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/*
 * Copyright 2011 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.checkState;

import com.google.common.base.Supplier;
import com.google.common.collect.Lists;
import com.google.javascript.jscomp.ReferenceCollectingCallback.Behavior;
import com.google.javascript.rhino.IR;
import com.google.javascript.rhino.Node;
import com.google.javascript.rhino.Token;
import com.google.javascript.rhino.TokenStream;
import java.util.ArrayList;
import java.util.HashMap;
import java.util.HashSet;
import java.util.LinkedHashMap;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Map;
import java.util.Set;

/**
 * Using the infrastructure provided by {@link ReferenceCollectingCallback},
 * identify variables that are only ever assigned to object literals
 * and that are never used in entirety, and expand the objects into
 * individual variables.
 *
 * Based on the InlineVariables pass
 *
 */
class InlineObjectLiterals implements CompilerPass {

  public static final String VAR_PREFIX = "JSCompiler_object_inline_";
  public static final String STRING_KEY_IDENTIFIER = "string_key";

  private final AbstractCompiler compiler;

  private final Supplier safeNameIdSupplier;

  InlineObjectLiterals(
      AbstractCompiler compiler,
      Supplier safeNameIdSupplier) {
    this.compiler = compiler;
    this.safeNameIdSupplier = safeNameIdSupplier;
  }

  @Override
  public void process(Node externs, Node root) {
    ReferenceCollectingCallback callback = new ReferenceCollectingCallback(
        compiler, new InliningBehavior(), new Es6SyntacticScopeCreator(compiler));
    callback.process(externs, root);
  }

  /**
   * Builds up information about nodes in each scope. When exiting the
   * scope, inspects all variables in that scope, and inlines any
   * that we can.
   */
  private class InliningBehavior implements Behavior {

    /**
     * A list of variables that should not be inlined, because their
     * reference information is out of sync with the state of the AST.
     */
    private final Set staleVars = new HashSet<>();

    @Override
    public void afterExitScope(NodeTraversal t, ReferenceMap referenceMap) {
      for (Var v : t.getScope().getVarIterable()) {
        if (isVarInlineForbidden(v)) {
          continue;
        }

        ReferenceCollection referenceInfo = referenceMap.getReferences(v);

        if (isInlinableObject(referenceInfo.references)) {
          // Blacklist the object itself, as well as any other values
          // that it refers to, since they will have been moved around.
          staleVars.add(v);

          Reference init = referenceInfo.getInitializingReference();

          // Split up the object into individual variables if the object
          // is never referenced directly in full.
          splitObject(v, init, referenceInfo);
        }
      }
    }

    /**
     * If there are any variable references in the given node tree,
     * blacklist them to prevent the pass from trying to inline the
     * variable. Any code modifications will have potentially made the
     * ReferenceCollection invalid.
     */
    private void blacklistVarReferencesInTree(Node root, final Scope scope) {
      NodeUtil.visitPreOrder(root, new NodeUtil.Visitor() {
        @Override
        public void visit(Node node) {
          if (node.isName()) {
            staleVars.add(scope.getVar(node.getString()));
          }
        }
      }, NodeUtil.MATCH_NOT_FUNCTION);
    }

    /**
     * Whether the given variable is forbidden from being inlined.
     */
    private boolean isVarInlineForbidden(Var var) {
      // A variable may not be inlined if:
      // 1) The variable is defined in the externs
      // 2) The variable is exported,
      // 3) Don't inline the special RENAME_PROPERTY_FUNCTION_NAME
      // 4) A reference to the variable has been inlined. We're downstream
      //    of the mechanism that creates variable references, so we don't
      //    have a good way to update the reference. Just punt on it.

      // Additionally, exclude global variables for now.

      return var.isGlobal()
          || var.isExtern()
          || compiler.getCodingConvention().isExported(var.name)
          || compiler
              .getCodingConvention()
              .isPropertyRenameFunction(var.nameNode.getQualifiedName())
          || staleVars.contains(var);
    }

    /**
     * Counts the number of direct (full) references to an object.
     * Specifically, we check for references of the following type:
     * 
     *   x;
     *   x.fn();
     * 
*/ private boolean isInlinableObject(List refs) { boolean ret = false; Set validProperties = new HashSet<>(); for (Reference ref : refs) { Node name = ref.getNode(); Node parent = ref.getParent(); Node grandparent = ref.getGrandparent(); // Ignore most indirect references, like x.y (but not x.y(), // since the function referenced by y might reference 'this'). // if (parent.isGetProp()) { checkState(parent.getFirstChild() == name); // A call target may be using the object as a 'this' value. if (grandparent.isCall() && grandparent.getFirstChild() == parent) { return false; } // Deleting a property has different semantics from deleting // a variable, so deleted properties should not be inlined. if (grandparent.isDelProp()) { return false; } // NOTE(nicksantos): This pass's object-splitting algorithm has // a blind spot. It assumes that if a property isn't defined on an // object, then the value is undefined. This is not true, because // Object.prototype can have arbitrary properties on it. // // We short-circuit this problem by bailing out if we see a reference // to a property that isn't defined on the object literal. This // isn't a perfect algorithm, but it should catch most cases. String propName = parent.getLastChild().getString(); if (!validProperties.contains(propName)) { if (NodeUtil.isNameDeclOrSimpleAssignLhs(parent, grandparent)) { validProperties.add(propName); } else { return false; } } continue; } // Only rewrite VAR declarations or simple assignment statements if (!isVarOrAssignExprLhs(name)) { return false; } Node val = ref.getAssignedValue(); if (val == null) { // A var with no assignment. continue; } // We're looking for object literal assignments only. if (!val.isObjectLit()) { return false; } // Make sure that the value is not self-referential. IOW, // disallow things like x = {b: x.a}. // // TODO(dimvar): Only exclude unorderable self-referential // assignments. i.e. x = {a: x.b, b: x.a} is not orderable, // but x = {a: 1, b: x.a} is. // // Also, ES5 getters/setters aren't handled by this pass. for (Node child = val.getFirstChild(); child != null; child = child.getNext()) { if (child.isGetterDef() || child.isSetterDef()) { // ES5 get/set not supported. return false; } // Don't inline computed property names if (child.isComputedProp()) { return false; } validProperties.add(child.getString()); Node childVal = child.getFirstChild(); // Check if childVal is the parent of any of the passed in // references, as that is how self-referential assignments // will happen. for (Reference t : refs) { Node refNode = t.getParent(); while (!NodeUtil.isStatementBlock(refNode)) { if (refNode == childVal) { // There's a self-referential assignment return false; } refNode = refNode.getParent(); } } } // We have found an acceptable object literal assignment. As // long as there are no other assignments that mess things up, // we can inline. ret = true; } return ret; } private boolean isVarOrAssignExprLhs(Node n) { Node parent = n.getParent(); return parent.isVar() || (parent.isAssign() && parent.getFirstChild() == n && parent.getParent().isExprResult()); } /** * Computes a list of ever-referenced keys in the object being * inlined, and returns a mapping of key name -> generated * variable name. */ private Map computeVarList( ReferenceCollection referenceInfo) { Map varmap = new LinkedHashMap<>(); for (Reference ref : referenceInfo.references) { if (ref.isLvalue() || ref.isInitializingDeclaration()) { Node val = ref.getAssignedValue(); if (val != null) { checkState(val.isObjectLit(), val); for (Node child = val.getFirstChild(); child != null; child = child.getNext()) { String varname = child.getString(); if (varmap.containsKey(varname)) { continue; } String var = varname; if (!TokenStream.isJSIdentifier(varname)) { var = STRING_KEY_IDENTIFIER; } var = VAR_PREFIX + var + "_" + safeNameIdSupplier.get(); varmap.put(varname, var); } } } else if (ref.getParent().isVar()) { // This is the var. There is no value. } else { Node getprop = ref.getParent(); checkState(getprop.isGetProp(), getprop); // The key being looked up in the original map. String varname = getprop.getLastChild().getString(); if (varmap.containsKey(varname)) { continue; } String var = VAR_PREFIX + varname + "_" + safeNameIdSupplier.get(); varmap.put(varname, var); } } return varmap; } /** * Populates a map of key names -> initial assigned values. The * object literal these are being pulled from is invalidated as * a result. */ private void fillInitialValues(Reference init, Map initvals) { Node object = init.getAssignedValue(); checkState(object.isObjectLit(), object); for (Node key = object.getFirstChild(); key != null; key = key.getNext()) { initvals.put(key.getString(), key.removeFirstChild()); } } /** * Replaces an assignment like x = {...} with t1=a,t2=b,t3=c,true. * Note that the resulting expression will always evaluate to * true, as would the x = {...} expression. */ private void replaceAssignmentExpression(Var v, Reference ref, Map varmap) { // Compute all of the assignments necessary List nodes = new ArrayList<>(); Node val = ref.getAssignedValue(); blacklistVarReferencesInTree(val, v.scope); checkState(val.isObjectLit(), val); Set all = new LinkedHashSet<>(varmap.keySet()); for (Node key = val.getFirstChild(); key != null; key = key.getNext()) { String var = key.getString(); Node value = key.removeFirstChild(); // TODO(user): Copy type information. nodes.add( IR.assign( IR.name(varmap.get(var)), value)); all.remove(var); } // TODO(user): Better source information. for (String var : all) { nodes.add( IR.assign( IR.name(varmap.get(var)), NodeUtil.newUndefinedNode(null))); } Node replacement; if (nodes.isEmpty()) { replacement = IR.trueNode(); } else { // All assignments evaluate to true, so make sure that the // expr statement evaluates to true in case it matters. nodes.add(IR.trueNode()); // Join these using COMMA. A COMMA node must have 2 children, so we // create a tree. In the tree the first child be the COMMA to match // the parser, otherwise tree equality tests fail. nodes = Lists.reverse(nodes); replacement = new Node(Token.COMMA); Node cur = replacement; int i; for (i = 0; i < nodes.size() - 2; i++) { cur.addChildToFront(nodes.get(i)); Node t = new Node(Token.COMMA); cur.addChildToFront(t); cur = t; } cur.addChildToFront(nodes.get(i)); cur.addChildToFront(nodes.get(i + 1)); } Node replace = ref.getParent(); replacement.useSourceInfoIfMissingFromForTree(replace); if (replace.isVar()) { replace.replaceWith(NodeUtil.newExpr(replacement)); } else { replace.replaceWith(replacement); } } /** * Splits up the object literal into individual variables, and * updates all uses. */ private void splitObject(Var v, Reference init, ReferenceCollection referenceInfo) { // First figure out the FULL set of possible keys, so that they // can all be properly set as necessary. Map varmap = computeVarList(referenceInfo); Map initvals = new HashMap<>(); // Figure out the top-level of the var assign node. If it's a plain // ASSIGN, then there's an EXPR_STATEMENT above it, if it's a // VAR then it should be directly replaced. Node vnode; boolean defined = referenceInfo.isWellDefined() && init.getParent().isVar(); if (defined) { vnode = init.getParent(); fillInitialValues(init, initvals); } else { // Find the beginning of the function body / script. vnode = v.getScope().getClosestHoistScope().getRootNode().getFirstChild(); } checkState(NodeUtil.isStatement(vnode), vnode); for (Map.Entry entry : varmap.entrySet()) { Node val = initvals.get(entry.getKey()); Node newVarNode = NodeUtil.newVarNode(entry.getValue(), val); if (val == null) { // is this right? newVarNode.useSourceInfoIfMissingFromForTree(vnode); } else { blacklistVarReferencesInTree(val, v.scope); } vnode.getParent().addChildBefore(newVarNode, vnode); compiler.reportChangeToEnclosingScope(vnode); } if (defined) { compiler.reportChangeToEnclosingScope(vnode.getParent()); vnode.detach(); } for (Reference ref : referenceInfo.references) { // The init/decl have already been converted. if (defined && ref == init) { continue; } compiler.reportChangeToEnclosingScope(ref.getNode()); if (ref.isLvalue()) { // Assignments have to be handled specially, since they // expand out into multiple assignments. replaceAssignmentExpression(v, ref, varmap); } else if (ref.getParent().isVar()) { // The old variable declaration. It didn't have a // value. Remove it entirely as it should now be unused. ref.getGrandparent().removeChild(ref.getParent()); } else { // Make sure that the reference is a GETPROP as we expect it to be. Node getprop = ref.getParent(); checkState(getprop.isGetProp(), getprop); // The key being looked up in the original map. String var = getprop.getSecondChild().getString(); // If the variable hasn't already been declared, add an empty // declaration near all the other declarations. checkState(varmap.containsKey(var)); // Replace the GETPROP node with a NAME. Node replacement = IR.name(varmap.get(var)); replacement.useSourceInfoIfMissingFrom(getprop); ref.getGrandparent().replaceChild(ref.getParent(), replacement); } } } } }




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