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/*
* Copyright (C) 2014, 2015 Apple Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
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* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
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*/
#include "config.h"
#include "DFGPutStackSinkingPhase.h"
#if ENABLE(DFG_JIT)
#include "DFGBlockMapInlines.h"
#include "DFGGraph.h"
#include "DFGInsertionSet.h"
#include "DFGPhase.h"
#include "DFGPreciseLocalClobberize.h"
#include "DFGSSACalculator.h"
#include "DFGValidate.h"
#include "JSCInlines.h"
#include "OperandsInlines.h"
namespace JSC { namespace DFG {
namespace {
namespace DFGPutStackSinkingPhaseInternal {
static const bool verbose = false;
}
class PutStackSinkingPhase : public Phase {
public:
PutStackSinkingPhase(Graph& graph)
: Phase(graph, "PutStack sinking")
{
}
bool run()
{
// FIXME: One of the problems of this approach is that it will create a duplicate Phi graph
// for sunken PutStacks in the presence of interesting control flow merges, and where the
// value being PutStack'd is also otherwise live in the DFG code. We could work around this
// by doing the sinking over CPS, or maybe just by doing really smart hoisting. It's also
// possible that the duplicate Phi graph can be deduplicated by B3. It would be best if we
// could observe that there is already a Phi graph in place that does what we want. In
// principle if we have a request to place a Phi at a particular place, we could just check
// if there is already a Phi that does what we want. Because PutStackSinkingPhase runs just
// after SSA conversion, we have almost a guarantee that the Phi graph we produce here would
// be trivially redundant to the one we already have.
// FIXME: This phase doesn't adequately use KillStacks. KillStack can be viewed as a def.
// This is mostly inconsequential; it would be a bug to have a local live at a KillStack.
// More important is that KillStack should swallow any deferral. After a KillStack, the
// local should behave like a TOP deferral because it would be invalid for anyone to trust
// the stack. It's not clear to me if this is important or not.
// https://bugs.webkit.org/show_bug.cgi?id=145296
if (DFGPutStackSinkingPhaseInternal::verbose) {
dataLog("Graph before PutStack sinking:\n");
m_graph.dump();
}
m_graph.ensureSSADominators();
SSACalculator ssaCalculator(m_graph);
InsertionSet insertionSet(m_graph);
// First figure out where various locals are live.
BlockMap<Operands<bool>> liveAtHead(m_graph);
BlockMap<Operands<bool>> liveAtTail(m_graph);
for (BasicBlock* block : m_graph.blocksInNaturalOrder()) {
liveAtHead[block] = Operands<bool>(OperandsLike, block->variablesAtHead);
liveAtTail[block] = Operands<bool>(OperandsLike, block->variablesAtHead);
liveAtHead[block].fill(false);
liveAtTail[block].fill(false);
}
bool changed;
do {
changed = false;
for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
BasicBlock* block = m_graph.block(blockIndex);
if (!block)
continue;
Operands<bool> live = liveAtTail[block];
for (unsigned nodeIndex = block->size(); nodeIndex--;) {
Node* node = block->at(nodeIndex);
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog("Live at ", node, ": ", live, "\n");
Vector<VirtualRegister, 4> reads;
Vector<VirtualRegister, 4> writes;
auto escapeHandler = [&] (VirtualRegister operand) {
if (operand.isHeader())
return;
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog(" ", operand, " is live at ", node, "\n");
reads.append(operand);
};
auto writeHandler = [&] (VirtualRegister operand) {
if (operand.isHeader())
return;
RELEASE_ASSERT(node->op() == PutStack || node->op() == LoadVarargs || node->op() == ForwardVarargs);
writes.append(operand);
};
preciseLocalClobberize(
m_graph, node, escapeHandler, writeHandler,
[&] (VirtualRegister, LazyNode) { });
for (VirtualRegister operand : writes)
live.operand(operand) = false;
for (VirtualRegister operand : reads)
live.operand(operand) = true;
}
if (live == liveAtHead[block])
continue;
liveAtHead[block] = live;
changed = true;
for (BasicBlock* predecessor : block->predecessors) {
for (size_t i = live.size(); i--;)
liveAtTail[predecessor][i] |= live[i];
}
}
} while (changed);
// All of the arguments should be live at head of root. Note that we may find that some
// locals are live at head of root. This seems wrong but isn't. This will happen for example
// if the function accesses closure variable #42 for some other function and we either don't
// have variable #42 at all or we haven't set it at root, for whatever reason. Basically this
// arises since our aliasing for closure variables is conservatively based on variable number
// and ignores the owning symbol table. We should probably fix this eventually and make our
// aliasing more precise.
//
// For our purposes here, the imprecision in the aliasing is harmless. It just means that we
// may not do as much Phi pruning as we wanted.
for (size_t i = liveAtHead.atIndex(0).numberOfArguments(); i--;)
DFG_ASSERT(m_graph, nullptr, liveAtHead.atIndex(0).argument(i));
// Next identify where we would want to sink PutStacks to. We say that there is a deferred
// flush if we had a PutStack with a given FlushFormat but it hasn't been materialized yet.
// Deferrals have the following lattice; but it's worth noting that the TOP part of the
// lattice serves an entirely different purpose than the rest of the lattice: it just means
// that we're in a region of code where nobody should have been relying on the value. The
// rest of the lattice means that we either have a PutStack that is deferred (i.e. still
// needs to be executed) or there isn't one (because we've alraedy executed it).
//
// Bottom:
// Represented as DeadFlush.
// Means that all previous PutStacks have been executed so there is nothing deferred.
// During merging this is subordinate to the other kinds of deferrals, because it
// represents the fact that we've already executed all necessary PutStacks. This implies
// that there *had* been some PutStacks that we should have executed.
//
// Top:
// Represented as ConflictingFlush.
// Represents the fact that we know, via forward flow, that there isn't any value in the
// given local that anyone should have been relying on. This comes into play at the
// prologue (because in SSA form at the prologue no local has any value) or when we merge
// deferrals for different formats's. A lexical scope in which a local had some semantic
// meaning will by this point share the same format; if we had stores from different
// lexical scopes that got merged together then we may have a conflicting format. Hence
// a conflicting format proves that we're no longer in an area in which the variable was
// in scope. Note that this is all approximate and only precise enough to later answer
// questions pertinent to sinking. For example, this doesn't always detect when a local
// is no longer semantically relevant - we may well have a deferral from inside some
// inlined call survive outside of that inlined code, and this is generally OK. In the
// worst case it means that we might think that a deferral that is actually dead must
// still be executed. But we usually catch that with liveness. Liveness usually catches
// such cases, but that's not guaranteed since liveness is conservative.
//
// What Top does give us is detects situations where we both don't need to care about a
// deferral and there is no way that we could reason about it anyway. If we merged
// deferrals for different formats then we wouldn't know the format to use. So, we use
// Top in that case because that's also a case where we know that we can ignore the
// deferral.
//
// Deferral with a concrete format:
// Represented by format values other than DeadFlush or ConflictingFlush.
// Represents the fact that the original code would have done a PutStack but we haven't
// identified an operation that would have observed that PutStack.
//
// We need to be precise about liveness in this phase because not doing so
// could cause us to insert a PutStack before a node we thought may escape a
// value that it doesn't really escape. Sinking this PutStack above such a node may
// cause us to insert a GetStack that we forward to the Phi we're feeding into the
// sunken PutStack. Inserting such a GetStack could cause us to load garbage and
// can confuse the AI to claim untrue things (like that the program will exit when
// it really won't).
BlockMap<Operands<FlushFormat>> deferredAtHead(m_graph);
BlockMap<Operands<FlushFormat>> deferredAtTail(m_graph);
for (BasicBlock* block : m_graph.blocksInNaturalOrder()) {
deferredAtHead[block] =
Operands<FlushFormat>(OperandsLike, block->variablesAtHead);
deferredAtTail[block] =
Operands<FlushFormat>(OperandsLike, block->variablesAtHead);
}
for (unsigned local = deferredAtHead.atIndex(0).numberOfLocals(); local--;)
deferredAtHead.atIndex(0).local(local) = ConflictingFlush;
do {
changed = false;
for (BasicBlock* block : m_graph.blocksInNaturalOrder()) {
Operands<FlushFormat> deferred = deferredAtHead[block];
for (Node* node : *block) {
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog("Deferred at ", node, ":", deferred, "\n");
if (node->op() == GetStack) {
// Handle the case that the input doesn't match our requirements. This is
// really a bug, but it's a benign one if we simply don't run this phase.
// It usually arises because of patterns like:
//
// if (thing)
// PutStack()
// ...
// if (thing)
// GetStack()
//
// Or:
//
// if (never happens)
// GetStack()
//
// Because this phase runs early in SSA, it should be sensible to enforce
// that no such code pattern has arisen yet. So, when validation is
// enabled, we assert that we aren't seeing this. But with validation
// disabled we silently let this fly and we just abort this phase.
// FIXME: Get rid of all remaining cases of conflicting GetStacks.
// https://bugs.webkit.org/show_bug.cgi?id=150398
bool isConflicting =
deferred.operand(node->stackAccessData()->local) == ConflictingFlush;
if (validationEnabled())
DFG_ASSERT(m_graph, node, !isConflicting);
if (isConflicting) {
// Oh noes! Abort!!
return false;
}
// A GetStack doesn't affect anything, since we know which local we are reading
// from.
continue;
} else if (node->op() == PutStack) {
VirtualRegister operand = node->stackAccessData()->local;
deferred.operand(operand) = node->stackAccessData()->format;
continue;
}
auto escapeHandler = [&] (VirtualRegister operand) {
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog("For ", node, " escaping ", operand, "\n");
if (operand.isHeader())
return;
// We will materialize just before any reads.
deferred.operand(operand) = DeadFlush;
};
auto writeHandler = [&] (VirtualRegister operand) {
if (operand.isHeader())
return;
RELEASE_ASSERT(node->op() == LoadVarargs || node->op() == ForwardVarargs);
deferred.operand(operand) = DeadFlush;
};
preciseLocalClobberize(
m_graph, node, escapeHandler, writeHandler,
[&] (VirtualRegister, LazyNode) { });
}
if (deferred == deferredAtTail[block])
continue;
deferredAtTail[block] = deferred;
changed = true;
for (BasicBlock* successor : block->successors()) {
for (size_t i = deferred.size(); i--;) {
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog("Considering ", VirtualRegister(deferred.operandForIndex(i)), " at ", pointerDump(block), "->", pointerDump(successor), ": ", deferred[i], " and ", deferredAtHead[successor][i], " merges to ");
deferredAtHead[successor][i] =
merge(deferredAtHead[successor][i], deferred[i]);
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog(deferredAtHead[successor][i], "\n");
}
}
}
} while (changed);
// We wish to insert PutStacks at all of the materialization points, which are defined
// implicitly as the places where we set deferred to Dead while it was previously not Dead.
// To do this, we may need to build some Phi functions to handle stuff like this:
//
// Before:
//
// if (p)
// PutStack(r42, @x)
// else
// PutStack(r42, @y)
//
// After:
//
// if (p)
// Upsilon(@x, ^z)
// else
// Upsilon(@y, ^z)
// z: Phi()
// PutStack(r42, @z)
//
// This means that we have an SSACalculator::Variable for each local, and a Def is any
// PutStack in the original program. The original PutStacks will simply vanish.
Operands<SSACalculator::Variable*> operandToVariable(
OperandsLike, m_graph.block(0)->variablesAtHead);
Vector<VirtualRegister> indexToOperand;
for (size_t i = m_graph.block(0)->variablesAtHead.size(); i--;) {
VirtualRegister operand(m_graph.block(0)->variablesAtHead.operandForIndex(i));
SSACalculator::Variable* variable = ssaCalculator.newVariable();
operandToVariable.operand(operand) = variable;
ASSERT(indexToOperand.size() == variable->index());
indexToOperand.append(operand);
}
HashSet<Node*> putStacksToSink;
for (BasicBlock* block : m_graph.blocksInNaturalOrder()) {
for (Node* node : *block) {
switch (node->op()) {
case PutStack:
putStacksToSink.add(node);
ssaCalculator.newDef(
operandToVariable.operand(node->stackAccessData()->local),
block, node->child1().node());
break;
case GetStack:
ssaCalculator.newDef(
operandToVariable.operand(node->stackAccessData()->local),
block, node);
break;
default:
break;
}
}
}
ssaCalculator.computePhis(
[&] (SSACalculator::Variable* variable, BasicBlock* block) -> Node* {
VirtualRegister operand = indexToOperand[variable->index()];
if (!liveAtHead[block].operand(operand))
return nullptr;
FlushFormat format = deferredAtHead[block].operand(operand);
// We could have an invalid deferral because liveness is imprecise.
if (!isConcrete(format))
return nullptr;
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog("Adding Phi for ", operand, " at ", pointerDump(block), "\n");
Node* phiNode = m_graph.addNode(SpecHeapTop, Phi, block->at(0)->origin.withInvalidExit());
phiNode->mergeFlags(resultFor(format));
return phiNode;
});
Operands<Node*> mapping(OperandsLike, m_graph.block(0)->variablesAtHead);
Operands<FlushFormat> deferred;
for (BasicBlock* block : m_graph.blocksInNaturalOrder()) {
mapping.fill(nullptr);
for (size_t i = mapping.size(); i--;) {
VirtualRegister operand(mapping.operandForIndex(i));
SSACalculator::Variable* variable = operandToVariable.operand(operand);
SSACalculator::Def* def = ssaCalculator.reachingDefAtHead(block, variable);
if (!def)
continue;
mapping.operand(operand) = def->value();
}
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog("Mapping at top of ", pointerDump(block), ": ", mapping, "\n");
for (SSACalculator::Def* phiDef : ssaCalculator.phisForBlock(block)) {
VirtualRegister operand = indexToOperand[phiDef->variable()->index()];
insertionSet.insert(0, phiDef->value());
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog(" Mapping ", operand, " to ", phiDef->value(), "\n");
mapping.operand(operand) = phiDef->value();
}
deferred = deferredAtHead[block];
for (unsigned nodeIndex = 0; nodeIndex < block->size(); ++nodeIndex) {
Node* node = block->at(nodeIndex);
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog("Deferred at ", node, ":", deferred, "\n");
switch (node->op()) {
case PutStack: {
StackAccessData* data = node->stackAccessData();
VirtualRegister operand = data->local;
deferred.operand(operand) = data->format;
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog(" Mapping ", operand, " to ", node->child1().node(), " at ", node, "\n");
mapping.operand(operand) = node->child1().node();
break;
}
case GetStack: {
StackAccessData* data = node->stackAccessData();
FlushFormat format = deferred.operand(data->local);
if (!isConcrete(format)) {
DFG_ASSERT(
m_graph, node,
deferred.operand(data->local) != ConflictingFlush, deferred.operand(data->local));
// This means there is no deferral. No deferral means that the most
// authoritative value for this stack slot is what is stored in the stack. So,
// keep the GetStack.
mapping.operand(data->local) = node;
break;
}
// We have a concrete deferral, which means a PutStack that hasn't executed yet. It
// would have stored a value with a certain format. That format must match our
// format. But more importantly, we can simply use the value that the PutStack would
// have stored and get rid of the GetStack.
DFG_ASSERT(m_graph, node, format == data->format, format, data->format);
Node* incoming = mapping.operand(data->local);
node->child1() = incoming->defaultEdge();
node->convertToIdentity();
break;
}
default: {
auto escapeHandler = [&] (VirtualRegister operand) {
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog("For ", node, " escaping ", operand, "\n");
if (operand.isHeader())
return;
FlushFormat format = deferred.operand(operand);
if (!isConcrete(format)) {
// It's dead now, rather than conflicting.
deferred.operand(operand) = DeadFlush;
return;
}
// Gotta insert a PutStack.
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog("Inserting a PutStack for ", operand, " at ", node, "\n");
Node* incoming = mapping.operand(operand);
DFG_ASSERT(m_graph, node, incoming);
insertionSet.insertNode(
nodeIndex, SpecNone, PutStack, node->origin,
OpInfo(m_graph.m_stackAccessData.add(operand, format)),
Edge(incoming, uncheckedUseKindFor(format)));
deferred.operand(operand) = DeadFlush;
};
auto writeHandler = [&] (VirtualRegister operand) {
if (operand.isHeader())
return;
// LoadVarargs and ForwardVarargs are unconditional writes to the stack
// locations they claim to write to. They do not read from the stack
// locations they write to. This makes those stack locations dead right
// before a LoadVarargs/ForwardVarargs. This means we should never sink
// PutStacks right to this point.
RELEASE_ASSERT(node->op() == LoadVarargs || node->op() == ForwardVarargs);
deferred.operand(operand) = DeadFlush;
};
preciseLocalClobberize(
m_graph, node, escapeHandler, writeHandler,
[&] (VirtualRegister, LazyNode) { });
break;
} }
}
NodeAndIndex terminal = block->findTerminal();
size_t upsilonInsertionPoint = terminal.index;
NodeOrigin upsilonOrigin = terminal.node->origin;
for (BasicBlock* successorBlock : block->successors()) {
for (SSACalculator::Def* phiDef : ssaCalculator.phisForBlock(successorBlock)) {
Node* phiNode = phiDef->value();
SSACalculator::Variable* variable = phiDef->variable();
VirtualRegister operand = indexToOperand[variable->index()];
if (DFGPutStackSinkingPhaseInternal::verbose)
dataLog("Creating Upsilon for ", operand, " at ", pointerDump(block), "->", pointerDump(successorBlock), "\n");
FlushFormat format = deferredAtHead[successorBlock].operand(operand);
DFG_ASSERT(m_graph, nullptr, isConcrete(format), format);
UseKind useKind = uncheckedUseKindFor(format);
// We need to get a value for the stack slot. This phase doesn't really have a
// good way of determining if a stack location got clobbered. It just knows if
// there is a deferral. The lack of a deferral might mean that a PutStack or
// GetStack had never happened, or it might mean that the value was read, or
// that it was written. It's OK for us to make some bad decisions here, since
// GCSE will clean it up anyway.
Node* incoming;
if (isConcrete(deferred.operand(operand))) {
incoming = mapping.operand(operand);
DFG_ASSERT(m_graph, phiNode, incoming);
} else {
// Issue a GetStack to get the value. This might introduce some redundancy
// into the code, but if it's bad enough, GCSE will clean it up.
incoming = insertionSet.insertNode(
upsilonInsertionPoint, SpecNone, GetStack, upsilonOrigin,
OpInfo(m_graph.m_stackAccessData.add(operand, format)));
incoming->setResult(resultFor(format));
}
insertionSet.insertNode(
upsilonInsertionPoint, SpecNone, Upsilon, upsilonOrigin,
OpInfo(phiNode), Edge(incoming, useKind));
}
}
insertionSet.execute(block);
}
// Finally eliminate the sunken PutStacks by turning them into Checks. This keeps whatever
// type check they were doing.
for (BasicBlock* block : m_graph.blocksInNaturalOrder()) {
for (auto* node : *block) {
if (!putStacksToSink.contains(node))
continue;
node->remove(m_graph);
}
}
if (DFGPutStackSinkingPhaseInternal::verbose) {
dataLog("Graph after PutStack sinking:\n");
m_graph.dump();
}
return true;
}
};
} // anonymous namespace
bool performPutStackSinking(Graph& graph)
{
return runPhase<PutStackSinkingPhase>(graph);
}
} } // namespace JSC::DFG
#endif // ENABLE(DFG_JIT)