Source/JavaScriptCore/dfg/DFGLICMPhase.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2013-2019 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
  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
  * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include "config.h"
 #include "DFGLICMPhase.h"

 #if ENABLE(DFG_JIT)

 #include "DFGAbstractInterpreterInlines.h"
 #include "DFGAtTailAbstractState.h"
 #include "DFGBasicBlockInlines.h"
 #include "DFGClobberSet.h"
 #include "DFGClobberize.h"
 #include "DFGControlEquivalenceAnalysis.h"
 #include "DFGEdgeDominates.h"
 #include "DFGGraph.h"
 #include "DFGInsertionSet.h"
 #include "DFGMayExit.h"
 #include "DFGNaturalLoops.h"
 #include "DFGPhase.h"
 #include "DFGSafeToExecute.h"
 #include "JSCInlines.h"

 namespace JSC { namespace DFG {

 class LICMPhase : public Phase {
     static constexpr bool verbose = false;

     using NaturalLoop = SSANaturalLoop;

     struct LoopData {
         ClobberSet writes;
         BasicBlock* preHeader { nullptr };
     };

 public:
     LICMPhase(Graph& graph)
         : Phase(graph, "LICM")
         , m_state(graph)
         , m_interpreter(graph, m_state)
     {
     }

     bool run()
     {
         DFG_ASSERT(m_graph, nullptr, m_graph.m_form == SSA);

         m_graph.ensureSSADominators();
         m_graph.ensureSSANaturalLoops();
         m_graph.ensureControlEquivalenceAnalysis();

         if (verbose) {
             dataLog("Graph before LICM:\n");
             m_graph.dump();
         }

         m_data.resize(m_graph.m_ssaNaturalLoops->numLoops());

         // Figure out the set of things each loop writes to, not including blocks that
         // belong to inner loops. We fix this later.
         for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
             BasicBlock* block = m_graph.block(blockIndex);
             if (!block)
                 continue;

             // Skip blocks that are proved to not execute.
             // FIXME: This shouldn't be needed.
             // https://bugs.webkit.org/show_bug.cgi?id=128584
             if (!block->cfaHasVisited)
                 continue;

             const NaturalLoop* loop = m_graph.m_ssaNaturalLoops->innerMostLoopOf(block);
             if (!loop)
                 continue;
             LoopData& data = m_data[loop->index()];
             for (auto* node : *block) {
                 // Don't look beyond parts of the code that definitely always exit.
                 // FIXME: This shouldn't be needed.
                 // https://bugs.webkit.org/show_bug.cgi?id=128584
                 if (node->op() == ForceOSRExit)
                     break;

                 addWrites(m_graph, node, data.writes);
             }
         }

         // For each loop:
         // - Identify its pre-header.
         // - Make sure its outer loops know what it clobbers.
         for (unsigned loopIndex = m_graph.m_ssaNaturalLoops->numLoops(); loopIndex--;) {
             const NaturalLoop& loop = m_graph.m_ssaNaturalLoops->loop(loopIndex);
             LoopData& data = m_data[loop.index()];

             for (
                 const NaturalLoop* outerLoop = m_graph.m_ssaNaturalLoops->innerMostOuterLoop(loop);
                 outerLoop;
                 outerLoop = m_graph.m_ssaNaturalLoops->innerMostOuterLoop(*outerLoop))
                 m_data[outerLoop->index()].writes.addAll(data.writes);

             BasicBlock* header = loop.header();
             BasicBlock* preHeader = nullptr;
             unsigned numberOfPreHeaders = 0; // We're cool if this is 1.

             // This is guaranteed because we expect the CFG not to have unreachable code. Therefore, a
             // loop header must have a predecessor. (Also, we don't allow the root block to be a loop,
             // which cuts out the one other way of having a loop header with only one predecessor.)
             DFG_ASSERT(m_graph, header->at(0), header->predecessors.size() > 1, header->predecessors.size());

             for (unsigned i = header->predecessors.size(); i--;) {
                 BasicBlock* predecessor = header->predecessors[i];
                 if (m_graph.m_ssaDominators->dominates(header, predecessor))
                     continue;

                 preHeader = predecessor;
                 ++numberOfPreHeaders;
             }

             // We need to validate the pre-header. There are a bunch of things that could be wrong
             // about it:
             //
             // - There might be more than one. This means that pre-header creation either did not run,
             //   or some CFG transformation destroyed the pre-headers.
             //
             // - It may not be legal to exit at the pre-header. That would be a real bummer. Currently,
             //   LICM assumes that it can always hoist checks. See
             //   https://bugs.webkit.org/show_bug.cgi?id=148545. Though even with that fixed, we anyway
             //   would need to check if it's OK to exit at the pre-header since if we can't then we
             //   would have to restrict hoisting to non-exiting nodes.

             if (numberOfPreHeaders != 1)
                 continue;

             // This is guaranteed because the header has multiple predecessors and critical edges are
             // broken. Therefore the predecessors must all have one successor, which implies that they
             // must end in a Jump.
             DFG_ASSERT(m_graph, preHeader->terminal(), preHeader->terminal()->op() == Jump, preHeader->terminal()->op());

             if (!preHeader->terminal()->origin.exitOK)
                 continue;

             data.preHeader = preHeader;
         }

         m_graph.initializeNodeOwners();

         // Walk all basic blocks that belong to loops, looking for hoisting opportunities.
         // We try to hoist to the outer-most loop that permits it. Hoisting is valid if:
         // - The node doesn't write anything.
         // - The node doesn't read anything that the loop writes.
         // - The preHeader is valid (i.e. it passed the validation above).
         // - The preHeader's state at tail makes the node safe to execute.
         // - The loop's children all belong to nodes that strictly dominate the loop header.
         // - The preHeader's state at tail is still valid. This is mostly to save compile
         //   time and preserve some kind of sanity, if we hoist something that must exit.
         //
         // Also, we need to remember to:
         // - Update the state-at-tail with the node we hoisted, so future hoist candidates
         //   know about any type checks we hoisted.
         //
         // For maximum profit, we walk blocks in DFS order to ensure that we generally
         // tend to hoist dominators before dominatees.
         Vector<const NaturalLoop*> loopStack;
         bool changed = false;
         for (BasicBlock* block : m_graph.blocksInPreOrder()) {
             if (!block->cfaHasVisited)
                 continue;

             const NaturalLoop* loop = m_graph.m_ssaNaturalLoops->innerMostLoopOf(block);
             if (!loop)
                 continue;

             loopStack.shrink(0);
             for (
                 const NaturalLoop* current = loop;
                 current;
                 current = m_graph.m_ssaNaturalLoops->innerMostOuterLoop(*current))
                 loopStack.append(current);

             // Remember: the loop stack has the inner-most loop at index 0, so if we want
             // to bias hoisting to outer loops then we need to use a reverse loop.

             if (verbose) {
                 dataLog(
                     "Attempting to hoist out of block ", *block, " in loops:\n");
                 for (unsigned stackIndex = loopStack.size(); stackIndex--;) {
                     dataLog(
                         "        ", *loopStack[stackIndex], ", which writes ",
                         m_data[loopStack[stackIndex]->index()].writes, "\n");
                 }
             }

             for (unsigned nodeIndex = 0; nodeIndex < block->size(); ++nodeIndex) {
                 Node*& nodeRef = block->at(nodeIndex);
                 if (nodeRef->op() == ForceOSRExit)
                     break;
                 for (unsigned stackIndex = loopStack.size(); stackIndex--;)
                     changed |= attemptHoist(block, nodeRef, loopStack[stackIndex]);
             }
         }

         return changed;
     }

 private:
     bool attemptHoist(BasicBlock* fromBlock, Node*& nodeRef, const NaturalLoop* loop)
     {
         Node* node = nodeRef;
         LoopData& data = m_data[loop->index()];

         if (!data.preHeader) {
             if (verbose)
                 dataLog("    Not hoisting ", node, " because the pre-header is invalid.\n");
             return false;
         }

         if (!data.preHeader->cfaDidFinish) {
             if (verbose)
                 dataLog("    Not hoisting ", node, " because CFA is invalid.\n");
             return false;
         }

         m_state.initializeTo(data.preHeader);
         ASSERT(m_state.isValid());
         NodeOrigin originalOrigin = node->origin;
         bool canSpeculateBlindly = !m_graph.hasGlobalExitSite(originalOrigin.semantic, HoistingFailed);

         // NOTE: We could just use BackwardsDominators here directly, since we already know that the
         // preHeader dominates fromBlock. But we wouldn't get anything from being so clever, since
         // dominance checks are O(1) and only a few integer compares.
         bool isControlEquivalent = m_graph.m_controlEquivalenceAnalysis->dominatesEquivalently(data.preHeader, fromBlock);

         bool addsBlindSpeculation = !isControlEquivalent;
         NodeOrigin terminalOrigin = data.preHeader->terminal()->origin;
         Vector<Node*, 2> hoistedNodes; // This is sorted in the program order they will appear in the basic block we're hoisting to.

         auto insertHoistedNode = [&] (Node* node) {
             data.preHeader->insertBeforeTerminal(node);
             node->owner = data.preHeader;
             node->origin = terminalOrigin.withSemantic(node->origin.semantic);
             node->origin.wasHoisted |= addsBlindSpeculation;
             hoistedNodes.append(node);
         };

         auto updateAbstractState = [&] {
             auto invalidate = [&] (const NaturalLoop* loop) {
                 LoopData& data = m_data[loop->index()];
                 data.preHeader->cfaDidFinish = false;

                 for (unsigned bodyIndex = loop->size(); bodyIndex--;) {
                     BasicBlock* block = loop->at(bodyIndex);
                     if (block != data.preHeader)
                         block->cfaHasVisited = false;
                     block->cfaDidFinish = false;
                 }
             };

             // We can trust what AI proves about edge proof statuses when hoisting to the preheader.
             m_state.trustEdgeProofs();
             for (unsigned i = 0; i < hoistedNodes.size(); ++i) {
                 if (!m_interpreter.execute(hoistedNodes[i])) {
                     invalidate(loop);
                     return;
                 }
             }

             // However, when walking various inner loops below, the proof status of
             // an edge may be trivially true, even if it's not true in the preheader
             // we hoist to. We don't allow the below node executions to change the
             // state of edge proofs. An example of where a proof is trivially true
             // is if we have two loops, L1 and L2, where L2 is nested inside L1. The
             // header for L1 dominates L2. We hoist a Check from L1's header into L1's
             // preheader. However, inside L2's preheader, we can't trust that AI will
             // tell us this edge is proven. It's proven in L2's preheader because L2
             // is dominated by L1's header. However, the edge is not guaranteed to be
             // proven inside L1's preheader.
             m_state.dontTrustEdgeProofs();

             // Modify the states at the end of the preHeader of the loop we hoisted to,
             // and all pre-headers inside the loop. This isn't a stability bottleneck right now
             // because most loops are small and most blocks belong to few loops.
             for (unsigned bodyIndex = loop->size(); bodyIndex--;) {
                 BasicBlock* subBlock = loop->at(bodyIndex);
                 const NaturalLoop* subLoop = m_graph.m_ssaNaturalLoops->headerOf(subBlock);
                 if (!subLoop)
                     continue;
                 BasicBlock* subPreHeader = m_data[subLoop->index()].preHeader;
                 // We may not have given this loop a pre-header because either it didn't have exitOK
                 // or the header had multiple predecessors that it did not dominate. In that case the
                 // loop wouldn't be a hoisting candidate anyway, so we don't have to do anything.
                 if (!subPreHeader)
                     continue;
                 // The pre-header's tail may be unreachable, in which case we have nothing to do.
                 if (!subPreHeader->cfaDidFinish)
                     continue;
                 // We handled this above.
                 if (subPreHeader == data.preHeader)
                     continue;
                 m_state.initializeTo(subPreHeader);
                 for (unsigned i = 0; i < hoistedNodes.size(); ++i) {
                     if (!m_interpreter.execute(hoistedNodes[i])) {
                         invalidate(subLoop);
                         break;
                     }
                 }
             }
         };

         auto tryHoistChecks = [&] {
             if (addsBlindSpeculation && !canSpeculateBlindly)
                 return false;

             ASSERT(hoistedNodes.isEmpty());

             Vector<Edge, 3> checks;
             m_graph.doToChildren(node, [&] (Edge edge) {
                 if (!m_graph.m_ssaDominators->dominates(edge.node()->owner, data.preHeader))
                     return;

                 if (!edge.willHaveCheck())
                     return;

                 if ((m_state.forNode(edge).m_type & SpecEmpty) && checkMayCrashIfInputIsEmpty(edge.useKind())) {
                     if (!canSpeculateBlindly)
                         return;
                     Node* checkNotEmpty = m_graph.addNode(CheckNotEmpty, originalOrigin, Edge(edge.node(), UntypedUse));
                     insertHoistedNode(checkNotEmpty);
                 }

                 checks.append(edge);
             });

             if (checks.isEmpty())
                 return false;

             AdjacencyList children;
             NodeType checkOp = Check;
             if (checks.size() <= AdjacencyList::Size) {
                 children = AdjacencyList(AdjacencyList::Fixed);
                 for (unsigned i = 0; i < checks.size(); ++i)
                     children.setChild(i, checks[i]);
             } else {
                 checkOp = CheckVarargs;
                 unsigned firstChild = m_graph.m_varArgChildren.size();
                 for (Edge edge : checks)
                     m_graph.m_varArgChildren.append(edge);
                 children = AdjacencyList(AdjacencyList::Variable, firstChild, checks.size());
             }

             Node* check = m_graph.addNode(checkOp, originalOrigin, children);
             insertHoistedNode(check);
             updateAbstractState();

             if (verbose)
                 dataLogLn("    Hoisted some checks from ", node, " and created a new Check ", check, ". Hoisted from ", *fromBlock, " to ", *data.preHeader);

             return true;
         };

         if (!edgesDominate(m_graph, node, data.preHeader)) {
             if (verbose) {
                 dataLog(
                     "    Not hoisting ", node, " because it isn't loop invariant.\n");
             }
             return tryHoistChecks();
         }

         if (doesWrites(m_graph, node)) {
             if (verbose)
                 dataLog("    Not hoisting ", node, " because it writes things.\n");
             return tryHoistChecks();
         }

         // It's not safe to consult the AbstractState inside mayExit until we prove all edges
         // dominate the pre-header we're hoisting to. We are more conservative above when assigning
         // to this variable since we hadn't yet proven all edges dominate the pre-header. Above, we
         // just assume mayExit is true. We refine that here since we can now consult the AbstractState.
         addsBlindSpeculation = mayExit(m_graph, node, m_state) && !isControlEquivalent;

         if (readsOverlap(m_graph, node, data.writes)) {
             if (verbose) {
                 dataLog(
                     "    Not hoisting ", node,
                     " because it reads things that the loop writes.\n");
             }
             return tryHoistChecks();
         }

         if (addsBlindSpeculation && !canSpeculateBlindly) {
             if (verbose) {
                 dataLog(
                     "    Not hoisting ", node, " because it may exit and the pre-header (",
                     *data.preHeader, ") is not control equivalent to the node's original block (",
                     *fromBlock, ") and hoisting had previously failed.\n");
             }
             return tryHoistChecks();
         }

         if (!safeToExecute(m_state, m_graph, node)) {
             // See if we can rescue the situation by inserting blind speculations.
             bool ignoreEmptyChildren = true;
             if (canSpeculateBlindly
                 && safeToExecute(m_state, m_graph, node, ignoreEmptyChildren)) {
                 if (verbose) {
                     dataLog(
                         "    Rescuing hoisting by inserting empty checks.\n");
                 }
                 m_graph.doToChildren(
                     node,
                     [&] (Edge& edge) {
                         if (!(m_state.forNode(edge).m_type & SpecEmpty))
                             return;

                         Node* check = m_graph.addNode(CheckNotEmpty, originalOrigin, Edge(edge.node(), UntypedUse));
                         insertHoistedNode(check);
                     });
             } else {
                 if (verbose) {
                     dataLog(
                         "    Not hoisting ", node, " because it isn't safe to execute.\n");
                 }
                 return tryHoistChecks();
             }
         }

         if (verbose) {
             dataLog(
                 "    Hoisting ", node, " from ", *fromBlock, " to ", *data.preHeader,
                 "\n");
         }

         insertHoistedNode(node);
         updateAbstractState();

         if (node->flags() & NodeHasVarArgs)
             nodeRef = m_graph.addNode(CheckVarargs, originalOrigin, m_graph.copyVarargChildren(node));
         else
             nodeRef = m_graph.addNode(Check, originalOrigin, node->children);

         return true;
     }

     AtTailAbstractState m_state;
     AbstractInterpreter<AtTailAbstractState> m_interpreter;
     Vector<LoopData> m_data;
 };

 bool performLICM(Graph& graph)
 {
     return runPhase<LICMPhase>(graph);
 }

 } } // namespace JSC::DFG

 #endif // ENABLE(DFG_JIT)
	/*
	* Copyright (C) 2013-2019 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
	* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
	* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
	* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "config.h"
	#include "DFGLICMPhase.h"

	#if ENABLE(DFG_JIT)

	#include "DFGAbstractInterpreterInlines.h"
	#include "DFGAtTailAbstractState.h"
	#include "DFGBasicBlockInlines.h"
	#include "DFGClobberSet.h"
	#include "DFGClobberize.h"
	#include "DFGControlEquivalenceAnalysis.h"
	#include "DFGEdgeDominates.h"
	#include "DFGGraph.h"
	#include "DFGInsertionSet.h"
	#include "DFGMayExit.h"
	#include "DFGNaturalLoops.h"
	#include "DFGPhase.h"
	#include "DFGSafeToExecute.h"
	#include "JSCInlines.h"

	namespace JSC { namespace DFG {

	class LICMPhase : public Phase {
	static constexpr bool verbose = false;

	using NaturalLoop = SSANaturalLoop;

	struct LoopData {
	ClobberSet writes;
	BasicBlock* preHeader { nullptr };
	};

	public:
	LICMPhase(Graph& graph)
	: Phase(graph, "LICM")
	, m_state(graph)
	, m_interpreter(graph, m_state)
	{
	}

	bool run()
	{
	DFG_ASSERT(m_graph, nullptr, m_graph.m_form == SSA);

	m_graph.ensureSSADominators();
	m_graph.ensureSSANaturalLoops();
	m_graph.ensureControlEquivalenceAnalysis();

	if (verbose) {
	dataLog("Graph before LICM:\n");
	m_graph.dump();
	}

	m_data.resize(m_graph.m_ssaNaturalLoops->numLoops());

	// Figure out the set of things each loop writes to, not including blocks that
	// belong to inner loops. We fix this later.
	for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
	BasicBlock* block = m_graph.block(blockIndex);
	if (!block)
	continue;

	// Skip blocks that are proved to not execute.
	// FIXME: This shouldn't be needed.
	// https://bugs.webkit.org/show_bug.cgi?id=128584
	if (!block->cfaHasVisited)
	continue;

	const NaturalLoop* loop = m_graph.m_ssaNaturalLoops->innerMostLoopOf(block);
	if (!loop)
	continue;
	LoopData& data = m_data[loop->index()];
	for (auto* node : *block) {
	// Don't look beyond parts of the code that definitely always exit.
	// FIXME: This shouldn't be needed.
	// https://bugs.webkit.org/show_bug.cgi?id=128584
	if (node->op() == ForceOSRExit)
	break;

	addWrites(m_graph, node, data.writes);
	}
	}

	// For each loop:
	// - Identify its pre-header.
	// - Make sure its outer loops know what it clobbers.
	for (unsigned loopIndex = m_graph.m_ssaNaturalLoops->numLoops(); loopIndex--;) {
	const NaturalLoop& loop = m_graph.m_ssaNaturalLoops->loop(loopIndex);
	LoopData& data = m_data[loop.index()];

	for (
	const NaturalLoop* outerLoop = m_graph.m_ssaNaturalLoops->innerMostOuterLoop(loop);
	outerLoop;
	outerLoop = m_graph.m_ssaNaturalLoops->innerMostOuterLoop(*outerLoop))
	m_data[outerLoop->index()].writes.addAll(data.writes);

	BasicBlock* header = loop.header();
	BasicBlock* preHeader = nullptr;
	unsigned numberOfPreHeaders = 0; // We're cool if this is 1.

	// This is guaranteed because we expect the CFG not to have unreachable code. Therefore, a
	// loop header must have a predecessor. (Also, we don't allow the root block to be a loop,
	// which cuts out the one other way of having a loop header with only one predecessor.)
	DFG_ASSERT(m_graph, header->at(0), header->predecessors.size() > 1, header->predecessors.size());

	for (unsigned i = header->predecessors.size(); i--;) {
	BasicBlock* predecessor = header->predecessors[i];
	if (m_graph.m_ssaDominators->dominates(header, predecessor))
	continue;

	preHeader = predecessor;
	++numberOfPreHeaders;
	}

	// We need to validate the pre-header. There are a bunch of things that could be wrong
	// about it:
	//
	// - There might be more than one. This means that pre-header creation either did not run,
	// or some CFG transformation destroyed the pre-headers.
	//
	// - It may not be legal to exit at the pre-header. That would be a real bummer. Currently,
	// LICM assumes that it can always hoist checks. See
	// https://bugs.webkit.org/show_bug.cgi?id=148545. Though even with that fixed, we anyway
	// would need to check if it's OK to exit at the pre-header since if we can't then we
	// would have to restrict hoisting to non-exiting nodes.

	if (numberOfPreHeaders != 1)
	continue;

	// This is guaranteed because the header has multiple predecessors and critical edges are
	// broken. Therefore the predecessors must all have one successor, which implies that they
	// must end in a Jump.
	DFG_ASSERT(m_graph, preHeader->terminal(), preHeader->terminal()->op() == Jump, preHeader->terminal()->op());

	if (!preHeader->terminal()->origin.exitOK)
	continue;

	data.preHeader = preHeader;
	}

	m_graph.initializeNodeOwners();

	// Walk all basic blocks that belong to loops, looking for hoisting opportunities.
	// We try to hoist to the outer-most loop that permits it. Hoisting is valid if:
	// - The node doesn't write anything.
	// - The node doesn't read anything that the loop writes.
	// - The preHeader is valid (i.e. it passed the validation above).
	// - The preHeader's state at tail makes the node safe to execute.
	// - The loop's children all belong to nodes that strictly dominate the loop header.
	// - The preHeader's state at tail is still valid. This is mostly to save compile
	// time and preserve some kind of sanity, if we hoist something that must exit.
	//
	// Also, we need to remember to:
	// - Update the state-at-tail with the node we hoisted, so future hoist candidates
	// know about any type checks we hoisted.
	//
	// For maximum profit, we walk blocks in DFS order to ensure that we generally
	// tend to hoist dominators before dominatees.
	Vector<const NaturalLoop*> loopStack;
	bool changed = false;
	for (BasicBlock* block : m_graph.blocksInPreOrder()) {
	if (!block->cfaHasVisited)
	continue;

	const NaturalLoop* loop = m_graph.m_ssaNaturalLoops->innerMostLoopOf(block);
	if (!loop)
	continue;

	loopStack.shrink(0);
	for (
	const NaturalLoop* current = loop;
	current;
	current = m_graph.m_ssaNaturalLoops->innerMostOuterLoop(*current))
	loopStack.append(current);

	// Remember: the loop stack has the inner-most loop at index 0, so if we want
	// to bias hoisting to outer loops then we need to use a reverse loop.

	if (verbose) {
	dataLog(
	"Attempting to hoist out of block ", *block, " in loops:\n");
	for (unsigned stackIndex = loopStack.size(); stackIndex--;) {
	dataLog(
	" ", *loopStack[stackIndex], ", which writes ",
	m_data[loopStack[stackIndex]->index()].writes, "\n");
	}
	}

	for (unsigned nodeIndex = 0; nodeIndex < block->size(); ++nodeIndex) {
	Node*& nodeRef = block->at(nodeIndex);
	if (nodeRef->op() == ForceOSRExit)
	break;
	for (unsigned stackIndex = loopStack.size(); stackIndex--;)
	changed \|= attemptHoist(block, nodeRef, loopStack[stackIndex]);
	}
	}

	return changed;
	}

	private:
	bool attemptHoist(BasicBlock* fromBlock, Node& nodeRef, const NaturalLoop loop)
	{
	Node* node = nodeRef;
	LoopData& data = m_data[loop->index()];

	if (!data.preHeader) {
	if (verbose)
	dataLog(" Not hoisting ", node, " because the pre-header is invalid.\n");
	return false;
	}

	if (!data.preHeader->cfaDidFinish) {
	if (verbose)
	dataLog(" Not hoisting ", node, " because CFA is invalid.\n");
	return false;
	}

	m_state.initializeTo(data.preHeader);
	ASSERT(m_state.isValid());
	NodeOrigin originalOrigin = node->origin;
	bool canSpeculateBlindly = !m_graph.hasGlobalExitSite(originalOrigin.semantic, HoistingFailed);

	// NOTE: We could just use BackwardsDominators here directly, since we already know that the
	// preHeader dominates fromBlock. But we wouldn't get anything from being so clever, since
	// dominance checks are O(1) and only a few integer compares.
	bool isControlEquivalent = m_graph.m_controlEquivalenceAnalysis->dominatesEquivalently(data.preHeader, fromBlock);

	bool addsBlindSpeculation = !isControlEquivalent;
	NodeOrigin terminalOrigin = data.preHeader->terminal()->origin;
	Vector<Node*, 2> hoistedNodes; // This is sorted in the program order they will appear in the basic block we're hoisting to.

	auto insertHoistedNode = [&] (Node* node) {
	data.preHeader->insertBeforeTerminal(node);
	node->owner = data.preHeader;
	node->origin = terminalOrigin.withSemantic(node->origin.semantic);
	node->origin.wasHoisted \|= addsBlindSpeculation;
	hoistedNodes.append(node);
	};

	auto updateAbstractState = [&] {
	auto invalidate = [&] (const NaturalLoop* loop) {
	LoopData& data = m_data[loop->index()];
	data.preHeader->cfaDidFinish = false;

	for (unsigned bodyIndex = loop->size(); bodyIndex--;) {
	BasicBlock* block = loop->at(bodyIndex);
	if (block != data.preHeader)
	block->cfaHasVisited = false;
	block->cfaDidFinish = false;
	}
	};

	// We can trust what AI proves about edge proof statuses when hoisting to the preheader.
	m_state.trustEdgeProofs();
	for (unsigned i = 0; i < hoistedNodes.size(); ++i) {
	if (!m_interpreter.execute(hoistedNodes[i])) {
	invalidate(loop);
	return;
	}
	}

	// However, when walking various inner loops below, the proof status of
	// an edge may be trivially true, even if it's not true in the preheader
	// we hoist to. We don't allow the below node executions to change the
	// state of edge proofs. An example of where a proof is trivially true
	// is if we have two loops, L1 and L2, where L2 is nested inside L1. The
	// header for L1 dominates L2. We hoist a Check from L1's header into L1's
	// preheader. However, inside L2's preheader, we can't trust that AI will
	// tell us this edge is proven. It's proven in L2's preheader because L2
	// is dominated by L1's header. However, the edge is not guaranteed to be
	// proven inside L1's preheader.
	m_state.dontTrustEdgeProofs();

	// Modify the states at the end of the preHeader of the loop we hoisted to,
	// and all pre-headers inside the loop. This isn't a stability bottleneck right now
	// because most loops are small and most blocks belong to few loops.
	for (unsigned bodyIndex = loop->size(); bodyIndex--;) {
	BasicBlock* subBlock = loop->at(bodyIndex);
	const NaturalLoop* subLoop = m_graph.m_ssaNaturalLoops->headerOf(subBlock);
	if (!subLoop)
	continue;
	BasicBlock* subPreHeader = m_data[subLoop->index()].preHeader;
	// We may not have given this loop a pre-header because either it didn't have exitOK
	// or the header had multiple predecessors that it did not dominate. In that case the
	// loop wouldn't be a hoisting candidate anyway, so we don't have to do anything.
	if (!subPreHeader)
	continue;
	// The pre-header's tail may be unreachable, in which case we have nothing to do.
	if (!subPreHeader->cfaDidFinish)
	continue;
	// We handled this above.
	if (subPreHeader == data.preHeader)
	continue;
	m_state.initializeTo(subPreHeader);
	for (unsigned i = 0; i < hoistedNodes.size(); ++i) {
	if (!m_interpreter.execute(hoistedNodes[i])) {
	invalidate(subLoop);
	break;
	}
	}
	}
	};

	auto tryHoistChecks = [&] {
	if (addsBlindSpeculation && !canSpeculateBlindly)
	return false;

	ASSERT(hoistedNodes.isEmpty());

	Vector<Edge, 3> checks;
	m_graph.doToChildren(node, [&] (Edge edge) {
	if (!m_graph.m_ssaDominators->dominates(edge.node()->owner, data.preHeader))
	return;

	if (!edge.willHaveCheck())
	return;

	if ((m_state.forNode(edge).m_type & SpecEmpty) && checkMayCrashIfInputIsEmpty(edge.useKind())) {
	if (!canSpeculateBlindly)
	return;
	Node* checkNotEmpty = m_graph.addNode(CheckNotEmpty, originalOrigin, Edge(edge.node(), UntypedUse));
	insertHoistedNode(checkNotEmpty);
	}

	checks.append(edge);
	});

	if (checks.isEmpty())
	return false;

	AdjacencyList children;
	NodeType checkOp = Check;
	if (checks.size() <= AdjacencyList::Size) {
	children = AdjacencyList(AdjacencyList::Fixed);
	for (unsigned i = 0; i < checks.size(); ++i)
	children.setChild(i, checks[i]);
	} else {
	checkOp = CheckVarargs;
	unsigned firstChild = m_graph.m_varArgChildren.size();
	for (Edge edge : checks)
	m_graph.m_varArgChildren.append(edge);
	children = AdjacencyList(AdjacencyList::Variable, firstChild, checks.size());
	}

	Node* check = m_graph.addNode(checkOp, originalOrigin, children);
	insertHoistedNode(check);
	updateAbstractState();

	if (verbose)
	dataLogLn(" Hoisted some checks from ", node, " and created a new Check ", check, ". Hoisted from ", fromBlock, " to ", data.preHeader);

	return true;
	};

	if (!edgesDominate(m_graph, node, data.preHeader)) {
	if (verbose) {
	dataLog(
	" Not hoisting ", node, " because it isn't loop invariant.\n");
	}
	return tryHoistChecks();
	}

	if (doesWrites(m_graph, node)) {
	if (verbose)
	dataLog(" Not hoisting ", node, " because it writes things.\n");
	return tryHoistChecks();
	}

	// It's not safe to consult the AbstractState inside mayExit until we prove all edges
	// dominate the pre-header we're hoisting to. We are more conservative above when assigning
	// to this variable since we hadn't yet proven all edges dominate the pre-header. Above, we
	// just assume mayExit is true. We refine that here since we can now consult the AbstractState.
	addsBlindSpeculation = mayExit(m_graph, node, m_state) && !isControlEquivalent;

	if (readsOverlap(m_graph, node, data.writes)) {
	if (verbose) {
	dataLog(
	" Not hoisting ", node,
	" because it reads things that the loop writes.\n");
	}
	return tryHoistChecks();
	}

	if (addsBlindSpeculation && !canSpeculateBlindly) {
	if (verbose) {
	dataLog(
	" Not hoisting ", node, " because it may exit and the pre-header (",
	*data.preHeader, ") is not control equivalent to the node's original block (",
	*fromBlock, ") and hoisting had previously failed.\n");
	}
	return tryHoistChecks();
	}

	if (!safeToExecute(m_state, m_graph, node)) {
	// See if we can rescue the situation by inserting blind speculations.
	bool ignoreEmptyChildren = true;
	if (canSpeculateBlindly
	&& safeToExecute(m_state, m_graph, node, ignoreEmptyChildren)) {
	if (verbose) {
	dataLog(
	" Rescuing hoisting by inserting empty checks.\n");
	}
	m_graph.doToChildren(
	node,
	[&] (Edge& edge) {
	if (!(m_state.forNode(edge).m_type & SpecEmpty))
	return;

	Node* check = m_graph.addNode(CheckNotEmpty, originalOrigin, Edge(edge.node(), UntypedUse));
	insertHoistedNode(check);
	});
	} else {
	if (verbose) {
	dataLog(
	" Not hoisting ", node, " because it isn't safe to execute.\n");
	}
	return tryHoistChecks();
	}
	}

	if (verbose) {
	dataLog(
	" Hoisting ", node, " from ", fromBlock, " to ", data.preHeader,
	"\n");
	}

	insertHoistedNode(node);
	updateAbstractState();

	if (node->flags() & NodeHasVarArgs)
	nodeRef = m_graph.addNode(CheckVarargs, originalOrigin, m_graph.copyVarargChildren(node));
	else
	nodeRef = m_graph.addNode(Check, originalOrigin, node->children);

	return true;
	}

	AtTailAbstractState m_state;
	AbstractInterpreter<AtTailAbstractState> m_interpreter;
	Vector<LoopData> m_data;
	};

	bool performLICM(Graph& graph)
	{
	return runPhase<LICMPhase>(graph);
	}

	} } // namespace JSC::DFG

	#endif // ENABLE(DFG_JIT)