* code must not allocate any new temps. If a new register is needed
* and base and dest are the same, spill some other register to
* rlp and then restore.
*/
{
LIR *res;
LIR *load = NULL;
LIR *load2 = NULL;
MipsOpCode opcode = kMipsNop;
bool shortForm = IS_SIMM16(displacement);
bool pair = false;
switch (size) {
case kLong:
case kDouble:
pair = true;
opcode = kMipsLw;
#ifdef __mips_hard_float
if (FPREG(rDest)) {
opcode = kMipsFlwc1;
if (DOUBLEREG(rDest)) {
rDest = rDest - FP_DOUBLE;
} else {
DCHECK(FPREG(rDestHi));
DCHECK(rDest == (rDestHi - 1));
}
rDestHi = rDest + 1;
}
#endif
shortForm = IS_SIMM16_2WORD(displacement);
DCHECK_EQ((displacement & 0x3), 0);
break;
case kWord:
case kSingle:
opcode = kMipsLw;
#ifdef __mips_hard_float
if (FPREG(rDest)) {
opcode = kMipsFlwc1;
DCHECK(SINGLEREG(rDest));
}
#endif
DCHECK_EQ((displacement & 0x3), 0);
break;
case kUnsignedHalf:
opcode = kMipsLhu;
DCHECK_EQ((displacement & 0x1), 0);
break;
case kSignedHalf:
opcode = kMipsLh;
DCHECK_EQ((displacement & 0x1), 0);
break;
case kUnsignedByte:
opcode = kMipsLbu;
break;
case kSignedByte:
opcode = kMipsLb;
break;
default:
LOG(FATAL) << "Bad case in loadBaseIndexedBody";
}
if (shortForm) {
if (!pair) {
load = res = newLIR3(cUnit, opcode, rDest, displacement, rBase);
} else {
load = res = newLIR3(cUnit, opcode, rDest, displacement + LOWORD_OFFSET, rBase);
load2 = newLIR3(cUnit, opcode, rDestHi, displacement + HIWORD_OFFSET, rBase);
}
} else {
if (pair) {
int rTmp = oatAllocFreeTemp(cUnit);
res = opRegRegImm(cUnit, kOpAdd, rTmp, rBase, displacement);
load = newLIR3(cUnit, opcode, rDest, LOWORD_OFFSET, rTmp);
load2 = newLIR3(cUnit, opcode, rDestHi, HIWORD_OFFSET, rTmp);
oatFreeTemp(cUnit, rTmp);
} else {
int rTmp = (rBase == rDest) ? oatAllocFreeTemp(cUnit)
: rDest;
res = loadConstant(cUnit, rTmp, displacement);
load = newLIR3(cUnit, opcode, rDest, rBase, rTmp);
if (rTmp != rDest)
oatFreeTemp(cUnit, rTmp);
}
}
if (rBase == rSP) {
annotateDalvikRegAccess(load, (displacement + (pair ? LOWORD_OFFSET : 0)) >> 2,
true /* isLoad */, pair /* is64bit */);
if (pair) {
annotateDalvikRegAccess(load2, (displacement + HIWORD_OFFSET) >> 2,
true /* isLoad */, pair /* is64bit */);
}
}
return load;
}
LIR *loadBaseDisp(CompilationUnit *cUnit, MIR *mir, int rBase,
int displacement, int rDest, OpSize size,
int sReg)
{
return loadBaseDispBody(cUnit, mir, rBase, displacement, rDest, -1,
size, sReg);
}
LIR *loadBaseDispWide(CompilationUnit *cUnit, MIR *mir, int rBase,
int displacement, int rDestLo, int rDestHi,
int sReg)
{
return loadBaseDispBody(cUnit, mir, rBase, displacement, rDestLo, rDestHi,
kLong, sReg);
}
LIR *storeBaseDispBody(CompilationUnit *cUnit, int rBase,
int displacement, int rSrc, int rSrcHi,
OpSize size)
{
LIR *res;
LIR *store = NULL;
LIR *store2 = NULL;
MipsOpCode opcode = kMipsNop;
bool shortForm = IS_SIMM16(displacement);
bool pair = false;
switch (size) {
case kLong:
case kDouble:
pair = true;
opcode = kMipsSw;
#ifdef __mips_hard_float
if (FPREG(rSrc)) {
opcode = kMipsFswc1;
if (DOUBLEREG(rSrc)) {
rSrc = rSrc - FP_DOUBLE;
} else {
DCHECK(FPREG(rSrcHi));
DCHECK_EQ(rSrc, (rSrcHi - 1));
}
rSrcHi = rSrc + 1;
}
#endif
shortForm = IS_SIMM16_2WORD(displacement);
DCHECK_EQ((displacement & 0x3), 0);
break;
case kWord:
case kSingle:
opcode = kMipsSw;
#ifdef __mips_hard_float
if (FPREG(rSrc)) {
opcode = kMipsFswc1;
DCHECK(SINGLEREG(rSrc));
}
#endif
DCHECK_EQ((displacement & 0x3), 0);
break;
case kUnsignedHalf:
case kSignedHalf:
opcode = kMipsSh;
DCHECK_EQ((displacement & 0x1), 0);
break;
case kUnsignedByte:
case kSignedByte:
opcode = kMipsSb;
break;
default:
LOG(FATAL) << "Bad case in storeBaseIndexedBody";
}
if (shortForm) {
if (!pair) {
store = res = newLIR3(cUnit, opcode, rSrc, displacement, rBase);
} else {
store = res = newLIR3(cUnit, opcode, rSrc, displacement + LOWORD_OFFSET, rBase);
store2 = newLIR3(cUnit, opcode, rSrcHi, displacement + HIWORD_OFFSET, rBase);
}
} else {
int rScratch = oatAllocTemp(cUnit);
res = opRegRegImm(cUnit, kOpAdd, rScratch, rBase, displacement);
if (!pair) {
store = newLIR3(cUnit, opcode, rSrc, 0, rScratch);
} else {
store = newLIR3(cUnit, opcode, rSrc, LOWORD_OFFSET, rScratch);
store2 = newLIR3(cUnit, opcode, rSrcHi, HIWORD_OFFSET, rScratch);
}
oatFreeTemp(cUnit, rScratch);
}
if (rBase == rSP) {
annotateDalvikRegAccess(store, (displacement + (pair ? LOWORD_OFFSET : 0)) >> 2,
false /* isLoad */, pair /* is64bit */);
if (pair) {
annotateDalvikRegAccess(store2, (displacement + HIWORD_OFFSET) >> 2,
false /* isLoad */, pair /* is64bit */);
}
}
return res;
}
LIR *storeBaseDisp(CompilationUnit *cUnit, int rBase,
int displacement, int rSrc, OpSize size)
{
return storeBaseDispBody(cUnit, rBase, displacement, rSrc, -1, size);
}
LIR *storeBaseDispWide(CompilationUnit *cUnit, int rBase,
int displacement, int rSrcLo, int rSrcHi)
{
return storeBaseDispBody(cUnit, rBase, displacement, rSrcLo, rSrcHi, kLong);
}
void storePair(CompilationUnit *cUnit, int base, int lowReg, int highReg)
{
storeWordDisp(cUnit, base, LOWORD_OFFSET, lowReg);
storeWordDisp(cUnit, base, HIWORD_OFFSET, highReg);
}
void loadPair(CompilationUnit *cUnit, int base, int lowReg, int highReg)
{
loadWordDisp(cUnit, base, LOWORD_OFFSET , lowReg);
loadWordDisp(cUnit, base, HIWORD_OFFSET , highReg);
}
} // namespace art