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gerrit-public.fairphone.software / platform / art / 866ac80d18c37a3854a8c857cb084614fba01110 / . / compiler / dex / quick / ralloc_util.cc
blob: bcc077bc181cad7fe2c8355c2e7e5eb9b68c7207 [file] [log] [blame]
/*
* Copyright (C) 2011 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.
*/
/* This file contains register alloction support. */
#include "dex/compiler_ir.h"
#include "dex/compiler_internals.h"
#include "mir_to_lir-inl.h"
namespace art {
/*
* Free all allocated temps in the temp pools. Note that this does
* not affect the "liveness" of a temp register, which will stay
* live until it is either explicitly killed or reallocated.
*/
void Mir2Lir::ResetRegPool() {
GrowableArray<RegisterInfo*>::Iterator iter(&tempreg_info_);
for (RegisterInfo* info = iter.Next(); info != NULL; info = iter.Next()) {
info->MarkFree();
}
// Reset temp tracking sanity check.
if (kIsDebugBuild) {
live_sreg_ = INVALID_SREG;
}
}
Mir2Lir::RegisterInfo::RegisterInfo(RegStorage r, uint64_t mask)
: reg_(r), is_temp_(false), wide_value_(false), dirty_(false), aliased_(false), partner_(r),
s_reg_(INVALID_SREG), def_use_mask_(mask), master_(this), def_start_(nullptr),
def_end_(nullptr), alias_chain_(nullptr) {
switch (r.StorageSize()) {
case 0: storage_mask_ = 0xffffffff; break;
case 4: storage_mask_ = 0x00000001; break;
case 8: storage_mask_ = 0x00000003; break;
case 16: storage_mask_ = 0x0000000f; break;
case 32: storage_mask_ = 0x000000ff; break;
case 64: storage_mask_ = 0x0000ffff; break;
case 128: storage_mask_ = 0xffffffff; break;
}
used_storage_ = r.Valid() ? ~storage_mask_ : storage_mask_;
liveness_ = used_storage_;
}
Mir2Lir::RegisterPool::RegisterPool(Mir2Lir* m2l, ArenaAllocator* arena,
const std::vector<RegStorage>& core_regs,
const std::vector<RegStorage>& sp_regs,
const std::vector<RegStorage>& dp_regs,
const std::vector<RegStorage>& reserved_regs,
const std::vector<RegStorage>& core_temps,
const std::vector<RegStorage>& sp_temps,
const std::vector<RegStorage>& dp_temps) :
core_regs_(arena, core_regs.size()), next_core_reg_(0), sp_regs_(arena, sp_regs.size()),
next_sp_reg_(0), dp_regs_(arena, dp_regs.size()), next_dp_reg_(0), m2l_(m2l) {
// Initialize the fast lookup map.
m2l_->reginfo_map_.Reset();
if (kIsDebugBuild) {
m2l_->reginfo_map_.Resize(RegStorage::kMaxRegs);
for (unsigned i = 0; i < RegStorage::kMaxRegs; i++) {
m2l_->reginfo_map_.Insert(nullptr);
}
} else {
m2l_->reginfo_map_.SetSize(RegStorage::kMaxRegs);
}
// Construct the register pool.
for (RegStorage reg : core_regs) {
RegisterInfo* info = new (arena) RegisterInfo(reg, m2l_->GetRegMaskCommon(reg));
m2l_->reginfo_map_.Put(reg.GetReg(), info);
core_regs_.Insert(info);
}
for (RegStorage reg : sp_regs) {
RegisterInfo* info = new (arena) RegisterInfo(reg, m2l_->GetRegMaskCommon(reg));
m2l_->reginfo_map_.Put(reg.GetReg(), info);
sp_regs_.Insert(info);
}
for (RegStorage reg : dp_regs) {
RegisterInfo* info = new (arena) RegisterInfo(reg, m2l_->GetRegMaskCommon(reg));
m2l_->reginfo_map_.Put(reg.GetReg(), info);
dp_regs_.Insert(info);
}
// Keep special registers from being allocated.
for (RegStorage reg : reserved_regs) {
m2l_->MarkInUse(reg);
}
// Mark temp regs - all others not in use can be used for promotion
for (RegStorage reg : core_temps) {
m2l_->MarkTemp(reg);
}
for (RegStorage reg : sp_temps) {
m2l_->MarkTemp(reg);
}
for (RegStorage reg : dp_temps) {
m2l_->MarkTemp(reg);
}
// Add an entry for InvalidReg with zero'd mask.
RegisterInfo* invalid_reg = new (arena) RegisterInfo(RegStorage::InvalidReg(), 0);
m2l_->reginfo_map_.Put(RegStorage::InvalidReg().GetReg(), invalid_reg);
}
void Mir2Lir::DumpRegPool(GrowableArray<RegisterInfo*>* regs) {
LOG(INFO) << "================================================";
GrowableArray<RegisterInfo*>::Iterator it(regs);
for (RegisterInfo* info = it.Next(); info != nullptr; info = it.Next()) {
LOG(INFO) << StringPrintf(
"R[%d:%d:%c]: T:%d, U:%d, W:%d, p:%d, LV:%d, D:%d, SR:%d, DEF:%d",
info->GetReg().GetReg(), info->GetReg().GetRegNum(), info->GetReg().IsFloat() ? 'f' : 'c',
info->IsTemp(), info->InUse(), info->IsWide(), info->Partner().GetReg(), info->IsLive(),
info->IsDirty(), info->SReg(), info->DefStart() != nullptr);
}
LOG(INFO) << "================================================";
}
void Mir2Lir::DumpCoreRegPool() {
DumpRegPool(&reg_pool_->core_regs_);
}
void Mir2Lir::DumpFpRegPool() {
DumpRegPool(&reg_pool_->sp_regs_);
DumpRegPool(&reg_pool_->dp_regs_);
}
void Mir2Lir::DumpRegPools() {
LOG(INFO) << "Core registers";
DumpCoreRegPool();
LOG(INFO) << "FP registers";
DumpFpRegPool();
}
void Mir2Lir::Clobber(RegStorage reg) {
if (UNLIKELY(reg.IsPair())) {
DCHECK(!GetRegInfo(reg.GetLow())->IsAliased());
Clobber(reg.GetLow());
DCHECK(!GetRegInfo(reg.GetHigh())->IsAliased());
Clobber(reg.GetHigh());
} else {
RegisterInfo* info = GetRegInfo(reg);
if (info->IsTemp() && !info->IsDead()) {
ClobberBody(info);
if (info->IsAliased()) {
ClobberAliases(info);
} else {
RegisterInfo* master = info->Master();
if (info != master) {
ClobberBody(info->Master());
}
}
}
}
}
void Mir2Lir::ClobberAliases(RegisterInfo* info) {
for (RegisterInfo* alias = info->GetAliasChain(); alias != nullptr;
alias = alias->GetAliasChain()) {
DCHECK(!alias->IsAliased()); // Only the master should be marked as alised.
if (alias->SReg() != INVALID_SREG) {
alias->SetSReg(INVALID_SREG);
alias->ResetDefBody();
if (alias->IsWide()) {
alias->SetIsWide(false);
if (alias->GetReg() != alias->Partner()) {
RegisterInfo* p = GetRegInfo(alias->Partner());
p->SetIsWide(false);
p->MarkDead();
p->ResetDefBody();
}
}
}
}
}
/*
* Break the association between a Dalvik vreg and a physical temp register of either register
* class.
* TODO: Ideally, the public version of this code should not exist. Besides its local usage
* in the register utilities, is is also used by code gen routines to work around a deficiency in
* local register allocation, which fails to distinguish between the "in" and "out" identities
* of Dalvik vregs. This can result in useless register copies when the same Dalvik vreg
* is used both as the source and destination register of an operation in which the type
* changes (for example: INT_TO_FLOAT v1, v1). Revisit when improved register allocation is
* addressed.
*/
void Mir2Lir::ClobberSReg(int s_reg) {
if (s_reg != INVALID_SREG) {
if (kIsDebugBuild && s_reg == live_sreg_) {
live_sreg_ = INVALID_SREG;
}
GrowableArray<RegisterInfo*>::Iterator iter(&tempreg_info_);
for (RegisterInfo* info = iter.Next(); info != NULL; info = iter.Next()) {
if (info->SReg() == s_reg) {
ClobberBody(info);
if (info->IsAliased()) {
ClobberAliases(info);
}
}
}
}
}
/*
* SSA names associated with the initial definitions of Dalvik
* registers are the same as the Dalvik register number (and
* thus take the same position in the promotion_map. However,
* the special Method* and compiler temp resisters use negative
* v_reg numbers to distinguish them and can have an arbitrary
* ssa name (above the last original Dalvik register). This function
* maps SSA names to positions in the promotion_map array.
*/
int Mir2Lir::SRegToPMap(int s_reg) {
DCHECK_LT(s_reg, mir_graph_->GetNumSSARegs());
DCHECK_GE(s_reg, 0);
int v_reg = mir_graph_->SRegToVReg(s_reg);
if (v_reg >= 0) {
DCHECK_LT(v_reg, cu_->num_dalvik_registers);
return v_reg;
} else {
/*
* It must be the case that the v_reg for temporary is less than or equal to the
* base reg for temps. For that reason, "position" must be zero or positive.
*/
unsigned int position = std::abs(v_reg) - std::abs(static_cast<int>(kVRegTempBaseReg));
// The temporaries are placed after dalvik registers in the promotion map
DCHECK_LT(position, mir_graph_->GetNumUsedCompilerTemps());
return cu_->num_dalvik_registers + position;
}
}
// TODO: refactor following Alloc/Record routines - much commonality.
void Mir2Lir::RecordCorePromotion(RegStorage reg, int s_reg) {
int p_map_idx = SRegToPMap(s_reg);
int v_reg = mir_graph_->SRegToVReg(s_reg);
int reg_num = reg.GetRegNum();
GetRegInfo(reg)->MarkInUse();
core_spill_mask_ |= (1 << reg_num);
// Include reg for later sort
core_vmap_table_.push_back(reg_num << VREG_NUM_WIDTH | (v_reg & ((1 << VREG_NUM_WIDTH) - 1)));
num_core_spills_++;
promotion_map_[p_map_idx].core_location = kLocPhysReg;
promotion_map_[p_map_idx].core_reg = reg_num;
}
/* Reserve a callee-save register. Return InvalidReg if none available */
RegStorage Mir2Lir::AllocPreservedCoreReg(int s_reg) {
RegStorage res;
GrowableArray<RegisterInfo*>::Iterator it(&reg_pool_->core_regs_);
for (RegisterInfo* info = it.Next(); info != nullptr; info = it.Next()) {
if (!info->IsTemp() && !info->InUse()) {
res = info->GetReg();
RecordCorePromotion(res, s_reg);
break;
}
}
return res;
}
void Mir2Lir::RecordSinglePromotion(RegStorage reg, int s_reg) {
int p_map_idx = SRegToPMap(s_reg);
int v_reg = mir_graph_->SRegToVReg(s_reg);
GetRegInfo(reg)->MarkInUse();
MarkPreservedSingle(v_reg, reg);
promotion_map_[p_map_idx].fp_location = kLocPhysReg;
promotion_map_[p_map_idx].FpReg = reg.GetReg();
}
// Reserve a callee-save sp single register.
RegStorage Mir2Lir::AllocPreservedSingle(int s_reg) {
RegStorage res;
GrowableArray<RegisterInfo*>::Iterator it(&reg_pool_->sp_regs_);
for (RegisterInfo* info = it.Next(); info != nullptr; info = it.Next()) {
if (!info->IsTemp() && !info->InUse()) {
res = info->GetReg();
RecordSinglePromotion(res, s_reg);
break;
}
}
return res;
}
void Mir2Lir::RecordDoublePromotion(RegStorage reg, int s_reg) {
int p_map_idx = SRegToPMap(s_reg);
int v_reg = mir_graph_->SRegToVReg(s_reg);
GetRegInfo(reg)->MarkInUse();
MarkPreservedDouble(v_reg, reg);
promotion_map_[p_map_idx].fp_location = kLocPhysReg;
promotion_map_[p_map_idx].FpReg = reg.GetReg();
}
// Reserve a callee-save dp solo register.
RegStorage Mir2Lir::AllocPreservedDouble(int s_reg) {
RegStorage res;
GrowableArray<RegisterInfo*>::Iterator it(&reg_pool_->dp_regs_);
for (RegisterInfo* info = it.Next(); info != nullptr; info = it.Next()) {
if (!info->IsTemp() && !info->InUse()) {
res = info->GetReg();
RecordDoublePromotion(res, s_reg);
break;
}
}
return res;
}
RegStorage Mir2Lir::AllocTempBody(GrowableArray<RegisterInfo*> &regs, int* next_temp, bool required) {
int num_regs = regs.Size();
int next = *next_temp;
for (int i = 0; i< num_regs; i++) {
if (next >= num_regs)
next = 0;
RegisterInfo* info = regs.Get(next);
// Try to allocate a register that doesn't hold a live value.
if (info->IsTemp() && !info->InUse() && !info->IsLive()) {
Clobber(info->GetReg());
info->MarkInUse();
/*
* NOTE: "wideness" is an attribute of how the container is used, not its physical size.
* The caller will set wideness as appropriate.
*/
info->SetIsWide(false);
*next_temp = next + 1;
return info->GetReg();
}
next++;
}
next = *next_temp;
// No free non-live regs. Anything we can kill?
for (int i = 0; i< num_regs; i++) {
if (next >= num_regs)
next = 0;
RegisterInfo* info = regs.Get(next);
if (info->IsTemp() && !info->InUse()) {
// Got one. Kill it.
ClobberSReg(info->SReg());
Clobber(info->GetReg());
info->MarkInUse();
info->SetIsWide(false);
*next_temp = next + 1;
return info->GetReg();
}
next++;
}
if (required) {
CodegenDump();
DumpRegPools();
LOG(FATAL) << "No free temp registers";
}
return RegStorage::InvalidReg(); // No register available
}
/* Return a temp if one is available, -1 otherwise */
RegStorage Mir2Lir::AllocFreeTemp() {
return AllocTempBody(reg_pool_->core_regs_, &reg_pool_->next_core_reg_, false);
}
RegStorage Mir2Lir::AllocTemp() {
return AllocTempBody(reg_pool_->core_regs_, &reg_pool_->next_core_reg_, true);
}
RegStorage Mir2Lir::AllocTempSingle() {
RegStorage res = AllocTempBody(reg_pool_->sp_regs_, &reg_pool_->next_sp_reg_, true);
DCHECK(res.IsSingle()) << "Reg: 0x" << std::hex << res.GetRawBits();
return res;
}
RegStorage Mir2Lir::AllocTempDouble() {
RegStorage res = AllocTempBody(reg_pool_->dp_regs_, &reg_pool_->next_dp_reg_, true);
DCHECK(res.IsDouble()) << "Reg: 0x" << std::hex << res.GetRawBits();
return res;
}
RegStorage Mir2Lir::FindLiveReg(GrowableArray<RegisterInfo*> &regs, int s_reg) {
RegStorage res;
GrowableArray<RegisterInfo*>::Iterator it(&regs);
for (RegisterInfo* info = it.Next(); info != nullptr; info = it.Next()) {
if ((info->SReg() == s_reg) && info->IsLive()) {
res = info->GetReg();
break;
}
}
return res;
}
RegStorage Mir2Lir::AllocLiveReg(int s_reg, int reg_class, bool wide) {
RegStorage reg;
// TODO: might be worth a sanity check here to verify at most 1 live reg per s_reg.
if ((reg_class == kAnyReg) || (reg_class == kFPReg)) {
reg = FindLiveReg(wide ? reg_pool_->dp_regs_ : reg_pool_->sp_regs_, s_reg);
}
if (!reg.Valid() && (reg_class != kFPReg)) {
// TODO: add 64-bit core pool similar to above.
reg = FindLiveReg(reg_pool_->core_regs_, s_reg);
}
if (reg.Valid()) {
if (wide && !reg.IsFloat() && !Is64BitInstructionSet(cu_->instruction_set)) {
// Only allow reg pairs for core regs on 32-bit targets.
RegStorage high_reg = FindLiveReg(reg_pool_->core_regs_, s_reg + 1);
if (high_reg.Valid()) {
reg = RegStorage::MakeRegPair(reg, high_reg);
MarkWide(reg);
} else {
// Only half available.
reg = RegStorage::InvalidReg();
}
}
if (reg.Valid() && (wide != GetRegInfo(reg)->IsWide())) {
// Width mismatch - don't try to reuse.
reg = RegStorage::InvalidReg();
}
}
if (reg.Valid()) {
if (reg.IsPair()) {
RegisterInfo* info_low = GetRegInfo(reg.GetLow());
RegisterInfo* info_high = GetRegInfo(reg.GetHigh());
if (info_low->IsTemp()) {
info_low->MarkInUse();
}
if (info_high->IsTemp()) {
info_high->MarkInUse();
}
} else {
RegisterInfo* info = GetRegInfo(reg);
if (info->IsTemp()) {
info->MarkInUse();
}
}
} else {
// Either not found, or something didn't match up. Clobber to prevent any stale instances.
ClobberSReg(s_reg);
if (wide) {
ClobberSReg(s_reg + 1);
}
}
return reg;
}
void Mir2Lir::FreeTemp(RegStorage reg) {
if (reg.IsPair()) {
FreeTemp(reg.GetLow());
FreeTemp(reg.GetHigh());
} else {
RegisterInfo* p = GetRegInfo(reg);
if (p->IsTemp()) {
p->MarkFree();
p->SetIsWide(false);
p->SetPartner(reg);
}
}
}
bool Mir2Lir::IsLive(RegStorage reg) {
bool res;
if (reg.IsPair()) {
RegisterInfo* p_lo = GetRegInfo(reg.GetLow());
RegisterInfo* p_hi = GetRegInfo(reg.GetHigh());
DCHECK_EQ(p_lo->IsLive(), p_hi->IsLive());
res = p_lo->IsLive() || p_hi->IsLive();
} else {
RegisterInfo* p = GetRegInfo(reg);
res = p->IsLive();
}
return res;
}
bool Mir2Lir::IsTemp(RegStorage reg) {
bool res;
if (reg.IsPair()) {
RegisterInfo* p_lo = GetRegInfo(reg.GetLow());
RegisterInfo* p_hi = GetRegInfo(reg.GetHigh());
res = p_lo->IsTemp() || p_hi->IsTemp();
} else {
RegisterInfo* p = GetRegInfo(reg);
res = p->IsTemp();
}
return res;
}
bool Mir2Lir::IsPromoted(RegStorage reg) {
bool res;
if (reg.IsPair()) {
RegisterInfo* p_lo = GetRegInfo(reg.GetLow());
RegisterInfo* p_hi = GetRegInfo(reg.GetHigh());
res = !p_lo->IsTemp() || !p_hi->IsTemp();
} else {
RegisterInfo* p = GetRegInfo(reg);
res = !p->IsTemp();
}
return res;
}
bool Mir2Lir::IsDirty(RegStorage reg) {
bool res;
if (reg.IsPair()) {
RegisterInfo* p_lo = GetRegInfo(reg.GetLow());
RegisterInfo* p_hi = GetRegInfo(reg.GetHigh());
res = p_lo->IsDirty() || p_hi->IsDirty();
} else {
RegisterInfo* p = GetRegInfo(reg);
res = p->IsDirty();
}
return res;
}
/*
* Similar to AllocTemp(), but forces the allocation of a specific
* register. No check is made to see if the register was previously
* allocated. Use with caution.
*/
void Mir2Lir::LockTemp(RegStorage reg) {
DCHECK(IsTemp(reg));
if (reg.IsPair()) {
RegisterInfo* p_lo = GetRegInfo(reg.GetLow());
RegisterInfo* p_hi = GetRegInfo(reg.GetHigh());
p_lo->MarkInUse();
p_lo->MarkDead();
p_hi->MarkInUse();
p_hi->MarkDead();
} else {
RegisterInfo* p = GetRegInfo(reg);
p->MarkInUse();
p->MarkDead();
}
}
void Mir2Lir::ResetDef(RegStorage reg) {
if (reg.IsPair()) {
GetRegInfo(reg.GetLow())->ResetDefBody();
GetRegInfo(reg.GetHigh())->ResetDefBody();
} else {
GetRegInfo(reg)->ResetDefBody();
}
}
void Mir2Lir::NullifyRange(RegStorage reg, int s_reg) {
RegisterInfo* info = nullptr;
RegStorage rs = reg.IsPair() ? reg.GetLow() : reg;
if (IsTemp(rs)) {
info = GetRegInfo(reg);
}
if ((info != nullptr) && (info->DefStart() != nullptr) && (info->DefEnd() != nullptr)) {
DCHECK_EQ(info->SReg(), s_reg); // Make sure we're on the same page.
for (LIR* p = info->DefStart();; p = p->next) {
NopLIR(p);
if (p == info->DefEnd()) {
break;
}
}
}
}
/*
* Mark the beginning and end LIR of a def sequence. Note that
* on entry start points to the LIR prior to the beginning of the
* sequence.
*/
void Mir2Lir::MarkDef(RegLocation rl, LIR *start, LIR *finish) {
DCHECK(!rl.wide);
DCHECK(start && start->next);
DCHECK(finish);
RegisterInfo* p = GetRegInfo(rl.reg);
p->SetDefStart(start->next);
p->SetDefEnd(finish);
}
/*
* Mark the beginning and end LIR of a def sequence. Note that
* on entry start points to the LIR prior to the beginning of the
* sequence.
*/
void Mir2Lir::MarkDefWide(RegLocation rl, LIR *start, LIR *finish) {
DCHECK(rl.wide);
DCHECK(start && start->next);
DCHECK(finish);
RegisterInfo* p;
if (rl.reg.IsPair()) {
p = GetRegInfo(rl.reg.GetLow());
ResetDef(rl.reg.GetHigh()); // Only track low of pair
} else {
p = GetRegInfo(rl.reg);
}
p->SetDefStart(start->next);
p->SetDefEnd(finish);
}
RegLocation Mir2Lir::WideToNarrow(RegLocation rl) {
DCHECK(rl.wide);
if (rl.location == kLocPhysReg) {
if (rl.reg.IsPair()) {
RegisterInfo* info_lo = GetRegInfo(rl.reg.GetLow());
RegisterInfo* info_hi = GetRegInfo(rl.reg.GetHigh());
if (info_lo->IsTemp()) {
info_lo->SetIsWide(false);
info_lo->ResetDefBody();
}
if (info_hi->IsTemp()) {
info_hi->SetIsWide(false);
info_hi->ResetDefBody();
}
rl.reg = rl.reg.GetLow();
} else {
/*
* TODO: If not a pair, we can't just drop the high register. On some targets, we may be
* able to re-cast the 64-bit register as 32 bits, so it might be worthwhile to revisit
* this code. Will probably want to make this a virtual function.
*/
// Can't narrow 64-bit register. Clobber.
if (GetRegInfo(rl.reg)->IsTemp()) {
Clobber(rl.reg);
FreeTemp(rl.reg);
}
rl.location = kLocDalvikFrame;
}
}
rl.wide = false;
return rl;
}
void Mir2Lir::ResetDefLoc(RegLocation rl) {
DCHECK(!rl.wide);
if (IsTemp(rl.reg) && !(cu_->disable_opt & (1 << kSuppressLoads))) {
NullifyRange(rl.reg, rl.s_reg_low);
}
ResetDef(rl.reg);
}
void Mir2Lir::ResetDefLocWide(RegLocation rl) {
DCHECK(rl.wide);
// If pair, only track low reg of pair.
RegStorage rs = rl.reg.IsPair() ? rl.reg.GetLow() : rl.reg;
if (IsTemp(rs) && !(cu_->disable_opt & (1 << kSuppressLoads))) {
NullifyRange(rs, rl.s_reg_low);
}
ResetDef(rs);
}
void Mir2Lir::ResetDefTracking() {
GrowableArray<RegisterInfo*>::Iterator core_it(&reg_pool_->core_regs_);
for (RegisterInfo* info = core_it.Next(); info != nullptr; info = core_it.Next()) {
info->ResetDefBody();
}
GrowableArray<RegisterInfo*>::Iterator sp_it(&reg_pool_->core_regs_);
for (RegisterInfo* info = sp_it.Next(); info != nullptr; info = sp_it.Next()) {
info->ResetDefBody();
}
GrowableArray<RegisterInfo*>::Iterator dp_it(&reg_pool_->core_regs_);
for (RegisterInfo* info = dp_it.Next(); info != nullptr; info = dp_it.Next()) {
info->ResetDefBody();
}
}
void Mir2Lir::ClobberAllTemps() {
GrowableArray<RegisterInfo*>::Iterator iter(&tempreg_info_);
for (RegisterInfo* info = iter.Next(); info != NULL; info = iter.Next()) {
ClobberBody(info);
}
}
void Mir2Lir::FlushRegWide(RegStorage reg) {
if (reg.IsPair()) {
RegisterInfo* info1 = GetRegInfo(reg.GetLow());
RegisterInfo* info2 = GetRegInfo(reg.GetHigh());
DCHECK(info1 && info2 && info1->IsWide() && info2->IsWide() &&
(info1->Partner() == info2->GetReg()) && (info2->Partner() == info1->GetReg()));
if ((info1->IsLive() && info1->IsDirty()) || (info2->IsLive() && info2->IsDirty())) {
if (!(info1->IsTemp() && info2->IsTemp())) {
/* Should not happen. If it does, there's a problem in eval_loc */
LOG(FATAL) << "Long half-temp, half-promoted";
}
info1->SetIsDirty(false);
info2->SetIsDirty(false);
if (mir_graph_->SRegToVReg(info2->SReg()) < mir_graph_->SRegToVReg(info1->SReg())) {
info1 = info2;
}
int v_reg = mir_graph_->SRegToVReg(info1->SReg());
StoreBaseDisp(TargetReg(kSp), VRegOffset(v_reg), reg, k64);
}
} else {
RegisterInfo* info = GetRegInfo(reg);
if (info->IsLive() && info->IsDirty()) {
info->SetIsDirty(false);
int v_reg = mir_graph_->SRegToVReg(info->SReg());
StoreBaseDisp(TargetReg(kSp), VRegOffset(v_reg), reg, k64);
}
}
}
void Mir2Lir::FlushReg(RegStorage reg) {
DCHECK(!reg.IsPair());
RegisterInfo* info = GetRegInfo(reg);
if (info->IsLive() && info->IsDirty()) {
info->SetIsDirty(false);
int v_reg = mir_graph_->SRegToVReg(info->SReg());
StoreBaseDisp(TargetReg(kSp), VRegOffset(v_reg), reg, kWord);
}
}
void Mir2Lir::FlushSpecificReg(RegisterInfo* info) {
if (info->IsWide()) {
FlushRegWide(info->GetReg());
} else {
FlushReg(info->GetReg());
}
}
void Mir2Lir::FlushAllRegs() {
GrowableArray<RegisterInfo*>::Iterator it(&tempreg_info_);
for (RegisterInfo* info = it.Next(); info != nullptr; info = it.Next()) {
if (info->IsDirty() && info->IsLive()) {
FlushSpecificReg(info);
}
info->MarkDead();
info->SetSReg(INVALID_SREG);
info->ResetDefBody();
info->SetIsWide(false);
}
}
bool Mir2Lir::RegClassMatches(int reg_class, RegStorage reg) {
if (reg_class == kAnyReg) {
return true;
} else if (reg_class == kCoreReg) {
return !reg.IsFloat();
} else {
return reg.IsFloat();
}
}
void Mir2Lir::MarkLiveReg(RegStorage reg, int s_reg) {
RegisterInfo* info = GetRegInfo(reg);
if ((info->SReg() == s_reg) && info->IsLive()) {
return; // Already live.
}
if (s_reg != INVALID_SREG) {
ClobberSReg(s_reg);
if (info->IsTemp()) {
info->MarkLive();
}
} else {
// Can't be live if no associated s_reg.
DCHECK(info->IsTemp());
info->MarkDead();
}
info->SetSReg(s_reg);
}
void Mir2Lir::MarkLive(RegLocation loc) {
RegStorage reg = loc.reg;
int s_reg = loc.s_reg_low;
if (reg.IsPair()) {
MarkLiveReg(reg.GetLow(), s_reg);
MarkLiveReg(reg.GetHigh(), s_reg+1);
} else {
if (loc.wide) {
ClobberSReg(s_reg + 1);
}
MarkLiveReg(reg, s_reg);
}
}
void Mir2Lir::MarkTemp(RegStorage reg) {
DCHECK(!reg.IsPair());
RegisterInfo* info = GetRegInfo(reg);
tempreg_info_.Insert(info);
info->SetIsTemp(true);
}
void Mir2Lir::UnmarkTemp(RegStorage reg) {
DCHECK(!reg.IsPair());
RegisterInfo* info = GetRegInfo(reg);
tempreg_info_.Delete(info);
info->SetIsTemp(false);
}
void Mir2Lir::MarkWide(RegStorage reg) {
if (reg.IsPair()) {
RegisterInfo* info_lo = GetRegInfo(reg.GetLow());
RegisterInfo* info_hi = GetRegInfo(reg.GetHigh());
info_lo->SetIsWide(true);
info_hi->SetIsWide(true);
info_lo->SetPartner(reg.GetHigh());
info_hi->SetPartner(reg.GetLow());
} else {
RegisterInfo* info = GetRegInfo(reg);
info->SetIsWide(true);
info->SetPartner(reg);
}
}
void Mir2Lir::MarkClean(RegLocation loc) {
if (loc.reg.IsPair()) {
RegisterInfo* info = GetRegInfo(loc.reg.GetLow());
info->SetIsDirty(false);
info = GetRegInfo(loc.reg.GetHigh());
info->SetIsDirty(false);
} else {
RegisterInfo* info = GetRegInfo(loc.reg);
info->SetIsDirty(false);
}
}
// FIXME: need to verify rules/assumptions about how wide values are treated in 64BitSolos.
void Mir2Lir::MarkDirty(RegLocation loc) {
if (loc.home) {
// If already home, can't be dirty
return;
}
if (loc.reg.IsPair()) {
RegisterInfo* info = GetRegInfo(loc.reg.GetLow());
info->SetIsDirty(true);
info = GetRegInfo(loc.reg.GetHigh());
info->SetIsDirty(true);
} else {
RegisterInfo* info = GetRegInfo(loc.reg);
info->SetIsDirty(true);
}
}
void Mir2Lir::MarkInUse(RegStorage reg) {
if (reg.IsPair()) {
GetRegInfo(reg.GetLow())->MarkInUse();
GetRegInfo(reg.GetHigh())->MarkInUse();
} else {
GetRegInfo(reg)->MarkInUse();
}
}
bool Mir2Lir::CheckCorePoolSanity() {
GrowableArray<RegisterInfo*>::Iterator it(&reg_pool_->core_regs_);
for (RegisterInfo* info = it.Next(); info != nullptr; info = it.Next()) {
RegStorage my_reg = info->GetReg();
if (info->IsWide() && my_reg.IsPair()) {
int my_sreg = info->SReg();
RegStorage partner_reg = info->Partner();
RegisterInfo* partner = GetRegInfo(partner_reg);
DCHECK(partner != NULL);
DCHECK(partner->IsWide());
DCHECK_EQ(my_reg.GetReg(), partner->Partner().GetReg());
int partner_sreg = partner->SReg();
if (my_sreg == INVALID_SREG) {
DCHECK_EQ(partner_sreg, INVALID_SREG);
} else {
int diff = my_sreg - partner_sreg;
DCHECK((diff == 0) || (diff == -1) || (diff == 1));
}
} else {
// TODO: add whatever sanity checks might be useful for 64BitSolo regs here.
// TODO: sanity checks for floating point pools?
}
if (!info->IsLive()) {
DCHECK(info->DefStart() == NULL);
DCHECK(info->DefEnd() == NULL);
}
}
return true;
}
/*
* Return an updated location record with current in-register status.
* If the value lives in live temps, reflect that fact. No code
* is generated. If the live value is part of an older pair,
* clobber both low and high.
* TUNING: clobbering both is a bit heavy-handed, but the alternative
* is a bit complex when dealing with FP regs. Examine code to see
* if it's worthwhile trying to be more clever here.
*/
RegLocation Mir2Lir::UpdateLoc(RegLocation loc) {
DCHECK(!loc.wide);
DCHECK(CheckCorePoolSanity());
if (loc.location != kLocPhysReg) {
DCHECK((loc.location == kLocDalvikFrame) ||
(loc.location == kLocCompilerTemp));
RegStorage reg = AllocLiveReg(loc.s_reg_low, kAnyReg, false);
if (reg.Valid()) {
bool match = true;
RegisterInfo* info = GetRegInfo(reg);
match &= !reg.IsPair();
match &= !info->IsWide();
if (match) {
loc.location = kLocPhysReg;
loc.reg = reg;
} else {
Clobber(reg);
FreeTemp(reg);
}
}
}
return loc;
}
RegLocation Mir2Lir::UpdateLocWide(RegLocation loc) {
DCHECK(loc.wide);
DCHECK(CheckCorePoolSanity());
if (loc.location != kLocPhysReg) {
DCHECK((loc.location == kLocDalvikFrame) ||
(loc.location == kLocCompilerTemp));
RegStorage reg = AllocLiveReg(loc.s_reg_low, kAnyReg, true);
if (reg.Valid()) {
bool match = true;
if (reg.IsPair()) {
// If we've got a register pair, make sure that it was last used as the same pair.
RegisterInfo* info_lo = GetRegInfo(reg.GetLow());
RegisterInfo* info_hi = GetRegInfo(reg.GetHigh());
match &= info_lo->IsWide();
match &= info_hi->IsWide();
match &= (info_lo->Partner() == info_hi->GetReg());
match &= (info_hi->Partner() == info_lo->GetReg());
} else {
RegisterInfo* info = GetRegInfo(reg);
match &= info->IsWide();
match &= (info->GetReg() == info->Partner());
}
if (match) {
loc.location = kLocPhysReg;
loc.reg = reg;
} else {
Clobber(reg);
FreeTemp(reg);
}
}
}
return loc;
}
/* For use in cases we don't know (or care) width */
RegLocation Mir2Lir::UpdateRawLoc(RegLocation loc) {
if (loc.wide)
return UpdateLocWide(loc);
else
return UpdateLoc(loc);
}
RegLocation Mir2Lir::EvalLocWide(RegLocation loc, int reg_class, bool update) {
DCHECK(loc.wide);
loc = UpdateLocWide(loc);
/* If already in registers, we can assume proper form. Right reg class? */
if (loc.location == kLocPhysReg) {
if (!RegClassMatches(reg_class, loc.reg)) {
// Wrong register class. Reallocate and transfer ownership.
RegStorage new_regs = AllocTypedTempWide(loc.fp, reg_class);
// Associate the old sreg with the new register and clobber the old register.
GetRegInfo(new_regs)->SetSReg(GetRegInfo(loc.reg)->SReg());
Clobber(loc.reg);
loc.reg = new_regs;
MarkWide(loc.reg);
}
return loc;
}
DCHECK_NE(loc.s_reg_low, INVALID_SREG);
DCHECK_NE(GetSRegHi(loc.s_reg_low), INVALID_SREG);
loc.reg = AllocTypedTempWide(loc.fp, reg_class);
MarkWide(loc.reg);
if (update) {
loc.location = kLocPhysReg;
MarkLive(loc);
}
return loc;
}
RegLocation Mir2Lir::EvalLoc(RegLocation loc, int reg_class, bool update) {
if (loc.wide) {
return EvalLocWide(loc, reg_class, update);
}
loc = UpdateLoc(loc);
if (loc.location == kLocPhysReg) {
if (!RegClassMatches(reg_class, loc.reg)) {
// Wrong register class. Reallocate and transfer ownership.
RegStorage new_reg = AllocTypedTemp(loc.fp, reg_class);
// Associate the old sreg with the new register and clobber the old register.
GetRegInfo(new_reg)->SetSReg(GetRegInfo(loc.reg)->SReg());
Clobber(loc.reg);
loc.reg = new_reg;
}
return loc;
}
DCHECK_NE(loc.s_reg_low, INVALID_SREG);
loc.reg = AllocTypedTemp(loc.fp, reg_class);
if (update) {
loc.location = kLocPhysReg;
MarkLive(loc);
}
return loc;
}
/* USE SSA names to count references of base Dalvik v_regs. */
void Mir2Lir::CountRefs(RefCounts* core_counts, RefCounts* fp_counts, size_t num_regs) {
for (int i = 0; i < mir_graph_->GetNumSSARegs(); i++) {
RegLocation loc = mir_graph_->reg_location_[i];
RefCounts* counts = loc.fp ? fp_counts : core_counts;
int p_map_idx = SRegToPMap(loc.s_reg_low);
if (loc.fp) {
if (loc.wide) {
// Treat doubles as a unit, using upper half of fp_counts array.
counts[p_map_idx + num_regs].count += mir_graph_->GetUseCount(i);
i++;
} else {
counts[p_map_idx].count += mir_graph_->GetUseCount(i);
}
} else if (!IsInexpensiveConstant(loc)) {
counts[p_map_idx].count += mir_graph_->GetUseCount(i);
}
}
}
/* qsort callback function, sort descending */
static int SortCounts(const void *val1, const void *val2) {
const Mir2Lir::RefCounts* op1 = reinterpret_cast<const Mir2Lir::RefCounts*>(val1);
const Mir2Lir::RefCounts* op2 = reinterpret_cast<const Mir2Lir::RefCounts*>(val2);
// Note that we fall back to sorting on reg so we get stable output
// on differing qsort implementations (such as on host and target or
// between local host and build servers).
return (op1->count == op2->count)
? (op1->s_reg - op2->s_reg)
: (op1->count < op2->count ? 1 : -1);
}
void Mir2Lir::DumpCounts(const RefCounts* arr, int size, const char* msg) {
LOG(INFO) << msg;
for (int i = 0; i < size; i++) {
if ((arr[i].s_reg & STARTING_DOUBLE_SREG) != 0) {
LOG(INFO) << "s_reg[D" << (arr[i].s_reg & ~STARTING_DOUBLE_SREG) << "]: " << arr[i].count;
} else {
LOG(INFO) << "s_reg[" << arr[i].s_reg << "]: " << arr[i].count;
}
}
}
/*
* Note: some portions of this code required even if the kPromoteRegs
* optimization is disabled.
*/
void Mir2Lir::DoPromotion() {
int dalvik_regs = cu_->num_dalvik_registers;
int num_regs = dalvik_regs + mir_graph_->GetNumUsedCompilerTemps();
const int promotion_threshold = 1;
// Allocate the promotion map - one entry for each Dalvik vReg or compiler temp
promotion_map_ = static_cast<PromotionMap*>
(arena_->Alloc(num_regs * sizeof(promotion_map_[0]), kArenaAllocRegAlloc));
// Allow target code to add any special registers
AdjustSpillMask();
/*
* Simple register promotion. Just do a static count of the uses
* of Dalvik registers. Note that we examine the SSA names, but
* count based on original Dalvik register name. Count refs
* separately based on type in order to give allocation
* preference to fp doubles - which must be allocated sequential
* physical single fp registers starting with an even-numbered
* reg.
* TUNING: replace with linear scan once we have the ability
* to describe register live ranges for GC.
*/
RefCounts *core_regs =
static_cast<RefCounts*>(arena_->Alloc(sizeof(RefCounts) * num_regs,
kArenaAllocRegAlloc));
RefCounts *FpRegs =
static_cast<RefCounts *>(arena_->Alloc(sizeof(RefCounts) * num_regs * 2,
kArenaAllocRegAlloc));
// Set ssa names for original Dalvik registers
for (int i = 0; i < dalvik_regs; i++) {
core_regs[i].s_reg = FpRegs[i].s_reg = i;
}
// Set ssa names for compiler temporaries
for (unsigned int ct_idx = 0; ct_idx < mir_graph_->GetNumUsedCompilerTemps(); ct_idx++) {
CompilerTemp* ct = mir_graph_->GetCompilerTemp(ct_idx);
core_regs[dalvik_regs + ct_idx].s_reg = ct->s_reg_low;
FpRegs[dalvik_regs + ct_idx].s_reg = ct->s_reg_low;
FpRegs[num_regs + dalvik_regs + ct_idx].s_reg = ct->s_reg_low;
}
// Duplicate in upper half to represent possible fp double starting sregs.
for (int i = 0; i < num_regs; i++) {
FpRegs[num_regs + i].s_reg = FpRegs[i].s_reg | STARTING_DOUBLE_SREG;
}
// Sum use counts of SSA regs by original Dalvik vreg.
CountRefs(core_regs, FpRegs, num_regs);
// Sort the count arrays
qsort(core_regs, num_regs, sizeof(RefCounts), SortCounts);
qsort(FpRegs, num_regs * 2, sizeof(RefCounts), SortCounts);
if (cu_->verbose) {
DumpCounts(core_regs, num_regs, "Core regs after sort");
DumpCounts(FpRegs, num_regs * 2, "Fp regs after sort");
}
if (!(cu_->disable_opt & (1 << kPromoteRegs))) {
// Promote FpRegs
for (int i = 0; (i < (num_regs * 2)) && (FpRegs[i].count >= promotion_threshold); i++) {
int p_map_idx = SRegToPMap(FpRegs[i].s_reg & ~STARTING_DOUBLE_SREG);
if ((FpRegs[i].s_reg & STARTING_DOUBLE_SREG) != 0) {
if ((promotion_map_[p_map_idx].fp_location != kLocPhysReg) &&
(promotion_map_[p_map_idx + 1].fp_location != kLocPhysReg)) {
int low_sreg = FpRegs[i].s_reg & ~STARTING_DOUBLE_SREG;
// Ignore result - if can't alloc double may still be able to alloc singles.
AllocPreservedDouble(low_sreg);
}
} else if (promotion_map_[p_map_idx].fp_location != kLocPhysReg) {
RegStorage reg = AllocPreservedSingle(FpRegs[i].s_reg);
if (!reg.Valid()) {
break; // No more left.
}
}
}
// Promote core regs
for (int i = 0; (i < num_regs) &&
(core_regs[i].count >= promotion_threshold); i++) {
int p_map_idx = SRegToPMap(core_regs[i].s_reg);
if (promotion_map_[p_map_idx].core_location !=
kLocPhysReg) {
RegStorage reg = AllocPreservedCoreReg(core_regs[i].s_reg);
if (!reg.Valid()) {
break; // No more left
}
}
}
}
// Now, update SSA names to new home locations
for (int i = 0; i < mir_graph_->GetNumSSARegs(); i++) {
RegLocation *curr = &mir_graph_->reg_location_[i];
int p_map_idx = SRegToPMap(curr->s_reg_low);
if (!curr->wide) {
if (curr->fp) {
if (promotion_map_[p_map_idx].fp_location == kLocPhysReg) {
curr->location = kLocPhysReg;
curr->reg = RegStorage::Solo32(promotion_map_[p_map_idx].FpReg);
curr->home = true;
}
} else {
if (promotion_map_[p_map_idx].core_location == kLocPhysReg) {
curr->location = kLocPhysReg;
curr->reg = RegStorage::Solo32(promotion_map_[p_map_idx].core_reg);
curr->home = true;
}
}
} else {
if (curr->high_word) {
continue;
}
if (curr->fp) {
if ((promotion_map_[p_map_idx].fp_location == kLocPhysReg) &&
(promotion_map_[p_map_idx+1].fp_location == kLocPhysReg)) {
int low_reg = promotion_map_[p_map_idx].FpReg;
int high_reg = promotion_map_[p_map_idx+1].FpReg;
// Doubles require pair of singles starting at even reg
// TODO: move target-specific restrictions out of here.
if (((low_reg & 0x1) == 0) && ((low_reg + 1) == high_reg)) {
curr->location = kLocPhysReg;
if (cu_->instruction_set == kThumb2) {
curr->reg = RegStorage::FloatSolo64(RegStorage::RegNum(low_reg) >> 1);
} else {
curr->reg = RegStorage(RegStorage::k64BitPair, low_reg, high_reg);
}
curr->home = true;
}
}
} else {
if ((promotion_map_[p_map_idx].core_location == kLocPhysReg)
&& (promotion_map_[p_map_idx+1].core_location ==
kLocPhysReg)) {
curr->location = kLocPhysReg;
curr->reg = RegStorage(RegStorage::k64BitPair, promotion_map_[p_map_idx].core_reg,
promotion_map_[p_map_idx+1].core_reg);
curr->home = true;
}
}
}
}
if (cu_->verbose) {
DumpPromotionMap();
}
}
/* Returns sp-relative offset in bytes for a VReg */
int Mir2Lir::VRegOffset(int v_reg) {
return StackVisitor::GetVRegOffset(cu_->code_item, core_spill_mask_,
fp_spill_mask_, frame_size_, v_reg,
cu_->instruction_set);
}
/* Returns sp-relative offset in bytes for a SReg */
int Mir2Lir::SRegOffset(int s_reg) {
return VRegOffset(mir_graph_->SRegToVReg(s_reg));
}
/* Mark register usage state and return long retloc */
RegLocation Mir2Lir::GetReturnWide(bool is_double) {
RegLocation gpr_res = LocCReturnWide();
RegLocation fpr_res = LocCReturnDouble();
RegLocation res = is_double ? fpr_res : gpr_res;
if (res.reg.IsPair()) {
Clobber(res.reg);
LockTemp(res.reg);
// Does this wide value live in two registers or one vector register?
if (res.reg.GetLowReg() != res.reg.GetHighReg()) {
// FIXME: I think we want to mark these as wide as well.
MarkWide(res.reg);
}
} else {
Clobber(res.reg);
LockTemp(res.reg);
MarkWide(res.reg);
}
return res;
}
RegLocation Mir2Lir::GetReturn(bool is_float) {
RegLocation gpr_res = LocCReturn();
RegLocation fpr_res = LocCReturnFloat();
RegLocation res = is_float ? fpr_res : gpr_res;
Clobber(res.reg);
if (cu_->instruction_set == kMips) {
MarkInUse(res.reg);
} else {
LockTemp(res.reg);
}
return res;
}
void Mir2Lir::SimpleRegAlloc() {
DoPromotion();
if (cu_->verbose && !(cu_->disable_opt & (1 << kPromoteRegs))) {
LOG(INFO) << "After Promotion";
mir_graph_->DumpRegLocTable(mir_graph_->reg_location_, mir_graph_->GetNumSSARegs());
}
/* Set the frame size */
frame_size_ = ComputeFrameSize();
}
/*
* Get the "real" sreg number associated with an s_reg slot. In general,
* s_reg values passed through codegen are the SSA names created by
* dataflow analysis and refer to slot numbers in the mir_graph_->reg_location
* array. However, renaming is accomplished by simply replacing RegLocation
* entries in the reglocation[] array. Therefore, when location
* records for operands are first created, we need to ask the locRecord
* identified by the dataflow pass what it's new name is.
*/
int Mir2Lir::GetSRegHi(int lowSreg) {
return (lowSreg == INVALID_SREG) ? INVALID_SREG : lowSreg + 1;
}
bool Mir2Lir::LiveOut(int s_reg) {
// For now.
return true;
}
} // namespace art