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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.javascript.jscomp.NodeTraversal.AbstractPostOrderCallback;
import com.google.javascript.jscomp.NodeTraversal.AbstractShallowStatementCallback;
import com.google.javascript.rhino.IR;
import com.google.javascript.rhino.Node;
import java.util.ArrayList;
import java.util.HashSet;
import java.util.List;
import java.util.Set;

/**
 * Finds all references to global symbols and rewrites them to be property accesses to a special
 * object with the same name as the global symbol.
 *
 * 

Given the name of the global object is NS * *

 var a = 1; function b() { return a }
* * becomes * *
 NS.a = 1; NS.b = function b() { return NS.a }
* * This allows splitting code into modules that depend on each other's global symbols, without using * polluting JavaScript's global scope with those symbols. You typically define just a single global * symbol, wrap each module in a function wrapper, and pass the global symbol around, eg, * *
 var uniqueNs = uniqueNs || {}; 
* *
 (function (NS) { ...your module code here... })(uniqueNs); 
* *

This compile step requires rewriteGlobalDeclarationsForTryCatchWrapping to be turned on to * guarantee semantics. * *

For lots of examples, see the unit test. */ final class RescopeGlobalSymbols implements CompilerPass { // Appended to variables names that conflict with globalSymbolNamespace. private static final String DISAMBIGUATION_SUFFIX = "$"; private final AbstractCompiler compiler; private final String globalSymbolNamespace; private final boolean addExtern; private final boolean assumeCrossModuleNames; private final Set crossModuleNames = new HashSet<>(); /** Global identifiers that may be a non-arrow function referencing "this" */ private final Set maybeReferencesThis = new HashSet<>(); private Set externNames; /** * Constructor for the RescopeGlobalSymbols compiler pass. * * @param compiler The JSCompiler, for reporting code changes. * @param globalSymbolNamespace Name of namespace into which all global * symbols are transferred. * @param assumeCrossModuleNames If true, all global symbols will be assumed * cross module boundaries and thus require renaming. */ RescopeGlobalSymbols( AbstractCompiler compiler, String globalSymbolNamespace, boolean assumeCrossModuleNames) { this(compiler, globalSymbolNamespace, true, assumeCrossModuleNames); } /** * Constructor for the RescopeGlobalSymbols compiler pass for use in testing. * * @param compiler The JSCompiler, for reporting code changes. * @param globalSymbolNamespace Name of namespace into which all global * symbols are transferred. * @param addExtern If true, the compiler will consider the * globalSymbolNamespace an extern name. * @param assumeCrossModuleNames If true, all global symbols will be assumed * cross module boundaries and thus require renaming. * VisibleForTesting */ RescopeGlobalSymbols( AbstractCompiler compiler, String globalSymbolNamespace, boolean addExtern, boolean assumeCrossModuleNames) { this.compiler = compiler; this.globalSymbolNamespace = globalSymbolNamespace; this.addExtern = addExtern; this.assumeCrossModuleNames = assumeCrossModuleNames; } private boolean isCrossModuleName(String name) { return assumeCrossModuleNames || crossModuleNames.contains(name) || compiler.getCodingConvention().isExported(name, /* local */ false); } private boolean isExternVar(String varname, NodeTraversal t) { if (varname.isEmpty()) { return false; } Var v = t.getScope().getVar(varname); return v == null || v.isExtern() || (v.getScope().isGlobal() && this.externNames.contains(varname)); } private void addExternForGlobalSymbolNamespace() { Node varNode = IR.var(IR.name(globalSymbolNamespace)); CompilerInput input = compiler.getSynthesizedExternsInput(); input.getAstRoot(compiler).addChildToBack(varNode); compiler.reportChangeToEnclosingScope(varNode); } @Override public void process(Node externs, Node root) { // Collect variables in externs; they can be shadowed by the same names in global scope. this.externNames = NodeUtil.collectExternVariableNames(this.compiler, externs); // Make the name of the globalSymbolNamespace an extern. if (addExtern) { addExternForGlobalSymbolNamespace(); } // Rewrite all references to global symbols to properties of a single symbol: // Turn global named function statements into var assignments. NodeTraversal.traverse( compiler, root, new RewriteGlobalClassFunctionDeclarationsToVarAssignmentsCallback()); // Find global names that are used in more than one module. Those that // are have to be rewritten. List nonMutatingPasses = new ArrayList<>(); nonMutatingPasses.add(new FindCrossModuleNamesCallback()); // And find names that may refer to functions that reference this. nonMutatingPasses.add(new FindNamesReferencingThis()); CombinedCompilerPass.traverse(compiler, root, nonMutatingPasses); // Rewrite all references to be property accesses of the single symbol. RewriteScopeCallback rewriteScope = new RewriteScopeCallback(); NodeTraversal.traverse(compiler, root, rewriteScope); // Remove the var from statements in global scope if the declared names have been rewritten // in the previous pass. NodeTraversal.traverse(compiler, root, new RemoveGlobalVarCallback()); rewriteScope.declareModuleGlobals(); } /** * Rewrites global function and class declarations to var statements + assignment. Ignores * non-global function and class declarations. * *

function test(){}
* * becomes * *
var test = function (){}
* *
class A {}
* * becomes * *
var A = class {}
* * After this traversal, the special case of global class and function statements can be ignored. * *

This is helpful when rewriting simple names to property accesses on the global symbol, since * {@code class A {}} cannot be rewritten directly to {@code class NS.A {}} */ private class RewriteGlobalClassFunctionDeclarationsToVarAssignmentsCallback extends AbstractShallowStatementCallback { @Override public void visit(NodeTraversal t, Node n, Node parent) { if (NodeUtil.isFunctionDeclaration(n) // Since class declarations are block-scoped, only handle them if in the global scope. || (NodeUtil.isClassDeclaration(n) && t.inGlobalScope())) { Node nameNode = NodeUtil.getNameNode(n); String name = nameNode.getString(); // Remove the class or function name. Anonymous classes have an EMPTY node, while anonymous // functions have a NAME node with an empty string. if (n.isClass()) { nameNode.replaceWith(IR.empty().srcref(nameNode)); } else { nameNode.setString(""); compiler.reportChangeToEnclosingScope(nameNode); } Node prev = n.getPrevious(); n.detach(); Node var = NodeUtil.newVarNode(name, n); if (prev == null) { parent.addChildToFront(var); } else { var.insertAfter(prev); } compiler.reportChangeToEnclosingScope(parent); } } } /** * Find all global names that are used in more than one module. The following * compiler transformations can ignore the globals that are not. */ private class FindCrossModuleNamesCallback extends AbstractPostOrderCallback { @Override public void visit(NodeTraversal t, Node n, Node parent) { if (n.isName()) { String name = n.getString(); if ("".equals(name) || crossModuleNames.contains(name)) { return; } Scope s = t.getScope(); Var v = s.getVar(name); if (v == null || !v.isGlobal()) { return; } CompilerInput input = v.getInput(); if (input == null) { // We know nothing. Assume name is used across modules. crossModuleNames.add(name); return; } // Compare the module where the variable is declared to the current // module. If they are different, the variable is used across modules. JSChunk module = input.getChunk(); if (module != t.getChunk()) { crossModuleNames.add(name); } } } } /** * Builds the maybeReferencesThis set of names that may reference a function * that references this. If the function a name references does not reference * this it can be called as a method call where the this value is not the * same as in a normal function call. */ private class FindNamesReferencingThis extends AbstractPostOrderCallback { @Override public void visit(NodeTraversal t, Node n, Node parent) { if (n.isName()) { String name = n.getString(); if (name.isEmpty()) { return; } Node value = null; if (parent.isAssign() && n == parent.getFirstChild()) { value = parent.getLastChild(); } else if (NodeUtil.isNameDeclaration(parent)) { value = n.getFirstChild(); } else if (parent.isFunction()) { value = parent; } if (value == null && !NodeUtil.isLhsByDestructuring(n)) { // If n is assigned in a destructuring pattern, don't bother finding its value and just // assume it may reference this. return; } // We already added this symbol. Done after checks above because those // are comparatively cheap. if (maybeReferencesThis.contains(name)) { return; } Scope s = t.getScope(); Var v = s.getVar(name); if (v == null || !v.isGlobal()) { return; } // If anything but a function is assigned we assume that possibly // a function referencing this is being assigned. Otherwise we // check whether the function assigned is a) an arrow function, which has a // lexically-scoped this, or b) a non-arrow function that does not reference this. if (value == null || !value.isFunction() || NodeUtil.referencesOwnReceiver(value)) { maybeReferencesThis.add(name); } } } } /** * Visits each NAME token and checks whether it refers to a global variable. If yes, rewrites the * name to be a property access on the "globalSymbolNamespace". If the NAME is an extern variable, * it becomes a property access on window. * *

var a = 1, b = 2, c = 3;
* * becomes * *
var NS.a = 1, NS.b = 2, NS.c = 4
* * (The var token is removed in a later traversal.) * *
a + b
* * becomes * *
NS.a + NS.b
* *
a()
* * becomes * *
(0,NS.a)()
* * Notice the special syntax here to preserve the *this* semantics in the function call. * *
var {a: b} = {}
* * becomes * *
var {a: NS.b} = {}
* * (This is invalid syntax, but the VAR token is removed later). */ private class RewriteScopeCallback implements NodeTraversal.Callback { final List preDeclarations = new ArrayList<>(); @Override public boolean shouldTraverse(NodeTraversal t, Node n, Node parent) { if (NodeUtil.isNameDeclaration(n)) { visitNameDeclaration(t, n); } return true; } @Override public void visit(NodeTraversal t, Node n, Node parent) { if (n.isName()) { visitName(t, n, parent); } } private void visitNameDeclaration(NodeTraversal t, Node declaration) { List allLhsNodes = NodeUtil.findLhsNodesInNode(declaration); if (allLhsNodes.isEmpty()) { return; } boolean hasImportantName = false; boolean isGlobalDeclaration = t.getScope().getVar(allLhsNodes.get(0).getString()).isGlobal(); // Check if any names are in the externs or are global and cross module. for (Node lhs : allLhsNodes) { checkState(lhs.isName(), "Unexpected lhs node %s, expected NAME", lhs); if ((isGlobalDeclaration && isCrossModuleName(lhs.getString())) || isExternVar(lhs.getString(), t)) { hasImportantName = true; break; } } if (hasImportantName) { rewriteNameDeclaration(t, declaration, allLhsNodes, isGlobalDeclaration); } } /** * Partially rewrites a declaration as an assignment. * *

In the post traversal, all global, cross-module names and extern name references will * become property accesses. They will then be invalid as the lhs of a declaration, so we need * to convert them to assignments. We also convert any other names or destructuring patterns in * the same declaration to assignments and add an earlier declaration. */ private void rewriteNameDeclaration( NodeTraversal t, Node declaration, List allLhsNodes, boolean isGlobalDeclaration) { // Add predeclarations for variables that are neither global/cross-module names nor externs. CompilerInput input = t.getInput(); for (Node lhs : allLhsNodes) { String name = lhs.getString(); if (!(isGlobalDeclaration && isCrossModuleName(name)) && !isExternVar(name, t)) { preDeclarations.add( new ModuleGlobal(input.getAstRoot(compiler), IR.name(name).srcref(lhs))); } } // Convert all names with an rhs and all destructuring patterns to be assignments. e.g. // VAR // NAME foo // NUMBER 3 // becomes // VAR // ASSIGN // NAME foo // NUMBER 3 for (Node child = declaration.getFirstChild(); child != null; ) { final Node next = child.getNext(); if (child.isName() && child.hasChildren()) { Node assign = IR.assign(child.cloneNode(), child.removeFirstChild()); child.replaceWith(assign); assign.setJSDocInfo(declaration.getJSDocInfo()); } else if (child.isDestructuringLhs()) { if (child.hasOneChild()) { checkState( NodeUtil.isEnhancedFor(declaration.getParent()), "DESTRUCTURING_LHS should have two children: %s", declaration.toStringTree()); // remove the DESTRUCTURING_LHS but leave the actual destructuring pattern child.replaceWith(child.removeFirstChild()); } else { Node assign = IR.assign(child.removeFirstChild(), child.removeFirstChild()); child.replaceWith(assign); assign.setJSDocInfo(declaration.getJSDocInfo()); } } child = next; } compiler.reportChangeToEnclosingScope(declaration); } private void visitName(NodeTraversal t, Node n, Node parent) { String name = n.getString(); // Ignore anonymous functions if (parent.isFunction() && name.isEmpty()) { return; } if (isExternVar(name, t)) { return; } // When the globalSymbolNamespace is used as a local variable name // add suffix to avoid shadowing the namespace. Also add a suffix // if a name starts with the name of the globalSymbolNamespace and // the suffix. Var var = t.getScope().getVar(name); if (!var.isGlobal() && (name.equals(globalSymbolNamespace) || name.startsWith(globalSymbolNamespace + DISAMBIGUATION_SUFFIX))) { n.setString(name + DISAMBIGUATION_SUFFIX); compiler.reportChangeToEnclosingScope(n); } // We only care about global vars. if (!(var.isGlobal() && isCrossModuleName(name))) { return; } replaceSymbol(n, name); } /** Replaces a global cross-module name with an access on the global namespace symbol */ private void replaceSymbol(Node node, String name) { Node parent = node.getParent(); Node replacement = IR.getprop(IR.name(globalSymbolNamespace), name); replacement.srcrefTree(node); node.replaceWith(replacement); compiler.reportChangeToEnclosingScope(replacement); if (parent.isCall() && !maybeReferencesThis.contains(name)) { // Do not write calls like this: (0, _a)() but rather as _.a(). The // this inside the function will be wrong, but it doesn't matter // because the this is never read. parent.putBooleanProp(Node.FREE_CALL, false); } compiler.reportChangeToEnclosingScope(parent); } /** * Adds back declarations for variables that do not cross module boundaries. * Must be called after RemoveGlobalVarCallback. */ void declareModuleGlobals() { for (ModuleGlobal global : preDeclarations) { if (global.root.hasChildren() && global.root.getFirstChild().isVar()) { global.root.getFirstChild().addChildToBack(global.name); } else { global.root.addChildToFront(IR.var(global.name).srcref(global.name)); } compiler.reportChangeToEnclosingScope(global.root); } } /** * Variable that doesn't cross module boundaries. */ private class ModuleGlobal { final Node root; final Node name; ModuleGlobal(Node root, Node name) { this.root = root; this.name = name; } } } /** * Removes every occurrence of var/let/const that declares a global variable. * *

var NS.a = 1, NS.b = 2;
* * becomes * *
NS.a = 1; NS.b = 2;
* *
for (var a = 0, b = 0;;)
* * becomes * *
for (NS.a = 0, NS.b = 0;;)
* * Declarations without assignments are optimized away: * *
var a = 1, b;
* * becomes * *
NS.a = 1
*/ private class RemoveGlobalVarCallback extends AbstractShallowStatementCallback { @Override public void visit(NodeTraversal t, Node n, Node parent) { if (!NodeUtil.isNameDeclaration(n)) { return; } List commas = new ArrayList<>(); List interestingChildren = new ArrayList<>(); // Filter out declarations without assignments. // As opposed to regular var nodes, there are always assignments // because the previous traversal in RewriteScopeCallback creates // them. boolean allNameOrDestructuring = true; for (Node c = n.getFirstChild(); c != null; c = c.getNext()) { if (!c.isName() && !c.isDestructuringLhs()) { allNameOrDestructuring = false; } if (c.isAssign() || NodeUtil.isAnyFor(parent)) { interestingChildren.add(c); } } // If every child of a var declares a name, it must stay in place. // This is the case if none of the declared variables cross module // boundaries. if (allNameOrDestructuring) { return; } for (Node c : interestingChildren) { if (NodeUtil.isAnyFor(parent) && parent.getFirstChild() == n) { commas.add(c.cloneTree()); } else { // Var statement outside of for-loop. Node expr = IR.exprResult(c.cloneTree()).srcref(c); NodeUtil.markNewScopesChanged(expr, compiler); expr.insertBefore(n); } } if (!commas.isEmpty()) { Node comma = joinOnComma(commas, n); comma.insertBefore(n); } // Remove the var/const/let node. n.detach(); NodeUtil.markFunctionsDeleted(n, compiler); compiler.reportChangeToEnclosingScope(parent); } private Node joinOnComma(List commas, Node source) { Node comma = commas.get(0); for (int i = 1; i < commas.size(); i++) { Node nextComma = IR.comma(comma, commas.get(i)); nextComma.srcrefIfMissing(source); comma = nextComma; } return comma; } } }




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