../deps/v8/src/compiler/backend/register-allocator.cc

Bug Summary

File:	out/../deps/v8/src/compiler/backend/register-allocator.cc
Warning:	line 4027, column 25 Value stored to 'rep' during its initialization is never read

Annotated Source Code

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clang -cc1 -cc1 -triple x86_64-unknown-linux-gnu -analyze -disable-free -clear-ast-before-backend -disable-llvm-verifier -discard-value-names -main-file-name register-allocator.cc -analyzer-checker=core -analyzer-checker=apiModeling -analyzer-checker=unix -analyzer-checker=deadcode -analyzer-checker=cplusplus -analyzer-checker=security.insecureAPI.UncheckedReturn -analyzer-checker=security.insecureAPI.getpw -analyzer-checker=security.insecureAPI.gets -analyzer-checker=security.insecureAPI.mktemp -analyzer-checker=security.insecureAPI.mkstemp -analyzer-checker=security.insecureAPI.vfork -analyzer-checker=nullability.NullPassedToNonnull -analyzer-checker=nullability.NullReturnedFromNonnull -analyzer-output plist -w -setup-static-analyzer -mrelocation-model pic -pic-level 2 -pic-is-pie -mframe-pointer=all -relaxed-aliasing -fmath-errno -ffp-contract=on -fno-rounding-math -mconstructor-aliases -funwind-tables=2 -target-cpu x86-64 -tune-cpu generic -debugger-tuning=gdb -ffunction-sections -fdata-sections -fcoverage-compilation-dir=/home/maurizio/node-v18.6.0/out -resource-dir /usr/local/lib/clang/16.0.0 -D _GLIBCXX_USE_CXX11_ABI=1 -D NODE_OPENSSL_CONF_NAME=nodejs_conf -D NODE_OPENSSL_HAS_QUIC -D V8_GYP_BUILD -D V8_TYPED_ARRAY_MAX_SIZE_IN_HEAP=64 -D __STDC_FORMAT_MACROS -D OPENSSL_NO_PINSHARED -D OPENSSL_THREADS -D V8_TARGET_ARCH_X64 -D V8_HAVE_TARGET_OS -D V8_TARGET_OS_LINUX -D V8_EMBEDDER_STRING="-node.8" -D ENABLE_DISASSEMBLER -D V8_PROMISE_INTERNAL_FIELD_COUNT=1 -D V8_SHORT_BUILTIN_CALLS -D OBJECT_PRINT -D V8_INTL_SUPPORT -D V8_ATOMIC_OBJECT_FIELD_WRITES -D V8_ENABLE_LAZY_SOURCE_POSITIONS -D V8_USE_SIPHASH -D V8_SHARED_RO_HEAP -D V8_WIN64_UNWINDING_INFO -D V8_ENABLE_REGEXP_INTERPRETER_THREADED_DISPATCH -D V8_SNAPSHOT_COMPRESSION -D V8_ENABLE_WEBASSEMBLY -D V8_ENABLE_JAVASCRIPT_PROMISE_HOOKS -D V8_ALLOCATION_FOLDING -D V8_ALLOCATION_SITE_TRACKING -D V8_SCRIPTORMODULE_LEGACY_LIFETIME -D V8_ADVANCED_BIGINT_ALGORITHMS -D UCONFIG_NO_SERVICE=1 -D U_ENABLE_DYLOAD=0 -D U_STATIC_IMPLEMENTATION=1 -D U_HAVE_STD_STRING=1 -D UCONFIG_NO_BREAK_ITERATION=0 -I ../deps/v8 -I ../deps/v8/include -I /home/maurizio/node-v18.6.0/out/Release/obj/gen/generate-bytecode-output-root -I /home/maurizio/node-v18.6.0/out/Release/obj/gen -I ../deps/icu-small/source/i18n -I ../deps/icu-small/source/common -internal-isystem /usr/lib/gcc/x86_64-redhat-linux/8/../../../../include/c++/8 -internal-isystem /usr/lib/gcc/x86_64-redhat-linux/8/../../../../include/c++/8/x86_64-redhat-linux -internal-isystem /usr/lib/gcc/x86_64-redhat-linux/8/../../../../include/c++/8/backward -internal-isystem /usr/local/lib/clang/16.0.0/include -internal-isystem /usr/local/include -internal-isystem /usr/lib/gcc/x86_64-redhat-linux/8/../../../../x86_64-redhat-linux/include -internal-externc-isystem /include -internal-externc-isystem /usr/include -O3 -Wno-unused-parameter -Wno-return-type -std=gnu++17 -fdeprecated-macro -fdebug-compilation-dir=/home/maurizio/node-v18.6.0/out -ferror-limit 19 -fno-rtti -fgnuc-version=4.2.1 -vectorize-loops -vectorize-slp -analyzer-output=html -faddrsig -D__GCC_HAVE_DWARF2_CFI_ASM=1 -o /tmp/scan-build-2022-08-22-142216-507842-1 -x c++ ../deps/v8/src/compiler/backend/register-allocator.cc

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/backend/register-allocator.h"
6
7	#include <iomanip>
8
9	#include "src/base/iterator.h"
10	#include "src/base/small-vector.h"
11	#include "src/base/vector.h"
12	#include "src/codegen/assembler-inl.h"
13	#include "src/codegen/tick-counter.h"
14	#include "src/compiler/backend/spill-placer.h"
15	#include "src/compiler/linkage.h"
16	#include "src/strings/string-stream.h"
17
18	namespace v8 {
19	namespace internal {
20	namespace compiler {
21
22	#define TRACE_COND(cond, ...) \
23	do { \
24	if (cond) PrintF(__VA_ARGS__); \
25	} while (false)
26
27	#define TRACE(...) TRACE_COND(data()->is_trace_alloc(), __VA_ARGS__)
28
29	namespace {
30
31	static constexpr int kFloat32Bit =
32	RepresentationBit(MachineRepresentation::kFloat32);
33	static constexpr int kSimd128Bit =
34	RepresentationBit(MachineRepresentation::kSimd128);
35
36
37	const InstructionBlock* GetContainingLoop(const InstructionSequence* sequence,
38	const InstructionBlock* block) {
39	RpoNumber index = block->loop_header();
40	if (!index.IsValid()) return nullptr;
41	return sequence->InstructionBlockAt(index);
42	}
43
44	const InstructionBlock* GetInstructionBlock(const InstructionSequence* code,
45	LifetimePosition pos) {
46	return code->GetInstructionBlock(pos.ToInstructionIndex());
47	}
48
49	Instruction* GetLastInstruction(InstructionSequence* code,
50	const InstructionBlock* block) {
51	return code->InstructionAt(block->last_instruction_index());
52	}
53
54	} // namespace
55
56	void LiveRangeBoundArray::Initialize(Zone* zone, TopLevelLiveRange* range) {
57	size_t max_child_count = range->GetMaxChildCount();
58
59	start_ = zone->NewArray<LiveRangeBound>(max_child_count);
60	length_ = 0;
61	LiveRangeBound* curr = start_;
62	// The primary loop in ResolveControlFlow is not responsible for inserting
63	// connecting moves for spilled ranges.
64	for (LiveRange* i = range; i != nullptr; i = i->next(), ++curr, ++length_) {
65	new (curr) LiveRangeBound(i, i->spilled());
66	}
67	}
68
69	LiveRangeBound* LiveRangeBoundArray::Find(
70	const LifetimePosition position) const {
71	size_t left_index = 0;
72	size_t right_index = length_;
73	while (true) {
74	size_t current_index = left_index + (right_index - left_index) / 2;
75	DCHECK(right_index > current_index)((void) 0);
76	LiveRangeBound* bound = &start_[current_index];
77	if (bound->start_ <= position) {
78	if (position < bound->end_) return bound;
79	DCHECK(left_index < current_index)((void) 0);
80	left_index = current_index;
81	} else {
82	right_index = current_index;
83	}
84	}
85	}
86
87	LiveRangeBound* LiveRangeBoundArray::FindPred(const InstructionBlock* pred) {
88	LifetimePosition pred_end = LifetimePosition::InstructionFromInstructionIndex(
89	pred->last_instruction_index());
90	return Find(pred_end);
91	}
92
93	LiveRangeBound* LiveRangeBoundArray::FindSucc(const InstructionBlock* succ) {
94	LifetimePosition succ_start = LifetimePosition::GapFromInstructionIndex(
95	succ->first_instruction_index());
96	return Find(succ_start);
97	}
98
99	bool LiveRangeBoundArray::FindConnectableSubranges(
100	const InstructionBlock* block, const InstructionBlock* pred,
101	FindResult* result) const {
102	LifetimePosition pred_end = LifetimePosition::InstructionFromInstructionIndex(
103	pred->last_instruction_index());
104	LiveRangeBound* bound = Find(pred_end);
105	result->pred_cover_ = bound->range_;
106	LifetimePosition cur_start = LifetimePosition::GapFromInstructionIndex(
107	block->first_instruction_index());
108
109	if (bound->CanCover(cur_start)) {
110	// Both blocks are covered by the same range, so there is nothing to
111	// connect.
112	return false;
113	}
114	bound = Find(cur_start);
115	if (bound->skip_) {
116	return false;
117	}
118	result->cur_cover_ = bound->range_;
119	DCHECK(result->pred_cover_ != nullptr && result->cur_cover_ != nullptr)((void) 0);
120	return (result->cur_cover_ != result->pred_cover_);
121	}
122
123	LiveRangeFinder::LiveRangeFinder(const TopTierRegisterAllocationData* data,
124	Zone* zone)
125	: data_(data),
126	bounds_length_(static_cast<int>(data_->live_ranges().size())),
127	bounds_(zone->NewArray<LiveRangeBoundArray>(bounds_length_)),
128	zone_(zone) {
129	for (int i = 0; i < bounds_length_; ++i) {
130	new (&bounds_[i]) LiveRangeBoundArray();
131	}
132	}
133
134	LiveRangeBoundArray* LiveRangeFinder::ArrayFor(int operand_index) {
135	DCHECK(operand_index < bounds_length_)((void) 0);
136	TopLevelLiveRange* range = data_->live_ranges()[operand_index];
137	DCHECK(range != nullptr && !range->IsEmpty())((void) 0);
138	DCHECK_EQ(range->vreg(), operand_index)((void) 0);
139	LiveRangeBoundArray* array = &bounds_[operand_index];
140	if (array->ShouldInitialize()) {
141	array->Initialize(zone_, range);
142	}
143	return array;
144	}
145
146	using DelayedInsertionMapKey = std::pair<ParallelMove*, InstructionOperand>;
147
148	struct DelayedInsertionMapCompare {
149	bool operator()(const DelayedInsertionMapKey& a,
150	const DelayedInsertionMapKey& b) const {
151	if (a.first == b.first) {
152	return a.second.Compare(b.second);
153	}
154	return a.first < b.first;
155	}
156	};
157
158	using DelayedInsertionMap = ZoneMap<DelayedInsertionMapKey, InstructionOperand,
159	DelayedInsertionMapCompare>;
160
161	UsePosition::UsePosition(LifetimePosition pos, InstructionOperand* operand,
162	void* hint, UsePositionHintType hint_type)
163	: operand_(operand), hint_(hint), next_(nullptr), pos_(pos), flags_(0) {
164	DCHECK_IMPLIES(hint == nullptr, hint_type == UsePositionHintType::kNone)((void) 0);
165	bool register_beneficial = true;
166	UsePositionType type = UsePositionType::kRegisterOrSlot;
167	if (operand_ != nullptr && operand_->IsUnallocated()) {
168	const UnallocatedOperand* unalloc = UnallocatedOperand::cast(operand_);
169	if (unalloc->HasRegisterPolicy()) {
170	type = UsePositionType::kRequiresRegister;
171	} else if (unalloc->HasSlotPolicy()) {
172	type = UsePositionType::kRequiresSlot;
173	register_beneficial = false;
174	} else if (unalloc->HasRegisterOrSlotOrConstantPolicy()) {
175	type = UsePositionType::kRegisterOrSlotOrConstant;
176	register_beneficial = false;
177	} else {
178	register_beneficial = !unalloc->HasRegisterOrSlotPolicy();
179	}
180	}
181	flags_ = TypeField::encode(type) \| HintTypeField::encode(hint_type) \|
182	RegisterBeneficialField::encode(register_beneficial) \|
183	AssignedRegisterField::encode(kUnassignedRegister);
184	DCHECK(pos_.IsValid())((void) 0);
185	}
186
187	bool UsePosition::HasHint() const {
188	int hint_register;
189	return HintRegister(&hint_register);
190	}
191
192	bool UsePosition::HintRegister(int* register_code) const {
193	if (hint_ == nullptr) return false;
194	switch (HintTypeField::decode(flags_)) {
195	case UsePositionHintType::kNone:
196	case UsePositionHintType::kUnresolved:
197	return false;
198	case UsePositionHintType::kUsePos: {
199	UsePosition* use_pos = reinterpret_cast<UsePosition*>(hint_);
200	int assigned_register = AssignedRegisterField::decode(use_pos->flags_);
201	if (assigned_register == kUnassignedRegister) return false;
202	*register_code = assigned_register;
203	return true;
204	}
205	case UsePositionHintType::kOperand: {
206	InstructionOperand* operand =
207	reinterpret_cast<InstructionOperand*>(hint_);
208	*register_code = LocationOperand::cast(operand)->register_code();
209	return true;
210	}
211	case UsePositionHintType::kPhi: {
212	TopTierRegisterAllocationData::PhiMapValue* phi =
213	reinterpret_cast<TopTierRegisterAllocationData::PhiMapValue*>(hint_);
214	int assigned_register = phi->assigned_register();
215	if (assigned_register == kUnassignedRegister) return false;
216	*register_code = assigned_register;
217	return true;
218	}
219	}
220	UNREACHABLE()V8_Fatal("unreachable code");
221	}
222
223	UsePositionHintType UsePosition::HintTypeForOperand(
224	const InstructionOperand& op) {
225	switch (op.kind()) {
226	case InstructionOperand::CONSTANT:
227	case InstructionOperand::IMMEDIATE:
228	return UsePositionHintType::kNone;
229	case InstructionOperand::UNALLOCATED:
230	return UsePositionHintType::kUnresolved;
231	case InstructionOperand::ALLOCATED:
232	if (op.IsRegister() \|\| op.IsFPRegister()) {
233	return UsePositionHintType::kOperand;
234	} else {
235	DCHECK(op.IsStackSlot() \|\| op.IsFPStackSlot())((void) 0);
236	return UsePositionHintType::kNone;
237	}
238	case InstructionOperand::PENDING:
239	case InstructionOperand::INVALID:
240	break;
241	}
242	UNREACHABLE()V8_Fatal("unreachable code");
243	}
244
245	void UsePosition::SetHint(UsePosition* use_pos) {
246	DCHECK_NOT_NULL(use_pos)((void) 0);
247	hint_ = use_pos;
248	flags_ = HintTypeField::update(flags_, UsePositionHintType::kUsePos);
249	}
250
251	void UsePosition::ResolveHint(UsePosition* use_pos) {
252	DCHECK_NOT_NULL(use_pos)((void) 0);
253	if (HintTypeField::decode(flags_) != UsePositionHintType::kUnresolved) return;
254	hint_ = use_pos;
255	flags_ = HintTypeField::update(flags_, UsePositionHintType::kUsePos);
256	}
257
258	void UsePosition::set_type(UsePositionType type, bool register_beneficial) {
259	DCHECK_IMPLIES(type == UsePositionType::kRequiresSlot, !register_beneficial)((void) 0);
260	DCHECK_EQ(kUnassignedRegister, AssignedRegisterField::decode(flags_))((void) 0);
261	flags_ = TypeField::encode(type) \|
262	RegisterBeneficialField::encode(register_beneficial) \|
263	HintTypeField::encode(HintTypeField::decode(flags_)) \|
264	AssignedRegisterField::encode(kUnassignedRegister);
265	}
266
267	UseInterval* UseInterval::SplitAt(LifetimePosition pos, Zone* zone) {
268	DCHECK(Contains(pos) && pos != start())((void) 0);
269	UseInterval* after = zone->New<UseInterval>(pos, end_);
270	after->next_ = next_;
271	next_ = nullptr;
272	end_ = pos;
273	return after;
274	}
275
276	void LifetimePosition::Print() const { StdoutStream{} << *this << std::endl; }
277
278	std::ostream& operator<<(std::ostream& os, const LifetimePosition pos) {
279	os << '@' << pos.ToInstructionIndex();
280	if (pos.IsGapPosition()) {
281	os << 'g';
282	} else {
283	os << 'i';
284	}
285	if (pos.IsStart()) {
286	os << 's';
287	} else {
288	os << 'e';
289	}
290	return os;
291	}
292
293	LiveRange::LiveRange(int relative_id, MachineRepresentation rep,
294	TopLevelLiveRange* top_level)
295	: relative_id_(relative_id),
296	bits_(0),
297	last_interval_(nullptr),
298	first_interval_(nullptr),
299	first_pos_(nullptr),
300	top_level_(top_level),
301	next_(nullptr),
302	current_interval_(nullptr),
303	last_processed_use_(nullptr),
304	current_hint_position_(nullptr) {
305	DCHECK(AllocatedOperand::IsSupportedRepresentation(rep))((void) 0);
306	bits_ = AssignedRegisterField::encode(kUnassignedRegister) \|
307	RepresentationField::encode(rep) \|
308	ControlFlowRegisterHint::encode(kUnassignedRegister);
309	}
310
311	void LiveRange::VerifyPositions() const {
312	// Walk the positions, verifying that each is in an interval.
313	UseInterval* interval = first_interval_;
314	for (UsePosition* pos = first_pos_; pos != nullptr; pos = pos->next()) {
315	CHECK(Start() <= pos->pos())do { if ((__builtin_expect(!!(!(Start() <= pos->pos())) , 0))) { V8_Fatal("Check failed: %s.", "Start() <= pos->pos()" ); } } while (false);
316	CHECK(pos->pos() <= End())do { if ((__builtin_expect(!!(!(pos->pos() <= End())), 0 ))) { V8_Fatal("Check failed: %s.", "pos->pos() <= End()" ); } } while (false);
317	CHECK_NOT_NULL(interval)do { if ((__builtin_expect(!!(!((interval) != nullptr)), 0))) { V8_Fatal("Check failed: %s.", "(interval) != nullptr"); } } while (false);
318	while (!interval->Contains(pos->pos()) && interval->end() != pos->pos()) {
319	interval = interval->next();
320	CHECK_NOT_NULL(interval)do { if ((__builtin_expect(!!(!((interval) != nullptr)), 0))) { V8_Fatal("Check failed: %s.", "(interval) != nullptr"); } } while (false);
321	}
322	}
323	}
324
325	void LiveRange::VerifyIntervals() const {
326	DCHECK(first_interval()->start() == Start())((void) 0);
327	LifetimePosition last_end = first_interval()->end();
328	for (UseInterval* interval = first_interval()->next(); interval != nullptr;
329	interval = interval->next()) {
330	DCHECK(last_end <= interval->start())((void) 0);
331	last_end = interval->end();
332	}
333	DCHECK(last_end == End())((void) 0);
334	}
335
336	void LiveRange::set_assigned_register(int reg) {
337	DCHECK(!HasRegisterAssigned() && !spilled())((void) 0);
338	bits_ = AssignedRegisterField::update(bits_, reg);
339	}
340
341	void LiveRange::UnsetAssignedRegister() {
342	DCHECK(HasRegisterAssigned() && !spilled())((void) 0);
343	bits_ = AssignedRegisterField::update(bits_, kUnassignedRegister);
344	}
345
346	void LiveRange::AttachToNext() {
347	DCHECK_NOT_NULL(next_)((void) 0);
348	DCHECK_NE(TopLevel()->last_child_covers_, next_)((void) 0);
349	last_interval_->set_next(next_->first_interval());
350	next_->first_interval_ = nullptr;
351	last_interval_ = next_->last_interval_;
352	next_->last_interval_ = nullptr;
353	if (first_pos() == nullptr) {
354	first_pos_ = next_->first_pos();
355	} else {
356	UsePosition* ptr = first_pos_;
357	while (ptr->next() != nullptr) {
358	ptr = ptr->next();
359	}
360	ptr->set_next(next_->first_pos());
361	}
362	next_->first_pos_ = nullptr;
363	LiveRange* old_next = next_;
364	next_ = next_->next_;
365	old_next->next_ = nullptr;
366	}
367
368	void LiveRange::Unspill() {
369	DCHECK(spilled())((void) 0);
370	set_spilled(false);
371	bits_ = AssignedRegisterField::update(bits_, kUnassignedRegister);
372	}
373
374	void LiveRange::Spill() {
375	DCHECK(!spilled())((void) 0);
376	DCHECK(!TopLevel()->HasNoSpillType())((void) 0);
377	set_spilled(true);
378	bits_ = AssignedRegisterField::update(bits_, kUnassignedRegister);
379	}
380
381	RegisterKind LiveRange::kind() const {
382	if (kFPAliasing == AliasingKind::kIndependent &&
383	IsSimd128(representation())) {
384	return RegisterKind::kSimd128;
385	} else {
386	return IsFloatingPoint(representation()) ? RegisterKind::kDouble
387	: RegisterKind::kGeneral;
388	}
389	}
390
391	UsePosition* LiveRange::FirstHintPosition(int* register_index) {
392	if (!first_pos_) return nullptr;
393	if (current_hint_position_) {
394	if (current_hint_position_->pos() < first_pos_->pos()) {
395	current_hint_position_ = first_pos_;
396	}
397	if (current_hint_position_->pos() > End()) {
398	current_hint_position_ = nullptr;
399	}
400	}
401	bool needs_revisit = false;
402	UsePosition* pos = current_hint_position_;
403	for (; pos != nullptr; pos = pos->next()) {
404	if (pos->HintRegister(register_index)) {
405	break;
406	}
407	// Phi and use position hints can be assigned during allocation which
408	// would invalidate the cached hint position. Make sure we revisit them.
409	needs_revisit = needs_revisit \|\|
410	pos->hint_type() == UsePositionHintType::kPhi \|\|
411	pos->hint_type() == UsePositionHintType::kUsePos;
412	}
413	if (!needs_revisit) {
414	current_hint_position_ = pos;
415	}
416	#ifdef DEBUG
417	UsePosition* pos_check = first_pos_;
418	for (; pos_check != nullptr; pos_check = pos_check->next()) {
419	if (pos_check->HasHint()) {
420	break;
421	}
422	}
423	CHECK_EQ(pos, pos_check)do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(pos)>::type, typename ::v8 ::base::pass_value_or_ref<decltype(pos_check)>::type> ((pos), (pos_check)); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal("Check failed: %s.", "pos" " " "==" " " "pos_check" ); } } while (false); } while (false);
424	#endif
425	return pos;
426	}
427
428	UsePosition* LiveRange::NextUsePosition(LifetimePosition start) const {
429	UsePosition* use_pos = last_processed_use_;
430	if (use_pos == nullptr \|\| use_pos->pos() > start) {
431	use_pos = first_pos();
432	}
433	while (use_pos != nullptr && use_pos->pos() < start) {
434	use_pos = use_pos->next();
435	}
436	last_processed_use_ = use_pos;
437	return use_pos;
438	}
439
440	UsePosition* LiveRange::NextUsePositionRegisterIsBeneficial(
441	LifetimePosition start) const {
442	UsePosition* pos = NextUsePosition(start);
443	while (pos != nullptr && !pos->RegisterIsBeneficial()) {
444	pos = pos->next();
445	}
446	return pos;
447	}
448
449	LifetimePosition LiveRange::NextLifetimePositionRegisterIsBeneficial(
450	const LifetimePosition& start) const {
451	UsePosition* next_use = NextUsePositionRegisterIsBeneficial(start);
452	if (next_use == nullptr) return End();
453	return next_use->pos();
454	}
455
456	UsePosition* LiveRange::PreviousUsePositionRegisterIsBeneficial(
457	LifetimePosition start) const {
458	UsePosition* pos = first_pos();
459	UsePosition* prev = nullptr;
460	while (pos != nullptr && pos->pos() < start) {
461	if (pos->RegisterIsBeneficial()) prev = pos;
462	pos = pos->next();
463	}
464	return prev;
465	}
466
467	UsePosition* LiveRange::NextUsePositionSpillDetrimental(
468	LifetimePosition start) const {
469	UsePosition* pos = NextUsePosition(start);
470	while (pos != nullptr && pos->type() != UsePositionType::kRequiresRegister &&
471	!pos->SpillDetrimental()) {
472	pos = pos->next();
473	}
474	return pos;
475	}
476
477	UsePosition* LiveRange::NextRegisterPosition(LifetimePosition start) const {
478	UsePosition* pos = NextUsePosition(start);
479	while (pos != nullptr && pos->type() != UsePositionType::kRequiresRegister) {
480	pos = pos->next();
481	}
482	return pos;
483	}
484
485	bool LiveRange::CanBeSpilled(LifetimePosition pos) const {
486	// We cannot spill a live range that has a use requiring a register
487	// at the current or the immediate next position.
488	UsePosition* use_pos = NextRegisterPosition(pos);
489	if (use_pos == nullptr) return true;
490	return use_pos->pos() > pos.NextStart().End();
491	}
492
493	bool LiveRange::IsTopLevel() const { return top_level_ == this; }
494
495	InstructionOperand LiveRange::GetAssignedOperand() const {
496	DCHECK(!IsEmpty())((void) 0);
497	if (HasRegisterAssigned()) {
498	DCHECK(!spilled())((void) 0);
499	return AllocatedOperand(LocationOperand::REGISTER, representation(),
500	assigned_register());
501	}
502	DCHECK(spilled())((void) 0);
503	DCHECK(!HasRegisterAssigned())((void) 0);
504	if (TopLevel()->HasSpillOperand()) {
505	InstructionOperand* op = TopLevel()->GetSpillOperand();
506	DCHECK(!op->IsUnallocated())((void) 0);
507	return *op;
508	}
509	return TopLevel()->GetSpillRangeOperand();
510	}
511
512	UseInterval* LiveRange::FirstSearchIntervalForPosition(
513	LifetimePosition position) const {
514	if (current_interval_ == nullptr) return first_interval_;
515	if (current_interval_->start() > position) {
516	current_interval_ = nullptr;
517	return first_interval_;
518	}
519	return current_interval_;
520	}
521
522	void LiveRange::AdvanceLastProcessedMarker(
523	UseInterval* to_start_of, LifetimePosition but_not_past) const {
524	if (to_start_of == nullptr) return;
525	if (to_start_of->start() > but_not_past) return;
526	LifetimePosition start = current_interval_ == nullptr
527	? LifetimePosition::Invalid()
528	: current_interval_->start();
529	if (to_start_of->start() > start) {
530	current_interval_ = to_start_of;
531	}
532	}
533
534	LiveRange* LiveRange::SplitAt(LifetimePosition position, Zone* zone) {
535	int new_id = TopLevel()->GetNextChildId();
536	LiveRange* child = zone->New<LiveRange>(new_id, representation(), TopLevel());
537	child->set_bundle(bundle_);
538	// If we split, we do so because we're about to switch registers or move
539	// to/from a slot, so there's no value in connecting hints.
540	DetachAt(position, child, zone, DoNotConnectHints);
541
542	child->top_level_ = TopLevel();
543	child->next_ = next_;
544	next_ = child;
545	return child;
546	}
547
548	UsePosition* LiveRange::DetachAt(LifetimePosition position, LiveRange* result,
549	Zone* zone,
550	HintConnectionOption connect_hints) {
551	DCHECK(Start() < position)((void) 0);
552	DCHECK(End() > position)((void) 0);
553	DCHECK(result->IsEmpty())((void) 0);
554	// Find the last interval that ends before the position. If the
555	// position is contained in one of the intervals in the chain, we
556	// split that interval and use the first part.
557	UseInterval* current = FirstSearchIntervalForPosition(position);
558
559	// If the split position coincides with the beginning of a use interval
560	// we need to split use positons in a special way.
561	bool split_at_start = false;
562
563	if (current->start() == position) {
564	// When splitting at start we need to locate the previous use interval.
565	current = first_interval_;
566	}
567
568	UseInterval* after = nullptr;
569	while (current != nullptr) {
570	if (current->Contains(position)) {
571	after = current->SplitAt(position, zone);
572	break;
573	}
574	UseInterval* next = current->next();
575	if (next->start() >= position) {
576	split_at_start = (next->start() == position);
577	after = next;
578	current->set_next(nullptr);
579	break;
580	}
581	current = next;
582	}
583	DCHECK_NOT_NULL(after)((void) 0);
584
585	// Partition original use intervals to the two live ranges.
586	UseInterval* before = current;
587	result->last_interval_ =
588	(last_interval_ == before)
589	? after // Only interval in the range after split.
590	: last_interval_; // Last interval of the original range.
591	result->first_interval_ = after;
592	last_interval_ = before;
593
594	// Find the last use position before the split and the first use
595	// position after it.
596	UsePosition* use_after = first_pos();
597	UsePosition* use_before = nullptr;
598	if (split_at_start) {
599	// The split position coincides with the beginning of a use interval (the
600	// end of a lifetime hole). Use at this position should be attributed to
601	// the split child because split child owns use interval covering it.
602	while (use_after != nullptr && use_after->pos() < position) {
603	use_before = use_after;
604	use_after = use_after->next();
605	}
606	} else {
607	while (use_after != nullptr && use_after->pos() <= position) {
608	use_before = use_after;
609	use_after = use_after->next();
610	}
611	}
612
613	// Partition original use positions to the two live ranges.
614	if (use_before != nullptr) {
615	use_before->set_next(nullptr);
616	} else {
617	first_pos_ = nullptr;
618	}
619	result->first_pos_ = use_after;
620	result->current_hint_position_ = current_hint_position_;
621
622	// Discard cached iteration state. It might be pointing
623	// to the use that no longer belongs to this live range.
624	last_processed_use_ = nullptr;
625	current_interval_ = nullptr;
626
627	if (connect_hints == ConnectHints && use_before != nullptr &&
628	use_after != nullptr) {
629	use_after->SetHint(use_before);
630	result->current_hint_position_ = use_after;
631	}
632	#ifdef DEBUG
633	VerifyChildStructure();
634	result->VerifyChildStructure();
635	#endif
636	return use_before;
637	}
638
639	void LiveRange::UpdateParentForAllChildren(TopLevelLiveRange* new_top_level) {
640	LiveRange* child = this;
641	for (; child != nullptr; child = child->next()) {
642	child->top_level_ = new_top_level;
643	}
644	}
645
646	void LiveRange::ConvertUsesToOperand(const InstructionOperand& op,
647	const InstructionOperand& spill_op) {
648	for (UsePosition* pos = first_pos(); pos != nullptr; pos = pos->next()) {
649	DCHECK(Start() <= pos->pos() && pos->pos() <= End())((void) 0);
650	if (!pos->HasOperand()) continue;
651	switch (pos->type()) {
652	case UsePositionType::kRequiresSlot:
653	DCHECK(spill_op.IsStackSlot() \|\| spill_op.IsFPStackSlot())((void) 0);
654	InstructionOperand::ReplaceWith(pos->operand(), &spill_op);
655	break;
656	case UsePositionType::kRequiresRegister:
657	DCHECK(op.IsRegister() \|\| op.IsFPRegister())((void) 0);
658	V8_FALLTHROUGH[[clang::fallthrough]];
659	case UsePositionType::kRegisterOrSlot:
660	case UsePositionType::kRegisterOrSlotOrConstant:
661	InstructionOperand::ReplaceWith(pos->operand(), &op);
662	break;
663	}
664	}
665	}
666
667	// This implements an ordering on live ranges so that they are ordered by their
668	// start positions. This is needed for the correctness of the register
669	// allocation algorithm. If two live ranges start at the same offset then there
670	// is a tie breaker based on where the value is first used. This part of the
671	// ordering is merely a heuristic.
672	bool LiveRange::ShouldBeAllocatedBefore(const LiveRange* other) const {
673	LifetimePosition start = Start();
674	LifetimePosition other_start = other->Start();
675	if (start == other_start) {
676	// Prefer register that has a controlflow hint to make sure it gets
677	// allocated first. This allows the control flow aware alloction to
678	// just put ranges back into the queue without other ranges interfering.
679	if (controlflow_hint() < other->controlflow_hint()) {
680	return true;
681	}
682	// The other has a smaller hint.
683	if (controlflow_hint() > other->controlflow_hint()) {
684	return false;
685	}
686	// Both have the same hint or no hint at all. Use first use position.
687	UsePosition* pos = first_pos();
688	UsePosition* other_pos = other->first_pos();
689	// To make the order total, handle the case where both positions are null.
690	if (pos == other_pos) return TopLevel()->vreg() < other->TopLevel()->vreg();
691	if (pos == nullptr) return false;
692	if (other_pos == nullptr) return true;
693	// To make the order total, handle the case where both positions are equal.
694	if (pos->pos() == other_pos->pos())
695	return TopLevel()->vreg() < other->TopLevel()->vreg();
696	return pos->pos() < other_pos->pos();
697	}
698	return start < other_start;
699	}
700
701	void LiveRange::SetUseHints(int register_index) {
702	for (UsePosition* pos = first_pos(); pos != nullptr; pos = pos->next()) {
703	if (!pos->HasOperand()) continue;
704	switch (pos->type()) {
705	case UsePositionType::kRequiresSlot:
706	break;
707	case UsePositionType::kRequiresRegister:
708	case UsePositionType::kRegisterOrSlot:
709	case UsePositionType::kRegisterOrSlotOrConstant:
710	pos->set_assigned_register(register_index);
711	break;
712	}
713	}
714	}
715
716	bool LiveRange::CanCover(LifetimePosition position) const {
717	if (IsEmpty()) return false;
718	return Start() <= position && position < End();
719	}
720
721	bool LiveRange::Covers(LifetimePosition position) const {
722	if (!CanCover(position)) return false;
723	UseInterval* start_search = FirstSearchIntervalForPosition(position);
724	for (UseInterval* interval = start_search; interval != nullptr;
725	interval = interval->next()) {
726	DCHECK(interval->next() == nullptr \|\|((void) 0)
727	interval->next()->start() >= interval->start())((void) 0);
728	AdvanceLastProcessedMarker(interval, position);
729	if (interval->Contains(position)) return true;
730	if (interval->start() > position) return false;
731	}
732	return false;
733	}
734
735	LifetimePosition LiveRange::NextEndAfter(LifetimePosition position) const {
736	UseInterval* start_search = FirstSearchIntervalForPosition(position);
737	while (start_search->end() < position) {
738	start_search = start_search->next();
739	}
740	return start_search->end();
741	}
742
743	LifetimePosition LiveRange::NextStartAfter(LifetimePosition position) {
744	UseInterval* start_search = FirstSearchIntervalForPosition(position);
745	while (start_search->start() < position) {
746	start_search = start_search->next();
747	}
748	next_start_ = start_search->start();
749	return next_start_;
750	}
751
752	LifetimePosition LiveRange::FirstIntersection(LiveRange* other) const {
753	UseInterval* b = other->first_interval();
754	if (b == nullptr) return LifetimePosition::Invalid();
755	LifetimePosition advance_last_processed_up_to = b->start();
756	UseInterval* a = FirstSearchIntervalForPosition(b->start());
757	while (a != nullptr && b != nullptr) {
758	if (a->start() > other->End()) break;
759	if (b->start() > End()) break;
760	LifetimePosition cur_intersection = a->Intersect(b);
761	if (cur_intersection.IsValid()) {
762	return cur_intersection;
763	}
764	if (a->start() < b->start()) {
765	a = a->next();
766	if (a == nullptr \|\| a->start() > other->End()) break;
767	AdvanceLastProcessedMarker(a, advance_last_processed_up_to);
768	} else {
769	b = b->next();
770	}
771	}
772	return LifetimePosition::Invalid();
773	}
774
775	void LiveRange::Print(const RegisterConfiguration* config,
776	bool with_children) const {
777	StdoutStream os;
778	PrintableLiveRange wrapper;
779	wrapper.register_configuration_ = config;
780	for (const LiveRange* i = this; i != nullptr; i = i->next()) {
781	wrapper.range_ = i;
782	os << wrapper << std::endl;
783	if (!with_children) break;
784	}
785	}
786
787	void LiveRange::Print(bool with_children) const {
788	Print(RegisterConfiguration::Default(), with_children);
789	}
790
791	bool LiveRange::RegisterFromBundle(int* hint) const {
792	if (bundle_ == nullptr \|\| bundle_->reg() == kUnassignedRegister) return false;
793	*hint = bundle_->reg();
794	return true;
795	}
796
797	void LiveRange::UpdateBundleRegister(int reg) const {
798	if (bundle_ == nullptr \|\| bundle_->reg() != kUnassignedRegister) return;
799	bundle_->set_reg(reg);
800	}
801
802	struct TopLevelLiveRange::SpillMoveInsertionList : ZoneObject {
803	SpillMoveInsertionList(int gap_index, InstructionOperand* operand,
804	SpillMoveInsertionList* next)
805	: gap_index(gap_index), operand(operand), next(next) {}
806	const int gap_index;
807	InstructionOperand* const operand;
808	SpillMoveInsertionList* next;
809	};
810
811	TopLevelLiveRange::TopLevelLiveRange(int vreg, MachineRepresentation rep)
812	: LiveRange(0, rep, this),
813	vreg_(vreg),
814	last_child_id_(0),
815	spill_operand_(nullptr),
816	spill_move_insertion_locations_(nullptr),
817	spilled_in_deferred_blocks_(false),
818	has_preassigned_slot_(false),
819	spill_start_index_(kMaxInt),
820	last_pos_(nullptr),
821	last_child_covers_(this) {
822	bits_ \|= SpillTypeField::encode(SpillType::kNoSpillType);
823	}
824
825	void TopLevelLiveRange::RecordSpillLocation(Zone* zone, int gap_index,
826	InstructionOperand* operand) {
827	DCHECK(HasNoSpillType())((void) 0);
828	spill_move_insertion_locations_ = zone->New<SpillMoveInsertionList>(
829	gap_index, operand, spill_move_insertion_locations_);
830	}
831
832	void TopLevelLiveRange::CommitSpillMoves(TopTierRegisterAllocationData* data,
833	const InstructionOperand& op) {
834	DCHECK_IMPLIES(op.IsConstant(),((void) 0)
835	GetSpillMoveInsertionLocations(data) == nullptr)((void) 0);
836
837	if (HasGeneralSpillRange()) {
838	SetLateSpillingSelected(false);
839	}
840
841	InstructionSequence* sequence = data->code();
842	Zone* zone = sequence->zone();
843
844	for (SpillMoveInsertionList* to_spill = GetSpillMoveInsertionLocations(data);
845	to_spill != nullptr; to_spill = to_spill->next) {
846	Instruction* instr = sequence->InstructionAt(to_spill->gap_index);
847	ParallelMove* move =
848	instr->GetOrCreateParallelMove(Instruction::START, zone);
849	move->AddMove(*to_spill->operand, op);
850	instr->block()->mark_needs_frame();
851	}
852	}
853
854	void TopLevelLiveRange::FilterSpillMoves(TopTierRegisterAllocationData* data,
855	const InstructionOperand& op) {
856	DCHECK_IMPLIES(op.IsConstant(),((void) 0)
857	GetSpillMoveInsertionLocations(data) == nullptr)((void) 0);
858	bool might_be_duplicated = has_slot_use() \|\| spilled();
859	InstructionSequence* sequence = data->code();
860
861	SpillMoveInsertionList* previous = nullptr;
862	for (SpillMoveInsertionList* to_spill = GetSpillMoveInsertionLocations(data);
863	to_spill != nullptr; previous = to_spill, to_spill = to_spill->next) {
864	Instruction* instr = sequence->InstructionAt(to_spill->gap_index);
865	ParallelMove* move = instr->GetParallelMove(Instruction::START);
866	// Skip insertion if it's possible that the move exists already as a
867	// constraint move from a fixed output register to a slot.
868	bool found = false;
869	if (move != nullptr && (might_be_duplicated \|\| has_preassigned_slot())) {
870	for (MoveOperands* move_op : *move) {
871	if (move_op->IsEliminated()) continue;
872	if (move_op->source().Equals(*to_spill->operand) &&
873	move_op->destination().Equals(op)) {
874	found = true;
875	if (has_preassigned_slot()) move_op->Eliminate();
876	break;
877	}
878	}
879	}
880	if (found \|\| has_preassigned_slot()) {
881	// Remove the item from the list.
882	if (previous == nullptr) {
883	spill_move_insertion_locations_ = to_spill->next;
884	} else {
885	previous->next = to_spill->next;
886	}
887	// Even though this location doesn't need a spill instruction, the
888	// block does require a frame.
889	instr->block()->mark_needs_frame();
890	}
891	}
892	}
893
894	void TopLevelLiveRange::SetSpillOperand(InstructionOperand* operand) {
895	DCHECK(HasNoSpillType())((void) 0);
896	DCHECK(!operand->IsUnallocated() && !operand->IsImmediate())((void) 0);
897	set_spill_type(SpillType::kSpillOperand);
898	spill_operand_ = operand;
899	}
900
901	void TopLevelLiveRange::SetSpillRange(SpillRange* spill_range) {
902	DCHECK(!HasSpillOperand())((void) 0);
903	DCHECK(spill_range)((void) 0);
904	spill_range_ = spill_range;
905	}
906
907	AllocatedOperand TopLevelLiveRange::GetSpillRangeOperand() const {
908	SpillRange* spill_range = GetSpillRange();
909	int index = spill_range->assigned_slot();
910	return AllocatedOperand(LocationOperand::STACK_SLOT, representation(), index);
911	}
912
913	void TopLevelLiveRange::VerifyChildrenInOrder() const {
914	LifetimePosition last_end = End();
915	for (const LiveRange* child = this->next(); child != nullptr;
916	child = child->next()) {
917	DCHECK(last_end <= child->Start())((void) 0);
918	last_end = child->End();
919	}
920	}
921
922	LiveRange* TopLevelLiveRange::GetChildCovers(LifetimePosition pos) {
923	LiveRange* child = last_child_covers_;
924	DCHECK_NE(child, nullptr)((void) 0);
925	if (pos < child->Start()) {
926	// Cached value has advanced too far; start from the top.
927	child = this;
928	}
929	LiveRange* previous_child = nullptr;
930	while (child != nullptr && child->End() <= pos) {
931	previous_child = child;
932	child = child->next();
933	}
934
935	// If we've walked past the end, cache the last child instead. This allows
936	// future calls that are also past the end to be fast, since they will know
937	// that there is no need to reset the search to the beginning.
938	last_child_covers_ = child == nullptr ? previous_child : child;
939
940	return !child \|\| !child->Covers(pos) ? nullptr : child;
941	}
942
943	void TopLevelLiveRange::Verify() const {
944	VerifyChildrenInOrder();
945	for (const LiveRange* child = this; child != nullptr; child = child->next()) {
946	VerifyChildStructure();
947	}
948	}
949
950	void TopLevelLiveRange::ShortenTo(LifetimePosition start, bool trace_alloc) {
951	TRACE_COND(trace_alloc, "Shorten live range %d to [%d\n", vreg(),
952	start.value());
953	DCHECK_NOT_NULL(first_interval_)((void) 0);
954	DCHECK(first_interval_->start() <= start)((void) 0);
955	DCHECK(start < first_interval_->end())((void) 0);
956	first_interval_->set_start(start);
957	}
958
959	void TopLevelLiveRange::EnsureInterval(LifetimePosition start,
960	LifetimePosition end, Zone* zone,
961	bool trace_alloc) {
962	TRACE_COND(trace_alloc, "Ensure live range %d in interval [%d %d[\n", vreg(),
963	start.value(), end.value());
964	LifetimePosition new_end = end;
965	while (first_interval_ != nullptr && first_interval_->start() <= end) {
966	if (first_interval_->end() > end) {
967	new_end = first_interval_->end();
968	}
969	first_interval_ = first_interval_->next();
970	}
971
972	UseInterval* new_interval = zone->New<UseInterval>(start, new_end);
973	new_interval->set_next(first_interval_);
974	first_interval_ = new_interval;
975	if (new_interval->next() == nullptr) {
976	last_interval_ = new_interval;
977	}
978	}
979
980	void TopLevelLiveRange::AddUseInterval(LifetimePosition start,
981	LifetimePosition end, Zone* zone,
982	bool trace_alloc) {
983	TRACE_COND(trace_alloc, "Add to live range %d interval [%d %d[\n", vreg(),
984	start.value(), end.value());
985	if (first_interval_ == nullptr) {
986	UseInterval* interval = zone->New<UseInterval>(start, end);
987	first_interval_ = interval;
988	last_interval_ = interval;
989	} else {
990	if (end == first_interval_->start()) {
991	first_interval_->set_start(start);
992	} else if (end < first_interval_->start()) {
993	UseInterval* interval = zone->New<UseInterval>(start, end);
994	interval->set_next(first_interval_);
995	first_interval_ = interval;
996	} else {
997	// Order of instruction's processing (see ProcessInstructions) guarantees
998	// that each new use interval either precedes, intersects with or touches
999	// the last added interval.
1000	DCHECK(start <= first_interval_->end())((void) 0);
1001	first_interval_->set_start(std::min(start, first_interval_->start()));
1002	first_interval_->set_end(std::max(end, first_interval_->end()));
1003	}
1004	}
1005	}
1006
1007	void TopLevelLiveRange::AddUsePosition(UsePosition* use_pos, bool trace_alloc) {
1008	LifetimePosition pos = use_pos->pos();
1009	TRACE_COND(trace_alloc, "Add to live range %d use position %d\n", vreg(),
1010	pos.value());
1011	UsePosition* prev_hint = nullptr;
1012	UsePosition* prev = nullptr;
1013	UsePosition* current = first_pos_;
1014	while (current != nullptr && current->pos() < pos) {
1015	prev_hint = current->HasHint() ? current : prev_hint;
1016	prev = current;
1017	current = current->next();
1018	}
1019
1020	if (prev == nullptr) {
1021	use_pos->set_next(first_pos_);
1022	first_pos_ = use_pos;
1023	} else {
1024	use_pos->set_next(prev->next());
1025	prev->set_next(use_pos);
1026	}
1027
1028	if (prev_hint == nullptr && use_pos->HasHint()) {
1029	current_hint_position_ = use_pos;
1030	}
1031	}
1032
1033	static bool AreUseIntervalsIntersecting(UseInterval* interval1,
1034	UseInterval* interval2) {
1035	while (interval1 != nullptr && interval2 != nullptr) {
1036	if (interval1->start() < interval2->start()) {
1037	if (interval1->end() > interval2->start()) {
1038	return true;
1039	}
1040	interval1 = interval1->next();
1041	} else {
1042	if (interval2->end() > interval1->start()) {
1043	return true;
1044	}
1045	interval2 = interval2->next();
1046	}
1047	}
1048	return false;
1049	}
1050
1051	std::ostream& operator<<(std::ostream& os,
1052	const PrintableLiveRange& printable_range) {
1053	const LiveRange* range = printable_range.range_;
1054	os << "Range: " << range->TopLevel()->vreg() << ":" << range->relative_id()
1055	<< " ";
1056	if (range->TopLevel()->is_phi()) os << "phi ";
1057	if (range->TopLevel()->is_non_loop_phi()) os << "nlphi ";
1058
1059	os << "{" << std::endl;
1060	UseInterval* interval = range->first_interval();
1061	UsePosition* use_pos = range->first_pos();
1062	while (use_pos != nullptr) {
1063	if (use_pos->HasOperand()) {
1064	os << *use_pos->operand() << use_pos->pos() << " ";
1065	}
1066	use_pos = use_pos->next();
1067	}
1068	os << std::endl;
1069
1070	while (interval != nullptr) {
1071	os << '[' << interval->start() << ", " << interval->end() << ')'
1072	<< std::endl;
1073	interval = interval->next();
1074	}
1075	os << "}";
1076	return os;
1077	}
1078
1079	namespace {
1080	void PrintBlockRow(std::ostream& os, const InstructionBlocks& blocks) {
1081	os << " ";
1082	for (auto block : blocks) {
1083	LifetimePosition start_pos = LifetimePosition::GapFromInstructionIndex(
1084	block->first_instruction_index());
1085	LifetimePosition end_pos = LifetimePosition::GapFromInstructionIndex(
1086	block->last_instruction_index())
1087	.NextFullStart();
1088	int length = end_pos.value() - start_pos.value();
1089	constexpr int kMaxPrefixLength = 32;
1090	char buffer[kMaxPrefixLength];
1091	int rpo_number = block->rpo_number().ToInt();
1092	const char* deferred_marker = block->IsDeferred() ? "(deferred)" : "";
1093	int max_prefix_length = std::min(length, kMaxPrefixLength);
1094	int prefix = snprintf(buffer, max_prefix_length, "[-B%d-%s", rpo_number,
1095	deferred_marker);
1096	os << buffer;
1097	int remaining = length - std::min(prefix, max_prefix_length) - 1;
1098	for (int i = 0; i < remaining; ++i) os << '-';
1099	os << ']';
1100	}
1101	os << '\n';
1102	}
1103	} // namespace
1104
1105	void LinearScanAllocator::PrintRangeRow(std::ostream& os,
1106	const TopLevelLiveRange* toplevel) {
1107	int position = 0;
1108	os << std::setw(3) << toplevel->vreg() << ": ";
1109
1110	const char* kind_string;
1111	switch (toplevel->spill_type()) {
1112	case TopLevelLiveRange::SpillType::kSpillRange:
1113	kind_string = "ss";
1114	break;
1115	case TopLevelLiveRange::SpillType::kDeferredSpillRange:
1116	kind_string = "sd";
1117	break;
1118	case TopLevelLiveRange::SpillType::kSpillOperand:
1119	kind_string = "so";
1120	break;
1121	default:
1122	kind_string = "s?";
1123	}
1124
1125	for (const LiveRange* range = toplevel; range != nullptr;
1126	range = range->next()) {
1127	for (UseInterval* interval = range->first_interval(); interval != nullptr;
1128	interval = interval->next()) {
1129	LifetimePosition start = interval->start();
1130	LifetimePosition end = interval->end();
1131	CHECK_GE(start.value(), position)do { bool _cmp = ::v8::base::CmpGEImpl< typename ::v8::base ::pass_value_or_ref<decltype(start.value())>::type, typename ::v8::base::pass_value_or_ref<decltype(position)>::type >((start.value()), (position)); do { if ((__builtin_expect (!!(!(_cmp)), 0))) { V8_Fatal("Check failed: %s.", "start.value()" " " ">=" " " "position"); } } while (false); } while (false );
1132	for (; start.value() > position; position++) {
1133	os << ' ';
1134	}
1135	int length = end.value() - start.value();
1136	constexpr int kMaxPrefixLength = 32;
1137	char buffer[kMaxPrefixLength];
1138	int max_prefix_length = std::min(length + 1, kMaxPrefixLength);
1139	int prefix;
1140	if (range->spilled()) {
1141	prefix = snprintf(buffer, max_prefix_length, "\|%s", kind_string);
1142	} else {
1143	prefix = snprintf(buffer, max_prefix_length, "\|%s",
1144	RegisterName(range->assigned_register()));
1145	}
1146	os << buffer;
1147	position += std::min(prefix, max_prefix_length - 1);
1148	CHECK_GE(end.value(), position)do { bool _cmp = ::v8::base::CmpGEImpl< typename ::v8::base ::pass_value_or_ref<decltype(end.value())>::type, typename ::v8::base::pass_value_or_ref<decltype(position)>::type >((end.value()), (position)); do { if ((__builtin_expect(! !(!(_cmp)), 0))) { V8_Fatal("Check failed: %s.", "end.value()" " " ">=" " " "position"); } } while (false); } while (false );
1149	const char line_style = range->spilled() ? '-' : '=';
1150	for (; end.value() > position; position++) {
1151	os << line_style;
1152	}
1153	}
1154	}
1155	os << '\n';
1156	}
1157
1158	void LinearScanAllocator::PrintRangeOverview() {
1159	std::ostringstream os;
1160	PrintBlockRow(os, code()->instruction_blocks());
1161	for (auto const toplevel : data()->fixed_live_ranges()) {
1162	if (toplevel == nullptr) continue;
1163	PrintRangeRow(os, toplevel);
1164	}
1165	int rowcount = 0;
1166	for (auto toplevel : data()->live_ranges()) {
1167	if (!CanProcessRange(toplevel)) continue;
1168	if (rowcount++ % 10 == 0) PrintBlockRow(os, code()->instruction_blocks());
1169	PrintRangeRow(os, toplevel);
1170	}
1171	PrintF("%s\n", os.str().c_str());
1172	}
1173
1174	SpillRange::SpillRange(TopLevelLiveRange* parent, Zone* zone)
1175	: live_ranges_(zone),
1176	assigned_slot_(kUnassignedSlot),
1177	byte_width_(ByteWidthForStackSlot(parent->representation())) {
1178	// Spill ranges are created for top level. This is so that, when merging
1179	// decisions are made, we consider the full extent of the virtual register,
1180	// and avoid clobbering it.
1181	UseInterval* result = nullptr;
1182	UseInterval* node = nullptr;
1183	// Copy the intervals for all ranges.
1184	for (LiveRange* range = parent; range != nullptr; range = range->next()) {
1185	UseInterval* src = range->first_interval();
1186	while (src != nullptr) {
1187	UseInterval* new_node = zone->New<UseInterval>(src->start(), src->end());
1188	if (result == nullptr) {
1189	result = new_node;
1190	} else {
1191	node->set_next(new_node);
1192	}
1193	node = new_node;
1194	src = src->next();
1195	}
1196	}
1197	use_interval_ = result;
1198	live_ranges().push_back(parent);
1199	end_position_ = node->end();
1200	parent->SetSpillRange(this);
1201	}
1202
1203	bool SpillRange::IsIntersectingWith(SpillRange* other) const {
1204	if (this->use_interval_ == nullptr \|\| other->use_interval_ == nullptr \|\|
1205	this->End() <= other->use_interval_->start() \|\|
1206	other->End() <= this->use_interval_->start()) {
1207	return false;
1208	}
1209	return AreUseIntervalsIntersecting(use_interval_, other->use_interval_);
1210	}
1211
1212	bool SpillRange::TryMerge(SpillRange* other) {
1213	if (HasSlot() \|\| other->HasSlot()) return false;
1214	if (byte_width() != other->byte_width() \|\| IsIntersectingWith(other))
1215	return false;
1216
1217	LifetimePosition max = LifetimePosition::MaxPosition();
1218	if (End() < other->End() && other->End() != max) {
1219	end_position_ = other->End();
1220	}
1221	other->end_position_ = max;
1222
1223	MergeDisjointIntervals(other->use_interval_);
1224	other->use_interval_ = nullptr;
1225
1226	for (TopLevelLiveRange* range : other->live_ranges()) {
1227	DCHECK(range->GetSpillRange() == other)((void) 0);
1228	range->SetSpillRange(this);
1229	}
1230
1231	live_ranges().insert(live_ranges().end(), other->live_ranges().begin(),
1232	other->live_ranges().end());
1233	other->live_ranges().clear();
1234
1235	return true;
1236	}
1237
1238	void SpillRange::MergeDisjointIntervals(UseInterval* other) {
1239	UseInterval* tail = nullptr;
1240	UseInterval* current = use_interval_;
1241	while (other != nullptr) {
1242	// Make sure the 'current' list starts first
1243	if (current == nullptr \|\| current->start() > other->start()) {
1244	std::swap(current, other);
1245	}
1246	// Check disjointness
1247	DCHECK(other == nullptr \|\| current->end() <= other->start())((void) 0);
1248	// Append the 'current' node to the result accumulator and move forward
1249	if (tail == nullptr) {
1250	use_interval_ = current;
1251	} else {
1252	tail->set_next(current);
1253	}
1254	tail = current;
1255	current = current->next();
1256	}
1257	// Other list is empty => we are done
1258	}
1259
1260	void SpillRange::Print() const {
1261	StdoutStream os;
1262	os << "{" << std::endl;
1263	for (TopLevelLiveRange* range : live_ranges()) {
1264	os << range->vreg() << " ";
1265	}
1266	os << std::endl;
1267
1268	for (UseInterval* i = interval(); i != nullptr; i = i->next()) {
1269	os << '[' << i->start() << ", " << i->end() << ')' << std::endl;
1270	}
1271	os << "}" << std::endl;
1272	}
1273
1274	TopTierRegisterAllocationData::PhiMapValue::PhiMapValue(
1275	PhiInstruction* phi, const InstructionBlock* block, Zone* zone)
1276	: phi_(phi),
1277	block_(block),
1278	incoming_operands_(zone),
1279	assigned_register_(kUnassignedRegister) {
1280	incoming_operands_.reserve(phi->operands().size());
1281	}
1282
1283	void TopTierRegisterAllocationData::PhiMapValue::AddOperand(
1284	InstructionOperand* operand) {
1285	incoming_operands_.push_back(operand);
1286	}
1287
1288	void TopTierRegisterAllocationData::PhiMapValue::CommitAssignment(
1289	const InstructionOperand& assigned) {
1290	for (InstructionOperand* operand : incoming_operands_) {
1291	InstructionOperand::ReplaceWith(operand, &assigned);
1292	}
1293	}
1294
1295	TopTierRegisterAllocationData::TopTierRegisterAllocationData(
1296	const RegisterConfiguration* config, Zone* zone, Frame* frame,
1297	InstructionSequence* code, RegisterAllocationFlags flags,
1298	TickCounter* tick_counter, const char* debug_name)
1299	: RegisterAllocationData(Type::kTopTier),
1300	allocation_zone_(zone),
1301	frame_(frame),
1302	code_(code),
1303	debug_name_(debug_name),
1304	config_(config),
1305	phi_map_(allocation_zone()),
1306	live_in_sets_(code->InstructionBlockCount(), nullptr, allocation_zone()),
1307	live_out_sets_(code->InstructionBlockCount(), nullptr, allocation_zone()),
1308	live_ranges_(code->VirtualRegisterCount() * 2, nullptr,
1309	allocation_zone()),
1310	fixed_live_ranges_(kNumberOfFixedRangesPerRegister *
1311	this->config()->num_general_registers(),
1312	nullptr, allocation_zone()),
1313	fixed_float_live_ranges_(allocation_zone()),
1314	fixed_double_live_ranges_(kNumberOfFixedRangesPerRegister *
1315	this->config()->num_double_registers(),
1316	nullptr, allocation_zone()),
1317	fixed_simd128_live_ranges_(allocation_zone()),
1318	spill_ranges_(code->VirtualRegisterCount(), nullptr, allocation_zone()),
1319	delayed_references_(allocation_zone()),
1320	assigned_registers_(nullptr),
1321	assigned_double_registers_(nullptr),
1322	virtual_register_count_(code->VirtualRegisterCount()),
1323	preassigned_slot_ranges_(zone),
1324	spill_state_(code->InstructionBlockCount(), ZoneVector<LiveRange*>(zone),
1325	zone),
1326	flags_(flags),
1327	tick_counter_(tick_counter),
1328	slot_for_const_range_(zone) {
1329	if (kFPAliasing == AliasingKind::kCombine) {
1330	fixed_float_live_ranges_.resize(
1331	kNumberOfFixedRangesPerRegister * this->config()->num_float_registers(),
1332	nullptr);
1333	fixed_simd128_live_ranges_.resize(
1334	kNumberOfFixedRangesPerRegister *
1335	this->config()->num_simd128_registers(),
1336	nullptr);
1337	} else if (kFPAliasing == AliasingKind::kIndependent) {
1338	fixed_simd128_live_ranges_.resize(
1339	kNumberOfFixedRangesPerRegister *
1340	this->config()->num_simd128_registers(),
1341	nullptr);
1342	}
1343
1344	assigned_registers_ = code_zone()->New<BitVector>(
1345	this->config()->num_general_registers(), code_zone());
1346	assigned_double_registers_ = code_zone()->New<BitVector>(
1347	this->config()->num_double_registers(), code_zone());
1348	fixed_register_use_ = code_zone()->New<BitVector>(
1349	this->config()->num_general_registers(), code_zone());
1350	fixed_fp_register_use_ = code_zone()->New<BitVector>(
1351	this->config()->num_double_registers(), code_zone());
1352	if (kFPAliasing == AliasingKind::kIndependent) {
1353	assigned_simd128_registers_ = code_zone()->New<BitVector>(
1354	this->config()->num_simd128_registers(), code_zone());
1355	fixed_simd128_register_use_ = code_zone()->New<BitVector>(
1356	this->config()->num_simd128_registers(), code_zone());
1357	}
1358
1359	this->frame()->SetAllocatedRegisters(assigned_registers_);
1360	this->frame()->SetAllocatedDoubleRegisters(assigned_double_registers_);
1361	}
1362
1363	MoveOperands* TopTierRegisterAllocationData::AddGapMove(
1364	int index, Instruction::GapPosition position,
1365	const InstructionOperand& from, const InstructionOperand& to) {
1366	Instruction* instr = code()->InstructionAt(index);
1367	ParallelMove* moves = instr->GetOrCreateParallelMove(position, code_zone());
1368	return moves->AddMove(from, to);
1369	}
1370
1371	MachineRepresentation TopTierRegisterAllocationData::RepresentationFor(
1372	int virtual_register) {
1373	DCHECK_LT(virtual_register, code()->VirtualRegisterCount())((void) 0);
1374	return code()->GetRepresentation(virtual_register);
1375	}
1376
1377	TopLevelLiveRange* TopTierRegisterAllocationData::GetOrCreateLiveRangeFor(
1378	int index) {
1379	if (index >= static_cast<int>(live_ranges().size())) {
1380	live_ranges().resize(index + 1, nullptr);
1381	}
1382	TopLevelLiveRange* result = live_ranges()[index];
1383	if (result == nullptr) {
1384	result = NewLiveRange(index, RepresentationFor(index));
1385	live_ranges()[index] = result;
1386	}
1387	DCHECK_EQ(live_ranges()[index]->vreg(), index)((void) 0);
1388	return result;
1389	}
1390
1391	TopLevelLiveRange* TopTierRegisterAllocationData::NewLiveRange(
1392	int index, MachineRepresentation rep) {
1393	return allocation_zone()->New<TopLevelLiveRange>(index, rep);
1394	}
1395
1396	TopTierRegisterAllocationData::PhiMapValue*
1397	TopTierRegisterAllocationData::InitializePhiMap(const InstructionBlock* block,
1398	PhiInstruction* phi) {
1399	TopTierRegisterAllocationData::PhiMapValue* map_value =
1400	allocation_zone()->New<TopTierRegisterAllocationData::PhiMapValue>(
1401	phi, block, allocation_zone());
1402	auto res =
1403	phi_map_.insert(std::make_pair(phi->virtual_register(), map_value));
1404	DCHECK(res.second)((void) 0);
1405	USE(res)do { ::v8::base::Use unused_tmp_array_for_use_macro[]{res}; ( void)unused_tmp_array_for_use_macro; } while (false);
1406	return map_value;
1407	}
1408
1409	TopTierRegisterAllocationData::PhiMapValue*
1410	TopTierRegisterAllocationData::GetPhiMapValueFor(int virtual_register) {
1411	auto it = phi_map_.find(virtual_register);
1412	DCHECK(it != phi_map_.end())((void) 0);
1413	return it->second;
1414	}
1415
1416	TopTierRegisterAllocationData::PhiMapValue*
1417	TopTierRegisterAllocationData::GetPhiMapValueFor(TopLevelLiveRange* top_range) {
1418	return GetPhiMapValueFor(top_range->vreg());
1419	}
1420
1421	bool TopTierRegisterAllocationData::ExistsUseWithoutDefinition() {
1422	bool found = false;
1423	for (int operand_index : *live_in_sets()[0]) {
1424	found = true;
1425	PrintF("Register allocator error: live v%d reached first block.\n",
1426	operand_index);
1427	LiveRange* range = GetOrCreateLiveRangeFor(operand_index);
1428	PrintF(" (first use is at %d)\n", range->first_pos()->pos().value());
1429	if (debug_name() == nullptr) {
1430	PrintF("\n");
1431	} else {
1432	PrintF(" (function: %s)\n", debug_name());
1433	}
1434	}
1435	return found;
1436	}
1437
1438	// If a range is defined in a deferred block, we can expect all the range
1439	// to only cover positions in deferred blocks. Otherwise, a block on the
1440	// hot path would be dominated by a deferred block, meaning it is unreachable
1441	// without passing through the deferred block, which is contradictory.
1442	// In particular, when such a range contributes a result back on the hot
1443	// path, it will be as one of the inputs of a phi. In that case, the value
1444	// will be transferred via a move in the Gap::END's of the last instruction
1445	// of a deferred block.
1446	bool TopTierRegisterAllocationData::RangesDefinedInDeferredStayInDeferred() {
1447	const size_t live_ranges_size = live_ranges().size();
1448	for (const TopLevelLiveRange* range : live_ranges()) {
1449	CHECK_EQ(live_ranges_size,do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(live_ranges().size ())>::type>((live_ranges_size), (live_ranges().size())) ; do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal("Check failed: %s." , "live_ranges_size" " " "==" " " "live_ranges().size()"); } } while (false); } while (false)
1450	live_ranges().size())do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(live_ranges().size ())>::type>((live_ranges_size), (live_ranges().size())) ; do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal("Check failed: %s." , "live_ranges_size" " " "==" " " "live_ranges().size()"); } } while (false); } while (false); // TODO(neis): crbug.com/831822
1451	if (range == nullptr \|\| range->IsEmpty() \|\|
1452	!code()
1453	->GetInstructionBlock(range->Start().ToInstructionIndex())
1454	->IsDeferred()) {
1455	continue;
1456	}
1457	for (const UseInterval* i = range->first_interval(); i != nullptr;
1458	i = i->next()) {
1459	int first = i->FirstGapIndex();
1460	int last = i->LastGapIndex();
1461	for (int instr = first; instr <= last;) {
1462	const InstructionBlock* block = code()->GetInstructionBlock(instr);
1463	if (!block->IsDeferred()) return false;
1464	instr = block->last_instruction_index() + 1;
1465	}
1466	}
1467	}
1468	return true;
1469	}
1470
1471	SpillRange* TopTierRegisterAllocationData::AssignSpillRangeToLiveRange(
1472	TopLevelLiveRange* range, SpillMode spill_mode) {
1473	using SpillType = TopLevelLiveRange::SpillType;
1474	DCHECK(!range->HasSpillOperand())((void) 0);
1475
1476	SpillRange* spill_range = range->GetAllocatedSpillRange();
1477	if (spill_range == nullptr) {
1478	spill_range = allocation_zone()->New<SpillRange>(range, allocation_zone());
1479	}
1480	if (spill_mode == SpillMode::kSpillDeferred &&
1481	(range->spill_type() != SpillType::kSpillRange)) {
1482	range->set_spill_type(SpillType::kDeferredSpillRange);
1483	} else {
1484	range->set_spill_type(SpillType::kSpillRange);
1485	}
1486
1487	spill_ranges()[range->vreg()] = spill_range;
1488	return spill_range;
1489	}
1490
1491	void TopTierRegisterAllocationData::MarkFixedUse(MachineRepresentation rep,
1492	int index) {
1493	switch (rep) {
1494	case MachineRepresentation::kFloat32:
1495	case MachineRepresentation::kSimd128:
1496	if (kFPAliasing == AliasingKind::kOverlap) {
1497	fixed_fp_register_use_->Add(index);
1498	} else if (kFPAliasing == AliasingKind::kIndependent) {
1499	if (rep == MachineRepresentation::kFloat32) {
1500	fixed_fp_register_use_->Add(index);
1501	} else {
1502	fixed_simd128_register_use_->Add(index);
1503	}
1504	} else {
1505	int alias_base_index = -1;
1506	int aliases = config()->GetAliases(
1507	rep, index, MachineRepresentation::kFloat64, &alias_base_index);
1508	DCHECK(aliases > 0 \|\| (aliases == 0 && alias_base_index == -1))((void) 0);
1509	while (aliases--) {
1510	int aliased_reg = alias_base_index + aliases;
1511	fixed_fp_register_use_->Add(aliased_reg);
1512	}
1513	}
1514	break;
1515	case MachineRepresentation::kFloat64:
1516	fixed_fp_register_use_->Add(index);
1517	break;
1518	default:
1519	DCHECK(!IsFloatingPoint(rep))((void) 0);
1520	fixed_register_use_->Add(index);
1521	break;
1522	}
1523	}
1524
1525	bool TopTierRegisterAllocationData::HasFixedUse(MachineRepresentation rep,
1526	int index) {
1527	switch (rep) {
1528	case MachineRepresentation::kFloat32:
1529	case MachineRepresentation::kSimd128: {
1530	if (kFPAliasing == AliasingKind::kOverlap) {
1531	return fixed_fp_register_use_->Contains(index);
1532	} else if (kFPAliasing == AliasingKind::kIndependent) {
1533	if (rep == MachineRepresentation::kFloat32) {
1534	return fixed_fp_register_use_->Contains(index);
1535	} else {
1536	return fixed_simd128_register_use_->Contains(index);
1537	}
1538	} else {
1539	int alias_base_index = -1;
1540	int aliases = config()->GetAliases(
1541	rep, index, MachineRepresentation::kFloat64, &alias_base_index);
1542	DCHECK(aliases > 0 \|\| (aliases == 0 && alias_base_index == -1))((void) 0);
1543	bool result = false;
1544	while (aliases-- && !result) {
1545	int aliased_reg = alias_base_index + aliases;
1546	result \|= fixed_fp_register_use_->Contains(aliased_reg);
1547	}
1548	return result;
1549	}
1550	}
1551	case MachineRepresentation::kFloat64:
1552	return fixed_fp_register_use_->Contains(index);
1553	default:
1554	DCHECK(!IsFloatingPoint(rep))((void) 0);
1555	return fixed_register_use_->Contains(index);
1556	}
1557	}
1558
1559	void TopTierRegisterAllocationData::MarkAllocated(MachineRepresentation rep,
1560	int index) {
1561	switch (rep) {
1562	case MachineRepresentation::kFloat32:
1563	case MachineRepresentation::kSimd128:
1564	if (kFPAliasing == AliasingKind::kOverlap) {
1565	assigned_double_registers_->Add(index);
1566	} else if (kFPAliasing == AliasingKind::kIndependent) {
1567	if (rep == MachineRepresentation::kFloat32) {
1568	assigned_double_registers_->Add(index);
1569	} else {
1570	assigned_simd128_registers_->Add(index);
1571	}
1572	} else {
1573	int alias_base_index = -1;
1574	int aliases = config()->GetAliases(
1575	rep, index, MachineRepresentation::kFloat64, &alias_base_index);
1576	DCHECK(aliases > 0 \|\| (aliases == 0 && alias_base_index == -1))((void) 0);
1577	while (aliases--) {
1578	int aliased_reg = alias_base_index + aliases;
1579	assigned_double_registers_->Add(aliased_reg);
1580	}
1581	}
1582	break;
1583	case MachineRepresentation::kFloat64:
1584	assigned_double_registers_->Add(index);
1585	break;
1586	default:
1587	DCHECK(!IsFloatingPoint(rep))((void) 0);
1588	assigned_registers_->Add(index);
1589	break;
1590	}
1591	}
1592
1593	bool TopTierRegisterAllocationData::IsBlockBoundary(
1594	LifetimePosition pos) const {
1595	return pos.IsFullStart() &&
1596	(static_cast<size_t>(pos.ToInstructionIndex()) ==
1597	code()->instructions().size() \|\|
1598	code()->GetInstructionBlock(pos.ToInstructionIndex())->code_start() ==
1599	pos.ToInstructionIndex());
1600	}
1601
1602	ConstraintBuilder::ConstraintBuilder(TopTierRegisterAllocationData* data)
1603	: data_(data) {}
1604
1605	InstructionOperand* ConstraintBuilder::AllocateFixed(
1606	UnallocatedOperand* operand, int pos, bool is_tagged, bool is_input) {
1607	TRACE("Allocating fixed reg for op %d\n", operand->virtual_register());
1608	DCHECK(operand->HasFixedPolicy())((void) 0);
1609	InstructionOperand allocated;
1610	MachineRepresentation rep = InstructionSequence::DefaultRepresentation();
1611	int virtual_register = operand->virtual_register();
1612	if (virtual_register != InstructionOperand::kInvalidVirtualRegister) {
1613	rep = data()->RepresentationFor(virtual_register);
1614	}
1615	if (operand->HasFixedSlotPolicy()) {
1616	allocated = AllocatedOperand(AllocatedOperand::STACK_SLOT, rep,
1617	operand->fixed_slot_index());
1618	} else if (operand->HasFixedRegisterPolicy()) {
1619	DCHECK(!IsFloatingPoint(rep))((void) 0);
1620	DCHECK(data()->config()->IsAllocatableGeneralCode(((void) 0)
1621	operand->fixed_register_index()))((void) 0);
1622	allocated = AllocatedOperand(AllocatedOperand::REGISTER, rep,
1623	operand->fixed_register_index());
1624	} else if (operand->HasFixedFPRegisterPolicy()) {
1625	DCHECK(IsFloatingPoint(rep))((void) 0);
1626	DCHECK_NE(InstructionOperand::kInvalidVirtualRegister, virtual_register)((void) 0);
1627	allocated = AllocatedOperand(AllocatedOperand::REGISTER, rep,
1628	operand->fixed_register_index());
1629	} else {
1630	UNREACHABLE()V8_Fatal("unreachable code");
1631	}
1632	if (is_input && allocated.IsAnyRegister()) {
1633	data()->MarkFixedUse(rep, operand->fixed_register_index());
1634	}
1635	InstructionOperand::ReplaceWith(operand, &allocated);
1636	if (is_tagged) {
1637	TRACE("Fixed reg is tagged at %d\n", pos);
1638	Instruction* instr = code()->InstructionAt(pos);
1639	if (instr->HasReferenceMap()) {
1640	instr->reference_map()->RecordReference(*AllocatedOperand::cast(operand));
1641	}
1642	}
1643	return operand;
1644	}
1645
1646	void ConstraintBuilder::MeetRegisterConstraints() {
1647	for (InstructionBlock* block : code()->instruction_blocks()) {
1648	data_->tick_counter()->TickAndMaybeEnterSafepoint();
1649	MeetRegisterConstraints(block);
1650	}
1651	}
1652
1653	void ConstraintBuilder::MeetRegisterConstraints(const InstructionBlock* block) {
1654	int start = block->first_instruction_index();
1655	int end = block->last_instruction_index();
1656	DCHECK_NE(-1, start)((void) 0);
1657	for (int i = start; i <= end; ++i) {
1658	MeetConstraintsBefore(i);
1659	if (i != end) MeetConstraintsAfter(i);
1660	}
1661	// Meet register constraints for the instruction in the end.
1662	MeetRegisterConstraintsForLastInstructionInBlock(block);
1663	}
1664
1665	void ConstraintBuilder::MeetRegisterConstraintsForLastInstructionInBlock(
1666	const InstructionBlock* block) {
1667	int end = block->last_instruction_index();
1668	Instruction* last_instruction = code()->InstructionAt(end);
1669	for (size_t i = 0; i < last_instruction->OutputCount(); i++) {
1670	InstructionOperand* output_operand = last_instruction->OutputAt(i);
1671	DCHECK(!output_operand->IsConstant())((void) 0);
1672	UnallocatedOperand* output = UnallocatedOperand::cast(output_operand);
1673	int output_vreg = output->virtual_register();
1674	TopLevelLiveRange* range = data()->GetOrCreateLiveRangeFor(output_vreg);
1675	bool assigned = false;
1676	if (output->HasFixedPolicy()) {
1677	AllocateFixed(output, -1, false, false);
1678	// This value is produced on the stack, we never need to spill it.
1679	if (output->IsStackSlot()) {
1680	DCHECK(LocationOperand::cast(output)->index() <((void) 0)
1681	data()->frame()->GetSpillSlotCount())((void) 0);
1682	range->SetSpillOperand(LocationOperand::cast(output));
1683	range->SetSpillStartIndex(end);
1684	assigned = true;
1685	}
1686
1687	for (const RpoNumber& succ : block->successors()) {
1688	const InstructionBlock* successor = code()->InstructionBlockAt(succ);
1689	DCHECK_EQ(1, successor->PredecessorCount())((void) 0);
1690	int gap_index = successor->first_instruction_index();
1691	// Create an unconstrained operand for the same virtual register
1692	// and insert a gap move from the fixed output to the operand.
1693	UnallocatedOperand output_copy(UnallocatedOperand::REGISTER_OR_SLOT,
1694	output_vreg);
1695	data()->AddGapMove(gap_index, Instruction::START, *output, output_copy);
1696	}
1697	}
1698
1699	if (!assigned) {
1700	for (const RpoNumber& succ : block->successors()) {
1701	const InstructionBlock* successor = code()->InstructionBlockAt(succ);
1702	DCHECK_EQ(1, successor->PredecessorCount())((void) 0);
1703	int gap_index = successor->first_instruction_index();
1704	range->RecordSpillLocation(allocation_zone(), gap_index, output);
1705	range->SetSpillStartIndex(gap_index);
1706	}
1707	}
1708	}
1709	}
1710
1711	void ConstraintBuilder::MeetConstraintsAfter(int instr_index) {
1712	Instruction* first = code()->InstructionAt(instr_index);
1713	// Handle fixed temporaries.
1714	for (size_t i = 0; i < first->TempCount(); i++) {
1715	UnallocatedOperand* temp = UnallocatedOperand::cast(first->TempAt(i));
1716	if (temp->HasFixedPolicy()) AllocateFixed(temp, instr_index, false, false);
1717	}
1718	// Handle constant/fixed output operands.
1719	for (size_t i = 0; i < first->OutputCount(); i++) {
1720	InstructionOperand* output = first->OutputAt(i);
1721	if (output->IsConstant()) {
1722	int output_vreg = ConstantOperand::cast(output)->virtual_register();
1723	TopLevelLiveRange* range = data()->GetOrCreateLiveRangeFor(output_vreg);
1724	range->SetSpillStartIndex(instr_index + 1);
1725	range->SetSpillOperand(output);
1726	continue;
1727	}
1728	UnallocatedOperand* first_output = UnallocatedOperand::cast(output);
1729	TopLevelLiveRange* range =
1730	data()->GetOrCreateLiveRangeFor(first_output->virtual_register());
1731	bool assigned = false;
1732	if (first_output->HasFixedPolicy()) {
1733	int output_vreg = first_output->virtual_register();
1734	UnallocatedOperand output_copy(UnallocatedOperand::REGISTER_OR_SLOT,
1735	output_vreg);
1736	bool is_tagged = code()->IsReference(output_vreg);
1737	if (first_output->HasSecondaryStorage()) {
1738	range->MarkHasPreassignedSlot();
1739	data()->preassigned_slot_ranges().push_back(
1740	std::make_pair(range, first_output->GetSecondaryStorage()));
1741	}
1742	AllocateFixed(first_output, instr_index, is_tagged, false);
1743
1744	// This value is produced on the stack, we never need to spill it.
1745	if (first_output->IsStackSlot()) {
1746	DCHECK(LocationOperand::cast(first_output)->index() <((void) 0)
1747	data()->frame()->GetTotalFrameSlotCount())((void) 0);
1748	range->SetSpillOperand(LocationOperand::cast(first_output));
1749	range->SetSpillStartIndex(instr_index + 1);
1750	assigned = true;
1751	}
1752	data()->AddGapMove(instr_index + 1, Instruction::START, *first_output,
1753	output_copy);
1754	}
1755	// Make sure we add a gap move for spilling (if we have not done
1756	// so already).
1757	if (!assigned) {
1758	range->RecordSpillLocation(allocation_zone(), instr_index + 1,
1759	first_output);
1760	range->SetSpillStartIndex(instr_index + 1);
1761	}
1762	}
1763	}
1764
1765	void ConstraintBuilder::MeetConstraintsBefore(int instr_index) {
1766	Instruction* second = code()->InstructionAt(instr_index);
1767	// Handle fixed input operands of second instruction.
1768	ZoneVector<TopLevelLiveRange> spilled_consts = nullptr;
1769	for (size_t i = 0; i < second->InputCount(); i++) {
1770	InstructionOperand* input = second->InputAt(i);
1771	if (input->IsImmediate()) {
1772	continue; // Ignore immediates.
1773	}
1774	UnallocatedOperand* cur_input = UnallocatedOperand::cast(input);
1775	if (cur_input->HasSlotPolicy()) {
1776	TopLevelLiveRange* range =
1777	data()->GetOrCreateLiveRangeFor(cur_input->virtual_register());
1778	if (range->HasSpillOperand() && range->GetSpillOperand()->IsConstant()) {
1779	bool already_spilled = false;
1780	if (spilled_consts == nullptr) {
1781	spilled_consts =
1782	allocation_zone()->New<ZoneVector<TopLevelLiveRange*>>(
1783	allocation_zone());
1784	} else {
1785	auto it =
1786	std::find(spilled_consts->begin(), spilled_consts->end(), range);
1787	already_spilled = it != spilled_consts->end();
1788	}
1789	auto it = data()->slot_for_const_range().find(range);
1790	if (it == data()->slot_for_const_range().end()) {
1791	DCHECK(!already_spilled)((void) 0);
1792	int width = ByteWidthForStackSlot(range->representation());
1793	int index = data()->frame()->AllocateSpillSlot(width);
1794	auto* slot = AllocatedOperand::New(allocation_zone(),
1795	LocationOperand::STACK_SLOT,
1796	range->representation(), index);
1797	it = data()->slot_for_const_range().emplace(range, slot).first;
1798	}
1799	if (!already_spilled) {
1800	auto* slot = it->second;
1801	int input_vreg = cur_input->virtual_register();
1802	UnallocatedOperand input_copy(UnallocatedOperand::REGISTER_OR_SLOT,
1803	input_vreg);
1804	// Spill at every use position for simplicity, this case is very rare.
1805	data()->AddGapMove(instr_index, Instruction::END, input_copy, *slot);
1806	spilled_consts->push_back(range);
1807	}
1808	}
1809	}
1810	if (cur_input->HasFixedPolicy()) {
1811	int input_vreg = cur_input->virtual_register();
1812	UnallocatedOperand input_copy(UnallocatedOperand::REGISTER_OR_SLOT,
1813	input_vreg);
1814	bool is_tagged = code()->IsReference(input_vreg);
1815	AllocateFixed(cur_input, instr_index, is_tagged, true);
1816	data()->AddGapMove(instr_index, Instruction::END, input_copy, *cur_input);
1817	}
1818	}
1819	// Handle "output same as input" for second instruction.
1820	for (size_t i = 0; i < second->OutputCount(); i++) {
1821	InstructionOperand* output = second->OutputAt(i);
1822	if (!output->IsUnallocated()) continue;
1823	UnallocatedOperand* second_output = UnallocatedOperand::cast(output);
1824	if (!second_output->HasSameAsInputPolicy()) continue;
1825	DCHECK_EQ(0, i)((void) 0); // Only valid for first output.
1826	UnallocatedOperand* cur_input =
1827	UnallocatedOperand::cast(second->InputAt(second_output->input_index()));
1828	int output_vreg = second_output->virtual_register();
1829	int input_vreg = cur_input->virtual_register();
1830	UnallocatedOperand input_copy(UnallocatedOperand::REGISTER_OR_SLOT,
1831	input_vreg);
1832	*cur_input =
1833	UnallocatedOperand(*cur_input, second_output->virtual_register());
1834	MoveOperands* gap_move = data()->AddGapMove(instr_index, Instruction::END,
1835	input_copy, *cur_input);
1836	DCHECK_NOT_NULL(gap_move)((void) 0);
1837	if (code()->IsReference(input_vreg) && !code()->IsReference(output_vreg)) {
1838	if (second->HasReferenceMap()) {
1839	TopTierRegisterAllocationData::DelayedReference delayed_reference = {
1840	second->reference_map(), &gap_move->source()};
1841	data()->delayed_references().push_back(delayed_reference);
1842	}
1843	}
1844	}
1845	}
1846
1847	void ConstraintBuilder::ResolvePhis() {
1848	// Process the blocks in reverse order.
1849	for (InstructionBlock* block : base::Reversed(code()->instruction_blocks())) {
1850	data_->tick_counter()->TickAndMaybeEnterSafepoint();
1851	ResolvePhis(block);
1852	}
1853	}
1854
1855	void ConstraintBuilder::ResolvePhis(const InstructionBlock* block) {
1856	for (PhiInstruction* phi : block->phis()) {
1857	int phi_vreg = phi->virtual_register();
1858	TopTierRegisterAllocationData::PhiMapValue* map_value =
1859	data()->InitializePhiMap(block, phi);
1860	InstructionOperand& output = phi->output();
1861	// Map the destination operands, so the commitment phase can find them.
1862	for (size_t i = 0; i < phi->operands().size(); ++i) {
1863	InstructionBlock* cur_block =
1864	code()->InstructionBlockAt(block->predecessors()[i]);
1865	UnallocatedOperand input(UnallocatedOperand::REGISTER_OR_SLOT,
1866	phi->operands()[i]);
1867	MoveOperands* move = data()->AddGapMove(
1868	cur_block->last_instruction_index(), Instruction::END, input, output);
1869	map_value->AddOperand(&move->destination());
1870	DCHECK(!code()((void) 0)
1871	->InstructionAt(cur_block->last_instruction_index())((void) 0)
1872	->HasReferenceMap())((void) 0);
1873	}
1874	TopLevelLiveRange* live_range = data()->GetOrCreateLiveRangeFor(phi_vreg);
1875	int gap_index = block->first_instruction_index();
1876	live_range->RecordSpillLocation(allocation_zone(), gap_index, &output);
1877	live_range->SetSpillStartIndex(gap_index);
1878	// We use the phi-ness of some nodes in some later heuristics.
1879	live_range->set_is_phi(true);
1880	live_range->set_is_non_loop_phi(!block->IsLoopHeader());
1881	}
1882	}
1883
1884	LiveRangeBuilder::LiveRangeBuilder(TopTierRegisterAllocationData* data,
1885	Zone* local_zone)
1886	: data_(data), phi_hints_(local_zone) {}
1887
1888	BitVector* LiveRangeBuilder::ComputeLiveOut(
1889	const InstructionBlock* block, TopTierRegisterAllocationData* data) {
1890	size_t block_index = block->rpo_number().ToSize();
1891	BitVector* live_out = data->live_out_sets()[block_index];
1892	if (live_out == nullptr) {
1893	// Compute live out for the given block, except not including backward
1894	// successor edges.
1895	Zone* zone = data->allocation_zone();
1896	const InstructionSequence* code = data->code();
1897
1898	live_out = zone->New<BitVector>(code->VirtualRegisterCount(), zone);
1899
1900	// Process all successor blocks.
1901	for (const RpoNumber& succ : block->successors()) {
1902	// Add values live on entry to the successor.
1903	if (succ <= block->rpo_number()) continue;
1904	BitVector* live_in = data->live_in_sets()[succ.ToSize()];
1905	if (live_in != nullptr) live_out->Union(*live_in);
1906
1907	// All phi input operands corresponding to this successor edge are live
1908	// out from this block.
1909	const InstructionBlock* successor = code->InstructionBlockAt(succ);
1910	size_t index = successor->PredecessorIndexOf(block->rpo_number());
1911	DCHECK(index < successor->PredecessorCount())((void) 0);
1912	for (PhiInstruction* phi : successor->phis()) {
1913	live_out->Add(phi->operands()[index]);
1914	}
1915	}
1916	data->live_out_sets()[block_index] = live_out;
1917	}
1918	return live_out;
1919	}
1920
1921	void LiveRangeBuilder::AddInitialIntervals(const InstructionBlock* block,
1922	BitVector* live_out) {
1923	// Add an interval that includes the entire block to the live range for
1924	// each live_out value.
1925	LifetimePosition start = LifetimePosition::GapFromInstructionIndex(
1926	block->first_instruction_index());
1927	LifetimePosition end = LifetimePosition::InstructionFromInstructionIndex(
1928	block->last_instruction_index())
1929	.NextStart();
1930	for (int operand_index : *live_out) {
1931	TopLevelLiveRange* range = data()->GetOrCreateLiveRangeFor(operand_index);
1932	range->AddUseInterval(start, end, allocation_zone(),
1933	data()->is_trace_alloc());
1934	}
1935	}
1936
1937	int LiveRangeBuilder::FixedFPLiveRangeID(int index, MachineRepresentation rep) {
1938	int result = -index - 1;
1939	switch (rep) {
1940	case MachineRepresentation::kSimd128:
1941	result -=
1942	kNumberOfFixedRangesPerRegister * config()->num_float_registers();
1943	V8_FALLTHROUGH[[clang::fallthrough]];
1944	case MachineRepresentation::kFloat32:
1945	result -=
1946	kNumberOfFixedRangesPerRegister * config()->num_double_registers();
1947	V8_FALLTHROUGH[[clang::fallthrough]];
1948	case MachineRepresentation::kFloat64:
1949	result -=
1950	kNumberOfFixedRangesPerRegister * config()->num_general_registers();
1951	break;
1952	default:
1953	UNREACHABLE()V8_Fatal("unreachable code");
1954	}
1955	return result;
1956	}
1957
1958	TopLevelLiveRange* LiveRangeBuilder::FixedLiveRangeFor(int index,
1959	SpillMode spill_mode) {
1960	int offset = spill_mode == SpillMode::kSpillAtDefinition
1961	? 0
1962	: config()->num_general_registers();
1963	DCHECK(index < config()->num_general_registers())((void) 0);
1964	TopLevelLiveRange* result = data()->fixed_live_ranges()[offset + index];
1965	if (result == nullptr) {
1966	MachineRepresentation rep = InstructionSequence::DefaultRepresentation();
1967	result = data()->NewLiveRange(FixedLiveRangeID(offset + index), rep);
1968	DCHECK(result->IsFixed())((void) 0);
1969	result->set_assigned_register(index);
1970	data()->MarkAllocated(rep, index);
1971	if (spill_mode == SpillMode::kSpillDeferred) {
1972	result->set_deferred_fixed();
1973	}
1974	data()->fixed_live_ranges()[offset + index] = result;
1975	}
1976	return result;
1977	}
1978
1979	TopLevelLiveRange* LiveRangeBuilder::FixedFPLiveRangeFor(
1980	int index, MachineRepresentation rep, SpillMode spill_mode) {
1981	int num_regs = config()->num_double_registers();
1982	ZoneVector<TopLevelLiveRange> live_ranges =
1983	&data()->fixed_double_live_ranges();
1984	if (kFPAliasing == AliasingKind::kCombine) {
1985	switch (rep) {
1986	case MachineRepresentation::kFloat32:
1987	num_regs = config()->num_float_registers();
1988	live_ranges = &data()->fixed_float_live_ranges();
1989	break;
1990	case MachineRepresentation::kSimd128:
1991	num_regs = config()->num_simd128_registers();
1992	live_ranges = &data()->fixed_simd128_live_ranges();
1993	break;
1994	default:
1995	break;
1996	}
1997	}
1998
1999	int offset = spill_mode == SpillMode::kSpillAtDefinition ? 0 : num_regs;
2000
2001	DCHECK(index < num_regs)((void) 0);
2002	USE(num_regs)do { ::v8::base::Use unused_tmp_array_for_use_macro[]{num_regs }; (void)unused_tmp_array_for_use_macro; } while (false);
2003	TopLevelLiveRange* result = (*live_ranges)[offset + index];
2004	if (result == nullptr) {
2005	result = data()->NewLiveRange(FixedFPLiveRangeID(offset + index, rep), rep);
2006	DCHECK(result->IsFixed())((void) 0);
2007	result->set_assigned_register(index);
2008	data()->MarkAllocated(rep, index);
2009	if (spill_mode == SpillMode::kSpillDeferred) {
2010	result->set_deferred_fixed();
2011	}
2012	(*live_ranges)[offset + index] = result;
2013	}
2014	return result;
2015	}
2016
2017	TopLevelLiveRange* LiveRangeBuilder::FixedSIMD128LiveRangeFor(
2018	int index, SpillMode spill_mode) {
2019	DCHECK_EQ(kFPAliasing, AliasingKind::kIndependent)((void) 0);
2020	int num_regs = config()->num_simd128_registers();
2021	ZoneVector<TopLevelLiveRange> live_ranges =
2022	&data()->fixed_simd128_live_ranges();
2023	int offset = spill_mode == SpillMode::kSpillAtDefinition ? 0 : num_regs;
2024
2025	DCHECK(index < num_regs)((void) 0);
2026	USE(num_regs)do { ::v8::base::Use unused_tmp_array_for_use_macro[]{num_regs }; (void)unused_tmp_array_for_use_macro; } while (false);
2027	TopLevelLiveRange* result = (*live_ranges)[offset + index];
2028	if (result == nullptr) {
2029	result = data()->NewLiveRange(
2030	FixedFPLiveRangeID(offset + index, MachineRepresentation::kSimd128),
2031	MachineRepresentation::kSimd128);
2032	DCHECK(result->IsFixed())((void) 0);
2033	result->set_assigned_register(index);
2034	data()->MarkAllocated(MachineRepresentation::kSimd128, index);
2035	if (spill_mode == SpillMode::kSpillDeferred) {
2036	result->set_deferred_fixed();
2037	}
2038	(*live_ranges)[offset + index] = result;
2039	}
2040	return result;
2041	}
2042
2043	TopLevelLiveRange* LiveRangeBuilder::LiveRangeFor(InstructionOperand* operand,
2044	SpillMode spill_mode) {
2045	if (operand->IsUnallocated()) {
2046	return data()->GetOrCreateLiveRangeFor(
2047	UnallocatedOperand::cast(operand)->virtual_register());
2048	} else if (operand->IsConstant()) {
2049	return data()->GetOrCreateLiveRangeFor(
2050	ConstantOperand::cast(operand)->virtual_register());
2051	} else if (operand->IsRegister()) {
2052	return FixedLiveRangeFor(
2053	LocationOperand::cast(operand)->GetRegister().code(), spill_mode);
2054	} else if (operand->IsFPRegister()) {
2055	LocationOperand* op = LocationOperand::cast(operand);
2056	if (kFPAliasing == AliasingKind::kIndependent &&
2057	op->representation() == MachineRepresentation::kSimd128) {
2058	return FixedSIMD128LiveRangeFor(op->register_code(), spill_mode);
2059	}
2060	return FixedFPLiveRangeFor(op->register_code(), op->representation(),
2061	spill_mode);
2062	} else {
2063	return nullptr;
2064	}
2065	}
2066
2067	UsePosition* LiveRangeBuilder::NewUsePosition(LifetimePosition pos,
2068	InstructionOperand* operand,
2069	void* hint,
2070	UsePositionHintType hint_type) {
2071	return allocation_zone()->New<UsePosition>(pos, operand, hint, hint_type);
2072	}
2073
2074	UsePosition* LiveRangeBuilder::Define(LifetimePosition position,
2075	InstructionOperand* operand, void* hint,
2076	UsePositionHintType hint_type,
2077	SpillMode spill_mode) {
2078	TopLevelLiveRange* range = LiveRangeFor(operand, spill_mode);
2079	if (range == nullptr) return nullptr;
2080
2081	if (range->IsEmpty() \|\| range->Start() > position) {
2082	// Can happen if there is a definition without use.
2083	range->AddUseInterval(position, position.NextStart(), allocation_zone(),
2084	data()->is_trace_alloc());
2085	range->AddUsePosition(NewUsePosition(position.NextStart()),
2086	data()->is_trace_alloc());
2087	} else {
2088	range->ShortenTo(position, data()->is_trace_alloc());
2089	}
2090	if (!operand->IsUnallocated()) return nullptr;
2091	UnallocatedOperand* unalloc_operand = UnallocatedOperand::cast(operand);
2092	UsePosition* use_pos =
2093	NewUsePosition(position, unalloc_operand, hint, hint_type);
2094	range->AddUsePosition(use_pos, data()->is_trace_alloc());
2095	return use_pos;
2096	}
2097
2098	UsePosition* LiveRangeBuilder::Use(LifetimePosition block_start,
2099	LifetimePosition position,
2100	InstructionOperand* operand, void* hint,
2101	UsePositionHintType hint_type,
2102	SpillMode spill_mode) {
2103	TopLevelLiveRange* range = LiveRangeFor(operand, spill_mode);
2104	if (range == nullptr) return nullptr;
2105	UsePosition* use_pos = nullptr;
2106	if (operand->IsUnallocated()) {
2107	UnallocatedOperand* unalloc_operand = UnallocatedOperand::cast(operand);
2108	use_pos = NewUsePosition(position, unalloc_operand, hint, hint_type);
2109	range->AddUsePosition(use_pos, data()->is_trace_alloc());
2110	}
2111	range->AddUseInterval(block_start, position, allocation_zone(),
2112	data()->is_trace_alloc());
2113	return use_pos;
2114	}
2115
2116	void LiveRangeBuilder::ProcessInstructions(const InstructionBlock* block,
2117	BitVector* live) {
2118	int block_start = block->first_instruction_index();
2119	LifetimePosition block_start_position =
2120	LifetimePosition::GapFromInstructionIndex(block_start);
2121	bool fixed_float_live_ranges = false;
2122	bool fixed_simd128_live_ranges = false;
2123	if (kFPAliasing == AliasingKind::kCombine) {
2124	int mask = data()->code()->representation_mask();
2125	fixed_float_live_ranges = (mask & kFloat32Bit) != 0;
2126	fixed_simd128_live_ranges = (mask & kSimd128Bit) != 0;
2127	} else if (kFPAliasing == AliasingKind::kIndependent) {
2128	int mask = data()->code()->representation_mask();
2129	fixed_simd128_live_ranges = (mask & kSimd128Bit) != 0;
2130	}
2131	SpillMode spill_mode = SpillModeForBlock(block);
2132
2133	for (int index = block->last_instruction_index(); index >= block_start;
2134	index--) {
2135	LifetimePosition curr_position =
2136	LifetimePosition::InstructionFromInstructionIndex(index);
2137	Instruction* instr = code()->InstructionAt(index);
2138	DCHECK_NOT_NULL(instr)((void) 0);
2139	DCHECK(curr_position.IsInstructionPosition())((void) 0);
2140	// Process output, inputs, and temps of this instruction.
2141	for (size_t i = 0; i < instr->OutputCount(); i++) {
2142	InstructionOperand* output = instr->OutputAt(i);
2143	if (output->IsUnallocated()) {
2144	// Unsupported.
2145	DCHECK(!UnallocatedOperand::cast(output)->HasSlotPolicy())((void) 0);
2146	int out_vreg = UnallocatedOperand::cast(output)->virtual_register();
2147	live->Remove(out_vreg);
2148	} else if (output->IsConstant()) {
2149	int out_vreg = ConstantOperand::cast(output)->virtual_register();
2150	live->Remove(out_vreg);
2151	}
2152	if (block->IsHandler() && index == block_start && output->IsAllocated() &&
2153	output->IsRegister() &&
2154	AllocatedOperand::cast(output)->GetRegister() ==
2155	v8::internal::kReturnRegister0) {
2156	// The register defined here is blocked from gap start - it is the
2157	// exception value.
2158	// TODO(mtrofin): should we explore an explicit opcode for
2159	// the first instruction in the handler?
2160	Define(LifetimePosition::GapFromInstructionIndex(index), output,
2161	spill_mode);
2162	} else {
2163	Define(curr_position, output, spill_mode);
2164	}
2165	}
2166
2167	if (instr->ClobbersRegisters()) {
2168	for (int i = 0; i < config()->num_allocatable_general_registers(); ++i) {
2169	// Create a UseInterval at this instruction for all fixed registers,
2170	// (including the instruction outputs). Adding another UseInterval here
2171	// is OK because AddUseInterval will just merge it with the existing
2172	// one at the end of the range.
2173	int code = config()->GetAllocatableGeneralCode(i);
2174	TopLevelLiveRange* range = FixedLiveRangeFor(code, spill_mode);
2175	range->AddUseInterval(curr_position, curr_position.End(),
2176	allocation_zone(), data()->is_trace_alloc());
2177	}
2178	}
2179
2180	if (instr->ClobbersDoubleRegisters()) {
2181	for (int i = 0; i < config()->num_allocatable_double_registers(); ++i) {
2182	// Add a UseInterval for all DoubleRegisters. See comment above for
2183	// general registers.
2184	int code = config()->GetAllocatableDoubleCode(i);
2185	TopLevelLiveRange* range = FixedFPLiveRangeFor(
2186	code, MachineRepresentation::kFloat64, spill_mode);
2187	range->AddUseInterval(curr_position, curr_position.End(),
2188	allocation_zone(), data()->is_trace_alloc());
2189	}
2190	// Clobber fixed float registers on archs with non-simple aliasing.
2191	if (kFPAliasing == AliasingKind::kCombine) {
2192	if (fixed_float_live_ranges) {
2193	for (int i = 0; i < config()->num_allocatable_float_registers();
2194	++i) {
2195	// Add a UseInterval for all FloatRegisters. See comment above for
2196	// general registers.
2197	int code = config()->GetAllocatableFloatCode(i);
2198	TopLevelLiveRange* range = FixedFPLiveRangeFor(
2199	code, MachineRepresentation::kFloat32, spill_mode);
2200	range->AddUseInterval(curr_position, curr_position.End(),
2201	allocation_zone(), data()->is_trace_alloc());
2202	}
2203	}
2204	if (fixed_simd128_live_ranges) {
2205	for (int i = 0; i < config()->num_allocatable_simd128_registers();
2206	++i) {
2207	int code = config()->GetAllocatableSimd128Code(i);
2208	TopLevelLiveRange* range = FixedFPLiveRangeFor(
2209	code, MachineRepresentation::kSimd128, spill_mode);
2210	range->AddUseInterval(curr_position, curr_position.End(),
2211	allocation_zone(), data()->is_trace_alloc());
2212	}
2213	}
2214	} else if (kFPAliasing == AliasingKind::kIndependent) {
2215	if (fixed_simd128_live_ranges) {
2216	for (int i = 0; i < config()->num_allocatable_simd128_registers();
2217	++i) {
2218	int code = config()->GetAllocatableSimd128Code(i);
2219	TopLevelLiveRange* range =
2220	FixedSIMD128LiveRangeFor(code, spill_mode);
2221	range->AddUseInterval(curr_position, curr_position.End(),
2222	allocation_zone(), data()->is_trace_alloc());
2223	}
2224	}
2225	}
2226	}
2227
2228	for (size_t i = 0; i < instr->InputCount(); i++) {
2229	InstructionOperand* input = instr->InputAt(i);
2230	if (input->IsImmediate()) {
2231	continue; // Ignore immediates.
2232	}
2233	LifetimePosition use_pos;
2234	if (input->IsUnallocated() &&
2235	UnallocatedOperand::cast(input)->IsUsedAtStart()) {
2236	use_pos = curr_position;
2237	} else {
2238	use_pos = curr_position.End();
2239	}
2240
2241	if (input->IsUnallocated()) {
2242	UnallocatedOperand* unalloc = UnallocatedOperand::cast(input);
2243	int vreg = unalloc->virtual_register();
2244	live->Add(vreg);
2245	if (unalloc->HasSlotPolicy()) {
2246	data()->GetOrCreateLiveRangeFor(vreg)->register_slot_use(
2247	block->IsDeferred()
2248	? TopLevelLiveRange::SlotUseKind::kDeferredSlotUse
2249	: TopLevelLiveRange::SlotUseKind::kGeneralSlotUse);
2250	}
2251	}
2252	Use(block_start_position, use_pos, input, spill_mode);
2253	}
2254
2255	for (size_t i = 0; i < instr->TempCount(); i++) {
2256	InstructionOperand* temp = instr->TempAt(i);
2257	// Unsupported.
2258	DCHECK_IMPLIES(temp->IsUnallocated(),((void) 0)
2259	!UnallocatedOperand::cast(temp)->HasSlotPolicy())((void) 0);
2260	if (instr->ClobbersTemps()) {
2261	if (temp->IsRegister()) continue;
2262	if (temp->IsUnallocated()) {
2263	UnallocatedOperand* temp_unalloc = UnallocatedOperand::cast(temp);
2264	if (temp_unalloc->HasFixedPolicy()) {
2265	continue;
2266	}
2267	}
2268	}
2269	Use(block_start_position, curr_position.End(), temp, spill_mode);
2270	Define(curr_position, temp, spill_mode);
2271	}
2272
2273	// Process the moves of the instruction's gaps, making their sources live.
2274	const Instruction::GapPosition kPositions[] = {Instruction::END,
2275	Instruction::START};
2276	curr_position = curr_position.PrevStart();
2277	DCHECK(curr_position.IsGapPosition())((void) 0);
2278	for (const Instruction::GapPosition& position : kPositions) {
2279	ParallelMove* move = instr->GetParallelMove(position);
2280	if (move == nullptr) continue;
2281	if (position == Instruction::END) {
2282	curr_position = curr_position.End();
2283	} else {
2284	curr_position = curr_position.Start();
2285	}
2286	for (MoveOperands* cur : *move) {
2287	InstructionOperand& from = cur->source();
2288	InstructionOperand& to = cur->destination();
2289	void* hint = &to;
2290	UsePositionHintType hint_type = UsePosition::HintTypeForOperand(to);
2291	UsePosition* to_use = nullptr;
2292	int phi_vreg = -1;
2293	if (to.IsUnallocated()) {
2294	int to_vreg = UnallocatedOperand::cast(to).virtual_register();
2295	TopLevelLiveRange* to_range =
2296	data()->GetOrCreateLiveRangeFor(to_vreg);
2297	if (to_range->is_phi()) {
2298	phi_vreg = to_vreg;
2299	if (to_range->is_non_loop_phi()) {
2300	hint = to_range->current_hint_position();
2301	hint_type = hint == nullptr ? UsePositionHintType::kNone
2302	: UsePositionHintType::kUsePos;
2303	} else {
2304	hint_type = UsePositionHintType::kPhi;
2305	hint = data()->GetPhiMapValueFor(to_vreg);
2306	}
2307	} else {
2308	if (live->Contains(to_vreg)) {
2309	to_use =
2310	Define(curr_position, &to, &from,
2311	UsePosition::HintTypeForOperand(from), spill_mode);
2312	live->Remove(to_vreg);
2313	} else {
2314	cur->Eliminate();
2315	continue;
2316	}
2317	}
2318	} else {
2319	Define(curr_position, &to, spill_mode);
2320	}
2321	UsePosition* from_use = Use(block_start_position, curr_position, &from,
2322	hint, hint_type, spill_mode);
2323	// Mark range live.
2324	if (from.IsUnallocated()) {
2325	live->Add(UnallocatedOperand::cast(from).virtual_register());
2326	}
2327	// When the value is moved to a register to meet input constraints,
2328	// we should consider this value use similar as a register use in the
2329	// backward spilling heuristics, even though this value use is not
2330	// register benefical at the AllocateBlockedReg stage.
2331	if (to.IsAnyRegister() \|\|
2332	(to.IsUnallocated() &&
2333	UnallocatedOperand::cast(&to)->HasRegisterPolicy())) {
2334	from_use->set_spill_detrimental();
2335	}
2336	// Resolve use position hints just created.
2337	if (to_use != nullptr && from_use != nullptr) {
2338	to_use->ResolveHint(from_use);
2339	from_use->ResolveHint(to_use);
2340	}
2341	DCHECK_IMPLIES(to_use != nullptr, to_use->IsResolved())((void) 0);
2342	DCHECK_IMPLIES(from_use != nullptr, from_use->IsResolved())((void) 0);
2343	// Potentially resolve phi hint.
2344	if (phi_vreg != -1) ResolvePhiHint(&from, from_use);
2345	}
2346	}
2347	}
2348	}
2349
2350	void LiveRangeBuilder::ProcessPhis(const InstructionBlock* block,
2351	BitVector* live) {
2352	for (PhiInstruction* phi : block->phis()) {
2353	// The live range interval already ends at the first instruction of the
2354	// block.
2355	int phi_vreg = phi->virtual_register();
2356	live->Remove(phi_vreg);
2357	// Select a hint from a predecessor block that precedes this block in the
2358	// rpo order. In order of priority:
2359	// - Avoid hints from deferred blocks.
2360	// - Prefer hints from allocated (or explicit) operands.
2361	// - Prefer hints from empty blocks (containing just parallel moves and a
2362	// jump). In these cases, if we can elide the moves, the jump threader
2363	// is likely to be able to elide the jump.
2364	// The enforcement of hinting in rpo order is required because hint
2365	// resolution that happens later in the compiler pipeline visits
2366	// instructions in reverse rpo order, relying on the fact that phis are
2367	// encountered before their hints.
2368	InstructionOperand* hint = nullptr;
2369	int hint_preference = 0;
2370
2371	// The cost of hinting increases with the number of predecessors. At the
2372	// same time, the typical benefit decreases, since this hinting only
2373	// optimises the execution path through one predecessor. A limit of 2 is
2374	// sufficient to hit the common if/else pattern.
2375	int predecessor_limit = 2;
2376
2377	for (RpoNumber predecessor : block->predecessors()) {
2378	const InstructionBlock* predecessor_block =
2379	code()->InstructionBlockAt(predecessor);
2380	DCHECK_EQ(predecessor_block->rpo_number(), predecessor)((void) 0);
2381
2382	// Only take hints from earlier rpo numbers.
2383	if (predecessor >= block->rpo_number()) continue;
2384
2385	// Look up the predecessor instruction.
2386	const Instruction* predecessor_instr =
2387	GetLastInstruction(code(), predecessor_block);
2388	InstructionOperand* predecessor_hint = nullptr;
2389	// Phis are assigned in the END position of the last instruction in each
2390	// predecessor block.
2391	for (MoveOperands* move :
2392	*predecessor_instr->GetParallelMove(Instruction::END)) {
2393	InstructionOperand& to = move->destination();
2394	if (to.IsUnallocated() &&
2395	UnallocatedOperand::cast(to).virtual_register() == phi_vreg) {
2396	predecessor_hint = &move->source();
2397	break;
2398	}
2399	}
2400	DCHECK_NOT_NULL(predecessor_hint)((void) 0);
2401
2402	// For each predecessor, generate a score according to the priorities
2403	// described above, and pick the best one. Flags in higher-order bits have
2404	// a higher priority than those in lower-order bits.
2405	int predecessor_hint_preference = 0;
2406	const int kNotDeferredBlockPreference = (1 << 2);
2407	const int kMoveIsAllocatedPreference = (1 << 1);
2408	const int kBlockIsEmptyPreference = (1 << 0);
2409
2410	// - Avoid hints from deferred blocks.
2411	if (!predecessor_block->IsDeferred()) {
2412	predecessor_hint_preference \|= kNotDeferredBlockPreference;
2413	}
2414
2415	// - Prefer hints from allocated operands.
2416	//
2417	// Already-allocated operands are typically assigned using the parallel
2418	// moves on the last instruction. For example:
2419	//
2420	// gap (v101 = [x0\|R\|w32]) (v100 = v101)
2421	// ArchJmp
2422	// ...
2423	// phi: v100 = v101 v102
2424	//
2425	// We have already found the END move, so look for a matching START move
2426	// from an allocated operand.
2427	//
2428	// Note that we cannot simply look up data()->live_ranges()[vreg] here
2429	// because the live ranges are still being built when this function is
2430	// called.
2431	// TODO(v8): Find a way to separate hinting from live range analysis in
2432	// BuildLiveRanges so that we can use the O(1) live-range look-up.
2433	auto moves = predecessor_instr->GetParallelMove(Instruction::START);
2434	if (moves != nullptr) {
2435	for (MoveOperands* move : *moves) {
2436	InstructionOperand& to = move->destination();
2437	if (predecessor_hint->Equals(to)) {
2438	if (move->source().IsAllocated()) {
2439	predecessor_hint_preference \|= kMoveIsAllocatedPreference;
2440	}
2441	break;
2442	}
2443	}
2444	}
2445
2446	// - Prefer hints from empty blocks.
2447	if (predecessor_block->last_instruction_index() ==
2448	predecessor_block->first_instruction_index()) {
2449	predecessor_hint_preference \|= kBlockIsEmptyPreference;
2450	}
2451
2452	if ((hint == nullptr) \|\|
2453	(predecessor_hint_preference > hint_preference)) {
2454	// Take the hint from this predecessor.
2455	hint = predecessor_hint;
2456	hint_preference = predecessor_hint_preference;
2457	}
2458
2459	if (--predecessor_limit <= 0) break;
2460	}
2461	DCHECK_NOT_NULL(hint)((void) 0);
2462
2463	LifetimePosition block_start = LifetimePosition::GapFromInstructionIndex(
2464	block->first_instruction_index());
2465	UsePosition* use_pos = Define(block_start, &phi->output(), hint,
2466	UsePosition::HintTypeForOperand(*hint),
2467	SpillModeForBlock(block));
2468	MapPhiHint(hint, use_pos);
2469	}
2470	}
2471
2472	void LiveRangeBuilder::ProcessLoopHeader(const InstructionBlock* block,
2473	BitVector* live) {
2474	DCHECK(block->IsLoopHeader())((void) 0);
2475	// Add a live range stretching from the first loop instruction to the last
2476	// for each value live on entry to the header.
2477	LifetimePosition start = LifetimePosition::GapFromInstructionIndex(
2478	block->first_instruction_index());
2479	LifetimePosition end = LifetimePosition::GapFromInstructionIndex(
2480	code()->LastLoopInstructionIndex(block))
2481	.NextFullStart();
2482	for (int operand_index : *live) {
2483	TopLevelLiveRange* range = data()->GetOrCreateLiveRangeFor(operand_index);
2484	range->EnsureInterval(start, end, allocation_zone(),
2485	data()->is_trace_alloc());
2486	}
2487	// Insert all values into the live in sets of all blocks in the loop.
2488	for (int i = block->rpo_number().ToInt() + 1; i < block->loop_end().ToInt();
2489	++i) {
2490	live_in_sets()[i]->Union(*live);
2491	}
2492	}
2493
2494	void LiveRangeBuilder::BuildLiveRanges() {
2495	// Process the blocks in reverse order.
2496	for (int block_id = code()->InstructionBlockCount() - 1; block_id >= 0;
2497	--block_id) {
2498	data_->tick_counter()->TickAndMaybeEnterSafepoint();
2499	InstructionBlock* block =
2500	code()->InstructionBlockAt(RpoNumber::FromInt(block_id));
2501	BitVector* live = ComputeLiveOut(block, data());
2502	// Initially consider all live_out values live for the entire block. We
2503	// will shorten these intervals if necessary.
2504	AddInitialIntervals(block, live);
2505	// Process the instructions in reverse order, generating and killing
2506	// live values.
2507	ProcessInstructions(block, live);
2508	// All phi output operands are killed by this block.
2509	ProcessPhis(block, live);
2510	// Now live is live_in for this block except not including values live
2511	// out on backward successor edges.
2512	if (block->IsLoopHeader()) ProcessLoopHeader(block, live);
2513	live_in_sets()[block_id] = live;
2514	}
2515	// Postprocess the ranges.
2516	const size_t live_ranges_size = data()->live_ranges().size();
2517	for (TopLevelLiveRange* range : data()->live_ranges()) {
2518	data_->tick_counter()->TickAndMaybeEnterSafepoint();
2519	CHECK_EQ(live_ranges_size,do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false)
2520	data()->live_ranges().size())do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false); // TODO(neis): crbug.com/831822
2521	if (range == nullptr) continue;
2522	// Give slots to all ranges with a non fixed slot use.
2523	if (range->has_slot_use() && range->HasNoSpillType()) {
2524	SpillMode spill_mode =
2525	range->slot_use_kind() ==
2526	TopLevelLiveRange::SlotUseKind::kDeferredSlotUse
2527	? SpillMode::kSpillDeferred
2528	: SpillMode::kSpillAtDefinition;
2529	data()->AssignSpillRangeToLiveRange(range, spill_mode);
2530	}
2531	// TODO(bmeurer): This is a horrible hack to make sure that for constant
2532	// live ranges, every use requires the constant to be in a register.
2533	// Without this hack, all uses with "any" policy would get the constant
2534	// operand assigned.
2535	if (range->HasSpillOperand() && range->GetSpillOperand()->IsConstant()) {
2536	for (UsePosition* pos = range->first_pos(); pos != nullptr;
2537	pos = pos->next()) {
2538	if (pos->type() == UsePositionType::kRequiresSlot \|\|
2539	pos->type() == UsePositionType::kRegisterOrSlotOrConstant) {
2540	continue;
2541	}
2542	UsePositionType new_type = UsePositionType::kRegisterOrSlot;
2543	// Can't mark phis as needing a register.
2544	if (!pos->pos().IsGapPosition()) {
2545	new_type = UsePositionType::kRequiresRegister;
2546	}
2547	pos->set_type(new_type, true);
2548	}
2549	}
2550	range->ResetCurrentHintPosition();
2551	}
2552	for (auto preassigned : data()->preassigned_slot_ranges()) {
2553	TopLevelLiveRange* range = preassigned.first;
2554	int slot_id = preassigned.second;
2555	SpillRange* spill = range->HasSpillRange()
2556	? range->GetSpillRange()
2557	: data()->AssignSpillRangeToLiveRange(
2558	range, SpillMode::kSpillAtDefinition);
2559	spill->set_assigned_slot(slot_id);
2560	}
2561	#ifdef DEBUG
2562	Verify();
2563	#endif
2564	}
2565
2566	void LiveRangeBuilder::MapPhiHint(InstructionOperand* operand,
2567	UsePosition* use_pos) {
2568	DCHECK(!use_pos->IsResolved())((void) 0);
2569	auto res = phi_hints_.insert(std::make_pair(operand, use_pos));
2570	DCHECK(res.second)((void) 0);
2571	USE(res)do { ::v8::base::Use unused_tmp_array_for_use_macro[]{res}; ( void)unused_tmp_array_for_use_macro; } while (false);
2572	}
2573
2574	void LiveRangeBuilder::ResolvePhiHint(InstructionOperand* operand,
2575	UsePosition* use_pos) {
2576	auto it = phi_hints_.find(operand);
2577	if (it == phi_hints_.end()) return;
2578	DCHECK(!it->second->IsResolved())((void) 0);
2579	it->second->ResolveHint(use_pos);
2580	}
2581
2582	void LiveRangeBuilder::Verify() const {
2583	for (auto& hint : phi_hints_) {
2584	CHECK(hint.second->IsResolved())do { if ((__builtin_expect(!!(!(hint.second->IsResolved()) ), 0))) { V8_Fatal("Check failed: %s.", "hint.second->IsResolved()" ); } } while (false);
2585	}
2586	for (const TopLevelLiveRange* current : data()->live_ranges()) {
2587	if (current != nullptr && !current->IsEmpty()) {
2588	// New LiveRanges should not be split.
2589	CHECK_NULL(current->next())do { if ((__builtin_expect(!!(!((current->next()) == nullptr )), 0))) { V8_Fatal("Check failed: %s.", "(current->next()) == nullptr" ); } } while (false);
2590	// General integrity check.
2591	current->Verify();
2592	const UseInterval* first = current->first_interval();
2593	if (first->next() == nullptr) continue;
2594
2595	// Consecutive intervals should not end and start in the same block,
2596	// otherwise the intervals should have been joined, because the
2597	// variable is live throughout that block.
2598	CHECK(NextIntervalStartsInDifferentBlocks(first))do { if ((__builtin_expect(!!(!(NextIntervalStartsInDifferentBlocks (first))), 0))) { V8_Fatal("Check failed: %s.", "NextIntervalStartsInDifferentBlocks(first)" ); } } while (false);
2599
2600	for (const UseInterval* i = first->next(); i != nullptr; i = i->next()) {
2601	// Except for the first interval, the other intevals must start at
2602	// a block boundary, otherwise data wouldn't flow to them.
2603	CHECK(IntervalStartsAtBlockBoundary(i))do { if ((__builtin_expect(!!(!(IntervalStartsAtBlockBoundary (i))), 0))) { V8_Fatal("Check failed: %s.", "IntervalStartsAtBlockBoundary(i)" ); } } while (false);
2604	// The last instruction of the predecessors of the block the interval
2605	// starts must be covered by the range.
2606	CHECK(IntervalPredecessorsCoveredByRange(i, current))do { if ((__builtin_expect(!!(!(IntervalPredecessorsCoveredByRange (i, current))), 0))) { V8_Fatal("Check failed: %s.", "IntervalPredecessorsCoveredByRange(i, current)" ); } } while (false);
2607	if (i->next() != nullptr) {
2608	// Check the consecutive intervals property, except for the last
2609	// interval, where it doesn't apply.
2610	CHECK(NextIntervalStartsInDifferentBlocks(i))do { if ((__builtin_expect(!!(!(NextIntervalStartsInDifferentBlocks (i))), 0))) { V8_Fatal("Check failed: %s.", "NextIntervalStartsInDifferentBlocks(i)" ); } } while (false);
2611	}
2612	}
2613	}
2614	}
2615	}
2616
2617	bool LiveRangeBuilder::IntervalStartsAtBlockBoundary(
2618	const UseInterval* interval) const {
2619	LifetimePosition start = interval->start();
2620	if (!start.IsFullStart()) return false;
2621	int instruction_index = start.ToInstructionIndex();
2622	const InstructionBlock* block =
2623	data()->code()->GetInstructionBlock(instruction_index);
2624	return block->first_instruction_index() == instruction_index;
2625	}
2626
2627	bool LiveRangeBuilder::IntervalPredecessorsCoveredByRange(
2628	const UseInterval* interval, const TopLevelLiveRange* range) const {
2629	LifetimePosition start = interval->start();
2630	int instruction_index = start.ToInstructionIndex();
2631	const InstructionBlock* block =
2632	data()->code()->GetInstructionBlock(instruction_index);
2633	for (RpoNumber pred_index : block->predecessors()) {
2634	const InstructionBlock* predecessor =
2635	data()->code()->InstructionBlockAt(pred_index);
2636	LifetimePosition last_pos = LifetimePosition::GapFromInstructionIndex(
2637	predecessor->last_instruction_index());
2638	last_pos = last_pos.NextStart().End();
2639	if (!range->Covers(last_pos)) return false;
2640	}
2641	return true;
2642	}
2643
2644	bool LiveRangeBuilder::NextIntervalStartsInDifferentBlocks(
2645	const UseInterval* interval) const {
2646	DCHECK_NOT_NULL(interval->next())((void) 0);
2647	LifetimePosition end = interval->end();
2648	LifetimePosition next_start = interval->next()->start();
2649	// Since end is not covered, but the previous position is, move back a
2650	// position
2651	end = end.IsStart() ? end.PrevStart().End() : end.Start();
2652	int last_covered_index = end.ToInstructionIndex();
2653	const InstructionBlock* block =
2654	data()->code()->GetInstructionBlock(last_covered_index);
2655	const InstructionBlock* next_block =
2656	data()->code()->GetInstructionBlock(next_start.ToInstructionIndex());
2657	return block->rpo_number() < next_block->rpo_number();
2658	}
2659
2660	void BundleBuilder::BuildBundles() {
2661	TRACE("Build bundles\n");
2662	// Process the blocks in reverse order.
2663	for (int block_id = code()->InstructionBlockCount() - 1; block_id >= 0;
2664	--block_id) {
2665	InstructionBlock* block =
2666	code()->InstructionBlockAt(RpoNumber::FromInt(block_id));
2667	TRACE("Block B%d\n", block_id);
2668	for (auto phi : block->phis()) {
2669	LiveRange* out_range =
2670	data()->GetOrCreateLiveRangeFor(phi->virtual_register());
2671	LiveRangeBundle* out = out_range->get_bundle();
2672	if (out == nullptr) {
2673	out = data()->allocation_zone()->New<LiveRangeBundle>(
2674	data()->allocation_zone(), next_bundle_id_++);
2675	out->TryAddRange(out_range);
2676	}
2677	TRACE("Processing phi for v%d with %d:%d\n", phi->virtual_register(),
2678	out_range->TopLevel()->vreg(), out_range->relative_id());
2679	bool phi_interferes_with_backedge_input = false;
2680	for (auto input : phi->operands()) {
2681	LiveRange* input_range = data()->GetOrCreateLiveRangeFor(input);
2682	TRACE("Input value v%d with range %d:%d\n", input,
2683	input_range->TopLevel()->vreg(), input_range->relative_id());
2684	LiveRangeBundle* input_bundle = input_range->get_bundle();
2685	if (input_bundle != nullptr) {
2686	TRACE("Merge\n");
2687	LiveRangeBundle* merged = LiveRangeBundle::TryMerge(
2688	out, input_bundle, data()->is_trace_alloc());
2689	if (merged != nullptr) {
2690	DCHECK_EQ(out_range->get_bundle(), merged)((void) 0);
2691	DCHECK_EQ(input_range->get_bundle(), merged)((void) 0);
2692	out = merged;
2693	TRACE("Merged %d and %d to %d\n", phi->virtual_register(), input,
2694	out->id());
2695	} else if (input_range->Start() > out_range->Start()) {
2696	// We are only interested in values defined after the phi, because
2697	// those are values that will go over a back-edge.
2698	phi_interferes_with_backedge_input = true;
2699	}
2700	} else {
2701	TRACE("Add\n");
2702	if (out->TryAddRange(input_range)) {
2703	TRACE("Added %d and %d to %d\n", phi->virtual_register(), input,
2704	out->id());
2705	} else if (input_range->Start() > out_range->Start()) {
2706	// We are only interested in values defined after the phi, because
2707	// those are values that will go over a back-edge.
2708	phi_interferes_with_backedge_input = true;
2709	}
2710	}
2711	}
2712	// Spilling the phi at the loop header is not beneficial if there is
2713	// a back-edge with an input for the phi that interferes with the phi's
2714	// value, because in case that input gets spilled it might introduce
2715	// a stack-to-stack move at the back-edge.
2716	if (phi_interferes_with_backedge_input)
2717	out_range->TopLevel()->set_spilling_at_loop_header_not_beneficial();
2718	}
2719	TRACE("Done block B%d\n", block_id);
2720	}
2721	}
2722
2723	bool LiveRangeBundle::TryAddRange(LiveRange* range) {
2724	DCHECK_NULL(range->get_bundle())((void) 0);
2725	// We may only add a new live range if its use intervals do not
2726	// overlap with existing intervals in the bundle.
2727	if (UsesOverlap(range->first_interval())) return false;
2728	ranges_.insert(range);
2729	range->set_bundle(this);
2730	InsertUses(range->first_interval());
2731	return true;
2732	}
2733
2734	LiveRangeBundle* LiveRangeBundle::TryMerge(LiveRangeBundle* lhs,
2735	LiveRangeBundle* rhs,
2736	bool trace_alloc) {
2737	if (rhs == lhs) return lhs;
2738
2739	auto iter1 = lhs->uses_.begin();
2740	auto iter2 = rhs->uses_.begin();
2741
2742	while (iter1 != lhs->uses_.end() && iter2 != rhs->uses_.end()) {
2743	if (iter1->start >= iter2->end) {
2744	++iter2;
2745	} else if (iter2->start >= iter1->end) {
2746	++iter1;
2747	} else {
2748	TRACE_COND(trace_alloc, "No merge %d:%d %d:%d\n", iter1->start,
2749	iter1->end, iter2->start, iter2->end);
2750	return nullptr;
2751	}
2752	}
2753	// Uses are disjoint, merging is possible.
2754	if (lhs->uses_.size() < rhs->uses_.size()) {
2755	// Merge the smallest bundle into the biggest.
2756	std::swap(lhs, rhs);
2757	}
2758	for (auto it = rhs->ranges_.begin(); it != rhs->ranges_.end(); ++it) {
2759	(*it)->set_bundle(lhs);
2760	lhs->InsertUses((*it)->first_interval());
2761	}
2762	lhs->ranges_.insert(rhs->ranges_.begin(), rhs->ranges_.end());
2763	rhs->ranges_.clear();
2764	return lhs;
2765	}
2766
2767	void LiveRangeBundle::MergeSpillRangesAndClear() {
2768	DCHECK_IMPLIES(ranges_.empty(), uses_.empty())((void) 0);
2769	SpillRange* target = nullptr;
2770	for (auto range : ranges_) {
2771	if (range->TopLevel()->HasSpillRange()) {
2772	SpillRange* current = range->TopLevel()->GetSpillRange();
2773	if (target == nullptr) {
2774	target = current;
2775	} else if (target != current) {
2776	target->TryMerge(current);
2777	}
2778	}
2779	}
2780	// Clear the fields so that we don't try to merge the spill ranges again when
2781	// we hit the same bundle from a different LiveRange in AssignSpillSlots.
2782	// LiveRangeBundles are not used after this.
2783	ranges_.clear();
2784	uses_.clear();
2785	}
2786
2787	RegisterAllocator::RegisterAllocator(TopTierRegisterAllocationData* data,
2788	RegisterKind kind)
2789	: data_(data),
2790	mode_(kind),
2791	num_registers_(GetRegisterCount(data->config(), kind)),
2792	num_allocatable_registers_(
2793	GetAllocatableRegisterCount(data->config(), kind)),
2794	allocatable_register_codes_(
2795	GetAllocatableRegisterCodes(data->config(), kind)),
2796	check_fp_aliasing_(false) {
2797	if (kFPAliasing == AliasingKind::kCombine && kind == RegisterKind::kDouble) {
2798	check_fp_aliasing_ = (data->code()->representation_mask() &
2799	(kFloat32Bit \| kSimd128Bit)) != 0;
2800	}
2801	}
2802
2803	LifetimePosition RegisterAllocator::GetSplitPositionForInstruction(
2804	const LiveRange* range, int instruction_index) {
2805	LifetimePosition ret = LifetimePosition::Invalid();
2806
2807	ret = LifetimePosition::GapFromInstructionIndex(instruction_index);
2808	if (range->Start() >= ret \|\| ret >= range->End()) {
2809	return LifetimePosition::Invalid();
2810	}
2811	return ret;
2812	}
2813
2814	void RegisterAllocator::SplitAndSpillRangesDefinedByMemoryOperand() {
2815	size_t initial_range_count = data()->live_ranges().size();
2816	for (size_t i = 0; i < initial_range_count; ++i) {
2817	CHECK_EQ(initial_range_count,do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(initial_range_count)>::type , typename ::v8::base::pass_value_or_ref<decltype(data()-> live_ranges().size())>::type>((initial_range_count), (data ()->live_ranges().size())); do { if ((__builtin_expect(!!( !(_cmp)), 0))) { V8_Fatal("Check failed: %s.", "initial_range_count" " " "==" " " "data()->live_ranges().size()"); } } while ( false); } while (false)
2818	data()->live_ranges().size())do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(initial_range_count)>::type , typename ::v8::base::pass_value_or_ref<decltype(data()-> live_ranges().size())>::type>((initial_range_count), (data ()->live_ranges().size())); do { if ((__builtin_expect(!!( !(_cmp)), 0))) { V8_Fatal("Check failed: %s.", "initial_range_count" " " "==" " " "data()->live_ranges().size()"); } } while ( false); } while (false); // TODO(neis): crbug.com/831822
2819	TopLevelLiveRange* range = data()->live_ranges()[i];
2820	if (!CanProcessRange(range)) continue;
2821	// Only assume defined by memory operand if we are guaranteed to spill it or
2822	// it has a spill operand.
2823	if (range->HasNoSpillType() \|\|
2824	(range->HasSpillRange() && !range->has_non_deferred_slot_use())) {
2825	continue;
2826	}
2827	LifetimePosition start = range->Start();
2828	TRACE("Live range %d:%d is defined by a spill operand.\n",
2829	range->TopLevel()->vreg(), range->relative_id());
2830	LifetimePosition next_pos = start;
2831	if (next_pos.IsGapPosition()) {
2832	next_pos = next_pos.NextStart();
2833	}
2834
2835	UsePosition* pos = range->NextUsePositionRegisterIsBeneficial(next_pos);
2836	// If the range already has a spill operand and it doesn't need a
2837	// register immediately, split it and spill the first part of the range.
2838	if (pos == nullptr) {
2839	Spill(range, SpillMode::kSpillAtDefinition);
2840	} else if (pos->pos() > range->Start().NextStart()) {
2841	// Do not spill live range eagerly if use position that can benefit from
2842	// the register is too close to the start of live range.
2843	LifetimePosition split_pos = GetSplitPositionForInstruction(
2844	range, pos->pos().ToInstructionIndex());
2845	// There is no place to split, so we can't split and spill.
2846	if (!split_pos.IsValid()) continue;
2847
2848	split_pos =
2849	FindOptimalSplitPos(range->Start().NextFullStart(), split_pos);
2850
2851	SplitRangeAt(range, split_pos);
2852	Spill(range, SpillMode::kSpillAtDefinition);
2853	}
2854	}
2855	}
2856
2857	LiveRange* RegisterAllocator::SplitRangeAt(LiveRange* range,
2858	LifetimePosition pos) {
2859	DCHECK(!range->TopLevel()->IsFixed())((void) 0);
2860	TRACE("Splitting live range %d:%d at %d\n", range->TopLevel()->vreg(),
2861	range->relative_id(), pos.value());
2862
2863	if (pos <= range->Start()) return range;
2864
2865	// We can't properly connect liveranges if splitting occurred at the end
2866	// a block.
2867	DCHECK(pos.IsStart() \|\| pos.IsGapPosition() \|\|((void) 0)
2868	(GetInstructionBlock(code(), pos)->last_instruction_index() !=((void) 0)
2869	pos.ToInstructionIndex()))((void) 0);
2870
2871	LiveRange* result = range->SplitAt(pos, allocation_zone());
2872	return result;
2873	}
2874
2875	LiveRange* RegisterAllocator::SplitBetween(LiveRange* range,
2876	LifetimePosition start,
2877	LifetimePosition end) {
2878	DCHECK(!range->TopLevel()->IsFixed())((void) 0);
2879	TRACE("Splitting live range %d:%d in position between [%d, %d]\n",
2880	range->TopLevel()->vreg(), range->relative_id(), start.value(),
2881	end.value());
2882
2883	LifetimePosition split_pos = FindOptimalSplitPos(start, end);
2884	DCHECK(split_pos >= start)((void) 0);
2885	return SplitRangeAt(range, split_pos);
2886	}
2887
2888	LifetimePosition RegisterAllocator::FindOptimalSplitPos(LifetimePosition start,
2889	LifetimePosition end) {
2890	int start_instr = start.ToInstructionIndex();
2891	int end_instr = end.ToInstructionIndex();
2892	DCHECK_LE(start_instr, end_instr)((void) 0);
2893
2894	// We have no choice
2895	if (start_instr == end_instr) return end;
2896
2897	const InstructionBlock* start_block = GetInstructionBlock(code(), start);
2898	const InstructionBlock* end_block = GetInstructionBlock(code(), end);
2899
2900	if (end_block == start_block) {
2901	// The interval is split in the same basic block. Split at the latest
2902	// possible position.
2903	return end;
2904	}
2905
2906	const InstructionBlock* block = end_block;
2907	// Find header of outermost loop.
2908	do {
2909	const InstructionBlock* loop = GetContainingLoop(code(), block);
2910	if (loop == nullptr \|\|
2911	loop->rpo_number().ToInt() <= start_block->rpo_number().ToInt()) {
2912	// No more loops or loop starts before the lifetime start.
2913	break;
2914	}
2915	block = loop;
2916	} while (true);
2917
2918	// We did not find any suitable outer loop. Split at the latest possible
2919	// position unless end_block is a loop header itself.
2920	if (block == end_block && !end_block->IsLoopHeader()) return end;
2921
2922	return LifetimePosition::GapFromInstructionIndex(
2923	block->first_instruction_index());
2924	}
2925
2926	LifetimePosition RegisterAllocator::FindOptimalSpillingPos(
2927	LiveRange* range, LifetimePosition pos, SpillMode spill_mode,
2928	LiveRange** begin_spill_out) {
2929	*begin_spill_out = range;
2930	// TODO(herhut): Be more clever here as long as we do not move pos out of
2931	// deferred code.
2932	if (spill_mode == SpillMode::kSpillDeferred) return pos;
2933	const InstructionBlock* block = GetInstructionBlock(code(), pos.Start());
2934	const InstructionBlock* loop_header =
2935	block->IsLoopHeader() ? block : GetContainingLoop(code(), block);
2936	if (loop_header == nullptr) return pos;
2937
2938	while (loop_header != nullptr) {
2939	// We are going to spill live range inside the loop.
2940	// If possible try to move spilling position backwards to loop header.
2941	// This will reduce number of memory moves on the back edge.
2942	LifetimePosition loop_start = LifetimePosition::GapFromInstructionIndex(
2943	loop_header->first_instruction_index());
2944	// Stop if we moved to a loop header before the value is defined or
2945	// at the define position that is not beneficial to spill.
2946	if (range->TopLevel()->Start() > loop_start \|\|
2947	(range->TopLevel()->Start() == loop_start &&
2948	range->TopLevel()->SpillAtLoopHeaderNotBeneficial()))
2949	return pos;
2950
2951	LiveRange* live_at_header = range->TopLevel()->GetChildCovers(loop_start);
2952
2953	if (live_at_header != nullptr && !live_at_header->spilled()) {
2954	for (LiveRange* check_use = live_at_header;
2955	check_use != nullptr && check_use->Start() < pos;
2956	check_use = check_use->next()) {
2957	// If we find a use for which spilling is detrimental, don't spill
2958	// at the loop header
2959	UsePosition* next_use =
2960	check_use->NextUsePositionSpillDetrimental(loop_start);
2961	// UsePosition at the end of a UseInterval may
2962	// have the same value as the start of next range.
2963	if (next_use != nullptr && next_use->pos() <= pos) {
2964	return pos;
2965	}
2966	}
2967	// No register beneficial use inside the loop before the pos.
2968	*begin_spill_out = live_at_header;
2969	pos = loop_start;
2970	}
2971
2972	// Try hoisting out to an outer loop.
2973	loop_header = GetContainingLoop(code(), loop_header);
2974	}
2975	return pos;
2976	}
2977
2978	void RegisterAllocator::Spill(LiveRange* range, SpillMode spill_mode) {
2979	DCHECK(!range->spilled())((void) 0);
2980	DCHECK(spill_mode == SpillMode::kSpillAtDefinition \|\|((void) 0)
2981	GetInstructionBlock(code(), range->Start())->IsDeferred())((void) 0);
2982	TopLevelLiveRange* first = range->TopLevel();
2983	TRACE("Spilling live range %d:%d mode %d\n", first->vreg(),
2984	range->relative_id(), spill_mode);
2985
2986	TRACE("Starting spill type is %d\n", static_cast<int>(first->spill_type()));
2987	if (first->HasNoSpillType()) {
2988	TRACE("New spill range needed");
2989	data()->AssignSpillRangeToLiveRange(first, spill_mode);
2990	}
2991	// Upgrade the spillmode, in case this was only spilled in deferred code so
2992	// far.
2993	if ((spill_mode == SpillMode::kSpillAtDefinition) &&
2994	(first->spill_type() ==
2995	TopLevelLiveRange::SpillType::kDeferredSpillRange)) {
2996	TRACE("Upgrading\n");
2997	first->set_spill_type(TopLevelLiveRange::SpillType::kSpillRange);
2998	}
2999	TRACE("Final spill type is %d\n", static_cast<int>(first->spill_type()));
3000	range->Spill();
3001	}
3002
3003	const char* RegisterAllocator::RegisterName(int register_code) const {
3004	if (register_code == kUnassignedRegister) return "unassigned";
3005	switch (mode()) {
3006	case RegisterKind::kGeneral:
3007	return i::RegisterName(Register::from_code(register_code));
3008	case RegisterKind::kDouble:
3009	return i::RegisterName(DoubleRegister::from_code(register_code));
3010	case RegisterKind::kSimd128:
3011	return i::RegisterName(Simd128Register::from_code(register_code));
3012	}
3013	}
3014
3015	LinearScanAllocator::LinearScanAllocator(TopTierRegisterAllocationData* data,
3016	RegisterKind kind, Zone* local_zone)
3017	: RegisterAllocator(data, kind),
3018	unhandled_live_ranges_(local_zone),
3019	active_live_ranges_(local_zone),
3020	inactive_live_ranges_(num_registers(), InactiveLiveRangeQueue(local_zone),
3021	local_zone),
3022	next_active_ranges_change_(LifetimePosition::Invalid()),
3023	next_inactive_ranges_change_(LifetimePosition::Invalid()) {
3024	active_live_ranges().reserve(8);
3025	}
3026
3027	void LinearScanAllocator::MaybeSpillPreviousRanges(LiveRange* begin_range,
3028	LifetimePosition begin_pos,
3029	LiveRange* end_range) {
3030	// Spill begin_range after begin_pos, then spill every live range of this
3031	// virtual register until but excluding end_range.
3032	DCHECK(begin_range->Covers(begin_pos))((void) 0);
3033	DCHECK_EQ(begin_range->TopLevel(), end_range->TopLevel())((void) 0);
3034
3035	if (begin_range != end_range) {
3036	DCHECK_LE(begin_range->End(), end_range->Start())((void) 0);
3037	if (!begin_range->spilled()) {
3038	SpillAfter(begin_range, begin_pos, SpillMode::kSpillAtDefinition);
3039	}
3040	for (LiveRange* range = begin_range->next(); range != end_range;
3041	range = range->next()) {
3042	if (!range->spilled()) {
3043	range->Spill();
3044	}
3045	}
3046	}
3047	}
3048
3049	void LinearScanAllocator::MaybeUndoPreviousSplit(LiveRange* range) {
3050	if (range->next() != nullptr && range->next()->ShouldRecombine()) {
3051	LiveRange* to_remove = range->next();
3052	TRACE("Recombining %d:%d with %d\n", range->TopLevel()->vreg(),
3053	range->relative_id(), to_remove->relative_id());
3054
3055	// Remove the range from unhandled, as attaching it will change its
3056	// state and hence ordering in the unhandled set.
3057	auto removed_cnt = unhandled_live_ranges().erase(to_remove);
3058	DCHECK_EQ(removed_cnt, 1)((void) 0);
3059	USE(removed_cnt)do { ::v8::base::Use unused_tmp_array_for_use_macro[]{removed_cnt }; (void)unused_tmp_array_for_use_macro; } while (false);
3060
3061	range->AttachToNext();
3062	} else if (range->next() != nullptr) {
3063	TRACE("No recombine for %d:%d to %d\n", range->TopLevel()->vreg(),
3064	range->relative_id(), range->next()->relative_id());
3065	}
3066	}
3067
3068	void LinearScanAllocator::SpillNotLiveRanges(RangeWithRegisterSet* to_be_live,
3069	LifetimePosition position,
3070	SpillMode spill_mode) {
3071	for (auto it = active_live_ranges().begin();
3072	it != active_live_ranges().end();) {
3073	LiveRange* active_range = *it;
3074	TopLevelLiveRange* toplevel = (*it)->TopLevel();
3075	auto found = to_be_live->find({toplevel, kUnassignedRegister});
3076	if (found == to_be_live->end()) {
3077	// Is not contained in {to_be_live}, spill it.
3078	// Fixed registers are exempt from this. They might have been
3079	// added from inactive at the block boundary but we know that
3080	// they cannot conflict as they are built before register
3081	// allocation starts. It would be algorithmically fine to split
3082	// them and reschedule but the code does not allow to do this.
3083	if (toplevel->IsFixed()) {
3084	TRACE("Keeping reactivated fixed range for %s\n",
3085	RegisterName(toplevel->assigned_register()));
3086	++it;
3087	} else {
3088	// When spilling a previously spilled/reloaded range, we add back the
3089	// tail that we might have split off when we reloaded/spilled it
3090	// previously. Otherwise we might keep generating small split-offs.
3091	MaybeUndoPreviousSplit(active_range);
3092	TRACE("Putting back %d:%d\n", toplevel->vreg(),
3093	active_range->relative_id());
3094	LiveRange* split = SplitRangeAt(active_range, position);
3095	DCHECK_NE(split, active_range)((void) 0);
3096
3097	// Make sure we revisit this range once it has a use that requires
3098	// a register.
3099	UsePosition* next_use = split->NextRegisterPosition(position);
3100	if (next_use != nullptr) {
3101	// Move to the start of the gap before use so that we have a space
3102	// to perform the potential reload. Otherwise, do not spill but add
3103	// to unhandled for reallocation.
3104	LifetimePosition revisit_at = next_use->pos().FullStart();
3105	TRACE("Next use at %d\n", revisit_at.value());
3106	if (!data()->IsBlockBoundary(revisit_at)) {
3107	// Leave some space so we have enough gap room.
3108	revisit_at = revisit_at.PrevStart().FullStart();
3109	}
3110	// If this range became life right at the block boundary that we are
3111	// currently processing, we do not need to split it. Instead move it
3112	// to unhandled right away.
3113	if (position < revisit_at) {
3114	LiveRange* third_part = SplitRangeAt(split, revisit_at);
3115	DCHECK_NE(split, third_part)((void) 0);
3116	Spill(split, spill_mode);
3117	TRACE("Marking %d:%d to recombine\n", toplevel->vreg(),
3118	third_part->relative_id());
3119	third_part->SetRecombine();
3120	AddToUnhandled(third_part);
3121	} else {
3122	AddToUnhandled(split);
3123	}
3124	} else {
3125	Spill(split, spill_mode);
3126	}
3127	it = ActiveToHandled(it);
3128	}
3129	} else {
3130	// This range is contained in {to_be_live}, so we can keep it.
3131	int expected_register = (*found).expected_register;
3132	to_be_live->erase(found);
3133	if (expected_register == active_range->assigned_register()) {
3134	// Was life and in correct register, simply pass through.
3135	TRACE("Keeping %d:%d in %s\n", toplevel->vreg(),
3136	active_range->relative_id(),
3137	RegisterName(active_range->assigned_register()));
3138	++it;
3139	} else {
3140	// Was life but wrong register. Split and schedule for
3141	// allocation.
3142	TRACE("Scheduling %d:%d\n", toplevel->vreg(),
3143	active_range->relative_id());
3144	LiveRange* split = SplitRangeAt(active_range, position);
3145	split->set_controlflow_hint(expected_register);
3146	AddToUnhandled(split);
3147	it = ActiveToHandled(it);
3148	}
3149	}
3150	}
3151	}
3152
3153	LiveRange* LinearScanAllocator::AssignRegisterOnReload(LiveRange* range,
3154	int reg) {
3155	// We know the register is currently free but it might be in
3156	// use by a currently inactive range. So we might not be able
3157	// to reload for the full distance. In such case, split here.
3158	// TODO(herhut):
3159	// It might be better if we could use the normal unhandled queue and
3160	// give reloading registers pecedence. That way we would compute the
3161	// intersection for the entire future.
3162	LifetimePosition new_end = range->End();
3163	for (int cur_reg = 0; cur_reg < num_registers(); ++cur_reg) {
3164	if ((kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing()) &&
3165	cur_reg != reg) {
3166	continue;
3167	}
3168	for (const LiveRange* cur_inactive : inactive_live_ranges(cur_reg)) {
3169	if (kFPAliasing == AliasingKind::kCombine && check_fp_aliasing() &&
3170	!data()->config()->AreAliases(cur_inactive->representation(), cur_reg,
3171	range->representation(), reg)) {
3172	continue;
3173	}
3174	if (new_end <= cur_inactive->NextStart()) {
3175	// Inactive ranges are sorted by their next start, so the remaining
3176	// ranges cannot contribute to new_end.
3177	break;
3178	}
3179	auto next_intersection = cur_inactive->FirstIntersection(range);
3180	if (!next_intersection.IsValid()) continue;
3181	new_end = std::min(new_end, next_intersection);
3182	}
3183	}
3184	if (new_end != range->End()) {
3185	TRACE("Found new end for %d:%d at %d\n", range->TopLevel()->vreg(),
3186	range->relative_id(), new_end.value());
3187	LiveRange* tail = SplitRangeAt(range, new_end);
3188	AddToUnhandled(tail);
3189	}
3190	SetLiveRangeAssignedRegister(range, reg);
3191	return range;
3192	}
3193
3194	void LinearScanAllocator::ReloadLiveRanges(
3195	RangeWithRegisterSet const& to_be_live, LifetimePosition position) {
3196	// Assumption: All ranges in {to_be_live} are currently spilled and there are
3197	// no conflicting registers in the active ranges.
3198	// The former is ensured by SpillNotLiveRanges, the latter is by construction
3199	// of the to_be_live set.
3200	for (RangeWithRegister range_with_register : to_be_live) {
3201	TopLevelLiveRange* range = range_with_register.range;
3202	int reg = range_with_register.expected_register;
3203	LiveRange* to_resurrect = range->GetChildCovers(position);
3204	if (to_resurrect == nullptr) {
3205	// While the range was life until the end of the predecessor block, it is
3206	// not live in this block. Either there is a lifetime gap or the range
3207	// died.
3208	TRACE("No candidate for %d at %d\n", range->vreg(), position.value());
3209	} else {
3210	// We might be resurrecting a range that we spilled until its next use
3211	// before. In such cases, we have to unsplit it before processing as
3212	// otherwise we might get register changes from one range to the other
3213	// in the middle of blocks.
3214	// If there is a gap between this range and the next, we can just keep
3215	// it as a register change won't hurt.
3216	MaybeUndoPreviousSplit(to_resurrect);
3217	if (to_resurrect->Start() == position) {
3218	// This range already starts at this block. It might have been spilled,
3219	// so we have to unspill it. Otherwise, it is already in the unhandled
3220	// queue waiting for processing.
3221	DCHECK(!to_resurrect->HasRegisterAssigned())((void) 0);
3222	TRACE("Reload %d:%d starting at %d itself\n", range->vreg(),
3223	to_resurrect->relative_id(), position.value());
3224	if (to_resurrect->spilled()) {
3225	to_resurrect->Unspill();
3226	to_resurrect->set_controlflow_hint(reg);
3227	AddToUnhandled(to_resurrect);
3228	} else {
3229	// Assign the preassigned register if we know. Otherwise, nothing to
3230	// do as already in unhandeled.
3231	if (reg != kUnassignedRegister) {
3232	auto erased_cnt = unhandled_live_ranges().erase(to_resurrect);
3233	DCHECK_EQ(erased_cnt, 1)((void) 0);
3234	USE(erased_cnt)do { ::v8::base::Use unused_tmp_array_for_use_macro[]{erased_cnt }; (void)unused_tmp_array_for_use_macro; } while (false);
3235	// We know that there is no conflict with active ranges, so just
3236	// assign the register to the range.
3237	to_resurrect = AssignRegisterOnReload(to_resurrect, reg);
3238	AddToActive(to_resurrect);
3239	}
3240	}
3241	} else {
3242	// This range was spilled before. We have to split it and schedule the
3243	// second part for allocation (or assign the register if we know).
3244	DCHECK(to_resurrect->spilled())((void) 0);
3245	LiveRange* split = SplitRangeAt(to_resurrect, position);
3246	TRACE("Reload %d:%d starting at %d as %d\n", range->vreg(),
3247	to_resurrect->relative_id(), split->Start().value(),
3248	split->relative_id());
3249	DCHECK_NE(split, to_resurrect)((void) 0);
3250	if (reg != kUnassignedRegister) {
3251	// We know that there is no conflict with active ranges, so just
3252	// assign the register to the range.
3253	split = AssignRegisterOnReload(split, reg);
3254	AddToActive(split);
3255	} else {
3256	// Let normal register assignment find a suitable register.
3257	split->set_controlflow_hint(reg);
3258	AddToUnhandled(split);
3259	}
3260	}
3261	}
3262	}
3263	}
3264
3265	RpoNumber LinearScanAllocator::ChooseOneOfTwoPredecessorStates(
3266	InstructionBlock* current_block, LifetimePosition boundary) {
3267	using SmallRangeVector =
3268	base::SmallVector<TopLevelLiveRange*,
3269	RegisterConfiguration::kMaxRegisters>;
3270	// Pick the state that would generate the least spill/reloads.
3271	// Compute vectors of ranges with imminent use for both sides.
3272	// As GetChildCovers is cached, it is cheaper to repeatedly
3273	// call is rather than compute a shared set first.
3274	auto& left = data()->GetSpillState(current_block->predecessors()[0]);
3275	auto& right = data()->GetSpillState(current_block->predecessors()[1]);
3276	SmallRangeVector left_used;
3277	for (const auto item : left) {
3278	LiveRange* at_next_block = item->TopLevel()->GetChildCovers(boundary);
3279	if (at_next_block != nullptr &&
3280	at_next_block->NextUsePositionRegisterIsBeneficial(boundary) !=
3281	nullptr) {
3282	left_used.emplace_back(item->TopLevel());
3283	}
3284	}
3285	SmallRangeVector right_used;
3286	for (const auto item : right) {
3287	LiveRange* at_next_block = item->TopLevel()->GetChildCovers(boundary);
3288	if (at_next_block != nullptr &&
3289	at_next_block->NextUsePositionRegisterIsBeneficial(boundary) !=
3290	nullptr) {
3291	right_used.emplace_back(item->TopLevel());
3292	}
3293	}
3294	if (left_used.empty() && right_used.empty()) {
3295	// There are no beneficial register uses. Look at any use at
3296	// all. We do not account for all uses, like flowing into a phi.
3297	// So we just look at ranges still being live.
3298	TRACE("Looking at only uses\n");
3299	for (const auto item : left) {
3300	LiveRange* at_next_block = item->TopLevel()->GetChildCovers(boundary);
3301	if (at_next_block != nullptr &&
3302	at_next_block->NextUsePosition(boundary) != nullptr) {
3303	left_used.emplace_back(item->TopLevel());
3304	}
3305	}
3306	for (const auto item : right) {
3307	LiveRange* at_next_block = item->TopLevel()->GetChildCovers(boundary);
3308	if (at_next_block != nullptr &&
3309	at_next_block->NextUsePosition(boundary) != nullptr) {
3310	right_used.emplace_back(item->TopLevel());
3311	}
3312	}
3313	}
3314	// Now left_used and right_used contains those ranges that matter.
3315	// Count which side matches this most.
3316	TRACE("Vote went %zu vs %zu\n", left_used.size(), right_used.size());
3317	return left_used.size() > right_used.size()
3318	? current_block->predecessors()[0]
3319	: current_block->predecessors()[1];
3320	}
3321
3322	bool LinearScanAllocator::CheckConflict(MachineRepresentation rep, int reg,
3323	RangeWithRegisterSet* to_be_live) {
3324	for (RangeWithRegister range_with_reg : *to_be_live) {
3325	if (data()->config()->AreAliases(range_with_reg.range->representation(),
3326	range_with_reg.expected_register, rep,
3327	reg)) {
3328	return true;
3329	}
3330	}
3331	return false;
3332	}
3333
3334	void LinearScanAllocator::ComputeStateFromManyPredecessors(
3335	InstructionBlock* current_block, RangeWithRegisterSet* to_be_live) {
3336	struct Vote {
3337	size_t count;
3338	int used_registers[RegisterConfiguration::kMaxRegisters];
3339	};
3340	struct TopLevelLiveRangeComparator {
3341	bool operator()(const TopLevelLiveRange* lhs,
3342	const TopLevelLiveRange* rhs) const {
3343	return lhs->vreg() < rhs->vreg();
3344	}
3345	};
3346	ZoneMap<TopLevelLiveRange*, Vote, TopLevelLiveRangeComparator> counts(
3347	data()->allocation_zone());
3348	int deferred_blocks = 0;
3349	for (RpoNumber pred : current_block->predecessors()) {
3350	if (!ConsiderBlockForControlFlow(current_block, pred)) {
3351	// Back edges of a loop count as deferred here too.
3352	deferred_blocks++;
3353	continue;
3354	}
3355	const auto& pred_state = data()->GetSpillState(pred);
3356	for (LiveRange* range : pred_state) {
3357	// We might have spilled the register backwards, so the range we
3358	// stored might have lost its register. Ignore those.
3359	if (!range->HasRegisterAssigned()) continue;
3360	TopLevelLiveRange* toplevel = range->TopLevel();
3361	auto previous = counts.find(toplevel);
3362	if (previous == counts.end()) {
3363	auto result = counts.emplace(std::make_pair(toplevel, Vote{1, {0}}));
3364	CHECK(result.second)do { if ((__builtin_expect(!!(!(result.second)), 0))) { V8_Fatal ("Check failed: %s.", "result.second"); } } while (false);
3365	result.first->second.used_registers[range->assigned_register()]++;
3366	} else {
3367	previous->second.count++;
3368	previous->second.used_registers[range->assigned_register()]++;
3369	}
3370	}
3371	}
3372
3373	// Choose the live ranges from the majority.
3374	const size_t majority =
3375	(current_block->PredecessorCount() + 2 - deferred_blocks) / 2;
3376	bool taken_registers[RegisterConfiguration::kMaxRegisters] = {false};
3377	auto assign_to_live = [this, counts, majority](
3378	std::function<bool(TopLevelLiveRange*)> filter,
3379	RangeWithRegisterSet* to_be_live,
3380	bool* taken_registers) {
3381	bool check_aliasing =
3382	kFPAliasing == AliasingKind::kCombine && check_fp_aliasing();
3383	for (const auto& val : counts) {
3384	if (!filter(val.first)) continue;
3385	if (val.second.count >= majority) {
3386	int register_max = 0;
3387	int reg = kUnassignedRegister;
3388	bool conflict = false;
3389	int num_regs = num_registers();
3390	int num_codes = num_allocatable_registers();
3391	const int* codes = allocatable_register_codes();
3392	MachineRepresentation rep = val.first->representation();
3393	if (check_aliasing && (rep == MachineRepresentation::kFloat32 \|\|
3394	rep == MachineRepresentation::kSimd128))
3395	GetFPRegisterSet(rep, &num_regs, &num_codes, &codes);
3396	for (int idx = 0; idx < num_regs; idx++) {
3397	int uses = val.second.used_registers[idx];
3398	if (uses == 0) continue;
3399	if (uses > register_max \|\| (conflict && uses == register_max)) {
3400	reg = idx;
3401	register_max = uses;
3402	conflict = check_aliasing ? CheckConflict(rep, reg, to_be_live)
3403	: taken_registers[reg];
3404	}
3405	}
3406	if (conflict) {
3407	reg = kUnassignedRegister;
3408	} else if (!check_aliasing) {
3409	taken_registers[reg] = true;
3410	}
3411	to_be_live->emplace(val.first, reg);
3412	TRACE("Reset %d as live due vote %zu in %s\n",
3413	val.first->TopLevel()->vreg(), val.second.count,
3414	RegisterName(reg));
3415	}
3416	}
3417	};
3418	// First round, process fixed registers, as these have precedence.
3419	// There is only one fixed range per register, so we cannot have
3420	// conflicts.
3421	assign_to_live([](TopLevelLiveRange* r) { return r->IsFixed(); }, to_be_live,
3422	taken_registers);
3423	// Second round, process the rest.
3424	assign_to_live([](TopLevelLiveRange* r) { return !r->IsFixed(); }, to_be_live,
3425	taken_registers);
3426	}
3427
3428	bool LinearScanAllocator::ConsiderBlockForControlFlow(
3429	InstructionBlock* current_block, RpoNumber predecessor) {
3430	// We ignore predecessors on back edges when looking for control flow effects,
3431	// as those lie in the future of allocation and we have no data yet. Also,
3432	// deferred bocks are ignored on deferred to non-deferred boundaries, as we do
3433	// not want them to influence allocation of non deferred code.
3434	return (predecessor < current_block->rpo_number()) &&
3435	(current_block->IsDeferred() \|\|
3436	!code()->InstructionBlockAt(predecessor)->IsDeferred());
3437	}
3438
3439	void LinearScanAllocator::UpdateDeferredFixedRanges(SpillMode spill_mode,
3440	InstructionBlock* block) {
3441	if (spill_mode == SpillMode::kSpillDeferred) {
3442	LifetimePosition max = LifetimePosition::InstructionFromInstructionIndex(
3443	LastDeferredInstructionIndex(block));
3444	// Adds range back to inactive, resolving resulting conflicts.
3445	auto add_to_inactive = [this, max](LiveRange* range) {
3446	AddToInactive(range);
3447	// Splits other if it conflicts with range. Other is placed in unhandled
3448	// for later reallocation.
3449	auto split_conflicting = [this, max](LiveRange* range, LiveRange* other,
3450	std::function<void(LiveRange*)>
3451	update_caches) {
3452	if (other->TopLevel()->IsFixed()) return;
3453	int reg = range->assigned_register();
3454	if (kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing()) {
3455	if (other->assigned_register() != reg) {
3456	return;
3457	}
3458	} else {
3459	if (!data()->config()->AreAliases(range->representation(), reg,
3460	other->representation(),
3461	other->assigned_register())) {
3462	return;
3463	}
3464	}
3465	// The inactive range might conflict, so check whether we need to
3466	// split and spill. We can look for the first intersection, as there
3467	// cannot be any intersections in the past, as those would have been a
3468	// conflict then.
3469	LifetimePosition next_start = range->FirstIntersection(other);
3470	if (!next_start.IsValid() \|\| (next_start > max)) {
3471	// There is no conflict or the conflict is outside of the current
3472	// stretch of deferred code. In either case we can ignore the
3473	// inactive range.
3474	return;
3475	}
3476	// They overlap. So we need to split active and reschedule it
3477	// for allocation.
3478	TRACE("Resolving conflict of %d with deferred fixed for register %s\n",
3479	other->TopLevel()->vreg(),
3480	RegisterName(other->assigned_register()));
3481	LiveRange* split_off =
3482	other->SplitAt(next_start, data()->allocation_zone());
3483	// Try to get the same register after the deferred block.
3484	split_off->set_controlflow_hint(other->assigned_register());
3485	DCHECK_NE(split_off, other)((void) 0);
3486	AddToUnhandled(split_off);
3487	update_caches(other);
3488	};
3489	// Now check for conflicts in active and inactive ranges. We might have
3490	// conflicts in inactive, as we do not do this check on every block
3491	// boundary but only on deferred/non-deferred changes but inactive
3492	// live ranges might become live on any block boundary.
3493	for (auto active : active_live_ranges()) {
3494	split_conflicting(range, active, [this](LiveRange* updated) {
3495	next_active_ranges_change_ =
3496	std::min(updated->End(), next_active_ranges_change_);
3497	});
3498	}
3499	for (int reg = 0; reg < num_registers(); ++reg) {
3500	if ((kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing()) &&
3501	reg != range->assigned_register()) {
3502	continue;
3503	}
3504	for (auto inactive : inactive_live_ranges(reg)) {
3505	if (inactive->NextStart() > max) break;
3506	split_conflicting(range, inactive, [this](LiveRange* updated) {
3507	next_inactive_ranges_change_ =
3508	std::min(updated->End(), next_inactive_ranges_change_);
3509	});
3510	}
3511	}
3512	};
3513	if (mode() == RegisterKind::kGeneral) {
3514	for (TopLevelLiveRange* current : data()->fixed_live_ranges()) {
3515	if (current != nullptr) {
3516	if (current->IsDeferredFixed()) {
3517	add_to_inactive(current);
3518	}
3519	}
3520	}
3521	} else if (mode() == RegisterKind::kDouble) {
3522	for (TopLevelLiveRange* current : data()->fixed_double_live_ranges()) {
3523	if (current != nullptr) {
3524	if (current->IsDeferredFixed()) {
3525	add_to_inactive(current);
3526	}
3527	}
3528	}
3529	if (kFPAliasing == AliasingKind::kCombine && check_fp_aliasing()) {
3530	for (TopLevelLiveRange* current : data()->fixed_float_live_ranges()) {
3531	if (current != nullptr) {
3532	if (current->IsDeferredFixed()) {
3533	add_to_inactive(current);
3534	}
3535	}
3536	}
3537	for (TopLevelLiveRange* current : data()->fixed_simd128_live_ranges()) {
3538	if (current != nullptr) {
3539	if (current->IsDeferredFixed()) {
3540	add_to_inactive(current);
3541	}
3542	}
3543	}
3544	}
3545	} else {
3546	DCHECK_EQ(mode(), RegisterKind::kSimd128)((void) 0);
3547	for (TopLevelLiveRange* current : data()->fixed_simd128_live_ranges()) {
3548	if (current != nullptr) {
3549	if (current->IsDeferredFixed()) {
3550	add_to_inactive(current);
3551	}
3552	}
3553	}
3554	}
3555	} else {
3556	// Remove all ranges.
3557	for (int reg = 0; reg < num_registers(); ++reg) {
3558	for (auto it = inactive_live_ranges(reg).begin();
3559	it != inactive_live_ranges(reg).end();) {
3560	if ((*it)->TopLevel()->IsDeferredFixed()) {
3561	it = inactive_live_ranges(reg).erase(it);
3562	} else {
3563	++it;
3564	}
3565	}
3566	}
3567	}
3568	}
3569
3570	bool LinearScanAllocator::BlockIsDeferredOrImmediatePredecessorIsNotDeferred(
3571	const InstructionBlock* block) {
3572	if (block->IsDeferred()) return true;
3573	if (block->PredecessorCount() == 0) return true;
3574	bool pred_is_deferred = false;
3575	for (auto pred : block->predecessors()) {
3576	if (pred.IsNext(block->rpo_number())) {
3577	pred_is_deferred = code()->InstructionBlockAt(pred)->IsDeferred();
3578	break;
3579	}
3580	}
3581	return !pred_is_deferred;
3582	}
3583
3584	bool LinearScanAllocator::HasNonDeferredPredecessor(InstructionBlock* block) {
3585	for (auto pred : block->predecessors()) {
3586	InstructionBlock* pred_block = code()->InstructionBlockAt(pred);
3587	if (!pred_block->IsDeferred()) return true;
3588	}
3589	return false;
3590	}
3591
3592	void LinearScanAllocator::AllocateRegisters() {
3593	DCHECK(unhandled_live_ranges().empty())((void) 0);
3594	DCHECK(active_live_ranges().empty())((void) 0);
3595	for (int reg = 0; reg < num_registers(); ++reg) {
3596	DCHECK(inactive_live_ranges(reg).empty())((void) 0);
3597	}
3598
3599	SplitAndSpillRangesDefinedByMemoryOperand();
3600	data()->ResetSpillState();
3601
3602	if (data()->is_trace_alloc()) {
3603	PrintRangeOverview();
3604	}
3605
3606	const size_t live_ranges_size = data()->live_ranges().size();
3607	for (TopLevelLiveRange* range : data()->live_ranges()) {
3608	CHECK_EQ(live_ranges_size,do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false)
3609	data()->live_ranges().size())do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false); // TODO(neis): crbug.com/831822
3610	if (!CanProcessRange(range)) continue;
3611	for (LiveRange* to_add = range; to_add != nullptr;
3612	to_add = to_add->next()) {
3613	if (!to_add->spilled()) {
3614	AddToUnhandled(to_add);
3615	}
3616	}
3617	}
3618
3619	if (mode() == RegisterKind::kGeneral) {
3620	for (TopLevelLiveRange* current : data()->fixed_live_ranges()) {
3621	if (current != nullptr) {
3622	if (current->IsDeferredFixed()) continue;
3623	AddToInactive(current);
3624	}
3625	}
3626	} else if (mode() == RegisterKind::kDouble) {
3627	for (TopLevelLiveRange* current : data()->fixed_double_live_ranges()) {
3628	if (current != nullptr) {
3629	if (current->IsDeferredFixed()) continue;
3630	AddToInactive(current);
3631	}
3632	}
3633	if (kFPAliasing == AliasingKind::kCombine && check_fp_aliasing()) {
3634	for (TopLevelLiveRange* current : data()->fixed_float_live_ranges()) {
3635	if (current != nullptr) {
3636	if (current->IsDeferredFixed()) continue;
3637	AddToInactive(current);
3638	}
3639	}
3640	for (TopLevelLiveRange* current : data()->fixed_simd128_live_ranges()) {
3641	if (current != nullptr) {
3642	if (current->IsDeferredFixed()) continue;
3643	AddToInactive(current);
3644	}
3645	}
3646	}
3647	} else {
3648	DCHECK(mode() == RegisterKind::kSimd128)((void) 0);
3649	for (TopLevelLiveRange* current : data()->fixed_simd128_live_ranges()) {
3650	if (current != nullptr) {
3651	if (current->IsDeferredFixed()) continue;
3652	AddToInactive(current);
3653	}
3654	}
3655	}
3656
3657	RpoNumber last_block = RpoNumber::FromInt(0);
3658	RpoNumber max_blocks =
3659	RpoNumber::FromInt(code()->InstructionBlockCount() - 1);
3660	LifetimePosition next_block_boundary =
3661	LifetimePosition::InstructionFromInstructionIndex(
3662	data()
3663	->code()
3664	->InstructionBlockAt(last_block)
3665	->last_instruction_index())
3666	.NextFullStart();
3667	SpillMode spill_mode = SpillMode::kSpillAtDefinition;
3668
3669	// Process all ranges. We also need to ensure that we have seen all block
3670	// boundaries. Linear scan might have assigned and spilled ranges before
3671	// reaching the last block and hence we would ignore control flow effects for
3672	// those. Not only does this produce a potentially bad assignment, it also
3673	// breaks with the invariant that we undo spills that happen in deferred code
3674	// when crossing a deferred/non-deferred boundary.
3675	while (!unhandled_live_ranges().empty() \|\| last_block < max_blocks) {
3676	data()->tick_counter()->TickAndMaybeEnterSafepoint();
3677	LiveRange* current = unhandled_live_ranges().empty()
3678	? nullptr
3679	: *unhandled_live_ranges().begin();
3680	LifetimePosition position =
3681	current ? current->Start() : next_block_boundary;
3682	#ifdef DEBUG
3683	allocation_finger_ = position;
3684	#endif
3685	// Check whether we just moved across a block boundary. This will trigger
3686	// for the first range that is past the current boundary.
3687	if (position >= next_block_boundary) {
3688	TRACE("Processing boundary at %d leaving %d\n",
3689	next_block_boundary.value(), last_block.ToInt());
3690
3691	// Forward state to before block boundary
3692	LifetimePosition end_of_block = next_block_boundary.PrevStart().End();
3693	ForwardStateTo(end_of_block);
3694
3695	// Remember this state.
3696	InstructionBlock* current_block = data()->code()->GetInstructionBlock(
3697	next_block_boundary.ToInstructionIndex());
3698
3699	// Store current spill state (as the state at end of block). For
3700	// simplicity, we store the active ranges, e.g., the live ranges that
3701	// are not spilled.
3702	data()->RememberSpillState(last_block, active_live_ranges());
3703
3704	// Only reset the state if this was not a direct fallthrough. Otherwise
3705	// control flow resolution will get confused (it does not expect changes
3706	// across fallthrough edges.).
3707	bool fallthrough =
3708	(current_block->PredecessorCount() == 1) &&
3709	current_block->predecessors()[0].IsNext(current_block->rpo_number());
3710
3711	// When crossing a deferred/non-deferred boundary, we have to load or
3712	// remove the deferred fixed ranges from inactive.
3713	if ((spill_mode == SpillMode::kSpillDeferred) !=
3714	current_block->IsDeferred()) {
3715	// Update spill mode.
3716	spill_mode = current_block->IsDeferred()
3717	? SpillMode::kSpillDeferred
3718	: SpillMode::kSpillAtDefinition;
3719
3720	ForwardStateTo(next_block_boundary);
3721
3722	#ifdef DEBUG
3723	// Allow allocation at current position.
3724	allocation_finger_ = next_block_boundary;
3725	#endif
3726	UpdateDeferredFixedRanges(spill_mode, current_block);
3727	}
3728
3729	// Allocation relies on the fact that each non-deferred block has at
3730	// least one non-deferred predecessor. Check this invariant here.
3731	DCHECK_IMPLIES(!current_block->IsDeferred(),((void) 0)
3732	HasNonDeferredPredecessor(current_block))((void) 0);
3733
3734	if (!fallthrough) {
3735	#ifdef DEBUG
3736	// Allow allocation at current position.
3737	allocation_finger_ = next_block_boundary;
3738	#endif
3739
3740	// We are currently at next_block_boundary - 1. Move the state to the
3741	// actual block boundary position. In particular, we have to
3742	// reactivate inactive ranges so that they get rescheduled for
3743	// allocation if they were not live at the predecessors.
3744	ForwardStateTo(next_block_boundary);
3745
3746	RangeWithRegisterSet to_be_live(data()->allocation_zone());
3747
3748	// If we end up deciding to use the state of the immediate
3749	// predecessor, it is better not to perform a change. It would lead to
3750	// the same outcome anyway.
3751	// This may never happen on boundaries between deferred and
3752	// non-deferred code, as we rely on explicit respill to ensure we
3753	// spill at definition.
3754	bool no_change_required = false;
3755
3756	auto pick_state_from = [this, current_block](
3757	RpoNumber pred,
3758	RangeWithRegisterSet* to_be_live) -> bool {
3759	TRACE("Using information from B%d\n", pred.ToInt());
3760	// If this is a fall-through that is not across a deferred
3761	// boundary, there is nothing to do.
3762	bool is_noop = pred.IsNext(current_block->rpo_number());
3763	if (!is_noop) {
3764	auto& spill_state = data()->GetSpillState(pred);
3765	TRACE("Not a fallthrough. Adding %zu elements...\n",
3766	spill_state.size());
3767	LifetimePosition pred_end =
3768	LifetimePosition::GapFromInstructionIndex(
3769	this->code()->InstructionBlockAt(pred)->code_end());
3770	for (const auto range : spill_state) {
3771	// Filter out ranges that were split or had their register
3772	// stolen by backwards working spill heuristics. These have
3773	// been spilled after the fact, so ignore them.
3774	if (range->End() < pred_end \|\| !range->HasRegisterAssigned())
3775	continue;
3776	to_be_live->emplace(range);
3777	}
3778	}
3779	return is_noop;
3780	};
3781
3782	// Multiple cases here:
3783	// 1) We have a single predecessor => this is a control flow split, so
3784	// just restore the predecessor state.
3785	// 2) We have two predecessors => this is a conditional, so break ties
3786	// based on what to do based on forward uses, trying to benefit
3787	// the same branch if in doubt (make one path fast).
3788	// 3) We have many predecessors => this is a switch. Compute union
3789	// based on majority, break ties by looking forward.
3790	if (current_block->PredecessorCount() == 1) {
3791	TRACE("Single predecessor for B%d\n",
3792	current_block->rpo_number().ToInt());
3793	no_change_required =
3794	pick_state_from(current_block->predecessors()[0], &to_be_live);
3795	} else if (current_block->PredecessorCount() == 2) {
3796	TRACE("Two predecessors for B%d\n",
3797	current_block->rpo_number().ToInt());
3798	// If one of the branches does not contribute any information,
3799	// e.g. because it is deferred or a back edge, we can short cut
3800	// here right away.
3801	RpoNumber chosen_predecessor = RpoNumber::Invalid();
3802	if (!ConsiderBlockForControlFlow(current_block,
3803	current_block->predecessors()[0])) {
3804	chosen_predecessor = current_block->predecessors()[1];
3805	} else if (!ConsiderBlockForControlFlow(
3806	current_block, current_block->predecessors()[1])) {
3807	chosen_predecessor = current_block->predecessors()[0];
3808	} else {
3809	chosen_predecessor = ChooseOneOfTwoPredecessorStates(
3810	current_block, next_block_boundary);
3811	}
3812	no_change_required = pick_state_from(chosen_predecessor, &to_be_live);
3813
3814	} else {
3815	// Merge at the end of, e.g., a switch.
3816	ComputeStateFromManyPredecessors(current_block, &to_be_live);
3817	}
3818
3819	if (!no_change_required) {
3820	SpillNotLiveRanges(&to_be_live, next_block_boundary, spill_mode);
3821	ReloadLiveRanges(to_be_live, next_block_boundary);
3822	}
3823	}
3824	// Update block information
3825	last_block = current_block->rpo_number();
3826	next_block_boundary = LifetimePosition::InstructionFromInstructionIndex(
3827	current_block->last_instruction_index())
3828	.NextFullStart();
3829
3830	// We might have created new unhandled live ranges, so cycle around the
3831	// loop to make sure we pick the top most range in unhandled for
3832	// processing.
3833	continue;
3834	}
3835
3836	DCHECK_NOT_NULL(current)((void) 0);
3837
3838	TRACE("Processing interval %d:%d start=%d\n", current->TopLevel()->vreg(),
3839	current->relative_id(), position.value());
3840
3841	// Now we can erase current, as we are sure to process it.
3842	unhandled_live_ranges().erase(unhandled_live_ranges().begin());
3843
3844	if (current->IsTopLevel() && TryReuseSpillForPhi(current->TopLevel()))
3845	continue;
3846
3847	ForwardStateTo(position);
3848
3849	DCHECK(!current->HasRegisterAssigned() && !current->spilled())((void) 0);
3850
3851	ProcessCurrentRange(current, spill_mode);
3852	}
3853
3854	if (data()->is_trace_alloc()) {
3855	PrintRangeOverview();
3856	}
3857	}
3858
3859	void LinearScanAllocator::SetLiveRangeAssignedRegister(LiveRange* range,
3860	int reg) {
3861	data()->MarkAllocated(range->representation(), reg);
3862	range->set_assigned_register(reg);
3863	range->SetUseHints(reg);
3864	range->UpdateBundleRegister(reg);
3865	if (range->IsTopLevel() && range->TopLevel()->is_phi()) {
3866	data()->GetPhiMapValueFor(range->TopLevel())->set_assigned_register(reg);
3867	}
3868	}
3869
3870	void LinearScanAllocator::AddToActive(LiveRange* range) {
3871	TRACE("Add live range %d:%d in %s to active\n", range->TopLevel()->vreg(),
3872	range->relative_id(), RegisterName(range->assigned_register()));
3873	active_live_ranges().push_back(range);
3874	next_active_ranges_change_ =
3875	std::min(next_active_ranges_change_, range->NextEndAfter(range->Start()));
3876	}
3877
3878	void LinearScanAllocator::AddToInactive(LiveRange* range) {
3879	TRACE("Add live range %d:%d to inactive\n", range->TopLevel()->vreg(),
3880	range->relative_id());
3881	next_inactive_ranges_change_ = std::min(
3882	next_inactive_ranges_change_, range->NextStartAfter(range->Start()));
3883	DCHECK(range->HasRegisterAssigned())((void) 0);
3884	inactive_live_ranges(range->assigned_register()).insert(range);
3885	}
3886
3887	void LinearScanAllocator::AddToUnhandled(LiveRange* range) {
3888	if (range == nullptr \|\| range->IsEmpty()) return;
3889	DCHECK(!range->HasRegisterAssigned() && !range->spilled())((void) 0);
3890	DCHECK(allocation_finger_ <= range->Start())((void) 0);
3891
3892	TRACE("Add live range %d:%d to unhandled\n", range->TopLevel()->vreg(),
3893	range->relative_id());
3894	unhandled_live_ranges().insert(range);
3895	}
3896
3897	ZoneVector<LiveRange*>::iterator LinearScanAllocator::ActiveToHandled(
3898	const ZoneVector<LiveRange*>::iterator it) {
3899	TRACE("Moving live range %d:%d from active to handled\n",
3900	(it)->TopLevel()->vreg(), (it)->relative_id());
3901	return active_live_ranges().erase(it);
3902	}
3903
3904	ZoneVector<LiveRange*>::iterator LinearScanAllocator::ActiveToInactive(
3905	const ZoneVector<LiveRange*>::iterator it, LifetimePosition position) {
3906	LiveRange* range = *it;
3907	TRACE("Moving live range %d:%d from active to inactive\n",
3908	(range)->TopLevel()->vreg(), range->relative_id());
3909	LifetimePosition next_active = range->NextStartAfter(position);
3910	next_inactive_ranges_change_ =
3911	std::min(next_inactive_ranges_change_, next_active);
3912	DCHECK(range->HasRegisterAssigned())((void) 0);
3913	inactive_live_ranges(range->assigned_register()).insert(range);
3914	return active_live_ranges().erase(it);
3915	}
3916
3917	LinearScanAllocator::InactiveLiveRangeQueue::iterator
3918	LinearScanAllocator::InactiveToHandled(InactiveLiveRangeQueue::iterator it) {
3919	LiveRange* range = *it;
3920	TRACE("Moving live range %d:%d from inactive to handled\n",
3921	range->TopLevel()->vreg(), range->relative_id());
3922	int reg = range->assigned_register();
3923	return inactive_live_ranges(reg).erase(it);
3924	}
3925
3926	LinearScanAllocator::InactiveLiveRangeQueue::iterator
3927	LinearScanAllocator::InactiveToActive(InactiveLiveRangeQueue::iterator it,
3928	LifetimePosition position) {
3929	LiveRange* range = *it;
3930	active_live_ranges().push_back(range);
3931	TRACE("Moving live range %d:%d from inactive to active\n",
3932	range->TopLevel()->vreg(), range->relative_id());
3933	next_active_ranges_change_ =
3934	std::min(next_active_ranges_change_, range->NextEndAfter(position));
3935	int reg = range->assigned_register();
3936	return inactive_live_ranges(reg).erase(it);
3937	}
3938
3939	void LinearScanAllocator::ForwardStateTo(LifetimePosition position) {
3940	if (position >= next_active_ranges_change_) {
3941	next_active_ranges_change_ = LifetimePosition::MaxPosition();
3942	for (auto it = active_live_ranges().begin();
3943	it != active_live_ranges().end();) {
3944	LiveRange* cur_active = *it;
3945	if (cur_active->End() <= position) {
3946	it = ActiveToHandled(it);
3947	} else if (!cur_active->Covers(position)) {
3948	it = ActiveToInactive(it, position);
3949	} else {
3950	next_active_ranges_change_ = std::min(
3951	next_active_ranges_change_, cur_active->NextEndAfter(position));
3952	++it;
3953	}
3954	}
3955	}
3956
3957	if (position >= next_inactive_ranges_change_) {
3958	next_inactive_ranges_change_ = LifetimePosition::MaxPosition();
3959	for (int reg = 0; reg < num_registers(); ++reg) {
3960	ZoneVector<LiveRange*> reorder(data()->allocation_zone());
3961	for (auto it = inactive_live_ranges(reg).begin();
3962	it != inactive_live_ranges(reg).end();) {
3963	LiveRange* cur_inactive = *it;
3964	if (cur_inactive->End() <= position) {
3965	it = InactiveToHandled(it);
3966	} else if (cur_inactive->Covers(position)) {
3967	it = InactiveToActive(it, position);
3968	} else {
3969	next_inactive_ranges_change_ =
3970	std::min(next_inactive_ranges_change_,
3971	cur_inactive->NextStartAfter(position));
3972	it = inactive_live_ranges(reg).erase(it);
3973	reorder.push_back(cur_inactive);
3974	}
3975	}
3976	for (LiveRange* range : reorder) {
3977	inactive_live_ranges(reg).insert(range);
3978	}
3979	}
3980	}
3981	}
3982
3983	int LinearScanAllocator::LastDeferredInstructionIndex(InstructionBlock* start) {
3984	DCHECK(start->IsDeferred())((void) 0);
3985	RpoNumber last_block =
3986	RpoNumber::FromInt(code()->InstructionBlockCount() - 1);
3987	while ((start->rpo_number() < last_block)) {
3988	InstructionBlock* next =
3989	code()->InstructionBlockAt(start->rpo_number().Next());
3990	if (!next->IsDeferred()) break;
3991	start = next;
3992	}
3993	return start->last_instruction_index();
3994	}
3995
3996	void LinearScanAllocator::GetFPRegisterSet(MachineRepresentation rep,
3997	int* num_regs, int* num_codes,
3998	const int** codes) const {
3999	DCHECK_EQ(kFPAliasing, AliasingKind::kCombine)((void) 0);
4000	if (rep == MachineRepresentation::kFloat32) {
4001	*num_regs = data()->config()->num_float_registers();
4002	*num_codes = data()->config()->num_allocatable_float_registers();
4003	*codes = data()->config()->allocatable_float_codes();
4004	} else if (rep == MachineRepresentation::kSimd128) {
4005	*num_regs = data()->config()->num_simd128_registers();
4006	*num_codes = data()->config()->num_allocatable_simd128_registers();
4007	*codes = data()->config()->allocatable_simd128_codes();
4008	} else {
4009	UNREACHABLE()V8_Fatal("unreachable code");
4010	}
4011	}
4012
4013	void LinearScanAllocator::GetSIMD128RegisterSet(int* num_regs, int* num_codes,
4014	const int** codes) const {
4015	DCHECK_EQ(kFPAliasing, AliasingKind::kIndependent)((void) 0);
4016
4017	*num_regs = data()->config()->num_simd128_registers();
4018	*num_codes = data()->config()->num_allocatable_simd128_registers();
4019	*codes = data()->config()->allocatable_simd128_codes();
4020	}
4021
4022	void LinearScanAllocator::FindFreeRegistersForRange(
4023	LiveRange* range, base::Vector<LifetimePosition> positions) {
4024	int num_regs = num_registers();
4025	int num_codes = num_allocatable_registers();
4026	const int* codes = allocatable_register_codes();
4027	MachineRepresentation rep = range->representation();
	Value stored to 'rep' during its initialization is never read
4028	if (kFPAliasing == AliasingKind::kCombine &&
4029	(rep == MachineRepresentation::kFloat32 \|\|
4030	rep == MachineRepresentation::kSimd128)) {
4031	GetFPRegisterSet(rep, &num_regs, &num_codes, &codes);
4032	} else if (kFPAliasing == AliasingKind::kIndependent &&
4033	(rep == MachineRepresentation::kSimd128)) {
4034	GetSIMD128RegisterSet(&num_regs, &num_codes, &codes);
4035	}
4036	DCHECK_GE(positions.length(), num_regs)((void) 0);
4037
4038	for (int i = 0; i < num_regs; ++i) {
4039	positions[i] = LifetimePosition::MaxPosition();
4040	}
4041
4042	for (LiveRange* cur_active : active_live_ranges()) {
4043	int cur_reg = cur_active->assigned_register();
4044	if (kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing()) {
4045	positions[cur_reg] = LifetimePosition::GapFromInstructionIndex(0);
4046	TRACE("Register %s is free until pos %d (1) due to %d\n",
4047	RegisterName(cur_reg),
4048	LifetimePosition::GapFromInstructionIndex(0).value(),
4049	cur_active->TopLevel()->vreg());
4050	} else {
4051	int alias_base_index = -1;
4052	int aliases = data()->config()->GetAliases(
4053	cur_active->representation(), cur_reg, rep, &alias_base_index);
4054	DCHECK(aliases > 0 \|\| (aliases == 0 && alias_base_index == -1))((void) 0);
4055	while (aliases--) {
4056	int aliased_reg = alias_base_index + aliases;
4057	positions[aliased_reg] = LifetimePosition::GapFromInstructionIndex(0);
4058	}
4059	}
4060	}
4061
4062	for (int cur_reg = 0; cur_reg < num_regs; ++cur_reg) {
4063	for (LiveRange* cur_inactive : inactive_live_ranges(cur_reg)) {
4064	DCHECK_GT(cur_inactive->End(), range->Start())((void) 0);
4065	CHECK_EQ(cur_inactive->assigned_register(), cur_reg)do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(cur_inactive->assigned_register ())>::type, typename ::v8::base::pass_value_or_ref<decltype (cur_reg)>::type>((cur_inactive->assigned_register() ), (cur_reg)); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal("Check failed: %s.", "cur_inactive->assigned_register()" " " "==" " " "cur_reg"); } } while (false); } while (false);
4066	// No need to carry out intersections, when this register won't be
4067	// interesting to this range anyway.
4068	// TODO(mtrofin): extend to aliased ranges, too.
4069	if ((kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing()) &&
4070	(positions[cur_reg] <= cur_inactive->NextStart() \|\|
4071	range->End() <= cur_inactive->NextStart())) {
4072	break;
4073	}
4074	LifetimePosition next_intersection =
4075	cur_inactive->FirstIntersection(range);
4076	if (!next_intersection.IsValid()) continue;
4077	if (kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing()) {
4078	positions[cur_reg] = std::min(positions[cur_reg], next_intersection);
4079	TRACE("Register %s is free until pos %d (2)\n", RegisterName(cur_reg),
4080	positions[cur_reg].value());
4081	} else {
4082	int alias_base_index = -1;
4083	int aliases = data()->config()->GetAliases(
4084	cur_inactive->representation(), cur_reg, rep, &alias_base_index);
4085	DCHECK(aliases > 0 \|\| (aliases == 0 && alias_base_index == -1))((void) 0);
4086	while (aliases--) {
4087	int aliased_reg = alias_base_index + aliases;
4088	positions[aliased_reg] =
4089	std::min(positions[aliased_reg], next_intersection);
4090	}
4091	}
4092	}
4093	}
4094	}
4095
4096	// High-level register allocation summary:
4097	//
4098	// We attempt to first allocate the preferred (hint) register. If that is not
4099	// possible, we find a register that's free, and allocate that. If that's not
4100	// possible, we search for a register to steal from a range that was allocated.
4101	// The goal is to optimize for throughput by avoiding register-to-memory moves,
4102	// which are expensive.
4103	void LinearScanAllocator::ProcessCurrentRange(LiveRange* current,
4104	SpillMode spill_mode) {
4105	base::EmbeddedVector<LifetimePosition, RegisterConfiguration::kMaxRegisters>
4106	free_until_pos;
4107	FindFreeRegistersForRange(current, free_until_pos);
4108	if (!TryAllocatePreferredReg(current, free_until_pos)) {
4109	if (!TryAllocateFreeReg(current, free_until_pos)) {
4110	AllocateBlockedReg(current, spill_mode);
4111	}
4112	}
4113	if (current->HasRegisterAssigned()) {
4114	AddToActive(current);
4115	}
4116	}
4117
4118	bool LinearScanAllocator::TryAllocatePreferredReg(
4119	LiveRange* current, const base::Vector<LifetimePosition>& free_until_pos) {
4120	int hint_register;
4121	if (current->RegisterFromControlFlow(&hint_register) \|\|
4122	current->FirstHintPosition(&hint_register) != nullptr \|\|
4123	current->RegisterFromBundle(&hint_register)) {
4124	TRACE(
4125	"Found reg hint %s (free until [%d) for live range %d:%d (end %d[).\n",
4126	RegisterName(hint_register), free_until_pos[hint_register].value(),
4127	current->TopLevel()->vreg(), current->relative_id(),
4128	current->End().value());
4129
4130	// The desired register is free until the end of the current live range.
4131	if (free_until_pos[hint_register] >= current->End()) {
4132	TRACE("Assigning preferred reg %s to live range %d:%d\n",
4133	RegisterName(hint_register), current->TopLevel()->vreg(),
4134	current->relative_id());
4135	SetLiveRangeAssignedRegister(current, hint_register);
4136	return true;
4137	}
4138	}
4139	return false;
4140	}
4141
4142	int LinearScanAllocator::PickRegisterThatIsAvailableLongest(
4143	LiveRange* current, int hint_reg,
4144	const base::Vector<LifetimePosition>& free_until_pos) {
4145	int num_regs = 0; // used only for the call to GetFPRegisterSet.
4146	int num_codes = num_allocatable_registers();
4147	const int* codes = allocatable_register_codes();
4148	MachineRepresentation rep = current->representation();
4149	if (kFPAliasing == AliasingKind::kCombine &&
4150	(rep == MachineRepresentation::kFloat32 \|\|
4151	rep == MachineRepresentation::kSimd128)) {
4152	GetFPRegisterSet(rep, &num_regs, &num_codes, &codes);
4153	} else if (kFPAliasing == AliasingKind::kIndependent &&
4154	(rep == MachineRepresentation::kSimd128)) {
4155	GetSIMD128RegisterSet(&num_regs, &num_codes, &codes);
4156	}
4157
4158	DCHECK_GE(free_until_pos.length(), num_codes)((void) 0);
4159
4160	// Find the register which stays free for the longest time. Check for
4161	// the hinted register first, as we might want to use that one. Only
4162	// count full instructions for free ranges, as an instruction's internal
4163	// positions do not help but might shadow a hinted register. This is
4164	// typically the case for function calls, where all registered are
4165	// cloberred after the call except for the argument registers, which are
4166	// set before the call. Hence, the argument registers always get ignored,
4167	// as their available time is shorter.
4168	int reg = (hint_reg == kUnassignedRegister) ? codes[0] : hint_reg;
4169	int current_free = free_until_pos[reg].ToInstructionIndex();
4170	for (int i = 0; i < num_codes; ++i) {
4171	int code = codes[i];
4172	// Prefer registers that have no fixed uses to avoid blocking later hints.
4173	// We use the first register that has no fixed uses to ensure we use
4174	// byte addressable registers in ia32 first.
4175	int candidate_free = free_until_pos[code].ToInstructionIndex();
4176	TRACE("Register %s in free until %d\n", RegisterName(code), candidate_free);
4177	if ((candidate_free > current_free) \|\|
4178	(candidate_free == current_free && reg != hint_reg &&
4179	(data()->HasFixedUse(current->representation(), reg) &&
4180	!data()->HasFixedUse(current->representation(), code)))) {
4181	reg = code;
4182	current_free = candidate_free;
4183	}
4184	}
4185
4186	return reg;
4187	}
4188
4189	bool LinearScanAllocator::TryAllocateFreeReg(
4190	LiveRange* current, const base::Vector<LifetimePosition>& free_until_pos) {
4191	// Compute register hint, if such exists.
4192	int hint_reg = kUnassignedRegister;
4193	current->RegisterFromControlFlow(&hint_reg) \|\|
4194	current->FirstHintPosition(&hint_reg) != nullptr \|\|
4195	current->RegisterFromBundle(&hint_reg);
4196
4197	int reg =
4198	PickRegisterThatIsAvailableLongest(current, hint_reg, free_until_pos);
4199
4200	LifetimePosition pos = free_until_pos[reg];
4201
4202	if (pos <= current->Start()) {
4203	// All registers are blocked.
4204	return false;
4205	}
4206
4207	if (pos < current->End()) {
4208	// Register reg is available at the range start but becomes blocked before
4209	// the range end. Split current before the position where it becomes
4210	// blocked. Shift the split position to the last gap position. This is to
4211	// ensure that if a connecting move is needed, that move coincides with the
4212	// start of the range that it defines. See crbug.com/1182985.
4213	LifetimePosition gap_pos =
4214	pos.IsGapPosition() ? pos : pos.FullStart().End();
4215	if (gap_pos <= current->Start()) return false;
4216	LiveRange* tail = SplitRangeAt(current, gap_pos);
4217	AddToUnhandled(tail);
4218
4219	// Try to allocate preferred register once more.
4220	if (TryAllocatePreferredReg(current, free_until_pos)) return true;
4221	}
4222
4223	// Register reg is available at the range start and is free until the range
4224	// end.
4225	DCHECK_GE(pos, current->End())((void) 0);
4226	TRACE("Assigning free reg %s to live range %d:%d\n", RegisterName(reg),
4227	current->TopLevel()->vreg(), current->relative_id());
4228	SetLiveRangeAssignedRegister(current, reg);
4229
4230	return true;
4231	}
4232
4233	void LinearScanAllocator::AllocateBlockedReg(LiveRange* current,
4234	SpillMode spill_mode) {
4235	UsePosition* register_use = current->NextRegisterPosition(current->Start());
4236	if (register_use == nullptr) {
4237	// There is no use in the current live range that requires a register.
4238	// We can just spill it.
4239	LiveRange* begin_spill = nullptr;
4240	LifetimePosition spill_pos = FindOptimalSpillingPos(
4241	current, current->Start(), spill_mode, &begin_spill);
4242	MaybeSpillPreviousRanges(begin_spill, spill_pos, current);
4243	Spill(current, spill_mode);
4244	return;
4245	}
4246
4247	MachineRepresentation rep = current->representation();
4248
4249	// use_pos keeps track of positions a register/alias is used at.
4250	// block_pos keeps track of positions where a register/alias is blocked
4251	// from.
4252	base::EmbeddedVector<LifetimePosition, RegisterConfiguration::kMaxRegisters>
4253	use_pos(LifetimePosition::MaxPosition());
4254	base::EmbeddedVector<LifetimePosition, RegisterConfiguration::kMaxRegisters>
4255	block_pos(LifetimePosition::MaxPosition());
4256
4257	for (LiveRange* range : active_live_ranges()) {
4258	int cur_reg = range->assigned_register();
4259	bool is_fixed_or_cant_spill =
4260	range->TopLevel()->IsFixed() \|\| !range->CanBeSpilled(current->Start());
4261	if (kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing()) {
4262	if (is_fixed_or_cant_spill) {
4263	block_pos[cur_reg] = use_pos[cur_reg] =
4264	LifetimePosition::GapFromInstructionIndex(0);
4265	} else {
4266	DCHECK_NE(LifetimePosition::GapFromInstructionIndex(0),((void) 0)
4267	block_pos[cur_reg])((void) 0);
4268	use_pos[cur_reg] =
4269	range->NextLifetimePositionRegisterIsBeneficial(current->Start());
4270	}
4271	} else {
4272	int alias_base_index = -1;
4273	int aliases = data()->config()->GetAliases(
4274	range->representation(), cur_reg, rep, &alias_base_index);
4275	DCHECK(aliases > 0 \|\| (aliases == 0 && alias_base_index == -1))((void) 0);
4276	while (aliases--) {
4277	int aliased_reg = alias_base_index + aliases;
4278	if (is_fixed_or_cant_spill) {
4279	block_pos[aliased_reg] = use_pos[aliased_reg] =
4280	LifetimePosition::GapFromInstructionIndex(0);
4281	} else {
4282	use_pos[aliased_reg] =
4283	std::min(block_pos[aliased_reg],
4284	range->NextLifetimePositionRegisterIsBeneficial(
4285	current->Start()));
4286	}
4287	}
4288	}
4289	}
4290
4291	for (int cur_reg = 0; cur_reg < num_registers(); ++cur_reg) {
4292	for (LiveRange* range : inactive_live_ranges(cur_reg)) {
4293	DCHECK(range->End() > current->Start())((void) 0);
4294	DCHECK_EQ(range->assigned_register(), cur_reg)((void) 0);
4295	bool is_fixed = range->TopLevel()->IsFixed();
4296
4297	// Don't perform costly intersections if they are guaranteed to not update
4298	// block_pos or use_pos.
4299	// TODO(mtrofin): extend to aliased ranges, too.
4300	if ((kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing())) {
4301	DCHECK_LE(use_pos[cur_reg], block_pos[cur_reg])((void) 0);
4302	if (block_pos[cur_reg] <= range->NextStart()) break;
4303	if (!is_fixed && use_pos[cur_reg] <= range->NextStart()) continue;
4304	}
4305
4306	LifetimePosition next_intersection = range->FirstIntersection(current);
4307	if (!next_intersection.IsValid()) continue;
4308
4309	if (kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing()) {
4310	if (is_fixed) {
4311	block_pos[cur_reg] = std::min(block_pos[cur_reg], next_intersection);
4312	use_pos[cur_reg] = std::min(block_pos[cur_reg], use_pos[cur_reg]);
4313	} else {
4314	use_pos[cur_reg] = std::min(use_pos[cur_reg], next_intersection);
4315	}
4316	} else {
4317	int alias_base_index = -1;
4318	int aliases = data()->config()->GetAliases(
4319	range->representation(), cur_reg, rep, &alias_base_index);
4320	DCHECK(aliases > 0 \|\| (aliases == 0 && alias_base_index == -1))((void) 0);
4321	while (aliases--) {
4322	int aliased_reg = alias_base_index + aliases;
4323	if (is_fixed) {
4324	block_pos[aliased_reg] =
4325	std::min(block_pos[aliased_reg], next_intersection);
4326	use_pos[aliased_reg] =
4327	std::min(block_pos[aliased_reg], use_pos[aliased_reg]);
4328	} else {
4329	use_pos[aliased_reg] =
4330	std::min(use_pos[aliased_reg], next_intersection);
4331	}
4332	}
4333	}
4334	}
4335	}
4336
4337	// Compute register hint if it exists.
4338	int hint_reg = kUnassignedRegister;
4339	current->RegisterFromControlFlow(&hint_reg) \|\|
4340	register_use->HintRegister(&hint_reg) \|\|
4341	current->RegisterFromBundle(&hint_reg);
4342	int reg = PickRegisterThatIsAvailableLongest(current, hint_reg, use_pos);
4343
4344	if (use_pos[reg] < register_use->pos()) {
4345	// If there is a gap position before the next register use, we can
4346	// spill until there. The gap position will then fit the fill move.
4347	if (LifetimePosition::ExistsGapPositionBetween(current->Start(),
4348	register_use->pos())) {
4349	SpillBetween(current, current->Start(), register_use->pos(), spill_mode);
4350	return;
4351	}
4352	}
4353
4354	// When in deferred spilling mode avoid stealing registers beyond the current
4355	// deferred region. This is required as we otherwise might spill an inactive
4356	// range with a start outside of deferred code and that would not be reloaded.
4357	LifetimePosition new_end = current->End();
4358	if (spill_mode == SpillMode::kSpillDeferred) {
4359	InstructionBlock* deferred_block =
4360	code()->GetInstructionBlock(current->Start().ToInstructionIndex());
4361	new_end =
4362	std::min(new_end, LifetimePosition::GapFromInstructionIndex(
4363	LastDeferredInstructionIndex(deferred_block)));
4364	}
4365
4366	// We couldn't spill until the next register use. Split before the register
4367	// is blocked, if applicable.
4368	if (block_pos[reg] < new_end) {
4369	// Register becomes blocked before the current range end. Split before that
4370	// position.
4371	new_end = block_pos[reg].Start();
4372	}
4373
4374	// If there is no register available at all, we can only spill this range.
4375	// Happens for instance on entry to deferred code where registers might
4376	// become blocked yet we aim to reload ranges.
4377	if (new_end == current->Start()) {
4378	SpillBetween(current, new_end, register_use->pos(), spill_mode);
4379	return;
4380	}
4381
4382	// Split at the new end if we found one.
4383	if (new_end != current->End()) {
4384	LiveRange* tail = SplitBetween(current, current->Start(), new_end);
4385	AddToUnhandled(tail);
4386	}
4387
4388	// Register reg is not blocked for the whole range.
4389	DCHECK(block_pos[reg] >= current->End())((void) 0);
4390	TRACE("Assigning blocked reg %s to live range %d:%d\n", RegisterName(reg),
4391	current->TopLevel()->vreg(), current->relative_id());
4392	SetLiveRangeAssignedRegister(current, reg);
4393
4394	// This register was not free. Thus we need to find and spill
4395	// parts of active and inactive live regions that use the same register
4396	// at the same lifetime positions as current.
4397	SplitAndSpillIntersecting(current, spill_mode);
4398	}
4399
4400	void LinearScanAllocator::SplitAndSpillIntersecting(LiveRange* current,
4401	SpillMode spill_mode) {
4402	DCHECK(current->HasRegisterAssigned())((void) 0);
4403	int reg = current->assigned_register();
4404	LifetimePosition split_pos = current->Start();
4405	for (auto it = active_live_ranges().begin();
4406	it != active_live_ranges().end();) {
4407	LiveRange* range = *it;
4408	if (kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing()) {
4409	if (range->assigned_register() != reg) {
4410	++it;
4411	continue;
4412	}
4413	} else {
4414	if (!data()->config()->AreAliases(current->representation(), reg,
4415	range->representation(),
4416	range->assigned_register())) {
4417	++it;
4418	continue;
4419	}
4420	}
4421
4422	UsePosition* next_pos = range->NextRegisterPosition(current->Start());
4423	LiveRange* begin_spill = nullptr;
4424	LifetimePosition spill_pos =
4425	FindOptimalSpillingPos(range, split_pos, spill_mode, &begin_spill);
4426	MaybeSpillPreviousRanges(begin_spill, spill_pos, range);
4427	if (next_pos == nullptr) {
4428	SpillAfter(range, spill_pos, spill_mode);
4429	} else {
4430	// When spilling between spill_pos and next_pos ensure that the range
4431	// remains spilled at least until the start of the current live range.
4432	// This guarantees that we will not introduce new unhandled ranges that
4433	// start before the current range as this violates allocation invariants
4434	// and will lead to an inconsistent state of active and inactive
4435	// live-ranges: ranges are allocated in order of their start positions,
4436	// ranges are retired from active/inactive when the start of the
4437	// current live-range is larger than their end.
4438	DCHECK(LifetimePosition::ExistsGapPositionBetween(current->Start(),((void) 0)
4439	next_pos->pos()))((void) 0);
4440	SpillBetweenUntil(range, spill_pos, current->Start(), next_pos->pos(),
4441	spill_mode);
4442	}
4443	it = ActiveToHandled(it);
4444	}
4445
4446	for (int cur_reg = 0; cur_reg < num_registers(); ++cur_reg) {
4447	if (kFPAliasing != AliasingKind::kCombine \|\| !check_fp_aliasing()) {
4448	if (cur_reg != reg) continue;
4449	}
4450	for (auto it = inactive_live_ranges(cur_reg).begin();
4451	it != inactive_live_ranges(cur_reg).end();) {
4452	LiveRange* range = *it;
4453	if (kFPAliasing == AliasingKind::kCombine && check_fp_aliasing() &&
4454	!data()->config()->AreAliases(current->representation(), reg,
4455	range->representation(), cur_reg)) {
4456	++it;
4457	continue;
4458	}
4459	DCHECK(range->End() > current->Start())((void) 0);
4460	if (range->TopLevel()->IsFixed()) {
4461	++it;
4462	continue;
4463	}
4464
4465	LifetimePosition next_intersection = range->FirstIntersection(current);
4466	if (next_intersection.IsValid()) {
4467	UsePosition* next_pos = range->NextRegisterPosition(current->Start());
4468	if (next_pos == nullptr) {
4469	SpillAfter(range, split_pos, spill_mode);
4470	} else {
4471	next_intersection = std::min(next_intersection, next_pos->pos());
4472	SpillBetween(range, split_pos, next_intersection, spill_mode);
4473	}
4474	it = InactiveToHandled(it);
4475	} else {
4476	++it;
4477	}
4478	}
4479	}
4480	}
4481
4482	bool LinearScanAllocator::TryReuseSpillForPhi(TopLevelLiveRange* range) {
4483	if (!range->is_phi()) return false;
4484
4485	DCHECK(!range->HasSpillOperand())((void) 0);
4486	// Check how many operands belong to the same bundle as the output.
4487	LiveRangeBundle* out_bundle = range->get_bundle();
4488	TopTierRegisterAllocationData::PhiMapValue* phi_map_value =
4489	data()->GetPhiMapValueFor(range);
4490	const PhiInstruction* phi = phi_map_value->phi();
4491	const InstructionBlock* block = phi_map_value->block();
4492	// Count the number of spilled operands.
4493	size_t spilled_count = 0;
4494	for (size_t i = 0; i < phi->operands().size(); i++) {
4495	int op = phi->operands()[i];
4496	LiveRange* op_range = data()->GetOrCreateLiveRangeFor(op);
4497	if (!op_range->TopLevel()->HasSpillRange()) continue;
4498	const InstructionBlock* pred =
4499	code()->InstructionBlockAt(block->predecessors()[i]);
4500	LifetimePosition pred_end =
4501	LifetimePosition::InstructionFromInstructionIndex(
4502	pred->last_instruction_index());
4503	while (op_range != nullptr && !op_range->CanCover(pred_end)) {
4504	op_range = op_range->next();
4505	}
4506	if (op_range != nullptr && op_range->spilled() &&
4507	op_range->get_bundle() == out_bundle) {
4508	spilled_count++;
4509	}
4510	}
4511
4512	// Only continue if more than half of the operands are spilled to the same
4513	// slot (because part of same bundle).
4514	if (spilled_count * 2 <= phi->operands().size()) {
4515	return false;
4516	}
4517
4518	// If the range does not need register soon, spill it to the merged
4519	// spill range.
4520	LifetimePosition next_pos = range->Start();
4521	if (next_pos.IsGapPosition()) next_pos = next_pos.NextStart();
4522	UsePosition* pos = range->NextUsePositionRegisterIsBeneficial(next_pos);
4523	if (pos == nullptr) {
4524	Spill(range, SpillMode::kSpillAtDefinition);
4525	return true;
4526	} else if (pos->pos() > range->Start().NextStart()) {
4527	SpillBetween(range, range->Start(), pos->pos(),
4528	SpillMode::kSpillAtDefinition);
4529	return true;
4530	}
4531	return false;
4532	}
4533
4534	void LinearScanAllocator::SpillAfter(LiveRange* range, LifetimePosition pos,
4535	SpillMode spill_mode) {
4536	LiveRange* second_part = SplitRangeAt(range, pos);
4537	Spill(second_part, spill_mode);
4538	}
4539
4540	void LinearScanAllocator::SpillBetween(LiveRange* range, LifetimePosition start,
4541	LifetimePosition end,
4542	SpillMode spill_mode) {
4543	SpillBetweenUntil(range, start, start, end, spill_mode);
4544	}
4545
4546	void LinearScanAllocator::SpillBetweenUntil(LiveRange* range,
4547	LifetimePosition start,
4548	LifetimePosition until,
4549	LifetimePosition end,
4550	SpillMode spill_mode) {
4551	CHECK(start < end)do { if ((__builtin_expect(!!(!(start < end)), 0))) { V8_Fatal ("Check failed: %s.", "start < end"); } } while (false);
4552	LiveRange* second_part = SplitRangeAt(range, start);
4553
4554	if (second_part->Start() < end) {
4555	// The split result intersects with [start, end[.
4556	// Split it at position between ]start+1, end[, spill the middle part
4557	// and put the rest to unhandled.
4558
4559	// Make sure that the third part always starts after the start of the
4560	// second part, as that likely is the current position of the register
4561	// allocator and we cannot add ranges to unhandled that start before
4562	// the current position.
4563	LifetimePosition split_start = std::max(second_part->Start().End(), until);
4564
4565	// If end is an actual use (which it typically is) we have to split
4566	// so that there is a gap before so that we have space for moving the
4567	// value into its position.
4568	// However, if we have no choice, split right where asked.
4569	LifetimePosition third_part_end =
4570	std::max(split_start, end.PrevStart().End());
4571	// Instead of spliting right after or even before the block boundary,
4572	// split on the boumndary to avoid extra moves.
4573	if (data()->IsBlockBoundary(end.Start())) {
4574	third_part_end = std::max(split_start, end.Start());
4575	}
4576
4577	LiveRange* third_part =
4578	SplitBetween(second_part, split_start, third_part_end);
4579	if (GetInstructionBlock(data()->code(), second_part->Start())
4580	->IsDeferred()) {
4581	// Try to use the same register as before.
4582	TRACE("Setting control flow hint for %d:%d to %s\n",
4583	third_part->TopLevel()->vreg(), third_part->relative_id(),
4584	RegisterName(range->controlflow_hint()));
4585	third_part->set_controlflow_hint(range->controlflow_hint());
4586	}
4587
4588	AddToUnhandled(third_part);
4589	// This can happen, even if we checked for start < end above, as we fiddle
4590	// with the end location. However, we are guaranteed to be after or at
4591	// until, so this is fine.
4592	if (third_part != second_part) {
4593	Spill(second_part, spill_mode);
4594	}
4595	} else {
4596	// The split result does not intersect with [start, end[.
4597	// Nothing to spill. Just put it to unhandled as whole.
4598	AddToUnhandled(second_part);
4599	}
4600	}
4601
4602	OperandAssigner::OperandAssigner(TopTierRegisterAllocationData* data)
4603	: data_(data) {}
4604
4605	void OperandAssigner::DecideSpillingMode() {
4606	for (auto range : data()->live_ranges()) {
4607	data()->tick_counter()->TickAndMaybeEnterSafepoint();
4608	int max_blocks = data()->code()->InstructionBlockCount();
4609	if (range != nullptr && range->IsSpilledOnlyInDeferredBlocks(data())) {
4610	// If the range is spilled only in deferred blocks and starts in
4611	// a non-deferred block, we transition its representation here so
4612	// that the LiveRangeConnector processes them correctly. If,
4613	// however, they start in a deferred block, we uograde them to
4614	// spill at definition, as that definition is in a deferred block
4615	// anyway. While this is an optimization, the code in LiveRangeConnector
4616	// relies on it!
4617	if (GetInstructionBlock(data()->code(), range->Start())->IsDeferred()) {
4618	TRACE("Live range %d is spilled and alive in deferred code only\n",
4619	range->vreg());
4620	range->TransitionRangeToSpillAtDefinition();
4621	} else {
4622	TRACE("Live range %d is spilled deferred code only but alive outside\n",
4623	range->vreg());
4624	range->TransitionRangeToDeferredSpill(data()->allocation_zone(),
4625	max_blocks);
4626	}
4627	}
4628	}
4629	}
4630
4631	void OperandAssigner::AssignSpillSlots() {
4632	for (auto range : data()->live_ranges()) {
4633	data()->tick_counter()->TickAndMaybeEnterSafepoint();
4634	if (range != nullptr && range->get_bundle() != nullptr) {
4635	range->get_bundle()->MergeSpillRangesAndClear();
4636	}
4637	}
4638	ZoneVector<SpillRange*>& spill_ranges = data()->spill_ranges();
4639	// Merge disjoint spill ranges
4640	for (size_t i = 0; i < spill_ranges.size(); ++i) {
4641	data()->tick_counter()->TickAndMaybeEnterSafepoint();
4642	SpillRange* range = spill_ranges[i];
4643	if (range == nullptr) continue;
4644	if (range->IsEmpty()) continue;
4645	for (size_t j = i + 1; j < spill_ranges.size(); ++j) {
4646	SpillRange* other = spill_ranges[j];
4647	if (other != nullptr && !other->IsEmpty()) {
4648	range->TryMerge(other);
4649	}
4650	}
4651	}
4652	// Allocate slots for the merged spill ranges.
4653	for (SpillRange* range : spill_ranges) {
4654	data()->tick_counter()->TickAndMaybeEnterSafepoint();
4655	if (range == nullptr \|\| range->IsEmpty()) continue;
4656	if (!range->HasSlot()) {
4657	// Allocate a new operand referring to the spill slot, aligned to the
4658	// operand size.
4659	int width = range->byte_width();
4660	int index = data()->frame()->AllocateSpillSlot(width, width);
4661	range->set_assigned_slot(index);
4662	}
4663	}
4664	}
4665
4666	void OperandAssigner::CommitAssignment() {
4667	const size_t live_ranges_size = data()->live_ranges().size();
4668	for (TopLevelLiveRange* top_range : data()->live_ranges()) {
4669	data()->tick_counter()->TickAndMaybeEnterSafepoint();
4670	CHECK_EQ(live_ranges_size,do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false)
4671	data()->live_ranges().size())do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false); // TODO(neis): crbug.com/831822
4672	if (top_range == nullptr \|\| top_range->IsEmpty()) continue;
4673	InstructionOperand spill_operand;
4674	if (top_range->HasSpillOperand()) {
4675	auto it = data()->slot_for_const_range().find(top_range);
4676	if (it != data()->slot_for_const_range().end()) {
4677	spill_operand = *it->second;
4678	} else {
4679	spill_operand = *top_range->GetSpillOperand();
4680	}
4681	} else if (top_range->HasSpillRange()) {
4682	spill_operand = top_range->GetSpillRangeOperand();
4683	}
4684	if (top_range->is_phi()) {
4685	data()->GetPhiMapValueFor(top_range)->CommitAssignment(
4686	top_range->GetAssignedOperand());
4687	}
4688	for (LiveRange* range = top_range; range != nullptr;
4689	range = range->next()) {
4690	InstructionOperand assigned = range->GetAssignedOperand();
4691	DCHECK(!assigned.IsUnallocated())((void) 0);
4692	range->ConvertUsesToOperand(assigned, spill_operand);
4693	}
4694
4695	if (!spill_operand.IsInvalid()) {
4696	// If this top level range has a child spilled in a deferred block, we use
4697	// the range and control flow connection mechanism instead of spilling at
4698	// definition. Refer to the ConnectLiveRanges and ResolveControlFlow
4699	// phases. Normally, when we spill at definition, we do not insert a
4700	// connecting move when a successor child range is spilled - because the
4701	// spilled range picks up its value from the slot which was assigned at
4702	// definition. For ranges that are determined to spill only in deferred
4703	// blocks, we let ConnectLiveRanges and ResolveControlFlow find the blocks
4704	// where a spill operand is expected, and then finalize by inserting the
4705	// spills in the deferred blocks dominators.
4706	if (!top_range->IsSpilledOnlyInDeferredBlocks(data()) &&
4707	!top_range->HasGeneralSpillRange()) {
4708	// Spill at definition if the range isn't spilled in a way that will be
4709	// handled later.
4710	top_range->FilterSpillMoves(data(), spill_operand);
4711	top_range->CommitSpillMoves(data(), spill_operand);
4712	}
4713	}
4714	}
4715	}
4716
4717	ReferenceMapPopulator::ReferenceMapPopulator(
4718	TopTierRegisterAllocationData* data)
4719	: data_(data) {}
4720
4721	bool ReferenceMapPopulator::SafePointsAreInOrder() const {
4722	int safe_point = 0;
4723	for (ReferenceMap* map : *data()->code()->reference_maps()) {
4724	if (safe_point > map->instruction_position()) return false;
4725	safe_point = map->instruction_position();
4726	}
4727	return true;
4728	}
4729
4730	void ReferenceMapPopulator::PopulateReferenceMaps() {
4731	DCHECK(SafePointsAreInOrder())((void) 0);
4732	// Map all delayed references.
4733	for (TopTierRegisterAllocationData::DelayedReference& delayed_reference :
4734	data()->delayed_references()) {
4735	delayed_reference.map->RecordReference(
4736	AllocatedOperand::cast(*delayed_reference.operand));
4737	}
4738	// Iterate over all safe point positions and record a pointer
4739	// for all spilled live ranges at this point.
4740	int last_range_start = 0;
4741	const ReferenceMapDeque* reference_maps = data()->code()->reference_maps();
4742	ReferenceMapDeque::const_iterator first_it = reference_maps->begin();
4743	const size_t live_ranges_size = data()->live_ranges().size();
4744	// We break the invariant that live ranges are indexed by their vregs here.
4745	// This is ok because we don't use that invariant here, and this is the last
4746	// phase.
4747	std::sort(data()->live_ranges().begin(), data()->live_ranges().end(),
4748	[](TopLevelLiveRange* a, TopLevelLiveRange* b) {
4749	if (!a \|\| a->IsEmpty()) return false;
4750	if (!b \|\| b->IsEmpty()) return true;
4751	return a->Start() < b->Start();
4752	});
4753	for (TopLevelLiveRange* range : data()->live_ranges()) {
4754	CHECK_EQ(live_ranges_size,do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false)
4755	data()->live_ranges().size())do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false); // TODO(neis): crbug.com/831822
4756	if (range == nullptr) continue;
4757	// Skip non-reference values.
4758	if (!data()->code()->IsReference(range->vreg())) continue;
4759	// Skip empty live ranges.
4760	if (range->IsEmpty()) continue;
4761	if (range->has_preassigned_slot()) continue;
4762
4763	// Find the extent of the range and its children.
4764	int start = range->Start().ToInstructionIndex();
4765	int end = 0;
4766	for (LiveRange* cur = range; cur != nullptr; cur = cur->next()) {
4767	LifetimePosition this_end = cur->End();
4768	if (this_end.ToInstructionIndex() > end)
4769	end = this_end.ToInstructionIndex();
4770	DCHECK(cur->Start().ToInstructionIndex() >= start)((void) 0);
4771	}
4772
4773	// Ranges should be sorted, so that the first reference map in the current
4774	// live range has to be after {first_it}.
4775	DCHECK_LE(last_range_start, start)((void) 0);
4776	last_range_start = start;
4777	USE(last_range_start)do { ::v8::base::Use unused_tmp_array_for_use_macro[]{last_range_start }; (void)unused_tmp_array_for_use_macro; } while (false);
4778
4779	// Step across all the safe points that are before the start of this range,
4780	// recording how far we step in order to save doing this for the next range.
4781	for (; first_it != reference_maps->end(); ++first_it) {
4782	ReferenceMap* map = *first_it;
4783	if (map->instruction_position() >= start) break;
4784	}
4785
4786	InstructionOperand spill_operand;
4787	if (((range->HasSpillOperand() &&
4788	!range->GetSpillOperand()->IsConstant()) \|\|
4789	range->HasSpillRange())) {
4790	if (range->HasSpillOperand()) {
4791	spill_operand = *range->GetSpillOperand();
4792	} else {
4793	spill_operand = range->GetSpillRangeOperand();
4794	}
4795	DCHECK(spill_operand.IsStackSlot())((void) 0);
4796	DCHECK(CanBeTaggedOrCompressedPointer(((void) 0)
4797	AllocatedOperand::cast(spill_operand).representation()))((void) 0);
4798	}
4799
4800	LiveRange* cur = range;
4801	// Step through the safe points to see whether they are in the range.
4802	for (auto it = first_it; it != reference_maps->end(); ++it) {
4803	ReferenceMap* map = *it;
4804	int safe_point = map->instruction_position();
4805
4806	// The safe points are sorted so we can stop searching here.
4807	if (safe_point - 1 > end) break;
4808
4809	// Advance to the next active range that covers the current
4810	// safe point position.
4811	LifetimePosition safe_point_pos =
4812	LifetimePosition::InstructionFromInstructionIndex(safe_point);
4813
4814	// Search for the child range (cur) that covers safe_point_pos. If we
4815	// don't find it before the children pass safe_point_pos, keep cur at
4816	// the last child, because the next safe_point_pos may be covered by cur.
4817	// This may happen if cur has more than one interval, and the current
4818	// safe_point_pos is in between intervals.
4819	// For that reason, cur may be at most the last child.
4820	DCHECK_NOT_NULL(cur)((void) 0);
4821	DCHECK(safe_point_pos >= cur->Start() \|\| range == cur)((void) 0);
4822	bool found = false;
4823	while (!found) {
4824	if (cur->Covers(safe_point_pos)) {
4825	found = true;
4826	} else {
4827	LiveRange* next = cur->next();
4828	if (next == nullptr \|\| next->Start() > safe_point_pos) {
4829	break;
4830	}
4831	cur = next;
4832	}
4833	}
4834
4835	if (!found) {
4836	continue;
4837	}
4838
4839	// Check if the live range is spilled and the safe point is after
4840	// the spill position.
4841	int spill_index = range->IsSpilledOnlyInDeferredBlocks(data()) \|\|
4842	range->LateSpillingSelected()
4843	? cur->Start().ToInstructionIndex()
4844	: range->spill_start_index();
4845
4846	if (!spill_operand.IsInvalid() && safe_point >= spill_index) {
4847	TRACE("Pointer for range %d (spilled at %d) at safe point %d\n",
4848	range->vreg(), spill_index, safe_point);
4849	map->RecordReference(AllocatedOperand::cast(spill_operand));
4850	}
4851
4852	if (!cur->spilled()) {
4853	TRACE(
4854	"Pointer in register for range %d:%d (start at %d) "
4855	"at safe point %d\n",
4856	range->vreg(), cur->relative_id(), cur->Start().value(),
4857	safe_point);
4858	InstructionOperand operand = cur->GetAssignedOperand();
4859	DCHECK(!operand.IsStackSlot())((void) 0);
4860	DCHECK(CanBeTaggedOrCompressedPointer(((void) 0)
4861	AllocatedOperand::cast(operand).representation()))((void) 0);
4862	map->RecordReference(AllocatedOperand::cast(operand));
4863	}
4864	}
4865	}
4866	}
4867
4868	LiveRangeConnector::LiveRangeConnector(TopTierRegisterAllocationData* data)
4869	: data_(data) {}
4870
4871	bool LiveRangeConnector::CanEagerlyResolveControlFlow(
4872	const InstructionBlock* block) const {
4873	if (block->PredecessorCount() != 1) return false;
4874	return block->predecessors()[0].IsNext(block->rpo_number());
4875	}
4876
4877	void LiveRangeConnector::ResolveControlFlow(Zone* local_zone) {
4878	// Lazily linearize live ranges in memory for fast lookup.
4879	LiveRangeFinder finder(data(), local_zone);
4880	ZoneVector<BitVector*>& live_in_sets = data()->live_in_sets();
4881	for (const InstructionBlock* block : code()->instruction_blocks()) {
4882	if (CanEagerlyResolveControlFlow(block)) continue;
4883	BitVector* live = live_in_sets[block->rpo_number().ToInt()];
4884	auto it = live->begin();
4885	auto end = live->end();
4886	while (it != end) {
4887	data()->tick_counter()->TickAndMaybeEnterSafepoint();
4888	int vreg = *it;
4889	LiveRangeBoundArray* array = finder.ArrayFor(vreg);
4890	for (const RpoNumber& pred : block->predecessors()) {
4891	FindResult result;
4892	const InstructionBlock* pred_block = code()->InstructionBlockAt(pred);
4893	if (!array->FindConnectableSubranges(block, pred_block, &result)) {
4894	continue;
4895	}
4896	InstructionOperand pred_op = result.pred_cover_->GetAssignedOperand();
4897	InstructionOperand cur_op = result.cur_cover_->GetAssignedOperand();
4898	if (pred_op.Equals(cur_op)) continue;
4899	if (!pred_op.IsAnyRegister() && cur_op.IsAnyRegister()) {
4900	// We're doing a reload.
4901	// We don't need to, if:
4902	// 1) there's no register use in this block, and
4903	// 2) the range ends before the block does, and
4904	// 3) we don't have a successor, or the successor is spilled.
4905	LifetimePosition block_start =
4906	LifetimePosition::GapFromInstructionIndex(block->code_start());
4907	LifetimePosition block_end =
4908	LifetimePosition::GapFromInstructionIndex(block->code_end());
4909	const LiveRange* current = result.cur_cover_;
4910	// Note that this is not the successor if we have control flow!
4911	// However, in the following condition, we only refer to it if it
4912	// begins in the current block, in which case we can safely declare it
4913	// to be the successor.
4914	const LiveRange* successor = current->next();
4915	if (current->End() < block_end &&
4916	(successor == nullptr \|\| successor->spilled())) {
4917	// verify point 1: no register use. We can go to the end of the
4918	// range, since it's all within the block.
4919
4920	bool uses_reg = false;
4921	for (const UsePosition* use = current->NextUsePosition(block_start);
4922	use != nullptr; use = use->next()) {
4923	if (use->operand()->IsAnyRegister()) {
4924	uses_reg = true;
4925	break;
4926	}
4927	}
4928	if (!uses_reg) continue;
4929	}
4930	if (current->TopLevel()->IsSpilledOnlyInDeferredBlocks(data()) &&
4931	pred_block->IsDeferred()) {
4932	// The spill location should be defined in pred_block, so add
4933	// pred_block to the list of blocks requiring a spill operand.
4934	TRACE("Adding B%d to list of spill blocks for %d\n",
4935	pred_block->rpo_number().ToInt(),
4936	current->TopLevel()->vreg());
4937	current->TopLevel()
4938	->GetListOfBlocksRequiringSpillOperands(data())
4939	->Add(pred_block->rpo_number().ToInt());
4940	}
4941	}
4942	int move_loc = ResolveControlFlow(block, cur_op, pred_block, pred_op);
4943	USE(move_loc)do { ::v8::base::Use unused_tmp_array_for_use_macro[]{move_loc }; (void)unused_tmp_array_for_use_macro; } while (false);
4944	DCHECK_IMPLIES(((void) 0)
4945	result.cur_cover_->TopLevel()->IsSpilledOnlyInDeferredBlocks(((void) 0)
4946	data()) &&((void) 0)
4947	!(pred_op.IsAnyRegister() && cur_op.IsAnyRegister()) &&((void) 0)
4948	move_loc != -1,((void) 0)
4949	code()->GetInstructionBlock(move_loc)->IsDeferred())((void) 0);
4950	}
4951	++it;
4952	}
4953	}
4954
4955	// At this stage, we collected blocks needing a spill operand due to reloads
4956	// from ConnectRanges and from ResolveControlFlow. Time to commit the spills
4957	// for deferred blocks. This is a convenient time to commit spills for general
4958	// spill ranges also, because they need to use the LiveRangeFinder.
4959	const size_t live_ranges_size = data()->live_ranges().size();
4960	SpillPlacer spill_placer(&finder, data(), local_zone);
4961	for (TopLevelLiveRange* top : data()->live_ranges()) {
4962	CHECK_EQ(live_ranges_size,do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false)
4963	data()->live_ranges().size())do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false); // TODO(neis): crbug.com/831822
4964	if (top == nullptr \|\| top->IsEmpty()) continue;
4965	if (top->IsSpilledOnlyInDeferredBlocks(data())) {
4966	CommitSpillsInDeferredBlocks(top, finder.ArrayFor(top->vreg()),
4967	local_zone);
4968	} else if (top->HasGeneralSpillRange()) {
4969	spill_placer.Add(top);
4970	}
4971	}
4972	}
4973
4974	int LiveRangeConnector::ResolveControlFlow(const InstructionBlock* block,
4975	const InstructionOperand& cur_op,
4976	const InstructionBlock* pred,
4977	const InstructionOperand& pred_op) {
4978	DCHECK(!pred_op.Equals(cur_op))((void) 0);
4979	int gap_index;
4980	Instruction::GapPosition position;
4981	if (block->PredecessorCount() == 1) {
4982	gap_index = block->first_instruction_index();
4983	position = Instruction::START;
4984	} else {
4985	Instruction* last = code()->InstructionAt(pred->last_instruction_index());
4986	// The connecting move might invalidate uses of the destination operand in
4987	// the deoptimization call. See crbug.com/v8/12218. Omitting the move is
4988	// safe since the deopt call exits the current code.
4989	if (last->IsDeoptimizeCall()) {
4990	return -1;
4991	}
4992	// In every other case the last instruction should not participate in
4993	// register allocation, or it could interfere with the connecting move.
4994	for (size_t i = 0; i < last->InputCount(); ++i) {
4995	DCHECK(last->InputAt(i)->IsImmediate())((void) 0);
4996	}
4997	DCHECK_EQ(1, pred->SuccessorCount())((void) 0);
4998	DCHECK(!code()((void) 0)
4999	->InstructionAt(pred->last_instruction_index())((void) 0)
5000	->HasReferenceMap())((void) 0);
5001	gap_index = pred->last_instruction_index();
5002	position = Instruction::END;
5003	}
5004	data()->AddGapMove(gap_index, position, pred_op, cur_op);
5005	return gap_index;
5006	}
5007
5008	void LiveRangeConnector::ConnectRanges(Zone* local_zone) {
5009	DelayedInsertionMap delayed_insertion_map(local_zone);
5010	const size_t live_ranges_size = data()->live_ranges().size();
5011	for (TopLevelLiveRange* top_range : data()->live_ranges()) {
5012	CHECK_EQ(live_ranges_size,do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false)
5013	data()->live_ranges().size())do { bool _cmp = ::v8::base::CmpEQImpl< typename ::v8::base ::pass_value_or_ref<decltype(live_ranges_size)>::type, typename ::v8::base::pass_value_or_ref<decltype(data()->live_ranges ().size())>::type>((live_ranges_size), (data()->live_ranges ().size())); do { if ((__builtin_expect(!!(!(_cmp)), 0))) { V8_Fatal ("Check failed: %s.", "live_ranges_size" " " "==" " " "data()->live_ranges().size()" ); } } while (false); } while (false); // TODO(neis): crbug.com/831822
5014	if (top_range == nullptr) continue;
5015	bool connect_spilled = top_range->IsSpilledOnlyInDeferredBlocks(data());
5016	LiveRange* first_range = top_range;
5017	for (LiveRange *second_range = first_range->next(); second_range != nullptr;
5018	first_range = second_range, second_range = second_range->next()) {
5019	LifetimePosition pos = second_range->Start();
5020	// Add gap move if the two live ranges touch and there is no block
5021	// boundary.
5022	if (second_range->spilled()) continue;
5023	if (first_range->End() != pos) continue;
5024	if (data()->IsBlockBoundary(pos) &&
5025	!CanEagerlyResolveControlFlow(GetInstructionBlock(code(), pos))) {
5026	continue;
5027	}
5028	InstructionOperand prev_operand = first_range->GetAssignedOperand();
5029	InstructionOperand cur_operand = second_range->GetAssignedOperand();
5030	if (prev_operand.Equals(cur_operand)) continue;
5031	bool delay_insertion = false;
5032	Instruction::GapPosition gap_pos;
5033	int gap_index = pos.ToInstructionIndex();
5034	if (connect_spilled && !prev_operand.IsAnyRegister() &&
5035	cur_operand.IsAnyRegister()) {
5036	const InstructionBlock* block = code()->GetInstructionBlock(gap_index);
5037	DCHECK(block->IsDeferred())((void) 0);
5038	// Performing a reload in this block, meaning the spill operand must
5039	// be defined here.
5040	top_range->GetListOfBlocksRequiringSpillOperands(data())->Add(
5041	block->rpo_number().ToInt());
5042	}
5043
5044	if (pos.IsGapPosition()) {
5045	gap_pos = pos.IsStart() ? Instruction::START : Instruction::END;
5046	} else {
5047	if (pos.IsStart()) {
5048	delay_insertion = true;
5049	} else {
5050	gap_index++;
5051	}
5052	gap_pos = delay_insertion ? Instruction::END : Instruction::START;
5053	}
5054	// Reloads or spills for spilled in deferred blocks ranges must happen
5055	// only in deferred blocks.
5056	DCHECK_IMPLIES(connect_spilled && !(prev_operand.IsAnyRegister() &&((void) 0)
5057	cur_operand.IsAnyRegister()),((void) 0)
5058	code()->GetInstructionBlock(gap_index)->IsDeferred())((void) 0);
5059
5060	ParallelMove* move =
5061	code()->InstructionAt(gap_index)->GetOrCreateParallelMove(
5062	gap_pos, code_zone());
5063	if (!delay_insertion) {
5064	move->AddMove(prev_operand, cur_operand);
5065	} else {
5066	delayed_insertion_map.insert(
5067	std::make_pair(std::make_pair(move, prev_operand), cur_operand));
5068	}
5069	}
5070	}
5071	if (delayed_insertion_map.empty()) return;
5072	// Insert all the moves which should occur after the stored move.
5073	ZoneVector<MoveOperands*> to_insert(local_zone);
5074	ZoneVector<MoveOperands*> to_eliminate(local_zone);
5075	to_insert.reserve(4);
5076	to_eliminate.reserve(4);
5077	ParallelMove* moves = delayed_insertion_map.begin()->first.first;
5078	for (auto it = delayed_insertion_map.begin();; ++it) {
5079	bool done = it == delayed_insertion_map.end();
5080	if (done \|\| it->first.first != moves) {
5081	// Commit the MoveOperands for current ParallelMove.
5082	for (MoveOperands* move : to_eliminate) {
5083	move->Eliminate();
5084	}
5085	for (MoveOperands* move : to_insert) {
5086	moves->push_back(move);
5087	}
5088	if (done) break;
5089	// Reset state.
5090	to_eliminate.clear();
5091	to_insert.clear();
5092	moves = it->first.first;
5093	}
5094	// Gather all MoveOperands for a single ParallelMove.
5095	MoveOperands* move =
5096	code_zone()->New<MoveOperands>(it->first.second, it->second);
5097	moves->PrepareInsertAfter(move, &to_eliminate);
5098	to_insert.push_back(move);
5099	}
5100	}
5101
5102	void LiveRangeConnector::CommitSpillsInDeferredBlocks(
5103	TopLevelLiveRange* range, LiveRangeBoundArray* array, Zone* temp_zone) {
5104	DCHECK(range->IsSpilledOnlyInDeferredBlocks(data()))((void) 0);
5105	DCHECK(!range->spilled())((void) 0);
5106
5107	InstructionSequence* code = data()->code();
5108	InstructionOperand spill_operand = range->GetSpillRangeOperand();
5109
5110	TRACE("Live Range %d will be spilled only in deferred blocks.\n",
5111	range->vreg());
5112	// If we have ranges that aren't spilled but require the operand on the stack,
5113	// make sure we insert the spill.
5114	for (const LiveRange* child = range; child != nullptr;
5115	child = child->next()) {
5116	for (const UsePosition* pos = child->first_pos(); pos != nullptr;
5117	pos = pos->next()) {
5118	if (pos->type() != UsePositionType::kRequiresSlot && !child->spilled())
5119	continue;
5120	range->AddBlockRequiringSpillOperand(
5121	code->GetInstructionBlock(pos->pos().ToInstructionIndex())
5122	->rpo_number(),
5123	data());
5124	}
5125	}
5126
5127	ZoneQueue<int> worklist(temp_zone);
5128
5129	for (int block_id : *range->GetListOfBlocksRequiringSpillOperands(data())) {
5130	worklist.push(block_id);
5131	}
5132
5133	ZoneSet<std::pair<RpoNumber, int>> done_moves(temp_zone);
5134	// Seek the deferred blocks that dominate locations requiring spill operands,
5135	// and spill there. We only need to spill at the start of such blocks.
5136	BitVector done_blocks(
5137	range->GetListOfBlocksRequiringSpillOperands(data())->length(),
5138	temp_zone);
5139	while (!worklist.empty()) {
5140	int block_id = worklist.front();
5141	worklist.pop();
5142	if (done_blocks.Contains(block_id)) continue;
5143	done_blocks.Add(block_id);
5144	InstructionBlock* spill_block =
5145	code->InstructionBlockAt(RpoNumber::FromInt(block_id));
5146
5147	for (const RpoNumber& pred : spill_block->predecessors()) {
5148	const InstructionBlock* pred_block = code->InstructionBlockAt(pred);
5149
5150	if (pred_block->IsDeferred()) {
5151	worklist.push(pred_block->rpo_number().ToInt());
5152	} else {
5153	LifetimePosition pred_end =
5154	LifetimePosition::InstructionFromInstructionIndex(
5155	pred_block->last_instruction_index());
5156
5157	LiveRangeBound* bound = array->Find(pred_end);
5158
5159	InstructionOperand pred_op = bound->range_->GetAssignedOperand();
5160
5161	RpoNumber spill_block_number = spill_block->rpo_number();
5162	if (done_moves.find(std::make_pair(
5163	spill_block_number, range->vreg())) == done_moves.end()) {
5164	TRACE("Spilling deferred spill for range %d at B%d\n", range->vreg(),
5165	spill_block_number.ToInt());
5166	data()->AddGapMove(spill_block->first_instruction_index(),
5167	Instruction::GapPosition::START, pred_op,
5168	spill_operand);
5169	done_moves.insert(std::make_pair(spill_block_number, range->vreg()));
5170	spill_block->mark_needs_frame();
5171	}
5172	}
5173	}
5174	}
5175	}
5176
5177	#undef TRACE
5178	#undef TRACE_COND
5179
5180	} // namespace compiler
5181	} // namespace internal
5182	} // namespace v8