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.

### Proof

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 (4). 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 10^{16}, so results will be wrong for bigger numbers. Use the Python script instead to get accurate results.

`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