// @flow // A recursive descent parser operates by defining functions for all // syntactic elements, and recursively calling those, each function // advancing the input stream and returning an AST node. Precedence // of constructs (for example, the fact that `!x[1]` means `!(x[1])` // instead of `(!x)[1]` is handled by the fact that the parser // function that parses unary prefix operators is called first, and // in turn calls the function that parses `[]` subscripts — that // way, it'll receive the node for `x[1]` already parsed, and wraps // *that* in the unary operator node. // // Acorn uses an [operator precedence parser][opp] to handle binary // operator precedence, because it is much more compact than using // the technique outlined above, which uses different, nesting // functions to specify precedence, for all of the ten binary // precedence levels that JavaScript defines. // // [opp]: http://en.wikipedia.org/wiki/Operator-precedence_parser import { types as tt, type TokenType } from "../tokenizer/types"; import { types as ct } from "../tokenizer/context"; import * as N from "../types"; import LValParser from "./lval"; import { isKeyword, isReservedWord, isStrictReservedWord, isStrictBindReservedWord, isIdentifierStart, } from "../util/identifier"; import type { Pos, Position } from "../util/location"; import * as charCodes from "charcodes"; import { BIND_OUTSIDE, BIND_VAR, SCOPE_ARROW, SCOPE_CLASS, SCOPE_DIRECT_SUPER, SCOPE_FUNCTION, SCOPE_SUPER, SCOPE_PROGRAM, } from "../util/scopeflags"; import { ExpressionErrors } from "./util"; import { PARAM_AWAIT, PARAM_RETURN, PARAM, functionFlags, } from "../util/production-parameter"; import { Errors } from "./error"; export default class ExpressionParser extends LValParser { // Forward-declaration: defined in statement.js /*:: +parseBlock: ( allowDirectives?: boolean, createNewLexicalScope?: boolean, afterBlockParse?: (hasStrictModeDirective: boolean) => void, ) => N.BlockStatement; +parseClass: ( node: N.Class, isStatement: boolean, optionalId?: boolean, ) => N.Class; +parseDecorators: (allowExport?: boolean) => void; +parseFunction: ( node: T, statement?: number, allowExpressionBody?: boolean, isAsync?: boolean, ) => T; +parseFunctionParams: (node: N.Function, allowModifiers?: boolean) => void; +takeDecorators: (node: N.HasDecorators) => void; */ // For object literal, check if property __proto__ has been used more than once. // If the expression is a destructuring assignment, then __proto__ may appear // multiple times. Otherwise, __proto__ is a duplicated key. // For record expression, check if property __proto__ exists checkProto( prop: N.ObjectMember | N.SpreadElement, isRecord: boolean, protoRef: { used: boolean }, refExpressionErrors: ?ExpressionErrors, ): void { if ( prop.type === "SpreadElement" || prop.type === "ObjectMethod" || prop.computed || // $FlowIgnore prop.shorthand ) { return; } const key = prop.key; // It is either an Identifier or a String/NumericLiteral const name = key.type === "Identifier" ? key.name : key.value; if (name === "__proto__") { if (isRecord) { this.raise(key.start, Errors.RecordNoProto); return; } if (protoRef.used) { if (refExpressionErrors) { // Store the first redefinition's position, otherwise ignore because // we are parsing ambiguous pattern if (refExpressionErrors.doubleProto === -1) { refExpressionErrors.doubleProto = key.start; } } else { this.raise(key.start, Errors.DuplicateProto); } } protoRef.used = true; } } // Convenience method to parse an Expression only getExpression(): N.Expression { let paramFlags = PARAM; if (this.hasPlugin("topLevelAwait") && this.inModule) { paramFlags |= PARAM_AWAIT; } this.scope.enter(SCOPE_PROGRAM); this.prodParam.enter(paramFlags); this.nextToken(); const expr = this.parseExpression(); if (!this.match(tt.eof)) { this.unexpected(); } expr.comments = this.state.comments; expr.errors = this.state.errors; return expr; } // ### Expression parsing // These nest, from the most general expression type at the top to // 'atomic', nondivisible expression types at the bottom. Most of // the functions will simply let the function (s) below them parse, // and, *if* the syntactic construct they handle is present, wrap // the AST node that the inner parser gave them in another node. // Parse a full expression. // - `noIn` // is used to forbid the `in` operator (in for loops initialization expressions) // When `noIn` is true, the production parameter [In] is not present. // Whenever [?In] appears in the right-hand sides of a production, we pass // `noIn` to the subroutine calls. // - `refExpressionErrors ` // provides reference for storing '=' operator inside shorthand // property assignment in contexts where both object expression // and object pattern might appear (so it's possible to raise // delayed syntax error at correct position). parseExpression( noIn?: boolean, refExpressionErrors?: ExpressionErrors, ): N.Expression { const startPos = this.state.start; const startLoc = this.state.startLoc; const expr = this.parseMaybeAssign(noIn, refExpressionErrors); if (this.match(tt.comma)) { const node = this.startNodeAt(startPos, startLoc); node.expressions = [expr]; while (this.eat(tt.comma)) { node.expressions.push(this.parseMaybeAssign(noIn, refExpressionErrors)); } this.toReferencedList(node.expressions); return this.finishNode(node, "SequenceExpression"); } return expr; } // Parse an assignment expression. This includes applications of // operators like `+=`. parseMaybeAssign( noIn?: ?boolean, refExpressionErrors?: ?ExpressionErrors, afterLeftParse?: Function, refNeedsArrowPos?: ?Pos, ): N.Expression { const startPos = this.state.start; const startLoc = this.state.startLoc; if (this.isContextual("yield")) { if (this.prodParam.hasYield) { let left = this.parseYield(noIn); if (afterLeftParse) { left = afterLeftParse.call(this, left, startPos, startLoc); } return left; } else { // The tokenizer will assume an expression is allowed after // `yield`, but this isn't that kind of yield this.state.exprAllowed = false; } } let ownExpressionErrors; if (refExpressionErrors) { ownExpressionErrors = false; } else { refExpressionErrors = new ExpressionErrors(); ownExpressionErrors = true; } if (this.match(tt.parenL) || this.match(tt.name)) { this.state.potentialArrowAt = this.state.start; } let left = this.parseMaybeConditional( noIn, refExpressionErrors, refNeedsArrowPos, ); if (afterLeftParse) { left = afterLeftParse.call(this, left, startPos, startLoc); } if (this.state.type.isAssign) { const node = this.startNodeAt(startPos, startLoc); const operator = this.state.value; node.operator = operator; if (operator === "??=") { this.expectPlugin("logicalAssignment"); } if (operator === "||=" || operator === "&&=") { this.expectPlugin("logicalAssignment"); } if (this.match(tt.eq)) { node.left = this.toAssignable(left); refExpressionErrors.doubleProto = -1; // reset because double __proto__ is valid in assignment expression } else { node.left = left; } if (refExpressionErrors.shorthandAssign >= node.left.start) { refExpressionErrors.shorthandAssign = -1; // reset because shorthand default was used correctly } this.checkLVal(left, undefined, undefined, "assignment expression"); this.next(); node.right = this.parseMaybeAssign(noIn); return this.finishNode(node, "AssignmentExpression"); } else if (ownExpressionErrors) { this.checkExpressionErrors(refExpressionErrors, true); } return left; } // Parse a ternary conditional (`?:`) operator. parseMaybeConditional( noIn: ?boolean, refExpressionErrors: ExpressionErrors, refNeedsArrowPos?: ?Pos, ): N.Expression { const startPos = this.state.start; const startLoc = this.state.startLoc; const potentialArrowAt = this.state.potentialArrowAt; const expr = this.parseExprOps(noIn, refExpressionErrors); if ( expr.type === "ArrowFunctionExpression" && expr.start === potentialArrowAt ) { return expr; } if (this.checkExpressionErrors(refExpressionErrors, false)) return expr; return this.parseConditional( expr, noIn, startPos, startLoc, refNeedsArrowPos, ); } parseConditional( expr: N.Expression, noIn: ?boolean, startPos: number, startLoc: Position, // FIXME: Disabling this for now since can't seem to get it to play nicely // eslint-disable-next-line no-unused-vars refNeedsArrowPos?: ?Pos, ): N.Expression { if (this.eat(tt.question)) { const node = this.startNodeAt(startPos, startLoc); node.test = expr; node.consequent = this.parseMaybeAssign(); this.expect(tt.colon); node.alternate = this.parseMaybeAssign(noIn); return this.finishNode(node, "ConditionalExpression"); } return expr; } // Start the precedence parser. parseExprOps( noIn: ?boolean, refExpressionErrors: ExpressionErrors, ): N.Expression { const startPos = this.state.start; const startLoc = this.state.startLoc; const potentialArrowAt = this.state.potentialArrowAt; const expr = this.parseMaybeUnary(refExpressionErrors); if ( expr.type === "ArrowFunctionExpression" && expr.start === potentialArrowAt ) { return expr; } if (this.checkExpressionErrors(refExpressionErrors, false)) { return expr; } return this.parseExprOp(expr, startPos, startLoc, -1, noIn); } // Parse binary operators with the operator precedence parsing // algorithm. `left` is the left-hand side of the operator. // `minPrec` provides context that allows the function to stop and // defer further parser to one of its callers when it encounters an // operator that has a lower precedence than the set it is parsing. parseExprOp( left: N.Expression, leftStartPos: number, leftStartLoc: Position, minPrec: number, noIn: ?boolean, ): N.Expression { let prec = this.state.type.binop; if (prec != null && (!noIn || !this.match(tt._in))) { if (prec > minPrec) { const operator = this.state.value; if (operator === "|>" && this.state.inFSharpPipelineDirectBody) { return left; } const node = this.startNodeAt(leftStartPos, leftStartLoc); node.left = left; node.operator = operator; if ( operator === "**" && left.type === "UnaryExpression" && (this.options.createParenthesizedExpressions || !(left.extra && left.extra.parenthesized)) ) { this.raise( left.argument.start, Errors.UnexpectedTokenUnaryExponentiation, ); } const op = this.state.type; const logical = op === tt.logicalOR || op === tt.logicalAND; const coalesce = op === tt.nullishCoalescing; if (op === tt.pipeline) { this.expectPlugin("pipelineOperator"); this.state.inPipeline = true; this.checkPipelineAtInfixOperator(left, leftStartPos); } else if (coalesce) { // Handle the precedence of `tt.coalesce` as equal to the range of logical expressions. // In other words, `node.right` shouldn't contain logical expressions in order to check the mixed error. prec = ((tt.logicalAND: any): { binop: number }).binop; } this.next(); if ( op === tt.pipeline && this.getPluginOption("pipelineOperator", "proposal") === "minimal" ) { if ( this.match(tt.name) && this.state.value === "await" && this.prodParam.hasAwait ) { throw this.raise( this.state.start, Errors.UnexpectedAwaitAfterPipelineBody, ); } } node.right = this.parseExprOpRightExpr(op, prec, noIn); this.finishNode( node, logical || coalesce ? "LogicalExpression" : "BinaryExpression", ); /* this check is for all ?? operators * a ?? b && c for this example * when op is coalesce and nextOp is logical (&&), throw at the pos of nextOp that it can not be mixed. * Symmetrically it also throws when op is logical and nextOp is coalesce */ const nextOp = this.state.type; if ( (coalesce && (nextOp === tt.logicalOR || nextOp === tt.logicalAND)) || (logical && nextOp === tt.nullishCoalescing) ) { throw this.raise(this.state.start, Errors.MixingCoalesceWithLogical); } return this.parseExprOp( node, leftStartPos, leftStartLoc, minPrec, noIn, ); } } return left; } // Helper function for `parseExprOp`. Parse the right-hand side of binary- // operator expressions, then apply any operator-specific functions. parseExprOpRightExpr( op: TokenType, prec: number, noIn: ?boolean, ): N.Expression { const startPos = this.state.start; const startLoc = this.state.startLoc; switch (op) { case tt.pipeline: switch (this.getPluginOption("pipelineOperator", "proposal")) { case "smart": return this.withTopicPermittingContext(() => { return this.parseSmartPipelineBody( this.parseExprOpBaseRightExpr(op, prec, noIn), startPos, startLoc, ); }); case "fsharp": return this.withSoloAwaitPermittingContext(() => { return this.parseFSharpPipelineBody(prec, noIn); }); } // falls through default: return this.parseExprOpBaseRightExpr(op, prec, noIn); } } // Helper function for `parseExprOpRightExpr`. Parse the right-hand side of // binary-operator expressions without applying any operator-specific functions. parseExprOpBaseRightExpr( op: TokenType, prec: number, noIn: ?boolean, ): N.Expression { const startPos = this.state.start; const startLoc = this.state.startLoc; return this.parseExprOp( this.parseMaybeUnary(), startPos, startLoc, op.rightAssociative ? prec - 1 : prec, noIn, ); } // Parse unary operators, both prefix and postfix. parseMaybeUnary(refExpressionErrors: ?ExpressionErrors): N.Expression { if (this.isContextual("await") && this.isAwaitAllowed()) { return this.parseAwait(); } else if (this.state.type.prefix) { const node = this.startNode(); const update = this.match(tt.incDec); node.operator = this.state.value; node.prefix = true; if (node.operator === "throw") { this.expectPlugin("throwExpressions"); } this.next(); node.argument = this.parseMaybeUnary(); this.checkExpressionErrors(refExpressionErrors, true); if (update) { this.checkLVal(node.argument, undefined, undefined, "prefix operation"); } else if (this.state.strict && node.operator === "delete") { const arg = node.argument; if (arg.type === "Identifier") { this.raise(node.start, Errors.StrictDelete); } else if ( (arg.type === "MemberExpression" || arg.type === "OptionalMemberExpression") && arg.property.type === "PrivateName" ) { this.raise(node.start, Errors.DeletePrivateField); } } return this.finishNode( node, update ? "UpdateExpression" : "UnaryExpression", ); } const startPos = this.state.start; const startLoc = this.state.startLoc; let expr = this.parseExprSubscripts(refExpressionErrors); if (this.checkExpressionErrors(refExpressionErrors, false)) return expr; while (this.state.type.postfix && !this.canInsertSemicolon()) { const node = this.startNodeAt(startPos, startLoc); node.operator = this.state.value; node.prefix = false; node.argument = expr; this.checkLVal(expr, undefined, undefined, "postfix operation"); this.next(); expr = this.finishNode(node, "UpdateExpression"); } return expr; } // Parse call, dot, and `[]`-subscript expressions. parseExprSubscripts(refExpressionErrors: ?ExpressionErrors): N.Expression { const startPos = this.state.start; const startLoc = this.state.startLoc; const potentialArrowAt = this.state.potentialArrowAt; const expr = this.parseExprAtom(refExpressionErrors); if ( expr.type === "ArrowFunctionExpression" && expr.start === potentialArrowAt ) { return expr; } return this.parseSubscripts(expr, startPos, startLoc); } parseSubscripts( base: N.Expression, startPos: number, startLoc: Position, noCalls?: ?boolean, ): N.Expression { const state = { optionalChainMember: false, maybeAsyncArrow: this.atPossibleAsyncArrow(base), stop: false, }; do { const oldMaybeInAsyncArrowHead = this.state.maybeInAsyncArrowHead; if (state.maybeAsyncArrow) { this.state.maybeInAsyncArrowHead = true; } base = this.parseSubscript(base, startPos, startLoc, noCalls, state); // After parsing a subscript, this isn't "async" for sure. state.maybeAsyncArrow = false; this.state.maybeInAsyncArrowHead = oldMaybeInAsyncArrowHead; } while (!state.stop); return base; } /** * @param state Set 'state.stop = true' to indicate that we should stop parsing subscripts. * state.optionalChainMember to indicate that the member is currently in OptionalChain */ parseSubscript( base: N.Expression, startPos: number, startLoc: Position, noCalls: ?boolean, state: N.ParseSubscriptState, ): N.Expression { if (!noCalls && this.eat(tt.doubleColon)) { const node = this.startNodeAt(startPos, startLoc); node.object = base; node.callee = this.parseNoCallExpr(); state.stop = true; return this.parseSubscripts( this.finishNode(node, "BindExpression"), startPos, startLoc, noCalls, ); } let optional = false; if (this.match(tt.questionDot)) { state.optionalChainMember = optional = true; if (noCalls && this.lookaheadCharCode() === charCodes.leftParenthesis) { state.stop = true; return base; } this.next(); } const computed = this.eat(tt.bracketL); if ( (optional && !this.match(tt.parenL) && !this.match(tt.backQuote)) || computed || this.eat(tt.dot) ) { const node = this.startNodeAt(startPos, startLoc); node.object = base; node.property = computed ? this.parseExpression() : this.parseMaybePrivateName(true); node.computed = computed; if (node.property.type === "PrivateName") { if (node.object.type === "Super") { this.raise(startPos, Errors.SuperPrivateField); } this.classScope.usePrivateName( node.property.id.name, node.property.start, ); } if (computed) { this.expect(tt.bracketR); } if (state.optionalChainMember) { node.optional = optional; return this.finishNode(node, "OptionalMemberExpression"); } else { return this.finishNode(node, "MemberExpression"); } } else if (!noCalls && this.match(tt.parenL)) { const oldMaybeInArrowParameters = this.state.maybeInArrowParameters; const oldYieldPos = this.state.yieldPos; const oldAwaitPos = this.state.awaitPos; this.state.maybeInArrowParameters = true; this.state.yieldPos = -1; this.state.awaitPos = -1; this.next(); let node = this.startNodeAt(startPos, startLoc); node.callee = base; if (state.optionalChainMember) { node.optional = optional; } if (optional) { node.arguments = this.parseCallExpressionArguments(tt.parenR, false); } else { node.arguments = this.parseCallExpressionArguments( tt.parenR, state.maybeAsyncArrow, base.type === "Import", base.type !== "Super", node, ); } this.finishCallExpression(node, state.optionalChainMember); if (state.maybeAsyncArrow && this.shouldParseAsyncArrow() && !optional) { state.stop = true; node = this.parseAsyncArrowFromCallExpression( this.startNodeAt(startPos, startLoc), node, ); this.checkYieldAwaitInDefaultParams(); this.state.yieldPos = oldYieldPos; this.state.awaitPos = oldAwaitPos; } else { this.toReferencedListDeep(node.arguments); // We keep the old value if it isn't null, for cases like // (x = async(yield)) => {} // // Hi developer of the future :) If you are implementing generator // arrow functions, please read the note below about "await" and // verify if the same logic is needed for yield. if (oldYieldPos !== -1) this.state.yieldPos = oldYieldPos; // Await is trickier than yield. When parsing a possible arrow function // (e.g. something starting with `async(`) we don't know if its possible // parameters will actually be inside an async arrow function or if it is // a normal call expression. // If it ended up being a call expression, if we are in a context where // await expression are disallowed (and thus "await" is an identifier) // we must be careful not to leak this.state.awaitPos to an even outer // context, where "await" could not be an identifier. // For example, this code is valid because "await" isn't directly inside // an async function: // // async function a() { // function b(param = async (await)) { // } // } // if ( (!this.isAwaitAllowed() && !oldMaybeInArrowParameters) || oldAwaitPos !== -1 ) { this.state.awaitPos = oldAwaitPos; } } this.state.maybeInArrowParameters = oldMaybeInArrowParameters; return node; } else if (this.match(tt.backQuote)) { return this.parseTaggedTemplateExpression( startPos, startLoc, base, state, ); } else { state.stop = true; return base; } } parseTaggedTemplateExpression( startPos: number, startLoc: Position, base: N.Expression, state: N.ParseSubscriptState, typeArguments?: ?N.TsTypeParameterInstantiation, ): N.TaggedTemplateExpression { const node: N.TaggedTemplateExpression = this.startNodeAt( startPos, startLoc, ); node.tag = base; node.quasi = this.parseTemplate(true); if (typeArguments) node.typeParameters = typeArguments; if (state.optionalChainMember) { this.raise(startPos, Errors.OptionalChainingNoTemplate); } return this.finishNode(node, "TaggedTemplateExpression"); } atPossibleAsyncArrow(base: N.Expression): boolean { return ( base.type === "Identifier" && base.name === "async" && this.state.lastTokEnd === base.end && !this.canInsertSemicolon() && // check there are no escape sequences, such as \u{61}sync base.end - base.start === 5 && base.start === this.state.potentialArrowAt ); } finishCallExpression( node: T, optional: boolean, ): N.Expression { if (node.callee.type === "Import") { if (node.arguments.length === 2) { this.expectPlugin("moduleAttributes"); } if (node.arguments.length === 0 || node.arguments.length > 2) { this.raise( node.start, Errors.ImportCallArity, this.hasPlugin("moduleAttributes") ? "one or two arguments" : "one argument", ); } else { for (const arg of node.arguments) { if (arg.type === "SpreadElement") { this.raise(arg.start, Errors.ImportCallSpreadArgument); } } } } return this.finishNode( node, optional ? "OptionalCallExpression" : "CallExpression", ); } parseCallExpressionArguments( close: TokenType, possibleAsyncArrow: boolean, dynamicImport?: boolean, allowPlaceholder?: boolean, nodeForExtra?: ?N.Node, ): $ReadOnlyArray { const elts = []; let innerParenStart; let first = true; const oldInFSharpPipelineDirectBody = this.state.inFSharpPipelineDirectBody; this.state.inFSharpPipelineDirectBody = false; while (!this.eat(close)) { if (first) { first = false; } else { this.expect(tt.comma); if (this.match(close)) { if (dynamicImport && !this.hasPlugin("moduleAttributes")) { this.raise( this.state.lastTokStart, Errors.ImportCallArgumentTrailingComma, ); } if (nodeForExtra) { this.addExtra( nodeForExtra, "trailingComma", this.state.lastTokStart, ); } this.next(); break; } } // we need to make sure that if this is an async arrow functions, // that we don't allow inner parens inside the params if (this.match(tt.parenL) && !innerParenStart) { innerParenStart = this.state.start; } elts.push( this.parseExprListItem( false, possibleAsyncArrow ? new ExpressionErrors() : undefined, possibleAsyncArrow ? { start: 0 } : undefined, allowPlaceholder, ), ); } // we found an async arrow function so let's not allow any inner parens if (possibleAsyncArrow && innerParenStart && this.shouldParseAsyncArrow()) { this.unexpected(); } this.state.inFSharpPipelineDirectBody = oldInFSharpPipelineDirectBody; return elts; } shouldParseAsyncArrow(): boolean { return this.match(tt.arrow) && !this.canInsertSemicolon(); } parseAsyncArrowFromCallExpression( node: N.ArrowFunctionExpression, call: N.CallExpression, ): N.ArrowFunctionExpression { this.expect(tt.arrow); this.parseArrowExpression( node, call.arguments, true, call.extra?.trailingComma, ); return node; } // Parse a no-call expression (like argument of `new` or `::` operators). parseNoCallExpr(): N.Expression { const startPos = this.state.start; const startLoc = this.state.startLoc; return this.parseSubscripts(this.parseExprAtom(), startPos, startLoc, true); } // Parse an atomic expression — either a single token that is an // expression, an expression started by a keyword like `function` or // `new`, or an expression wrapped in punctuation like `()`, `[]`, // or `{}`. parseExprAtom(refExpressionErrors?: ?ExpressionErrors): N.Expression { // If a division operator appears in an expression position, the // tokenizer got confused, and we force it to read a regexp instead. if (this.state.type === tt.slash) this.readRegexp(); const canBeArrow = this.state.potentialArrowAt === this.state.start; let node; switch (this.state.type) { case tt._super: node = this.startNode(); this.next(); if ( this.match(tt.parenL) && !this.scope.allowDirectSuper && !this.options.allowSuperOutsideMethod ) { this.raise(node.start, Errors.SuperNotAllowed); } else if ( !this.scope.allowSuper && !this.options.allowSuperOutsideMethod ) { this.raise(node.start, Errors.UnexpectedSuper); } if ( !this.match(tt.parenL) && !this.match(tt.bracketL) && !this.match(tt.dot) ) { this.raise(node.start, Errors.UnsupportedSuper); } return this.finishNode(node, "Super"); case tt._import: node = this.startNode(); this.next(); if (this.match(tt.dot)) { return this.parseImportMetaProperty(node); } if (!this.match(tt.parenL)) { this.raise(this.state.lastTokStart, Errors.UnsupportedImport); } return this.finishNode(node, "Import"); case tt._this: node = this.startNode(); this.next(); return this.finishNode(node, "ThisExpression"); case tt.name: { node = this.startNode(); const containsEsc = this.state.containsEsc; const id = this.parseIdentifier(); if ( !containsEsc && id.name === "async" && this.match(tt._function) && !this.canInsertSemicolon() ) { const last = this.state.context.length - 1; if (this.state.context[last] !== ct.functionStatement) { // Since "async" is an identifier and normally identifiers // can't be followed by expression, the tokenizer assumes // that "function" starts a statement. // Fixing it in the tokenizer would mean tracking not only the // previous token ("async"), but also the one before to know // its beforeExpr value. // It's easier and more efficient to adjust the context here. throw new Error("Internal error"); } this.state.context[last] = ct.functionExpression; this.next(); return this.parseFunction(node, undefined, true); } else if ( canBeArrow && !containsEsc && id.name === "async" && this.match(tt.name) && !this.canInsertSemicolon() ) { const oldMaybeInArrowParameters = this.state.maybeInArrowParameters; const oldMaybeInAsyncArrowHead = this.state.maybeInAsyncArrowHead; const oldYieldPos = this.state.yieldPos; const oldAwaitPos = this.state.awaitPos; this.state.maybeInArrowParameters = true; this.state.maybeInAsyncArrowHead = true; this.state.yieldPos = -1; this.state.awaitPos = -1; const params = [this.parseIdentifier()]; this.expect(tt.arrow); this.checkYieldAwaitInDefaultParams(); this.state.maybeInArrowParameters = oldMaybeInArrowParameters; this.state.maybeInAsyncArrowHead = oldMaybeInAsyncArrowHead; this.state.yieldPos = oldYieldPos; this.state.awaitPos = oldAwaitPos; // let foo = async bar => {}; this.parseArrowExpression(node, params, true); return node; } if (canBeArrow && this.match(tt.arrow) && !this.canInsertSemicolon()) { this.next(); this.parseArrowExpression(node, [id], false); return node; } return id; } case tt._do: { this.expectPlugin("doExpressions"); const node = this.startNode(); this.next(); const oldLabels = this.state.labels; this.state.labels = []; node.body = this.parseBlock(); this.state.labels = oldLabels; return this.finishNode(node, "DoExpression"); } case tt.regexp: { const value = this.state.value; node = this.parseLiteral(value.value, "RegExpLiteral"); node.pattern = value.pattern; node.flags = value.flags; return node; } case tt.num: return this.parseLiteral(this.state.value, "NumericLiteral"); case tt.bigint: return this.parseLiteral(this.state.value, "BigIntLiteral"); case tt.string: return this.parseLiteral(this.state.value, "StringLiteral"); case tt._null: node = this.startNode(); this.next(); return this.finishNode(node, "NullLiteral"); case tt._true: case tt._false: return this.parseBooleanLiteral(); case tt.parenL: return this.parseParenAndDistinguishExpression(canBeArrow); case tt.bracketBarL: case tt.bracketHashL: { this.expectPlugin("recordAndTuple"); const oldInFSharpPipelineDirectBody = this.state .inFSharpPipelineDirectBody; const close = this.state.type === tt.bracketBarL ? tt.bracketBarR : tt.bracketR; this.state.inFSharpPipelineDirectBody = false; node = this.startNode(); this.next(); node.elements = this.parseExprList( close, false, refExpressionErrors, node, ); this.state.inFSharpPipelineDirectBody = oldInFSharpPipelineDirectBody; return this.finishNode(node, "TupleExpression"); } case tt.bracketL: { const oldInFSharpPipelineDirectBody = this.state .inFSharpPipelineDirectBody; this.state.inFSharpPipelineDirectBody = false; node = this.startNode(); this.next(); node.elements = this.parseExprList( tt.bracketR, true, refExpressionErrors, node, ); if (!this.state.maybeInArrowParameters) { // This could be an array pattern: // ([a: string, b: string]) => {} // In this case, we don't have to call toReferencedList. We will // call it, if needed, when we are sure that it is a parenthesized // expression by calling toReferencedListDeep. this.toReferencedList(node.elements); } this.state.inFSharpPipelineDirectBody = oldInFSharpPipelineDirectBody; return this.finishNode(node, "ArrayExpression"); } case tt.braceBarL: case tt.braceHashL: { this.expectPlugin("recordAndTuple"); const oldInFSharpPipelineDirectBody = this.state .inFSharpPipelineDirectBody; const close = this.state.type === tt.braceBarL ? tt.braceBarR : tt.braceR; this.state.inFSharpPipelineDirectBody = false; const ret = this.parseObj(close, false, true, refExpressionErrors); this.state.inFSharpPipelineDirectBody = oldInFSharpPipelineDirectBody; return ret; } case tt.braceL: { const oldInFSharpPipelineDirectBody = this.state .inFSharpPipelineDirectBody; this.state.inFSharpPipelineDirectBody = false; const ret = this.parseObj(tt.braceR, false, false, refExpressionErrors); this.state.inFSharpPipelineDirectBody = oldInFSharpPipelineDirectBody; return ret; } case tt._function: return this.parseFunctionExpression(); case tt.at: this.parseDecorators(); // fall through case tt._class: node = this.startNode(); this.takeDecorators(node); return this.parseClass(node, false); case tt._new: return this.parseNew(); case tt.backQuote: return this.parseTemplate(false); case tt.doubleColon: { node = this.startNode(); this.next(); node.object = null; const callee = (node.callee = this.parseNoCallExpr()); if (callee.type === "MemberExpression") { return this.finishNode(node, "BindExpression"); } else { throw this.raise(callee.start, Errors.UnsupportedBind); } } case tt.hash: { if (this.state.inPipeline) { node = this.startNode(); if ( this.getPluginOption("pipelineOperator", "proposal") !== "smart" ) { this.raise(node.start, Errors.PrimaryTopicRequiresSmartPipeline); } this.next(); if (!this.primaryTopicReferenceIsAllowedInCurrentTopicContext()) { this.raise(node.start, Errors.PrimaryTopicNotAllowed); } this.registerTopicReference(); return this.finishNode(node, "PipelinePrimaryTopicReference"); } const nextCh = this.input.codePointAt(this.state.end); if (isIdentifierStart(nextCh) || nextCh === charCodes.backslash) { const start = this.state.start; // $FlowIgnore It'll either parse a PrivateName or throw. node = (this.parseMaybePrivateName(true): N.PrivateName); if (this.match(tt._in)) { this.expectPlugin("privateIn"); this.classScope.usePrivateName(node.id.name, node.start); } else if (this.hasPlugin("privateIn")) { this.raise( this.state.start, Errors.PrivateInExpectedIn, node.id.name, ); } else { throw this.unexpected(start); } return node; } } // fall through case tt.relational: { if (this.state.value === "<") { const lookaheadCh = this.input.codePointAt(this.nextTokenStart()); if ( isIdentifierStart(lookaheadCh) || // Element/Type Parameter lookaheadCh === charCodes.greaterThan // Fragment <> ) { this.expectOnePlugin(["jsx", "flow", "typescript"]); } } } // fall through default: throw this.unexpected(); } } parseBooleanLiteral(): N.BooleanLiteral { const node = this.startNode(); node.value = this.match(tt._true); this.next(); return this.finishNode(node, "BooleanLiteral"); } parseMaybePrivateName( isPrivateNameAllowed: boolean, ): N.PrivateName | N.Identifier { const isPrivate = this.match(tt.hash); if (isPrivate) { this.expectOnePlugin(["classPrivateProperties", "classPrivateMethods"]); if (!isPrivateNameAllowed) { this.raise(this.state.pos, Errors.UnexpectedPrivateField); } const node = this.startNode(); this.next(); this.assertNoSpace("Unexpected space between # and identifier"); node.id = this.parseIdentifier(true); return this.finishNode(node, "PrivateName"); } else { return this.parseIdentifier(true); } } parseFunctionExpression(): N.FunctionExpression | N.MetaProperty { const node = this.startNode(); // We do not do parseIdentifier here because when parseFunctionExpression // is called we already know that the current token is a "name" with the value "function" // This will improve perf a tiny little bit as we do not do validation but more importantly // here is that parseIdentifier will remove an item from the expression stack // if "function" or "class" is parsed as identifier (in objects e.g.), which should not happen here. let meta = this.startNode(); this.next(); meta = this.createIdentifier(meta, "function"); if (this.prodParam.hasYield && this.eat(tt.dot)) { return this.parseMetaProperty(node, meta, "sent"); } return this.parseFunction(node); } parseMetaProperty( node: N.MetaProperty, meta: N.Identifier, propertyName: string, ): N.MetaProperty { node.meta = meta; if (meta.name === "function" && propertyName === "sent") { if (this.isContextual(propertyName)) { this.expectPlugin("functionSent"); } else if (!this.hasPlugin("functionSent")) { // The code wasn't `function.sent` but just `function.`, so a simple error is less confusing. this.unexpected(); } } const containsEsc = this.state.containsEsc; node.property = this.parseIdentifier(true); if (node.property.name !== propertyName || containsEsc) { this.raise( node.property.start, Errors.UnsupportedMetaProperty, meta.name, propertyName, ); } return this.finishNode(node, "MetaProperty"); } parseImportMetaProperty(node: N.MetaProperty): N.MetaProperty { const id = this.createIdentifier(this.startNodeAtNode(node), "import"); this.expect(tt.dot); if (this.isContextual("meta")) { if (!this.inModule) { this.raiseWithData( id.start, { code: "BABEL_PARSER_SOURCETYPE_MODULE_REQUIRED" }, Errors.ImportMetaOutsideModule, ); } this.sawUnambiguousESM = true; } return this.parseMetaProperty(node, id, "meta"); } parseLiteral( value: any, type: /*T["kind"]*/ string, startPos?: number, startLoc?: Position, ): T { startPos = startPos || this.state.start; startLoc = startLoc || this.state.startLoc; const node = this.startNodeAt(startPos, startLoc); this.addExtra(node, "rawValue", value); this.addExtra(node, "raw", this.input.slice(startPos, this.state.end)); node.value = value; this.next(); return this.finishNode(node, type); } parseParenAndDistinguishExpression(canBeArrow: boolean): N.Expression { const startPos = this.state.start; const startLoc = this.state.startLoc; let val; this.expect(tt.parenL); const oldMaybeInArrowParameters = this.state.maybeInArrowParameters; const oldYieldPos = this.state.yieldPos; const oldAwaitPos = this.state.awaitPos; const oldInFSharpPipelineDirectBody = this.state.inFSharpPipelineDirectBody; this.state.maybeInArrowParameters = true; this.state.yieldPos = -1; this.state.awaitPos = -1; this.state.inFSharpPipelineDirectBody = false; const innerStartPos = this.state.start; const innerStartLoc = this.state.startLoc; const exprList = []; const refExpressionErrors = new ExpressionErrors(); const refNeedsArrowPos = { start: 0 }; let first = true; let spreadStart; let optionalCommaStart; while (!this.match(tt.parenR)) { if (first) { first = false; } else { this.expect(tt.comma, refNeedsArrowPos.start || null); if (this.match(tt.parenR)) { optionalCommaStart = this.state.start; break; } } if (this.match(tt.ellipsis)) { const spreadNodeStartPos = this.state.start; const spreadNodeStartLoc = this.state.startLoc; spreadStart = this.state.start; exprList.push( this.parseParenItem( this.parseRestBinding(), spreadNodeStartPos, spreadNodeStartLoc, ), ); this.checkCommaAfterRest(charCodes.rightParenthesis); break; } else { exprList.push( this.parseMaybeAssign( false, refExpressionErrors, this.parseParenItem, refNeedsArrowPos, ), ); } } const innerEndPos = this.state.start; const innerEndLoc = this.state.startLoc; this.expect(tt.parenR); this.state.maybeInArrowParameters = oldMaybeInArrowParameters; this.state.inFSharpPipelineDirectBody = oldInFSharpPipelineDirectBody; let arrowNode = this.startNodeAt(startPos, startLoc); if ( canBeArrow && this.shouldParseArrow() && (arrowNode = this.parseArrow(arrowNode)) ) { if (!this.isAwaitAllowed() && !this.state.maybeInAsyncArrowHead) { this.state.awaitPos = oldAwaitPos; } this.checkYieldAwaitInDefaultParams(); this.state.yieldPos = oldYieldPos; this.state.awaitPos = oldAwaitPos; for (const param of exprList) { if (param.extra && param.extra.parenthesized) { this.unexpected(param.extra.parenStart); } } this.parseArrowExpression(arrowNode, exprList, false); return arrowNode; } // We keep the old value if it isn't null, for cases like // (x = (yield)) => {} if (oldYieldPos !== -1) this.state.yieldPos = oldYieldPos; if (oldAwaitPos !== -1) this.state.awaitPos = oldAwaitPos; if (!exprList.length) { this.unexpected(this.state.lastTokStart); } if (optionalCommaStart) this.unexpected(optionalCommaStart); if (spreadStart) this.unexpected(spreadStart); this.checkExpressionErrors(refExpressionErrors, true); if (refNeedsArrowPos.start) this.unexpected(refNeedsArrowPos.start); this.toReferencedListDeep(exprList, /* isParenthesizedExpr */ true); if (exprList.length > 1) { val = this.startNodeAt(innerStartPos, innerStartLoc); val.expressions = exprList; this.finishNodeAt(val, "SequenceExpression", innerEndPos, innerEndLoc); } else { val = exprList[0]; } if (!this.options.createParenthesizedExpressions) { this.addExtra(val, "parenthesized", true); this.addExtra(val, "parenStart", startPos); return val; } const parenExpression = this.startNodeAt(startPos, startLoc); parenExpression.expression = val; this.finishNode(parenExpression, "ParenthesizedExpression"); return parenExpression; } shouldParseArrow(): boolean { return !this.canInsertSemicolon(); } parseArrow(node: N.ArrowFunctionExpression): ?N.ArrowFunctionExpression { if (this.eat(tt.arrow)) { return node; } } parseParenItem( node: N.Expression, startPos: number, // eslint-disable-line no-unused-vars startLoc: Position, // eslint-disable-line no-unused-vars ): N.Expression { return node; } // New's precedence is slightly tricky. It must allow its argument to // be a `[]` or dot subscript expression, but not a call — at least, // not without wrapping it in parentheses. Thus, it uses the noCalls // argument to parseSubscripts to prevent it from consuming the // argument list. parseNew(): N.NewExpression | N.MetaProperty { const node = this.startNode(); let meta = this.startNode(); this.next(); meta = this.createIdentifier(meta, "new"); if (this.eat(tt.dot)) { const metaProp = this.parseMetaProperty(node, meta, "target"); if (!this.scope.inNonArrowFunction && !this.scope.inClass) { let error = Errors.UnexpectedNewTarget; if (this.hasPlugin("classProperties")) { error += " or class properties"; } /* eslint-disable @babel/development-internal/dry-error-messages */ this.raise(metaProp.start, error); /* eslint-enable @babel/development-internal/dry-error-messages */ } return metaProp; } node.callee = this.parseNoCallExpr(); if (node.callee.type === "Import") { this.raise(node.callee.start, Errors.ImportCallNotNewExpression); } else if ( node.callee.type === "OptionalMemberExpression" || node.callee.type === "OptionalCallExpression" ) { this.raise(this.state.lastTokEnd, Errors.OptionalChainingNoNew); } else if (this.eat(tt.questionDot)) { this.raise(this.state.start, Errors.OptionalChainingNoNew); } this.parseNewArguments(node); return this.finishNode(node, "NewExpression"); } parseNewArguments(node: N.NewExpression): void { if (this.eat(tt.parenL)) { const args = this.parseExprList(tt.parenR); this.toReferencedList(args); // $FlowFixMe (parseExprList should be all non-null in this case) node.arguments = args; } else { node.arguments = []; } } // Parse template expression. parseTemplateElement(isTagged: boolean): N.TemplateElement { const elem = this.startNode(); if (this.state.value === null) { if (!isTagged) { this.raise(this.state.start + 1, Errors.InvalidEscapeSequenceTemplate); } } elem.value = { raw: this.input .slice(this.state.start, this.state.end) .replace(/\r\n?/g, "\n"), cooked: this.state.value, }; this.next(); elem.tail = this.match(tt.backQuote); return this.finishNode(elem, "TemplateElement"); } parseTemplate(isTagged: boolean): N.TemplateLiteral { const node = this.startNode(); this.next(); node.expressions = []; let curElt = this.parseTemplateElement(isTagged); node.quasis = [curElt]; while (!curElt.tail) { this.expect(tt.dollarBraceL); node.expressions.push(this.parseExpression()); this.expect(tt.braceR); node.quasis.push((curElt = this.parseTemplateElement(isTagged))); } this.next(); return this.finishNode(node, "TemplateLiteral"); } // Parse an object literal, binding pattern, or record. parseObj( close: TokenType, isPattern: boolean, isRecord?: ?boolean, refExpressionErrors?: ?ExpressionErrors, ): T { const propHash: any = Object.create(null); let first = true; const node = this.startNode(); node.properties = []; this.next(); while (!this.eat(close)) { if (first) { first = false; } else { this.expect(tt.comma); if (this.match(close)) { this.addExtra(node, "trailingComma", this.state.lastTokStart); this.next(); break; } } const prop = this.parseObjectMember(isPattern, refExpressionErrors); if (!isPattern) { // $FlowIgnore RestElement will never be returned if !isPattern this.checkProto(prop, isRecord, propHash, refExpressionErrors); } if ( isRecord && prop.type !== "ObjectProperty" && prop.type !== "SpreadElement" ) { this.raise(prop.start, Errors.InvalidRecordProperty); } // $FlowIgnore if (prop.shorthand) { this.addExtra(prop, "shorthand", true); } node.properties.push(prop); } let type = "ObjectExpression"; if (isPattern) { type = "ObjectPattern"; } else if (isRecord) { type = "RecordExpression"; } return this.finishNode(node, type); } isAsyncProp(prop: N.ObjectProperty): boolean { return ( !prop.computed && prop.key.type === "Identifier" && prop.key.name === "async" && (this.isLiteralPropertyName() || this.match(tt.bracketL) || this.match(tt.star)) && !this.hasPrecedingLineBreak() ); } parseObjectMember( isPattern: boolean, refExpressionErrors?: ?ExpressionErrors, ): N.ObjectMember | N.SpreadElement | N.RestElement { let decorators = []; if (this.match(tt.at)) { if (this.hasPlugin("decorators")) { this.raise(this.state.start, Errors.UnsupportedPropertyDecorator); } // we needn't check if decorators (stage 0) plugin is enabled since it's checked by // the call to this.parseDecorator while (this.match(tt.at)) { decorators.push(this.parseDecorator()); } } const prop = this.startNode(); let isGenerator = false; let isAsync = false; let startPos; let startLoc; if (this.match(tt.ellipsis)) { if (decorators.length) this.unexpected(); if (isPattern) { this.next(); // Don't use parseRestBinding() as we only allow Identifier here. prop.argument = this.parseIdentifier(); this.checkCommaAfterRest(charCodes.rightCurlyBrace); return this.finishNode(prop, "RestElement"); } return this.parseSpread(); } if (decorators.length) { prop.decorators = decorators; decorators = []; } prop.method = false; if (isPattern || refExpressionErrors) { startPos = this.state.start; startLoc = this.state.startLoc; } if (!isPattern) { isGenerator = this.eat(tt.star); } const containsEsc = this.state.containsEsc; this.parsePropertyName(prop, /* isPrivateNameAllowed */ false); if (!isPattern && !containsEsc && !isGenerator && this.isAsyncProp(prop)) { isAsync = true; isGenerator = this.eat(tt.star); this.parsePropertyName(prop, /* isPrivateNameAllowed */ false); } else { isAsync = false; } this.parseObjPropValue( prop, startPos, startLoc, isGenerator, isAsync, isPattern, refExpressionErrors, containsEsc, ); return prop; } isGetterOrSetterMethod(prop: N.ObjectMethod, isPattern: boolean): boolean { return ( !isPattern && !prop.computed && prop.key.type === "Identifier" && (prop.key.name === "get" || prop.key.name === "set") && (this.isLiteralPropertyName() || // get foo() {} this.match(tt.bracketL)) // get ["string"]() {} ); } getGetterSetterExpectedParamCount( method: N.ObjectMethod | N.ClassMethod, ): number { return method.kind === "get" ? 0 : 1; } // get methods aren't allowed to have any parameters // set methods must have exactly 1 parameter which is not a rest parameter checkGetterSetterParams(method: N.ObjectMethod | N.ClassMethod): void { const paramCount = this.getGetterSetterExpectedParamCount(method); const start = method.start; if (method.params.length !== paramCount) { if (method.kind === "get") { this.raise(start, Errors.BadGetterArity); } else { this.raise(start, Errors.BadSetterArity); } } if ( method.kind === "set" && method.params[method.params.length - 1].type === "RestElement" ) { this.raise(start, Errors.BadSetterRestParameter); } } parseObjectMethod( prop: N.ObjectMethod, isGenerator: boolean, isAsync: boolean, isPattern: boolean, containsEsc: boolean, ): ?N.ObjectMethod { if (isAsync || isGenerator || this.match(tt.parenL)) { if (isPattern) this.unexpected(); prop.kind = "method"; prop.method = true; return this.parseMethod( prop, isGenerator, isAsync, /* isConstructor */ false, false, "ObjectMethod", ); } if (!containsEsc && this.isGetterOrSetterMethod(prop, isPattern)) { if (isGenerator || isAsync) this.unexpected(); prop.kind = prop.key.name; this.parsePropertyName(prop, /* isPrivateNameAllowed */ false); this.parseMethod( prop, /* isGenerator */ false, /* isAsync */ false, /* isConstructor */ false, false, "ObjectMethod", ); this.checkGetterSetterParams(prop); return prop; } } parseObjectProperty( prop: N.ObjectProperty, startPos: ?number, startLoc: ?Position, isPattern: boolean, refExpressionErrors: ?ExpressionErrors, ): ?N.ObjectProperty { prop.shorthand = false; if (this.eat(tt.colon)) { prop.value = isPattern ? this.parseMaybeDefault(this.state.start, this.state.startLoc) : this.parseMaybeAssign(false, refExpressionErrors); return this.finishNode(prop, "ObjectProperty"); } if (!prop.computed && prop.key.type === "Identifier") { this.checkReservedWord(prop.key.name, prop.key.start, true, true); if (isPattern) { prop.value = this.parseMaybeDefault( startPos, startLoc, prop.key.__clone(), ); } else if (this.match(tt.eq) && refExpressionErrors) { if (refExpressionErrors.shorthandAssign === -1) { refExpressionErrors.shorthandAssign = this.state.start; } prop.value = this.parseMaybeDefault( startPos, startLoc, prop.key.__clone(), ); } else { prop.value = prop.key.__clone(); } prop.shorthand = true; return this.finishNode(prop, "ObjectProperty"); } } parseObjPropValue( prop: any, startPos: ?number, startLoc: ?Position, isGenerator: boolean, isAsync: boolean, isPattern: boolean, refExpressionErrors?: ?ExpressionErrors, containsEsc: boolean, ): void { const node = this.parseObjectMethod( prop, isGenerator, isAsync, isPattern, containsEsc, ) || this.parseObjectProperty( prop, startPos, startLoc, isPattern, refExpressionErrors, ); if (!node) this.unexpected(); // $FlowFixMe return node; } parsePropertyName( prop: N.ObjectOrClassMember | N.ClassMember | N.TsNamedTypeElementBase, isPrivateNameAllowed: boolean, ): N.Expression | N.Identifier { if (this.eat(tt.bracketL)) { (prop: $FlowSubtype).computed = true; prop.key = this.parseMaybeAssign(); this.expect(tt.bracketR); } else { const oldInPropertyName = this.state.inPropertyName; this.state.inPropertyName = true; // We check if it's valid for it to be a private name when we push it. (prop: $FlowFixMe).key = this.match(tt.num) || this.match(tt.string) || this.match(tt.bigint) ? this.parseExprAtom() : this.parseMaybePrivateName(isPrivateNameAllowed); if (prop.key.type !== "PrivateName") { // ClassPrivateProperty is never computed, so we don't assign in that case. prop.computed = false; } this.state.inPropertyName = oldInPropertyName; } return prop.key; } // Initialize empty function node. initFunction(node: N.BodilessFunctionOrMethodBase, isAsync: ?boolean): void { node.id = null; node.generator = false; node.async = !!isAsync; } // Parse object or class method. parseMethod( node: T, isGenerator: boolean, isAsync: boolean, isConstructor: boolean, allowDirectSuper: boolean, type: string, inClassScope: boolean = false, ): T { const oldYieldPos = this.state.yieldPos; const oldAwaitPos = this.state.awaitPos; this.state.yieldPos = -1; this.state.awaitPos = -1; this.initFunction(node, isAsync); node.generator = !!isGenerator; const allowModifiers = isConstructor; // For TypeScript parameter properties this.scope.enter( SCOPE_FUNCTION | SCOPE_SUPER | (inClassScope ? SCOPE_CLASS : 0) | (allowDirectSuper ? SCOPE_DIRECT_SUPER : 0), ); this.prodParam.enter(functionFlags(isAsync, node.generator)); this.parseFunctionParams((node: any), allowModifiers); this.parseFunctionBodyAndFinish(node, type, true); this.prodParam.exit(); this.scope.exit(); this.state.yieldPos = oldYieldPos; this.state.awaitPos = oldAwaitPos; return node; } // Parse arrow function expression. // If the parameters are provided, they will be converted to an // assignable list. parseArrowExpression( node: N.ArrowFunctionExpression, params: ?(N.Expression[]), isAsync: boolean, trailingCommaPos: ?number, ): N.ArrowFunctionExpression { this.scope.enter(SCOPE_FUNCTION | SCOPE_ARROW); this.prodParam.enter(functionFlags(isAsync, false)); this.initFunction(node, isAsync); const oldMaybeInArrowParameters = this.state.maybeInArrowParameters; const oldYieldPos = this.state.yieldPos; const oldAwaitPos = this.state.awaitPos; if (params) { this.state.maybeInArrowParameters = true; this.setArrowFunctionParameters(node, params, trailingCommaPos); } this.state.maybeInArrowParameters = false; this.state.yieldPos = -1; this.state.awaitPos = -1; this.parseFunctionBody(node, true); this.prodParam.exit(); this.scope.exit(); this.state.maybeInArrowParameters = oldMaybeInArrowParameters; this.state.yieldPos = oldYieldPos; this.state.awaitPos = oldAwaitPos; return this.finishNode(node, "ArrowFunctionExpression"); } setArrowFunctionParameters( node: N.ArrowFunctionExpression, params: N.Expression[], trailingCommaPos: ?number, ): void { node.params = this.toAssignableList(params, trailingCommaPos); } parseFunctionBodyAndFinish( node: N.BodilessFunctionOrMethodBase, type: string, isMethod?: boolean = false, ): void { // $FlowIgnore (node is not bodiless if we get here) this.parseFunctionBody(node, false, isMethod); this.finishNode(node, type); } // Parse function body and check parameters. parseFunctionBody( node: N.Function, allowExpression: ?boolean, isMethod?: boolean = false, ): void { const isExpression = allowExpression && !this.match(tt.braceL); const oldInParameters = this.state.inParameters; this.state.inParameters = false; if (isExpression) { node.body = this.parseMaybeAssign(); this.checkParams(node, false, allowExpression, false); } else { const oldStrict = this.state.strict; // Start a new scope with regard to labels // flag (restore them to their old value afterwards). const oldLabels = this.state.labels; this.state.labels = []; // FunctionBody[Yield, Await]: // StatementList[?Yield, ?Await, +Return] opt this.prodParam.enter(this.prodParam.currentFlags() | PARAM_RETURN); node.body = this.parseBlock( true, false, // Strict mode function checks after we parse the statements in the function body. (hasStrictModeDirective: boolean) => { const nonSimple = !this.isSimpleParamList(node.params); if (hasStrictModeDirective && nonSimple) { // This logic is here to align the error location with the ESTree plugin. const errorPos = // $FlowIgnore (node.kind === "method" || node.kind === "constructor") && // $FlowIgnore !!node.key ? node.key.end : node.start; this.raise(errorPos, Errors.IllegalLanguageModeDirective); } const strictModeChanged = !oldStrict && this.state.strict; // Add the params to varDeclaredNames to ensure that an error is thrown // if a let/const declaration in the function clashes with one of the params. this.checkParams( node, !this.state.strict && !allowExpression && !isMethod && !nonSimple, allowExpression, strictModeChanged, ); // Ensure the function name isn't a forbidden identifier in strict mode, e.g. 'eval' if (this.state.strict && node.id) { this.checkLVal( node.id, BIND_OUTSIDE, undefined, "function name", undefined, strictModeChanged, ); } }, ); this.prodParam.exit(); this.state.labels = oldLabels; } this.state.inParameters = oldInParameters; } isSimpleParamList( params: $ReadOnlyArray, ): boolean { for (let i = 0, len = params.length; i < len; i++) { if (params[i].type !== "Identifier") return false; } return true; } checkParams( node: N.Function, allowDuplicates: boolean, // eslint-disable-next-line no-unused-vars isArrowFunction: ?boolean, strictModeChanged?: boolean = true, ): void { // $FlowIssue const nameHash: {} = Object.create(null); for (let i = 0; i < node.params.length; i++) { this.checkLVal( node.params[i], BIND_VAR, allowDuplicates ? null : nameHash, "function parameter list", undefined, strictModeChanged, ); } } // Parses a comma-separated list of expressions, and returns them as // an array. `close` is the token type that ends the list, and // `allowEmpty` can be turned on to allow subsequent commas with // nothing in between them to be parsed as `null` (which is needed // for array literals). parseExprList( close: TokenType, allowEmpty?: boolean, refExpressionErrors?: ?ExpressionErrors, nodeForExtra?: ?N.Node, ): $ReadOnlyArray { const elts = []; let first = true; while (!this.eat(close)) { if (first) { first = false; } else { this.expect(tt.comma); if (this.match(close)) { if (nodeForExtra) { this.addExtra( nodeForExtra, "trailingComma", this.state.lastTokStart, ); } this.next(); break; } } elts.push(this.parseExprListItem(allowEmpty, refExpressionErrors)); } return elts; } parseExprListItem( allowEmpty: ?boolean, refExpressionErrors?: ?ExpressionErrors, refNeedsArrowPos: ?Pos, allowPlaceholder: ?boolean, ): ?N.Expression { let elt; if (this.match(tt.comma)) { if (!allowEmpty) { this.raise(this.state.pos, Errors.UnexpectedToken, ","); } elt = null; } else if (this.match(tt.ellipsis)) { const spreadNodeStartPos = this.state.start; const spreadNodeStartLoc = this.state.startLoc; elt = this.parseParenItem( this.parseSpread(refExpressionErrors, refNeedsArrowPos), spreadNodeStartPos, spreadNodeStartLoc, ); } else if (this.match(tt.question)) { this.expectPlugin("partialApplication"); if (!allowPlaceholder) { this.raise(this.state.start, Errors.UnexpectedArgumentPlaceholder); } const node = this.startNode(); this.next(); elt = this.finishNode(node, "ArgumentPlaceholder"); } else { elt = this.parseMaybeAssign( false, refExpressionErrors, this.parseParenItem, refNeedsArrowPos, ); } return elt; } // Parse the next token as an identifier. If `liberal` is true (used // when parsing properties), it will also convert keywords into // identifiers. // This shouldn't be used to parse the keywords of meta properties, since they // are not identifiers and cannot contain escape sequences. parseIdentifier(liberal?: boolean): N.Identifier { const node = this.startNode(); const name = this.parseIdentifierName(node.start, liberal); return this.createIdentifier(node, name); } createIdentifier(node: N.Identifier, name: string): N.Identifier { node.name = name; node.loc.identifierName = name; return this.finishNode(node, "Identifier"); } parseIdentifierName(pos: number, liberal?: boolean): string { let name: string; if (this.match(tt.name)) { name = this.state.value; } else if (this.state.type.keyword) { name = this.state.type.keyword; // `class` and `function` keywords push function-type token context into this.context. // But there is no chance to pop the context if the keyword is consumed // as an identifier such as a property name. const context = this.state.context; if ( (name === "class" || name === "function") && context[context.length - 1].token === "function" ) { context.pop(); } } else { throw this.unexpected(); } if (liberal) { // If the current token is not used as a keyword, set its type to "tt.name". // This will prevent this.next() from throwing about unexpected escapes. this.state.type = tt.name; } else { this.checkReservedWord( name, this.state.start, !!this.state.type.keyword, false, ); } this.next(); return name; } checkReservedWord( word: string, startLoc: number, checkKeywords: boolean, isBinding: boolean, ): void { if (this.prodParam.hasYield && word === "yield") { this.raise(startLoc, Errors.YieldBindingIdentifier); return; } if (word === "await") { if (this.prodParam.hasAwait) { this.raise(startLoc, Errors.AwaitBindingIdentifier); return; } if ( this.state.awaitPos === -1 && (this.state.maybeInAsyncArrowHead || this.isAwaitAllowed()) ) { this.state.awaitPos = this.state.start; } } if ( this.scope.inClass && !this.scope.inNonArrowFunction && word === "arguments" ) { this.raise(startLoc, Errors.ArgumentsDisallowedInInitializer); return; } if (checkKeywords && isKeyword(word)) { this.raise(startLoc, Errors.UnexpectedKeyword, word); return; } const reservedTest = !this.state.strict ? isReservedWord : isBinding ? isStrictBindReservedWord : isStrictReservedWord; if (reservedTest(word, this.inModule)) { if (!this.prodParam.hasAwait && word === "await") { this.raise(startLoc, Errors.AwaitNotInAsyncFunction); } else { this.raise(startLoc, Errors.UnexpectedReservedWord, word); } } } isAwaitAllowed(): boolean { if (this.scope.inFunction) return this.prodParam.hasAwait; if (this.options.allowAwaitOutsideFunction) return true; if (this.hasPlugin("topLevelAwait")) { return this.inModule && this.prodParam.hasAwait; } return false; } // Parses await expression inside async function. parseAwait(): N.AwaitExpression { const node = this.startNode(); this.next(); if (this.state.inParameters) { this.raise(node.start, Errors.AwaitExpressionFormalParameter); } else if (this.state.awaitPos === -1) { this.state.awaitPos = node.start; } if (this.eat(tt.star)) { this.raise(node.start, Errors.ObsoleteAwaitStar); } if (!this.scope.inFunction && !this.options.allowAwaitOutsideFunction) { if ( this.hasPrecedingLineBreak() || // All the following expressions are ambiguous: // await + 0, await - 0, await ( 0 ), await [ 0 ], await / 0 /u, await `` this.match(tt.plusMin) || this.match(tt.parenL) || this.match(tt.bracketL) || this.match(tt.backQuote) || // Sometimes the tokenizer generates tt.slash for regexps, and this is // handler by parseExprAtom this.match(tt.regexp) || this.match(tt.slash) || // This code could be parsed both as a modulo operator or as an intrinsic: // await %x(0) (this.hasPlugin("v8intrinsic") && this.match(tt.modulo)) ) { this.ambiguousScriptDifferentAst = true; } else { this.sawUnambiguousESM = true; } } if (!this.state.soloAwait) { node.argument = this.parseMaybeUnary(); } return this.finishNode(node, "AwaitExpression"); } // Parses yield expression inside generator. parseYield(noIn?: ?boolean): N.YieldExpression { const node = this.startNode(); if (this.state.inParameters) { this.raise(node.start, Errors.YieldInParameter); } else if (this.state.yieldPos === -1) { this.state.yieldPos = node.start; } this.next(); if ( this.match(tt.semi) || (!this.match(tt.star) && !this.state.type.startsExpr) || this.hasPrecedingLineBreak() ) { node.delegate = false; node.argument = null; } else { node.delegate = this.eat(tt.star); node.argument = this.parseMaybeAssign(noIn); } return this.finishNode(node, "YieldExpression"); } // Validates a pipeline (for any of the pipeline Babylon plugins) at the point // of the infix operator `|>`. checkPipelineAtInfixOperator(left: N.Expression, leftStartPos: number) { if (this.getPluginOption("pipelineOperator", "proposal") === "smart") { if (left.type === "SequenceExpression") { // Ensure that the pipeline head is not a comma-delimited // sequence expression. this.raise(leftStartPos, Errors.PipelineHeadSequenceExpression); } } } parseSmartPipelineBody( childExpression: N.Expression, startPos: number, startLoc: Position, ): N.PipelineBody { const pipelineStyle = this.checkSmartPipelineBodyStyle(childExpression); this.checkSmartPipelineBodyEarlyErrors( childExpression, pipelineStyle, startPos, ); return this.parseSmartPipelineBodyInStyle( childExpression, pipelineStyle, startPos, startLoc, ); } checkSmartPipelineBodyEarlyErrors( childExpression: N.Expression, pipelineStyle: N.PipelineStyle, startPos: number, ): void { if (this.match(tt.arrow)) { // If the following token is invalidly `=>`, then throw a human-friendly error // instead of something like 'Unexpected token, expected ";"'. throw this.raise(this.state.start, Errors.PipelineBodyNoArrow); } else if ( pipelineStyle === "PipelineTopicExpression" && childExpression.type === "SequenceExpression" ) { this.raise(startPos, Errors.PipelineBodySequenceExpression); } } parseSmartPipelineBodyInStyle( childExpression: N.Expression, pipelineStyle: N.PipelineStyle, startPos: number, startLoc: Position, ): N.PipelineBody { const bodyNode = this.startNodeAt(startPos, startLoc); switch (pipelineStyle) { case "PipelineBareFunction": bodyNode.callee = childExpression; break; case "PipelineBareConstructor": bodyNode.callee = childExpression.callee; break; case "PipelineBareAwaitedFunction": bodyNode.callee = childExpression.argument; break; case "PipelineTopicExpression": if (!this.topicReferenceWasUsedInCurrentTopicContext()) { this.raise(startPos, Errors.PipelineTopicUnused); } bodyNode.expression = childExpression; break; default: throw new Error( `Internal @babel/parser error: Unknown pipeline style (${pipelineStyle})`, ); } return this.finishNode(bodyNode, pipelineStyle); } checkSmartPipelineBodyStyle(expression: N.Expression): N.PipelineStyle { switch (expression.type) { default: return this.isSimpleReference(expression) ? "PipelineBareFunction" : "PipelineTopicExpression"; } } isSimpleReference(expression: N.Expression): boolean { switch (expression.type) { case "MemberExpression": return ( !expression.computed && this.isSimpleReference(expression.object) ); case "Identifier": return true; default: return false; } } // Enable topic references from outer contexts within smart pipeline bodies. // The function modifies the parser's topic-context state to enable or disable // the use of topic references with the smartPipelines plugin. They then run a // callback, then they reset the parser to the old topic-context state that it // had before the function was called. withTopicPermittingContext(callback: () => T): T { const outerContextTopicState = this.state.topicContext; this.state.topicContext = { // Enable the use of the primary topic reference. maxNumOfResolvableTopics: 1, // Hide the use of any topic references from outer contexts. maxTopicIndex: null, }; try { return callback(); } finally { this.state.topicContext = outerContextTopicState; } } // Disable topic references from outer contexts within syntax constructs // such as the bodies of iteration statements. // The function modifies the parser's topic-context state to enable or disable // the use of topic references with the smartPipelines plugin. They then run a // callback, then they reset the parser to the old topic-context state that it // had before the function was called. withTopicForbiddingContext(callback: () => T): T { const outerContextTopicState = this.state.topicContext; this.state.topicContext = { // Disable the use of the primary topic reference. maxNumOfResolvableTopics: 0, // Hide the use of any topic references from outer contexts. maxTopicIndex: null, }; try { return callback(); } finally { this.state.topicContext = outerContextTopicState; } } withSoloAwaitPermittingContext(callback: () => T): T { const outerContextSoloAwaitState = this.state.soloAwait; this.state.soloAwait = true; try { return callback(); } finally { this.state.soloAwait = outerContextSoloAwaitState; } } // Register the use of a primary topic reference (`#`) within the current // topic context. registerTopicReference(): void { this.state.topicContext.maxTopicIndex = 0; } primaryTopicReferenceIsAllowedInCurrentTopicContext(): boolean { return this.state.topicContext.maxNumOfResolvableTopics >= 1; } topicReferenceWasUsedInCurrentTopicContext(): boolean { return ( this.state.topicContext.maxTopicIndex != null && this.state.topicContext.maxTopicIndex >= 0 ); } parseFSharpPipelineBody(prec: number, noIn: ?boolean): N.Expression { const startPos = this.state.start; const startLoc = this.state.startLoc; this.state.potentialArrowAt = this.state.start; const oldInFSharpPipelineDirectBody = this.state.inFSharpPipelineDirectBody; this.state.inFSharpPipelineDirectBody = true; const ret = this.parseExprOp( this.parseMaybeUnary(), startPos, startLoc, prec, noIn, ); this.state.inFSharpPipelineDirectBody = oldInFSharpPipelineDirectBody; return ret; } }