test: fold ported-clojure batteries into spec

Mine the remaining integration 'ported Clojure' batteries into the spec layer
and delete them (clojure-atom/control/for/logic/macros, core, logic). A broad
function-coverage diff confirmed they exercised no clojure.core fn the spec
lacked; their distinctive value was the truthiness/boolean contract, now
captured in a dedicated spec.

New/expanded spec coverage:
- spec/truthiness-spec: only nil/false are falsy (0, "", [], {}, #{} are truthy);
  not / and / or return-value & short-circuit semantics; if-not/when-not/boolean
- assert (exceptions-spec), get-validator (state-spec)

Layout now: spec 23 files / 732 cases; integration trimmed to 10 genuine
cross-cutting batteries (conformance, SCI bootstrap/runtime, jank, compile-mode,
api, namespace, bootstrap, features, systematic-coverage). conformance 218/218,
jpm test green.
This commit is contained in:
Yogthos 2026-06-05 07:50:16 -04:00
parent a6491d025c
commit a0943cb944
11 changed files with 70 additions and 754 deletions

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@ -99,7 +99,7 @@ Tests are organized in three layers:
is the authoritative description of what Jolt promises. is the authoritative description of what Jolt promises.
- **`test/integration/`** — cross-cutting and regression batteries: the Clojure - **`test/integration/`** — cross-cutting and regression batteries: the Clojure
conformance suite, SCI bootstrap/runtime loading, jank conformance, compile-mode conformance suite, SCI bootstrap/runtime loading, jank conformance, compile-mode
tests, and ported Clojure test batteries. tests, the library API, and a broad systematic-coverage net.
- **`test/unit/`** — white-box tests for individual components (reader, - **`test/unit/`** — white-box tests for individual components (reader,
evaluator, types, persistent collections, regex, compiler). evaluator, types, persistent collections, regex, compiler).

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@ -1,154 +0,0 @@
# Ported from clojure/test_clojure/atoms.clj + systematic atom tests
(use ../../src/jolt/api)
(defn ct-eval [ctx s] (normalize-pvecs (eval-string ctx s)))
(print "Ported Atom Tests")
# --- atom creation ---
(print "test atom creation...")
(let [ctx (init)]
(assert (= true (ct-eval ctx "(atom? (atom 0))")) "atom?")
(assert (= false (ct-eval ctx "(atom? nil)")) "atom? nil")
(assert (= false (ct-eval ctx "(atom? 42)")) "atom? number")
(assert (= false (ct-eval ctx "(atom? \"x\")")) "atom? string")
(assert (= 42 (ct-eval ctx "(deref (atom 42))")) "deref atom")
(assert (= 99 (ct-eval ctx "(let [a (atom 99)] @a)")) "@ deref macro"))
(print " ok")
# --- deref on non-atoms ---
(print "test deref...")
(let [ctx (init)]
(assert (= 1 (ct-eval ctx "(deref 1)")) "deref non-atom passes through")
(assert (= "x" (ct-eval ctx "(deref \"x\")")) "deref string passes through")
(assert (= nil (ct-eval ctx "(deref nil)")) "deref nil"))
(print " ok")
# --- reset! ---
(print "test reset!...")
(let [ctx (init)]
(assert (= :b (ct-eval ctx "(let [a (atom :a)] (reset! a :b))")) "reset! returns new")
(assert (= 42 (ct-eval ctx "(let [a (atom 0)] (reset! a 42) @a)")) "reset! updates value")
(assert (= true (ct-eval ctx "(= [1 1] (let [a (atom 0)] [(reset! a 1) @a]))")) "reset! returns new, value changed"))
(print " ok")
# --- swap! ---
(print "test swap!...")
(let [ctx (init)]
(assert (= 1 (ct-eval ctx "(let [a (atom 0)] (swap! a inc))")) "swap! inc returns new")
(assert (= 2 (ct-eval ctx "(let [a (atom 0)] (swap! a + 2))")) "swap! + 2")
(assert (= 3 (ct-eval ctx "(let [a (atom 0)] (swap! a + 1 2) @a)")) "swap! + 1 2")
(assert (= 6 (ct-eval ctx "(let [a (atom 0)] (swap! a + 1 2 3) @a)")) "swap! + 1 2 3")
(assert (= 10 (ct-eval ctx "(let [a (atom 0)] (swap! a + 1 2 3 4) @a)")) "swap! + 1 2 3 4"))
(print " ok")
# --- swap-vals! (returns [old new]) ---
(print "test swap-vals!...")
(let [ctx (init)]
(assert (= true (ct-eval ctx
"(= [0 1] (let [a (atom 0)] (swap-vals! a inc)))")) "swap-vals! inc")
(assert (= true (ct-eval ctx
"(= [1 2] (let [a (atom 1)] (swap-vals! a inc)))")) "swap-vals! inc from 1")
(assert (= 2 (ct-eval ctx
"(let [a (atom 1)] (swap-vals! a inc) @a)")) "swap-vals! updates value"))
(print " ok")
# --- swap-vals! with extra args ---
(print "test swap-vals! arities...")
(let [ctx (init)]
(assert (= true (ct-eval ctx
"(= [0 1] (let [a (atom 0)] (swap-vals! a + 1)))")) "swap-vals! + 1")
(assert (= true (ct-eval ctx
"(= [1 3] (let [a (atom 0)] (swap-vals! a + 1) (swap-vals! a + 1 1)))")) "swap-vals! + 1 1")
(assert (= true (ct-eval ctx
"(= [3 6] (let [a (atom 0)] (swap-vals! a + 1) (swap-vals! a + 1 1) (swap-vals! a + 1 1 1)))")) "swap-vals! + 1 1 1")
(assert (= true (ct-eval ctx
"(= [6 10] (let [a (atom 0)] (swap-vals! a + 1) (swap-vals! a + 1 1) (swap-vals! a + 1 1 1) (swap-vals! a + 1 1 1 1)))")) "swap-vals! + 1 1 1 1"))
(print " ok")
# --- reset-vals! (returns [old new]) ---
(print "test reset-vals!...")
(let [ctx (init)]
(assert (= true (ct-eval ctx
"(= [0 :b] (let [a (atom 0)] (reset-vals! a :b)))")) "reset-vals! returns old new")
(assert (= true (ct-eval ctx
"(= [:b 42] (let [a (atom 0)] (reset-vals! a :b) (reset-vals! a 42)))")) "reset-vals! chain")
(assert (= 42 (ct-eval ctx
"(let [a (atom 0)] (reset-vals! a :b) (reset-vals! a 42) @a)")) "reset-vals! updates value"))
(print " ok")
# --- compare-and-set! ---
(print "test compare-and-set!...")
(let [ctx (init)]
(assert (= true (ct-eval ctx
"(let [a (atom 0)] (compare-and-set! a 0 1))")) "CAS true match")
(assert (= true (ct-eval ctx
"(= [true 1] (let [a (atom 0)] [(compare-and-set! a 0 1) @a]))")) "CAS true + value changed")
(assert (= true (ct-eval ctx
"(= [false 0] (let [a (atom 0)] [(compare-and-set! a 1 2) @a]))")) "CAS false no match")
(assert (= true (ct-eval ctx
"(= [false 1] (let [a (atom 0)] (compare-and-set! a 0 1) [(compare-and-set! a 0 2) @a]))")) "CAS false after change"))
(print " ok")
# --- validator ---
(print "test validator...")
(let [ctx (init)]
(assert (= 42 (ct-eval ctx
"(let [a (atom 0 :validator pos?)] (reset! a 42) @a)")) "validator passes")
(assert (= true (ct-eval ctx
"(= false (try (let [a (atom 0 :validator pos?)] (reset! a -1) true) (catch Exception e false)))")) "validator blocks invalid reset!")
(assert (= true (ct-eval ctx
"(= false (try (let [a (atom 0 :validator pos?)] (swap! a (fn [x] -1)) true) (catch Exception e false)))")) "validator blocks invalid swap!")
(assert (= nil (ct-eval ctx "(set-validator! (atom 0) pos?)")) "set-validator! returns nil")
(assert (= nil (ct-eval ctx "(get-validator (atom 0))")) "get-validator nil default")
(assert (= true (ct-eval ctx
"(= even? (do (def a (atom 0)) (set-validator! a even?) (get-validator a)))")) "get-validator returns set fn"))
(print " ok")
# --- watches ---
(print "test watches...")
(let [ctx (init)]
(assert (= true (ct-eval ctx
"(empty? (:watches (atom 0)))")) "atom starts with empty watches")
(assert (= true (ct-eval ctx
"(= [0 42] (let [a (atom 0)
w (atom nil)]
(add-watch a :my-key (fn [k ref old new] (reset! w [old new])))
(swap! a + 42)
@w))")) "add-watch triggers on swap!")
(assert (= true (ct-eval ctx
"(= :unchanged (let [a (atom 0)
w (atom :unchanged)]
(add-watch a :x (fn [_ _ _ _] (reset! w :fired)))
(remove-watch a :x)
(swap! a inc)
@w))")) "remove-watch stops notification")
(assert (= true (ct-eval ctx
"(= 2 (let [a (atom 0)]
(add-watch a :foo (fn [_ _ _ _] nil))
(add-watch a :bar (fn [_ _ _ _] nil))
(count (:watches a))))")) "multiple watches")
(assert (= true (ct-eval ctx
"(= 0 (let [a (atom 0)]
(add-watch a :foo (fn [_ _ _ _] nil))
(remove-watch a :foo)
(count (:watches a))))")) "remove-watch clears count")
(assert (= true (ct-eval ctx
"(= 2 (let [a (atom 0)
fired (atom [])]
(add-watch a :w1 (fn [_ _ o n] (swap! fired conj [:w1 o n])))
(add-watch a :w2 (fn [_ _ o n] (swap! fired conj [:w2 o n])))
(reset! a 99)
(count @fired)))")) "multiple watches both fire"))
(print " ok")
# --- metadata on atoms ---
(print "test atom metadata...")
(let [ctx (init)]
(assert (= nil (ct-eval ctx "(meta (atom 0))")) "atom meta nil by default")
(assert (= true (ct-eval ctx
"(= {:foo \"bar\"} (meta (atom 0 :meta {:foo \"bar\"})))")) "atom with :meta")
(assert (= true (ct-eval ctx
"(= {:validated true} (meta (atom 0 :validator pos? :meta {:validated true})))")) "atom with validator and meta"))
(print " ok")
(print "\nAll Ported Atom tests passed!")

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@ -1,151 +0,0 @@
# Ported from clojure/test_clojure/control.clj
(use ../../src/jolt/api)
(defn ct-eval [ctx s] (normalize-pvecs (eval-string ctx s)))
(print "Ported Control Tests")
# --- test-do ---
(print "test-do...")
(let [ctx (init)]
(assert (= nil (ct-eval ctx "(do)")) "do empty -> nil")
(assert (= 1 (ct-eval ctx "(do 1)")) "do returns last")
(assert (= 2 (ct-eval ctx "(do 1 2)")) "do returns last")
(assert (= 5 (ct-eval ctx "(do 1 2 3 4 5)")) "do returns last"))
(print " ok")
# --- test-loop ---
(print "test-loop...")
(let [ctx (init)]
(assert (= 1 (ct-eval ctx "(loop [] 1)")) "loop body")
(assert (= 3 (ct-eval ctx "(loop [a 1] (if (< a 3) (recur (inc a)) a))")) "loop recur")
(assert (= true (ct-eval ctx
"(= [6 4 2] (loop [a () b [1 2 3]]
(if (seq b)
(recur (conj a (* 2 (first b))) (next b))
a)))")) "loop accum list")
(assert (= true (ct-eval ctx
"(= [2 4 6] (loop [a [] b [1 2 3]]
(if (seq b)
(recur (conj a (* 2 (first b))) (next b))
a)))")) "loop accum vector"))
(print " ok")
# --- test-when ---
(print "test-when...")
(let [ctx (init)]
(assert (= 1 (ct-eval ctx "(when true 1)")) "when true")
(assert (= nil (ct-eval ctx "(when true)")) "when true no body")
(assert (= nil (ct-eval ctx "(when false)")) "when false")
(assert (= nil (ct-eval ctx "(when false 1)")) "when false with body"))
(print " ok")
# --- test-when-not ---
(print "test-when-not...")
(let [ctx (init)]
(assert (= 1 (ct-eval ctx "(when-not false 1)")) "when-not false")
(assert (= nil (ct-eval ctx "(when-not true)")) "when-not true no body")
(assert (= nil (ct-eval ctx "(when-not false)")) "when-not false no body")
(assert (= nil (ct-eval ctx "(when-not true 1)")) "when-not true with body"))
(print " ok")
# --- test-if-not ---
(print "test-if-not...")
(let [ctx (init)]
(assert (= 1 (ct-eval ctx "(if-not false 1)")) "if-not false")
(assert (= 1 (ct-eval ctx "(if-not false 1 2)")) "if-not false with else")
(assert (= nil (ct-eval ctx "(if-not true 1)")) "if-not true")
(assert (= 2 (ct-eval ctx "(if-not true 1 2)")) "if-not true with else"))
(print " ok")
# --- test-when-let ---
(print "test-when-let...")
(let [ctx (init)]
(assert (= 1 (ct-eval ctx "(when-let [a 1] a)")) "when-let simple")
(assert (= 2 (ct-eval ctx "(when-let [[a b] '(1 2)] b)")) "when-let destructure")
(assert (= nil (ct-eval ctx "(when-let [a false] 1)")) "when-let false"))
(print " ok")
# --- test-if-let ---
(print "test-if-let...")
(let [ctx (init)]
(assert (= 1 (ct-eval ctx "(if-let [a 1] a)")) "if-let simple")
(assert (= 2 (ct-eval ctx "(if-let [[a b] '(1 2)] b)")) "if-let destructure")
(assert (= nil (ct-eval ctx "(if-let [a false] 1)")) "if-let false")
(assert (= 1 (ct-eval ctx "(if-let [a false] a 1)")) "if-let false with else"))
(print " ok")
# --- test-if-some ---
(print "test-if-some...")
(let [ctx (init)]
(assert (= 1 (ct-eval ctx "(if-some [a 1] a)")) "if-some simple")
(assert (= false (ct-eval ctx "(if-some [a false] a)")) "if-some false is some")
(assert (= nil (ct-eval ctx "(if-some [a nil] 1)")) "if-some nil")
(assert (= 3 (ct-eval ctx "(if-some [[a b] [1 2]] (+ a b))")) "if-some destructure"))
(print " ok")
# --- test-when-some ---
(print "test-when-some...")
(let [ctx (init)]
(assert (= 1 (ct-eval ctx "(when-some [a 1] a)")) "when-some simple")
(assert (= 2 (ct-eval ctx "(when-some [[a b] [1 2]] b)")) "when-some destructure")
(assert (= false (ct-eval ctx "(when-some [a false] a)")) "when-some false is some")
(assert (= nil (ct-eval ctx "(when-some [a nil] 1)")) "when-some nil"))
(print " ok")
# --- test-cond ---
(print "test-cond...")
(let [ctx (init)]
(assert (= nil (ct-eval ctx "(cond)")) "cond empty -> nil")
(assert (= nil (ct-eval ctx "(cond nil true)")) "cond nil -> nil")
(assert (= nil (ct-eval ctx "(cond false true)")) "cond false -> nil")
(assert (= 1 (ct-eval ctx "(cond true 1)")) "cond true -> 1")
(assert (= 3 (ct-eval ctx "(cond nil 1 false 2 true 3 true 4)")) "cond third branch")
(assert (= :b (ct-eval ctx "(cond false :a true :b)")) "cond skips false")
(assert (= :a (ct-eval ctx "(cond true :a true :b)")) "cond takes first true"))
(print " ok")
# --- test-condp ---
(print "test-condp...")
(let [ctx (init)]
(assert (= :pass (ct-eval ctx "(condp = 1 1 :pass 2 :fail)")) "condp match first")
(assert (= :pass (ct-eval ctx "(condp = 1 2 :fail 1 :pass)")) "condp match second")
(assert (= :pass (ct-eval ctx "(condp = 1 2 :fail :pass)")) "condp default"))
(print " ok")
# --- test-dotimes ---
(print "test-dotimes...")
(let [ctx (init)]
(assert (= nil (ct-eval ctx "(dotimes [n 1] n)")) "dotimes returns nil")
(assert (= 3 (ct-eval ctx
"(let [a (atom 0)]
(dotimes [n 3] (swap! a inc))
@a)")) "dotimes 3 iterations")
(assert (= [0 1 2] (ct-eval ctx
"(let [a (atom [])]
(dotimes [n 3] (swap! a conj n))
@a)")) "dotimes with index"))
(print " ok")
# --- test-while ---
(print "test-while...")
(let [ctx (init)]
(assert (= nil (ct-eval ctx "(while nil 1)")) "while nil returns nil")
(assert (= true (ct-eval ctx
"(= [0 nil]
(let [a (atom 3)
w (while (pos? @a) (swap! a dec))]
[@a w]))")) "while dec to 0"))
(print " ok")
# --- test-case ---
(print "test-case...")
(let [ctx (init)]
(assert (= :number (ct-eval ctx "(case 1 1 :number :default)")) "case match 1")
(assert (= :string (ct-eval ctx "(case \"foo\" \"foo\" :string :default)")) "case match string")
(assert (= :kw (ct-eval ctx "(case :zap :zap :kw :default)")) "case match keyword")
(assert (= :symbol (ct-eval ctx "(case 'pow pow :symbol :default)")) "case match symbol")
(assert (= :default (ct-eval ctx "(case 99 1 :number :default)")) "case default")
(assert (= :matched (ct-eval ctx "(case 2 (2 3 4) :matched :default)")) "case one-of-many"))
(print " ok")
(print "\nAll Ported Control tests passed!")

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@ -1,35 +0,0 @@
# Ported from clojure/test_clojure/for.clj
(use ../../src/jolt/api)
(defn ct-eval [ctx s] (normalize-pvecs (eval-string ctx s)))
(print "Ported For Tests")
# --- When ---
(print "test-for :when...")
(let [ctx (init)]
(assert (= true (ct-eval ctx
"(= (for [x (range 10) :when (odd? x)] x)
(quote (1 3 5 7 9)))")) "for :when odd?")
(assert (= true (ct-eval ctx
"(= (for [x (range 4) y (range 4) :when (odd? y)] [x y])
(quote ([0 1] [0 3] [1 1] [1 3] [2 1] [2 3] [3 1] [3 3])))")) "for nested :when"))
(print " ok")
# --- Let ---
(print "test-for :let...")
(let [ctx (init)]
(assert (= true (ct-eval ctx
"(= (for [x (range 3) y (range 3) :let [z (+ x y)] :when (odd? z)] [x y z])
(quote ([0 1 1] [1 0 1] [1 2 3] [2 1 3])))")) "for :let :when"))
(print " ok")
# --- Nesting ---
(print "test-for nesting...")
(let [ctx (init)]
(assert (= true (ct-eval ctx
"(= (for [x (quote (a b)) y (interpose x (quote (1 2))) z (list x y)] [x y z])
(quote ([a 1 a] [a 1 1] [a a a] [a a a] [a 2 a] [a 2 2]
[b 1 b] [b 1 1] [b b b] [b b b] [b 2 b] [b 2 2])))")) "for nested interpose"))
(print " ok")
(print "\nAll Ported For tests passed!")

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@ -1,127 +0,0 @@
# Ported from clojure/test_clojure/logic.clj
(use ../../src/jolt/api)
(defn ct-eval [ctx s] (normalize-pvecs (eval-string ctx s)))
(print "Ported Logic Tests (from clojure/test-clojure/logic.clj)")
# --- test-if ---
(print "test-if: true/false/nil...")
(let [ctx (init)]
(assert (= :t (ct-eval ctx "(if true :t)")) "if true")
(assert (= :t (ct-eval ctx "(if true :t :f)")) "if true with else")
(assert (= nil (ct-eval ctx "(if false :t)")) "if false no else")
(assert (= :f (ct-eval ctx "(if false :t :f)")) "if false with else")
(assert (= nil (ct-eval ctx "(if nil :t)")) "if nil no else")
(assert (= :f (ct-eval ctx "(if nil :t :f)")) "if nil with else"))
(print " ok")
(print "test-if: zero/empty is true...")
(let [ctx (init)]
(assert (= :t (ct-eval ctx "(if 0 :t :f)")) "0 is true")
(assert (= :t (ct-eval ctx "(if 0.0 :t :f)")) "0.0 is true")
(assert (= :t (ct-eval ctx "(if \"\" :t :f)")) "empty string is true")
(assert (= :t (ct-eval ctx "(if () :t :f)")) "empty list is true")
(assert (= :t (ct-eval ctx "(if [] :t :f)")) "empty vector is true")
(assert (= :t (ct-eval ctx "(if {} :t :f)")) "empty map is true")
(assert (= :t (ct-eval ctx "(if #{} :t :f)")) "empty set is true"))
(print " ok")
(print "test-if: anything except nil/false is true...")
(let [ctx (init)]
(assert (= :t (ct-eval ctx "(if 42 :t :f)")) "42 is true")
(assert (= :t (ct-eval ctx "(if 1.2 :t :f)")) "1.2 is true")
(assert (= :t (ct-eval ctx "(if \"abc\" :t :f)")) "string is true")
(assert (= :t (ct-eval ctx "(if 'abc :t :f)")) "symbol is true")
(assert (= :t (ct-eval ctx "(if :kw :t :f)")) "keyword is true")
(assert (= :t (ct-eval ctx "(if '(1 2) :t :f)")) "list is true")
(assert (= :t (ct-eval ctx "(if [1 2] :t :f)")) "vector is true")
(assert (= :t (ct-eval ctx "(if {:a 1 :b 2} :t :f)")) "map is true")
(assert (= :t (ct-eval ctx "(if #{1 2} :t :f)")) "set is true"))
(print " ok")
# --- test-nil-punning ---
(print "test-nil-punning...")
(let [ctx (init)]
(assert (= :yes (ct-eval ctx "(if (first []) :no :yes)")) "first [] nil")
(assert (= :yes (ct-eval ctx "(if (next [1]) :no :yes)")) "next [1] nil")
(assert (= :no (ct-eval ctx "(if (rest [1]) :no :yes)")) "rest [1] non-nil")
(assert (= :yes (ct-eval ctx "(if (seq nil) :no :yes)")) "seq nil")
(assert (= :yes (ct-eval ctx "(if (seq []) :no :yes)")) "seq [] nil")
(assert (= :no (ct-eval ctx "(if (lazy-seq nil) :no :yes)")) "lazy-seq nil non-nil")
(assert (= :no (ct-eval ctx "(if (lazy-seq []) :no :yes)")) "lazy-seq [] non-nil")
(assert (= :no (ct-eval ctx "(if (filter (fn [x] (> x 10)) [1 2 3]) :no :yes)")) "filter non-match non-nil")
(assert (= :no (ct-eval ctx "(if (map identity []) :no :yes)")) "map empty non-nil")
(assert (= :no (ct-eval ctx "(if (apply concat []) :no :yes)")) "apply concat [] non-nil")
(assert (= :no (ct-eval ctx "(if (concat) :no :yes)")) "concat empty non-nil")
(assert (= :no (ct-eval ctx "(if (concat []) :no :yes)")) "concat [] non-nil")
(assert (= :no (ct-eval ctx "(if (reverse nil) :no :yes)")) "reverse nil non-nil")
(assert (= :no (ct-eval ctx "(if (reverse []) :no :yes)")) "reverse [] non-nil")
(assert (= :no (ct-eval ctx "(if (sort nil) :no :yes)")) "sort nil non-nil")
(assert (= :no (ct-eval ctx "(if (sort []) :no :yes)")) "sort [] non-nil"))
(print " ok")
# --- test-and ---
(print "test-and...")
(let [ctx (init)]
(assert (= true (ct-eval ctx "(and)")) "and empty")
(assert (= true (ct-eval ctx "(and true)")) "and true")
(assert (= nil (ct-eval ctx "(and nil)")) "and nil")
(assert (= false (ct-eval ctx "(and false)")) "and false")
(assert (= nil (ct-eval ctx "(and true nil)")) "and true nil")
(assert (= false (ct-eval ctx "(and true false)")) "and true false")
(assert (= "abc" (ct-eval ctx "(and 1 true :kw 'abc \"abc\")")) "and chain last")
(assert (= nil (ct-eval ctx "(and 1 true :kw nil 'abc \"abc\")")) "and chain nil")
(assert (= false (ct-eval ctx "(and 1 true :kw 'abc \"abc\" false)")) "and chain false"))
(print " ok")
# --- test-or ---
(print "test-or...")
(let [ctx (init)]
(assert (= nil (ct-eval ctx "(or)")) "or empty")
(assert (= true (ct-eval ctx "(or true)")) "or true")
(assert (= nil (ct-eval ctx "(or nil)")) "or nil")
(assert (= false (ct-eval ctx "(or false)")) "or false")
(assert (= true (ct-eval ctx "(or nil false true)")) "or nil false true")
(assert (= 1 (ct-eval ctx "(or nil false 1 2)")) "or picks first truthy")
(assert (= "abc" (ct-eval ctx "(or nil false \"abc\" :kw)")) "or picks string")
(assert (= nil (ct-eval ctx "(or false nil)")) "or false nil -> nil")
(assert (= false (ct-eval ctx "(or nil false)")) "or nil false -> false")
(assert (= false (ct-eval ctx "(or nil nil nil false)")) "or chain to false")
(assert (= true (ct-eval ctx "(or nil true false)")) "or nil true false"))
(print " ok")
# --- test-not ---
(print "test-not...")
(let [ctx (init)]
(assert (= true (ct-eval ctx "(not nil)")) "not nil")
(assert (= true (ct-eval ctx "(not false)")) "not false")
(assert (= false (ct-eval ctx "(not true)")) "not true")
(assert (= false (ct-eval ctx "(not 0)")) "not 0")
(assert (= false (ct-eval ctx "(not 0.0)")) "not 0.0")
(assert (= false (ct-eval ctx "(not 42)")) "not 42")
(assert (= false (ct-eval ctx "(not 1.2)")) "not 1.2")
(assert (= false (ct-eval ctx "(not \"\")")) "not empty string")
(assert (= false (ct-eval ctx "(not \"abc\")")) "not string")
(assert (= false (ct-eval ctx "(not 'abc)")) "not symbol")
(assert (= false (ct-eval ctx "(not :kw)")) "not keyword")
(assert (= false (ct-eval ctx "(not ())")) "not empty list")
(assert (= false (ct-eval ctx "(not '(1 2))")) "not list")
(assert (= false (ct-eval ctx "(not []))")) "not empty vector")
(assert (= false (ct-eval ctx "(not [1 2])")) "not vector")
(assert (= false (ct-eval ctx "(not {})")) "not empty map")
(assert (= false (ct-eval ctx "(not {:a 1 :b 2})")) "not map")
(assert (= false (ct-eval ctx "(not #{})")) "not empty set")
(assert (= false (ct-eval ctx "(not #{1 2})")) "not set"))
(print " ok")
# --- test-some? ---
(print "test-some?...")
(let [ctx (init)]
(assert (= false (ct-eval ctx "(some? nil)")) "some? nil")
(assert (= true (ct-eval ctx "(some? false)")) "some? false")
(assert (= true (ct-eval ctx "(some? 0)")) "some? 0")
(assert (= true (ct-eval ctx "(some? \"abc\")")) "some? string")
(assert (= true (ct-eval ctx "(some? [])")) "some? empty vec"))
(print " ok")
(print "\nAll Ported Logic tests passed!")

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@ -1,63 +0,0 @@
# Ported from clojure/test_clojure/macros.clj
(use ../../src/jolt/api)
(defn ct-eval [ctx s] (normalize-pvecs (eval-string ctx s)))
(print "Ported Macros Tests")
# --- -> and ->> threading ---
(print "test -> and ->>...")
(let [ctx (init)]
(ct-eval ctx "(defmacro c [arg] (if (= 'b (first arg)) :foo :bar))")
(ct-eval ctx "(def a 2)")
(ct-eval ctx "(def b identity)")
(assert (= :foo (ct-eval ctx "(-> a b c)")) "-> threading")
(assert (= :foo (ct-eval ctx "(->> a b c)")) "->> threading"))
(print " ok")
# --- some-> ---
(print "test some->...")
(let [ctx (init)]
(assert (= nil (ct-eval ctx "(some-> nil)")) "some-> nil")
(assert (= 0 (ct-eval ctx "(some-> 0)")) "some-> 0")
(assert (= -1 (ct-eval ctx "(some-> 1 (- 2))")) "some-> with form")
(ct-eval ctx "(defn const-nil [_] nil)")
(assert (= nil (ct-eval ctx "(some-> 1 const-nil (- 2))")) "some-> stop at nil"))
(print " ok")
# --- some->> ---
(print "test some->>...")
(let [ctx (init)]
(assert (= nil (ct-eval ctx "(some->> nil)")) "some->> nil")
(assert (= 0 (ct-eval ctx "(some->> 0)")) "some->> 0")
(assert (= 1 (ct-eval ctx "(some->> 1 (- 2))")) "some->> with form")
(ct-eval ctx "(defn const-nil2 [_] nil)")
(assert (= nil (ct-eval ctx "(some->> 1 const-nil2 (- 2))")) "some->> stop at nil"))
(print " ok")
# --- cond-> ---
(print "test cond->...")
(let [ctx (init)]
(assert (= 0 (ct-eval ctx "(cond-> 0)")) "cond-> single")
(assert (= -1 (ct-eval ctx "(cond-> 0 true inc true (- 2))")) "cond-> with tests")
(assert (= 0 (ct-eval ctx "(cond-> 0 false inc)")) "cond-> false test")
(assert (= -1 (ct-eval ctx "(cond-> 1 true (- 2) false inc)")) "cond-> mix"))
(print " ok")
# --- cond->> ---
(print "test cond->>...")
(let [ctx (init)]
(assert (= 0 (ct-eval ctx "(cond->> 0)")) "cond->> single")
(assert (= 1 (ct-eval ctx "(cond->> 0 true inc true (- 2))")) "cond->> with tests")
(assert (= 0 (ct-eval ctx "(cond->> 0 false inc)")) "cond->> false test")
(assert (= 1 (ct-eval ctx "(cond->> 1 true (- 2) false inc)")) "cond->> mix"))
(print " ok")
# --- as-> ---
(print "test as->...")
(let [ctx (init)]
(assert (= 0 (ct-eval ctx "(as-> 0 x)")) "as-> single")
(assert (= 1 (ct-eval ctx "(as-> 0 x (inc x))")) "as-> one form")
(assert (= 2 (ct-eval ctx "(as-> [0 1] x (map inc x) (reverse x) (first x))")) "as-> chain"))
(print " ok")
(print "\nAll Ported Macros tests passed!")

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@ -1,122 +0,0 @@
(use ../../src/jolt/types)
(use ../../src/jolt/pv)
(use ../../src/jolt/plist)
(use ../../src/jolt/reader)
(use ../../src/jolt/evaluator)
(use ../../src/jolt/core)
# Normalize jolt collection results to Janet tuples so Janet-level deep=/= can
# compare against tuple literals regardless of the (pvec/plist) representation.
(defn norm [x]
(cond
(pvec? x) (tuple ;(map norm (pv->array x)))
(plist? x) (tuple ;(map norm (pl->array x)))
(tuple? x) (tuple ;(map norm x))
(array? x) (tuple ;(map norm x))
x))
# Helper: create a fresh bootstrapped context
(defn make-boot-ctx []
(let [ctx (make-ctx)]
(init-core! ctx)
ctx))
# Helper: parse + eval
(defn eval-str [ctx s]
(let [form (parse-string s)]
(norm (eval-form ctx @{} form))))
(print "1: predicates...")
(let [ctx (make-boot-ctx)]
(assert (= true (eval-str ctx "(nil? nil)")) "nil?")
(assert (= false (eval-str ctx "(nil? 1)")) "nil? false")
(assert (= true (eval-str ctx "(string? \"hello\")")) "string?")
(assert (= true (eval-str ctx "(number? 42)")) "number?")
(assert (= true (eval-str ctx "(fn? inc)")) "fn?")
(assert (= true (eval-str ctx "(keyword? :foo)")) "keyword?")
(assert (= false (eval-str ctx "(keyword? 1)")) "keyword? false")
(assert (= true (eval-str ctx "(zero? 0)")) "zero?")
(assert (= true (eval-str ctx "(pos? 1)")) "pos?")
(assert (= true (eval-str ctx "(neg? -1)")) "neg?")
(assert (= true (eval-str ctx "(even? 2)")) "even?")
(assert (= true (eval-str ctx "(odd? 1)")) "odd?")
(assert (= true (eval-str ctx "(empty? [])")) "empty? vector")
(assert (= false (eval-str ctx "(empty? [1])")) "empty? non-empty"))
(print " passed")
(print "2: math...")
(let [ctx (make-boot-ctx)]
(assert (= 0 (eval-str ctx "(+)")) "+ 0 args")
(assert (= 5 (eval-str ctx "(+ 2 3)")) "+ 2 args")
(assert (= 10 (eval-str ctx "(+ 1 2 3 4)")) "+ varargs")
(assert (= -5 (eval-str ctx "(- 5)")) "- unary")
(assert (= 2 (eval-str ctx "(- 5 3)")) "- binary")
(assert (= 6 (eval-str ctx "(* 2 3)")) "*")
(assert (= 1 (eval-str ctx "(*)")) "* 0 args")
(assert (= 42 (eval-str ctx "(inc 41)")) "inc")
(assert (= 40 (eval-str ctx "(dec 41)")) "dec")
(assert (= 4 (eval-str ctx "(max 1 4 2)")) "max"))
(print " passed")
(print "3: comparison...")
(let [ctx (make-boot-ctx)]
(assert (= true (eval-str ctx "(= 1 1)")) "= same")
(assert (= false (eval-str ctx "(= 1 2)")) "= diff")
(assert (= true (eval-str ctx "(= 1 1 1)")) "= multi same")
(assert (= false (eval-str ctx "(= 1 2 1)")) "= multi diff")
(assert (= true (eval-str ctx "(not= 1 2)")) "not="))
(print " passed")
(print "4: collections...")
(let [ctx (make-boot-ctx)]
(assert (= 3 (eval-str ctx "(count [1 2 3])")) "count vector")
(assert (= 1 (eval-str ctx "(first [1 2 3])")) "first")
(assert (deep= [2 3] (eval-str ctx "(rest [1 2 3])")) "rest")
(assert (= nil (eval-str ctx "(next [1])")) "next singleton")
(assert (deep= [1 2 3] (eval-str ctx "(conj [1 2] 3)")) "conj vector")
(assert (= 1 (eval-str ctx "(get {:a 1} :a)")) "get map")
(assert (= 2 (eval-str ctx "(get [1 2 3] 1)")) "get vector")
(assert (= :default (eval-str ctx "(get {:a 1} :b :default)")) "get default")
(assert (deep= {:a 1 :c 3} (eval-str ctx "(assoc {:a 1} :c 3)")) "assoc")
(assert (deep= {:a 1} (eval-str ctx "(dissoc {:a 1 :b 2} :b)")) "dissoc"))
(print " passed")
(print "5: seq ops...")
(let [ctx (make-boot-ctx)]
(assert (deep= [2 3 4] (eval-str ctx "(map inc [1 2 3])")) "map")
(assert (deep= [2 4] (eval-str ctx "(filter even? [1 2 3 4])")) "filter")
(assert (= 6 (eval-str ctx "(reduce + [1 2 3])")) "reduce")
(assert (= 10 (eval-str ctx "(reduce + 4 [1 2 3])")) "reduce with val")
(assert (deep= [1 2] (eval-str ctx "(take 2 [1 2 3 4])")) "take")
(assert (deep= [3 4] (eval-str ctx "(drop 2 [1 2 3 4])")) "drop")
(assert (deep= [1 2] (eval-str ctx "(take-while (fn* [x] (<= x 2)) [1 2 3 4])")) "take-while"))
(print " passed")
(print "6: range...")
(let [ctx (make-boot-ctx)]
(assert (deep= [0 1 2 3 4] (eval-str ctx "(range 5)")) "range end")
(assert (deep= [2 3 4] (eval-str ctx "(range 2 5)")) "range start end"))
(print " passed")
(print "7: higher-order...")
(let [ctx (make-boot-ctx)]
(assert (= 42 (eval-str ctx "(identity 42)")) "identity")
(assert (= 42 (eval-str ctx "(let* [f (constantly 42)] (f))")) "constantly")
(assert (= 3 (eval-str ctx "(let* [f (comp inc inc)] (f 1))")) "comp")
(assert (deep= [2 0] (eval-str ctx "(let* [f (juxt inc dec)] (f 1))")) "juxt"))
(print " passed")
(print "8: str...")
(let [ctx (make-boot-ctx)]
(assert (= "hello" (eval-str ctx "(str \"hello\")")) "str")
(assert (= "hello42" (eval-str ctx "(str \"hello\" 42)")) "str concat"))
(print " passed")
(print "9: atom...")
(let [ctx (make-boot-ctx)]
(assert (= 1 (eval-str ctx "(let* [a (atom 1)] (deref a))")) "atom + deref")
(assert (= 42 (eval-str ctx "(let* [a (atom 1)] (reset! a 42) (deref a))")) "reset!")
(assert (= 2 (eval-str ctx "(let* [a (atom 1)] (swap! a inc) (deref a))")) "swap!"))
(print " passed")
(print "\nAll core tests passed!")

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@ -1,100 +0,0 @@
(use ../../src/jolt/api)
(defn ct-eval [ctx s] (normalize-pvecs (eval-string ctx s)))
(print "Ported Logic Tests (from clojure/test-clojure/logic.clj)")
(print "1: test-if true/false/nil...")
(let [ctx (init)]
(assert (= :t (ct-eval ctx "(if true :t)")) "if true")
(assert (= :t (ct-eval ctx "(if true :t :f)")) "if true with else")
(assert (= nil (ct-eval ctx "(if false :t)")) "if false no else")
(assert (= :f (ct-eval ctx "(if false :t :f)")) "if false with else")
(assert (= nil (ct-eval ctx "(if nil :t)")) "if nil no else")
(assert (= :f (ct-eval ctx "(if nil :t :f)")) "if nil with else"))
(print " ok")
(print "2: test-if zero/empty is true...")
(let [ctx (init)]
(assert (= true (ct-eval ctx "(= :t (if 0 :t :f))")) "0 is true")
(assert (= true (ct-eval ctx "(= :t (if 0.0 :t :f))")) "0.0 is true")
(assert (= true (ct-eval ctx "(= :t (if \"\" :t :f))")) "empty string is true")
(assert (= true (ct-eval ctx "(= :t (if () :t :f))")) "empty list is true")
(assert (= true (ct-eval ctx "(= :t (if [] :t :f))")) "empty vector is true")
(assert (= true (ct-eval ctx "(= :t (if {} :t :f))")) "empty map is true")
(assert (= true (ct-eval ctx "(= :t (if #{} :t :f))")) "empty set is true"))
(print " ok")
(print "3: test-if anything except nil/false is true...")
(let [ctx (init)]
(assert (= true (ct-eval ctx "(= :t (if 42 :t :f))")) "42 is true")
(assert (= true (ct-eval ctx "(= :t (if 1.5 :t :f))")) "float is true")
(assert (= true (ct-eval ctx "(= :t (if \"abc\" :t :f))")) "string is true")
(assert (= true (ct-eval ctx "(= :t (if 'abc :t :f))")) "symbol is true")
(assert (= true (ct-eval ctx "(= :t (if :kw :t :f))")) "keyword is true")
(assert (= true (ct-eval ctx "(= :t (if '(1 2) :t :f))")) "list is true")
(assert (= true (ct-eval ctx "(= :t (if [1 2] :t :f))")) "vector is true")
(assert (= true (ct-eval ctx "(= :t (if {:a 1 :b 2} :t :f))")) "map is true")
(assert (= true (ct-eval ctx "(= :t (if #{1 2} :t :f))")) "set is true"))
(print " ok")
(print "4: test-nil-punning...")
(let [ctx (init)]
(assert (= :yes (ct-eval ctx "(if (first []) :no :yes)")) "first [] nil")
(assert (= :yes (ct-eval ctx "(if (next [1]) :no :yes)")) "next [1] nil")
(assert (= :no (ct-eval ctx "(if (rest [1]) :no :yes)")) "rest [1] non-nil")
(assert (= :yes (ct-eval ctx "(if (seq nil) :no :yes)")) "seq nil")
(assert (= :yes (ct-eval ctx "(if (seq []) :no :yes)")) "seq [] nil")
(assert (= :no (ct-eval ctx "(if (lazy-seq nil) :no :yes)")) "lazy-seq nil non-nil")
(assert (= :no (ct-eval ctx "(if (lazy-seq []) :no :yes)")) "lazy-seq [] non-nil"))
(print " ok")
(print "5: test-and...")
(let [ctx (init)]
(assert (= true (ct-eval ctx "(and)")) "and empty")
(assert (= true (ct-eval ctx "(and true)")) "and true")
(assert (= nil (ct-eval ctx "(and nil)")) "and nil")
(assert (= false (ct-eval ctx "(and false)")) "and false")
(assert (ct-eval ctx "(= \"abc\" (and 1 true :kw 'abc \"abc\"))") "and chain last")
(assert (= nil (ct-eval ctx "(and 1 true nil 'abc \"abc\")")) "and chain nil")
(assert (= false (ct-eval ctx "(and 1 true 'abc \"abc\" false)")) "and chain false"))
(print " ok")
(print "6: test-or...")
(let [ctx (init)]
(assert (= nil (ct-eval ctx "(or)")) "or empty")
(assert (= true (ct-eval ctx "(or true)")) "or true")
(assert (= nil (ct-eval ctx "(or nil)")) "or nil")
(assert (= false (ct-eval ctx "(or false)")) "or false")
(assert (= true (ct-eval ctx "(or nil false true)")) "or nil false true")
(assert (= 1 (ct-eval ctx "(or nil false 1 2)")) "or picks first truthy")
(assert (ct-eval ctx "(= \"abc\" (or nil false \"abc\" :kw))") "or picks string")
(assert (= nil (ct-eval ctx "(or false nil)")) "or false nil -> nil")
(assert (= false (ct-eval ctx "(or nil false)")) "or nil false -> false")
(assert (= false (ct-eval ctx "(or nil nil nil false)")) "or chain to false")
(assert (= true (ct-eval ctx "(or nil true false)")) "or nil true false"))
(print " ok")
(print "7: test-not...")
(let [ctx (init)]
(assert (= true (ct-eval ctx "(not nil)")) "not nil")
(assert (= true (ct-eval ctx "(not false)")) "not false")
(assert (= false (ct-eval ctx "(not true)")) "not true")
(assert (= false (ct-eval ctx "(not 0)")) "not 0")
(assert (= false (ct-eval ctx "(not 42)")) "not 42")
(assert (= false (ct-eval ctx "(not \"\")")) "not empty string")
(assert (= false (ct-eval ctx "(not \"abc\")")) "not string")
(assert (= false (ct-eval ctx "(not ())")) "not empty list")
(assert (= false (ct-eval ctx "(not [])")) "not empty vector")
(assert (= false (ct-eval ctx "(not {})")) "not empty map")
(assert (= false (ct-eval ctx "(not #{})")) "not empty set"))
(print " ok")
(print "8: test-some?...")
(let [ctx (init)]
(assert (= false (ct-eval ctx "(some? nil)")) "some? nil")
(assert (= true (ct-eval ctx "(some? false)")) "some? false")
(assert (= true (ct-eval ctx "(some? 0)")) "some? 0")
(assert (= true (ct-eval ctx "(some? \"abc\")")) "some? string")
(assert (= true (ct-eval ctx "(some? [])")) "some? empty vec"))
(print " ok")
(print "\nAll Ported Logic tests passed!")

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@ -17,6 +17,12 @@
["catch value of body" "5" ["catch value of body" "5"
"(try (+ 2 3) (catch :default e 0))"]) "(try (+ 2 3) (catch :default e 0))"])
(defspec "exceptions / assert"
["assert true -> ok" ":ok" "(do (assert true) :ok)"]
["assert expr -> ok" ":ok" "(do (assert (= 1 1)) :ok)"]
["assert false throws" :throws "(assert false)"]
["assert nil throws" :throws "(assert nil)"])
(defspec "exceptions / ex-info" (defspec "exceptions / ex-info"
["ex-message" "\"oops\"" "(ex-message (ex-info \"oops\" {}))"] ["ex-message" "\"oops\"" "(ex-message (ex-info \"oops\" {}))"]
["ex-data" "{:k 1}" "(ex-data (ex-info \"oops\" {:k 1}))"] ["ex-data" "{:k 1}" "(ex-data (ex-info \"oops\" {:k 1}))"]

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@ -21,7 +21,8 @@
["add-watch fires" "1" "(let [a (atom 0) seen (atom 0)] (add-watch a :k (fn [k r o n] (reset! seen 1))) (reset! a 5) @seen)"] ["add-watch fires" "1" "(let [a (atom 0) seen (atom 0)] (add-watch a :k (fn [k r o n] (reset! seen 1))) (reset! a 5) @seen)"]
["remove-watch" "0" "(let [a (atom 0) seen (atom 0)] (add-watch a :k (fn [k r o n] (swap! seen inc))) (remove-watch a :k) (reset! a 5) @seen)"] ["remove-watch" "0" "(let [a (atom 0) seen (atom 0)] (add-watch a :k (fn [k r o n] (swap! seen inc))) (remove-watch a :k) (reset! a 5) @seen)"]
["set-validator! ok" "5" "(let [a (atom 0)] (set-validator! a number?) (reset! a 5) @a)"] ["set-validator! ok" "5" "(let [a (atom 0)] (set-validator! a number?) (reset! a 5) @a)"]
["set-validator! rejects" :throws "(let [a (atom 0)] (set-validator! a pos?) (reset! a -1))"]) ["set-validator! rejects" :throws "(let [a (atom 0)] (set-validator! a pos?) (reset! a -1))"]
["get-validator" "true" "(let [a (atom 0)] (set-validator! a number?) (fn? (get-validator a)))"])
(defspec "state / volatiles & delays" (defspec "state / volatiles & delays"
["volatile! deref" "0" "(let [v (volatile! 0)] @v)"] ["volatile! deref" "0" "(let [v (volatile! 0)] @v)"]

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@ -0,0 +1,61 @@
# Specification: truthiness & boolean logic.
# The core Clojure rule: ONLY nil and false are logically false; every other
# value — including 0, 0.0, "", and empty collections — is logically true.
(use ../support/harness)
(defspec "truthiness / if (only nil & false are falsy)"
["nil is falsy" ":f" "(if nil :t :f)"]
["false is falsy" ":f" "(if false :t :f)"]
["zero is truthy" ":t" "(if 0 :t :f)"]
["zero float truthy" ":t" "(if 0.0 :t :f)"]
["empty string truthy" ":t" "(if \"\" :t :f)"]
["empty list truthy" ":t" "(if (list) :t :f)"]
["empty vector truthy" ":t" "(if [] :t :f)"]
["empty map truthy" ":t" "(if {} :t :f)"]
["empty set truthy" ":t" "(if #{} :t :f)"]
["number truthy" ":t" "(if 42 :t :f)"]
["string truthy" ":t" "(if \"x\" :t :f)"]
["keyword truthy" ":t" "(if :kw :t :f)"]
["symbol truthy" ":t" "(if (quote abc) :t :f)"]
["coll truthy" ":t" "(if [1 2] :t :f)"]
["map truthy" ":t" "(if {:a 1} :t :f)"]
["if no else -> nil" "nil" "(if false :t)"])
(defspec "truthiness / not"
["not nil" "true" "(not nil)"]
["not false" "true" "(not false)"]
["not zero" "false" "(not 0)"]
["not empty vector" "false" "(not [])"]
["not empty string" "false" "(not \"\")"]
["not number" "false" "(not 42)"]
["not true" "false" "(not true)"])
(defspec "truthiness / and"
["empty is true" "true" "(and)"]
["single value" "5" "(and 5)"]
["all truthy -> last" "3" "(and 1 2 3)"]
["stops at false" "false" "(and 1 false 3)"]
["stops at nil" "nil" "(and 1 nil 3)"]
["false alone" "false" "(and false)"]
["nil alone" "nil" "(and nil)"]
["zero is truthy" "0" "(and 1 0)"])
(defspec "truthiness / or"
["empty is nil" "nil" "(or)"]
["first truthy" "1" "(or 1 2)"]
["skips nil/false" "5" "(or nil false 5)"]
["all falsy -> last" "false" "(or nil false)"]
["nil chain -> false" "false" "(or nil nil nil false)"]
["zero is truthy" "0" "(or 0 1)"]
["false alone" "false" "(or false)"])
(defspec "truthiness / if-not & boolean"
["if-not false" ":yes" "(if-not false :yes :no)"]
["if-not truthy" ":no" "(if-not 0 :yes :no)"]
["when-not nil" "1" "(when-not nil 1)"]
["when-not truthy" "nil" "(when-not 5 1)"]
["boolean of nil" "false" "(boolean nil)"]
["boolean of false" "false" "(boolean false)"]
["boolean of 0" "true" "(boolean 0)"]
["boolean of value" "true" "(boolean :x)"]
["true?/false?" "true" "(and (true? true) (false? false) (not (true? 1)))"])