;;; module/nyacc/util.scm ;;; ;;; Copyright (C) 2015 Matthew R. Wette ;;; ;;; This software is covered by the GNU GENERAL PUBLIC LICENCE, Version 3, ;;; or any later version published by the Free Software Foundation. See the ;;; file COPYING included with the nyacc distribution. ;; runtime utilities for the parsers -- needs work (define-module (nyacc lang util) #:export (lang-crn-lic push-input pop-input reset-input-stack make-tl tl->list ;; rename?? to tl->sx for sxml-expr tl-append tl-insert tl-extend tl+attr sx-tag sx-attr sx-attr-ref sx-has-attr? sx-set-attr! sx-set-attr* sx-ref sx-tail sx-find ;; for pretty-printing make-protect-expr make-pp-formatter make-pp-formatter/ugly ;; for ??? move-if-changed fmterr) #:use-module ((srfi srfi-1) #:select(find)) ) (cond-expand (guile-2) (guile (use-modules (ice-9 optargs)) (use-modules (ice-9 syncase))) (mes)) ;; This is a generic copyright/licence that will be printed in the output ;; of the examples/nyacc/lang/*/ actions.scm and tables.scm files. (define lang-crn-lic "Copyright (C) 2015,2016 Matthew R. Wette This software is covered by the GNU GENERAL PUBLIC LICENCE, Version 3, or any later version published by the Free Software Foundation. See the file COPYING included with the this distribution.") (define (fmterr fmt . args) (apply simple-format (current-error-port) fmt args)) ;; === input stack ===================== (define *input-stack* (make-fluid '())) (define (reset-input-stack) (fluid-set! *input-stack* '())) (define (push-input port) (let ((curr (current-input-port)) (ipstk (fluid-ref *input-stack*))) (fluid-set! *input-stack* (cons curr ipstk)) (set-current-input-port port))) ;; Return #f if empty (define (pop-input) (let ((ipstk (fluid-ref *input-stack*))) (if (null? ipstk) #f (begin (set-current-input-port (car ipstk)) (fluid-set! *input-stack* (cdr ipstk)))))) ;; It may be possible to reimplement with closures, using soft-ports. ;; (push-string-input ... #| (define (push-string-input str) (let* ((prev (current-input-port)) (port (make-soft-port ...)) ) #f)) |# ;; === tl ============================== ;; @section Tagged Lists ;; Tagged lists are ;; They are implemented as a cons cell with the car and the cdr a list. ;; The cdr is used to accumulate appended items and the car is used to ;; keep the tag, attributes and inserted items. ;; @example ;; tl => '(H . T), H => (c a b 'tag); T => ;; @end example ;; @table code ;; @deffn make-tl tag [item item ...] ;; Create a tagged-list structure. (define (make-tl tag . rest) (let iter ((tail tag) (l rest)) (if (null? l) (cons '() tail) (iter (cons (car l) tail) (cdr l))))) ;; @deffn tl->list tl ;; Convert a tagged list structure to a list. This collects added attributes ;; and puts them right after the (leading) tag, resulting in something like ;; @example ;; ( (@ ) ) ;; @end example (define (tl->list tl) (let ((heda (car tl)) (head (let iter ((head '()) (attr '()) (tl-head (car tl))) (if (null? tl-head) (if (pair? attr) (cons (cons '@ attr) (reverse head)) (reverse head)) (if (and (pair? (car tl-head)) (eq? '@ (caar tl-head))) (iter head (cons (cdar tl-head) attr) (cdr tl-head)) (iter (cons (car tl-head) head) attr (cdr tl-head))))))) (let iter ((tail '()) (tl-tail (cdr tl))) (if (pair? tl-tail) (iter (cons (car tl-tail) tail) (cdr tl-tail)) (cons tl-tail (append head tail)))))) ;; @deffn tl-insert tl item ;; Insert item at front of tagged list (but after tag). (define (tl-insert tl item) (cons (cons item (car tl)) (cdr tl))) ;; @deffn tl-append tl item ... ;; Append item at end of tagged list. (define (tl-append tl . rest) (cons (car tl) (let iter ((tail (cdr tl)) (items rest)) (if (null? items) tail (iter (cons (car items) tail) (cdr items)))))) ;; @deffn tl-extend tl item-l ;; Extend with a list of items. (define (tl-extend tl item-l) (apply tl-append tl item-l)) ;; @deffn tl+attr tl key val) ;; Add an attribute to a tagged list. Return the tl. ;; @example ;; (tl+attr tl 'type "int") ;; @end example (define (tl+attr tl key val) (tl-insert tl (cons '@ (list key val)))) ;; @deffn tl-merge tl tl1 ;; Merge guts of phony-tl @code{tl1} into @code{tl}. (define (tl-merge tl tl1) (error "not implemented (yet)") ) ;; === sx ============================== ;; @section SXML Utility Procedures ;; @deffn sx-ref sx ix => item ;; Reference the @code{ix}-th element of the list, not counting the optional ;; attributes item. If the list is shorter than the index, return @code{#f}. ;; @example ;; (sx-ref '(abc "def") 1) => "def" ;; (sx-ref '(abc (@ (foo "1")) "def") 1) => "def" ;; @end example (define (sx-ref sx ix) (define (list-xref l x) (if (> (length l) x) (list-ref l x) #f)) (cond ((zero? ix) (car sx)) ((and (pair? (cadr sx)) (eqv? '@ (caadr sx))) (list-xref sx (1+ ix))) (else (list-xref sx ix)))) ;; @deffn sx-tag sx => tag ;; Return the tag for a tree (define (sx-tag sx) (if (pair? sx) (car sx) #f)) ;; @deffn sx-tail sx ix => (list) ;; Return the tail starting at the ix-th cdr, starting from 0. ;; For example, if sx has 3 items then (sx-tail sx 2) returns '(). ;; BUG: not working for (sx '(foo) 1) (define (sx-tail sx ix) (if (zero? ix) (error "zero index not supported")) (let ((sx (cdr sx)) (ix (1- ix))) (cond ((and (null? sx) (zero? ix)) sx) ((and (pair? (car sx)) (eqv? '@ (caar sx))) (list-tail sx (1+ ix))) (else (list-tail sx ix))))) ;; @deffn sx-has-attr? sx ;; p to determine if @arg{sx} has attributes. (define (sx-has-attr? sx) (and (pair? (cdr sx)) (pair? (cadr sx)) (eqv? '@ (caadr sx)))) ;; @deffn sx-attr sx => '(@ ...)|#f ;; @example ;; (sx-attr '(abc (@ (foo "1")) def) 1) => '(@ (foo "1")) ;; @end example (define (sx-attr sx) (if (and (pair? (cdr sx)) (pair? (cadr sx))) (if (eqv? '@ (caadr sx)) (cadr sx) #f) #f)) ;; @deffn sx-attr-ref sx key => val ;; Return an attribute value given the key, or @code{#f}. (define (sx-attr-ref sx key) (and=> (sx-attr sx) (lambda (attr) (and=> (assq-ref (cdr attr) key) car)))) ;; @deffn sx-set-attr! sx key val ;; Set attribute for sx. If no attributes exist, if key does not exist, ;; add it, if it does exist, replace it. (define (sx-set-attr! sx key val . rest) (if (sx-has-attr? sx) (let ((attr (cadr sx))) (set-cdr! attr (assoc-set! (cdr attr) key (list val)))) (set-cdr! sx (cons `(@ (,key ,val)) (cdr sx)))) sx) ;; @deffn sx-set-attr* sx key val [key val [key ... ]] ;; Set attribute for sx. If no attributes exist, if key does not exist, ;; add it, if it does exist, replace it. (define (sx-set-attr* sx . rest) (let iter ((attr (or (and=> (sx-attr sx) cdr) '())) (kvl rest)) (cond ((null? kvl) (cons* (sx-tag sx) (cons '@ (reverse attr)) (sx-tail sx 1))) (else (iter (cons (list (car kvl) (cadr kvl)) attr) (cddr kvl)))))) ;; @deffn sx-find tag sx => ((tag ...) (tag ...)) ;; Find the first matching element (in the first level). (define (sx-find tag sx) (find (lambda (node) (and (pair? node) (eqv? tag (car node)))) sx)) ;;; === pp ========================== ;; @section Pretty-Print and Other Utility Procedures ;; @deffn make-protect-expr op-prec op-assc => side op expr => #t|#f ;; Generate procedure @code{protect-expr} for pretty-printers, which takes ;; the form @code{(protect-expr? side op expr)} and where @code{side} ;; is @code{'lval} or @code{'rval}, @code{op} is the operator and @code{expr} ;; is the expression. The argument @arg{op-prec} is a list of equivalent ;; operators in order of decreasing precedence and @arg{op-assc} is an ;; a-list of precedence with keys @code{'left}, @code{'right} and ;; @code{nonassoc}. ;; @example ;; (protect-expr? 'lval '+ '(mul ...)) => TBD ;; @end example (define (make-protect-expr op-prec op-assc) (define (assc-lt? op) (memq op (assq-ref op-assc 'left))) (define (assc-rt? op) (memq op (assq-ref op-assc 'right))) ;; @deffn prec a b => '>|'<|'=|#f ;; Returns the prececence relation of @code{a}, @code{b} as ;; @code{<}, @code{>}, @code{=} or @code{#f} (no relation). (define (prec a b) (let iter ((ag #f) (bg #f) (opg op-prec)) ;; a-group, b-group (cond ((null? opg) #f) ; indeterminate ((memq a (car opg)) (if bg '< (if (memq b (car opg)) '= (iter #t bg (cdr opg))))) ((memq b (car opg)) (if ag '> (if (memq a (car opg)) '= (iter ag #t (cdr opg))))) (else (iter ag bg (cdr opg)))))) (lambda (side op expr) (let ((assc? (case side ((lt left) assc-rt?) ((rt right) assc-lt?))) (vtag (car expr))) (case (prec op vtag) ((>) #t) ((<) #f) ((=) (assc? op)) (else #f))))) ;; @deffn make-pp-formatter => fmtr ;; @example ;; (fmtr 'push) ;; push indent level ;; (fmtr 'pop) ;; pop indent level ;; (fmtr "fmt" arg1 arg2 ...) ;; @end example (define* (make-pp-formatter) (letrec ((maxcol 78) (maxind 36) (column 0) (ind-lev 0) (ind-len 0) (blanks " ") (ind-str (lambda () (substring blanks 0 ind-len))) (cnt-str (lambda () (substring blanks 0 (+ 4 ind-len)))) ;;(sf-nl (lambda () (newline) (set! column 0))) (push-il (lambda () (set! ind-lev (min maxind (1+ ind-lev))) (set! ind-len (* 2 ind-lev)))) (pop-il (lambda () (set! ind-lev (max 0 (1- ind-lev))) (set! ind-len (* 2 ind-lev)))) (sf (lambda (fmt . args) (let* ((str (apply simple-format #f fmt args)) (len (string-length str))) (cond ((zero? column) (display (ind-str)) (set! column (+ column ind-len))) ((> (+ column len) maxcol) (newline) (display (cnt-str)) (set! column (+ column ind-len 4)))) (display str) (when (and (positive? len) (eqv? #\newline (string-ref str (1- len)))) (set! column 0)))))) (lambda (arg0 . rest) (cond ;;((string? arg0) (if (> (string-length arg0) 0) (apply sf arg0 rest))) ((string? arg0) (apply sf arg0 rest)) ((eqv? 'push arg0) (push-il)) ((eqv? 'pop arg0) (pop-il)) ((eqv? 'nlin arg0) ;; newline if needed (cond ((positive? column) (newline) (set! column 0)))) (else (error "pp-formatter: bad args")) )))) ;; @deffn make-pp-formatter/ugly => fmtr ;; Makes a @code{fmtr} like @code{make-pp-formatter} but no indentation ;; and just adds strings on ... ;; This is specific to C/C++ because it will newline if #\# seen first. (define* (make-pp-formatter/ugly) (let* ((maxcol 78) (column 0) (sf (lambda (fmt . args) (let* ((str (apply simple-format #f fmt args)) (len (string-length str))) (if (and (positive? len) (char=? #\newline (string-ref str (1- len)))) (string-set! str (1- len) #\space)) (cond ((zero? len) #t) ; we reference str[0] next ((and (equal? len 1) (char=? #\newline (string-ref str 0))) #t) ((char=? #\# (string-ref str 0)) ; CPP-stmt: force newline (when (positive? column) (newline)) (display str) ; str always ends in \n (set! column ; if ends \n then col= 0 else len (if (char=? #\newline (string-ref str (1- len))) 0 len))) ((zero? column) (display str) (set! column len)) (else (when (> (+ column len) maxcol) (newline) (set! column 0)) (display str) (set! column (+ column len)))))))) (lambda (arg0 . rest) (cond ((string? arg0) (apply sf arg0 rest)) ((eqv? 'nlin arg0) ;; newline if needed (cond ((positive? column) (newline) (set! column 0)))) ((eqv? 'push arg0) #f) ((eqv? 'pop arg0) #f) (else (error "pp-formatter/ugly: bad args")))))) ;; @deffn move-if-changed src-file dst-file [sav-file] ;; Return @code{#t} if changed. (define (move-if-changed src-file dst-file . rest) (define (doit) (let ((sav-file (if (pair? rest) (car rest) #f))) (if (and sav-file (access? sav-file W_OK)) (system (simple-format #f "mv ~A ~A" dst-file sav-file))) (system (simple-format #f "mv ~A ~A" src-file dst-file)) #t)) (cond ;; src-file does not exist ((not (access? src-file R_OK)) #f) ;; dst-file does not exist, update anyhow ((not (access? dst-file F_OK)) (system (simple-format #f "mv ~A ~A" src-file dst-file)) #t) ;; both exist, but no changes ((zero? (system (simple-format #f "cmp ~A ~A >/dev/null" src-file dst-file))) (system (simple-format #f "rm ~A" src-file)) #f) ;; both exist, update ((access? dst-file W_OK) (doit)) (else (simple-format (current-error-port) "move-if-changed: no write access\n") #f))) ;; @end table ;;; --- last line ---