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abrendan
2023-11-30 14:15:19 +00:00
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58
node_modules/acorn/src/bin/acorn.js generated vendored Normal file
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import {basename} from "path"
import {readFileSync as readFile} from "fs"
import * as acorn from "acorn"
let infile, forceFile, silent = false, compact = false, tokenize = false
const options = {}
function help(status) {
const print = (status == 0) ? console.log : console.error
print("usage: " + basename(process.argv[1]) + " [--ecma3|--ecma5|--ecma6|--ecma7]")
print(" [--tokenize] [--locations] [---allow-hash-bang] [--compact] [--silent] [--module] [--help] [--] [infile]")
process.exit(status)
}
for (let i = 2; i < process.argv.length; ++i) {
const arg = process.argv[i]
if ((arg == "-" || arg[0] != "-") && !infile) infile = arg
else if (arg == "--" && !infile && i + 2 == process.argv.length) forceFile = infile = process.argv[++i]
else if (arg == "--ecma3") options.ecmaVersion = 3
else if (arg == "--ecma5") options.ecmaVersion = 5
else if (arg == "--ecma6") options.ecmaVersion = 6
else if (arg == "--ecma7") options.ecmaVersion = 7
else if (arg == "--locations") options.locations = true
else if (arg == "--allow-hash-bang") options.allowHashBang = true
else if (arg == "--silent") silent = true
else if (arg == "--compact") compact = true
else if (arg == "--help") help(0)
else if (arg == "--tokenize") tokenize = true
else if (arg == "--module") options.sourceType = 'module'
else help(1)
}
function run(code) {
let result
if (!tokenize) {
try { result = acorn.parse(code, options) }
catch(e) { console.error(e.message); process.exit(1) }
} else {
result = []
let tokenizer = acorn.tokenizer(code, options), token
while (true) {
try { token = tokenizer.getToken() }
catch(e) { console.error(e.message); process.exit(1) }
result.push(token)
if (token.type == acorn.tokTypes.eof) break
}
}
if (!silent) console.log(JSON.stringify(result, null, compact ? null : 2))
}
if (forceFile || infile && infile != "-") {
run(readFile(infile, "utf8"))
} else {
let code = ""
process.stdin.resume()
process.stdin.on("data", chunk => code += chunk)
process.stdin.on("end", () => run(code))
}

701
node_modules/acorn/src/expression.js generated vendored Normal file
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// 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} from "./tokentype"
import {Parser} from "./state"
import {DestructuringErrors} from "./parseutil"
const pp = Parser.prototype
// Check if property name clashes with already added.
// Object/class getters and setters are not allowed to clash —
// either with each other or with an init property — and in
// strict mode, init properties are also not allowed to be repeated.
pp.checkPropClash = function(prop, propHash) {
if (this.options.ecmaVersion >= 6 && (prop.computed || prop.method || prop.shorthand))
return
let {key} = prop, name
switch (key.type) {
case "Identifier": name = key.name; break
case "Literal": name = String(key.value); break
default: return
}
let {kind} = prop
if (this.options.ecmaVersion >= 6) {
if (name === "__proto__" && kind === "init") {
if (propHash.proto) this.raiseRecoverable(key.start, "Redefinition of __proto__ property")
propHash.proto = true
}
return
}
name = "$" + name
let other = propHash[name]
if (other) {
let isGetSet = kind !== "init"
if ((this.strict || isGetSet) && other[kind] || !(isGetSet ^ other.init))
this.raiseRecoverable(key.start, "Redefinition of property")
} else {
other = propHash[name] = {
init: false,
get: false,
set: false
}
}
other[kind] = true
}
// ### 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. The optional arguments are used to
// forbid the `in` operator (in for loops initalization expressions)
// and provide 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).
pp.parseExpression = function(noIn, refDestructuringErrors) {
let startPos = this.start, startLoc = this.startLoc
let expr = this.parseMaybeAssign(noIn, refDestructuringErrors)
if (this.type === tt.comma) {
let node = this.startNodeAt(startPos, startLoc)
node.expressions = [expr]
while (this.eat(tt.comma)) node.expressions.push(this.parseMaybeAssign(noIn, refDestructuringErrors))
return this.finishNode(node, "SequenceExpression")
}
return expr
}
// Parse an assignment expression. This includes applications of
// operators like `+=`.
pp.parseMaybeAssign = function(noIn, refDestructuringErrors, afterLeftParse) {
if (this.inGenerator && this.isContextual("yield")) return this.parseYield()
let ownDestructuringErrors = false
if (!refDestructuringErrors) {
refDestructuringErrors = new DestructuringErrors
ownDestructuringErrors = true
}
let startPos = this.start, startLoc = this.startLoc
if (this.type == tt.parenL || this.type == tt.name)
this.potentialArrowAt = this.start
let left = this.parseMaybeConditional(noIn, refDestructuringErrors)
if (afterLeftParse) left = afterLeftParse.call(this, left, startPos, startLoc)
if (this.type.isAssign) {
this.checkPatternErrors(refDestructuringErrors, true)
if (!ownDestructuringErrors) DestructuringErrors.call(refDestructuringErrors)
let node = this.startNodeAt(startPos, startLoc)
node.operator = this.value
node.left = this.type === tt.eq ? this.toAssignable(left) : left
refDestructuringErrors.shorthandAssign = 0 // reset because shorthand default was used correctly
this.checkLVal(left)
this.next()
node.right = this.parseMaybeAssign(noIn)
return this.finishNode(node, "AssignmentExpression")
} else {
if (ownDestructuringErrors) this.checkExpressionErrors(refDestructuringErrors, true)
}
return left
}
// Parse a ternary conditional (`?:`) operator.
pp.parseMaybeConditional = function(noIn, refDestructuringErrors) {
let startPos = this.start, startLoc = this.startLoc
let expr = this.parseExprOps(noIn, refDestructuringErrors)
if (this.checkExpressionErrors(refDestructuringErrors)) return expr
if (this.eat(tt.question)) {
let 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.
pp.parseExprOps = function(noIn, refDestructuringErrors) {
let startPos = this.start, startLoc = this.startLoc
let expr = this.parseMaybeUnary(refDestructuringErrors, false)
if (this.checkExpressionErrors(refDestructuringErrors)) 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.
pp.parseExprOp = function(left, leftStartPos, leftStartLoc, minPrec, noIn) {
let prec = this.type.binop
if (prec != null && (!noIn || this.type !== tt._in)) {
if (prec > minPrec) {
let logical = this.type === tt.logicalOR || this.type === tt.logicalAND
let op = this.value
this.next()
let startPos = this.start, startLoc = this.startLoc
let right = this.parseExprOp(this.parseMaybeUnary(null, false), startPos, startLoc, prec, noIn)
let node = this.buildBinary(leftStartPos, leftStartLoc, left, right, op, logical)
return this.parseExprOp(node, leftStartPos, leftStartLoc, minPrec, noIn)
}
}
return left
}
pp.buildBinary = function(startPos, startLoc, left, right, op, logical) {
let node = this.startNodeAt(startPos, startLoc)
node.left = left
node.operator = op
node.right = right
return this.finishNode(node, logical ? "LogicalExpression" : "BinaryExpression")
}
// Parse unary operators, both prefix and postfix.
pp.parseMaybeUnary = function(refDestructuringErrors, sawUnary) {
let startPos = this.start, startLoc = this.startLoc, expr
if (this.type.prefix) {
let node = this.startNode(), update = this.type === tt.incDec
node.operator = this.value
node.prefix = true
this.next()
node.argument = this.parseMaybeUnary(null, true)
this.checkExpressionErrors(refDestructuringErrors, true)
if (update) this.checkLVal(node.argument)
else if (this.strict && node.operator === "delete" &&
node.argument.type === "Identifier")
this.raiseRecoverable(node.start, "Deleting local variable in strict mode")
else sawUnary = true
expr = this.finishNode(node, update ? "UpdateExpression" : "UnaryExpression")
} else {
expr = this.parseExprSubscripts(refDestructuringErrors)
if (this.checkExpressionErrors(refDestructuringErrors)) return expr
while (this.type.postfix && !this.canInsertSemicolon()) {
let node = this.startNodeAt(startPos, startLoc)
node.operator = this.value
node.prefix = false
node.argument = expr
this.checkLVal(expr)
this.next()
expr = this.finishNode(node, "UpdateExpression")
}
}
if (!sawUnary && this.eat(tt.starstar))
return this.buildBinary(startPos, startLoc, expr, this.parseMaybeUnary(null, false), "**", false)
else
return expr
}
// Parse call, dot, and `[]`-subscript expressions.
pp.parseExprSubscripts = function(refDestructuringErrors) {
let startPos = this.start, startLoc = this.startLoc
let expr = this.parseExprAtom(refDestructuringErrors)
let skipArrowSubscripts = expr.type === "ArrowFunctionExpression" && this.input.slice(this.lastTokStart, this.lastTokEnd) !== ")"
if (this.checkExpressionErrors(refDestructuringErrors) || skipArrowSubscripts) return expr
return this.parseSubscripts(expr, startPos, startLoc)
}
pp.parseSubscripts = function(base, startPos, startLoc, noCalls) {
for (;;) {
if (this.eat(tt.dot)) {
let node = this.startNodeAt(startPos, startLoc)
node.object = base
node.property = this.parseIdent(true)
node.computed = false
base = this.finishNode(node, "MemberExpression")
} else if (this.eat(tt.bracketL)) {
let node = this.startNodeAt(startPos, startLoc)
node.object = base
node.property = this.parseExpression()
node.computed = true
this.expect(tt.bracketR)
base = this.finishNode(node, "MemberExpression")
} else if (!noCalls && this.eat(tt.parenL)) {
let node = this.startNodeAt(startPos, startLoc)
node.callee = base
node.arguments = this.parseExprList(tt.parenR, false)
base = this.finishNode(node, "CallExpression")
} else if (this.type === tt.backQuote) {
let node = this.startNodeAt(startPos, startLoc)
node.tag = base
node.quasi = this.parseTemplate()
base = this.finishNode(node, "TaggedTemplateExpression")
} else {
return base
}
}
}
// 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 `{}`.
pp.parseExprAtom = function(refDestructuringErrors) {
let node, canBeArrow = this.potentialArrowAt == this.start
switch (this.type) {
case tt._super:
if (!this.inFunction)
this.raise(this.start, "'super' outside of function or class")
case tt._this:
let type = this.type === tt._this ? "ThisExpression" : "Super"
node = this.startNode()
this.next()
return this.finishNode(node, type)
case tt.name:
let startPos = this.start, startLoc = this.startLoc
let id = this.parseIdent(this.type !== tt.name)
if (canBeArrow && !this.canInsertSemicolon() && this.eat(tt.arrow))
return this.parseArrowExpression(this.startNodeAt(startPos, startLoc), [id])
return id
case tt.regexp:
let value = this.value
node = this.parseLiteral(value.value)
node.regex = {pattern: value.pattern, flags: value.flags}
return node
case tt.num: case tt.string:
return this.parseLiteral(this.value)
case tt._null: case tt._true: case tt._false:
node = this.startNode()
node.value = this.type === tt._null ? null : this.type === tt._true
node.raw = this.type.keyword
this.next()
return this.finishNode(node, "Literal")
case tt.parenL:
return this.parseParenAndDistinguishExpression(canBeArrow)
case tt.bracketL:
node = this.startNode()
this.next()
node.elements = this.parseExprList(tt.bracketR, true, true, refDestructuringErrors)
return this.finishNode(node, "ArrayExpression")
case tt.braceL:
return this.parseObj(false, refDestructuringErrors)
case tt._function:
node = this.startNode()
this.next()
return this.parseFunction(node, false)
case tt._class:
return this.parseClass(this.startNode(), false)
case tt._new:
return this.parseNew()
case tt.backQuote:
return this.parseTemplate()
default:
this.unexpected()
}
}
pp.parseLiteral = function(value) {
let node = this.startNode()
node.value = value
node.raw = this.input.slice(this.start, this.end)
this.next()
return this.finishNode(node, "Literal")
}
pp.parseParenExpression = function() {
this.expect(tt.parenL)
let val = this.parseExpression()
this.expect(tt.parenR)
return val
}
pp.parseParenAndDistinguishExpression = function(canBeArrow) {
let startPos = this.start, startLoc = this.startLoc, val
if (this.options.ecmaVersion >= 6) {
this.next()
let innerStartPos = this.start, innerStartLoc = this.startLoc
let exprList = [], first = true
let refDestructuringErrors = new DestructuringErrors, spreadStart, innerParenStart
while (this.type !== tt.parenR) {
first ? first = false : this.expect(tt.comma)
if (this.type === tt.ellipsis) {
spreadStart = this.start
exprList.push(this.parseParenItem(this.parseRest()))
break
} else {
if (this.type === tt.parenL && !innerParenStart) {
innerParenStart = this.start
}
exprList.push(this.parseMaybeAssign(false, refDestructuringErrors, this.parseParenItem))
}
}
let innerEndPos = this.start, innerEndLoc = this.startLoc
this.expect(tt.parenR)
if (canBeArrow && !this.canInsertSemicolon() && this.eat(tt.arrow)) {
this.checkPatternErrors(refDestructuringErrors, true)
if (innerParenStart) this.unexpected(innerParenStart)
return this.parseParenArrowList(startPos, startLoc, exprList)
}
if (!exprList.length) this.unexpected(this.lastTokStart)
if (spreadStart) this.unexpected(spreadStart)
this.checkExpressionErrors(refDestructuringErrors, true)
if (exprList.length > 1) {
val = this.startNodeAt(innerStartPos, innerStartLoc)
val.expressions = exprList
this.finishNodeAt(val, "SequenceExpression", innerEndPos, innerEndLoc)
} else {
val = exprList[0]
}
} else {
val = this.parseParenExpression()
}
if (this.options.preserveParens) {
let par = this.startNodeAt(startPos, startLoc)
par.expression = val
return this.finishNode(par, "ParenthesizedExpression")
} else {
return val
}
}
pp.parseParenItem = function(item) {
return item
}
pp.parseParenArrowList = function(startPos, startLoc, exprList) {
return this.parseArrowExpression(this.startNodeAt(startPos, startLoc), exprList)
}
// 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.
const empty = []
pp.parseNew = function() {
let node = this.startNode()
let meta = this.parseIdent(true)
if (this.options.ecmaVersion >= 6 && this.eat(tt.dot)) {
node.meta = meta
node.property = this.parseIdent(true)
if (node.property.name !== "target")
this.raiseRecoverable(node.property.start, "The only valid meta property for new is new.target")
if (!this.inFunction)
this.raiseRecoverable(node.start, "new.target can only be used in functions")
return this.finishNode(node, "MetaProperty")
}
let startPos = this.start, startLoc = this.startLoc
node.callee = this.parseSubscripts(this.parseExprAtom(), startPos, startLoc, true)
if (this.eat(tt.parenL)) node.arguments = this.parseExprList(tt.parenR, false)
else node.arguments = empty
return this.finishNode(node, "NewExpression")
}
// Parse template expression.
pp.parseTemplateElement = function() {
let elem = this.startNode()
elem.value = {
raw: this.input.slice(this.start, this.end).replace(/\r\n?/g, '\n'),
cooked: this.value
}
this.next()
elem.tail = this.type === tt.backQuote
return this.finishNode(elem, "TemplateElement")
}
pp.parseTemplate = function() {
let node = this.startNode()
this.next()
node.expressions = []
let curElt = this.parseTemplateElement()
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())
}
this.next()
return this.finishNode(node, "TemplateLiteral")
}
// Parse an object literal or binding pattern.
pp.parseObj = function(isPattern, refDestructuringErrors) {
let node = this.startNode(), first = true, propHash = {}
node.properties = []
this.next()
while (!this.eat(tt.braceR)) {
if (!first) {
this.expect(tt.comma)
if (this.afterTrailingComma(tt.braceR)) break
} else first = false
let prop = this.startNode(), isGenerator, startPos, startLoc
if (this.options.ecmaVersion >= 6) {
prop.method = false
prop.shorthand = false
if (isPattern || refDestructuringErrors) {
startPos = this.start
startLoc = this.startLoc
}
if (!isPattern)
isGenerator = this.eat(tt.star)
}
this.parsePropertyName(prop)
this.parsePropertyValue(prop, isPattern, isGenerator, startPos, startLoc, refDestructuringErrors)
this.checkPropClash(prop, propHash)
node.properties.push(this.finishNode(prop, "Property"))
}
return this.finishNode(node, isPattern ? "ObjectPattern" : "ObjectExpression")
}
pp.parsePropertyValue = function(prop, isPattern, isGenerator, startPos, startLoc, refDestructuringErrors) {
if (this.eat(tt.colon)) {
prop.value = isPattern ? this.parseMaybeDefault(this.start, this.startLoc) : this.parseMaybeAssign(false, refDestructuringErrors)
prop.kind = "init"
} else if (this.options.ecmaVersion >= 6 && this.type === tt.parenL) {
if (isPattern) this.unexpected()
prop.kind = "init"
prop.method = true
prop.value = this.parseMethod(isGenerator)
} else if (this.options.ecmaVersion >= 5 && !prop.computed && prop.key.type === "Identifier" &&
(prop.key.name === "get" || prop.key.name === "set") &&
(this.type != tt.comma && this.type != tt.braceR)) {
if (isGenerator || isPattern) this.unexpected()
prop.kind = prop.key.name
this.parsePropertyName(prop)
prop.value = this.parseMethod(false)
let paramCount = prop.kind === "get" ? 0 : 1
if (prop.value.params.length !== paramCount) {
let start = prop.value.start
if (prop.kind === "get")
this.raiseRecoverable(start, "getter should have no params")
else
this.raiseRecoverable(start, "setter should have exactly one param")
}
if (prop.kind === "set" && prop.value.params[0].type === "RestElement")
this.raiseRecoverable(prop.value.params[0].start, "Setter cannot use rest params")
} else if (this.options.ecmaVersion >= 6 && !prop.computed && prop.key.type === "Identifier") {
if (this.keywords.test(prop.key.name) ||
(this.strict ? this.reservedWordsStrictBind : this.reservedWords).test(prop.key.name) ||
(this.inGenerator && prop.key.name == "yield"))
this.raiseRecoverable(prop.key.start, "'" + prop.key.name + "' can not be used as shorthand property")
prop.kind = "init"
if (isPattern) {
prop.value = this.parseMaybeDefault(startPos, startLoc, prop.key)
} else if (this.type === tt.eq && refDestructuringErrors) {
if (!refDestructuringErrors.shorthandAssign)
refDestructuringErrors.shorthandAssign = this.start
prop.value = this.parseMaybeDefault(startPos, startLoc, prop.key)
} else {
prop.value = prop.key
}
prop.shorthand = true
} else this.unexpected()
}
pp.parsePropertyName = function(prop) {
if (this.options.ecmaVersion >= 6) {
if (this.eat(tt.bracketL)) {
prop.computed = true
prop.key = this.parseMaybeAssign()
this.expect(tt.bracketR)
return prop.key
} else {
prop.computed = false
}
}
return prop.key = this.type === tt.num || this.type === tt.string ? this.parseExprAtom() : this.parseIdent(true)
}
// Initialize empty function node.
pp.initFunction = function(node) {
node.id = null
if (this.options.ecmaVersion >= 6) {
node.generator = false
node.expression = false
}
}
// Parse object or class method.
pp.parseMethod = function(isGenerator) {
let node = this.startNode(), oldInGen = this.inGenerator
this.inGenerator = isGenerator
this.initFunction(node)
this.expect(tt.parenL)
node.params = this.parseBindingList(tt.parenR, false, false)
if (this.options.ecmaVersion >= 6)
node.generator = isGenerator
this.parseFunctionBody(node, false)
this.inGenerator = oldInGen
return this.finishNode(node, "FunctionExpression")
}
// Parse arrow function expression with given parameters.
pp.parseArrowExpression = function(node, params) {
let oldInGen = this.inGenerator
this.inGenerator = false
this.initFunction(node)
node.params = this.toAssignableList(params, true)
this.parseFunctionBody(node, true)
this.inGenerator = oldInGen
return this.finishNode(node, "ArrowFunctionExpression")
}
// Parse function body and check parameters.
pp.parseFunctionBody = function(node, isArrowFunction) {
let isExpression = isArrowFunction && this.type !== tt.braceL
if (isExpression) {
node.body = this.parseMaybeAssign()
node.expression = true
} else {
// Start a new scope with regard to labels and the `inFunction`
// flag (restore them to their old value afterwards).
let oldInFunc = this.inFunction, oldLabels = this.labels
this.inFunction = true; this.labels = []
node.body = this.parseBlock(true)
node.expression = false
this.inFunction = oldInFunc; this.labels = oldLabels
}
// If this is a strict mode function, verify that argument names
// are not repeated, and it does not try to bind the words `eval`
// or `arguments`.
let useStrict = (!isExpression && node.body.body.length && this.isUseStrict(node.body.body[0])) ? node.body.body[0] : null;
if (this.strict || useStrict) {
let oldStrict = this.strict
this.strict = true
if (node.id)
this.checkLVal(node.id, true)
this.checkParams(node, useStrict)
this.strict = oldStrict
} else if (isArrowFunction) {
this.checkParams(node, useStrict)
}
}
// Checks function params for various disallowed patterns such as using "eval"
// or "arguments" and duplicate parameters.
pp.checkParams = function(node, useStrict) {
let nameHash = {}
for (let i = 0; i < node.params.length; i++) {
if (useStrict && this.options.ecmaVersion >= 7 && node.params[i].type !== "Identifier")
this.raiseRecoverable(useStrict.start, "Illegal 'use strict' directive in function with non-simple parameter list");
this.checkLVal(node.params[i], true, nameHash)
}
}
// 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).
pp.parseExprList = function(close, allowTrailingComma, allowEmpty, refDestructuringErrors) {
let elts = [], first = true
while (!this.eat(close)) {
if (!first) {
this.expect(tt.comma)
if (allowTrailingComma && this.afterTrailingComma(close)) break
} else first = false
let elt
if (allowEmpty && this.type === tt.comma)
elt = null
else if (this.type === tt.ellipsis) {
elt = this.parseSpread(refDestructuringErrors)
if (this.type === tt.comma && refDestructuringErrors && !refDestructuringErrors.trailingComma) {
refDestructuringErrors.trailingComma = this.lastTokStart
}
} else
elt = this.parseMaybeAssign(false, refDestructuringErrors)
elts.push(elt)
}
return elts
}
// Parse the next token as an identifier. If `liberal` is true (used
// when parsing properties), it will also convert keywords into
// identifiers.
pp.parseIdent = function(liberal) {
let node = this.startNode()
if (liberal && this.options.allowReserved == "never") liberal = false
if (this.type === tt.name) {
if (!liberal && (this.strict ? this.reservedWordsStrict : this.reservedWords).test(this.value) &&
(this.options.ecmaVersion >= 6 ||
this.input.slice(this.start, this.end).indexOf("\\") == -1))
this.raiseRecoverable(this.start, "The keyword '" + this.value + "' is reserved")
if (!liberal && this.inGenerator && this.value === "yield")
this.raiseRecoverable(this.start, "Can not use 'yield' as identifier inside a generator")
node.name = this.value
} else if (liberal && this.type.keyword) {
node.name = this.type.keyword
} else {
this.unexpected()
}
this.next()
return this.finishNode(node, "Identifier")
}
// Parses yield expression inside generator.
pp.parseYield = function() {
let node = this.startNode()
this.next()
if (this.type == tt.semi || this.canInsertSemicolon() || (this.type != tt.star && !this.type.startsExpr)) {
node.delegate = false
node.argument = null
} else {
node.delegate = this.eat(tt.star)
node.argument = this.parseMaybeAssign()
}
return this.finishNode(node, "YieldExpression")
}

82
node_modules/acorn/src/identifier.js generated vendored Normal file
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@@ -0,0 +1,82 @@
// Reserved word lists for various dialects of the language
export const reservedWords = {
3: "abstract boolean byte char class double enum export extends final float goto implements import int interface long native package private protected public short static super synchronized throws transient volatile",
5: "class enum extends super const export import",
6: "enum",
7: "enum",
strict: "implements interface let package private protected public static yield",
strictBind: "eval arguments"
}
// And the keywords
var ecma5AndLessKeywords = "break case catch continue debugger default do else finally for function if return switch throw try var while with null true false instanceof typeof void delete new in this"
export const keywords = {
5: ecma5AndLessKeywords,
6: ecma5AndLessKeywords + " const class extends export import super"
}
// ## Character categories
// Big ugly regular expressions that match characters in the
// whitespace, identifier, and identifier-start categories. These
// are only applied when a character is found to actually have a
// code point above 128.
// Generated by `bin/generate-identifier-regex.js`.
let nonASCIIidentifierStartChars = "\xaa\xb5\xba\xc0-\xd6\xd8-\xf6\xf8-\u02c1\u02c6-\u02d1\u02e0-\u02e4\u02ec\u02ee\u0370-\u0374\u0376\u0377\u037a-\u037d\u037f\u0386\u0388-\u038a\u038c\u038e-\u03a1\u03a3-\u03f5\u03f7-\u0481\u048a-\u052f\u0531-\u0556\u0559\u0561-\u0587\u05d0-\u05ea\u05f0-\u05f2\u0620-\u064a\u066e\u066f\u0671-\u06d3\u06d5\u06e5\u06e6\u06ee\u06ef\u06fa-\u06fc\u06ff\u0710\u0712-\u072f\u074d-\u07a5\u07b1\u07ca-\u07ea\u07f4\u07f5\u07fa\u0800-\u0815\u081a\u0824\u0828\u0840-\u0858\u08a0-\u08b4\u08b6-\u08bd\u0904-\u0939\u093d\u0950\u0958-\u0961\u0971-\u0980\u0985-\u098c\u098f\u0990\u0993-\u09a8\u09aa-\u09b0\u09b2\u09b6-\u09b9\u09bd\u09ce\u09dc\u09dd\u09df-\u09e1\u09f0\u09f1\u0a05-\u0a0a\u0a0f\u0a10\u0a13-\u0a28\u0a2a-\u0a30\u0a32\u0a33\u0a35\u0a36\u0a38\u0a39\u0a59-\u0a5c\u0a5e\u0a72-\u0a74\u0a85-\u0a8d\u0a8f-\u0a91\u0a93-\u0aa8\u0aaa-\u0ab0\u0ab2\u0ab3\u0ab5-\u0ab9\u0abd\u0ad0\u0ae0\u0ae1\u0af9\u0b05-\u0b0c\u0b0f\u0b10\u0b13-\u0b28\u0b2a-\u0b30\u0b32\u0b33\u0b35-\u0b39\u0b3d\u0b5c\u0b5d\u0b5f-\u0b61\u0b71\u0b83\u0b85-\u0b8a\u0b8e-\u0b90\u0b92-\u0b95\u0b99\u0b9a\u0b9c\u0b9e\u0b9f\u0ba3\u0ba4\u0ba8-\u0baa\u0bae-\u0bb9\u0bd0\u0c05-\u0c0c\u0c0e-\u0c10\u0c12-\u0c28\u0c2a-\u0c39\u0c3d\u0c58-\u0c5a\u0c60\u0c61\u0c80\u0c85-\u0c8c\u0c8e-\u0c90\u0c92-\u0ca8\u0caa-\u0cb3\u0cb5-\u0cb9\u0cbd\u0cde\u0ce0\u0ce1\u0cf1\u0cf2\u0d05-\u0d0c\u0d0e-\u0d10\u0d12-\u0d3a\u0d3d\u0d4e\u0d54-\u0d56\u0d5f-\u0d61\u0d7a-\u0d7f\u0d85-\u0d96\u0d9a-\u0db1\u0db3-\u0dbb\u0dbd\u0dc0-\u0dc6\u0e01-\u0e30\u0e32\u0e33\u0e40-\u0e46\u0e81\u0e82\u0e84\u0e87\u0e88\u0e8a\u0e8d\u0e94-\u0e97\u0e99-\u0e9f\u0ea1-\u0ea3\u0ea5\u0ea7\u0eaa\u0eab\u0ead-\u0eb0\u0eb2\u0eb3\u0ebd\u0ec0-\u0ec4\u0ec6\u0edc-\u0edf\u0f00\u0f40-\u0f47\u0f49-\u0f6c\u0f88-\u0f8c\u1000-\u102a\u103f\u1050-\u1055\u105a-\u105d\u1061\u1065\u1066\u106e-\u1070\u1075-\u1081\u108e\u10a0-\u10c5\u10c7\u10cd\u10d0-\u10fa\u10fc-\u1248\u124a-\u124d\u1250-\u1256\u1258\u125a-\u125d\u1260-\u1288\u128a-\u128d\u1290-\u12b0\u12b2-\u12b5\u12b8-\u12be\u12c0\u12c2-\u12c5\u12c8-\u12d6\u12d8-\u1310\u1312-\u1315\u1318-\u135a\u1380-\u138f\u13a0-\u13f5\u13f8-\u13fd\u1401-\u166c\u166f-\u167f\u1681-\u169a\u16a0-\u16ea\u16ee-\u16f8\u1700-\u170c\u170e-\u1711\u1720-\u1731\u1740-\u1751\u1760-\u176c\u176e-\u1770\u1780-\u17b3\u17d7\u17dc\u1820-\u1877\u1880-\u18a8\u18aa\u18b0-\u18f5\u1900-\u191e\u1950-\u196d\u1970-\u1974\u1980-\u19ab\u19b0-\u19c9\u1a00-\u1a16\u1a20-\u1a54\u1aa7\u1b05-\u1b33\u1b45-\u1b4b\u1b83-\u1ba0\u1bae\u1baf\u1bba-\u1be5\u1c00-\u1c23\u1c4d-\u1c4f\u1c5a-\u1c7d\u1c80-\u1c88\u1ce9-\u1cec\u1cee-\u1cf1\u1cf5\u1cf6\u1d00-\u1dbf\u1e00-\u1f15\u1f18-\u1f1d\u1f20-\u1f45\u1f48-\u1f4d\u1f50-\u1f57\u1f59\u1f5b\u1f5d\u1f5f-\u1f7d\u1f80-\u1fb4\u1fb6-\u1fbc\u1fbe\u1fc2-\u1fc4\u1fc6-\u1fcc\u1fd0-\u1fd3\u1fd6-\u1fdb\u1fe0-\u1fec\u1ff2-\u1ff4\u1ff6-\u1ffc\u2071\u207f\u2090-\u209c\u2102\u2107\u210a-\u2113\u2115\u2118-\u211d\u2124\u2126\u2128\u212a-\u2139\u213c-\u213f\u2145-\u2149\u214e\u2160-\u2188\u2c00-\u2c2e\u2c30-\u2c5e\u2c60-\u2ce4\u2ceb-\u2cee\u2cf2\u2cf3\u2d00-\u2d25\u2d27\u2d2d\u2d30-\u2d67\u2d6f\u2d80-\u2d96\u2da0-\u2da6\u2da8-\u2dae\u2db0-\u2db6\u2db8-\u2dbe\u2dc0-\u2dc6\u2dc8-\u2dce\u2dd0-\u2dd6\u2dd8-\u2dde\u3005-\u3007\u3021-\u3029\u3031-\u3035\u3038-\u303c\u3041-\u3096\u309b-\u309f\u30a1-\u30fa\u30fc-\u30ff\u3105-\u312d\u3131-\u318e\u31a0-\u31ba\u31f0-\u31ff\u3400-\u4db5\u4e00-\u9fd5\ua000-\ua48c\ua4d0-\ua4fd\ua500-\ua60c\ua610-\ua61f\ua62a\ua62b\ua640-\ua66e\ua67f-\ua69d\ua6a0-\ua6ef\ua717-\ua71f\ua722-\ua788\ua78b-\ua7ae\ua7b0-\ua7b7\ua7f7-\ua801\ua803-\ua805\ua807-\ua80a\ua80c-\ua822\ua840-\ua873\ua882-\ua8b3\ua8f2-\ua8f7\ua8fb\ua8fd\ua90a-\ua925\ua930-\ua946\ua960-\ua97c\ua984-\ua9b2\ua9cf\ua9e0-\ua9e4\ua9e6-\ua9ef\ua9fa-\ua9fe\uaa00-\uaa28\uaa40-\uaa42\uaa44-\uaa4b\uaa60-\uaa76\uaa7a\uaa7e-\uaaaf\uaab1\uaab5\uaab6\uaab9-\uaabd\uaac0\uaac2\uaadb-\uaadd\uaae0-\uaaea\uaaf2-\uaaf4\uab01-\uab06\uab09-\uab0e\uab11-\uab16\uab20-\uab26\uab28-\uab2e\uab30-\uab5a\uab5c-\uab65\uab70-\uabe2\uac00-\ud7a3\ud7b0-\ud7c6\ud7cb-\ud7fb\uf900-\ufa6d\ufa70-\ufad9\ufb00-\ufb06\ufb13-\ufb17\ufb1d\ufb1f-\ufb28\ufb2a-\ufb36\ufb38-\ufb3c\ufb3e\ufb40\ufb41\ufb43\ufb44\ufb46-\ufbb1\ufbd3-\ufd3d\ufd50-\ufd8f\ufd92-\ufdc7\ufdf0-\ufdfb\ufe70-\ufe74\ufe76-\ufefc\uff21-\uff3a\uff41-\uff5a\uff66-\uffbe\uffc2-\uffc7\uffca-\uffcf\uffd2-\uffd7\uffda-\uffdc"
let nonASCIIidentifierChars = "\u200c\u200d\xb7\u0300-\u036f\u0387\u0483-\u0487\u0591-\u05bd\u05bf\u05c1\u05c2\u05c4\u05c5\u05c7\u0610-\u061a\u064b-\u0669\u0670\u06d6-\u06dc\u06df-\u06e4\u06e7\u06e8\u06ea-\u06ed\u06f0-\u06f9\u0711\u0730-\u074a\u07a6-\u07b0\u07c0-\u07c9\u07eb-\u07f3\u0816-\u0819\u081b-\u0823\u0825-\u0827\u0829-\u082d\u0859-\u085b\u08d4-\u08e1\u08e3-\u0903\u093a-\u093c\u093e-\u094f\u0951-\u0957\u0962\u0963\u0966-\u096f\u0981-\u0983\u09bc\u09be-\u09c4\u09c7\u09c8\u09cb-\u09cd\u09d7\u09e2\u09e3\u09e6-\u09ef\u0a01-\u0a03\u0a3c\u0a3e-\u0a42\u0a47\u0a48\u0a4b-\u0a4d\u0a51\u0a66-\u0a71\u0a75\u0a81-\u0a83\u0abc\u0abe-\u0ac5\u0ac7-\u0ac9\u0acb-\u0acd\u0ae2\u0ae3\u0ae6-\u0aef\u0b01-\u0b03\u0b3c\u0b3e-\u0b44\u0b47\u0b48\u0b4b-\u0b4d\u0b56\u0b57\u0b62\u0b63\u0b66-\u0b6f\u0b82\u0bbe-\u0bc2\u0bc6-\u0bc8\u0bca-\u0bcd\u0bd7\u0be6-\u0bef\u0c00-\u0c03\u0c3e-\u0c44\u0c46-\u0c48\u0c4a-\u0c4d\u0c55\u0c56\u0c62\u0c63\u0c66-\u0c6f\u0c81-\u0c83\u0cbc\u0cbe-\u0cc4\u0cc6-\u0cc8\u0cca-\u0ccd\u0cd5\u0cd6\u0ce2\u0ce3\u0ce6-\u0cef\u0d01-\u0d03\u0d3e-\u0d44\u0d46-\u0d48\u0d4a-\u0d4d\u0d57\u0d62\u0d63\u0d66-\u0d6f\u0d82\u0d83\u0dca\u0dcf-\u0dd4\u0dd6\u0dd8-\u0ddf\u0de6-\u0def\u0df2\u0df3\u0e31\u0e34-\u0e3a\u0e47-\u0e4e\u0e50-\u0e59\u0eb1\u0eb4-\u0eb9\u0ebb\u0ebc\u0ec8-\u0ecd\u0ed0-\u0ed9\u0f18\u0f19\u0f20-\u0f29\u0f35\u0f37\u0f39\u0f3e\u0f3f\u0f71-\u0f84\u0f86\u0f87\u0f8d-\u0f97\u0f99-\u0fbc\u0fc6\u102b-\u103e\u1040-\u1049\u1056-\u1059\u105e-\u1060\u1062-\u1064\u1067-\u106d\u1071-\u1074\u1082-\u108d\u108f-\u109d\u135d-\u135f\u1369-\u1371\u1712-\u1714\u1732-\u1734\u1752\u1753\u1772\u1773\u17b4-\u17d3\u17dd\u17e0-\u17e9\u180b-\u180d\u1810-\u1819\u18a9\u1920-\u192b\u1930-\u193b\u1946-\u194f\u19d0-\u19da\u1a17-\u1a1b\u1a55-\u1a5e\u1a60-\u1a7c\u1a7f-\u1a89\u1a90-\u1a99\u1ab0-\u1abd\u1b00-\u1b04\u1b34-\u1b44\u1b50-\u1b59\u1b6b-\u1b73\u1b80-\u1b82\u1ba1-\u1bad\u1bb0-\u1bb9\u1be6-\u1bf3\u1c24-\u1c37\u1c40-\u1c49\u1c50-\u1c59\u1cd0-\u1cd2\u1cd4-\u1ce8\u1ced\u1cf2-\u1cf4\u1cf8\u1cf9\u1dc0-\u1df5\u1dfb-\u1dff\u203f\u2040\u2054\u20d0-\u20dc\u20e1\u20e5-\u20f0\u2cef-\u2cf1\u2d7f\u2de0-\u2dff\u302a-\u302f\u3099\u309a\ua620-\ua629\ua66f\ua674-\ua67d\ua69e\ua69f\ua6f0\ua6f1\ua802\ua806\ua80b\ua823-\ua827\ua880\ua881\ua8b4-\ua8c5\ua8d0-\ua8d9\ua8e0-\ua8f1\ua900-\ua909\ua926-\ua92d\ua947-\ua953\ua980-\ua983\ua9b3-\ua9c0\ua9d0-\ua9d9\ua9e5\ua9f0-\ua9f9\uaa29-\uaa36\uaa43\uaa4c\uaa4d\uaa50-\uaa59\uaa7b-\uaa7d\uaab0\uaab2-\uaab4\uaab7\uaab8\uaabe\uaabf\uaac1\uaaeb-\uaaef\uaaf5\uaaf6\uabe3-\uabea\uabec\uabed\uabf0-\uabf9\ufb1e\ufe00-\ufe0f\ufe20-\ufe2f\ufe33\ufe34\ufe4d-\ufe4f\uff10-\uff19\uff3f"
const nonASCIIidentifierStart = new RegExp("[" + nonASCIIidentifierStartChars + "]")
const nonASCIIidentifier = new RegExp("[" + nonASCIIidentifierStartChars + nonASCIIidentifierChars + "]")
nonASCIIidentifierStartChars = nonASCIIidentifierChars = null
// These are a run-length and offset encoded representation of the
// >0xffff code points that are a valid part of identifiers. The
// offset starts at 0x10000, and each pair of numbers represents an
// offset to the next range, and then a size of the range. They were
// generated by bin/generate-identifier-regex.js
const astralIdentifierStartCodes = [0,11,2,25,2,18,2,1,2,14,3,13,35,122,70,52,268,28,4,48,48,31,17,26,6,37,11,29,3,35,5,7,2,4,43,157,19,35,5,35,5,39,9,51,157,310,10,21,11,7,153,5,3,0,2,43,2,1,4,0,3,22,11,22,10,30,66,18,2,1,11,21,11,25,71,55,7,1,65,0,16,3,2,2,2,26,45,28,4,28,36,7,2,27,28,53,11,21,11,18,14,17,111,72,56,50,14,50,785,52,76,44,33,24,27,35,42,34,4,0,13,47,15,3,22,0,2,0,36,17,2,24,85,6,2,0,2,3,2,14,2,9,8,46,39,7,3,1,3,21,2,6,2,1,2,4,4,0,19,0,13,4,159,52,19,3,54,47,21,1,2,0,185,46,42,3,37,47,21,0,60,42,86,25,391,63,32,0,449,56,264,8,2,36,18,0,50,29,881,921,103,110,18,195,2749,1070,4050,582,8634,568,8,30,114,29,19,47,17,3,32,20,6,18,881,68,12,0,67,12,65,0,32,6124,20,754,9486,1,3071,106,6,12,4,8,8,9,5991,84,2,70,2,1,3,0,3,1,3,3,2,11,2,0,2,6,2,64,2,3,3,7,2,6,2,27,2,3,2,4,2,0,4,6,2,339,3,24,2,24,2,30,2,24,2,30,2,24,2,30,2,24,2,30,2,24,2,7,4149,196,60,67,1213,3,2,26,2,1,2,0,3,0,2,9,2,3,2,0,2,0,7,0,5,0,2,0,2,0,2,2,2,1,2,0,3,0,2,0,2,0,2,0,2,0,2,1,2,0,3,3,2,6,2,3,2,3,2,0,2,9,2,16,6,2,2,4,2,16,4421,42710,42,4148,12,221,3,5761,10591,541]
const astralIdentifierCodes = [509,0,227,0,150,4,294,9,1368,2,2,1,6,3,41,2,5,0,166,1,1306,2,54,14,32,9,16,3,46,10,54,9,7,2,37,13,2,9,52,0,13,2,49,13,10,2,4,9,83,11,7,0,161,11,6,9,7,3,57,0,2,6,3,1,3,2,10,0,11,1,3,6,4,4,193,17,10,9,87,19,13,9,214,6,3,8,28,1,83,16,16,9,82,12,9,9,84,14,5,9,423,9,838,7,2,7,17,9,57,21,2,13,19882,9,135,4,60,6,26,9,1016,45,17,3,19723,1,5319,4,4,5,9,7,3,6,31,3,149,2,1418,49,513,54,5,49,9,0,15,0,23,4,2,14,1361,6,2,16,3,6,2,1,2,4,2214,6,110,6,6,9,792487,239]
// This has a complexity linear to the value of the code. The
// assumption is that looking up astral identifier characters is
// rare.
function isInAstralSet(code, set) {
let pos = 0x10000
for (let i = 0; i < set.length; i += 2) {
pos += set[i]
if (pos > code) return false
pos += set[i + 1]
if (pos >= code) return true
}
}
// Test whether a given character code starts an identifier.
export function isIdentifierStart(code, astral) {
if (code < 65) return code === 36
if (code < 91) return true
if (code < 97) return code === 95
if (code < 123) return true
if (code <= 0xffff) return code >= 0xaa && nonASCIIidentifierStart.test(String.fromCharCode(code))
if (astral === false) return false
return isInAstralSet(code, astralIdentifierStartCodes)
}
// Test whether a given character is part of an identifier.
export function isIdentifierChar(code, astral) {
if (code < 48) return code === 36
if (code < 58) return true
if (code < 65) return false
if (code < 91) return true
if (code < 97) return code === 95
if (code < 123) return true
if (code <= 0xffff) return code >= 0xaa && nonASCIIidentifier.test(String.fromCharCode(code))
if (astral === false) return false
return isInAstralSet(code, astralIdentifierStartCodes) || isInAstralSet(code, astralIdentifierCodes)
}

67
node_modules/acorn/src/index.js generated vendored Normal file
View File

@@ -0,0 +1,67 @@
// Acorn is a tiny, fast JavaScript parser written in JavaScript.
//
// Acorn was written by Marijn Haverbeke, Ingvar Stepanyan, and
// various contributors and released under an MIT license.
//
// Git repositories for Acorn are available at
//
// http://marijnhaverbeke.nl/git/acorn
// https://github.com/ternjs/acorn.git
//
// Please use the [github bug tracker][ghbt] to report issues.
//
// [ghbt]: https://github.com/ternjs/acorn/issues
//
// This file defines the main parser interface. The library also comes
// with a [error-tolerant parser][dammit] and an
// [abstract syntax tree walker][walk], defined in other files.
//
// [dammit]: acorn_loose.js
// [walk]: util/walk.js
import {Parser} from "./state"
import "./parseutil"
import "./statement"
import "./lval"
import "./expression"
import "./location"
export {Parser, plugins} from "./state"
export {defaultOptions} from "./options"
export {Position, SourceLocation, getLineInfo} from "./locutil"
export {Node} from "./node"
export {TokenType, types as tokTypes} from "./tokentype"
export {TokContext, types as tokContexts} from "./tokencontext"
export {isIdentifierChar, isIdentifierStart} from "./identifier"
export {Token} from "./tokenize"
export {isNewLine, lineBreak, lineBreakG} from "./whitespace"
export const version = "3.3.0"
// The main exported interface (under `self.acorn` when in the
// browser) is a `parse` function that takes a code string and
// returns an abstract syntax tree as specified by [Mozilla parser
// API][api].
//
// [api]: https://developer.mozilla.org/en-US/docs/SpiderMonkey/Parser_API
export function parse(input, options) {
return new Parser(options, input).parse()
}
// This function tries to parse a single expression at a given
// offset in a string. Useful for parsing mixed-language formats
// that embed JavaScript expressions.
export function parseExpressionAt(input, pos, options) {
let p = new Parser(options, input, pos)
p.nextToken()
return p.parseExpression()
}
// Acorn is organized as a tokenizer and a recursive-descent parser.
// The `tokenizer` export provides an interface to the tokenizer.
export function tokenizer(input, options) {
return new Parser(options, input)
}

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node_modules/acorn/src/location.js generated vendored Normal file
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import {Parser} from "./state"
import {Position, getLineInfo} from "./locutil"
const pp = Parser.prototype
// This function is used to raise exceptions on parse errors. It
// takes an offset integer (into the current `input`) to indicate
// the location of the error, attaches the position to the end
// of the error message, and then raises a `SyntaxError` with that
// message.
pp.raise = function(pos, message) {
let loc = getLineInfo(this.input, pos)
message += " (" + loc.line + ":" + loc.column + ")"
let err = new SyntaxError(message)
err.pos = pos; err.loc = loc; err.raisedAt = this.pos
throw err
}
pp.raiseRecoverable = pp.raise
pp.curPosition = function() {
if (this.options.locations) {
return new Position(this.curLine, this.pos - this.lineStart)
}
}

42
node_modules/acorn/src/locutil.js generated vendored Normal file
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import {lineBreakG} from "./whitespace"
// These are used when `options.locations` is on, for the
// `startLoc` and `endLoc` properties.
export class Position {
constructor(line, col) {
this.line = line
this.column = col
}
offset(n) {
return new Position(this.line, this.column + n)
}
}
export class SourceLocation {
constructor(p, start, end) {
this.start = start
this.end = end
if (p.sourceFile !== null) this.source = p.sourceFile
}
}
// The `getLineInfo` function is mostly useful when the
// `locations` option is off (for performance reasons) and you
// want to find the line/column position for a given character
// offset. `input` should be the code string that the offset refers
// into.
export function getLineInfo(input, offset) {
for (let line = 1, cur = 0;;) {
lineBreakG.lastIndex = cur
let match = lineBreakG.exec(input)
if (match && match.index < offset) {
++line
cur = match.index + match[0].length
} else {
return new Position(line, offset - cur)
}
}
}

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node_modules/acorn/src/loose/expression.js generated vendored Normal file
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import {LooseParser} from "./state"
import {isDummy} from "./parseutil"
import {tokTypes as tt} from "acorn"
const lp = LooseParser.prototype
lp.checkLVal = function(expr) {
if (!expr) return expr
switch (expr.type) {
case "Identifier":
case "MemberExpression":
return expr
case "ParenthesizedExpression":
expr.expression = this.checkLVal(expr.expression)
return expr
default:
return this.dummyIdent()
}
}
lp.parseExpression = function(noIn) {
let start = this.storeCurrentPos()
let expr = this.parseMaybeAssign(noIn)
if (this.tok.type === tt.comma) {
let node = this.startNodeAt(start)
node.expressions = [expr]
while (this.eat(tt.comma)) node.expressions.push(this.parseMaybeAssign(noIn))
return this.finishNode(node, "SequenceExpression")
}
return expr
}
lp.parseParenExpression = function() {
this.pushCx()
this.expect(tt.parenL)
let val = this.parseExpression()
this.popCx()
this.expect(tt.parenR)
return val
}
lp.parseMaybeAssign = function(noIn) {
if (this.toks.isContextual("yield")) {
let node = this.startNode()
this.next()
if (this.semicolon() || this.canInsertSemicolon() || (this.tok.type != tt.star && !this.tok.type.startsExpr)) {
node.delegate = false
node.argument = null
} else {
node.delegate = this.eat(tt.star)
node.argument = this.parseMaybeAssign()
}
return this.finishNode(node, "YieldExpression")
}
let start = this.storeCurrentPos()
let left = this.parseMaybeConditional(noIn)
if (this.tok.type.isAssign) {
let node = this.startNodeAt(start)
node.operator = this.tok.value
node.left = this.tok.type === tt.eq ? this.toAssignable(left) : this.checkLVal(left)
this.next()
node.right = this.parseMaybeAssign(noIn)
return this.finishNode(node, "AssignmentExpression")
}
return left
}
lp.parseMaybeConditional = function(noIn) {
let start = this.storeCurrentPos()
let expr = this.parseExprOps(noIn)
if (this.eat(tt.question)) {
let node = this.startNodeAt(start)
node.test = expr
node.consequent = this.parseMaybeAssign()
node.alternate = this.expect(tt.colon) ? this.parseMaybeAssign(noIn) : this.dummyIdent()
return this.finishNode(node, "ConditionalExpression")
}
return expr
}
lp.parseExprOps = function(noIn) {
let start = this.storeCurrentPos()
let indent = this.curIndent, line = this.curLineStart
return this.parseExprOp(this.parseMaybeUnary(false), start, -1, noIn, indent, line)
}
lp.parseExprOp = function(left, start, minPrec, noIn, indent, line) {
if (this.curLineStart != line && this.curIndent < indent && this.tokenStartsLine()) return left
let prec = this.tok.type.binop
if (prec != null && (!noIn || this.tok.type !== tt._in)) {
if (prec > minPrec) {
let node = this.startNodeAt(start)
node.left = left
node.operator = this.tok.value
this.next()
if (this.curLineStart != line && this.curIndent < indent && this.tokenStartsLine()) {
node.right = this.dummyIdent()
} else {
let rightStart = this.storeCurrentPos()
node.right = this.parseExprOp(this.parseMaybeUnary(false), rightStart, prec, noIn, indent, line)
}
this.finishNode(node, /&&|\|\|/.test(node.operator) ? "LogicalExpression" : "BinaryExpression")
return this.parseExprOp(node, start, minPrec, noIn, indent, line)
}
}
return left
}
lp.parseMaybeUnary = function(sawUnary) {
let start = this.storeCurrentPos(), expr
if (this.tok.type.prefix) {
let node = this.startNode(), update = this.tok.type === tt.incDec
if (!update) sawUnary = true
node.operator = this.tok.value
node.prefix = true
this.next()
node.argument = this.parseMaybeUnary(true)
if (update) node.argument = this.checkLVal(node.argument)
expr = this.finishNode(node, update ? "UpdateExpression" : "UnaryExpression")
} else if (this.tok.type === tt.ellipsis) {
let node = this.startNode()
this.next()
node.argument = this.parseMaybeUnary(sawUnary)
expr = this.finishNode(node, "SpreadElement")
} else {
expr = this.parseExprSubscripts()
while (this.tok.type.postfix && !this.canInsertSemicolon()) {
let node = this.startNodeAt(start)
node.operator = this.tok.value
node.prefix = false
node.argument = this.checkLVal(expr)
this.next()
expr = this.finishNode(node, "UpdateExpression")
}
}
if (!sawUnary && this.eat(tt.starstar)) {
let node = this.startNodeAt(start)
node.operator = "**"
node.left = expr
node.right = this.parseMaybeUnary(false)
return this.finishNode(node, "BinaryExpression")
}
return expr
}
lp.parseExprSubscripts = function() {
let start = this.storeCurrentPos()
return this.parseSubscripts(this.parseExprAtom(), start, false, this.curIndent, this.curLineStart)
}
lp.parseSubscripts = function(base, start, noCalls, startIndent, line) {
for (;;) {
if (this.curLineStart != line && this.curIndent <= startIndent && this.tokenStartsLine()) {
if (this.tok.type == tt.dot && this.curIndent == startIndent)
--startIndent
else
return base
}
if (this.eat(tt.dot)) {
let node = this.startNodeAt(start)
node.object = base
if (this.curLineStart != line && this.curIndent <= startIndent && this.tokenStartsLine())
node.property = this.dummyIdent()
else
node.property = this.parsePropertyAccessor() || this.dummyIdent()
node.computed = false
base = this.finishNode(node, "MemberExpression")
} else if (this.tok.type == tt.bracketL) {
this.pushCx()
this.next()
let node = this.startNodeAt(start)
node.object = base
node.property = this.parseExpression()
node.computed = true
this.popCx()
this.expect(tt.bracketR)
base = this.finishNode(node, "MemberExpression")
} else if (!noCalls && this.tok.type == tt.parenL) {
let node = this.startNodeAt(start)
node.callee = base
node.arguments = this.parseExprList(tt.parenR)
base = this.finishNode(node, "CallExpression")
} else if (this.tok.type == tt.backQuote) {
let node = this.startNodeAt(start)
node.tag = base
node.quasi = this.parseTemplate()
base = this.finishNode(node, "TaggedTemplateExpression")
} else {
return base
}
}
}
lp.parseExprAtom = function() {
let node
switch (this.tok.type) {
case tt._this:
case tt._super:
let type = this.tok.type === tt._this ? "ThisExpression" : "Super"
node = this.startNode()
this.next()
return this.finishNode(node, type)
case tt.name:
let start = this.storeCurrentPos()
let id = this.parseIdent()
return this.eat(tt.arrow) ? this.parseArrowExpression(this.startNodeAt(start), [id]) : id
case tt.regexp:
node = this.startNode()
let val = this.tok.value
node.regex = {pattern: val.pattern, flags: val.flags}
node.value = val.value
node.raw = this.input.slice(this.tok.start, this.tok.end)
this.next()
return this.finishNode(node, "Literal")
case tt.num: case tt.string:
node = this.startNode()
node.value = this.tok.value
node.raw = this.input.slice(this.tok.start, this.tok.end)
this.next()
return this.finishNode(node, "Literal")
case tt._null: case tt._true: case tt._false:
node = this.startNode()
node.value = this.tok.type === tt._null ? null : this.tok.type === tt._true
node.raw = this.tok.type.keyword
this.next()
return this.finishNode(node, "Literal")
case tt.parenL:
let parenStart = this.storeCurrentPos()
this.next()
let inner = this.parseExpression()
this.expect(tt.parenR)
if (this.eat(tt.arrow)) {
return this.parseArrowExpression(this.startNodeAt(parenStart), inner.expressions || (isDummy(inner) ? [] : [inner]))
}
if (this.options.preserveParens) {
let par = this.startNodeAt(parenStart)
par.expression = inner
inner = this.finishNode(par, "ParenthesizedExpression")
}
return inner
case tt.bracketL:
node = this.startNode()
node.elements = this.parseExprList(tt.bracketR, true)
return this.finishNode(node, "ArrayExpression")
case tt.braceL:
return this.parseObj()
case tt._class:
return this.parseClass()
case tt._function:
node = this.startNode()
this.next()
return this.parseFunction(node, false)
case tt._new:
return this.parseNew()
case tt.backQuote:
return this.parseTemplate()
default:
return this.dummyIdent()
}
}
lp.parseNew = function() {
let node = this.startNode(), startIndent = this.curIndent, line = this.curLineStart
let meta = this.parseIdent(true)
if (this.options.ecmaVersion >= 6 && this.eat(tt.dot)) {
node.meta = meta
node.property = this.parseIdent(true)
return this.finishNode(node, "MetaProperty")
}
let start = this.storeCurrentPos()
node.callee = this.parseSubscripts(this.parseExprAtom(), start, true, startIndent, line)
if (this.tok.type == tt.parenL) {
node.arguments = this.parseExprList(tt.parenR)
} else {
node.arguments = []
}
return this.finishNode(node, "NewExpression")
}
lp.parseTemplateElement = function() {
let elem = this.startNode()
elem.value = {
raw: this.input.slice(this.tok.start, this.tok.end).replace(/\r\n?/g, '\n'),
cooked: this.tok.value
}
this.next()
elem.tail = this.tok.type === tt.backQuote
return this.finishNode(elem, "TemplateElement")
}
lp.parseTemplate = function() {
let node = this.startNode()
this.next()
node.expressions = []
let curElt = this.parseTemplateElement()
node.quasis = [curElt]
while (!curElt.tail) {
this.next()
node.expressions.push(this.parseExpression())
if (this.expect(tt.braceR)) {
curElt = this.parseTemplateElement()
} else {
curElt = this.startNode()
curElt.value = {cooked: '', raw: ''}
curElt.tail = true
this.finishNode(curElt, "TemplateElement")
}
node.quasis.push(curElt)
}
this.expect(tt.backQuote)
return this.finishNode(node, "TemplateLiteral")
}
lp.parseObj = function() {
let node = this.startNode()
node.properties = []
this.pushCx()
let indent = this.curIndent + 1, line = this.curLineStart
this.eat(tt.braceL)
if (this.curIndent + 1 < indent) { indent = this.curIndent; line = this.curLineStart }
while (!this.closes(tt.braceR, indent, line)) {
let prop = this.startNode(), isGenerator, start
if (this.options.ecmaVersion >= 6) {
start = this.storeCurrentPos()
prop.method = false
prop.shorthand = false
isGenerator = this.eat(tt.star)
}
this.parsePropertyName(prop)
if (isDummy(prop.key)) { if (isDummy(this.parseMaybeAssign())) this.next(); this.eat(tt.comma); continue }
if (this.eat(tt.colon)) {
prop.kind = "init"
prop.value = this.parseMaybeAssign()
} else if (this.options.ecmaVersion >= 6 && (this.tok.type === tt.parenL || this.tok.type === tt.braceL)) {
prop.kind = "init"
prop.method = true
prop.value = this.parseMethod(isGenerator)
} else if (this.options.ecmaVersion >= 5 && prop.key.type === "Identifier" &&
!prop.computed && (prop.key.name === "get" || prop.key.name === "set") &&
(this.tok.type != tt.comma && this.tok.type != tt.braceR)) {
prop.kind = prop.key.name
this.parsePropertyName(prop)
prop.value = this.parseMethod(false)
} else {
prop.kind = "init"
if (this.options.ecmaVersion >= 6) {
if (this.eat(tt.eq)) {
let assign = this.startNodeAt(start)
assign.operator = "="
assign.left = prop.key
assign.right = this.parseMaybeAssign()
prop.value = this.finishNode(assign, "AssignmentExpression")
} else {
prop.value = prop.key
}
} else {
prop.value = this.dummyIdent()
}
prop.shorthand = true
}
node.properties.push(this.finishNode(prop, "Property"))
this.eat(tt.comma)
}
this.popCx()
if (!this.eat(tt.braceR)) {
// If there is no closing brace, make the node span to the start
// of the next token (this is useful for Tern)
this.last.end = this.tok.start
if (this.options.locations) this.last.loc.end = this.tok.loc.start
}
return this.finishNode(node, "ObjectExpression")
}
lp.parsePropertyName = function(prop) {
if (this.options.ecmaVersion >= 6) {
if (this.eat(tt.bracketL)) {
prop.computed = true
prop.key = this.parseExpression()
this.expect(tt.bracketR)
return
} else {
prop.computed = false
}
}
let key = (this.tok.type === tt.num || this.tok.type === tt.string) ? this.parseExprAtom() : this.parseIdent()
prop.key = key || this.dummyIdent()
}
lp.parsePropertyAccessor = function() {
if (this.tok.type === tt.name || this.tok.type.keyword) return this.parseIdent()
}
lp.parseIdent = function() {
let name = this.tok.type === tt.name ? this.tok.value : this.tok.type.keyword
if (!name) return this.dummyIdent()
let node = this.startNode()
this.next()
node.name = name
return this.finishNode(node, "Identifier")
}
lp.initFunction = function(node) {
node.id = null
node.params = []
if (this.options.ecmaVersion >= 6) {
node.generator = false
node.expression = false
}
}
// Convert existing expression atom to assignable pattern
// if possible.
lp.toAssignable = function(node, binding) {
if (!node || node.type == "Identifier" || (node.type == "MemberExpression" && !binding)) {
// Okay
} else if (node.type == "ParenthesizedExpression") {
node.expression = this.toAssignable(node.expression, binding)
} else if (this.options.ecmaVersion < 6) {
return this.dummyIdent()
} else if (node.type == "ObjectExpression") {
node.type = "ObjectPattern"
let props = node.properties
for (let i = 0; i < props.length; i++)
props[i].value = this.toAssignable(props[i].value, binding)
} else if (node.type == "ArrayExpression") {
node.type = "ArrayPattern"
this.toAssignableList(node.elements, binding)
} else if (node.type == "SpreadElement") {
node.type = "RestElement"
node.argument = this.toAssignable(node.argument, binding)
} else if (node.type == "AssignmentExpression") {
node.type = "AssignmentPattern"
delete node.operator
} else {
return this.dummyIdent()
}
return node
}
lp.toAssignableList = function(exprList, binding) {
for (let i = 0; i < exprList.length; i++)
exprList[i] = this.toAssignable(exprList[i], binding)
return exprList
}
lp.parseFunctionParams = function(params) {
params = this.parseExprList(tt.parenR)
return this.toAssignableList(params, true)
}
lp.parseMethod = function(isGenerator) {
let node = this.startNode()
this.initFunction(node)
node.params = this.parseFunctionParams()
node.generator = isGenerator || false
node.expression = this.options.ecmaVersion >= 6 && this.tok.type !== tt.braceL
node.body = node.expression ? this.parseMaybeAssign() : this.parseBlock()
return this.finishNode(node, "FunctionExpression")
}
lp.parseArrowExpression = function(node, params) {
this.initFunction(node)
node.params = this.toAssignableList(params, true)
node.expression = this.tok.type !== tt.braceL
node.body = node.expression ? this.parseMaybeAssign() : this.parseBlock()
return this.finishNode(node, "ArrowFunctionExpression")
}
lp.parseExprList = function(close, allowEmpty) {
this.pushCx()
let indent = this.curIndent, line = this.curLineStart, elts = []
this.next() // Opening bracket
while (!this.closes(close, indent + 1, line)) {
if (this.eat(tt.comma)) {
elts.push(allowEmpty ? null : this.dummyIdent())
continue
}
let elt = this.parseMaybeAssign()
if (isDummy(elt)) {
if (this.closes(close, indent, line)) break
this.next()
} else {
elts.push(elt)
}
this.eat(tt.comma)
}
this.popCx()
if (!this.eat(close)) {
// If there is no closing brace, make the node span to the start
// of the next token (this is useful for Tern)
this.last.end = this.tok.start
if (this.options.locations) this.last.loc.end = this.tok.loc.start
}
return elts
}

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node_modules/acorn/src/loose/index.js generated vendored Normal file
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// Acorn: Loose parser
//
// This module provides an alternative parser (`parse_dammit`) that
// exposes that same interface as `parse`, but will try to parse
// anything as JavaScript, repairing syntax error the best it can.
// There are circumstances in which it will raise an error and give
// up, but they are very rare. The resulting AST will be a mostly
// valid JavaScript AST (as per the [Mozilla parser API][api], except
// that:
//
// - Return outside functions is allowed
//
// - Label consistency (no conflicts, break only to existing labels)
// is not enforced.
//
// - Bogus Identifier nodes with a name of `"✖"` are inserted whenever
// the parser got too confused to return anything meaningful.
//
// [api]: https://developer.mozilla.org/en-US/docs/SpiderMonkey/Parser_API
//
// The expected use for this is to *first* try `acorn.parse`, and only
// if that fails switch to `parse_dammit`. The loose parser might
// parse badly indented code incorrectly, so **don't** use it as
// your default parser.
//
// Quite a lot of acorn.js is duplicated here. The alternative was to
// add a *lot* of extra cruft to that file, making it less readable
// and slower. Copying and editing the code allowed me to make
// invasive changes and simplifications without creating a complicated
// tangle.
import acorn from "acorn"
import {LooseParser, pluginsLoose} from "./state"
import "./tokenize"
import "./statement"
import "./expression"
export {LooseParser, pluginsLoose} from "./state"
acorn.defaultOptions.tabSize = 4
export function parse_dammit(input, options) {
let p = new LooseParser(input, options)
p.next()
return p.parseTopLevel()
}
acorn.parse_dammit = parse_dammit
acorn.LooseParser = LooseParser
acorn.pluginsLoose = pluginsLoose

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node_modules/acorn/src/loose/parseutil.js generated vendored Normal file
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export function isDummy(node) { return node.name == "✖" }

160
node_modules/acorn/src/loose/state.js generated vendored Normal file
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import {tokenizer, SourceLocation, tokTypes as tt, Node, lineBreak, isNewLine} from "acorn"
// Registered plugins
export const pluginsLoose = {}
export class LooseParser {
constructor(input, options = {}) {
this.toks = tokenizer(input, options)
this.options = this.toks.options
this.input = this.toks.input
this.tok = this.last = {type: tt.eof, start: 0, end: 0}
if (this.options.locations) {
let here = this.toks.curPosition()
this.tok.loc = new SourceLocation(this.toks, here, here)
}
this.ahead = [] // Tokens ahead
this.context = [] // Indentation contexted
this.curIndent = 0
this.curLineStart = 0
this.nextLineStart = this.lineEnd(this.curLineStart) + 1
// Load plugins
this.options.pluginsLoose = options.pluginsLoose || {}
this.loadPlugins(this.options.pluginsLoose)
}
startNode() {
return new Node(this.toks, this.tok.start, this.options.locations ? this.tok.loc.start : null)
}
storeCurrentPos() {
return this.options.locations ? [this.tok.start, this.tok.loc.start] : this.tok.start
}
startNodeAt(pos) {
if (this.options.locations) {
return new Node(this.toks, pos[0], pos[1])
} else {
return new Node(this.toks, pos)
}
}
finishNode(node, type) {
node.type = type
node.end = this.last.end
if (this.options.locations)
node.loc.end = this.last.loc.end
if (this.options.ranges)
node.range[1] = this.last.end
return node
}
dummyNode(type) {
let dummy = this.startNode()
dummy.type = type
dummy.end = dummy.start
if (this.options.locations)
dummy.loc.end = dummy.loc.start
if (this.options.ranges)
dummy.range[1] = dummy.start
this.last = {type: tt.name, start: dummy.start, end: dummy.start, loc: dummy.loc}
return dummy
}
dummyIdent() {
let dummy = this.dummyNode("Identifier")
dummy.name = "✖"
return dummy
}
dummyString() {
let dummy = this.dummyNode("Literal")
dummy.value = dummy.raw = "✖"
return dummy
}
eat(type) {
if (this.tok.type === type) {
this.next()
return true
} else {
return false
}
}
isContextual(name) {
return this.tok.type === tt.name && this.tok.value === name
}
eatContextual(name) {
return this.tok.value === name && this.eat(tt.name)
}
canInsertSemicolon() {
return this.tok.type === tt.eof || this.tok.type === tt.braceR ||
lineBreak.test(this.input.slice(this.last.end, this.tok.start))
}
semicolon() {
return this.eat(tt.semi)
}
expect(type) {
if (this.eat(type)) return true
for (let i = 1; i <= 2; i++) {
if (this.lookAhead(i).type == type) {
for (let j = 0; j < i; j++) this.next()
return true
}
}
}
pushCx() {
this.context.push(this.curIndent)
}
popCx() {
this.curIndent = this.context.pop()
}
lineEnd(pos) {
while (pos < this.input.length && !isNewLine(this.input.charCodeAt(pos))) ++pos
return pos
}
indentationAfter(pos) {
for (let count = 0;; ++pos) {
let ch = this.input.charCodeAt(pos)
if (ch === 32) ++count
else if (ch === 9) count += this.options.tabSize
else return count
}
}
closes(closeTok, indent, line, blockHeuristic) {
if (this.tok.type === closeTok || this.tok.type === tt.eof) return true
return line != this.curLineStart && this.curIndent < indent && this.tokenStartsLine() &&
(!blockHeuristic || this.nextLineStart >= this.input.length ||
this.indentationAfter(this.nextLineStart) < indent)
}
tokenStartsLine() {
for (let p = this.tok.start - 1; p >= this.curLineStart; --p) {
let ch = this.input.charCodeAt(p)
if (ch !== 9 && ch !== 32) return false
}
return true
}
extend(name, f) {
this[name] = f(this[name])
}
loadPlugins(pluginConfigs) {
for (let name in pluginConfigs) {
let plugin = pluginsLoose[name]
if (!plugin) throw new Error("Plugin '" + name + "' not found")
plugin(this, pluginConfigs[name])
}
}
}

425
node_modules/acorn/src/loose/statement.js generated vendored Normal file
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@@ -0,0 +1,425 @@
import {LooseParser} from "./state"
import {isDummy} from "./parseutil"
import {getLineInfo, tokTypes as tt} from "acorn"
const lp = LooseParser.prototype
lp.parseTopLevel = function() {
let node = this.startNodeAt(this.options.locations ? [0, getLineInfo(this.input, 0)] : 0)
node.body = []
while (this.tok.type !== tt.eof) node.body.push(this.parseStatement())
this.last = this.tok
if (this.options.ecmaVersion >= 6) {
node.sourceType = this.options.sourceType
}
return this.finishNode(node, "Program")
}
lp.parseStatement = function() {
let starttype = this.tok.type, node = this.startNode(), kind
if (this.toks.isLet()) {
starttype = tt._var
kind = "let"
}
switch (starttype) {
case tt._break: case tt._continue:
this.next()
let isBreak = starttype === tt._break
if (this.semicolon() || this.canInsertSemicolon()) {
node.label = null
} else {
node.label = this.tok.type === tt.name ? this.parseIdent() : null
this.semicolon()
}
return this.finishNode(node, isBreak ? "BreakStatement" : "ContinueStatement")
case tt._debugger:
this.next()
this.semicolon()
return this.finishNode(node, "DebuggerStatement")
case tt._do:
this.next()
node.body = this.parseStatement()
node.test = this.eat(tt._while) ? this.parseParenExpression() : this.dummyIdent()
this.semicolon()
return this.finishNode(node, "DoWhileStatement")
case tt._for:
this.next()
this.pushCx()
this.expect(tt.parenL)
if (this.tok.type === tt.semi) return this.parseFor(node, null)
let isLet = this.toks.isLet()
if (isLet || this.tok.type === tt._var || this.tok.type === tt._const) {
let init = this.parseVar(true, isLet ? "let" : this.tok.value)
if (init.declarations.length === 1 && (this.tok.type === tt._in || this.isContextual("of"))) {
return this.parseForIn(node, init)
}
return this.parseFor(node, init)
}
let init = this.parseExpression(true)
if (this.tok.type === tt._in || this.isContextual("of"))
return this.parseForIn(node, this.toAssignable(init))
return this.parseFor(node, init)
case tt._function:
this.next()
return this.parseFunction(node, true)
case tt._if:
this.next()
node.test = this.parseParenExpression()
node.consequent = this.parseStatement()
node.alternate = this.eat(tt._else) ? this.parseStatement() : null
return this.finishNode(node, "IfStatement")
case tt._return:
this.next()
if (this.eat(tt.semi) || this.canInsertSemicolon()) node.argument = null
else { node.argument = this.parseExpression(); this.semicolon() }
return this.finishNode(node, "ReturnStatement")
case tt._switch:
let blockIndent = this.curIndent, line = this.curLineStart
this.next()
node.discriminant = this.parseParenExpression()
node.cases = []
this.pushCx()
this.expect(tt.braceL)
let cur
while (!this.closes(tt.braceR, blockIndent, line, true)) {
if (this.tok.type === tt._case || this.tok.type === tt._default) {
let isCase = this.tok.type === tt._case
if (cur) this.finishNode(cur, "SwitchCase")
node.cases.push(cur = this.startNode())
cur.consequent = []
this.next()
if (isCase) cur.test = this.parseExpression()
else cur.test = null
this.expect(tt.colon)
} else {
if (!cur) {
node.cases.push(cur = this.startNode())
cur.consequent = []
cur.test = null
}
cur.consequent.push(this.parseStatement())
}
}
if (cur) this.finishNode(cur, "SwitchCase")
this.popCx()
this.eat(tt.braceR)
return this.finishNode(node, "SwitchStatement")
case tt._throw:
this.next()
node.argument = this.parseExpression()
this.semicolon()
return this.finishNode(node, "ThrowStatement")
case tt._try:
this.next()
node.block = this.parseBlock()
node.handler = null
if (this.tok.type === tt._catch) {
let clause = this.startNode()
this.next()
this.expect(tt.parenL)
clause.param = this.toAssignable(this.parseExprAtom(), true)
this.expect(tt.parenR)
clause.body = this.parseBlock()
node.handler = this.finishNode(clause, "CatchClause")
}
node.finalizer = this.eat(tt._finally) ? this.parseBlock() : null
if (!node.handler && !node.finalizer) return node.block
return this.finishNode(node, "TryStatement")
case tt._var:
case tt._const:
return this.parseVar(false, kind || this.tok.value)
case tt._while:
this.next()
node.test = this.parseParenExpression()
node.body = this.parseStatement()
return this.finishNode(node, "WhileStatement")
case tt._with:
this.next()
node.object = this.parseParenExpression()
node.body = this.parseStatement()
return this.finishNode(node, "WithStatement")
case tt.braceL:
return this.parseBlock()
case tt.semi:
this.next()
return this.finishNode(node, "EmptyStatement")
case tt._class:
return this.parseClass(true)
case tt._import:
return this.parseImport()
case tt._export:
return this.parseExport()
default:
let expr = this.parseExpression()
if (isDummy(expr)) {
this.next()
if (this.tok.type === tt.eof) return this.finishNode(node, "EmptyStatement")
return this.parseStatement()
} else if (starttype === tt.name && expr.type === "Identifier" && this.eat(tt.colon)) {
node.body = this.parseStatement()
node.label = expr
return this.finishNode(node, "LabeledStatement")
} else {
node.expression = expr
this.semicolon()
return this.finishNode(node, "ExpressionStatement")
}
}
}
lp.parseBlock = function() {
let node = this.startNode()
this.pushCx()
this.expect(tt.braceL)
let blockIndent = this.curIndent, line = this.curLineStart
node.body = []
while (!this.closes(tt.braceR, blockIndent, line, true))
node.body.push(this.parseStatement())
this.popCx()
this.eat(tt.braceR)
return this.finishNode(node, "BlockStatement")
}
lp.parseFor = function(node, init) {
node.init = init
node.test = node.update = null
if (this.eat(tt.semi) && this.tok.type !== tt.semi) node.test = this.parseExpression()
if (this.eat(tt.semi) && this.tok.type !== tt.parenR) node.update = this.parseExpression()
this.popCx()
this.expect(tt.parenR)
node.body = this.parseStatement()
return this.finishNode(node, "ForStatement")
}
lp.parseForIn = function(node, init) {
let type = this.tok.type === tt._in ? "ForInStatement" : "ForOfStatement"
this.next()
node.left = init
node.right = this.parseExpression()
this.popCx()
this.expect(tt.parenR)
node.body = this.parseStatement()
return this.finishNode(node, type)
}
lp.parseVar = function(noIn, kind) {
let node = this.startNode()
node.kind = kind
this.next()
node.declarations = []
do {
let decl = this.startNode()
decl.id = this.options.ecmaVersion >= 6 ? this.toAssignable(this.parseExprAtom(), true) : this.parseIdent()
decl.init = this.eat(tt.eq) ? this.parseMaybeAssign(noIn) : null
node.declarations.push(this.finishNode(decl, "VariableDeclarator"))
} while (this.eat(tt.comma))
if (!node.declarations.length) {
let decl = this.startNode()
decl.id = this.dummyIdent()
node.declarations.push(this.finishNode(decl, "VariableDeclarator"))
}
if (!noIn) this.semicolon()
return this.finishNode(node, "VariableDeclaration")
}
lp.parseClass = function(isStatement) {
let node = this.startNode()
this.next()
if (this.tok.type === tt.name) node.id = this.parseIdent()
else if (isStatement) node.id = this.dummyIdent()
else node.id = null
node.superClass = this.eat(tt._extends) ? this.parseExpression() : null
node.body = this.startNode()
node.body.body = []
this.pushCx()
let indent = this.curIndent + 1, line = this.curLineStart
this.eat(tt.braceL)
if (this.curIndent + 1 < indent) { indent = this.curIndent; line = this.curLineStart }
while (!this.closes(tt.braceR, indent, line)) {
if (this.semicolon()) continue
let method = this.startNode(), isGenerator
if (this.options.ecmaVersion >= 6) {
method.static = false
isGenerator = this.eat(tt.star)
}
this.parsePropertyName(method)
if (isDummy(method.key)) { if (isDummy(this.parseMaybeAssign())) this.next(); this.eat(tt.comma); continue }
if (method.key.type === "Identifier" && !method.computed && method.key.name === "static" &&
(this.tok.type != tt.parenL && this.tok.type != tt.braceL)) {
method.static = true
isGenerator = this.eat(tt.star)
this.parsePropertyName(method)
} else {
method.static = false
}
if (this.options.ecmaVersion >= 5 && method.key.type === "Identifier" &&
!method.computed && (method.key.name === "get" || method.key.name === "set") &&
this.tok.type !== tt.parenL && this.tok.type !== tt.braceL) {
method.kind = method.key.name
this.parsePropertyName(method)
method.value = this.parseMethod(false)
} else {
if (!method.computed && !method.static && !isGenerator && (
method.key.type === "Identifier" && method.key.name === "constructor" ||
method.key.type === "Literal" && method.key.value === "constructor")) {
method.kind = "constructor"
} else {
method.kind = "method"
}
method.value = this.parseMethod(isGenerator)
}
node.body.body.push(this.finishNode(method, "MethodDefinition"))
}
this.popCx()
if (!this.eat(tt.braceR)) {
// If there is no closing brace, make the node span to the start
// of the next token (this is useful for Tern)
this.last.end = this.tok.start
if (this.options.locations) this.last.loc.end = this.tok.loc.start
}
this.semicolon()
this.finishNode(node.body, "ClassBody")
return this.finishNode(node, isStatement ? "ClassDeclaration" : "ClassExpression")
}
lp.parseFunction = function(node, isStatement) {
this.initFunction(node)
if (this.options.ecmaVersion >= 6) {
node.generator = this.eat(tt.star)
}
if (this.tok.type === tt.name) node.id = this.parseIdent()
else if (isStatement) node.id = this.dummyIdent()
node.params = this.parseFunctionParams()
node.body = this.parseBlock()
return this.finishNode(node, isStatement ? "FunctionDeclaration" : "FunctionExpression")
}
lp.parseExport = function() {
let node = this.startNode()
this.next()
if (this.eat(tt.star)) {
node.source = this.eatContextual("from") ? this.parseExprAtom() : this.dummyString()
return this.finishNode(node, "ExportAllDeclaration")
}
if (this.eat(tt._default)) {
let expr = this.parseMaybeAssign()
if (expr.id) {
switch (expr.type) {
case "FunctionExpression": expr.type = "FunctionDeclaration"; break
case "ClassExpression": expr.type = "ClassDeclaration"; break
}
}
node.declaration = expr
this.semicolon()
return this.finishNode(node, "ExportDefaultDeclaration")
}
if (this.tok.type.keyword || this.toks.isLet()) {
node.declaration = this.parseStatement()
node.specifiers = []
node.source = null
} else {
node.declaration = null
node.specifiers = this.parseExportSpecifierList()
node.source = this.eatContextual("from") ? this.parseExprAtom() : null
this.semicolon()
}
return this.finishNode(node, "ExportNamedDeclaration")
}
lp.parseImport = function() {
let node = this.startNode()
this.next()
if (this.tok.type === tt.string) {
node.specifiers = []
node.source = this.parseExprAtom()
node.kind = ''
} else {
let elt
if (this.tok.type === tt.name && this.tok.value !== "from") {
elt = this.startNode()
elt.local = this.parseIdent()
this.finishNode(elt, "ImportDefaultSpecifier")
this.eat(tt.comma)
}
node.specifiers = this.parseImportSpecifierList()
node.source = this.eatContextual("from") && this.tok.type == tt.string ? this.parseExprAtom() : this.dummyString()
if (elt) node.specifiers.unshift(elt)
}
this.semicolon()
return this.finishNode(node, "ImportDeclaration")
}
lp.parseImportSpecifierList = function() {
let elts = []
if (this.tok.type === tt.star) {
let elt = this.startNode()
this.next()
elt.local = this.eatContextual("as") ? this.parseIdent() : this.dummyIdent()
elts.push(this.finishNode(elt, "ImportNamespaceSpecifier"))
} else {
let indent = this.curIndent, line = this.curLineStart, continuedLine = this.nextLineStart
this.pushCx()
this.eat(tt.braceL)
if (this.curLineStart > continuedLine) continuedLine = this.curLineStart
while (!this.closes(tt.braceR, indent + (this.curLineStart <= continuedLine ? 1 : 0), line)) {
let elt = this.startNode()
if (this.eat(tt.star)) {
elt.local = this.eatContextual("as") ? this.parseIdent() : this.dummyIdent()
this.finishNode(elt, "ImportNamespaceSpecifier")
} else {
if (this.isContextual("from")) break
elt.imported = this.parseIdent()
if (isDummy(elt.imported)) break
elt.local = this.eatContextual("as") ? this.parseIdent() : elt.imported
this.finishNode(elt, "ImportSpecifier")
}
elts.push(elt)
this.eat(tt.comma)
}
this.eat(tt.braceR)
this.popCx()
}
return elts
}
lp.parseExportSpecifierList = function() {
let elts = []
let indent = this.curIndent, line = this.curLineStart, continuedLine = this.nextLineStart
this.pushCx()
this.eat(tt.braceL)
if (this.curLineStart > continuedLine) continuedLine = this.curLineStart
while (!this.closes(tt.braceR, indent + (this.curLineStart <= continuedLine ? 1 : 0), line)) {
if (this.isContextual("from")) break
let elt = this.startNode()
elt.local = this.parseIdent()
if (isDummy(elt.local)) break
elt.exported = this.eatContextual("as") ? this.parseIdent() : elt.local
this.finishNode(elt, "ExportSpecifier")
elts.push(elt)
this.eat(tt.comma)
}
this.eat(tt.braceR)
this.popCx()
return elts
}

108
node_modules/acorn/src/loose/tokenize.js generated vendored Normal file
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import {tokTypes as tt, Token, isNewLine, SourceLocation, getLineInfo, lineBreakG} from "acorn"
import {LooseParser} from "./state"
const lp = LooseParser.prototype
function isSpace(ch) {
return (ch < 14 && ch > 8) || ch === 32 || ch === 160 || isNewLine(ch)
}
lp.next = function() {
this.last = this.tok
if (this.ahead.length)
this.tok = this.ahead.shift()
else
this.tok = this.readToken()
if (this.tok.start >= this.nextLineStart) {
while (this.tok.start >= this.nextLineStart) {
this.curLineStart = this.nextLineStart
this.nextLineStart = this.lineEnd(this.curLineStart) + 1
}
this.curIndent = this.indentationAfter(this.curLineStart)
}
}
lp.readToken = function() {
for (;;) {
try {
this.toks.next()
if (this.toks.type === tt.dot &&
this.input.substr(this.toks.end, 1) === "." &&
this.options.ecmaVersion >= 6) {
this.toks.end++
this.toks.type = tt.ellipsis
}
return new Token(this.toks)
} catch(e) {
if (!(e instanceof SyntaxError)) throw e
// Try to skip some text, based on the error message, and then continue
let msg = e.message, pos = e.raisedAt, replace = true
if (/unterminated/i.test(msg)) {
pos = this.lineEnd(e.pos + 1)
if (/string/.test(msg)) {
replace = {start: e.pos, end: pos, type: tt.string, value: this.input.slice(e.pos + 1, pos)}
} else if (/regular expr/i.test(msg)) {
let re = this.input.slice(e.pos, pos)
try { re = new RegExp(re) } catch(e) {}
replace = {start: e.pos, end: pos, type: tt.regexp, value: re}
} else if (/template/.test(msg)) {
replace = {start: e.pos, end: pos,
type: tt.template,
value: this.input.slice(e.pos, pos)}
} else {
replace = false
}
} else if (/invalid (unicode|regexp|number)|expecting unicode|octal literal|is reserved|directly after number|expected number in radix/i.test(msg)) {
while (pos < this.input.length && !isSpace(this.input.charCodeAt(pos))) ++pos
} else if (/character escape|expected hexadecimal/i.test(msg)) {
while (pos < this.input.length) {
let ch = this.input.charCodeAt(pos++)
if (ch === 34 || ch === 39 || isNewLine(ch)) break
}
} else if (/unexpected character/i.test(msg)) {
pos++
replace = false
} else if (/regular expression/i.test(msg)) {
replace = true
} else {
throw e
}
this.resetTo(pos)
if (replace === true) replace = {start: pos, end: pos, type: tt.name, value: "✖"}
if (replace) {
if (this.options.locations)
replace.loc = new SourceLocation(
this.toks,
getLineInfo(this.input, replace.start),
getLineInfo(this.input, replace.end))
return replace
}
}
}
}
lp.resetTo = function(pos) {
this.toks.pos = pos
let ch = this.input.charAt(pos - 1)
this.toks.exprAllowed = !ch || /[\[\{\(,;:?\/*=+\-~!|&%^<>]/.test(ch) ||
/[enwfd]/.test(ch) &&
/\b(keywords|case|else|return|throw|new|in|(instance|type)of|delete|void)$/.test(this.input.slice(pos - 10, pos))
if (this.options.locations) {
this.toks.curLine = 1
this.toks.lineStart = lineBreakG.lastIndex = 0
let match
while ((match = lineBreakG.exec(this.input)) && match.index < pos) {
++this.toks.curLine
this.toks.lineStart = match.index + match[0].length
}
}
}
lp.lookAhead = function(n) {
while (n > this.ahead.length)
this.ahead.push(this.readToken())
return this.ahead[n - 1]
}

216
node_modules/acorn/src/lval.js generated vendored Normal file
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import {types as tt} from "./tokentype"
import {Parser} from "./state"
import {has} from "./util"
const pp = Parser.prototype
// Convert existing expression atom to assignable pattern
// if possible.
pp.toAssignable = function(node, isBinding) {
if (this.options.ecmaVersion >= 6 && node) {
switch (node.type) {
case "Identifier":
case "ObjectPattern":
case "ArrayPattern":
break
case "ObjectExpression":
node.type = "ObjectPattern"
for (let i = 0; i < node.properties.length; i++) {
let prop = node.properties[i]
if (prop.kind !== "init") this.raise(prop.key.start, "Object pattern can't contain getter or setter")
this.toAssignable(prop.value, isBinding)
}
break
case "ArrayExpression":
node.type = "ArrayPattern"
this.toAssignableList(node.elements, isBinding)
break
case "AssignmentExpression":
if (node.operator === "=") {
node.type = "AssignmentPattern"
delete node.operator
// falls through to AssignmentPattern
} else {
this.raise(node.left.end, "Only '=' operator can be used for specifying default value.")
break
}
case "AssignmentPattern":
if (node.right.type === "YieldExpression")
this.raise(node.right.start, "Yield expression cannot be a default value")
break
case "ParenthesizedExpression":
node.expression = this.toAssignable(node.expression, isBinding)
break
case "MemberExpression":
if (!isBinding) break
default:
this.raise(node.start, "Assigning to rvalue")
}
}
return node
}
// Convert list of expression atoms to binding list.
pp.toAssignableList = function(exprList, isBinding) {
let end = exprList.length
if (end) {
let last = exprList[end - 1]
if (last && last.type == "RestElement") {
--end
} else if (last && last.type == "SpreadElement") {
last.type = "RestElement"
let arg = last.argument
this.toAssignable(arg, isBinding)
if (arg.type !== "Identifier" && arg.type !== "MemberExpression" && arg.type !== "ArrayPattern")
this.unexpected(arg.start)
--end
}
if (isBinding && last && last.type === "RestElement" && last.argument.type !== "Identifier")
this.unexpected(last.argument.start)
}
for (let i = 0; i < end; i++) {
let elt = exprList[i]
if (elt) this.toAssignable(elt, isBinding)
}
return exprList
}
// Parses spread element.
pp.parseSpread = function(refDestructuringErrors) {
let node = this.startNode()
this.next()
node.argument = this.parseMaybeAssign(false, refDestructuringErrors)
return this.finishNode(node, "SpreadElement")
}
pp.parseRest = function(allowNonIdent) {
let node = this.startNode()
this.next()
// RestElement inside of a function parameter must be an identifier
if (allowNonIdent) node.argument = this.type === tt.name ? this.parseIdent() : this.unexpected()
else node.argument = this.type === tt.name || this.type === tt.bracketL ? this.parseBindingAtom() : this.unexpected()
return this.finishNode(node, "RestElement")
}
// Parses lvalue (assignable) atom.
pp.parseBindingAtom = function() {
if (this.options.ecmaVersion < 6) return this.parseIdent()
switch (this.type) {
case tt.name:
return this.parseIdent()
case tt.bracketL:
let node = this.startNode()
this.next()
node.elements = this.parseBindingList(tt.bracketR, true, true)
return this.finishNode(node, "ArrayPattern")
case tt.braceL:
return this.parseObj(true)
default:
this.unexpected()
}
}
pp.parseBindingList = function(close, allowEmpty, allowTrailingComma, allowNonIdent) {
let elts = [], first = true
while (!this.eat(close)) {
if (first) first = false
else this.expect(tt.comma)
if (allowEmpty && this.type === tt.comma) {
elts.push(null)
} else if (allowTrailingComma && this.afterTrailingComma(close)) {
break
} else if (this.type === tt.ellipsis) {
let rest = this.parseRest(allowNonIdent)
this.parseBindingListItem(rest)
elts.push(rest)
if (this.type === tt.comma) this.raise(this.start, "Comma is not permitted after the rest element")
this.expect(close)
break
} else {
let elem = this.parseMaybeDefault(this.start, this.startLoc)
this.parseBindingListItem(elem)
elts.push(elem)
}
}
return elts
}
pp.parseBindingListItem = function(param) {
return param
}
// Parses assignment pattern around given atom if possible.
pp.parseMaybeDefault = function(startPos, startLoc, left) {
left = left || this.parseBindingAtom()
if (this.options.ecmaVersion < 6 || !this.eat(tt.eq)) return left
let node = this.startNodeAt(startPos, startLoc)
node.left = left
node.right = this.parseMaybeAssign()
return this.finishNode(node, "AssignmentPattern")
}
// Verify that a node is an lval — something that can be assigned
// to.
pp.checkLVal = function(expr, isBinding, checkClashes) {
switch (expr.type) {
case "Identifier":
if (this.strict && this.reservedWordsStrictBind.test(expr.name))
this.raiseRecoverable(expr.start, (isBinding ? "Binding " : "Assigning to ") + expr.name + " in strict mode")
if (checkClashes) {
if (has(checkClashes, expr.name))
this.raiseRecoverable(expr.start, "Argument name clash")
checkClashes[expr.name] = true
}
break
case "MemberExpression":
if (isBinding) this.raiseRecoverable(expr.start, (isBinding ? "Binding" : "Assigning to") + " member expression")
break
case "ObjectPattern":
for (let i = 0; i < expr.properties.length; i++)
this.checkLVal(expr.properties[i].value, isBinding, checkClashes)
break
case "ArrayPattern":
for (let i = 0; i < expr.elements.length; i++) {
let elem = expr.elements[i]
if (elem) this.checkLVal(elem, isBinding, checkClashes)
}
break
case "AssignmentPattern":
this.checkLVal(expr.left, isBinding, checkClashes)
break
case "RestElement":
this.checkLVal(expr.argument, isBinding, checkClashes)
break
case "ParenthesizedExpression":
this.checkLVal(expr.expression, isBinding, checkClashes)
break
default:
this.raise(expr.start, (isBinding ? "Binding" : "Assigning to") + " rvalue")
}
}

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import {Parser} from "./state"
import {SourceLocation} from "./locutil"
export class Node {
constructor(parser, pos, loc) {
this.type = ""
this.start = pos
this.end = 0
if (parser.options.locations)
this.loc = new SourceLocation(parser, loc)
if (parser.options.directSourceFile)
this.sourceFile = parser.options.directSourceFile
if (parser.options.ranges)
this.range = [pos, 0]
}
}
// Start an AST node, attaching a start offset.
const pp = Parser.prototype
pp.startNode = function() {
return new Node(this, this.start, this.startLoc)
}
pp.startNodeAt = function(pos, loc) {
return new Node(this, pos, loc)
}
// Finish an AST node, adding `type` and `end` properties.
function finishNodeAt(node, type, pos, loc) {
node.type = type
node.end = pos
if (this.options.locations)
node.loc.end = loc
if (this.options.ranges)
node.range[1] = pos
return node
}
pp.finishNode = function(node, type) {
return finishNodeAt.call(this, node, type, this.lastTokEnd, this.lastTokEndLoc)
}
// Finish node at given position
pp.finishNodeAt = function(node, type, pos, loc) {
return finishNodeAt.call(this, node, type, pos, loc)
}

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node_modules/acorn/src/options.js generated vendored Normal file
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import {has, isArray} from "./util"
import {SourceLocation} from "./locutil"
// A second optional argument can be given to further configure
// the parser process. These options are recognized:
export const defaultOptions = {
// `ecmaVersion` indicates the ECMAScript version to parse. Must
// be either 3, or 5, or 6. This influences support for strict
// mode, the set of reserved words, support for getters and
// setters and other features. The default is 6.
ecmaVersion: 6,
// Source type ("script" or "module") for different semantics
sourceType: "script",
// `onInsertedSemicolon` can be a callback that will be called
// when a semicolon is automatically inserted. It will be passed
// th position of the comma as an offset, and if `locations` is
// enabled, it is given the location as a `{line, column}` object
// as second argument.
onInsertedSemicolon: null,
// `onTrailingComma` is similar to `onInsertedSemicolon`, but for
// trailing commas.
onTrailingComma: null,
// By default, reserved words are only enforced if ecmaVersion >= 5.
// Set `allowReserved` to a boolean value to explicitly turn this on
// an off. When this option has the value "never", reserved words
// and keywords can also not be used as property names.
allowReserved: null,
// When enabled, a return at the top level is not considered an
// error.
allowReturnOutsideFunction: false,
// When enabled, import/export statements are not constrained to
// appearing at the top of the program.
allowImportExportEverywhere: false,
// When enabled, hashbang directive in the beginning of file
// is allowed and treated as a line comment.
allowHashBang: false,
// When `locations` is on, `loc` properties holding objects with
// `start` and `end` properties in `{line, column}` form (with
// line being 1-based and column 0-based) will be attached to the
// nodes.
locations: false,
// A function can be passed as `onToken` option, which will
// cause Acorn to call that function with object in the same
// format as tokens returned from `tokenizer().getToken()`. Note
// that you are not allowed to call the parser from the
// callback—that will corrupt its internal state.
onToken: null,
// A function can be passed as `onComment` option, which will
// cause Acorn to call that function with `(block, text, start,
// end)` parameters whenever a comment is skipped. `block` is a
// boolean indicating whether this is a block (`/* */`) comment,
// `text` is the content of the comment, and `start` and `end` are
// character offsets that denote the start and end of the comment.
// When the `locations` option is on, two more parameters are
// passed, the full `{line, column}` locations of the start and
// end of the comments. Note that you are not allowed to call the
// parser from the callback—that will corrupt its internal state.
onComment: null,
// Nodes have their start and end characters offsets recorded in
// `start` and `end` properties (directly on the node, rather than
// the `loc` object, which holds line/column data. To also add a
// [semi-standardized][range] `range` property holding a `[start,
// end]` array with the same numbers, set the `ranges` option to
// `true`.
//
// [range]: https://bugzilla.mozilla.org/show_bug.cgi?id=745678
ranges: false,
// It is possible to parse multiple files into a single AST by
// passing the tree produced by parsing the first file as
// `program` option in subsequent parses. This will add the
// toplevel forms of the parsed file to the `Program` (top) node
// of an existing parse tree.
program: null,
// When `locations` is on, you can pass this to record the source
// file in every node's `loc` object.
sourceFile: null,
// This value, if given, is stored in every node, whether
// `locations` is on or off.
directSourceFile: null,
// When enabled, parenthesized expressions are represented by
// (non-standard) ParenthesizedExpression nodes
preserveParens: false,
plugins: {}
}
// Interpret and default an options object
export function getOptions(opts) {
let options = {}
for (let opt in defaultOptions)
options[opt] = opts && has(opts, opt) ? opts[opt] : defaultOptions[opt]
if (options.allowReserved == null)
options.allowReserved = options.ecmaVersion < 5
if (isArray(options.onToken)) {
let tokens = options.onToken
options.onToken = (token) => tokens.push(token)
}
if (isArray(options.onComment))
options.onComment = pushComment(options, options.onComment)
return options
}
function pushComment(options, array) {
return function (block, text, start, end, startLoc, endLoc) {
let comment = {
type: block ? 'Block' : 'Line',
value: text,
start: start,
end: end
}
if (options.locations)
comment.loc = new SourceLocation(this, startLoc, endLoc)
if (options.ranges)
comment.range = [start, end]
array.push(comment)
}
}

109
node_modules/acorn/src/parseutil.js generated vendored Normal file
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import {types as tt} from "./tokentype"
import {Parser} from "./state"
import {lineBreak} from "./whitespace"
const pp = Parser.prototype
// ## Parser utilities
// Test whether a statement node is the string literal `"use strict"`.
pp.isUseStrict = function(stmt) {
return this.options.ecmaVersion >= 5 && stmt.type === "ExpressionStatement" &&
stmt.expression.type === "Literal" &&
stmt.expression.raw.slice(1, -1) === "use strict"
}
// Predicate that tests whether the next token is of the given
// type, and if yes, consumes it as a side effect.
pp.eat = function(type) {
if (this.type === type) {
this.next()
return true
} else {
return false
}
}
// Tests whether parsed token is a contextual keyword.
pp.isContextual = function(name) {
return this.type === tt.name && this.value === name
}
// Consumes contextual keyword if possible.
pp.eatContextual = function(name) {
return this.value === name && this.eat(tt.name)
}
// Asserts that following token is given contextual keyword.
pp.expectContextual = function(name) {
if (!this.eatContextual(name)) this.unexpected()
}
// Test whether a semicolon can be inserted at the current position.
pp.canInsertSemicolon = function() {
return this.type === tt.eof ||
this.type === tt.braceR ||
lineBreak.test(this.input.slice(this.lastTokEnd, this.start))
}
pp.insertSemicolon = function() {
if (this.canInsertSemicolon()) {
if (this.options.onInsertedSemicolon)
this.options.onInsertedSemicolon(this.lastTokEnd, this.lastTokEndLoc)
return true
}
}
// Consume a semicolon, or, failing that, see if we are allowed to
// pretend that there is a semicolon at this position.
pp.semicolon = function() {
if (!this.eat(tt.semi) && !this.insertSemicolon()) this.unexpected()
}
pp.afterTrailingComma = function(tokType) {
if (this.type == tokType) {
if (this.options.onTrailingComma)
this.options.onTrailingComma(this.lastTokStart, this.lastTokStartLoc)
this.next()
return true
}
}
// Expect a token of a given type. If found, consume it, otherwise,
// raise an unexpected token error.
pp.expect = function(type) {
this.eat(type) || this.unexpected()
}
// Raise an unexpected token error.
pp.unexpected = function(pos) {
this.raise(pos != null ? pos : this.start, "Unexpected token")
}
export class DestructuringErrors {
constructor() {
this.shorthandAssign = 0
this.trailingComma = 0
}
}
pp.checkPatternErrors = function(refDestructuringErrors, andThrow) {
let trailing = refDestructuringErrors && refDestructuringErrors.trailingComma
if (!andThrow) return !!trailing
if (trailing) this.raise(trailing, "Comma is not permitted after the rest element")
}
pp.checkExpressionErrors = function(refDestructuringErrors, andThrow) {
let pos = refDestructuringErrors && refDestructuringErrors.shorthandAssign
if (!andThrow) return !!pos
if (pos) this.raise(pos, "Shorthand property assignments are valid only in destructuring patterns")
}

104
node_modules/acorn/src/state.js generated vendored Normal file
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import {reservedWords, keywords} from "./identifier"
import {types as tt} from "./tokentype"
import {lineBreak} from "./whitespace"
import {getOptions} from "./options"
// Registered plugins
export const plugins = {}
function keywordRegexp(words) {
return new RegExp("^(" + words.replace(/ /g, "|") + ")$")
}
export class Parser {
constructor(options, input, startPos) {
this.options = options = getOptions(options)
this.sourceFile = options.sourceFile
this.keywords = keywordRegexp(keywords[options.ecmaVersion >= 6 ? 6 : 5])
let reserved = options.allowReserved ? "" :
reservedWords[options.ecmaVersion] + (options.sourceType == "module" ? " await" : "")
this.reservedWords = keywordRegexp(reserved)
let reservedStrict = (reserved ? reserved + " " : "") + reservedWords.strict
this.reservedWordsStrict = keywordRegexp(reservedStrict)
this.reservedWordsStrictBind = keywordRegexp(reservedStrict + " " + reservedWords.strictBind)
this.input = String(input)
// Used to signal to callers of `readWord1` whether the word
// contained any escape sequences. This is needed because words with
// escape sequences must not be interpreted as keywords.
this.containsEsc = false
// Load plugins
this.loadPlugins(options.plugins)
// Set up token state
// The current position of the tokenizer in the input.
if (startPos) {
this.pos = startPos
this.lineStart = Math.max(0, this.input.lastIndexOf("\n", startPos))
this.curLine = this.input.slice(0, this.lineStart).split(lineBreak).length
} else {
this.pos = this.lineStart = 0
this.curLine = 1
}
// Properties of the current token:
// Its type
this.type = tt.eof
// For tokens that include more information than their type, the value
this.value = null
// Its start and end offset
this.start = this.end = this.pos
// And, if locations are used, the {line, column} object
// corresponding to those offsets
this.startLoc = this.endLoc = this.curPosition()
// Position information for the previous token
this.lastTokEndLoc = this.lastTokStartLoc = null
this.lastTokStart = this.lastTokEnd = this.pos
// The context stack is used to superficially track syntactic
// context to predict whether a regular expression is allowed in a
// given position.
this.context = this.initialContext()
this.exprAllowed = true
// Figure out if it's a module code.
this.strict = this.inModule = options.sourceType === "module"
// Used to signify the start of a potential arrow function
this.potentialArrowAt = -1
// Flags to track whether we are in a function, a generator.
this.inFunction = this.inGenerator = false
// Labels in scope.
this.labels = []
// If enabled, skip leading hashbang line.
if (this.pos === 0 && options.allowHashBang && this.input.slice(0, 2) === '#!')
this.skipLineComment(2)
}
// DEPRECATED Kept for backwards compatibility until 3.0 in case a plugin uses them
isKeyword(word) { return this.keywords.test(word) }
isReservedWord(word) { return this.reservedWords.test(word) }
extend(name, f) {
this[name] = f(this[name])
}
loadPlugins(pluginConfigs) {
for (let name in pluginConfigs) {
let plugin = plugins[name]
if (!plugin) throw new Error("Plugin '" + name + "' not found")
plugin(this, pluginConfigs[name])
}
}
parse() {
let node = this.options.program || this.startNode()
this.nextToken()
return this.parseTopLevel(node)
}
}

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node_modules/acorn/src/statement.js generated vendored Normal file
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import {types as tt} from "./tokentype"
import {Parser} from "./state"
import {lineBreak, skipWhiteSpace} from "./whitespace"
import {isIdentifierStart, isIdentifierChar} from "./identifier"
import {DestructuringErrors} from "./parseutil"
const pp = Parser.prototype
// ### Statement parsing
// Parse a program. Initializes the parser, reads any number of
// statements, and wraps them in a Program node. Optionally takes a
// `program` argument. If present, the statements will be appended
// to its body instead of creating a new node.
pp.parseTopLevel = function(node) {
let first = true
if (!node.body) node.body = []
while (this.type !== tt.eof) {
let stmt = this.parseStatement(true, true)
node.body.push(stmt)
if (first) {
if (this.isUseStrict(stmt)) this.setStrict(true)
first = false
}
}
this.next()
if (this.options.ecmaVersion >= 6) {
node.sourceType = this.options.sourceType
}
return this.finishNode(node, "Program")
}
const loopLabel = {kind: "loop"}, switchLabel = {kind: "switch"}
pp.isLet = function() {
if (this.type !== tt.name || this.options.ecmaVersion < 6 || this.value != "let") return false
skipWhiteSpace.lastIndex = this.pos
let skip = skipWhiteSpace.exec(this.input)
let next = this.pos + skip[0].length, nextCh = this.input.charCodeAt(next)
if (nextCh === 91 || nextCh == 123) return true // '{' and '['
if (isIdentifierStart(nextCh, true)) {
for (var pos = next + 1; isIdentifierChar(this.input.charCodeAt(pos), true); ++pos) {}
let ident = this.input.slice(next, pos)
if (!this.isKeyword(ident)) return true
}
return false
}
// Parse a single statement.
//
// If expecting a statement and finding a slash operator, parse a
// regular expression literal. This is to handle cases like
// `if (foo) /blah/.exec(foo)`, where looking at the previous token
// does not help.
pp.parseStatement = function(declaration, topLevel) {
let starttype = this.type, node = this.startNode(), kind
if (this.isLet()) {
starttype = tt._var
kind = "let"
}
// Most types of statements are recognized by the keyword they
// start with. Many are trivial to parse, some require a bit of
// complexity.
switch (starttype) {
case tt._break: case tt._continue: return this.parseBreakContinueStatement(node, starttype.keyword)
case tt._debugger: return this.parseDebuggerStatement(node)
case tt._do: return this.parseDoStatement(node)
case tt._for: return this.parseForStatement(node)
case tt._function:
if (!declaration && this.options.ecmaVersion >= 6) this.unexpected()
return this.parseFunctionStatement(node)
case tt._class:
if (!declaration) this.unexpected()
return this.parseClass(node, true)
case tt._if: return this.parseIfStatement(node)
case tt._return: return this.parseReturnStatement(node)
case tt._switch: return this.parseSwitchStatement(node)
case tt._throw: return this.parseThrowStatement(node)
case tt._try: return this.parseTryStatement(node)
case tt._const: case tt._var:
kind = kind || this.value
if (!declaration && kind != "var") this.unexpected()
return this.parseVarStatement(node, kind)
case tt._while: return this.parseWhileStatement(node)
case tt._with: return this.parseWithStatement(node)
case tt.braceL: return this.parseBlock()
case tt.semi: return this.parseEmptyStatement(node)
case tt._export:
case tt._import:
if (!this.options.allowImportExportEverywhere) {
if (!topLevel)
this.raise(this.start, "'import' and 'export' may only appear at the top level")
if (!this.inModule)
this.raise(this.start, "'import' and 'export' may appear only with 'sourceType: module'")
}
return starttype === tt._import ? this.parseImport(node) : this.parseExport(node)
// If the statement does not start with a statement keyword or a
// brace, it's an ExpressionStatement or LabeledStatement. We
// simply start parsing an expression, and afterwards, if the
// next token is a colon and the expression was a simple
// Identifier node, we switch to interpreting it as a label.
default:
let maybeName = this.value, expr = this.parseExpression()
if (starttype === tt.name && expr.type === "Identifier" && this.eat(tt.colon))
return this.parseLabeledStatement(node, maybeName, expr)
else return this.parseExpressionStatement(node, expr)
}
}
pp.parseBreakContinueStatement = function(node, keyword) {
let isBreak = keyword == "break"
this.next()
if (this.eat(tt.semi) || this.insertSemicolon()) node.label = null
else if (this.type !== tt.name) this.unexpected()
else {
node.label = this.parseIdent()
this.semicolon()
}
// Verify that there is an actual destination to break or
// continue to.
for (var i = 0; i < this.labels.length; ++i) {
let lab = this.labels[i]
if (node.label == null || lab.name === node.label.name) {
if (lab.kind != null && (isBreak || lab.kind === "loop")) break
if (node.label && isBreak) break
}
}
if (i === this.labels.length) this.raise(node.start, "Unsyntactic " + keyword)
return this.finishNode(node, isBreak ? "BreakStatement" : "ContinueStatement")
}
pp.parseDebuggerStatement = function(node) {
this.next()
this.semicolon()
return this.finishNode(node, "DebuggerStatement")
}
pp.parseDoStatement = function(node) {
this.next()
this.labels.push(loopLabel)
node.body = this.parseStatement(false)
this.labels.pop()
this.expect(tt._while)
node.test = this.parseParenExpression()
if (this.options.ecmaVersion >= 6)
this.eat(tt.semi)
else
this.semicolon()
return this.finishNode(node, "DoWhileStatement")
}
// Disambiguating between a `for` and a `for`/`in` or `for`/`of`
// loop is non-trivial. Basically, we have to parse the init `var`
// statement or expression, disallowing the `in` operator (see
// the second parameter to `parseExpression`), and then check
// whether the next token is `in` or `of`. When there is no init
// part (semicolon immediately after the opening parenthesis), it
// is a regular `for` loop.
pp.parseForStatement = function(node) {
this.next()
this.labels.push(loopLabel)
this.expect(tt.parenL)
if (this.type === tt.semi) return this.parseFor(node, null)
let isLet = this.isLet()
if (this.type === tt._var || this.type === tt._const || isLet) {
let init = this.startNode(), kind = isLet ? "let" : this.value
this.next()
this.parseVar(init, true, kind)
this.finishNode(init, "VariableDeclaration")
if ((this.type === tt._in || (this.options.ecmaVersion >= 6 && this.isContextual("of"))) && init.declarations.length === 1 &&
!(kind !== "var" && init.declarations[0].init))
return this.parseForIn(node, init)
return this.parseFor(node, init)
}
let refDestructuringErrors = new DestructuringErrors
let init = this.parseExpression(true, refDestructuringErrors)
if (this.type === tt._in || (this.options.ecmaVersion >= 6 && this.isContextual("of"))) {
this.checkPatternErrors(refDestructuringErrors, true)
this.toAssignable(init)
this.checkLVal(init)
return this.parseForIn(node, init)
} else {
this.checkExpressionErrors(refDestructuringErrors, true)
}
return this.parseFor(node, init)
}
pp.parseFunctionStatement = function(node) {
this.next()
return this.parseFunction(node, true)
}
pp.parseIfStatement = function(node) {
this.next()
node.test = this.parseParenExpression()
node.consequent = this.parseStatement(false)
node.alternate = this.eat(tt._else) ? this.parseStatement(false) : null
return this.finishNode(node, "IfStatement")
}
pp.parseReturnStatement = function(node) {
if (!this.inFunction && !this.options.allowReturnOutsideFunction)
this.raise(this.start, "'return' outside of function")
this.next()
// In `return` (and `break`/`continue`), the keywords with
// optional arguments, we eagerly look for a semicolon or the
// possibility to insert one.
if (this.eat(tt.semi) || this.insertSemicolon()) node.argument = null
else { node.argument = this.parseExpression(); this.semicolon() }
return this.finishNode(node, "ReturnStatement")
}
pp.parseSwitchStatement = function(node) {
this.next()
node.discriminant = this.parseParenExpression()
node.cases = []
this.expect(tt.braceL)
this.labels.push(switchLabel)
// Statements under must be grouped (by label) in SwitchCase
// nodes. `cur` is used to keep the node that we are currently
// adding statements to.
for (var cur, sawDefault = false; this.type != tt.braceR;) {
if (this.type === tt._case || this.type === tt._default) {
let isCase = this.type === tt._case
if (cur) this.finishNode(cur, "SwitchCase")
node.cases.push(cur = this.startNode())
cur.consequent = []
this.next()
if (isCase) {
cur.test = this.parseExpression()
} else {
if (sawDefault) this.raiseRecoverable(this.lastTokStart, "Multiple default clauses")
sawDefault = true
cur.test = null
}
this.expect(tt.colon)
} else {
if (!cur) this.unexpected()
cur.consequent.push(this.parseStatement(true))
}
}
if (cur) this.finishNode(cur, "SwitchCase")
this.next() // Closing brace
this.labels.pop()
return this.finishNode(node, "SwitchStatement")
}
pp.parseThrowStatement = function(node) {
this.next()
if (lineBreak.test(this.input.slice(this.lastTokEnd, this.start)))
this.raise(this.lastTokEnd, "Illegal newline after throw")
node.argument = this.parseExpression()
this.semicolon()
return this.finishNode(node, "ThrowStatement")
}
// Reused empty array added for node fields that are always empty.
const empty = []
pp.parseTryStatement = function(node) {
this.next()
node.block = this.parseBlock()
node.handler = null
if (this.type === tt._catch) {
let clause = this.startNode()
this.next()
this.expect(tt.parenL)
clause.param = this.parseBindingAtom()
this.checkLVal(clause.param, true)
this.expect(tt.parenR)
clause.body = this.parseBlock()
node.handler = this.finishNode(clause, "CatchClause")
}
node.finalizer = this.eat(tt._finally) ? this.parseBlock() : null
if (!node.handler && !node.finalizer)
this.raise(node.start, "Missing catch or finally clause")
return this.finishNode(node, "TryStatement")
}
pp.parseVarStatement = function(node, kind) {
this.next()
this.parseVar(node, false, kind)
this.semicolon()
return this.finishNode(node, "VariableDeclaration")
}
pp.parseWhileStatement = function(node) {
this.next()
node.test = this.parseParenExpression()
this.labels.push(loopLabel)
node.body = this.parseStatement(false)
this.labels.pop()
return this.finishNode(node, "WhileStatement")
}
pp.parseWithStatement = function(node) {
if (this.strict) this.raise(this.start, "'with' in strict mode")
this.next()
node.object = this.parseParenExpression()
node.body = this.parseStatement(false)
return this.finishNode(node, "WithStatement")
}
pp.parseEmptyStatement = function(node) {
this.next()
return this.finishNode(node, "EmptyStatement")
}
pp.parseLabeledStatement = function(node, maybeName, expr) {
for (let i = 0; i < this.labels.length; ++i)
if (this.labels[i].name === maybeName) this.raise(expr.start, "Label '" + maybeName + "' is already declared")
let kind = this.type.isLoop ? "loop" : this.type === tt._switch ? "switch" : null
for (let i = this.labels.length - 1; i >= 0; i--) {
let label = this.labels[i]
if (label.statementStart == node.start) {
label.statementStart = this.start
label.kind = kind
} else break
}
this.labels.push({name: maybeName, kind: kind, statementStart: this.start})
node.body = this.parseStatement(true)
this.labels.pop()
node.label = expr
return this.finishNode(node, "LabeledStatement")
}
pp.parseExpressionStatement = function(node, expr) {
node.expression = expr
this.semicolon()
return this.finishNode(node, "ExpressionStatement")
}
// Parse a semicolon-enclosed block of statements, handling `"use
// strict"` declarations when `allowStrict` is true (used for
// function bodies).
pp.parseBlock = function(allowStrict) {
let node = this.startNode(), first = true, oldStrict
node.body = []
this.expect(tt.braceL)
while (!this.eat(tt.braceR)) {
let stmt = this.parseStatement(true)
node.body.push(stmt)
if (first && allowStrict && this.isUseStrict(stmt)) {
oldStrict = this.strict
this.setStrict(this.strict = true)
}
first = false
}
if (oldStrict === false) this.setStrict(false)
return this.finishNode(node, "BlockStatement")
}
// Parse a regular `for` loop. The disambiguation code in
// `parseStatement` will already have parsed the init statement or
// expression.
pp.parseFor = function(node, init) {
node.init = init
this.expect(tt.semi)
node.test = this.type === tt.semi ? null : this.parseExpression()
this.expect(tt.semi)
node.update = this.type === tt.parenR ? null : this.parseExpression()
this.expect(tt.parenR)
node.body = this.parseStatement(false)
this.labels.pop()
return this.finishNode(node, "ForStatement")
}
// Parse a `for`/`in` and `for`/`of` loop, which are almost
// same from parser's perspective.
pp.parseForIn = function(node, init) {
let type = this.type === tt._in ? "ForInStatement" : "ForOfStatement"
this.next()
node.left = init
node.right = this.parseExpression()
this.expect(tt.parenR)
node.body = this.parseStatement(false)
this.labels.pop()
return this.finishNode(node, type)
}
// Parse a list of variable declarations.
pp.parseVar = function(node, isFor, kind) {
node.declarations = []
node.kind = kind
for (;;) {
let decl = this.startNode()
this.parseVarId(decl)
if (this.eat(tt.eq)) {
decl.init = this.parseMaybeAssign(isFor)
} else if (kind === "const" && !(this.type === tt._in || (this.options.ecmaVersion >= 6 && this.isContextual("of")))) {
this.unexpected()
} else if (decl.id.type != "Identifier" && !(isFor && (this.type === tt._in || this.isContextual("of")))) {
this.raise(this.lastTokEnd, "Complex binding patterns require an initialization value")
} else {
decl.init = null
}
node.declarations.push(this.finishNode(decl, "VariableDeclarator"))
if (!this.eat(tt.comma)) break
}
return node
}
pp.parseVarId = function(decl) {
decl.id = this.parseBindingAtom()
this.checkLVal(decl.id, true)
}
// Parse a function declaration or literal (depending on the
// `isStatement` parameter).
pp.parseFunction = function(node, isStatement, allowExpressionBody) {
this.initFunction(node)
if (this.options.ecmaVersion >= 6)
node.generator = this.eat(tt.star)
var oldInGen = this.inGenerator
this.inGenerator = node.generator
if (isStatement || this.type === tt.name)
node.id = this.parseIdent()
this.parseFunctionParams(node)
this.parseFunctionBody(node, allowExpressionBody)
this.inGenerator = oldInGen
return this.finishNode(node, isStatement ? "FunctionDeclaration" : "FunctionExpression")
}
pp.parseFunctionParams = function(node) {
this.expect(tt.parenL)
node.params = this.parseBindingList(tt.parenR, false, false, true)
}
// Parse a class declaration or literal (depending on the
// `isStatement` parameter).
pp.parseClass = function(node, isStatement) {
this.next()
this.parseClassId(node, isStatement)
this.parseClassSuper(node)
let classBody = this.startNode()
let hadConstructor = false
classBody.body = []
this.expect(tt.braceL)
while (!this.eat(tt.braceR)) {
if (this.eat(tt.semi)) continue
let method = this.startNode()
let isGenerator = this.eat(tt.star)
let isMaybeStatic = this.type === tt.name && this.value === "static"
this.parsePropertyName(method)
method.static = isMaybeStatic && this.type !== tt.parenL
if (method.static) {
if (isGenerator) this.unexpected()
isGenerator = this.eat(tt.star)
this.parsePropertyName(method)
}
method.kind = "method"
let isGetSet = false
if (!method.computed) {
let {key} = method
if (!isGenerator && key.type === "Identifier" && this.type !== tt.parenL && (key.name === "get" || key.name === "set")) {
isGetSet = true
method.kind = key.name
key = this.parsePropertyName(method)
}
if (!method.static && (key.type === "Identifier" && key.name === "constructor" ||
key.type === "Literal" && key.value === "constructor")) {
if (hadConstructor) this.raise(key.start, "Duplicate constructor in the same class")
if (isGetSet) this.raise(key.start, "Constructor can't have get/set modifier")
if (isGenerator) this.raise(key.start, "Constructor can't be a generator")
method.kind = "constructor"
hadConstructor = true
}
}
this.parseClassMethod(classBody, method, isGenerator)
if (isGetSet) {
let paramCount = method.kind === "get" ? 0 : 1
if (method.value.params.length !== paramCount) {
let start = method.value.start
if (method.kind === "get")
this.raiseRecoverable(start, "getter should have no params")
else
this.raiseRecoverable(start, "setter should have exactly one param")
}
if (method.kind === "set" && method.value.params[0].type === "RestElement")
this.raise(method.value.params[0].start, "Setter cannot use rest params")
}
}
node.body = this.finishNode(classBody, "ClassBody")
return this.finishNode(node, isStatement ? "ClassDeclaration" : "ClassExpression")
}
pp.parseClassMethod = function(classBody, method, isGenerator) {
method.value = this.parseMethod(isGenerator)
classBody.body.push(this.finishNode(method, "MethodDefinition"))
}
pp.parseClassId = function(node, isStatement) {
node.id = this.type === tt.name ? this.parseIdent() : isStatement ? this.unexpected() : null
}
pp.parseClassSuper = function(node) {
node.superClass = this.eat(tt._extends) ? this.parseExprSubscripts() : null
}
// Parses module export declaration.
pp.parseExport = function(node) {
this.next()
// export * from '...'
if (this.eat(tt.star)) {
this.expectContextual("from")
node.source = this.type === tt.string ? this.parseExprAtom() : this.unexpected()
this.semicolon()
return this.finishNode(node, "ExportAllDeclaration")
}
if (this.eat(tt._default)) { // export default ...
let parens = this.type == tt.parenL
let expr = this.parseMaybeAssign()
let needsSemi = true
if (!parens && (expr.type == "FunctionExpression" ||
expr.type == "ClassExpression")) {
needsSemi = false
if (expr.id) {
expr.type = expr.type == "FunctionExpression"
? "FunctionDeclaration"
: "ClassDeclaration"
}
}
node.declaration = expr
if (needsSemi) this.semicolon()
return this.finishNode(node, "ExportDefaultDeclaration")
}
// export var|const|let|function|class ...
if (this.shouldParseExportStatement()) {
node.declaration = this.parseStatement(true)
node.specifiers = []
node.source = null
} else { // export { x, y as z } [from '...']
node.declaration = null
node.specifiers = this.parseExportSpecifiers()
if (this.eatContextual("from")) {
node.source = this.type === tt.string ? this.parseExprAtom() : this.unexpected()
} else {
// check for keywords used as local names
for (let i = 0; i < node.specifiers.length; i++) {
if (this.keywords.test(node.specifiers[i].local.name) || this.reservedWords.test(node.specifiers[i].local.name)) {
this.unexpected(node.specifiers[i].local.start)
}
}
node.source = null
}
this.semicolon()
}
return this.finishNode(node, "ExportNamedDeclaration")
}
pp.shouldParseExportStatement = function() {
return this.type.keyword || this.isLet()
}
// Parses a comma-separated list of module exports.
pp.parseExportSpecifiers = function() {
let nodes = [], first = true
// export { x, y as z } [from '...']
this.expect(tt.braceL)
while (!this.eat(tt.braceR)) {
if (!first) {
this.expect(tt.comma)
if (this.afterTrailingComma(tt.braceR)) break
} else first = false
let node = this.startNode()
node.local = this.parseIdent(this.type === tt._default)
node.exported = this.eatContextual("as") ? this.parseIdent(true) : node.local
nodes.push(this.finishNode(node, "ExportSpecifier"))
}
return nodes
}
// Parses import declaration.
pp.parseImport = function(node) {
this.next()
// import '...'
if (this.type === tt.string) {
node.specifiers = empty
node.source = this.parseExprAtom()
} else {
node.specifiers = this.parseImportSpecifiers()
this.expectContextual("from")
node.source = this.type === tt.string ? this.parseExprAtom() : this.unexpected()
}
this.semicolon()
return this.finishNode(node, "ImportDeclaration")
}
// Parses a comma-separated list of module imports.
pp.parseImportSpecifiers = function() {
let nodes = [], first = true
if (this.type === tt.name) {
// import defaultObj, { x, y as z } from '...'
let node = this.startNode()
node.local = this.parseIdent()
this.checkLVal(node.local, true)
nodes.push(this.finishNode(node, "ImportDefaultSpecifier"))
if (!this.eat(tt.comma)) return nodes
}
if (this.type === tt.star) {
let node = this.startNode()
this.next()
this.expectContextual("as")
node.local = this.parseIdent()
this.checkLVal(node.local, true)
nodes.push(this.finishNode(node, "ImportNamespaceSpecifier"))
return nodes
}
this.expect(tt.braceL)
while (!this.eat(tt.braceR)) {
if (!first) {
this.expect(tt.comma)
if (this.afterTrailingComma(tt.braceR)) break
} else first = false
let node = this.startNode()
node.imported = this.parseIdent(true)
if (this.eatContextual("as")) {
node.local = this.parseIdent()
} else {
node.local = node.imported
if (this.isKeyword(node.local.name)) this.unexpected(node.local.start)
if (this.reservedWordsStrict.test(node.local.name)) this.raise(node.local.start, "The keyword '" + node.local.name + "' is reserved")
}
this.checkLVal(node.local, true)
nodes.push(this.finishNode(node, "ImportSpecifier"))
}
return nodes
}

110
node_modules/acorn/src/tokencontext.js generated vendored Normal file
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// The algorithm used to determine whether a regexp can appear at a
// given point in the program is loosely based on sweet.js' approach.
// See https://github.com/mozilla/sweet.js/wiki/design
import {Parser} from "./state"
import {types as tt} from "./tokentype"
import {lineBreak} from "./whitespace"
export class TokContext {
constructor(token, isExpr, preserveSpace, override) {
this.token = token
this.isExpr = !!isExpr
this.preserveSpace = !!preserveSpace
this.override = override
}
}
export const types = {
b_stat: new TokContext("{", false),
b_expr: new TokContext("{", true),
b_tmpl: new TokContext("${", true),
p_stat: new TokContext("(", false),
p_expr: new TokContext("(", true),
q_tmpl: new TokContext("`", true, true, p => p.readTmplToken()),
f_expr: new TokContext("function", true)
}
const pp = Parser.prototype
pp.initialContext = function() {
return [types.b_stat]
}
pp.braceIsBlock = function(prevType) {
if (prevType === tt.colon) {
let parent = this.curContext()
if (parent === types.b_stat || parent === types.b_expr)
return !parent.isExpr
}
if (prevType === tt._return)
return lineBreak.test(this.input.slice(this.lastTokEnd, this.start))
if (prevType === tt._else || prevType === tt.semi || prevType === tt.eof || prevType === tt.parenR)
return true
if (prevType == tt.braceL)
return this.curContext() === types.b_stat
return !this.exprAllowed
}
pp.updateContext = function(prevType) {
let update, type = this.type
if (type.keyword && prevType == tt.dot)
this.exprAllowed = false
else if (update = type.updateContext)
update.call(this, prevType)
else
this.exprAllowed = type.beforeExpr
}
// Token-specific context update code
tt.parenR.updateContext = tt.braceR.updateContext = function() {
if (this.context.length == 1) {
this.exprAllowed = true
return
}
let out = this.context.pop()
if (out === types.b_stat && this.curContext() === types.f_expr) {
this.context.pop()
this.exprAllowed = false
} else if (out === types.b_tmpl) {
this.exprAllowed = true
} else {
this.exprAllowed = !out.isExpr
}
}
tt.braceL.updateContext = function(prevType) {
this.context.push(this.braceIsBlock(prevType) ? types.b_stat : types.b_expr)
this.exprAllowed = true
}
tt.dollarBraceL.updateContext = function() {
this.context.push(types.b_tmpl)
this.exprAllowed = true
}
tt.parenL.updateContext = function(prevType) {
let statementParens = prevType === tt._if || prevType === tt._for || prevType === tt._with || prevType === tt._while
this.context.push(statementParens ? types.p_stat : types.p_expr)
this.exprAllowed = true
}
tt.incDec.updateContext = function() {
// tokExprAllowed stays unchanged
}
tt._function.updateContext = function(prevType) {
if (prevType.beforeExpr && prevType !== tt.semi && prevType !== tt._else &&
!((prevType === tt.colon || prevType === tt.braceL) && this.curContext() === types.b_stat))
this.context.push(types.f_expr)
this.exprAllowed = false
}
tt.backQuote.updateContext = function() {
if (this.curContext() === types.q_tmpl)
this.context.pop()
else
this.context.push(types.q_tmpl)
this.exprAllowed = false
}

696
node_modules/acorn/src/tokenize.js generated vendored Normal file
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import {isIdentifierStart, isIdentifierChar} from "./identifier"
import {types as tt, keywords as keywordTypes} from "./tokentype"
import {Parser} from "./state"
import {SourceLocation} from "./locutil"
import {lineBreak, lineBreakG, isNewLine, nonASCIIwhitespace} from "./whitespace"
// Object type used to represent tokens. Note that normally, tokens
// simply exist as properties on the parser object. This is only
// used for the onToken callback and the external tokenizer.
export class Token {
constructor(p) {
this.type = p.type
this.value = p.value
this.start = p.start
this.end = p.end
if (p.options.locations)
this.loc = new SourceLocation(p, p.startLoc, p.endLoc)
if (p.options.ranges)
this.range = [p.start, p.end]
}
}
// ## Tokenizer
const pp = Parser.prototype
// Are we running under Rhino?
const isRhino = typeof Packages == "object" && Object.prototype.toString.call(Packages) == "[object JavaPackage]"
// Move to the next token
pp.next = function() {
if (this.options.onToken)
this.options.onToken(new Token(this))
this.lastTokEnd = this.end
this.lastTokStart = this.start
this.lastTokEndLoc = this.endLoc
this.lastTokStartLoc = this.startLoc
this.nextToken()
}
pp.getToken = function() {
this.next()
return new Token(this)
}
// If we're in an ES6 environment, make parsers iterable
if (typeof Symbol !== "undefined")
pp[Symbol.iterator] = function () {
let self = this
return {next: function () {
let token = self.getToken()
return {
done: token.type === tt.eof,
value: token
}
}}
}
// Toggle strict mode. Re-reads the next number or string to please
// pedantic tests (`"use strict"; 010;` should fail).
pp.setStrict = function(strict) {
this.strict = strict
if (this.type !== tt.num && this.type !== tt.string) return
this.pos = this.start
if (this.options.locations) {
while (this.pos < this.lineStart) {
this.lineStart = this.input.lastIndexOf("\n", this.lineStart - 2) + 1
--this.curLine
}
}
this.nextToken()
}
pp.curContext = function() {
return this.context[this.context.length - 1]
}
// Read a single token, updating the parser object's token-related
// properties.
pp.nextToken = function() {
let curContext = this.curContext()
if (!curContext || !curContext.preserveSpace) this.skipSpace()
this.start = this.pos
if (this.options.locations) this.startLoc = this.curPosition()
if (this.pos >= this.input.length) return this.finishToken(tt.eof)
if (curContext.override) return curContext.override(this)
else this.readToken(this.fullCharCodeAtPos())
}
pp.readToken = function(code) {
// Identifier or keyword. '\uXXXX' sequences are allowed in
// identifiers, so '\' also dispatches to that.
if (isIdentifierStart(code, this.options.ecmaVersion >= 6) || code === 92 /* '\' */)
return this.readWord()
return this.getTokenFromCode(code)
}
pp.fullCharCodeAtPos = function() {
let code = this.input.charCodeAt(this.pos)
if (code <= 0xd7ff || code >= 0xe000) return code
let next = this.input.charCodeAt(this.pos + 1)
return (code << 10) + next - 0x35fdc00
}
pp.skipBlockComment = function() {
let startLoc = this.options.onComment && this.curPosition()
let start = this.pos, end = this.input.indexOf("*/", this.pos += 2)
if (end === -1) this.raise(this.pos - 2, "Unterminated comment")
this.pos = end + 2
if (this.options.locations) {
lineBreakG.lastIndex = start
let match
while ((match = lineBreakG.exec(this.input)) && match.index < this.pos) {
++this.curLine
this.lineStart = match.index + match[0].length
}
}
if (this.options.onComment)
this.options.onComment(true, this.input.slice(start + 2, end), start, this.pos,
startLoc, this.curPosition())
}
pp.skipLineComment = function(startSkip) {
let start = this.pos
let startLoc = this.options.onComment && this.curPosition()
let ch = this.input.charCodeAt(this.pos+=startSkip)
while (this.pos < this.input.length && ch !== 10 && ch !== 13 && ch !== 8232 && ch !== 8233) {
++this.pos
ch = this.input.charCodeAt(this.pos)
}
if (this.options.onComment)
this.options.onComment(false, this.input.slice(start + startSkip, this.pos), start, this.pos,
startLoc, this.curPosition())
}
// Called at the start of the parse and after every token. Skips
// whitespace and comments, and.
pp.skipSpace = function() {
loop: while (this.pos < this.input.length) {
let ch = this.input.charCodeAt(this.pos)
switch (ch) {
case 32: case 160: // ' '
++this.pos
break
case 13:
if (this.input.charCodeAt(this.pos + 1) === 10) {
++this.pos
}
case 10: case 8232: case 8233:
++this.pos
if (this.options.locations) {
++this.curLine
this.lineStart = this.pos
}
break
case 47: // '/'
switch (this.input.charCodeAt(this.pos + 1)) {
case 42: // '*'
this.skipBlockComment()
break
case 47:
this.skipLineComment(2)
break
default:
break loop
}
break
default:
if (ch > 8 && ch < 14 || ch >= 5760 && nonASCIIwhitespace.test(String.fromCharCode(ch))) {
++this.pos
} else {
break loop
}
}
}
}
// Called at the end of every token. Sets `end`, `val`, and
// maintains `context` and `exprAllowed`, and skips the space after
// the token, so that the next one's `start` will point at the
// right position.
pp.finishToken = function(type, val) {
this.end = this.pos
if (this.options.locations) this.endLoc = this.curPosition()
let prevType = this.type
this.type = type
this.value = val
this.updateContext(prevType)
}
// ### Token reading
// This is the function that is called to fetch the next token. It
// is somewhat obscure, because it works in character codes rather
// than characters, and because operator parsing has been inlined
// into it.
//
// All in the name of speed.
//
pp.readToken_dot = function() {
let next = this.input.charCodeAt(this.pos + 1)
if (next >= 48 && next <= 57) return this.readNumber(true)
let next2 = this.input.charCodeAt(this.pos + 2)
if (this.options.ecmaVersion >= 6 && next === 46 && next2 === 46) { // 46 = dot '.'
this.pos += 3
return this.finishToken(tt.ellipsis)
} else {
++this.pos
return this.finishToken(tt.dot)
}
}
pp.readToken_slash = function() { // '/'
let next = this.input.charCodeAt(this.pos + 1)
if (this.exprAllowed) {++this.pos; return this.readRegexp()}
if (next === 61) return this.finishOp(tt.assign, 2)
return this.finishOp(tt.slash, 1)
}
pp.readToken_mult_modulo_exp = function(code) { // '%*'
let next = this.input.charCodeAt(this.pos + 1)
let size = 1
let tokentype = code === 42 ? tt.star : tt.modulo
// exponentiation operator ** and **=
if (this.options.ecmaVersion >= 7 && next === 42) {
++size
tokentype = tt.starstar
next = this.input.charCodeAt(this.pos + 2)
}
if (next === 61) return this.finishOp(tt.assign, size + 1)
return this.finishOp(tokentype, size)
}
pp.readToken_pipe_amp = function(code) { // '|&'
let next = this.input.charCodeAt(this.pos + 1)
if (next === code) return this.finishOp(code === 124 ? tt.logicalOR : tt.logicalAND, 2)
if (next === 61) return this.finishOp(tt.assign, 2)
return this.finishOp(code === 124 ? tt.bitwiseOR : tt.bitwiseAND, 1)
}
pp.readToken_caret = function() { // '^'
let next = this.input.charCodeAt(this.pos + 1)
if (next === 61) return this.finishOp(tt.assign, 2)
return this.finishOp(tt.bitwiseXOR, 1)
}
pp.readToken_plus_min = function(code) { // '+-'
let next = this.input.charCodeAt(this.pos + 1)
if (next === code) {
if (next == 45 && this.input.charCodeAt(this.pos + 2) == 62 &&
lineBreak.test(this.input.slice(this.lastTokEnd, this.pos))) {
// A `-->` line comment
this.skipLineComment(3)
this.skipSpace()
return this.nextToken()
}
return this.finishOp(tt.incDec, 2)
}
if (next === 61) return this.finishOp(tt.assign, 2)
return this.finishOp(tt.plusMin, 1)
}
pp.readToken_lt_gt = function(code) { // '<>'
let next = this.input.charCodeAt(this.pos + 1)
let size = 1
if (next === code) {
size = code === 62 && this.input.charCodeAt(this.pos + 2) === 62 ? 3 : 2
if (this.input.charCodeAt(this.pos + size) === 61) return this.finishOp(tt.assign, size + 1)
return this.finishOp(tt.bitShift, size)
}
if (next == 33 && code == 60 && this.input.charCodeAt(this.pos + 2) == 45 &&
this.input.charCodeAt(this.pos + 3) == 45) {
if (this.inModule) this.unexpected()
// `<!--`, an XML-style comment that should be interpreted as a line comment
this.skipLineComment(4)
this.skipSpace()
return this.nextToken()
}
if (next === 61) size = 2
return this.finishOp(tt.relational, size)
}
pp.readToken_eq_excl = function(code) { // '=!'
let next = this.input.charCodeAt(this.pos + 1)
if (next === 61) return this.finishOp(tt.equality, this.input.charCodeAt(this.pos + 2) === 61 ? 3 : 2)
if (code === 61 && next === 62 && this.options.ecmaVersion >= 6) { // '=>'
this.pos += 2
return this.finishToken(tt.arrow)
}
return this.finishOp(code === 61 ? tt.eq : tt.prefix, 1)
}
pp.getTokenFromCode = function(code) {
switch (code) {
// The interpretation of a dot depends on whether it is followed
// by a digit or another two dots.
case 46: // '.'
return this.readToken_dot()
// Punctuation tokens.
case 40: ++this.pos; return this.finishToken(tt.parenL)
case 41: ++this.pos; return this.finishToken(tt.parenR)
case 59: ++this.pos; return this.finishToken(tt.semi)
case 44: ++this.pos; return this.finishToken(tt.comma)
case 91: ++this.pos; return this.finishToken(tt.bracketL)
case 93: ++this.pos; return this.finishToken(tt.bracketR)
case 123: ++this.pos; return this.finishToken(tt.braceL)
case 125: ++this.pos; return this.finishToken(tt.braceR)
case 58: ++this.pos; return this.finishToken(tt.colon)
case 63: ++this.pos; return this.finishToken(tt.question)
case 96: // '`'
if (this.options.ecmaVersion < 6) break
++this.pos
return this.finishToken(tt.backQuote)
case 48: // '0'
let next = this.input.charCodeAt(this.pos + 1)
if (next === 120 || next === 88) return this.readRadixNumber(16) // '0x', '0X' - hex number
if (this.options.ecmaVersion >= 6) {
if (next === 111 || next === 79) return this.readRadixNumber(8) // '0o', '0O' - octal number
if (next === 98 || next === 66) return this.readRadixNumber(2) // '0b', '0B' - binary number
}
// Anything else beginning with a digit is an integer, octal
// number, or float.
case 49: case 50: case 51: case 52: case 53: case 54: case 55: case 56: case 57: // 1-9
return this.readNumber(false)
// Quotes produce strings.
case 34: case 39: // '"', "'"
return this.readString(code)
// Operators are parsed inline in tiny state machines. '=' (61) is
// often referred to. `finishOp` simply skips the amount of
// characters it is given as second argument, and returns a token
// of the type given by its first argument.
case 47: // '/'
return this.readToken_slash()
case 37: case 42: // '%*'
return this.readToken_mult_modulo_exp(code)
case 124: case 38: // '|&'
return this.readToken_pipe_amp(code)
case 94: // '^'
return this.readToken_caret()
case 43: case 45: // '+-'
return this.readToken_plus_min(code)
case 60: case 62: // '<>'
return this.readToken_lt_gt(code)
case 61: case 33: // '=!'
return this.readToken_eq_excl(code)
case 126: // '~'
return this.finishOp(tt.prefix, 1)
}
this.raise(this.pos, "Unexpected character '" + codePointToString(code) + "'")
}
pp.finishOp = function(type, size) {
let str = this.input.slice(this.pos, this.pos + size)
this.pos += size
return this.finishToken(type, str)
}
// Parse a regular expression. Some context-awareness is necessary,
// since a '/' inside a '[]' set does not end the expression.
function tryCreateRegexp(src, flags, throwErrorAt, parser) {
try {
return new RegExp(src, flags)
} catch (e) {
if (throwErrorAt !== undefined) {
if (e instanceof SyntaxError) parser.raise(throwErrorAt, "Error parsing regular expression: " + e.message)
throw e
}
}
}
var regexpUnicodeSupport = !!tryCreateRegexp("\uffff", "u")
pp.readRegexp = function() {
let escaped, inClass, start = this.pos
for (;;) {
if (this.pos >= this.input.length) this.raise(start, "Unterminated regular expression")
let ch = this.input.charAt(this.pos)
if (lineBreak.test(ch)) this.raise(start, "Unterminated regular expression")
if (!escaped) {
if (ch === "[") inClass = true
else if (ch === "]" && inClass) inClass = false
else if (ch === "/" && !inClass) break
escaped = ch === "\\"
} else escaped = false
++this.pos
}
let content = this.input.slice(start, this.pos)
++this.pos
// Need to use `readWord1` because '\uXXXX' sequences are allowed
// here (don't ask).
let mods = this.readWord1()
let tmp = content, tmpFlags = ""
if (mods) {
let validFlags = /^[gim]*$/
if (this.options.ecmaVersion >= 6) validFlags = /^[gimuy]*$/
if (!validFlags.test(mods)) this.raise(start, "Invalid regular expression flag")
if (mods.indexOf("u") >= 0) {
if (regexpUnicodeSupport) {
tmpFlags = "u"
} else {
// Replace each astral symbol and every Unicode escape sequence that
// possibly represents an astral symbol or a paired surrogate with a
// single ASCII symbol to avoid throwing on regular expressions that
// are only valid in combination with the `/u` flag.
// Note: replacing with the ASCII symbol `x` might cause false
// negatives in unlikely scenarios. For example, `[\u{61}-b]` is a
// perfectly valid pattern that is equivalent to `[a-b]`, but it would
// be replaced by `[x-b]` which throws an error.
tmp = tmp.replace(/\\u\{([0-9a-fA-F]+)\}/g, (_match, code, offset) => {
code = Number("0x" + code)
if (code > 0x10FFFF) this.raise(start + offset + 3, "Code point out of bounds")
return "x"
})
tmp = tmp.replace(/\\u([a-fA-F0-9]{4})|[\uD800-\uDBFF][\uDC00-\uDFFF]/g, "x")
tmpFlags = tmpFlags.replace("u", "")
}
}
}
// Detect invalid regular expressions.
let value = null
// Rhino's regular expression parser is flaky and throws uncatchable exceptions,
// so don't do detection if we are running under Rhino
if (!isRhino) {
tryCreateRegexp(tmp, tmpFlags, start, this)
// Get a regular expression object for this pattern-flag pair, or `null` in
// case the current environment doesn't support the flags it uses.
value = tryCreateRegexp(content, mods)
}
return this.finishToken(tt.regexp, {pattern: content, flags: mods, value: value})
}
// Read an integer in the given radix. Return null if zero digits
// were read, the integer value otherwise. When `len` is given, this
// will return `null` unless the integer has exactly `len` digits.
pp.readInt = function(radix, len) {
let start = this.pos, total = 0
for (let i = 0, e = len == null ? Infinity : len; i < e; ++i) {
let code = this.input.charCodeAt(this.pos), val
if (code >= 97) val = code - 97 + 10 // a
else if (code >= 65) val = code - 65 + 10 // A
else if (code >= 48 && code <= 57) val = code - 48 // 0-9
else val = Infinity
if (val >= radix) break
++this.pos
total = total * radix + val
}
if (this.pos === start || len != null && this.pos - start !== len) return null
return total
}
pp.readRadixNumber = function(radix) {
this.pos += 2 // 0x
let val = this.readInt(radix)
if (val == null) this.raise(this.start + 2, "Expected number in radix " + radix)
if (isIdentifierStart(this.fullCharCodeAtPos())) this.raise(this.pos, "Identifier directly after number")
return this.finishToken(tt.num, val)
}
// Read an integer, octal integer, or floating-point number.
pp.readNumber = function(startsWithDot) {
let start = this.pos, isFloat = false, octal = this.input.charCodeAt(this.pos) === 48
if (!startsWithDot && this.readInt(10) === null) this.raise(start, "Invalid number")
let next = this.input.charCodeAt(this.pos)
if (next === 46) { // '.'
++this.pos
this.readInt(10)
isFloat = true
next = this.input.charCodeAt(this.pos)
}
if (next === 69 || next === 101) { // 'eE'
next = this.input.charCodeAt(++this.pos)
if (next === 43 || next === 45) ++this.pos // '+-'
if (this.readInt(10) === null) this.raise(start, "Invalid number")
isFloat = true
}
if (isIdentifierStart(this.fullCharCodeAtPos())) this.raise(this.pos, "Identifier directly after number")
let str = this.input.slice(start, this.pos), val
if (isFloat) val = parseFloat(str)
else if (!octal || str.length === 1) val = parseInt(str, 10)
else if (/[89]/.test(str) || this.strict) this.raise(start, "Invalid number")
else val = parseInt(str, 8)
return this.finishToken(tt.num, val)
}
// Read a string value, interpreting backslash-escapes.
pp.readCodePoint = function() {
let ch = this.input.charCodeAt(this.pos), code
if (ch === 123) {
if (this.options.ecmaVersion < 6) this.unexpected()
let codePos = ++this.pos
code = this.readHexChar(this.input.indexOf('}', this.pos) - this.pos)
++this.pos
if (code > 0x10FFFF) this.raise(codePos, "Code point out of bounds")
} else {
code = this.readHexChar(4)
}
return code
}
function codePointToString(code) {
// UTF-16 Decoding
if (code <= 0xFFFF) return String.fromCharCode(code)
code -= 0x10000
return String.fromCharCode((code >> 10) + 0xD800, (code & 1023) + 0xDC00)
}
pp.readString = function(quote) {
let out = "", chunkStart = ++this.pos
for (;;) {
if (this.pos >= this.input.length) this.raise(this.start, "Unterminated string constant")
let ch = this.input.charCodeAt(this.pos)
if (ch === quote) break
if (ch === 92) { // '\'
out += this.input.slice(chunkStart, this.pos)
out += this.readEscapedChar(false)
chunkStart = this.pos
} else {
if (isNewLine(ch)) this.raise(this.start, "Unterminated string constant")
++this.pos
}
}
out += this.input.slice(chunkStart, this.pos++)
return this.finishToken(tt.string, out)
}
// Reads template string tokens.
pp.readTmplToken = function() {
let out = "", chunkStart = this.pos
for (;;) {
if (this.pos >= this.input.length) this.raise(this.start, "Unterminated template")
let ch = this.input.charCodeAt(this.pos)
if (ch === 96 || ch === 36 && this.input.charCodeAt(this.pos + 1) === 123) { // '`', '${'
if (this.pos === this.start && this.type === tt.template) {
if (ch === 36) {
this.pos += 2
return this.finishToken(tt.dollarBraceL)
} else {
++this.pos
return this.finishToken(tt.backQuote)
}
}
out += this.input.slice(chunkStart, this.pos)
return this.finishToken(tt.template, out)
}
if (ch === 92) { // '\'
out += this.input.slice(chunkStart, this.pos)
out += this.readEscapedChar(true)
chunkStart = this.pos
} else if (isNewLine(ch)) {
out += this.input.slice(chunkStart, this.pos)
++this.pos
switch (ch) {
case 13:
if (this.input.charCodeAt(this.pos) === 10) ++this.pos
case 10:
out += "\n"
break
default:
out += String.fromCharCode(ch)
break
}
if (this.options.locations) {
++this.curLine
this.lineStart = this.pos
}
chunkStart = this.pos
} else {
++this.pos
}
}
}
// Used to read escaped characters
pp.readEscapedChar = function(inTemplate) {
let ch = this.input.charCodeAt(++this.pos)
++this.pos
switch (ch) {
case 110: return "\n" // 'n' -> '\n'
case 114: return "\r" // 'r' -> '\r'
case 120: return String.fromCharCode(this.readHexChar(2)) // 'x'
case 117: return codePointToString(this.readCodePoint()) // 'u'
case 116: return "\t" // 't' -> '\t'
case 98: return "\b" // 'b' -> '\b'
case 118: return "\u000b" // 'v' -> '\u000b'
case 102: return "\f" // 'f' -> '\f'
case 13: if (this.input.charCodeAt(this.pos) === 10) ++this.pos // '\r\n'
case 10: // ' \n'
if (this.options.locations) { this.lineStart = this.pos; ++this.curLine }
return ""
default:
if (ch >= 48 && ch <= 55) {
let octalStr = this.input.substr(this.pos - 1, 3).match(/^[0-7]+/)[0]
let octal = parseInt(octalStr, 8)
if (octal > 255) {
octalStr = octalStr.slice(0, -1)
octal = parseInt(octalStr, 8)
}
if (octalStr !== "0" && (this.strict || inTemplate)) {
this.raise(this.pos - 2, "Octal literal in strict mode")
}
this.pos += octalStr.length - 1
return String.fromCharCode(octal)
}
return String.fromCharCode(ch)
}
}
// Used to read character escape sequences ('\x', '\u', '\U').
pp.readHexChar = function(len) {
let codePos = this.pos
let n = this.readInt(16, len)
if (n === null) this.raise(codePos, "Bad character escape sequence")
return n
}
// Read an identifier, and return it as a string. Sets `this.containsEsc`
// to whether the word contained a '\u' escape.
//
// Incrementally adds only escaped chars, adding other chunks as-is
// as a micro-optimization.
pp.readWord1 = function() {
this.containsEsc = false
let word = "", first = true, chunkStart = this.pos
let astral = this.options.ecmaVersion >= 6
while (this.pos < this.input.length) {
let ch = this.fullCharCodeAtPos()
if (isIdentifierChar(ch, astral)) {
this.pos += ch <= 0xffff ? 1 : 2
} else if (ch === 92) { // "\"
this.containsEsc = true
word += this.input.slice(chunkStart, this.pos)
let escStart = this.pos
if (this.input.charCodeAt(++this.pos) != 117) // "u"
this.raise(this.pos, "Expecting Unicode escape sequence \\uXXXX")
++this.pos
let esc = this.readCodePoint()
if (!(first ? isIdentifierStart : isIdentifierChar)(esc, astral))
this.raise(escStart, "Invalid Unicode escape")
word += codePointToString(esc)
chunkStart = this.pos
} else {
break
}
first = false
}
return word + this.input.slice(chunkStart, this.pos)
}
// Read an identifier or keyword token. Will check for reserved
// words when necessary.
pp.readWord = function() {
let word = this.readWord1()
let type = tt.name
if ((this.options.ecmaVersion >= 6 || !this.containsEsc) && this.keywords.test(word))
type = keywordTypes[word]
return this.finishToken(type, word)
}

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node_modules/acorn/src/tokentype.js generated vendored Normal file
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// ## Token types
// The assignment of fine-grained, information-carrying type objects
// allows the tokenizer to store the information it has about a
// token in a way that is very cheap for the parser to look up.
// All token type variables start with an underscore, to make them
// easy to recognize.
// The `beforeExpr` property is used to disambiguate between regular
// expressions and divisions. It is set on all token types that can
// be followed by an expression (thus, a slash after them would be a
// regular expression).
//
// The `startsExpr` property is used to check if the token ends a
// `yield` expression. It is set on all token types that either can
// directly start an expression (like a quotation mark) or can
// continue an expression (like the body of a string).
//
// `isLoop` marks a keyword as starting a loop, which is important
// to know when parsing a label, in order to allow or disallow
// continue jumps to that label.
export class TokenType {
constructor(label, conf = {}) {
this.label = label
this.keyword = conf.keyword
this.beforeExpr = !!conf.beforeExpr
this.startsExpr = !!conf.startsExpr
this.isLoop = !!conf.isLoop
this.isAssign = !!conf.isAssign
this.prefix = !!conf.prefix
this.postfix = !!conf.postfix
this.binop = conf.binop || null
this.updateContext = null
}
}
function binop(name, prec) {
return new TokenType(name, {beforeExpr: true, binop: prec})
}
const beforeExpr = {beforeExpr: true}, startsExpr = {startsExpr: true}
// Map keyword names to token types.
export const keywords = {}
// Succinct definitions of keyword token types
function kw(name, options = {}) {
options.keyword = name
return keywords[name] = new TokenType(name, options)
}
export const types = {
num: new TokenType("num", startsExpr),
regexp: new TokenType("regexp", startsExpr),
string: new TokenType("string", startsExpr),
name: new TokenType("name", startsExpr),
eof: new TokenType("eof"),
// Punctuation token types.
bracketL: new TokenType("[", {beforeExpr: true, startsExpr: true}),
bracketR: new TokenType("]"),
braceL: new TokenType("{", {beforeExpr: true, startsExpr: true}),
braceR: new TokenType("}"),
parenL: new TokenType("(", {beforeExpr: true, startsExpr: true}),
parenR: new TokenType(")"),
comma: new TokenType(",", beforeExpr),
semi: new TokenType(";", beforeExpr),
colon: new TokenType(":", beforeExpr),
dot: new TokenType("."),
question: new TokenType("?", beforeExpr),
arrow: new TokenType("=>", beforeExpr),
template: new TokenType("template"),
ellipsis: new TokenType("...", beforeExpr),
backQuote: new TokenType("`", startsExpr),
dollarBraceL: new TokenType("${", {beforeExpr: true, startsExpr: true}),
// Operators. These carry several kinds of properties to help the
// parser use them properly (the presence of these properties is
// what categorizes them as operators).
//
// `binop`, when present, specifies that this operator is a binary
// operator, and will refer to its precedence.
//
// `prefix` and `postfix` mark the operator as a prefix or postfix
// unary operator.
//
// `isAssign` marks all of `=`, `+=`, `-=` etcetera, which act as
// binary operators with a very low precedence, that should result
// in AssignmentExpression nodes.
eq: new TokenType("=", {beforeExpr: true, isAssign: true}),
assign: new TokenType("_=", {beforeExpr: true, isAssign: true}),
incDec: new TokenType("++/--", {prefix: true, postfix: true, startsExpr: true}),
prefix: new TokenType("prefix", {beforeExpr: true, prefix: true, startsExpr: true}),
logicalOR: binop("||", 1),
logicalAND: binop("&&", 2),
bitwiseOR: binop("|", 3),
bitwiseXOR: binop("^", 4),
bitwiseAND: binop("&", 5),
equality: binop("==/!=", 6),
relational: binop("</>", 7),
bitShift: binop("<</>>", 8),
plusMin: new TokenType("+/-", {beforeExpr: true, binop: 9, prefix: true, startsExpr: true}),
modulo: binop("%", 10),
star: binop("*", 10),
slash: binop("/", 10),
starstar: new TokenType("**", {beforeExpr: true}),
// Keyword token types.
_break: kw("break"),
_case: kw("case", beforeExpr),
_catch: kw("catch"),
_continue: kw("continue"),
_debugger: kw("debugger"),
_default: kw("default", beforeExpr),
_do: kw("do", {isLoop: true, beforeExpr: true}),
_else: kw("else", beforeExpr),
_finally: kw("finally"),
_for: kw("for", {isLoop: true}),
_function: kw("function", startsExpr),
_if: kw("if"),
_return: kw("return", beforeExpr),
_switch: kw("switch"),
_throw: kw("throw", beforeExpr),
_try: kw("try"),
_var: kw("var"),
_const: kw("const"),
_while: kw("while", {isLoop: true}),
_with: kw("with"),
_new: kw("new", {beforeExpr: true, startsExpr: true}),
_this: kw("this", startsExpr),
_super: kw("super", startsExpr),
_class: kw("class"),
_extends: kw("extends", beforeExpr),
_export: kw("export"),
_import: kw("import"),
_null: kw("null", startsExpr),
_true: kw("true", startsExpr),
_false: kw("false", startsExpr),
_in: kw("in", {beforeExpr: true, binop: 7}),
_instanceof: kw("instanceof", {beforeExpr: true, binop: 7}),
_typeof: kw("typeof", {beforeExpr: true, prefix: true, startsExpr: true}),
_void: kw("void", {beforeExpr: true, prefix: true, startsExpr: true}),
_delete: kw("delete", {beforeExpr: true, prefix: true, startsExpr: true})
}

9
node_modules/acorn/src/util.js generated vendored Normal file
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export function isArray(obj) {
return Object.prototype.toString.call(obj) === "[object Array]"
}
// Checks if an object has a property.
export function has(obj, propName) {
return Object.prototype.hasOwnProperty.call(obj, propName)
}

342
node_modules/acorn/src/walk/index.js generated vendored Normal file
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// AST walker module for Mozilla Parser API compatible trees
// A simple walk is one where you simply specify callbacks to be
// called on specific nodes. The last two arguments are optional. A
// simple use would be
//
// walk.simple(myTree, {
// Expression: function(node) { ... }
// });
//
// to do something with all expressions. All Parser API node types
// can be used to identify node types, as well as Expression,
// Statement, and ScopeBody, which denote categories of nodes.
//
// The base argument can be used to pass a custom (recursive)
// walker, and state can be used to give this walked an initial
// state.
export function simple(node, visitors, base, state, override) {
if (!base) base = exports.base
;(function c(node, st, override) {
let type = override || node.type, found = visitors[type]
base[type](node, st, c)
if (found) found(node, st)
})(node, state, override)
}
// An ancestor walk keeps an array of ancestor nodes (including the
// current node) and passes them to the callback as third parameter
// (and also as state parameter when no other state is present).
export function ancestor(node, visitors, base, state) {
if (!base) base = exports.base
let ancestors = []
;(function c(node, st, override) {
let type = override || node.type, found = visitors[type]
let isNew = node != ancestors[ancestors.length - 1]
if (isNew) ancestors.push(node)
base[type](node, st, c)
if (found) found(node, st || ancestors, ancestors)
if (isNew) ancestors.pop()
})(node, state)
}
// A recursive walk is one where your functions override the default
// walkers. They can modify and replace the state parameter that's
// threaded through the walk, and can opt how and whether to walk
// their child nodes (by calling their third argument on these
// nodes).
export function recursive(node, state, funcs, base, override) {
let visitor = funcs ? exports.make(funcs, base) : base
;(function c(node, st, override) {
visitor[override || node.type](node, st, c)
})(node, state, override)
}
function makeTest(test) {
if (typeof test == "string")
return type => type == test
else if (!test)
return () => true
else
return test
}
class Found {
constructor(node, state) { this.node = node; this.state = state }
}
// Find a node with a given start, end, and type (all are optional,
// null can be used as wildcard). Returns a {node, state} object, or
// undefined when it doesn't find a matching node.
export function findNodeAt(node, start, end, test, base, state) {
test = makeTest(test)
if (!base) base = exports.base
try {
;(function c(node, st, override) {
let type = override || node.type
if ((start == null || node.start <= start) &&
(end == null || node.end >= end))
base[type](node, st, c)
if ((start == null || node.start == start) &&
(end == null || node.end == end) &&
test(type, node))
throw new Found(node, st)
})(node, state)
} catch (e) {
if (e instanceof Found) return e
throw e
}
}
// Find the innermost node of a given type that contains the given
// position. Interface similar to findNodeAt.
export function findNodeAround(node, pos, test, base, state) {
test = makeTest(test)
if (!base) base = exports.base
try {
;(function c(node, st, override) {
let type = override || node.type
if (node.start > pos || node.end < pos) return
base[type](node, st, c)
if (test(type, node)) throw new Found(node, st)
})(node, state)
} catch (e) {
if (e instanceof Found) return e
throw e
}
}
// Find the outermost matching node after a given position.
export function findNodeAfter(node, pos, test, base, state) {
test = makeTest(test)
if (!base) base = exports.base
try {
;(function c(node, st, override) {
if (node.end < pos) return
let type = override || node.type
if (node.start >= pos && test(type, node)) throw new Found(node, st)
base[type](node, st, c)
})(node, state)
} catch (e) {
if (e instanceof Found) return e
throw e
}
}
// Find the outermost matching node before a given position.
export function findNodeBefore(node, pos, test, base, state) {
test = makeTest(test)
if (!base) base = exports.base
let max
;(function c(node, st, override) {
if (node.start > pos) return
let type = override || node.type
if (node.end <= pos && (!max || max.node.end < node.end) && test(type, node))
max = new Found(node, st)
base[type](node, st, c)
})(node, state)
return max
}
// Fallback to an Object.create polyfill for older environments.
const create = Object.create || function(proto) {
function Ctor() {}
Ctor.prototype = proto
return new Ctor
}
// Used to create a custom walker. Will fill in all missing node
// type properties with the defaults.
export function make(funcs, base) {
if (!base) base = exports.base
let visitor = create(base)
for (var type in funcs) visitor[type] = funcs[type]
return visitor
}
function skipThrough(node, st, c) { c(node, st) }
function ignore(_node, _st, _c) {}
// Node walkers.
export const base = {}
base.Program = base.BlockStatement = (node, st, c) => {
for (let i = 0; i < node.body.length; ++i)
c(node.body[i], st, "Statement")
}
base.Statement = skipThrough
base.EmptyStatement = ignore
base.ExpressionStatement = base.ParenthesizedExpression =
(node, st, c) => c(node.expression, st, "Expression")
base.IfStatement = (node, st, c) => {
c(node.test, st, "Expression")
c(node.consequent, st, "Statement")
if (node.alternate) c(node.alternate, st, "Statement")
}
base.LabeledStatement = (node, st, c) => c(node.body, st, "Statement")
base.BreakStatement = base.ContinueStatement = ignore
base.WithStatement = (node, st, c) => {
c(node.object, st, "Expression")
c(node.body, st, "Statement")
}
base.SwitchStatement = (node, st, c) => {
c(node.discriminant, st, "Expression")
for (let i = 0; i < node.cases.length; ++i) {
let cs = node.cases[i]
if (cs.test) c(cs.test, st, "Expression")
for (let j = 0; j < cs.consequent.length; ++j)
c(cs.consequent[j], st, "Statement")
}
}
base.ReturnStatement = base.YieldExpression = (node, st, c) => {
if (node.argument) c(node.argument, st, "Expression")
}
base.ThrowStatement = base.SpreadElement =
(node, st, c) => c(node.argument, st, "Expression")
base.TryStatement = (node, st, c) => {
c(node.block, st, "Statement")
if (node.handler) c(node.handler, st)
if (node.finalizer) c(node.finalizer, st, "Statement")
}
base.CatchClause = (node, st, c) => {
c(node.param, st, "Pattern")
c(node.body, st, "ScopeBody")
}
base.WhileStatement = base.DoWhileStatement = (node, st, c) => {
c(node.test, st, "Expression")
c(node.body, st, "Statement")
}
base.ForStatement = (node, st, c) => {
if (node.init) c(node.init, st, "ForInit")
if (node.test) c(node.test, st, "Expression")
if (node.update) c(node.update, st, "Expression")
c(node.body, st, "Statement")
}
base.ForInStatement = base.ForOfStatement = (node, st, c) => {
c(node.left, st, "ForInit")
c(node.right, st, "Expression")
c(node.body, st, "Statement")
}
base.ForInit = (node, st, c) => {
if (node.type == "VariableDeclaration") c(node, st)
else c(node, st, "Expression")
}
base.DebuggerStatement = ignore
base.FunctionDeclaration = (node, st, c) => c(node, st, "Function")
base.VariableDeclaration = (node, st, c) => {
for (let i = 0; i < node.declarations.length; ++i)
c(node.declarations[i], st)
}
base.VariableDeclarator = (node, st, c) => {
c(node.id, st, "Pattern")
if (node.init) c(node.init, st, "Expression")
}
base.Function = (node, st, c) => {
if (node.id) c(node.id, st, "Pattern")
for (let i = 0; i < node.params.length; i++)
c(node.params[i], st, "Pattern")
c(node.body, st, node.expression ? "ScopeExpression" : "ScopeBody")
}
// FIXME drop these node types in next major version
// (They are awkward, and in ES6 every block can be a scope.)
base.ScopeBody = (node, st, c) => c(node, st, "Statement")
base.ScopeExpression = (node, st, c) => c(node, st, "Expression")
base.Pattern = (node, st, c) => {
if (node.type == "Identifier")
c(node, st, "VariablePattern")
else if (node.type == "MemberExpression")
c(node, st, "MemberPattern")
else
c(node, st)
}
base.VariablePattern = ignore
base.MemberPattern = skipThrough
base.RestElement = (node, st, c) => c(node.argument, st, "Pattern")
base.ArrayPattern = (node, st, c) => {
for (let i = 0; i < node.elements.length; ++i) {
let elt = node.elements[i]
if (elt) c(elt, st, "Pattern")
}
}
base.ObjectPattern = (node, st, c) => {
for (let i = 0; i < node.properties.length; ++i)
c(node.properties[i].value, st, "Pattern")
}
base.Expression = skipThrough
base.ThisExpression = base.Super = base.MetaProperty = ignore
base.ArrayExpression = (node, st, c) => {
for (let i = 0; i < node.elements.length; ++i) {
let elt = node.elements[i]
if (elt) c(elt, st, "Expression")
}
}
base.ObjectExpression = (node, st, c) => {
for (let i = 0; i < node.properties.length; ++i)
c(node.properties[i], st)
}
base.FunctionExpression = base.ArrowFunctionExpression = base.FunctionDeclaration
base.SequenceExpression = base.TemplateLiteral = (node, st, c) => {
for (let i = 0; i < node.expressions.length; ++i)
c(node.expressions[i], st, "Expression")
}
base.UnaryExpression = base.UpdateExpression = (node, st, c) => {
c(node.argument, st, "Expression")
}
base.BinaryExpression = base.LogicalExpression = (node, st, c) => {
c(node.left, st, "Expression")
c(node.right, st, "Expression")
}
base.AssignmentExpression = base.AssignmentPattern = (node, st, c) => {
c(node.left, st, "Pattern")
c(node.right, st, "Expression")
}
base.ConditionalExpression = (node, st, c) => {
c(node.test, st, "Expression")
c(node.consequent, st, "Expression")
c(node.alternate, st, "Expression")
}
base.NewExpression = base.CallExpression = (node, st, c) => {
c(node.callee, st, "Expression")
if (node.arguments) for (let i = 0; i < node.arguments.length; ++i)
c(node.arguments[i], st, "Expression")
}
base.MemberExpression = (node, st, c) => {
c(node.object, st, "Expression")
if (node.computed) c(node.property, st, "Expression")
}
base.ExportNamedDeclaration = base.ExportDefaultDeclaration = (node, st, c) => {
if (node.declaration)
c(node.declaration, st, node.type == "ExportNamedDeclaration" || node.declaration.id ? "Statement" : "Expression")
if (node.source) c(node.source, st, "Expression")
}
base.ExportAllDeclaration = (node, st, c) => {
c(node.source, st, "Expression")
}
base.ImportDeclaration = (node, st, c) => {
for (let i = 0; i < node.specifiers.length; i++)
c(node.specifiers[i], st)
c(node.source, st, "Expression")
}
base.ImportSpecifier = base.ImportDefaultSpecifier = base.ImportNamespaceSpecifier = base.Identifier = base.Literal = ignore
base.TaggedTemplateExpression = (node, st, c) => {
c(node.tag, st, "Expression")
c(node.quasi, st)
}
base.ClassDeclaration = base.ClassExpression = (node, st, c) => c(node, st, "Class")
base.Class = (node, st, c) => {
if (node.id) c(node.id, st, "Pattern")
if (node.superClass) c(node.superClass, st, "Expression")
for (let i = 0; i < node.body.body.length; i++)
c(node.body.body[i], st)
}
base.MethodDefinition = base.Property = (node, st, c) => {
if (node.computed) c(node.key, st, "Expression")
c(node.value, st, "Expression")
}

13
node_modules/acorn/src/whitespace.js generated vendored Normal file
View File

@@ -0,0 +1,13 @@
// Matches a whole line break (where CRLF is considered a single
// line break). Used to count lines.
export const lineBreak = /\r\n?|\n|\u2028|\u2029/
export const lineBreakG = new RegExp(lineBreak.source, "g")
export function isNewLine(code) {
return code === 10 || code === 13 || code === 0x2028 || code == 0x2029
}
export const nonASCIIwhitespace = /[\u1680\u180e\u2000-\u200a\u202f\u205f\u3000\ufeff]/
export const skipWhiteSpace = /(?:\s|\/\/.*|\/\*[^]*?\*\/)*/g