As the other answer explains, backtracking is not necessary. For the fun of it a little implementation of that approach. (See link to run online at the bottom):

First we need a function that determines the number of binary digits in a number:

```
def getLength(i: Int): Int = {
@annotation.tailrec
def rec(i: Int, result: Int): Int =
if(i > 0)
rec(i >> 1, result + 1)
else
result
rec(i, 0)
}
```

Then we need a function that determines the common prefix of two numbers of equal length

```
@annotation.tailrec
def getPrefix(i: Int, j: Int): Int =
if(i == j) i
else getPrefix(i >> 1, j >> 1)
```

And of a list of arbitrary numbers:

```
def getPrefix(is: List[Int]): Int = is.reduce((x,y) => {
val shift = Math.abs(getLength(x) - getLength(y))
val x2 = Math.max(x,y)
val y2 = Math.min(x,y)
getPrefix((x2 >> shift), y2)
})
```

Then we need the length of the suffix without counting leeding zeros of the suffix:

```
def getSuffixLength(i: Int, prefix: Int) = {
val suffix = i ^ (prefix << (getLength(i) - getLength(prefix)))
getLength(suffix)
}
```

Now we can compute the number of operations we need to synchronize an operation i to the prefix with "zeros" zeros appended.

```
def getOperations(i: Int, prefix: Int, zeros: Int): Int = {
val length = getLength(i) - getLength(prefix)
val suffixLength = getSuffixLength(i, prefix)
suffixLength + Math.abs(zeros - length + suffixLength)
}
```

Now we can find the minimal numbers of operations and return that together with the value we will sync to:

```
def getMinOperations(is: List[Int]) = {
val prefix = getPrefix(is)
val maxZeros = getLength(is.max) - getLength(prefix)
(0 to maxZeros).map{zeros => (is.map{getOperations(_, prefix, zeros)}.sum, prefix << zeros)}.minBy(_._1)
}
```

You can try this solution at:

http://goo.gl/lLr5jl

The last step of finding the right number of zeros can be improved, as only the length of a suffix without leading zeros matters, not what it looks like. So we can compute the number of operations we need for these together by counting how many there are:

```
def getSuffixLength(i: Int, prefix: Int) = {
val suffix = i ^ (prefix << (getLength(i) - getLength(prefix)))
getLength(suffix)
}
def getMinOperations(is: List[Int]) = {
val prefix = getPrefix(is)
val maxZeros = getLength(is.max) - getLength(prefix)
val baseCosts = is.map(getSuffixLength(_,prefix)).sum
val suffixLengths: List[(Int, Int)] = is.foldLeft(Map[Int, Int]()){
case (m,i) => {
val x = getSuffixLength(i,prefix) - getLength(i) + getLength(prefix)
m.updated(x, 1 + m.getOrElse(x, 0))
}
}.toList
val (minOp, minSol) = (0 to maxZeros).map{zeros => (suffixLengths.map{
case (x, count) => count * Math.abs(zeros + x)
}.sum, prefix << zeros)}.minBy(_._1)
(minOp + baseCosts, minSol)
}
```

All axillary operations only take logarithmic time in the size of the maximal number. We have to go through the hole list to collect the suffix lengths. And then we have to guess the number of zeros where there are at most logarithmic in the maximal number many zeros. So we should have a complexity of

```
O(|list|*ld(maxNum) + (ld(maxNum))^2)
```

So for your bounds this is basically linear in the input size.

This version can be found here:

http://goo.gl/ijzYik