1001 lines
34 KiB
Racket
1001 lines
34 KiB
Racket
#lang racket/base
|
||
|
||
(require racket/set)
|
||
(require racket/match)
|
||
(require (only-in racket/port call-with-output-string))
|
||
(require (only-in racket/class object?))
|
||
|
||
(require rackunit)
|
||
|
||
(provide ?
|
||
wildcard?
|
||
?!
|
||
capture?
|
||
pattern->matcher
|
||
matcher? ;; expensive; see implementation
|
||
matcher-empty
|
||
matcher-empty?
|
||
matcher-union
|
||
matcher-intersect
|
||
matcher-erase-path
|
||
matcher-match-value
|
||
matcher-match-matcher
|
||
matcher-relabel
|
||
compile-projection
|
||
matcher-project
|
||
matcher-key-set
|
||
pretty-print-matcher)
|
||
|
||
(define-syntax-rule (define-singleton-struct singleton-name struct-name print-representation)
|
||
(begin
|
||
(struct struct-name ()
|
||
#:transparent
|
||
#:property prop:custom-write
|
||
(lambda (v port mode) (display print-representation port)))
|
||
(define singleton-name (struct-name))))
|
||
|
||
;; Unicode angle brackets: 〈, 〉
|
||
|
||
;; A Sigma is, roughly, a token in a value being matched. It is one of:
|
||
;; - a struct-type, signifying the start of a struct.
|
||
;; - start-of-pair, signifying the start of a pair.
|
||
;; - start-of-vector, signifying the start of a vector.
|
||
;; - end-of-sequence, signifying the notional close-paren at the end of a compound.
|
||
;; - any other value, representing itself.
|
||
(define-singleton-struct SOP start-of-pair "<pair")
|
||
(define-singleton-struct SOV start-of-vector "<vector")
|
||
(define-singleton-struct EOS end-of-sequence ">")
|
||
|
||
;; A Pattern is an atom, the special wildcard value, or a Racket
|
||
;; compound (struct, pair, or vector) containing Patterns.
|
||
(define-singleton-struct ? wildcard "★") ;; alternative printing: ¿
|
||
|
||
;; When projecting a matcher, the capturing wildcard can be used.
|
||
(define-singleton-struct ?! capture "‽")
|
||
|
||
;; A Matcher is either
|
||
;; - #f, indicating no further matches possible
|
||
;; - a (success Any), representing a successful match (if the end of the input has been reached)
|
||
;; - a Hashtable mapping (Sigma or wildcard) to Matcher
|
||
;; - a (wildcard-sequence Matcher)
|
||
;; If, in a hashtable matcher, a wild key is present, it is intended
|
||
;; to catch all and ONLY those keys not otherwise present in the
|
||
;; table.
|
||
(struct success (value) #:transparent)
|
||
(struct wildcard-sequence (matcher) #:transparent)
|
||
|
||
(define (matcher? x)
|
||
(or (eq? x #f)
|
||
(success? x)
|
||
(wildcard-sequence? x)
|
||
(and (hash? x)
|
||
(for/and ([v (in-hash-values x)])
|
||
(matcher? v)))))
|
||
|
||
(define (matcher-empty) #f)
|
||
(define (matcher-empty? r) (not r))
|
||
|
||
(define (rseq e r) (if (matcher-empty? r) r (hash e r)))
|
||
(define (rwild r) (rseq ? r))
|
||
(define (rwildseq r) (if (matcher-empty? r) r (wildcard-sequence r)))
|
||
|
||
(define (rseq* x . xs)
|
||
(let walk ((xs (cons x xs)))
|
||
(match xs
|
||
[(list r) r]
|
||
[(cons e xs1) (rseq e (walk xs1))])))
|
||
|
||
;; Any -> Boolean
|
||
;; Racket objects are structures, so we reject them explicitly for
|
||
;; now, leaving them opaque to unification.
|
||
(define (non-object-struct? x)
|
||
(and (struct? x)
|
||
(not (object? x))))
|
||
|
||
(define (vector-foldr kons knil v)
|
||
(for/fold [(acc knil)] [(elem (in-vector v (- (vector-length v) 1) -1 -1))]
|
||
(kons elem acc)))
|
||
|
||
(define (pattern->matcher v p)
|
||
(let walk ((p p) (acc (rseq EOS (success v))))
|
||
(match p
|
||
[(== ?) (rwild acc)]
|
||
[(cons p1 p2) (rseq SOP (walk p1 (walk p2 (rseq EOS acc))))]
|
||
[(? vector? v) (rseq SOV (vector-foldr walk (rseq EOS acc) v))]
|
||
[(? non-object-struct?)
|
||
(define-values (t skipped?) (struct-info p))
|
||
(when skipped? (error 'pattern->matcher "Cannot reflect on struct instance ~v" p))
|
||
(define fs (cdr (vector->list (struct->vector p))))
|
||
(rseq t (foldr walk (rseq EOS acc) fs))]
|
||
;; TODO: consider options for treating hash tables as compounds rather than (useless) atoms
|
||
[(? hash?) (error 'pattern->matcher "Cannot match on hash tables at present")]
|
||
[other (rseq other acc)])))
|
||
|
||
(define (rlookup r key)
|
||
(hash-ref r key (lambda () #f)))
|
||
|
||
(define (rupdate r key k)
|
||
(if (matcher-empty? k)
|
||
(and r
|
||
(let ((r1 (hash-remove r key)))
|
||
(if (zero? (hash-count r1))
|
||
#f
|
||
r1)))
|
||
(hash-set (or r (hash)) key k)))
|
||
|
||
(define (key-open? k)
|
||
(or (eq? k SOP)
|
||
(eq? k SOV)
|
||
(struct-type? k)))
|
||
|
||
(define (key-close? k)
|
||
(eq? k EOS))
|
||
|
||
(define (key-normal? k)
|
||
(not (or (key-open? k)
|
||
(key-close? k))))
|
||
|
||
(define (expand-wildseq r)
|
||
(matcher-union (rwild (rwildseq r))
|
||
(rseq EOS r)))
|
||
|
||
(define (matcher-union re1 re2 [combine-successes set-union])
|
||
(define (merge o1 o2)
|
||
(match* (o1 o2)
|
||
[(#f #f) #f]
|
||
[(#f r) r]
|
||
[(r #f) r]
|
||
[(r1 r2) (walk r1 r2)]))
|
||
(define (walk re1 re2)
|
||
(match* (re1 re2)
|
||
[((wildcard-sequence r1) (wildcard-sequence r2)) (rwildseq (walk r1 r2))]
|
||
[((wildcard-sequence r1) r2) (walk (expand-wildseq r1) r2)]
|
||
[(r1 (wildcard-sequence r2)) (walk (expand-wildseq r2) r1)]
|
||
[((success v1) (success v2)) (success (combine-successes v1 v2))]
|
||
[((? hash? h1) (? hash? h2))
|
||
(define w (merge (rlookup h1 ?) (rlookup h2 ?)))
|
||
(cond
|
||
[w (merge/wildcard w h1 h2)]
|
||
[(< (hash-count h2) (hash-count h1)) (merge/no-wildcard h2 h1)]
|
||
[else (merge/no-wildcard h1 h2)])]))
|
||
(define (merge/wildcard w h1 h2)
|
||
(for/fold [(acc (rwild w))]
|
||
[(key (set-remove (set-union (hash-keys h1) (hash-keys h2)) ?))]
|
||
(define k (merge (rlookup h1 key) (rlookup h2 key)))
|
||
(rupdate acc
|
||
key
|
||
(cond
|
||
[(key-open? key) (merge (rwildseq w) k)]
|
||
[(key-close? key) (if (wildcard-sequence? w)
|
||
(merge (wildcard-sequence-matcher w) k)
|
||
k)]
|
||
[else (merge w k)]))))
|
||
(define (merge/no-wildcard h1 h2)
|
||
(for/fold [(acc h2)] [((key k1) (in-hash h1))]
|
||
(define k (merge k1 (rlookup h2 key)))
|
||
(rupdate acc key k)))
|
||
(match* (re1 re2)
|
||
[(#f r) r]
|
||
[(r #f) r]
|
||
[(r1 r2) (walk r1 r2)]))
|
||
|
||
(define (smaller-hash h1 h2)
|
||
(if (< (hash-count h1) (hash-count h2))
|
||
h1
|
||
h2))
|
||
|
||
(define (matcher-intersect re1 re2 [combine-successes set-union])
|
||
(let ()
|
||
;; INVARIANT: re1 is a part of the original re1, and likewise for
|
||
;; re2. This is so that the first arg to combine-success-values
|
||
;; always comes from re1, and the second from re2.
|
||
(define (walk re1 re2)
|
||
(match* (re1 re2)
|
||
[((wildcard-sequence r1) (wildcard-sequence r2)) (rwildseq (walk r1 r2))]
|
||
[((wildcard-sequence r1) r2) (walk (expand-wildseq r1) r2)]
|
||
[(r1 (wildcard-sequence r2)) (walk r1 (expand-wildseq r2))]
|
||
[((success v1) (success v2)) (success (combine-successes v1 v2))]
|
||
[((? hash? h1) (? hash? h2))
|
||
(define w1 (rlookup h1 ?))
|
||
(define w2 (rlookup h2 ?))
|
||
(define w (and w1 w2 (walk w1 w2)))
|
||
(define (examine-key acc key)
|
||
(rupdate acc
|
||
key
|
||
(match* ((rlookup h1 key) (rlookup h2 key))
|
||
[(#f #f) #f]
|
||
[(#f k2) (walk-wild walk w1 key k2)]
|
||
[(k1 #f) (walk-wild (lambda (a2 a1) (walk a1 a2)) w2 key k1)]
|
||
[(k1 k2) (walk k1 k2)])))
|
||
;; If, say, w1 is #f, then we don't need to examine
|
||
;; every key in h2. So there are four cases:
|
||
;; - both false -> examine the intersection of the key sets
|
||
;; (done by enumerating keys in the smaller hash)
|
||
;; - one nonfalse -> examine only the keys in the other
|
||
;; - both nonfalse -> examine the union of the key sets
|
||
;; This is important for avoiding examination of the whole
|
||
;; structure when wildcards aren't being used.
|
||
(match* (w1 w2)
|
||
[(#f #f) (for/fold [(acc #f)] [(key (in-hash-keys (smaller-hash h1 h2)))]
|
||
(examine-key acc key))]
|
||
[(#f _) (for/fold [(acc #f)] [(key (in-hash-keys h1))] (examine-key acc key))]
|
||
[(_ #f) (for/fold [(acc #f)] [(key (in-hash-keys h2))] (examine-key acc key))]
|
||
[(_ _) (for/fold [(acc (rwild w))] [(key (set-remove (set-union (hash-keys h1)
|
||
(hash-keys h2))
|
||
?))]
|
||
(examine-key acc key))])]))
|
||
(define (walk-wild walk-fn w key k)
|
||
(and w (cond
|
||
[(key-open? key) (walk-fn (rwildseq w) k)]
|
||
[(key-close? key) (if (wildcard-sequence? w)
|
||
(walk-fn (wildcard-sequence-matcher w) k)
|
||
#f)]
|
||
[else (walk-fn w k)])))
|
||
(match* (re1 re2)
|
||
[(#f r) #f]
|
||
[(r #f) #f]
|
||
[(r1 r2) (walk r1 r2)])))
|
||
|
||
(define (set-subtract/false s1 s2)
|
||
(define r (set-subtract s1 s2))
|
||
(if (set-empty? r) #f r))
|
||
|
||
;; Removes re2's mappings from re1. Assumes re2 has previously been union'd into re1.
|
||
;; The combine-successes function should return #f to signal "no remaining success values".
|
||
(define (matcher-erase-path re1 re2 [combine-successes set-subtract/false])
|
||
(define (cofinite-pattern)
|
||
(error 'matcher-erase-path "Cofinite pattern required"))
|
||
(define (walk path aggregate)
|
||
(match* (path aggregate)
|
||
[((wildcard-sequence r1) (wildcard-sequence r2)) (rwildseq (walk r1 r2))]
|
||
[((wildcard-sequence r1) r2) (cofinite-pattern)]
|
||
[(r1 (wildcard-sequence r2)) (walk r1 (expand-wildseq r2))]
|
||
[((success v1) (success v2))
|
||
(define new-v (combine-successes v1 v2))
|
||
(and new-v (success new-v))]
|
||
[((? hash? h1) (? hash? h2))
|
||
(define w1 (rlookup h1 ?))
|
||
(define w2 (rlookup h2 ?))
|
||
(define w (match* (w1 w2)
|
||
[(#f #f) #f]
|
||
[(r #f) r]
|
||
[(#f r) (cofinite-pattern)]
|
||
[(r1 r2) (walk r1 r2)]))
|
||
(define (examine-key acc key)
|
||
(rupdate acc
|
||
key
|
||
(match* ((rlookup h1 key) (rlookup h2 key))
|
||
[(#f #f) #f]
|
||
[(#f k2) (cofinite-pattern)]
|
||
[(k1 #f) (walk-wild key k1 w2)]
|
||
[(k1 k2) (walk k1 k2)])))
|
||
;; TODO: need to ensure "minimal" remainder in cases where
|
||
;; after an erasure, a particular key's continuation is the
|
||
;; same as the wildcard's continuation. See tests/examples
|
||
;; below.
|
||
;;
|
||
;; --
|
||
;; We only need to examine all keys of h2 if w1 nonfalse.
|
||
(if w2
|
||
(for/fold [(acc (rwild w))] [(key (set-remove (set-union (hash-keys h1)
|
||
(hash-keys h2))
|
||
?))]
|
||
(examine-key acc key))
|
||
(for/fold [(acc h1)] [(key (in-hash-keys h2))]
|
||
(examine-key acc key)))]))
|
||
(define (walk-wild key k w)
|
||
(if w
|
||
(cond
|
||
[(key-open? key) (walk k (rwildseq w))]
|
||
[(key-close? key) (if (wildcard-sequence? w)
|
||
(walk k (wildcard-sequence-matcher w))
|
||
k)]
|
||
[else (walk k w)])
|
||
k))
|
||
(match* (re1 re2)
|
||
[(r #f) r]
|
||
[(#f r) (cofinite-pattern)]
|
||
[(r1 r2) (walk r1 r2)]))
|
||
|
||
(define (matcher-match-value r v [result-nil (set)])
|
||
(if (matcher-empty? r)
|
||
result-nil
|
||
(let walk ((vs (list v)) (stack '(())) (r r))
|
||
(define (walk-wild vs stack)
|
||
(match (rlookup r ?)
|
||
[#f result-nil]
|
||
[k (walk vs stack k)]))
|
||
(match r
|
||
[(wildcard-sequence k)
|
||
(match stack
|
||
['() result-nil]
|
||
[(cons rest stack1) (walk rest stack1 k)])]
|
||
[(success result)
|
||
(if (and (null? vs)
|
||
(null? stack))
|
||
result
|
||
result-nil)]
|
||
[(? hash?)
|
||
(match vs
|
||
['()
|
||
(match stack
|
||
['() result-nil]
|
||
[(cons rest stack1)
|
||
(match (rlookup r EOS)
|
||
[#f result-nil]
|
||
[k (walk rest stack1 k)])])]
|
||
[(cons (== ?) rest)
|
||
(error 'matcher-match-value "Cannot match wildcard as a value")]
|
||
[(cons (cons v1 v2) rest)
|
||
(match (rlookup r SOP)
|
||
[#f (walk-wild rest stack)]
|
||
[k (walk (list v1 v2) (cons rest stack) k)])]
|
||
[(cons (vector vv ...) rest)
|
||
(match (rlookup r SOV)
|
||
[#f (walk-wild rest stack)]
|
||
[k (walk vv (cons rest stack) k)])]
|
||
[(cons (? non-object-struct? s) rest)
|
||
(define-values (t skipped?) (struct-info s))
|
||
(when skipped? (error 'matcher-match-value "Cannot reflect on struct instance ~v" s))
|
||
(define fs (cdr (vector->list (struct->vector s))))
|
||
(match (rlookup r t)
|
||
[#f (walk-wild rest stack)]
|
||
[k (walk fs (cons rest stack) k)])]
|
||
[(cons v rest)
|
||
(match (rlookup r v)
|
||
[#f (walk-wild rest stack)]
|
||
[k (walk rest stack k)])])]))))
|
||
|
||
(define (matcher-match-matcher re1 re2 [combine-successes set-union] [result-nil (set)])
|
||
(let ()
|
||
(define (walk re1 re2 acc1 acc2)
|
||
(match* (re1 re2)
|
||
[((wildcard-sequence r1) (wildcard-sequence r2)) (walk r1 r2 acc1 acc2)]
|
||
[((wildcard-sequence r1) r2) (walk (expand-wildseq r1) r2 acc1 acc2)]
|
||
[(r1 (wildcard-sequence r2)) (walk r1 (expand-wildseq r2) acc1 acc2)]
|
||
[((success v1) (success v2)) (values (combine-successes acc1 v1)
|
||
(combine-successes acc2 v2))]
|
||
[((? hash? h1) (? hash? h2))
|
||
(define w1 (rlookup h1 ?))
|
||
(define w2 (rlookup h2 ?))
|
||
(define-values (r1 r2) (if (and w1 w2)
|
||
(walk w1 w2 acc1 acc2)
|
||
(values acc1 acc2)))
|
||
(define (examine-key r1 r2 key)
|
||
(match* ((rlookup h1 key) (rlookup h2 key))
|
||
[(#f #f) (values r1 r2)]
|
||
[(#f k2)
|
||
(define-values (rr1 rr2) (walk-wild w1 key k2 r1 r2))
|
||
(values rr1 rr2)]
|
||
[(k1 #f)
|
||
(define-values (rr2 rr1) (walk-wild w2 key k1 r2 r1))
|
||
(values rr1 rr2)]
|
||
[(k1 k2) (walk k1 k2 r1 r2)]))
|
||
;; We optimize as described in matcher-intersect.
|
||
(match* (w1 w2)
|
||
[(#f #f) (for/fold [(r1 r1) (r2 r2)] [(key (in-hash-keys (smaller-hash h1 h2)))]
|
||
(examine-key r1 r2 key))]
|
||
[(#f _) (for/fold [(r1 r1) (r2 r2)] [(key (in-hash-keys h1))] (examine-key r1 r2 key))]
|
||
[(_ #f) (for/fold [(r1 r1) (r2 r2)] [(key (in-hash-keys h2))] (examine-key r1 r2 key))]
|
||
[(_ _) (for/fold [(r1 r1) (r2 r2)] [(key (set-remove (set-union (hash-keys h1)
|
||
(hash-keys h2))
|
||
?))]
|
||
(examine-key r1 r2 key))])]))
|
||
(define (walk-wild w key k acc1 acc2)
|
||
(if w
|
||
(cond
|
||
[(key-open? key) (walk (rwildseq w) k acc1 acc2)]
|
||
[(key-close? key) (if (wildcard-sequence? w)
|
||
(walk (wildcard-sequence-matcher w) k acc1 acc2)
|
||
(values acc1 acc2))]
|
||
[else (walk w k acc1 acc2)])
|
||
(values acc1 acc2)))
|
||
(match* (re1 re2)
|
||
[(#f r) (values result-nil result-nil)]
|
||
[(r #f) (values result-nil result-nil)]
|
||
[(r1 r2) (walk r1 r2 result-nil result-nil)])))
|
||
|
||
(define (matcher-relabel m f)
|
||
(let walk ((m m))
|
||
(match m
|
||
[#f #f]
|
||
[(success v) (success (f v))]
|
||
[(wildcard-sequence m1) (wildcard-sequence (walk m1))]
|
||
[(? hash?) (for/hash [((k v) (in-hash m))] (values k (walk v)))])))
|
||
|
||
(define (compile-projection p)
|
||
;; Extremely similar to pattern->matcher. Besides use of conses
|
||
;; rather than chained hashtables, the only interesting difference
|
||
;; is how ?! is treated.
|
||
(let walk ((p p) (acc (cons EOS '())))
|
||
(match p
|
||
[(== ?!) (cons ?! acc)]
|
||
[(== ?) (cons ? acc)]
|
||
[(cons p1 p2) (cons SOP (walk p1 (walk p2 (cons EOS acc))))]
|
||
[(? vector? v) (cons SOV (vector-foldr walk (cons EOS acc) v))]
|
||
[(? non-object-struct?)
|
||
(define-values (t skipped?) (struct-info p))
|
||
(when skipped? (error 'pattern->matcher "Cannot reflect on struct instance ~v" p))
|
||
(define fs (cdr (vector->list (struct->vector p))))
|
||
(cons t (foldr walk (cons EOS acc) fs))]
|
||
;; TODO: consider options for treating hash tables as compounds rather than (useless) atoms
|
||
[(? hash?) (error 'pattern->matcher "Cannot match on hash tables at present")]
|
||
[other (cons other acc)])))
|
||
|
||
;; Matcher × CompiledProjection [× (Value -> (Option Value))] → Matcher
|
||
;; The result matches a vector of length equal to the number of captures.
|
||
;; The project-success function should return #f to signal "no success values".
|
||
(define matcher-project
|
||
;; TODO: skip-nested, capture-nested, and the ? and ?! cases in
|
||
;; walk-out all share a suspicious amount of code. Refactor it away.
|
||
(let ()
|
||
(define (skip-nested m k)
|
||
(match m
|
||
[(wildcard-sequence mk) (k mk)]
|
||
[(? hash?)
|
||
(for/fold [(acc (skip-nested (rlookup m ?) k))] [((key mk) (in-hash m))]
|
||
(if (eq? key ?)
|
||
acc
|
||
(matcher-union acc (cond
|
||
[(key-open? key) (skip-nested mk (lambda (mk) (skip-nested mk k)))]
|
||
[(key-close? key) (k mk)]
|
||
[else (skip-nested mk k)]))))]
|
||
[_ (matcher-empty)]))
|
||
|
||
(define (capture-nested m k)
|
||
(match m
|
||
[(wildcard-sequence mk) (rwildseq (k mk))]
|
||
[(? hash?)
|
||
(for/fold [(acc (rwild (capture-nested (rlookup m ?) k)))] [((key mk) (in-hash m))]
|
||
(if (eq? key ?)
|
||
acc
|
||
(cond
|
||
[(key-open? key)
|
||
(rupdate acc key (capture-nested mk (lambda (mk) (capture-nested mk k))))]
|
||
[(key-close? key) (rupdate acc key (k mk))]
|
||
[else (rupdate acc key (capture-nested mk k))])))]
|
||
[_ (matcher-empty)]))
|
||
|
||
(lambda (m spec [project-success values])
|
||
(define (walk-out m spec)
|
||
(match spec
|
||
['()
|
||
(match m
|
||
[(success v)
|
||
(define new-v (project-success v))
|
||
(if new-v
|
||
(rseq EOS (rseq EOS (success new-v)))
|
||
(matcher-empty))]
|
||
[_ (matcher-empty)])]
|
||
|
||
[(cons (== ?) k)
|
||
(match m
|
||
[(wildcard-sequence _) (walk-out m k)]
|
||
[(? hash?)
|
||
(for/fold [(acc (walk-out (rlookup m ?) k))] [((key mk) (in-hash m))]
|
||
(if (eq? key ?)
|
||
acc
|
||
(matcher-union acc (cond
|
||
[(key-open? key) (skip-nested mk (lambda (mk) (walk-out mk k)))]
|
||
[(key-close? key) #f]
|
||
[else (walk-out mk k)]))))]
|
||
[_ (matcher-empty)])]
|
||
|
||
[(cons (== ?!) k)
|
||
(match m
|
||
[(wildcard-sequence _) (rwild (walk-out m k))]
|
||
[(? hash?)
|
||
(for/fold [(acc (rwild (walk-out (rlookup m ?) k)))] [((key mk) (in-hash m))]
|
||
(if (eq? key ?)
|
||
acc
|
||
(cond
|
||
[(key-open? key)
|
||
(rupdate acc key (capture-nested mk (lambda (mk) (walk-out mk k))))]
|
||
[(key-close? key) acc]
|
||
[else (rupdate acc key (walk-out mk k))])))]
|
||
[_ (matcher-empty)])]
|
||
|
||
[(cons sigma k)
|
||
(match m
|
||
[(wildcard-sequence mk)
|
||
(if (key-close? sigma)
|
||
(walk-out mk k)
|
||
(walk-out m k))]
|
||
[(? hash?)
|
||
(matcher-union (walk-out (rlookup m sigma) k)
|
||
(walk-out (rlookup m ?) k))]
|
||
[_ (matcher-empty)])]))
|
||
(rseq SOV (walk-out m spec)))))
|
||
|
||
;; Matcher → (Option (Setof Value))
|
||
;; Multiplies out unions. Returns #f if any dimension of m is infinite.
|
||
(define matcher-key-set
|
||
(let ()
|
||
;; Matcher (Value Matcher -> (Setof Value)) -> (Option (Setof Value))
|
||
;; Calls k with each possible atomic value at this matcher
|
||
;; position, and accumulates the results.
|
||
(define (walk m k)
|
||
(match m
|
||
[(wildcard-sequence _) #f]
|
||
[(? hash?)
|
||
(and (not (hash-has-key? m ?))
|
||
(for/fold [(acc (set))] [((key mk) (in-hash m))]
|
||
(maybe-union
|
||
acc
|
||
(cond
|
||
[(key-open? key)
|
||
(walk-seq mk (lambda (vss vsk)
|
||
(for/fold [(acc (set))] [(vs (in-set vss))]
|
||
(maybe-union acc
|
||
(k (transform-seqs vs key) vsk)))))]
|
||
[(key-close? key)
|
||
(error 'matcher-key-set "Internal error: unexpected key-close")]
|
||
[else
|
||
(k key mk)]))))]
|
||
[_ (set)]))
|
||
|
||
;; Matcher (Value Matcher -> (Setof (Listof Value))) -> (Option (Setof (Listof Value)))
|
||
;; Calls k with each possible sequence of atomic values at this
|
||
;; matcher position, and accumulates the results.
|
||
(define (walk-seq m k)
|
||
(match m
|
||
[(wildcard-sequence _) #f]
|
||
[(? hash?)
|
||
(and (not (hash-has-key? m ?))
|
||
(for/fold [(acc (set))] [((key mk) (in-hash m))]
|
||
(maybe-union acc (cond
|
||
[(key-close? key) (k (set '()) mk)]
|
||
[else (walk (rseq key mk)
|
||
(lambda (v vk)
|
||
(walk-seq vk (lambda (vss vsk)
|
||
(k (for/set [(vs (in-set vss))]
|
||
(cons v vs))
|
||
vsk)))))]))))]
|
||
[_ (k (set) #f)])) ;; TODO: ??
|
||
|
||
;; (Listof Value) Sigma -> Value
|
||
(define (transform-seqs vs opener)
|
||
(cond
|
||
[(eq? opener SOP) (apply cons vs)]
|
||
[(eq? opener SOV) (list->vector vs)]
|
||
[(struct-type? opener) (apply (struct-type-make-constructor opener) vs)]))
|
||
|
||
;; (Option (Setof A)) (Option (Setof A)) -> (Option (Setof A))
|
||
(define (maybe-union s1 s2) (and s1 s2 (set-union s1 s2)))
|
||
|
||
(lambda (m)
|
||
(walk m (lambda (v k) (set v))))))
|
||
|
||
(define (pretty-print-matcher m [port (current-output-port)] #:indent [initial-indent 0])
|
||
(define (d x) (display x port))
|
||
(define (walk i m)
|
||
(match m
|
||
[#f
|
||
(d "::: no further matches possible")]
|
||
[(wildcard-sequence k)
|
||
(d "...>")
|
||
(walk (+ i 4) k)]
|
||
[(success vs)
|
||
(d "{")
|
||
(d vs)
|
||
(d "}")]
|
||
[(? hash? h)
|
||
(if (zero? (hash-count h))
|
||
(d " ::: empty hash!")
|
||
(for/fold [(need-sep? #f)] [((key k) (in-hash h))]
|
||
(when need-sep?
|
||
(newline port)
|
||
(d (make-string i #\space)))
|
||
(d " ")
|
||
(define keystr (call-with-output-string
|
||
(lambda (p)
|
||
(if (struct-type? key)
|
||
(let-values (((name x2 x3 x4 x5 x6 x7 x8)
|
||
(struct-type-info key)))
|
||
(display "<s:" p)
|
||
(display name p))
|
||
(display key p)))))
|
||
(d keystr)
|
||
(walk (+ i 1 (string-length keystr)) k)
|
||
#t))]))
|
||
(walk initial-indent m)
|
||
(newline port)
|
||
m)
|
||
|
||
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||
|
||
(module+ test
|
||
(define SA (set 'A))
|
||
(define SB (set 'B))
|
||
(define SC (set 'C))
|
||
(define SD (set 'D))
|
||
(define Sfoo (set 'foo))
|
||
(define S+ (set '+))
|
||
(define SX (set 'X))
|
||
(define (E v) (hash EOS (success v)))
|
||
(check-equal? (pattern->matcher SA 123) (hash 123 (E SA)))
|
||
(check-equal? (pattern->matcher SA (cons 1 2)) (hash SOP (hash 1 (hash 2 (hash EOS (E SA))))))
|
||
(check-equal? (pattern->matcher SA (cons ? 2)) (hash SOP (hash ? (hash 2 (hash EOS (E SA))))))
|
||
(check-equal? (pattern->matcher SA SOP) (hash struct:start-of-pair (hash EOS (E SA))))
|
||
(check-equal? (pattern->matcher SA ?) (hash ? (E SA)))
|
||
)
|
||
|
||
(module+ test
|
||
(define (check-matches matcher . tests)
|
||
(let walk ((tests tests))
|
||
(match tests
|
||
['() (void)]
|
||
[(list* message expectedstr rest)
|
||
(define actualset (matcher-match-value matcher message))
|
||
(printf "~v ==> ~v\n" message actualset)
|
||
(check-equal? actualset
|
||
(apply set (map (lambda (c) (string->symbol (string c)))
|
||
(string->list expectedstr))))
|
||
(walk rest)])))
|
||
|
||
(check-matches
|
||
#f
|
||
(list 'z 'x) ""
|
||
'foo ""
|
||
(list (list 'z (list 'z))) "")
|
||
|
||
(define (pretty-print-matcher* m)
|
||
(newline)
|
||
(pretty-print-matcher m)
|
||
(flush-output)
|
||
m)
|
||
|
||
(void (pretty-print-matcher*
|
||
(matcher-union (pattern->matcher SA (list (list ?) 'x))
|
||
(pattern->matcher SB (list (list ?) 'y)))))
|
||
|
||
(void (pretty-print-matcher*
|
||
(matcher-union (pattern->matcher SA (list (list 'a 'b) 'x))
|
||
(pattern->matcher SB (list (list 'c 'd) 'y)))))
|
||
|
||
(void (pretty-print-matcher*
|
||
(matcher-union (pattern->matcher SA (list (list 'a 'b) 'x))
|
||
(pattern->matcher SB (list (list ? ?) 'y)))))
|
||
|
||
(check-matches
|
||
(pretty-print-matcher*
|
||
(matcher-union (pattern->matcher SA (list (list 'a 'b) 'x))
|
||
(pattern->matcher SB (list (list ? ?) 'x))))
|
||
(list 'z 'x) ""
|
||
(list (list 'z 'z) 'x) "B"
|
||
(list (list 'z (list 'z)) 'x) "B"
|
||
(list (list 'a 'b) 'x) "AB")
|
||
|
||
(check-matches
|
||
(pretty-print-matcher*
|
||
(matcher-union (pattern->matcher SA (list (list 'a 'b) 'x))
|
||
(pattern->matcher SB (list (list ?) 'y))))
|
||
(list 'z 'y) ""
|
||
(list (list 'z 'z) 'y) ""
|
||
(list (list 'z 'z) 'x) ""
|
||
(list (list 'a 'b) 'x) "A")
|
||
|
||
(check-matches
|
||
(pretty-print-matcher*
|
||
(matcher-union (pattern->matcher SA (list (list 'a 'b) 'x))
|
||
(pattern->matcher SB (list ? 'y))))
|
||
(list 'z 'y) "B"
|
||
(list (list 'z 'z) 'y) "B"
|
||
(list (list 'a 'b) 'x) "A")
|
||
|
||
(check-matches
|
||
(pretty-print-matcher*
|
||
(matcher-union (pattern->matcher SA (list 'a 'b))
|
||
(pattern->matcher SB (list 'c 'd))))
|
||
(list 'a 'b) "A"
|
||
(list 'c 'd) "B"
|
||
(list 'a 'd) ""
|
||
(list 'c 'b) "")
|
||
|
||
(void (pretty-print-matcher* (matcher-union (pattern->matcher SA (list (list 'a 'b) 'x))
|
||
;; Note: this is a largely nonsense matcher,
|
||
;; since it expects no input at all
|
||
(rseq EOS (success (set 'B))))))
|
||
|
||
(check-matches
|
||
(pretty-print-matcher*
|
||
(matcher-union (pattern->matcher SA (list (list 'a 'b) 'x))
|
||
(pattern->matcher SB ?)))
|
||
(list (list 'a 'b) 'x) "AB"
|
||
'p "B"
|
||
(list 'p) "B")
|
||
|
||
(check-matches
|
||
(pretty-print-matcher*
|
||
(matcher-union (pattern->matcher SA (list 'a ?))
|
||
(pattern->matcher SB (list 'a (list 'b)))))
|
||
|
||
(list 'a (list 'b)) "AB"
|
||
(list 'a (list 'b 'b)) "A"
|
||
(list 'a (list 'c 'c)) "A"
|
||
(list 'a (list 'c)) "A"
|
||
(list 'a (list (list))) "A"
|
||
(list 'a (list)) "A"
|
||
(list 'a 'x) "A")
|
||
|
||
(check-matches
|
||
(pretty-print-matcher*
|
||
(matcher-union (matcher-union (pattern->matcher SA (list 'a ?))
|
||
(pattern->matcher SA (list 'q ?)))
|
||
(pattern->matcher SB (list 'a (list 'b)))))
|
||
(list 'a (list 'b)) "AB"
|
||
(list 'q (list 'b)) "A"
|
||
(list 'a 'x) "A"
|
||
(list 'q 'x) "A"
|
||
(list 'a (list)) "A"
|
||
(list 'q (list)) "A"
|
||
(list 'z (list)) "")
|
||
|
||
(define (bigdemo)
|
||
(define ps
|
||
(for/list ((c (in-string "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ")))
|
||
(define csym (string->symbol (string c)))
|
||
(pattern->matcher (set csym) (list csym ?))))
|
||
(matcher-union (foldr matcher-union (matcher-empty) ps)
|
||
(pattern->matcher S+ (list 'Z (list ? '- ?)))))
|
||
|
||
(void (pretty-print-matcher* (bigdemo)))
|
||
(check-matches
|
||
(bigdemo)
|
||
(list 'a '-) "a"
|
||
(list 'Z '-) "Z"
|
||
(list '? '-) ""
|
||
(list 'a (list '- '- '-)) "a"
|
||
(list 'a (list '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '-)) "a"
|
||
(list 'Z) ""
|
||
(list 'Z 'x) "Z"
|
||
(list 'Z (list)) "Z"
|
||
(list 'Z (list '-)) "Z"
|
||
(list 'Z (list '-)) "Z"
|
||
(list 'Z (list '- '-)) "Z"
|
||
(list 'Z (list '- '- '-)) "Z+"
|
||
(list 'Z (list '- '- '- '-)) "Z"
|
||
(list 'Z (list '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '-)) "Z"
|
||
(list 'Z '((()) - -)) "Z+"
|
||
(list '? (list '- '- '-)) "")
|
||
|
||
(check-matches (pretty-print-matcher* (pattern->matcher SA (list* 'a 'b ?)))
|
||
(list 'a 'b 'c 'd 'e 'f) "A"
|
||
(list 'b 'c 'd 'e 'f 'a) ""
|
||
3 "")
|
||
|
||
(void (pretty-print-matcher* (matcher-intersect (pattern->matcher SA (list 'a))
|
||
(pattern->matcher SB (list 'b)))))
|
||
|
||
(let ((r1 (matcher-union (pattern->matcher SA (list ? 'b))
|
||
(pattern->matcher SA (list ? 'c))))
|
||
(r2 (matcher-union (pattern->matcher SB (list 'a ?))
|
||
(pattern->matcher SB (list 'b ?)))))
|
||
(pretty-print-matcher* (matcher-union r1 r2))
|
||
(pretty-print-matcher* (matcher-union r1 r1))
|
||
(pretty-print-matcher* (matcher-union r2 r2))
|
||
(pretty-print-matcher* (matcher-intersect r1 r2))
|
||
(pretty-print-matcher* (matcher-intersect r1 r1))
|
||
(pretty-print-matcher* (matcher-intersect r2 r2))
|
||
(void))
|
||
|
||
(void (pretty-print-matcher* (matcher-intersect (bigdemo) (pattern->matcher SX (list 'm 'n)))))
|
||
|
||
(check-matches
|
||
(pretty-print-matcher* (matcher-intersect (bigdemo) (pattern->matcher SX (list 'Z ?))))
|
||
(list 'a '-) ""
|
||
(list 'Z '-) "XZ"
|
||
(list '? '-) ""
|
||
(list 'a (list '- '- '-)) ""
|
||
(list 'a (list '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '-)) ""
|
||
(list 'Z) ""
|
||
(list 'Z 'x) "XZ"
|
||
(list 'Z (list)) "XZ"
|
||
(list 'Z (list '-)) "XZ"
|
||
(list 'Z (list '-)) "XZ"
|
||
(list 'Z (list '- '-)) "XZ"
|
||
(list 'Z (list '- '- '-)) "XZ+"
|
||
(list 'Z (list '- '- '- '-)) "XZ"
|
||
(list 'Z (list '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '-)) "XZ"
|
||
(list 'Z '((()) - -)) "XZ+"
|
||
(list '? (list '- '- '-)) "")
|
||
|
||
(check-matches
|
||
(pretty-print-matcher* (matcher-intersect (bigdemo) (pattern->matcher SX (list 'Z ?))
|
||
(lambda (a b) b)))
|
||
(list 'a '-) ""
|
||
(list 'Z '-) "X"
|
||
(list '? '-) ""
|
||
(list 'a (list '- '- '-)) ""
|
||
(list 'a (list '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '-)) ""
|
||
(list 'Z) ""
|
||
(list 'Z 'x) "X"
|
||
(list 'Z (list)) "X"
|
||
(list 'Z (list '-)) "X"
|
||
(list 'Z (list '-)) "X"
|
||
(list 'Z (list '- '-)) "X"
|
||
(list 'Z (list '- '- '-)) "X"
|
||
(list 'Z (list '- '- '- '-)) "X"
|
||
(list 'Z (list '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '-)) "X"
|
||
(list 'Z '((()) - -)) "X"
|
||
(list '? (list '- '- '-)) "")
|
||
|
||
(check-matches
|
||
(pretty-print-matcher* (matcher-intersect (bigdemo) (pattern->matcher SX ?)
|
||
(lambda (a b) b)))
|
||
(list 'a '-) "X"
|
||
(list 'Z '-) "X"
|
||
(list '? '-) ""
|
||
(list 'a (list '- '- '-)) "X"
|
||
(list 'a (list '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '-)) "X"
|
||
(list 'Z) ""
|
||
(list 'Z 'x) "X"
|
||
(list 'Z (list)) "X"
|
||
(list 'Z (list '-)) "X"
|
||
(list 'Z (list '-)) "X"
|
||
(list 'Z (list '- '-)) "X"
|
||
(list 'Z (list '- '- '-)) "X"
|
||
(list 'Z (list '- '- '- '-)) "X"
|
||
(list 'Z (list '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '- '-)) "X"
|
||
(list 'Z '((()) - -)) "X"
|
||
(list '? (list '- '- '-)) "")
|
||
|
||
(let* ((r1 (pattern->matcher SA (list ? 'b)))
|
||
(r2 (pattern->matcher SB (list 'a ?)))
|
||
(r12 (matcher-union r1 r2)))
|
||
(printf "\n-=-=-=-=-=-=-=-=- erase1\n")
|
||
(pretty-print-matcher* r1)
|
||
(pretty-print-matcher* r2)
|
||
(pretty-print-matcher* r12)
|
||
;; TODO: these next two are not currently "minimal"
|
||
(pretty-print-matcher* (matcher-erase-path r12 r1))
|
||
(pretty-print-matcher* (matcher-erase-path r12 r2))
|
||
(void))
|
||
|
||
(let* ((r1 (matcher-union (pattern->matcher SA (list 'a ?))
|
||
(pattern->matcher SA (list 'b ?))))
|
||
(r2 (pattern->matcher SB (list 'b ?)))
|
||
(r12 (matcher-union r1 r2)))
|
||
(printf "\n-=-=-=-=-=-=-=-=- erase2\n")
|
||
(pretty-print-matcher* r12)
|
||
(pretty-print-matcher* (matcher-erase-path r12 r1))
|
||
(pretty-print-matcher* (matcher-erase-path r12 r2))
|
||
(void))
|
||
|
||
)
|
||
|
||
(module+ test
|
||
(struct a (x) #:prefab)
|
||
(struct b (x) #:transparent)
|
||
|
||
(define (intersect a b)
|
||
(matcher-intersect (pattern->matcher SA a)
|
||
(pattern->matcher SB b)))
|
||
|
||
(define EAB (E (set 'A 'B)))
|
||
|
||
(check-equal? (intersect ? ?) (rwild EAB))
|
||
(check-equal? (intersect 'a ?) (rseq 'a EAB))
|
||
(check-equal? (intersect 123 ?) (rseq 123 EAB))
|
||
(check-equal? (intersect (cons ? 2) (cons 1 ?)) (rseq* SOP 1 2 EOS EAB))
|
||
(check-equal? (intersect (cons 1 2) ?) (rseq* SOP 1 2 EOS EAB))
|
||
(check-equal? (intersect 1 2) #f)
|
||
(check-equal? (intersect (cons 1 2) (cons ? 2)) (rseq* SOP 1 2 EOS EAB))
|
||
(check-equal? (intersect (cons 1 2) (cons 3 2)) #f)
|
||
(check-equal? (intersect (cons 1 2) (cons 1 3)) #f)
|
||
(check-equal? (intersect (vector 1 2) (vector 1 2)) (rseq* SOV 1 2 EOS EAB))
|
||
(check-equal? (intersect (vector 1 2) (vector 1 2 3)) #f)
|
||
|
||
(check-equal? (intersect (a 'a) (a 'b)) #f)
|
||
(check-equal? (intersect (a 'a) (a 'a)) (rseq* struct:a 'a EOS EAB))
|
||
(check-equal? (intersect (a 'a) (a ?)) (rseq* struct:a 'a EOS EAB))
|
||
(check-equal? (intersect (a 'a) ?) (rseq* struct:a 'a EOS EAB))
|
||
(check-equal? (intersect (b 'a) (b 'b)) #f)
|
||
(check-equal? (intersect (b 'a) (b 'a)) (rseq* struct:b 'a EOS EAB))
|
||
(check-equal? (intersect (b 'a) (b ?)) (rseq* struct:b 'a EOS EAB))
|
||
(check-equal? (intersect (b 'a) ?) (rseq* struct:b 'a EOS EAB))
|
||
|
||
(check-equal? (intersect (a 'a) (b 'a)) #f)
|
||
|
||
(check-exn #px"Cannot match on hash tables at present"
|
||
(lambda ()
|
||
(intersect (hash 'a 1 'b ?) (hash 'a ? 'b 2))))
|
||
;; (check-equal? (intersect (hash 'a 1 'b ?) (hash 'a ? 'b 2)) (hash 'a 1 'b 2))
|
||
;; (check-equal? (intersect (hash 'a 1 'b ?) (hash 'a ?)) (void))
|
||
;; (check-equal? (intersect (hash 'a 1 'b ?) (hash 'a 1 'b ?)) (hash 'a 1 'b ?))
|
||
;; (check-equal? (intersect (hash 'a 1 'b ?) (hash 'a ? 'c ?)) (void))
|
||
|
||
;; (check-equal? (intersect (hash 'a 1 'b ?) (hash 'a 1 'b (list 2 ?)))
|
||
;; (hash 'a 1 'b (list 2 ?)))
|
||
;; (check-equal? (intersect (hash 'a 1 'b (list ? 3)) (hash 'a 1 'b (list 2 ?)))
|
||
;; (hash 'a 1 'b (list 2 3)))
|
||
|
||
)
|
||
|
||
(module+ test
|
||
(define (matcher-match-matcher-list m1 m2)
|
||
(define-values (s1 s2) (matcher-match-matcher m1 m2))
|
||
(list s1 s2))
|
||
(let ((abc (foldr matcher-union (matcher-empty)
|
||
(list (pattern->matcher SA (list 'a ?))
|
||
(pattern->matcher SB (list 'b ?))
|
||
(pattern->matcher SC (list 'c ?)))))
|
||
(bcd (foldr matcher-union (matcher-empty)
|
||
(list (pattern->matcher SB (list 'b ?))
|
||
(pattern->matcher SC (list 'c ?))
|
||
(pattern->matcher SD (list 'd ?))))))
|
||
(check-equal? (matcher-match-matcher-list abc abc)
|
||
(list (set 'A 'B 'C) (set 'A 'B 'C)))
|
||
(check-equal? (matcher-match-matcher-list abc (matcher-relabel bcd (lambda (old) (set #t))))
|
||
(list (set 'B 'C) (set #t)))
|
||
(check-equal? (matcher-match-matcher-list abc (pattern->matcher Sfoo ?))
|
||
(list (set 'A 'B 'C) (set 'foo)))
|
||
(check-equal? (matcher-match-matcher-list abc (pattern->matcher Sfoo (list ? ?)))
|
||
(list (set 'A 'B 'C) (set 'foo)))
|
||
(check-equal? (matcher-match-matcher-list abc (pattern->matcher Sfoo (list ? 'x)))
|
||
(list (set 'A 'B 'C) (set 'foo)))
|
||
(check-equal? (matcher-match-matcher-list abc (pattern->matcher Sfoo (list ? 'x ?)))
|
||
(list (set) (set)))))
|
||
|
||
(module+ test
|
||
(check-equal? (compile-projection (list 'a 'b))
|
||
(list SOP 'a SOP 'b '() EOS EOS EOS))
|
||
(check-equal? (compile-projection (list 'a ?!))
|
||
(list SOP 'a SOP ?! '() EOS EOS EOS))
|
||
|
||
(check-equal? (matcher-project (matcher-union (pattern->matcher SA (list 'a 'a))
|
||
(pattern->matcher SB (list 'a 'b)))
|
||
(compile-projection (list 'a ?!))
|
||
(lambda (v) #t))
|
||
(matcher-union (pattern->matcher #t (vector 'a))
|
||
(pattern->matcher #t (vector 'b))))
|
||
|
||
(check-equal? (matcher-project (matcher-union (pattern->matcher SA (list 'a 'a))
|
||
(pattern->matcher SB (list 'a (vector 'b 'c 'd))))
|
||
(compile-projection (list 'a ?!))
|
||
(lambda (v) #t))
|
||
(matcher-union (pattern->matcher #t (vector 'a))
|
||
(pattern->matcher #t (vector (vector 'b 'c 'd)))))
|
||
|
||
(check-equal? (matcher-project (matcher-union (pattern->matcher SA (list 'a 'a))
|
||
(pattern->matcher SB (list 'a (vector 'b ? 'd))))
|
||
(compile-projection (list 'a ?!))
|
||
(lambda (v) #t))
|
||
(matcher-union (pattern->matcher #t (vector 'a))
|
||
(pattern->matcher #t (vector (vector 'b ? 'd)))))
|
||
|
||
(check-equal? (matcher-key-set
|
||
(matcher-project (matcher-union (pattern->matcher SA (list 'a 'a))
|
||
(pattern->matcher SB (list 'a 'b)))
|
||
(compile-projection (list 'a ?!))
|
||
(lambda (v) #t)))
|
||
(set '#(a) '#(b)))
|
||
|
||
(check-equal? (matcher-key-set
|
||
(matcher-project (matcher-union (pattern->matcher SA (list 'a 'a))
|
||
(pattern->matcher SB (list 'a (vector 'b 'c 'd))))
|
||
(compile-projection (list 'a ?!))
|
||
(lambda (v) #t)))
|
||
(set '#(a) '#(#(b c d))))
|
||
|
||
(check-equal? (matcher-key-set
|
||
(matcher-project (matcher-union (pattern->matcher SA (list 'a 'a))
|
||
(pattern->matcher SB (list 'a (vector 'b ? 'd))))
|
||
(compile-projection (list 'a ?!))
|
||
(lambda (v) #t)))
|
||
#f)
|
||
|
||
(check-equal? (matcher-project (matcher-union (pattern->matcher SA (cons 1 2))
|
||
(pattern->matcher SB (cons 3 4)))
|
||
(compile-projection (cons ?! ?!))
|
||
(lambda (v) #t))
|
||
(matcher-union (pattern->matcher #t (vector 1 2))
|
||
(pattern->matcher #t (vector 3 4))))
|
||
|
||
(check-equal? (matcher-key-set
|
||
(matcher-project (matcher-union (pattern->matcher SA (cons 1 2))
|
||
(pattern->matcher SB (cons 3 4)))
|
||
(compile-projection (cons ?! ?!))
|
||
(lambda (v) #t)))
|
||
(set '#(1 2) '#(3 4)))
|
||
) |