/* eslint max-len: 0 */ // 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 { flowParseArrow, flowParseFunctionBodyAndFinish, flowParseMaybeAssign, flowParseSubscript, flowParseSubscripts, flowParseVariance, flowStartParseAsyncArrowFromCallExpression, flowStartParseNewArguments, flowStartParseObjPropValue, } from "../plugins/flow"; import {jsxParseElement} from "../plugins/jsx/index"; import {typedParseConditional, typedParseParenItem} from "../plugins/types"; import { tsParseArrow, tsParseFunctionBodyAndFinish, tsParseMaybeAssign, tsParseSubscript, tsParseType, tsParseTypeAssertion, tsStartParseAsyncArrowFromCallExpression, tsStartParseObjPropValue, } from "../plugins/typescript"; import { eat, IdentifierRole, lookaheadCharCode, lookaheadType, match, next, nextTemplateToken, popTypeContext, pushTypeContext, rescan_gt, retokenizeSlashAsRegex, } from "../tokenizer/index"; import {ContextualKeyword} from "../tokenizer/keywords"; import {Scope} from "../tokenizer/state"; import {TokenType, TokenType as tt} from "../tokenizer/types"; import {charCodes} from "../util/charcodes"; import {IS_IDENTIFIER_START} from "../util/identifier"; import {getNextContextId, isFlowEnabled, isJSXEnabled, isTypeScriptEnabled, state} from "./base"; import { markPriorBindingIdentifier, parseBindingIdentifier, parseMaybeDefault, parseRest, parseSpread, } from "./lval"; import { parseBlock, parseBlockBody, parseClass, parseDecorators, parseFunction, parseFunctionParams, } from "./statement"; import { canInsertSemicolon, eatContextual, expect, expectContextual, hasFollowingLineBreak, hasPrecedingLineBreak, isContextual, unexpected, } from "./util"; export class StopState { constructor(stop) { this.stop = stop; } } // ### 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. export function parseExpression(noIn = false) { parseMaybeAssign(noIn); if (match(tt.comma)) { while (eat(tt.comma)) { parseMaybeAssign(noIn); } } } /** * noIn is used when parsing a for loop so that we don't interpret a following "in" as the binary * operatior. * isWithinParens is used to indicate that we're parsing something that might be a comma expression * or might be an arrow function or might be a Flow type assertion (which requires explicit parens). * In these cases, we should allow : and ?: after the initial "left" part. */ export function parseMaybeAssign(noIn = false, isWithinParens = false) { if (isTypeScriptEnabled) { return tsParseMaybeAssign(noIn, isWithinParens); } else if (isFlowEnabled) { return flowParseMaybeAssign(noIn, isWithinParens); } else { return baseParseMaybeAssign(noIn, isWithinParens); } } // Parse an assignment expression. This includes applications of // operators like `+=`. // Returns true if the expression was an arrow function. export function baseParseMaybeAssign(noIn, isWithinParens) { if (match(tt._yield)) { parseYield(); return false; } if (match(tt.parenL) || match(tt.name) || match(tt._yield)) { state.potentialArrowAt = state.start; } const wasArrow = parseMaybeConditional(noIn); if (isWithinParens) { parseParenItem(); } if (state.type & TokenType.IS_ASSIGN) { next(); parseMaybeAssign(noIn); return false; } return wasArrow; } // Parse a ternary conditional (`?:`) operator. // Returns true if the expression was an arrow function. function parseMaybeConditional(noIn) { const wasArrow = parseExprOps(noIn); if (wasArrow) { return true; } parseConditional(noIn); return false; } function parseConditional(noIn) { if (isTypeScriptEnabled || isFlowEnabled) { typedParseConditional(noIn); } else { baseParseConditional(noIn); } } export function baseParseConditional(noIn) { if (eat(tt.question)) { parseMaybeAssign(); expect(tt.colon); parseMaybeAssign(noIn); } } // Start the precedence parser. // Returns true if this was an arrow function function parseExprOps(noIn) { const startTokenIndex = state.tokens.length; const wasArrow = parseMaybeUnary(); if (wasArrow) { return true; } parseExprOp(startTokenIndex, -1, noIn); return false; } // 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. function parseExprOp(startTokenIndex, minPrec, noIn) { if ( isTypeScriptEnabled && (tt._in & TokenType.PRECEDENCE_MASK) > minPrec && !hasPrecedingLineBreak() && (eatContextual(ContextualKeyword._as) || eatContextual(ContextualKeyword._satisfies)) ) { const oldIsType = pushTypeContext(1); tsParseType(); popTypeContext(oldIsType); rescan_gt(); parseExprOp(startTokenIndex, minPrec, noIn); return; } const prec = state.type & TokenType.PRECEDENCE_MASK; if (prec > 0 && (!noIn || !match(tt._in))) { if (prec > minPrec) { const op = state.type; next(); if (op === tt.nullishCoalescing) { state.tokens[state.tokens.length - 1].nullishStartIndex = startTokenIndex; } const rhsStartTokenIndex = state.tokens.length; parseMaybeUnary(); // Extend the right operand of this operator if possible. parseExprOp(rhsStartTokenIndex, op & TokenType.IS_RIGHT_ASSOCIATIVE ? prec - 1 : prec, noIn); if (op === tt.nullishCoalescing) { state.tokens[startTokenIndex].numNullishCoalesceStarts++; state.tokens[state.tokens.length - 1].numNullishCoalesceEnds++; } // Continue with any future operator holding this expression as the left operand. parseExprOp(startTokenIndex, minPrec, noIn); } } } // Parse unary operators, both prefix and postfix. // Returns true if this was an arrow function. export function parseMaybeUnary() { if (isTypeScriptEnabled && !isJSXEnabled && eat(tt.lessThan)) { tsParseTypeAssertion(); return false; } if ( isContextual(ContextualKeyword._module) && lookaheadCharCode() === charCodes.leftCurlyBrace && !hasFollowingLineBreak() ) { parseModuleExpression(); return false; } if (state.type & TokenType.IS_PREFIX) { next(); parseMaybeUnary(); return false; } const wasArrow = parseExprSubscripts(); if (wasArrow) { return true; } while (state.type & TokenType.IS_POSTFIX && !canInsertSemicolon()) { // The tokenizer calls everything a preincrement, so make it a postincrement when // we see it in that context. if (state.type === tt.preIncDec) { state.type = tt.postIncDec; } next(); } return false; } // Parse call, dot, and `[]`-subscript expressions. // Returns true if this was an arrow function. export function parseExprSubscripts() { const startTokenIndex = state.tokens.length; const wasArrow = parseExprAtom(); if (wasArrow) { return true; } parseSubscripts(startTokenIndex); // If there was any optional chain operation, the start token would be marked // as such, so also mark the end now. if (state.tokens.length > startTokenIndex && state.tokens[startTokenIndex].isOptionalChainStart) { state.tokens[state.tokens.length - 1].isOptionalChainEnd = true; } return false; } function parseSubscripts(startTokenIndex, noCalls = false) { if (isFlowEnabled) { flowParseSubscripts(startTokenIndex, noCalls); } else { baseParseSubscripts(startTokenIndex, noCalls); } } export function baseParseSubscripts(startTokenIndex, noCalls = false) { const stopState = new StopState(false); do { parseSubscript(startTokenIndex, noCalls, stopState); } while (!stopState.stop && !state.error); } function parseSubscript(startTokenIndex, noCalls, stopState) { if (isTypeScriptEnabled) { tsParseSubscript(startTokenIndex, noCalls, stopState); } else if (isFlowEnabled) { flowParseSubscript(startTokenIndex, noCalls, stopState); } else { baseParseSubscript(startTokenIndex, noCalls, stopState); } } /** Set 'state.stop = true' to indicate that we should stop parsing subscripts. */ export function baseParseSubscript( startTokenIndex, noCalls, stopState, ) { if (!noCalls && eat(tt.doubleColon)) { parseNoCallExpr(); stopState.stop = true; // Propagate startTokenIndex so that `a::b?.()` will keep `a` as the first token. We may want // to revisit this in the future when fully supporting bind syntax. parseSubscripts(startTokenIndex, noCalls); } else if (match(tt.questionDot)) { state.tokens[startTokenIndex].isOptionalChainStart = true; if (noCalls && lookaheadType() === tt.parenL) { stopState.stop = true; return; } next(); state.tokens[state.tokens.length - 1].subscriptStartIndex = startTokenIndex; if (eat(tt.bracketL)) { parseExpression(); expect(tt.bracketR); } else if (eat(tt.parenL)) { parseCallExpressionArguments(); } else { parseMaybePrivateName(); } } else if (eat(tt.dot)) { state.tokens[state.tokens.length - 1].subscriptStartIndex = startTokenIndex; parseMaybePrivateName(); } else if (eat(tt.bracketL)) { state.tokens[state.tokens.length - 1].subscriptStartIndex = startTokenIndex; parseExpression(); expect(tt.bracketR); } else if (!noCalls && match(tt.parenL)) { if (atPossibleAsync()) { // We see "async", but it's possible it's a usage of the name "async". Parse as if it's a // function call, and if we see an arrow later, backtrack and re-parse as a parameter list. const snapshot = state.snapshot(); const asyncStartTokenIndex = state.tokens.length; next(); state.tokens[state.tokens.length - 1].subscriptStartIndex = startTokenIndex; const callContextId = getNextContextId(); state.tokens[state.tokens.length - 1].contextId = callContextId; parseCallExpressionArguments(); state.tokens[state.tokens.length - 1].contextId = callContextId; if (shouldParseAsyncArrow()) { // We hit an arrow, so backtrack and start again parsing function parameters. state.restoreFromSnapshot(snapshot); stopState.stop = true; state.scopeDepth++; parseFunctionParams(); parseAsyncArrowFromCallExpression(asyncStartTokenIndex); } } else { next(); state.tokens[state.tokens.length - 1].subscriptStartIndex = startTokenIndex; const callContextId = getNextContextId(); state.tokens[state.tokens.length - 1].contextId = callContextId; parseCallExpressionArguments(); state.tokens[state.tokens.length - 1].contextId = callContextId; } } else if (match(tt.backQuote)) { // Tagged template expression. parseTemplate(); } else { stopState.stop = true; } } export function atPossibleAsync() { // This was made less strict than the original version to avoid passing around nodes, but it // should be safe to have rare false positives here. return ( state.tokens[state.tokens.length - 1].contextualKeyword === ContextualKeyword._async && !canInsertSemicolon() ); } export function parseCallExpressionArguments() { let first = true; while (!eat(tt.parenR) && !state.error) { if (first) { first = false; } else { expect(tt.comma); if (eat(tt.parenR)) { break; } } parseExprListItem(false); } } function shouldParseAsyncArrow() { return match(tt.colon) || match(tt.arrow); } function parseAsyncArrowFromCallExpression(startTokenIndex) { if (isTypeScriptEnabled) { tsStartParseAsyncArrowFromCallExpression(); } else if (isFlowEnabled) { flowStartParseAsyncArrowFromCallExpression(); } expect(tt.arrow); parseArrowExpression(startTokenIndex); } // Parse a no-call expression (like argument of `new` or `::` operators). function parseNoCallExpr() { const startTokenIndex = state.tokens.length; parseExprAtom(); parseSubscripts(startTokenIndex, 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 `{}`. // Returns true if the parsed expression was an arrow function. export function parseExprAtom() { if (eat(tt.modulo)) { // V8 intrinsic expression. Just parse the identifier, and the function invocation is parsed // naturally. parseIdentifier(); return false; } if (match(tt.jsxText) || match(tt.jsxEmptyText)) { parseLiteral(); return false; } else if (match(tt.lessThan) && isJSXEnabled) { state.type = tt.jsxTagStart; jsxParseElement(); next(); return false; } const canBeArrow = state.potentialArrowAt === state.start; switch (state.type) { case tt.slash: case tt.assign: retokenizeSlashAsRegex(); // Fall through. case tt._super: case tt._this: case tt.regexp: case tt.num: case tt.bigint: case tt.decimal: case tt.string: case tt._null: case tt._true: case tt._false: next(); return false; case tt._import: next(); if (match(tt.dot)) { // import.meta state.tokens[state.tokens.length - 1].type = tt.name; next(); parseIdentifier(); } return false; case tt.name: { const startTokenIndex = state.tokens.length; const functionStart = state.start; const contextualKeyword = state.contextualKeyword; parseIdentifier(); if (contextualKeyword === ContextualKeyword._await) { parseAwait(); return false; } else if ( contextualKeyword === ContextualKeyword._async && match(tt._function) && !canInsertSemicolon() ) { next(); parseFunction(functionStart, false); return false; } else if ( canBeArrow && contextualKeyword === ContextualKeyword._async && !canInsertSemicolon() && match(tt.name) ) { state.scopeDepth++; parseBindingIdentifier(false); expect(tt.arrow); // let foo = async bar => {}; parseArrowExpression(startTokenIndex); return true; } else if (match(tt._do) && !canInsertSemicolon()) { next(); parseBlock(); return false; } if (canBeArrow && !canInsertSemicolon() && match(tt.arrow)) { state.scopeDepth++; markPriorBindingIdentifier(false); expect(tt.arrow); parseArrowExpression(startTokenIndex); return true; } state.tokens[state.tokens.length - 1].identifierRole = IdentifierRole.Access; return false; } case tt._do: { next(); parseBlock(); return false; } case tt.parenL: { const wasArrow = parseParenAndDistinguishExpression(canBeArrow); return wasArrow; } case tt.bracketL: next(); parseExprList(tt.bracketR, true); return false; case tt.braceL: parseObj(false, false); return false; case tt._function: parseFunctionExpression(); return false; case tt.at: parseDecorators(); // Fall through. case tt._class: parseClass(false); return false; case tt._new: parseNew(); return false; case tt.backQuote: parseTemplate(); return false; case tt.doubleColon: { next(); parseNoCallExpr(); return false; } case tt.hash: { const code = lookaheadCharCode(); if (IS_IDENTIFIER_START[code] || code === charCodes.backslash) { parseMaybePrivateName(); } else { next(); } // Smart pipeline topic reference. return false; } default: unexpected(); return false; } } function parseMaybePrivateName() { eat(tt.hash); parseIdentifier(); } function parseFunctionExpression() { const functionStart = state.start; parseIdentifier(); if (eat(tt.dot)) { // function.sent parseIdentifier(); } parseFunction(functionStart, false); } export function parseLiteral() { next(); } export function parseParenExpression() { expect(tt.parenL); parseExpression(); expect(tt.parenR); } // Returns true if this was an arrow expression. function parseParenAndDistinguishExpression(canBeArrow) { // Assume this is a normal parenthesized expression, but if we see an arrow, we'll bail and // start over as a parameter list. const snapshot = state.snapshot(); const startTokenIndex = state.tokens.length; expect(tt.parenL); let first = true; while (!match(tt.parenR) && !state.error) { if (first) { first = false; } else { expect(tt.comma); if (match(tt.parenR)) { break; } } if (match(tt.ellipsis)) { parseRest(false /* isBlockScope */); parseParenItem(); break; } else { parseMaybeAssign(false, true); } } expect(tt.parenR); if (canBeArrow && shouldParseArrow()) { const wasArrow = parseArrow(); if (wasArrow) { // It was an arrow function this whole time, so start over and parse it as params so that we // get proper token annotations. state.restoreFromSnapshot(snapshot); state.scopeDepth++; // Don't specify a context ID because arrow functions don't need a context ID. parseFunctionParams(); parseArrow(); parseArrowExpression(startTokenIndex); if (state.error) { // Nevermind! This must have been something that looks very much like an // arrow function but where its "parameter list" isn't actually a valid // parameter list. Force non-arrow parsing. // See https://github.com/alangpierce/sucrase/issues/666 for an example. state.restoreFromSnapshot(snapshot); parseParenAndDistinguishExpression(false); return false; } return true; } } return false; } function shouldParseArrow() { return match(tt.colon) || !canInsertSemicolon(); } // Returns whether there was an arrow token. export function parseArrow() { if (isTypeScriptEnabled) { return tsParseArrow(); } else if (isFlowEnabled) { return flowParseArrow(); } else { return eat(tt.arrow); } } function parseParenItem() { if (isTypeScriptEnabled || isFlowEnabled) { typedParseParenItem(); } } // 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. function parseNew() { expect(tt._new); if (eat(tt.dot)) { // new.target parseIdentifier(); return; } parseNewCallee(); if (isFlowEnabled) { flowStartParseNewArguments(); } if (eat(tt.parenL)) { parseExprList(tt.parenR); } } function parseNewCallee() { parseNoCallExpr(); eat(tt.questionDot); } export function parseTemplate() { // Finish `, read quasi nextTemplateToken(); // Finish quasi, read ${ nextTemplateToken(); while (!match(tt.backQuote) && !state.error) { expect(tt.dollarBraceL); parseExpression(); // Finish }, read quasi nextTemplateToken(); // Finish quasi, read either ${ or ` nextTemplateToken(); } next(); } // Parse an object literal or binding pattern. export function parseObj(isPattern, isBlockScope) { // Attach a context ID to the object open and close brace and each object key. const contextId = getNextContextId(); let first = true; next(); state.tokens[state.tokens.length - 1].contextId = contextId; while (!eat(tt.braceR) && !state.error) { if (first) { first = false; } else { expect(tt.comma); if (eat(tt.braceR)) { break; } } let isGenerator = false; if (match(tt.ellipsis)) { const previousIndex = state.tokens.length; parseSpread(); if (isPattern) { // Mark role when the only thing being spread over is an identifier. if (state.tokens.length === previousIndex + 2) { markPriorBindingIdentifier(isBlockScope); } if (eat(tt.braceR)) { break; } } continue; } if (!isPattern) { isGenerator = eat(tt.star); } if (!isPattern && isContextual(ContextualKeyword._async)) { if (isGenerator) unexpected(); parseIdentifier(); if ( match(tt.colon) || match(tt.parenL) || match(tt.braceR) || match(tt.eq) || match(tt.comma) ) { // This is a key called "async" rather than an async function. } else { if (match(tt.star)) { next(); isGenerator = true; } parsePropertyName(contextId); } } else { parsePropertyName(contextId); } parseObjPropValue(isPattern, isBlockScope, contextId); } state.tokens[state.tokens.length - 1].contextId = contextId; } function isGetterOrSetterMethod(isPattern) { // We go off of the next and don't bother checking if the node key is actually "get" or "set". // This lets us avoid generating a node, and should only make the validation worse. return ( !isPattern && (match(tt.string) || // get "string"() {} match(tt.num) || // get 1() {} match(tt.bracketL) || // get ["string"]() {} match(tt.name) || // get foo() {} !!(state.type & TokenType.IS_KEYWORD)) // get debugger() {} ); } // Returns true if this was a method. function parseObjectMethod(isPattern, objectContextId) { // We don't need to worry about modifiers because object methods can't have optional bodies, so // the start will never be used. const functionStart = state.start; if (match(tt.parenL)) { if (isPattern) unexpected(); parseMethod(functionStart, /* isConstructor */ false); return true; } if (isGetterOrSetterMethod(isPattern)) { parsePropertyName(objectContextId); parseMethod(functionStart, /* isConstructor */ false); return true; } return false; } function parseObjectProperty(isPattern, isBlockScope) { if (eat(tt.colon)) { if (isPattern) { parseMaybeDefault(isBlockScope); } else { parseMaybeAssign(false); } return; } // Since there's no colon, we assume this is an object shorthand. // If we're in a destructuring, we've now discovered that the key was actually an assignee, so // we need to tag it as a declaration with the appropriate scope. Otherwise, we might need to // transform it on access, so mark it as a normal object shorthand. let identifierRole; if (isPattern) { if (state.scopeDepth === 0) { identifierRole = IdentifierRole.ObjectShorthandTopLevelDeclaration; } else if (isBlockScope) { identifierRole = IdentifierRole.ObjectShorthandBlockScopedDeclaration; } else { identifierRole = IdentifierRole.ObjectShorthandFunctionScopedDeclaration; } } else { identifierRole = IdentifierRole.ObjectShorthand; } state.tokens[state.tokens.length - 1].identifierRole = identifierRole; // Regardless of whether we know this to be a pattern or if we're in an ambiguous context, allow // parsing as if there's a default value. parseMaybeDefault(isBlockScope, true); } function parseObjPropValue( isPattern, isBlockScope, objectContextId, ) { if (isTypeScriptEnabled) { tsStartParseObjPropValue(); } else if (isFlowEnabled) { flowStartParseObjPropValue(); } const wasMethod = parseObjectMethod(isPattern, objectContextId); if (!wasMethod) { parseObjectProperty(isPattern, isBlockScope); } } export function parsePropertyName(objectContextId) { if (isFlowEnabled) { flowParseVariance(); } if (eat(tt.bracketL)) { state.tokens[state.tokens.length - 1].contextId = objectContextId; parseMaybeAssign(); expect(tt.bracketR); state.tokens[state.tokens.length - 1].contextId = objectContextId; } else { if (match(tt.num) || match(tt.string) || match(tt.bigint) || match(tt.decimal)) { parseExprAtom(); } else { parseMaybePrivateName(); } state.tokens[state.tokens.length - 1].identifierRole = IdentifierRole.ObjectKey; state.tokens[state.tokens.length - 1].contextId = objectContextId; } } // Parse object or class method. export function parseMethod(functionStart, isConstructor) { const funcContextId = getNextContextId(); state.scopeDepth++; const startTokenIndex = state.tokens.length; const allowModifiers = isConstructor; // For TypeScript parameter properties parseFunctionParams(allowModifiers, funcContextId); parseFunctionBodyAndFinish(functionStart, funcContextId); const endTokenIndex = state.tokens.length; state.scopes.push(new Scope(startTokenIndex, endTokenIndex, true)); state.scopeDepth--; } // Parse arrow function expression. // If the parameters are provided, they will be converted to an // assignable list. export function parseArrowExpression(startTokenIndex) { parseFunctionBody(true); const endTokenIndex = state.tokens.length; state.scopes.push(new Scope(startTokenIndex, endTokenIndex, true)); state.scopeDepth--; } export function parseFunctionBodyAndFinish(functionStart, funcContextId = 0) { if (isTypeScriptEnabled) { tsParseFunctionBodyAndFinish(functionStart, funcContextId); } else if (isFlowEnabled) { flowParseFunctionBodyAndFinish(funcContextId); } else { parseFunctionBody(false, funcContextId); } } export function parseFunctionBody(allowExpression, funcContextId = 0) { const isExpression = allowExpression && !match(tt.braceL); if (isExpression) { parseMaybeAssign(); } else { parseBlock(true /* isFunctionScope */, funcContextId); } } // 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). function parseExprList(close, allowEmpty = false) { let first = true; while (!eat(close) && !state.error) { if (first) { first = false; } else { expect(tt.comma); if (eat(close)) break; } parseExprListItem(allowEmpty); } } function parseExprListItem(allowEmpty) { if (allowEmpty && match(tt.comma)) { // Empty item; nothing more to parse for this item. } else if (match(tt.ellipsis)) { parseSpread(); parseParenItem(); } else if (match(tt.question)) { // Partial function application proposal. next(); } else { parseMaybeAssign(false, true); } } // Parse the next token as an identifier. export function parseIdentifier() { next(); state.tokens[state.tokens.length - 1].type = tt.name; } // Parses await expression inside async function. function parseAwait() { parseMaybeUnary(); } // Parses yield expression inside generator. function parseYield() { next(); if (!match(tt.semi) && !canInsertSemicolon()) { eat(tt.star); parseMaybeAssign(); } } // https://github.com/tc39/proposal-js-module-blocks function parseModuleExpression() { expectContextual(ContextualKeyword._module); expect(tt.braceL); // For now, just call parseBlockBody to parse the block. In the future when we // implement full support, we'll want to emit scopes and possibly other // information. parseBlockBody(tt.braceR); }