1 // Copyright 2013 the V8 project authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
4
5 #include "src/compiler/scheduler.h"
6
7 #include <iomanip>
8
9 #include "src/base/adapters.h"
10 #include "src/bit-vector.h"
11 #include "src/compiler/common-operator.h"
12 #include "src/compiler/control-equivalence.h"
13 #include "src/compiler/graph.h"
14 #include "src/compiler/node-marker.h"
15 #include "src/compiler/node-properties.h"
16 #include "src/compiler/node.h"
17 #include "src/zone/zone-containers.h"
18
19 namespace v8 {
20 namespace internal {
21 namespace compiler {
22
23 #define TRACE(...) \
24 do { \
25 if (FLAG_trace_turbo_scheduler) PrintF(__VA_ARGS__); \
26 } while (false)
27
Scheduler(Zone * zone,Graph * graph,Schedule * schedule,Flags flags)28 Scheduler::Scheduler(Zone* zone, Graph* graph, Schedule* schedule, Flags flags)
29 : zone_(zone),
30 graph_(graph),
31 schedule_(schedule),
32 flags_(flags),
33 scheduled_nodes_(zone),
34 schedule_root_nodes_(zone),
35 schedule_queue_(zone),
36 node_data_(graph_->NodeCount(), DefaultSchedulerData(), zone) {}
37
38
ComputeSchedule(Zone * zone,Graph * graph,Flags flags)39 Schedule* Scheduler::ComputeSchedule(Zone* zone, Graph* graph, Flags flags) {
40 Schedule* schedule = new (graph->zone())
41 Schedule(graph->zone(), static_cast<size_t>(graph->NodeCount()));
42 Scheduler scheduler(zone, graph, schedule, flags);
43
44 scheduler.BuildCFG();
45 scheduler.ComputeSpecialRPONumbering();
46 scheduler.GenerateImmediateDominatorTree();
47
48 scheduler.PrepareUses();
49 scheduler.ScheduleEarly();
50 scheduler.ScheduleLate();
51
52 scheduler.SealFinalSchedule();
53
54 return schedule;
55 }
56
57
DefaultSchedulerData()58 Scheduler::SchedulerData Scheduler::DefaultSchedulerData() {
59 SchedulerData def = {schedule_->start(), 0, kUnknown};
60 return def;
61 }
62
63
GetData(Node * node)64 Scheduler::SchedulerData* Scheduler::GetData(Node* node) {
65 return &node_data_[node->id()];
66 }
67
68
GetPlacement(Node * node)69 Scheduler::Placement Scheduler::GetPlacement(Node* node) {
70 SchedulerData* data = GetData(node);
71 if (data->placement_ == kUnknown) { // Compute placement, once, on demand.
72 switch (node->opcode()) {
73 case IrOpcode::kParameter:
74 case IrOpcode::kOsrValue:
75 // Parameters and OSR values are always fixed to the start block.
76 data->placement_ = kFixed;
77 break;
78 case IrOpcode::kPhi:
79 case IrOpcode::kEffectPhi: {
80 // Phis and effect phis are fixed if their control inputs are, whereas
81 // otherwise they are coupled to a floating control node.
82 Placement p = GetPlacement(NodeProperties::GetControlInput(node));
83 data->placement_ = (p == kFixed ? kFixed : kCoupled);
84 break;
85 }
86 #define DEFINE_CONTROL_CASE(V) case IrOpcode::k##V:
87 CONTROL_OP_LIST(DEFINE_CONTROL_CASE)
88 #undef DEFINE_CONTROL_CASE
89 {
90 // Control nodes that were not control-reachable from end may float.
91 data->placement_ = kSchedulable;
92 break;
93 }
94 default:
95 data->placement_ = kSchedulable;
96 break;
97 }
98 }
99 return data->placement_;
100 }
101
102
UpdatePlacement(Node * node,Placement placement)103 void Scheduler::UpdatePlacement(Node* node, Placement placement) {
104 SchedulerData* data = GetData(node);
105 if (data->placement_ != kUnknown) { // Trap on mutation, not initialization.
106 switch (node->opcode()) {
107 case IrOpcode::kParameter:
108 // Parameters are fixed once and for all.
109 UNREACHABLE();
110 break;
111 case IrOpcode::kPhi:
112 case IrOpcode::kEffectPhi: {
113 // Phis and effect phis are coupled to their respective blocks.
114 DCHECK_EQ(Scheduler::kCoupled, data->placement_);
115 DCHECK_EQ(Scheduler::kFixed, placement);
116 Node* control = NodeProperties::GetControlInput(node);
117 BasicBlock* block = schedule_->block(control);
118 schedule_->AddNode(block, node);
119 break;
120 }
121 #define DEFINE_CONTROL_CASE(V) case IrOpcode::k##V:
122 CONTROL_OP_LIST(DEFINE_CONTROL_CASE)
123 #undef DEFINE_CONTROL_CASE
124 {
125 // Control nodes force coupled uses to be placed.
126 for (auto use : node->uses()) {
127 if (GetPlacement(use) == Scheduler::kCoupled) {
128 DCHECK_EQ(node, NodeProperties::GetControlInput(use));
129 UpdatePlacement(use, placement);
130 }
131 }
132 break;
133 }
134 default:
135 DCHECK_EQ(Scheduler::kSchedulable, data->placement_);
136 DCHECK_EQ(Scheduler::kScheduled, placement);
137 break;
138 }
139 // Reduce the use count of the node's inputs to potentially make them
140 // schedulable. If all the uses of a node have been scheduled, then the node
141 // itself can be scheduled.
142 for (Edge const edge : node->input_edges()) {
143 DecrementUnscheduledUseCount(edge.to(), edge.index(), edge.from());
144 }
145 }
146 data->placement_ = placement;
147 }
148
149
IsCoupledControlEdge(Node * node,int index)150 bool Scheduler::IsCoupledControlEdge(Node* node, int index) {
151 return GetPlacement(node) == kCoupled &&
152 NodeProperties::FirstControlIndex(node) == index;
153 }
154
155
IncrementUnscheduledUseCount(Node * node,int index,Node * from)156 void Scheduler::IncrementUnscheduledUseCount(Node* node, int index,
157 Node* from) {
158 // Make sure that control edges from coupled nodes are not counted.
159 if (IsCoupledControlEdge(from, index)) return;
160
161 // Tracking use counts for fixed nodes is useless.
162 if (GetPlacement(node) == kFixed) return;
163
164 // Use count for coupled nodes is summed up on their control.
165 if (GetPlacement(node) == kCoupled) {
166 Node* control = NodeProperties::GetControlInput(node);
167 return IncrementUnscheduledUseCount(control, index, from);
168 }
169
170 ++(GetData(node)->unscheduled_count_);
171 if (FLAG_trace_turbo_scheduler) {
172 TRACE(" Use count of #%d:%s (used by #%d:%s)++ = %d\n", node->id(),
173 node->op()->mnemonic(), from->id(), from->op()->mnemonic(),
174 GetData(node)->unscheduled_count_);
175 }
176 }
177
178
DecrementUnscheduledUseCount(Node * node,int index,Node * from)179 void Scheduler::DecrementUnscheduledUseCount(Node* node, int index,
180 Node* from) {
181 // Make sure that control edges from coupled nodes are not counted.
182 if (IsCoupledControlEdge(from, index)) return;
183
184 // Tracking use counts for fixed nodes is useless.
185 if (GetPlacement(node) == kFixed) return;
186
187 // Use count for coupled nodes is summed up on their control.
188 if (GetPlacement(node) == kCoupled) {
189 Node* control = NodeProperties::GetControlInput(node);
190 return DecrementUnscheduledUseCount(control, index, from);
191 }
192
193 DCHECK(GetData(node)->unscheduled_count_ > 0);
194 --(GetData(node)->unscheduled_count_);
195 if (FLAG_trace_turbo_scheduler) {
196 TRACE(" Use count of #%d:%s (used by #%d:%s)-- = %d\n", node->id(),
197 node->op()->mnemonic(), from->id(), from->op()->mnemonic(),
198 GetData(node)->unscheduled_count_);
199 }
200 if (GetData(node)->unscheduled_count_ == 0) {
201 TRACE(" newly eligible #%d:%s\n", node->id(), node->op()->mnemonic());
202 schedule_queue_.push(node);
203 }
204 }
205
206
207 // -----------------------------------------------------------------------------
208 // Phase 1: Build control-flow graph.
209
210
211 // Internal class to build a control flow graph (i.e the basic blocks and edges
212 // between them within a Schedule) from the node graph. Visits control edges of
213 // the graph backwards from an end node in order to find the connected control
214 // subgraph, needed for scheduling.
215 class CFGBuilder : public ZoneObject {
216 public:
CFGBuilder(Zone * zone,Scheduler * scheduler)217 CFGBuilder(Zone* zone, Scheduler* scheduler)
218 : zone_(zone),
219 scheduler_(scheduler),
220 schedule_(scheduler->schedule_),
221 queued_(scheduler->graph_, 2),
222 queue_(zone),
223 control_(zone),
224 component_entry_(nullptr),
225 component_start_(nullptr),
226 component_end_(nullptr) {}
227
228 // Run the control flow graph construction algorithm by walking the graph
229 // backwards from end through control edges, building and connecting the
230 // basic blocks for control nodes.
Run()231 void Run() {
232 ResetDataStructures();
233 Queue(scheduler_->graph_->end());
234
235 while (!queue_.empty()) { // Breadth-first backwards traversal.
236 Node* node = queue_.front();
237 queue_.pop();
238 int max = NodeProperties::PastControlIndex(node);
239 for (int i = NodeProperties::FirstControlIndex(node); i < max; i++) {
240 Queue(node->InputAt(i));
241 }
242 }
243
244 for (NodeVector::iterator i = control_.begin(); i != control_.end(); ++i) {
245 ConnectBlocks(*i); // Connect block to its predecessor/successors.
246 }
247 }
248
249 // Run the control flow graph construction for a minimal control-connected
250 // component ending in {exit} and merge that component into an existing
251 // control flow graph at the bottom of {block}.
Run(BasicBlock * block,Node * exit)252 void Run(BasicBlock* block, Node* exit) {
253 ResetDataStructures();
254 Queue(exit);
255
256 component_entry_ = nullptr;
257 component_start_ = block;
258 component_end_ = schedule_->block(exit);
259 scheduler_->equivalence_->Run(exit);
260 while (!queue_.empty()) { // Breadth-first backwards traversal.
261 Node* node = queue_.front();
262 queue_.pop();
263
264 // Use control dependence equivalence to find a canonical single-entry
265 // single-exit region that makes up a minimal component to be scheduled.
266 if (IsSingleEntrySingleExitRegion(node, exit)) {
267 TRACE("Found SESE at #%d:%s\n", node->id(), node->op()->mnemonic());
268 DCHECK(!component_entry_);
269 component_entry_ = node;
270 continue;
271 }
272
273 int max = NodeProperties::PastControlIndex(node);
274 for (int i = NodeProperties::FirstControlIndex(node); i < max; i++) {
275 Queue(node->InputAt(i));
276 }
277 }
278 DCHECK(component_entry_);
279
280 for (NodeVector::iterator i = control_.begin(); i != control_.end(); ++i) {
281 ConnectBlocks(*i); // Connect block to its predecessor/successors.
282 }
283 }
284
285 private:
286 friend class ScheduleLateNodeVisitor;
287 friend class Scheduler;
288
FixNode(BasicBlock * block,Node * node)289 void FixNode(BasicBlock* block, Node* node) {
290 schedule_->AddNode(block, node);
291 scheduler_->UpdatePlacement(node, Scheduler::kFixed);
292 }
293
Queue(Node * node)294 void Queue(Node* node) {
295 // Mark the connected control nodes as they are queued.
296 if (!queued_.Get(node)) {
297 BuildBlocks(node);
298 queue_.push(node);
299 queued_.Set(node, true);
300 control_.push_back(node);
301 }
302 }
303
BuildBlocks(Node * node)304 void BuildBlocks(Node* node) {
305 switch (node->opcode()) {
306 case IrOpcode::kEnd:
307 FixNode(schedule_->end(), node);
308 break;
309 case IrOpcode::kStart:
310 FixNode(schedule_->start(), node);
311 break;
312 case IrOpcode::kLoop:
313 case IrOpcode::kMerge:
314 BuildBlockForNode(node);
315 break;
316 case IrOpcode::kTerminate: {
317 // Put Terminate in the loop to which it refers.
318 Node* loop = NodeProperties::GetControlInput(node);
319 BasicBlock* block = BuildBlockForNode(loop);
320 FixNode(block, node);
321 break;
322 }
323 case IrOpcode::kBranch:
324 case IrOpcode::kSwitch:
325 BuildBlocksForSuccessors(node);
326 break;
327 #define BUILD_BLOCK_JS_CASE(Name) case IrOpcode::k##Name:
328 JS_OP_LIST(BUILD_BLOCK_JS_CASE)
329 // JS opcodes are just like calls => fall through.
330 #undef BUILD_BLOCK_JS_CASE
331 case IrOpcode::kCall:
332 if (NodeProperties::IsExceptionalCall(node)) {
333 BuildBlocksForSuccessors(node);
334 }
335 break;
336 default:
337 break;
338 }
339 }
340
ConnectBlocks(Node * node)341 void ConnectBlocks(Node* node) {
342 switch (node->opcode()) {
343 case IrOpcode::kLoop:
344 case IrOpcode::kMerge:
345 ConnectMerge(node);
346 break;
347 case IrOpcode::kBranch:
348 scheduler_->UpdatePlacement(node, Scheduler::kFixed);
349 ConnectBranch(node);
350 break;
351 case IrOpcode::kSwitch:
352 scheduler_->UpdatePlacement(node, Scheduler::kFixed);
353 ConnectSwitch(node);
354 break;
355 case IrOpcode::kDeoptimize:
356 scheduler_->UpdatePlacement(node, Scheduler::kFixed);
357 ConnectDeoptimize(node);
358 break;
359 case IrOpcode::kTailCall:
360 scheduler_->UpdatePlacement(node, Scheduler::kFixed);
361 ConnectTailCall(node);
362 break;
363 case IrOpcode::kReturn:
364 scheduler_->UpdatePlacement(node, Scheduler::kFixed);
365 ConnectReturn(node);
366 break;
367 case IrOpcode::kThrow:
368 scheduler_->UpdatePlacement(node, Scheduler::kFixed);
369 ConnectThrow(node);
370 break;
371 #define CONNECT_BLOCK_JS_CASE(Name) case IrOpcode::k##Name:
372 JS_OP_LIST(CONNECT_BLOCK_JS_CASE)
373 // JS opcodes are just like calls => fall through.
374 #undef CONNECT_BLOCK_JS_CASE
375 case IrOpcode::kCall:
376 if (NodeProperties::IsExceptionalCall(node)) {
377 scheduler_->UpdatePlacement(node, Scheduler::kFixed);
378 ConnectCall(node);
379 }
380 break;
381 default:
382 break;
383 }
384 }
385
BuildBlockForNode(Node * node)386 BasicBlock* BuildBlockForNode(Node* node) {
387 BasicBlock* block = schedule_->block(node);
388 if (block == nullptr) {
389 block = schedule_->NewBasicBlock();
390 TRACE("Create block id:%d for #%d:%s\n", block->id().ToInt(), node->id(),
391 node->op()->mnemonic());
392 FixNode(block, node);
393 }
394 return block;
395 }
396
BuildBlocksForSuccessors(Node * node)397 void BuildBlocksForSuccessors(Node* node) {
398 size_t const successor_cnt = node->op()->ControlOutputCount();
399 Node** successors = zone_->NewArray<Node*>(successor_cnt);
400 NodeProperties::CollectControlProjections(node, successors, successor_cnt);
401 for (size_t index = 0; index < successor_cnt; ++index) {
402 BuildBlockForNode(successors[index]);
403 }
404 }
405
CollectSuccessorBlocks(Node * node,BasicBlock ** successor_blocks,size_t successor_cnt)406 void CollectSuccessorBlocks(Node* node, BasicBlock** successor_blocks,
407 size_t successor_cnt) {
408 Node** successors = reinterpret_cast<Node**>(successor_blocks);
409 NodeProperties::CollectControlProjections(node, successors, successor_cnt);
410 for (size_t index = 0; index < successor_cnt; ++index) {
411 successor_blocks[index] = schedule_->block(successors[index]);
412 }
413 }
414
FindPredecessorBlock(Node * node)415 BasicBlock* FindPredecessorBlock(Node* node) {
416 BasicBlock* predecessor_block = nullptr;
417 while (true) {
418 predecessor_block = schedule_->block(node);
419 if (predecessor_block != nullptr) break;
420 node = NodeProperties::GetControlInput(node);
421 }
422 return predecessor_block;
423 }
424
ConnectCall(Node * call)425 void ConnectCall(Node* call) {
426 BasicBlock* successor_blocks[2];
427 CollectSuccessorBlocks(call, successor_blocks, arraysize(successor_blocks));
428
429 // Consider the exception continuation to be deferred.
430 successor_blocks[1]->set_deferred(true);
431
432 Node* call_control = NodeProperties::GetControlInput(call);
433 BasicBlock* call_block = FindPredecessorBlock(call_control);
434 TraceConnect(call, call_block, successor_blocks[0]);
435 TraceConnect(call, call_block, successor_blocks[1]);
436 schedule_->AddCall(call_block, call, successor_blocks[0],
437 successor_blocks[1]);
438 }
439
ConnectBranch(Node * branch)440 void ConnectBranch(Node* branch) {
441 BasicBlock* successor_blocks[2];
442 CollectSuccessorBlocks(branch, successor_blocks,
443 arraysize(successor_blocks));
444
445 // Consider branch hints.
446 switch (BranchHintOf(branch->op())) {
447 case BranchHint::kNone:
448 break;
449 case BranchHint::kTrue:
450 successor_blocks[1]->set_deferred(true);
451 break;
452 case BranchHint::kFalse:
453 successor_blocks[0]->set_deferred(true);
454 break;
455 }
456
457 if (branch == component_entry_) {
458 TraceConnect(branch, component_start_, successor_blocks[0]);
459 TraceConnect(branch, component_start_, successor_blocks[1]);
460 schedule_->InsertBranch(component_start_, component_end_, branch,
461 successor_blocks[0], successor_blocks[1]);
462 } else {
463 Node* branch_control = NodeProperties::GetControlInput(branch);
464 BasicBlock* branch_block = FindPredecessorBlock(branch_control);
465 TraceConnect(branch, branch_block, successor_blocks[0]);
466 TraceConnect(branch, branch_block, successor_blocks[1]);
467 schedule_->AddBranch(branch_block, branch, successor_blocks[0],
468 successor_blocks[1]);
469 }
470 }
471
ConnectSwitch(Node * sw)472 void ConnectSwitch(Node* sw) {
473 size_t const successor_count = sw->op()->ControlOutputCount();
474 BasicBlock** successor_blocks =
475 zone_->NewArray<BasicBlock*>(successor_count);
476 CollectSuccessorBlocks(sw, successor_blocks, successor_count);
477
478 if (sw == component_entry_) {
479 for (size_t index = 0; index < successor_count; ++index) {
480 TraceConnect(sw, component_start_, successor_blocks[index]);
481 }
482 schedule_->InsertSwitch(component_start_, component_end_, sw,
483 successor_blocks, successor_count);
484 } else {
485 Node* switch_control = NodeProperties::GetControlInput(sw);
486 BasicBlock* switch_block = FindPredecessorBlock(switch_control);
487 for (size_t index = 0; index < successor_count; ++index) {
488 TraceConnect(sw, switch_block, successor_blocks[index]);
489 }
490 schedule_->AddSwitch(switch_block, sw, successor_blocks, successor_count);
491 }
492 }
493
ConnectMerge(Node * merge)494 void ConnectMerge(Node* merge) {
495 // Don't connect the special merge at the end to its predecessors.
496 if (IsFinalMerge(merge)) return;
497
498 BasicBlock* block = schedule_->block(merge);
499 DCHECK_NOT_NULL(block);
500 // For all of the merge's control inputs, add a goto at the end to the
501 // merge's basic block.
502 for (Node* const input : merge->inputs()) {
503 BasicBlock* predecessor_block = FindPredecessorBlock(input);
504 TraceConnect(merge, predecessor_block, block);
505 schedule_->AddGoto(predecessor_block, block);
506 }
507 }
508
ConnectTailCall(Node * call)509 void ConnectTailCall(Node* call) {
510 Node* call_control = NodeProperties::GetControlInput(call);
511 BasicBlock* call_block = FindPredecessorBlock(call_control);
512 TraceConnect(call, call_block, nullptr);
513 schedule_->AddTailCall(call_block, call);
514 }
515
ConnectReturn(Node * ret)516 void ConnectReturn(Node* ret) {
517 Node* return_control = NodeProperties::GetControlInput(ret);
518 BasicBlock* return_block = FindPredecessorBlock(return_control);
519 TraceConnect(ret, return_block, nullptr);
520 schedule_->AddReturn(return_block, ret);
521 }
522
ConnectDeoptimize(Node * deopt)523 void ConnectDeoptimize(Node* deopt) {
524 Node* deoptimize_control = NodeProperties::GetControlInput(deopt);
525 BasicBlock* deoptimize_block = FindPredecessorBlock(deoptimize_control);
526 TraceConnect(deopt, deoptimize_block, nullptr);
527 schedule_->AddDeoptimize(deoptimize_block, deopt);
528 }
529
ConnectThrow(Node * thr)530 void ConnectThrow(Node* thr) {
531 Node* throw_control = NodeProperties::GetControlInput(thr);
532 BasicBlock* throw_block = FindPredecessorBlock(throw_control);
533 TraceConnect(thr, throw_block, nullptr);
534 schedule_->AddThrow(throw_block, thr);
535 }
536
TraceConnect(Node * node,BasicBlock * block,BasicBlock * succ)537 void TraceConnect(Node* node, BasicBlock* block, BasicBlock* succ) {
538 DCHECK_NOT_NULL(block);
539 if (succ == nullptr) {
540 TRACE("Connect #%d:%s, id:%d -> end\n", node->id(),
541 node->op()->mnemonic(), block->id().ToInt());
542 } else {
543 TRACE("Connect #%d:%s, id:%d -> id:%d\n", node->id(),
544 node->op()->mnemonic(), block->id().ToInt(), succ->id().ToInt());
545 }
546 }
547
IsFinalMerge(Node * node)548 bool IsFinalMerge(Node* node) {
549 return (node->opcode() == IrOpcode::kMerge &&
550 node == scheduler_->graph_->end()->InputAt(0));
551 }
552
IsSingleEntrySingleExitRegion(Node * entry,Node * exit) const553 bool IsSingleEntrySingleExitRegion(Node* entry, Node* exit) const {
554 size_t entry_class = scheduler_->equivalence_->ClassOf(entry);
555 size_t exit_class = scheduler_->equivalence_->ClassOf(exit);
556 return entry != exit && entry_class == exit_class;
557 }
558
ResetDataStructures()559 void ResetDataStructures() {
560 control_.clear();
561 DCHECK(queue_.empty());
562 DCHECK(control_.empty());
563 }
564
565 Zone* zone_;
566 Scheduler* scheduler_;
567 Schedule* schedule_;
568 NodeMarker<bool> queued_; // Mark indicating whether node is queued.
569 ZoneQueue<Node*> queue_; // Queue used for breadth-first traversal.
570 NodeVector control_; // List of encountered control nodes.
571 Node* component_entry_; // Component single-entry node.
572 BasicBlock* component_start_; // Component single-entry block.
573 BasicBlock* component_end_; // Component single-exit block.
574 };
575
576
BuildCFG()577 void Scheduler::BuildCFG() {
578 TRACE("--- CREATING CFG -------------------------------------------\n");
579
580 // Instantiate a new control equivalence algorithm for the graph.
581 equivalence_ = new (zone_) ControlEquivalence(zone_, graph_);
582
583 // Build a control-flow graph for the main control-connected component that
584 // is being spanned by the graph's start and end nodes.
585 control_flow_builder_ = new (zone_) CFGBuilder(zone_, this);
586 control_flow_builder_->Run();
587
588 // Initialize per-block data.
589 scheduled_nodes_.resize(schedule_->BasicBlockCount(), NodeVector(zone_));
590 }
591
592
593 // -----------------------------------------------------------------------------
594 // Phase 2: Compute special RPO and dominator tree.
595
596
597 // Compute the special reverse-post-order block ordering, which is essentially
598 // a RPO of the graph where loop bodies are contiguous. Properties:
599 // 1. If block A is a predecessor of B, then A appears before B in the order,
600 // unless B is a loop header and A is in the loop headed at B
601 // (i.e. A -> B is a backedge).
602 // => If block A dominates block B, then A appears before B in the order.
603 // => If block A is a loop header, A appears before all blocks in the loop
604 // headed at A.
605 // 2. All loops are contiguous in the order (i.e. no intervening blocks that
606 // do not belong to the loop.)
607 // Note a simple RPO traversal satisfies (1) but not (2).
608 class SpecialRPONumberer : public ZoneObject {
609 public:
SpecialRPONumberer(Zone * zone,Schedule * schedule)610 SpecialRPONumberer(Zone* zone, Schedule* schedule)
611 : zone_(zone),
612 schedule_(schedule),
613 order_(nullptr),
614 beyond_end_(nullptr),
615 loops_(zone),
616 backedges_(zone),
617 stack_(zone),
618 previous_block_count_(0),
619 empty_(0, zone) {}
620
621 // Computes the special reverse-post-order for the main control flow graph,
622 // that is for the graph spanned between the schedule's start and end blocks.
ComputeSpecialRPO()623 void ComputeSpecialRPO() {
624 DCHECK(schedule_->end()->SuccessorCount() == 0);
625 DCHECK(!order_); // Main order does not exist yet.
626 ComputeAndInsertSpecialRPO(schedule_->start(), schedule_->end());
627 }
628
629 // Computes the special reverse-post-order for a partial control flow graph,
630 // that is for the graph spanned between the given {entry} and {end} blocks,
631 // then updates the existing ordering with this new information.
UpdateSpecialRPO(BasicBlock * entry,BasicBlock * end)632 void UpdateSpecialRPO(BasicBlock* entry, BasicBlock* end) {
633 DCHECK(order_); // Main order to be updated is present.
634 ComputeAndInsertSpecialRPO(entry, end);
635 }
636
637 // Serialize the previously computed order as a special reverse-post-order
638 // numbering for basic blocks into the final schedule.
SerializeRPOIntoSchedule()639 void SerializeRPOIntoSchedule() {
640 int32_t number = 0;
641 for (BasicBlock* b = order_; b != nullptr; b = b->rpo_next()) {
642 b->set_rpo_number(number++);
643 schedule_->rpo_order()->push_back(b);
644 }
645 BeyondEndSentinel()->set_rpo_number(number);
646 }
647
648 // Print and verify the special reverse-post-order.
PrintAndVerifySpecialRPO()649 void PrintAndVerifySpecialRPO() {
650 #if DEBUG
651 if (FLAG_trace_turbo_scheduler) PrintRPO();
652 VerifySpecialRPO();
653 #endif
654 }
655
GetOutgoingBlocks(BasicBlock * block)656 const ZoneVector<BasicBlock*>& GetOutgoingBlocks(BasicBlock* block) {
657 if (HasLoopNumber(block)) {
658 LoopInfo const& loop = loops_[GetLoopNumber(block)];
659 if (loop.outgoing) return *loop.outgoing;
660 }
661 return empty_;
662 }
663
664 private:
665 typedef std::pair<BasicBlock*, size_t> Backedge;
666
667 // Numbering for BasicBlock::rpo_number for this block traversal:
668 static const int kBlockOnStack = -2;
669 static const int kBlockVisited1 = -3;
670 static const int kBlockVisited2 = -4;
671 static const int kBlockUnvisited1 = -1;
672 static const int kBlockUnvisited2 = kBlockVisited1;
673
674 struct SpecialRPOStackFrame {
675 BasicBlock* block;
676 size_t index;
677 };
678
679 struct LoopInfo {
680 BasicBlock* header;
681 ZoneVector<BasicBlock*>* outgoing;
682 BitVector* members;
683 LoopInfo* prev;
684 BasicBlock* end;
685 BasicBlock* start;
686
AddOutgoingv8::internal::compiler::SpecialRPONumberer::LoopInfo687 void AddOutgoing(Zone* zone, BasicBlock* block) {
688 if (outgoing == nullptr) {
689 outgoing = new (zone->New(sizeof(ZoneVector<BasicBlock*>)))
690 ZoneVector<BasicBlock*>(zone);
691 }
692 outgoing->push_back(block);
693 }
694 };
695
Push(ZoneVector<SpecialRPOStackFrame> & stack,int depth,BasicBlock * child,int unvisited)696 int Push(ZoneVector<SpecialRPOStackFrame>& stack, int depth,
697 BasicBlock* child, int unvisited) {
698 if (child->rpo_number() == unvisited) {
699 stack[depth].block = child;
700 stack[depth].index = 0;
701 child->set_rpo_number(kBlockOnStack);
702 return depth + 1;
703 }
704 return depth;
705 }
706
PushFront(BasicBlock * head,BasicBlock * block)707 BasicBlock* PushFront(BasicBlock* head, BasicBlock* block) {
708 block->set_rpo_next(head);
709 return block;
710 }
711
GetLoopNumber(BasicBlock * block)712 static int GetLoopNumber(BasicBlock* block) { return block->loop_number(); }
SetLoopNumber(BasicBlock * block,int loop_number)713 static void SetLoopNumber(BasicBlock* block, int loop_number) {
714 return block->set_loop_number(loop_number);
715 }
HasLoopNumber(BasicBlock * block)716 static bool HasLoopNumber(BasicBlock* block) {
717 return block->loop_number() >= 0;
718 }
719
720 // TODO(mstarzinger): We only need this special sentinel because some tests
721 // use the schedule's end block in actual control flow (e.g. with end having
722 // successors). Once this has been cleaned up we can use the end block here.
BeyondEndSentinel()723 BasicBlock* BeyondEndSentinel() {
724 if (beyond_end_ == nullptr) {
725 BasicBlock::Id id = BasicBlock::Id::FromInt(-1);
726 beyond_end_ = new (schedule_->zone()) BasicBlock(schedule_->zone(), id);
727 }
728 return beyond_end_;
729 }
730
731 // Compute special RPO for the control flow graph between {entry} and {end},
732 // mutating any existing order so that the result is still valid.
ComputeAndInsertSpecialRPO(BasicBlock * entry,BasicBlock * end)733 void ComputeAndInsertSpecialRPO(BasicBlock* entry, BasicBlock* end) {
734 // RPO should not have been serialized for this schedule yet.
735 CHECK_EQ(kBlockUnvisited1, schedule_->start()->loop_number());
736 CHECK_EQ(kBlockUnvisited1, schedule_->start()->rpo_number());
737 CHECK_EQ(0, static_cast<int>(schedule_->rpo_order()->size()));
738
739 // Find correct insertion point within existing order.
740 BasicBlock* insertion_point = entry->rpo_next();
741 BasicBlock* order = insertion_point;
742
743 // Perform an iterative RPO traversal using an explicit stack,
744 // recording backedges that form cycles. O(|B|).
745 DCHECK_LT(previous_block_count_, schedule_->BasicBlockCount());
746 stack_.resize(schedule_->BasicBlockCount() - previous_block_count_);
747 previous_block_count_ = schedule_->BasicBlockCount();
748 int stack_depth = Push(stack_, 0, entry, kBlockUnvisited1);
749 int num_loops = static_cast<int>(loops_.size());
750
751 while (stack_depth > 0) {
752 int current = stack_depth - 1;
753 SpecialRPOStackFrame* frame = &stack_[current];
754
755 if (frame->block != end &&
756 frame->index < frame->block->SuccessorCount()) {
757 // Process the next successor.
758 BasicBlock* succ = frame->block->SuccessorAt(frame->index++);
759 if (succ->rpo_number() == kBlockVisited1) continue;
760 if (succ->rpo_number() == kBlockOnStack) {
761 // The successor is on the stack, so this is a backedge (cycle).
762 backedges_.push_back(Backedge(frame->block, frame->index - 1));
763 if (!HasLoopNumber(succ)) {
764 // Assign a new loop number to the header if it doesn't have one.
765 SetLoopNumber(succ, num_loops++);
766 }
767 } else {
768 // Push the successor onto the stack.
769 DCHECK(succ->rpo_number() == kBlockUnvisited1);
770 stack_depth = Push(stack_, stack_depth, succ, kBlockUnvisited1);
771 }
772 } else {
773 // Finished with all successors; pop the stack and add the block.
774 order = PushFront(order, frame->block);
775 frame->block->set_rpo_number(kBlockVisited1);
776 stack_depth--;
777 }
778 }
779
780 // If no loops were encountered, then the order we computed was correct.
781 if (num_loops > static_cast<int>(loops_.size())) {
782 // Otherwise, compute the loop information from the backedges in order
783 // to perform a traversal that groups loop bodies together.
784 ComputeLoopInfo(stack_, num_loops, &backedges_);
785
786 // Initialize the "loop stack". Note the entry could be a loop header.
787 LoopInfo* loop =
788 HasLoopNumber(entry) ? &loops_[GetLoopNumber(entry)] : nullptr;
789 order = insertion_point;
790
791 // Perform an iterative post-order traversal, visiting loop bodies before
792 // edges that lead out of loops. Visits each block once, but linking loop
793 // sections together is linear in the loop size, so overall is
794 // O(|B| + max(loop_depth) * max(|loop|))
795 stack_depth = Push(stack_, 0, entry, kBlockUnvisited2);
796 while (stack_depth > 0) {
797 SpecialRPOStackFrame* frame = &stack_[stack_depth - 1];
798 BasicBlock* block = frame->block;
799 BasicBlock* succ = nullptr;
800
801 if (block != end && frame->index < block->SuccessorCount()) {
802 // Process the next normal successor.
803 succ = block->SuccessorAt(frame->index++);
804 } else if (HasLoopNumber(block)) {
805 // Process additional outgoing edges from the loop header.
806 if (block->rpo_number() == kBlockOnStack) {
807 // Finish the loop body the first time the header is left on the
808 // stack.
809 DCHECK(loop != nullptr && loop->header == block);
810 loop->start = PushFront(order, block);
811 order = loop->end;
812 block->set_rpo_number(kBlockVisited2);
813 // Pop the loop stack and continue visiting outgoing edges within
814 // the context of the outer loop, if any.
815 loop = loop->prev;
816 // We leave the loop header on the stack; the rest of this iteration
817 // and later iterations will go through its outgoing edges list.
818 }
819
820 // Use the next outgoing edge if there are any.
821 size_t outgoing_index = frame->index - block->SuccessorCount();
822 LoopInfo* info = &loops_[GetLoopNumber(block)];
823 DCHECK(loop != info);
824 if (block != entry && info->outgoing != nullptr &&
825 outgoing_index < info->outgoing->size()) {
826 succ = info->outgoing->at(outgoing_index);
827 frame->index++;
828 }
829 }
830
831 if (succ != nullptr) {
832 // Process the next successor.
833 if (succ->rpo_number() == kBlockOnStack) continue;
834 if (succ->rpo_number() == kBlockVisited2) continue;
835 DCHECK(succ->rpo_number() == kBlockUnvisited2);
836 if (loop != nullptr && !loop->members->Contains(succ->id().ToInt())) {
837 // The successor is not in the current loop or any nested loop.
838 // Add it to the outgoing edges of this loop and visit it later.
839 loop->AddOutgoing(zone_, succ);
840 } else {
841 // Push the successor onto the stack.
842 stack_depth = Push(stack_, stack_depth, succ, kBlockUnvisited2);
843 if (HasLoopNumber(succ)) {
844 // Push the inner loop onto the loop stack.
845 DCHECK(GetLoopNumber(succ) < num_loops);
846 LoopInfo* next = &loops_[GetLoopNumber(succ)];
847 next->end = order;
848 next->prev = loop;
849 loop = next;
850 }
851 }
852 } else {
853 // Finished with all successors of the current block.
854 if (HasLoopNumber(block)) {
855 // If we are going to pop a loop header, then add its entire body.
856 LoopInfo* info = &loops_[GetLoopNumber(block)];
857 for (BasicBlock* b = info->start; true; b = b->rpo_next()) {
858 if (b->rpo_next() == info->end) {
859 b->set_rpo_next(order);
860 info->end = order;
861 break;
862 }
863 }
864 order = info->start;
865 } else {
866 // Pop a single node off the stack and add it to the order.
867 order = PushFront(order, block);
868 block->set_rpo_number(kBlockVisited2);
869 }
870 stack_depth--;
871 }
872 }
873 }
874
875 // Publish new order the first time.
876 if (order_ == nullptr) order_ = order;
877
878 // Compute the correct loop headers and set the correct loop ends.
879 LoopInfo* current_loop = nullptr;
880 BasicBlock* current_header = entry->loop_header();
881 int32_t loop_depth = entry->loop_depth();
882 if (entry->IsLoopHeader()) --loop_depth; // Entry might be a loop header.
883 for (BasicBlock* b = order; b != insertion_point; b = b->rpo_next()) {
884 BasicBlock* current = b;
885
886 // Reset BasicBlock::rpo_number again.
887 current->set_rpo_number(kBlockUnvisited1);
888
889 // Finish the previous loop(s) if we just exited them.
890 while (current_header != nullptr &&
891 current == current_header->loop_end()) {
892 DCHECK(current_header->IsLoopHeader());
893 DCHECK_NOT_NULL(current_loop);
894 current_loop = current_loop->prev;
895 current_header =
896 current_loop == nullptr ? nullptr : current_loop->header;
897 --loop_depth;
898 }
899 current->set_loop_header(current_header);
900
901 // Push a new loop onto the stack if this loop is a loop header.
902 if (HasLoopNumber(current)) {
903 ++loop_depth;
904 current_loop = &loops_[GetLoopNumber(current)];
905 BasicBlock* end = current_loop->end;
906 current->set_loop_end(end == nullptr ? BeyondEndSentinel() : end);
907 current_header = current_loop->header;
908 TRACE("id:%d is a loop header, increment loop depth to %d\n",
909 current->id().ToInt(), loop_depth);
910 }
911
912 current->set_loop_depth(loop_depth);
913
914 if (current->loop_header() == nullptr) {
915 TRACE("id:%d is not in a loop (depth == %d)\n", current->id().ToInt(),
916 current->loop_depth());
917 } else {
918 TRACE("id:%d has loop header id:%d, (depth == %d)\n",
919 current->id().ToInt(), current->loop_header()->id().ToInt(),
920 current->loop_depth());
921 }
922 }
923 }
924
925 // Computes loop membership from the backedges of the control flow graph.
ComputeLoopInfo(ZoneVector<SpecialRPOStackFrame> & queue,size_t num_loops,ZoneVector<Backedge> * backedges)926 void ComputeLoopInfo(ZoneVector<SpecialRPOStackFrame>& queue,
927 size_t num_loops, ZoneVector<Backedge>* backedges) {
928 // Extend existing loop membership vectors.
929 for (LoopInfo& loop : loops_) {
930 BitVector* new_members = new (zone_)
931 BitVector(static_cast<int>(schedule_->BasicBlockCount()), zone_);
932 new_members->CopyFrom(*loop.members);
933 loop.members = new_members;
934 }
935
936 // Extend loop information vector.
937 loops_.resize(num_loops, LoopInfo());
938
939 // Compute loop membership starting from backedges.
940 // O(max(loop_depth) * max(|loop|)
941 for (size_t i = 0; i < backedges->size(); i++) {
942 BasicBlock* member = backedges->at(i).first;
943 BasicBlock* header = member->SuccessorAt(backedges->at(i).second);
944 size_t loop_num = GetLoopNumber(header);
945 if (loops_[loop_num].header == nullptr) {
946 loops_[loop_num].header = header;
947 loops_[loop_num].members = new (zone_)
948 BitVector(static_cast<int>(schedule_->BasicBlockCount()), zone_);
949 }
950
951 int queue_length = 0;
952 if (member != header) {
953 // As long as the header doesn't have a backedge to itself,
954 // Push the member onto the queue and process its predecessors.
955 if (!loops_[loop_num].members->Contains(member->id().ToInt())) {
956 loops_[loop_num].members->Add(member->id().ToInt());
957 }
958 queue[queue_length++].block = member;
959 }
960
961 // Propagate loop membership backwards. All predecessors of M up to the
962 // loop header H are members of the loop too. O(|blocks between M and H|).
963 while (queue_length > 0) {
964 BasicBlock* block = queue[--queue_length].block;
965 for (size_t i = 0; i < block->PredecessorCount(); i++) {
966 BasicBlock* pred = block->PredecessorAt(i);
967 if (pred != header) {
968 if (!loops_[loop_num].members->Contains(pred->id().ToInt())) {
969 loops_[loop_num].members->Add(pred->id().ToInt());
970 queue[queue_length++].block = pred;
971 }
972 }
973 }
974 }
975 }
976 }
977
978 #if DEBUG
PrintRPO()979 void PrintRPO() {
980 OFStream os(stdout);
981 os << "RPO with " << loops_.size() << " loops";
982 if (loops_.size() > 0) {
983 os << " (";
984 for (size_t i = 0; i < loops_.size(); i++) {
985 if (i > 0) os << " ";
986 os << "id:" << loops_[i].header->id();
987 }
988 os << ")";
989 }
990 os << ":\n";
991
992 for (BasicBlock* block = order_; block != nullptr;
993 block = block->rpo_next()) {
994 os << std::setw(5) << "B" << block->rpo_number() << ":";
995 for (size_t i = 0; i < loops_.size(); i++) {
996 bool range = loops_[i].header->LoopContains(block);
997 bool membership = loops_[i].header != block && range;
998 os << (membership ? " |" : " ");
999 os << (range ? "x" : " ");
1000 }
1001 os << " id:" << block->id() << ": ";
1002 if (block->loop_end() != nullptr) {
1003 os << " range: [B" << block->rpo_number() << ", B"
1004 << block->loop_end()->rpo_number() << ")";
1005 }
1006 if (block->loop_header() != nullptr) {
1007 os << " header: id:" << block->loop_header()->id();
1008 }
1009 if (block->loop_depth() > 0) {
1010 os << " depth: " << block->loop_depth();
1011 }
1012 os << "\n";
1013 }
1014 }
1015
VerifySpecialRPO()1016 void VerifySpecialRPO() {
1017 BasicBlockVector* order = schedule_->rpo_order();
1018 DCHECK(order->size() > 0);
1019 DCHECK((*order)[0]->id().ToInt() == 0); // entry should be first.
1020
1021 for (size_t i = 0; i < loops_.size(); i++) {
1022 LoopInfo* loop = &loops_[i];
1023 BasicBlock* header = loop->header;
1024 BasicBlock* end = header->loop_end();
1025
1026 DCHECK_NOT_NULL(header);
1027 DCHECK(header->rpo_number() >= 0);
1028 DCHECK(header->rpo_number() < static_cast<int>(order->size()));
1029 DCHECK_NOT_NULL(end);
1030 DCHECK(end->rpo_number() <= static_cast<int>(order->size()));
1031 DCHECK(end->rpo_number() > header->rpo_number());
1032 DCHECK(header->loop_header() != header);
1033
1034 // Verify the start ... end list relationship.
1035 int links = 0;
1036 BasicBlock* block = loop->start;
1037 DCHECK_EQ(header, block);
1038 bool end_found;
1039 while (true) {
1040 if (block == nullptr || block == loop->end) {
1041 end_found = (loop->end == block);
1042 break;
1043 }
1044 // The list should be in same order as the final result.
1045 DCHECK(block->rpo_number() == links + header->rpo_number());
1046 links++;
1047 block = block->rpo_next();
1048 DCHECK_LT(links, static_cast<int>(2 * order->size())); // cycle?
1049 }
1050 DCHECK(links > 0);
1051 DCHECK(links == end->rpo_number() - header->rpo_number());
1052 DCHECK(end_found);
1053
1054 // Check loop depth of the header.
1055 int loop_depth = 0;
1056 for (LoopInfo* outer = loop; outer != nullptr; outer = outer->prev) {
1057 loop_depth++;
1058 }
1059 DCHECK_EQ(loop_depth, header->loop_depth());
1060
1061 // Check the contiguousness of loops.
1062 int count = 0;
1063 for (int j = 0; j < static_cast<int>(order->size()); j++) {
1064 BasicBlock* block = order->at(j);
1065 DCHECK(block->rpo_number() == j);
1066 if (j < header->rpo_number() || j >= end->rpo_number()) {
1067 DCHECK(!header->LoopContains(block));
1068 } else {
1069 DCHECK(header->LoopContains(block));
1070 DCHECK_GE(block->loop_depth(), loop_depth);
1071 count++;
1072 }
1073 }
1074 DCHECK(links == count);
1075 }
1076 }
1077 #endif // DEBUG
1078
1079 Zone* zone_;
1080 Schedule* schedule_;
1081 BasicBlock* order_;
1082 BasicBlock* beyond_end_;
1083 ZoneVector<LoopInfo> loops_;
1084 ZoneVector<Backedge> backedges_;
1085 ZoneVector<SpecialRPOStackFrame> stack_;
1086 size_t previous_block_count_;
1087 ZoneVector<BasicBlock*> const empty_;
1088 };
1089
1090
ComputeSpecialRPO(Zone * zone,Schedule * schedule)1091 BasicBlockVector* Scheduler::ComputeSpecialRPO(Zone* zone, Schedule* schedule) {
1092 SpecialRPONumberer numberer(zone, schedule);
1093 numberer.ComputeSpecialRPO();
1094 numberer.SerializeRPOIntoSchedule();
1095 numberer.PrintAndVerifySpecialRPO();
1096 return schedule->rpo_order();
1097 }
1098
1099
ComputeSpecialRPONumbering()1100 void Scheduler::ComputeSpecialRPONumbering() {
1101 TRACE("--- COMPUTING SPECIAL RPO ----------------------------------\n");
1102
1103 // Compute the special reverse-post-order for basic blocks.
1104 special_rpo_ = new (zone_) SpecialRPONumberer(zone_, schedule_);
1105 special_rpo_->ComputeSpecialRPO();
1106 }
1107
1108
PropagateImmediateDominators(BasicBlock * block)1109 void Scheduler::PropagateImmediateDominators(BasicBlock* block) {
1110 for (/*nop*/; block != nullptr; block = block->rpo_next()) {
1111 auto pred = block->predecessors().begin();
1112 auto end = block->predecessors().end();
1113 DCHECK(pred != end); // All blocks except start have predecessors.
1114 BasicBlock* dominator = *pred;
1115 bool deferred = dominator->deferred();
1116 // For multiple predecessors, walk up the dominator tree until a common
1117 // dominator is found. Visitation order guarantees that all predecessors
1118 // except for backwards edges have been visited.
1119 for (++pred; pred != end; ++pred) {
1120 // Don't examine backwards edges.
1121 if ((*pred)->dominator_depth() < 0) continue;
1122 dominator = BasicBlock::GetCommonDominator(dominator, *pred);
1123 deferred = deferred & (*pred)->deferred();
1124 }
1125 block->set_dominator(dominator);
1126 block->set_dominator_depth(dominator->dominator_depth() + 1);
1127 block->set_deferred(deferred | block->deferred());
1128 TRACE("Block id:%d's idom is id:%d, depth = %d\n", block->id().ToInt(),
1129 dominator->id().ToInt(), block->dominator_depth());
1130 }
1131 }
1132
1133
GenerateImmediateDominatorTree()1134 void Scheduler::GenerateImmediateDominatorTree() {
1135 TRACE("--- IMMEDIATE BLOCK DOMINATORS -----------------------------\n");
1136
1137 // Seed start block to be the first dominator.
1138 schedule_->start()->set_dominator_depth(0);
1139
1140 // Build the block dominator tree resulting from the above seed.
1141 PropagateImmediateDominators(schedule_->start()->rpo_next());
1142 }
1143
1144
1145 // -----------------------------------------------------------------------------
1146 // Phase 3: Prepare use counts for nodes.
1147
1148
1149 class PrepareUsesVisitor {
1150 public:
PrepareUsesVisitor(Scheduler * scheduler)1151 explicit PrepareUsesVisitor(Scheduler* scheduler)
1152 : scheduler_(scheduler), schedule_(scheduler->schedule_) {}
1153
Pre(Node * node)1154 void Pre(Node* node) {
1155 if (scheduler_->GetPlacement(node) == Scheduler::kFixed) {
1156 // Fixed nodes are always roots for schedule late.
1157 scheduler_->schedule_root_nodes_.push_back(node);
1158 if (!schedule_->IsScheduled(node)) {
1159 // Make sure root nodes are scheduled in their respective blocks.
1160 TRACE("Scheduling fixed position node #%d:%s\n", node->id(),
1161 node->op()->mnemonic());
1162 IrOpcode::Value opcode = node->opcode();
1163 BasicBlock* block =
1164 opcode == IrOpcode::kParameter
1165 ? schedule_->start()
1166 : schedule_->block(NodeProperties::GetControlInput(node));
1167 DCHECK_NOT_NULL(block);
1168 schedule_->AddNode(block, node);
1169 }
1170 }
1171 }
1172
PostEdge(Node * from,int index,Node * to)1173 void PostEdge(Node* from, int index, Node* to) {
1174 // If the edge is from an unscheduled node, then tally it in the use count
1175 // for all of its inputs. The same criterion will be used in ScheduleLate
1176 // for decrementing use counts.
1177 if (!schedule_->IsScheduled(from)) {
1178 DCHECK_NE(Scheduler::kFixed, scheduler_->GetPlacement(from));
1179 scheduler_->IncrementUnscheduledUseCount(to, index, from);
1180 }
1181 }
1182
1183 private:
1184 Scheduler* scheduler_;
1185 Schedule* schedule_;
1186 };
1187
1188
PrepareUses()1189 void Scheduler::PrepareUses() {
1190 TRACE("--- PREPARE USES -------------------------------------------\n");
1191
1192 // Count the uses of every node, which is used to ensure that all of a
1193 // node's uses are scheduled before the node itself.
1194 PrepareUsesVisitor prepare_uses(this);
1195
1196 // TODO(turbofan): simplify the careful pre/post ordering here.
1197 BoolVector visited(graph_->NodeCount(), false, zone_);
1198 ZoneStack<Node::InputEdges::iterator> stack(zone_);
1199 Node* node = graph_->end();
1200 prepare_uses.Pre(node);
1201 visited[node->id()] = true;
1202 stack.push(node->input_edges().begin());
1203 while (!stack.empty()) {
1204 Edge edge = *stack.top();
1205 Node* node = edge.to();
1206 if (visited[node->id()]) {
1207 prepare_uses.PostEdge(edge.from(), edge.index(), edge.to());
1208 if (++stack.top() == edge.from()->input_edges().end()) stack.pop();
1209 } else {
1210 prepare_uses.Pre(node);
1211 visited[node->id()] = true;
1212 if (node->InputCount() > 0) stack.push(node->input_edges().begin());
1213 }
1214 }
1215 }
1216
1217
1218 // -----------------------------------------------------------------------------
1219 // Phase 4: Schedule nodes early.
1220
1221
1222 class ScheduleEarlyNodeVisitor {
1223 public:
ScheduleEarlyNodeVisitor(Zone * zone,Scheduler * scheduler)1224 ScheduleEarlyNodeVisitor(Zone* zone, Scheduler* scheduler)
1225 : scheduler_(scheduler), schedule_(scheduler->schedule_), queue_(zone) {}
1226
1227 // Run the schedule early algorithm on a set of fixed root nodes.
Run(NodeVector * roots)1228 void Run(NodeVector* roots) {
1229 for (Node* const root : *roots) {
1230 queue_.push(root);
1231 while (!queue_.empty()) {
1232 VisitNode(queue_.front());
1233 queue_.pop();
1234 }
1235 }
1236 }
1237
1238 private:
1239 // Visits one node from the queue and propagates its current schedule early
1240 // position to all uses. This in turn might push more nodes onto the queue.
VisitNode(Node * node)1241 void VisitNode(Node* node) {
1242 Scheduler::SchedulerData* data = scheduler_->GetData(node);
1243
1244 // Fixed nodes already know their schedule early position.
1245 if (scheduler_->GetPlacement(node) == Scheduler::kFixed) {
1246 data->minimum_block_ = schedule_->block(node);
1247 TRACE("Fixing #%d:%s minimum_block = id:%d, dominator_depth = %d\n",
1248 node->id(), node->op()->mnemonic(),
1249 data->minimum_block_->id().ToInt(),
1250 data->minimum_block_->dominator_depth());
1251 }
1252
1253 // No need to propagate unconstrained schedule early positions.
1254 if (data->minimum_block_ == schedule_->start()) return;
1255
1256 // Propagate schedule early position.
1257 DCHECK_NOT_NULL(data->minimum_block_);
1258 for (auto use : node->uses()) {
1259 PropagateMinimumPositionToNode(data->minimum_block_, use);
1260 }
1261 }
1262
1263 // Propagates {block} as another minimum position into the given {node}. This
1264 // has the net effect of computing the minimum dominator block of {node} that
1265 // still post-dominates all inputs to {node} when the queue is processed.
PropagateMinimumPositionToNode(BasicBlock * block,Node * node)1266 void PropagateMinimumPositionToNode(BasicBlock* block, Node* node) {
1267 Scheduler::SchedulerData* data = scheduler_->GetData(node);
1268
1269 // No need to propagate to fixed node, it's guaranteed to be a root.
1270 if (scheduler_->GetPlacement(node) == Scheduler::kFixed) return;
1271
1272 // Coupled nodes influence schedule early position of their control.
1273 if (scheduler_->GetPlacement(node) == Scheduler::kCoupled) {
1274 Node* control = NodeProperties::GetControlInput(node);
1275 PropagateMinimumPositionToNode(block, control);
1276 }
1277
1278 // Propagate new position if it is deeper down the dominator tree than the
1279 // current. Note that all inputs need to have minimum block position inside
1280 // the dominator chain of {node}'s minimum block position.
1281 DCHECK(InsideSameDominatorChain(block, data->minimum_block_));
1282 if (block->dominator_depth() > data->minimum_block_->dominator_depth()) {
1283 data->minimum_block_ = block;
1284 queue_.push(node);
1285 TRACE("Propagating #%d:%s minimum_block = id:%d, dominator_depth = %d\n",
1286 node->id(), node->op()->mnemonic(),
1287 data->minimum_block_->id().ToInt(),
1288 data->minimum_block_->dominator_depth());
1289 }
1290 }
1291
1292 #if DEBUG
InsideSameDominatorChain(BasicBlock * b1,BasicBlock * b2)1293 bool InsideSameDominatorChain(BasicBlock* b1, BasicBlock* b2) {
1294 BasicBlock* dominator = BasicBlock::GetCommonDominator(b1, b2);
1295 return dominator == b1 || dominator == b2;
1296 }
1297 #endif
1298
1299 Scheduler* scheduler_;
1300 Schedule* schedule_;
1301 ZoneQueue<Node*> queue_;
1302 };
1303
1304
ScheduleEarly()1305 void Scheduler::ScheduleEarly() {
1306 TRACE("--- SCHEDULE EARLY -----------------------------------------\n");
1307 if (FLAG_trace_turbo_scheduler) {
1308 TRACE("roots: ");
1309 for (Node* node : schedule_root_nodes_) {
1310 TRACE("#%d:%s ", node->id(), node->op()->mnemonic());
1311 }
1312 TRACE("\n");
1313 }
1314
1315 // Compute the minimum block for each node thereby determining the earliest
1316 // position each node could be placed within a valid schedule.
1317 ScheduleEarlyNodeVisitor schedule_early_visitor(zone_, this);
1318 schedule_early_visitor.Run(&schedule_root_nodes_);
1319 }
1320
1321
1322 // -----------------------------------------------------------------------------
1323 // Phase 5: Schedule nodes late.
1324
1325
1326 class ScheduleLateNodeVisitor {
1327 public:
ScheduleLateNodeVisitor(Zone * zone,Scheduler * scheduler)1328 ScheduleLateNodeVisitor(Zone* zone, Scheduler* scheduler)
1329 : scheduler_(scheduler),
1330 schedule_(scheduler_->schedule_),
1331 marked_(scheduler->zone_),
1332 marking_queue_(scheduler->zone_) {}
1333
1334 // Run the schedule late algorithm on a set of fixed root nodes.
Run(NodeVector * roots)1335 void Run(NodeVector* roots) {
1336 for (Node* const root : *roots) {
1337 ProcessQueue(root);
1338 }
1339 }
1340
1341 private:
ProcessQueue(Node * root)1342 void ProcessQueue(Node* root) {
1343 ZoneQueue<Node*>* queue = &(scheduler_->schedule_queue_);
1344 for (Node* node : root->inputs()) {
1345 // Don't schedule coupled nodes on their own.
1346 if (scheduler_->GetPlacement(node) == Scheduler::kCoupled) {
1347 node = NodeProperties::GetControlInput(node);
1348 }
1349
1350 // Test schedulability condition by looking at unscheduled use count.
1351 if (scheduler_->GetData(node)->unscheduled_count_ != 0) continue;
1352
1353 queue->push(node);
1354 do {
1355 Node* const node = queue->front();
1356 queue->pop();
1357 VisitNode(node);
1358 } while (!queue->empty());
1359 }
1360 }
1361
1362 // Visits one node from the queue of schedulable nodes and determines its
1363 // schedule late position. Also hoists nodes out of loops to find a more
1364 // optimal scheduling position.
VisitNode(Node * node)1365 void VisitNode(Node* node) {
1366 DCHECK_EQ(0, scheduler_->GetData(node)->unscheduled_count_);
1367
1368 // Don't schedule nodes that are already scheduled.
1369 if (schedule_->IsScheduled(node)) return;
1370 DCHECK_EQ(Scheduler::kSchedulable, scheduler_->GetPlacement(node));
1371
1372 // Determine the dominating block for all of the uses of this node. It is
1373 // the latest block that this node can be scheduled in.
1374 TRACE("Scheduling #%d:%s\n", node->id(), node->op()->mnemonic());
1375 BasicBlock* block = GetCommonDominatorOfUses(node);
1376 DCHECK_NOT_NULL(block);
1377
1378 // The schedule early block dominates the schedule late block.
1379 BasicBlock* min_block = scheduler_->GetData(node)->minimum_block_;
1380 DCHECK_EQ(min_block, BasicBlock::GetCommonDominator(block, min_block));
1381 TRACE(
1382 "Schedule late of #%d:%s is id:%d at loop depth %d, minimum = id:%d\n",
1383 node->id(), node->op()->mnemonic(), block->id().ToInt(),
1384 block->loop_depth(), min_block->id().ToInt());
1385
1386 // Hoist nodes out of loops if possible. Nodes can be hoisted iteratively
1387 // into enclosing loop pre-headers until they would preceed their schedule
1388 // early position.
1389 BasicBlock* hoist_block = GetHoistBlock(block);
1390 if (hoist_block &&
1391 hoist_block->dominator_depth() >= min_block->dominator_depth()) {
1392 do {
1393 TRACE(" hoisting #%d:%s to block id:%d\n", node->id(),
1394 node->op()->mnemonic(), hoist_block->id().ToInt());
1395 DCHECK_LT(hoist_block->loop_depth(), block->loop_depth());
1396 block = hoist_block;
1397 hoist_block = GetHoistBlock(hoist_block);
1398 } while (hoist_block &&
1399 hoist_block->dominator_depth() >= min_block->dominator_depth());
1400 } else if (scheduler_->flags_ & Scheduler::kSplitNodes) {
1401 // Split the {node} if beneficial and return the new {block} for it.
1402 block = SplitNode(block, node);
1403 }
1404
1405 // Schedule the node or a floating control structure.
1406 if (IrOpcode::IsMergeOpcode(node->opcode())) {
1407 ScheduleFloatingControl(block, node);
1408 } else if (node->opcode() == IrOpcode::kFinishRegion) {
1409 ScheduleRegion(block, node);
1410 } else {
1411 ScheduleNode(block, node);
1412 }
1413 }
1414
1415 // Mark {block} and push its non-marked predecessor on the marking queue.
MarkBlock(BasicBlock * block)1416 void MarkBlock(BasicBlock* block) {
1417 DCHECK_LT(block->id().ToSize(), marked_.size());
1418 marked_[block->id().ToSize()] = true;
1419 for (BasicBlock* pred_block : block->predecessors()) {
1420 DCHECK_LT(pred_block->id().ToSize(), marked_.size());
1421 if (marked_[pred_block->id().ToSize()]) continue;
1422 marking_queue_.push_back(pred_block);
1423 }
1424 }
1425
SplitNode(BasicBlock * block,Node * node)1426 BasicBlock* SplitNode(BasicBlock* block, Node* node) {
1427 // For now, we limit splitting to pure nodes.
1428 if (!node->op()->HasProperty(Operator::kPure)) return block;
1429 // TODO(titzer): fix the special case of splitting of projections.
1430 if (node->opcode() == IrOpcode::kProjection) return block;
1431
1432 // The {block} is common dominator of all uses of {node}, so we cannot
1433 // split anything unless the {block} has at least two successors.
1434 DCHECK_EQ(block, GetCommonDominatorOfUses(node));
1435 if (block->SuccessorCount() < 2) return block;
1436
1437 // Clear marking bits.
1438 DCHECK(marking_queue_.empty());
1439 std::fill(marked_.begin(), marked_.end(), false);
1440 marked_.resize(schedule_->BasicBlockCount() + 1, false);
1441
1442 // Check if the {node} has uses in {block}.
1443 for (Edge edge : node->use_edges()) {
1444 BasicBlock* use_block = GetBlockForUse(edge);
1445 if (use_block == nullptr || marked_[use_block->id().ToSize()]) continue;
1446 if (use_block == block) {
1447 TRACE(" not splitting #%d:%s, it is used in id:%d\n", node->id(),
1448 node->op()->mnemonic(), block->id().ToInt());
1449 marking_queue_.clear();
1450 return block;
1451 }
1452 MarkBlock(use_block);
1453 }
1454
1455 // Compute transitive marking closure; a block is marked if all its
1456 // successors are marked.
1457 do {
1458 BasicBlock* top_block = marking_queue_.front();
1459 marking_queue_.pop_front();
1460 if (marked_[top_block->id().ToSize()]) continue;
1461 bool marked = true;
1462 for (BasicBlock* successor : top_block->successors()) {
1463 if (!marked_[successor->id().ToSize()]) {
1464 marked = false;
1465 break;
1466 }
1467 }
1468 if (marked) MarkBlock(top_block);
1469 } while (!marking_queue_.empty());
1470
1471 // If the (common dominator) {block} is marked, we know that all paths from
1472 // {block} to the end contain at least one use of {node}, and hence there's
1473 // no point in splitting the {node} in this case.
1474 if (marked_[block->id().ToSize()]) {
1475 TRACE(" not splitting #%d:%s, its common dominator id:%d is perfect\n",
1476 node->id(), node->op()->mnemonic(), block->id().ToInt());
1477 return block;
1478 }
1479
1480 // Split {node} for uses according to the previously computed marking
1481 // closure. Every marking partition has a unique dominator, which get's a
1482 // copy of the {node} with the exception of the first partition, which get's
1483 // the {node} itself.
1484 ZoneMap<BasicBlock*, Node*> dominators(scheduler_->zone_);
1485 for (Edge edge : node->use_edges()) {
1486 BasicBlock* use_block = GetBlockForUse(edge);
1487 if (use_block == nullptr) continue;
1488 while (marked_[use_block->dominator()->id().ToSize()]) {
1489 use_block = use_block->dominator();
1490 }
1491 auto& use_node = dominators[use_block];
1492 if (use_node == nullptr) {
1493 if (dominators.size() == 1u) {
1494 // Place the {node} at {use_block}.
1495 block = use_block;
1496 use_node = node;
1497 TRACE(" pushing #%d:%s down to id:%d\n", node->id(),
1498 node->op()->mnemonic(), block->id().ToInt());
1499 } else {
1500 // Place a copy of {node} at {use_block}.
1501 use_node = CloneNode(node);
1502 TRACE(" cloning #%d:%s for id:%d\n", use_node->id(),
1503 use_node->op()->mnemonic(), use_block->id().ToInt());
1504 scheduler_->schedule_queue_.push(use_node);
1505 }
1506 }
1507 edge.UpdateTo(use_node);
1508 }
1509 return block;
1510 }
1511
GetHoistBlock(BasicBlock * block)1512 BasicBlock* GetHoistBlock(BasicBlock* block) {
1513 if (block->IsLoopHeader()) return block->dominator();
1514 // We have to check to make sure that the {block} dominates all
1515 // of the outgoing blocks. If it doesn't, then there is a path
1516 // out of the loop which does not execute this {block}, so we
1517 // can't hoist operations from this {block} out of the loop, as
1518 // that would introduce additional computations.
1519 if (BasicBlock* header_block = block->loop_header()) {
1520 for (BasicBlock* outgoing_block :
1521 scheduler_->special_rpo_->GetOutgoingBlocks(header_block)) {
1522 if (BasicBlock::GetCommonDominator(block, outgoing_block) != block) {
1523 return nullptr;
1524 }
1525 }
1526 return header_block->dominator();
1527 }
1528 return nullptr;
1529 }
1530
GetCommonDominatorOfUses(Node * node)1531 BasicBlock* GetCommonDominatorOfUses(Node* node) {
1532 BasicBlock* block = nullptr;
1533 for (Edge edge : node->use_edges()) {
1534 BasicBlock* use_block = GetBlockForUse(edge);
1535 block = block == nullptr
1536 ? use_block
1537 : use_block == nullptr
1538 ? block
1539 : BasicBlock::GetCommonDominator(block, use_block);
1540 }
1541 return block;
1542 }
1543
FindPredecessorBlock(Node * node)1544 BasicBlock* FindPredecessorBlock(Node* node) {
1545 return scheduler_->control_flow_builder_->FindPredecessorBlock(node);
1546 }
1547
GetBlockForUse(Edge edge)1548 BasicBlock* GetBlockForUse(Edge edge) {
1549 // TODO(titzer): ignore uses from dead nodes (not visited in PrepareUses()).
1550 // Dead uses only occur if the graph is not trimmed before scheduling.
1551 Node* use = edge.from();
1552 if (IrOpcode::IsPhiOpcode(use->opcode())) {
1553 // If the use is from a coupled (i.e. floating) phi, compute the common
1554 // dominator of its uses. This will not recurse more than one level.
1555 if (scheduler_->GetPlacement(use) == Scheduler::kCoupled) {
1556 TRACE(" inspecting uses of coupled #%d:%s\n", use->id(),
1557 use->op()->mnemonic());
1558 // TODO(titzer): reenable once above TODO is addressed.
1559 // DCHECK_EQ(edge.to(), NodeProperties::GetControlInput(use));
1560 return GetCommonDominatorOfUses(use);
1561 }
1562 // If the use is from a fixed (i.e. non-floating) phi, we use the
1563 // predecessor block of the corresponding control input to the merge.
1564 if (scheduler_->GetPlacement(use) == Scheduler::kFixed) {
1565 TRACE(" input@%d into a fixed phi #%d:%s\n", edge.index(), use->id(),
1566 use->op()->mnemonic());
1567 Node* merge = NodeProperties::GetControlInput(use, 0);
1568 DCHECK(IrOpcode::IsMergeOpcode(merge->opcode()));
1569 Node* input = NodeProperties::GetControlInput(merge, edge.index());
1570 return FindPredecessorBlock(input);
1571 }
1572 } else if (IrOpcode::IsMergeOpcode(use->opcode())) {
1573 // If the use is from a fixed (i.e. non-floating) merge, we use the
1574 // predecessor block of the current input to the merge.
1575 if (scheduler_->GetPlacement(use) == Scheduler::kFixed) {
1576 TRACE(" input@%d into a fixed merge #%d:%s\n", edge.index(), use->id(),
1577 use->op()->mnemonic());
1578 return FindPredecessorBlock(edge.to());
1579 }
1580 }
1581 BasicBlock* result = schedule_->block(use);
1582 if (result == nullptr) return nullptr;
1583 TRACE(" must dominate use #%d:%s in id:%d\n", use->id(),
1584 use->op()->mnemonic(), result->id().ToInt());
1585 return result;
1586 }
1587
ScheduleFloatingControl(BasicBlock * block,Node * node)1588 void ScheduleFloatingControl(BasicBlock* block, Node* node) {
1589 scheduler_->FuseFloatingControl(block, node);
1590 }
1591
ScheduleRegion(BasicBlock * block,Node * region_end)1592 void ScheduleRegion(BasicBlock* block, Node* region_end) {
1593 // We only allow regions of instructions connected into a linear
1594 // effect chain. The only value allowed to be produced by a node
1595 // in the chain must be the value consumed by the FinishRegion node.
1596
1597 // We schedule back to front; we first schedule FinishRegion.
1598 CHECK_EQ(IrOpcode::kFinishRegion, region_end->opcode());
1599 ScheduleNode(block, region_end);
1600
1601 // Schedule the chain.
1602 Node* node = NodeProperties::GetEffectInput(region_end);
1603 while (node->opcode() != IrOpcode::kBeginRegion) {
1604 DCHECK_EQ(0, scheduler_->GetData(node)->unscheduled_count_);
1605 DCHECK_EQ(1, node->op()->EffectInputCount());
1606 DCHECK_EQ(1, node->op()->EffectOutputCount());
1607 DCHECK_EQ(0, node->op()->ControlOutputCount());
1608 // The value output (if there is any) must be consumed
1609 // by the EndRegion node.
1610 DCHECK(node->op()->ValueOutputCount() == 0 ||
1611 node == region_end->InputAt(0));
1612 ScheduleNode(block, node);
1613 node = NodeProperties::GetEffectInput(node);
1614 }
1615 // Schedule the BeginRegion node.
1616 DCHECK_EQ(0, scheduler_->GetData(node)->unscheduled_count_);
1617 ScheduleNode(block, node);
1618 }
1619
ScheduleNode(BasicBlock * block,Node * node)1620 void ScheduleNode(BasicBlock* block, Node* node) {
1621 schedule_->PlanNode(block, node);
1622 scheduler_->scheduled_nodes_[block->id().ToSize()].push_back(node);
1623 scheduler_->UpdatePlacement(node, Scheduler::kScheduled);
1624 }
1625
CloneNode(Node * node)1626 Node* CloneNode(Node* node) {
1627 int const input_count = node->InputCount();
1628 for (int index = 0; index < input_count; ++index) {
1629 Node* const input = node->InputAt(index);
1630 scheduler_->IncrementUnscheduledUseCount(input, index, node);
1631 }
1632 Node* const copy = scheduler_->graph_->CloneNode(node);
1633 TRACE(("clone #%d:%s -> #%d\n"), node->id(), node->op()->mnemonic(),
1634 copy->id());
1635 scheduler_->node_data_.resize(copy->id() + 1,
1636 scheduler_->DefaultSchedulerData());
1637 scheduler_->node_data_[copy->id()] = scheduler_->node_data_[node->id()];
1638 return copy;
1639 }
1640
1641 Scheduler* scheduler_;
1642 Schedule* schedule_;
1643 BoolVector marked_;
1644 ZoneDeque<BasicBlock*> marking_queue_;
1645 };
1646
1647
ScheduleLate()1648 void Scheduler::ScheduleLate() {
1649 TRACE("--- SCHEDULE LATE ------------------------------------------\n");
1650 if (FLAG_trace_turbo_scheduler) {
1651 TRACE("roots: ");
1652 for (Node* node : schedule_root_nodes_) {
1653 TRACE("#%d:%s ", node->id(), node->op()->mnemonic());
1654 }
1655 TRACE("\n");
1656 }
1657
1658 // Schedule: Places nodes in dominator block of all their uses.
1659 ScheduleLateNodeVisitor schedule_late_visitor(zone_, this);
1660 schedule_late_visitor.Run(&schedule_root_nodes_);
1661 }
1662
1663
1664 // -----------------------------------------------------------------------------
1665 // Phase 6: Seal the final schedule.
1666
1667
SealFinalSchedule()1668 void Scheduler::SealFinalSchedule() {
1669 TRACE("--- SEAL FINAL SCHEDULE ------------------------------------\n");
1670
1671 // Serialize the assembly order and reverse-post-order numbering.
1672 special_rpo_->SerializeRPOIntoSchedule();
1673 special_rpo_->PrintAndVerifySpecialRPO();
1674
1675 // Add collected nodes for basic blocks to their blocks in the right order.
1676 int block_num = 0;
1677 for (NodeVector& nodes : scheduled_nodes_) {
1678 BasicBlock::Id id = BasicBlock::Id::FromInt(block_num++);
1679 BasicBlock* block = schedule_->GetBlockById(id);
1680 for (Node* node : base::Reversed(nodes)) {
1681 schedule_->AddNode(block, node);
1682 }
1683 }
1684 }
1685
1686
1687 // -----------------------------------------------------------------------------
1688
1689
FuseFloatingControl(BasicBlock * block,Node * node)1690 void Scheduler::FuseFloatingControl(BasicBlock* block, Node* node) {
1691 TRACE("--- FUSE FLOATING CONTROL ----------------------------------\n");
1692 if (FLAG_trace_turbo_scheduler) {
1693 OFStream os(stdout);
1694 os << "Schedule before control flow fusion:\n" << *schedule_;
1695 }
1696
1697 // Iterate on phase 1: Build control-flow graph.
1698 control_flow_builder_->Run(block, node);
1699
1700 // Iterate on phase 2: Compute special RPO and dominator tree.
1701 special_rpo_->UpdateSpecialRPO(block, schedule_->block(node));
1702 // TODO(mstarzinger): Currently "iterate on" means "re-run". Fix that.
1703 for (BasicBlock* b = block->rpo_next(); b != nullptr; b = b->rpo_next()) {
1704 b->set_dominator_depth(-1);
1705 b->set_dominator(nullptr);
1706 }
1707 PropagateImmediateDominators(block->rpo_next());
1708
1709 // Iterate on phase 4: Schedule nodes early.
1710 // TODO(mstarzinger): The following loop gathering the propagation roots is a
1711 // temporary solution and should be merged into the rest of the scheduler as
1712 // soon as the approach settled for all floating loops.
1713 NodeVector propagation_roots(control_flow_builder_->control_);
1714 for (Node* node : control_flow_builder_->control_) {
1715 for (Node* use : node->uses()) {
1716 if (NodeProperties::IsPhi(use)) propagation_roots.push_back(use);
1717 }
1718 }
1719 if (FLAG_trace_turbo_scheduler) {
1720 TRACE("propagation roots: ");
1721 for (Node* node : propagation_roots) {
1722 TRACE("#%d:%s ", node->id(), node->op()->mnemonic());
1723 }
1724 TRACE("\n");
1725 }
1726 ScheduleEarlyNodeVisitor schedule_early_visitor(zone_, this);
1727 schedule_early_visitor.Run(&propagation_roots);
1728
1729 // Move previously planned nodes.
1730 // TODO(mstarzinger): Improve that by supporting bulk moves.
1731 scheduled_nodes_.resize(schedule_->BasicBlockCount(), NodeVector(zone_));
1732 MovePlannedNodes(block, schedule_->block(node));
1733
1734 if (FLAG_trace_turbo_scheduler) {
1735 OFStream os(stdout);
1736 os << "Schedule after control flow fusion:\n" << *schedule_;
1737 }
1738 }
1739
1740
MovePlannedNodes(BasicBlock * from,BasicBlock * to)1741 void Scheduler::MovePlannedNodes(BasicBlock* from, BasicBlock* to) {
1742 TRACE("Move planned nodes from id:%d to id:%d\n", from->id().ToInt(),
1743 to->id().ToInt());
1744 NodeVector* nodes = &(scheduled_nodes_[from->id().ToSize()]);
1745 for (Node* const node : *nodes) {
1746 schedule_->SetBlockForNode(to, node);
1747 scheduled_nodes_[to->id().ToSize()].push_back(node);
1748 }
1749 nodes->clear();
1750 }
1751
1752 } // namespace compiler
1753 } // namespace internal
1754 } // namespace v8
1755