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|
/*
* 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.
*/
#include "compiler_internals.h"
#include "dataflow_iterator-inl.h"
#define NOTVISITED (-1)
namespace art {
void MIRGraph::ClearAllVisitedFlags() {
AllNodesIterator iter(this, false /* not iterative */);
for (BasicBlock* bb = iter.Next(); bb != NULL; bb = iter.Next()) {
bb->visited = false;
}
}
BasicBlock* MIRGraph::NeedsVisit(BasicBlock* bb) {
if (bb != NULL) {
if (bb->visited || bb->hidden) {
bb = NULL;
}
}
return bb;
}
BasicBlock* MIRGraph::NextUnvisitedSuccessor(BasicBlock* bb)
{
BasicBlock* res = NeedsVisit(bb->fall_through);
if (res == NULL) {
res = NeedsVisit(bb->taken);
if (res == NULL) {
if (bb->successor_block_list.block_list_type != kNotUsed) {
GrowableArray<SuccessorBlockInfo*>::Iterator iterator(bb->successor_block_list.blocks);
while (true) {
SuccessorBlockInfo *sbi = iterator.Next();
if (sbi == NULL) break;
res = NeedsVisit(sbi->block);
if (res != NULL) break;
}
}
}
}
return res;
}
void MIRGraph::MarkPreOrder(BasicBlock* block)
{
block->visited = true;
/* Enqueue the pre_order block id */
dfs_order_->Insert(block->id);
}
void MIRGraph::RecordDFSOrders(BasicBlock* block)
{
std::vector<BasicBlock*> succ;
MarkPreOrder(block);
succ.push_back(block);
while (!succ.empty()) {
BasicBlock* curr = succ.back();
BasicBlock* next_successor = NextUnvisitedSuccessor(curr);
if (next_successor != NULL) {
MarkPreOrder(next_successor);
succ.push_back(next_successor);
continue;
}
curr->dfs_id = dfs_post_order_->Size();
dfs_post_order_->Insert(curr->id);
succ.pop_back();
}
}
/* Sort the blocks by the Depth-First-Search */
void MIRGraph::ComputeDFSOrders()
{
/* Initialize or reset the DFS pre_order list */
if (dfs_order_ == NULL) {
dfs_order_ = new (arena_) GrowableArray<int>(arena_, GetNumBlocks(), kGrowableArrayDfsOrder);
} else {
/* Just reset the used length on the counter */
dfs_order_->Reset();
}
/* Initialize or reset the DFS post_order list */
if (dfs_post_order_ == NULL) {
dfs_post_order_ = new (arena_) GrowableArray<int>(arena_, GetNumBlocks(), kGrowableArrayDfsPostOrder);
} else {
/* Just reset the used length on the counter */
dfs_post_order_->Reset();
}
// Reset visited flags from all nodes
ClearAllVisitedFlags();
// Record dfs orders
RecordDFSOrders(GetEntryBlock());
num_reachable_blocks_ = dfs_order_->Size();
}
/*
* Mark block bit on the per-Dalvik register vector to denote that Dalvik
* register idx is defined in BasicBlock bb.
*/
bool MIRGraph::FillDefBlockMatrix(BasicBlock* bb)
{
if (bb->data_flow_info == NULL) return false;
ArenaBitVector::Iterator iterator(bb->data_flow_info->def_v);
while (true) {
int idx = iterator.Next();
if (idx == -1) break;
/* Block bb defines register idx */
def_block_matrix_[idx]->SetBit(bb->id);
}
return true;
}
void MIRGraph::ComputeDefBlockMatrix()
{
int num_registers = cu_->num_dalvik_registers;
/* Allocate num_dalvik_registers bit vector pointers */
def_block_matrix_ = static_cast<ArenaBitVector**>
(arena_->NewMem(sizeof(ArenaBitVector *) * num_registers, true,
ArenaAllocator::kAllocDFInfo));
int i;
/* Initialize num_register vectors with num_blocks bits each */
for (i = 0; i < num_registers; i++) {
def_block_matrix_[i] =
new (arena_) ArenaBitVector(arena_, GetNumBlocks(), false, kBitMapBMatrix);
}
AllNodesIterator iter(this, false /* not iterative */);
for (BasicBlock* bb = iter.Next(); bb != NULL; bb = iter.Next()) {
FindLocalLiveIn(bb);
}
AllNodesIterator iter2(this, false /* not iterative */);
for (BasicBlock* bb = iter2.Next(); bb != NULL; bb = iter2.Next()) {
FillDefBlockMatrix(bb);
}
/*
* Also set the incoming parameters as defs in the entry block.
* Only need to handle the parameters for the outer method.
*/
int num_regs = cu_->num_dalvik_registers;
int in_reg = num_regs - cu_->num_ins;
for (; in_reg < num_regs; in_reg++) {
def_block_matrix_[in_reg]->SetBit(GetEntryBlock()->id);
}
}
void MIRGraph::ComputeDomPostOrderTraversal(BasicBlock* bb) {
if (dom_post_order_traversal_ == NULL) {
// First time - create the array.
dom_post_order_traversal_ =
new (arena_) GrowableArray<int>(arena_, num_reachable_blocks_,
kGrowableArrayDomPostOrderTraversal);
} else {
dom_post_order_traversal_->Reset();
}
ClearAllVisitedFlags();
std::vector<std::pair<BasicBlock*, ArenaBitVector::Iterator*> > work_stack;
bb->visited = true;
work_stack.push_back(std::make_pair(bb, new (arena_) ArenaBitVector::Iterator(bb->i_dominated)));
while (!work_stack.empty()) {
std::pair<BasicBlock*, ArenaBitVector::Iterator*> curr = work_stack.back();
BasicBlock* curr_bb = curr.first;
ArenaBitVector::Iterator* curr_idom_iter = curr.second;
int bb_idx = curr_idom_iter->Next();
while ((bb_idx != -1) && (NeedsVisit(GetBasicBlock(bb_idx)) == NULL)) {
bb_idx = curr_idom_iter->Next();
}
if (bb_idx != -1) {
BasicBlock* new_bb = GetBasicBlock(bb_idx);
new_bb->visited = true;
work_stack.push_back(
std::make_pair(new_bb, new (arena_) ArenaBitVector::Iterator(new_bb->i_dominated)));
} else {
// no successor/next
dom_post_order_traversal_->Insert(curr_bb->id);
work_stack.pop_back();
/* hacky loop detection */
if (curr_bb->taken && curr_bb->dominators->IsBitSet(curr_bb->taken->id)) {
attributes_ |= METHOD_HAS_LOOP;
}
}
}
}
void MIRGraph::CheckForDominanceFrontier(BasicBlock* dom_bb,
const BasicBlock* succ_bb)
{
/*
* TODO - evaluate whether phi will ever need to be inserted into exit
* blocks.
*/
if (succ_bb->i_dom != dom_bb &&
succ_bb->block_type == kDalvikByteCode &&
succ_bb->hidden == false) {
dom_bb->dom_frontier->SetBit(succ_bb->id);
}
}
/* Worker function to compute the dominance frontier */
bool MIRGraph::ComputeDominanceFrontier(BasicBlock* bb)
{
/* Calculate DF_local */
if (bb->taken) {
CheckForDominanceFrontier(bb, bb->taken);
}
if (bb->fall_through) {
CheckForDominanceFrontier(bb, bb->fall_through);
}
if (bb->successor_block_list.block_list_type != kNotUsed) {
GrowableArray<SuccessorBlockInfo*>::Iterator iterator(bb->successor_block_list.blocks);
while (true) {
SuccessorBlockInfo *successor_block_info = iterator.Next();
if (successor_block_info == NULL) break;
BasicBlock* succ_bb = successor_block_info->block;
CheckForDominanceFrontier(bb, succ_bb);
}
}
/* Calculate DF_up */
ArenaBitVector::Iterator bv_iterator(bb->i_dominated);
while (true) {
//TUNING: hot call to BitVectorIteratorNext
int dominated_idx = bv_iterator.Next();
if (dominated_idx == -1) break;
BasicBlock* dominated_bb = GetBasicBlock(dominated_idx);
ArenaBitVector::Iterator df_iterator(dominated_bb->dom_frontier);
while (true) {
//TUNING: hot call to BitVectorIteratorNext
int df_up_idx = df_iterator.Next();
if (df_up_idx == -1) break;
BasicBlock* df_up_block = GetBasicBlock(df_up_idx);
CheckForDominanceFrontier(bb, df_up_block);
}
}
return true;
}
/* Worker function for initializing domination-related data structures */
void MIRGraph::InitializeDominationInfo(BasicBlock* bb)
{
int num_total_blocks = GetBasicBlockListCount();
if (bb->dominators == NULL ) {
bb->dominators = new (arena_) ArenaBitVector(arena_, num_total_blocks,
false /* expandable */, kBitMapDominators);
bb->i_dominated = new (arena_) ArenaBitVector(arena_, num_total_blocks,
false /* expandable */, kBitMapIDominated);
bb->dom_frontier = new (arena_) ArenaBitVector(arena_, num_total_blocks,
false /* expandable */, kBitMapDomFrontier);
} else {
bb->dominators->ClearAllBits();
bb->i_dominated->ClearAllBits();
bb->dom_frontier->ClearAllBits();
}
/* Set all bits in the dominator vector */
bb->dominators->SetInitialBits(num_total_blocks);
return;
}
/*
* Walk through the ordered i_dom list until we reach common parent.
* Given the ordering of i_dom_list, this common parent represents the
* last element of the intersection of block1 and block2 dominators.
*/
int MIRGraph::FindCommonParent(int block1, int block2)
{
while (block1 != block2) {
while (block1 < block2) {
block1 = i_dom_list_[block1];
DCHECK_NE(block1, NOTVISITED);
}
while (block2 < block1) {
block2 = i_dom_list_[block2];
DCHECK_NE(block2, NOTVISITED);
}
}
return block1;
}
/* Worker function to compute each block's immediate dominator */
bool MIRGraph::ComputeblockIDom(BasicBlock* bb)
{
/* Special-case entry block */
if (bb == GetEntryBlock()) {
return false;
}
/* Iterate through the predecessors */
GrowableArray<BasicBlock*>::Iterator iter(bb->predecessors);
/* Find the first processed predecessor */
int idom = -1;
while (true) {
BasicBlock* pred_bb = iter.Next();
CHECK(pred_bb != NULL);
if (i_dom_list_[pred_bb->dfs_id] != NOTVISITED) {
idom = pred_bb->dfs_id;
break;
}
}
/* Scan the rest of the predecessors */
while (true) {
BasicBlock* pred_bb = iter.Next();
if (!pred_bb) break;
if (i_dom_list_[pred_bb->dfs_id] == NOTVISITED) {
continue;
} else {
idom = FindCommonParent(pred_bb->dfs_id, idom);
}
}
DCHECK_NE(idom, NOTVISITED);
/* Did something change? */
if (i_dom_list_[bb->dfs_id] != idom) {
i_dom_list_[bb->dfs_id] = idom;
return true;
}
return false;
}
/* Worker function to compute each block's domintors */
bool MIRGraph::ComputeBlockDominators(BasicBlock* bb)
{
if (bb == GetEntryBlock()) {
bb->dominators->ClearAllBits();
} else {
bb->dominators->Copy(bb->i_dom->dominators);
}
bb->dominators->SetBit(bb->id);
return false;
}
bool MIRGraph::SetDominators(BasicBlock* bb)
{
if (bb != GetEntryBlock()) {
int idom_dfs_idx = i_dom_list_[bb->dfs_id];
DCHECK_NE(idom_dfs_idx, NOTVISITED);
int i_dom_idx = dfs_post_order_->Get(idom_dfs_idx);
BasicBlock* i_dom = GetBasicBlock(i_dom_idx);
bb->i_dom = i_dom;
/* Add bb to the i_dominated set of the immediate dominator block */
i_dom->i_dominated->SetBit(bb->id);
}
return false;
}
/* Compute dominators, immediate dominator, and dominance fronter */
void MIRGraph::ComputeDominators()
{
int num_reachable_blocks = num_reachable_blocks_;
int num_total_blocks = GetBasicBlockListCount();
/* Initialize domination-related data structures */
ReachableNodesIterator iter(this, false /* not iterative */);
for (BasicBlock* bb = iter.Next(); bb != NULL; bb = iter.Next()) {
InitializeDominationInfo(bb);
}
/* Initalize & Clear i_dom_list */
if (i_dom_list_ == NULL) {
i_dom_list_ = static_cast<int*>(arena_->NewMem(sizeof(int) * num_reachable_blocks, false,
ArenaAllocator::kAllocDFInfo));
}
for (int i = 0; i < num_reachable_blocks; i++) {
i_dom_list_[i] = NOTVISITED;
}
/* For post-order, last block is entry block. Set its i_dom to istelf */
DCHECK_EQ(GetEntryBlock()->dfs_id, num_reachable_blocks-1);
i_dom_list_[GetEntryBlock()->dfs_id] = GetEntryBlock()->dfs_id;
/* Compute the immediate dominators */
ReversePostOrderDfsIterator iter2(this, true /* iterative */);
bool change = false;
for (BasicBlock* bb = iter2.Next(false); bb != NULL; bb = iter2.Next(change)) {
change = ComputeblockIDom(bb);
}
/* Set the dominator for the root node */
GetEntryBlock()->dominators->ClearAllBits();
GetEntryBlock()->dominators->SetBit(GetEntryBlock()->id);
if (temp_block_v_ == NULL) {
temp_block_v_ = new (arena_) ArenaBitVector(arena_, num_total_blocks,
false /* expandable */, kBitMapTmpBlockV);
} else {
temp_block_v_->ClearAllBits();
}
GetEntryBlock()->i_dom = NULL;
ReachableNodesIterator iter3(this, false /* not iterative */);
for (BasicBlock* bb = iter3.Next(); bb != NULL; bb = iter3.Next()) {
SetDominators(bb);
}
ReversePostOrderDfsIterator iter4(this, false /* not iterative */);
for (BasicBlock* bb = iter4.Next(); bb != NULL; bb = iter4.Next()) {
ComputeBlockDominators(bb);
}
// Compute the dominance frontier for each block.
ComputeDomPostOrderTraversal(GetEntryBlock());
PostOrderDOMIterator iter5(this, false /* not iterative */);
for (BasicBlock* bb = iter5.Next(); bb != NULL; bb = iter5.Next()) {
ComputeDominanceFrontier(bb);
}
}
/*
* Perform dest U= src1 ^ ~src2
* This is probably not general enough to be placed in BitVector.[ch].
*/
void MIRGraph::ComputeSuccLineIn(ArenaBitVector* dest, const ArenaBitVector* src1,
const ArenaBitVector* src2)
{
if (dest->GetStorageSize() != src1->GetStorageSize() ||
dest->GetStorageSize() != src2->GetStorageSize() ||
dest->IsExpandable() != src1->IsExpandable() ||
dest->IsExpandable() != src2->IsExpandable()) {
LOG(FATAL) << "Incompatible set properties";
}
unsigned int idx;
for (idx = 0; idx < dest->GetStorageSize(); idx++) {
dest->GetRawStorage()[idx] |= src1->GetRawStorageWord(idx) & ~(src2->GetRawStorageWord(idx));
}
}
/*
* Iterate through all successor blocks and propagate up the live-in sets.
* The calculated result is used for phi-node pruning - where we only need to
* insert a phi node if the variable is live-in to the block.
*/
bool MIRGraph::ComputeBlockLiveIns(BasicBlock* bb)
{
ArenaBitVector* temp_dalvik_register_v = temp_dalvik_register_v_;
if (bb->data_flow_info == NULL) return false;
temp_dalvik_register_v->Copy(bb->data_flow_info->live_in_v);
if (bb->taken && bb->taken->data_flow_info)
ComputeSuccLineIn(temp_dalvik_register_v, bb->taken->data_flow_info->live_in_v,
bb->data_flow_info->def_v);
if (bb->fall_through && bb->fall_through->data_flow_info)
ComputeSuccLineIn(temp_dalvik_register_v, bb->fall_through->data_flow_info->live_in_v,
bb->data_flow_info->def_v);
if (bb->successor_block_list.block_list_type != kNotUsed) {
GrowableArray<SuccessorBlockInfo*>::Iterator iterator(bb->successor_block_list.blocks);
while (true) {
SuccessorBlockInfo *successor_block_info = iterator.Next();
if (successor_block_info == NULL) break;
BasicBlock* succ_bb = successor_block_info->block;
if (succ_bb->data_flow_info) {
ComputeSuccLineIn(temp_dalvik_register_v, succ_bb->data_flow_info->live_in_v,
bb->data_flow_info->def_v);
}
}
}
if (!temp_dalvik_register_v->Equal(bb->data_flow_info->live_in_v)) {
bb->data_flow_info->live_in_v->Copy(temp_dalvik_register_v);
return true;
}
return false;
}
/* Insert phi nodes to for each variable to the dominance frontiers */
void MIRGraph::InsertPhiNodes()
{
int dalvik_reg;
ArenaBitVector* phi_blocks =
new (arena_) ArenaBitVector(arena_, GetNumBlocks(), false, kBitMapPhi);
ArenaBitVector* tmp_blocks =
new (arena_) ArenaBitVector(arena_, GetNumBlocks(), false, kBitMapTmpBlocks);
ArenaBitVector* input_blocks =
new (arena_) ArenaBitVector(arena_, GetNumBlocks(), false, kBitMapInputBlocks);
temp_dalvik_register_v_ =
new (arena_) ArenaBitVector(arena_, cu_->num_dalvik_registers, false, kBitMapRegisterV);
PostOrderDfsIterator iter(this, true /* iterative */);
bool change = false;
for (BasicBlock* bb = iter.Next(false); bb != NULL; bb = iter.Next(change)) {
change = ComputeBlockLiveIns(bb);
}
/* Iterate through each Dalvik register */
for (dalvik_reg = cu_->num_dalvik_registers - 1; dalvik_reg >= 0; dalvik_reg--) {
bool change;
input_blocks->Copy(def_block_matrix_[dalvik_reg]);
phi_blocks->ClearAllBits();
/* Calculate the phi blocks for each Dalvik register */
do {
change = false;
tmp_blocks->ClearAllBits();
ArenaBitVector::Iterator iterator(input_blocks);
while (true) {
int idx = iterator.Next();
if (idx == -1) break;
BasicBlock* def_bb = GetBasicBlock(idx);
/* Merge the dominance frontier to tmp_blocks */
//TUNING: hot call to Union().
if (def_bb->dom_frontier != NULL) {
tmp_blocks->Union(def_bb->dom_frontier);
}
}
if (!phi_blocks->Equal(tmp_blocks)) {
change = true;
phi_blocks->Copy(tmp_blocks);
/*
* Iterate through the original blocks plus the new ones in
* the dominance frontier.
*/
input_blocks->Copy(phi_blocks);
input_blocks->Union(def_block_matrix_[dalvik_reg]);
}
} while (change);
/*
* Insert a phi node for dalvik_reg in the phi_blocks if the Dalvik
* register is in the live-in set.
*/
ArenaBitVector::Iterator iterator(phi_blocks);
while (true) {
int idx = iterator.Next();
if (idx == -1) break;
BasicBlock* phi_bb = GetBasicBlock(idx);
/* Variable will be clobbered before being used - no need for phi */
if (!phi_bb->data_flow_info->live_in_v->IsBitSet(dalvik_reg)) continue;
MIR *phi =
static_cast<MIR*>(arena_->NewMem(sizeof(MIR), true, ArenaAllocator::kAllocDFInfo));
phi->dalvikInsn.opcode = static_cast<Instruction::Code>(kMirOpPhi);
phi->dalvikInsn.vA = dalvik_reg;
phi->offset = phi_bb->start_offset;
phi->m_unit_index = 0; // Arbitrarily assign all Phi nodes to outermost method.
PrependMIR(phi_bb, phi);
}
}
}
/*
* Worker function to insert phi-operands with latest SSA names from
* predecessor blocks
*/
bool MIRGraph::InsertPhiNodeOperands(BasicBlock* bb)
{
MIR *mir;
std::vector<int> uses;
std::vector<int> incoming_arc;
/* Phi nodes are at the beginning of each block */
for (mir = bb->first_mir_insn; mir != NULL; mir = mir->next) {
if (mir->dalvikInsn.opcode != static_cast<Instruction::Code>(kMirOpPhi))
return true;
int ssa_reg = mir->ssa_rep->defs[0];
DCHECK_GE(ssa_reg, 0); // Shouldn't see compiler temps here
int v_reg = SRegToVReg(ssa_reg);
uses.clear();
incoming_arc.clear();
/* Iterate through the predecessors */
GrowableArray<BasicBlock*>::Iterator iter(bb->predecessors);
while (true) {
BasicBlock* pred_bb = iter.Next();
if (!pred_bb) break;
int ssa_reg = pred_bb->data_flow_info->vreg_to_ssa_map[v_reg];
uses.push_back(ssa_reg);
incoming_arc.push_back(pred_bb->id);
}
/* Count the number of SSA registers for a Dalvik register */
int num_uses = uses.size();
mir->ssa_rep->num_uses = num_uses;
mir->ssa_rep->uses =
static_cast<int*>(arena_->NewMem(sizeof(int) * num_uses, false,
ArenaAllocator::kAllocDFInfo));
mir->ssa_rep->fp_use =
static_cast<bool*>(arena_->NewMem(sizeof(bool) * num_uses, true,
ArenaAllocator::kAllocDFInfo));
int* incoming =
static_cast<int*>(arena_->NewMem(sizeof(int) * num_uses, false,
ArenaAllocator::kAllocDFInfo));
// TODO: Ugly, rework (but don't burden each MIR/LIR for Phi-only needs)
mir->dalvikInsn.vB = reinterpret_cast<uintptr_t>(incoming);
/* Set the uses array for the phi node */
int *use_ptr = mir->ssa_rep->uses;
for (int i = 0; i < num_uses; i++) {
*use_ptr++ = uses[i];
*incoming++ = incoming_arc[i];
}
}
return true;
}
void MIRGraph::DoDFSPreOrderSSARename(BasicBlock* block)
{
if (block->visited || block->hidden) return;
block->visited = true;
/* Process this block */
DoSSAConversion(block);
int map_size = sizeof(int) * cu_->num_dalvik_registers;
/* Save SSA map snapshot */
int* saved_ssa_map =
static_cast<int*>(arena_->NewMem(map_size, false, ArenaAllocator::kAllocDalvikToSSAMap));
memcpy(saved_ssa_map, vreg_to_ssa_map_, map_size);
if (block->fall_through) {
DoDFSPreOrderSSARename(block->fall_through);
/* Restore SSA map snapshot */
memcpy(vreg_to_ssa_map_, saved_ssa_map, map_size);
}
if (block->taken) {
DoDFSPreOrderSSARename(block->taken);
/* Restore SSA map snapshot */
memcpy(vreg_to_ssa_map_, saved_ssa_map, map_size);
}
if (block->successor_block_list.block_list_type != kNotUsed) {
GrowableArray<SuccessorBlockInfo*>::Iterator iterator(block->successor_block_list.blocks);
while (true) {
SuccessorBlockInfo *successor_block_info = iterator.Next();
if (successor_block_info == NULL) break;
BasicBlock* succ_bb = successor_block_info->block;
DoDFSPreOrderSSARename(succ_bb);
/* Restore SSA map snapshot */
memcpy(vreg_to_ssa_map_, saved_ssa_map, map_size);
}
}
vreg_to_ssa_map_ = saved_ssa_map;
return;
}
/* Perform SSA transformation for the whole method */
void MIRGraph::SSATransformation()
{
/* Compute the DFS order */
ComputeDFSOrders();
/* Compute the dominator info */
ComputeDominators();
/* Allocate data structures in preparation for SSA conversion */
CompilerInitializeSSAConversion();
/* Find out the "Dalvik reg def x block" relation */
ComputeDefBlockMatrix();
/* Insert phi nodes to dominance frontiers for all variables */
InsertPhiNodes();
/* Rename register names by local defs and phi nodes */
ClearAllVisitedFlags();
DoDFSPreOrderSSARename(GetEntryBlock());
/*
* Shared temp bit vector used by each block to count the number of defs
* from all the predecessor blocks.
*/
temp_ssa_register_v_ =
new (arena_) ArenaBitVector(arena_, GetNumSSARegs(), false, kBitMapTempSSARegisterV);
/* Insert phi-operands with latest SSA names from predecessor blocks */
ReachableNodesIterator iter2(this, false /* not iterative */);
for (BasicBlock* bb = iter2.Next(); bb != NULL; bb = iter2.Next()) {
InsertPhiNodeOperands(bb);
}
if (cu_->enable_debug & (1 << kDebugDumpCFG)) {
DumpCFG("/sdcard/3_post_ssa_cfg/", false);
}
if (cu_->enable_debug & (1 << kDebugVerifyDataflow)) {
VerifyDataflow();
}
}
} // namespace art
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