本文整理汇总了C++中MInstruction::isGuardRangeBailouts方法的典型用法代码示例。如果您正苦于以下问题:C++ MInstruction::isGuardRangeBailouts方法的具体用法?C++ MInstruction::isGuardRangeBailouts怎么用?C++ MInstruction::isGuardRangeBailouts使用的例子?那么, 这里精选的方法代码示例或许可以为您提供帮助。您也可以进一步了解该方法所在类MInstruction的用法示例。
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示例1: operands
bool
Sink(MIRGenerator* mir, MIRGraph& graph)
{
TempAllocator& alloc = graph.alloc();
bool sinkEnabled = mir->optimizationInfo().sinkEnabled();
for (PostorderIterator block = graph.poBegin(); block != graph.poEnd(); block++) {
if (mir->shouldCancel("Sink"))
return false;
for (MInstructionReverseIterator iter = block->rbegin(); iter != block->rend(); ) {
MInstruction* ins = *iter++;
// Only instructions which can be recovered on bailout can be moved
// into the bailout paths.
if (ins->isGuard() || ins->isGuardRangeBailouts() ||
ins->isRecoveredOnBailout() || !ins->canRecoverOnBailout())
{
continue;
}
// Compute a common dominator for all uses of the current
// instruction.
bool hasLiveUses = false;
bool hasUses = false;
MBasicBlock* usesDominator = nullptr;
for (MUseIterator i(ins->usesBegin()), e(ins->usesEnd()); i != e; i++) {
hasUses = true;
MNode* consumerNode = (*i)->consumer();
if (consumerNode->isResumePoint())
continue;
MDefinition* consumer = consumerNode->toDefinition();
if (consumer->isRecoveredOnBailout())
continue;
hasLiveUses = true;
// If the instruction is a Phi, then we should dominate the
// predecessor from which the value is coming from.
MBasicBlock* consumerBlock = consumer->block();
if (consumer->isPhi())
consumerBlock = consumerBlock->getPredecessor(consumer->indexOf(*i));
usesDominator = CommonDominator(usesDominator, consumerBlock);
if (usesDominator == *block)
break;
}
// Leave this instruction for DCE.
if (!hasUses)
continue;
// We have no uses, so sink this instruction in all the bailout
// paths.
if (!hasLiveUses) {
MOZ_ASSERT(!usesDominator);
ins->setRecoveredOnBailout();
JitSpewDef(JitSpew_Sink, " No live uses, recover the instruction on bailout\n", ins);
continue;
}
// This guard is temporarly moved here as the above code deals with
// Dead Code elimination, which got moved into this Sink phase, as
// the Dead Code elimination used to move instructions with no-live
// uses to the bailout path.
if (!sinkEnabled)
continue;
// To move an effectful instruction, we would have to verify that the
// side-effect is not observed. In the mean time, we just inhibit
// this optimization on effectful instructions.
if (ins->isEffectful())
continue;
// If all the uses are under a loop, we might not want to work
// against LICM by moving everything back into the loop, but if the
// loop is it-self inside an if, then we still want to move the
// computation under this if statement.
while (block->loopDepth() < usesDominator->loopDepth()) {
MOZ_ASSERT(usesDominator != usesDominator->immediateDominator());
usesDominator = usesDominator->immediateDominator();
}
// Only move instructions if there is a branch between the dominator
// of the uses and the original instruction. This prevent moving the
// computation of the arguments into an inline function if there is
// no major win.
MBasicBlock* lastJoin = usesDominator;
while (*block != lastJoin && lastJoin->numPredecessors() == 1) {
MOZ_ASSERT(lastJoin != lastJoin->immediateDominator());
MBasicBlock* next = lastJoin->immediateDominator();
if (next->numSuccessors() > 1)
break;
lastJoin = next;
}
if (*block == lastJoin)
continue;
// Skip to the next instruction if we cannot find a common dominator
//.........这里部分代码省略.........