# Copyright (c) 2023 Calvin Rose # # Permission is hereby granted, free of charge, to any person obtaining a copy # of this software and associated documentation files (the "Software"), to # deal in the Software without restriction, including without limitation the # rights to use, copy, modify, merge, publish, distribute, sublicense, and/or # sell copies of the Software, and to permit persons to whom the Software is # furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice shall be included in # all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING # FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS # IN THE SOFTWARE. (import ./helper :prefix "" :exit true) (start-suite) # Let # 807f981 (assert (= (let [a 1 b 2] (+ a b)) 3) "simple let") (assert (= (let [[a b] @[1 2]] (+ a b)) 3) "destructured let") (assert (= (let [[a [c d] b] @[1 (tuple 4 3) 2]] (+ a b c d)) 10) "double destructured let") # Macros # b305a7c (defn dub [x] (+ x x)) (assert (= 2 (dub 1)) "defn macro") (do (defn trip [x] (+ x x x)) (assert (= 3 (trip 1)) "defn macro triple")) (do (var i 0) (when true (++ i) (++ i) (++ i) (++ i) (++ i) (++ i)) (assert (= i 6) "when macro")) # Add truthy? to core # ded08b6 (assert (= true ;(map truthy? [0 "" true @{} {} [] '()])) "truthy values") (assert (= false ;(map truthy? [nil false])) "non-truthy values") ## Polymorphic comparison -- Issue #272 # 81d301a42 # confirm polymorphic comparison delegation to primitive comparators: (assert (= 0 (cmp 3 3)) "compare-primitive integers (1)") (assert (= -1 (cmp 3 5)) "compare-primitive integers (2)") (assert (= 1 (cmp "foo" "bar")) "compare-primitive strings") (assert (= 0 (compare 1 1)) "compare integers (1)") (assert (= -1 (compare 1 2)) "compare integers (2)") (assert (= 1 (compare "foo" "bar")) "compare strings (1)") (assert (compare< 1 2 3 4 5 6) "compare less than integers") (assert (not (compare> 1 2 3 4 5 6)) "compare not greater than integers") (assert (compare< 1.0 2.0 3.0 4.0 5.0 6.0) "compare less than reals") (assert (compare> 6 5 4 3 2 1) "compare greater than integers") (assert (compare> 6.0 5.0 4.0 3.0 2.0 1.0) "compare greater than reals") (assert (not (compare< 6.0 5.0 4.0 3.0 2.0 1.0)) "compare less than reals") (assert (compare<= 1 2 3 3 4 5 6) "compare less than or equal to integers") (assert (compare<= 1.0 2.0 3.0 3.0 4.0 5.0 6.0) "compare less than or equal to reals") (assert (compare>= 6 5 4 4 3 2 1) "compare greater than or equal to integers") (assert (compare>= 6.0 5.0 4.0 4.0 3.0 2.0 1.0) "compare greater than or equal to reals") (assert (compare< 1.0 nil false true (fiber/new (fn [] 1)) "hi" (quote hello) :hello (array 1 2 3) (tuple 1 2 3) (table "a" "b" "c" "d") (struct 1 2 3 4) (buffer "hi") (fn [x] (+ x x)) print) "compare type ordering") # test polymorphic compare with 'objects' (table/setproto) (def mynum @{:type :mynum :v 0 :compare (fn [self other] (case (type other) :number (cmp (self :v) other) :table (when (= (get other :type) :mynum) (cmp (self :v) (other :v)))))}) (let [n3 (table/setproto @{:v 3} mynum)] (assert (= 0 (compare 3 n3)) "compare num to object (1)") (assert (= -1 (compare n3 4)) "compare object to num (2)") (assert (= 1 (compare (table/setproto @{:v 4} mynum) n3)) "compare object to object") (assert (compare< 2 n3 4) "compare< poly") (assert (compare> 4 n3 2) "compare> poly") (assert (compare<= 2 3 n3 4) "compare<= poly") (assert (compare= 3 n3 (table/setproto @{:v 3} mynum)) "compare= poly") (assert (deep= (sorted @[4 5 n3 2] compare<) @[2 n3 4 5]) "polymorphic sort")) # Add any? predicate to core # 7478ad11 (assert (= nil (any? [])) "any? 1") (assert (= nil (any? [false nil])) "any? 2") (assert (= nil (any? [nil false])) "any? 3") (assert (= 1 (any? [1])) "any? 4") (assert (nan? (any? [nil math/nan nil])) "any? 5") (assert (= true (any? [nil nil false nil nil true nil nil nil nil false :a nil])) "any? 6") # Some higher order functions and macros # 5e2de33 (def my-array @[1 2 3 4 5 6]) (def x (if-let [x (get my-array 5)] x)) (assert (= x 6) "if-let") (def x (if-let [y (get @{} :key)] 10 nil)) (assert (not x) "if-let 2") (assert (= 14 (sum (map inc @[1 2 3 4]))) "sum map") (def myfun (juxt + - * /)) (assert (= [2 -2 2 0.5] (myfun 2)) "juxt") # Case statements # 5249228 (assert (= :six (case (+ 1 2 3) 1 :one 2 :two 3 :three 4 :four 5 :five 6 :six 7 :seven 8 :eight 9 :nine)) "case macro") (assert (= 7 (case :a :b 5 :c 6 :u 10 7)) "case with default") # Testing the seq, tabseq, catseq, and loop macros # 547529e (def xs (apply tuple (seq [x :range [0 10] :when (even? x)] (tuple (/ x 2) x)))) (assert (= xs '((0 0) (1 2) (2 4) (3 6) (4 8))) "seq macro 1") # 624be87c9 (def xs (apply tuple (seq [x :down [8 -2] :when (even? x)] (tuple (/ x 2) x)))) (assert (= xs '((4 8) (3 6) (2 4) (1 2) (0 0))) "seq macro 2") # Looping idea # 45f8db0 (def xs (seq [x :in [-1 0 1] y :in [-1 0 1] :when (not= x y 0)] (tuple x y))) (def txs (apply tuple xs)) (assert (= txs [[-1 -1] [-1 0] [-1 1] [0 -1] [0 1] [1 -1] [1 0] [1 1]]) "nested seq") # 515891b03 (assert (deep= (tabseq [i :in (range 3)] i (* 3 i)) @{0 0 1 3 2 6})) (assert (deep= (tabseq [i :in (range 3)] i) @{})) # ccd874fe4 (def xs (catseq [x :range [0 3]] [x x])) (assert (deep= xs @[0 0 1 1 2 2]) "catseq") # :range-to and :down-to # e0c9910d8 (assert (deep= (seq [x :range-to [0 10]] x) (seq [x :range [0 11]] x)) "loop :range-to") (assert (deep= (seq [x :down-to [10 0]] x) (seq [x :down [10 -1]] x)) "loop :down-to") # 7880d7320 (def res @{}) (loop [[k v] :pairs @{1 2 3 4 5 6}] (put res k v)) (assert (and (= (get res 1) 2) (= (get res 3) 4) (= (get res 5) 6)) "loop :pairs") # Issue #428 # 08a3687eb (var result nil) (defn f [] (yield {:a :ok})) (assert-no-error "issue 428 1" (loop [{:a x} :in (fiber/new f)] (set result x))) (assert (= result :ok) "issue 428 2") # Generators # 184fe31e0 (def gen (generate [x :range [0 100] :when (pos? (% x 4))] x)) (var gencount 0) (loop [x :in gen] (++ gencount) (assert (pos? (% x 4)) "generate in loop")) (assert (= gencount 75) "generate loop count") # Even and odd # ff163a5ae (assert (odd? 9) "odd? 1") (assert (odd? -9) "odd? 2") (assert (not (odd? 10)) "odd? 3") (assert (not (odd? 0)) "odd? 4") (assert (not (odd? -10)) "odd? 5") (assert (not (odd? 1.1)) "odd? 6") (assert (not (odd? -0.1)) "odd? 7") (assert (not (odd? -1.1)) "odd? 8") (assert (not (odd? -1.6)) "odd? 9") (assert (even? 10) "even? 1") (assert (even? -10) "even? 2") (assert (even? 0) "even? 3") (assert (not (even? 9)) "even? 4") (assert (not (even? -9)) "even? 5") (assert (not (even? 0.1)) "even? 6") (assert (not (even? -0.1)) "even? 7") (assert (not (even? -10.1)) "even? 8") (assert (not (even? -10.6)) "even? 9") # Map arities # 25ded775a (assert (deep= (map inc [1 2 3]) @[2 3 4])) (assert (deep= (map + [1 2 3] [10 20 30]) @[11 22 33])) (assert (deep= (map + [1 2 3] [10 20 30] [100 200 300]) @[111 222 333])) (assert (deep= (map + [1 2 3] [10 20 30] [100 200 300] [1000 2000 3000]) @[1111 2222 3333])) (assert (deep= (map + [1 2 3] [10 20 30] [100 200 300] [1000 2000 3000] [10000 20000 30000]) @[11111 22222 33333])) # 77e62a2 (assert (deep= (map + [1 2 3] [10 20 30] [100 200 300] [1000 2000 3000] [10000 20000 30000] [100000 200000 300000]) @[111111 222222 333333])) # Mapping uses the shortest sequence # a69799aa4 (assert (deep= (map + [1 2 3 4] [10 20 30]) @[11 22 33])) (assert (deep= (map + [1 2 3 4] [10 20 30] [100 200]) @[111 222])) (assert (deep= (map + [1 2 3 4] [10 20 30] [100 200] [1000]) @[1111])) # 77e62a2 (assert (deep= (map + [1 2 3 4] [10 20 30] [100 200] [1000] []) @[])) # Variadic arguments to map-like functions # 77e62a2 (assert (deep= (mapcat tuple [1 2 3 4] [5 6 7 8]) @[1 5 2 6 3 7 4 8])) (assert (deep= (keep |(if (> $1 0) (/ $0 $1)) [1 2 3 4 5] [1 2 1 0 1]) @[1 1 3 5])) (assert (= (count = [1 3 2 4 3 5 4 2 1] [1 2 3 4 5 4 3 2 1]) 4)) (assert (= (some not= (range 5) (range 5)) nil)) (assert (= (some = [1 2 3 4 5] [5 4 3 2 1]) true)) (assert (= (all = (range 5) (range 5)) true)) (assert (= (all not= [1 2 3 4 5] [5 4 3 2 1]) false)) # 4194374 (assert (= false (deep-not= [1] [1])) "issue #1149") # Merge sort # f5b29b8 # Imperative (and verbose) merge sort merge (defn merge-sort [xs ys] (def ret @[]) (def xlen (length xs)) (def ylen (length ys)) (var i 0) (var j 0) # Main merge (while (if (< i xlen) (< j ylen)) (def xi (get xs i)) (def yj (get ys j)) (if (< xi yj) (do (array/push ret xi) (set i (+ i 1))) (do (array/push ret yj) (set j (+ j 1))))) # Push rest of xs (while (< i xlen) (def xi (get xs i)) (array/push ret xi) (set i (+ i 1))) # Push rest of ys (while (< j ylen) (def yj (get ys j)) (array/push ret yj) (set j (+ j 1))) ret) (assert (apply <= (merge-sort @[1 3 5] @[2 4 6])) "merge sort merge 1") (assert (apply <= (merge-sort @[1 2 3] @[4 5 6])) "merge sort merge 2") (assert (apply <= (merge-sort @[1 3 5] @[2 4 6 6 6 9])) "merge sort merge 3") (assert (apply <= (merge-sort '(1 3 5) @[2 4 6 6 6 9])) "merge sort merge 4") (assert (deep= @[1 2 3 4 5] (sort @[5 3 4 1 2])) "sort 1") (assert (deep= @[{:a 1} {:a 4} {:a 7}] (sort-by |($ :a) @[{:a 4} {:a 7} {:a 1}])) "sort 2") (assert (deep= @[1 2 3 4 5] (sorted [5 3 4 1 2])) "sort 3") (assert (deep= @[{:a 1} {:a 4} {:a 7}] (sorted-by |($ :a) [{:a 4} {:a 7} {:a 1}])) "sort 4") # Sort function # 2ca9300bf (assert (deep= (range 99) (sort (mapcat (fn [[x y z]] [z y x]) (partition 3 (range 99))))) "sort 5") (assert (<= ;(sort (map (fn [x] (math/random)) (range 1000)))) "sort 6") # And and or # c16a9d846 (assert (= (and true true) true) "and true true") (assert (= (and true false) false) "and true false") (assert (= (and false true) false) "and false true") (assert (= (and true true true) true) "and true true true") (assert (= (and 0 1 2) 2) "and 0 1 2") (assert (= (and 0 1 nil) nil) "and 0 1 nil") (assert (= (and 1) 1) "and 1") (assert (= (and) true) "and with no arguments") (assert (= (and 1 true) true) "and with trailing true") (assert (= (and 1 true 2) 2) "and with internal true") (assert (= (or true true) true) "or true true") (assert (= (or true false) true) "or true false") (assert (= (or false true) true) "or false true") (assert (= (or false false) false) "or false true") (assert (= (or true true false) true) "or true true false") (assert (= (or 0 1 2) 0) "or 0 1 2") (assert (= (or nil 1 2) 1) "or nil 1 2") (assert (= (or 1) 1) "or 1") (assert (= (or) nil) "or with no arguments") # And/or checks # 6123c41f1 (assert (= false (and false false)) "and 1") (assert (= false (or false false)) "or 1") # Range # a982f351d (assert (deep= (range 10) @[0 1 2 3 4 5 6 7 8 9]) "range 1 argument") (assert (deep= (range 5 10) @[5 6 7 8 9]) "range 2 arguments") (assert (deep= (range 5 10 2) @[5 7 9]) "range 3 arguments") # 11cd1279d (assert (= (length (range 10)) 10) "(range 10)") (assert (= (length (range 1 10)) 9) "(range 1 10)") (assert (deep= @{:a 1 :b 2 :c 3} (zipcoll '[:a :b :c] '[1 2 3])) "zipcoll") # bc8be266f (def- a 100) (assert (= a 100) "def-") # bc8be266f (assert (= :first (match @[1 3 5] @[x y z] :first :second)) "match 1") (def val1 :avalue) (assert (= :second (match val1 @[x y z] :first :avalue :second :third)) "match 2") (assert (= 100 (match @[50 40] @[x x] (* x 3) @[x y] (+ x y 10) 0)) "match 3") # Match checks # 47e8f669f (assert (= :hi (match nil nil :hi)) "match 1") (assert (= :hi (match {:a :hi} {:a a} a)) "match 2") (assert (= nil (match {:a :hi} {:a a :b b} a)) "match 3") (assert (= nil (match [1 2] [a b c] a)) "match 4") (assert (= 2 (match [1 2] [a b] b)) "match 5") # db631097b (assert (= [2 :a :b] (match [1 2 :a :b] [o & rest] rest)) "match 6") (assert (= [] (match @[:a] @[x & r] r :fallback)) "match 7") (assert (= :fallback (match @[1] @[x y & r] r :fallback)) "match 8") (assert (= [1 2 3 4] (match @[1 2 3 4] @[x y z & r] [x y z ;r] :fallback)) "match 9") # Test cases for #293 # d3b9b8d45 (assert (= :yes (match [1 2 3] [_ a _] :yes :no)) "match wildcard 1") (assert (= :no (match [1 2 3] [__ a __] :yes :no)) "match wildcard 2") (assert (= :yes (match [1 2 [1 2 3]] [_ a [_ _ _]] :yes :no)) "match wildcard 3") (assert (= :yes (match [1 2 3] (_ (even? 2)) :yes :no)) "match wildcard 4") (assert (= :yes (match {:a 1} {:a _} :yes :no)) "match wildcard 5") (assert (= false (match {:a 1 :b 2 :c 3} {:a a :b _ :c _ :d _} :no {:a _ :b _ :c _} false :no)) "match wildcard 6") (assert (= nil (match {:a 1 :b 2 :c 3} {:a a :b _ :c _ :d _} :no {:a _ :b _ :c _} nil :no)) "match wildcard 7") # issue #529 - 602010600 (assert (= "t" (match [true nil] [true _] "t")) "match wildcard 8") # quoted match test # 425a0fcf0 (assert (= :yes (match 'john 'john :yes _ :nope)) "quoted literal match 1") (assert (= :nope (match 'john ''john :yes _ :nope)) "quoted literal match 2") # Some macros # 7880d7320 (assert (= 2 (if-not 1 3 2)) "if-not 1") (assert (= 3 (if-not false 3)) "if-not 2") (assert (= 3 (if-not nil 3 2)) "if-not 3") (assert (= nil (if-not true 3)) "if-not 4") (assert (= 4 (unless false (+ 1 2 3) 4)) "unless") # take # 18da183ef (assert (deep= (take 0 []) []) "take 1") (assert (deep= (take 10 []) []) "take 2") (assert (deep= (take 0 [1 2 3 4 5]) []) "take 3") (assert (deep= (take 10 [1 2 3]) [1 2 3]) "take 4") (assert (deep= (take -1 [:a :b :c]) [:c]) "take 5") # 34019222c (assert (deep= (take 3 (generate [x :in [1 2 3 4 5]] x)) @[1 2 3]) "take from fiber") # NB: repeatedly resuming a fiber created with `generate` includes a `nil` # as the final element. Thus a generate of 2 elements will create an array # of 3. (assert (= (length (take 4 (generate [x :in [1 2]] x))) 2) "take from short fiber") # take-until # 18da183ef (assert (deep= (take-until pos? @[]) []) "take-until 1") (assert (deep= (take-until pos? @[1 2 3]) []) "take-until 2") (assert (deep= (take-until pos? @[-1 -2 -3]) [-1 -2 -3]) "take-until 3") (assert (deep= (take-until pos? @[-1 -2 3]) [-1 -2]) "take-until 4") (assert (deep= (take-until pos? @[-1 1 -2]) [-1]) "take-until 5") (assert (deep= (take-until |(= $ 115) "books") "book") "take-until 6") (assert (deep= (take-until |(= $ 115) (generate [x :in "books"] x)) @[98 111 111 107]) "take-until from fiber") # take-while # 18da183ef (assert (deep= (take-while neg? @[]) []) "take-while 1") (assert (deep= (take-while neg? @[1 2 3]) []) "take-while 2") (assert (deep= (take-while neg? @[-1 -2 -3]) [-1 -2 -3]) "take-while 3") (assert (deep= (take-while neg? @[-1 -2 3]) [-1 -2]) "take-while 4") (assert (deep= (take-while neg? @[-1 1 -2]) [-1]) "take-while 5") (assert (deep= (take-while neg? (generate [x :in @[-1 1 -2]] x)) @[-1]) "take-while from fiber") # drop # 18da183ef (assert (deep= (drop 0 []) []) "drop 1") (assert (deep= (drop 10 []) []) "drop 2") (assert (deep= (drop 0 [1 2 3 4 5]) [1 2 3 4 5]) "drop 3") (assert (deep= (drop 10 [1 2 3]) []) "drop 4") (assert (deep= (drop -1 [1 2 3]) [1 2]) "drop 5") (assert (deep= (drop -10 [1 2 3]) []) "drop 6") (assert (deep= (drop 1 "abc") "bc") "drop 7") (assert (deep= (drop 10 "abc") "") "drop 8") (assert (deep= (drop -1 "abc") "ab") "drop 9") (assert (deep= (drop -10 "abc") "") "drop 10") # drop-until # 75dc08f (assert (deep= (drop-until pos? @[]) []) "drop-until 1") (assert (deep= (drop-until pos? @[1 2 3]) [1 2 3]) "drop-until 2") (assert (deep= (drop-until pos? @[-1 -2 -3]) []) "drop-until 3") (assert (deep= (drop-until pos? @[-1 -2 3]) [3]) "drop-until 4") (assert (deep= (drop-until pos? @[-1 1 -2]) [1 -2]) "drop-until 5") (assert (deep= (drop-until |(= $ 115) "books") "s") "drop-until 6") # take-drop symmetry #1178 (def items-list ['abcde :abcde "abcde" @"abcde" [1 2 3 4 5] @[1 2 3 4 5]]) (each items items-list (def len (length items)) (for i 0 (+ len 1) (assert (deep= (take i items) (drop (- i len) items)) (string/format "take-drop symmetry %q %d" items i)) (assert (deep= (take (- i) items) (drop (- len i) items)) (string/format "take-drop symmetry %q %d" items i)))) (defn squares [] (coro (var [a b] [0 1]) (forever (yield a) (+= a b) (+= b 2)))) (def sqr1 (squares)) (assert (deep= (take 10 sqr1) @[0 1 4 9 16 25 36 49 64 81])) (assert (deep= (take 1 sqr1) @[100]) "take fiber next value") (def sqr2 (drop 10 (squares))) (assert (deep= (take 1 sqr2) @[100]) "drop fiber next value") (def dict @{:a 1 :b 2 :c 3 :d 4 :e 5}) (def dict1 (take 2 dict)) (def dict2 (drop 2 dict)) (assert (= (length dict1) 2) "take dictionary") (assert (= (length dict2) 3) "drop dictionary") (assert (deep= (merge dict1 dict2) dict) "take-drop symmetry for dictionary") # Comment macro # issue #110 - 698e89aba (comment 1) (comment 1 2) (comment 1 2 3) (comment 1 2 3 4) # comp should be variadic # 5c83ebd75, 02ce3031 (assert (= 10 ((comp +) 1 2 3 4)) "variadic comp 1") (assert (= 11 ((comp inc +) 1 2 3 4)) "variadic comp 2") (assert (= 12 ((comp inc inc +) 1 2 3 4)) "variadic comp 3") (assert (= 13 ((comp inc inc inc +) 1 2 3 4)) "variadic comp 4") (assert (= 14 ((comp inc inc inc inc +) 1 2 3 4)) "variadic comp 5") (assert (= 15 ((comp inc inc inc inc inc +) 1 2 3 4)) "variadic comp 6") (assert (= 16 ((comp inc inc inc inc inc inc +) 1 2 3 4)) "variadic comp 7") # Function shorthand # 44e752d73 (assert (= (|(+ 1 2 3)) 6) "function shorthand 1") (assert (= (|(+ 1 2 3 $) 4) 10) "function shorthand 2") (assert (= (|(+ 1 2 3 $0) 4) 10) "function shorthand 3") (assert (= (|(+ $0 $0 $0 $0) 4) 16) "function shorthand 4") (assert (= (|(+ $ $ $ $) 4) 16) "function shorthand 5") (assert (= (|4) 4) "function shorthand 6") (assert (= (((|||4))) 4) "function shorthand 7") (assert (= (|(+ $1 $1 $1 $1) 2 4) 16) "function shorthand 8") (assert (= (|(+ $0 $1 $3 $2 $6) 0 1 2 3 4 5 6) 12) "function shorthand 9") # 5f5147652 (assert (= (|(+ $0 $99) ;(range 100)) 99) "function shorthand 10") # 655d4b3aa (defn idx= [x y] (= (tuple/slice x) (tuple/slice y))) # Simple take, drop, etc. tests. (assert (idx= (take 10 (range 100)) (range 10)) "take 10") (assert (idx= (drop 10 (range 100)) (range 10 100)) "drop 10") # with-vars # 6ceaf9d28 (var abc 123) (assert (= 356 (with-vars [abc 456] (- abc 100))) "with-vars 1") (assert-error "with-vars 2" (with-vars [abc 456] (error :oops))) (assert (= abc 123) "with-vars 3") # Top level unquote # 2487162cc (defn constantly [] (comptime (math/random))) (assert (= (constantly) (constantly)) "comptime 1") # issue #232 - b872ee024 (assert-error "arity issue in macro" (eval '(each []))) # c6b639b93 (assert-error "comptime issue" (eval '(comptime (error "oops")))) # 962cd7e5f (var counter 0) (when-with [x nil |$] (++ counter)) (when-with [x 10 |$] (+= counter 10)) (assert (= 10 counter) "when-with 1") (if-with [x nil |$] (++ counter) (+= counter 10)) (if-with [x true |$] (+= counter 20) (+= counter 30)) (assert (= 40 counter) "if-with 1") # a45509d28 (def a @[]) (eachk x [:a :b :c :d] (array/push a x)) (assert (deep= (range 4) a) "eachk 1") # issue 609 - 1fcaffe (with-dyns [:err @""] (tracev (def my-unique-var-name true)) (assert my-unique-var-name "tracev upscopes")) # Prompts and Labels # 59d288c (assert (= 10 (label a (for i 0 10 (if (= i 5) (return a 10))))) "label 1") (defn recur [lab x y] (when (= x y) (return lab :done)) (def res (label newlab (recur (or lab newlab) (+ x 1) y))) (if lab :oops res)) (assert (= :done (recur nil 0 10)) "label 2") (assert (= 10 (prompt :a (for i 0 10 (if (= i 5) (return :a 10))))) "prompt 1") (defn- inner-loop [i] (if (= i 5) (return :a 10))) (assert (= 10 (prompt :a (for i 0 10 (inner-loop i)))) "prompt 2") (defn- inner-loop2 [i] (try (if (= i 5) (error 10)) ([err] (return :a err)))) (assert (= 10 (prompt :a (for i 0 10 (inner-loop2 i)))) "prompt 3") # chr # issue 304 - 77343e02e (assert (= (chr "a") 97) "chr 1") # Reduce2 # 3eb0927a2 (assert (= (reduce + 0 (range 1 10)) (reduce2 + (range 10))) "reduce2 1") # 65379741f (assert (= (reduce * 1 (range 2 10)) (reduce2 * (range 1 10))) "reduce2 2") (assert (= nil (reduce2 * [])) "reduce2 3") # Accumulate # 3eb0927a2 (assert (deep= (accumulate + 0 (range 5)) @[0 1 3 6 10]) "accumulate 1") (assert (deep= (accumulate2 + (range 5)) @[0 1 3 6 10]) "accumulate2 1") # 65379741f (assert (deep= @[] (accumulate2 + [])) "accumulate2 2") (assert (deep= @[] (accumulate 0 + [])) "accumulate 2") # in vs get regression # issue #340 - b63a0796f (assert (nil? (first @"")) "in vs get 1") (assert (nil? (last @"")) "in vs get 1") # index-of # 259812314 (assert (= nil (index-of 10 [])) "index-of 1") (assert (= nil (index-of 10 [1 2 3])) "index-of 2") (assert (= 1 (index-of 2 [1 2 3])) "index-of 3") (assert (= 0 (index-of :a [:a :b :c])) "index-of 4") (assert (= nil (index-of :a {})) "index-of 5") (assert (= :a (index-of :A {:a :A :b :B})) "index-of 6") (assert (= :a (index-of :A @{:a :A :b :B})) "index-of 7") (assert (= 0 (index-of (chr "a") "abc")) "index-of 8") (assert (= nil (index-of (chr "a") "")) "index-of 9") (assert (= nil (index-of 10 @[])) "index-of 10") (assert (= nil (index-of 10 @[1 2 3])) "index-of 11") # e78a3d1 # NOTE: These is a motivation for the has-value? and has-key? functions below # returns false despite key present (assert (= false (index-of 8 {true 7 false 8})) "index-of corner key (false) 1") (assert (= false (index-of 8 @{false 8})) "index-of corner key (false) 2") # still returns null (assert (= nil (index-of 7 {false 8})) "index-of corner key (false) 3") # has-value? (assert (= false (has-value? [] "foo")) "has-value? 1") (assert (= true (has-value? [4 7 1 3] 4)) "has-value? 2") (assert (= false (has-value? [4 7 1 3] 22)) "has-value? 3") (assert (= false (has-value? @[1 2 3] 4)) "has-value? 4") (assert (= true (has-value? @[:a :b :c] :a)) "has-value? 5") (assert (= false (has-value? {} :foo)) "has-value? 6") (assert (= true (has-value? {:a :A :b :B} :A)) "has-value? 7") (assert (= true (has-value? {:a :A :b :B} :A)) "has-value? 7") (assert (= true (has-value? @{:a :A :b :B} :A)) "has-value? 8") (assert (= true (has-value? "abc" (chr "a"))) "has-value? 9") (assert (= false (has-value? "abc" "1")) "has-value? 10") # weird true/false corner cases, should align with "index-of corner # key {k}" cases (assert (= true (has-value? {true 7 false 8} 8)) "has-value? corner key (false) 1") (assert (= true (has-value? @{false 8} 8)) "has-value? corner key (false) 2") (assert (= false (has-value? {false 8} 7)) "has-value? corner key (false) 3") # has-key? (do (var test-has-key-auto 0) (defn test-has-key [col key expected &keys {:name name}] ``Test that has-key has the outcome `expected`, and that if the result is true, then ensure (in key) does not fail either`` (assert (boolean? expected)) (default name (string "has-key? " (++ test-has-key-auto))) (assert (= expected (has-key? col key)) name) (if # guarenteed by `has-key?` to never fail expected (in col key) # if `has-key?` is false, then `in` should fail (for indexed types) # # For dictionary types, it should return nil (let [[success retval] (protect (in col key))] (def should-succeed (dictionary? col)) (assert (= success should-succeed) (string/format "%s: expected (in col key) to %s, but got %q" name (if expected "succeed" "fail") retval))))) (test-has-key [] 0 false) # 1 (test-has-key [4 7 1 3] 2 true) # 2 (test-has-key [4 7 1 3] 22 false) # 3 (test-has-key @[1 2 3] 4 false) # 4 (test-has-key @[:a :b :c] 2 true) # 5 (test-has-key {} :foo false) # 6 (test-has-key {:a :A :b :B} :a true) # 7 (test-has-key {:a :A :b :B} :A false) # 8 (test-has-key @{:a :A :b :B} :a true) # 9 (test-has-key "abc" 1 true) # 10 (test-has-key "abc" 4 false) # 11 # weird true/false corner cases # # Tries to mimic the corresponding corner cases in has-value? and # index-of, but with keys/values inverted # # in the first two cases (truthy? (get val col)) would have given false # negatives (test-has-key {7 true 8 false} 8 true :name "has-key? corner value (false) 1") (test-has-key @{8 false} 8 true :name "has-key? corner value (false) 2") (test-has-key @{8 false} 7 false :name "has-key? corner value (false) 3")) # Regression # issue #463 - 7e7498350 (assert (= {:x 10} (|(let [x $] ~{:x ,x}) 10)) "issue 463") # macex testing # 7e7498350 (assert (deep= (macex1 '~{1 2 3 4}) '~{1 2 3 4}) "macex1 qq struct") (assert (deep= (macex1 '~@{1 2 3 4}) '~@{1 2 3 4}) "macex1 qq table") (assert (deep= (macex1 '~(1 2 3 4)) '~[1 2 3 4]) "macex1 qq tuple") (assert (= :brackets (tuple/type (1 (macex1 '~[1 2 3 4])))) "macex1 qq bracket tuple") (assert (deep= (macex1 '~@[1 2 3 4 ,blah]) '~@[1 2 3 4 ,blah]) "macex1 qq array") # Sourcemaps in threading macros # b6175e429 (defn check-threading [macro expansion] (def expanded (macex1 (tuple macro 0 '(x) '(y)))) (assert (= expanded expansion) (string macro " expansion value")) (def smap-x (tuple/sourcemap (get expanded 1))) (def smap-y (tuple/sourcemap expanded)) (def line first) (defn column [t] (t 1)) (assert (not= smap-x [-1 -1]) (string macro " x sourcemap existence")) (assert (not= smap-y [-1 -1]) (string macro " y sourcemap existence")) (assert (or (< (line smap-x) (line smap-y)) (and (= (line smap-x) (line smap-y)) (< (column smap-x) (column smap-y)))) (string macro " relation between x and y sourcemap"))) (check-threading '-> '(y (x 0))) (check-threading '->> '(y (x 0))) # keep-syntax # b6175e429 (let [brak '[1 2 3] par '(1 2 3)] (tuple/setmap brak 2 1) (assert (deep= (keep-syntax brak @[1 2 3]) @[1 2 3]) "keep-syntax brackets ignore array") (assert (= (keep-syntax! brak @[1 2 3]) '[1 2 3]) "keep-syntax! brackets replace array") (assert (= (keep-syntax! par (map inc @[1 2 3])) '(2 3 4)) "keep-syntax! parens coerce array") (assert (not= (keep-syntax! brak @[1 2 3]) '(1 2 3)) "keep-syntax! brackets not parens") (assert (not= (keep-syntax! par @[1 2 3]) '[1 2 3]) "keep-syntax! parens not brackets") (assert (= (tuple/sourcemap brak) (tuple/sourcemap (keep-syntax! brak @[1 2 3]))) "keep-syntax! brackets source map") (keep-syntax par brak) (assert (not= (tuple/sourcemap brak) (tuple/sourcemap par)) "keep-syntax no mutate") (assert (= (keep-syntax 1 brak) brak) "keep-syntax brackets ignore type")) # Curenv # 28439d822, f7c556e (assert (= (curenv) (curenv 0)) "curenv 1") (assert (= (table/getproto (curenv)) (curenv 1)) "curenv 2") (assert (= nil (curenv 1000000)) "curenv 3") (assert (= root-env (curenv 1)) "curenv 4") # Import macro test # a31e079f9 (assert-no-error "import macro 1" (macex '(import a :as b :fresh maybe))) (assert (deep= ~(,import* "a" :as "b" :fresh maybe) (macex '(import a :as b :fresh maybe))) "import macro 2") # #477 walk preserving bracket type # 0a1d902f4 (assert (= :brackets (tuple/type (postwalk identity '[]))) "walk square brackets 1") (assert (= :brackets (tuple/type (walk identity '[]))) "walk square brackets 2") # Issue #751 # 547fda6a4 (def t {:side false}) (assert (nil? (get-in t [:side :note])) "get-in with false value") (assert (= (get-in t [:side :note] "dflt") "dflt") "get-in with false value and default") # Evaluate stream with `dofile` # 9cc4e4812 (def [r w] (os/pipe)) (:write w "(setdyn :x 10)") (:close w) (def stream-env (dofile r)) (assert (= (stream-env :x) 10) "dofile stream 1") # Test thaw and freeze # 9cc0645a1 (def table-to-freeze @{:c 22 :b [1 2 3 4] :d @"test" :e "test2"}) (def table-to-freeze-with-inline-proto @{:a @[1 2 3] :b @[1 2 3 4] :c 22 :d @"test" :e @"test2"}) (def struct-to-thaw (struct/with-proto {:a [1 2 3]} :c 22 :b [1 2 3 4] :d "test" :e "test2")) (table/setproto table-to-freeze @{:a @[1 2 3]}) (assert (deep= {:a [1 2 3] :b [1 2 3 4] :c 22 :d "test" :e "test2"} (freeze table-to-freeze))) (assert (deep= table-to-freeze-with-inline-proto (thaw table-to-freeze))) (assert (deep= table-to-freeze-with-inline-proto (thaw struct-to-thaw))) # Make sure Carriage Returns don't end up in doc strings # e528b86 (assert (not (string/find "\r" (get ((fiber/getenv (fiber/current)) 'cond) :doc ""))) "no \\r in doc strings") # cff718f37 (var counter 0) (def thunk (delay (++ counter))) (assert (= (thunk) 1) "delay 1") (assert (= counter 1) "delay 2") (assert (= (thunk) 1) "delay 3") (assert (= counter 1) "delay 4") (end-suite)