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/*
 * Copyright 2016 The Closure Compiler Authors.
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

package com.google.javascript.jscomp;

import static com.google.common.base.Preconditions.checkArgument;
import static com.google.common.base.Preconditions.checkNotNull;
import static com.google.common.base.Preconditions.checkState;
import static com.google.common.base.Predicates.alwaysTrue;

import com.google.common.collect.Iterators;
import com.google.common.collect.PeekingIterator;
import com.google.common.collect.Sets;
import com.google.javascript.rhino.Node;
import com.google.javascript.rhino.Token;
import java.util.ArrayDeque;
import java.util.Deque;
import java.util.HashMap;
import java.util.HashSet;
import java.util.Map;
import java.util.Objects;
import java.util.Queue;
import java.util.Set;
import javax.annotation.Nullable;

/**
 * An optimization pass that finds and removes dead property assignments within functions and
 * classes.
 *
 * 

This pass does not currently use the control-flow graph. It makes the following assumptions: *

    *
  • Functions with inner functions are not processed.
  • *
  • All properties are read whenever entering a block node. Dead assignments within a block * are processed.
  • *
  • Hook nodes are not processed (it's assumed they read everything)
  • *
  • Switch blocks are not processed (it's assumed they read everything)
  • *
  • Any reference to a property getter/setter is treated like a call that escapes all props.
  • *
  • If there's an Object.definePropert{y,ies} call where the object or property name is aliased * then the optimization does not run at all.
  • *
  • Properties names defined in externs will not be pruned.
  • *
*/ public class DeadPropertyAssignmentElimination implements CompilerPass { private final AbstractCompiler compiler; DeadPropertyAssignmentElimination(AbstractCompiler compiler) { this.compiler = compiler; } @Override public void process(Node externs, Node root) { // GatherExternProperties must be enabled for this pass to safely know what property writes are // eligible for removal. if (compiler.getExternProperties() == null || compiler.getAccessorSummary() == null) { return; } Set skiplistedPropNames = Sets.union( compiler.getAccessorSummary().getAccessors().keySet(), compiler.getExternProperties()); NodeTraversal.traverse( compiler, compiler.getJsRoot(), new FunctionVisitor(skiplistedPropNames)); } private static class FunctionVisitor extends NodeTraversal.AbstractChangedScopeCallback { /** A set of properties names that are potentially unsafe to remove duplicate writes to. */ private final Set skiplistedPropNames; FunctionVisitor(Set skiplistedPropNames) { this.skiplistedPropNames = skiplistedPropNames; } @Override public void enterChangedScopeRoot(AbstractCompiler compiler, Node root) { if (!root.isFunction()) { return; } Node body = NodeUtil.getFunctionBody(root); if (!body.hasChildren() || NodeUtil.has(body, Node::isFunction, alwaysTrue())) { return; } FindCandidateAssignmentTraversal traversal = new FindCandidateAssignmentTraversal(skiplistedPropNames); NodeTraversal.traverse(compiler, body, traversal); // Any candidate property assignment can have a write removed if that write is never read // and it's written to at least one more time. for (Property property : traversal.propertyMap.values()) { if (property.writes.size() <= 1) { continue; } PeekingIterator iter = Iterators.peekingIterator(property.writes.iterator()); while (iter.hasNext()) { PropertyWrite propertyWrite = iter.next(); if (iter.hasNext() && propertyWrite.isSafeToRemove(iter.peek())) { Node lhs = propertyWrite.assignedAt; Node rhs = lhs.getNext(); Node assignNode = lhs.getParent(); if (assignNode.isAssign()) { // replace "a.b.c = " with "" rhs.detach(); assignNode.replaceWith(rhs); compiler.reportChangeToEnclosingScope(rhs); } else { checkState(NodeUtil.isAssignmentOp(assignNode)); // replace "a.b.c += " with "a.b.c + expr" Token opType = NodeUtil.getOpFromAssignmentOp(assignNode); assignNode.setToken(opType); compiler.reportChangeToEnclosingScope(assignNode); } } } } } } private static class Property { private final String name; // This pass doesn't use a control-flow graph; this field contains a rough approximation // of the control flow. For writes in the same block, they appear in this list in // program-execution order. // All writes in a list are to the same property name, but the full qualified names may // differ, eg, a.b.c and e.d.c can be in the list. Consecutive writes to the same qname // may mean that the first write can be removed (see isSafeToRemove). private final Deque writes = new ArrayDeque<>(); private final Set children = new HashSet<>(); Property(String name) { this.name = name; } void markLastWriteRead() { if (!writes.isEmpty()) { writes.getLast().markRead(); } } /** * Marks all children of this property as read. */ void markChildrenRead() { // If a property is in propertiesSet, it has been added to the queue and processed, // it will not be added to the queue again. Set propertiesSet = new HashSet<>(children); Queue propertyQueue = new ArrayDeque<>(propertiesSet); // Ensure we don't process ourselves. propertiesSet.add(this); while (!propertyQueue.isEmpty()) { Property childProperty = propertyQueue.remove(); childProperty.markLastWriteRead(); for (Property grandchildProperty : childProperty.children) { if (propertiesSet.add(grandchildProperty)) { propertyQueue.add(grandchildProperty); } } } } void addWrite(Node lhs) { checkArgument(lhs.isQualifiedName()); writes.addLast(new PropertyWrite(lhs)); } @Override public String toString() { return "Property " + name; } } private static class PropertyWrite { private final Node assignedAt; private boolean isRead = false; private final String qualifiedName; PropertyWrite(Node assignedAt) { checkArgument(assignedAt.isQualifiedName()); this.assignedAt = assignedAt; this.qualifiedName = assignedAt.getQualifiedName(); } boolean isSafeToRemove(@Nullable PropertyWrite nextWrite) { return !isRead && nextWrite != null && Objects.equals(qualifiedName, nextWrite.qualifiedName); } void markRead() { isRead = true; } } /** * A NodeTraversal that operates within a function block and collects candidate properties * assignments. */ private static class FindCandidateAssignmentTraversal implements NodeTraversal.Callback { /** * A map of property names to their nodes. * *

Note: the references {@code a.b} and {@code c.b} will assume that it's the same b, because * a and c may be aliased, and we don't track aliasing. */ final Map propertyMap = new HashMap<>(); /** A set of properties names that are potentially unsafe to remove duplicate writes to. */ private final Set skiplistedPropNames; FindCandidateAssignmentTraversal(Set skiplistedPropNames) { this.skiplistedPropNames = skiplistedPropNames; } /** * Gets a {@link Property} given the node that references it; the {@link Property} is created * if it does not already exist. * * @return A {@link Property}, or null if the provided node is not a qualified name. */ private Property getOrCreateProperty(Node propNode) { if (!propNode.isQualifiedName()) { return null; } String propName = propNode.isGetProp() ? propNode.getString() : propNode.getQualifiedName(); Property property = propertyMap.computeIfAbsent(propName, Property::new); /* Using the GETPROP chain, build out the tree of children properties. For example, from a.b.c and a.c we can build: a / \ b c / c Note: c is the same Property in this tree. */ if (propNode.isGetProp()) { Property parentProperty = getOrCreateProperty(propNode.getFirstChild()); if (parentProperty != null) { parentProperty.children.add(property); } } return property; } @Override public boolean shouldTraverse(NodeTraversal nodeTraversal, Node n, Node parent) { return visitNode(n, parent); } @Override public void visit(NodeTraversal t, Node n, Node parent) { // Visit the LHS of an assignment in post-order if (NodeUtil.isAssignmentOp(n)) { visitAssignmentLhs(n.getFirstChild()); } // Assume that all properties may be read when control flow leaves the function if (NodeUtil.isInvocation(n) || n.isYield() || n.isAwait()) { markAllPropsRead(); } // Mark all properties as read when leaving a block since we haven't proven that the block // will execute. if (n.isBlock()) { visitBlock(n); } } private void visitBlock(Node blockNode) { checkArgument(blockNode.isBlock()); // We don't do flow analysis yet so we're going to assume everything written up to this // block is read. if (blockNode.hasChildren()) { markAllPropsRead(); } } private static boolean isConditionalExpression(Node n) { switch (n.getToken()) { case AND: case OR: case HOOK: case COALESCE: case OPTCHAIN_CALL: case OPTCHAIN_GETELEM: case OPTCHAIN_GETPROP: return true; default: return false; } } private void visitAssignmentLhs(Node lhs) { Property property = getOrCreateProperty(lhs); if (property == null) { return; } if (!lhs.isGetProp()) { property.markLastWriteRead(); property.markChildrenRead(); return; } Node assignNode = lhs.getParent(); // If it's mutating assignment (+=, *=, etc.) then mark the last assignment read first. if (!assignNode.isAssign()) { property.markLastWriteRead(); } // Reassignment of a qualified name prefix might change what child properties are referenced // later on, so consider children properties as read. // Ex. a.b.c = 10; a.b = other; a.b.c = 20; property.markChildrenRead(); property.addWrite(lhs); // Now we need to go up the prop chain and mark those as read. Node child = lhs.getFirstChild(); while (child != null) { Property childProperty = getOrCreateProperty(child); if (childProperty == null) { break; } childProperty.markLastWriteRead(); child = child.getFirstChild(); } } private boolean visitNode(Node n, Node parent) { switch (n.getToken()) { case GETPROP: // Handle potential getters/setters. if (n.isGetProp() && skiplistedPropNames.contains(n.getString())) { // We treat getters/setters as if they were a call, thus we mark all properties as read. markAllPropsRead(); return true; } if (NodeUtil.isAssignmentOp(parent) && parent.getFirstChild() == n) { // This is a write to the property, so skip the read handling below. // We'll handle this write in the visit() method // We need to continue traversing, because there could be a function call // child. return true; } Property property = getOrCreateProperty(n); if (property != null) { // Mark all children properties as read. property.markLastWriteRead(); // Only mark children properties as read if we're at the end of the referenced // property chain. // Ex. A read of "a.b.c" should mark a, a.b, a.b.c, and a.b.c.* as read, but not a.d if (!parent.isGetProp()) { property.markChildrenRead(); } } return true; case THIS: case NAME: Property nameProp = checkNotNull(getOrCreateProperty(n)); nameProp.markLastWriteRead(); if (!parent.isGetProp()) { nameProp.markChildrenRead(); } return true; case THROW: case FOR: case FOR_IN: case SWITCH: // TODO(kevinoconnor): Switch/for statements need special consideration since they may // execute out of order. markAllPropsRead(); return false; case BLOCK: visitBlock(n); return true; default: if (isConditionalExpression(n)) { markAllPropsRead(); return false; } return true; } } private void markAllPropsRead() { for (Property property : propertyMap.values()) { if (property.writes.isEmpty()) { continue; } property.markLastWriteRead(); } } } }





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