Given any number n, and three operations on n:

  1. add 1
  2. subtract 1
  3. divide by 2 if the number is even

I want to find the minimum number of the above operations to reduce n to 1. I have tried dynamic progamming approach, also BFS with pruning, but n can be very large (10^300) and I do not know how to make my algorithm faster. The greedy approach (divide by 2 if even and subtract 1 if odd) also does not give the optimal result. Is another solution exists?

  • 4
    The greedy approach ... does not give the optimal result ... can you give a number for which this is not optimal? – Tim Biegeleisen Sep 20 '16 at 7:54
  • 7
    15, greedy will give 6 (14 -> 7 -> 6 -> 3 -> 2 -> 1) but optimal is 5 (16 -> 8 -> 4 -> 2 -> 1) – natydn52 Sep 20 '16 at 7:56
  • 2
    Sounds like you want to approach a power of 2 if possible. – Ignacio Vazquez-Abrams Sep 20 '16 at 8:00
  • Do a variant of the greedy approach, but at each step check whether it's quicker to get to the nearest power of 2 and divide until 1. – user5226582 Sep 20 '16 at 8:02
  • Problem statement needs to be more clear. You want min number of above operations, but can i use other operations (e.g. multiply, add two numbers) to calculate the min number of steps? – Joel Lee Sep 20 '16 at 8:06

There is a pattern which allows you to know the optimal next step in constant time. In fact, there can be cases where there are two equally optimal choices -- in that case one of them can be derived in constant time.

If you look at the binary representation of n, and its least significant bits, you can make some conclusions about which operation is leading to the solution. In short:

  • if the least significant bit is zero, then divide by 2
  • if n is 3, or the 2 least significant bits are 01, then subtract
  • In all other cases: add.


If the least significant bit is zero, the next operation should be the division by 2. We could instead try 2 additions and then a division, but then that same result can be achieved in two steps: divide and add. Similarly with 2 subtractions. And of course, we can ignore the useless subsequent add & subtract steps (or vice versa). So if the final bit is 0, division is the way to go.

Then the remaining 3-bit patterns are like **1. There are four of them. Let's write a011 to denote a number that ends with bits 011 and has a set of prefixed bits that would represent the value a:

  • a001: adding one would give a010, after which a division should occur: a01: 2 steps taken. We would not want to subtract one now, because that would lead to a00, which we could have arrived at in two steps from the start (subtract 1 and divide). So again we add and divide to get a1, and for the same reason we repeat that again, giving: a+1. This took 6 steps, but leads to a number that could be arrived at in 5 steps (subtract 1, divide 3 times, add 1), so clearly, we should not perform the addition. Subtraction is always better.

  • a111: addition is equal or better than subtraction. In 4 steps we get a+1. Subtraction and division would give a11. Adding now would be inefficient compared to the initial addition path, so we repeat this subtract/divide twice and get a in 6 steps. If a ends in 0, then we could have done this in 5 steps (add, divide three times, subtract), if a ends in a 1, then even in 4. So Addition is always better.

  • a101: subtraction and double division leads to a1 in 3 steps. Addition and division leads to a11. To now subtract and divide would be inefficient, compared to the subtraction path, so we add and divide twice to get a+1 in 5 steps. But with the subtraction path, we could reach this in 4 steps. So subtraction is always better.

  • a011: addition and double division leads to a1. To get a would take 2 more steps (5), to get a+1: one more (6). Subtraction, division, subtraction, double division leads to a (5), to get a+1 would take one more step (6). So addition is at least as good as subtraction. There is however one case not to overlook: if a is 0, then the subtraction path reaches the solution half-way, in 2 steps, while the addition path takes 3 steps. So addition is always leading to the solution, except when n is 3: then subtraction should be chosen.

So for odd numbers the second-last bit determines the next step (except for 3).

Python Code

This leads to the following algorithm (Python), which needs one iteration for each step and should thus have O(logn) complexity:

def stepCount(n):
    count = 0
    while n > 1:
        if n % 2 == 0:             # bitmask: *0
            n = n // 2
        elif n == 3 or n % 4 == 1: # bitmask: 01
            n = n - 1
        else:                      # bitmask: 11
            n = n + 1
        count += 1
    return count

See it run on repl.it.

JavaScript Snippet

Here is a version where you can input a value for n and let the snippet produce the number of steps:

function stepCount(n) {
    var count = 0
    while (n > 1) {
        if (n % 2 == 0)                // bitmask: *0
            n = n / 2
        else if (n == 3 || n % 4 == 1) // bitmask: 01
            n = n - 1
        else                           // bitmask: 11
            n = n + 1
        count += 1
    return count

// I/O
var input = document.getElementById('input')
var output = document.getElementById('output')
var calc = document.getElementById('calc')

calc.onclick = function () {
  var n = +input.value
  if (n > 9007199254740991) { // 2^53-1
    alert('Number too large for JavaScript')
  } else {
    var res = stepCount(n)
    output.textContent = res
<input id="input" value="123549811245">
<button id="calc">Caluclate steps</button><br>
Result: <span id="output"></span>

Please be aware that the accuracy of JavaScript is limited to around 1016, so results will be wrong for bigger numbers. Use the Python script instead to get accurate results.

  • 1
    This seems to need a really huge cache. the number can be as big as 10^300 – Ayon Nahiyan Sep 20 '16 at 8:51
  • 1
    I rewrote my answer completely. I believe it is now the fastest solution posted. It needs no cache, no recursion. – trincot Sep 20 '16 at 14:11
  • 1
    Nice algorithm, avoids unnecessary "tail recursion". Minor edit suggestion: Remove "Obviously," from your proof. Makes intuitive sense, but not obvious and, in fact, requires proof (which you did). – Joel Lee Sep 21 '16 at 20:01
  • First, @trincot this is an excellent answer, so thank you! I was wondering if you could talk about what led you limit your scope to only three bits? – Will Nov 2 '17 at 21:06
  • 1
    I made a breadth first search to confirm this answer and it works out for the first 1400 integers. Makes sense upon inspection. With the 2^x line in kind should we choose 1(first bit), 2(first two bits), 4 (three bits) or 8(four) or higher powers of 2 as a filter? Choosing 1 or two wouldn’t filter anything. 4 (3 sig bits) is the first that filters anything and any higher power is only redundant. Great answer. – peer Nov 22 '18 at 0:03

In summary:

  • If n is even, divide by 2
  • If n is 3 or its least significant bits are 01, subtract.
  • If n's least significant bits are 11, add.

Repeat these operations on n until you reach 1, counting the number of operations performed. This is guaranteed to give the correct answer.

As an alternative to the proof from @trincot, here is one that has less cases and is hopefully more clear:


Case 1: n is even

Let y be the value of the number after performing some operations on it. To start, y = n.

  1. Assume that dividing n by 2 is not the optimal approach.
  2. Then either add or subtract an even number of times
    1. Mixing addition and subtraction will result in unnecessary operations, so only either one is done.
    2. An even number must be added/subtracted, since stopping on an odd number would force continued adding or subtracting.
  3. Let 2k, where k is some integer, be the number of additions or subtractions performed
    1. Limit k when subtracting so that n - 2k >= 2.
  4. After adding/subtracting, y = n + 2k, or y = n - 2k.
  5. Now divide. After dividing, y = n/2 + k, or y = n/2 - k
  6. 2k + 1 operations have been performed. But the same result could have have been achieved in 1 + k operations, by dividing first then adding or subtracting k times.
  7. Thus the assumption that dividing is not the optimal approach was wrong, and dividing is the optimal approach.

Case 2: n is odd

The goal here is to show that when faced with an odd n, either adding or subtracting will result in less operations to reach a given state. We can use that fact that dividing is optimal when faced with an even number.

We will represent n with a partial bitstring showing the least significant bits: X1, or X01, etc, where X represents the remaining bits, and is nonzero. When X is 0, the correct answers are clear: for 1, you're done; for 2 (0b10), divide; for 3 (0b11), subtract and divide.

Attempt 1: Check whether adding or subtracting is better with one bit of information:

  1. Start: X1
    1. add: (X+1)0, divide: X+1 (2 operations)
    2. subtract: X0, divide: X (2 operations)

We reach an impass: if X or X+1 were even, the optimal move would be to divide. But we don't know if X or X+1 are even, so we can't continue.

Attempt 2: Check whether adding or subtracting is better with two bits of information:

  1. Start: X01
    1. add: X10, divide: X1
      1. add: (X+1)0, divide: X+1 (4 operations)
      2. subtract: X0, divide: X (4 operations)
    2. subtract: X00, divide: X0, divide: X (3 operations)
      1. add: X+1 (possibly not optimal) (4 operations)

Conclusion: for X01, subtracting will result in at least as few operations as adding: 3 and 4 operations versus 4 and 4 operations to reach X and X+1.

  1. Start: X11
    1. add: (X+1)00, divide: (X+1)0, divide: X+1 (3 operations)
      1. subtract: X (possibly not optimal) (4 operations)
    2. subtract: X10, divide: X1
      1. add: (X+1)0, divide: X+1 (4 operations)
      2. subtract: X0, divide: X (4 operations)

Conclusion: for X11, adding will result in at least as few operations as subtracting: 3 and 4 operations versus 4 and 4 operations to reach X+1 and X.

Thus, if n's least significant bits are 01, subtract. If n's least significant bits are 11, add.


To solve the above problem you can either use recursion or loops A recursive answer is already provided so i would try to give a while loop approach.

Logic: We should remember that the number multiple of 2 would always have less set bits than those which are not divisible by 2.

To solve your problem i'm using java code. I have tried it with few numbers and it works fine, if it doesn't add a comment or edit the answer

        if(n%2 == 0)

            if(Integer.bitCount(n-1) > Integer.bitCount(n+1))
                n += 1;
                n -=1;


The code is written in a very simple form so that it could be understood by everyone. Here n is the number entered and steps are the steps required to reach 1

  • 1
    This function gives the wrong result for 59. It returns 9 steps, while the correct answer is 8. The first step it does for 59 is -1, while it should choose +1. The counting of set bits is thus not a sound basis to find the shortest path. Also: the statement in the "logic" paragraph is not correct: 5 (odd) has 2 set bits, while 14 (even) has 3. The statement needs to be further qualified to make it correct. – trincot Sep 22 '16 at 8:17

I like the idea by squeamish ossifrage of greedily looking (for the case of odd numbers) whether n + 1 or n - 1 looks more promising, but think deciding what looks more promising can be done a bit better than looking at the total number of set bits.

For a number x,

bin(x)[:: -1].index('1')

indicates the number of least-significant 0s until the first 1. The idea, then, is to see whether this number is higher for n + 1 or n - 1, and choose the higher of the two (many consecutive least-significant 0s indicate more consecutive halving).

This leads to

def min_steps_back(n):
    count_to_1 = lambda x: bin(x)[:: -1].index('1')

    if n in [0, 1]:
        return 1 - n

    if n % 2 == 0:
        return 1 + min_steps_back(n / 2)

    return 1 + (min_steps_back(n + 1) if count_to_1(n + 1) > count_to_1(n - 1) else min_steps_back(n - 1))

To compare the two, I ran

num = 10000
ms, msb = 0., 0.
for i in range(1000):
    n =  random.randint(1, 99999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999)

    ms += min_steps(n)
    msb += min_steps_back(n)

print ms / num, msb / num

Which outputs

57.4797 56.5844

showing that, on average, this does use fewer operations (albeit not by that much).

  • Should be if n in [0, 1]: return 1-n, but otherwise this looks good :-) +1 – r3mainer Sep 20 '16 at 12:38
  • @squeamishossifrage Thanks! Once again, really liked your answer (can't upvote it more than once). – Ami Tavory Sep 20 '16 at 12:42
  • The division should be an integer division (// instead of /). Also: this function gives the wrong result for 3, 6, 11, 12, 13, and many others: in all these cases it returns 1 step more than the optimal solution. – trincot Sep 22 '16 at 7:51
  • @trincot Thanks, I'll check it. In any case, my answer is just a heuristic, not an optimal solution. – Ami Tavory Sep 22 '16 at 7:54

I am really bad at binaries so not counting the lsb or msb. What about below program -

public class ReduceNto1 {
    public static void main(String[] args) {
        int count1 = count(59);//input number
        System.out.println("total min steps - " + count1);
    static int count(int n){
        System.out.println(n + " > ");
            return 0;
        else if(n %2 ==0){

            return 1 + count(n/2);
            return 1 + Math.min(count(n-1), count(n+1));

  • it return 8 for 59. It returns 5 for 15 – Arvind Kumar Oct 3 '19 at 12:52
  • I think you would not be able to solve it for large numbers – dmyma Dec 23 '19 at 4:23

The solution offered by Ami Tavoy works if the 3 is considered (adding to 4 would produce 0b100 and count_to_1 equals 2 which is greater than subtracting to 2 for 0b10 and count_to_1 equals 1). You can add two steps when we get down no n = 3 to finish off the solution:

def min_steps_back(n):
count_to_1 = lambda x: bin(x)[:: -1].index('1')

if n in [0, 1]:
    return 1 - n

if n == 3:
    return 2

if n % 2 == 0:
    return 1 + min_steps_back(n / 2)

return 1 + (min_steps_back(n + 1) if count_to_1(n + 1) > count_to_1(n - 1) else min_steps_back(n - 1))

Sorry, I know would make a better comment, but I just started.


As @trincot pointed out, we should always try to divide by two the number so, but one easy way to see why if the number is odd we should decrease by 1 if it's 3 or ends it "01", and add 1 in the other case is this. If n is odd, n % 4 will be 1 or 3, then n+1 or n-1 are going to be multiples of 4, which means that we are going to be able to divide twice the number by two.


Based on @trincot answer, an alternative way to verify the 2 LSB's is simply using bin(n)[-2:] and voila for those who don't want to deal with binaries!

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