# Calculate count of ones in result of 11^n

The following problem was asked in an interview. Given a number 11n (where `n``[0, 1000]`), get the count of `1`s in the result. For example, n=3, 113 = 1331, so the expected result would be 2. Or given n=6, 116 = 1771561, the expected result would be 3.

My first thought was that it had to do something with the pascal's triangle and binomial coefficients (because as we know simply calculating `pow(11, 1000)` doesn't work, at least in C).

I thought by simply iterating over the columns in the pascal's triangle should give me the result, but that clearly doesn't work.

So I'm kind of stuck right now. My next thought was to use some kind of `bignum library` to solve the problem, but in my opinion there must be another way to solve this kind of task.

Update I forgot to mention that I was supposed to solve this task with C / Objective-C.

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You don't need any bignum library to multiply by 11 :-) –  Egor Skriptunoff Apr 27 '13 at 10:35
Python can count the number of `1`s in `11^100000` in about `2.09s`, so for your constraints, the bignum library should work. I don't think there's any sort of analytic solution to this problem. –  Blender Apr 27 '13 at 10:58
Sounds like a great candidate for preprocessing. –  cheeken Apr 27 '13 at 17:27

Like Bartosz suggested, I would solve this by simply performing the calculations in base 10. A multiplication by 11 in base 10 can be done with a left shift and an addition. Here's a C program that works on ASCII strings. Note that the least significant digit comes first in each string.

``````#include <stdio.h>
#include <stdlib.h>
#include <string.h>

char *multiply_by_11(const char *num, int *num_ones_ptr)
{
size_t len = strlen(num);
char *result = (char *)malloc(len + 3);
int carry = 0;
int num_ones = 0;
size_t i;

for (i = 0; i <= len; ++i) {
int digit = carry;

if (i < len) {
digit += num[i] - '0';
}
if (i > 0) {
digit += num[i-1] - '0';
}

if (digit < 10) {
carry = 0;
}
else {
digit -= 10;
carry = 1;
}

if (digit == 1) {
++num_ones;
}
result[i] = digit + '0';
}

if (carry) {
result[i++] = '1';
++num_ones;
}

result[i] = '\0';

*num_ones_ptr = num_ones;
return result;
}

int main()
{
char *num = (char *)malloc(2);
int i;

strcpy(num, "1");

for (i = 1; i <= 1000; ++i) {
int num_ones;

char *product = multiply_by_11(num, &num_ones);
printf("11 ^ %4d: %3d ones\n", i, num_ones);

free(num);
num = product;
}

free(num);
return 0;
}
``````
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Thanks for the example. If I could, I'd accept both yours and Bartosz Marcinkowski answers. But unfortunately I can't and your answer contains a working example, so yours win :) –  mAu May 9 '13 at 13:11

Did they tell you how efficent the algorithm should be?

I would implement it straightforwardly on strings; multiplying by 11 is simply making a copy with one trailing 0 added and then adding, so all you'd have to do is implement adding numbers written as strings.

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Complexity is O(n^2) –  Egor Skriptunoff Apr 27 '13 at 10:42
How is this more efficient than computing 11^n with a bignum library? My Python interpreter prints `str(11**1000)` in an instant. It's probably doing exponentiation by squaring. –  larsmans Apr 27 '13 at 10:44
It is O(n^2), but for n < 1000 it gives the answer immediately. It is not more efficient that using bigint library, but we don't know if he was supposed to use one. That is why I asked if he was told about coplexity. –  Bartosz Marcinkowski Apr 27 '13 at 11:01
Sorry for the delayed answer. Yes the worst case complexity should have been O(n^2). –  mAu Apr 27 '13 at 11:11
I'll try your solution as soon as I'm back on my computer. –  mAu Apr 27 '13 at 11:12

A string version in Haskell seems to work quite well:

``````Prelude> let f n = length . filter (=='1') . show . (11^) \$ n
Prelude> f 1000
105
(0.00 secs, 1129452 bytes)
Prelude> f 1000000
104499
(2.64 secs, 69393408 bytes)
``````
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Thanks for the input. But I forgot to mention that I was supposed to solve this task in C or Objective-C. –  mAu Apr 29 '13 at 8:01

assume K(i) is a string that is produced from k-th row of pascal triangle.

11^0=1,11^1=11,11^2= 121. But 11^i=k(i) is a false assumption. Because 11^i=(10+1)^i &

====>

so for small numbers it is true because 10^i is very bigger than a[i] for big numbers it maybe has an overflow for the following reason.

``````a[i+1]=((n-i+1)/a[i])*a[i]
&
suppose that: a[i]*10^(n-i+1) and a[i+1]*10^(n-i) are two Consecutive numbers
``````

so when `a[i]*10^(n-i+1) < a[i+1]*10^(n-i)` overflow happens. By simplifying those, you get `(n-i+1)/i >10` that is when overflow happens.
you should calculate these overflows in your algorithm.

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Why would you do this? –  Karoly Horvath Apr 29 '13 at 8:17
mAu said I thought by simply iterating over the columns in the pascal's triangle should give me the result, but that clearly doesn't work. and i guess his mistake and try to explain how he can solve your problem by improve his solution.i think my answer need edit but my English language is week. –  amin k Apr 29 '13 at 9:15