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android / platform / art / c1b643cc6ac45dbd0eabdcd7425c7e86006c27d6 / . / compiler / dex / quick / x86 / target_x86.cc
blob: 8b341682c32fbe484a2c3645c82f88a2e1f53001 [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.
*/
#include <string>
#include <inttypes.h>
#include "codegen_x86.h"
#include "dex/compiler_internals.h"
#include "dex/quick/mir_to_lir-inl.h"
#include "mirror/array.h"
#include "mirror/string.h"
#include "x86_lir.h"
namespace art {
static const RegStorage core_regs_arr_32[] = {
rs_rAX, rs_rCX, rs_rDX, rs_rBX, rs_rX86_SP_32, rs_rBP, rs_rSI, rs_rDI,
};
static const RegStorage core_regs_arr_64[] = {
rs_rAX, rs_rCX, rs_rDX, rs_rBX, rs_rX86_SP_64, rs_rBP, rs_rSI, rs_rDI,
#ifdef TARGET_REX_SUPPORT
rs_r8, rs_r9, rs_r10, rs_r11, rs_r12, rs_r13, rs_r14, rs_r15
#endif
};
static const RegStorage core_regs_arr_64q[] = {
rs_r0q, rs_r1q, rs_r2q, rs_r3q, rs_rX86_SP_64, rs_r5q, rs_r6q, rs_r7q,
#ifdef TARGET_REX_SUPPORT
rs_r8q, rs_r9q, rs_r10q, rs_r11q, rs_r12q, rs_r13q, rs_r14q, rs_r15q
#endif
};
static const RegStorage sp_regs_arr_32[] = {
rs_fr0, rs_fr1, rs_fr2, rs_fr3, rs_fr4, rs_fr5, rs_fr6, rs_fr7,
};
static const RegStorage sp_regs_arr_64[] = {
rs_fr0, rs_fr1, rs_fr2, rs_fr3, rs_fr4, rs_fr5, rs_fr6, rs_fr7,
#ifdef TARGET_REX_SUPPORT
rs_fr8, rs_fr9, rs_fr10, rs_fr11, rs_fr12, rs_fr13, rs_fr14, rs_fr15
#endif
};
static const RegStorage dp_regs_arr_32[] = {
rs_dr0, rs_dr1, rs_dr2, rs_dr3, rs_dr4, rs_dr5, rs_dr6, rs_dr7,
};
static const RegStorage dp_regs_arr_64[] = {
rs_dr0, rs_dr1, rs_dr2, rs_dr3, rs_dr4, rs_dr5, rs_dr6, rs_dr7,
#ifdef TARGET_REX_SUPPORT
rs_dr8, rs_dr9, rs_dr10, rs_dr11, rs_dr12, rs_dr13, rs_dr14, rs_dr15
#endif
};
static const RegStorage reserved_regs_arr_32[] = {rs_rX86_SP_32};
static const RegStorage reserved_regs_arr_64[] = {rs_rX86_SP_64};
static const RegStorage reserved_regs_arr_64q[] = {rs_rX86_SP_64};
static const RegStorage core_temps_arr_32[] = {rs_rAX, rs_rCX, rs_rDX, rs_rBX};
static const RegStorage core_temps_arr_64[] = {
rs_rAX, rs_rCX, rs_rDX, rs_rSI, rs_rDI,
#ifdef TARGET_REX_SUPPORT
rs_r8, rs_r9, rs_r10, rs_r11
#endif
};
static const RegStorage core_temps_arr_64q[] = {
rs_r0q, rs_r1q, rs_r2q, rs_r6q, rs_r7q,
#ifdef TARGET_REX_SUPPORT
rs_r8q, rs_r9q, rs_r10q, rs_r11q
#endif
};
static const RegStorage sp_temps_arr_32[] = {
rs_fr0, rs_fr1, rs_fr2, rs_fr3, rs_fr4, rs_fr5, rs_fr6, rs_fr7,
};
static const RegStorage sp_temps_arr_64[] = {
rs_fr0, rs_fr1, rs_fr2, rs_fr3, rs_fr4, rs_fr5, rs_fr6, rs_fr7,
#ifdef TARGET_REX_SUPPORT
rs_fr8, rs_fr9, rs_fr10, rs_fr11, rs_fr12, rs_fr13, rs_fr14, rs_fr15
#endif
};
static const RegStorage dp_temps_arr_32[] = {
rs_dr0, rs_dr1, rs_dr2, rs_dr3, rs_dr4, rs_dr5, rs_dr6, rs_dr7,
};
static const RegStorage dp_temps_arr_64[] = {
rs_dr0, rs_dr1, rs_dr2, rs_dr3, rs_dr4, rs_dr5, rs_dr6, rs_dr7,
#ifdef TARGET_REX_SUPPORT
rs_dr8, rs_dr9, rs_dr10, rs_dr11, rs_dr12, rs_dr13, rs_dr14, rs_dr15
#endif
};
static const RegStorage xp_temps_arr_32[] = {
rs_xr0, rs_xr1, rs_xr2, rs_xr3, rs_xr4, rs_xr5, rs_xr6, rs_xr7,
};
static const RegStorage xp_temps_arr_64[] = {
rs_xr0, rs_xr1, rs_xr2, rs_xr3, rs_xr4, rs_xr5, rs_xr6, rs_xr7,
#ifdef TARGET_REX_SUPPORT
rs_xr8, rs_xr9, rs_xr10, rs_xr11, rs_xr12, rs_xr13, rs_xr14, rs_xr15
#endif
};
static const std::vector<RegStorage> empty_pool;
static const std::vector<RegStorage> core_regs_32(core_regs_arr_32,
core_regs_arr_32 + sizeof(core_regs_arr_32) / sizeof(core_regs_arr_32[0]));
static const std::vector<RegStorage> core_regs_64(core_regs_arr_64,
core_regs_arr_64 + sizeof(core_regs_arr_64) / sizeof(core_regs_arr_64[0]));
static const std::vector<RegStorage> core_regs_64q(core_regs_arr_64q,
core_regs_arr_64q + sizeof(core_regs_arr_64q) / sizeof(core_regs_arr_64q[0]));
static const std::vector<RegStorage> sp_regs_32(sp_regs_arr_32,
sp_regs_arr_32 + sizeof(sp_regs_arr_32) / sizeof(sp_regs_arr_32[0]));
static const std::vector<RegStorage> sp_regs_64(sp_regs_arr_64,
sp_regs_arr_64 + sizeof(sp_regs_arr_64) / sizeof(sp_regs_arr_64[0]));
static const std::vector<RegStorage> dp_regs_32(dp_regs_arr_32,
dp_regs_arr_32 + sizeof(dp_regs_arr_32) / sizeof(dp_regs_arr_32[0]));
static const std::vector<RegStorage> dp_regs_64(dp_regs_arr_64,
dp_regs_arr_64 + sizeof(dp_regs_arr_64) / sizeof(dp_regs_arr_64[0]));
static const std::vector<RegStorage> reserved_regs_32(reserved_regs_arr_32,
reserved_regs_arr_32 + sizeof(reserved_regs_arr_32) / sizeof(reserved_regs_arr_32[0]));
static const std::vector<RegStorage> reserved_regs_64(reserved_regs_arr_64,
reserved_regs_arr_64 + sizeof(reserved_regs_arr_64) / sizeof(reserved_regs_arr_64[0]));
static const std::vector<RegStorage> reserved_regs_64q(reserved_regs_arr_64q,
reserved_regs_arr_64q + sizeof(reserved_regs_arr_64q) / sizeof(reserved_regs_arr_64q[0]));
static const std::vector<RegStorage> core_temps_32(core_temps_arr_32,
core_temps_arr_32 + sizeof(core_temps_arr_32) / sizeof(core_temps_arr_32[0]));
static const std::vector<RegStorage> core_temps_64(core_temps_arr_64,
core_temps_arr_64 + sizeof(core_temps_arr_64) / sizeof(core_temps_arr_64[0]));
static const std::vector<RegStorage> core_temps_64q(core_temps_arr_64q,
core_temps_arr_64q + sizeof(core_temps_arr_64q) / sizeof(core_temps_arr_64q[0]));
static const std::vector<RegStorage> sp_temps_32(sp_temps_arr_32,
sp_temps_arr_32 + sizeof(sp_temps_arr_32) / sizeof(sp_temps_arr_32[0]));
static const std::vector<RegStorage> sp_temps_64(sp_temps_arr_64,
sp_temps_arr_64 + sizeof(sp_temps_arr_64) / sizeof(sp_temps_arr_64[0]));
static const std::vector<RegStorage> dp_temps_32(dp_temps_arr_32,
dp_temps_arr_32 + sizeof(dp_temps_arr_32) / sizeof(dp_temps_arr_32[0]));
static const std::vector<RegStorage> dp_temps_64(dp_temps_arr_64,
dp_temps_arr_64 + sizeof(dp_temps_arr_64) / sizeof(dp_temps_arr_64[0]));
static const std::vector<RegStorage> xp_temps_32(xp_temps_arr_32,
xp_temps_arr_32 + sizeof(xp_temps_arr_32) / sizeof(xp_temps_arr_32[0]));
static const std::vector<RegStorage> xp_temps_64(xp_temps_arr_64,
xp_temps_arr_64 + sizeof(xp_temps_arr_64) / sizeof(xp_temps_arr_64[0]));
RegStorage rs_rX86_SP;
X86NativeRegisterPool rX86_ARG0;
X86NativeRegisterPool rX86_ARG1;
X86NativeRegisterPool rX86_ARG2;
X86NativeRegisterPool rX86_ARG3;
X86NativeRegisterPool rX86_FARG0;
X86NativeRegisterPool rX86_FARG1;
X86NativeRegisterPool rX86_FARG2;
X86NativeRegisterPool rX86_FARG3;
X86NativeRegisterPool rX86_RET0;
X86NativeRegisterPool rX86_RET1;
X86NativeRegisterPool rX86_INVOKE_TGT;
X86NativeRegisterPool rX86_COUNT;
RegStorage rs_rX86_ARG0;
RegStorage rs_rX86_ARG1;
RegStorage rs_rX86_ARG2;
RegStorage rs_rX86_ARG3;
RegStorage rs_rX86_FARG0;
RegStorage rs_rX86_FARG1;
RegStorage rs_rX86_FARG2;
RegStorage rs_rX86_FARG3;
RegStorage rs_rX86_RET0;
RegStorage rs_rX86_RET1;
RegStorage rs_rX86_INVOKE_TGT;
RegStorage rs_rX86_COUNT;
RegLocation X86Mir2Lir::LocCReturn() {
return x86_loc_c_return;
}
RegLocation X86Mir2Lir::LocCReturnWide() {
return x86_loc_c_return_wide;
}
RegLocation X86Mir2Lir::LocCReturnFloat() {
return x86_loc_c_return_float;
}
RegLocation X86Mir2Lir::LocCReturnDouble() {
return x86_loc_c_return_double;
}
// Return a target-dependent special register.
RegStorage X86Mir2Lir::TargetReg(SpecialTargetRegister reg) {
RegStorage res_reg = RegStorage::InvalidReg();
switch (reg) {
case kSelf: res_reg = RegStorage::InvalidReg(); break;
case kSuspend: res_reg = RegStorage::InvalidReg(); break;
case kLr: res_reg = RegStorage::InvalidReg(); break;
case kPc: res_reg = RegStorage::InvalidReg(); break;
case kSp: res_reg = rs_rX86_SP; break;
case kArg0: res_reg = rs_rX86_ARG0; break;
case kArg1: res_reg = rs_rX86_ARG1; break;
case kArg2: res_reg = rs_rX86_ARG2; break;
case kArg3: res_reg = rs_rX86_ARG3; break;
case kFArg0: res_reg = rs_rX86_FARG0; break;
case kFArg1: res_reg = rs_rX86_FARG1; break;
case kFArg2: res_reg = rs_rX86_FARG2; break;
case kFArg3: res_reg = rs_rX86_FARG3; break;
case kRet0: res_reg = rs_rX86_RET0; break;
case kRet1: res_reg = rs_rX86_RET1; break;
case kInvokeTgt: res_reg = rs_rX86_INVOKE_TGT; break;
case kHiddenArg: res_reg = rs_rAX; break;
case kHiddenFpArg: res_reg = rs_fr0; break;
case kCount: res_reg = rs_rX86_COUNT; break;
}
return res_reg;
}
RegStorage X86Mir2Lir::GetArgMappingToPhysicalReg(int arg_num) {
// For the 32-bit internal ABI, the first 3 arguments are passed in registers.
// TODO: This is not 64-bit compliant and depends on new internal ABI.
switch (arg_num) {
case 0:
return rs_rX86_ARG1;
case 1:
return rs_rX86_ARG2;
case 2:
return rs_rX86_ARG3;
default:
return RegStorage::InvalidReg();
}
}
/*
* Decode the register id.
*/
uint64_t X86Mir2Lir::GetRegMaskCommon(RegStorage reg) {
uint64_t seed;
int shift;
int reg_id;
reg_id = reg.GetRegNum();
/* Double registers in x86 are just a single FP register */
seed = 1;
/* FP register starts at bit position 16 */
shift = (reg.IsFloat() || reg.StorageSize() > 8) ? kX86FPReg0 : 0;
/* Expand the double register id into single offset */
shift += reg_id;
return (seed << shift);
}
uint64_t X86Mir2Lir::GetPCUseDefEncoding() {
/*
* FIXME: might make sense to use a virtual resource encoding bit for pc. Might be
* able to clean up some of the x86/Arm_Mips differences
*/
LOG(FATAL) << "Unexpected call to GetPCUseDefEncoding for x86";
return 0ULL;
}
void X86Mir2Lir::SetupTargetResourceMasks(LIR* lir, uint64_t flags) {
DCHECK(cu_->instruction_set == kX86 || cu_->instruction_set == kX86_64);
DCHECK(!lir->flags.use_def_invalid);
// X86-specific resource map setup here.
if (flags & REG_USE_SP) {
lir->u.m.use_mask |= ENCODE_X86_REG_SP;
}
if (flags & REG_DEF_SP) {
lir->u.m.def_mask |= ENCODE_X86_REG_SP;
}
if (flags & REG_DEFA) {
SetupRegMask(&lir->u.m.def_mask, rs_rAX.GetReg());
}
if (flags & REG_DEFD) {
SetupRegMask(&lir->u.m.def_mask, rs_rDX.GetReg());
}
if (flags & REG_USEA) {
SetupRegMask(&lir->u.m.use_mask, rs_rAX.GetReg());
}
if (flags & REG_USEC) {
SetupRegMask(&lir->u.m.use_mask, rs_rCX.GetReg());
}
if (flags & REG_USED) {
SetupRegMask(&lir->u.m.use_mask, rs_rDX.GetReg());
}
if (flags & REG_USEB) {
SetupRegMask(&lir->u.m.use_mask, rs_rBX.GetReg());
}
// Fixup hard to describe instruction: Uses rAX, rCX, rDI; sets rDI.
if (lir->opcode == kX86RepneScasw) {
SetupRegMask(&lir->u.m.use_mask, rs_rAX.GetReg());
SetupRegMask(&lir->u.m.use_mask, rs_rCX.GetReg());
SetupRegMask(&lir->u.m.use_mask, rs_rDI.GetReg());
SetupRegMask(&lir->u.m.def_mask, rs_rDI.GetReg());
}
if (flags & USE_FP_STACK) {
lir->u.m.use_mask |= ENCODE_X86_FP_STACK;
lir->u.m.def_mask |= ENCODE_X86_FP_STACK;
}
}
/* For dumping instructions */
static const char* x86RegName[] = {
"rax", "rcx", "rdx", "rbx", "rsp", "rbp", "rsi", "rdi",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15"
};
static const char* x86CondName[] = {
"O",
"NO",
"B/NAE/C",
"NB/AE/NC",
"Z/EQ",
"NZ/NE",
"BE/NA",
"NBE/A",
"S",
"NS",
"P/PE",
"NP/PO",
"L/NGE",
"NL/GE",
"LE/NG",
"NLE/G"
};
/*
* Interpret a format string and build a string no longer than size
* See format key in Assemble.cc.
*/
std::string X86Mir2Lir::BuildInsnString(const char *fmt, LIR *lir, unsigned char* base_addr) {
std::string buf;
size_t i = 0;
size_t fmt_len = strlen(fmt);
while (i < fmt_len) {
if (fmt[i] != '!') {
buf += fmt[i];
i++;
} else {
i++;
DCHECK_LT(i, fmt_len);
char operand_number_ch = fmt[i];
i++;
if (operand_number_ch == '!') {
buf += "!";
} else {
int operand_number = operand_number_ch - '0';
DCHECK_LT(operand_number, 6); // Expect upto 6 LIR operands.
DCHECK_LT(i, fmt_len);
int operand = lir->operands[operand_number];
switch (fmt[i]) {
case 'c':
DCHECK_LT(static_cast<size_t>(operand), sizeof(x86CondName));
buf += x86CondName[operand];
break;
case 'd':
buf += StringPrintf("%d", operand);
break;
case 'p': {
EmbeddedData *tab_rec = reinterpret_cast<EmbeddedData*>(UnwrapPointer(operand));
buf += StringPrintf("0x%08x", tab_rec->offset);
break;
}
case 'r':
if (RegStorage::IsFloat(operand)) {
int fp_reg = RegStorage::RegNum(operand);
buf += StringPrintf("xmm%d", fp_reg);
} else {
int reg_num = RegStorage::RegNum(operand);
DCHECK_LT(static_cast<size_t>(reg_num), sizeof(x86RegName));
buf += x86RegName[reg_num];
}
break;
case 't':
buf += StringPrintf("0x%08" PRIxPTR " (L%p)",
reinterpret_cast<uintptr_t>(base_addr) + lir->offset + operand,
lir->target);
break;
default:
buf += StringPrintf("DecodeError '%c'", fmt[i]);
break;
}
i++;
}
}
}
return buf;
}
void X86Mir2Lir::DumpResourceMask(LIR *x86LIR, uint64_t mask, const char *prefix) {
char buf[256];
buf[0] = 0;
if (mask == ENCODE_ALL) {
strcpy(buf, "all");
} else {
char num[8];
int i;
for (i = 0; i < kX86RegEnd; i++) {
if (mask & (1ULL << i)) {
snprintf(num, arraysize(num), "%d ", i);
strcat(buf, num);
}
}
if (mask & ENCODE_CCODE) {
strcat(buf, "cc ");
}
/* Memory bits */
if (x86LIR && (mask & ENCODE_DALVIK_REG)) {
snprintf(buf + strlen(buf), arraysize(buf) - strlen(buf), "dr%d%s",
DECODE_ALIAS_INFO_REG(x86LIR->flags.alias_info),
(DECODE_ALIAS_INFO_WIDE(x86LIR->flags.alias_info)) ? "(+1)" : "");
}
if (mask & ENCODE_LITERAL) {
strcat(buf, "lit ");
}
if (mask & ENCODE_HEAP_REF) {
strcat(buf, "heap ");
}
if (mask & ENCODE_MUST_NOT_ALIAS) {
strcat(buf, "noalias ");
}
}
if (buf[0]) {
LOG(INFO) << prefix << ": " << buf;
}
}
void X86Mir2Lir::AdjustSpillMask() {
// Adjustment for LR spilling, x86 has no LR so nothing to do here
core_spill_mask_ |= (1 << rs_rRET.GetRegNum());
num_core_spills_++;
}
/*
* Mark a callee-save fp register as promoted. Note that
* vpush/vpop uses contiguous register lists so we must
* include any holes in the mask. Associate holes with
* Dalvik register INVALID_VREG (0xFFFFU).
*/
void X86Mir2Lir::MarkPreservedSingle(int v_reg, RegStorage reg) {
UNIMPLEMENTED(FATAL) << "MarkPreservedSingle";
}
void X86Mir2Lir::MarkPreservedDouble(int v_reg, RegStorage reg) {
UNIMPLEMENTED(FATAL) << "MarkPreservedDouble";
}
RegStorage X86Mir2Lir::AllocateByteRegister() {
return AllocTypedTemp(false, kCoreReg);
}
/* Clobber all regs that might be used by an external C call */
void X86Mir2Lir::ClobberCallerSave() {
Clobber(rs_rAX);
Clobber(rs_rCX);
Clobber(rs_rDX);
Clobber(rs_rBX);
}
RegLocation X86Mir2Lir::GetReturnWideAlt() {
RegLocation res = LocCReturnWide();
DCHECK(res.reg.GetLowReg() == rs_rAX.GetReg());
DCHECK(res.reg.GetHighReg() == rs_rDX.GetReg());
Clobber(rs_rAX);
Clobber(rs_rDX);
MarkInUse(rs_rAX);
MarkInUse(rs_rDX);
MarkWide(res.reg);
return res;
}
RegLocation X86Mir2Lir::GetReturnAlt() {
RegLocation res = LocCReturn();
res.reg.SetReg(rs_rDX.GetReg());
Clobber(rs_rDX);
MarkInUse(rs_rDX);
return res;
}
/* To be used when explicitly managing register use */
void X86Mir2Lir::LockCallTemps() {
LockTemp(rs_rX86_ARG0);
LockTemp(rs_rX86_ARG1);
LockTemp(rs_rX86_ARG2);
LockTemp(rs_rX86_ARG3);
}
/* To be used when explicitly managing register use */
void X86Mir2Lir::FreeCallTemps() {
FreeTemp(rs_rX86_ARG0);
FreeTemp(rs_rX86_ARG1);
FreeTemp(rs_rX86_ARG2);
FreeTemp(rs_rX86_ARG3);
}
bool X86Mir2Lir::ProvidesFullMemoryBarrier(X86OpCode opcode) {
switch (opcode) {
case kX86LockCmpxchgMR:
case kX86LockCmpxchgAR:
case kX86LockCmpxchg8bM:
case kX86LockCmpxchg8bA:
case kX86XchgMR:
case kX86Mfence:
// Atomic memory instructions provide full barrier.
return true;
default:
break;
}
// Conservative if cannot prove it provides full barrier.
return false;
}
bool X86Mir2Lir::GenMemBarrier(MemBarrierKind barrier_kind) {
#if ANDROID_SMP != 0
// Start off with using the last LIR as the barrier. If it is not enough, then we will update it.
LIR* mem_barrier = last_lir_insn_;
bool ret = false;
/*
* According to the JSR-133 Cookbook, for x86 only StoreLoad barriers need memory fence. All other barriers
* (LoadLoad, LoadStore, StoreStore) are nops due to the x86 memory model. For those cases, all we need
* to ensure is that there is a scheduling barrier in place.
*/
if (barrier_kind == kStoreLoad) {
// If no LIR exists already that can be used a barrier, then generate an mfence.
if (mem_barrier == nullptr) {
mem_barrier = NewLIR0(kX86Mfence);
ret = true;
}
// If last instruction does not provide full barrier, then insert an mfence.
if (ProvidesFullMemoryBarrier(static_cast<X86OpCode>(mem_barrier->opcode)) == false) {
mem_barrier = NewLIR0(kX86Mfence);
ret = true;
}
}
// Now ensure that a scheduling barrier is in place.
if (mem_barrier == nullptr) {
GenBarrier();
} else {
// Mark as a scheduling barrier.
DCHECK(!mem_barrier->flags.use_def_invalid);
mem_barrier->u.m.def_mask = ENCODE_ALL;
}
return ret;
#else
return false;
#endif
}
void X86Mir2Lir::CompilerInitializeRegAlloc() {
if (Gen64Bit()) {
reg_pool_ = new (arena_) RegisterPool(this, arena_, core_regs_64, empty_pool/*core_regs_64q*/, sp_regs_64,
dp_regs_64, reserved_regs_64, empty_pool/*reserved_regs_64q*/,
core_temps_64, empty_pool/*core_temps_64q*/, sp_temps_64, dp_temps_64);
} else {
reg_pool_ = new (arena_) RegisterPool(this, arena_, core_regs_32, empty_pool, sp_regs_32,
dp_regs_32, reserved_regs_32, empty_pool,
core_temps_32, empty_pool, sp_temps_32, dp_temps_32);
}
// Target-specific adjustments.
// Add in XMM registers.
const std::vector<RegStorage> *xp_temps = Gen64Bit() ? &xp_temps_64 : &xp_temps_32;
for (RegStorage reg : *xp_temps) {
RegisterInfo* info = new (arena_) RegisterInfo(reg, GetRegMaskCommon(reg));
reginfo_map_.Put(reg.GetReg(), info);
info->SetIsTemp(true);
}
// Alias single precision xmm to double xmms.
// TODO: as needed, add larger vector sizes - alias all to the largest.
GrowableArray<RegisterInfo*>::Iterator it(&reg_pool_->sp_regs_);
for (RegisterInfo* info = it.Next(); info != nullptr; info = it.Next()) {
int sp_reg_num = info->GetReg().GetRegNum();
RegStorage xp_reg = RegStorage::Solo128(sp_reg_num);
RegisterInfo* xp_reg_info = GetRegInfo(xp_reg);
// 128-bit xmm vector register's master storage should refer to itself.
DCHECK_EQ(xp_reg_info, xp_reg_info->Master());
// Redirect 32-bit vector's master storage to 128-bit vector.
info->SetMaster(xp_reg_info);
RegStorage dp_reg = RegStorage::Solo64(RegStorage::kFloatingPoint | sp_reg_num);
RegisterInfo* dp_reg_info = GetRegInfo(dp_reg);
// Redirect 64-bit vector's master storage to 128-bit vector.
dp_reg_info->SetMaster(xp_reg_info);
}
// Don't start allocating temps at r0/s0/d0 or you may clobber return regs in early-exit methods.
// TODO: adjust for x86/hard float calling convention.
reg_pool_->next_core_reg_ = 2;
reg_pool_->next_sp_reg_ = 2;
reg_pool_->next_dp_reg_ = 1;
}
void X86Mir2Lir::SpillCoreRegs() {
if (num_core_spills_ == 0) {
return;
}
// Spill mask not including fake return address register
uint32_t mask = core_spill_mask_ & ~(1 << rs_rRET.GetRegNum());
int offset = frame_size_ - (GetInstructionSetPointerSize(cu_->instruction_set) * num_core_spills_);
for (int reg = 0; mask; mask >>= 1, reg++) {
if (mask & 0x1) {
StoreWordDisp(rs_rX86_SP, offset, RegStorage::Solo32(reg));
offset += GetInstructionSetPointerSize(cu_->instruction_set);
}
}
}
void X86Mir2Lir::UnSpillCoreRegs() {
if (num_core_spills_ == 0) {
return;
}
// Spill mask not including fake return address register
uint32_t mask = core_spill_mask_ & ~(1 << rs_rRET.GetRegNum());
int offset = frame_size_ - (GetInstructionSetPointerSize(cu_->instruction_set) * num_core_spills_);
for (int reg = 0; mask; mask >>= 1, reg++) {
if (mask & 0x1) {
LoadWordDisp(rs_rX86_SP, offset, RegStorage::Solo32(reg));
offset += GetInstructionSetPointerSize(cu_->instruction_set);
}
}
}
bool X86Mir2Lir::IsUnconditionalBranch(LIR* lir) {
return (lir->opcode == kX86Jmp8 || lir->opcode == kX86Jmp32);
}
bool X86Mir2Lir::SupportsVolatileLoadStore(OpSize size) {
return true;
}
RegisterClass X86Mir2Lir::RegClassForFieldLoadStore(OpSize size, bool is_volatile) {
if (UNLIKELY(is_volatile)) {
// On x86, atomic 64-bit load/store requires an fp register.
// Smaller aligned load/store is atomic for both core and fp registers.
if (size == k64 || size == kDouble) {
return kFPReg;
}
}
return RegClassBySize(size);
}
X86Mir2Lir::X86Mir2Lir(CompilationUnit* cu, MIRGraph* mir_graph, ArenaAllocator* arena, bool gen64bit)
: Mir2Lir(cu, mir_graph, arena),
base_of_code_(nullptr), store_method_addr_(false), store_method_addr_used_(false),
method_address_insns_(arena, 100, kGrowableArrayMisc),
class_type_address_insns_(arena, 100, kGrowableArrayMisc),
call_method_insns_(arena, 100, kGrowableArrayMisc),
stack_decrement_(nullptr), stack_increment_(nullptr), gen64bit_(gen64bit),
const_vectors_(nullptr) {
store_method_addr_used_ = false;
if (kIsDebugBuild) {
for (int i = 0; i < kX86Last; i++) {
if (X86Mir2Lir::EncodingMap[i].opcode != i) {
LOG(FATAL) << "Encoding order for " << X86Mir2Lir::EncodingMap[i].name
<< " is wrong: expecting " << i << ", seeing "
<< static_cast<int>(X86Mir2Lir::EncodingMap[i].opcode);
}
}
}
if (Gen64Bit()) {
rs_rX86_SP = rs_rX86_SP_64;
rs_rX86_ARG0 = rs_rDI;
rs_rX86_ARG1 = rs_rSI;
rs_rX86_ARG2 = rs_rDX;
rs_rX86_ARG3 = rs_rCX;
rX86_ARG0 = rDI;
rX86_ARG1 = rSI;
rX86_ARG2 = rDX;
rX86_ARG3 = rCX;
// TODO: ARG4(r8), ARG5(r9), floating point args.
} else {
rs_rX86_SP = rs_rX86_SP_32;
rs_rX86_ARG0 = rs_rAX;
rs_rX86_ARG1 = rs_rCX;
rs_rX86_ARG2 = rs_rDX;
rs_rX86_ARG3 = rs_rBX;
rX86_ARG0 = rAX;
rX86_ARG1 = rCX;
rX86_ARG2 = rDX;
rX86_ARG3 = rBX;
}
rs_rX86_FARG0 = rs_rAX;
rs_rX86_FARG1 = rs_rCX;
rs_rX86_FARG2 = rs_rDX;
rs_rX86_FARG3 = rs_rBX;
rs_rX86_RET0 = rs_rAX;
rs_rX86_RET1 = rs_rDX;
rs_rX86_INVOKE_TGT = rs_rAX;
rs_rX86_COUNT = rs_rCX;
rX86_FARG0 = rAX;
rX86_FARG1 = rCX;
rX86_FARG2 = rDX;
rX86_FARG3 = rBX;
rX86_RET0 = rAX;
rX86_RET1 = rDX;
rX86_INVOKE_TGT = rAX;
rX86_COUNT = rCX;
}
Mir2Lir* X86CodeGenerator(CompilationUnit* const cu, MIRGraph* const mir_graph,
ArenaAllocator* const arena) {
return new X86Mir2Lir(cu, mir_graph, arena, false);
}
Mir2Lir* X86_64CodeGenerator(CompilationUnit* const cu, MIRGraph* const mir_graph,
ArenaAllocator* const arena) {
return new X86Mir2Lir(cu, mir_graph, arena, true);
}
// Not used in x86
RegStorage X86Mir2Lir::LoadHelper(ThreadOffset<4> offset) {
LOG(FATAL) << "Unexpected use of LoadHelper in x86";
return RegStorage::InvalidReg();
}
// Not used in x86
RegStorage X86Mir2Lir::LoadHelper(ThreadOffset<8> offset) {
LOG(FATAL) << "Unexpected use of LoadHelper in x86";
return RegStorage::InvalidReg();
}
LIR* X86Mir2Lir::CheckSuspendUsingLoad() {
LOG(FATAL) << "Unexpected use of CheckSuspendUsingLoad in x86";
return nullptr;
}
uint64_t X86Mir2Lir::GetTargetInstFlags(int opcode) {
DCHECK(!IsPseudoLirOp(opcode));
return X86Mir2Lir::EncodingMap[opcode].flags;
}
const char* X86Mir2Lir::GetTargetInstName(int opcode) {
DCHECK(!IsPseudoLirOp(opcode));
return X86Mir2Lir::EncodingMap[opcode].name;
}
const char* X86Mir2Lir::GetTargetInstFmt(int opcode) {
DCHECK(!IsPseudoLirOp(opcode));
return X86Mir2Lir::EncodingMap[opcode].fmt;
}
void X86Mir2Lir::GenConstWide(RegLocation rl_dest, int64_t value) {
// Can we do this directly to memory?
rl_dest = UpdateLocWide(rl_dest);
if ((rl_dest.location == kLocDalvikFrame) ||
(rl_dest.location == kLocCompilerTemp)) {
int32_t val_lo = Low32Bits(value);
int32_t val_hi = High32Bits(value);
int r_base = TargetReg(kSp).GetReg();
int displacement = SRegOffset(rl_dest.s_reg_low);
LIR * store = NewLIR3(kX86Mov32MI, r_base, displacement + LOWORD_OFFSET, val_lo);
AnnotateDalvikRegAccess(store, (displacement + LOWORD_OFFSET) >> 2,
false /* is_load */, true /* is64bit */);
store = NewLIR3(kX86Mov32MI, r_base, displacement + HIWORD_OFFSET, val_hi);
AnnotateDalvikRegAccess(store, (displacement + HIWORD_OFFSET) >> 2,
false /* is_load */, true /* is64bit */);
return;
}
// Just use the standard code to do the generation.
Mir2Lir::GenConstWide(rl_dest, value);
}
// TODO: Merge with existing RegLocation dumper in vreg_analysis.cc
void X86Mir2Lir::DumpRegLocation(RegLocation loc) {
LOG(INFO) << "location: " << loc.location << ','
<< (loc.wide ? " w" : " ")
<< (loc.defined ? " D" : " ")
<< (loc.is_const ? " c" : " ")
<< (loc.fp ? " F" : " ")
<< (loc.core ? " C" : " ")
<< (loc.ref ? " r" : " ")
<< (loc.high_word ? " h" : " ")
<< (loc.home ? " H" : " ")
<< ", low: " << static_cast<int>(loc.reg.GetLowReg())
<< ", high: " << static_cast<int>(loc.reg.GetHighReg())
<< ", s_reg: " << loc.s_reg_low
<< ", orig: " << loc.orig_sreg;
}
void X86Mir2Lir::Materialize() {
// A good place to put the analysis before starting.
AnalyzeMIR();
// Now continue with regular code generation.
Mir2Lir::Materialize();
}
void X86Mir2Lir::LoadMethodAddress(const MethodReference& target_method, InvokeType type,
SpecialTargetRegister symbolic_reg) {
/*
* For x86, just generate a 32 bit move immediate instruction, that will be filled
* in at 'link time'. For now, put a unique value based on target to ensure that
* code deduplication works.
*/
int target_method_idx = target_method.dex_method_index;
const DexFile* target_dex_file = target_method.dex_file;
const DexFile::MethodId& target_method_id = target_dex_file->GetMethodId(target_method_idx);
uintptr_t target_method_id_ptr = reinterpret_cast<uintptr_t>(&target_method_id);
// Generate the move instruction with the unique pointer and save index, dex_file, and type.
LIR *move = RawLIR(current_dalvik_offset_, kX86Mov32RI, TargetReg(symbolic_reg).GetReg(),
static_cast<int>(target_method_id_ptr), target_method_idx,
WrapPointer(const_cast<DexFile*>(target_dex_file)), type);
AppendLIR(move);
method_address_insns_.Insert(move);
}
void X86Mir2Lir::LoadClassType(uint32_t type_idx, SpecialTargetRegister symbolic_reg) {
/*
* For x86, just generate a 32 bit move immediate instruction, that will be filled
* in at 'link time'. For now, put a unique value based on target to ensure that
* code deduplication works.
*/
const DexFile::TypeId& id = cu_->dex_file->GetTypeId(type_idx);
uintptr_t ptr = reinterpret_cast<uintptr_t>(&id);
// Generate the move instruction with the unique pointer and save index and type.
LIR *move = RawLIR(current_dalvik_offset_, kX86Mov32RI, TargetReg(symbolic_reg).GetReg(),
static_cast<int>(ptr), type_idx);
AppendLIR(move);
class_type_address_insns_.Insert(move);
}
LIR *X86Mir2Lir::CallWithLinkerFixup(const MethodReference& target_method, InvokeType type) {
/*
* For x86, just generate a 32 bit call relative instruction, that will be filled
* in at 'link time'. For now, put a unique value based on target to ensure that
* code deduplication works.
*/
int target_method_idx = target_method.dex_method_index;
const DexFile* target_dex_file = target_method.dex_file;
const DexFile::MethodId& target_method_id = target_dex_file->GetMethodId(target_method_idx);
uintptr_t target_method_id_ptr = reinterpret_cast<uintptr_t>(&target_method_id);
// Generate the call instruction with the unique pointer and save index, dex_file, and type.
LIR *call = RawLIR(current_dalvik_offset_, kX86CallI, static_cast<int>(target_method_id_ptr),
target_method_idx, WrapPointer(const_cast<DexFile*>(target_dex_file)), type);
AppendLIR(call);
call_method_insns_.Insert(call);
return call;
}
/*
* @brief Enter a 32 bit quantity into a buffer
* @param buf buffer.
* @param data Data value.
*/
static void PushWord(std::vector<uint8_t>&buf, int32_t data) {
buf.push_back(data & 0xff);
buf.push_back((data >> 8) & 0xff);
buf.push_back((data >> 16) & 0xff);
buf.push_back((data >> 24) & 0xff);
}
void X86Mir2Lir::InstallLiteralPools() {
// These are handled differently for x86.
DCHECK(code_literal_list_ == nullptr);
DCHECK(method_literal_list_ == nullptr);
DCHECK(class_literal_list_ == nullptr);
// Align to 16 byte boundary. We have implicit knowledge that the start of the method is
// on a 4 byte boundary. How can I check this if it changes (other than aligned loads
// will fail at runtime)?
if (const_vectors_ != nullptr) {
int align_size = (16-4) - (code_buffer_.size() & 0xF);
if (align_size < 0) {
align_size += 16;
}
while (align_size > 0) {
code_buffer_.push_back(0);
align_size--;
}
for (LIR *p = const_vectors_; p != nullptr; p = p->next) {
PushWord(code_buffer_, p->operands[0]);
PushWord(code_buffer_, p->operands[1]);
PushWord(code_buffer_, p->operands[2]);
PushWord(code_buffer_, p->operands[3]);
}
}
// Handle the fixups for methods.
for (uint32_t i = 0; i < method_address_insns_.Size(); i++) {
LIR* p = method_address_insns_.Get(i);
DCHECK_EQ(p->opcode, kX86Mov32RI);
uint32_t target_method_idx = p->operands[2];
const DexFile* target_dex_file =
reinterpret_cast<const DexFile*>(UnwrapPointer(p->operands[3]));
// The offset to patch is the last 4 bytes of the instruction.
int patch_offset = p->offset + p->flags.size - 4;
cu_->compiler_driver->AddMethodPatch(cu_->dex_file, cu_->class_def_idx,
cu_->method_idx, cu_->invoke_type,
target_method_idx, target_dex_file,
static_cast<InvokeType>(p->operands[4]),
patch_offset);
}
// Handle the fixups for class types.
for (uint32_t i = 0; i < class_type_address_insns_.Size(); i++) {
LIR* p = class_type_address_insns_.Get(i);
DCHECK_EQ(p->opcode, kX86Mov32RI);
uint32_t target_method_idx = p->operands[2];
// The offset to patch is the last 4 bytes of the instruction.
int patch_offset = p->offset + p->flags.size - 4;
cu_->compiler_driver->AddClassPatch(cu_->dex_file, cu_->class_def_idx,
cu_->method_idx, target_method_idx, patch_offset);
}
// And now the PC-relative calls to methods.
for (uint32_t i = 0; i < call_method_insns_.Size(); i++) {
LIR* p = call_method_insns_.Get(i);
DCHECK_EQ(p->opcode, kX86CallI);
uint32_t target_method_idx = p->operands[1];
const DexFile* target_dex_file =
reinterpret_cast<const DexFile*>(UnwrapPointer(p->operands[2]));
// The offset to patch is the last 4 bytes of the instruction.
int patch_offset = p->offset + p->flags.size - 4;
cu_->compiler_driver->AddRelativeCodePatch(cu_->dex_file, cu_->class_def_idx,
cu_->method_idx, cu_->invoke_type,
target_method_idx, target_dex_file,
static_cast<InvokeType>(p->operands[3]),
patch_offset, -4 /* offset */);
}
// And do the normal processing.
Mir2Lir::InstallLiteralPools();
}
/*
* Fast string.index_of(I) & (II). Inline check for simple case of char <= 0xffff,
* otherwise bails to standard library code.
*/
bool X86Mir2Lir::GenInlinedIndexOf(CallInfo* info, bool zero_based) {
ClobberCallerSave();
LockCallTemps(); // Using fixed registers
// EAX: 16 bit character being searched.
// ECX: count: number of words to be searched.
// EDI: String being searched.
// EDX: temporary during execution.
// EBX: temporary during execution.
RegLocation rl_obj = info->args[0];
RegLocation rl_char = info->args[1];
RegLocation rl_start; // Note: only present in III flavor or IndexOf.
uint32_t char_value =
rl_char.is_const ? mir_graph_->ConstantValue(rl_char.orig_sreg) : 0;
if (char_value > 0xFFFF) {
// We have to punt to the real String.indexOf.
return false;
}
// Okay, we are commited to inlining this.
RegLocation rl_return = GetReturn(false);
RegLocation rl_dest = InlineTarget(info);
// Is the string non-NULL?
LoadValueDirectFixed(rl_obj, rs_rDX);
GenNullCheck(rs_rDX, info->opt_flags);
info->opt_flags |= MIR_IGNORE_NULL_CHECK; // Record that we've null checked.
// Does the character fit in 16 bits?
LIR* slowpath_branch = nullptr;
if (rl_char.is_const) {
// We need the value in EAX.
LoadConstantNoClobber(rs_rAX, char_value);
} else {
// Character is not a constant; compare at runtime.
LoadValueDirectFixed(rl_char, rs_rAX);
slowpath_branch = OpCmpImmBranch(kCondGt, rs_rAX, 0xFFFF, nullptr);
}
// From here down, we know that we are looking for a char that fits in 16 bits.
// Location of reference to data array within the String object.
int value_offset = mirror::String::ValueOffset().Int32Value();
// Location of count within the String object.
int count_offset = mirror::String::CountOffset().Int32Value();
// Starting offset within data array.
int offset_offset = mirror::String::OffsetOffset().Int32Value();
// Start of char data with array_.
int data_offset = mirror::Array::DataOffset(sizeof(uint16_t)).Int32Value();
// Character is in EAX.
// Object pointer is in EDX.
// We need to preserve EDI, but have no spare registers, so push it on the stack.
// We have to remember that all stack addresses after this are offset by sizeof(EDI).
NewLIR1(kX86Push32R, rs_rDI.GetReg());
// Compute the number of words to search in to rCX.
Load32Disp(rs_rDX, count_offset, rs_rCX);
LIR *length_compare = nullptr;
int start_value = 0;
bool is_index_on_stack = false;
if (zero_based) {
// We have to handle an empty string. Use special instruction JECXZ.
length_compare = NewLIR0(kX86Jecxz8);
} else {
rl_start = info->args[2];
// We have to offset by the start index.
if (rl_start.is_const) {
start_value = mir_graph_->ConstantValue(rl_start.orig_sreg);
start_value = std::max(start_value, 0);
// Is the start > count?
length_compare = OpCmpImmBranch(kCondLe, rs_rCX, start_value, nullptr);
if (start_value != 0) {
OpRegImm(kOpSub, rs_rCX, start_value);
}
} else {
// Runtime start index.
rl_start = UpdateLocTyped(rl_start, kCoreReg);
if (rl_start.location == kLocPhysReg) {
// Handle "start index < 0" case.
OpRegReg(kOpXor, rs_rBX, rs_rBX);
OpRegReg(kOpCmp, rl_start.reg, rs_rBX);
OpCondRegReg(kOpCmov, kCondLt, rl_start.reg, rs_rBX);
// The length of the string should be greater than the start index.
length_compare = OpCmpBranch(kCondLe, rs_rCX, rl_start.reg, nullptr);
OpRegReg(kOpSub, rs_rCX, rl_start.reg);
if (rl_start.reg == rs_rDI) {
// The special case. We will use EDI further, so lets put start index to stack.
NewLIR1(kX86Push32R, rs_rDI.GetReg());
is_index_on_stack = true;
}
} else {
// Load the start index from stack, remembering that we pushed EDI.
int displacement = SRegOffset(rl_start.s_reg_low) + sizeof(uint32_t);
Load32Disp(rs_rX86_SP, displacement, rs_rBX);
OpRegReg(kOpXor, rs_rDI, rs_rDI);
OpRegReg(kOpCmp, rs_rBX, rs_rDI);
OpCondRegReg(kOpCmov, kCondLt, rs_rBX, rs_rDI);
length_compare = OpCmpBranch(kCondLe, rs_rCX, rs_rBX, nullptr);
OpRegReg(kOpSub, rs_rCX, rs_rBX);
// Put the start index to stack.
NewLIR1(kX86Push32R, rs_rBX.GetReg());
is_index_on_stack = true;
}
}
}
DCHECK(length_compare != nullptr);
// ECX now contains the count in words to be searched.
// Load the address of the string into EBX.
// The string starts at VALUE(String) + 2 * OFFSET(String) + DATA_OFFSET.
Load32Disp(rs_rDX, value_offset, rs_rDI);
Load32Disp(rs_rDX, offset_offset, rs_rBX);
OpLea(rs_rBX, rs_rDI, rs_rBX, 1, data_offset);
// Now compute into EDI where the search will start.
if (zero_based || rl_start.is_const) {
if (start_value == 0) {
OpRegCopy(rs_rDI, rs_rBX);
} else {
NewLIR3(kX86Lea32RM, rs_rDI.GetReg(), rs_rBX.GetReg(), 2 * start_value);
}
} else {
if (is_index_on_stack == true) {
// Load the start index from stack.
NewLIR1(kX86Pop32R, rs_rDX.GetReg());
OpLea(rs_rDI, rs_rBX, rs_rDX, 1, 0);
} else {
OpLea(rs_rDI, rs_rBX, rl_start.reg, 1, 0);
}
}
// EDI now contains the start of the string to be searched.
// We are all prepared to do the search for the character.
NewLIR0(kX86RepneScasw);
// Did we find a match?
LIR* failed_branch = OpCondBranch(kCondNe, nullptr);
// yes, we matched. Compute the index of the result.
// index = ((curr_ptr - orig_ptr) / 2) - 1.
OpRegReg(kOpSub, rs_rDI, rs_rBX);
OpRegImm(kOpAsr, rs_rDI, 1);
NewLIR3(kX86Lea32RM, rl_return.reg.GetReg(), rs_rDI.GetReg(), -1);
LIR *all_done = NewLIR1(kX86Jmp8, 0);
// Failed to match; return -1.
LIR *not_found = NewLIR0(kPseudoTargetLabel);
length_compare->target = not_found;
failed_branch->target = not_found;
LoadConstantNoClobber(rl_return.reg, -1);
// And join up at the end.
all_done->target = NewLIR0(kPseudoTargetLabel);
// Restore EDI from the stack.
NewLIR1(kX86Pop32R, rs_rDI.GetReg());
// Out of line code returns here.
if (slowpath_branch != nullptr) {
LIR *return_point = NewLIR0(kPseudoTargetLabel);
AddIntrinsicSlowPath(info, slowpath_branch, return_point);
}
StoreValue(rl_dest, rl_return);
return true;
}
/*
* @brief Enter an 'advance LOC' into the FDE buffer
* @param buf FDE buffer.
* @param increment Amount by which to increase the current location.
*/
static void AdvanceLoc(std::vector<uint8_t>&buf, uint32_t increment) {
if (increment < 64) {
// Encoding in opcode.
buf.push_back(0x1 << 6 | increment);
} else if (increment < 256) {
// Single byte delta.
buf.push_back(0x02);
buf.push_back(increment);
} else if (increment < 256 * 256) {
// Two byte delta.
buf.push_back(0x03);
buf.push_back(increment & 0xff);
buf.push_back((increment >> 8) & 0xff);
} else {
// Four byte delta.
buf.push_back(0x04);
PushWord(buf, increment);
}
}
std::vector<uint8_t>* X86CFIInitialization() {
return X86Mir2Lir::ReturnCommonCallFrameInformation();
}
std::vector<uint8_t>* X86Mir2Lir::ReturnCommonCallFrameInformation() {
std::vector<uint8_t>*cfi_info = new std::vector<uint8_t>;
// Length of the CIE (except for this field).
PushWord(*cfi_info, 16);
// CIE id.
PushWord(*cfi_info, 0xFFFFFFFFU);
// Version: 3.
cfi_info->push_back(0x03);
// Augmentation: empty string.
cfi_info->push_back(0x0);
// Code alignment: 1.
cfi_info->push_back(0x01);
// Data alignment: -4.
cfi_info->push_back(0x7C);
// Return address register (R8).
cfi_info->push_back(0x08);
// Initial return PC is 4(ESP): DW_CFA_def_cfa R4 4.
cfi_info->push_back(0x0C);
cfi_info->push_back(0x04);
cfi_info->push_back(0x04);
// Return address location: 0(SP): DW_CFA_offset R8 1 (* -4);.
cfi_info->push_back(0x2 << 6 | 0x08);
cfi_info->push_back(0x01);
// And 2 Noops to align to 4 byte boundary.
cfi_info->push_back(0x0);
cfi_info->push_back(0x0);
DCHECK_EQ(cfi_info->size() & 3, 0U);
return cfi_info;
}
static void EncodeUnsignedLeb128(std::vector<uint8_t>& buf, uint32_t value) {
uint8_t buffer[12];
uint8_t *ptr = EncodeUnsignedLeb128(buffer, value);
for (uint8_t *p = buffer; p < ptr; p++) {
buf.push_back(*p);
}
}
std::vector<uint8_t>* X86Mir2Lir::ReturnCallFrameInformation() {
std::vector<uint8_t>*cfi_info = new std::vector<uint8_t>;
// Generate the FDE for the method.
DCHECK_NE(data_offset_, 0U);
// Length (will be filled in later in this routine).
PushWord(*cfi_info, 0);
// CIE_pointer (can be filled in by linker); might be left at 0 if there is only
// one CIE for the whole debug_frame section.
PushWord(*cfi_info, 0);
// 'initial_location' (filled in by linker).
PushWord(*cfi_info, 0);
// 'address_range' (number of bytes in the method).
PushWord(*cfi_info, data_offset_);
// The instructions in the FDE.
if (stack_decrement_ != nullptr) {
// Advance LOC to just past the stack decrement.
uint32_t pc = NEXT_LIR(stack_decrement_)->offset;
AdvanceLoc(*cfi_info, pc);
// Now update the offset to the call frame: DW_CFA_def_cfa_offset frame_size.
cfi_info->push_back(0x0e);
EncodeUnsignedLeb128(*cfi_info, frame_size_);
// We continue with that stack until the epilogue.
if (stack_increment_ != nullptr) {
uint32_t new_pc = NEXT_LIR(stack_increment_)->offset;
AdvanceLoc(*cfi_info, new_pc - pc);
// We probably have code snippets after the epilogue, so save the
// current state: DW_CFA_remember_state.
cfi_info->push_back(0x0a);
// We have now popped the stack: DW_CFA_def_cfa_offset 4. There is only the return
// PC on the stack now.
cfi_info->push_back(0x0e);
EncodeUnsignedLeb128(*cfi_info, 4);
// Everything after that is the same as before the epilogue.
// Stack bump was followed by RET instruction.
LIR *post_ret_insn = NEXT_LIR(NEXT_LIR(stack_increment_));
if (post_ret_insn != nullptr) {
pc = new_pc;
new_pc = post_ret_insn->offset;
AdvanceLoc(*cfi_info, new_pc - pc);
// Restore the state: DW_CFA_restore_state.
cfi_info->push_back(0x0b);
}
}
}
// Padding to a multiple of 4
while ((cfi_info->size() & 3) != 0) {
// DW_CFA_nop is encoded as 0.
cfi_info->push_back(0);
}
// Set the length of the FDE inside the generated bytes.
uint32_t length = cfi_info->size() - 4;
(*cfi_info)[0] = length;
(*cfi_info)[1] = length >> 8;
(*cfi_info)[2] = length >> 16;
(*cfi_info)[3] = length >> 24;
return cfi_info;
}
void X86Mir2Lir::GenMachineSpecificExtendedMethodMIR(BasicBlock* bb, MIR* mir) {
switch (static_cast<ExtendedMIROpcode>(mir->dalvikInsn.opcode)) {
case kMirOpConstVector:
GenConst128(bb, mir);
break;
case kMirOpMoveVector:
GenMoveVector(bb, mir);
break;
case kMirOpPackedMultiply:
GenMultiplyVector(bb, mir);
break;
case kMirOpPackedAddition:
GenAddVector(bb, mir);
break;
case kMirOpPackedSubtract:
GenSubtractVector(bb, mir);
break;
case kMirOpPackedShiftLeft:
GenShiftLeftVector(bb, mir);
break;
case kMirOpPackedSignedShiftRight:
GenSignedShiftRightVector(bb, mir);
break;
case kMirOpPackedUnsignedShiftRight:
GenUnsignedShiftRightVector(bb, mir);
break;
case kMirOpPackedAnd:
GenAndVector(bb, mir);
break;
case kMirOpPackedOr:
GenOrVector(bb, mir);
break;
case kMirOpPackedXor:
GenXorVector(bb, mir);
break;
case kMirOpPackedAddReduce:
GenAddReduceVector(bb, mir);
break;
case kMirOpPackedReduce:
GenReduceVector(bb, mir);
break;
case kMirOpPackedSet:
GenSetVector(bb, mir);
break;
default:
break;
}
}
void X86Mir2Lir::GenConst128(BasicBlock* bb, MIR* mir) {
int type_size = mir->dalvikInsn.vA;
// We support 128 bit vectors.
DCHECK_EQ(type_size & 0xFFFF, 128);
RegStorage rs_dest = RegStorage::Solo128(mir->dalvikInsn.vB);
uint32_t *args = mir->dalvikInsn.arg;
int reg = rs_dest.GetReg();
// Check for all 0 case.
if (args[0] == 0 && args[1] == 0 && args[2] == 0 && args[3] == 0) {
NewLIR2(kX86XorpsRR, reg, reg);
return;
}
// Okay, load it from the constant vector area.
LIR *data_target = ScanVectorLiteral(mir);
if (data_target == nullptr) {
data_target = AddVectorLiteral(mir);
}
// Address the start of the method.
RegLocation rl_method = mir_graph_->GetRegLocation(base_of_code_->s_reg_low);
rl_method = LoadValue(rl_method, kCoreReg);
// Load the proper value from the literal area.
// We don't know the proper offset for the value, so pick one that will force
// 4 byte offset. We will fix this up in the assembler later to have the right
// value.
LIR *load = NewLIR3(kX86Mova128RM, reg, rl_method.reg.GetReg(), 256 /* bogus */);
load->flags.fixup = kFixupLoad;
load->target = data_target;
SetMemRefType(load, true, kLiteral);
}
void X86Mir2Lir::GenMoveVector(BasicBlock *bb, MIR *mir) {
// We only support 128 bit registers.
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
RegStorage rs_dest = RegStorage::Solo128(mir->dalvikInsn.vB);
RegStorage rs_src = RegStorage::Solo128(mir->dalvikInsn.vC);
NewLIR2(kX86Mova128RR, rs_dest.GetReg(), rs_src.GetReg());
}
void X86Mir2Lir::GenMultiplyVector(BasicBlock *bb, MIR *mir) {
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
OpSize opsize = static_cast<OpSize>(mir->dalvikInsn.vA >> 16);
RegStorage rs_dest_src1 = RegStorage::Solo128(mir->dalvikInsn.vB);
RegStorage rs_src2 = RegStorage::Solo128(mir->dalvikInsn.vC);
int opcode = 0;
switch (opsize) {
case k32:
opcode = kX86PmulldRR;
break;
case kSignedHalf:
opcode = kX86PmullwRR;
break;
case kSingle:
opcode = kX86MulpsRR;
break;
case kDouble:
opcode = kX86MulpdRR;
break;
default:
LOG(FATAL) << "Unsupported vector multiply " << opsize;
break;
}
NewLIR2(opcode, rs_dest_src1.GetReg(), rs_src2.GetReg());
}
void X86Mir2Lir::GenAddVector(BasicBlock *bb, MIR *mir) {
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
OpSize opsize = static_cast<OpSize>(mir->dalvikInsn.vA >> 16);
RegStorage rs_dest_src1 = RegStorage::Solo128(mir->dalvikInsn.vB);
RegStorage rs_src2 = RegStorage::Solo128(mir->dalvikInsn.vC);
int opcode = 0;
switch (opsize) {
case k32:
opcode = kX86PadddRR;
break;
case kSignedHalf:
case kUnsignedHalf:
opcode = kX86PaddwRR;
break;
case kUnsignedByte:
case kSignedByte:
opcode = kX86PaddbRR;
break;
case kSingle:
opcode = kX86AddpsRR;
break;
case kDouble:
opcode = kX86AddpdRR;
break;
default:
LOG(FATAL) << "Unsupported vector addition " << opsize;
break;
}
NewLIR2(opcode, rs_dest_src1.GetReg(), rs_src2.GetReg());
}
void X86Mir2Lir::GenSubtractVector(BasicBlock *bb, MIR *mir) {
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
OpSize opsize = static_cast<OpSize>(mir->dalvikInsn.vA >> 16);
RegStorage rs_dest_src1 = RegStorage::Solo128(mir->dalvikInsn.vB);
RegStorage rs_src2 = RegStorage::Solo128(mir->dalvikInsn.vC);
int opcode = 0;
switch (opsize) {
case k32:
opcode = kX86PsubdRR;
break;
case kSignedHalf:
case kUnsignedHalf:
opcode = kX86PsubwRR;
break;
case kUnsignedByte:
case kSignedByte:
opcode = kX86PsubbRR;
break;
case kSingle:
opcode = kX86SubpsRR;
break;
case kDouble:
opcode = kX86SubpdRR;
break;
default:
LOG(FATAL) << "Unsupported vector subtraction " << opsize;
break;
}
NewLIR2(opcode, rs_dest_src1.GetReg(), rs_src2.GetReg());
}
void X86Mir2Lir::GenShiftLeftVector(BasicBlock *bb, MIR *mir) {
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
OpSize opsize = static_cast<OpSize>(mir->dalvikInsn.vA >> 16);
RegStorage rs_dest_src1 = RegStorage::Solo128(mir->dalvikInsn.vB);
int imm = mir->dalvikInsn.vC;
int opcode = 0;
switch (opsize) {
case k32:
opcode = kX86PslldRI;
break;
case k64:
opcode = kX86PsllqRI;
break;
case kSignedHalf:
case kUnsignedHalf:
opcode = kX86PsllwRI;
break;
default:
LOG(FATAL) << "Unsupported vector shift left " << opsize;
break;
}
NewLIR2(opcode, rs_dest_src1.GetReg(), imm);
}
void X86Mir2Lir::GenSignedShiftRightVector(BasicBlock *bb, MIR *mir) {
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
OpSize opsize = static_cast<OpSize>(mir->dalvikInsn.vA >> 16);
RegStorage rs_dest_src1 = RegStorage::Solo128(mir->dalvikInsn.vB);
int imm = mir->dalvikInsn.vC;
int opcode = 0;
switch (opsize) {
case k32:
opcode = kX86PsradRI;
break;
case kSignedHalf:
case kUnsignedHalf:
opcode = kX86PsrawRI;
break;
default:
LOG(FATAL) << "Unsupported vector signed shift right " << opsize;
break;
}
NewLIR2(opcode, rs_dest_src1.GetReg(), imm);
}
void X86Mir2Lir::GenUnsignedShiftRightVector(BasicBlock *bb, MIR *mir) {
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
OpSize opsize = static_cast<OpSize>(mir->dalvikInsn.vA >> 16);
RegStorage rs_dest_src1 = RegStorage::Solo128(mir->dalvikInsn.vB);
int imm = mir->dalvikInsn.vC;
int opcode = 0;
switch (opsize) {
case k32:
opcode = kX86PsrldRI;
break;
case k64:
opcode = kX86PsrlqRI;
break;
case kSignedHalf:
case kUnsignedHalf:
opcode = kX86PsrlwRI;
break;
default:
LOG(FATAL) << "Unsupported vector unsigned shift right " << opsize;
break;
}
NewLIR2(opcode, rs_dest_src1.GetReg(), imm);
}
void X86Mir2Lir::GenAndVector(BasicBlock *bb, MIR *mir) {
// We only support 128 bit registers.
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
RegStorage rs_dest_src1 = RegStorage::Solo128(mir->dalvikInsn.vB);
RegStorage rs_src2 = RegStorage::Solo128(mir->dalvikInsn.vC);
NewLIR2(kX86PandRR, rs_dest_src1.GetReg(), rs_src2.GetReg());
}
void X86Mir2Lir::GenOrVector(BasicBlock *bb, MIR *mir) {
// We only support 128 bit registers.
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
RegStorage rs_dest_src1 = RegStorage::Solo128(mir->dalvikInsn.vB);
RegStorage rs_src2 = RegStorage::Solo128(mir->dalvikInsn.vC);
NewLIR2(kX86PorRR, rs_dest_src1.GetReg(), rs_src2.GetReg());
}
void X86Mir2Lir::GenXorVector(BasicBlock *bb, MIR *mir) {
// We only support 128 bit registers.
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
RegStorage rs_dest_src1 = RegStorage::Solo128(mir->dalvikInsn.vB);
RegStorage rs_src2 = RegStorage::Solo128(mir->dalvikInsn.vC);
NewLIR2(kX86PxorRR, rs_dest_src1.GetReg(), rs_src2.GetReg());
}
void X86Mir2Lir::GenAddReduceVector(BasicBlock *bb, MIR *mir) {
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
OpSize opsize = static_cast<OpSize>(mir->dalvikInsn.vA >> 16);
RegStorage rs_dest_src1 = RegStorage::Solo128(mir->dalvikInsn.vB);
int imm = mir->dalvikInsn.vC;
int opcode = 0;
switch (opsize) {
case k32:
opcode = kX86PhadddRR;
break;
case kSignedHalf:
case kUnsignedHalf:
opcode = kX86PhaddwRR;
break;
default:
LOG(FATAL) << "Unsupported vector add reduce " << opsize;
break;
}
NewLIR2(opcode, rs_dest_src1.GetReg(), imm);
}
void X86Mir2Lir::GenReduceVector(BasicBlock *bb, MIR *mir) {
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
OpSize opsize = static_cast<OpSize>(mir->dalvikInsn.vA >> 16);
RegStorage rs_src = RegStorage::Solo128(mir->dalvikInsn.vB);
int index = mir->dalvikInsn.arg[0];
int opcode = 0;
switch (opsize) {
case k32:
opcode = kX86PextrdRRI;
break;
case kSignedHalf:
case kUnsignedHalf:
opcode = kX86PextrwRRI;
break;
case kUnsignedByte:
case kSignedByte:
opcode = kX86PextrbRRI;
break;
default:
LOG(FATAL) << "Unsupported vector reduce " << opsize;
break;
}
// We need to extract to a GPR.
RegStorage temp = AllocTemp();
NewLIR3(opcode, temp.GetReg(), rs_src.GetReg(), index);
// Assume that the destination VR is in the def for the mir.
RegLocation rl_dest = mir_graph_->GetDest(mir);
RegLocation rl_temp =
{kLocPhysReg, 0, 0, 0, 0, 0, 0, 0, 1, temp, INVALID_SREG, INVALID_SREG};
StoreValue(rl_dest, rl_temp);
}
void X86Mir2Lir::GenSetVector(BasicBlock *bb, MIR *mir) {
DCHECK_EQ(mir->dalvikInsn.vA & 0xFFFF, 128U);
OpSize opsize = static_cast<OpSize>(mir->dalvikInsn.vA >> 16);
RegStorage rs_dest = RegStorage::Solo128(mir->dalvikInsn.vB);
int op_low = 0, op_high = 0;
switch (opsize) {
case k32:
op_low = kX86PshufdRRI;
break;
case kSignedHalf:
case kUnsignedHalf:
// Handles low quadword.
op_low = kX86PshuflwRRI;
// Handles upper quadword.
op_high = kX86PshufdRRI;
break;
default:
LOG(FATAL) << "Unsupported vector set " << opsize;
break;
}
// Load the value from the VR into a GPR.
RegLocation rl_src = mir_graph_->GetSrc(mir, 0);
rl_src = LoadValue(rl_src, kCoreReg);
// Load the value into the XMM register.
NewLIR2(kX86MovdxrRR, rs_dest.GetReg(), rl_src.reg.GetReg());
// Now shuffle the value across the destination.
NewLIR3(op_low, rs_dest.GetReg(), rs_dest.GetReg(), 0);
// And then repeat as needed.
if (op_high != 0) {
NewLIR3(op_high, rs_dest.GetReg(), rs_dest.GetReg(), 0);
}
}
LIR *X86Mir2Lir::ScanVectorLiteral(MIR *mir) {
int *args = reinterpret_cast<int*>(mir->dalvikInsn.arg);
for (LIR *p = const_vectors_; p != nullptr; p = p->next) {
if (args[0] == p->operands[0] && args[1] == p->operands[1] &&
args[2] == p->operands[2] && args[3] == p->operands[3]) {
return p;
}
}
return nullptr;
}
LIR *X86Mir2Lir::AddVectorLiteral(MIR *mir) {
LIR* new_value = static_cast<LIR*>(arena_->Alloc(sizeof(LIR), kArenaAllocData));
int *args = reinterpret_cast<int*>(mir->dalvikInsn.arg);
new_value->operands[0] = args[0];
new_value->operands[1] = args[1];
new_value->operands[2] = args[2];
new_value->operands[3] = args[3];
new_value->next = const_vectors_;
if (const_vectors_ == nullptr) {
estimated_native_code_size_ += 12; // Amount needed to align to 16 byte boundary.
}
estimated_native_code_size_ += 16; // Space for one vector.
const_vectors_ = new_value;
return new_value;
}
} // namespace art