(use ../src/jolt/api) (defn ct-eval [ctx s] (eval-string ctx s)) (print "CLJS Ported Tests") (print "1: math...") (let [ctx (init)] (assert (= 3 (ct-eval ctx "(+ 1 2)")) "+") (assert (= 1 (ct-eval ctx "(- 3 2)")) "-") (assert (= 6 (ct-eval ctx "(* 2 3)")) "*") (assert (= 3 (ct-eval ctx "(inc 2)")) "inc") (assert (= 1 (ct-eval ctx "(dec 2)")) "dec") (assert (= 1 (ct-eval ctx "(quot 5 3)")) "quot") (assert (= 2 (ct-eval ctx "(rem 5 3)")) "rem") (assert (= 2 (ct-eval ctx "(mod 5 3)")) "mod") (assert (= 3 (ct-eval ctx "(max 1 2 3)")) "max") (assert (= 1 (ct-eval ctx "(min 1 2 3)")) "min")) (print " ok") (print "2: predicates...") (let [ctx (init)] (assert (= true (ct-eval ctx "(nil? nil)")) "nil?") (assert (= false (ct-eval ctx "(nil? 1)")) "nil? false") (assert (= false (ct-eval ctx "(not true)")) "not") (assert (= true (ct-eval ctx "(not false)")) "not false") (assert (= true (ct-eval ctx "(some? 1)")) "some?") (assert (= true (ct-eval ctx "(number? 42)")) "number?") (assert (= true (ct-eval ctx "(fn? inc)")) "fn?") (assert (= true (ct-eval ctx "(keyword? :foo)")) "keyword?") (assert (= true (ct-eval ctx "(zero? 0)")) "zero?") (assert (= true (ct-eval ctx "(pos? 5)")) "pos?") (assert (= true (ct-eval ctx "(neg? -1)")) "neg?") (assert (= true (ct-eval ctx "(even? 4)")) "even?") (assert (= true (ct-eval ctx "(odd? 3)")) "odd?")) (print " ok") (print "3: comparison...") (let [ctx (init)] (assert (= true (ct-eval ctx "(= 1 1)")) "=") (assert (= false (ct-eval ctx "(= 1 2)")) "= false") (assert (= true (ct-eval ctx "(= 1 1 1)")) "= three") (assert (= true (ct-eval ctx "(not= 1 2)")) "not= true") (assert (= true (ct-eval ctx "(< 1 2)")) "<") (assert (= true (ct-eval ctx "(> 2 1)")) ">") (assert (= true (ct-eval ctx "(<= 1 1)")) "<=") (assert (= true (ct-eval ctx "(>= 2 2)")) ">=")) (print " ok") (print "4: vectors...") (let [ctx (init)] (assert (= :a (ct-eval ctx "(nth [:a :b :c :d] 0)")) "nth") (assert (= [1 2 3 4] (ct-eval ctx "(conj [1 2 3] 4)")) "conj") (assert (= 1 (ct-eval ctx "(first [1 2 3])")) "first") (assert (= [2 3] (ct-eval ctx "(rest [1 2 3])")) "rest") (assert (= 3 (ct-eval ctx "(count [1 2 3])")) "count")) (print " ok") (print "5: maps...") (let [ctx (init)] (assert (= 1 (ct-eval ctx "(get {:a 1} :a)")) "get") (assert (= nil (ct-eval ctx "(get {:a 1} :z)")) "get missing") (assert (= :d (ct-eval ctx "(get {:a 1} :z :d)")) "get default") (assert (= {:a 1 :b 2} (ct-eval ctx "(assoc {:a 1} :b 2)")) "assoc") (assert (= {:b 2} (ct-eval ctx "(dissoc {:a 1 :b 2} :a)")) "dissoc") (assert (= true (ct-eval ctx "(contains? {:a 1} :a)")) "contains?") (assert (= 3 (ct-eval ctx "(count {:a 1 :b 2 :c 3})")) "count") (assert (= 2 (ct-eval ctx "(count (keys {:a 1 :b 2}))")) "keys")) (print " ok") (print "6: sets...") (let [ctx (init)] (assert (= true (ct-eval ctx "(set? #{1 2 3})")) "set?") (assert (= #{1 2 3 4} (ct-eval ctx "(conj #{1 2 3} 4)")) "conj") (assert (= #{1 2} (ct-eval ctx "(disj #{1 2 3} 3)")) "disj") (assert (= 3 (ct-eval ctx "(count #{1 2 3})")) "count") (assert (= true (ct-eval ctx "(= #{1 2 3} #{3 2 1})")) "= order")) (print " ok") (print "7: seq ops...") (let [ctx (init)] (assert (= nil (ct-eval ctx "(seq [])")) "seq empty") (assert (= [2 3 4] (ct-eval ctx "(map inc [1 2 3])")) "map") (assert (= [2 3] (ct-eval ctx "(filter odd? [1 2 3 4])")) "filter") (assert (= 6 (ct-eval ctx "(reduce + [1 2 3])")) "reduce") (assert (= [1 2 3] (ct-eval ctx "(take 3 [1 2 3 4 5])")) "take") (assert (= [4 5] (ct-eval ctx "(drop 3 [1 2 3 4 5])")) "drop") (assert (= [3 2 1] (ct-eval ctx "(reverse [1 2 3])")) "reverse") (assert (= true (ct-eval ctx "(every? even? [2 4 6])")) "every?")) (print " ok") (print "8: atoms...") (let [ctx (init)] (assert (= 0 (ct-eval ctx "(deref (atom 0))")) "deref") (assert (= 1 (ct-eval ctx "(let [a (atom 0)] (swap! a inc) (deref a))")) "swap!") (assert (= true (ct-eval ctx "(atom? (atom 0))")) "atom?")) (print " ok") (print "9: special forms...") (let [ctx (init)] (assert (= 30 (ct-eval ctx "(let [x 10 y 20] (+ x y))")) "let") (assert (= :a (ct-eval ctx "(if true :a :b)")) "if true") (assert (= :b (ct-eval ctx "(if false :a :b)")) "if false") (assert (= 2 (ct-eval ctx "(do 1 2)")) "do") (assert (= 3 (ct-eval ctx "(loop [x 0] (if (< x 3) (recur (inc x)) x))")) "loop") (assert (= :caught (ct-eval ctx "(try (throw 42) (catch Exception e :caught))")) "try")) (print " ok") (print "10: macros...") (let [ctx (init)] (ct-eval ctx "(defn add [a b] (+ a b))") (assert (= 7 (ct-eval ctx "(add 3 4)")) "defn") (assert (= 42 (ct-eval ctx "(when true 42)")) "when") (assert (= 3 (ct-eval ctx "(and 1 2 3)")) "and") (assert (= 1 (ct-eval ctx "(or 1 2 3)")) "or") (assert (= 49 (ct-eval ctx "((fn [x] (* x x)) 7)")) "fn")) (print " ok") (print "11: higher-order...") (let [ctx (init)] (assert (= 3 (ct-eval ctx "((comp inc inc) 1)")) "comp") (assert (= 3 (ct-eval ctx "((partial + 1 2))")) "partial") (assert (= 5 (ct-eval ctx "((constantly 5) :anything)")) "constantly") (assert (= 3 (ct-eval ctx "((identity 3))")) "identity")) (print " ok") (print "12: constructors...") (let [ctx (init)] (assert (= [1 2 3] (ct-eval ctx "(vector 1 2 3)")) "vector") (assert (= {:a 1 :b 2} (ct-eval ctx "(hash-map :a 1 :b 2)")) "hash-map") (assert (= #{1 2 3} (ct-eval ctx "(hash-set 1 2 3)")) "hash-set") (assert (= {:a 1 :b 2 :c 3} (ct-eval ctx "(zipmap [:a :b :c] [1 2 3])")) "zipmap")) (print " ok")