From 11919c0ebde7c071c5d126cef3d04775d8b450fe Mon Sep 17 00:00:00 2001 From: Carlo Zancanaro Date: Tue, 23 Feb 2021 13:33:02 +1100 Subject: Initial commit --- src/jester/comparisons.clj | 36 +++ src/jester/expansion.clj | 460 ++++++++++++++++++++++++++++++++ src/jester/match.clj | 142 ++++++++++ src/jester/types.clj | 633 +++++++++++++++++++++++++++++++++++++++++++++ 4 files changed, 1271 insertions(+) create mode 100644 src/jester/comparisons.clj create mode 100644 src/jester/expansion.clj create mode 100644 src/jester/match.clj create mode 100644 src/jester/types.clj (limited to 'src') diff --git a/src/jester/comparisons.clj b/src/jester/comparisons.clj new file mode 100644 index 0000000..c47469e --- /dev/null +++ b/src/jester/comparisons.clj @@ -0,0 +1,36 @@ +(ns jester.comparisons + "Comparison functions to specify how Jester comparisons work.") + +(defn string= + "Compare two (potentially-nil) strings. If either is nil, return nil. + Otherwise, return true iff a = b, ignoring case, and false + otherwise." + [^String a, ^String b] + (boolean (and a b (.equalsIgnoreCase a b)))) + +(defn string< + "Compare two (potentially-nil) strings. If either is nil, return nil. + Otherwise, return true iff a < b, ignoring case, and false + otherwise." + [^String a, ^String b] + (and a b (< (.compareToIgnoreCase a b) 0))) + +(defn number= + "Compare two (potentially-nil) numbers. If either is nil, return nil. + If either is NaN, return false. Otherwise, return true iff a = b, + and false otherwise." + [a b] + (boolean (and a b (== a b)))) + +(defn number< + "Compare two (potentially-nil) numbers. If either is nil, return nil. + If either is NaN, return false. Otherwise, return true iff a < b, + and false otherwise." + [a b] + (boolean (and a b (< a b)))) + +(defn boolean= + "Compare two (potentially-nil) booleans. If either is nil, return nil. + Otherwise, return true iff a = b, and false otherwise." + [a b] + (boolean (and (some? a) (some? b) (= a b)))) diff --git a/src/jester/expansion.clj b/src/jester/expansion.clj new file mode 100644 index 0000000..b6c915b --- /dev/null +++ b/src/jester/expansion.clj @@ -0,0 +1,460 @@ +(ns jester.expansion + (:require [clojure.string :as str] + [clojure.walk :as walk] + [jester.comparisons :refer [string= string< + number= number< + boolean=]] + [jester.match :refer [type-match]] + [jester.types :refer [in-constraint-environment + constrain + ground-type + type-variable]])) + +(defn ^:private type-of + "Return the type of an expanded form. This relies on the metadata, + except for primitive types where metadata can't be stored." + [expanded-form] + (cond (number? expanded-form) `(enum ~expanded-form) + (string? expanded-form) `(enum ~expanded-form) + (boolean? expanded-form) `(enum ~expanded-form) + (nil? expanded-form) `(optional ~(type-variable)) + :else (::type (meta expanded-form)))) + +(defn ^:private with-type [object type] + (with-meta object {::type type})) + +(def ^:private ^:dynamic *parameters*) + +(declare expand-form*) + +(defn regex-start-index + "Return the index of the first character in `string` which matches the + start of an instance of `regex`." + [regex string] + (let [matcher (re-matcher #"\??\." string)] + (when (.find matcher) + (.start matcher)))) + +(defn expand-symbol [form] + (let [string (name form)] + (if-let [sep-index (regex-start-index #"\??\." string)] + (let [root (.substring string 0 sep-index) + rest (.substring string sep-index) + root-sym (symbol root)] + (expand-form* `(~(symbol rest) + ~root-sym))) + (with-type form + (or (get *parameters* form) + (let [type (type-variable)] + (set! *parameters* (assoc *parameters* form type)) + type)))))) + +(defn getter-expander [form] + (let [[head arg] form + string (name head)] + (when-not (or (str/starts-with? string ".") + (str/starts-with? string "?.")) + (throw (ex-info "Unknown value in head of form" + {:form form}))) + (let [;; This complicated regex splits the string into parts + ;; starting with either "?" or "?." + parts (str/split string #"(?=\?\.|(? ~(mapv type-of args) ~result)) + (with-type `(~(:name operator) ~@args) + result))) + +(defn expand-form* [form] + (cond + (number? form) form + (string? form) form + (boolean? form) form + (nil? form) form + (symbol? form) (expand-symbol form) + (map? form) (expand-map form) + (vector? form) (expand-vector form) + (seq? form) (if (symbol? (first form)) + (if-let [operator (get operators (first form))] + (if (get expanders (first form)) + (throw (ex-info (format "Found both an operator and an expander for %s" + (pr-str (first form))) + {:head (first form) + :form form})) + (expand-operator-form operator form)) + (if-let [expander (get expanders (first form))] + (expander form) + (getter-expander form))) + (throw (ex-info "Invalid form" + {:form form}))) + :else (throw (ex-info "Invalid form" + {:form form})))) + +(defn ^:private force-all + "Walk over a structure, iterating over child objects and forcing + sequences. The result is identical the input object. + + (let [x ...] + (identical? x (force-all x))) + ;;=> true " + [obj] + (cond + ;; Reduce over sequences, vectors, and sets + (or (seq? obj) + (vector? obj) + (set? obj)) + (reduce (fn [result item] + (force-all item) + result) + obj obj) + ;; Reduce over the keys and values in maps + (map? obj) + (reduce-kv (fn [result key value] + (force-all key) + (force-all value) + result) + obj obj) + ;; Return everything else unchanged. + :else + obj)) + +(defn expand-form [form] + (binding [*parameters* {}] + (in-constraint-environment + (let [expanded (force-all (expand-form* form)) + grounded (ground-type *parameters* :argument)] + ;; Once we've solved the input types, add constraints to + ;; ensure that information is captured when we solve the + ;; output type. We only need to add them as lower bounds, + ;; because :return grounding solves for the greatest lower + ;; bound. + (doseq [[param type] grounded] + (constrain type (get *parameters* param))) + (if (instance? clojure.lang.IMeta expanded) + (with-meta expanded + {:input grounded + :output (ground-type (type-of expanded) :return)}) + expanded))))) + +(defmacro define-expander + {:style/indent 2} + [operator-name [& args] & body] + `(alter-var-root #'expanders + assoc '~operator-name (fn [[_# ~@args]] + ~@body))) + +(defn ^:private resolve-symbol [sym] + (let [resolved (meta (ns-resolve *ns* sym)) + ns (:ns resolved)] + (when resolved + (symbol (-> ns ns-name name) + (-> resolved :name name))))) + +(defmacro define-simple-operator + {:style/indent :defn} + ([name type] + (if-let [resolved (resolve-symbol name)] + `(define-simple-operator ~name ~resolved ~type) + (throw (ex-info (format "Cannot resolve symbol for operator: %s" (pr-str name)) + {:namespace *ns* + :symbol name})))) + ([name operator-symbol type] + (let [type (type-match type + (∀ args value) + `(let [~@(mapcat #(list % `(list 'var (gensym '~%))) args)] + ~(quote-type value (set args))) + _ + (list 'quote type))] + (if (namespace operator-symbol) + `(alter-var-root #'operators assoc '~name + {:type (fn [] ~type) + :name '~operator-symbol}) + (throw (ex-info (format "Operator symbol must have a namespace" (pr-str name)) + {:symbol operator-symbol})))))) + +(defn ^:private e-use [form type] + (let [result (expand-form* form)] + (constrain (type-of result) type) + result)) + +(defmacro ^:private with-temporary-parameter-type [[parameter type] & body] + `(try + (let [old# (get *parameters* ~parameter)] + (try + (set! *parameters* (assoc *parameters* ~parameter ~type)) + (force-all (do ~@body)) + (finally + (if old# + (set! *parameters* (assoc *parameters* ~parameter old#)) + (set! *parameters* (dissoc *parameters* ~parameter)))))))) + +(defn ? [optional default] + (if (nil? optional) default optional)) + +(define-simple-operator ? + (∀ [x] (-> [(optional x) x] x))) + +(define-simple-operator string= (-> [string string] boolean)) +(define-simple-operator string=? (-> [(optional string) (optional string)] (optional boolean))) + +(define-expander find [[var & {list :in condition :when}] value] + (let [type (type-variable) + result (with-temporary-parameter-type [var type] + (expand-form* value))] + (with-type `(reduce (fn [_# ~var] + (when ~(with-temporary-parameter-type [var type] + (e-use (or condition true) '(optional boolean))) + (reduced ~result))) + nil ~(e-use list `(list ~type))) + `(optional ~(type-of result))))) + +(define-expander for [[var & {list :in condition :when}] value] + (let [type (type-variable) + result (with-temporary-parameter-type [var type] + (expand-form* value))] + (with-type `(reduce (fn [acc# ~var] + (if ~(with-temporary-parameter-type [var type] + (e-use (or condition true) '(optional boolean))) + (conj acc# ~result) + acc#)) + [] ~(e-use list `(list ~type))) + `(list ~(type-of result))))) + +(define-expander all-of [[var & {list :in condition :when}] value] + (let [type (type-variable)] + (with-type `(reduce (fn [_# ~var] + (if ~(with-temporary-parameter-type [var type] + `(or (not ~(e-use (or condition true) '(optional boolean))) + ~(e-use value 'boolean))) + true + (reduced false))) + true ~(e-use list `(list ~type))) + 'boolean))) + +(define-expander one-of [[var & {list :in condition :when}] value] + (let [type (type-variable)] + (with-type `(reduce (fn [_# ~var] + (if ~(with-temporary-parameter-type [var type] + `(or (not ~(e-use (or condition true) '(optional boolean))) + ~(e-use value 'boolean))) + true + (reduced false))) + true ~(e-use list `(list ~type))) + 'boolean))) + +(define-expander with-optional [[var optional] value] + (assert (symbol? var) "Binding in with-optional must be a symbol") + (let [type (type-variable) + result (with-temporary-parameter-type [var type] + (expand-form* value))] + (with-type `(let [~var ~(e-use optional `(optional ~type))] + (when (some? ~var) + ~result)) + `(optional ~(type-of result))))) + +(defn ^:private quote-type [type escape?] + (cond + (escape? type) + type + (seq? type) + (cons 'list (map #(quote-type % escape?) type)) + ;; Reduce over sequences, vectors, and sets + (or (vector? type)) + (reduce (fn [result item] + (conj result (quote-type item escape?))) + [] type) + ;; Reduce over the values in maps + (map? type) + (reduce-kv (fn [result key value] + (assoc result key (quote-type value))) + {} type) + ;; Return everything else quoted. + :else + (list 'quote type))) + +(define-simple-operator number= (-> [number number] boolean)) +(def number=? number=) +(define-simple-operator number=? (-> [(optional number) (optional number)] (optional boolean))) + +;; Working out how exactly these should behave in the presence of +;; optionals is a bit tricky, mostly because of short-circuiting. The +;; easiest option is to not short circuit and define it as: "and? is +;; nil if any argument is nil, false if any argument is false, and +;; true otherwise". The obvious question then is "why does nil win +;; over false? Why not have it false, then nil, then true?" Working +;; out which makes the most sense might require some thinking. +;; TODO: work this out. +(define-simple-operator and + (-> [& (list boolean)] boolean)) +(define-simple-operator and? clojure.core/and + (-> [& (list (optional boolean))] (optional boolean))) + +(define-simple-operator or + (-> [& (list boolean)] boolean)) +(defmacro or? [& values] + (if-let [[x & xs] (seq values)] + `(let [val# ~x] + (cond (nil? val#) nil + (true? val#) true + :else `(or? ~@xs))) + false)) +(define-simple-operator or? + (-> [& (list (optional boolean))] (optional boolean))) + +(define-simple-operator not + (-> [boolean] boolean)) +(defn not? [value] + (cond (nil? value) nil + (true? value) false + :else true)) +(define-simple-operator not? + (-> [(optional boolean)] (optional boolean))) + +(define-simple-operator get + (∀ [k v] (-> [(map k v) k] (optional v)))) + +(define-simple-operator str + (-> [& (list string)] string)) + +(def str? str) +(define-simple-operator str? + (-> [& (list (optional string))] string)) + +(define-simple-operator count + (-> [(list any)] number)) + +(def has? some?) +(define-simple-operator has? + (-> [(optional any)] boolean)) + + + +(import java.time.OffsetDateTime + java.time.ZonedDateTime + java.time.temporal.ChronoField + java.time.format.DateTimeFormatterBuilder) + +(def date-time-format + (-> (DateTimeFormatterBuilder.) + (.parseCaseInsensitive) + (.appendValue ChronoField/YEAR) + (.appendLiteral "-") + (.appendValue ChronoField/MONTH_OF_YEAR) + (.appendLiteral "-") + (.appendValue ChronoField/DAY_OF_MONTH) + (-> .optionalStart + (.appendLiteral "T") + (.appendValue ChronoField/HOUR_OF_DAY) + (.appendLiteral ":") + (.appendValue ChronoField/MINUTE_OF_HOUR) + (-> .optionalStart + (.appendLiteral ":") + (.appendValue ChronoField/SECOND_OF_MINUTE) + .optionalEnd) + .optionalEnd) + (-> .optionalStart + (.appendOffset "+HH:mm" "Z") + .optionalEnd) + (.parseDefaulting ChronoField/HOUR_OF_DAY 0) + (.parseDefaulting ChronoField/MINUTE_OF_HOUR 0) + (.parseDefaulting ChronoField/SECOND_OF_MINUTE 0) + (.toFormatter) + (.withZone java.time.ZoneOffset/UTC))) + +(defn parse-timestamp [string] + (.withOffsetSameInstant (OffsetDateTime/parse string date-time-format) + (java.time.ZoneOffset/UTC))) + +(parse-timestamp "2021-02-23") + +(define-simple-operator parse-timestamp + (-> [string] timestamp)) + +(defn time-unit->chrono-unit [time-unit] + (condp #(.equalsIgnoreCase ^String %1 ^String %2) + time-unit + "second" java.time.temporal.ChronoUnit/SECONDS + "minute" java.time.temporal.ChronoUnit/MINUTES + "hour" java.time.temporal.ChronoUnit/HOURS + "day" java.time.temporal.ChronoUnit/DAYS + "month" java.time.temporal.ChronoUnit/MONTHS + "year" java.time.temporal.ChronoUnit/YEARS)) +(defn truncate-timestamp [^OffsetDateTime time time-unit] + (.truncatedTo time (time-unit->chrono-unit time-unit))) +(defn truncate-timestamp? [time time-unit] + (and time time-unit (truncate-timestamp time time-unit))) + +(define-simple-operator truncate-timestamp + (-> [timestamp (enum "second" "minute" "hour" "day" "month" "year")] timestamp)) +(define-simple-operator truncate-timestamp? + (-> [(optional timestamp) + (optional (enum "second" "minute" "hour" "day" "month" "year"))] + (optional timestamp))) + +(define-simple-operator then jester.core/then + (∀ [x y] (-> [x y] y))) + +;; (alter-var-root #'operators +;; assoc 'str {:type #(quote (-> [& (list string)] string)) +;; :name 'str}) + +;; ;; (alter-var-root #'operators +;; ;; assoc 'get {:type #(let [k (type-variable) +;; ;; v (type-variable)] +;; ;; `(-> [(map ~k ~v) ~k] (optional ~v)))}) + +;; (alter-var-root #'operators +;; assoc 'str? {:type #(quote (-> [& (list (optional string))] string)) +;; :name 'str}) + +;; (alter-var-root #'operators +;; assoc 'count {:type #(quote (-> [(list any)] number)) +;; :name 'count}) diff --git a/src/jester/match.clj b/src/jester/match.clj new file mode 100644 index 0000000..5d18aec --- /dev/null +++ b/src/jester/match.clj @@ -0,0 +1,142 @@ +(ns jester.match + "A simple pattern matcher, to avoid pulling in core.match. It is also + designed to specifically match against types, so it has some special + symbol handling." + (:require [clojure.walk :as walk])) + +(def ^:dynamic ^:private *seen-vars*) + +(defn ^:private special-type-symbol? [symbol] + (and (symbol? symbol) + (contains? #{"string" "number" "boolean" "any" "none" "_" "&"} + (name symbol)))) + +(defmacro ^:private ensuring-unique-vars + {:style/indent 0} + [& body] + `(binding [*seen-vars* {}] + (let [result# (do ~@body) + multiple-vars# (into #{} + (comp (filter (fn [[_# v#]] (> v# 1))) + (map key)) + *seen-vars*)] + (when-not (empty? multiple-vars#) + (throw (ex-info "Variables are bound multiple times" + {:names (mapv symbol multiple-vars#)}))) + result#))) + +(declare pattern->condition) + +(defn seq-pattern->condition [pattern value] + (if-let [[pat-head & pat-tail] (seq pattern)] + (if (= pat-head '&) + (pattern->condition (first pat-tail) value) + (let [head-s (gensym "head") + tail-s (gensym "tail")] + `(let [[~head-s & ~tail-s] ~value] + (and ~(pattern->condition pat-head head-s) + ~(seq-pattern->condition pat-tail tail-s))))) + true)) + +(defn ^:private pattern->condition [pattern value] + (cond + (vector? pattern) + (let [value-s (gensym "value")] + `(let [~value-s ~value] + (and (vector? ~value-s) + ~@(->> pattern + (take-while #(not= % '&)) + (map-indexed (fn [i p] + (pattern->condition p `(get ~value-s ~i)))) + doall) + ~@(when (seq (drop-while #(not= % '&) pattern)) + [(pattern->condition (second (drop-while #(not= % '&) pattern)) + `(subvec ~value-s + ~(count + (take-while #(not= % '&) + pattern))))])))) + (seq? pattern) + (let [[head & tail] pattern] + (assert (symbol? head) (str "Head of a seq pattern must be a symbol, not " (pr-str head))) + (let [head-s (gensym "head") + tail-s (gensym "tail")] + `(let [v# ~value] + (when (seq? v#) + (let [[~head-s & ~tail-s] v#] + (and (symbol? ~head-s) + (= ~(name head) (name ~head-s)) + ~(seq-pattern->condition tail tail-s))))))) + (special-type-symbol? pattern) + (if (= (name pattern) "_") + true + `(let [v# ~value] + (and (symbol? v#) + (= ~(name pattern) (name v#))))) + (symbol? pattern) + (do (when-not (= (name pattern) "_") + (set! *seen-vars* (update *seen-vars* (name pattern) (fnil inc 0)))) + true) + :else + `(= ~pattern ~value))) + +(defn ^:private pattern->destructuring-form [pattern] + (cond + (vector? pattern) (into [] (map pattern->destructuring-form) pattern) + (seq? pattern) (into ['_] (map pattern->destructuring-form) (rest pattern)) + (symbol? pattern) (if (= pattern '&) + '& + (if (special-type-symbol? pattern) + '_ + pattern)) + :else '_)) + +(defmacro type-match-let + {:style/indent 1} + [[pattern value] & body] + (ensuring-unique-vars + (let [value-s (gensym "value")] + `(let [~value-s ~value] + (if ~(pattern->condition pattern value-s) + (let [~(pattern->destructuring-form pattern) ~value-s] + ~@body) + (throw (ex-info "Value did not match pattern" + {:pattern '~pattern + :value ~value-s}))))))) + +(defmacro type-match + {:style/indent 1} + [value & clauses] + (let [value-s (gensym "value")] + `(let [~value-s ~value] + (cond + ~@(mapcat (fn [[pattern result]] + (ensuring-unique-vars + [(pattern->condition pattern value-s) + `(let [~(pattern->destructuring-form pattern) + ~value-s] + ~result)])) + (partition 2 clauses)) + :else + (throw (ex-info "Value did not match any pattern" + {:patterns '~(mapv first (partition 2 clauses)) + :value ~value-s})))))) + +(defmacro defn-type-match [fn-name & clauses] + (let [[doc clauses] (if (and (string? (first clauses)) + (odd? (count clauses))) + [(first clauses) (rest clauses)] + [nil clauses]) + patterns (map first (partition 2 clauses)) + all-symbols? (fn [pattern] + (every? (fn [s] + (and (symbol? s) (not (special-type-symbol? s)))) + pattern)) + argument-symbols (or (seq (first (filter all-symbols? patterns))) + (map #(do % (gensym "arg")) (first patterns)))] + (assert (every? vector? patterns) "All patterns in a defn-type-match must be a vector") + (assert (apply = (map count patterns)) "All patterns in a defn-type-match must have the same number of items") + `(defn ~fn-name + ~@(when doc [doc]) + [~@argument-symbols] + (type-match [~@argument-symbols] + ~@clauses)))) diff --git a/src/jester/types.clj b/src/jester/types.clj new file mode 100644 index 0000000..9451ea5 --- /dev/null +++ b/src/jester/types.clj @@ -0,0 +1,633 @@ +(ns jester.types + (:require [clojure.string :as str] + [jester.comparisons :refer [string= number= boolean=]] + [jester.match :refer [type-match-let type-match defn-type-match]])) + +;; Valid jester types are: +;; +;; These types are all "atomic": +;; - any (supertype of all types) +;; - none (subtype of all types) +;; - number, string, boolean +;; - (enum "a" ...), subtype of string +;; - (enum 0 ...), subtype of number +;; - (enum true ...), subtype of boolean + +;; These types are all "compound": +;; - (optional α) +;; - (list α), a list of values satisfying α +;; - [α β], a tuple of α and β +;; - [α β & γ], a tuple of α and β, and an additional sequence which matches γ +;; - (map α β), a map of αs to βs +;; - (-> [α β & γ] δ), a function taking an α, a β, and a sequence matching γ to δ +;; - records, denoted by a map of property names to types + +;; Subtyping relationships are: +;; +;; - α ≤ any +;; - (enum "a" ...) ≤ string +;; - (enum 0 ...) ≤ number +;; - (enum true ...) ≤ boolean +;; - α ≤ (optional α) +;; - [α α] ≤ (list α) +;; - [α α & (list α)] ≤ (list α) +;; - {l₁ α, l₂ β} ≤ {l₁ α} +;; ... and more! + +(defn ^:private split-rest [coll] + (let [[main rest] (split-with #(not= % '&) coll)] + (if (seq rest) + (do (assert (= (count rest) 2) "Tail must consist of only one element") + [main (second rest)]) + [main nil]))) + +(defn ^:private assert-type* + [object type path root-object root-type] + (letfn [(type-error [message & format-args] + (throw (ex-info (apply format message format-args) + {:object object, :root-object root-object + :type type, :root-type root-type + :path path})))] + (type-match type + any true + none (type-error "No value can satisfy none, but got %s" (pr-str object)) + + string (when-not (string? object) + (type-error "Expected a string, but got %s" (pr-str object))) + number (when-not (number? object) + (type-error "Expected a number, but got %s" (pr-str object))) + boolean (when-not (boolean? object) + (type-error "Expected a boolean, but got %s" (pr-str object))) + + (enum & values) + (when-not (some #(cond + (string? %) (and (string? object) (string= % object)) + (number? %) (and (number? object) (number= % object)) + (boolean? %) (and (boolean? object) (boolean= % object)) + :else (assert false "Invalid enum value")) + values) + (if (empty? values) + (type-error "Empty enumeration type cannot have a value, but got %s" + (pr-str object)) + (type-error "Expected %s, but got %s" + (cond + (= (count values) 1) (pr-str (first values)) + (= (count values) 2) (str (pr-str (first values)) " or " (pr-str (second values))) + :else (str (str/join ", " (map pr-str (butlast values))) ", or " (pr-str (last values)))) + (pr-str object)))) + + (optional t) + (when-not (nil? object) + (assert-type* object t path root-object root-type)) + + [& types] + (if (sequential? object) + (let [[main rest] (split-rest types)] + (if (< (count object) (count main)) + (type-error "Expected at least %s item%s, but got %s" (count main) (if (> (count main) 1) "s" "") (count object)) + (do (reduce (fn [index [item-type item]] + (assert-type* item item-type (conj path index) root-object root-type) + (inc index)) + 0 (map vector main object)) + (if rest + (assert-type* (drop (count main) object) rest (conj path (list 'drop (count main))) root-object root-type) + (when-not (= (count object) (count main)) + (type-error "Expected at most %s item%s, but got %s" (count main) (if (> (count main) 1) "s" "") (count object))))))) + (type-error "Expected a sequential object, but got %s" (pr-str object))) + + (list item-type) + (if (sequential? object) + (reduce (fn [index item] + (assert-type* item item-type (conj path index) root-object root-type) + (inc index)) + 0 object) + (type-error "Expected a sequential object, but got %s" (pr-str object))) + + (map k v) + (if (map? object) + (reduce-kv (fn [_ key value] + (assert-type* key k type root-object root-type) + (assert-type* value v (conj path key) root-object root-type)) + nil object) + (type-error "Expected a map, but got %s" (pr-str object))) + + (-> args result) + (type-error "Cannot verify function type of %s for %s" (pr-str type) (pr-str object)) + + _ + (if (map? type) + (if (map? object) + (reduce-kv (fn [_ key key-type] + (assert-type* (get object key) key-type (conj path key) root-object root-type)) + nil type) + (type-error "Expected an object (map), but got %s" (pr-str object))) + (type-error "Invalid type: %s" (pr-str type)))))) + +(defn assert-type + "Assert that `object` is of type `type`. Throws an exception with + failure details if this is not the case. Returns nil otherwise." + [object type] + (assert-type* object type [] object type) + nil) + +(defn-type-match subtype? + "Returns true if every object of type `sub` also satisfies the type + `super`. Returns false otherwise." + + [_ any] true + [none _] true + + [(enum & values) string] (every? string? values) + [(enum & values) number] (every? number? values) + [(enum & values) boolean] (every? boolean? values) + + [(enum & sub-values) (enum & super-values)] + (every? (fn [sub-value] + (cond (string? sub-value) (some #(and (string? %) (string= sub-value %)) + super-values) + (number? sub-value) (some #(and (number? %) (number= sub-value %)) + super-values) + (boolean? sub-value) (some #(and (boolean? %) (boolean= sub-value %)) + super-values) + :else (assert false "We should not reach here."))) + sub-values) + + [(optional subtype) (optional supertype)] + (subtype? subtype supertype) + + [subtype (optional supertype)] + (subtype? subtype supertype) + + ;; This is unfortunately quite complicated. :( + [[& subtypes] [& supertypes]] + (let [[sub-main sub-rest] (split-rest subtypes) + [super-main super-rest] (split-rest supertypes)] + (and + ;; The subtype must guarantree at least as many elements as the + ;; supertype. + (>= (count sub-main) (count super-main)) + ;; Any compulsory types from both arrays are subtypes + (every? true? (map subtype? sub-main super-main)) + (or + ;; If there are no excess compulsory subtypes then we're good. + (= (count sub-main) (count super-main)) + ;; Otherwise, we need to check them against the super-rest. + (if super-rest + (subtype? (->> sub-main + (drop (count super-main)) + vec) + super-rest) + ;; If there's no super-rest, then we just have excess types, + ;; which means there's no subtype relationship here. + false)) + ;; If the subtype has a rest, then the supertype does too and + ;; they have an appropriate subtyping relationship + (if sub-rest + (and super-rest + (subtype? sub-rest super-rest)) + true))) + + [[& subtypes] (list supertype)] + (let [[sub-main sub-rest] (split-rest subtypes)] + (and (every? #(subtype? % supertype) sub-main) + (if sub-rest + (subtype? sub-rest `(list ~supertype)) + true))) + + [(list subtype) (list supertype)] + (subtype? subtype supertype) + + [(map sub-key sub-val) (map super-key super-val)] + (and (subtype? super-key sub-key) + (subtype? sub-val super-val)) + + [(-> sub-args sub-result) (-> super-args super-result)] + (and (subtype? super-args sub-args) + (subtype? sub-result super-result)) + + [subtype supertype] + (cond + (and (map? subtype) (map? supertype)) + (reduce-kv (fn [_ prop prop-type] + (or (subtype? (get subtype prop) prop-type) + (reduced false))) + nil supertype) + + (and (symbol? subtype) (symbol? supertype)) + (= (name subtype) (name supertype)) + + :else + false)) + +(def ^:private ^:dynamic *upper-bounds*) +(def ^:private ^:dynamic *lower-bounds*) + +(defn call-in-constraint-environment [thunk] + (binding [*upper-bounds* {} + *lower-bounds* {}] + (thunk))) + +(defmacro in-constraint-environment + {:style/indent 0} + [& body] + `(call-in-constraint-environment #(do ~@body))) + +(defn-type-match constrain + "Add a constraint that `sub` is a subtype of `super` within the + current constraint environment (see `in-constraint-environment`). + The return value of this function is meaningless, and it will throw + an exception if the provided constraint leads to a contradiction." + + ;; No point doing anything for the constraints that aren't really constraints. + [_ any] nil + [none _] nil + + [subtype (var n)] + (when-not (contains? (get *lower-bounds* n) subtype) + (set! *lower-bounds* (update *lower-bounds* n (fnil conj #{}) subtype)) + (doseq [upper (get *upper-bounds* n)] + (constrain subtype upper)) + ;; The type hierarchy splits for all of the "atomic" types, so if + ;; we're constrained to be a supertype of one of the divisions + ;; then add a constraint on the top as well. While there is still + ;; the `any` type at the top of the hierachy, we only want it to + ;; show up for truly unconstrained types. This makes things like + ;; (? a 10) infer `a` to be (optional number) rather than the less + ;; accurate/helpful (optional any). + (type-match subtype + string (constrain `(var ~n) `(optional string)) + number (constrain `(var ~n) `(optional number)) + boolean (constrain `(var ~n) `(optional boolean)) + (enum & values) (do (when (some string? values) + (constrain `(var ~n) `(optional string))) + (when (some number? values) + (constrain `(var ~n) `(optional number))) + (when (some boolean? values) + (constrain `(var ~n) `(optional boolean)))) + _ nil)) + + [(var n) supertype] + (when-not (contains? (get *upper-bounds* n) supertype) + (set! *upper-bounds* (update *upper-bounds* n (fnil conj #{}) supertype)) + (doseq [lower (get *lower-bounds* n)] + (constrain lower supertype)) + ;; If we're a subtype of an optional type then add an artificial + ;; "unoptional" constraint to track the constraint against the + ;; wrapped type variable. + (type-match supertype + (optional x) (constrain `(unoptional (var ~n)) + x) + _ nil)) + + [subtype (optional super)] + (constrain (loop [subtype subtype] + (type-match subtype + (optional sub) (recur sub) + _ subtype)) + super) + + [(unoptional _) _] + nil ;; This is a weird extra constraint we add to propagate the + ;; restrictions imposed by having an optional on the RHS. It + ;; doesn't impose any other constraint, so just ingore it. + + [[& subtypes] [& supertypes]] + (let [[sub-main sub-rest] (split-rest subtypes) + [super-main super-rest] (split-rest supertypes)] + (when (< (count sub-main) (count super-main)) + (throw (ex-info "Constraint error: cannot solve type relation" + {:subtype (vec subtypes) + :supertype (vec supertypes)}))) + (doall (map constrain sub-main super-main)) + (when-not (= (count sub-main) (count super-main)) + (if super-rest + (constrain (->> sub-main + (drop (count super-main)) + vec) + super-rest) + (throw (ex-info "Constraint error: cannot solve type relation" + {:subtype (vec subtypes) + :supertype (vec supertypes)})))) + (when sub-rest + (if super-rest + (constrain sub-rest super-rest) + (throw (ex-info "Constraint error: cannot solve type relation" + {:subtype (vec subtypes) + :supertype (vec supertypes)}))))) + + [[& subtypes] (list supertype)] + (let [[sub-main sub-rest] (split-rest subtypes)] + (doall (map #(constrain % supertype) sub-main)) + (when sub-rest + (constrain sub-rest `(list ~supertype)))) + + [(list sub) (list super)] + (constrain sub super) + + [(map subk subv) (map superk superv)] + (do (constrain superk subk) + (constrain subv superv)) + + [(-> sub-args sub-result) (-> super-args super-result)] + (do (constrain super-args sub-args) + (constrain sub-result super-result)) + + [subtype supertype] + (cond + (and (map? subtype) (map? supertype)) + (doseq [[property super-value] supertype + :let [sub-value (get subtype property)]] + (if (nil? sub-value) + (throw (ex-info "Object type does not meet subtype constraint" + {:subtype subtype + :supertype supertype})) + (constrain sub-value super-value))) + + (not (subtype? subtype supertype)) + (throw (ex-info "Constraint error: cannot solve type relation" + {:subtype subtype + :supertype supertype})))) + +;; ;; This helper just prints out all the constraints that get added. +;; (def constrain (let [c constrain] +;; (fn [a b] +;; (prn a '≤ b) +;; (c a b)))) + +(declare union-types) + +(defn-type-match ^:private intersect-types + "Return a type that is a subtype of both `t1` and `t2`. The + resulting type should be the greatest such type (that is, for all x + that are subtypes of both t1 and t2, x is a subtype of, or equal + to, (intersect-types t1 t2))." + + [any t] t + [t any] t + [none _] 'none + [_ none] 'none + + [(enum & t1values) (enum & t2values)] + (if-let [common-values (seq (filter (fn [t1value] + (cond (string? t1value) (some #(and (string? %) (string= t1value %)) + t2values) + (number? t1value) (some #(and (number? %) (number= t1value %)) + t2values) + (boolean? t1value) (some #(and (boolean? %) (boolean= t1value %)) + t2values) + :else (assert false "We should not reach here."))) + t1values))] + (cons 'enum common-values) + 'none) + + [(optional t1) (optional t2)] + (list 'optional (intersect-types t1 t2)) + + [(optional t1) t2] + (intersect-types t1 t2) + [t1 (optional t2)] + (intersect-types t1 t2) + + [[& t1s] [& t2s]] + (let [[t1-main t1-rest] (split-rest t1s) + [t2-main t2-rest] (split-rest t2s)] + (cond + (empty? t1-main) + (intersect-types t1-rest t2s) + (empty? t2-main) + (intersect-types t1s t2-rest) + (= (count t1-main) (count t2-main)) + (into (mapv intersect-types t1-main t2-main) + (when (and t1-rest t2-rest) + ['& (intersect-types t1-rest t2-rest)])) + (< (count t1-main) (count t2-main)) + (if t1-rest + (into (mapv intersect-types t1-main t2-main) + (concat (intersect-types t1-rest + (->> t2-main + (drop (count t1-main)) + vec)) + (when t2-rest + ['& (intersect-types t1-rest t2-rest)]))) + (throw (ex-info "No value can possible satisfy type" + {:type (list 'intersect t1 t2)}))) + (> (count t1-main) (count t2-main)) + (if t2-rest + (into (mapv intersect-types t1-main t2-main) + (concat (intersect-types (->> t1-main + (drop (count t2-main)) + vec) + t2-rest) + (when t1-rest + ['& (intersect-types t1-rest t2-rest)]))) + (throw (ex-info "No value can possible satisfy type" + {:type (list 'intersect t1 t2)}))) + :else + (throw (ex-info "No value can possible satisfy type" + {:type (list 'intersect t1 t2)})))) + + [[& t1s] (list t2)] + (mapv #(intersect-types % t2) t1s) + + [(list t1) [& t2s]] + (mapv #(intersect-types t1 %) t2s) + + [(list t1) (list t2)] + (list 'list (intersect-types t1 t2)) + + [(map t1k t1v) (map t2k t2v)] + (list 'map + (union-types t1k t2k) + (intersect-types t1v t2v)) + + [(-> t1k t1v) (-> t2k t2v)] + (list '-> + (union-types t1k t2k) + (intersect-types t1v t2v)) + + [t1 t2] + (cond + (and (map? t1) (map? t2)) (merge-with intersect-types t1 t2) + (subtype? t1 t2) t1 + (subtype? t2 t1) t2 + :else (throw (ex-info "No value can possible satisfy type" + {:type (list 'intersect t1 t2)})))) + +(defn-type-match ^:private union-types + "Return a type that is a supertype of both `t1` and `t2`. The + resulting type should be the least such type (that is, for all x + that are supertypes of both t1 and t2, x is a supertype of, or equal + to, (union-types t1 t2))." + + [any _] 'any + [_ any] 'any + [none t] t + [t none] t + + [(enum & t1values) (enum & t2values)] + (cons 'enum + (concat (remove (fn [t1value] + (cond (string? t1value) (some #(and (string? %) (string= t1value %)) + t2values) + (number? t1value) (some #(and (number? %) (number= t1value %)) + t2values) + (boolean? t1value) (some #(and (boolean? %) (boolean= t1value %)) + t2values) + :else (assert false "We should not reach here."))) + t1values) + t2values)) + + [(optional t1) (optional t2)] + (list 'optional (union-types t1 t2)) + + [(optional t1) t2] + (list 'optional (union-types t1 t2)) + [t1 (optional t2)] + (list 'optional (union-types t1 t2)) + + [[& t1s] [& t2s]] + (let [[t1-main t1-rest] (split-rest t1s) + [t2-main t2-rest] (split-rest t2s)] + (cond + (empty? t1-main) + (union-types t1-rest t2s) + (empty? t2-main) + (union-types t1s t2-rest) + (= (count t1-main) (count t2-main)) + (into (mapv union-types t1-main t2-main) + (when (and t1-rest t2-rest) + ['& (union-types t1-rest t2-rest)])) + (< (count t1-main) (count t2-main)) + (if t1-rest + (into (mapv union-types t1-main t2-main) + (concat (union-types t1-rest + (->> t2-main + (drop (count t1-main)) + vec)) + (when t2-rest + ['& (union-types t1-rest t2-rest)]))) + (throw (ex-info "Cannot construct type union" + {:type (list 'union t1 t2)}))) + (> (count t1-main) (count t2-main)) + (if t2-rest + (into (mapv union-types t1-main t2-main) + (concat (union-types (->> t1-main + (drop (count t2-main)) + vec) + t2-rest) + (when t1-rest + ['& (union-types t1-rest t2-rest)]))) + (throw (ex-info "Cannot construct type union" + {:type (list 'union t1 t2)}))) + :else + (throw (ex-info "Cannot construct type union" + {:type (list 'union t1 t2)})))) + + [[& t1s] (list t2)] + (let [[t1-main t1-rest] (split-rest t1s)] + (into (mapv #(union-types % t2) t1-main) + (if t1-rest + ['& (union-types t1-rest t2)] + ['& `(list ~t2)]))) + + [(list t1) [& t2s]] + (let [[t2-main t2-rest] (split-rest t2s)] + (into (mapv #(union-types t1 %) t2-main) + (if t2-rest + ['& (union-types t1 t2-rest)] + ['& `(list ~t1)]))) + + [(list t1) (list t2)] + (list 'list (union-types t1 t2)) + + [(map t1k t1v) (map t2k t2v)] + (list 'map + (intersect-types t1k t2k) + (union-types t1v t2v)) + + [(-> t1k t1v) (-> t2k t2v)] + (list '-> + (intersect-types t1k t2k) + (union-types t1v t2v)) + + [t1 t2] + (cond + (subtype? t1 t2) t2 + (subtype? t2 t1) t1 + :else (throw (ex-info "Cannot construct type union" + {:type (list 'union t1 t2)})))) + +(defn-type-match ground-type + "Attempt to eliminate type-variables from `type` by solving any + constraints that can be solved. If `position` is :argument then + variables will be solved for their least upper bound, if `position` + is :return + bound." + + [(var n) position] + (do (when-not (or (= position :argument) (= position :return)) + (throw (ex-info (str "Invalid position: " (pr-str position)) + {:position position}))) + (if-let [type-bounds (->> (get (case position + :argument *upper-bounds* + :return *lower-bounds*) + n) + (map #(ground-type % position)) + seq)] + (reduce (case position + :argument intersect-types + :return union-types) + type-bounds) + 'any)) + + [(enum & values) _] + (cons 'enum values) + + [(optional t) position] + (list 'optional + (type-match (ground-type t position) + (optional t2) t2 + t2 t2)) + + [(unoptional t) position] + (type-match (ground-type t position) + (optional t2) t2 + t2 t2) + + [[& ts] position] + (let [[t-main t-rest] (split-rest ts)] + (into (mapv #(ground-type % position) t-main) + (when t-rest + ['& (ground-type t-rest position)]))) + + [(list t) position] + (list 'list (ground-type t position)) + + [(map k v) position] + (list 'map + (ground-type k (case position + :argument :return + :return :argument)) + (ground-type v position)) + + [(-> k v) position] + (list '-> + (ground-type k (case position + :argument :return + :return :argument)) + (ground-type v position)) + + [type position] + (cond + (map? type) (persistent! + (reduce-kv (fn [acc prop prop-type] + (assoc! acc prop (ground-type prop-type position))) + (transient {}) type)) + (symbol? type) (symbol (name type)) + :else (throw (ex-info "Cannot ground invalid type" {:type type})))) + +(defn type-variable + "Create a new type variable, distinct from all existing type + variables." + [] + (list 'var (gensym "type"))) -- cgit v1.2.3