Finding the total number of set-bits from 1 to n

Write an algorithm to find `F(n)` the number of bits set to 1, in all numbers from 1 to n for any given value of n.

Complexity should be `O(log n)`

For example:

``````1: 001
2: 010
3: 011
4: 100
5: 101
6: 110
``````

So

``````F(1) = 1,
F(2) = F(1) + 1 = 2,
F(3) = F(2) + 2 = 4,
F(4) = F(3) + 1 = 5,
etc.
``````

I can only design an `O(n)` algorithm.

-
Hint: If you can design an O(1) solution for "how many numbers have a particular bit set from 1 to N", you can design an O(log N) solution for total number of bits. –  Jimmy Mar 21 '12 at 20:59
umm, I have a question. Are you asking "How to find the total bits set in a number?" or something else? –  noMAD Mar 21 '12 at 21:05
@owlstead I don't know about you, but when I find a question that's interesting to me I invest time in answering it regardless of how much time somebody else already has, especially for classic puzzlers like interview questions. I don't get the big deal about investing time before posting - you either appreciate interview questions or you don't. It's not like somebody is asking you to do their job for them... sheesh.. –  Assaf Lavie Mar 21 '12 at 21:16
@noMAD, for example, given n = 3, since 1 = 01, 2 = 10, 3 = 11, the total number of 1 bit from 1 to 3 is 1+1+2=4. Hope this clarity. –  FihopZz Mar 21 '12 at 21:23
@gigantt.com I was just commenting on the formatting of the question, hoping to get the asker to create a question that doesn't need translation, I'll edit the "ur"'s out myself, maybe the asker learned English from YouTube... oh, too late. –  Maarten Bodewes Mar 21 '12 at 21:28

The way to solve these sorts of problems is to write out the first few values, and look for a pattern

```Number  binary   # bits set   F(n)
1       0001     1            1
2       0010     1            2
3       0011     2            4
4       0100     1            5
5       0101     2            7
6       0110     2            9
7       0111     3            12
8       1000     1            13
9       1001     2            15
10      1010     2            17
11      1011     3            20
12      1100     2            22
13      1101     3            25
14      1110     3            28
15      1111     4            32
```

It takes a bit of staring at, but with some thought you notice that the binary-representations of the first 8 and the last 8 numbers are exactly the same, except the first 8 have a `0` in the MSB (most significant bit), while the last 8 have a `1`. Thus, for example to calculate `F(12)`, we can just take `F(7)` and add to it the number of set bits in 8, 9, 10, 11 and 12. But that's the same as the number of set-bits in 0, 1, 2, 3, and 4 (ie. `F(4)`), plus one more for each number!

```#    binary
0    0 000
1    0 001
2    0 010
3    0 011
4    0 100
5    0 101
6    0 110
7    0 111

8    1 000  <--Notice that rightmost-bits repeat themselves
9    1 001     except now we have an extra '1' in every number!
10   1 010
11   1 011
12   1 100
```

Thus, for `8 <= n <= 15`, `F(n) = F(7) + F(n-8) + (n-7)`. Similarly, we could note that for `4 <= n <= 7`, `F(n) = F(3) + F(n-4) + (n-3)`; and for `2 <= n <= 3`, `F(n) = F(1) + F(n-2) + (n-1)`. In general, if we set `a = 2^(floor(log(n)))`, then `F(n) = F(a-1) + F(n-a) + (n-a+1)`

This doesn't quite give us an `O(log n)` algorithm; however, doing so is easy. If `a = 2^x`, then note in the table above that for `a-1`, the first bit is set exactly `a/2` times, the second bit is set exactly `a/2` times, the third bit... all the way to the x'th bit. Thus, `F(a-1) = x*a/2 = x*2^(x-1)`. In the above equation, this gives us

```F(n) = x*2x-1 + F(n-2x) + (n-2x+1)
```

Where `x = floor(log(n))`. Each iteration of calculating `F` will essentially remove the MSB; thus, this is an `O(log(n))` algorithm.

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I find it crazy that so many people believe this algorithm is lg n. It's not. If you can't read it, try implementing it. –  kasavbere Mar 23 '12 at 17:32
"Each iteration of calculating F will essentially remove the MSB; thus, this is an O(log(n)) algorithm." That's not a true statement. You don't get x for free, do you? so you for each looping F(n-2^x) you must get x, then x*2^(x-1), etc. –  tribal Mar 23 '12 at 17:47
@kasavbre, tribal: Care to explain? It is indeed `O(log n)` if you assume `2^x` is an `O(1)` operation (which is it on real-world computers, using left-shift) –  BlueRaja - Danny Pflughoeft Mar 23 '12 at 17:50
but getting x is not. –  tribal Mar 23 '12 at 17:52
@tribal: Yes, obtaining `x` can be done theoretically be done in `O(1)` in hardware. In fact, on modern x86 and x64 machines, it is: It's called the BSR instruction (__builtin_clz in GCC; _BitScanReverse in VC++). In either case, though, I really don't believe this bit of pedantry deserves a downvote :| –  BlueRaja - Danny Pflughoeft Mar 23 '12 at 18:01

If `n= 2^k-1, then F(n)=k*(n+1)/2`

For a general `n`, let `m` be the largest number such that `m = 2^k-1` and `m<=n`. `F(n) = F(m) + F(n-m-1) + (n-m)`.

Corner condition: `F(0)=0` and `F(-1)=0`.

-

A quick search for the values of the sequence F lead to this integer sequence http://oeis.org/A000788

There I spotted a formula: a(0) = 0, a(2n) = a(n)+a(n-1)+n, a(2n+1) = 2a(n)+n+1 (a is the same as F since I just copy the formula from oeis)

which could be used to compute a(n) in log(n).

Here's my sample C++ code:

``````memset(cache, -1, sizeof(cache))
cache[0] = 0

int f(int n)
if cache[n] != -1 return cache[n];
cache[n] = n % 2 ? (2 * f(n / 2) + n / 2 + 1) : (f(n / 2) + f(n / 2 - 1) + n / 2)
``````
-

Let `k` be the number of bits needed for `n`.

for `0,...,2^(k-1)-1` each bit is up exactly for half of the numbers, so we have `(k-1)*2^(k-1)/2 = (k-1)*2^(k-2)` bits up so far. We only need to check what's up with the numbers that are bigger then `2^(k-1)-1`
We also have for those `n-2^(k-1)-1` bits "up" for the MSB.

So we can derive to the recursive function:

``````f(n) = (k-1)*2^(k-2) + n-(2^(k-1)-1) + f(n-(2^(k-1)))
^               ^            ^
first            MSBs        recursive call for
2^(k-1)-1                      n-2^(k-1) highest numbers
numbers
``````

Where base is `f(0) = 0` and `f(2^k) = k*2^(k-1) + 1` [as we seen before, we know exactly how much bits are up for `2^(k-1)-1`, and we just need to add 1 - for the MSB of `2^k`]

Since the value sent to `f` is reduced by by at least half at every iteration, we get total of `O(logn)`

-
"each bit is up exactly for half of the numbers, so we have `2^k/2` bits up" - it's `k*2^k/2`, each number is k bits long. also the resursive formula is not right, see the definition of f(x). –  Karoly Horvath Mar 21 '12 at 21:58
@KarolyHorvath: fixed, thanks.. I followed the logic trail without putting to much thaught into details, thanks for catching that up! –  amit Mar 21 '12 at 22:02
no problem ;) though you start wondering what kind of drugs the upvoters are using.. :D –  Karoly Horvath Mar 21 '12 at 22:04
@KarolyHorvath: I editted again, it is actually `(k-1) * 2^k/2` since we are talking only about the first k-1 bits... I think the upvoters are after an approach and not necesserally a perfect solution... –  amit Mar 21 '12 at 22:05
in that case it's `(k-1) * 2^(k-1)/2` –  Karoly Horvath Mar 21 '12 at 22:07

consider the below:

``````0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
``````

If you want to find total number of set bits from 1 to say 14 (1110) Few Observations:

1. `0th` bit (LSB) `1` bit appears once every two bit (see vertically) so number of set bits = `n/2 +`(`1` if `n's 0th bit is 1` else `0`)
2. 1st bit : 2 consecutive 1s appear every four bits (see 1st bit vertically along all numbers) number of set bits in `1st` bit position = `(n/4 *2) + 1` (since `1st` bit is a set, else `0`)
3. `2nd` bit: `4` consecutive `1s` appear every `8` bits ( this one is a bit tricky) number of set bits in 2nd position = `(n/8*4 )+ 1`( since `2nd` bit is set, else `0`) `+ ((n%8)%(8/2))` The last term is to include the number of `1s` that were outside first `(n/8)` group of bits (`14/8 =1` considers only `1` group ie. `4` set bits in `8` bits. we need to include `1s` found in last `14-8 = 6` bits)
4. `3rd` bit: `8` consecutive 1s appear every `16` bits (similar to above) number of set bits in `3rd` position = `(n/16*8)+1`(since `3rd` bit is set, else `0`)`+ ((n%16)%(16/2))`

so we do `O(1)` calculation for each bit of a number `n`. a number contains `log2(n)` bits. so when we iterate the above for all positions of `n` and add all the set bits at each step, we get the answer in `O(logn)` steps

-

short and sweet!

`````` public static int countbits(int num){
int count=0, n;
while(num > 0){
n=0;
while(num >= 1<<(n+1))
n++;
num -= 1<<n;
count += (num + 1 + (1<<(n-1))*n);
}
return count;
}//countbis
``````
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Not logarithmic time –  Nemo Mar 23 '12 at 2:15
@Nemo, try again. –  kasavbere Mar 23 '12 at 4:14
@kasavbere, can you explain it? Thanks. –  FihopZz Mar 23 '12 at 4:57
FihopZz is there a reason you marked @BlueRaja - Danny Pflughoeft as the correct answer instead of this one? –  kasavbere Mar 23 '12 at 5:04
Well for one thing this is `O((log n)^2)`, not `O(log n)` –  BlueRaja - Danny Pflughoeft Mar 23 '12 at 5:21

Here is the java function

``````private static int[] findx(int i) {
//find the biggest power of two number that is smaller than i
int c = 0;
int pow2 = 1;
while((pow2<< 1) <= i) {
c++;
pow2 = pow2 << 1;
}
return new int[] {c, pow2};
}

public static int TotalBits2(int number) {
if(number == 0) {
return 0;
}
int[] xAndPow = findx(number);
int x = xAndPow[0];
return x*(xAndPow[1] >> 1) + TotalBits2(number - xAndPow[1]) + number - xAndPow[1] + 1;
}
``````
-

this is coded in java...
logic: say number is 34, binary equal-ant is 10010, which can be written as 10000 + 10. 10000 has 4 zeros, so count of all 1's before this number is 2^4(reason below). so count is 2^4 + 2^1 + 1(number it self). so answer is 35.
*for binary number 10000. total combinations of filling 4 places is 2*2*2*2x2(one or zero). So total combinations of ones is 2*2*2*2.

``````public static int getOnesCount(int number) {
String binary = Integer.toBinaryString(number);
return getOnesCount(binary);
}

private static int getOnesCount(String binary) {
int i = binary.length();

if (i>0 && binary.charAt(0) == '1') {
return gePowerof2(i) + getOnesCount(binary.substring(1));
}else if(i==0)
return 1;
else
return getOnesCount(binary.substring(1));

}
//can be replaced with any default power function
private static int gePowerof2(int i){
int count = 1;
while(i>1){
count*=2;
i--;
}
return count;
}
``````
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Doesnt work . Input -2 returns 3 instead of 2. –  KodeSeeker Nov 8 '13 at 1:42