# Counting the bits set in the Fibonacci number system?

We know that, each non negative decimal number can be represented uniquely by sum of Fibonacci numbers(here we are concerned about minimal representation i.e- no consecutive Fibonacci numbers are taken in the representation of a number and also each Fibonacci number is taken at most one in the representation).

For example:

``````1->  1
2-> 10
3->100
4->101, here f1=1 , f2=2 and f(n)=f(n-1)+f(n-2);
``````

so each decimal number can be represented in the Fibonacci system as a binary sequence. If we write all natural numbers successively in Fibonacci system, we will obtain a sequence like this: 110100101… This is called “Fibonacci bit sequence of natural numbers”.

My task is is counting the numbers of times that bit 1 appears in first N bits of this sequence.Since N can take value from 1 to 10^15,Can i do this without storing the Fibonacci sequence ?

for example: if N is 5,the answer is 3.

-
Your question is interesting, but it also looks like a homework assignment. If it is, then please add the homework tag to your question. –  thb Mar 30 '12 at 13:05
Could you elaborate more what is `N`? For example when you say `N` is 5, what is the bit sequence (I thought it would be 1000, no?) and what exactly did you count to get to 4? –  Shahbaz Mar 30 '12 at 13:06
Uniquely? 3 = `0f11` = `0f100` –  Colonel Panic Mar 30 '12 at 13:07
@MattHickford `0f` is great! –  Shahbaz Mar 30 '12 at 13:11
For the reference you can see: en.wikipedia.org/wiki/Zeckendorf's_theorem –  Rafał Rawicki Mar 30 '12 at 16:04

So this is just a preliminary sketch of an algorithm. It works when the upper bound is itself a Fibonacci number, but I'm not sure how to adapt it for general upper bounds. Hopefully someone can improve upon this.

The general idea is to look at the structure of the Fibonacci encodings. Here are the first few numbers:

``````     0
1
10
100
101
1000
1001
1010
10000
10001
10010
10100
10101
100000
``````

The invariant in each of these numbers is that there's never a pair of consecutive 1s. Given this invariant, we can increment from one number to the next using the following pattern:

1. If the last digit is 0, set it to 1.
2. If the last digit is 1, then since there aren't any consecutive 1s, set the last digit to 0 and the next digit to 1.
3. Eliminate any doubled 1s by setting them both to 0 and setting the next digit to a 1, repeating until all doubled 1s are eliminated.

The reason that this is important is that property (3) tells us something about the structure of these numbers. Let's revisit the first few Fibonacci-encoded numbers once more. Look, for example, at the first three numbers:

``````  00
01
10
``````

Now, look at all four-bit numbers:

``````1000
1001
1010
``````

The next number will have five digits, as shown here:

1011 → 1100 → 10000

The interesting detail to notice is that the number of numbers with four digits is equal to the number of values with up to two digits. In fact, we get the four-digit numbers by just prefixing the at-most-two-digit-numbers with 10.

Now, look at three-digit numbers:

``````000
001
010
100
101
``````

And look at five-digit numbers:

``````10000
10001
10010
10100
10101
``````

Notice that the five-digit numbers are just the three-digit numbers with 10 prefixed.

This gives us a very interesting way for counting up how many 1s there are. Specifically, if you look at (k+2)-digit numbers, each of them is just a k-digit number with a 10 prefixed to it. This means that if there are B 1s total in all of the k-digit numbers, the number of Bs total in numbers that are just k+2 digits is equal to B plus the number of k-digit numbers, since we're just replaying the sequence with an extra 1 prepended to each number.

We can exploit this to compute the number of 1s in the Fibonacci codings that have at most k digits in them. The trick is as follows - if for each number of digits we keep track of

1. How many numbers have at most that many digits (call this N(d)), and
2. How many 1s are represented numbers with at most d digits (call this B(d)).

We can use this information to compute these two pieces of information for one more digit. It's a beautiful DP recurrence. Initially, we seed it as follows. For one digit, N(d) = 2 and B(d) is 1, since for one digit the numbers are 0 and 1. For two digits, N(d) = 3 (there's just one two-digit number, 10, and the two one-digit numbers 0 and 1) and B(d) is 2 (one from 1, one from 10). From there, we have that

• N(d + 2) = N(d) + N(d + 1). This is because the number of numbers with up to d + 2 digits is the number of numbers with up to d + 1 digits (N(d + 1)), plus the numbers formed by prefixing 10 to numbers with d digits (N(d))
• B(d + 2) = B(d + 1) + B(d) + N(d) (The number of total 1 bits in numbers of length at most d + 2 is the total number of 1 bits in numbers of length at most d + 1, plus the extra we get from numbers of just d + 2 digits)

For example, we get the following:

`````` d     N(d)      B(d)
---------------------
1       2          1
2       3          2
3       5          5
4       8         10
5      13         20
``````

We can actually check this. For 1-digit numbers, there are a total of 1 one bit used. For 2-digit numbers, there are two ones (1 and 10). For 3-digit numbers, there are five 1s (1, 10, 100, 101). For four-digit numbers, there are 10 ones (the five previous, plus 1000, 1001, 1010). Extending this outward gives us the sequence that we'd like.

This is extremely easy to compute - we can compute the value for k digits in time O(k) with just O(1) memory usage if we reuse space from before. Since the Fibonacci numbers grow exponentially quickly, this means that if we have some number N and want to find the sum of all 1s bits to the largest Fibonacci number smaller than N, we can do so in time O(log N) and space O(1).

That said, I'm not sure how to adapt this to work with general upper bounds. However, I'm optimistic that there is some way to do it. This is a beautiful recurrence and there just has to be a nice way to generalize it.

Hope this helps! Thanks for an awesome problem!

-
The above shows a recurrence relation I'd not seen before with the Fibonacci sequence: each number is the sum of alternating preceding numbers, plus 1. If F[N] is the nth number in the sequence, and PSum[N] is the sum F[N]+F[N-2]+F[N-4]..., then if F[N] = PSum[N-1]+1, then F[N+1] = PSum[N]+1, and F[N+2] = PSum[N+1]+1 = (F[N+1]+PSum[N-1])+1 = F[N+1]+(PSum[N-1]+1) = F[N+1]+F[N]. Very elegant. –  supercat Mar 30 '12 at 17:21
Incidentally, Fibinacci coding might be useful for something like magnetic data encoding with two poulse widths, if "0" means a state transition and "1" means no transition. All such encoding schemes I've seen were table based, but it's interesting that one could use Fibonacci place values instead. –  supercat Mar 30 '12 at 17:30
To go to general upper bounds, I believe that you should represent your bound in Zeckendorf representation and then successively overcount and overcompensate as I wrote in my solution. I hope I wrote this part clearly enough. –  Dale Gerdemann Apr 2 '12 at 14:52
Could you explain how to find the number of one's only in the Nth Fibonacci number, also? –  Adwait Kumar Feb 3 '13 at 9:00
@AdwaitKumar- Any Fibonacci number will have exactly one 1 in it, just as in binary any power of two has exactly one 1 in it. –  templatetypedef Feb 3 '13 at 9:38

Lest solve 3 problems. Each next is harder then previous, each one uses result of previous.

## 1. How many ones are set if you write down every number from 0 to fib[i]-1.

Call this `dp[i]`. Lets look at the numbers

``````     0
1
10
100
101
1000
1001
1010 <-- we want to count ones up to here
10000
``````

If you write all numbers up to fib[i]-1, first you write all numbers up to fib[i-1]-1 (dp[i-1]), then you write the last block of numbers. There are exactly fib[i-2] of those numbers, each has a one on the first position, so we add fib[i-2], and if you erase those ones

``````000
001
010
``````

then remove leading zeros, you can see that each number from 0 to fib[i-2]-1 is written down. Numbers of one there is equal to dp[i-2], which gives us:

``````dp[i] = fib[i-2] + dp[i-2] + dp[i-1];
``````

## 2. How many ones are set if you write down every number from 0 to n.

``````     0
1
10
100
101
1000
1001 <-- we want to count ones up to here
1010
``````

Lets call this `solNumber(n)`

Suppose, that your number is f[i] + x, where f[i] is a maximum possible fibonacci number. Then anser if dp[i] + solNumber(x). This can be proved in the same way as in point 1.

## 3. How many ones are set in first n digits.

### 3a. How many numbers have representation length exactly l

if l = 1 the answer is 1, else its fib[l-2] + 1. You can note, that if you erase leading ones and then all leading zeros you'll have each number from 0 to fib[l-1]-1. Exactly fib[l] numbers.

//End of 3a

Now you can find such number m than, if you write all numbers from 1 to m, their total length will be <=n. But if you write all from 1 to m+1, total length will be > n. Solve the problem manually for m+1 and add solNumber(m).

All 3 problems are solved in O(log n)

``````#include <iostream>

using namespace std;

#define FOR(i, a, b) for(int i = a; i < b; ++i)
#define RFOR(i, b, a) for(int i = b - 1; i >= a; --i)
#define REP(i, N) FOR(i, 0, N)
#define RREP(i, N) RFOR(i, N, 0)

typedef long long Long;

const int MAXL = 30;

long long fib[MAXL];

//How much ones are if you write down the representation of first fib[i]-1 natural numbers
long long dp[MAXL];

void buildDP()
{
fib[0] = 1;
fib[1] = 1;
FOR(i,2,MAXL)
fib[i] = fib[i-1] + fib[i-2];

dp[0] = 0;
dp[1] = 0;
dp[2] = 1;

FOR(i,3,MAXL)
dp[i] = fib[i-2] + dp[i-2] + dp[i-1];
}

//How much ones are if you write down the representation of first n natural numbers
Long solNumber(Long n)
{
if(n == 0)
return n;
Long res = 0;
RREP(i,MAXL)
if(n>=fib[i])
{
n -= fib[i];
res += dp[i];
res += (n+1);
}
return res;
}

int solManual(Long num, Long n)
{
int cr = 0;

RREP(i,MAXL)
{
if(n == 0)
break;

if(num>=fib[i])
{
num -= fib[i];
++cr;
}

if(cr != 0)
--n;
}
return cr;
}

Long num(int l)
{
if(l<=2)
return 1;
return fib[l-1];
}

Long sol(Long n)
{
//length of fibonacci representation
int l = 1;
//totatl acumulated length
int cl = 0;
while(num(l)*l + cl <= n)
{
cl += num(l)*l;
++l;
}
//Number of digits, that represent numbers with maxlength
Long nn = n - cl;

//Number of full numbers;
Long t = nn/l;

//The last full number
n = fib[l] + t-1;

return solNumber(n) + solManual(n+1, nn%l);

}

int main(int argc, char** argv)
{
ios_base::sync_with_stdio(false);
buildDP();

Long n;
while(cin>>n)
cout<<"ANS: "<<sol(n)<<endl;
return 0;
}
``````
-
1. Compute m, the number responsible for the (N+1)th bit of the sequence. Compute the contribution of m to the count.

2. We have reduced the problem to counting the number of one bits in the range [1, m). In the style of interval trees, partition this range into O(log N) subranges, each having an associated glob like 10100???? that matches the representations of exactly the numbers belonging to that range. It is easy to compute the contribution of the prefixes.

3. We have reduced the problem to counting the total number T(k) of one bits in all Fibonacci words of length k (i.e., the ???? part of the globs). T(k) is given by the following recurrence.

``````T(0) = 0
T(1) = 1
T(k) = T(k - 1) + T(k - 2) + F(k - 2)
``````

Mathematica says there's a closed form solution, but it looks awful and isn't needed for this polylog(N)-time algorithm.

-

This is not a full answer but it does outline how you can do this calculation without using brute force.

The Fibonacci representation of `Fn` is a 1 followed by `n-1` zeros.

For the numbers from `Fn` up to but not including `F(n+1)`, the number of 1's consists of two parts:

1. There are `F(n-1)` such numbers, so there are `F(n-1)` leading 1's.
2. The binary digits after the leading numbers are just the binary representations of all numbers up to but not including `F(n-1)`.

So, if we call the total number of bits in the sequence up to but not including the `nth` Fibonacci number `an`, then we have the following recursion:

``````a(n+1) = an + F(n-1) + a(n-1)
``````

You can also easily get the number of bits in the sequence up to `Fn`.

If it takes `k` Fibonacci numbers to get to (but not pass) `N`, then you can count those bits with the above formula, and after some further manipulation reduce the problem to counting the number of bits in the remaining sequence.

-

 : Basically I have followed the property that for any number `n` which is to be represented in fibonacci base, we can break it as `n = n - x` where `x` is the largest fibonacci just less than `n`. Using this property, any number can be broken in bit form.

First step is finding the decimal number such that `Nth` bit ends in it. We can see that all numbers between fibonacci number `F(n)` and `F(n+1)` will have same number of bits. Using this, we can pre-calculate a table and find the appropriate number.

Lets say that you have the decimal number `D` at which there is the `Nth` bit. Now, let `X` be the largest fibonacci number lesser than or equal to `D`. To find set bits for all numbers from `1` to `D` we represnt it as ... `X+0, X+1, X+2, .... X + D-X`. So, all the `X` will be repsented by `1` at the end and we have broken the problem into a much smaller sub-problem. That is, we need to find all set bits till `D-X`. We keep doing this recusively. Using the same logic, we can build a table which has appropriate number of set bits count for all fibonacci numbers (till limit). We would use this table for finding number of set bits from `1` to `X`. So,

``````Findsetbits(D) { // finds number of set bits from 1 to D.
find X; // largest fibonacci number just less than D
ans = tablesetbits[X];
ans += 1 * (D-x+1); // All 1s at the end due to X+0,X+1,...
ans += Findsetbits(D-x);
return ans;
}
``````

I tried some examples by hand and saw the pattern.

I have coded a rough solution which I have checked by hand for N <= 35. It works pretty fast for large numbers, though I can't be sure that it is correct. If it is an online judge problem, please give the link to it.

``````#include<iostream>
#include<vector>
#include<map>
#include<algorithm>
using namespace std;

#define pb push_back
typedef long long LL;
vector<LL>numbits;
vector<LL>fib;
vector<LL>numones;
vector<LL>cfones;

void init() {
fib.pb(1);
fib.pb(2);
int i = 2;
LL c = 1;
while ( c < 100000000000000LL ) {
c = fib[i-1] + fib[i-2];
i++;
fib.pb(c);
}
}

if (n <= 3) return n;
int a = (lower_bound(fib.begin(),fib.end(),n))-fib.begin();
int c = 1;
if (fib[a] == n) {
c = 0;
}
LL ans = cfones[a-1-c] ;
return ans + answer(n - fib[a-c]) + 1 * (n - fib[a-c] + 1);
}
int fillarr(vector<int>& a, LL n) {
if (n == 0)return -1;
if (n == 1) {
a[0] = 1;
return 0;
}
int in = lower_bound(fib.begin(),fib.end(),n) - fib.begin(),v=0;
if (fib[in] != n) v = 1;
LL c = n - fib[in-v];
a[in-v] = 1;
fillarr(a, c);
return in-v;
}
int main() {
init();
numbits.pb(1);
int b = 2;
LL c;
for (int i = 1; i < fib.size()-2; i++) {
c = fib[i+1] - fib[i] ;
c = c*(LL)b;
b++;
numbits.pb(c);
}
for (int i = 1; i < numbits.size(); i++) {
numbits[i] += numbits[i-1];
}
numones.pb(1);
cfones.pb(1);
numones.pb(1);
cfones.pb(2);
numones.pb(1);
cfones.pb(5);
for (int i = 3; i < fib.size(); i++ ) {
LL c = 0;
c += cfones[i-2]+ 1 * fib[i-1];
numones.pb(c);
cfones.pb(c + cfones[i-1]);
}
for (int i = 1; i < numones.size(); i++) {
numones[i] += numones[i-1];
}
LL N;
cin>>N;
if (N == 1) {
cout<<1<<"\n";
return 0;
}
// find the integer just before Nth bit
int pos;
for (int i = 0;; i++) {
if (numbits[i] >= N) {
pos = i;
break;
}
}

LL temp = (N-numbits[pos-1])/(pos+1);
LL temp1 = (N-numbits[pos-1]);
LL num = fib[pos]-1 + (temp1>0?temp+(temp1%(pos+1)?1:0):0);
temp1 -= temp*(pos+1);
if(!temp1) temp1 = pos+1;
vector<int>arr(70,0);
int in = fillarr(arr, num);
int sub = 0;
for (int i = in-(temp1); i >= 0; i--) {
if (arr[i] == 1)
sub += 1;
}
return 0;
}
``````
-

Here is O((log n)^3).

# Lets compute how many numbers fits in first N bits

Imagine that we have function:

``````long long number_of_all_bits_in_sequence(long long M);
``````

It computes length of "Fibonacci bit sequence of natural numbers" created by all numbers that aren't greater than M.

With this function we could use binary search to find how many numbers fits in the first N bits.

# How many bits are 1's in representation of first M numbers

Lets create function which calculates how many numbers <= M have 1 at k-th bit.

``````long long kth_bit_equal_1(long long M, int k);
``````

First lets preprocess results of this function for all small values, lets say M <= 1000000.

Implementation for M > PREPROCESS_LIMIT:

``````long long kth_bit_equal_1(long long M, int k) {
if (M <= PREPROCESS_LIMIT) return preprocess_result[M][k];

long long fib_number = greatest_fib_which_isnt_greater_than(M);
int fib_index = index_of_fib_in_fibonnaci_sequence(fib);

if (fib_index < k) {
// all numbers are smaller than k-th fibbonacci number
return 0;
}

if (fib_index == k) {
// only numbers between [fib_number, M] have k-th bit set to 1
return M - fib_number + 1;
}

if (fib_index > k) {
long long result = 0;

// all numbers between [fib_number, M] have bit at fib_index set to 1
// so lets subtrack fib_number from all numbers in this interval
// now this interval is [0, M - fib_number]
// lets calculate how many numbers in this inteval have k-th bit set.
result += kth_bit_equal_1(M - fib_number, k);

// don't forget about remaining numbers (interval [1, fib_number - 1])
result += kth_bit_equal_1(fib_number - 1, k);

return result;
}
}
``````

Complexity of this function is O(M / PREPROCESS_LIMIT).

Notice that in reccurence one of the addends is always one of fibbonaci numbers.

``````kth_bit_equal_1(fib_number - 1, k);
``````

So if we memorize all computed results than complexity will improve to T(N) = T(N/2) + O(1) . T(n) = O(log N).

# Lets get back to number_of_all_bits_in_sequence

We can slighly modify kth_bit_equal_1 so it would also count bits equal to 0.

-

Here's a way to count all the one digits in the set of numbers up to a given digit length bound. This seems to me to be a reasonable starting point for a solution

Consider 10 digits. Start by writing;

``````0000000000
``````

Now we can turn some number of these zeros into ones, keeping the last digit always as a 0. Consider the possibilities case by case.

0 There's just one way to chose 0 of these to be ones. Summing the 1-bits in this one case gives 0.

1 There are {9 choose 1} ways to turn one of the zeros into a one. Each of these contributes 1.

2 There are {8 choose 2} ways to turn two of the zeros into ones. Each of these contributes 2.

...

5 There are {5 choose 5} ways to turn five of the zeros into ones. Each of these contributes 5 to the bit count.

It's easy to think of this as a tiling problem. The string of 10 zeros is a 10x1 board, which we want to tile with 1x1 squares and 2x1 dominoes. Choosing some number of the zeros to be ones is then the same as choosing some of the tiles to be dominoes. My solution is closely related to Identity 4 in "Proofs that really count" by Benjamin and Quinn.

Second step Now try to use the above construction to solve the original problem

Suppose we want to the one bits in the first 100100010 bits (the number is in Fibonacci representation of course). Start by overcounting the sum for all ways to replace the x's with zeros and ones in 10xxxxx0. To overcompensate for overcounting, subract the count for 10xxx0. Continue the procedure of overcounting and overcompensation.

-

This problem has a dynamic solution, as illustrated by the tested algorithm below. Some points to keep in mind, which are evident in the code:

The best solution for each number i will be obtained by using the fibonacci number f where f == i OR where f is less than i then it must be f and the greatest number n <= f: i = f+n.

Note that the fib sequence is memoized over the entire algorithm.

``````public static int[] fibonacciBitSequenceOfNaturalNumbers(int num) {
int[] setBits = new int[num + 1];
setBits[0] = 0;//anchor case of fib seq
setBits[1] = 1;//anchor case of fib seq
int a = 1, b = 1;//anchor case of fib seq
for (int i = 2; i <= num; i++) {
int c = b;
while (c < i) {
c = a + b;
a = b;
b = c;
}//fib
if (c == i) {
setBits[i] = 1;
continue;
}
c = a;
int tmp = c;//to optimize further, make tmp the fib before a
while (c + tmp != i) {
tmp--;
}
setBits[i] = 1 + setBits[tmp];
}//done

return setBits;
}
``````

Test with:

`````` public static void main(String... args) {
int[] arr = fibonacciBitSequenceOfNaturalNumbers(23);
//print result
for(int i=1; i<arr.length; i++)
System.out.format("%d has %d%n", i, arr[i]);
}
``````

RESULT OF TEST: i has x set bits

``````1 has 1
2 has 1
3 has 1
4 has 2
5 has 1
6 has 2
7 has 2
8 has 1
9 has 2
10 has 2
11 has 2
12 has 3
13 has 1
14 has 2
15 has 2
16 has 2
17 has 3
18 has 2
19 has 3
20 has 3
21 has 1
22 has 2
23 has 2
``````

EDIT BASED ON COMMENT:

``````//to return total number of set between 1 and n inclusive
//instead of returning as in original post, replace with this code

int total = 0;
for(int i: setBits)
total+=i;