bool run()
 {
     ASSERT(m_graph.m_form == ThreadedCPS);
     ASSERT(m_graph.m_unificationState == LocallyUnified);
     
     // Ensure that all Phi functions are unified.
     for (BlockIndex blockIndex = m_graph.m_blocks.size(); blockIndex--;) {
         BasicBlock* block = m_graph.m_blocks[blockIndex].get();
         if (!block)
             continue;
         ASSERT(block->isReachable);
         
         for (unsigned phiIndex = block->phis.size(); phiIndex--;) {
             Node* phi = block->phis[phiIndex];
             for (unsigned childIdx = 0; childIdx < AdjacencyList::Size; ++childIdx) {
                 if (!phi->children.child(childIdx))
                     break;
                 
                 phi->variableAccessData()->unify(
                     phi->children.child(childIdx)->variableAccessData());
             }
         }
     }
     
     // Ensure that all predictions are fixed up based on the unification.
     for (unsigned i = 0; i < m_graph.m_variableAccessData.size(); ++i) {
         VariableAccessData* data = &m_graph.m_variableAccessData[i];
         data->find()->predict(data->nonUnifiedPrediction());
         data->find()->mergeIsCaptured(data->isCaptured());
         data->find()->mergeStructureCheckHoistingFailed(data->structureCheckHoistingFailed());
         data->find()->mergeShouldNeverUnbox(data->shouldNeverUnbox());
         data->find()->mergeIsLoadedFrom(data->isLoadedFrom());
     }
     
     m_graph.m_unificationState = GloballyUnified;
     return true;
 }
Ejemplo n.º 2
0
    void doRoundOfDoubleVoting()
    {
#if DFG_ENABLE(DEBUG_PROPAGATION_VERBOSE)
        dataLog("Voting on double uses of locals [%u]\n", m_count);
#endif
        for (unsigned i = 0; i < m_graph.m_variableAccessData.size(); ++i)
            m_graph.m_variableAccessData[i].find()->clearVotes();
        for (m_compileIndex = 0; m_compileIndex < m_graph.size(); ++m_compileIndex) {
            Node& node = m_graph[m_compileIndex];
            switch (node.op()) {
            case ValueAdd:
            case ArithAdd:
            case ArithSub: {
                SpeculatedType left = m_graph[node.child1()].prediction();
                SpeculatedType right = m_graph[node.child2()].prediction();
                
                DoubleBallot ballot;
                
                if (isNumberSpeculation(left) && isNumberSpeculation(right)
                    && !m_graph.addShouldSpeculateInteger(node))
                    ballot = VoteDouble;
                else
                    ballot = VoteValue;
                
                m_graph.vote(node.child1(), ballot);
                m_graph.vote(node.child2(), ballot);
                break;
            }
                
            case ArithMul: {
                SpeculatedType left = m_graph[node.child1()].prediction();
                SpeculatedType right = m_graph[node.child2()].prediction();
                
                DoubleBallot ballot;
                
                if (isNumberSpeculation(left) && isNumberSpeculation(right)
                    && !m_graph.mulShouldSpeculateInteger(node))
                    ballot = VoteDouble;
                else
                    ballot = VoteValue;
                
                m_graph.vote(node.child1(), ballot);
                m_graph.vote(node.child2(), ballot);
                break;
            }

            case ArithMin:
            case ArithMax:
            case ArithMod:
            case ArithDiv: {
                SpeculatedType left = m_graph[node.child1()].prediction();
                SpeculatedType right = m_graph[node.child2()].prediction();
                
                DoubleBallot ballot;
                
                if (isNumberSpeculation(left) && isNumberSpeculation(right)
                    && !(Node::shouldSpeculateInteger(m_graph[node.child1()], m_graph[node.child1()])
                         && node.canSpeculateInteger()))
                    ballot = VoteDouble;
                else
                    ballot = VoteValue;
                
                m_graph.vote(node.child1(), ballot);
                m_graph.vote(node.child2(), ballot);
                break;
            }
                
            case ArithAbs:
                DoubleBallot ballot;
                if (!(m_graph[node.child1()].shouldSpeculateInteger()
                      && node.canSpeculateInteger()))
                    ballot = VoteDouble;
                else
                    ballot = VoteValue;
                
                m_graph.vote(node.child1(), ballot);
                break;
                
            case ArithSqrt:
                m_graph.vote(node.child1(), VoteDouble);
                break;
                
            case SetLocal: {
                SpeculatedType prediction = m_graph[node.child1()].prediction();
                if (isDoubleSpeculation(prediction))
                    node.variableAccessData()->vote(VoteDouble);
                else if (!isNumberSpeculation(prediction) || isInt32Speculation(prediction))
                    node.variableAccessData()->vote(VoteValue);
                break;
            }
                
            default:
                m_graph.vote(node, VoteValue);
                break;
            }
        }
        for (unsigned i = 0; i < m_graph.m_variableAccessData.size(); ++i) {
            VariableAccessData* variableAccessData = &m_graph.m_variableAccessData[i];
            if (!variableAccessData->isRoot())
                continue;
            if (operandIsArgument(variableAccessData->local())
                || variableAccessData->isCaptured())
                continue;
            m_changed |= variableAccessData->tallyVotesForShouldUseDoubleFormat();
        }
        for (unsigned i = 0; i < m_graph.m_argumentPositions.size(); ++i)
            m_changed |= m_graph.m_argumentPositions[i].mergeArgumentAwareness();
        for (unsigned i = 0; i < m_graph.m_variableAccessData.size(); ++i) {
            VariableAccessData* variableAccessData = &m_graph.m_variableAccessData[i];
            if (!variableAccessData->isRoot())
                continue;
            if (operandIsArgument(variableAccessData->local())
                || variableAccessData->isCaptured())
                continue;
            m_changed |= variableAccessData->makePredictionForDoubleFormat();
        }
    }
Ejemplo n.º 3
0
    bool run()
    {
        for (unsigned i = m_graph.m_variableAccessData.size(); i--;) {
            VariableAccessData* variable = &m_graph.m_variableAccessData[i];
            if (!variable->isRoot())
                continue;
            variable->clearVotes();
        }
        
        // Identify the set of variables that are always subject to the same structure
        // checks. For now, only consider monomorphic structure checks (one structure).
        
        for (BlockIndex blockIndex = 0; blockIndex < m_graph.m_blocks.size(); ++blockIndex) {
            BasicBlock* block = m_graph.m_blocks[blockIndex].get();
            if (!block)
                continue;
            for (unsigned indexInBlock = 0; indexInBlock < block->size(); ++indexInBlock) {
                NodeIndex nodeIndex = block->at(indexInBlock);
                Node& node = m_graph[nodeIndex];
                if (!node.shouldGenerate())
                    continue;
                switch (node.op()) {
                case CheckStructure: {
                    Node& child = m_graph[node.child1()];
                    if (child.op() != GetLocal)
                        break;
                    VariableAccessData* variable = child.variableAccessData();
                    variable->vote(VoteStructureCheck);
                    if (variable->isCaptured() || variable->structureCheckHoistingFailed())
                        break;
                    if (!isCellSpeculation(variable->prediction()))
                        break;
                    noticeStructureCheck(variable, node.structureSet());
                    break;
                }
                    
                case ForwardCheckStructure:
                case ForwardStructureTransitionWatchpoint:
                    // We currently rely on the fact that we're the only ones who would
                    // insert this node.
                    ASSERT_NOT_REACHED();
                    break;
                    
                case GetByOffset:
                case PutByOffset:
                case PutStructure:
                case StructureTransitionWatchpoint:
                case AllocatePropertyStorage:
                case ReallocatePropertyStorage:
                case GetPropertyStorage:
                case GetByVal:
                case PutByVal:
                case PutByValAlias:
                case GetArrayLength:
                case CheckArray:
                case GetIndexedPropertyStorage:
                case Phantom:
                    // Don't count these uses.
                    break;
                    
                default:
                    m_graph.vote(node, VoteOther);
                    break;
                }
            }
        }
        
        // Disable structure hoisting on variables that appear to mostly be used in
        // contexts where it doesn't make sense.
        
        for (unsigned i = m_graph.m_variableAccessData.size(); i--;) {
            VariableAccessData* variable = &m_graph.m_variableAccessData[i];
            if (!variable->isRoot())
                continue;
            if (variable->voteRatio() >= Options::structureCheckVoteRatioForHoisting())
                continue;
            HashMap<VariableAccessData*, CheckData>::iterator iter = m_map.find(variable);
            if (iter == m_map.end())
                continue;
#if DFG_ENABLE(DEBUG_PROPAGATION_VERBOSE)
            dataLog("Zeroing the structure to hoist for %s because the ratio is %lf.\n",
                    m_graph.nameOfVariableAccessData(variable), variable->voteRatio());
#endif
            iter->second.m_structure = 0;
        }

        // Identify the set of variables that are live across a structure clobber.
        
        Operands<VariableAccessData*> live(
            m_graph.m_blocks[0]->variablesAtTail.numberOfArguments(),
            m_graph.m_blocks[0]->variablesAtTail.numberOfLocals());
        for (BlockIndex blockIndex = 0; blockIndex < m_graph.m_blocks.size(); ++blockIndex) {
            BasicBlock* block = m_graph.m_blocks[blockIndex].get();
            if (!block)
                continue;
            ASSERT(live.numberOfArguments() == block->variablesAtTail.numberOfArguments());
            ASSERT(live.numberOfLocals() == block->variablesAtTail.numberOfLocals());
            for (unsigned i = live.size(); i--;) {
                NodeIndex indexAtTail = block->variablesAtTail[i];
                VariableAccessData* variable;
                if (indexAtTail == NoNode)
                    variable = 0;
                else
                    variable = m_graph[indexAtTail].variableAccessData();
                live[i] = variable;
            }
            for (unsigned indexInBlock = block->size(); indexInBlock--;) {
                NodeIndex nodeIndex = block->at(indexInBlock);
                Node& node = m_graph[nodeIndex];
                if (!node.shouldGenerate())
                    continue;
                switch (node.op()) {
                case GetLocal:
                case Flush:
                    // This is a birth.
                    live.operand(node.local()) = node.variableAccessData();
                    break;
                    
                case SetLocal:
                case SetArgument:
                    ASSERT(live.operand(node.local())); // Must be live.
                    ASSERT(live.operand(node.local()) == node.variableAccessData()); // Must have the variable we expected.
                    // This is a death.
                    live.operand(node.local()) = 0;
                    break;
                    
                // Use the CFA's notion of what clobbers the world.
                case ValueAdd:
                    if (m_graph.addShouldSpeculateInteger(node))
                        break;
                    if (Node::shouldSpeculateNumber(m_graph[node.child1()], m_graph[node.child2()]))
                        break;
                    clobber(live);
                    break;
                    
                case CompareLess:
                case CompareLessEq:
                case CompareGreater:
                case CompareGreaterEq:
                case CompareEq: {
                    Node& left = m_graph[node.child1()];
                    Node& right = m_graph[node.child2()];
                    if (Node::shouldSpeculateInteger(left, right))
                        break;
                    if (Node::shouldSpeculateNumber(left, right))
                        break;
                    if (node.op() == CompareEq) {
                        if ((m_graph.isConstant(node.child1().index())
                             && m_graph.valueOfJSConstant(node.child1().index()).isNull())
                            || (m_graph.isConstant(node.child2().index())
                                && m_graph.valueOfJSConstant(node.child2().index()).isNull()))
                            break;
                        
                        if (Node::shouldSpeculateFinalObject(left, right))
                            break;
                        if (Node::shouldSpeculateArray(left, right))
                            break;
                        if (left.shouldSpeculateFinalObject() && right.shouldSpeculateFinalObjectOrOther())
                            break;
                        if (right.shouldSpeculateFinalObject() && left.shouldSpeculateFinalObjectOrOther())
                            break;
                        if (left.shouldSpeculateArray() && right.shouldSpeculateArrayOrOther())
                            break;
                        if (right.shouldSpeculateArray() && left.shouldSpeculateArrayOrOther())
                            break;
                    }
                    clobber(live);
                    break;
                }
                    
                case GetByVal:
                case PutByVal:
                case PutByValAlias:
                    if (m_graph.byValIsPure(node))
                        break;
                    clobber(live);
                    break;
                    
                case GetMyArgumentsLengthSafe:
                case GetMyArgumentByValSafe:
                case GetById:
                case GetByIdFlush:
                case PutStructure:
                case PhantomPutStructure:
                case PutById:
                case PutByIdDirect:
                case Call:
                case Construct:
                case Resolve:
                case ResolveBase:
                case ResolveBaseStrictPut:
                case ResolveGlobal:
                    clobber(live);
                    break;
                    
                default:
                    ASSERT(node.op() != Phi);
                    break;
                }
            }
        }
        
        bool changed = false;

#if DFG_ENABLE(DEBUG_PROPAGATION_VERBOSE)
        for (HashMap<VariableAccessData*, CheckData>::iterator it = m_map.begin();
             it != m_map.end(); ++it) {
            if (!it->second.m_structure) {
                dataLog("Not hoisting checks for %s because of heuristics.\n", m_graph.nameOfVariableAccessData(it->first));
                continue;
            }
            if (it->second.m_isClobbered && !it->second.m_structure->transitionWatchpointSetIsStillValid()) {
                dataLog("Not hoisting checks for %s because the structure is clobbered and has an invalid watchpoint set.\n", m_graph.nameOfVariableAccessData(it->first));
                continue;
            }
            dataLog("Hoisting checks for %s\n", m_graph.nameOfVariableAccessData(it->first));
        }
#endif // DFG_ENABLE(DEBUG_PROPAGATION_VERBOSE)
        
        // Make changes:
        // 1) If a variable's live range does not span a clobber, then inject structure
        //    checks before the SetLocal.
        // 2) If a variable's live range spans a clobber but is watchpointable, then
        //    inject structure checks before the SetLocal and replace all other structure
        //    checks on that variable with structure transition watchpoints.
        
        InsertionSet<NodeIndex> insertionSet;
        for (BlockIndex blockIndex = 0; blockIndex < m_graph.m_blocks.size(); ++blockIndex) {
            BasicBlock* block = m_graph.m_blocks[blockIndex].get();
            if (!block)
                continue;
            for (unsigned indexInBlock = 0; indexInBlock < block->size(); ++indexInBlock) {
                NodeIndex nodeIndex = block->at(indexInBlock);
                Node& node = m_graph[nodeIndex];
                // Be careful not to use 'node' after appending to the graph. In those switch
                // cases where we need to append, we first carefully extract everything we need
                // from the node, before doing any appending.
                if (!node.shouldGenerate())
                    continue;
                switch (node.op()) {
                case SetArgument: {
                    ASSERT(!blockIndex);
                    // Insert a GetLocal and a CheckStructure immediately following this
                    // SetArgument, if the variable was a candidate for structure hoisting.
                    // If the basic block previously only had the SetArgument as its
                    // variable-at-tail, then replace it with this GetLocal.
                    VariableAccessData* variable = node.variableAccessData();
                    HashMap<VariableAccessData*, CheckData>::iterator iter = m_map.find(variable);
                    if (iter == m_map.end())
                        break;
                    if (!iter->second.m_structure)
                        break;
                    if (iter->second.m_isClobbered && !iter->second.m_structure->transitionWatchpointSetIsStillValid())
                        break;
                    
                    node.ref();

                    CodeOrigin codeOrigin = node.codeOrigin;
                    
                    Node getLocal(GetLocal, codeOrigin, OpInfo(variable), nodeIndex);
                    getLocal.predict(variable->prediction());
                    getLocal.ref();
                    NodeIndex getLocalIndex = m_graph.size();
                    m_graph.append(getLocal);
                    insertionSet.append(indexInBlock + 1, getLocalIndex);
                    
                    Node checkStructure(CheckStructure, codeOrigin, OpInfo(m_graph.addStructureSet(iter->second.m_structure)), getLocalIndex);
                    checkStructure.ref();
                    NodeIndex checkStructureIndex = m_graph.size();
                    m_graph.append(checkStructure);
                    insertionSet.append(indexInBlock + 1, checkStructureIndex);
                    
                    if (block->variablesAtTail.operand(variable->local()) == nodeIndex)
                        block->variablesAtTail.operand(variable->local()) = getLocalIndex;
                    
                    m_graph.substituteGetLocal(*block, indexInBlock, variable, getLocalIndex);
                    
                    changed = true;
                    break;
                }
                    
                case SetLocal: {
                    VariableAccessData* variable = node.variableAccessData();
                    HashMap<VariableAccessData*, CheckData>::iterator iter = m_map.find(variable);
                    if (iter == m_map.end())
                        break;
                    if (!iter->second.m_structure)
                        break;
                    if (iter->second.m_isClobbered && !iter->second.m_structure->transitionWatchpointSetIsStillValid())
                        break;

                    // First insert a dead SetLocal to tell OSR that the child's value should
                    // be dropped into this bytecode variable if the CheckStructure decides
                    // to exit.
                    
                    CodeOrigin codeOrigin = node.codeOrigin;
                    NodeIndex child1 = node.child1().index();
                    
                    Node setLocal(SetLocal, codeOrigin, OpInfo(variable), child1);
                    NodeIndex setLocalIndex = m_graph.size();
                    m_graph.append(setLocal);
                    insertionSet.append(indexInBlock, setLocalIndex);
                    m_graph[child1].ref();
                    // Use a ForwardCheckStructure to indicate that we should exit to the
                    // next bytecode instruction rather than reexecuting the current one.
                    Node checkStructure(ForwardCheckStructure, codeOrigin, OpInfo(m_graph.addStructureSet(iter->second.m_structure)), child1);
                    checkStructure.ref();
                    NodeIndex checkStructureIndex = m_graph.size();
                    m_graph.append(checkStructure);
                    insertionSet.append(indexInBlock, checkStructureIndex);
                    changed = true;
                    break;
                }
                    
                case CheckStructure: {
                    Node& child = m_graph[node.child1()];
                    if (child.op() != GetLocal)
                        break;
                    HashMap<VariableAccessData*, CheckData>::iterator iter = m_map.find(child.variableAccessData());
                    if (iter == m_map.end())
                        break;
                    if (!iter->second.m_structure)
                        break;
                    if (!iter->second.m_isClobbered) {
                        node.setOpAndDefaultFlags(Phantom);
                        ASSERT(node.refCount() == 1);
                        break;
                    }
                    if (!iter->second.m_structure->transitionWatchpointSetIsStillValid())
                        break;
                    ASSERT(iter->second.m_structure == node.structureSet().singletonStructure());
                    node.convertToStructureTransitionWatchpoint();
                    changed = true;
                    break;
                }
                    
                default:
                    break;
                }
            }
            insertionSet.execute(*block);
        }
        
        return changed;
    }
Ejemplo n.º 4
0
    bool run()
    {
        RELEASE_ASSERT(m_graph.m_form == ThreadedCPS);
        
        if (dumpGraph) {
            dataLog("Graph dump at top of SSA conversion:\n");
            m_graph.dump();
        }
        
        // Eliminate all duplicate or self-pointing Phi edges. This means that
        // we transform:
        //
        // p: Phi(@n1, @n2, @n3)
        //
        // into:
        //
        // p: Phi(@x)
        //
        // if each @ni in {@n1, @n2, @n3} is either equal to @p to is equal
        // to @x, for exactly one other @x. Additionally, trivial Phis (i.e.
        // p: Phi(@x)) are forwarded, so that if have an edge to such @p, we
        // replace it with @x. This loop does this for Phis only; later we do
        // such forwarding for Phi references found in other nodes.
        //
        // See Aycock and Horspool in CC'00 for a better description of what
        // we're doing here.
        do {
            m_changed = false;
            for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
                BasicBlock* block = m_graph.block(blockIndex);
                if (!block)
                    continue;
                for (unsigned phiIndex = block->phis.size(); phiIndex--;) {
                    Node* phi = block->phis[phiIndex];
                    if (phi->variableAccessData()->isCaptured())
                        continue;
                    forwardPhiChildren(phi);
                    deduplicateChildren(phi);
                }
            }
        } while (m_changed);
        
        // For each basic block, for each local live at the head of that block,
        // figure out what node we should be referring to instead of that local.
        // If it turns out to be a non-trivial Phi, make sure that we create an
        // SSA Phi and Upsilons in predecessor blocks. We reuse
        // BasicBlock::variablesAtHead for tracking which nodes to refer to.
        Operands<bool> nonTrivialPhis(OperandsLike, m_graph.block(0)->variablesAtHead);
        for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
            BasicBlock* block = m_graph.block(blockIndex);
            if (!block)
                continue;

            nonTrivialPhis.fill(false);
            for (unsigned i = block->phis.size(); i--;) {
                Node* phi = block->phis[i];
                if (!phi->children.justOneChild())
                    nonTrivialPhis.operand(phi->local()) = true;
            }
                
            for (unsigned i = block->variablesAtHead.size(); i--;) {
                Node* node = block->variablesAtHead[i];
                if (!node)
                    continue;
                
                if (verbose)
                    dataLog("At block #", blockIndex, " for operand r", block->variablesAtHead.operandForIndex(i), " have node ", node, "\n");
                
                VariableAccessData* variable = node->variableAccessData();
                if (variable->isCaptured()) {
                    // Poison this entry in variablesAtHead because we don't
                    // want anyone to try to refer to it, if the variable is
                    // captured.
                    block->variablesAtHead[i] = 0;
                    continue;
                }
                
                switch (node->op()) {
                case Phi:
                case SetArgument:
                    break;
                case Flush:
                case GetLocal:
                case PhantomLocal:
                    node = node->child1().node();
                    break;
                default:
                    RELEASE_ASSERT_NOT_REACHED();
                }
                RELEASE_ASSERT(node->op() == Phi || node->op() == SetArgument);
                
                bool isFlushed = !!(node->flags() & NodeIsFlushed);
                
                if (node->op() == Phi) {
                    if (!nonTrivialPhis.operand(node->local())) {
                        Edge edge = node->children.justOneChild();
                        ASSERT(edge);
                        if (verbose)
                            dataLog("    One child: ", edge, ", ", RawPointer(edge.node()), "\n");
                        node = edge.node(); // It's something from a different basic block.
                    } else {
                        if (verbose)
                            dataLog("    Non-trivial.\n");
                        // It's a non-trivial Phi.
                        FlushFormat format = variable->flushFormat();
                        NodeFlags result = resultFor(format);
                        UseKind useKind = useKindFor(format);
                        
                        node = m_insertionSet.insertNode(0, SpecNone, Phi, NodeOrigin());
                        if (verbose)
                            dataLog("    Inserted new node: ", node, "\n");
                        node->mergeFlags(result);
                        RELEASE_ASSERT((node->flags() & NodeResultMask) == result);
                        
                        for (unsigned j = block->predecessors.size(); j--;) {
                            BasicBlock* predecessor = block->predecessors[j];
                            predecessor->appendNonTerminal(
                                m_graph, SpecNone, Upsilon, predecessor->last()->origin,
                                OpInfo(node), Edge(predecessor->variablesAtTail[i], useKind));
                        }
                        
                        if (isFlushed) {
                            // Do nothing. For multiple reasons.
                            
                            // Reason #1: If the local is flushed then we don't need to bother
                            // with a MovHint since every path to this point in the code will
                            // have flushed the bytecode variable using a SetLocal and hence
                            // the Availability::flushedAt() will agree, and that will be
                            // sufficient for figuring out how to recover the variable's value.
                            
                            // Reason #2: If we had inserted a MovHint and the Phi function had
                            // died (because the only user of the value was the "flush" - i.e.
                            // some asynchronous runtime thingy) then the MovHint would turn
                            // into a ZombieHint, which would fool us into thinking that the
                            // variable is dead.
                            
                            // Reason #3: If we had inserted a MovHint then even if the Phi
                            // stayed alive, we would still end up generating inefficient code
                            // since we would be telling the OSR exit compiler to use some SSA
                            // value for the bytecode variable rather than just telling it that
                            // the value was already on the stack.
                        } else {
                            m_insertionSet.insertNode(
                                0, SpecNone, MovHint, NodeOrigin(),
                                OpInfo(variable->local().offset()), Edge(node));
                        }
                    }
                }
                
                block->variablesAtHead[i] = node;
            }

            m_insertionSet.execute(block);
        }
        
        if (verbose) {
            dataLog("Variables at head after SSA Phi insertion:\n");
            for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
                BasicBlock* block = m_graph.block(blockIndex);
                if (!block)
                    continue;
                dataLog("    ", *block, ": ", block->variablesAtHead, "\n");
            }
        }
        
        // At this point variablesAtHead in each block refers to either:
        //
        // 1) A new SSA phi in the current block.
        // 2) A SetArgument, which will soon get converted into a GetArgument.
        // 3) An old CPS phi in a different block.
        //
        // We don't have to do anything for (1) and (2), but we do need to
        // do a replacement for (3).
        
        // Clear all replacements, since other phases may have used them.
        m_graph.clearReplacements();
        
        if (dumpGraph) {
            dataLog("Graph just before identifying replacements:\n");
            m_graph.dump();
        }
        
        // For all of the old CPS Phis, figure out what they correspond to in SSA.
        for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
            BasicBlock* block = m_graph.block(blockIndex);
            if (!block)
                continue;
            if (verbose)
                dataLog("Dealing with block #", blockIndex, "\n");
            for (unsigned phiIndex = block->phis.size(); phiIndex--;) {
                Node* phi = block->phis[phiIndex];
                if (verbose) {
                    dataLog(
                        "Considering ", phi, " (", RawPointer(phi), "), for r",
                        phi->local(), ", and its replacement in ", *block, ", ",
                        block->variablesAtHead.operand(phi->local()), "\n");
                }
                ASSERT(phi != block->variablesAtHead.operand(phi->local()));
                phi->misc.replacement = block->variablesAtHead.operand(phi->local());
            }
        }
        
        // Now make sure that all variablesAtHead in each block points to the
        // canonical SSA value. Prior to this, variablesAtHead[local] may point to
        // an old CPS Phi in a different block.
        for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
            BasicBlock* block = m_graph.block(blockIndex);
            if (!block)
                continue;
            for (size_t i = block->variablesAtHead.size(); i--;) {
                Node* node = block->variablesAtHead[i];
                if (!node)
                    continue;
                while (node->misc.replacement) {
                    ASSERT(node != node->misc.replacement);
                    node = node->misc.replacement;
                }
                block->variablesAtHead[i] = node;
            }
        }
        
        if (verbose) {
            dataLog("Variables at head after convergence:\n");
            for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
                BasicBlock* block = m_graph.block(blockIndex);
                if (!block)
                    continue;
                dataLog("    ", *block, ": ", block->variablesAtHead, "\n");
            }
        }
        
        // Convert operations over locals into operations over SSA nodes.
        // - GetLocal over captured variables lose their phis.
        // - GetLocal over uncaptured variables die and get replaced with references
        //   to the node specified by variablesAtHead.
        // - SetLocal gets NodeMustGenerate if it's flushed, or turns into a
        //   Check otherwise.
        // - Flush loses its children and turns into a Phantom.
        // - PhantomLocal becomes Phantom, and its child is whatever is specified
        //   by variablesAtHead.
        // - SetArgument turns into GetArgument unless it's a captured variable.
        // - Upsilons get their children fixed to refer to the true value of that local
        //   at the end of the block. Prior to this loop, Upsilons will refer to
        //   variableAtTail[operand], which may be any of Flush, PhantomLocal, GetLocal,
        //   SetLocal, SetArgument, or Phi. We accomplish this by setting the
        //   replacement pointers of all of those nodes to refer to either
        //   variablesAtHead[operand], or the child of the SetLocal.
        for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
            BasicBlock* block = m_graph.block(blockIndex);
            if (!block)
                continue;
            
            for (unsigned phiIndex = block->phis.size(); phiIndex--;) {
                block->phis[phiIndex]->misc.replacement =
                    block->variablesAtHead.operand(block->phis[phiIndex]->local());
            }
            for (unsigned nodeIndex = block->size(); nodeIndex--;)
                ASSERT(!block->at(nodeIndex)->misc.replacement);
            
            for (unsigned nodeIndex = 0; nodeIndex < block->size(); ++nodeIndex) {
                Node* node = block->at(nodeIndex);
                
                m_graph.performSubstitution(node);
                
                switch (node->op()) {
                case SetLocal: {
                    VariableAccessData* variable = node->variableAccessData();
                    if (variable->isCaptured() || !!(node->flags() & NodeIsFlushed))
                        node->mergeFlags(NodeMustGenerate);
                    else
                        node->setOpAndDefaultFlags(Check);
                    node->misc.replacement = node->child1().node(); // Only for Upsilons.
                    break;
                }
                    
                case GetLocal: {
                    // It seems tempting to just do forwardPhi(GetLocal), except that we
                    // could have created a new (SSA) Phi, and the GetLocal could still be
                    // referring to an old (CPS) Phi. Uses variablesAtHead to tell us what
                    // to refer to.
                    node->children.reset();
                    VariableAccessData* variable = node->variableAccessData();
                    if (variable->isCaptured())
                        break;
                    node->convertToPhantom();
                    node->misc.replacement = block->variablesAtHead.operand(variable->local());
                    break;
                }
                    
                case Flush: {
                    node->children.reset();
                    node->convertToPhantom();
                    // This is only for Upsilons. An Upsilon will only refer to a Flush if
                    // there were no SetLocals or GetLocals in the block.
                    node->misc.replacement = block->variablesAtHead.operand(node->local());
                    break;
                }
                    
                case PhantomLocal: {
                    VariableAccessData* variable = node->variableAccessData();
                    if (variable->isCaptured())
                        break;
                    node->child1().setNode(block->variablesAtHead.operand(variable->local()));
                    node->convertToPhantom();
                    // This is only for Upsilons. An Upsilon will only refer to a
                    // PhantomLocal if there were no SetLocals or GetLocals in the block.
                    node->misc.replacement = block->variablesAtHead.operand(variable->local());
                    break;
                }
                    
                case SetArgument: {
                    VariableAccessData* variable = node->variableAccessData();
                    if (variable->isCaptured())
                        break;
                    node->setOpAndDefaultFlags(GetArgument);
                    node->mergeFlags(resultFor(node->variableAccessData()->flushFormat()));
                    break;
                }

                default:
                    break;
                }
            }
        }
        
        // Free all CPS phis and reset variables vectors.
        for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
            BasicBlock* block = m_graph.block(blockIndex);
            if (!block)
                continue;
            for (unsigned phiIndex = block->phis.size(); phiIndex--;)
                m_graph.m_allocator.free(block->phis[phiIndex]);
            block->phis.clear();
            block->variablesAtHead.clear();
            block->variablesAtTail.clear();
            block->valuesAtHead.clear();
            block->valuesAtHead.clear();
            block->ssa = adoptPtr(new BasicBlock::SSAData(block));
        }
        
        m_graph.m_arguments.clear();
        
        m_graph.m_form = SSA;
        return true;
    }
Ejemplo n.º 5
0
    bool run()
    {
        RELEASE_ASSERT(m_graph.m_form == ThreadedCPS);
        
        m_graph.clearReplacements();
        m_graph.m_dominators.computeIfNecessary(m_graph);
        
        if (verbose) {
            dataLog("Graph before SSA transformation:\n");
            m_graph.dump();
        }

        // Create a SSACalculator::Variable for every root VariableAccessData.
        for (VariableAccessData& variable : m_graph.m_variableAccessData) {
            if (!variable.isRoot() || variable.isCaptured())
                continue;
            
            SSACalculator::Variable* ssaVariable = m_calculator.newVariable();
            ASSERT(ssaVariable->index() == m_variableForSSAIndex.size());
            m_variableForSSAIndex.append(&variable);
            m_ssaVariableForVariable.add(&variable, ssaVariable);
        }
        
        // Find all SetLocals and create Defs for them. We handle SetArgument by creating a
        // GetLocal, and recording the flush format.
        for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
            BasicBlock* block = m_graph.block(blockIndex);
            if (!block)
                continue;
            
            // Must process the block in forward direction because we want to see the last
            // assignment for every local.
            for (unsigned nodeIndex = 0; nodeIndex < block->size(); ++nodeIndex) {
                Node* node = block->at(nodeIndex);
                if (node->op() != SetLocal && node->op() != SetArgument)
                    continue;
                
                VariableAccessData* variable = node->variableAccessData();
                if (variable->isCaptured())
                    continue;
                
                Node* childNode;
                if (node->op() == SetLocal)
                    childNode = node->child1().node();
                else {
                    ASSERT(node->op() == SetArgument);
                    childNode = m_insertionSet.insertNode(
                        nodeIndex, node->variableAccessData()->prediction(),
                        GetStack, node->origin,
                        OpInfo(m_graph.m_stackAccessData.add(variable->local(), variable->flushFormat())));
                    if (!ASSERT_DISABLED)
                        m_argumentGetters.add(childNode);
                    m_argumentMapping.add(node, childNode);
                }
                
                m_calculator.newDef(
                    m_ssaVariableForVariable.get(variable), block, childNode);
            }
            
            m_insertionSet.execute(block);
        }
        
        // Decide where Phis are to be inserted. This creates the Phi's but doesn't insert them
        // yet. We will later know where to insert them because SSACalculator is such a bro.
        m_calculator.computePhis(
            [&] (SSACalculator::Variable* ssaVariable, BasicBlock* block) -> Node* {
                VariableAccessData* variable = m_variableForSSAIndex[ssaVariable->index()];
                
                // Prune by liveness. This doesn't buy us much other than compile times.
                Node* headNode = block->variablesAtHead.operand(variable->local());
                if (!headNode)
                    return nullptr;

                // There is the possibiltiy of "rebirths". The SSA calculator will already prune
                // rebirths for the same VariableAccessData. But it will not be able to prune
                // rebirths that arose from the same local variable number but a different
                // VariableAccessData. We do that pruning here.
                //
                // Here's an example of a rebirth that this would catch:
                //
                //     var x;
                //     if (foo) {
                //         if (bar) {
                //             x = 42;
                //         } else {
                //             x = 43;
                //         }
                //         print(x);
                //         x = 44;
                //     } else {
                //         x = 45;
                //     }
                //     print(x); // Without this check, we'd have a Phi for x = 42|43 here.
                //
                // FIXME: Consider feeding local variable numbers, not VariableAccessData*'s, as
                // the "variables" for SSACalculator. That would allow us to eliminate this
                // special case.
                // https://bugs.webkit.org/show_bug.cgi?id=136641
                if (headNode->variableAccessData() != variable)
                    return nullptr;
                
                Node* phiNode = m_graph.addNode(
                    variable->prediction(), Phi, NodeOrigin());
                FlushFormat format = variable->flushFormat();
                NodeFlags result = resultFor(format);
                phiNode->mergeFlags(result);
                return phiNode;
            });
        
        if (verbose) {
            dataLog("Computed Phis, about to transform the graph.\n");
            dataLog("\n");
            dataLog("Graph:\n");
            m_graph.dump();
            dataLog("\n");
            dataLog("Mappings:\n");
            for (unsigned i = 0; i < m_variableForSSAIndex.size(); ++i)
                dataLog("    ", i, ": ", VariableAccessDataDump(m_graph, m_variableForSSAIndex[i]), "\n");
            dataLog("\n");
            dataLog("SSA calculator: ", m_calculator, "\n");
        }
        
        // Do the bulk of the SSA conversion. For each block, this tracks the operand->Node
        // mapping based on a combination of what the SSACalculator tells us, and us walking over
        // the block in forward order. We use our own data structure, valueForOperand, for
        // determining the local mapping, but we rely on SSACalculator for the non-local mapping.
        //
        // This does three things at once:
        //
        // - Inserts the Phis in all of the places where they need to go. We've already created
        //   them and they are accounted for in the SSACalculator's data structures, but we
        //   haven't inserted them yet, mostly because we want to insert all of a block's Phis in
        //   one go to amortize the cost of node insertion.
        //
        // - Create and insert Upsilons.
        //
        // - Convert all of the preexisting SSA nodes (other than the old CPS Phi nodes) into SSA
        //   form by replacing as follows:
        //
        //   - MovHint has KillLocal prepended to it.
        //
        //   - GetLocal over captured variables lose their phis and become GetStack.
        //
        //   - GetLocal over uncaptured variables die and get replaced with references to the node
        //     specified by valueForOperand.
        //
        //   - SetLocal turns into PutStack if it's flushed, or turns into a Check otherwise.
        //
        //   - Flush loses its children and turns into a Phantom.
        //
        //   - PhantomLocal becomes Phantom, and its child is whatever is specified by
        //     valueForOperand.
        //
        //   - SetArgument is removed. Note that GetStack nodes have already been inserted.
        Operands<Node*> valueForOperand(OperandsLike, m_graph.block(0)->variablesAtHead);
        for (BasicBlock* block : m_graph.blocksInPreOrder()) {
            valueForOperand.clear();
            
            // CPS will claim that the root block has all arguments live. But we have already done
            // the first step of SSA conversion: argument locals are no longer live at head;
            // instead we have GetStack nodes for extracting the values of arguments. So, we
            // skip the at-head available value calculation for the root block.
            if (block != m_graph.block(0)) {
                for (size_t i = valueForOperand.size(); i--;) {
                    Node* nodeAtHead = block->variablesAtHead[i];
                    if (!nodeAtHead)
                        continue;
                    
                    VariableAccessData* variable = nodeAtHead->variableAccessData();
                    if (variable->isCaptured())
                        continue;
                    
                    if (verbose)
                        dataLog("Considering live variable ", VariableAccessDataDump(m_graph, variable), " at head of block ", *block, "\n");
                    
                    SSACalculator::Variable* ssaVariable = m_ssaVariableForVariable.get(variable);
                    SSACalculator::Def* def = m_calculator.reachingDefAtHead(block, ssaVariable);
                    if (!def) {
                        // If we are required to insert a Phi, then we won't have a reaching def
                        // at head.
                        continue;
                    }
                    
                    Node* node = def->value();
                    if (node->replacement) {
                        // This will occur when a SetLocal had a GetLocal as its source. The
                        // GetLocal would get replaced with an actual SSA value by the time we get
                        // here. Note that the SSA value with which the GetLocal got replaced
                        // would not in turn have a replacement.
                        node = node->replacement;
                        ASSERT(!node->replacement);
                    }
                    if (verbose)
                        dataLog("Mapping: ", VirtualRegister(valueForOperand.operandForIndex(i)), " -> ", node, "\n");
                    valueForOperand[i] = node;
                }
            }
            
            // Insert Phis by asking the calculator what phis there are in this block. Also update
            // valueForOperand with those Phis. For Phis associated with variables that are not
            // flushed, we also insert a MovHint.
            size_t phiInsertionPoint = 0;
            for (SSACalculator::Def* phiDef : m_calculator.phisForBlock(block)) {
                VariableAccessData* variable = m_variableForSSAIndex[phiDef->variable()->index()];
                
                m_insertionSet.insert(phiInsertionPoint, phiDef->value());
                valueForOperand.operand(variable->local()) = phiDef->value();
                
                m_insertionSet.insertNode(
                    phiInsertionPoint, SpecNone, MovHint, NodeOrigin(),
                    OpInfo(variable->local().offset()), phiDef->value()->defaultEdge());
            }
            
            for (unsigned nodeIndex = 0; nodeIndex < block->size(); ++nodeIndex) {
                Node* node = block->at(nodeIndex);
                
                if (verbose) {
                    dataLog("Processing node ", node, ":\n");
                    m_graph.dump(WTF::dataFile(), "    ", node);
                }
                
                m_graph.performSubstitution(node);
                
                switch (node->op()) {
                case MovHint: {
                    m_insertionSet.insertNode(
                        nodeIndex, SpecNone, KillStack, node->origin,
                        OpInfo(node->unlinkedLocal().offset()));
                    break;
                }
                    
                case SetLocal: {
                    VariableAccessData* variable = node->variableAccessData();
                    
                    if (variable->isCaptured() || !!(node->flags() & NodeIsFlushed)) {
                        node->convertToPutStack(
                            m_graph.m_stackAccessData.add(
                                variable->local(), variable->flushFormat()));
                    } else
                        node->setOpAndDefaultFlags(Check);
                    
                    if (!variable->isCaptured()) {
                        if (verbose)
                            dataLog("Mapping: ", variable->local(), " -> ", node->child1().node(), "\n");
                        valueForOperand.operand(variable->local()) = node->child1().node();
                    }
                    break;
                }
                    
                case GetStack: {
                    ASSERT(m_argumentGetters.contains(node));
                    valueForOperand.operand(node->stackAccessData()->local) = node;
                    break;
                }
                    
                case GetLocal: {
                    VariableAccessData* variable = node->variableAccessData();
                    node->children.reset();
                    
                    if (variable->isCaptured()) {
                        node->convertToGetStack(m_graph.m_stackAccessData.add(variable->local(), variable->flushFormat()));
                        break;
                    }
                    
                    node->convertToPhantom();
                    if (verbose)
                        dataLog("Replacing node ", node, " with ", valueForOperand.operand(variable->local()), "\n");
                    node->replacement = valueForOperand.operand(variable->local());
                    break;
                }
                    
                case Flush: {
                    node->children.reset();
                    node->convertToPhantom();
                    break;
                }
                    
                case PhantomLocal: {
                    ASSERT(node->child1().useKind() == UntypedUse);
                    VariableAccessData* variable = node->variableAccessData();
                    if (variable->isCaptured()) {
                        // This is a fun case. We could have a captured variable that had some
                        // or all of its uses strength reduced to phantoms rather than flushes.
                        // SSA conversion will currently still treat it as flushed, in the sense
                        // that it will just keep the SetLocal. Therefore, there is nothing that
                        // needs to be done here: we don't need to also keep the source value
                        // alive. And even if we did want to keep the source value alive, we
                        // wouldn't be able to, because the variablesAtHead value for a captured
                        // local wouldn't have been computed by the Phi reduction algorithm
                        // above.
                        node->children.reset();
                    } else
                        node->child1() = valueForOperand.operand(variable->local())->defaultEdge();
                    node->convertToPhantom();
                    break;
                }
                    
                case SetArgument: {
                    node->convertToPhantom();
                    break;
                }
                    
                default:
                    break;
                }
            }
            
            // We want to insert Upsilons just before the end of the block. On the surface this
            // seems dangerous because the Upsilon will have a checking UseKind. But, we will not
            // actually be performing the check at the point of the Upsilon; the check will
            // already have been performed at the point where the original SetLocal was.
            size_t upsilonInsertionPoint = block->size() - 1;
            NodeOrigin upsilonOrigin = block->last()->origin;
            for (unsigned successorIndex = block->numSuccessors(); successorIndex--;) {
                BasicBlock* successorBlock = block->successor(successorIndex);
                for (SSACalculator::Def* phiDef : m_calculator.phisForBlock(successorBlock)) {
                    Node* phiNode = phiDef->value();
                    SSACalculator::Variable* ssaVariable = phiDef->variable();
                    VariableAccessData* variable = m_variableForSSAIndex[ssaVariable->index()];
                    FlushFormat format = variable->flushFormat();
                    UseKind useKind = useKindFor(format);
                    
                    m_insertionSet.insertNode(
                        upsilonInsertionPoint, SpecNone, Upsilon, upsilonOrigin,
                        OpInfo(phiNode), Edge(
                            valueForOperand.operand(variable->local()),
                            useKind));
                }
            }
            
            m_insertionSet.execute(block);
        }
        
        // Free all CPS phis and reset variables vectors.
        for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
            BasicBlock* block = m_graph.block(blockIndex);
            if (!block)
                continue;
            for (unsigned phiIndex = block->phis.size(); phiIndex--;)
                m_graph.m_allocator.free(block->phis[phiIndex]);
            block->phis.clear();
            block->variablesAtHead.clear();
            block->variablesAtTail.clear();
            block->valuesAtHead.clear();
            block->valuesAtHead.clear();
            block->ssa = std::make_unique<BasicBlock::SSAData>(block);
        }
        
        m_graph.m_argumentFormats.resize(m_graph.m_arguments.size());
        for (unsigned i = m_graph.m_arguments.size(); i--;) {
            FlushFormat format = FlushedJSValue;

            Node* node = m_argumentMapping.get(m_graph.m_arguments[i]);

            // m_argumentMapping.get could return null for a captured local. That's fine. We only
            // track the argument loads of those arguments for which we speculate type. We don't
            // speculate type for captured arguments.
            if (node)
                format = node->stackAccessData()->format;
            
            m_graph.m_argumentFormats[i] = format;
            m_graph.m_arguments[i] = node; // Record the load that loads the arguments for the benefit of exit profiling.
        }
        
        m_graph.m_form = SSA;

        if (verbose) {
            dataLog("Graph after SSA transformation:\n");
            m_graph.dump();
        }

        return true;
    }