DFGPredictionPropagationPhase.cpp source code [jsc/Source/JavaScriptCore/dfg/DFGPredictionPropagationPhase.cpp]

1	/*
2	* Copyright (C) 2011-2017 Apple Inc. All rights reserved.
3	*
4	* Redistribution and use in source and binary forms, with or without
5	* modification, are permitted provided that the following conditions
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8	* notice, this list of conditions and the following disclaimer.
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12	*
13	* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
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15	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
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19	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
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25
26	#include "config.h"
27	#include "DFGPredictionPropagationPhase.h"
28
29	#if ENABLE(DFG_JIT)
30
31	#include "DFGGraph.h"
32	#include "DFGPhase.h"
33	#include "JSCInlines.h"
34
35	namespace JSC { namespace DFG {
36
37	namespace {
38
39	bool verboseFixPointLoops = false;
40
41	class PredictionPropagationPhase : public Phase {
42	public:
43	PredictionPropagationPhase(Graph& graph)
44	: Phase (graph, "prediction propagation")
45	{
46	}
47
48	bool run()
49	{
50	ASSERT(m_graph.m_form == ThreadedCPS);
51	ASSERT(m_graph.m_unificationState == GloballyUnified);
52
53	m_pass = PrimaryPass;
54
55	propagateThroughArgumentPositions();
56
57	processInvariants();
58
59	propagateToFixpoint();
60
61	m_pass = RareCasePass;
62	propagateToFixpoint();
63
64	m_pass = DoubleVotingPass;
65	unsigned counter = `0`;
66	do {
67	if (verboseFixPointLoops)
68	++counter;
69
70	m_changed = false;
71	doRoundOfDoubleVoting();
72	if (!m_changed)
73	break;
74	m_changed = false;
75	propagateForward();
76	} while (m_changed);
77
78	if (verboseFixPointLoops)
79	dataLog("Iterated ", counter, " times in double voting fixpoint.\n");
80
81	return true;
82	}
83
84	private:
85	void propagateToFixpoint()
86	{
87	unsigned counter = `0`;
88	do {
89	if (verboseFixPointLoops)
90	++counter;
91
92	m_changed = false;
93
94	// Forward propagation is near-optimal for both topologically-sorted and
95	// DFS-sorted code.
96	propagateForward();
97	if (!m_changed)
98	break;
99
100	// Backward propagation reduces the likelihood that pathological code will
101	// cause slowness. Loops (especially nested ones) resemble backward flow.
102	// This pass captures two cases: (1) it detects if the forward fixpoint
103	// found a sound solution and (2) short-circuits backward flow.
104	m_changed = false;
105	propagateBackward();
106	} while (m_changed);
107
108	if (verboseFixPointLoops)
109	dataLog("Iterated ", counter, " times in propagateToFixpoint.\n");
110	}
111
112	bool setPrediction(SpeculatedType prediction)
113	{
114	ASSERT(m_currentNode->hasResult());
115
116	// setPrediction() is used when we know that there is no way that we can change
117	// our minds about what the prediction is going to be. There is no semantic
118	// difference between setPrediction() and mergeSpeculation() other than the
119	// increased checking to validate this property.
120	ASSERT(m_currentNode->prediction() == SpecNone \|\| m_currentNode->prediction() == prediction);
121
122	return m_currentNode->predict(prediction);
123	}
124
125	bool mergePrediction(SpeculatedType prediction)
126	{
127	ASSERT(m_currentNode->hasResult());
128
129	return m_currentNode->predict(prediction);
130	}
131
132	SpeculatedType speculatedDoubleTypeForPrediction(SpeculatedType value)
133	{
134	SpeculatedType result = SpecDoubleReal;
135	if (value & SpecDoubleImpureNaN)
136	result \|= SpecDoubleImpureNaN;
137	if (value & SpecDoublePureNaN)
138	result \|= SpecDoublePureNaN;
139	if (!isFullNumberOrBooleanSpeculation(value))
140	result \|= SpecDoublePureNaN;
141	return result;
142	}
143
144	SpeculatedType speculatedDoubleTypeForPredictions(SpeculatedType left, SpeculatedType right)
145	{
146	return speculatedDoubleTypeForPrediction(mergeSpeculations(left, right));
147	}
148
149	void propagate(Node* node)
150	{
151	NodeType op = node->op();
152
153	bool changed = false;
154
155	switch (op) {
156	case GetLocal: {
157	VariableAccessData* variable = node->variableAccessData();
158	SpeculatedType prediction = variable->prediction();
159	if (!variable->couldRepresentInt52() && (prediction & SpecNonInt32AsInt52))
160	prediction = (prediction \| SpecAnyIntAsDouble) & ~SpecNonInt32AsInt52;
161	if (prediction)
162	changed \|= mergePrediction(prediction);
163	break;
164	}
165
166	case SetLocal: {
167	VariableAccessData* variableAccessData = node->variableAccessData();
168	changed \|= variableAccessData->predict(node->child1()->prediction());
169	break;
170	}
171
172	case UInt32ToNumber: {
173	if (node->canSpeculateInt32(m_pass))
174	changed \|= mergePrediction(SpecInt32Only);
175	else if (enableInt52())
176	changed \|= mergePrediction(SpecInt52Any);
177	else
178	changed \|= mergePrediction(SpecBytecodeNumber);
179	break;
180	}
181
182	case ValueAdd: {
183	SpeculatedType left = node->child1()->prediction();
184	SpeculatedType right = node->child2()->prediction();
185
186	if (left && right) {
187	if (isFullNumberOrBooleanSpeculationExpectingDefined(left)
188	&& isFullNumberOrBooleanSpeculationExpectingDefined(right)) {
189	if (m_graph.addSpeculationMode(node, m_pass) != DontSpeculateInt32)
190	changed \|= mergePrediction(SpecInt32Only);
191	else if (m_graph.addShouldSpeculateInt52(node))
192	changed \|= mergePrediction(SpecInt52Any);
193	else
194	changed \|= mergePrediction(speculatedDoubleTypeForPredictions(left, right));
195	} else if (isStringOrStringObjectSpeculation(left) \|\| isStringOrStringObjectSpeculation(right)) {
196	// left or right is definitely something other than a number.
197	changed \|= mergePrediction(SpecString);
198	} else if (isBigIntSpeculation(left) && isBigIntSpeculation(right))
199	changed \|= mergePrediction(SpecBigInt);
200	else {
201	changed \|= mergePrediction(SpecInt32Only);
202	if (node->mayHaveDoubleResult())
203	changed \|= mergePrediction(SpecBytecodeDouble);
204	if (node->mayHaveBigIntResult())
205	changed \|= mergePrediction(SpecBigInt);
206	if (node->mayHaveNonNumericResult())
207	changed \|= mergePrediction(SpecString);
208	}
209	}
210	break;
211	}
212
213	case ArithAdd: {
214	SpeculatedType left = node->child1()->prediction();
215	SpeculatedType right = node->child2()->prediction();
216
217	if (left && right) {
218	if (m_graph.addSpeculationMode(node, m_pass) != DontSpeculateInt32)
219	changed \|= mergePrediction(SpecInt32Only);
220	else if (m_graph.addShouldSpeculateInt52(node))
221	changed \|= mergePrediction(SpecInt52Any);
222	else if (isFullNumberOrBooleanSpeculation(left) && isFullNumberOrBooleanSpeculation(right))
223	changed \|= mergePrediction(speculatedDoubleTypeForPredictions(left, right));
224	else if (node->mayHaveNonIntResult() \|\| (left & SpecBytecodeDouble) \|\| (right & SpecBytecodeDouble))
225	changed \|= mergePrediction(SpecInt32Only \| SpecBytecodeDouble);
226	else
227	changed \|= mergePrediction(SpecInt32Only);
228	}
229	break;
230	}
231
232	case ArithSub: {
233	SpeculatedType left = node->child1()->prediction();
234	SpeculatedType right = node->child2()->prediction();
235
236	if (left && right) {
237	if (isFullNumberOrBooleanSpeculationExpectingDefined(left)
238	&& isFullNumberOrBooleanSpeculationExpectingDefined(right)) {
239	if (m_graph.addSpeculationMode(node, m_pass) != DontSpeculateInt32)
240	changed \|= mergePrediction(SpecInt32Only);
241	else if (m_graph.addShouldSpeculateInt52(node))
242	changed \|= mergePrediction(SpecInt52Any);
243	else
244	changed \|= mergePrediction(speculatedDoubleTypeForPredictions(left, right));
245	} else if (node->mayHaveNonIntResult() \|\| (left & SpecBytecodeDouble) \|\| (right & SpecBytecodeDouble))
246	changed \|= mergePrediction(SpecInt32Only \| SpecBytecodeDouble);
247	else
248	changed \|= mergePrediction(SpecInt32Only);
249	}
250	break;
251	}
252
253	case ValueSub: {
254	SpeculatedType left = node->child1()->prediction();
255	SpeculatedType right = node->child2()->prediction();
256
257	if (left && right) {
258	if (isFullNumberOrBooleanSpeculationExpectingDefined(left)
259	&& isFullNumberOrBooleanSpeculationExpectingDefined(right)) {
260	if (m_graph.addSpeculationMode(node, m_pass) != DontSpeculateInt32)
261	changed \|= mergePrediction(SpecInt32Only);
262	else if (m_graph.addShouldSpeculateInt52(node))
263	changed \|= mergePrediction(SpecInt52Any);
264	else
265	changed \|= mergePrediction(speculatedDoubleTypeForPredictions(left, right));
266	} else if (isBigIntSpeculation(left) && isBigIntSpeculation(right))
267	changed \|= mergePrediction(SpecBigInt);
268	else {
269	changed \|= mergePrediction(SpecInt32Only);
270	if (node->mayHaveDoubleResult())
271	changed \|= mergePrediction(SpecBytecodeDouble);
272	if (node->mayHaveBigIntResult())
273	changed \|= mergePrediction(SpecBigInt);
274	}
275	}
276
277	break;
278	}
279
280	case ValuePow: {
281	SpeculatedType left = node->child1()->prediction();
282	SpeculatedType right = node->child2()->prediction();
283
284	if (left && right) {
285	if (node->child1()->shouldSpeculateBigInt() && node->child2()->shouldSpeculateBigInt())
286	changed \|= mergePrediction(SpecBigInt);
287	else if (isFullNumberOrBooleanSpeculationExpectingDefined(left)
288	&& isFullNumberOrBooleanSpeculationExpectingDefined(right))
289	changed \|= mergePrediction(SpecBytecodeDouble);
290	else
291	changed \|= mergePrediction(SpecBytecodeDouble \| SpecBigInt);
292	}
293	break;
294	}
295
296	case ValueNegate:
297	case ArithNegate: {
298	SpeculatedType prediction = node->child1()->prediction();
299	if (prediction) {
300	if (isInt32OrBooleanSpeculation(prediction) && node->canSpeculateInt32(m_pass))
301	changed \|= mergePrediction(SpecInt32Only);
302	else if (m_graph.unaryArithShouldSpeculateInt52(node, m_pass))
303	changed \|= mergePrediction(SpecInt52Any);
304	else if (isBytecodeNumberSpeculation(prediction))
305	changed \|= mergePrediction(speculatedDoubleTypeForPrediction(node->child1()->prediction()));
306	else {
307	changed \|= mergePrediction(SpecInt32Only);
308	if (node->op() == ValueNegate && node->mayHaveBigIntResult())
309	changed \|= mergePrediction(SpecBigInt);
310	if (node->mayHaveDoubleResult())
311	changed \|= mergePrediction(SpecBytecodeDouble);
312	}
313	}
314	break;
315	}
316	case ArithMin:
317	case ArithMax: {
318	SpeculatedType left = node->child1()->prediction();
319	SpeculatedType right = node->child2()->prediction();
320
321	if (left && right) {
322	if (Node::shouldSpeculateInt32OrBooleanForArithmetic(node->child1().node(), node->child2().node())
323	&& node->canSpeculateInt32(m_pass))
324	changed \|= mergePrediction(SpecInt32Only);
325	else
326	changed \|= mergePrediction(speculatedDoubleTypeForPredictions(left, right));
327	}
328	break;
329	}
330
331	case ValueMul:
332	case ArithMul: {
333	SpeculatedType left = node->child1()->prediction();
334	SpeculatedType right = node->child2()->prediction();
335
336	if (left && right) {
337	// FIXME: We're currently relying on prediction propagation and backwards propagation
338	// whenever we can, and only falling back on result flags if that fails. And the result
339	// flags logic doesn't know how to use backwards propagation. We should get rid of the
340	// prediction propagation logic and rely solely on the result type.
341	if (isFullNumberOrBooleanSpeculationExpectingDefined(left)
342	&& isFullNumberOrBooleanSpeculationExpectingDefined(right)) {
343	if (m_graph.binaryArithShouldSpeculateInt32(node, m_pass))
344	changed \|= mergePrediction(SpecInt32Only);
345	else if (m_graph.binaryArithShouldSpeculateInt52(node, m_pass))
346	changed \|= mergePrediction(SpecInt52Any);
347	else
348	changed \|= mergePrediction(speculatedDoubleTypeForPredictions(left, right));
349	} else if (op == ValueMul && isBigIntSpeculation(left) && isBigIntSpeculation(right))
350	changed \|= mergePrediction(SpecBigInt);
351	else {
352	changed \|= mergePrediction(SpecInt32Only);
353	if (node->mayHaveDoubleResult()
354	\|\| (left & SpecBytecodeDouble)
355	\|\| (right & SpecBytecodeDouble))
356	changed \|= mergePrediction(SpecBytecodeDouble);
357	if ((op == ValueMul && node->mayHaveBigIntResult())
358	\|\| (left & SpecBigInt)
359	\|\| (right & SpecBigInt))
360	changed \|= mergePrediction(SpecBigInt);
361	}
362	}
363	break;
364	}
365
366	case ValueDiv:
367	case ValueMod:
368	case ArithDiv:
369	case ArithMod: {
370	SpeculatedType left = node->child1()->prediction();
371	SpeculatedType right = node->child2()->prediction();
372
373	if (left && right) {
374	if (isFullNumberOrBooleanSpeculationExpectingDefined(left)
375	&& isFullNumberOrBooleanSpeculationExpectingDefined(right)) {
376	if (m_graph.binaryArithShouldSpeculateInt32(node, m_pass))
377	changed \|= mergePrediction(SpecInt32Only);
378	else
379	changed \|= mergePrediction(SpecBytecodeDouble);
380	} else if ((op == ValueDiv \|\| op == ValueMod) && isBigIntSpeculation(left) && isBigIntSpeculation(right))
381	changed \|= mergePrediction(SpecBigInt);
382	else {
383	changed \|= mergePrediction(SpecInt32Only \| SpecBytecodeDouble);
384	if ((op == ValueDiv \|\| op == ValueMod) && (node->mayHaveBigIntResult()
385	\|\| (left & SpecBigInt)
386	\|\| (right & SpecBigInt)))
387	changed \|= mergePrediction(SpecBigInt);
388	}
389	}
390	break;
391	}
392
393	case ArithAbs: {
394	SpeculatedType childPrediction = node->child1()->prediction();
395	if (isInt32OrBooleanSpeculation(childPrediction)
396	&& node->canSpeculateInt32(m_pass))
397	changed \|= mergePrediction(SpecInt32Only);
398	else
399	changed \|= mergePrediction(SpecBytecodeDouble);
400	break;
401	}
402
403	case GetByVal:
404	case AtomicsAdd:
405	case AtomicsAnd:
406	case AtomicsCompareExchange:
407	case AtomicsExchange:
408	case AtomicsLoad:
409	case AtomicsOr:
410	case AtomicsStore:
411	case AtomicsSub:
412	case AtomicsXor: {
413	Edge child1 = m_graph.child(node, `0`);
414	if (!child1 ->prediction())
415	break;
416
417	Edge child2 = m_graph.child(node, `1`);
418	ArrayMode arrayMode = node->arrayMode().refine(
419	m_graph, node,
420	child1 ->prediction(),
421	child2 ->prediction(),
422	SpecNone);
423
424	switch (arrayMode.type()) {
425	case Array::Int32:
426	if (arrayMode.isOutOfBounds())
427	changed \|= mergePrediction(node->getHeapPrediction() \| SpecInt32Only);
428	else
429	changed \|= mergePrediction(SpecInt32Only);
430	break;
431	case Array::Double:
432	if (arrayMode.isOutOfBounds())
433	changed \|= mergePrediction(node->getHeapPrediction() \| SpecDoubleReal);
434	else if (node->getHeapPrediction() & SpecNonIntAsDouble)
435	changed \|= mergePrediction(SpecDoubleReal);
436	else
437	changed \|= mergePrediction(SpecAnyIntAsDouble);
438	break;
439	case Array::Float32Array:
440	case Array::Float64Array:
441	changed \|= mergePrediction(SpecFullDouble);
442	break;
443	case Array::Uint32Array:
444	if (isInt32SpeculationForArithmetic(node->getHeapPrediction()) && node->op() == GetByVal)
445	changed \|= mergePrediction(SpecInt32Only);
446	else if (enableInt52())
447	changed \|= mergePrediction(SpecInt52Any);
448	else
449	changed \|= mergePrediction(SpecInt32Only \| SpecAnyIntAsDouble);
450	break;
451	case Array::Int8Array:
452	case Array::Uint8Array:
453	case Array::Int16Array:
454	case Array::Uint16Array:
455	case Array::Int32Array:
456	changed \|= mergePrediction(SpecInt32Only);
457	break;
458	default:
459	changed \|= mergePrediction(node->getHeapPrediction());
460	break;
461	}
462	break;
463	}
464
465	case ToThis: {
466	// ToThis in methods for primitive types should speculate primitive types in strict mode.
467	bool isStrictMode = m_graph.isStrictModeFor(node->origin.semantic);
468	if (isStrictMode) {
469	if (node->child1()->shouldSpeculateBoolean()) {
470	changed \|= mergePrediction(SpecBoolean);
471	break;
472	}
473
474	if (node->child1()->shouldSpeculateInt32()) {
475	changed \|= mergePrediction(SpecInt32Only);
476	break;
477	}
478
479	if (node->child1()->shouldSpeculateInt52()) {
480	changed \|= mergePrediction(SpecInt52Any);
481	break;
482	}
483
484	if (node->child1()->shouldSpeculateNumber()) {
485	changed \|= mergePrediction(SpecBytecodeNumber);
486	break;
487	}
488
489	if (node->child1()->shouldSpeculateSymbol()) {
490	changed \|= mergePrediction(SpecSymbol);
491	break;
492	}
493
494	if (node->child1()->shouldSpeculateBigInt()) {
495	changed \|= mergePrediction(SpecBigInt);
496	break;
497	}
498
499	if (node->child1()->shouldSpeculateStringIdent()) {
500	changed \|= mergePrediction(SpecStringIdent);
501	break;
502	}
503
504	if (node->child1()->shouldSpeculateString()) {
505	changed \|= mergePrediction(SpecString);
506	break;
507	}
508	} else {
509	if (node->child1()->shouldSpeculateString()) {
510	changed \|= mergePrediction(SpecStringObject);
511	break;
512	}
513	}
514
515	SpeculatedType prediction = node->child1()->prediction();
516	if (isStrictMode)
517	changed \|= mergePrediction(node->getHeapPrediction());
518	else if (prediction) {
519	if (prediction & ~SpecObject) {
520	// Wrapper objects are created only in sloppy mode.
521	prediction &= SpecObject;
522	prediction = mergeSpeculations(prediction, SpecObjectOther);
523	}
524	changed \|= mergePrediction(prediction);
525	}
526	break;
527	}
528
529	case ToPrimitive: {
530	SpeculatedType child = node->child1()->prediction();
531	if (child)
532	changed \|= mergePrediction(resultOfToPrimitive(child));
533	break;
534	}
535
536	case NormalizeMapKey: {
537	SpeculatedType prediction = node->child1()->prediction();
538	if (prediction)
539	changed \|= mergePrediction(prediction);
540	break;
541	}
542
543	default:
544	break;
545	}
546
547	m_changed \|= changed;
548	}
549
550	void propagateForward()
551	{
552	for (Node* node : m_dependentNodes) {
553	m_currentNode = node;
554	propagate(m_currentNode);
555	}
556	}
557
558	void propagateBackward()
559	{
560	for (unsigned i = m_dependentNodes.size(); i--;) {
561	m_currentNode = m_dependentNodes [i];
562	propagate(m_currentNode);
563	}
564	}
565
566	void doDoubleVoting(Node* node, float weight)
567	{
568	// Loop pre-headers created by OSR entrypoint creation may have NaN weight to indicate
569	// that we actually don't know they weight. Assume that they execute once. This turns
570	// out to be an OK assumption since the pre-header doesn't have any meaningful code.
571	if (weight != weight)
572	weight = `1`;
573
574	switch (node->op()) {
575	case ValueAdd:
576	case ValueSub:
577	case ArithAdd:
578	case ArithSub: {
579	SpeculatedType left = node->child1()->prediction();
580	SpeculatedType right = node->child2()->prediction();
581
582	DoubleBallot ballot;
583
584	if (isFullNumberSpeculation(left)
585	&& isFullNumberSpeculation(right)
586	&& !m_graph.addShouldSpeculateInt32(node, m_pass)
587	&& !m_graph.addShouldSpeculateInt52(node))
588	ballot = VoteDouble;
589	else
590	ballot = VoteValue;
591
592	m_graph.voteNode(node->child1(), ballot, weight);
593	m_graph.voteNode(node->child2(), ballot, weight);
594	break;
595	}
596
597	case ValueMul:
598	case ArithMul: {
599	SpeculatedType left = node->child1()->prediction();
600	SpeculatedType right = node->child2()->prediction();
601
602	DoubleBallot ballot;
603
604	if (isFullNumberSpeculation(left)
605	&& isFullNumberSpeculation(right)
606	&& !m_graph.binaryArithShouldSpeculateInt32(node, m_pass)
607	&& !m_graph.binaryArithShouldSpeculateInt52(node, m_pass))
608	ballot = VoteDouble;
609	else
610	ballot = VoteValue;
611
612	m_graph.voteNode(node->child1(), ballot, weight);
613	m_graph.voteNode(node->child2(), ballot, weight);
614	break;
615	}
616
617	case ArithMin:
618	case ArithMax:
619	case ArithMod:
620	case ValueDiv:
621	case ValueMod:
622	case ArithDiv: {
623	SpeculatedType left = node->child1()->prediction();
624	SpeculatedType right = node->child2()->prediction();
625
626	DoubleBallot ballot;
627
628	if (isFullNumberSpeculation(left)
629	&& isFullNumberSpeculation(right)
630	&& !m_graph.binaryArithShouldSpeculateInt32(node, m_pass))
631	ballot = VoteDouble;
632	else
633	ballot = VoteValue;
634
635	m_graph.voteNode(node->child1(), ballot, weight);
636	m_graph.voteNode(node->child2(), ballot, weight);
637	break;
638	}
639
640	case ArithAbs:
641	DoubleBallot ballot;
642	if (node->child1()->shouldSpeculateNumber()
643	&& !m_graph.unaryArithShouldSpeculateInt32(node, m_pass))
644	ballot = VoteDouble;
645	else
646	ballot = VoteValue;
647
648	m_graph.voteNode(node->child1(), ballot, weight);
649	break;
650
651	case ArithSqrt:
652	case ArithUnary:
653	if (node->child1()->shouldSpeculateNumber())
654	m_graph.voteNode(node->child1(), VoteDouble, weight);
655	else
656	m_graph.voteNode(node->child1(), VoteValue, weight);
657	break;
658
659	case SetLocal: {
660	SpeculatedType prediction = node->child1()->prediction();
661	if (isDoubleSpeculation(prediction))
662	node->variableAccessData()->vote(VoteDouble, weight);
663	else if (!isFullNumberSpeculation(prediction) \|\| isInt32OrInt52Speculation(prediction))
664	node->variableAccessData()->vote(VoteValue, weight);
665	break;
666	}
667
668	case PutByValDirect:
669	case PutByVal:
670	case PutByValAlias: {
671	Edge child1 = m_graph.varArgChild(node, `0`);
672	Edge child2 = m_graph.varArgChild(node, `1`);
673	Edge child3 = m_graph.varArgChild(node, `2`);
674	m_graph.voteNode(child1, VoteValue, weight);
675	m_graph.voteNode(child2, VoteValue, weight);
676	switch (node->arrayMode().type()) {
677	case Array::Double:
678	m_graph.voteNode(child3, VoteDouble, weight);
679	break;
680	default:
681	m_graph.voteNode(child3, VoteValue, weight);
682	break;
683	}
684	break;
685	}
686
687	case DataViewSet: {
688	DataViewData data = node->dataViewData();
689	if (data.isFloatingPoint)
690	m_graph.voteNode(m_graph.varArgChild(node, `2`), VoteValue, weight);
691	break;
692	}
693
694	case MovHint:
695	// Ignore these since they have no effect on in-DFG execution.
696	break;
697
698	default:
699	m_graph.voteChildren(node, VoteValue, weight);
700	break;
701	}
702	}
703
704	void doRoundOfDoubleVoting()
705	{
706	for (unsigned i = `0`; i < m_graph.m_variableAccessData.size(); ++i)
707	m_graph.m_variableAccessData [i].find()->clearVotes();
708	for (BlockIndex blockIndex = `0`; blockIndex < m_graph.numBlocks(); ++blockIndex) {
709	BasicBlock* block = m_graph.block(blockIndex);
710	if (!block)
711	continue;
712	ASSERT(block->isReachable);
713	for (unsigned i = `0`; i < block->size(); ++i) {
714	m_currentNode = block->at(i);
715	doDoubleVoting(m_currentNode, block->executionCount);
716	}
717	}
718	for (unsigned i = `0`; i < m_graph.m_variableAccessData.size(); ++i) {
719	VariableAccessData* variableAccessData = &m_graph.m_variableAccessData [i];
720	if (!variableAccessData->isRoot())
721	continue;
722	m_changed \|= variableAccessData->tallyVotesForShouldUseDoubleFormat();
723	}
724	propagateThroughArgumentPositions();
725	for (unsigned i = `0`; i < m_graph.m_variableAccessData.size(); ++i) {
726	VariableAccessData* variableAccessData = &m_graph.m_variableAccessData [i];
727	if (!variableAccessData->isRoot())
728	continue;
729	m_changed \|= variableAccessData->makePredictionForDoubleFormat();
730	}
731	}
732
733	void propagateThroughArgumentPositions()
734	{
735	for (unsigned i = `0`; i < m_graph.m_argumentPositions.size(); ++i)
736	m_changed \|= m_graph.m_argumentPositions [i].mergeArgumentPredictionAwareness();
737	}
738
739	// Sets any predictions that do not depends on other nodes.
740	void processInvariants()
741	{
742	for (BasicBlock* block : m_graph.blocksInNaturalOrder()) {
743	for (Node* node : *block) {
744	m_currentNode = node;
745	processInvariantsForNode();
746	}
747	}
748	}
749
750	void processInvariantsForNode()
751	{
752	switch (m_currentNode->op()) {
753	case JSConstant: {
754	SpeculatedType type = speculationFromValue(m_currentNode->asJSValue());
755	if (type == SpecAnyIntAsDouble && enableInt52())
756	type = int52AwareSpeculationFromValue(m_currentNode->asJSValue());
757	setPrediction(type);
758	break;
759	}
760	case DoubleConstant: {
761	SpeculatedType type = speculationFromValue(m_currentNode->asJSValue());
762	setPrediction(type);
763	break;
764	}
765
766	case ArithBitNot:
767	case ArithBitAnd:
768	case ArithBitOr:
769	case ArithBitXor:
770	case BitRShift:
771	case BitLShift:
772	case BitURShift:
773	case ArithIMul:
774	case ArithClz32: {
775	setPrediction(SpecInt32Only);
776	break;
777	}
778
779	case ArrayPop:
780	case ArrayPush:
781	case RegExpExec:
782	case RegExpExecNonGlobalOrSticky:
783	case RegExpTest:
784	case RegExpMatchFast:
785	case RegExpMatchFastGlobal:
786	case StringReplace:
787	case StringReplaceRegExp:
788	case GetById:
789	case GetByIdFlush:
790	case GetByIdWithThis:
791	case GetByIdDirect:
792	case GetByIdDirectFlush:
793	case TryGetById:
794	case GetByValWithThis:
795	case GetByOffset:
796	case MultiGetByOffset:
797	case GetDirectPname:
798	case Call:
799	case DirectCall:
800	case TailCallInlinedCaller:
801	case DirectTailCallInlinedCaller:
802	case Construct:
803	case DirectConstruct:
804	case CallVarargs:
805	case CallEval:
806	case TailCallVarargsInlinedCaller:
807	case ConstructVarargs:
808	case CallForwardVarargs:
809	case ConstructForwardVarargs:
810	case TailCallForwardVarargsInlinedCaller:
811	case GetGlobalVar:
812	case GetGlobalLexicalVariable:
813	case GetClosureVar:
814	case GetFromArguments:
815	case LoadKeyFromMapBucket:
816	case LoadValueFromMapBucket:
817	case ToNumber:
818	case ToObject:
819	case ValueBitAnd:
820	case ValueBitXor:
821	case ValueBitOr:
822	case ValueBitNot:
823	case CallObjectConstructor:
824	case GetArgument:
825	case CallDOMGetter:
826	case GetDynamicVar:
827	case GetPrototypeOf:
828	case ExtractValueFromWeakMapGet:
829	case DataViewGetInt:
830	case DataViewGetFloat: {
831	setPrediction(m_currentNode->getHeapPrediction());
832	break;
833	}
834
835	case WeakMapGet:
836	case ResolveScopeForHoistingFuncDeclInEval: {
837	setPrediction(SpecBytecodeTop);
838	break;
839	}
840
841	case GetGetterSetterByOffset:
842	case GetExecutable: {
843	setPrediction(SpecCellOther);
844	break;
845	}
846
847	case GetGetter:
848	case GetSetter:
849	case GetCallee:
850	case NewFunction:
851	case NewGeneratorFunction:
852	case NewAsyncGeneratorFunction:
853	case NewAsyncFunction: {
854	setPrediction(SpecFunction);
855	break;
856	}
857
858	case GetArgumentCountIncludingThis: {
859	setPrediction(SpecInt32Only);
860	break;
861	}
862
863	case SetCallee:
864	case SetArgumentCountIncludingThis:
865	break;
866
867	case MapHash:
868	setPrediction(SpecInt32Only);
869	break;
870
871	case GetMapBucket:
872	case GetMapBucketHead:
873	case GetMapBucketNext:
874	case SetAdd:
875	case MapSet:
876	setPrediction(SpecCellOther);
877	break;
878
879	case GetRestLength:
880	case ArrayIndexOf: {
881	setPrediction(SpecInt32Only);
882	break;
883	}
884
885	case GetTypedArrayByteOffset:
886	case GetArrayLength:
887	case GetVectorLength: {
888	setPrediction(SpecInt32Only);
889	break;
890	}
891
892	case StringCharCodeAt: {
893	setPrediction(SpecInt32Only);
894	break;
895	}
896
897	case StringValueOf:
898	case StringSlice:
899	case ToLowerCase:
900	setPrediction(SpecString);
901	break;
902
903	case ArithPow:
904	case ArithSqrt:
905	case ArithFRound:
906	case ArithUnary: {
907	setPrediction(SpecBytecodeDouble);
908	break;
909	}
910
911	case ArithRound:
912	case ArithFloor:
913	case ArithCeil:
914	case ArithTrunc: {
915	if (isInt32OrBooleanSpeculation(m_currentNode->getHeapPrediction())
916	&& m_graph.roundShouldSpeculateInt32(m_currentNode, m_pass))
917	setPrediction(SpecInt32Only);
918	else
919	setPrediction(SpecBytecodeDouble);
920	break;
921	}
922
923	case ArithRandom: {
924	setPrediction(SpecDoubleReal);
925	break;
926	}
927	case DeleteByVal:
928	case DeleteById:
929	case LogicalNot:
930	case CompareLess:
931	case CompareLessEq:
932	case CompareGreater:
933	case CompareGreaterEq:
934	case CompareBelow:
935	case CompareBelowEq:
936	case CompareEq:
937	case CompareStrictEq:
938	case CompareEqPtr:
939	case SameValue:
940	case OverridesHasInstance:
941	case InstanceOf:
942	case InstanceOfCustom:
943	case IsEmpty:
944	case IsUndefined:
945	case IsUndefinedOrNull:
946	case IsBoolean:
947	case IsNumber:
948	case NumberIsInteger:
949	case IsObject:
950	case IsObjectOrNull:
951	case IsFunction:
952	case IsCellWithType:
953	case IsTypedArrayView:
954	case MatchStructure: {
955	setPrediction(SpecBoolean);
956	break;
957	}
958
959	case TypeOf: {
960	setPrediction(SpecStringIdent);
961	break;
962	}
963	case GetButterfly:
964	case GetIndexedPropertyStorage:
965	case AllocatePropertyStorage:
966	case ReallocatePropertyStorage: {
967	setPrediction(SpecOther);
968	break;
969	}
970
971	case CheckSubClass:
972	break;
973
974	case SkipScope:
975	case GetGlobalObject: {
976	setPrediction(SpecObjectOther);
977	break;
978	}
979
980	case GetGlobalThis:
981	setPrediction(SpecObject);
982	break;
983
984	case ResolveScope: {
985	setPrediction(SpecObjectOther);
986	break;
987	}
988
989	case ObjectCreate:
990	case CreateThis:
991	case NewObject: {
992	setPrediction(SpecFinalObject);
993	break;
994	}
995
996	case ArraySlice:
997	case NewArrayWithSpread:
998	case NewArray:
999	case NewArrayWithSize:
1000	case CreateRest:
1001	case NewArrayBuffer:
1002	case ObjectKeys: {
1003	setPrediction(SpecArray);
1004	break;
1005	}
1006
1007	case Spread:
1008	setPrediction(SpecCellOther);
1009	break;
1010
1011	case NewTypedArray: {
1012	setPrediction(speculationFromTypedArrayType(m_currentNode->typedArrayType()));
1013	break;
1014	}
1015
1016	case NewRegexp: {
1017	setPrediction(SpecRegExpObject);
1018	break;
1019	}
1020
1021	case PushWithScope:
1022	case CreateActivation: {
1023	setPrediction(SpecObjectOther);
1024	break;
1025	}
1026
1027	case StringFromCharCode: {
1028	setPrediction(SpecString);
1029	m_currentNode->child1()->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsInt);
1030	break;
1031	}
1032	case StringCharAt:
1033	case CallStringConstructor:
1034	case ToString:
1035	case NumberToStringWithRadix:
1036	case NumberToStringWithValidRadixConstant:
1037	case MakeRope:
1038	case StrCat: {
1039	setPrediction(SpecString);
1040	break;
1041	}
1042	case NewStringObject: {
1043	setPrediction(SpecStringObject);
1044	break;
1045	}
1046	case NewSymbol: {
1047	setPrediction(SpecSymbol);
1048	break;
1049	}
1050
1051	case CreateDirectArguments: {
1052	setPrediction(SpecDirectArguments);
1053	break;
1054	}
1055
1056	case CreateScopedArguments: {
1057	setPrediction(SpecScopedArguments);
1058	break;
1059	}
1060
1061	case CreateClonedArguments: {
1062	setPrediction(SpecObjectOther);
1063	break;
1064	}
1065
1066	case FiatInt52: {
1067	RELEASE_ASSERT(enableInt52());
1068	setPrediction(SpecInt52Any);
1069	break;
1070	}
1071
1072	case GetScope:
1073	setPrediction(SpecObjectOther);
1074	break;
1075
1076	case InByVal:
1077	case InById:
1078	setPrediction(SpecBoolean);
1079	break;
1080
1081	case HasOwnProperty:
1082	setPrediction(SpecBoolean);
1083	break;
1084
1085	case GetEnumerableLength: {
1086	setPrediction(SpecInt32Only);
1087	break;
1088	}
1089	case HasGenericProperty:
1090	case HasStructureProperty:
1091	case HasIndexedProperty: {
1092	setPrediction(SpecBoolean);
1093	break;
1094	}
1095	case GetPropertyEnumerator: {
1096	setPrediction(SpecCell);
1097	break;
1098	}
1099	case GetEnumeratorStructurePname: {
1100	setPrediction(SpecCell \| SpecOther);
1101	break;
1102	}
1103	case GetEnumeratorGenericPname: {
1104	setPrediction(SpecCell \| SpecOther);
1105	break;
1106	}
1107	case ToIndexString: {
1108	setPrediction(SpecString);
1109	break;
1110	}
1111	case ParseInt: {
1112	// We expect this node to almost always produce an int32. However,
1113	// it's possible it produces NaN or integers out of int32 range. We
1114	// rely on the heap prediction since the parseInt() call profiled
1115	// its result.
1116	setPrediction(m_currentNode->getHeapPrediction());
1117	break;
1118	}
1119
1120	case IdentityWithProfile: {
1121	setPrediction(m_currentNode->getForcedPrediction());
1122	break;
1123	}
1124
1125	case ExtractCatchLocal: {
1126	setPrediction(m_currentNode->catchLocalPrediction());
1127	break;
1128	}
1129
1130	case GetLocal:
1131	case SetLocal:
1132	case UInt32ToNumber:
1133	case ValueNegate:
1134	case ValueAdd:
1135	case ValueSub:
1136	case ValueMul:
1137	case ValueDiv:
1138	case ValueMod:
1139	case ValuePow:
1140	case ArithAdd:
1141	case ArithSub:
1142	case ArithNegate:
1143	case ArithMin:
1144	case ArithMax:
1145	case ArithMul:
1146	case ArithDiv:
1147	case ArithMod:
1148	case ArithAbs:
1149	case GetByVal:
1150	case ToThis:
1151	case ToPrimitive:
1152	case NormalizeMapKey:
1153	case AtomicsAdd:
1154	case AtomicsAnd:
1155	case AtomicsCompareExchange:
1156	case AtomicsExchange:
1157	case AtomicsLoad:
1158	case AtomicsOr:
1159	case AtomicsStore:
1160	case AtomicsSub:
1161	case AtomicsXor: {
1162	m_dependentNodes.append(m_currentNode);
1163	break;
1164	}
1165
1166	case AtomicsIsLockFree: {
1167	setPrediction(SpecBoolean);
1168	break;
1169	}
1170
1171	case CPUIntrinsic: {
1172	if (m_currentNode->intrinsic() == CPURdtscIntrinsic)
1173	setPrediction(SpecInt32Only);
1174	else
1175	setPrediction(SpecOther);
1176	break;
1177	}
1178
1179	case PutByValAlias:
1180	case DoubleAsInt32:
1181	case CheckArray:
1182	case CheckTypeInfoFlags:
1183	case Arrayify:
1184	case ArrayifyToStructure:
1185	case CheckTierUpInLoop:
1186	case CheckTierUpAtReturn:
1187	case CheckTierUpAndOSREnter:
1188	case CheckInBounds:
1189	case ValueToInt32:
1190	case DoubleRep:
1191	case ValueRep:
1192	case Int52Rep:
1193	case Int52Constant:
1194	case Identity:
1195	case BooleanToNumber:
1196	case PhantomNewObject:
1197	case PhantomNewFunction:
1198	case PhantomNewGeneratorFunction:
1199	case PhantomNewAsyncGeneratorFunction:
1200	case PhantomNewAsyncFunction:
1201	case PhantomCreateActivation:
1202	case PhantomDirectArguments:
1203	case PhantomCreateRest:
1204	case PhantomSpread:
1205	case PhantomNewArrayWithSpread:
1206	case PhantomNewArrayBuffer:
1207	case PhantomClonedArguments:
1208	case PhantomNewRegexp:
1209	case GetMyArgumentByVal:
1210	case GetMyArgumentByValOutOfBounds:
1211	case PutHint:
1212	case CheckStructureImmediate:
1213	case CheckStructureOrEmpty:
1214	case MaterializeNewObject:
1215	case MaterializeCreateActivation:
1216	case PutStack:
1217	case KillStack:
1218	case StoreBarrier:
1219	case FencedStoreBarrier:
1220	case GetStack:
1221	case GetRegExpObjectLastIndex:
1222	case SetRegExpObjectLastIndex:
1223	case RecordRegExpCachedResult:
1224	case LazyJSConstant:
1225	case CallDOM: {
1226	// This node should never be visible at this stage of compilation.
1227	DFG_CRASH(m_graph, m_currentNode, "Unexpected node during prediction propagation");
1228	break;
1229	}
1230
1231	case Phi:
1232	// Phis should not be visible here since we're iterating the all-but-Phi's
1233	// part of basic blocks.
1234	RELEASE_ASSERT_NOT_REACHED();
1235	break;
1236
1237	case EntrySwitch:
1238	case Upsilon:
1239	// These don't get inserted until we go into SSA.
1240	RELEASE_ASSERT_NOT_REACHED();
1241	break;
1242
1243	#ifndef NDEBUG
1244	// These get ignored because they don't return anything.
1245	case PutByValDirect:
1246	case PutByValWithThis:
1247	case PutByIdWithThis:
1248	case PutByVal:
1249	case PutClosureVar:
1250	case PutToArguments:
1251	case Return:
1252	case Throw:
1253	case ThrowStaticError:
1254	case TailCall:
1255	case DirectTailCall:
1256	case TailCallVarargs:
1257	case TailCallForwardVarargs:
1258	case PutById:
1259	case PutByIdFlush:
1260	case PutByIdDirect:
1261	case PutByOffset:
1262	case MultiPutByOffset:
1263	case PutGetterById:
1264	case PutSetterById:
1265	case PutGetterSetterById:
1266	case PutGetterByVal:
1267	case PutSetterByVal:
1268	case DefineDataProperty:
1269	case DefineAccessorProperty:
1270	case DFG::Jump:
1271	case Branch:
1272	case Switch:
1273	case ProfileType:
1274	case ProfileControlFlow:
1275	case ForceOSRExit:
1276	case SetArgumentDefinitely:
1277	case SetArgumentMaybe:
1278	case SetFunctionName:
1279	case CheckStructure:
1280	case CheckCell:
1281	case CheckNotEmpty:
1282	case AssertNotEmpty:
1283	case CheckStringIdent:
1284	case CheckBadCell:
1285	case PutStructure:
1286	case Phantom:
1287	case Check:
1288	case CheckVarargs:
1289	case PutGlobalVariable:
1290	case CheckTraps:
1291	case LogShadowChickenPrologue:
1292	case LogShadowChickenTail:
1293	case Unreachable:
1294	case LoopHint:
1295	case NotifyWrite:
1296	case ConstantStoragePointer:
1297	case MovHint:
1298	case ZombieHint:
1299	case ExitOK:
1300	case LoadVarargs:
1301	case ForwardVarargs:
1302	case PutDynamicVar:
1303	case NukeStructureAndSetButterfly:
1304	case InitializeEntrypointArguments:
1305	case WeakSetAdd:
1306	case WeakMapSet:
1307	case FilterCallLinkStatus:
1308	case FilterGetByIdStatus:
1309	case FilterPutByIdStatus:
1310	case FilterInByIdStatus:
1311	case ClearCatchLocals:
1312	case DataViewSet:
1313	case InvalidationPoint:
1314	break;
1315
1316	// This gets ignored because it only pretends to produce a value.
1317	case BottomValue:
1318	break;
1319
1320	// This gets ignored because it already has a prediction.
1321	case ExtractOSREntryLocal:
1322	break;
1323
1324	// These gets ignored because it doesn't do anything.
1325	case CountExecution:
1326	case SuperSamplerBegin:
1327	case SuperSamplerEnd:
1328	case PhantomLocal:
1329	case Flush:
1330	break;
1331
1332	case LastNodeType:
1333	RELEASE_ASSERT_NOT_REACHED();
1334	break;
1335	#else
1336	default:
1337	break;
1338	#endif
1339	}
1340	}
1341
1342	SpeculatedType resultOfToPrimitive(SpeculatedType type)
1343	{
1344	if (type & SpecObject) {
1345	// We try to be optimistic here about StringObjects since it's unlikely that
1346	// someone overrides the valueOf or toString methods.
1347	if (type & SpecStringObject && m_graph.canOptimizeStringObjectAccess(m_currentNode->origin.semantic))
1348	return mergeSpeculations(type & ~SpecObject, SpecString);
1349
1350	return mergeSpeculations(type & ~SpecObject, SpecPrimitive);
1351	}
1352
1353	return type;
1354	}
1355
1356	Vector<Node*> m_dependentNodes;
1357	Node* m_currentNode;
1358	bool m_changed { false };
1359	PredictionPass m_pass { PrimaryPass }; // We use different logic for considering predictions depending on how far along we are in propagation.
1360	};
1361
1362	} // Anonymous namespace.
1363
1364	bool performPredictionPropagation(Graph& graph)
1365	{
1366	return runPhase<PredictionPropagationPhase>(graph);
1367	}
1368
1369	} } // namespace JSC::DFG
1370
1371	#endif // ENABLE(DFG_JIT)
1372
1373

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