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#cs
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(module grammar mzscheme
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(require (lib "class.ss"))
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;; Constructs to create and access grammars, the internal
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;; representation of the input to the parser generator.
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(provide
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make-item
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make-term
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make-non-term
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make-prec
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make-prod
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;; Things that work on items
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start-item? item-prod item->string
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sym-at-dot move-dot-right item<? item-dot-pos
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;; Things that operate on grammar symbols
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gram-sym-symbol gram-sym-index term-prec gram-sym->string
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non-term? term? non-term<? term<?
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term-list->bit-vector term-index non-term-index
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;; Things that work on precs
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prec-num prec-assoc
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grammar%
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;; Things that work on productions
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prod-index prod-prec prod-rhs prod-lhs prod-action)
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;;---------------------- LR items --------------------------
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;; LR-item = (make-item production nat)
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;; The dot-pos field is the index of the element in the rhs
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;; of prod that the dot immediately preceeds.
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;; Thus 0 <= dot-pos <= (vector-length rhs).
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(define-struct item (prod dot-pos) (make-inspector))
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;; item<?: LR-item * LR-item -> bool
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;; Lexicographic comparison on two items.
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(define (item<? i1 i2)
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(let ((p1 (prod-index (item-prod i1)))
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(p2 (prod-index (item-prod i2))))
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(or (< p1 p2)
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(and (= p1 p2)
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(let ((d1 (item-dot-pos i1))
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(d2 (item-dot-pos i2)))
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(< d1 d2))))))
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;; start-item?: LR-item -> bool
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;; The start production always has index 0
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(define (start-item? i)
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(= 0 (non-term-index (prod-lhs (item-prod i)))))
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;; move-dot-right: LR-item -> LR-item | #f
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;; moves the dot to the right in the item, unless it is at its
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;; rightmost, then it returns false
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(define (move-dot-right i)
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(cond
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((= (item-dot-pos i) (vector-length (prod-rhs (item-prod i)))) #f)
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(else (make-item (item-prod i)
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(add1 (item-dot-pos i))))))
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;; sym-at-dot: LR-item -> gram-sym | #f
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;; returns the symbol after the dot in the item or #f if there is none
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(define (sym-at-dot i)
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(let ((dp (item-dot-pos i))
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(rhs (prod-rhs (item-prod i))))
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(cond
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((= dp (vector-length rhs)) #f)
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(else (vector-ref rhs dp)))))
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;; print-item: LR-item ->
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(define (item->string it)
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(let ((print-sym (lambda (i)
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(let ((gs (vector-ref (prod-rhs (item-prod it)) i)))
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(cond
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((term? gs) (format "~a " (term-sym gs)))
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(else (format "~a " (non-term-sym gs))))))))
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(string-append
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(format "~a -> " (non-term-sym (prod-lhs (item-prod it))))
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(let loop ((i 0))
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(cond
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((= i (vector-length (prod-rhs (item-prod it))))
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(if (= i (item-dot-pos it))
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". "
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""))
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((= i (item-dot-pos it))
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(string-append ". " (print-sym i) (loop (add1 i))))
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(else (string-append (print-sym i) (loop (add1 i)))))))))
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;; --------------------- Grammar Symbols --------------------------
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;; gram-sym = (make-term symbol int prec)
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;; | (make-non-term symbol int)
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;; Each term has a unique index 0 <= index < number of terms
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;; Each non-term has a unique index 0 <= index < number of non-terms
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(define-struct term (sym index prec) (make-inspector))
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(define-struct non-term (sym index) (make-inspector))
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(define (non-term<? nt1 nt2)
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(< (non-term-index nt1) (non-term-index nt2)))
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(define (term<? nt1 nt2)
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(< (term-index nt1) (term-index nt2)))
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(define (gram-sym-index gs)
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(cond
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((term? gs) (term-index gs))
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(else (non-term-index gs))))
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(define (gram-sym-symbol gs)
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(cond
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((term? gs) (term-sym gs))
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(else (non-term-sym gs))))
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(define (gram-sym->string gs)
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(symbol->string (gram-sym-symbol gs)))
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;; term-list->bit-vector: term list -> int
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;; Creates a number where the nth bit is 1 if the term with index n is in
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;; the list, and whose nth bit is 0 otherwise
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(define (term-list->bit-vector terms)
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(cond
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((null? terms) 0)
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(else
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(bitwise-ior (arithmetic-shift 1 (term-index (car terms))) (term-list->bit-vector (cdr terms))))))
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;; ------------------------- Precedences ---------------------------
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;; a precedence declaration. the sym should be 'left 'right or 'nonassoc
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;; prec = (make-prec int sym)
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;; | #f
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(define-struct prec (num assoc) (make-inspector))
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;; ------------------------- Grammar ------------------------------
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(define grammar%
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(class object%
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(super-instantiate ())
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;; prods: production list list
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;; where the nth element in the outermost list is the list of productions with the nth non-term as lhs
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(init prods)
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;; nullable-non-terms is indexed by the non-term-index and is true iff non-term is nullable
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(init-field terms non-terms nullable-non-terms end-terms)
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;; indexed by the index of the non-term - contains the list of productions for that non-term
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(define nt->prods (list->vector prods))
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;; list of all productions
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(define all-prods (apply append prods))
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(define num-prods (length all-prods))
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(define num-terms (length terms))
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(define num-non-terms (length non-terms))
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(define/public (get-num-terms) num-terms)
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(define/public (get-num-non-terms) num-non-terms)
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(define/public (get-prods-for-non-term nt)
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(vector-ref nt->prods (non-term-index nt)))
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(define/public (get-prods) all-prods)
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(define/public (get-init-prod)
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(car (vector-ref nt->prods 0)))
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(define/public (get-terms) terms)
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(define/public (get-non-terms) non-terms)
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(define/public (get-num-prods) num-prods)
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(define/public (get-end-terms) end-terms)
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(define/public (nullable-non-term? nt)
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(vector-ref nullable-non-terms (non-term-index nt)))
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(define/public (nullable-after-dot? item)
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(let* ((rhs (prod-rhs (item-prod item)))
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(prod-length (vector-length rhs)))
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(let loop ((i (item-dot-pos item)))
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(cond
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((< i prod-length)
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(if (and (non-term? (vector-ref rhs i)) (nullable-non-term? (vector-ref rhs i)))
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(loop (add1 i))
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#f))
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((= i prod-length) #t)))))
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(define/public (nullable-non-term-thunk)
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(lambda (nt)
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(nullable-non-term? nt)))
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(define/public (nullable-after-dot?-thunk)
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(lambda (item)
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(nullable-after-dot? item)))))
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;; ------------------------ Productions ---------------------------
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;; production = (make-prod non-term (gram-sym vector) int prec syntax-object)
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;; Each production has a unique index 0 <= index <= number of productions
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(define-struct prod (lhs rhs index prec action) (make-inspector))
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)
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