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.

`k`

?`k`

is limited by`10^9`

. I have updated question.`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.`0`

s and`1`

s with`A`

s and`B`

s and don't mention the word "binary" ;-)1more comment