ts-nat-comm/test.ts

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import { Nat, NatOf, Suc, Zero, suc, zero } from "./typeLevelNats";
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type GenericFunction = (...x: never[]) => unknown;
type Assume<T, U> = T extends U ? T : U;
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abstract class TypeFunc<Arg, Ret, Param = unknown> {
readonly _1?: Param;
abstract new: (_: Arg) => Ret;
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}
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type Apply<Arg, Ret, F extends TypeFunc<Arg, Ret>, _1> = ReturnType<
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(F & {
readonly _1: _1;
})["new"]
>;
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interface GetPrev<N extends Nat> extends TypeFunc<Suc<N>, N> {
new: (arg: Suc<N>) => N;
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}
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// nat-elim : (M : T -> U) -> (cz : M z) -> (sz : (n : N) -> M n -> M (suc n)) -> (n : N) -> M n
// (M : T -> U) -> (cz : M z) -> (sz : (n : N) -> M n -> M (suc n)) -> (n : N) -> M n
//
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interface ConstNat extends TypeFunc<any, Nat> {
new: (_: any) => Nat;
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}
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type NatElim0<
M extends TypeFunc<Nat, any>,
ZCase,
SCase extends TypeFunc<
Nat,
TypeFunc<Apply<Nat, any, M, Nat>, Apply<Nat, any, M, Suc<Nat>>>
>,
N
> =
/** --------------------------------------------------------------- */
N extends Zero // // if N matches Zero
? ZCase // return ZCase
: N extends Suc<infer Prev> // if N matches Suc(Prev)
? Apply<
any /* TODO: */,
any /* TODO: */,
Apply<
Nat,
TypeFunc<Apply<Nat, any, M, Nat>, Apply<Nat, any, M, Suc<Nat>>>,
SCase,
Prev
>,
Apply<Nat, any, M, Prev>
>
: never;
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/*
export interface DoubleSuc extends TypeFunc<Nat, Nat> {
new: (arg: Assume<this["_1"], Nat>) => Suc<Suc<typeof arg>>;
}
*/
interface ExampleM extends TypeFunc<Nat, null[]> {
new: (
arg: Nat
) => typeof arg extends Suc<infer Prev>
? ["x", ...Apply<Nat, null[], ExampleM, Prev>]
: [];
}
export const _1: Apply<Nat, null[], ExampleM, Zero> = [];
export const _2: Apply<Nat, null[], ExampleM, Zero> = [null];
/**
* M is the type family being mapped over
* M : (n : N) -> U
* M zero = Nat
*/
interface DoubleNat_M extends TypeFunc<Nat, any> {
new: (arg: Nat) => Nat;
/*
typeof arg extends Suc<infer Prev>
? Suc<Suc<Apply<Nat, Nat, DoubleNat_M, Prev>>>
: Zero; */
}
/**
* DoubleNat_SCase_App1 is what happens after applying 1 arg to DoubleNat_SCase
* (given n : N in the context)
* SCase_App1 : (prev : M n) -> M (suc n)
* SCase_App1 prev = prev + 2
*/
interface DoubleNat_SCase_App1<
M extends TypeFunc<Nat<any>, Nat<any>, any>,
N extends Nat<P>,
P = unknown
> extends TypeFunc<
Apply<Nat<P>, Nat<any>, M, N>, // (prev : M n)
Apply<Nat<Suc<P>>, Nat<any>, M, Suc<N>>, // -> M (suc n)
Nat<unknown>
> {
new: (prev: Assume<this["_1"], Nat<P>>) => Suc<Suc<typeof prev>>;
}
/**
* This is the suc case for DoubleNat:
* SCase : (n : N) -> (prev : M n) -> M (suc n)
*/
interface DoubleNat_SCase<M extends TypeFunc<Nat, Nat>>
extends TypeFunc<Nat, TypeFunc<Nat, Nat>> {
new: (arg: Nat) => DoubleNat_SCase_App1<M, typeof arg>;
}
export const _3: Apply<
Nat,
Nat,
Apply<Nat, TypeFunc<Nat, Nat>, DoubleNat_SCase<DoubleNat_M>, NatOf<4>>,
NatOf<4>
> = suc(suc(suc(suc(suc(suc(zero))))));
function isNatOfFour<T extends NatOf<4>>(_: T) {}
/* 3 */ isNatOfFour(undefined as unknown as Suc<Suc<Suc<Zero>>>);
/* 4 */ isNatOfFour(undefined as unknown as Suc<Suc<Suc<Suc<Zero>>>>);
/* 5 */ isNatOfFour(undefined as unknown as Suc<Suc<Suc<Suc<Suc<Zero>>>>>);
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interface DoubleNat extends TypeFunc<Nat, Nat> {
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new: (
arg: Nat
) => NatElim0<ConstNat, Zero, DoubleNat_SCase<ConstNat>, typeof arg>;
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}
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type Two = Suc<Suc<Zero>>;
function isTwo<F extends Two>(_: F) {}
isTwo(suc(zero));
isTwo(suc(suc(zero)));
isTwo(suc(suc(suc(zero))));
const realThree: Suc<Suc<Suc<Zero>>> = suc(suc(suc(zero)));
const realFour: Suc<Suc<Suc<Suc<Zero>>>> = suc(suc(suc(suc(zero))));
function isFour<F extends Apply<Nat, Nat, DoubleNat, Two>>(_: F) {}
isFour(realThree);
isFour(realFour);
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/*
interface NatElim<
MRet,
M extends TypeFunc<Nat, MRet>,
ZCase extends Apply<infer A, infer R, M<A, R>, Z>,
SCase extends TypeFunc
> extends TypeFunc {
_unused: (_1: ZCase, _2: SCase) => never;
new: (arg: Assume<this["_1"], Nat>) => Apply<M, typeof arg>;
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}
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*/
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/////
type Length<T extends any[]> = T extends { length: infer L } ? L : never;
type BuildTuple<L extends number, T extends any[] = []> = T extends {
length: L;
}
? T
: BuildTuple<L, [...T, any]>;
type Add<A extends number, B extends number> = Length<
[...BuildTuple<A>, ...BuildTuple<B>]
>;
type Equals<T, T1 extends T, T2 extends T> = { eq: [T1, T2] };
type Seven = Add<3, 4>; // 7
function isSeven(s: Seven) {}
isSeven(6);
isSeven(7);
///
class Eq<A, B> {
private a: (_: A) => A;
private b: (_: B) => B;
private constructor() {}
static refl<T>(): Eq<T, T> {
return new Eq();
}
}
function isEqual1(_: Eq<3, 3>) {}
isEqual1(Eq.refl());
function isEqual2(_: Eq<3, 4>) {}
isEqual2(Eq.refl());
function isEqual3(_: Eq<Add<3, 4>, 7>) {}
isEqual3(Eq.refl());
function isEqual4(_: Eq<Add<3, 4>, 8>) {}
isEqual4(Eq.refl());
///
type Commutative<A extends number, B extends number> = Eq<Add<A, B>, Add<B, A>>;
function comm<A extends number, B extends number>(): Commutative<A, B> {
return Eq.refl();
}