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1 // Copyright 2014 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/raw-machine-assembler.h"
6 
7 #include "src/base/small-vector.h"
8 #include "src/compiler/compiler-source-position-table.h"
9 #include "src/compiler/node-properties.h"
10 #include "src/compiler/pipeline.h"
11 #include "src/compiler/scheduler.h"
12 #include "src/heap/factory-inl.h"
13 
14 namespace v8 {
15 namespace internal {
16 namespace compiler {
17 
RawMachineAssembler(Isolate * isolate,Graph * graph,CallDescriptor * call_descriptor,MachineRepresentation word,MachineOperatorBuilder::Flags flags,MachineOperatorBuilder::AlignmentRequirements alignment_requirements,PoisoningMitigationLevel poisoning_level)18 RawMachineAssembler::RawMachineAssembler(
19     Isolate* isolate, Graph* graph, CallDescriptor* call_descriptor,
20     MachineRepresentation word, MachineOperatorBuilder::Flags flags,
21     MachineOperatorBuilder::AlignmentRequirements alignment_requirements,
22     PoisoningMitigationLevel poisoning_level)
23     : isolate_(isolate),
24       graph_(graph),
25       schedule_(zone()->New<Schedule>(zone())),
26       source_positions_(zone()->New<SourcePositionTable>(graph)),
27       machine_(zone(), word, flags, alignment_requirements),
28       common_(zone()),
29       simplified_(zone()),
30       call_descriptor_(call_descriptor),
31       target_parameter_(nullptr),
32       parameters_(parameter_count(), zone()),
33       current_block_(schedule()->start()),
34       poisoning_level_(poisoning_level) {
35   int param_count = static_cast<int>(parameter_count());
36   // Add an extra input for the JSFunction parameter to the start node.
37   graph->SetStart(graph->NewNode(common_.Start(param_count + 1)));
38   if (call_descriptor->IsJSFunctionCall()) {
39     target_parameter_ = AddNode(
40         common()->Parameter(Linkage::kJSCallClosureParamIndex), graph->start());
41   }
42   for (size_t i = 0; i < parameter_count(); ++i) {
43     parameters_[i] =
44         AddNode(common()->Parameter(static_cast<int>(i)), graph->start());
45   }
46   graph->SetEnd(graph->NewNode(common_.End(0)));
47   source_positions_->AddDecorator();
48 }
49 
SetCurrentExternalSourcePosition(FileAndLine file_and_line)50 void RawMachineAssembler::SetCurrentExternalSourcePosition(
51     FileAndLine file_and_line) {
52   int file_id =
53       isolate()->LookupOrAddExternallyCompiledFilename(file_and_line.first);
54   SourcePosition p = SourcePosition::External(file_and_line.second, file_id);
55   DCHECK(p.ExternalLine() == file_and_line.second);
56   source_positions()->SetCurrentPosition(p);
57 }
58 
GetCurrentExternalSourcePosition() const59 FileAndLine RawMachineAssembler::GetCurrentExternalSourcePosition() const {
60   SourcePosition p = source_positions_->GetCurrentPosition();
61   if (!p.IsKnown()) return {nullptr, -1};
62   int file_id = p.ExternalFileId();
63   const char* file_name = isolate()->GetExternallyCompiledFilename(file_id);
64   int line = p.ExternalLine();
65   return {file_name, line};
66 }
67 
NullConstant()68 Node* RawMachineAssembler::NullConstant() {
69   return HeapConstant(isolate()->factory()->null_value());
70 }
71 
UndefinedConstant()72 Node* RawMachineAssembler::UndefinedConstant() {
73   return HeapConstant(isolate()->factory()->undefined_value());
74 }
75 
RelocatableIntPtrConstant(intptr_t value,RelocInfo::Mode rmode)76 Node* RawMachineAssembler::RelocatableIntPtrConstant(intptr_t value,
77                                                      RelocInfo::Mode rmode) {
78   return kSystemPointerSize == 8
79              ? RelocatableInt64Constant(value, rmode)
80              : RelocatableInt32Constant(static_cast<int>(value), rmode);
81 }
82 
OptimizedAllocate(Node * size,AllocationType allocation,AllowLargeObjects allow_large_objects)83 Node* RawMachineAssembler::OptimizedAllocate(
84     Node* size, AllocationType allocation,
85     AllowLargeObjects allow_large_objects) {
86   return AddNode(
87       simplified()->AllocateRaw(Type::Any(), allocation, allow_large_objects),
88       size);
89 }
90 
ExportForTest()91 Schedule* RawMachineAssembler::ExportForTest() {
92   // Compute the correct codegen order.
93   DCHECK(schedule_->rpo_order()->empty());
94   if (FLAG_trace_turbo_scheduler) {
95     PrintF("--- RAW SCHEDULE -------------------------------------------\n");
96     StdoutStream{} << *schedule_;
97   }
98   schedule_->EnsureCFGWellFormedness();
99   Scheduler::ComputeSpecialRPO(zone(), schedule_);
100   schedule_->PropagateDeferredMark();
101   if (FLAG_trace_turbo_scheduler) {
102     PrintF("--- EDGE SPLIT AND PROPAGATED DEFERRED SCHEDULE ------------\n");
103     StdoutStream{} << *schedule_;
104   }
105   // Invalidate RawMachineAssembler.
106   source_positions_->RemoveDecorator();
107   Schedule* schedule = schedule_;
108   schedule_ = nullptr;
109   return schedule;
110 }
111 
ExportForOptimization()112 Graph* RawMachineAssembler::ExportForOptimization() {
113   // Compute the correct codegen order.
114   DCHECK(schedule_->rpo_order()->empty());
115   if (FLAG_trace_turbo_scheduler) {
116     PrintF("--- RAW SCHEDULE -------------------------------------------\n");
117     StdoutStream{} << *schedule_;
118   }
119   schedule_->EnsureCFGWellFormedness();
120   OptimizeControlFlow(schedule_, graph(), common());
121   Scheduler::ComputeSpecialRPO(zone(), schedule_);
122   if (FLAG_trace_turbo_scheduler) {
123     PrintF("--- SCHEDULE BEFORE GRAPH CREATION -------------------------\n");
124     StdoutStream{} << *schedule_;
125   }
126   MakeReschedulable();
127   // Invalidate RawMachineAssembler.
128   schedule_ = nullptr;
129   return graph();
130 }
131 
OptimizeControlFlow(Schedule * schedule,Graph * graph,CommonOperatorBuilder * common)132 void RawMachineAssembler::OptimizeControlFlow(Schedule* schedule, Graph* graph,
133                                               CommonOperatorBuilder* common) {
134   for (bool changed = true; changed;) {
135     changed = false;
136     for (size_t i = 0; i < schedule->all_blocks()->size(); ++i) {
137       BasicBlock* block = (*schedule->all_blocks())[i];
138       if (block == nullptr) continue;
139 
140       // Short-circuit a goto if the succeeding block is not a control-flow
141       // merge. This is not really useful on it's own since graph construction
142       // has the same effect, but combining blocks improves the pattern-match on
143       // their structure below.
144       if (block->control() == BasicBlock::kGoto) {
145         DCHECK_EQ(block->SuccessorCount(), 1);
146         BasicBlock* successor = block->SuccessorAt(0);
147         if (successor->PredecessorCount() == 1) {
148           DCHECK_EQ(successor->PredecessorAt(0), block);
149           for (Node* node : *successor) {
150             schedule->SetBlockForNode(nullptr, node);
151             schedule->AddNode(block, node);
152           }
153           block->set_control(successor->control());
154           Node* control_input = successor->control_input();
155           block->set_control_input(control_input);
156           if (control_input) {
157             schedule->SetBlockForNode(block, control_input);
158           }
159           if (successor->deferred()) block->set_deferred(true);
160           block->ClearSuccessors();
161           schedule->MoveSuccessors(successor, block);
162           schedule->ClearBlockById(successor->id());
163           changed = true;
164           --i;
165           continue;
166         }
167       }
168       // Block-cloning in the simple case where a block consists only of a phi
169       // node and a branch on that phi. This just duplicates the branch block
170       // for each predecessor, replacing the phi node with the corresponding phi
171       // input.
172       if (block->control() == BasicBlock::kBranch && block->NodeCount() == 1) {
173         Node* phi = block->NodeAt(0);
174         if (phi->opcode() != IrOpcode::kPhi) continue;
175         Node* branch = block->control_input();
176         DCHECK_EQ(branch->opcode(), IrOpcode::kBranch);
177         if (NodeProperties::GetValueInput(branch, 0) != phi) continue;
178         if (phi->UseCount() != 1) continue;
179         DCHECK_EQ(phi->op()->ValueInputCount(), block->PredecessorCount());
180 
181         // Turn projection blocks into normal blocks.
182         DCHECK_EQ(block->SuccessorCount(), 2);
183         BasicBlock* true_block = block->SuccessorAt(0);
184         BasicBlock* false_block = block->SuccessorAt(1);
185         DCHECK_EQ(true_block->NodeAt(0)->opcode(), IrOpcode::kIfTrue);
186         DCHECK_EQ(false_block->NodeAt(0)->opcode(), IrOpcode::kIfFalse);
187         (*true_block->begin())->Kill();
188         true_block->RemoveNode(true_block->begin());
189         (*false_block->begin())->Kill();
190         false_block->RemoveNode(false_block->begin());
191         true_block->ClearPredecessors();
192         false_block->ClearPredecessors();
193 
194         size_t arity = block->PredecessorCount();
195         for (size_t i = 0; i < arity; ++i) {
196           BasicBlock* predecessor = block->PredecessorAt(i);
197           predecessor->ClearSuccessors();
198           if (block->deferred()) predecessor->set_deferred(true);
199           Node* branch_clone = graph->CloneNode(branch);
200           int phi_input = static_cast<int>(i);
201           NodeProperties::ReplaceValueInput(
202               branch_clone, NodeProperties::GetValueInput(phi, phi_input), 0);
203           BasicBlock* new_true_block = schedule->NewBasicBlock();
204           BasicBlock* new_false_block = schedule->NewBasicBlock();
205           new_true_block->AddNode(
206               graph->NewNode(common->IfTrue(), branch_clone));
207           new_false_block->AddNode(
208               graph->NewNode(common->IfFalse(), branch_clone));
209           schedule->AddGoto(new_true_block, true_block);
210           schedule->AddGoto(new_false_block, false_block);
211           DCHECK_EQ(predecessor->control(), BasicBlock::kGoto);
212           predecessor->set_control(BasicBlock::kNone);
213           schedule->AddBranch(predecessor, branch_clone, new_true_block,
214                               new_false_block);
215         }
216         branch->Kill();
217         schedule->ClearBlockById(block->id());
218         changed = true;
219         continue;
220       }
221     }
222   }
223 }
224 
MakeReschedulable()225 void RawMachineAssembler::MakeReschedulable() {
226   std::vector<Node*> block_final_control(schedule_->all_blocks_.size());
227   std::vector<Node*> block_final_effect(schedule_->all_blocks_.size());
228 
229   struct LoopHeader {
230     BasicBlock* block;
231     Node* loop_node;
232     Node* effect_phi;
233   };
234   std::vector<LoopHeader> loop_headers;
235 
236   // These are hoisted outside of the loop to avoid re-allocation.
237   std::vector<Node*> merge_inputs;
238   std::vector<Node*> effect_phi_inputs;
239 
240   for (BasicBlock* block : *schedule_->rpo_order()) {
241     Node* current_control;
242     Node* current_effect;
243     if (block == schedule_->start()) {
244       current_control = current_effect = graph()->start();
245     } else if (block == schedule_->end()) {
246       for (size_t i = 0; i < block->PredecessorCount(); ++i) {
247         NodeProperties::MergeControlToEnd(
248             graph(), common(), block->PredecessorAt(i)->control_input());
249       }
250     } else if (block->IsLoopHeader()) {
251       // The graph()->start() inputs are just placeholders until we computed the
252       // real back-edges and re-structure the control flow so the loop has
253       // exactly two predecessors.
254       current_control = graph()->NewNode(common()->Loop(2), graph()->start(),
255                                          graph()->start());
256       current_effect =
257           graph()->NewNode(common()->EffectPhi(2), graph()->start(),
258                            graph()->start(), current_control);
259 
260       Node* terminate = graph()->NewNode(common()->Terminate(), current_effect,
261                                          current_control);
262       NodeProperties::MergeControlToEnd(graph(), common(), terminate);
263       loop_headers.push_back(
264           LoopHeader{block, current_control, current_effect});
265     } else if (block->PredecessorCount() == 1) {
266       BasicBlock* predecessor = block->PredecessorAt(0);
267       DCHECK_LT(predecessor->rpo_number(), block->rpo_number());
268       current_effect = block_final_effect[predecessor->id().ToSize()];
269       current_control = block_final_control[predecessor->id().ToSize()];
270     } else {
271       // Create control merge nodes and effect phis for all predecessor blocks.
272       merge_inputs.clear();
273       effect_phi_inputs.clear();
274       int predecessor_count = static_cast<int>(block->PredecessorCount());
275       for (int i = 0; i < predecessor_count; ++i) {
276         BasicBlock* predecessor = block->PredecessorAt(i);
277         DCHECK_LT(predecessor->rpo_number(), block->rpo_number());
278         merge_inputs.push_back(block_final_control[predecessor->id().ToSize()]);
279         effect_phi_inputs.push_back(
280             block_final_effect[predecessor->id().ToSize()]);
281       }
282       current_control = graph()->NewNode(common()->Merge(predecessor_count),
283                                          static_cast<int>(merge_inputs.size()),
284                                          merge_inputs.data());
285       effect_phi_inputs.push_back(current_control);
286       current_effect = graph()->NewNode(
287           common()->EffectPhi(predecessor_count),
288           static_cast<int>(effect_phi_inputs.size()), effect_phi_inputs.data());
289     }
290 
291     auto update_current_control_and_effect = [&](Node* node) {
292       bool existing_effect_and_control =
293           IrOpcode::IsIfProjectionOpcode(node->opcode()) ||
294           IrOpcode::IsPhiOpcode(node->opcode());
295       if (node->op()->EffectInputCount() > 0) {
296         DCHECK_EQ(1, node->op()->EffectInputCount());
297         if (existing_effect_and_control) {
298           NodeProperties::ReplaceEffectInput(node, current_effect);
299         } else {
300           node->AppendInput(graph()->zone(), current_effect);
301         }
302       }
303       if (node->op()->ControlInputCount() > 0) {
304         DCHECK_EQ(1, node->op()->ControlInputCount());
305         if (existing_effect_and_control) {
306           NodeProperties::ReplaceControlInput(node, current_control);
307         } else {
308           node->AppendInput(graph()->zone(), current_control);
309         }
310       }
311       if (node->op()->EffectOutputCount() > 0) {
312         DCHECK_EQ(1, node->op()->EffectOutputCount());
313         current_effect = node;
314       }
315       if (node->op()->ControlOutputCount() > 0) {
316         current_control = node;
317       }
318     };
319 
320     for (Node* node : *block) {
321       update_current_control_and_effect(node);
322     }
323     if (block->deferred()) MarkControlDeferred(current_control);
324 
325     if (Node* block_terminator = block->control_input()) {
326       update_current_control_and_effect(block_terminator);
327     }
328 
329     block_final_effect[block->id().ToSize()] = current_effect;
330     block_final_control[block->id().ToSize()] = current_control;
331   }
332 
333   // Fix-up loop backedges and re-structure control flow so that loop nodes have
334   // exactly two control predecessors.
335   for (const LoopHeader& loop_header : loop_headers) {
336     BasicBlock* block = loop_header.block;
337     std::vector<BasicBlock*> loop_entries;
338     std::vector<BasicBlock*> loop_backedges;
339     for (size_t i = 0; i < block->PredecessorCount(); ++i) {
340       BasicBlock* predecessor = block->PredecessorAt(i);
341       if (block->LoopContains(predecessor)) {
342         loop_backedges.push_back(predecessor);
343       } else {
344         DCHECK(loop_backedges.empty());
345         loop_entries.push_back(predecessor);
346       }
347     }
348     DCHECK(!loop_entries.empty());
349     DCHECK(!loop_backedges.empty());
350 
351     int entrance_count = static_cast<int>(loop_entries.size());
352     int backedge_count = static_cast<int>(loop_backedges.size());
353     Node* control_loop_entry = CreateNodeFromPredecessors(
354         loop_entries, block_final_control, common()->Merge(entrance_count), {});
355     Node* control_backedge =
356         CreateNodeFromPredecessors(loop_backedges, block_final_control,
357                                    common()->Merge(backedge_count), {});
358     Node* effect_loop_entry = CreateNodeFromPredecessors(
359         loop_entries, block_final_effect, common()->EffectPhi(entrance_count),
360         {control_loop_entry});
361     Node* effect_backedge = CreateNodeFromPredecessors(
362         loop_backedges, block_final_effect, common()->EffectPhi(backedge_count),
363         {control_backedge});
364 
365     loop_header.loop_node->ReplaceInput(0, control_loop_entry);
366     loop_header.loop_node->ReplaceInput(1, control_backedge);
367     loop_header.effect_phi->ReplaceInput(0, effect_loop_entry);
368     loop_header.effect_phi->ReplaceInput(1, effect_backedge);
369 
370     for (Node* node : *block) {
371       if (node->opcode() == IrOpcode::kPhi) {
372         MakePhiBinary(node, static_cast<int>(loop_entries.size()),
373                       control_loop_entry, control_backedge);
374       }
375     }
376   }
377 }
378 
CreateNodeFromPredecessors(const std::vector<BasicBlock * > & predecessors,const std::vector<Node * > & sidetable,const Operator * op,const std::vector<Node * > & additional_inputs)379 Node* RawMachineAssembler::CreateNodeFromPredecessors(
380     const std::vector<BasicBlock*>& predecessors,
381     const std::vector<Node*>& sidetable, const Operator* op,
382     const std::vector<Node*>& additional_inputs) {
383   if (predecessors.size() == 1) {
384     return sidetable[predecessors.front()->id().ToSize()];
385   }
386   std::vector<Node*> inputs;
387   for (BasicBlock* predecessor : predecessors) {
388     inputs.push_back(sidetable[predecessor->id().ToSize()]);
389   }
390   for (Node* additional_input : additional_inputs) {
391     inputs.push_back(additional_input);
392   }
393   return graph()->NewNode(op, static_cast<int>(inputs.size()), inputs.data());
394 }
395 
MakePhiBinary(Node * phi,int split_point,Node * left_control,Node * right_control)396 void RawMachineAssembler::MakePhiBinary(Node* phi, int split_point,
397                                         Node* left_control,
398                                         Node* right_control) {
399   int value_count = phi->op()->ValueInputCount();
400   if (value_count == 2) return;
401   DCHECK_LT(split_point, value_count);
402   DCHECK_GT(split_point, 0);
403 
404   MachineRepresentation rep = PhiRepresentationOf(phi->op());
405   int left_input_count = split_point;
406   int right_input_count = value_count - split_point;
407 
408   Node* left_input;
409   if (left_input_count == 1) {
410     left_input = NodeProperties::GetValueInput(phi, 0);
411   } else {
412     std::vector<Node*> inputs;
413     for (int i = 0; i < left_input_count; ++i) {
414       inputs.push_back(NodeProperties::GetValueInput(phi, i));
415     }
416     inputs.push_back(left_control);
417     left_input =
418         graph()->NewNode(common()->Phi(rep, static_cast<int>(left_input_count)),
419                          static_cast<int>(inputs.size()), inputs.data());
420   }
421 
422   Node* right_input;
423   if (right_input_count == 1) {
424     right_input = NodeProperties::GetValueInput(phi, split_point);
425   } else {
426     std::vector<Node*> inputs;
427     for (int i = split_point; i < value_count; ++i) {
428       inputs.push_back(NodeProperties::GetValueInput(phi, i));
429     }
430     inputs.push_back(right_control);
431     right_input = graph()->NewNode(
432         common()->Phi(rep, static_cast<int>(right_input_count)),
433         static_cast<int>(inputs.size()), inputs.data());
434   }
435 
436   Node* control = NodeProperties::GetControlInput(phi);
437   phi->TrimInputCount(3);
438   phi->ReplaceInput(0, left_input);
439   phi->ReplaceInput(1, right_input);
440   phi->ReplaceInput(2, control);
441   NodeProperties::ChangeOp(phi, common()->Phi(rep, 2));
442 }
443 
MarkControlDeferred(Node * control_node)444 void RawMachineAssembler::MarkControlDeferred(Node* control_node) {
445   BranchHint new_branch_hint;
446   Node* responsible_branch = nullptr;
447   while (responsible_branch == nullptr) {
448     switch (control_node->opcode()) {
449       case IrOpcode::kIfException:
450         // IfException projections are deferred by default.
451         return;
452       case IrOpcode::kIfSuccess:
453         control_node = NodeProperties::GetControlInput(control_node);
454         continue;
455       case IrOpcode::kIfValue: {
456         IfValueParameters parameters = IfValueParametersOf(control_node->op());
457         if (parameters.hint() != BranchHint::kFalse) {
458           NodeProperties::ChangeOp(
459               control_node, common()->IfValue(parameters.value(),
460                                               parameters.comparison_order(),
461                                               BranchHint::kFalse));
462         }
463         return;
464       }
465       case IrOpcode::kIfDefault:
466         if (BranchHintOf(control_node->op()) != BranchHint::kFalse) {
467           NodeProperties::ChangeOp(control_node,
468                                    common()->IfDefault(BranchHint::kFalse));
469         }
470         return;
471       case IrOpcode::kIfTrue: {
472         Node* branch = NodeProperties::GetControlInput(control_node);
473         BranchHint hint = BranchOperatorInfoOf(branch->op()).hint;
474         if (hint == BranchHint::kTrue) {
475           // The other possibility is also deferred, so the responsible branch
476           // has to be before.
477           control_node = NodeProperties::GetControlInput(branch);
478           continue;
479         }
480         new_branch_hint = BranchHint::kFalse;
481         responsible_branch = branch;
482         break;
483       }
484       case IrOpcode::kIfFalse: {
485         Node* branch = NodeProperties::GetControlInput(control_node);
486         BranchHint hint = BranchOperatorInfoOf(branch->op()).hint;
487         if (hint == BranchHint::kFalse) {
488           // The other possibility is also deferred, so the responsible branch
489           // has to be before.
490           control_node = NodeProperties::GetControlInput(branch);
491           continue;
492         }
493         new_branch_hint = BranchHint::kTrue;
494         responsible_branch = branch;
495         break;
496       }
497       case IrOpcode::kMerge:
498         for (int i = 0; i < control_node->op()->ControlInputCount(); ++i) {
499           MarkControlDeferred(NodeProperties::GetControlInput(control_node, i));
500         }
501         return;
502       case IrOpcode::kLoop:
503         control_node = NodeProperties::GetControlInput(control_node, 0);
504         continue;
505       case IrOpcode::kBranch:
506       case IrOpcode::kSwitch:
507         UNREACHABLE();
508       case IrOpcode::kStart:
509         return;
510       default:
511         DCHECK_EQ(1, control_node->op()->ControlInputCount());
512         control_node = NodeProperties::GetControlInput(control_node);
513         continue;
514     }
515   }
516 
517   BranchOperatorInfo info = BranchOperatorInfoOf(responsible_branch->op());
518   if (info.hint == new_branch_hint) return;
519   NodeProperties::ChangeOp(
520       responsible_branch,
521       common()->Branch(new_branch_hint, info.is_safety_check));
522 }
523 
TargetParameter()524 Node* RawMachineAssembler::TargetParameter() {
525   DCHECK_NOT_NULL(target_parameter_);
526   return target_parameter_;
527 }
528 
Parameter(size_t index)529 Node* RawMachineAssembler::Parameter(size_t index) {
530   DCHECK_LT(index, parameter_count());
531   return parameters_[index];
532 }
533 
534 
Goto(RawMachineLabel * label)535 void RawMachineAssembler::Goto(RawMachineLabel* label) {
536   DCHECK(current_block_ != schedule()->end());
537   schedule()->AddGoto(CurrentBlock(), Use(label));
538   current_block_ = nullptr;
539 }
540 
541 
Branch(Node * condition,RawMachineLabel * true_val,RawMachineLabel * false_val)542 void RawMachineAssembler::Branch(Node* condition, RawMachineLabel* true_val,
543                                  RawMachineLabel* false_val) {
544   DCHECK(current_block_ != schedule()->end());
545   Node* branch = MakeNode(
546       common()->Branch(BranchHint::kNone, IsSafetyCheck::kNoSafetyCheck), 1,
547       &condition);
548   BasicBlock* true_block = schedule()->NewBasicBlock();
549   BasicBlock* false_block = schedule()->NewBasicBlock();
550   schedule()->AddBranch(CurrentBlock(), branch, true_block, false_block);
551 
552   true_block->AddNode(MakeNode(common()->IfTrue(), 1, &branch));
553   schedule()->AddGoto(true_block, Use(true_val));
554 
555   false_block->AddNode(MakeNode(common()->IfFalse(), 1, &branch));
556   schedule()->AddGoto(false_block, Use(false_val));
557 
558   current_block_ = nullptr;
559 }
560 
Continuations(Node * call,RawMachineLabel * if_success,RawMachineLabel * if_exception)561 void RawMachineAssembler::Continuations(Node* call, RawMachineLabel* if_success,
562                                         RawMachineLabel* if_exception) {
563   DCHECK_NOT_NULL(schedule_);
564   DCHECK_NOT_NULL(current_block_);
565   schedule()->AddCall(CurrentBlock(), call, Use(if_success), Use(if_exception));
566   current_block_ = nullptr;
567 }
568 
Switch(Node * index,RawMachineLabel * default_label,const int32_t * case_values,RawMachineLabel ** case_labels,size_t case_count)569 void RawMachineAssembler::Switch(Node* index, RawMachineLabel* default_label,
570                                  const int32_t* case_values,
571                                  RawMachineLabel** case_labels,
572                                  size_t case_count) {
573   DCHECK_NE(schedule()->end(), current_block_);
574   size_t succ_count = case_count + 1;
575   Node* switch_node = MakeNode(common()->Switch(succ_count), 1, &index);
576   BasicBlock** succ_blocks = zone()->NewArray<BasicBlock*>(succ_count);
577   for (size_t index = 0; index < case_count; ++index) {
578     int32_t case_value = case_values[index];
579     BasicBlock* case_block = schedule()->NewBasicBlock();
580     Node* case_node =
581         graph()->NewNode(common()->IfValue(case_value), switch_node);
582     schedule()->AddNode(case_block, case_node);
583     schedule()->AddGoto(case_block, Use(case_labels[index]));
584     succ_blocks[index] = case_block;
585   }
586   BasicBlock* default_block = schedule()->NewBasicBlock();
587   Node* default_node = graph()->NewNode(common()->IfDefault(), switch_node);
588   schedule()->AddNode(default_block, default_node);
589   schedule()->AddGoto(default_block, Use(default_label));
590   succ_blocks[case_count] = default_block;
591   schedule()->AddSwitch(CurrentBlock(), switch_node, succ_blocks, succ_count);
592   current_block_ = nullptr;
593 }
594 
Return(Node * value)595 void RawMachineAssembler::Return(Node* value) {
596   Node* values[] = {Int32Constant(0), value};
597   Node* ret = MakeNode(common()->Return(1), 2, values);
598   schedule()->AddReturn(CurrentBlock(), ret);
599   current_block_ = nullptr;
600 }
601 
Return(Node * v1,Node * v2)602 void RawMachineAssembler::Return(Node* v1, Node* v2) {
603   Node* values[] = {Int32Constant(0), v1, v2};
604   Node* ret = MakeNode(common()->Return(2), 3, values);
605   schedule()->AddReturn(CurrentBlock(), ret);
606   current_block_ = nullptr;
607 }
608 
Return(Node * v1,Node * v2,Node * v3)609 void RawMachineAssembler::Return(Node* v1, Node* v2, Node* v3) {
610   Node* values[] = {Int32Constant(0), v1, v2, v3};
611   Node* ret = MakeNode(common()->Return(3), 4, values);
612   schedule()->AddReturn(CurrentBlock(), ret);
613   current_block_ = nullptr;
614 }
615 
Return(Node * v1,Node * v2,Node * v3,Node * v4)616 void RawMachineAssembler::Return(Node* v1, Node* v2, Node* v3, Node* v4) {
617   Node* values[] = {Int32Constant(0), v1, v2, v3, v4};
618   Node* ret = MakeNode(common()->Return(4), 5, values);
619   schedule()->AddReturn(CurrentBlock(), ret);
620   current_block_ = nullptr;
621 }
622 
Return(int count,Node * vs[])623 void RawMachineAssembler::Return(int count, Node* vs[]) {
624   using Node_ptr = Node*;
625   Node** values = new Node_ptr[count + 1];
626   values[0] = Int32Constant(0);
627   for (int i = 0; i < count; ++i) values[i + 1] = vs[i];
628   Node* ret = MakeNode(common()->Return(count), count + 1, values);
629   schedule()->AddReturn(CurrentBlock(), ret);
630   current_block_ = nullptr;
631   delete[] values;
632 }
633 
PopAndReturn(Node * pop,Node * value)634 void RawMachineAssembler::PopAndReturn(Node* pop, Node* value) {
635   // PopAndReturn is supposed to be using ONLY in CSA/Torque builtins for
636   // dropping ALL JS arguments that are currently located on the stack.
637   // The check below ensures that there are no directly accessible stack
638   // parameters from current builtin, which implies that the builtin with
639   // JS calling convention (TFJ) was created with kDontAdaptArgumentsSentinel.
640   // This simplifies semantics of this instruction because in case of presence
641   // of directly accessible stack parameters it's impossible to distinguish
642   // the following cases:
643   // 1) stack parameter is included in JS arguments (and therefore it will be
644   //    dropped as a part of 'pop' number of arguments),
645   // 2) stack parameter is NOT included in JS arguments (and therefore it should
646   //    be dropped in ADDITION to the 'pop' number of arguments).
647   // Additionally, in order to simplify assembly code, PopAndReturn is also
648   // not allowed in builtins with stub linkage and parameters on stack.
649   CHECK_EQ(call_descriptor()->StackParameterCount(), 0);
650   Node* values[] = {pop, value};
651   Node* ret = MakeNode(common()->Return(1), 2, values);
652   schedule()->AddReturn(CurrentBlock(), ret);
653   current_block_ = nullptr;
654 }
655 
PopAndReturn(Node * pop,Node * v1,Node * v2)656 void RawMachineAssembler::PopAndReturn(Node* pop, Node* v1, Node* v2) {
657   Node* values[] = {pop, v1, v2};
658   Node* ret = MakeNode(common()->Return(2), 3, values);
659   schedule()->AddReturn(CurrentBlock(), ret);
660   current_block_ = nullptr;
661 }
662 
PopAndReturn(Node * pop,Node * v1,Node * v2,Node * v3)663 void RawMachineAssembler::PopAndReturn(Node* pop, Node* v1, Node* v2,
664                                        Node* v3) {
665   Node* values[] = {pop, v1, v2, v3};
666   Node* ret = MakeNode(common()->Return(3), 4, values);
667   schedule()->AddReturn(CurrentBlock(), ret);
668   current_block_ = nullptr;
669 }
670 
PopAndReturn(Node * pop,Node * v1,Node * v2,Node * v3,Node * v4)671 void RawMachineAssembler::PopAndReturn(Node* pop, Node* v1, Node* v2, Node* v3,
672                                        Node* v4) {
673   Node* values[] = {pop, v1, v2, v3, v4};
674   Node* ret = MakeNode(common()->Return(4), 5, values);
675   schedule()->AddReturn(CurrentBlock(), ret);
676   current_block_ = nullptr;
677 }
678 
AbortCSAAssert(Node * message)679 void RawMachineAssembler::AbortCSAAssert(Node* message) {
680   AddNode(machine()->AbortCSAAssert(), message);
681 }
682 
DebugBreak()683 void RawMachineAssembler::DebugBreak() { AddNode(machine()->DebugBreak()); }
684 
Unreachable()685 void RawMachineAssembler::Unreachable() {
686   Node* ret = MakeNode(common()->Throw(), 0, nullptr);
687   schedule()->AddThrow(CurrentBlock(), ret);
688   current_block_ = nullptr;
689 }
690 
Comment(const std::string & msg)691 void RawMachineAssembler::Comment(const std::string& msg) {
692   size_t length = msg.length() + 1;
693   char* zone_buffer = zone()->NewArray<char>(length);
694   MemCopy(zone_buffer, msg.c_str(), length);
695   AddNode(machine()->Comment(zone_buffer));
696 }
697 
StaticAssert(Node * value,const char * source)698 void RawMachineAssembler::StaticAssert(Node* value, const char* source) {
699   AddNode(common()->StaticAssert(source), value);
700 }
701 
CallN(CallDescriptor * call_descriptor,int input_count,Node * const * inputs)702 Node* RawMachineAssembler::CallN(CallDescriptor* call_descriptor,
703                                  int input_count, Node* const* inputs) {
704   DCHECK(!call_descriptor->NeedsFrameState());
705   // +1 is for target.
706   DCHECK_EQ(input_count, call_descriptor->ParameterCount() + 1);
707   return AddNode(common()->Call(call_descriptor), input_count, inputs);
708 }
709 
CallNWithFrameState(CallDescriptor * call_descriptor,int input_count,Node * const * inputs)710 Node* RawMachineAssembler::CallNWithFrameState(CallDescriptor* call_descriptor,
711                                                int input_count,
712                                                Node* const* inputs) {
713   DCHECK(call_descriptor->NeedsFrameState());
714   // +2 is for target and frame state.
715   DCHECK_EQ(input_count, call_descriptor->ParameterCount() + 2);
716   return AddNode(common()->Call(call_descriptor), input_count, inputs);
717 }
718 
TailCallN(CallDescriptor * call_descriptor,int input_count,Node * const * inputs)719 void RawMachineAssembler::TailCallN(CallDescriptor* call_descriptor,
720                                     int input_count, Node* const* inputs) {
721   // +1 is for target.
722   DCHECK_EQ(input_count, call_descriptor->ParameterCount() + 1);
723   Node* tail_call =
724       MakeNode(common()->TailCall(call_descriptor), input_count, inputs);
725   schedule()->AddTailCall(CurrentBlock(), tail_call);
726   current_block_ = nullptr;
727 }
728 
729 namespace {
730 
731 enum FunctionDescriptorMode { kHasFunctionDescriptor, kNoFunctionDescriptor };
732 
CallCFunctionImpl(RawMachineAssembler * rasm,Node * function,MachineType return_type,std::initializer_list<RawMachineAssembler::CFunctionArg> args,bool caller_saved_regs,SaveFPRegsMode mode,FunctionDescriptorMode no_function_descriptor)733 Node* CallCFunctionImpl(
734     RawMachineAssembler* rasm, Node* function, MachineType return_type,
735     std::initializer_list<RawMachineAssembler::CFunctionArg> args,
736     bool caller_saved_regs, SaveFPRegsMode mode,
737     FunctionDescriptorMode no_function_descriptor) {
738   static constexpr std::size_t kNumCArgs = 10;
739 
740   MachineSignature::Builder builder(rasm->zone(), 1, args.size());
741   builder.AddReturn(return_type);
742   for (const auto& arg : args) builder.AddParam(arg.first);
743 
744   bool caller_saved_fp_regs = caller_saved_regs && (mode == kSaveFPRegs);
745   CallDescriptor::Flags flags = CallDescriptor::kNoFlags;
746   if (caller_saved_regs) flags |= CallDescriptor::kCallerSavedRegisters;
747   if (caller_saved_fp_regs) flags |= CallDescriptor::kCallerSavedFPRegisters;
748   if (no_function_descriptor) flags |= CallDescriptor::kNoFunctionDescriptor;
749   auto call_descriptor =
750       Linkage::GetSimplifiedCDescriptor(rasm->zone(), builder.Build(), flags);
751 
752   base::SmallVector<Node*, kNumCArgs> nodes(args.size() + 1);
753   nodes[0] = function;
754   std::transform(
755       args.begin(), args.end(), std::next(nodes.begin()),
756       [](const RawMachineAssembler::CFunctionArg& arg) { return arg.second; });
757 
758   auto common = rasm->common();
759   return rasm->AddNode(common->Call(call_descriptor),
760                        static_cast<int>(nodes.size()), nodes.begin());
761 }
762 
763 }  // namespace
764 
CallCFunction(Node * function,MachineType return_type,std::initializer_list<RawMachineAssembler::CFunctionArg> args)765 Node* RawMachineAssembler::CallCFunction(
766     Node* function, MachineType return_type,
767     std::initializer_list<RawMachineAssembler::CFunctionArg> args) {
768   return CallCFunctionImpl(this, function, return_type, args, false,
769                            kDontSaveFPRegs, kHasFunctionDescriptor);
770 }
771 
CallCFunctionWithoutFunctionDescriptor(Node * function,MachineType return_type,std::initializer_list<RawMachineAssembler::CFunctionArg> args)772 Node* RawMachineAssembler::CallCFunctionWithoutFunctionDescriptor(
773     Node* function, MachineType return_type,
774     std::initializer_list<RawMachineAssembler::CFunctionArg> args) {
775   return CallCFunctionImpl(this, function, return_type, args, false,
776                            kDontSaveFPRegs, kNoFunctionDescriptor);
777 }
778 
CallCFunctionWithCallerSavedRegisters(Node * function,MachineType return_type,SaveFPRegsMode mode,std::initializer_list<RawMachineAssembler::CFunctionArg> args)779 Node* RawMachineAssembler::CallCFunctionWithCallerSavedRegisters(
780     Node* function, MachineType return_type, SaveFPRegsMode mode,
781     std::initializer_list<RawMachineAssembler::CFunctionArg> args) {
782   return CallCFunctionImpl(this, function, return_type, args, true, mode,
783                            kHasFunctionDescriptor);
784 }
785 
Use(RawMachineLabel * label)786 BasicBlock* RawMachineAssembler::Use(RawMachineLabel* label) {
787   label->used_ = true;
788   return EnsureBlock(label);
789 }
790 
EnsureBlock(RawMachineLabel * label)791 BasicBlock* RawMachineAssembler::EnsureBlock(RawMachineLabel* label) {
792   if (label->block_ == nullptr) {
793     label->block_ = schedule()->NewBasicBlock();
794   }
795   return label->block_;
796 }
797 
Bind(RawMachineLabel * label)798 void RawMachineAssembler::Bind(RawMachineLabel* label) {
799   DCHECK_NULL(current_block_);
800   DCHECK(!label->bound_);
801   label->bound_ = true;
802   current_block_ = EnsureBlock(label);
803   current_block_->set_deferred(label->deferred_);
804 }
805 
806 #if DEBUG
Bind(RawMachineLabel * label,AssemblerDebugInfo info)807 void RawMachineAssembler::Bind(RawMachineLabel* label,
808                                AssemblerDebugInfo info) {
809   if (current_block_ != nullptr) {
810     std::stringstream str;
811     str << "Binding label without closing previous block:"
812         << "\n#    label:          " << info
813         << "\n#    previous block: " << *current_block_;
814     FATAL("%s", str.str().c_str());
815   }
816   Bind(label);
817   current_block_->set_debug_info(info);
818 }
819 
PrintCurrentBlock(std::ostream & os)820 void RawMachineAssembler::PrintCurrentBlock(std::ostream& os) {
821   os << CurrentBlock();
822 }
823 
SetInitialDebugInformation(AssemblerDebugInfo debug_info)824 void RawMachineAssembler::SetInitialDebugInformation(
825     AssemblerDebugInfo debug_info) {
826   CurrentBlock()->set_debug_info(debug_info);
827 }
828 #endif  // DEBUG
829 
InsideBlock()830 bool RawMachineAssembler::InsideBlock() { return current_block_ != nullptr; }
831 
CurrentBlock()832 BasicBlock* RawMachineAssembler::CurrentBlock() {
833   DCHECK(current_block_);
834   return current_block_;
835 }
836 
Phi(MachineRepresentation rep,int input_count,Node * const * inputs)837 Node* RawMachineAssembler::Phi(MachineRepresentation rep, int input_count,
838                                Node* const* inputs) {
839   Node** buffer = zone()->NewArray<Node*>(input_count + 1);
840   std::copy(inputs, inputs + input_count, buffer);
841   buffer[input_count] = graph()->start();
842   return AddNode(common()->Phi(rep, input_count), input_count + 1, buffer);
843 }
844 
AppendPhiInput(Node * phi,Node * new_input)845 void RawMachineAssembler::AppendPhiInput(Node* phi, Node* new_input) {
846   const Operator* op = phi->op();
847   const Operator* new_op = common()->ResizeMergeOrPhi(op, phi->InputCount());
848   phi->InsertInput(zone(), phi->InputCount() - 1, new_input);
849   NodeProperties::ChangeOp(phi, new_op);
850 }
851 
AddNode(const Operator * op,int input_count,Node * const * inputs)852 Node* RawMachineAssembler::AddNode(const Operator* op, int input_count,
853                                    Node* const* inputs) {
854   DCHECK_NOT_NULL(schedule_);
855   DCHECK_NOT_NULL(current_block_);
856   Node* node = MakeNode(op, input_count, inputs);
857   schedule()->AddNode(CurrentBlock(), node);
858   return node;
859 }
860 
MakeNode(const Operator * op,int input_count,Node * const * inputs)861 Node* RawMachineAssembler::MakeNode(const Operator* op, int input_count,
862                                     Node* const* inputs) {
863   // The raw machine assembler nodes do not have effect and control inputs,
864   // so we disable checking input counts here.
865   return graph()->NewNodeUnchecked(op, input_count, inputs);
866 }
867 
~RawMachineLabel()868 RawMachineLabel::~RawMachineLabel() {
869 #if DEBUG
870   if (bound_ == used_) return;
871   std::stringstream str;
872   if (bound_) {
873     str << "A label has been bound but it's not used."
874         << "\n#    label: " << *block_;
875   } else {
876     str << "A label has been used but it's not bound.";
877   }
878   FATAL("%s", str.str().c_str());
879 #endif  // DEBUG
880 }
881 
882 }  // namespace compiler
883 }  // namespace internal
884 }  // namespace v8
885