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PEG.js
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======
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PEG.js is a simple parser generator for JavaScript that produces fast parsers
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with excellent error reporting. You can use it to process complex data or
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computer languages and build transformers, interpreters, compilers and other
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tools easily.
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Features
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--------
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* Simple and expressive grammar syntax
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* Integrates both lexical and syntactical analysis
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* Parsers have excellent error reporting out of the box
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* Based on [parsing expression
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grammar](http://en.wikipedia.org/wiki/Parsing_expression_grammar) formalism
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— more powerful than traditional LL(*k*) and LR(*k*) parsers
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* Usable [from your browser](http://pegjs.org/online), from the command line,
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or via JavaScript API
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Getting Started
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---------------
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[Online version](http://pegjs.org/online) is the easiest way to generate a
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parser. Just enter your grammar, try parsing few inputs, and download generated
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parser code.
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Installation
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------------
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### Node.js
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To use the `pegjs` command, install PEG.js globally:
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$ npm install -g pegjs
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To use the JavaScript API, install PEG.js locally:
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$ npm install pegjs
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If you need both the `pegjs` command and the JavaScript API, install PEG.js both
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ways.
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### Browser
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[Download](http://pegjs.org/#download) the PEG.js library (regular or minified
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version) or install it using Bower:
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$ bower install pegjs
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Generating a Parser
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-------------------
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PEG.js generates parser from a grammar that describes expected input and can
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specify what the parser returns (using semantic actions on matched parts of the
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input). Generated parser itself is a JavaScript object with a simple API.
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### Command Line
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To generate a parser from your grammar, use the `pegjs` command:
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$ pegjs arithmetics.pegjs
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This writes parser source code into a file with the same name as the grammar
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file but with “.js” extension. You can also specify the output file explicitly:
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$ pegjs arithmetics.pegjs arithmetics-parser.js
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If you omit both input and output file, standard input and output are used.
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By default, the parser object is assigned to `module.exports`, which makes the
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output a Node.js module. You can assign it to another variable by passing a
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variable name using the `-e`/`--export-var` option. This may be helpful if you
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want to use the parser in browser environment.
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You can tweak the generated parser with several options:
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* `--cache` — makes the parser cache results, avoiding exponential parsing
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time in pathological cases but making the parser slower
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* `--allowed-start-rules` — comma-separated list of rules the parser will be
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allowed to start parsing from (default: the first rule in the grammar)
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* `--plugin` — makes PEG.js use a specified plugin (can be specified multiple
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times)
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* `--extra-options` — additional options (in JSON format) to pass to
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`PEG.buildParser`
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* `--extra-options-file` — file with additional options (in JSON format) to
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pass to `PEG.buildParser`
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* `--trace` — makes the parser trace its progress
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### JavaScript API
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In Node.js, require the PEG.js parser generator module:
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var PEG = require("pegjs");
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In browser, include the PEG.js library in your web page or application using the
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`<script>` tag. The API will be available in the `PEG` global object.
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To generate a parser, call the `PEG.buildParser` method and pass your grammar as
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a parameter:
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var parser = PEG.buildParser("start = ('a' / 'b')+");
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The method will return generated parser object or its source code as a string
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(depending on the value of the `output` option — see below). It will throw an
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exception if the grammar is invalid. The exception will contain `message`
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property with more details about the error.
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You can tweak the generated parser by passing a second parameter with an options
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object to `PEG.buildParser`. The following options are supported:
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* `cache` — if `true`, makes the parser cache results, avoiding exponential
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parsing time in pathological cases but making the parser slower (default:
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`false`)
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* `allowedStartRules` — rules the parser will be allowed to start parsing from
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(default: the first rule in the grammar)
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* `output` — if set to `"parser"`, the method will return generated parser
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object; if set to `"source"`, it will return parser source code as a string
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(default: `"parser"`)
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Code generator rewrite
This is a complete rewrite of the PEG.js code generator. Its goals are:
1. Allow optimizing the generated parser code for code size as well as
for parsing speed.
2. Prepare ground for future optimizations and big features (like
incremental parsing).
2. Replace the old template-based code-generation system with
something more lightweight and flexible.
4. General code cleanup (structure, style, variable names, ...).
New Architecture
----------------
The new code generator consists of two steps:
* Bytecode generator -- produces bytecode for an abstract virtual
machine
* JavaScript generator -- produces JavaScript code based on the
bytecode
The abstract virtual machine is stack-based. Originally I wanted to make
it register-based, but it turned out that all the code related to it
would be more complex and the bytecode itself would be longer (because
of explicit register specifications in instructions). The only downsides
of the stack-based approach seem to be few small inefficiencies (see
e.g. the |NIP| instruction), which seem to be insignificant.
The new generator allows optimizing for parsing speed or code size (you
can choose using the |optimize| option of the |PEG.buildParser| method
or the --optimize/-o option on the command-line).
When optimizing for size, the JavaScript generator emits the bytecode
together with its constant table and a generic bytecode interpreter.
Because the interpreter is small and the bytecode and constant table
grow only slowly with size of the grammar, the resulting parser is also
small.
When optimizing for speed, the JavaScript generator just compiles the
bytecode into JavaScript. The generated code is relatively efficient, so
the resulting parser is fast.
Internal Identifiers
--------------------
As a small bonus, all internal identifiers visible to user code in the
initializer, actions and predicates are prefixed by |peg$|. This lowers
the chance that identifiers in user code will conflict with the ones
from PEG.js. It also makes using any internals in user code ugly, which
is a good thing. This solves GH-92.
Performance
-----------
The new code generator improved parsing speed and parser code size
significantly. The generated parsers are now:
* 39% faster when optimizing for speed
* 69% smaller when optimizing for size (without minification)
* 31% smaller when optimizing for size (with minification)
(Parsing speed was measured using the |benchmark/run| script. Code size
was measured by generating parsers for examples in the |examples|
directory and adding up the file sizes. Minification was done by |uglify
--ascii| in version 1.3.4.)
Final Note
----------
This is just a beginning! The new code generator lays a foundation upon
which many optimizations and improvements can (and will) be made.
Stay tuned :-)
12 years ago
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* `optimize`— selects between optimizing the generated parser for parsing
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speed (`"speed"`) or code size (`"size"`) (default: `"speed"`)
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* `plugins` — plugins to use
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Using the Parser
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----------------
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Using the generated parser is simple — just call its `parse` method and pass an
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input string as a parameter. The method will return a parse result (the exact
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value depends on the grammar used to build the parser) or throw an exception if
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the input is invalid. The exception will contain `offset`, `line`, `column`,
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`expected`, `found` and `message` properties with more details about the error.
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parser.parse("abba"); // returns ["a", "b", "b", "a"]
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parser.parse("abcd"); // throws an exception
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You can tweak parser behavior by passing a second parameter with an options
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object to the `parse` method. The following options are supported:
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* `startRule` — name of the rule to start parsing from
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* `tracer` — tracer to use
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Parsers can also support their own custom options.
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Grammar Syntax and Semantics
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----------------------------
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The grammar syntax is similar to JavaScript in that it is not line-oriented and
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ignores whitespace between tokens. You can also use JavaScript-style comments
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(`// ...` and `/* ... */`).
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Let's look at example grammar that recognizes simple arithmetic expressions like
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`2*(3+4)`. A parser generated from this grammar computes their values.
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start
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= additive
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additive
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= left:multiplicative "+" right:additive { return left + right; }
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/ multiplicative
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multiplicative
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= left:primary "*" right:multiplicative { return left * right; }
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/ primary
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primary
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= integer
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/ "(" additive:additive ")" { return additive; }
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integer "integer"
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= digits:[0-9]+ { return parseInt(digits.join(""), 10); }
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On the top level, the grammar consists of *rules* (in our example, there are
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five of them). Each rule has a *name* (e.g. `integer`) that identifies the rule,
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and a *parsing expression* (e.g. `digits:[0-9]+ { return
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parseInt(digits.join(""), 10); }`) that defines a pattern to match against the
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input text and possibly contains some JavaScript code that determines what
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happens when the pattern matches successfully. A rule can also contain
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*human-readable name* that is used in error messages (in our example, only the
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`integer` rule has a human-readable name). The parsing starts at the first rule,
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which is also called the *start rule*.
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A rule name must be a JavaScript identifier. It is followed by an equality sign
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(“=”) and a parsing expression. If the rule has a human-readable name, it is
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written as a JavaScript string between the name and separating equality sign.
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Rules need to be separated only by whitespace (their beginning is easily
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recognizable), but a semicolon (“;”) after the parsing expression is allowed.
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The first rule can be preceded by an *initializer* — a piece of JavaScript code
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in curly braces (“{” and “}”). This code is executed before the generated parser
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starts parsing. All variables and functions defined in the initializer are
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accessible in rule actions and semantic predicates. The code inside the
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initializer can access the parser object using the `parser` variable and options
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passed to the parser using the `options` variable. Curly braces in the
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initializer code must be balanced. Let's look at the example grammar from above
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using a simple initializer.
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{
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function makeInteger(o) {
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return parseInt(o.join(""), 10);
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}
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}
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start
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= additive
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additive
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= left:multiplicative "+" right:additive { return left + right; }
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/ multiplicative
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multiplicative
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= left:primary "*" right:multiplicative { return left * right; }
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/ primary
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primary
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= integer
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/ "(" additive:additive ")" { return additive; }
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integer "integer"
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= digits:[0-9]+ { return makeInteger(digits); }
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The parsing expressions of the rules are used to match the input text to the
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grammar. There are various types of expressions — matching characters or
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character classes, indicating optional parts and repetition, etc. Expressions
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can also contain references to other rules. See detailed description below.
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If an expression successfully matches a part of the text when running the
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generated parser, it produces a *match result*, which is a JavaScript value. For
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example:
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* An expression matching a literal string produces a JavaScript string
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containing matched part of the input.
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* An expression matching repeated occurrence of some subexpression produces a
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JavaScript array with all the matches.
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The match results propagate through the rules when the rule names are used in
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expressions, up to the start rule. The generated parser returns start rule's
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match result when parsing is successful.
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One special case of parser expression is a *parser action* — a piece of
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JavaScript code inside curly braces (“{” and “}”) that takes match results of
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some of the the preceding expressions and returns a JavaScript value. This value
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is considered match result of the preceding expression (in other words, the
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parser action is a match result transformer).
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In our arithmetics example, there are many parser actions. Consider the action
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in expression `digits:[0-9]+ { return parseInt(digits.join(""), 10); }`. It
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takes the match result of the expression [0-9]+, which is an array of strings
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containing digits, as its parameter. It joins the digits together to form a
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number and converts it to a JavaScript `number` object.
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### Parsing Expression Types
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There are several types of parsing expressions, some of them containing
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subexpressions and thus forming a recursive structure:
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#### "*literal*"<br>'*literal*'
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Match exact literal string and return it. The string syntax is the same as in
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JavaScript. Appending `i` right after the literal makes the match
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case-insensitive.
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#### .
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Match exactly one character and return it as a string.
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#### [*characters*]
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Match one character from a set and return it as a string. The characters in the
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list can be escaped in exactly the same way as in JavaScript string. The list of
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characters can also contain ranges (e.g. `[a-z]` means “all lowercase letters”).
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Preceding the characters with `^` inverts the matched set (e.g. `[^a-z]` means
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“all character but lowercase letters”). Appending `i` right after the right
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bracket makes the match case-insensitive.
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#### *rule*
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Match a parsing expression of a rule recursively and return its match result.
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#### ( *expression* )
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Match a subexpression and return its match result.
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#### *expression* \*
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Match zero or more repetitions of the expression and return their match results
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in an array. The matching is greedy, i.e. the parser tries to match the
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expression as many times as possible.
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#### *expression* +
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Match one or more repetitions of the expression and return their match results
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in an array. The matching is greedy, i.e. the parser tries to match the
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expression as many times as possible.
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#### *expression* ?
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Try to match the expression. If the match succeeds, return its match result,
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otherwise return `null`.
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#### & *expression*
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Try to match the expression. If the match succeeds, just return `undefined` and
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do not advance the parser position, otherwise consider the match failed.
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#### ! *expression*
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Try to match the expression. If the match does not succeed, just return
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`undefined` and do not advance the parser position, otherwise consider the match
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failed.
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#### & { *predicate* }
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The predicate is a piece of JavaScript code that is executed as if it was inside
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a function. It gets the match results of labeled expressions in preceding
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expression as its arguments. It should return some JavaScript value using the
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`return` statement. If the returned value evaluates to `true` in boolean
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context, just return `undefined` and do not advance the parser position;
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otherwise consider the match failed.
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The code inside the predicate can access all variables and functions defined in
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the initializer at the beginning of the grammar.
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The code inside the predicate can also access location information using the
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`location` function. It returns an object like this:
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{
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start: { offset: 23, line: 5, column: 6 },
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end: { offset: 23, line: 5, column: 6 }
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}
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The `start` and `end` properties both refer to the current parse position. The
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`offset` property contains an offset as a zero-based index and `line` and
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`column` properties contain a line and a column as one-based indices.
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The code inside the predicate can also access the parser object using the
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`parser` variable and options passed to the parser using the `options` variable.
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Note that curly braces in the predicate code must be balanced.
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#### ! { *predicate* }
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The predicate is a piece of JavaScript code that is executed as if it was inside
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a function. It gets the match results of labeled expressions in preceding
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expression as its arguments. It should return some JavaScript value using the
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`return` statement. If the returned value evaluates to `false` in boolean
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context, just return `undefined` and do not advance the parser position;
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otherwise consider the match failed.
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The code inside the predicate can access all variables and functions defined in
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the initializer at the beginning of the grammar.
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The code inside the predicate can also access location information using the
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`location` function. It returns an object like this:
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{
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start: { offset: 23, line: 5, column: 6 },
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end: { offset: 23, line: 5, column: 6 }
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}
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The `start` and `end` properties both refer to the current parse position. The
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`offset` property contains an offset as a zero-based index and `line` and
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`column` properties contain a line and a column as one-based indices.
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The code inside the predicate can also access the parser object using the
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`parser` variable and options passed to the parser using the `options` variable.
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Note that curly braces in the predicate code must be balanced.
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#### $ *expression*
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Try to match the expression. If the match succeeds, return the matched string
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instead of the match result.
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#### *label* : *expression*
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Match the expression and remember its match result under given label. The label
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must be a JavaScript identifier.
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Labeled expressions are useful together with actions, where saved match results
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can be accessed by action's JavaScript code.
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#### *expression<sub>1</sub>* *expression<sub>2</sub>* ... *expression<sub>n</sub>*
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Match a sequence of expressions and return their match results in an array.
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#### *expression* { *action* }
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Match the expression. If the match is successful, run the action, otherwise
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consider the match failed.
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The action is a piece of JavaScript code that is executed as if it was inside a
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function. It gets the match results of labeled expressions in preceding
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expression as its arguments. The action should return some JavaScript value
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using the `return` statement. This value is considered match result of the
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preceding expression.
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Refine error handling further
Before this commit, the |expected| and |error| functions didn't halt the
parsing immediately, but triggered a regular match failure. After they
were called, the parser could backtrack, try another branches, and only
if no other branch succeeded, it triggered an exception with information
possibly based on parameters passed to the |expected| or |error|
function (this depended on positions where failures in other branches
have occurred).
While nice in theory, this solution didn't work well in practice. There
were at least two problems:
1. Action expression could have easily triggered a match failure later
in the input than the action itself. This resulted in the
action-triggered failure to be shadowed by the expression-triggered
one.
Consider the following example:
integer = digits:[0-9]+ {
var result = parseInt(digits.join(""), 10);
if (result % 2 === 0) {
error("The number must be an odd integer.");
return;
}
return result;
}
Given input "2", the |[0-9]+| expression would record a match
failure at position 1 (an unsuccessful attempt to parse yet another
digit after "2"). However, a failure triggered by the |error| call
would occur at position 0.
This problem could have been solved by silencing match failures in
action expressions, but that would lead to severe performance
problems (yes, I tried and measured). Other possible solutions are
hacks which I didn't want to introduce into PEG.js.
2. Triggering a match failure in action code could have lead to
unexpected backtracking.
Consider the following example:
class = "[" (charRange / char)* "]"
charRange = begin:char "-" end:char {
if (begin.data.charCodeAt(0) > end.data.charCodeAt(0)) {
error("Invalid character range: " + begin + "-" + end + ".");
}
// ...
}
char = [a-zA-Z0-9_\-]
Given input "[b-a]", the |charRange| rule would fail, but the
parser would try the |char| rule and succeed repeatedly, resulting
in "b-a" being parsed as a sequence of three |char|'s, which it is
not.
This problem could have been solved by using negative predicates,
but that would complicate the grammar and still wouldn't get rid of
unintuitive behavior.
Given these problems I decided to change the semantics of the |expected|
and |error| functions. They don't interact with regular match failure
mechanism anymore, but they cause and immediate parse failure by
throwing an exception. I think this is more intuitive behavior with less
harmful side effects.
The disadvantage of the new approach is that one can't backtrack from an
action-triggered error. I don't see this as a big deal as I think this
will be rarely needed and one can always use a semantic predicate as a
workaround.
Speed impact
------------
Before: 993.84 kB/s
After: 998.05 kB/s
Difference: 0.42%
Size impact
-----------
Before: 1019968 b
After: 975434 b
Difference: -4.37%
(Measured by /tools/impact with Node.js v0.6.18 on x86_64 GNU/Linux.)
11 years ago
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To indicate an error, the code inside the action can invoke the `expected`
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|
function, which makes the parser throw an exception. The function takes one
|
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|
parameter — a description of what was expected at the current position. This
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|
description will be used as part of a message of the thrown exception.
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The code inside an action can also invoke the `error` function, which also makes
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|
the parser throw an exception. The function takes one parameter — an error
|
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|
|
message. This message will be used by the thrown exception.
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|
The code inside the action can access all variables and functions defined in the
|
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|
|
initializer at the beginning of the grammar. Curly braces in the action code
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|
must be balanced.
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The code inside the action can also access the string matched by the expression
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|
using the `text` function.
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|
The code inside the action can also access location information using the
|
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|
|
`location` function. It returns an object like this:
|
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|
|
{
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|
start: { offset: 23, line: 5, column: 6 },
|
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|
end: { offset: 25, line: 5, column: 8 }
|
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|
}
|
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|
The `start` property refers to the position at the beginning of the expression,
|
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|
the `end` property refers to position after the end of the expression. The
|
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|
|
`offset` property contains an offset as a zero-based index and `line` and
|
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|
|
`column` properties contain a line and a column as one-based indices.
|
|
|
|
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|
|
|
The code inside the action can also access the parser object using the `parser`
|
|
|
|
variable and options passed to the parser using the `options` variable.
|
|
|
|
|
|
|
|
Note that curly braces in the action code must be balanced.
|
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|
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|
#### *expression<sub>1</sub>* / *expression<sub>2</sub>* / ... / *expression<sub>n</sub>*
|
|
|
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|
Try to match the first expression, if it does not succeed, try the second one,
|
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|
|
etc. Return the match result of the first successfully matched expression. If no
|
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|
|
expression matches, consider the match failed.
|
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|
Compatibility
|
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|
|
-------------
|
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|
Both the parser generator and generated parsers should run well in the following
|
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|
environments:
|
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|
|
* Node.js 0.10.0+
|
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|
* IE 8+
|
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* Firefox
|
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* Chrome
|
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* Safari
|
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* Opera
|
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|
Development
|
|
|
|
-----------
|
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|
|
|
|
|
|
* [Project website](http://pegjs.org/)
|
|
|
|
* [Wiki](https://github.com/pegjs/pegjs/wiki)
|
|
|
|
* [Source code](https://github.com/pegjs/pegjs)
|
|
|
|
* [Trello board](https://trello.com/board/peg-js/50a8eba48cf95d4957006b01)
|
|
|
|
* [Issue tracker](https://github.com/pegjs/pegjs/issues)
|
|
|
|
* [Google Group](http://groups.google.com/group/pegjs)
|
|
|
|
* [Twitter](http://twitter.com/peg_js)
|
|
|
|
|
|
|
|
PEG.js is developed by [David Majda](http://majda.cz/)
|
|
|
|
([@dmajda](http://twitter.com/dmajda)). The [Bower
|
|
|
|
package](https://github.com/pegjs/bower) is maintained by [Michel
|
|
|
|
Krämer](http://www.michel-kraemer.com/)
|
|
|
|
([@michelkraemer](https://twitter.com/michelkraemer)).
|
|
|
|
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|
|
You are welcome to contribute code. Unless your contribution is really trivial
|
|
|
|
you should get in touch with me first — this can prevent wasted effort on both
|
|
|
|
sides. You can send code both as a patch or a GitHub pull request.
|
|
|
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|
|
|
Note that PEG.js is still very much work in progress. There are no compatibility
|
|
|
|
guarantees until version 1.0.
|