# Algorithm for finding kth binary number with certain properties

Let's assume we will consider binary numbers which has length `2n` and `n` might be about `1000`. We are looking for `kth` number (k is limited by `10^9`) which has following properties:

• Amount of `1's` is equal to amount of `0's` what can be described as following: `#(1) = #(0)`
• Every prefix of this number has to contain atleast as much `0's` as `1's`. It might be easier to understand it after negating the sentence, which is: There is no prefix which would contain more `1's` than `0's`.

And basically that's it. So to make it clear let's do some example: `n=2`, `k=2` we have to take binary number of length `2n`:

``````0000
0001
0010
0011
0100
0101
0110
0111
1000
and so on...
``````

And now we have to find `2nd` number which fulfill those two requirements. So we see `0011` is the first one, and `0101` is second one. If we change `k=3`, then answer doesn't exist since there are number which have same amount of opposite bits, but for `0110`, there is prefix `011` so number doesn't fulfill second constraint and same would be with all numbers which has `1` as most significant bit.

So what I did so far to find algorithm?

Well my first idea was to generate all possible bits settings, and check whether it has those two properties, but generate them all would take `O(2^(2n))` which is not an option for `n=1000`.

Additionally I realize there is no need to check all numbers which are smaller than `0011` for `n=2`, `000111` for `n=3`, and so on... frankly speaking those which half of most significant bits remains "untouched" because those numbers have no possibility to fulfill `#(1) = #(0)` condition. Using that I can reduce `n` by half, but it doesn't help much. Instead of 2 * forever I have forever running algorithm. It's still `O(2^n)` complexity, which is way too big.

Any idea for algorithm?

Conclusion

This text has been created as a result of my thoughts after reading Andy Jones post.

First of all I wouldn't post code I have used since it's point 6 in following document from Andy's post Kasa 2009. All you have to do is consider `nr` as that what I described as `k`. Unranking Dyck words algorithm, would help us find out answer much faster. However it has one bottleneck.

``````while (k >= C(n-i,j))
``````

Considering that `n <= 1000`, Catalan number can be quite huge, even `C(999,999)`. We can use some big number arithmetic, but on the other hand I came up with little trick to overpass it and use standard integer.

We don't want to know how big actually Catalan number is as long as it's bigger than `k`. So now we will create Catalan numbers caching partial sums in `n x n` table.

``````...                                     ...
5 |                              42     ...
4 |                        14    42     ...
3 |                   5    14    28     ...
2 |             2     5     9    14     ...
1 |       1     2     3     4     5     ...
0 | 1     1     1     1     1     1     ...
----------------------------------   ...
0     1     2     3     4     5     ...
``````

To generate it is quite trivial:

``````C(x,0) = 1
C(x,y) = C(x,y-1) + C(x-1,y)  where y > 0 && y < x
C(x,y) = C(x,y-1) where x == y
``````

So what we can see only this:

``````C(x,y) = C(x,y-1) + C(x-1,y)  where y > 0 && y < x
``````

can cause overflow.

Let's stop at this point and provide definition.

`k-flow` - it's not real overflow of integer but rather information that value of `C(x,y)` is bigger than `k`.

My idea is to check after each running of above formula whether `C(x,y)` is grater than `k` or any of sum components is `-1`. If it is we put `-1` instead, which would act as a marker, that `k-flow` has happened. I guess it quite obvious that if `k-flow` number is sum up with any positive number it's still be `k-flowed` in particular sum of 2 `k-flowed` numbers is `k-flowed`.

The last what we have to prove is that there is no possibility to create real overflow. Real overflow might only happen if we sum up `a + b` which non of them is `k-flowed` but as sum they generated the real overflow.

Of course it's impossible since maximum value can be described as `a + b <= 2 * k <= 2*10^9 <= 2,147,483,647` where last value in this inequality is value of int with sign. I assume also that int has 32 bits, as in my case.

• I haven't got a full solution, but thinking about it a bit I feel like you can build strings like this up by deciding n places to put the 1's, starting from the right side, and a rule that you can only place 0's if you have that many 1's already there. For example, if you have ???101, you've placed two 1's and one 0. Therefore you can only place up to one more 0 before placing another 1. Might be a start... Dec 16, 2013 at 0:29
• What is the limit for `k`? Dec 16, 2013 at 0:43
• `k` is limited by `10^9`. I have updated question.
– abc
Dec 16, 2013 at 0:45
• Ok, so basically, you have the first number that matches k=3 is `000111` so the second number would be `000111 + 111` which is `01110` and for k=4 you will have `00001111` then add `1111` to it so you got the second matching number which is `00011110` and so on and so forth. correct me if I'm wrong. Dec 16, 2013 at 2:12
• This is partly a combinatorics problem and as such you might get some good insight by asking on math.stackexchange.com. Just replace your `0`s and `1`s with `A`s and `B`s and don't mention the word "binary" ;-) Dec 16, 2013 at 3:08

The numbers you are describing correspond to Dyck words. Pt 2 of Kasa 2009 gives a simple algorithm for enumerating them in lexicographic order. Its references should be helpful if you want to do any further reading.

As an aside (and be warned I'm half asleep as I write this, so it might be wrong), the wikipedia article notes that the number of Dyck words of length `2n` is the `n` th Catalan number, `C(n)`. You might want to find the smallest `n` such that `C(n)` is larger than the `k` you're looking for, and then enumerate Dyck words starting from `X^n Y^n`.

• I will search information about it and try to figure out myself and if I won't succeed I will back for sure so +1 ATM.
– abc
Dec 16, 2013 at 13:20
• Problem solved. Generation one by one was too slow, but based on that document and knowledge after reading about Catalan numbers I worked out faster algorithm.
– abc
Dec 18, 2013 at 21:49
• Mind sharing the algorithm or code you settled for, in case anyone else needs to solve the same problem? Dec 18, 2013 at 21:59
• I have edited question and share an idea as you suggest.
– abc
Dec 19, 2013 at 0:24

I'm sorry for misunderstood this problem last time, so I edit it and now I can promise the correction and you can test the code first, the complexity is `O(n^2)`, the detail answer is follow

First, we can equal the problem to the next one

We are looking for `kth largest` number (k is limited by `10^9`) which has following properties:

• Amount of `1's` is equal to amount of `0's` what can be described as following: `#(1) = #(0)`
• Every prefix of this number has to contain at least as much [[`1's` as `0's`]], which means: There is no prefix which would contain more [[`0's` than `1's`]].

Let's give an example to explain it: let `n=3` and `k=4`, the amount of satisfied numbers is `5`, and the picture below has explain what we should determine in previous problem and new problem:

``````|                       000111  ------>    111000                          ^
|                       001011  ------>    110100                          |
|                       001101  ------>    110010                          |
|  previous 4th number  010011  ------>    101100  new 4th largest number  |
v                       010101  ------>    101010                          |
``````

so after we solve the new problem, we just need to bitwise not.

Now the main problem is how to solve the new problem. First, let A be the array, so `A[m]{1<=m<=2n}` only can be 1 or 0, let `DP[v][q]` be the amount of numbers which satisfy condition2 and condition #(1)=q in `{A[2n-v+1]~A[2n]}`, so the `DP[2n][n]` is the amount of satisfied numbers.

`A` only can be 1 or 0, if `A=1`, the amount of numbers is `DP[2n-1][n-1]`, if `A=0`, the amount of numbers is `DP[2n-1][n]`, now we want to find the `kth largest` number, if `k<=DP[2n-1][n-1]`, `kth largest` number's `A` must be 1, then we can judge `A` with `DP[2n-2][n-2]`; if `k>DP[2n-1][n-1]`, `kth largest` number's `A` must be 0 and `k=k-DP[2n-1][n-1]`, then we can judge `A` with `DP[2n-2][n-1]`. So with the same theory, we can judge `A[j]` one by one until there is no number to compare. Now we can give a example to understand `(n=3, k=4)`

(We use dynamic programming to determine DP matrix, the DP equation is DP[v][q]=DP[v-1][q-1]+DP[v-1][q])

``````   Intention: we need the number in leftest row can be compared,
so we add a row on DP's left row, but it's not include by DP matrix
in the row, all the number is 1.
the number include by bracket are initialized by ourselves
the theory of initialize just follow the mean of DP matrix

DP matrix = (1) (0) (0) (0)                4<=DP=5  -->  A=1
(1) (1) (0) (0)                4>DP=3  -->  A=0, k=4-3=1
(1) (2) (0) (0)                1<=DP=3  -->  A=1
(1) (3)  2  (0)                1<=1  -->  a=1
(1) (4)  5  (0)                no number to compare, A~A=0
(1) (5)  9   5                 so the number is 101100
``````

If you have not understand clearly, you can use the code to understand

Intention`DP[2n][n]` increase very fast, so the code can only work when `n<=19`, in the problem `n<1000`, so you can use big number programming, and the code can be optimize by bit operation, so the code is just a reference

``````/*--------------------------------------------------
Environment: X86 Ubuntu GCC
Author: Cong Yu
Blog: aimager.com
Mail: [email protected]
Build_Date: Mon Dec 16 21:52:49 CST 2013
Function:
--------------------------------------------------*/

#include <stdio.h>

int DP;
// kth is the result
int kth;

void Oper(int n, int k){
int i,j,h;
// temp is the compare number
// jishu is the
int temp,jishu=0;

// initialize
for(i=1;i<=2*n;i++)
DP[i-1]=i-1;
for(j=2;j<=n;j++)
for(i=1;i<=2*j-1;i++)
DP[i-1][j-1]=0;
for(i=1;i<=2*n;i++)
kth[i-1]=0;

// operate DP matrix with dynamic programming
for(j=2;j<=n;j++)
for(i=2*j;i<=2*n;i++)
DP[i-1][j-1]=DP[i-2][j-2]+DP[i-2][j-1];

// the main thought
if(k>DP[2*n-1][n-1])
printf("nothing\n");
else{
i=2*n;
j=n;
for(;j>=1;i--,jishu++){
if(j==1)
temp=1;
else
temp=DP[i-2][j-2];

if(k<=temp){
kth[jishu]=1;
j--;
}
else{
kth[jishu]=0;
if(j==1)
k-=1;
else
k-=DP[i-2][j-2];
}
}
for(i=1;i<=2*n;i++){
kth[i-1]=1-kth[i-1];
printf("%d",kth[i-1]);
}
printf("\n");
}
}

int main(){
int n,k;
scanf("%d",&n);
scanf("%d",&k);
Oper(n,k);
return 0;
}
``````
• Print all `kth` number? There is always only one. As input I have given `n` which is bits number times two and `k` which tells me what number we looking for as output we have to write one line containing the number (as binary).
– abc
Dec 16, 2013 at 13:19
• @Kostek: I have change my answer, you can have a look Dec 17, 2013 at 3:49