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1108 lines
37 KiB
Plaintext
1108 lines
37 KiB
Plaintext
9 years ago
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#lang scribble/manual
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@(require scribble/eval
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racket/date
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file/md5
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(for-label racket
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br/ragg/support
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br/ragg/examples/nested-word-list
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(only-in parser-tools/lex lexer-src-pos)
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(only-in syntax/parse syntax-parse ~literal)))
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@(define (lookup-date filename [default ""])
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(cond
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[(file-exists? filename)
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(define modify-seconds (file-or-directory-modify-seconds filename))
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(define a-date (seconds->date modify-seconds))
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(date->string a-date)]
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[else
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default]))
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@(define (compute-md5sum filename [default ""])
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(cond [(file-exists? filename)
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(bytes->string/utf-8 (call-with-input-file filename md5 #:mode 'binary))]
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[else
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default]))
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@title{ragg: a Racket AST Generator Generator}
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@author+email["Danny Yoo" "dyoo@hashcollision.org"]
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@section{Informal quickstart}
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@(define my-eval (make-base-eval))
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@(my-eval '(require br/ragg/examples/nested-word-list
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racket/list
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racket/match))
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Salutations! Let's consider the following scenario: say that we're given the
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following string:
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@racketblock["(radiant (humble))"]
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@margin-note{(... and pretend that we don't already know about the built-in
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@racket[read] function.)} How do we go about turning this kind of string into a
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structured value? That is, how would we @emph{parse} it?
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We need to first consider the shape of the things we'd like to parse. The
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string above looks like a deeply nested list of words. How might we describe
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this formally? A convenient notation to describe the shape of these things is
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@link["http://en.wikipedia.org/wiki/Backus%E2%80%93Naur_Form"]{Backus-Naur
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Form} (BNF). So let's try to notate the structure of nested word lists in BNF.
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@nested[#:style 'code-inset]{
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@verbatim{
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nested-word-list: WORD
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| LEFT-PAREN nested-word-list* RIGHT-PAREN
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}}
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What we intend by this notation is this: @racket[nested-word-list] is either an
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atomic @racket[WORD], or a parenthesized list of any number of
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@racket[nested-word-list]s. We use the character @litchar{*} to represent zero
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or more repetitions of the previous thing, and we treat the uppercased
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@racket[LEFT-PAREN], @racket[RIGHT-PAREN], and @racket[WORD] as placeholders
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for atomic @emph{tokens}.
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@margin-note{See @secref{install-ragg} for instructions on installing
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@tt{ragg.}}
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Here are a few examples of tokens:
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@interaction[#:eval my-eval
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(require br/ragg/support)
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(token 'LEFT-PAREN)
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(token 'WORD "crunchy" #:span 7)
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(token 'RIGHT-PAREN)]
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Have we made progress? At this point, we only have a BNF description in hand,
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but we're still missing a @emph{parser}, something to take that description and
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use it to make structures out of a sequence of tokens.
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It's clear that we don't yet have a program because there's no @litchar{#lang}
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line. We should add one. Put @litchar{#lang br/ragg} at the top of the BNF
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description, and save it as a file called @filepath{nested-word-list.rkt}.
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@filebox["nested-word-list.rkt"]{
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@verbatim{
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#lang br/ragg
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nested-word-list: WORD
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| LEFT-PAREN nested-word-list* RIGHT-PAREN
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}}
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Now it is a proper program. But what does it do?
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@interaction[#:eval my-eval
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@eval:alts[(require "nested-word-list.rkt") (void)]
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parse
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]
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It gives us a @racket[parse] function. Let's investigate what @racket[parse]
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does for us. What happens if we pass it a sequence of tokens?
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@interaction[#:eval my-eval
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(define a-parsed-value
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(parse (list (token 'LEFT-PAREN "(")
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(token 'WORD "some")
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(token 'LEFT-PAREN "[")
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(token 'WORD "pig")
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(token 'RIGHT-PAREN "]")
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(token 'RIGHT-PAREN ")"))))
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a-parsed-value]
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Wait... that looks suspiciously like a syntax object!
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@interaction[#:eval my-eval
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(syntax->datum a-parsed-value)
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]
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That's @racket[(some [pig])], essentially.
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What happens if we pass it a more substantial source of tokens?
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@interaction[#:eval my-eval
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@code:comment{tokenize: string -> (sequenceof token-struct?)}
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@code:comment{Generate tokens from a string:}
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(define (tokenize s)
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(for/list ([str (regexp-match* #px"\\(|\\)|\\w+" s)])
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(match str
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["("
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(token 'LEFT-PAREN str)]
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[")"
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(token 'RIGHT-PAREN str)]
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[else
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(token 'WORD str)])))
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@code:comment{For example:}
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(define token-source (tokenize "(welcome (to (((ragg)) ())))"))
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(define v (parse token-source))
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(syntax->datum v)
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]
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Welcome to @tt{ragg}.
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@;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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@;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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@section{Introduction}
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@tt{ragg} is a parsing framework for Racket with the design goal to be easy
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to use. It includes the following features:
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@itemize[
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@item{It provides a @litchar{#lang} for writing extended BNF grammars.
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A module written in @litchar{#lang br/ragg} automatically generates a
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parser. The output of this parser tries to follow
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@link["http://en.wikipedia.org/wiki/How_to_Design_Programs"]{HTDP}
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doctrine; the structure of the grammar informs the structure of the
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Racket syntax objects it generates.}
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@item{The language uses a few conventions to simplify the expression of
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grammars. The first rule in the grammar is automatically assumed to be the
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starting production. Identifiers in uppercase are assumed to represent
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terminal tokens, and are otherwise the names of nonterminals.}
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@item{Tokenizers can be developed completely independently of parsers.
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@tt{ragg} takes a liberal view on tokens: they can be strings,
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symbols, or instances constructed with @racket[token]. Furthermore,
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tokens can optionally provide location: if tokens provide location, the
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generated syntax objects will as well.}
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@item{The underlying parser should be able to handle ambiguous grammars.}
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@item{It should integrate with the rest of the Racket
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@link["http://docs.racket-lang.org/guide/languages.html"]{language toolchain}.}
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]
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@subsection[#:tag "install-ragg"]{Installation}
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@itemize[
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@item{@margin-note{At the time of this writing, Racket 5.3.2 is in
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@link["http://pre.racket-lang.org/"]{pre-release}.} If you are using a version
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of Racket > 5.3.1, then follow the instructions on the
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@link["https://plt-etc.byu.edu:9004/info/ragg"]{PLaneT2 page}.}
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@item{For those who are using Racket <= 5.3.1, you can download the following PLT package:
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@nested[#:style 'inset]{@link["ragg.plt"]{ragg.plt} [md5sum: @compute-md5sum["ragg.plt" "ab79038b40e510a5cf13363825c4aef4"]]
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Last updated: @lookup-date["ragg.plt" "Wednesday, January 16th, 2013"]
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}
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Once downloaded, either use DrRacket's package installation features
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(@link["http://docs.racket-lang.org/drracket/Menus.html#(idx._(gentag._57._(lib._scribblings/drracket/drracket..scrbl)))"]{Install
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PLT File...} under DrRacket's File menu), or use the command line:
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@nested[#:style 'inset]{@tt{raco setup -A ragg.plt}}}
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]
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@subsection{Example: a small DSL for ASCII diagrams}
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@margin-note{This is a
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@link["http://stackoverflow.com/questions/12345647/rewrite-this-script-by-designing-an-interpreter-in-racket"]{restatement
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of a question on Stack Overflow}.} To motivate @tt{ragg}'s design, let's look
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at the following toy problem: we'd like to define a language for
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drawing simple ASCII diagrams. We'd like to be able write something like this:
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@nested[#:style 'inset]{
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@verbatim|{
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3 9 X;
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6 3 b 3 X 3 b;
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3 9 X;
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}|}
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whose interpretation should generate the following picture:
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@nested[#:style 'inset]{
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@verbatim|{
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XXXXXXXXX
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XXXXXXXXX
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XXXXXXXXX
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XXX
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XXX
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XXX
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XXX
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XXX
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XXX
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XXXXXXXXX
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XXXXXXXXX
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XXXXXXXXX
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}|}
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@subsection{Syntax and semantics}
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We're being very fast-and-loose with what we mean by the program above, so
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let's try to nail down some meanings. Each line of the program has a semicolon
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at the end, and describes the output of several @emph{rows} of the line
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drawing. Let's look at two of the lines in the example:
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@itemize[
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@item{@litchar{3 9 X;}: ``Repeat the following 3 times: print @racket["X"] nine times, followed by
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a newline.''}
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@item{@litchar{6 3 b 3 X 3 b;}: ``Repeat the following 6 times: print @racket[" "] three times,
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followed by @racket["X"] three times, followed by @racket[" "] three times, followed by a newline.''}
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]
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Then each line consists of a @emph{repeat} number, followed by pairs of
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(number, character) @emph{chunks}. We will
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assume here that the intent of the lowercased character @litchar{b} is to
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represent the printing of a 1-character whitespace @racket[" "], and for other
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uppercase letters to represent the printing of themselves.
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Once we have a better idea of the pieces of each line, we have a better chance
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to capture that meaning in a formal notation. Once we have each instruction in
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a structured format, we should be able to interpret it with a straighforward
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case analysis.
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Here is a first pass at expressing the structure of these line-drawing
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programs.
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@subsection{Parsing the concrete syntax}
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@filebox["simple-line-drawing.rkt"]{
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@verbatim|{
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#lang br/ragg
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drawing: rows*
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rows: repeat chunk+ ";"
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repeat: INTEGER
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chunk: INTEGER STRING
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}|
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}
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@margin-note{@secref{ragg-syntax} describes @tt{ragg}'s syntax in more detail.}
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We write a @tt{ragg} program as an extended BNF grammar, where patterns can be:
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@itemize[
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@item{the names of other rules (e.g. @racket[chunk])}
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@item{literal and symbolic token names (e.g. @racket[";"], @racket[INTEGER])}
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@item{quantified patterns (e.g. @litchar{+} to represent one-or-more repetitions)}
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]
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The result of a @tt{ragg} program is a module with a @racket[parse] function
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that can parse tokens and produce a syntax object as a result.
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Let's exercise this function:
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@interaction[#:eval my-eval
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(require br/ragg/support)
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@eval:alts[(require "simple-line-drawing.rkt")
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(require br/ragg/examples/simple-line-drawing)]
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(define stx
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(parse (list (token 'INTEGER 6)
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(token 'INTEGER 2)
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(token 'STRING " ")
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(token 'INTEGER 3)
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(token 'STRING "X")
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";")))
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(syntax->datum stx)
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]
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Tokens can either be: plain strings, symbols, or instances produced by the
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@racket[token] function. (Plus a few more special cases, one in which we'll describe in a
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moment.)
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Preferably, we want to attach each token with auxiliary source location
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information. The more source location we can provide, the better, as the
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syntax objects produced by @racket[parse] will incorporate them.
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Let's write a helper function, a @emph{lexer}, to help us construct tokens more
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easily. The Racket standard library comes with a module called
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@racketmodname[parser-tools/lex] which can help us write a position-sensitive
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tokenizer:
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@interaction[#:eval my-eval
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(require parser-tools/lex)
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(define (tokenize ip)
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(port-count-lines! ip)
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(define my-lexer
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(lexer-src-pos
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[(repetition 1 +inf.0 numeric)
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(token 'INTEGER (string->number lexeme))]
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[upper-case
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(token 'STRING lexeme)]
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["b"
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(token 'STRING " ")]
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[";"
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(token ";" lexeme)]
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[whitespace
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(token 'WHITESPACE lexeme #:skip? #t)]
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[(eof)
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(void)]))
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(define (next-token) (my-lexer ip))
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next-token)
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(define a-sample-input-port (open-input-string "6 2 b 3 X;"))
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(define token-thunk (tokenize a-sample-input-port))
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@code:comment{Now we can pass token-thunk to the parser:}
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(define another-stx (parse token-thunk))
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(syntax->datum another-stx)
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@code:comment{The syntax object has location information:}
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(syntax-line another-stx)
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(syntax-column another-stx)
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(syntax-span another-stx)
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]
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There are a few things to note from this lexer example:
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@itemize[
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@item{The @racket[parse] function can consume either sequences of tokens, or a
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function that produces tokens. Both of these are considered sources of
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tokens.}
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@item{As a special case for acceptable tokens, a token can also be an instance
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of the @racket[position-token] structure of @racketmodname[parser-tools/lex],
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in which case the token will try to derive its position from that of the
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position-token.}
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@item{The @racket[parse] function will stop reading from a token source if any
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token is @racket[void].}
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@item{The @racket[parse] function will skip over any token with the
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@racket[#:skip?] attribute. Elements such as whitespace and comments will
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often have @racket[#:skip?] set to @racket[#t].}
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]
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@subsection{From parsing to interpretation}
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We now have a parser for programs written in this simple-line-drawing language.
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Our parser will give us back syntax objects:
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@interaction[#:eval my-eval
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(define parsed-program
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(parse (tokenize (open-input-string "3 9 X; 6 3 b 3 X 3 b; 3 9 X;"))))
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(syntax->datum parsed-program)
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]
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Moreover, we know that these syntax objects have a regular, predictable
|
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structure. Their structure follows the grammar, so we know we'll be looking at
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values of the form:
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||
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@racketblock[
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(drawing (rows (repeat <number>)
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(chunk <number> <string>) ... ";")
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...)
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]
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where @racket[drawing], @racket[rows], @racket[repeat], and @racket[chunk]
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should be treated literally, and everything else will be numbers or strings.
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Still, these syntax object values are just inert structures. How do we
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interpret them, and make them @emph{print}? We did claim at the beginning of
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this section that these syntax objects should be fairly easy to case-analyze
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and interpret, so let's do it.
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|
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@margin-note{This is a very quick-and-dirty treatment of @racket[syntax-parse].
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|
See the @racketmodname[syntax/parse] documentation for a gentler guide to its
|
||
|
features.} Racket provides a special form called @racket[syntax-parse] in the
|
||
|
@racketmodname[syntax/parse] library. @racket[syntax-parse] lets us do a
|
||
|
structural case-analysis on syntax objects: we provide it a set of patterns to
|
||
|
parse and actions to perform when those patterns match.
|
||
|
|
||
|
|
||
|
As a simple example, we can write a function that looks at a syntax object and
|
||
|
says @racket[#t] if it's the literal @racket[yes], and @racket[#f] otherwise:
|
||
|
|
||
|
@interaction[#:eval my-eval
|
||
|
(require syntax/parse)
|
||
|
@code:comment{yes-syntax-object?: syntax-object -> boolean}
|
||
|
@code:comment{Returns true if the syntax-object is yes.}
|
||
|
(define (yes-syntax-object? stx)
|
||
|
(syntax-parse stx
|
||
|
[(~literal yes)
|
||
|
#t]
|
||
|
[else
|
||
|
#f]))
|
||
|
(yes-syntax-object? #'yes)
|
||
|
(yes-syntax-object? #'nooooooooooo)
|
||
|
]
|
||
|
|
||
|
Here, we use @racket[~literal] to let @racket[syntax-parse] know that
|
||
|
@racket[yes] should show up literally in the syntax object. The patterns can
|
||
|
also have some structure to them, such as:
|
||
|
@racketblock[({~literal drawing} rows-stxs ...)]
|
||
|
which matches on syntax objects that begin, literally, with @racket[drawing],
|
||
|
followed by any number of rows (which are syntax objects too).
|
||
|
|
||
|
|
||
|
Now that we know a little bit more about @racket[syntax-parse],
|
||
|
we can use it to do a case analysis on the syntax
|
||
|
objects that our @racket[parse] function gives us.
|
||
|
We start by defining a function on syntax objects of the form @racket[(drawing
|
||
|
rows-stx ...)].
|
||
|
@interaction[#:eval my-eval
|
||
|
(define (interpret-drawing drawing-stx)
|
||
|
(syntax-parse drawing-stx
|
||
|
[({~literal drawing} rows-stxs ...)
|
||
|
|
||
|
(for ([rows-stx (syntax->list #'(rows-stxs ...))])
|
||
|
(interpret-rows rows-stx))]))]
|
||
|
|
||
|
When we encounter a syntax object with @racket[(drawing rows-stx
|
||
|
...)], then @racket[interpret-rows] each @racket[rows-stx].
|
||
|
|
||
|
@;The pattern we
|
||
|
@;express in @racket[syntax-parse] above marks what things should be treated
|
||
|
@;literally, and the @racket[...] is a a part of the pattern matching language
|
||
|
@;known by @racket[syntax-parse] that lets us match multiple instances of the
|
||
|
@;last pattern.
|
||
|
|
||
|
|
||
|
Let's define @racket[interpret-rows] now:
|
||
|
@interaction[#:eval my-eval
|
||
|
(define (interpret-rows rows-stx)
|
||
|
(syntax-parse rows-stx
|
||
|
[({~literal rows}
|
||
|
({~literal repeat} repeat-number)
|
||
|
chunks ... ";")
|
||
|
|
||
|
(for ([i (syntax-e #'repeat-number)])
|
||
|
(for ([chunk-stx (syntax->list #'(chunks ...))])
|
||
|
(interpret-chunk chunk-stx))
|
||
|
(newline))]))]
|
||
|
|
||
|
For a @racket[rows], we extract out the @racket[repeat-number] out of the
|
||
|
syntax object and use it as the range of the @racket[for] loop. The inner loop
|
||
|
walks across each @racket[chunk-stx] and calls @racket[interpret-chunk] on it.
|
||
|
|
||
|
|
||
|
Finally, we need to write a definition for @racket[interpret-chunk]. We want
|
||
|
it to extract out the @racket[chunk-size] and @racket[chunk-string] portions,
|
||
|
and print to standard output:
|
||
|
|
||
|
@interaction[#:eval my-eval
|
||
|
(define (interpret-chunk chunk-stx)
|
||
|
(syntax-parse chunk-stx
|
||
|
[({~literal chunk} chunk-size chunk-string)
|
||
|
|
||
|
(for ([k (syntax-e #'chunk-size)])
|
||
|
(display (syntax-e #'chunk-string)))]))
|
||
|
]
|
||
|
|
||
|
|
||
|
@margin-note{Here are the definitions in a single file:
|
||
|
@link["examples/simple-line-drawing/interpret.rkt"]{interpret.rkt}.}
|
||
|
With these definitions in hand, now we can pass it syntax objects
|
||
|
that we construct directly by hand:
|
||
|
|
||
|
@interaction[#:eval my-eval
|
||
|
(interpret-chunk #'(chunk 3 "X"))
|
||
|
(interpret-drawing #'(drawing (rows (repeat 5) (chunk 3 "X") ";")))
|
||
|
]
|
||
|
|
||
|
or we can pass it the result generated by our parser:
|
||
|
@interaction[#:eval my-eval
|
||
|
(define parsed-program
|
||
|
(parse (tokenize (open-input-string "3 9 X; 6 3 b 3 X 3 b; 3 9 X;"))))
|
||
|
(interpret-drawing parsed-program)]
|
||
|
|
||
|
And now we've got an interpreter!
|
||
|
|
||
|
|
||
|
@subsection{From interpretation to compilation}
|
||
|
|
||
|
@margin-note{For a gentler tutorial on writing @litchar{#lang} extensions, see:
|
||
|
@link["http://hashcollision.org/brainfudge"]{F*dging up a Racket}.} (Just as a
|
||
|
warning: the following material is slightly more advanced, but shows how
|
||
|
writing a compiler for the line-drawing language reuses the ideas for the
|
||
|
interpreter.)
|
||
|
|
||
|
Wouldn't it be nice to be able to write something like:
|
||
|
|
||
|
@nested[#:style 'inset]{
|
||
|
@verbatim|{
|
||
|
3 9 X;
|
||
|
6 3 b 3 X 3 b;
|
||
|
3 9 X;
|
||
|
}|}
|
||
|
|
||
|
and have Racket automatically compile this down to something like this?
|
||
|
@racketblock[
|
||
|
(for ([i 3])
|
||
|
(for ([k 9]) (displayln "X"))
|
||
|
(newline))
|
||
|
|
||
|
(for ([i 6])
|
||
|
(for ([k 3]) (displayln " "))
|
||
|
(for ([k 3]) (displayln "X"))
|
||
|
(for ([k 3]) (displayln " "))
|
||
|
(newline))
|
||
|
|
||
|
(for ([i 3])
|
||
|
(for ([k 9]) (displayln "X"))
|
||
|
(newline))
|
||
|
]
|
||
|
|
||
|
Well, of course it won't work: we don't have a @litchar{#lang} line.
|
||
|
|
||
|
Let's add one.
|
||
|
|
||
|
@filebox["letter-i.rkt"]{
|
||
|
@verbatim|{
|
||
|
#lang br/ragg/examples/simple-line-drawing
|
||
|
3 9 X;
|
||
|
6 3 b 3 X 3 b;
|
||
|
3 9 X;
|
||
|
}|
|
||
|
}
|
||
|
|
||
|
Now @filepath{letter-i.rkt} is a program.
|
||
|
|
||
|
|
||
|
How does this work? From the previous sections, we've seen how to take the
|
||
|
contents of a file and interpret it. What we want to do now is teach Racket
|
||
|
how to compile programs labeled with this @litchar{#lang} line. We'll do two
|
||
|
things:
|
||
|
|
||
|
@itemize[
|
||
|
@item{Tell Racket to use the @tt{ragg}-generated parser and lexer we defined
|
||
|
earlier whenever it sees a program written with
|
||
|
@litchar{#lang br/ragg/examples/simple-line-drawing}.}
|
||
|
|
||
|
@item{Define transformation rules for @racket[drawing], @racket[rows], and
|
||
|
@racket[chunk] to rewrite these into standard Racket forms.}
|
||
|
]
|
||
|
|
||
|
The second part, the writing of the transformation rules, will look very
|
||
|
similar to the definitions we wrote for the interpreter, but the transformation
|
||
|
will happen at compile-time. (We @emph{could} just resort to simply calling
|
||
|
into the interpreter we just wrote up, but this section is meant to show that
|
||
|
compilation is also viable.)
|
||
|
|
||
|
|
||
|
We do the first part by defining a @emph{module reader}: a
|
||
|
@link["http://docs.racket-lang.org/guide/syntax_module-reader.html"]{module
|
||
|
reader} tells Racket how to parse and compile a file. Whenever Racket sees a
|
||
|
@litchar{#lang <name>}, it looks for a corresponding module reader in
|
||
|
@filepath{<name>/lang/reader}.
|
||
|
|
||
|
Here's the definition for
|
||
|
@filepath{br/ragg/examples/simple-line-drawing/lang/reader.rkt}:
|
||
|
|
||
|
@filebox["br/ragg/examples/simple-line-drawing/lang/reader.rkt"]{
|
||
|
@codeblock|{
|
||
|
#lang s-exp syntax/module-reader
|
||
|
br/ragg/examples/simple-line-drawing/semantics
|
||
|
#:read my-read
|
||
|
#:read-syntax my-read-syntax
|
||
|
#:whole-body-readers? #t
|
||
|
|
||
|
(require br/ragg/examples/simple-line-drawing/lexer
|
||
|
br/ragg/examples/simple-line-drawing/grammar)
|
||
|
|
||
|
(define (my-read in)
|
||
|
(syntax->datum (my-read-syntax #f in)))
|
||
|
|
||
|
(define (my-read-syntax src ip)
|
||
|
(list (parse src (tokenize ip))))
|
||
|
}|
|
||
|
}
|
||
|
|
||
|
We use a helper module @racketmodname[syntax/module-reader], which provides
|
||
|
utilities for creating a module reader. It uses the lexer and
|
||
|
@tt{ragg}-generated parser we defined earlier (saved into
|
||
|
@link["http://hashcollision.org/ragg/examples/simple-line-drawing/lexer.rkt"]{lexer.rkt}
|
||
|
and
|
||
|
@link["http://hashcollision.org/ragg/examples/simple-line-drawing/grammar.rkt"]{grammar.rkt}
|
||
|
modules), and also tells Racket that it should compile the forms in the syntax
|
||
|
object using a module called @filepath{semantics.rkt}.
|
||
|
|
||
|
@margin-note{For a systematic treatment on capturing the semantics of
|
||
|
a language, see @link["http://cs.brown.edu/~sk/Publications/Books/ProgLangs/"]{Programming Languages: Application and
|
||
|
Interpretation}.}
|
||
|
|
||
|
Let's look into @filepath{semantics.rkt} and see what's involved in
|
||
|
compilation:
|
||
|
@filebox["br/ragg/examples/simple-line-drawing/semantics.rkt"]{
|
||
|
@codeblock|{
|
||
|
#lang racket/base
|
||
|
(require (for-syntax racket/base syntax/parse))
|
||
|
|
||
|
(provide #%module-begin
|
||
|
;; We reuse Racket's treatment of raw datums, specifically
|
||
|
;; for strings and numbers:
|
||
|
#%datum
|
||
|
|
||
|
;; And otherwise, we provide definitions of these three forms.
|
||
|
;; During compiliation, Racket uses these definitions to
|
||
|
;; rewrite into for loops, displays, and newlines.
|
||
|
drawing rows chunk)
|
||
|
|
||
|
;; Define a few compile-time functions to do the syntax rewriting:
|
||
|
(begin-for-syntax
|
||
|
(define (compile-drawing drawing-stx)
|
||
|
(syntax-parse drawing-stx
|
||
|
[({~literal drawing} rows-stxs ...)
|
||
|
|
||
|
(syntax/loc drawing-stx
|
||
|
(begin rows-stxs ...))]))
|
||
|
|
||
|
(define (compile-rows rows-stx)
|
||
|
(syntax-parse rows-stx
|
||
|
[({~literal rows}
|
||
|
({~literal repeat} repeat-number)
|
||
|
chunks ...
|
||
|
";")
|
||
|
|
||
|
(syntax/loc rows-stx
|
||
|
(for ([i repeat-number])
|
||
|
chunks ...
|
||
|
(newline)))]))
|
||
|
|
||
|
(define (compile-chunk chunk-stx)
|
||
|
(syntax-parse chunk-stx
|
||
|
[({~literal chunk} chunk-size chunk-string)
|
||
|
|
||
|
(syntax/loc chunk-stx
|
||
|
(for ([k chunk-size])
|
||
|
(display chunk-string)))])))
|
||
|
|
||
|
|
||
|
;; Wire up the use of "drawing", "rows", and "chunk" to these
|
||
|
;; transformers:
|
||
|
(define-syntax drawing compile-drawing)
|
||
|
(define-syntax rows compile-rows)
|
||
|
(define-syntax chunk compile-chunk)
|
||
|
}|
|
||
|
}
|
||
|
|
||
|
The semantics hold definitions for @racket[compile-drawing],
|
||
|
@racket[compile-rows], and @racket[compile-chunk], similar to what we had for
|
||
|
interpretation with @racket[interpret-drawing], @racket[interpret-rows], and
|
||
|
@racket[interpret-chunk]. However, compilation is not the same as
|
||
|
interpretation: each definition does not immediately execute the act of
|
||
|
drawing, but rather returns a syntax object whose evaluation will do the actual
|
||
|
work.
|
||
|
|
||
|
There are a few things to note:
|
||
|
|
||
|
@itemize[
|
||
|
|
||
|
@item{@tt{ragg}'s native data structure is the syntax object because the
|
||
|
majority of Racket's language-processing infrastructure knows how to read and
|
||
|
write this structured value.}
|
||
|
|
||
|
|
||
|
@item{
|
||
|
@margin-note{By the way, we can just as easily rewrite the semantics so that
|
||
|
@racket[compile-rows] does explicitly call @racket[compile-chunk]. Often,
|
||
|
though, it's easier to write the transformation functions in this piecemeal way
|
||
|
and depend on the Racket macro expansion system to do the rewriting as it
|
||
|
encounters each of the forms.}
|
||
|
Unlike in interpretation, @racket[compile-rows] doesn't
|
||
|
compile each chunk by directly calling @racket[compile-chunk]. Rather, it
|
||
|
depends on the Racket macro expander to call each @racket[compile-XXX] function
|
||
|
as it encounters a @racket[drawing], @racket[rows], or @racket[chunk] in the
|
||
|
parsed value. The three statements at the bottom of @filepath{semantics.rkt} inform
|
||
|
the macro expansion system to do this:
|
||
|
|
||
|
@racketblock[
|
||
|
(define-syntax drawing compile-drawing)
|
||
|
(define-syntax rows compile-rows)
|
||
|
(define-syntax chunk compile-chunk)
|
||
|
]}
|
||
|
]
|
||
|
|
||
|
|
||
|
Altogether, @tt{ragg}'s intent is to be a parser generator generator for Racket
|
||
|
that's easy and fun to use. It's meant to fit naturally with the other tools
|
||
|
in the Racket language toolchain. Hopefully, it will reduce the friction in
|
||
|
making new languages with alternative concrete syntaxes.
|
||
|
|
||
|
The rest of this document describes the @tt{ragg} language and the parsers it
|
||
|
generates.
|
||
|
|
||
|
|
||
|
@;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||
|
@;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||
|
|
||
|
@section{The language}
|
||
|
|
||
|
@subsection[#:tag "ragg-syntax"]{Syntax and terminology}
|
||
|
A program in the @tt{ragg} language consists of the language line
|
||
|
@litchar{#lang br/ragg}, followed by a collection of @tech{rule}s and
|
||
|
@tech{line comment}s.
|
||
|
|
||
|
A @deftech{rule} is a sequence consisting of: a @tech{rule identifier}, a colon
|
||
|
@litchar{":"}, and a @tech{pattern}.
|
||
|
|
||
|
A @deftech{rule identifier} is an @tech{identifier} that is not in upper case.
|
||
|
|
||
|
A @deftech{token identifier} is an @tech{identifier} that is in upper case.
|
||
|
|
||
|
An @deftech{identifier} is a character sequence of letters, numbers, and
|
||
|
characters in @racket["-.!$%&/<=>?^_~@"]. It must not contain
|
||
|
@litchar{*} or @litchar{+}, as those characters are used to denote
|
||
|
quantification.
|
||
|
|
||
|
|
||
|
A @deftech{pattern} is one of the following:
|
||
|
@itemize[
|
||
|
@item{an implicit sequence of @tech{pattern}s separated by whitespace}
|
||
|
@item{a terminal: either a literal string or a @tech{token identifier}}
|
||
|
@item{a @tech{rule identifier}}
|
||
|
@item{a @deftech{choice pattern}: a sequence of @tech{pattern}s delimited with @litchar{|} characters.}
|
||
|
@item{a @deftech{quantifed pattern}: a @tech{pattern} followed by either @litchar{*} (``zero or more'') or @litchar{+} (``one or more'')}
|
||
|
@item{an @deftech{optional pattern}: a @tech{pattern} surrounded by @litchar{[} and @litchar{]}}
|
||
|
@item{an explicit sequence: a @tech{pattern} surrounded by @litchar{(} and @litchar{)}}]
|
||
|
|
||
|
A @deftech{line comment} begins with either @litchar{#} or @litchar{;} and
|
||
|
continues till the end of the line.
|
||
|
|
||
|
|
||
|
For example, in the following program:
|
||
|
@nested[#:style 'inset
|
||
|
@verbatim|{
|
||
|
#lang br/ragg
|
||
|
;; A parser for a silly language
|
||
|
sentence: verb optional-adjective object
|
||
|
verb: greeting
|
||
|
optional-adjective: ["happy" | "frumpy"]
|
||
|
greeting: "hello" | "hola" | "aloha"
|
||
|
object: "world" | WORLD
|
||
|
}|]
|
||
|
|
||
|
the elements @tt{sentence}, @tt{verb}, @tt{greeting}, and @tt{object} are rule
|
||
|
identifiers. The first rule, @litchar{sentence: verb optional-adjective
|
||
|
object}, is a rule whose right side is an implicit pattern sequence of three
|
||
|
sub-patterns. The uppercased @tt{WORLD} is a token identifier. The fourth rule in the program associates @tt{greeting} with a @tech{choice pattern}.
|
||
|
|
||
|
|
||
|
|
||
|
More examples:
|
||
|
@itemize[
|
||
|
|
||
|
@item{A
|
||
|
@link["http://hashcollision.org/ragg/examples/01-equal.rkt"]{BNF} for binary
|
||
|
strings that contain an equal number of zeros and ones.
|
||
|
@verbatim|{
|
||
|
#lang br/ragg
|
||
|
equal: [zero one | one zero] ;; equal number of "0"s and "1"s.
|
||
|
zero: "0" equal | equal "0" ;; has an extra "0" in it.
|
||
|
one: "1" equal | equal "1" ;; has an extra "1" in it.
|
||
|
}|
|
||
|
}
|
||
|
|
||
|
@item{A @link["http://hashcollision.org/ragg/examples/baby-json.rkt"]{BNF} for
|
||
|
@link["http://www.json.org/"]{JSON}-like structures.
|
||
|
@verbatim|{
|
||
|
#lang br/ragg
|
||
|
json: number | string
|
||
|
| array | object
|
||
|
number: NUMBER
|
||
|
string: STRING
|
||
|
array: "[" [json ("," json)*] "]"
|
||
|
object: "{" [kvpair ("," kvpair)*] "}"
|
||
|
kvpair: ID ":" json
|
||
|
}|
|
||
|
}
|
||
|
]
|
||
|
|
||
|
The @link["https://github.com/dyoo/ragg"]{ragg github source repository}
|
||
|
includes
|
||
|
@link["https://github.com/dyoo/ragg/tree/master/ragg/examples"]{several more
|
||
|
examples}.
|
||
|
|
||
|
|
||
|
|
||
|
@subsection{Syntax errors}
|
||
|
|
||
|
Besides the basic syntax errors that can occur with a malformed grammar, there
|
||
|
are a few other classes of situations that @litchar{#lang br/ragg} will consider
|
||
|
as syntax errors.
|
||
|
|
||
|
@tt{ragg} will raise a syntax error if the grammar:
|
||
|
@itemize[
|
||
|
@item{doesn't have any rules.}
|
||
|
|
||
|
@item{has a rule with the same left hand side as any other rule.}
|
||
|
|
||
|
@item{refers to rules that have not been defined. e.g. the
|
||
|
following program:
|
||
|
@nested[#:style 'code-inset
|
||
|
@verbatim|{
|
||
|
#lang br/ragg
|
||
|
foo: [bar]
|
||
|
}|
|
||
|
]
|
||
|
should raise an error because @tt{bar} has not been defined, even though
|
||
|
@tt{foo} refers to it in an @tech{optional pattern}.}
|
||
|
|
||
|
|
||
|
@item{uses the token name @racket[EOF]; the end-of-file token type is reserved
|
||
|
for internal use by @tt{ragg}.}
|
||
|
|
||
|
|
||
|
@item{contains a rule that has no finite derivation. e.g. the following
|
||
|
program:
|
||
|
@nested[#:style 'code-inset
|
||
|
@verbatim|{
|
||
|
#lang br/ragg
|
||
|
infinite-a: "a" infinite-a
|
||
|
}|
|
||
|
]
|
||
|
should raise an error because no finite sequence of tokens will satisfy
|
||
|
@tt{infinite-a}.}
|
||
|
|
||
|
]
|
||
|
|
||
|
Otherwise, @tt{ragg} should be fairly tolerant and permit even ambiguous
|
||
|
grammars.
|
||
|
|
||
|
@subsection{Semantics}
|
||
|
@declare-exporting[br/ragg/examples/nested-word-list]
|
||
|
|
||
|
A program written in @litchar{#lang br/ragg} produces a module that provides a few
|
||
|
bindings. The most important of these is @racket[parse]:
|
||
|
|
||
|
@defproc[(parse [source any/c #f]
|
||
|
[token-source (or/c (sequenceof token)
|
||
|
(-> token))])
|
||
|
syntax?]{
|
||
|
|
||
|
Parses the sequence of @tech{tokens} according to the rules in the grammar, using the
|
||
|
first rule as the start production. The parse must completely consume
|
||
|
@racket[token-source].
|
||
|
|
||
|
The @deftech{token source} can either be a sequence, or a 0-arity function that
|
||
|
produces @tech{tokens}.
|
||
|
|
||
|
A @deftech{token} in @tt{ragg} can be any of the following values:
|
||
|
@itemize[
|
||
|
@item{a string}
|
||
|
@item{a symbol}
|
||
|
@item{an instance produced by @racket[token]}
|
||
|
@item{an instance produced by the token constructors of @racketmodname[parser-tools/lex]}
|
||
|
@item{an instance of @racketmodname[parser-tools/lex]'s @racket[position-token] whose
|
||
|
@racket[position-token-token] is a @tech{token}.}
|
||
|
]
|
||
|
|
||
|
A token whose type is either @racket[void] or @racket['EOF] terminates the
|
||
|
source.
|
||
|
|
||
|
|
||
|
If @racket[parse] succeeds, it will return a structured syntax object. The
|
||
|
structure of the syntax object follows the overall structure of the rules in
|
||
|
the BNF. For each rule @racket[r] and its associated pattern @racket[p],
|
||
|
@racket[parse] generates a syntax object @racket[#'(r p-value)] where
|
||
|
@racket[p-value]'s structure follows a case analysis on @racket[p]:
|
||
|
|
||
|
@itemize[
|
||
|
@item{For implicit and explicit sequences of @tech{pattern}s @racket[p1],
|
||
|
@racket[p2], ..., the corresponding values, spliced into the
|
||
|
structure.}
|
||
|
@item{For terminals, the value associated to the token.}
|
||
|
@item{For @tech{rule identifier}s: the associated parse value for the rule.}
|
||
|
@item{For @tech{choice pattern}s: the associated parse value for one of the matching subpatterns.}
|
||
|
@item{For @tech{quantifed pattern}s and @tech{optional pattern}s: the corresponding values, spliced into the structure.}
|
||
|
]
|
||
|
|
||
|
Consequently, it's only the presence of @tech{rule identifier}s in a rule's
|
||
|
pattern that informs the parser to introduces nested structure into the syntax
|
||
|
object.
|
||
|
|
||
|
|
||
|
If the grammar has ambiguity, @tt{ragg} will choose and return a parse, though
|
||
|
it does not guarantee which one it chooses.
|
||
|
|
||
|
|
||
|
If the parse cannot be performed successfully, or if a token in the
|
||
|
@racket[token-source] uses a type that isn't mentioned in the grammar, then
|
||
|
@racket[parse] raises an instance of @racket[exn:fail:parsing].}
|
||
|
|
||
|
|
||
|
|
||
|
It's often convenient to extract a parser for other non-terminal rules in the
|
||
|
grammar, and not just for the first rule. A @tt{ragg}-generated module also
|
||
|
provides a form called @racket[make-rule-parser] to extract a parser for the
|
||
|
other non-terminals:
|
||
|
|
||
|
@defform[#:id make-rule-parser
|
||
|
(make-rule-parser name)]{
|
||
|
Constructs a parser for the @racket[name] of one of the non-terminals
|
||
|
in the grammar.
|
||
|
|
||
|
For example, given the @tt{ragg} program
|
||
|
@filepath{simple-arithmetic-grammar.rkt}:
|
||
|
@filebox["simple-arithmetic-grammar.rkt"]{
|
||
|
@verbatim|{
|
||
|
#lang br/ragg
|
||
|
expr : term ('+' term)*
|
||
|
term : factor ('*' factor)*
|
||
|
factor : INT
|
||
|
}|
|
||
|
}
|
||
|
the following interaction shows how to extract a parser for @racket[term]s.
|
||
|
@interaction[#:eval my-eval
|
||
|
@eval:alts[(require "simple-arithmetic-grammar.rkt")
|
||
|
(require br/ragg/examples/simple-arithmetic-grammar)]
|
||
|
(define term-parse (make-rule-parser term))
|
||
|
(define tokens (list (token 'INT 3)
|
||
|
"*"
|
||
|
(token 'INT 4)))
|
||
|
(syntax->datum (parse tokens))
|
||
|
(syntax->datum (term-parse tokens))
|
||
|
|
||
|
(define another-token-sequence
|
||
|
(list (token 'INT 1) "+" (token 'INT 2)
|
||
|
"*" (token 'INT 3)))
|
||
|
(syntax->datum (parse another-token-sequence))
|
||
|
@code:comment{Note that term-parse will break on another-token-sequence}
|
||
|
@code:comment{as it does not know what to do with the "+"}
|
||
|
(term-parse another-token-sequence)
|
||
|
]
|
||
|
|
||
|
}
|
||
|
|
||
|
|
||
|
Finally, the module provides a set of all the used token types in the grammar
|
||
|
in @racket[all-token-types]:
|
||
|
@defthing[all-token-types (setof symbol?)]{
|
||
|
A set of all the token types used in a grammar.
|
||
|
|
||
|
For example:
|
||
|
@interaction[#:eval my-eval
|
||
|
@eval:alts[(require "simple-arithmetic-grammar.rkt")
|
||
|
(require br/ragg/examples/simple-arithmetic-grammar)]
|
||
|
all-token-types
|
||
|
]
|
||
|
|
||
|
}
|
||
|
|
||
|
|
||
|
|
||
|
|
||
|
|
||
|
@section{Support API}
|
||
|
|
||
|
@defmodule[br/ragg/support]
|
||
|
|
||
|
The @racketmodname[br/ragg/support] module provides functions to interact with
|
||
|
@tt{ragg} programs. The most useful is the @racket[token] function, which
|
||
|
produces tokens to be parsed.
|
||
|
|
||
|
@defproc[(token [type (or/c string? symbol?)]
|
||
|
[val any/c #f]
|
||
|
[#:line line (or/c positive-integer? #f) #f]
|
||
|
[#:column column (or/c natural-number? #f) #f]
|
||
|
[#:offset offset (or/c positive-integer? #f) #f]
|
||
|
[#:span span (or/c natural-number? #f) #f]
|
||
|
[#:skip? skip? boolean? #f]
|
||
|
)
|
||
|
token-struct?]{
|
||
|
Creates instances of @racket[token-struct]s.
|
||
|
|
||
|
The syntax objects produced by a parse will inject the value @racket[val] in
|
||
|
place of the token name in the grammar.
|
||
|
|
||
|
If @racket[#:skip?] is true, then the parser will skip over it during a
|
||
|
parse.}
|
||
|
|
||
|
|
||
|
@defstruct[token-struct ([type symbol?]
|
||
|
[val any/c]
|
||
|
[offset (or/c positive-integer? #f)]
|
||
|
[line (or/c natural-number? #f)]
|
||
|
[column (or/c positive-integer? #f)]
|
||
|
[span (or/c natural-number? #f)]
|
||
|
[skip? boolean?])
|
||
|
#:transparent]{
|
||
|
The token structure type.
|
||
|
|
||
|
Rather than directly using the @racket[token-struct] constructor, please use
|
||
|
the helper function @racket[token] to construct instances.
|
||
|
}
|
||
|
|
||
|
|
||
|
|
||
|
|
||
|
@defstruct[(exn:fail:parsing exn:fail)
|
||
|
([message string?]
|
||
|
[continuation-marks continuation-mark-set?]
|
||
|
[srclocs (listof srcloc?)])]{
|
||
|
The exception raised when parsing fails.
|
||
|
|
||
|
@racket[exn:fail:parsing] implements Racket's @racket[prop:exn:srcloc]
|
||
|
property, so if this exception reaches DrRacket's default error handler,
|
||
|
DrRacket should highlight the offending locations in the source.}
|
||
|
|
||
|
|
||
|
|
||
|
|
||
|
|
||
|
|
||
|
@;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||
|
@;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||
|
|
||
|
|
||
|
@section{Caveats and things to do}
|
||
|
|
||
|
Here are a few caveats and future aims for @tt{ragg}.
|
||
|
|
||
|
@itemize[
|
||
|
|
||
|
@item{@tt{ragg} doesn't currently have a good story about operator precedence.
|
||
|
Future versions of @tt{ragg} will support the specification of operator
|
||
|
precedence to deal with grammar ambiguity, probably by extending the BNF
|
||
|
grammar rules in @litchar{#lang br/ragg} with keyword arguments.}
|
||
|
|
||
|
|
||
|
@item{I currently depend on the lexer framework provided by
|
||
|
@racketmodname[parser-tools/lex], which has a steeper learning curve than I'd
|
||
|
like. A future version of @tt{ragg} will probably try to provide a nicer set
|
||
|
of tools for defining lexers.}
|
||
|
|
||
|
|
||
|
@item{The underlying parsing engine (an Earley-style parser) has not been fully
|
||
|
optimized, so it may exhibit degenerate parse times. A future version of
|
||
|
@tt{ragg} will guarantee @math{O(n^3)} time bounds so that at the very least,
|
||
|
parses will be polynomial-time.}
|
||
|
|
||
|
|
||
|
@item{@tt{ragg} doesn't yet have a good story on dealing with parser error
|
||
|
recovery. If a parse fails, it tries to provide the source location, but does
|
||
|
little else.}
|
||
|
|
||
|
@item{@tt{ragg} is slightly misnamed: what it really builds is a concrete
|
||
|
syntax tree rather than an abstract syntax tree. A future version of @tt{ragg}
|
||
|
will probably support annotations on patterns so that they can be omitted or
|
||
|
transformed in the parser output.}
|
||
|
|
||
|
]
|
||
|
|
||
|
|
||
|
@;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||
|
@;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||
|
|
||
|
|
||
|
@section{Miscellaneous and thanks}
|
||
|
|
||
|
Thanks to Matthew Flatt for pointing me to @racket[cfg-parser] from the
|
||
|
@racket[cfg-parser] library. Joe Politz gave me good advice and
|
||
|
feedback. Also, he suggested the name ``ragg''. Other alternatives I'd been
|
||
|
considering were ``autogrammar'' or ``chompy''. Thankfully, he is a better
|
||
|
Namer than me. Daniel Patterson provided feedback that led to
|
||
|
@racket[make-rule-parser]. Robby Findler and Guillaume Marceau provided
|
||
|
steadfast suggestions to look into other parsing frameworks like
|
||
|
@link["http://en.wikipedia.org/wiki/Syntax_Definition_Formalism"]{SDF} and
|
||
|
@link["http://sablecc.org/"]{SableCC}. Special thanks to Shriram
|
||
|
Krishnamurthi, who convinced me that other people might find this package
|
||
|
useful.
|
||
|
|
||
|
|
||
|
@close-eval[my-eval]
|