413 lines
15 KiB
Racket
413 lines
15 KiB
Racket
#lang racket
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;;; dds/functions
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;;; This modules provides some definitions for working with functions:
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;;; tabulating, (re)constructing from tables, generating random
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;;; functions, etc. Some definitions of particular kinds of functions
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;;; are also provided (threshold Boolean functions, etc.).
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(require "utils.rkt")
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(provide
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;; Structures
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(contract-out
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[struct tbf ((weights (vectorof number?)) (threshold number?))])
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;; Functions
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(contract-out
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[tabulate (-> procedure? (listof generic-set?) (listof list?))]
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[tabulate* (-> (listof procedure?) (listof generic-set?) (listof list?))]
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[tabulate/boolean (-> procedure-fixed-arity? (listof (listof boolean?)))]
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[tabulate*/boolean (-> (non-empty-listof procedure-fixed-arity?) (listof (listof boolean?)))]
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[tabulate/01 (-> procedure? (listof (listof (or/c 0 1))))]
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[tabulate*/01 (-> (non-empty-listof procedure?) (listof (listof (or/c 0 1))))]
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[table->function (-> (listof (*list/c any/c any/c)) procedure?)]
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[table->function/list (-> (listof (*list/c any/c any/c)) procedure?)]
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[enumerate-boolean-tables (-> number? (stream/c (listof (*list/c boolean? boolean?))))]
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[enumerate-boolean-functions (-> number? (stream/c procedure?))]
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[enumerate-boolean-functions/list (-> number? (stream/c procedure?))]
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[random-boolean-table (-> number? (listof (*list/c boolean? boolean?)))]
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[random-boolean-function (-> number? procedure?)]
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[random-boolean-function/list (-> number? procedure?)]
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[tbf-w (-> tbf? (vectorof number?))]
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[tbf-θ (-> tbf? number?)]
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[vector-boolean->01 (-> (vectorof boolean?) (vectorof (or/c 0 1)))]
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[apply-tbf (-> tbf? (vectorof (or/c 0 1)) (or/c 0 1))]
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[apply-tbf/boolean (-> tbf? (vectorof boolean?) boolean?)]
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[list->tbf (-> (cons/c number? (cons/c number? (listof number?))) tbf?)]
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[lists->tbfs (-> (listof (listof number?)) (listof tbf?))]
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[read-org-tbfs (->* (string?) (#:headers boolean?) (listof tbf?))]
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[tbf-tabulate* (-> (listof tbf?) (listof (listof (or/c 0 1))))]
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[tbf-tabulate (-> tbf? (listof (listof (or/c 0 1))))]
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[tbf-tabulate*/boolean (-> (listof tbf?) (listof (listof boolean?)))]
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[sbf (-> (vectorof number?) tbf?)]
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[list->sbf (-> (listof number?) sbf?)]
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[read-org-sbfs (->* (string?) (#:headers boolean?) (listof sbf?))])
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;; Predicates
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(contract-out
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[sbf? (-> any/c boolean?)]))
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(module+ test
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(require rackunit))
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;;; ==========
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;;; Tabulating
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;;; ==========
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;;; Given a function and a list of domains for each of its arguments,
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;;; in order, produces a list of lists giving the values of arguments
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;;; and the value of the functions for these inputs.
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(define (tabulate func doms)
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(tabulate* `(,func) doms))
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(module+ test
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(test-case "tabulate"
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(check-equal? (tabulate (λ (x y) (and x y)) '((#f #t) (#f #t)))
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'((#f #f #f) (#f #t #f) (#t #f #f) (#t #t #t)))))
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;;; Like tabulate, but takes a list of functions taking
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;;; the same arguments over the same domains.
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(define (tabulate* funcs doms)
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(for/list ([xs (apply cartesian-product doms)])
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(append xs (for/list ([f funcs]) (apply f xs)))))
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(module+ test
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(test-case "tabulate*"
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(check-equal? (tabulate* (list (λ (x y) (and x y))
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(λ (x y) (or x y)))
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'((#f #t) (#f #t)))
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'((#f #f #f #f) (#f #t #f #t) (#t #f #f #t) (#t #t #t #t)))
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(check-equal? (tabulate* empty '((#f #t) (#f #t)))
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'((#f #f) (#f #t) (#t #f) (#t #t)))))
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;;; Like tabulate, but assumes the domains of all variables of the
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;;; function are Boolean. func must have a fixed arity. It is an
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;;; error to supply a function of variable arity.
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(define (tabulate/boolean func)
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(tabulate func (make-list (procedure-arity func) '(#f #t))))
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(module+ test
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(test-case "tabulate/boolean"
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(check-equal? (tabulate/boolean (lambda (x y) (and x y)))
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'((#f #f #f) (#f #t #f) (#t #f #f) (#t #t #t)))))
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;;; Like tabulate/boolean, but takes a list of functions of the same
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;;; arity.
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(define (tabulate*/boolean funcs)
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(define doms (make-list (procedure-arity (car funcs)) '(#f #t)))
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(tabulate* funcs doms))
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(module+ test
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(test-case "tabulate*/boolean"
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(check-equal? (tabulate*/boolean `(,(λ (x y) (and x y))
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,(λ (x y) (or x y))))
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'((#f #f #f #f) (#f #t #f #t) (#t #f #f #t) (#t #t #t #t)))))
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;;; Like tabulate, but assumes the domains of all variables of the
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;;; function are {0, 1}. func must have a fixed arity. It is an
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;;; error to supply a function of variable arity.
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(define (tabulate/01 func)
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(tabulate func (make-list (procedure-arity func) '(0 1))))
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(module+ test
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(test-case "tabulate/01"
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(check-equal? (tabulate/01 (λ (x y) (modulo (+ x y) 2)))
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'((0 0 0) (0 1 1) (1 0 1) (1 1 0)))))
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;;; Like tabulate/01, but takes a list of functions of the same arity.
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(define (tabulate*/01 funcs)
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(tabulate* funcs (make-list (procedure-arity (car funcs)) '(0 1))))
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(module+ test
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(test-case "tabulate*/01"
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(check-equal? (tabulate*/01 `(,(λ (x y) (min x y)) ,(λ (x y) (max x y))))
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'((0 0 0 0) (0 1 0 1) (1 0 0 1) (1 1 1 1)))))
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;;; ======================
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;;; Constructing functions
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;;; ======================
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;;; Given a table like the one produced by the tabulate functions,
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;;; creates a function which has this behaviour.
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;;;
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;;; More exactly, the input is a list of lists of values. All but the
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;;; last elements of every list give the values of the parameters of
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;;; the function, while the the last element of every list gives the
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;;; value of the function. Thus, every list should have at least two
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;;; elements.
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;;;
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;;; The produced function is implemented via lookups in hash tables,
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;;; meaning that it may be sometimes more expensive to compute than by
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;;; using an direct symbolic implementation.
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(define (table->function table)
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(let ([func (table->function/list table)])
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(λ args (func args))))
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(module+ test
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(test-case "table->function"
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(define negation (table->function '((#t #f) (#f #t))))
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(check-true (negation #f))
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(check-false (negation #t))))
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;;; Like table->function, but the produced function accepts a single
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;;; list of arguments instead of individual arguments.
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(define (table->function/list table)
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((curry hash-ref)
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(for/hash ([line table])
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(let-values ([(x fx) (split-at-right line 1)])
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(values x (car fx))))))
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(module+ test
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(test-case "table->function/list"
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(define negation/list (table->function/list '((#t #f) (#f #t))))
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(check-true (negation/list '(#f)))
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(check-false (negation/list '(#t)))))
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;;; Returns the stream of the truth tables of all Boolean functions of
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;;; a given arity.
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;;;
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;;; There are 2^(2^n) Boolean functions of arity n.
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(define (enumerate-boolean-tables n)
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(let ([inputs (boolean-power/stream n)]
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[outputs (boolean-power/stream (expt 2 n))])
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(for/stream ([out (in-stream outputs)])
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(for/list ([in (in-stream inputs)] [o out])
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(append in (list o))))))
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;;; Returns the stream of all Boolean functions of a given arity.
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;;;
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;;; There are 2^(2^n) Boolean functions of arity n.
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(define (enumerate-boolean-functions n)
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(stream-map table->function (enumerate-boolean-tables n)))
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(module+ test
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(test-case "enumerate-boolean-tables"
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(define f1 (stream-first (enumerate-boolean-functions 1)))
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(check-false (f1 #f))
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(check-false (f1 #t))))
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;;; Returns the stream of all Boolean functions of a given arity. As
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;;; different from the functions returned by
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;;; enumerate-boolean-functions, the functions take lists of arguments
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;;; instead of n arguments.
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;;;
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;;; There are 2^(2^n) Boolean functions of arity n.
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(define (enumerate-boolean-functions/list n)
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(stream-map table->function/list (enumerate-boolean-tables n)))
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(module+ test
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(test-case "enumerate-boolean-functions/list"
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(define f1/list (stream-first (enumerate-boolean-functions/list 1)))
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(check-false (f1/list '(#f)))
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(check-false (f1/list '(#t)))))
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;;; ================
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;;; Random functions
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;;; ================
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;;; Generates a random truth table for a Boolean function of arity n.
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(define (random-boolean-table n)
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(define/match (num->bool x) [(0) #f] [(1) #t])
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(define inputs (boolean-power n))
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(define outputs (stream-take (in-random 2) (expt 2 n)))
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(for/list ([i inputs] [o outputs])
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(append i (list (num->bool o)))))
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(module+ test
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(test-case "random-boolean-table"
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(random-seed 0)
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(check-equal? (random-boolean-table 2) '((#f #f #t) (#f #t #t) (#t #f #f) (#t #t #f)))))
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;;; Generates a random Boolean function of arity n.
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(define random-boolean-function (compose table->function random-boolean-table))
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(module+ test
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(test-case "random-boolean-function"
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(define f (random-boolean-function 2))
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(check-true (f #f #f)) (check-false (f #f #t))
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(check-true (f #t #f)) (check-false (f #t #t))))
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;;; Like random-boolean-function, but the constructed function takes a
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;;; list of arguments.
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(define random-boolean-function/list (compose table->function/list random-boolean-table))
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(module+ test
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(test-case "random-boolean-function/list"
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(define f (random-boolean-function/list 2))
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(check-false (f '(#f #f))) (check-true (f '(#f #t)))
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(check-true (f '(#t #f))) (check-false (f '(#t #t)))))
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;;; ===========================
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;;; Threshold Boolean functions
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;;; ===========================
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;;; A threshold Boolean function (TBF) is a pair (w, θ), where w is a
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;;; vector of weights and θ is the threshold.
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(struct tbf (weights threshold) #:transparent)
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;;; Unicode shortcuts for accessing the elements of a TBF.
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(define tbf-w tbf-weights)
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(define tbf-θ tbf-threshold)
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;;; Converts a Boolean vector to a 0-1 vector.
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(define (vector-boolean->01 bool-v)
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(vector-map any->01 bool-v))
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(module+ test
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(test-case "boolean->0-1"
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(check-equal? (vector-boolean->01 #(#t #f #f)) #(1 0 0))))
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;;; Applies the TBF to its inputs.
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;;;
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;;; Applying a TBF consists in multiplying the weights by the
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;;; corresponding inputs and comparing the sum of the products to the
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;;; threshold.
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(define (apply-tbf tbf inputs)
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(any->01
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(>
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;; The scalar product between the inputs and the weights
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(for/sum ([x (in-vector inputs)]
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[w (in-vector (tbf-w tbf))])
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(* x w))
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(tbf-θ tbf))))
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(module+ test
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(test-case "apply-tbf"
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(define f1 (tbf #(2 -2) 1))
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(check-equal? (tabulate/01 (λ (x y) (apply-tbf f1 (vector x y))))
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'((0 0 0) (0 1 0) (1 0 1) (1 1 0)))))
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;;; Like apply-tbf, but takes Boolean values as inputs and outputs a
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;;; boolean value.
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(define (apply-tbf/boolean tbf inputs)
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(01->boolean (apply-tbf tbf (vector-map any->01 inputs))))
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(module+ test
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(test-case "apply-tbf/boolean"
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(define f1 (tbf #(2 -2) 1))
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(check-equal? (tabulate/boolean (λ (x y) (apply-tbf/boolean f1 (vector x y))))
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'((#f #f #f) (#f #t #f) (#t #f #t) (#t #t #f)))))
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;;; Converts a list of numbers to a TBF. The last element of the list
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;;; is taken to be the threshold, while the other elements are taken
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;;; to be the weights.
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(define (list->tbf lst)
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(define-values (w θ) (split-at-right lst 1))
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(tbf (list->vector w) (car θ)))
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(module+ test
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(test-case "list->tbf"
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(check-equal? (list->tbf '(1 2 3)) (tbf #(1 2) 3))))
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;;; Reads a list of TBF from an Org-mode table read by
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;;; read-org-sexp.
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(define lists->tbfs ((curry map) list->tbf))
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(module+ test
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(test-case "read-tbfs"
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(check-equal? (lists->tbfs '((1 2 3) (2 3 4)))
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(list (tbf '#(1 2) 3) (tbf '#(2 3) 4)))))
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;;; Reads a list of TBF from an Org-mode string containing a sexp,
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;;; containing a list of lists of numbers. If headers is #t, drops
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;;; the first list, supposing that it contains the headers of the
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;;; table.
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;;;
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;;; The input is typically what read-org-sexp reads.
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(define (read-org-tbfs str #:headers [headers #f])
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(define sexp (read-org-sexp str))
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(define sexp-clean (cond [headers (cdr sexp)] [else sexp]))
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(lists->tbfs sexp-clean))
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(module+ test
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(test-case "read-org-tbfs"
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(check-equal? (read-org-tbfs "((1 2 1) (1 0 1))")
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(list (tbf '#(1 2) 1) (tbf '#(1 0) 1)))))
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;;; Tabulates a list of TBFs.
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;;;
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;;; The result is a list of lists describing the truth table of the
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;;; given TBFs. The first elements of each line give the values of
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;;; the inputs, while the last elements give the values of each the
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;;; functions corresponding to the input.
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;;;
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;;; All the TBFs in tbfs must have the same number of inputs as the
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;;; first TBF in the list. This function does not check this
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;;; condition.
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(define (tbf-tabulate* tbfs)
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(define funcs (for/list ([tbf tbfs])
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(λ in (apply-tbf tbf (list->vector in)))))
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(define nvars (vector-length (tbf-w (car tbfs))))
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(tabulate* funcs (make-list nvars '(0 1))))
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(module+ test
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(test-case "tbf-tabulate*"
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(check-equal? (tbf-tabulate* (list (tbf #(2 2) 1) (tbf #(1 1) 1)))
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'((0 0 0 0) (0 1 1 0) (1 0 1 0) (1 1 1 1)))))
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;;; Tabulates a TBF.
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(define tbf-tabulate (compose tbf-tabulate* list))
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(module+ test
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(test-case "tbf-tabulate"
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(check-equal? (tbf-tabulate (tbf #(1 2) 1))
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'((0 0 0) (0 1 1) (1 0 0) (1 1 1)))))
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;;; Tabulates a list of TBFs like tbf-boolean*, but uses Boolean
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;;; values #f and #t instead of 0 and 1.
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;;;
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;;; All the TBFs in tbfs must have the same number of inputs as the
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;;; first TBF in the list. This function does not check this
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;;; condition.
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(define (tbf-tabulate*/boolean tbfs)
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(define funcs (for/list ([tbf tbfs])
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(λ in (apply-tbf/boolean tbf (list->vector in)))))
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(define nvars (vector-length (tbf-w (car tbfs))))
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(tabulate* funcs (make-list nvars '(#f #t))))
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(module+ test
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(test-case "tbf-tabulate*/boolean"
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(check-equal? (tbf-tabulate*/boolean `(,(tbf #(1 2) 1)))
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'((#f #f #f) (#f #t #t) (#t #f #f) (#t #t #t)))))
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;;; A sign Boolean function (SBF) is a TBF whose threshold is 0.
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(define sbf? (and/c tbf? (λ (x) (= 0 (tbf-θ x)))))
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(module+ test
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(test-case "sbf?"
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(check-false (sbf? (tbf #(1 2) 3)))
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(check-true (sbf? (tbf #(1 2) 0)))))
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;;; Creates a TBF which is an SBF from a vector of weights.
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(define (sbf w) (tbf w 0))
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(module+ test
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(test-case "sbf"
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(check-equal? (sbf #(1 -1)) (tbf '#(1 -1) 0))))
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;;; Converts a list of numbers to an SBF. The elements of the list
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;;; are taken to be the weights of the SBF.
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(define list->sbf (compose sbf list->vector))
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(module+ test
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(test-case "list->sbf"
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(check-equal? (list->sbf '(1 -1)) (tbf '#(1 -1) 0))))
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;;; Reads a list of SBF from an Org-mode string containing a sexp,
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;;; containing a list of lists of numbers. If headers is #t, drops
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;;; the first list, supposing that it contains the headers of the
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;;; table.
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;;;
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;;; The input is typically what read-org-sexp reads.
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(define (read-org-sbfs str #:headers [headers #f])
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(define sexp (read-org-sexp str))
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(define sexp-clean (cond [headers (cdr sexp)] [else sexp]))
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(map list->sbf sexp-clean))
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(module+ test
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(test-case "read-org-sbfs"
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(check-equal? (read-org-sbfs "((1 1) (1 -1))")
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(list (tbf '#(1 1) 0) (tbf '#(1 -1) 0)))))
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