45 lines
1.8 KiB
JavaScript
45 lines
1.8 KiB
JavaScript
"use strict";
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Object.defineProperty(exports, "__esModule", { value: true });
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exports.getApplicativeComposition = exports.getApplicativeMonoid = void 0;
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/**
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* The `Applicative` type class extends the `Apply` type class with a `of` function, which can be used to create values
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* of type `f a` from values of type `a`.
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*
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* Where `Apply` provides the ability to lift functions of two or more arguments to functions whose arguments are
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* wrapped using `f`, and `Functor` provides the ability to lift functions of one argument, `pure` can be seen as the
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* function which lifts functions of _zero_ arguments. That is, `Applicative` functors support a lifting operation for
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* any number of function arguments.
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*
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* Instances must satisfy the following laws in addition to the `Apply` laws:
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*
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* 1. Identity: `A.ap(A.of(a => a), fa) <-> fa`
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* 2. Homomorphism: `A.ap(A.of(ab), A.of(a)) <-> A.of(ab(a))`
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* 3. Interchange: `A.ap(fab, A.of(a)) <-> A.ap(A.of(ab => ab(a)), fab)`
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*
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* Note. `Functor`'s `map` can be derived: `A.map(x, f) = A.ap(A.of(f), x)`
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*
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* @since 2.0.0
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*/
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var Apply_1 = require("./Apply");
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var function_1 = require("./function");
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var Functor_1 = require("./Functor");
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function getApplicativeMonoid(F) {
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var f = (0, Apply_1.getApplySemigroup)(F);
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return function (M) { return ({
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concat: f(M).concat,
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empty: F.of(M.empty)
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}); };
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}
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exports.getApplicativeMonoid = getApplicativeMonoid;
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/** @deprecated */
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function getApplicativeComposition(F, G) {
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var map = (0, Functor_1.getFunctorComposition)(F, G).map;
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var _ap = (0, Apply_1.ap)(F, G);
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return {
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map: map,
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of: function (a) { return F.of(G.of(a)); },
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ap: function (fgab, fga) { return (0, function_1.pipe)(fgab, _ap(fga)); }
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};
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}
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exports.getApplicativeComposition = getApplicativeComposition;
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