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Closure Compiler is a JavaScript optimizing compiler. It parses your JavaScript, analyzes it, removes dead code and rewrites and minimizes what's left. It also checks syntax, variable references, and types, and warns about common JavaScript pitfalls. It is used in many of Google's JavaScript apps, including Gmail, Google Web Search, Google Maps, and Google Docs. This binary checks for style issues such as incorrect or missing JSDoc usage, and missing goog.require() statements. It does not do more advanced checks such as typechecking.

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/*
 * Copyright 2008 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.checkNotNull;

import com.google.javascript.jscomp.type.FlowScope;
import com.google.javascript.rhino.HamtPMap;
import com.google.javascript.rhino.JSDocInfo;
import com.google.javascript.rhino.Node;
import com.google.javascript.rhino.PMap;
import com.google.javascript.rhino.jstype.JSType;
import com.google.javascript.rhino.jstype.StaticTypedRef;
import com.google.javascript.rhino.jstype.StaticTypedScope;
import com.google.javascript.rhino.jstype.StaticTypedSlot;

/**
 * A flow scope that tries to store as little symbol information as possible,
 * instead delegating to its parents. Optimized for low memory use.
 */
class LinkedFlowScope implements FlowScope {

  private final CompilerInputProvider inputProvider;

  // Map from TypedScope to OverlayScope.
  private final PMap scopes;

  private final TypedScope functionScope;

  // The TypedScope for the block that this flow scope is defined for.
  private final TypedScope syntacticScope;

  /**
   * Creates a flow scope without a direct parent. This can happen in three cases: (1) the "bottom"
   * scope for a CFG root, (2) a direct child of a parent at the maximum depth, or (3) a joined
   * scope with more than one direct parent. The parent is non-null only in the second case.
   */
  private LinkedFlowScope(
      CompilerInputProvider inputProvider,
      PMap scopes,
      TypedScope syntacticScope,
      TypedScope functionScope) {
    this.inputProvider = inputProvider;
    this.scopes = scopes;
    this.syntacticScope = syntacticScope;
    this.functionScope = functionScope;
  }

  /**
   * Returns the scope map, trimmed to the common ancestor between this FlowScope's syntacticScope
   * and the given scope. Any inferred types on variables in deeper scopes cannot be propagated past
   * this point (since they're no longer in scope), and trimming them eagerly allows us to ignore
   * these irrelevant types when checking equality and joining.
   */
  private PMap trimScopes(TypedScope scope) {
    TypedScope thisScope = syntacticScope;
    TypedScope thatScope = scope;
    int thisDepth = thisScope.getDepth();
    int thatDepth = thatScope.getDepth();
    PMap result = scopes;
    while (thatDepth > thisDepth) {
      thatScope = thatScope.getParent();
      thatDepth--;
    }
    while (thisDepth > thatDepth) {
      result = result.minus(thisScope);
      thisScope = thisScope.getParent();
      thisDepth--;
    }
    while (thisScope != thatScope && thisScope != null && thatScope != null) {
      result = result.minus(thisScope);
      thisScope = thisScope.getParent();
      thatScope = thatScope.getParent();
    }
    return result;
  }

  /** Whether this flows from a bottom scope. */
  private boolean flowsFromBottom() {
    return functionScope.isBottom();
  }

  /** Creates an entry lattice for the flow. */
  public static LinkedFlowScope createEntryLattice(
      CompilerInputProvider inputProvider, TypedScope scope) {
    return new LinkedFlowScope(
        inputProvider, HamtPMap.empty(), scope, scope);
  }

  @Override
  public LinkedFlowScope inferSlotType(String symbol, JSType type) {
    OverlayScope scope = getOverlayScopeForName(symbol, true);
    OverlayScope newScope = scope.infer(symbol, type);
    // Aggressively remove empty scopes to maintain a reasonable equivalence.
    PMap newScopes =
        !newScope.slots.isEmpty() ? scopes.plus(scope.scope, newScope) : scopes.minus(scope.scope);
    return newScopes != scopes
        ? new LinkedFlowScope(inputProvider, newScopes, syntacticScope, functionScope)
        : this;
  }

  @Override
  public LinkedFlowScope inferQualifiedSlot(
      Node node, String symbol, JSType bottomType, JSType inferredType, boolean declared) {
    if (functionScope.isGlobal()) {
      // Do not infer qualified names on the global scope.  Ideally these would be
      // added to the scope by TypedScopeCreator, but if they are not, adding them
      // here causes scaling problems (large projects can have tens of thousands of
      // undeclared qualified names in the global scope) with no real benefit.
      return this;
    }
    TypedVar v = syntacticScope.getVar(symbol);
    if (v == null && !functionScope.isBottom()) {
      // NOTE(sdh): Qualified names are declared on scopes lazily via this method.
      // The difficulty is that it's not always clear which scope they need to be
      // defined on.  In particular, syntacticScope is wrong because it is often a
      // nested block scope that is ignored when branches are joined; functionScope
      // is also wrong because it could lead to ambiguity if the same root name is
      // declared in multiple different blocks.  Instead, the qualified name is declared
      // on the scope that owns the root, when possible. When the root is undeclared, the qualified
      // name is declared in the global scope, as only global variables can be undeclared.
      TypedVar rootVar = syntacticScope.getVar(getRootOfQualifiedName(symbol));
      TypedScope rootScope = rootVar != null ? rootVar.getScope() : syntacticScope.getGlobalScope();
      v =
          rootScope.declare(
              symbol,
              node,
              bottomType,
              inputProvider.getInput(NodeUtil.getInputId(node)),
              !declared);
    }

    JSType declaredType = v != null ? v.getType() : null;
    if (v != null) {
      if (!v.isTypeInferred()) {
        // Use the inferred type over the declared type only if the
        // inferred type is a strict subtype of the declared type.
        if (declaredType == null
            || !inferredType.isSubtypeOf(declaredType)
            || declaredType.isSubtypeOf(inferredType)
            || inferredType.equals(declaredType)) {
          return this;
        }
      } else if (declaredType != null && !inferredType.isSubtypeOf(declaredType)) {
        // If this inferred type is incompatible with another type previously
        // inferred and stored on the scope, then update the scope.
        v.setType(v.getType().getLeastSupertype(inferredType));
      }
    }
    return inferSlotType(symbol, inferredType);
  }

  @Override
  public JSType getTypeOfThis() {
    return functionScope.getTypeOfThis();
  }

  @Override
  public Node getRootNode() {
    return syntacticScope.getRootNode();
  }

  @Override
  public StaticTypedScope getParentScope() {
    throw new UnsupportedOperationException();
  }

  /** Get the slot for the given symbol. */
  @Override
  public StaticTypedSlot getSlot(String name) {
    TypedVar var = syntacticScope.getVar(name);
    OverlayScope scope =
        var == null
            ? getOverlayScopeForName(name, false)
            : getOverlayScopeForScope(var.getScope(), false);

    return scope != null ? scope.getSlot(name) : var;
  }

  private static String getRootOfQualifiedName(String name) {
    int index = name.indexOf('.');
    return index < 0 ? name : name.substring(0, index);
  }

  /**
   * Returns the overlay scope corresponding to this qualified name
   *
   * @param create whether to create a new OverlayScope if one does not already exist.
   */
  private OverlayScope getOverlayScopeForName(String name, boolean create) {
    TypedVar rootVar = syntacticScope.getVar(getRootOfQualifiedName(name));
    TypedScope scope = rootVar != null ? rootVar.getScope() : null;
    scope = scope != null ? scope : functionScope;
    return getOverlayScopeForScope(scope, create);
  }

  /**
   * Returns the overlay scope corresponding to this syntactic scope.
   *
   * 

Use instead of {@link #getOverlayScopeForName(String, boolean)} if you already know the * correct scope in order to avoid a variable lookup. * * @param scope the syntactic scope * @param create whether to create a new OverlayScope if one does not already exist. */ private OverlayScope getOverlayScopeForScope(TypedScope scope, boolean create) { OverlayScope overlay = scopes.get(scope); if (overlay == null && create) { overlay = new OverlayScope(scope); } return overlay; } @Override public StaticTypedSlot getOwnSlot(String name) { throw new UnsupportedOperationException(); } @Override public FlowScope withSyntacticScope(StaticTypedScope scope) { TypedScope typedScope = (TypedScope) scope; return scope != syntacticScope ? new LinkedFlowScope(inputProvider, trimScopes(typedScope), typedScope, functionScope) : this; } @Override public TypedScope getDeclarationScope() { return syntacticScope; } /** Join the two FlowScopes. */ static class FlowScopeJoinOp extends JoinOp.BinaryJoinOp { final CompilerInputProvider inputProvider; FlowScopeJoinOp(CompilerInputProvider inputProvider) { this.inputProvider = inputProvider; } // NOTE(sdh): When joining flow scopes with different syntactic scopes, // we do not attempt to recover the correct syntactic scope. This is // okay because joins only occur in two situations: (1) performed by // the DataFlowAnalysis class automatically between CFG nodes, and (2) // requested manually while traversing a single expression within a CFG // node. The syntactic scope is always set at the beginning of flowing // through a CFG node. In the case of (1), the join result's syntactic // scope is immediately replaced with the correct one when we flow through // the next node. In the case of (2), both inputs will always have the // same syntactic scope. So simply propagating either input's scope is // perfectly fine. @Override public FlowScope apply(FlowScope a, FlowScope b) { // To join the two scopes, we have to LinkedFlowScope linkedA = (LinkedFlowScope) a; LinkedFlowScope linkedB = (LinkedFlowScope) b; if (linkedA.scopes == linkedB.scopes && linkedA.functionScope == linkedB.functionScope) { return linkedA; } // NOTE: it would be nice to put 'null' as the syntactic scope if they're not // equal, but this is not currently feasible. For joins that occur within a // single CFG node's flow, it's irrelevant, but for joins between separate // CFG nodes, there is *one* place where the syntactic scope is actually used: // when joining more than two scopes, the first two scopes are joined, and // then the join result is joined with the third. When joining, we look up // the types (and existence) of vars in one scope in the other; so when a var // from the third scope (say, a local) is missing from the join result, it // looks through the syntactic scope before realizing this. A quick fix // might be to just check that the scope is non-null before trying to join; // a better long-term fix would be to improve how we do joins to avoid // excessive map entry creation: find a common ancestor, etc. One // interesting consequence of the current approach is that we may end up // adding irrelevant block-local variables to the joined scope unnecessarily. TypedScope common = getCommonParentDeclarationScope(linkedA, linkedB); return new LinkedFlowScope( inputProvider, join(linkedA, linkedB, common), common, linkedA.flowsFromBottom() ? linkedB.functionScope : linkedA.functionScope); } } static TypedScope getCommonParentDeclarationScope(LinkedFlowScope left, LinkedFlowScope right) { if (left.flowsFromBottom()) { return right.syntacticScope; } else if (right.flowsFromBottom()) { return left.syntacticScope; } return left.syntacticScope.getCommonParent(right.syntacticScope); } @Override public boolean equals(Object other) { if (!(other instanceof LinkedFlowScope)) { return false; } LinkedFlowScope that = (LinkedFlowScope) other; // If two flow scopes are in the same function, then they could have // two possible function scopes: the real one and the BOTTOM scope. // If they have different function scopes, we *should* iterate through all // the variables in each scope and compare. However, 99.9% of the time, // they're not equal. And the other .1% of the time, we can pretend // they're equal--this just means that data flow analysis will have // to propagate the entry lattice a little bit further than it // really needs to. Everything will still come out ok. return this.functionScope == that.functionScope && this.scopes.equivalent(that.scopes, LinkedFlowScope::equalScopes); } private static boolean equalScopes(OverlayScope left, OverlayScope right) { if (left == right) { return true; } return left.slots.equivalent(right.slots, LinkedFlowScope::equalSlots); } /** * Determines whether two slots are meaningfully different for the purposes of data flow analysis. */ private static boolean equalSlots(StaticTypedSlot slotA, StaticTypedSlot slotB) { return slotA == slotB || !slotA.getType().differsFrom(slotB.getType()); } @Override public int hashCode() { throw new UnsupportedOperationException(); } @SuppressWarnings("ReferenceEquality") // JSType comparisons are expensive, so just use identity. private static PMap join( LinkedFlowScope linkedA, LinkedFlowScope linkedB, TypedScope commonParent) { return linkedA .trimScopes(commonParent) .reconcile( linkedB.trimScopes(commonParent), (scopeKey, scopeA, scopeB) -> { PMap slotsA = scopeA != null ? scopeA.slots : EMPTY_SLOTS; PMap slotsB = scopeB != null ? scopeB.slots : EMPTY_SLOTS; // TODO(sdh): Simplify this logic: we want the best non-bottom scope we can get, // for the purpose of (a) passing to the joined OverlayScope constructor, and // (b) joining types only present in one scope. TypedScope typedScopeA = linkedA.flowsFromBottom() ? null : scopeA != null ? scopeA.scope : scopeB.scope; TypedScope typedScopeB = linkedB.flowsFromBottom() ? null : scopeB != null ? scopeB.scope : scopeA.scope; TypedScope bestScope = typedScopeA != null ? typedScopeA : typedScopeB; bestScope = bestScope != null ? bestScope : scopeA != null ? scopeA.scope : scopeB.scope; return new OverlayScope( bestScope, slotsA.reconcile( slotsB, (slotKey, slotA, slotB) -> { // There are 5 different join cases: // 1) The type is present in joinedScopeA, not in joinedScopeB, // and not in functionScope. Just use the one in A. // 2) The type is present in joinedScopeB, not in joinedScopeA, // and not in functionScope. Just use the one in B. // 3) The type is present in functionScope and joinedScopeA, but // not in joinedScopeB. Join the two types. // 4) The type is present in functionScope and joinedScopeB, but // not in joinedScopeA. Join the two types. // 5) The type is present in joinedScopeA and joinedScopeB. Join // the two types. String name = slotA != null ? slotA.getName() : slotB.getName(); if (slotB == null || slotB.getType() == null) { TypedVar fnSlot = typedScopeB != null ? typedScopeB.getSlot(name) : null; JSType fnSlotType = fnSlot != null ? fnSlot.getType() : null; if (fnSlotType != null && fnSlotType != slotA.getType()) { // Case #3 JSType joinedType = slotA.getType().getLeastSupertype(fnSlotType); return joinedType != slotA.getType() ? new OverlaySlot(name, joinedType) : slotA; } else { // Case #1 return slotA; } } else if (slotA == null || slotA.getType() == null) { TypedVar fnSlot = typedScopeA != null ? typedScopeA.getSlot(name) : null; JSType fnSlotType = fnSlot != null ? fnSlot.getType() : null; if (fnSlotType != null && fnSlotType != slotB.getType()) { // Case #4 JSType joinedType = slotB.getType().getLeastSupertype(fnSlotType); return joinedType != slotB.getType() ? new OverlaySlot(name, joinedType) : slotB; } else { // Case #2 return slotB; } } // Case #5 if (slotA.getType() == slotB.getType()) { return slotA; } JSType joinedType = slotA.getType().getLeastSupertype(slotB.getType()); return joinedType != slotA.getType() ? new OverlaySlot(name, joinedType) : slotA; })); }); } private static class OverlayScope { final TypedScope scope; final PMap slots; OverlayScope(TypedScope scope) { this.scope = checkNotNull(scope); this.slots = EMPTY_SLOTS; } OverlayScope(TypedScope scope, PMap slots) { this.scope = checkNotNull(scope); this.slots = slots; } @SuppressWarnings("ReferenceEquality") // JSType#equals is expensive, so use identity. OverlayScope infer(String name, JSType type) { // TODO(sdh): variants that do or don't clobber properties (i.e. look up and modify instead) OverlaySlot slot = slots.get(name); if (slot != null && type == slot.type) { return this; } return new OverlayScope(scope, slots.plus(name, new OverlaySlot(name, type))); } StaticTypedSlot getSlot(String name) { OverlaySlot slot = slots.get(name); return slot != null ? slot : scope.getSlot(name); } } private static class OverlaySlot implements StaticTypedSlot { // TODO(sdh): add a final PMap for properties final String name; final JSType type; OverlaySlot(String name, JSType type) { this.name = name; this.type = type; } @Override public String getName() { return name; } @Override public JSType getType() { return type; } @Override public boolean isTypeInferred() { return true; } @Override public StaticTypedRef getDeclaration() { return null; } @Override public JSDocInfo getJSDocInfo() { return null; } @Override public StaticTypedScope getScope() { throw new UnsupportedOperationException(); } } private static final PMap EMPTY_SLOTS = HamtPMap.empty(); }





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