mirror of
https://github.com/janet-lang/janet
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308 lines
9.8 KiB
Clojure
308 lines
9.8 KiB
Clojure
# Copyright (c) 2019 Calvin Rose
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#
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# Permission is hereby granted, free of charge, to any person obtaining a copy
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# of this software and associated documentation files (the "Software"), to
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# deal in the Software without restriction, including without limitation the
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# rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
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# sell copies of the Software, and to permit persons to whom the Software is
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# furnished to do so, subject to the following conditions:
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#
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# The above copyright notice and this permission notice shall be included in
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# all copies or substantial portions of the Software.
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#
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# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
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# FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
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# IN THE SOFTWARE.
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(import test/helper :prefix "" :exit true)
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(start-suite 0)
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(assert (= 10 (+ 1 2 3 4)) "addition")
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(assert (= -8 (- 1 2 3 4)) "subtraction")
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(assert (= 24 (* 1 2 3 4)) "multiplication")
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(assert (= 4 (blshift 1 2)) "left shift")
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(assert (= 1 (brshift 4 2)) "right shift")
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(assert (< 1 2 3 4 5 6) "less than integers")
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(assert (< 1.0 2.0 3.0 4.0 5.0 6.0) "less than reals")
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(assert (> 6 5 4 3 2 1) "greater than integers")
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(assert (> 6.0 5.0 4.0 3.0 2.0 1.0) "greater than reals")
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(assert (<= 1 2 3 3 4 5 6) "less than or equal to integers")
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(assert (<= 1.0 2.0 3.0 3.0 4.0 5.0 6.0) "less than or equal to reals")
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(assert (>= 6 5 4 4 3 2 1) "greater than or equal to integers")
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(assert (>= 6.0 5.0 4.0 4.0 3.0 2.0 1.0) "greater than or equal to reals")
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(assert (= 7 (% 20 13)) "modulo 1")
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(assert (= -7 (% -20 13)) "modulo 2")
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(assert (order< 1.0 nil false true
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(fiber/new (fn [] 1))
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"hi"
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(quote hello)
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:hello
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(array 1 2 3)
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(tuple 1 2 3)
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(table "a" "b" "c" "d")
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(struct 1 2 3 4)
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(buffer "hi")
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(fn [x] (+ x x))
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print) "type ordering")
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(assert (= (string (buffer "123" "456")) (string @"123456")) "buffer literal")
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(assert (= (get {} 1) nil) "get nil from empty struct")
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(assert (= (get @{} 1) nil) "get nil from empty table")
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(assert (= (get {:boop :bap} :boop) :bap) "get non nil from struct")
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(assert (= (get @{:boop :bap} :boop) :bap) "get non nil from table")
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(assert (put @{} :boop :bap) "can add to empty table")
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(assert (put @{1 3} :boop :bap) "can add to non-empty table")
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(assert (not false) "false literal")
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(assert true "true literal")
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(assert (not nil) "nil literal")
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(assert (= 7 (bor 3 4)) "bit or")
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(assert (= 0 (band 3 4)) "bit and")
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(assert (= 0xFF (bxor 0x0F 0xF0)) "bit xor")
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(assert (= 0xF0 (bxor 0xFF 0x0F)) "bit xor 2")
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# Set global variables to prevent some possible compiler optimizations that defeat point of the test
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(var zero 0)
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(var one 1)
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(var two 2)
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(var three 3)
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(var plus +)
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(assert (= 22 (plus one (plus 1 2 two) (plus 8 (plus zero 1) 4 three))) "nested function calls")
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# String literals
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(assert (= "abcd" "\x61\x62\x63\x64") "hex escapes")
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(assert (= "\e" "\x1B") "escape character")
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(assert (= "\x09" "\t") "tab character")
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# McCarthy's 91 function
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(var f91 nil)
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(set f91 (fn [n] (if (> n 100) (- n 10) (f91 (f91 (+ n 11))))))
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(assert (= 91 (f91 10)) "f91(10) = 91")
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(assert (= 91 (f91 11)) "f91(11) = 91")
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(assert (= 91 (f91 20)) "f91(20) = 91")
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(assert (= 91 (f91 31)) "f91(31) = 91")
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(assert (= 91 (f91 100)) "f91(100) = 91")
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(assert (= 91 (f91 101)) "f91(101) = 91")
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(assert (= 92 (f91 102)) "f91(102) = 92")
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(assert (= 93 (f91 103)) "f91(103) = 93")
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(assert (= 94 (f91 104)) "f91(104) = 94")
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# Fibonacci
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(def fib (do (var fib nil) (set fib (fn [n] (if (< n 2) n (+ (fib (- n 1)) (fib (- n 2))))))))
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(def fib2 (fn fib2 [n] (if (< n 2) n (+ (fib2 (- n 1)) (fib2 (- n 2))))))
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(assert (= (fib 0) (fib2 0) 0) "fib(0)")
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(assert (= (fib 1) (fib2 1) 1) "fib(1)")
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(assert (= (fib 2) (fib2 2) 1) "fib(2)")
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(assert (= (fib 3) (fib2 3) 2) "fib(3)")
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(assert (= (fib 4) (fib2 4) 3) "fib(4)")
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(assert (= (fib 5) (fib2 5) 5) "fib(5)")
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(assert (= (fib 6) (fib2 6) 8) "fib(6)")
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(assert (= (fib 7) (fib2 7) 13) "fib(7)")
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(assert (= (fib 8) (fib2 8) 21) "fib(8)")
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(assert (= (fib 9) (fib2 9) 34) "fib(9)")
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(assert (= (fib 10) (fib2 10) 55) "fib(10)")
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# Closure in non function scope
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(def outerfun (fn [x y]
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(def c (do
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(def someval (+ 10 y))
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(def ctemp (if x (fn [] someval) (fn [] y)))
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ctemp
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))
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(+ 1 2 3 4 5 6 7)
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c))
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(assert (= ((outerfun 1 2)) 12) "inner closure 1")
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(assert (= ((outerfun nil 2)) 2) "inner closure 2")
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(assert (= ((outerfun false 3)) 3) "inner closure 3")
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(assert (= '(1 2 3) (quote (1 2 3)) (tuple 1 2 3)) "quote shorthand")
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((fn []
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(var accum 1)
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(var count 0)
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(while (< count 16)
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(set accum (blshift accum 1))
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(set count (+ 1 count)))
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(assert (= accum 65536) "loop in closure")))
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(var accum 1)
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(var count 0)
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(while (< count 16)
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(set accum (blshift accum 1))
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(set count (+ 1 count)))
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(assert (= accum 65536) "loop globally")
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(assert (= (struct 1 2 3 4 5 6 7 8) (struct 7 8 5 6 3 4 1 2)) "struct order does not matter 1")
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(assert (= (struct
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:apple 1
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6 :bork
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'(1 2 3) 5)
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(struct
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6 :bork
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'(1 2 3) 5
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:apple 1)) "struct order does not matter 2")
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# Symbol function
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(assert (= (symbol "abc" 1 2 3) 'abc123) "symbol function")
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# Fiber tests
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(def afiber (fiber/new (fn []
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(def x (yield))
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(error (string "hello, " x))) :ye))
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(resume afiber) # first resume to prime
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(def afiber-result (resume afiber "world!"))
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(assert (= afiber-result "hello, world!") "fiber error result")
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(assert (= (fiber/status afiber) :error) "fiber error status")
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# yield tests
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(def t (fiber/new (fn [&] (yield 1) (yield 2) 3)))
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(assert (= 1 (resume t)) "initial transfer to new fiber")
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(assert (= 2 (resume t)) "second transfer to fiber")
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(assert (= 3 (resume t)) "return from fiber")
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(assert (= (fiber/status t) :dead) "finished fiber is dead")
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# Var arg tests
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(def vargf (fn [more] (apply + more)))
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(assert (= 0 (vargf @[])) "var arg no arguments")
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(assert (= 1 (vargf @[1])) "var arg no packed arguments")
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(assert (= 3 (vargf @[1 2])) "var arg tuple size 1")
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(assert (= 10 (vargf @[1 2 3 4])) "var arg tuple size 2, 2 normal args")
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(assert (= 110 (vargf @[1 2 3 4 10 10 10 10 10 10 10 10 10 10])) "var arg large tuple")
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# Higher order functions
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(def compose (fn [f g] (fn [& xs] (f (apply g xs)))))
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(def -+ (compose - +))
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(def +- (compose + -))
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(assert (= (-+ 1 2 3 4) -10) "compose - +")
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(assert (= (+- 1 2 3 4) -8) "compose + -")
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(assert (= ((compose -+ +-) 1 2 3 4) 8) "compose -+ +-")
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(assert (= ((compose +- -+) 1 2 3 4) 10) "compose +- -+")
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# UTF-8
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#🐙🐙🐙🐙
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(def 🦊 :fox)
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(def 🐮 :cow)
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(assert (= (string "🐼" 🦊 🐮) "🐼foxcow") "emojis 🙉 :)")
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(assert (not= 🦊 "🦊") "utf8 strings are not symbols and vice versa")
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# Symbols with @ character
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(def @ 1)
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(assert (= @ 1) "@ symbol")
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(def @-- 2)
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(assert (= @-- 2) "@-- symbol")
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(def @hey 3)
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(assert (= @hey 3) "@hey symbol")
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# Merge sort
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# Imperative (and verbose) merge sort merge
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(defn merge
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[xs ys]
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(def ret @[])
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(def xlen (length xs))
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(def ylen (length ys))
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(var i 0)
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(var j 0)
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# Main merge
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(while (if (< i xlen) (< j ylen))
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(def xi (get xs i))
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(def yj (get ys j))
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(if (< xi yj)
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(do (array/push ret xi) (set i (+ i 1)))
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(do (array/push ret yj) (set j (+ j 1)))))
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# Push rest of xs
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(while (< i xlen)
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(def xi (get xs i))
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(array/push ret xi)
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(set i (+ i 1)))
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# Push rest of ys
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(while (< j ylen)
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(def yj (get ys j))
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(array/push ret yj)
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(set j (+ j 1)))
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ret)
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(assert (apply <= (merge @[1 3 5] @[2 4 6])) "merge sort merge 1")
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(assert (apply <= (merge @[1 2 3] @[4 5 6])) "merge sort merge 2")
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(assert (apply <= (merge @[1 3 5] @[2 4 6 6 6 9])) "merge sort merge 3")
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(assert (apply <= (merge '(1 3 5) @[2 4 6 6 6 9])) "merge sort merge 4")
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# Gensym tests
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(assert (not= (gensym) (gensym)) "two gensyms not equal")
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((fn []
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(def syms (table))
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(var count 0)
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(while (< count 128)
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(put syms (gensym) true)
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(set count (+ 1 count)))
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(assert (= (length syms) 128) "many symbols")))
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# Let
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(assert (= (let [a 1 b 2] (+ a b)) 3) "simple let")
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(assert (= (let [[a b] @[1 2]] (+ a b)) 3) "destructured let")
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(assert (= (let [[a [c d] b] @[1 (tuple 4 3) 2]] (+ a b c d)) 10) "double destructured let")
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# Macros
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(defn dub [x] (+ x x))
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(assert (= 2 (dub 1)) "defn macro")
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(do
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(defn trip [x] (+ x x x))
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(assert (= 3 (trip 1)) "defn macro triple"))
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(do
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(var i 0)
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(when true
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(++ i)
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(++ i)
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(++ i)
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(++ i)
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(++ i)
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(++ i))
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(assert (= i 6) "when macro"))
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# Denormal tables and structs
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(assert (= (length {1 2 nil 3}) 1) "nil key struct literal")
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(assert (= (length @{1 2 nil 3}) 1) "nil key table literal")
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(assert (= (length (struct 1 2 nil 3)) 1) "nil key struct ctor")
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(assert (= (length (table 1 2 nil 3)) 1) "nil key table ctor")
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(assert (= (length (struct (/ 0 0) 2 1 3)) 1) "nan key struct ctor")
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(assert (= (length (table (/ 0 0) 2 1 3)) 1) "nan key table ctor")
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(assert (= (length {1 2 nil 3}) 1) "nan key struct literal")
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(assert (= (length @{1 2 nil 3}) 1) "nan key table literal")
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(assert (= (length (struct 2 1 3 nil)) 1) "nil value struct ctor")
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(assert (= (length (table 2 1 3 nil)) 1) "nil value table ctor")
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(assert (= (length {1 2 3 nil}) 1) "nil value struct literal")
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(assert (= (length @{1 2 3 nil}) 1) "nil value table literal")
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# Regression Test
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(assert (= 1 (((compile '(fn [] 1) @{})))) "regression test")
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(end-suite)
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