#lang racket/base ;; This module implements a parser form like the parser-tools's ;; `parser', except that it works on an arbitrary CFG (returning ;; the first sucecssful parse). ;; I'm pretty sure that this is an implementation of Earley's ;; algorithm. ;; To a first approximation, it's a backtracking parser. Alternative ;; for a non-terminal are computed in parallel, and multiple attempts ;; to compute the same result block until the first one completes. If ;; you get into deadlock, such as when trying to match ;; := ;; then it means that there's no successful parse, so everything ;; that's blocked fails. ;; A cache holds the series of results for a particular non-terminal ;; at a particular starting location. (A series is used, instead of a ;; sinlge result, for backtracking.) Otherwise, the parser uses ;; backtracking search. Backtracking is implemented through explicit ;; success and failure continuations. Multiple results for a ;; particular nonterminal and location are kept only when they have ;; different lengths. (Otherwise, in the spirit of finding one ;; successful parse, only the first result is kept.) ;; The parser-tools's `parse' is used to transform tokens in the ;; grammar to tokens specific to this parser. In other words, this ;; parser uses `parser' so that it doesn't have to know anything about ;; tokens. ;; (require parser-tools/yacc parser-tools/lex) (require (for-syntax racket/base syntax/boundmap parser-tools/private-lex/token-syntax)) (provide cfg-parser) ;; A raw token, wrapped so that we can recognize it: (define-struct tok (name orig-name val start end)) ;; Represents the thread scheduler: (define-struct tasks (active active-back waits multi-waits cache progress?)) (define-for-syntax make-token-identifier-mapping make-hasheq) (define-for-syntax token-identifier-mapping-get (case-lambda [(t tok) (hash-ref t (syntax-e tok))] [(t tok fail) (hash-ref t (syntax-e tok) fail)])) (define-for-syntax token-identifier-mapping-put! (lambda (t tok v) (hash-set! t (syntax-e tok) v))) (define-for-syntax token-identifier-mapping-map (lambda (t f) (hash-map t f))) ;; Used to calculate information on the grammar, such as whether ;; a particular non-terminal is "simple" instead of recursively defined. (define-for-syntax (nt-fixpoint nts proc nt-ids patss) (define (ormap-all val f as bs) (cond [(null? as) val] [else (ormap-all (or (f (car as) (car bs)) val) f (cdr as) (cdr bs))])) (let loop () (when (ormap-all #f (lambda (nt pats) (let ([old (bound-identifier-mapping-get nts nt)]) (let ([new (proc nt pats old)]) (if (equal? old new) #f (begin (bound-identifier-mapping-put! nts nt new) #t))))) nt-ids patss) (loop)))) ;; Tries parse-a followed by parse-b. If parse-a is not simple, ;; then after parse-a succeeds once, we parallelize parse-b ;; and trying a second result for parse-a. (define (parse-and simple-a? parse-a parse-b stream last-consumed-token depth end success-k fail-k max-depth tasks) (letrec ([mk-got-k (lambda (success-k fail-k) (lambda (val stream last-consumed-token depth max-depth tasks next1-k) (if simple-a? (parse-b val stream last-consumed-token depth end (mk-got2-k success-k fail-k next1-k) (mk-fail2-k success-k fail-k next1-k) max-depth tasks) (parallel-or (lambda (success-k fail-k max-depth tasks) (parse-b val stream last-consumed-token depth end success-k fail-k max-depth tasks)) (lambda (success-k fail-k max-depth tasks) (next1-k (mk-got-k success-k fail-k) fail-k max-depth tasks)) success-k fail-k max-depth tasks))))] [mk-got2-k (lambda (success-k fail-k next1-k) (lambda (val stream last-consumed-token depth max-depth tasks next-k) (success-k val stream last-consumed-token depth max-depth tasks (lambda (success-k fail-k max-depth tasks) (next-k (mk-got2-k success-k fail-k next1-k) (mk-fail2-k success-k fail-k next1-k) max-depth tasks)))))] [mk-fail2-k (lambda (success-k fail-k next1-k) (lambda (max-depth tasks) (next1-k (mk-got-k success-k fail-k) fail-k max-depth tasks)))]) (parse-a stream last-consumed-token depth end (mk-got-k success-k fail-k) fail-k max-depth tasks))) ;; Parallel or for non-terminal alternatives (define (parse-parallel-or parse-a parse-b stream last-consumed-token depth end success-k fail-k max-depth tasks) (parallel-or (lambda (success-k fail-k max-depth tasks) (parse-a stream last-consumed-token depth end success-k fail-k max-depth tasks)) (lambda (success-k fail-k max-depth tasks) (parse-b stream last-consumed-token depth end success-k fail-k max-depth tasks)) success-k fail-k max-depth tasks)) ;; Generic parallel-or (define (parallel-or parse-a parse-b success-k fail-k max-depth tasks) (define answer-key (gensym)) (letrec ([gota-k (lambda (val stream last-consumed-token depth max-depth tasks next-k) (report-answer answer-key max-depth tasks (list val stream last-consumed-token depth next-k)))] [faila-k (lambda (max-depth tasks) (report-answer answer-key max-depth tasks null))]) (let* ([tasks (queue-task tasks (lambda (max-depth tasks) (parse-a gota-k faila-k max-depth tasks)))] [tasks (queue-task tasks (lambda (max-depth tasks) (parse-b gota-k faila-k max-depth tasks)))] [queue-next (lambda (next-k tasks) (queue-task tasks (lambda (max-depth tasks) (next-k gota-k faila-k max-depth tasks))))]) (letrec ([mk-got-one (lambda (immediate-next? get-nth success-k) (lambda (val stream last-consumed-token depth max-depth tasks next-k) (let ([tasks (if immediate-next? (queue-next next-k tasks) tasks)]) (success-k val stream last-consumed-token depth max-depth tasks (lambda (success-k fail-k max-depth tasks) (let ([tasks (if immediate-next? tasks (queue-next next-k tasks))]) (get-nth max-depth tasks success-k fail-k)))))))] [get-first (lambda (max-depth tasks success-k fail-k) (wait-for-answer #f max-depth tasks answer-key (mk-got-one #t get-first success-k) (lambda (max-depth tasks) (get-second max-depth tasks success-k fail-k)) #f))] [get-second (lambda (max-depth tasks success-k fail-k) (wait-for-answer #f max-depth tasks answer-key (mk-got-one #f get-second success-k) fail-k #f))]) (get-first max-depth tasks success-k fail-k))))) ;; Non-terminal alternatives where the first is "simple" can be done ;; sequentially, which is simpler (define (parse-or parse-a parse-b stream last-consumed-token depth end success-k fail-k max-depth tasks) (letrec ([mk-got-k (lambda (success-k fail-k) (lambda (val stream last-consumed-token depth max-depth tasks next-k) (success-k val stream last-consumed-token depth max-depth tasks (lambda (success-k fail-k max-depth tasks) (next-k (mk-got-k success-k fail-k) (mk-fail-k success-k fail-k) max-depth tasks)))))] [mk-fail-k (lambda (success-k fail-k) (lambda (max-depth tasks) (parse-b stream last-consumed-token depth end success-k fail-k max-depth tasks)))]) (parse-a stream last-consumed-token depth end (mk-got-k success-k fail-k) (mk-fail-k success-k fail-k) max-depth tasks))) ;; Starts a thread (define queue-task (lambda (tasks t [progress? #t]) (make-tasks (tasks-active tasks) (cons t (tasks-active-back tasks)) (tasks-waits tasks) (tasks-multi-waits tasks) (tasks-cache tasks) (or progress? (tasks-progress? tasks))))) ;; Reports an answer to a waiting thread: (define (report-answer answer-key max-depth tasks val) (let ([v (hash-ref (tasks-waits tasks) answer-key (lambda () #f))]) (if v (let ([tasks (make-tasks (cons (v val) (tasks-active tasks)) (tasks-active-back tasks) (tasks-waits tasks) (tasks-multi-waits tasks) (tasks-cache tasks) #t)]) (hash-remove! (tasks-waits tasks) answer-key) (swap-task max-depth tasks)) ;; We have an answer ready too fast; wait (swap-task max-depth (queue-task tasks (lambda (max-depth tasks) (report-answer answer-key max-depth tasks val)) #f))))) ;; Reports an answer to multiple waiting threads: (define (report-answer-all answer-key max-depth tasks val k) (let ([v (hash-ref (tasks-multi-waits tasks) answer-key (lambda () null))]) (hash-remove! (tasks-multi-waits tasks) answer-key) (let ([tasks (make-tasks (append (map (lambda (a) (a val)) v) (tasks-active tasks)) (tasks-active-back tasks) (tasks-waits tasks) (tasks-multi-waits tasks) (tasks-cache tasks) #t)]) (k max-depth tasks)))) ;; Waits for an answer; if `multi?' is #f, this is sole waiter, otherwise ;; there might be many. Use wither #t or #f (and `report-answer' or ;; `report-answer-all', resptively) consistently for a particular answer key. (define (wait-for-answer multi? max-depth tasks answer-key success-k fail-k deadlock-k) (let ([wait (lambda (val) (lambda (max-depth tasks) (if val (if (null? val) (fail-k max-depth tasks) (let-values ([(val stream last-consumed-token depth next-k) (apply values val)]) (success-k val stream last-consumed-token depth max-depth tasks next-k))) (deadlock-k max-depth tasks))))]) (if multi? (hash-set! (tasks-multi-waits tasks) answer-key (cons wait (hash-ref (tasks-multi-waits tasks) answer-key (lambda () null)))) (hash-set! (tasks-waits tasks) answer-key wait)) (let ([tasks (make-tasks (tasks-active tasks) (tasks-active-back tasks) (tasks-waits tasks) (tasks-multi-waits tasks) (tasks-cache tasks) #t)]) (swap-task max-depth tasks)))) ;; Swap thread (define (swap-task max-depth tasks) ;; Swap in first active: (if (null? (tasks-active tasks)) (if (tasks-progress? tasks) (swap-task max-depth (make-tasks (reverse (tasks-active-back tasks)) null (tasks-waits tasks) (tasks-multi-waits tasks) (tasks-cache tasks) #f)) ;; No progress, so issue failure for all multi-waits (if (zero? (hash-count (tasks-multi-waits tasks))) (error 'swap-task "Deadlock") (swap-task max-depth (make-tasks (apply append (hash-map (tasks-multi-waits tasks) (lambda (k l) (map (lambda (v) (v #f)) l)))) (tasks-active-back tasks) (tasks-waits tasks) (make-hasheq) (tasks-cache tasks) #t)))) (let ([t (car (tasks-active tasks))] [tasks (make-tasks (cdr (tasks-active tasks)) (tasks-active-back tasks) (tasks-waits tasks) (tasks-multi-waits tasks) (tasks-cache tasks) (tasks-progress? tasks))]) (t max-depth tasks)))) ;; Finds the symbolic representative of a token class (define-for-syntax (map-token toks tok) (car (token-identifier-mapping-get toks tok))) (define no-pos-val (make-position #f #f #f)) (define-for-syntax no-pos (let ([npv ((syntax-local-certifier) #'no-pos-val)]) (lambda (stx) npv))) (define-for-syntax at-tok-pos (lambda (sel expr) (lambda (stx) #`(let ([v #,expr]) (if v (#,sel v) no-pos-val))))) ;; Builds a matcher for a particular alternative (define-for-syntax (build-match nts toks pat handle $ctx) (let loop ([pat pat] [pos 1]) (if (null? pat) #`(success-k #,handle stream last-consumed-token depth max-depth tasks (lambda (success-k fail-k max-depth tasks) (fail-k max-depth tasks))) (let ([id (datum->syntax (car pat) (string->symbol (format "$~a" pos)))] [id-start-pos (datum->syntax (car pat) (string->symbol (format "$~a-start-pos" pos)))] [id-end-pos (datum->syntax (car pat) (string->symbol (format "$~a-end-pos" pos)))] [n-end-pos (and (null? (cdr pat)) (datum->syntax (car pat) '$n-end-pos))]) (cond [(bound-identifier-mapping-get nts (car pat) (lambda () #f)) ;; Match non-termimal #`(parse-and ;; First part is simple? (If so, we don't have to parallelize the `and'.) #,(let ([l (bound-identifier-mapping-get nts (car pat) (lambda () #f))]) (or (not l) (andmap values (caddr l)))) #,(car pat) (let ([original-stream stream]) (lambda (#,id stream last-consumed-token depth end success-k fail-k max-depth tasks) (let-syntax ([#,id-start-pos (at-tok-pos #'(if (eq? original-stream stream) tok-end tok-start) #'(if (eq? original-stream stream) last-consumed-token (and (pair? original-stream) (car original-stream))))] [#,id-end-pos (at-tok-pos #'tok-end #'last-consumed-token)] #,@(if n-end-pos #`([#,n-end-pos (at-tok-pos #'tok-end #'last-consumed-token)]) null)) #,(loop (cdr pat) (add1 pos))))) stream last-consumed-token depth #,(let ([cnt (apply + (map (lambda (item) (cond [(bound-identifier-mapping-get nts item (lambda () #f)) => (lambda (l) (car l))] [else 1])) (cdr pat)))]) #`(- end #,cnt)) success-k fail-k max-depth tasks)] [else ;; Match token (let ([tok-id (map-token toks (car pat))]) #`(if (and (pair? stream) (eq? '#,tok-id (tok-name (car stream)))) (let* ([stream-a (car stream)] [#,id (tok-val stream-a)] [last-consumed-token (car stream)] [stream (cdr stream)] [depth (add1 depth)]) (let ([max-depth (max max-depth depth)]) (let-syntax ([#,id-start-pos (at-tok-pos #'tok-start #'stream-a)] [#,id-end-pos (at-tok-pos #'tok-end #'stream-a)] #,@(if n-end-pos #`([#,n-end-pos (at-tok-pos #'tok-end #'stream-a)]) null)) #,(loop (cdr pat) (add1 pos))))) (fail-k max-depth tasks)))]))))) ;; Starts parsing to match a non-terminal. There's a minor ;; optimization that checks for known starting tokens. Otherwise, ;; use the cache, block if someone else is already trying the match, ;; and cache the result if it's computed. ;; The cache maps nontermial+startingpos+iteration to a result, where ;; the iteration is 0 for the first match attempt, 1 for the second, ;; etc. (define (parse-nt/share key min-cnt init-tokens stream last-consumed-token depth end max-depth tasks success-k fail-k k) (if (and (positive? min-cnt) (pair? stream) (not (memq (tok-name (car stream)) init-tokens))) ;; No such leading token; give up (fail-k max-depth tasks) ;; Run pattern (let loop ([n 0] [success-k success-k] [fail-k fail-k] [max-depth max-depth] [tasks tasks] [k k]) (let ([answer-key (gensym)] [table-key (vector key depth n)] [old-depth depth] [old-stream stream]) #;(printf "Loop ~a\n" table-key) (cond [(hash-ref (tasks-cache tasks) table-key (lambda () #f)) => (lambda (result) #;(printf "Reuse ~a\n" table-key) (result success-k fail-k max-depth tasks))] [else #;(printf "Try ~a ~a\n" table-key (map tok-name stream)) (hash-set! (tasks-cache tasks) table-key (lambda (success-k fail-k max-depth tasks) #;(printf "Wait ~a ~a\n" table-key answer-key) (wait-for-answer #t max-depth tasks answer-key success-k fail-k (lambda (max-depth tasks) #;(printf "Deadlock ~a ~a\n" table-key answer-key) (fail-k max-depth tasks))))) (let result-loop ([max-depth max-depth][tasks tasks][k k]) (letrec ([orig-stream stream] [new-got-k (lambda (val stream last-consumed-token depth max-depth tasks next-k) ;; Check whether we already have a result that consumed the same amount: (let ([result-key (vector #f key old-depth depth)]) (cond [(hash-ref (tasks-cache tasks) result-key (lambda () #f)) ;; Go for the next-result (result-loop max-depth tasks (lambda (end max-depth tasks success-k fail-k) (next-k success-k fail-k max-depth tasks)))] [else #;(printf "Success ~a ~a\n" table-key (map tok-name (let loop ([d old-depth][s old-stream]) (if (= d depth) null (cons (car s) (loop (add1 d) (cdr s))))))) (let ([next-k (lambda (success-k fail-k max-depth tasks) (loop (add1 n) success-k fail-k max-depth tasks (lambda (end max-depth tasks success-k fail-k) (next-k success-k fail-k max-depth tasks))))]) (hash-set! (tasks-cache tasks) result-key #t) (hash-set! (tasks-cache tasks) table-key (lambda (success-k fail-k max-depth tasks) (success-k val stream last-consumed-token depth max-depth tasks next-k))) (report-answer-all answer-key max-depth tasks (list val stream last-consumed-token depth next-k) (lambda (max-depth tasks) (success-k val stream last-consumed-token depth max-depth tasks next-k))))])))] [new-fail-k (lambda (max-depth tasks) #;(printf "Failure ~a\n" table-key) (hash-set! (tasks-cache tasks) table-key (lambda (success-k fail-k max-depth tasks) (fail-k max-depth tasks))) (report-answer-all answer-key max-depth tasks null (lambda (max-depth tasks) (fail-k max-depth tasks))))]) (k end max-depth tasks new-got-k new-fail-k)))]))))) (define-syntax (cfg-parser stx) (syntax-case stx () [(_ clause ...) (let ([clauses (syntax->list #'(clause ...))]) (let-values ([(start grammar cfg-error parser-clauses src-pos?) (let ([all-toks (apply append (map (lambda (clause) (syntax-case clause (tokens) [(tokens t ...) (apply append (map (lambda (t) (let ([v (syntax-local-value t (lambda () #f))]) (cond [(terminals-def? v) (map (lambda (v) (cons v #f)) (syntax->list (terminals-def-t v)))] [(e-terminals-def? v) (map (lambda (v) (cons v #t)) (syntax->list (e-terminals-def-t v)))] [else null]))) (syntax->list #'(t ...))))] [_else null])) clauses))] [all-end-toks (apply append (map (lambda (clause) (syntax-case clause (end) [(end t ...) (syntax->list #'(t ...))] [_else null])) clauses))]) (let loop ([clauses clauses] [cfg-start #f] [cfg-grammar #f] [cfg-error #f] [src-pos? #f] [parser-clauses null]) (if (null? clauses) (values cfg-start cfg-grammar cfg-error (reverse parser-clauses) src-pos?) (syntax-case (car clauses) (start error grammar src-pos) [(start tok) (loop (cdr clauses) #'tok cfg-grammar cfg-error src-pos? parser-clauses)] [(error expr) (loop (cdr clauses) cfg-start cfg-grammar #'expr src-pos? parser-clauses)] [(grammar [nt [pat handle0 handle ...] ...] ...) (let ([nts (make-bound-identifier-mapping)] [toks (make-token-identifier-mapping)] [end-toks (make-token-identifier-mapping)] [nt-ids (syntax->list #'(nt ...))] [patss (map (lambda (stx) (map syntax->list (syntax->list stx))) (syntax->list #'((pat ...) ...)))]) (for-each (lambda (nt) (bound-identifier-mapping-put! nts nt (list 0))) nt-ids) (for-each (lambda (t) (token-identifier-mapping-put! end-toks t #t)) all-end-toks) (for-each (lambda (t) (unless (token-identifier-mapping-get end-toks (car t) (lambda () #f)) (let ([id (gensym (syntax-e (car t)))]) (token-identifier-mapping-put! toks (car t) (cons id (cdr t)))))) all-toks) ;; Compute min max size for each non-term: (nt-fixpoint nts (lambda (nt pats old-list) (let ([new-cnt (apply min (map (lambda (pat) (apply + (map (lambda (elem) (car (bound-identifier-mapping-get nts elem (lambda () (list 1))))) pat))) pats))]) (if (new-cnt . > . (car old-list)) (cons new-cnt (cdr old-list)) old-list))) nt-ids patss) ;; Compute set of toks that must appear at the beginning ;; for a non-terminal (nt-fixpoint nts (lambda (nt pats old-list) (let ([new-list (apply append (map (lambda (pat) (let loop ([pat pat]) (if (pair? pat) (let ([l (bound-identifier-mapping-get nts (car pat) (lambda () (list 1 (map-token toks (car pat)))))]) ;; If the non-terminal can match 0 things, ;; then it might match something from the ;; next pattern element. Otherwise, it must ;; match the first element: (if (zero? (car l)) (append (cdr l) (loop (cdr pat))) (cdr l))) null))) pats))]) (let ([new (filter (lambda (id) (andmap (lambda (id2) (not (eq? id id2))) (cdr old-list))) new-list)]) (if (pair? new) ;; Drop dups in new list: (let ([new (let loop ([new new]) (if (null? (cdr new)) new (if (ormap (lambda (id) (eq? (car new) id)) (cdr new)) (loop (cdr new)) (cons (car new) (loop (cdr new))))))]) (cons (car old-list) (append new (cdr old-list)))) old-list)))) nt-ids patss) ;; Determine left-recursive clauses: (for-each (lambda (nt pats) (let ([l (bound-identifier-mapping-get nts nt)]) (bound-identifier-mapping-put! nts nt (list (car l) (cdr l) (map (lambda (x) #f) pats))))) nt-ids patss) (nt-fixpoint nts (lambda (nt pats old-list) (list (car old-list) (cadr old-list) (map (lambda (pat simple?) (or simple? (let ([l (map (lambda (elem) (bound-identifier-mapping-get nts elem (lambda () #f))) pat)]) (andmap (lambda (i) (or (not i) (andmap values (caddr i)))) l)))) pats (caddr old-list)))) nt-ids patss) ;; Build a definition for each non-term: (loop (cdr clauses) cfg-start (map (lambda (nt pats handles $ctxs) (define info (bound-identifier-mapping-get nts nt)) (list nt #`(let ([key (gensym '#,nt)]) (lambda (stream last-consumed-token depth end success-k fail-k max-depth tasks) (parse-nt/share key #,(car info) '#,(cadr info) stream last-consumed-token depth end max-depth tasks success-k fail-k (lambda (end max-depth tasks success-k fail-k) #,(let loop ([pats pats] [handles (syntax->list handles)] [$ctxs (syntax->list $ctxs)] [simple?s (caddr info)]) (if (null? pats) #'(fail-k max-depth tasks) #`(#,(if (or (null? (cdr pats)) (car simple?s)) #'parse-or #'parse-parallel-or) (lambda (stream last-consumed-token depth end success-k fail-k max-depth tasks) #,(build-match nts toks (car pats) (car handles) (car $ctxs))) (lambda (stream last-consumed-token depth end success-k fail-k max-depth tasks) #,(loop (cdr pats) (cdr handles) (cdr $ctxs) (cdr simple?s))) stream last-consumed-token depth end success-k fail-k max-depth tasks))))))))) nt-ids patss (syntax->list #'(((begin handle0 handle ...) ...) ...)) (syntax->list #'((handle0 ...) ...))) cfg-error src-pos? (list* (with-syntax ([((tok tok-id . $e) ...) (token-identifier-mapping-map toks (lambda (k v) (list* k (car v) (if (cdr v) #f '$1))))] [(pos ...) (if src-pos? #'($1-start-pos $1-end-pos) #'(#f #f))]) #`(grammar (start [() null] [(atok start) (cons $1 $2)]) (atok [(tok) (make-tok 'tok-id 'tok $e pos ...)] ...))) #`(start start) parser-clauses)))] [(grammar . _) (raise-syntax-error #f "bad grammar clause" stx (car clauses))] [(src-pos) (loop (cdr clauses) cfg-start cfg-grammar cfg-error #t (cons (car clauses) parser-clauses))] [_else (loop (cdr clauses) cfg-start cfg-grammar cfg-error src-pos? (cons (car clauses) parser-clauses))]))))]) #`(let ([orig-parse (parser [error (lambda (a b c) (error 'cfg-parser "unexpected ~a token: ~a" b c))] . #,parser-clauses)] [error-proc #,cfg-error]) (letrec #,grammar (lambda (get-tok) (let ([tok-list (orig-parse get-tok)]) (letrec ([success-k (lambda (val stream last-consumed-token depth max-depth tasks next) (if (null? stream) val (next success-k fail-k max-depth tasks)))] [fail-k (lambda (max-depth tasks) (cond [(null? tok-list) (if error-proc (error-proc #t 'no-tokens #f (make-position #f #f #f) (make-position #f #f #f)) (error 'cfg-parse "no tokens"))] [else (let ([bad-tok (list-ref tok-list (min (sub1 (length tok-list)) max-depth))]) (if error-proc (error-proc #t (tok-orig-name bad-tok) (tok-val bad-tok) (tok-start bad-tok) (tok-end bad-tok)) (error 'cfg-parse "failed at ~a" (tok-val bad-tok))))]))]) (#,start tok-list ;; we simulate a token at the very beginning with zero width ;; for use with the position-generating code (*-start-pos, *-end-pos). (if (null? tok-list) (tok #f #f #f (position 1 #,(if src-pos? #'1 #'#f) #,(if src-pos? #'0 #'#f)) (position 1 #,(if src-pos? #'1 #'#f) #,(if src-pos? #'0 #'#f))) (tok (tok-name (car tok-list)) (tok-orig-name (car tok-list)) (tok-val (car tok-list)) (tok-start (car tok-list)) (tok-start (car tok-list)))) 0 (length tok-list) success-k fail-k 0 (make-tasks null null (make-hasheq) (make-hasheq) (make-hash) #t)))))))))])) (module* test racket/base (require (submod "..") parser-tools/lex racket/block rackunit) ;; Test: parsing regular expressions. ;; Here is a test case on locations: (block (define-tokens regexp-tokens (ANCHOR STAR OR LIT LPAREN RPAREN EOF)) (define lex (lexer-src-pos ["|" (token-OR lexeme)] ["^" (token-ANCHOR lexeme)] ["*" (token-STAR lexeme)] [(repetition 1 +inf.0 alphabetic) (token-LIT lexeme)] ["(" (token-LPAREN lexeme)] [")" (token-RPAREN lexeme)] [whitespace (return-without-pos (lex input-port))] [(eof) (token-EOF 'eof)])) (define -parse (cfg-parser (tokens regexp-tokens) (start top) (end EOF) (src-pos) (grammar [top [(maybe-anchor regexp) (cond [$1 `(anchored ,$2 ,(pos->sexp $1-start-pos) ,(pos->sexp $2-end-pos))] [else `(unanchored ,$2 ,(pos->sexp $1-start-pos) ,(pos->sexp $2-end-pos))])]] [maybe-anchor [(ANCHOR) #t] [() #f]] [regexp [(regexp STAR) `(star ,$1 ,(pos->sexp $1-start-pos) ,(pos->sexp $2-end-pos))] [(regexp OR regexp) `(or ,$1 ,$3 ,(pos->sexp $1-start-pos) ,(pos->sexp $3-end-pos))] [(LPAREN regexp RPAREN) `(group ,$2 ,(pos->sexp $1-start-pos) ,(pos->sexp $3-end-pos))] [(LIT) `(lit ,$1 ,(pos->sexp $1-start-pos) ,(pos->sexp $1-end-pos))]]))) (define (pos->sexp pos) (position-offset pos)) (define (parse s) (define ip (open-input-string s)) (port-count-lines! ip) (-parse (lambda () (lex ip)))) (check-equal? (parse "abc") '(unanchored (lit "abc" 1 4) 1 4)) (check-equal? (parse "a | (b*) | c") '(unanchored (or (or (lit "a" 1 2) (group (star (lit "b" 6 7) 6 8) 5 9) 1 9) (lit "c" 12 13) 1 13) 1 13))) ;; Tests used during development (define-tokens non-terminals (PLUS MINUS STAR BAR COLON EOF)) (define lex (lexer ["+" (token-PLUS '+)] ["-" (token-MINUS '-)] ["*" (token-STAR '*)] ["|" (token-BAR '||)] [":" (token-COLON '|:|)] [whitespace (lex input-port)] [(eof) (token-EOF 'eof)])) (define parse (cfg-parser (tokens non-terminals) (start ) (end EOF) (error (lambda (a b stx) (error 'parse "failed at ~s" stx))) (grammar [ [(PLUS) "plus"] [( BAR ) (list $1 $2 $3)] [( COLON) (list $1)]] [ [(MINUS) "minus"] [( STAR) (cons $1 $2)]] [ [( MINUS) "yes"]] [ [(PLUS) 'plus] [(MINUS) 'minus]] [ [() '0] [( PLUS) (add1 $1)] [( PLUS) (add1 $1)]]))) (let ([p (open-input-string #;"+*|-|-*|+**" #;"-|+*|+**" #;"+*|+**|-" #;"-|-*|-|-*" #;"-|-*|-|-**|-|-*|-|-**" "-|-*|-|-**|-|-*|-|-***|-|-*|-|-**|-|-*|-|-****|-|-*|-|-**|-|-*|-|-*** |-|-*|-|-**|-|-*|-|-*****|-|-*|-|-**|-|-*|-|-***|-|-*|-|-**|-|-*|-|-****| -|-*|-|-**|-|-*|-|-***|-|-*|-|-**|-|-*|-|-*****" ;; This one fails: #;"+*")]) (check-equal? (parse (lambda () (lex p))) '((((((((((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *) || (((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *)) . *) || (((((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *) || (((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *)) . *)) . *) || (((((((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *) || (((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *)) . *) || (((((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *) || (((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *)) . *)) . *)) . *) || (((((((((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *) || (((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *)) . *) || (((((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *) || (((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *)) . *)) . *) || (((((((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *) || (((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *)) . *) || (((((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *) || (((("minus" || "minus") . *) || (("minus" || "minus") . *)) . *)) . *)) . *)) . *)))))