scolobb
/
dds
1
0
Fork 0
Code Issues Pull Requests Releases Wiki Activity
dds/utils.rkt

718 lines
26 KiB
Racket
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

#lang racket
;;; dds/utils
;;; Various utilities.
(require
graph
(for-syntax syntax/parse racket/list))
(provide
;; Functions
(contract-out [eval-with (-> variable-mapping? any/c any)]
[extract-symbols (-> any/c list?)]
[any->string (-> any/c string?)]
[stringify-variable-mapping (-> variable-mapping? string-variable-mapping?)]
[string->any (-> string? any/c)]
[read-org-sexp (-> string? (listof any/c))]
[map-sexp (-> procedure? any/c any/c)]
[unorg (-> string? (listof any/c))]
[unstringify-pairs (-> (listof (general-pair/c string? any/c))
(listof (general-pair/c symbol? any/c)))]
[read-org-variable-mapping (-> string? variable-mapping?)]
[unorgv (-> string? variable-mapping?)]
[dotit (-> graph? void?)]
[read-symbol-list (-> string? (listof symbol?))]
[drop-first-last (-> string? string?)]
[list-sets->list-strings (-> (listof (set/c any/c)) (listof string?))]
[pretty-print-set-sets (-> (set/c (set/c symbol?) #:kind 'dont-care) string?)]
[update-vertices/unweighted (-> graph? (-> any/c any/c) graph?)]
[update-graph (->* (graph?)
(#:v-func (-> any/c any/c)
#:e-func (-> any/c any/c))
graph?)]
[pretty-print-set (-> generic-set? string?)]
[collect-by-key (-> (listof any/c) (listof any/c) (values (listof any/c) (listof (listof any/c))))]
[collect-by-key/sets (-> (listof any/c) (listof any/c) (values (listof any/c) (listof (set/c any/c))))]
[ht-values/list->set (-> (hash/c any/c (listof any/c)) (hash/c any/c (set/c any/c)))]
[hash->list/ordered (-> hash? (listof (cons/c any/c any/c)))]
[multi-split-at (-> (listof (listof any/c)) number?
(values (listof (listof any/c)) (listof (listof any/c))))]
[lists-transpose (-> (listof (listof any/c)) (listof (listof any/c)))]
[procedure-fixed-arity? (-> procedure? boolean?)]
[in-random (case-> (-> (stream/c (and/c real? inexact? (>/c 0) (</c 1))))
(-> (integer-in 1 4294967087) (stream/c exact-nonnegative-integer?))
(-> exact-integer? (integer-in 1 4294967087)
(stream/c exact-nonnegative-integer?)))]
[cartesian-product/stream (->* () #:rest (listof stream?) stream?)]
[boolean-power (-> number? (listof (listof boolean?)))]
[boolean-power/stream (-> number? (stream/c (listof boolean?)))]
[any->01 (-> any/c (or/c 0 1))]
[01->boolean (-> (or/c 0 1) boolean?)])
;; Contracts
(contract-out [variable-mapping? contract?]
[string-variable-mapping? contract?]
[general-pair/c (-> contract? contract? contract?)])
;; Syntax
auto-hash-ref/explicit auto-hash-ref/:)
(module+ test
(require rackunit))
;;; ===================
;;; HashTable Injection
;;; ===================
;;; This section of the file contains some utilities to streamline the
;;; usage of hash tables mapping symbols to values. The goal is
;;; essentially to avoid having to write explicit hash-ref calls.
;;; A variable mapping is a hash table mapping symbols to values.
(define (variable-mapping? dict) (hash/c symbol? any/c))
;;; Given a (HashTable Symbol a) and a sequence of symbols, binds
;;; these symbols to the values they are associated to in the hash
;;; table, then puts the body in the context of these bindings.
;;;
;;; > (let ([ht #hash((a . 1) (b . 2))])
;;; (auto-hash-ref/explicit (ht a b) (+ a (* 2 b))))
;;; 5
;;;
;;; Note that only one expression can be supplied in the body.
(define-syntax (auto-hash-ref/explicit stx)
(syntax-parse stx
[(_ (ht:id xs:id ...) body:expr)
#`(let #,(for/list ([x (syntax->list #'(xs ...))])
#`[#,x (hash-ref ht '#,x)])
body)]))
(module+ test
(test-case "auto-hash-ref/explicit"
(define mytable #hash((a . 3) (b . 4)))
(check-equal? (auto-hash-ref/explicit (mytable b a)
(* a b))
12)
(define ht #hash((a . #t) (b . #f)))
(check-equal? (auto-hash-ref/explicit (ht a b)
(and (not a) b))
#f)))
;;; Given an expression and a (HashTable Symbol a), looks up the
;;; symbols with a leading semicolon and binds them to the value they
;;; are associated to in the hash table.
;;;
;;; > (let ([ht #hash((a . 1) (b . 2))])
;;; (auto-hash-ref/: ht (+ :a (* 2 :b))))
;;; 5
;;;
;;; Note that the symbol :a is matched to the key 'a in the hash
;;; table.
;;;
;;; Note that only one expression can be supplied in the body.
(define-syntax (auto-hash-ref/: stx)
(syntax-parse stx
[(_ ht:id body)
(let* ([names/: (collect-colons (syntax->datum #'body))])
#`(let #,(for/list ([x names/:])
;; put x in the same context as body
#`[#,(datum->syntax #'body x)
(hash-ref ht '#,(strip-colon x))])
body))]))
(module+ test
(test-case "auto-hash-ref/:"
(define ht1 #hash((x . #t) (y . #t) (t . #f)))
(define z #t)
(check-equal? (auto-hash-ref/: ht1
(and :x (not :y) z (or (and :t) :x)))
#f)
(define ht2 #hash((a . 1) (b . 2)))
(check-equal? (auto-hash-ref/: ht2 (+ :a (* 2 :b)))
5)))
;;; The helper functions for auto-hash-ref/:.
(begin-for-syntax
;; Collect all the symbols starting with a colon in datum.
(define (collect-colons datum)
(remove-duplicates
(flatten
(for/list ([token datum])
(cond
[(symbol? token)
(let ([name (symbol->string token)])
(if (eq? #\: (string-ref name 0))
token
'()))]
[(list? token)
(collect-colons token)]
[else '()])))))
;; Strip the leading colon off x.
(define (strip-colon x)
(let ([x-str (symbol->string x)])
(if (eq? #\: (string-ref x-str 0))
(string->symbol (substring x-str 1))
x))))
;;; Temporarily injects the mappings from the given hash table as
;;; bindings in a namespace including racket/base and then evaluates
;;; the expression.
;;;
;;; > (let ([ht #hash((a . 1) (b . 1))])
;;; (eval-with ht '(+ b a 1)))
;;; 3
;;;
;;; The local bindings from the current lexical scope are not
;;; conserved. Therefore, the following outputs an error about a
;;; missing identifier:
;;;
;;; > (let ([ht #hash((a . 1) (b . 1))]
;;; [z 1])
;;; (eval-with ht '(+ b z a 1)))
;;;
(define (eval-with ht expr)
(parameterize ([current-namespace (make-base-namespace)])
(for ([(x val) ht]) (namespace-set-variable-value! x val))
(eval expr)))
(module+ test
(test-case "eval-with"
(check-equal? (let ([ht #hash((a . 1) (b . 1))])
(eval-with ht '(+ b a 1)))
3)))
;;; Same as eval-with, but returns only the first value produced by
;;; the evaluated expression.
(define (eval-with1 ht expr)
(let ([vals (call-with-values (λ () (eval-with ht expr))
(λ vals vals))])
(car vals)))
;;; ==============================
;;; Analysis of quoted expressions
;;; ==============================
;;; Produces a list of symbols appearing in the quoted expression
;;; passed in the first argument.
(define (extract-symbols form)
(match form
[(? symbol?) (list form)]
[(? list?) (flatten (for/list ([x form])
(extract-symbols x)))]
[else '()]))
(module+ test
(test-case "extract-symbols"
(check-equal? (extract-symbols '(1 (2 3) x (y z 3)))
'(x y z))))
;;; =========================
;;; Interaction with Org-mode
;;; =========================
;;; Org-mode supports laying out the output of code blocks as tables,
;;; which is very practical for various variable mappings (e.g.,
;;; states). However, when the hash table maps variables to lists,
;;; Org-mode will create a column per list element, which may or may
;;; not be the desired effect. In this section I define some
;;; utilities for nicer interoperation with Org-mode tables. I also
;;; define some shortcuts to reduce the number of words to type when
;;; using dds with Org-mode. See example.org for examples of usage.
;;; Converts any value to string.
(define (any->string x)
(with-output-to-string (λ () (display x))))
(module+ test
(test-case "any->string"
(check-equal? (any->string 'a) "a")
(check-equal? (any->string '(a 1 (x y))) "(a 1 (x y))")
(check-equal? (any->string "hello") "hello")))
;;; A string variable mapping is a mapping from variables to strings.
(define (string-variable-mapping? dict) (hash/c symbol? string?))
;;; Converts all the values of a variable mapping to string.
(define (stringify-variable-mapping ht)
(for/hash ([(key val) ht]) (values key (any->string val))))
(module+ test
(test-case "stringify-variable-mapping"
(define mp (stringify-variable-mapping #hash((a . (and a b)) (b . (not b)))))
(check-equal? (hash-ref mp 'a) "(and a b)")
(check-equal? (hash-ref mp 'b) "(not b)")))
;;; Reads any value from string.
(define (string->any str)
(with-input-from-string str (λ () (read))))
(module+ test
(test-case "string->any"
(check-equal? (string->any "(or b (not a))") '(or b (not a)))
(check-equal? (string->any "14") 14)))
;;; Given a sexp, converts all "#f" to #f and "#t" to #t.
;;;
;;; When I read Org-mode tables, I pump them through a call to the
;;; prin1 because the elisp sexp seems incompatible with Racket. On
;;; the other hand, Racket Booleans seem to upset elisp a little, so
;;; prin1 wraps them in additional double quotes. This function
;;; removes those quotes.
(define/match (handle-org-booleans datum)
[("#t") #t]
[("#f") #f]
[((? list?)) (map handle-org-booleans datum)]
[(_) datum])
;;; Given a sexp, applies the given function to any object which is
;;; not a list.
;;;
;;; The contract of this function will not check whether func is
;;; indeed applicable to every non-list element of the sexp. If this
;;; is not the case, a contract violation for func will be generated.
(define (map-sexp func sexp)
(match sexp
[(? list?) (map ((curry map-sexp) func) sexp)]
[datum (func datum)]))
(module+ test
(test-case "map-sexp"
(check-equal? (map-sexp add1 '(1 2 (4 10) 3)) '(2 3 (5 11) 4))))
;;; Reads a sexp from a string produced by Org-mode for a named table.
;;; See example.org for examples.
(define read-org-sexp
(compose ((curry map-sexp) (match-lambda
[(and (? string?) str) (string->any str)]
[x x]))
string->any))
;;; A shortcut for read-org-sexp.
(define unorg read-org-sexp)
(module+ test
(test-case "read-org-sexp"
(check-equal? (read-org-sexp "((\"a\" \"(and a b)\") (\"b\" \"(or b (not a))\"))")
'((a (and a b)) (b (or b (not a)))))
(check-equal? (read-org-sexp "(#t \"#t\" \"#t \" '(1 2 \"#f\"))")
'(#t #t #t '(1 2 #f)))))
;;; A contract allowing pairs constructed via cons or via list.
(define (general-pair/c key-contract val-contract)
(or/c (list/c key-contract val-contract)
(cons/c key-contract val-contract)))
;;; Given a list of pairs of strings and some other values (possibly
;;; strings), converts the first element of each pair to a string, and
;;; reads the second element with string->any or keeps it as is if it
;;; is not a string.
(define (unstringify-pairs pairs)
(for/list ([p pairs])
(match p
[(list key val)
(cons (string->symbol key) (if (string? val)
(string->any val)
val))]
[(cons key val) ; also handle improper pairs
(cons (string->symbol key) (if (string? val)
(string->any val)
val))])))
(module+ test
(test-case "unstringify-pairs"
(check-equal? (unstringify-pairs '(("a" . "1") ("b" . "(and a (not b))")))
'((a . 1) (b . (and a (not b)))))
(check-equal? (unstringify-pairs '(("a" . 1) ("b" . "(and a (not b))")))
'((a . 1) (b . (and a (not b)))))))
;;; Reads a variable mapping from a string, such as the one which
;;; Org-mode produces from tables.
(define read-org-variable-mapping
(compose make-immutable-hash unstringify-pairs string->any))
(module+ test
(test-case "read-org-variable-mapping"
(define m1 (read-org-variable-mapping "((\"a\" \"(and a b)\") (\"b\" \"(or b (not a))\"))"))
(define m2 (read-org-variable-mapping "((\"a\" . \"(and a b)\") (\"b\" . \"(or b (not a))\"))"))
(define m3 (unorgv "((\"a\" . \"(and a b)\") (\"b\" . \"(or b (not a))\"))"))
(check-equal? (hash-ref m1 'a) '(and a b))
(check-equal? (hash-ref m2 'a) '(and a b))
(check-equal? (hash-ref m3 'a) '(and a b))
(check-equal? (hash-ref m1 'b) '(or b (not a)))
(check-equal? (hash-ref m2 'b) '(or b (not a)))
(check-equal? (hash-ref m3 'b) '(or b (not a)))))
;;; A synonym for read-org-variable-mapping.
(define unorgv read-org-variable-mapping)
;;; Typeset the graph via graphviz and display it.
(define dotit (compose display graphviz))
;;; Reads a list of symbols from a string.
(define (read-symbol-list str)
(string->any (string-append "(" str ")")))
(module+ test
(test-case "read-symbol-list"
(check-equal? (read-symbol-list "a b c") '(a b c))))
;;; Removes the first and the last symbol of a given string.
;;;
;;; Useful for removing the parentheses in string representations of
;;; lists.
(define (drop-first-last str)
(substring str 1 (- (string-length str) 1)))
(module+ test
(test-case "drop-first-last"
(check-equal? (drop-first-last "(a b)") "a b")))
;;; Converts a list of sets of symbols to a list of strings containing
;;; those symbols.
(define (list-sets->list-strings lst)
(map (compose drop-first-last any->string set->list) lst))
(module+ test
(test-case "list-sets->list-strings"
(check-equal? (list-sets->list-strings (list (set 'x 'y) (set 'z) (set) (set 't)))
'("y x" "z" "" "t"))))
;;; Pretty-prints a set of sets of symbols.
;;;
;;; Typically used for pretty-printing the annotations on the edges of
;;; the state graph.
(define (pretty-print-set-sets ms)
(string-join (for/list ([m ms]) (format "{~a}" (pretty-print-set m))) ""))
(module+ test
(test-case "pretty-print-set-sets"
(check-equal? (pretty-print-set-sets (set (set 'a 'b) (set 'c))) "{a b}{c}")))
;;; ==========================
;;; Additional graph utilities
;;; ==========================
;;; Apply a transformation to every vertex in the unweighted graph,
;;; return the new graph. If the transformation function maps two
;;; vertices to the same values, these vertices will be merged in the
;;; resulting graph. The transformation function may be called
;;; multiple times for the same vertex.
;;;
;;; This function does not rely on rename-vertex!, so it can be used
;;; to permute vertex labels.
(define (update-vertices/unweighted gr func)
(unweighted-graph/directed
(for/list ([e (in-edges gr)])
(match-let ([(list u v) e])
(list (func u) (func v))))))
(module+ test
(test-case "update-vertices/unweighted"
(define gr1 (directed-graph '((a b) (b c))))
(define gr2 (undirected-graph '((a b) (b c))))
(define dbl (λ (x) (let ([x-str (symbol->string x)])
(string->symbol (string-append x-str x-str)))))
(define new-gr1 (update-vertices/unweighted gr1 dbl))
(define new-gr2 (update-vertices/unweighted gr2 dbl))
(check-false (has-vertex? new-gr1 'a))
(check-true (has-vertex? new-gr1 'aa))
(check-false (has-vertex? new-gr1 'b))
(check-true (has-vertex? new-gr1 'bb))
(check-false (has-vertex? new-gr1 'c))
(check-true (has-vertex? new-gr1 'cc))
(check-true (has-edge? new-gr1 'aa 'bb))
(check-true (has-edge? new-gr1 'bb 'cc))
(check-true (has-edge? new-gr2 'aa 'bb))
(check-true (has-edge? new-gr2 'bb 'aa))
(check-true (has-edge? new-gr2 'bb 'cc))
(check-true (has-edge? new-gr2 'cc 'bb))))
;;; Given a graph, apply a transformation v-func to every vertex label
;;; and, if the graph is a weighted graph, the transformation e-func
;;; to every edge label. Both transformations default to identity
;;; functions. If gr is an weighted graph, the result is a weighted
;;; graph. If gr is an unweighted graph, the result is an unweighted
;;; graph.
(define (update-graph gr
#:v-func [v-func identity]
#:e-func [e-func identity])
(define edges
(for/list ([e (in-edges gr)])
(match-let ([(list u v) e])
(cond
[(unweighted-graph? gr) (list (v-func u) (v-func v))]
[else (list (e-func (edge-weight gr u v))
(v-func u) (v-func v))]))))
(cond
[(unweighted-graph? gr) (unweighted-graph/directed edges)]
[else
(weighted-graph/directed edges)]))
(module+ test
(test-case "update-graph"
(define gr1 (directed-graph '((a b) (b c))))
(define gr2 (undirected-graph '((a b) (b c))))
(define dbl (λ (x) (let ([x-str (symbol->string x)])
(string->symbol (string-append x-str x-str)))))
(define new-gr1-ug (update-graph gr1 #:v-func dbl))
(define new-gr2-ug (update-graph gr2 #:v-func dbl))
(define gr3 (weighted-graph/directed '((10 a b) (11 b c))))
(define new-gr3 (update-graph gr3 #:v-func dbl #:e-func (λ (x) (* 2 x))))
(check-false (has-vertex? new-gr1-ug 'a))
(check-true (has-vertex? new-gr1-ug 'aa))
(check-false (has-vertex? new-gr1-ug 'b))
(check-true (has-vertex? new-gr1-ug 'bb))
(check-false (has-vertex? new-gr1-ug 'c))
(check-true (has-vertex? new-gr1-ug 'cc))
(check-true (has-edge? new-gr1-ug 'aa 'bb))
(check-true (has-edge? new-gr1-ug 'bb 'cc))
(check-true (has-edge? new-gr2-ug 'aa 'bb))
(check-true (has-edge? new-gr2-ug 'bb 'aa))
(check-true (has-edge? new-gr2-ug 'bb 'cc))
(check-true (has-edge? new-gr2-ug 'cc 'bb))
(check-true (has-edge? new-gr3 'aa 'bb))
(check-false (has-edge? new-gr3 'bb 'aa))
(check-true (has-edge? new-gr3 'bb 'cc))
(check-false (has-edge? new-gr3 'cc 'bb))
(check-equal? (edge-weight new-gr3 'aa 'bb) 20)
(check-equal? (edge-weight new-gr3 'bb 'cc) 22)))
;;; ===============
;;; Pretty printing
;;; ===============
;;; Pretty print a set by listing its elements in alphabetic order.
(define (pretty-print-set s)
(string-join (sort (set-map s any->string) string<?)))
(module+ test
(test-case "pretty-print-set"
(check-equal? (pretty-print-set (set 'a 'b 1)) "1 a b")))
;;; =========================
;;; Additional list utilities
;;; =========================
;;; Collects labels for duplicate edges into a sets of labels.
;;;
;;; More precisely, given a list of edges and weights, produces a new
;;; list of edges without duplicates, and a list of lists of weights
;;; in which each element corresponds to the edge (the input is
;;; suitable for graph constructors).
(define (collect-by-key edges labels)
(for/fold ([ht (make-immutable-hash)]
#:result (values (hash-keys ht) (hash-values ht)))
([e edges] [l labels])
(hash-update ht e (λ (ls) (cons l ls)) empty)))
(module+ test
(test-case "collect-by-key"
(define-values (e1 l1) (collect-by-key '((1 2) (1 3)) '(a b)))
(define-values (e2 l2) (collect-by-key '((1 2) (1 2)) '(a b)))
(check-equal? e1 '((1 2) (1 3))) (check-equal? l1 '((a) (b)))
(check-equal? e2 '((1 2))) (check-equal? l2 '((b a)))))
;;; Like collect-by-key, but returns a list of sets of weights.
(define (collect-by-key/sets edges labels)
(let-values ([(es ls) (collect-by-key edges labels)])
(values es (map list->set ls))))
(module+ test
(test-case "collect-by-key/sets"
(define-values (e3 l3) (collect-by-key/sets '(a b a) '(1 2 1)))
(check-equal? e3 '(a b)) (check-equal? l3 (list (set 1) (set 2)))))
;;; Converts the values of a hash table from lists to sets.
(define (ht-values/list->set ht)
(for/hash ([(k v) (in-hash ht)])
(values k (list->set v))))
(module+ test
(test-case "ht-values/list->set"
(check-equal? (ht-values/list->set #hash((a . (1 1))))
(hash 'a (set 1)))))
;;; Returns the key-value pairs of a given hash table in the order in
;;; which the hash table orders them for hash-map and hash-for-each.
(define (hash->list/ordered ht) (hash-map ht cons #t))
(module+ test
(test-case "hash->list/ordered"
(check-equal? (hash->list/ordered #hash((b . 1) (a . 1)))
'((a . 1) (b . 1)))))
;;; Given a list of lists, splits every single list at the given
;;; position, and then returns two lists: one consisting of the first
;;; halves, and the one consisting of the second halves.
(define (multi-split-at lsts pos)
(define (split-1 lst res)
(define-values (l r) (split-at lst pos))
(match res [(cons left right)
(cons (cons l left) (cons r right))]))
(match (foldr split-1 (cons '() '()) lsts)
[(cons lefts rights) (values lefts rights)]))
(module+ test
(test-case "multi-split-at"
(define-values (l1 l2) (multi-split-at '((1 2 3) (a b c)) 2))
(check-equal? l1 '((1 2) (a b))) (check-equal? l2 '((3) (c)))))
;;; Given a list of lists of the same length, transposes them.
;;;
;;; > (lists-transpose '((1 2) (a b)))
;;; '((1 a) (2 b))
;;;
;;; This function is essentially in-parallel, wrapped in a couple
;;; conversions.
(define lists-transpose
(compose sequence->list
in-values-sequence
((curry apply) in-parallel)))
(module+ test
(test-case "lists-transpose"
(check-equal? (lists-transpose '((1 2) (a b))) '((1 a) (2 b)))))
;;; =========
;;; Functions
;;; =========
;;; Returns #t if the function has fixed arity (i.e. if it does not
;;; take a variable number of arguments).
(define (procedure-fixed-arity? func)
(match (procedure-arity func)
[(arity-at-least _) #f] [arity #t]))
(module+ test
(test-case "procedure-fixed-arity?"
(check-true (procedure-fixed-arity? not))
(check-false (procedure-fixed-arity? +))))
;;; ==========
;;; Randomness
;;; ==========
;;; Generates a stream of inexact random numbers. The meaning of the
;;; arguments is the same as for the function random:
;;;
;;; (in-randoms k) — a sequence of random exact integers in the range
;;; 0 to k-1.
;;;
;;; (in-randoms min max) — a sequence of random exact integers the
;;; range min to max-1.
;;;
;;; (in-randoms) — a sequence of random inexact numbers between
;;; 0 and 1.
(define in-random
(case-lambda
[() (for/stream ([i (in-naturals)]) (random))]
[(k) (for/stream ([i (in-naturals)]) (random k))]
[(min max) (for/stream ([i (in-naturals)]) (random min max))]))
(module+ test
(test-case "in-random"
(random-seed 0)
(check-equal? (stream->list (stream-take (in-random 100) 10))
'(85 65 20 40 89 45 54 38 26 62))
(check-equal? (stream->list (stream-take (in-random 50 100) 10))
'(75 59 82 85 61 85 59 64 75 53))
(check-equal? (stream->list (stream-take (in-random) 10))
'(0.1656109603231493
0.9680391127132195
0.051518813640790355
0.755901955353936
0.5923534604277275
0.5513340634474264
0.7022057040731392
0.48375400938578744
0.7538961707172924
0.01828428516237329))))
;;; ===========================
;;; Additional stream utilities
;;; ===========================
;;; Returns the Cartesian product of the given streams. The result is
;;; a stream whose elements are the elements of the Cartesian product.
;;;
;;; The implementation is inspired from the implementation of
;;; cartesian-product in racket/list.
(define (cartesian-product/stream . ss)
;; Cartesian product of two streams, produces an improper pair.
(define (cp-2 ss1 ss2)
(for*/stream ([s1 (in-stream ss1)] [s2 (in-stream ss2)]) (cons s1 s2)))
;; Fold-right over the list of streams. The value for the fold is a
;; 1-value stream containing the empty list, which makes all the
;; lists proper.
(foldr cp-2 (sequence->stream (in-value (list))) ss))
(module+ test
(test-case "cartesian-product/stream"
(check-equal? (stream->list (cartesian-product/stream (in-range 3) (in-range 4 6) '(a b)))
'((0 4 a)
(0 4 b)
(0 5 a)
(0 5 b)
(1 4 a)
(1 4 b)
(1 5 a)
(1 5 b)
(2 4 a)
(2 4 b)
(2 5 a)
(2 5 b)))))
;;; ==================
;;; Boolean operations
;;; ==================
;;; Returns the n-th Cartesian power of the Boolean domain: {0,1}^n.
(define (boolean-power n) (apply cartesian-product (make-list n '(#f #t))))
(module+ test
(test-case "boolean-power"
(check-equal? (boolean-power 2) '((#f #f) (#f #t) (#t #f) (#t #t)))))
;;; Like boolean-power, but returns a stream whose elements the
;;; elements of the Cartesian power.
(define (boolean-power/stream n) (apply cartesian-product/stream (make-list n '(#f #t))))
(module+ test
(test-case "boolean-power/stream"
(check-equal? (stream->list (boolean-power/stream 2)) '((#f #f) (#f #t) (#t #f) (#t #t)))))
;;; Converts any non-#f value to 1 and #f to 0.
(define (any->01 x) (if x 1 0))
(module+ test
(test-case "any->01"
(check-equal? (any->01 #t) 1)
(check-equal? (any->01 #f) 0)))
;;; Converts 0 to #f and 1 to #t
(define (01->boolean x)
(case x [(0) #f] [else #t]))
(module+ test
(test-case "01->boolean"
(check-equal? (01->boolean 0) #f)
(check-equal? (01->boolean 1) #t)))
Reference in New Issue View Git Blame Copy Permalink