11

Let's start with a definition: A transducer is a function that takes a reducer function and returns a reducer function.

A reducer is a binary function that takes an accumulator and a value and returns an accumulator. A reducer can be executed with a reduce function (note: all function are curried but I've cat out this as well as definitions for pipe and compose for the sake of readability - you can see them in live demo):

const reduce = (reducer, init, data) => {
  let result = init;
  for (const item of data) {
    result = reducer(result, item);
  }
  return result;
}

With reduce we can implement map and filter functions:

const mapReducer = xf => (acc, item) => [...acc, xf(item)];
const map = (xf, arr) => reduce(mapReducer(xf), [], arr);

const filterReducer = predicate => (acc, item) => predicate(item) ?
  [...acc, item] :
  acc;
const filter = (predicate, arr) => reduce(filterReducer(predicate), [], arr);

As we can see there're a few similarities between map and filter and both of those functions work only with arrays. Another disadvantage is that when we compose those two functions, in each step a temporary array is created that gets passed to another function.

const even = n => n % 2 === 0;
const double = n => n * 2;

const doubleEven = pipe(filter(even), map(double));

doubleEven([1,2,3,4,5]);
// first we get [2, 4] from filter
// then final result: [4, 8]

Transducers help us solve that concerns: when we use a transducer there are no temporary arrays created and we can generalize our functions to work not only with arrays. Transducers need a transduce function to work Transducers are generally executed by passing to transduce function:

const transduce = (xform, iterator, init, data) =>
  reduce(xform(iterator), init, data);

const mapping = (xf, reducer) => (acc, item) => reducer(acc, xf(item));

const filtering = (predicate, reducer) => (acc, item) => predicate(item) ?
  reducer(acc, item) :
  acc;

const arrReducer = (acc, item) => [...acc, item];

const transformer = compose(filtering(even), mapping(double));

const performantDoubleEven = transduce(transformer, arrReducer, [])

performantDoubleEven([1, 2, 3, 4, 5]); // -> [4, 8] with no temporary arrays created

We can even define array map and filter using transducer because it's so composable:

const map = (xf, data) => transduce(mapping(xf), arrReducer, [], data);

const filter = (predicate, data) => transduce(filtering(predicate), arrReducer, [], data);

live version if you'd like to run the code -> https://runkit.com/marzelin/transducers

Does my reasoning makes sense?

10
  • 2
    I didn't read your code, but the description is correct, and the output looks correct. Just remember that there are two ways to perform a series of transformations on a list: you can apply the first transform to every element, then the second, etc. Or you can compose the transformations, apply the combined transform to the first element, then the second, etc. Transducers are the second thing. They're even cooler than that, nothing about them says anything about the nature of the collection, so you can use them on Observables, generators, etc. Sep 11, 2018 at 11:04
  • 1
    I implemented transducers in JavaScript a while back for fun, you can check the repo and compare notes if you like. Sep 11, 2018 at 11:10
  • 1
    This is good. Didn't know transducers was a thing before this.
    – rmn
    Sep 11, 2018 at 11:12
  • 1
    @rmn they were developed for the Clojure language, but you can implement them in just about any language with higher-order functions. See this for details Sep 11, 2018 at 11:13
  • 1
    Yes, your understanding seems to be fine and match the common expectations. Where did you learn from? Notice that for js specifically, there's also an interoperability protocol.
    – Bergi
    Sep 11, 2018 at 12:21

1 Answer 1

3

Your understanding is correct but incomplete.

In addition to the concepts you've described, transducers can do the following:

  • Support a early exit semantic
  • Support a completion semantic
  • Be stateful
  • Support an init value for the step function.

So for instance, an implementation in JavaScript would need to do this:

// Ensure reduce preserves early termination
let called = 0;
let updatesCalled = map(a => { called += 1; return a; });
let hasTwo = reduce(compose(take(2), updatesCalled)(append), [1,2,3]).toString();
console.assert(hasTwo === '1,2', hasTwo);
console.assert(called === 2, called);

Here because of the call to take the reducing operation bails early.

It needs to be able to (optionally) call the step function with no arguments for an initial value:

// handles lack of initial value
let mapDouble = map(n => n * 2);
console.assert(reduce(mapDouble(sum), [1,2]) === 6);

Here a call to sum with no arguments returns the additive identity (zero) to seed the reduction.

In order to accomplish this, here's a helper function:

const addArities = (defaultValue, reducer) => (...args) => {
  switch (args.length) {
    case 0: return typeof defaultValue === 'function' ? defaultValue() : defaultValue;
    case 1: return args[0];
    default: return reducer(...args);
  }
};

This takes an initial value (or a function that can provide one) and a reducer to seed for:

const sum = addArities(0, (a, b) => a + b);

Now sum has the proper semantics, and it's also how append in the first example is defined. For a stateful transducer, look at take (including helper functions):

// Denotes early completion
class _Wrapped {
  constructor (val) { this[DONE] = val }
};

const isReduced = a => a instanceof _Wrapped;
// ensures reduced for bubbling
const reduced = a => a instanceof _Wrapped ? a : new _Wrapped(a);
const unWrap = a => isReduced(a) ? a[DONE] : a;

const enforceArgumentContract = f => (xform, reducer, accum, input, state) => {
  // initialization
  if (!exists(input)) return reducer();
  // Early termination, bubble
  if (isReduced(accum)) return accum;
  return f(xform, reducer, accum, input, state);
};

/*
 * factory
 *
 * Helper for creating transducers.
 *
 * Takes a step process, intial state and returns a function that takes a
 * transforming function which returns a transducer takes a reducing function,
 * optional collection, optional initial value. If collection is not passed
 * returns a modified reducing function, otherwise reduces the collection.
 */
const factory = (process, initState) => xform => (reducer, coll, initValue) => {
  let state = {};
  state.value = typeof initState === 'function' ? initState() : initState;
  let step = enforceArgumentContract(process);
  let trans = (accum, input) => step(xform, reducer, accum, input, state);
  if (coll === undefined) {
    return trans; // return transducer
  } else if (typeof coll[Symbol.iterator] === 'function') {
    return unWrap(reduce(...[trans, coll, initValue].filter(exists))); 
  } else {
    throw NON_ITER;
  }
};

const take = factory((n, reducer, accum, input, state) => {
  if (state.value >= n) {
    return reduced(accum);
  } else {
    state.value += 1;
  }
  return reducer(accum, input);
}, () => 0);

If you want to see all of this in action I made a little library a while back. Although I ignored the interop protocol from Cognitect (I just wanted to get the concepts) I did try to implement the semantics as accurately as possible based on Rich Hickey's talks from Strange Loop and Conj.

2
  • To be honest, these are mostly hacks and not very clean. Especially providing an init value and adding state to it is easily messed up (IIRC the cognitect protocol had a fundamental problem there, not sure how much your implementation deviates). I can't recommend doing the distinction between the functionalities based on the arguments length - overloading methods like that seems fine in clojure but it is not in JavaScript (especially, functional JavaScript).
    – Bergi
    Sep 11, 2018 at 15:59
  • @Bergi I had no intention for this to be production-ready (I didn't even add a testing framework, just used console.assert). I just naively implemented it for fun, transcribing as I watched the talk. If I wanted to actually use transducers, I'd use e.g. Ramda. I also agree that arity overloading isn't very JavaScript-y, but again, naively transcribed. OP was asking if (s)he understood the concepts behind transducers, and I've tried to outline some of the ones that got missed. Sep 11, 2018 at 16:07

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