53

 function singleDigit(num) {
      let counter = 0
      let number = [...num + ''].map(Number).reduce((x, y) => {return x * y})

      if(number <= 9){
          console.log(number)
      }else{
          console.log(number)
          return singleDigit(number), counter += 1
      }
   }
singleDigit(39)

The code above takes an integer and reduces it to a single digit by multiplying it by its own digits.

Example is 39.

3 x 9 = 27.
2 x 7 = 14.
1 x 4 = 4.

The console will log:

27 
14 
4

How do I keep track that the recursive function was called 3 times?

I have tried adding a counter but it fails to update. Would appreciate any help

  • 4
    .map(Number) is redundant since the * operator coerces the values to number anyway. ;-) – RobG Jan 2 at 22:48
  • 4
    A couple of questions: 1) How do you intend on dealing with negative numbers? For instance, the number -57 is really a -50 and a -7 .. when looked at this way, it would do a reduction of -5 x -7 yielding a positive number 35. Or do you want it to see only the negative sign with the 5 and not the 7, even tho the 7 is actually negative as well. 2) How do you intend on dealing with numbers which include a zero? as this will automatically zero out the reduction. Therefore, the larger number you pass in, the more likely it will zero out. The other option would be to skip the zeros – Pimp Trizkit Jan 3 at 13:06
  • 3
    I realize my above questions are not about counting the recursion, but rather just the puzzle solving aspect of content used in this question. Please, forgive me. – Pimp Trizkit Jan 3 at 13:08
  • 3
    I'm flattered that you like my answer, but for practical purposes, I think stackoverflow.com/a/59570894/1346276 is the cleanest general variant. – phipsgabler Jan 6 at 16:39
  • 2
    @phipsgabler anyone who takes the time to write an intelligent and coherent answer deserves a like. Thank you – chs242 Jan 6 at 18:53
18

This is an almost purely academic variant, but you can use a modified fixed point combinator for this purpose.

Lets shorten and improve your original function a bit:

function singleDigit(n) {
    let digitProduct = [...(n + '')].reduce((x, y) => x * y, 1);
    return digitProduct <= 9 ? digitProduct : singleDigit(digitProduct);
}

// singleDigit(123234234) == 0

From this variant, we can factor out and curry the recursive call:

function singleDigitF(recur) {
    return function (n) {
        let digitProduct = [...(n + '')].reduce((x, y) => x * y, 1);
        return digitProduct <= 9 ? digitProduct : recur()(digitProduct);
    };
}

This function can now be used with a fixed point combinator; specifically I implemented a Y combinator adapted for (strict) JavaScript as follows:

function Ynormal(f, ...args) {
    let Y = (g) => g(() => Y(g));
    return Y(f)(...args);
}

where we have Ynormal(singleDigitF, 123234234) == 0.

Now comes the trick. Since we have factored out the recursion to the Y combinator, we can count the number of recursions within it:

function Ycount(f, ...args) {
    let count = 1;
    let Y = (g) => g(() => {count += 1; return Y(g);});
    return [Y(f)(...args), count];
}

A quick check in the Node REPL gives:

> Ycount(singleDigitF, 123234234)
[ 0, 3 ]
> let digitProduct = (n) => [...(n + '')].reduce((x, y) => x * y, 1)
undefined
> digitProduct(123234234)
3456
> digitProduct(3456)
360
> digitProduct(360)
0
> Ycount(singleDigitF, 39)
[ 4, 3 ]

This combinator will now work for counting the number of calls in any recursive function written in the style of singleDigitF.

(Note that there's two sources of getting zero as a very frequent answer: numeric overflow (123345456999999999 becoming 123345457000000000 etc.), and the fact that you will almost surely get zero as an intermediate value somewhere, when the size of the input is growing.)

  • 5
    To the downvoters: I really agree with you that this is not the best practical solution -- that is why I prefixed it as "purely academic". – phipsgabler Jan 8 at 9:17
  • Honestly, it's an awesome solution and totally suited for the regression / math type of the original question. – Sheraff Jan 9 at 23:09
69

You should add a counter argument to your function definition:

function singleDigit(num, counter = 0) {
    console.log(`called ${counter} times`)
    //...
    return singleDigit(number, counter+1)
}
singleDigit(39)
  • 6
    awesome. It looks like my counter wasn't working because I declared it in the function – chs242 Jan 2 at 22:39
  • 7
    @chs242 scope rules would dictate that declaring it in the function would create a new one each invocation. stackoverflow.com/questions/500431/… – Taplar Jan 2 at 22:40
  • 10
    @chs242 it's not that you declared it within the function. Technically that's all default parameters are doing as well - in your case it's simply that the value never carried over to the next time the function was recursively called. a.e. every time the function runs counter would get scrapped and set to 0, unless you explicitly carry it over in your recursive call as Sheraff does. A.e. singleDigit(number, ++counter) – zfrisch Jan 2 at 22:50
  • 2
    right @zfrisch I understand that now. Thanks for taking the time to explain it – chs242 Jan 2 at 23:07
  • 35
    Please change ++counter to counter+1. They're functionally equivalent, but the latter specifies intent better, doesn't (unnecessarily) mutate and parameter, and doesn't have the possibility of accidentally post-incrementing. Or better yet, since it's a tail-call, use a loop instead. – BlueRaja - Danny Pflughoeft Jan 3 at 9:36
35

The traditional solution is to pass the count as a parameter to the function as suggested by another answer.

However, there is another solution in js. A few other answers suggested simply declaring count outside the recursive function:

let counter = 0
function singleDigit(num) {
  counter++;
  // ..
}

This of course works. However this makes the function non-reentrant (cannot be called twice correctly). In some cases you can ignore this problem and simply make sure you don't call singleDigit twice (javascript is single threaded so it's not too hard to do) but this is a bug waiting to happen if you update singleDigit later to be asynchronous and it also feels ugly.

The solution is to declare the counter variable outside but not globally. This is possible because javascript has closures:

function singleDigit(num) {
  let counter = 0; // outside but in a closure

  // use an inner function as the real recursive function:
  function recursion (num) {
    counter ++
    let number = [...num + ''].map(Number).reduce((x, y) => {return x * y})

    if(number <= 9){
      return counter            // return final count (terminate)
    }else{
      return recursion(number)  // recurse!
    }
  }

  return recursion(num); // start recursion
}

This is similar to the global solution but each time you call singleDigit (which is now not a recursive function) it will create a new instance of the counter variable.

  • 1
    The counter variable is only available within the singleDigit function and provides a alternative clean way of doing this without passing an argument imo. +1 – AndrewL64 Jan 2 at 22:59
  • 1
    Since recursion is now completely isolated it should be totally safe to pass the counter as the last parameter. I don't think creating an inner function is necessary. If you don't like the idea of having parameters for the sole benefit of the recursion (I do take the point that the user could mess with those) then lock them up with Function#bind in a partially applied function. – customcommander Jan 3 at 0:41
  • @customcommander Yes, I mentioned this in summary in the first part of my answer -- the traditional solution is to pass the count as a parameter. This is an alternate solution in a language that has closures. In some ways it is simpler to follow because it is only one variable instead of a possibly infinite number of variable instances. In other ways knowing this solution helps when the thing you're tracking is a shared object (imagine constructing a unique map) or a very large object (such as an HTML string) – slebetman Jan 3 at 10:11
  • counter-- would be the traditional way of solving your claim of "cannot be called twice correctly" – MonkeyZeus Jan 3 at 15:54
  • 1
    @MonkeyZeus What difference does that make? Also, how would you know what number to initialize the counter to seeing that it is the count that we want to find? – slebetman Jan 3 at 23:37
18

Another approach, since you produce all the numbers, is to use a generator.

The last element is your number n reduced to a single digit number and to count how many times you have iterated, just read the length of the array.

const digits = [...to_single_digit(39)];
console.log(digits);
//=> [27, 14, 4]
<script>
function* to_single_digit(n) {
  do {
    n = [...String(n)].reduce((x, y) => x * y);
    yield n;
  } while (n > 9);
}
</script>


Final thoughts

You may want to consider having a return-early condition in your function. Any numbers with a zero in it will return zero.

singleDigit(1024);       //=> 0
singleDigit(9876543210); //=> 0

// possible solution: String(n).includes('0')

The same can be said for any numbers made of 1 only.

singleDigit(11);    //=> 1
singleDigit(111);   //=> 1
singleDigit(11111); //=> 1

// possible solution: [...String(n)].every(n => n === '1')

Finally, you didn't clarify whether you accept only positive integers. If you accept negative integers then casting them to strings can be risky:

[...String(39)].reduce((x, y) => x * y)
//=> 27

[...String(-39)].reduce((x, y) => x * y)
//=> NaN

Possible solution:

const mult = n =>
  [...String(Math.abs(n))].reduce((x, y) => x * y, n < 0 ? -1 : 1)

mult(39)
//=> 27

mult(-39)
//=> -27
  • great. @customcommander thank you for explaining this very clearly – chs242 Jan 3 at 11:02
5

Why not make a call to console.count in your function ?

Edit: Snippet to try in your browser :

function singleDigit(num) {
    console.count("singleDigit");

    let counter = 0
    let number = [...num + ''].map(Number).reduce((x, y) => {return x * y})

    if(number <= 9){
        console.log(number)
    }else{
        console.log(number)
        return singleDigit(number), counter += 1
    }
}
singleDigit(39)

I have it working in Chrome 79 and Firefox 72

  • console.count wouldn't help as the counter gets reset every time the function is called (as has been explaine in the answers above) – chs242 Jan 6 at 15:58
  • 2
    I don't understand your issue as I have it working in Chrome and Firefox, I added a snippet in my answer – Mistermatt Jan 8 at 10:27
4

There have been many interesting answers here. I think my version offers an additional interesting alternative.

You do several things with your required function. You recursively reduce it to a single digit. You log the intermediate values, and you would like a count of the recursive calls made. One way to handle all this is to write a pure function which will return a data structure that contains the final result, the steps taken and the call count all in one:

  {
    digit: 4,
    steps: [39, 27, 14, 4],
    calls: 3
  }

You can then log the steps if you desire, or store them for further processing.

Here is a version which does that:

const singleDigit = (n, steps = []) =>
  n <= 9
    ? {digit: n, steps: [... steps, n], calls: steps .length}
    : singleDigit ([... (n + '')] .reduce ((a, b) => a * b), [... steps, n])

console .log (singleDigit (39))

Note that we track the steps but derive the calls. While we could track the call count with an additional parameter, that seems to gain nothing. We also skip the map(Number) step -- these will be coerced to numbers in any case by the multiplication.

If you have concerns about that defaulted steps parameter being exposed as part of your API, it's easy enough to hide it by using an internal function like this:

const singleDigit = (n) => {
  const recur = (n, steps) => 
    n <= 9
      ? {digit: n, steps: [... steps, n], calls: steps .length}
      : recur ([... (n + '')] .reduce ((a, b) => a * b), [... steps, n])
  return recur (n, [])
}

And in either case, it might be a bit cleaner to extract the digit multiplication into a helper function:

const digitProduct = (n) => [... (n + '')] .reduce ((a, b) => a * b)

const singleDigit = (n, steps = []) =>
  n <= 9
    ? {digit: n, steps: [... steps, n], calls: steps .length}
    : singleDigit (digitProduct(n), [... steps, n])
  • 2
    Another great answer ;) Please note that when n is negative, digitProduct will return NaN (-39 ~> ('-' * '3') * '9'). So you may want to use an absolute value of n and use -1 or 1 as the initial value of your reduce. – customcommander Jan 3 at 15:23
  • @customcommander: actually, it will return {"digit":-39,"steps":[-39],"calls":0}, since -39 < 9. While I agree that this might do with some error-checking: is the parameter a number? - is it a positive integer? - etc. I don't think I'll update to include that. This captures the algorithm, and error-handling is often specific to one's code-base. – Scott Sauyet Jan 3 at 18:26
4

If you are just trying to count how many times it gets reduced and are not caring about the recursion specifically... you can just remove the recursion. The below code remains faithful to the Original Post as it does not count num <= 9 as needing reduction. Therefore, singleDigit(8) will have count = 0, and singleDigit(39) will have count = 3, just like the OP and accepted answer are demonstrating:

const singleDigit = (num) => {
    let count = 0, ret, x;
    while (num > 9) {
        ret = 1;
        while (num > 9) {
            x = num % 10;
            num = (num - x) / 10;
            ret *= x;
        }
        num *= ret;
        count++;
        console.log(num);
    }
    console.log("Answer = " + num + ", count = " + count);
    return num;
}

It is unnecessary to process numbers 9 or less (ie. num <= 9). Unfortunately the OP code will process num <= 9 even tho it does not count it. The code above will not process nor count num <= 9, at all. It just passes it thru.

I choose not to use .reduce because doing the actual math was much faster to execute. And, for me, easier to understand.


Further thinking on speed

I feel good code is also fast. If you are using this type of reduction (which is used in numerology a lot) you might be needing to use it on a massive amount of data. In this case, speed will become the upmost of importance.

Using both .map(Number) and console.log (at each reduction step) are both very very long to execute and unnecessary. Simply deleting .map(Number) from the OP sped it up by about 4.38x. Deleting console.log sped it up so much it was almost impossible to properly test (I didn't want to wait for it).

So, similar to customcommander's answer, not using .map(Number) nor console.log and pushing the results into an array and using .length for count is much much faster. Unfortunately for customcommander's answer, using a generator function is really really slow (that answer is about 2.68x slower than the OP without .map(Number) and console.log)

Also, instead of using .reduce I just used the actual math. This single change alone sped up my version of the function by a factor of 3.59x.

Finally, recursion is slower, it takes up stack space, uses more memory, and has a limit to how many times it can "recur". Or, in this case, how many steps of reduction it can use to finish the full reduction. Rolling out your recursion to iterative loops keeps it all on the same place on the stack and has no theoretical limit on how many reduction steps it can use to finish. Thus, these functions here can "reduce" almost any sized integer, only limited by execution time and how long an array can be.

All this in mind...

const singleDigit2 = (num) => {
    let red, x, arr = [];
    do {
        red = 1;
        while (num > 9) {
            x = num % 10;
            num = (num - x) / 10;
            red *= x;
        }
        num *= red;
        arr.push(num);
    } while (num > 9);
    return arr;
}

let ans = singleDigit2(39);
console.log("singleDigit2(39) = [" + ans + "],  count = " + ans.length );
 // Output: singleDigit2(39) = [27,14,4],  count = 3

The above function runs extremely fast. It is about 3.13x faster than the OP (without .map(Number) and console.log) and about 8.4x faster than customcommander's answer. Keep in mind that deleting console.log from the OP prevents it from producing a number at each step of reduction. Hence, the need here to push these results into an array.

PT

  • 1
    There's a lot of education value in this answer so thanks for that. I feel good code is also fast. I'd say that code quality has to be measured against a predefined set of requirements. If performance isn't one of them then you gain nothing by replacing code that anybody can understand with "fast" code. You wouldn't believe the amount of code I've seen that has been refactored to be performant to the point nobody can understand it anymore (for some reason optimal code tends to also be undocumented ;). Finally be aware that lazy-generated lists allow one to consume items on demand. – customcommander Jan 3 at 15:35
  • Thank you, I think. IMHO, reading the actual math of how to do it was easier to understand for me.. than the [...num+''].map(Number).reduce((x,y)=> {return x*y}) or even [...String(num)].reduce((x,y)=>x*y) statements that I am seeing in most answers here. So, to me, this had the added benefit of better understanding of whats going on at each iteration and much faster. Yes, minified code (which has its place) is terribly hard to read. But in those cases one is generally consciously not caring about its readability but rather just the final result to cut and paste and move on. – Pimp Trizkit Jan 3 at 19:05
  • Doesn't JavaScript have integer division so you can do the equivalent of C digit = num%10; num /= 10;? Having to do num - x first to remove the trailing digit before dividing is likely to force the JIT compiler to do a separate division from the one it did to get the remainder. – Peter Cordes Jan 4 at 9:43
  • I don't think so.These are vars (JS has no ints). Therefore, n /= 10; will convert n to a float if needed. num = num/10 - x/10 might convert it to a float, which is the long form of the equation. Hence, I have to use the refactored version num = (num-x)/10; to keep it an integer.There is no way that I can find in JavaScript that can give you both the quotient and remainder of a single division operation. Also,digit = num%10; num /= 10; is two separate statements and thus two separate division operations.It's been a while since I've used C, but I thought it was true there as well. – Pimp Trizkit Jan 4 at 21:18
4

You can use closure for this.

Just simply store counter into the closure of function.

Here is example:

function singleDigitDecorator() {
	let counter = 0;

	return function singleDigitWork(num, isCalledRecursively) {

		// Reset if called with new params 
		if (!isCalledRecursively) {
			counter = 0;
		}

		counter++; // *

		console.log(`called ${counter} times`);

		let number = [...(num + "")].map(Number).reduce((x, y) => {
			return x * y;
		});

		if (number <= 9) {
			console.log(number);
		} else {
			console.log(number);

			return singleDigitWork(number, true);
		}
	};
}

const singleDigit = singleDigitDecorator();

singleDigit(39);

console.log('`===========`');

singleDigit(44);

  • 1
    But this way the counter keeps counting on the next call, it needs to be reset on each initial call. It leads to a difficult question: how to tell when a recursive function is called from a different context, in this case global vs function. – RobG Jan 2 at 22:49
  • This is just example in order to come up with a thought. It might be modified by asking user for his needs. – Kholiavko Jan 2 at 22:53
  • @RobG I don't understand your question. The recursive function cannot be called outside of the closure because it is an inner function. So there is no possibility or need to differentiate context because there is only one possible context – slebetman Jan 2 at 22:56
  • @slebetman The counter is never reset. The function returned by singleDigitDecorator() will keep incrementing the same counter every time it is called. – customcommander Jan 2 at 23:00
  • 1
    @slebetman—the problem is that the function returned by singleDigitDecorator does not reset its counter when it's called again. That is the function that needs to know when to reset the counter, otherwise a new instance of the function is required for each use. A possible use case for Function.caller? ;-) – RobG Jan 2 at 23:04
0

Here's a Python version that uses a wrapper function to simplify the counter, as has been suggested by slebetman's answer — I write this only because the core idea is very clear in this implementation:

from functools import reduce

def single_digit(n: int) -> tuple:
    """Take an integer >= 0 and return a tuple of the single-digit product reduction
    and the number of reductions performed."""

    def _single_digit(n, i):
        if n <= 9:
            return n, i
        else:
            digits = (int(d) for d in str(n))
            product = reduce(lambda x, y: x * y, digits)
            return _single_digit(product, i + 1)

    return _single_digit(n, 0)

>>> single_digit(39)
(4, 3)
  • In Python, I'd prefer something like this. – phipsgabler Jan 6 at 16:35

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