/** * Copyright (c) 2014, Facebook, Inc. * All rights reserved. * * This source code is licensed under the BSD-style license found in the * https://raw.github.com/facebook/regenerator/master/LICENSE file. An * additional grant of patent rights can be found in the PATENTS file in * the same directory. */ "use strict"; import assert from "assert"; import * as t from "babel-types"; import { hoist } from "./hoist"; import { Emitter } from "./emit"; import replaceShorthandObjectMethod from "./replaceShorthandObjectMethod"; import * as util from "./util"; exports.visitor = { Function: { exit: function(path, state) { let node = path.node; if (node.generator) { if (node.async) { // Async generator if (state.opts.asyncGenerators === false) return; } else { // Plain generator if (state.opts.generators === false) return; } } else if (node.async) { // Async function if (state.opts.async === false) return; } else { // Not a generator or async function. return; } // if this is an ObjectMethod, we need to convert it to an ObjectProperty path = replaceShorthandObjectMethod(path); node = path.node; let contextId = path.scope.generateUidIdentifier("context"); let argsId = path.scope.generateUidIdentifier("args"); path.ensureBlock(); let bodyBlockPath = path.get("body"); if (node.async) { bodyBlockPath.traverse(awaitVisitor); } bodyBlockPath.traverse(functionSentVisitor, { context: contextId }); let outerBody = []; let innerBody = []; bodyBlockPath.get("body").forEach(function(childPath) { let node = childPath.node; if (t.isExpressionStatement(node) && t.isStringLiteral(node.expression)) { // Babylon represents directives like "use strict" as elements // of a bodyBlockPath.node.directives array, but they could just // as easily be represented (by other parsers) as traditional // string-literal-valued expression statements, so we need to // handle that here. (#248) outerBody.push(node); } else if (node && node._blockHoist != null) { outerBody.push(node); } else { innerBody.push(node); } }); if (outerBody.length > 0) { // Only replace the inner body if we actually hoisted any statements // to the outer body. bodyBlockPath.node.body = innerBody; } let outerFnExpr = getOuterFnExpr(path); // Note that getOuterFnExpr has the side-effect of ensuring that the // function has a name (so node.id will always be an Identifier), even // if a temporary name has to be synthesized. t.assertIdentifier(node.id); let innerFnId = t.identifier(node.id.name + "$"); // Turn all declarations into vars, and replace the original // declarations with equivalent assignment expressions. let vars = hoist(path); let didRenameArguments = renameArguments(path, argsId); if (didRenameArguments) { vars = vars || t.variableDeclaration("var", []); const argumentIdentifier = t.identifier("arguments"); // we need to do this as otherwise arguments in arrow functions gets hoisted argumentIdentifier._shadowedFunctionLiteral = path; vars.declarations.push(t.variableDeclarator( argsId, argumentIdentifier )); } let emitter = new Emitter(contextId); emitter.explode(path.get("body")); if (vars && vars.declarations.length > 0) { outerBody.push(vars); } let wrapArgs = [ emitter.getContextFunction(innerFnId), // Async functions that are not generators don't care about the // outer function because they don't need it to be marked and don't // inherit from its .prototype. node.generator ? outerFnExpr : t.nullLiteral(), t.thisExpression() ]; let tryLocsList = emitter.getTryLocsList(); if (tryLocsList) { wrapArgs.push(tryLocsList); } let wrapCall = t.callExpression( util.runtimeProperty(node.async ? "async" : "wrap"), wrapArgs ); outerBody.push(t.returnStatement(wrapCall)); node.body = t.blockStatement(outerBody); const oldDirectives = bodyBlockPath.node.directives; if (oldDirectives) { // Babylon represents directives like "use strict" as elements of // a bodyBlockPath.node.directives array. (#248) node.body.directives = oldDirectives; } let wasGeneratorFunction = node.generator; if (wasGeneratorFunction) { node.generator = false; } if (node.async) { node.async = false; } if (wasGeneratorFunction && t.isExpression(node)) { util.replaceWithOrRemove(path, t.callExpression(util.runtimeProperty("mark"), [node])) path.addComment("leading", "#__PURE__"); } // Generators are processed in 'exit' handlers so that regenerator only has to run on // an ES5 AST, but that means traversal will not pick up newly inserted references // to things like 'regeneratorRuntime'. To avoid this, we explicitly requeue. path.requeue(); } } }; // Given a NodePath for a Function, return an Expression node that can be // used to refer reliably to the function object from inside the function. // This expression is essentially a replacement for arguments.callee, with // the key advantage that it works in strict mode. function getOuterFnExpr(funPath) { let node = funPath.node; t.assertFunction(node); if (!node.id) { // Default-exported function declarations, and function expressions may not // have a name to reference, so we explicitly add one. node.id = funPath.scope.parent.generateUidIdentifier("callee"); } if (node.generator && // Non-generator functions don't need to be marked. t.isFunctionDeclaration(node)) { // Return the identifier returned by runtime.mark(). return getMarkedFunctionId(funPath); } return node.id; } const getMarkInfo = require("private").makeAccessor(); function getMarkedFunctionId(funPath) { const node = funPath.node; t.assertIdentifier(node.id); const blockPath = funPath.findParent(function (path) { return path.isProgram() || path.isBlockStatement(); }); if (!blockPath) { return node.id; } const block = blockPath.node; assert.ok(Array.isArray(block.body)); const info = getMarkInfo(block); if (!info.decl) { info.decl = t.variableDeclaration("var", []); blockPath.unshiftContainer("body", info.decl); info.declPath = blockPath.get("body.0"); } assert.strictEqual(info.declPath.node, info.decl); // Get a new unique identifier for our marked variable. const markedId = blockPath.scope.generateUidIdentifier("marked"); const markCallExp = t.callExpression( util.runtimeProperty("mark"), [node.id] ); const index = info.decl.declarations.push( t.variableDeclarator(markedId, markCallExp) ) - 1; const markCallExpPath = info.declPath.get("declarations." + index + ".init"); assert.strictEqual(markCallExpPath.node, markCallExp); markCallExpPath.addComment("leading", "#__PURE__"); return markedId; } function renameArguments(funcPath, argsId) { let state = { didRenameArguments: false, argsId: argsId }; funcPath.traverse(argumentsVisitor, state); // If the traversal replaced any arguments references, then we need to // alias the outer function's arguments binding (be it the implicit // arguments object or some other parameter or variable) to the variable // named by argsId. return state.didRenameArguments; } let argumentsVisitor = { "FunctionExpression|FunctionDeclaration": function(path) { path.skip(); }, Identifier: function(path, state) { if (path.node.name === "arguments" && util.isReference(path)) { util.replaceWithOrRemove(path, state.argsId); state.didRenameArguments = true; } } }; let functionSentVisitor = { MetaProperty(path) { let { node } = path; if (node.meta.name === "function" && node.property.name === "sent") { util.replaceWithOrRemove(path, t.memberExpression(this.context, t.identifier("_sent"))); } } }; let awaitVisitor = { Function: function(path) { path.skip(); // Don't descend into nested function scopes. }, AwaitExpression: function(path) { // Convert await expressions to yield expressions. let argument = path.node.argument; // Transforming `await x` to `yield regeneratorRuntime.awrap(x)` // causes the argument to be wrapped in such a way that the runtime // can distinguish between awaited and merely yielded values. util.replaceWithOrRemove(path, t.yieldExpression( t.callExpression( util.runtimeProperty("awrap"), [argument] ), false )); } };