{Parser} = require 'jison'
The CoffeeScript parser is generated by Jison from this grammar file. Jison is a bottom-up parser generator, similar in style to Bison, implemented in JavaScript. It can recognize LALR(1), LR(0), SLR(1), and LR(1) type grammars. To create the Jison parser, we list the pattern to match on the left-hand side, and the action to take (usually the creation of syntax tree nodes) on the right. As the parser runs, it shifts tokens from our token stream, from left to right, and attempts to match the token sequence against the rules below. When a match can be made, it reduces into the nonterminal (the enclosing name at the top), and we proceed from there.
If you run the cake build:parser
command, Jison constructs a parse table
from our rules and saves it into lib/parser.js
.
The only dependency is on the Jison.Parser.
{Parser} = require 'jison'
Since we’re going to be wrapped in a function by Jison in any case, if our action immediately returns a value, we can optimize by removing the function wrapper and just returning the value directly.
unwrap = /^function\s*\(\)\s*\{\s*return\s*([\s\S]*);\s*\}/
Our handy DSL for Jison grammar generation, thanks to Tim Caswell. For every rule in the grammar, we pass the pattern-defining string, the action to run, and extra options, optionally. If no action is specified, we simply pass the value of the previous nonterminal.
o = (patternString, action, options) ->
patternString = patternString.replace /\s{2,}/g, ' '
patternCount = patternString.split(' ').length
return [patternString, '$$ = $1;', options] unless action
action = if match = unwrap.exec action then match[1] else "(#{action}())"
All runtime functions we need are defined on “yy”
action = action.replace /\bnew /g, '$&yy.'
action = action.replace /\b(?:Block\.wrap|extend)\b/g, 'yy.$&'
Returns a function which adds location data to the first parameter passed in, and returns the parameter. If the parameter is not a node, it will just be passed through unaffected.
addLocationDataFn = (first, last) ->
if not last
"yy.addLocationDataFn(@#{first})"
else
"yy.addLocationDataFn(@#{first}, @#{last})"
action = action.replace /LOC\(([0-9]*)\)/g, addLocationDataFn('$1')
action = action.replace /LOC\(([0-9]*),\s*([0-9]*)\)/g, addLocationDataFn('$1', '$2')
[patternString, "$$ = #{addLocationDataFn(1, patternCount)}(#{action});", options]
In all of the rules that follow, you’ll see the name of the nonterminal as the key to a list of alternative matches. With each match’s action, the dollar-sign variables are provided by Jison as references to the value of their numeric position, so in this rule:
"Expression UNLESS Expression"
$1
would be the value of the first Expression
, $2
would be the token
for the UNLESS
terminal, and $3
would be the value of the second
Expression
.
grammar =
The Root is the top-level node in the syntax tree. Since we parse bottom-up, all parsing must end here.
Root: [
o '', -> new Block
o 'Body'
]
Any list of statements and expressions, separated by line breaks or semicolons.
Body: [
o 'Line', -> Block.wrap [$1]
o 'Body TERMINATOR Line', -> $1.push $3
o 'Body TERMINATOR'
]
Block and statements, which make up a line in a body. YieldReturn is a statement, but not included in Statement because that results in an ambiguous grammar.
Line: [
o 'Expression'
o 'Statement'
o 'YieldReturn'
]
Pure statements which cannot be expressions.
Statement: [
o 'Return'
o 'Comment'
o 'STATEMENT', -> new StatementLiteral $1
o 'Import'
o 'Export'
]
All the different types of expressions in our language. The basic unit of CoffeeScript is the Expression – everything that can be an expression is one. Blocks serve as the building blocks of many other rules, making them somewhat circular.
Expression: [
o 'Value'
o 'Invocation'
o 'Code'
o 'Operation'
o 'Assign'
o 'If'
o 'Try'
o 'While'
o 'For'
o 'Switch'
o 'Class'
o 'Throw'
o 'Yield'
]
Yield: [
o 'YIELD', -> new Op $1, new Value new Literal ''
o 'YIELD Expression', -> new Op $1, $2
o 'YIELD FROM Expression', -> new Op $1.concat($2), $3
]
An indented block of expressions. Note that the Rewriter will convert some postfix forms into blocks for us, by adjusting the token stream.
Block: [
o 'INDENT OUTDENT', -> new Block
o 'INDENT Body OUTDENT', -> $2
]
Identifier: [
o 'IDENTIFIER', -> new IdentifierLiteral $1
]
Property: [
o 'PROPERTY', -> new PropertyName $1
]
Alphanumerics are separated from the other Literal matchers because they can also serve as keys in object literals.
AlphaNumeric: [
o 'NUMBER', -> new NumberLiteral $1
o 'String'
]
String: [
o 'STRING', -> new StringLiteral $1
o 'STRING_START Body STRING_END', -> new StringWithInterpolations $2
]
Regex: [
o 'REGEX', -> new RegexLiteral $1
o 'REGEX_START Invocation REGEX_END', -> new RegexWithInterpolations $2.args
]
All of our immediate values. Generally these can be passed straight through and printed to JavaScript.
Literal: [
o 'AlphaNumeric'
o 'JS', -> new PassthroughLiteral $1
o 'Regex'
o 'UNDEFINED', -> new UndefinedLiteral
o 'NULL', -> new NullLiteral
o 'BOOL', -> new BooleanLiteral $1
o 'INFINITY', -> new InfinityLiteral $1
o 'NAN', -> new NaNLiteral
]
Assignment of a variable, property, or index to a value.
Assign: [
o 'Assignable = Expression', -> new Assign $1, $3
o 'Assignable = TERMINATOR Expression', -> new Assign $1, $4
o 'Assignable = INDENT Expression OUTDENT', -> new Assign $1, $4
]
Assignment when it happens within an object literal. The difference from the ordinary Assign is that these allow numbers and strings as keys.
AssignObj: [
o 'ObjAssignable', -> new Value $1
o 'ObjAssignable : Expression', -> new Assign LOC(1)(new Value $1), $3, 'object',
operatorToken: LOC(2)(new Literal $2)
o 'ObjAssignable :
INDENT Expression OUTDENT', -> new Assign LOC(1)(new Value $1), $4, 'object',
operatorToken: LOC(2)(new Literal $2)
o 'SimpleObjAssignable = Expression', -> new Assign LOC(1)(new Value $1), $3, null,
operatorToken: LOC(2)(new Literal $2)
o 'SimpleObjAssignable =
INDENT Expression OUTDENT', -> new Assign LOC(1)(new Value $1), $4, null,
operatorToken: LOC(2)(new Literal $2)
o 'Comment'
]
SimpleObjAssignable: [
o 'Identifier'
o 'Property'
o 'ThisProperty'
]
ObjAssignable: [
o 'SimpleObjAssignable'
o 'AlphaNumeric'
]
A return statement from a function body.
Return: [
o 'RETURN Expression', -> new Return $2
o 'RETURN', -> new Return
]
YieldReturn: [
o 'YIELD RETURN Expression', -> new YieldReturn $3
o 'YIELD RETURN', -> new YieldReturn
]
A block comment.
Comment: [
o 'HERECOMMENT', -> new Comment $1
]
The Code node is the function literal. It’s defined by an indented block of Block preceded by a function arrow, with an optional parameter list.
Code: [
o 'PARAM_START ParamList PARAM_END FuncGlyph Block', -> new Code $2, $5, $4
o 'FuncGlyph Block', -> new Code [], $2, $1
]
CoffeeScript has two different symbols for functions. ->
is for ordinary
functions, and =>
is for functions bound to the current value of this.
FuncGlyph: [
o '->', -> 'func'
o '=>', -> 'boundfunc'
]
An optional, trailing comma.
OptComma: [
o ''
o ','
]
The list of parameters that a function accepts can be of any length.
ParamList: [
o '', -> []
o 'Param', -> [$1]
o 'ParamList , Param', -> $1.concat $3
o 'ParamList OptComma TERMINATOR Param', -> $1.concat $4
o 'ParamList OptComma INDENT ParamList OptComma OUTDENT', -> $1.concat $4
]
A single parameter in a function definition can be ordinary, or a splat that hoovers up the remaining arguments.
Param: [
o 'ParamVar', -> new Param $1
o 'ParamVar ...', -> new Param $1, null, on
o 'ParamVar = Expression', -> new Param $1, $3
o '...', -> new Expansion
]
Function Parameters
ParamVar: [
o 'Identifier'
o 'ThisProperty'
o 'Array'
o 'Object'
]
A splat that occurs outside of a parameter list.
Splat: [
o 'Expression ...', -> new Splat $1
]
Variables and properties that can be assigned to.
SimpleAssignable: [
o 'Identifier', -> new Value $1
o 'Value Accessor', -> $1.add $2
o 'Invocation Accessor', -> new Value $1, [].concat $2
o 'ThisProperty'
]
Everything that can be assigned to.
Assignable: [
o 'SimpleAssignable'
o 'Array', -> new Value $1
o 'Object', -> new Value $1
]
The types of things that can be treated as values – assigned to, invoked as functions, indexed into, named as a class, etc.
Value: [
o 'Assignable'
o 'Literal', -> new Value $1
o 'Parenthetical', -> new Value $1
o 'Range', -> new Value $1
o 'This'
]
The general group of accessors into an object, by property, by prototype or by array index or slice.
Accessor: [
o '. Property', -> new Access $2
o '?. Property', -> new Access $2, 'soak'
o ':: Property', -> [LOC(1)(new Access new PropertyName('prototype')), LOC(2)(new Access $2)]
o '?:: Property', -> [LOC(1)(new Access new PropertyName('prototype'), 'soak'), LOC(2)(new Access $2)]
o '::', -> new Access new PropertyName 'prototype'
o 'Index'
]
Indexing into an object or array using bracket notation.
Index: [
o 'INDEX_START IndexValue INDEX_END', -> $2
o 'INDEX_SOAK Index', -> extend $2, soak : yes
]
IndexValue: [
o 'Expression', -> new Index $1
o 'Slice', -> new Slice $1
]
In CoffeeScript, an object literal is simply a list of assignments.
Object: [
o '{ AssignList OptComma }', -> new Obj $2, $1.generated
]
Assignment of properties within an object literal can be separated by comma, as in JavaScript, or simply by newline.
AssignList: [
o '', -> []
o 'AssignObj', -> [$1]
o 'AssignList , AssignObj', -> $1.concat $3
o 'AssignList OptComma TERMINATOR AssignObj', -> $1.concat $4
o 'AssignList OptComma INDENT AssignList OptComma OUTDENT', -> $1.concat $4
]
Class definitions have optional bodies of prototype property assignments, and optional references to the superclass.
Class: [
o 'CLASS', -> new Class
o 'CLASS Block', -> new Class null, null, $2
o 'CLASS EXTENDS Expression', -> new Class null, $3
o 'CLASS EXTENDS Expression Block', -> new Class null, $3, $4
o 'CLASS SimpleAssignable', -> new Class $2
o 'CLASS SimpleAssignable Block', -> new Class $2, null, $3
o 'CLASS SimpleAssignable EXTENDS Expression', -> new Class $2, $4
o 'CLASS SimpleAssignable EXTENDS Expression Block', -> new Class $2, $4, $5
]
Import: [
o 'IMPORT String', -> new ImportDeclaration null, $2
o 'IMPORT ImportDefaultSpecifier FROM String', -> new ImportDeclaration new ImportClause($2, null), $4
o 'IMPORT ImportNamespaceSpecifier FROM String', -> new ImportDeclaration new ImportClause(null, $2), $4
o 'IMPORT { } FROM String', -> new ImportDeclaration new ImportClause(null, new ImportSpecifierList []), $5
o 'IMPORT { ImportSpecifierList OptComma } FROM String', -> new ImportDeclaration new ImportClause(null, new ImportSpecifierList $3), $7
o 'IMPORT ImportDefaultSpecifier , ImportNamespaceSpecifier FROM String', -> new ImportDeclaration new ImportClause($2, $4), $6
o 'IMPORT ImportDefaultSpecifier , { ImportSpecifierList OptComma } FROM String', -> new ImportDeclaration new ImportClause($2, new ImportSpecifierList $5), $9
]
ImportSpecifierList: [
o 'ImportSpecifier', -> [$1]
o 'ImportSpecifierList , ImportSpecifier', -> $1.concat $3
o 'ImportSpecifierList OptComma TERMINATOR ImportSpecifier', -> $1.concat $4
o 'INDENT ImportSpecifierList OptComma OUTDENT', -> $2
o 'ImportSpecifierList OptComma INDENT ImportSpecifierList OptComma OUTDENT', -> $1.concat $4
]
ImportSpecifier: [
o 'Identifier', -> new ImportSpecifier $1
o 'Identifier AS Identifier', -> new ImportSpecifier $1, $3
]
ImportDefaultSpecifier: [
o 'Identifier', -> new ImportDefaultSpecifier $1
]
ImportNamespaceSpecifier: [
o 'IMPORT_ALL AS Identifier', -> new ImportNamespaceSpecifier new Literal($1), $3
]
Export: [
o 'EXPORT { }', -> new ExportNamedDeclaration new ExportSpecifierList []
o 'EXPORT { ExportSpecifierList OptComma }', -> new ExportNamedDeclaration new ExportSpecifierList $3
o 'EXPORT Class', -> new ExportNamedDeclaration $2
o 'EXPORT Identifier = Expression', -> new ExportNamedDeclaration new Assign $2, $4, null,
moduleDeclaration: 'export'
o 'EXPORT Identifier = TERMINATOR Expression', -> new ExportNamedDeclaration new Assign $2, $5, null,
moduleDeclaration: 'export'
o 'EXPORT Identifier = INDENT Expression OUTDENT', -> new ExportNamedDeclaration new Assign $2, $5, null,
moduleDeclaration: 'export'
o 'EXPORT DEFAULT Expression', -> new ExportDefaultDeclaration $3
o 'EXPORT EXPORT_ALL FROM String', -> new ExportAllDeclaration new Literal($2), $4
o 'EXPORT { ExportSpecifierList OptComma } FROM String', -> new ExportNamedDeclaration new ExportSpecifierList($3), $7
]
ExportSpecifierList: [
o 'ExportSpecifier', -> [$1]
o 'ExportSpecifierList , ExportSpecifier', -> $1.concat $3
o 'ExportSpecifierList OptComma TERMINATOR ExportSpecifier', -> $1.concat $4
o 'INDENT ExportSpecifierList OptComma OUTDENT', -> $2
o 'ExportSpecifierList OptComma INDENT ExportSpecifierList OptComma OUTDENT', -> $1.concat $4
]
ExportSpecifier: [
o 'Identifier', -> new ExportSpecifier $1
o 'Identifier AS Identifier', -> new ExportSpecifier $1, $3
o 'Identifier AS DEFAULT', -> new ExportSpecifier $1, new Literal $3
]
Ordinary function invocation, or a chained series of calls.
Invocation: [
o 'Value OptFuncExist Arguments', -> new Call $1, $3, $2
o 'Invocation OptFuncExist Arguments', -> new Call $1, $3, $2
o 'Super'
]
Super: [
o 'SUPER', -> new SuperCall
o 'SUPER Arguments', -> new SuperCall $2
]
An optional existence check on a function.
OptFuncExist: [
o '', -> no
o 'FUNC_EXIST', -> yes
]
The list of arguments to a function call.
Arguments: [
o 'CALL_START CALL_END', -> []
o 'CALL_START ArgList OptComma CALL_END', -> $2
]
A reference to the this current object.
This: [
o 'THIS', -> new Value new ThisLiteral
o '@', -> new Value new ThisLiteral
]
A reference to a property on this.
ThisProperty: [
o '@ Property', -> new Value LOC(1)(new ThisLiteral), [LOC(2)(new Access($2))], 'this'
]
The array literal.
Array: [
o '[ ]', -> new Arr []
o '[ ArgList OptComma ]', -> new Arr $2
]
Inclusive and exclusive range dots.
RangeDots: [
o '..', -> 'inclusive'
o '...', -> 'exclusive'
]
The CoffeeScript range literal.
Range: [
o '[ Expression RangeDots Expression ]', -> new Range $2, $4, $3
]
Array slice literals.
Slice: [
o 'Expression RangeDots Expression', -> new Range $1, $3, $2
o 'Expression RangeDots', -> new Range $1, null, $2
o 'RangeDots Expression', -> new Range null, $2, $1
o 'RangeDots', -> new Range null, null, $1
]
The ArgList is both the list of objects passed into a function call, as well as the contents of an array literal (i.e. comma-separated expressions). Newlines work as well.
ArgList: [
o 'Arg', -> [$1]
o 'ArgList , Arg', -> $1.concat $3
o 'ArgList OptComma TERMINATOR Arg', -> $1.concat $4
o 'INDENT ArgList OptComma OUTDENT', -> $2
o 'ArgList OptComma INDENT ArgList OptComma OUTDENT', -> $1.concat $4
]
Valid arguments are Blocks or Splats.
Arg: [
o 'Expression'
o 'Splat'
o '...', -> new Expansion
]
Just simple, comma-separated, required arguments (no fancy syntax). We need this to be separate from the ArgList for use in Switch blocks, where having the newlines wouldn’t make sense.
SimpleArgs: [
o 'Expression'
o 'SimpleArgs , Expression', -> [].concat $1, $3
]
The variants of try/catch/finally exception handling blocks.
Try: [
o 'TRY Block', -> new Try $2
o 'TRY Block Catch', -> new Try $2, $3[0], $3[1]
o 'TRY Block FINALLY Block', -> new Try $2, null, null, $4
o 'TRY Block Catch FINALLY Block', -> new Try $2, $3[0], $3[1], $5
]
A catch clause names its error and runs a block of code.
Catch: [
o 'CATCH Identifier Block', -> [$2, $3]
o 'CATCH Object Block', -> [LOC(2)(new Value($2)), $3]
o 'CATCH Block', -> [null, $2]
]
Throw an exception object.
Throw: [
o 'THROW Expression', -> new Throw $2
]
Parenthetical expressions. Note that the Parenthetical is a Value, not an Expression, so if you need to use an expression in a place where only values are accepted, wrapping it in parentheses will always do the trick.
Parenthetical: [
o '( Body )', -> new Parens $2
o '( INDENT Body OUTDENT )', -> new Parens $3
]
The condition portion of a while loop.
WhileSource: [
o 'WHILE Expression', -> new While $2
o 'WHILE Expression WHEN Expression', -> new While $2, guard: $4
o 'UNTIL Expression', -> new While $2, invert: true
o 'UNTIL Expression WHEN Expression', -> new While $2, invert: true, guard: $4
]
The while loop can either be normal, with a block of expressions to execute, or postfix, with a single expression. There is no do..while.
While: [
o 'WhileSource Block', -> $1.addBody $2
o 'Statement WhileSource', -> $2.addBody LOC(1) Block.wrap([$1])
o 'Expression WhileSource', -> $2.addBody LOC(1) Block.wrap([$1])
o 'Loop', -> $1
]
Loop: [
o 'LOOP Block', -> new While(LOC(1) new BooleanLiteral 'true').addBody $2
o 'LOOP Expression', -> new While(LOC(1) new BooleanLiteral 'true').addBody LOC(2) Block.wrap [$2]
]
Array, object, and range comprehensions, at the most generic level. Comprehensions can either be normal, with a block of expressions to execute, or postfix, with a single expression.
For: [
o 'Statement ForBody', -> new For $1, $2
o 'Expression ForBody', -> new For $1, $2
o 'ForBody Block', -> new For $2, $1
]
ForBody: [
o 'FOR Range', -> source: (LOC(2) new Value($2))
o 'FOR Range BY Expression', -> source: (LOC(2) new Value($2)), step: $4
o 'ForStart ForSource', -> $2.own = $1.own; $2.name = $1[0]; $2.index = $1[1]; $2
]
ForStart: [
o 'FOR ForVariables', -> $2
o 'FOR OWN ForVariables', -> $3.own = yes; $3
]
An array of all accepted values for a variable inside the loop. This enables support for pattern matching.
ForValue: [
o 'Identifier'
o 'ThisProperty'
o 'Array', -> new Value $1
o 'Object', -> new Value $1
]
An array or range comprehension has variables for the current element and (optional) reference to the current index. Or, key, value, in the case of object comprehensions.
ForVariables: [
o 'ForValue', -> [$1]
o 'ForValue , ForValue', -> [$1, $3]
]
The source of a comprehension is an array or object with an optional guard clause. If it’s an array comprehension, you can also choose to step through in fixed-size increments.
ForSource: [
o 'FORIN Expression', -> source: $2
o 'FOROF Expression', -> source: $2, object: yes
o 'FORIN Expression WHEN Expression', -> source: $2, guard: $4
o 'FOROF Expression WHEN Expression', -> source: $2, guard: $4, object: yes
o 'FORIN Expression BY Expression', -> source: $2, step: $4
o 'FORIN Expression WHEN Expression BY Expression', -> source: $2, guard: $4, step: $6
o 'FORIN Expression BY Expression WHEN Expression', -> source: $2, step: $4, guard: $6
]
Switch: [
o 'SWITCH Expression INDENT Whens OUTDENT', -> new Switch $2, $4
o 'SWITCH Expression INDENT Whens ELSE Block OUTDENT', -> new Switch $2, $4, $6
o 'SWITCH INDENT Whens OUTDENT', -> new Switch null, $3
o 'SWITCH INDENT Whens ELSE Block OUTDENT', -> new Switch null, $3, $5
]
Whens: [
o 'When'
o 'Whens When', -> $1.concat $2
]
An individual When clause, with action.
When: [
o 'LEADING_WHEN SimpleArgs Block', -> [[$2, $3]]
o 'LEADING_WHEN SimpleArgs Block TERMINATOR', -> [[$2, $3]]
]
The most basic form of if is a condition and an action. The following if-related rules are broken up along these lines in order to avoid ambiguity.
IfBlock: [
o 'IF Expression Block', -> new If $2, $3, type: $1
o 'IfBlock ELSE IF Expression Block', -> $1.addElse LOC(3,5) new If $4, $5, type: $3
]
The full complement of if expressions, including postfix one-liner if and unless.
If: [
o 'IfBlock'
o 'IfBlock ELSE Block', -> $1.addElse $3
o 'Statement POST_IF Expression', -> new If $3, LOC(1)(Block.wrap [$1]), type: $2, statement: true
o 'Expression POST_IF Expression', -> new If $3, LOC(1)(Block.wrap [$1]), type: $2, statement: true
]
Arithmetic and logical operators, working on one or more operands. Here they are grouped by order of precedence. The actual precedence rules are defined at the bottom of the page. It would be shorter if we could combine most of these rules into a single generic Operand OpSymbol Operand -type rule, but in order to make the precedence binding possible, separate rules are necessary.
Operation: [
o 'UNARY Expression', -> new Op $1 , $2
o 'UNARY_MATH Expression', -> new Op $1 , $2
o '- Expression', (-> new Op '-', $2), prec: 'UNARY_MATH'
o '+ Expression', (-> new Op '+', $2), prec: 'UNARY_MATH'
o '-- SimpleAssignable', -> new Op '--', $2
o '++ SimpleAssignable', -> new Op '++', $2
o 'SimpleAssignable --', -> new Op '--', $1, null, true
o 'SimpleAssignable ++', -> new Op '++', $1, null, true
o 'Expression ?', -> new Existence $1
o 'Expression + Expression', -> new Op '+' , $1, $3
o 'Expression - Expression', -> new Op '-' , $1, $3
o 'Expression MATH Expression', -> new Op $2, $1, $3
o 'Expression ** Expression', -> new Op $2, $1, $3
o 'Expression SHIFT Expression', -> new Op $2, $1, $3
o 'Expression COMPARE Expression', -> new Op $2, $1, $3
o 'Expression LOGIC Expression', -> new Op $2, $1, $3
o 'Expression RELATION Expression', ->
if $2.charAt(0) is '!'
new Op($2[1..], $1, $3).invert()
else
new Op $2, $1, $3
o 'SimpleAssignable COMPOUND_ASSIGN
Expression', -> new Assign $1, $3, $2
o 'SimpleAssignable COMPOUND_ASSIGN
INDENT Expression OUTDENT', -> new Assign $1, $4, $2
o 'SimpleAssignable COMPOUND_ASSIGN TERMINATOR
Expression', -> new Assign $1, $4, $2
o 'SimpleAssignable EXTENDS Expression', -> new Extends $1, $3
]
Operators at the top of this list have higher precedence than the ones lower
down. Following these rules is what makes 2 + 3 * 4
parse as:
2 + (3 * 4)
And not:
(2 + 3) * 4
operators = [
['left', '.', '?.', '::', '?::']
['left', 'CALL_START', 'CALL_END']
['nonassoc', '++', '--']
['left', '?']
['right', 'UNARY']
['right', '**']
['right', 'UNARY_MATH']
['left', 'MATH']
['left', '+', '-']
['left', 'SHIFT']
['left', 'RELATION']
['left', 'COMPARE']
['left', 'LOGIC']
['nonassoc', 'INDENT', 'OUTDENT']
['right', 'YIELD']
['right', '=', ':', 'COMPOUND_ASSIGN', 'RETURN', 'THROW', 'EXTENDS']
['right', 'FORIN', 'FOROF', 'BY', 'WHEN']
['right', 'IF', 'ELSE', 'FOR', 'WHILE', 'UNTIL', 'LOOP', 'SUPER', 'CLASS', 'IMPORT', 'EXPORT']
['left', 'POST_IF']
]
Finally, now that we have our grammar and our operators, we can create our Jison.Parser. We do this by processing all of our rules, recording all terminals (every symbol which does not appear as the name of a rule above) as “tokens”.
tokens = []
for name, alternatives of grammar
grammar[name] = for alt in alternatives
for token in alt[0].split ' '
tokens.push token unless grammar[token]
alt[1] = "return #{alt[1]}" if name is 'Root'
alt
Initialize the Parser with our list of terminal tokens, our grammar rules, and the name of the root. Reverse the operators because Jison orders precedence from low to high, and we have it high to low (as in Yacc).
exports.parser = new Parser
tokens : tokens.join ' '
bnf : grammar
operators : operators.reverse()
startSymbol : 'Root'