# Good C++ solutions to the “Bring all the zeros to the back of the array” interview challenge

I had an interview for a Jr. development job and he asked me to write a procedure that takes an array of ints and shoves the zeroes to the back. Here are the constraints (which he didn't tell me at the beginning .... As often happens in programming interviews, I learned the constraints of the problem while I solved it lol):

• Have to do it in-place; no creating temporary arrays, new arrays, etc.
• Don't have to preserve the order of the nonzero numbers (I wish he would've told me this at the beginning)

Setup:

``````int arr[] = {0, -2, 4, 0, 19, 69};
/* Transform arr to {-2, 4, 19, 69, 0, 0} or {69, 4, -2, 19, 0, 0}
or anything that pushes all the nonzeros to the back and keeps
all the nonzeros in front */
``````

``````bool f (int a, int b) {return a == 0;}
std::sort(arr, arr+sizeof(arr)/sizeof(int), f);
``````

What are some other good answers?

• I think your answer is great. What did the interviewer say? – Bartlomiej Lewandowski Nov 18 '14 at 20:46
• "I want to put stuff over on this side, and the other stuff on this side." That is `std::partition`, hands down. See my answer. – PaulMcKenzie Nov 18 '14 at 20:49
• Your call to `std::sort` is invalid, because your comparison function does not establish a strict weak ordering. – Benjamin Lindley Nov 18 '14 at 20:53
• @barakmanos: `std::partition` can, and does guarantee O(n). – Benjamin Lindley Nov 18 '14 at 20:57
• Smartass Answer: Overwrite every entry in the array with 0. This does not violate the constraints listed. `O(n)` algorithm. – Zéychin Nov 18 '14 at 21:03

Maybe the interviewer was looking for this answer:

``````#include <algorithm>
//...
std::partition(std::begin(arr), std::end(arr), [](int n) { return n != 0; });
``````

If the order needs to be preserved, then `std::stable_partition` should be used:

``````#include <algorithm>
//...
std::stable_partition(std::begin(arr), std::end(arr), [](int n) { return n != 0; });
``````

For pre C++11:

``````#include <functional>
#include <algorithm>
//...
std::partition(arr, arr + sizeof(arr)/sizeof(int),
std::bind1st(std::not_equal_to<int>(), 0));
``````

Live Example

Basically, if the situation is that you need to move items that satisfy a condition to "one side" of a container, then the partition algorithm functions should be high up on the list of solutions to choose (if not the solution to use).

• Isn't `partition` still O(NlogN)? – Jonathan Mee Nov 18 '14 at 20:54
• @JonathanMee - en.cppreference.com/w/cpp/algorithm/partition For stable_partition, it becomes logarithmic in the worst case. en.cppreference.com/w/cpp/algorithm/stable_partition – PaulMcKenzie Nov 18 '14 at 20:59
• In the circumstance of an interview, it might be better to write the lambda as `[](const int &n){return n!=0;}` or perhaps even `[](const int &n)->bool{return n;}`, while being prepared to talk about the relative merits of `const int &` versus just `int`. In either case, one doesn't need to capture any variables. – Edward Nov 18 '14 at 21:07
• This is the clearest way. OTOH, since `std::partition()` is implemented in terms of swaps, it does a constant factor's worth of unnecessary copying around. – j_random_hacker Nov 18 '14 at 21:11
• @j_random_hacker code for clarity before optimality. It is good to know where cpu cycles might be hiding though. – Tim Seguine Nov 18 '14 at 21:17

An approach that sorts is O(N*Log2N). There is a linear solution that goes like this:

• Set up two pointers - `readPtr` and `writePtr`, initially pointing to the beginning of the array
• Make a loop that walks `readPtr` up the array to the end. If `*readPtr` is not zero, copy to `*writePtr`, and advance both pointers; otherwise, advance only `readPtr`.
• Once `readPtr` is at the end of the array, walk `writePtr` to the end of the array, while writing zeros to the remaining elements.
• There are even fewer writes needed if you do the following: Start `readPtr` at the end and walk it backwards until it hits a nonzero element or `writePtr` (which starts out at the start as before). If `readPtr` hits `writePtr`, you're finished. Otherwise it hit a nonzero element, so walk `writePtr` forwards until it hits a zero element or `readPtr`. If it hits `readPtr` then you're finished. Otherwise it hit a zero element, so set it to `*readPtr`, set `*writePtr` to zero, and repeat. Only the "out-of-position" zeroes and nonzeroes need to be copied this way. – j_random_hacker Nov 18 '14 at 21:07
• This sounds a lot like `std::remove` followed by `std::fill`. – Benjamin Lindley Nov 18 '14 at 21:21

This is O(n) so it may be what he's looking for:

``````auto arrBegin = begin(arr);
const auto arrEnd = end(arr);

for(int i = 0; arrBegin < arrEnd - i; ++arrBegin){
if(*arrBegin == 0){
i++;
*arrBegin = *(arrEnd - i);
}
}
std::fill(arrBegin, arrEnd, 0);
``````