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Utility decorators to enable the use of features commonly found in functional languages for use with classes.

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Introduction

This library provides a number of utility decorators to enable the use of features commonly found in functional languages for use with classes.

Note that the license for this library is AGPL-3.0-only. You should know what that means before using this library. If you would like an exception to this license per section 7 contact the author.

Library Installation

As a dependency run the command:

npm install @final-hill/class-tools

You can also use a specific version:

npm install @final-hill/[email protected]

For use in a webpage:

<script src="https://unpkg.com/@final-hill/class-tools"></script>

With a specific version:

<script src="https://unpkg.com/@final-hill/[email protected]></script>

Memoization

The @memo decorator memoizes (caches) the results of the associated method call.

import {memo} from '@final-hill/class-tools';

class Fib {
    @memo
    calcMemo(n: number): number {
        return n < 2 ? n : this.calcMemo(n - 1) + this.calcMemo(n - 2);
    }
    calc(n: number): number {
        return n < 2 ? n : this.calc(n - 1) + this.calc(n - 2);
    }
}

fib.calc(30) // 832040; 9ms
fib.calcMemo(30) // 832040; less than 1ms

Currying

The @curry decorator converts the associated method into a method that supports currying the parameters.

import {curry} from '@final-hill/class-tools';

class Adder {
    @curry
    add(a: number, b: number): number {
        return a + b;
    }
}

const adder = new Adder(),
      addOne = adder.add(1);

addOne(3) // 4
addOne()(3) // 4

Partial Application

The @partial decorator converts the associated method into one that supports partial application of its parameters

import {partial, _} from '@final-hill/class-tools';

class A {
    @partial
    m(a: number, b: number, c: number): number { return a + b + c; }
}

const a = new A();

a.m(1,2,3) === 6
a.m(_,2,3)(1) === 6
a.m(1,_,3)(2) === 6
a.m(1,2,_)(3) === 6
a.m(1,_,_)(2,3) === 6
a.m(_,2,_)(1,3) === 6
a.m(_,_,3)(1,2) === 6
a.m(_,_,_)(1,2,3) === 6
a.m(_,_,_)(_,2,_)(1,3) === 6

Lazy Fields

The @lazy decorator converts the associated getter into a lazily initialized field. Practically this means that the body of the getter will only executed once on its first use. Subsequent usages will return the cached result of the first call.

import {lazy} from '@final-hill/class-tools';

class Counter {
    static usage = 0;
    constructor(){
        Counter.usage++;
    }
}

class Foo {
    @lazy
    get bar(): Counter { return new Counter(); }
}

const foo = new Foo();

void foo.bar;
void foo.bar;
void foo.bar;

Counter.usage // 1

Fixed-Point

The @fix decorator can be assigned to methods in order to control the behavior of its recursion and find its least fixed-point. It provides options to limit runaway recursion as well as handle self-referential calls while returning a value.

The bottom option defines the value to return when the recursive call bottoms out. In other words, if the current method has been recursively called with the same arguments then it is replaced with the value given.

import {fix} from '@final-hill/class-tools';

class Foo {
    @fix({bottom: 0})
    bar(): number {
        return this.bar();
    }
}

new Foo().bar() === 0;

Recursive calls may always vary in their arguments leading to runaway recursion in a different way. The limit option prevents infinite recursion by replacing the nth call with the value defined by the bottom option:

import {fix} from '@final-hill/class-tools';

class Foo {
    @fix({bottom: 0, limit: 10})
    bar(n: number): number {
        return 1 + this.bar(n + 1);
    }
}

new Foo().bar(0) === 10;

The bottom option can also be defined as a function if a computed result is desired:

import {fix} from '@final-hill/class-tools';

class Foo {
    @fix({bottom: (n: number) => n**2})
    bar(n: number): number {
        if(n <= 3) {
            return 1 + this.bar(n + 1);
        } else {
            return this.bar(n); // bottom(4) == 4**2 == 16
        }
    }
}
new Foo().bar(0) === 20;

Known Limitations

When using TypeScript a decorator can not change the type of the associated class feature. This is a limitation of the language. Depending on your usage you may need to perform explicit casting or utilize the // @ts-ignore option. For example:

import {partial, _} from '@final-hill/class-tools';

class A {
    @partial
    m(a: number, b: number, c: number): number { return a + b + c; }
}

const a = new A();

a.m(1,2,3) === 6
// @ts-ignore
a.m(_,2,3)(1) === 6
// @ts-ignore
a.m(1,_,3)(2) === 6
// @ts-ignore
a.m(1,2,_)(3) === 6

Further Reading

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Utility decorators to enable the use of features commonly found in functional languages for use with classes.

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