Codility Fibonacci Solution

I'm trying to do the Codility self-certification at : http://codility.com/cert/start/

The Question is as follows:

The Fibonacci sequence is defined by the following recursive formula:

F(0) = 0

F(1) = 1

F(N) = F(N−1) + F(N−2) for N ≥ 2

Write a function:

int power_fib(int N, int M);

that, given two non-negative integers N and M, returns a remainder of F(N^M) modulo 10,000,103.

Note: 10,000,103 is a prime number.

For example, given N = 2 and M = 3, the function should return 21, since 2^3 = 8 and F(8) = 21. Assume that:

N and M are integers within the range [0..10,000,000].

Complexity: expected worst-case time complexity is O(log(N*M));

expected worst-case space complexity is O(1).

Here is my solution:

``````    public int power_fib(int N, int M)
{
double x = Math.Pow(N, M);
Console.WriteLine(x);
int modfib = ModFib(Convert.ToInt64(x));

return modfib;
}

public int ModFib(Int64 n)
{
double a = 0;
double b = 1;

for (long i = 0; i < n; i++)
{
double temp = a;
a = b;
b = temp + b;
}
var mod = a%10000103;
return Convert.ToInt32(mod);
}
``````

Problem is, my solution fails for very large numbers:

The solution failed on test: (4, 7) with WRONG ANSWER [ got -2147483648 expected 909213 ]

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What do you mean it fails due to taking too long? Do you receive an error? –  Matt T Feb 24 '12 at 23:18
I assume you’re missing something. Using the `double` type will result in a loss of precision for very large numbers, meaning that your output will not match the expected. –  Douglas Feb 24 '12 at 23:27
I assume you're missing something. letting the SO community help you solve this problem means you're unable to solve it on your own. In other words it means you cheat and shouldn't get that certificate. But hey, at least you're honest. –  Kaii Feb 24 '12 at 23:33
I don't really want the certificate - but I need to do one of these Codility Tests over the weekend for a job application so want to practice. I got 100% on one of the other sample tests but this one has me stumped. –  kev847382 Feb 24 '12 at 23:35
Two things: 1. Do not use any floating point numbers for this. 2. Learn some basic number theory if you really want to solve this problem. 3. Good luck. –  Daniel Fischer Feb 24 '12 at 23:42

Start by thinking about the range of the problem:

Given two non-negative integers N and M, returns a remainder of F(N^M) modulo 10,000,103. N and M are integers within the range [0..10,000,000].

So max, that is F(10100000000000000). Your solution is to (1) do that many additions, which will take some time, and (2) store the result, which is far, far larger, in a double, that has a maximum range of about 10308 and is only accurate to 15 significant digits anyways.

You need to come up with a better solution. Start by learning about modular arithmetic. Here's a hint: Suppose you want to compute 10100000000000000 mod 9. I'll tell you right now: it's one. How did I do that so fast? Because if a mod b = c and d mod b = f then a*d mod b is congruent to c*f. And similarly, a+d mod b is congruent to c+f. These sorts of facts are crucial when solving these kinds of problems.

Once you've got that, then look into what are the properties of congruences that involve primes? They told you that the modulus was a prime number for a reason; you're going to need that fact.

A few more thoughts:

• When faced with these sorts of programming challenge problems, use meta reasoning about the problem itself. You were given the problem "compute fib(a perfect power) modulo a given prime". You decided to try to solve the more general problem of "compute any_recurrance(something) and then compute something modulo something", which is a far, far harder problem. Don't make it harder on yourself. It is not an accident that the problem is restricted to the fib recurrance on perfect powers modulo a prime; if you are not using all of those facts in your solution, you're probably doing it wrong.

• The learn-it-yourself-the-hard-way approach: For example, try solving the problem "compute fib(n) modulo 2 for any n". Solve it by hand. You should be able to do that with pencil and paper in a few minutes. Then try solving "compute fib(3m) modulo 2". Once you know the solution to the first problem, that should be easy. Then try "compute fib(nm) modulo 2". Again, that should be straightforward given the solution to the previous problem. Once you've solved the problem completely for a modulus of two, try it with a modulus of three. Then five. Then seven. Then eleven. Then for an arbitrary prime number. And then you will have an algorithm that you can actually turn into code.

• The stand-on-the-shoulders-of-others approach: there is an efficient algorithm (that does not use floating point) for computing fib numbers as "powers" of a tuple with a special multiplication rule. However, when doing that the numbers in the tuple rapidly get huge. You can modify the power rule using the rules of modular arithmetic to keep the numbers small while still producing the right answer quickly.

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very nice answer. –  Saeed Amiri Feb 25 '12 at 0:25
Great answer thanks! Relieved to say that the two questions I had to do before my job interview were nowhere near as hard as this one and I scored 100% - still haven't got this one sussed but I'll get there! –  kev847382 Feb 25 '12 at 14:40
@kev847382: You're welcome. This is quite a tricky problem. I cogitated on it a bit and worked out two algorithms; both require some knowledge of (1) how to calculate fib quickly, much more quickly than doing all the additions, and (2) how to use modular arithmetic correctly and safely to keep the numbers small enough so that every sub-calculation fits into a long. Good luck! –  Eric Lippert Feb 25 '12 at 15:16
This explains a lot blog.codility.com/2012/02/its-not-easy-to-get-codility.html Only 6% of people actually pass these tests and only 1% get Gold. Suddenly I don't feel so bad. –  kev847382 Feb 25 '12 at 16:12

Below is my code, that seems to work on all my tests, but the Codility.com says it do not pass their tests. It has O(log(max(N,M))) time complexity and O(1) memory use.

``````    typedef unsigned long long tlong;
#ifndef swap
#define swap(a,b) { \
(a) ^= (b);     \
(b) ^= (a);     \
(a) ^= (b);     \
};

#endif // !1

unsigned int FastLn(unsigned int n){
unsigned k;
for (k = 0; n >=2; k++)
{
n >>= 1;
}
return k;
};
unsigned int Reduce(unsigned int N, unsigned int M){
const unsigned int mod = 10000103;
const unsigned int rep = 2*mod + 2;
unsigned int MM = M;
tlong NN,TOT;
NN = N % rep;
TOT = 1;
while(MM >= 2){
if(MM%2){
TOT *= (NN);TOT %= rep;
}
NN *= NN; NN %= rep;
MM /= 2;
}
NN *= TOT; NN %= rep;
return (unsigned int)(NN);
};
unsigned int Fn(unsigned int N){
switch (N){
case(0):return 0;
case(1):return 1;
case(2):return 1;
case(3):return 2;
case(4):return 3;
}
const unsigned int mod = 10000103;
unsigned int M,l,a,b,n2;
tlong ta,tb;
M = 2;
a = 1;b = 1;
l = FastLn(N);
n2 = 1 << (l-1);
while(M < N)
{
if ((M+1) * n2 <= N)
{
swap(a,b);
a += b;
a %= mod;
M++;
}
if(M == N){
break;
};
if (M>N) M/=0;//A kind of assert, that should throw a DivisionByZero exception, to assure we don't have computational problems
ta = a;
ta *= ta;
//ta %= mod;
tb = b;
tb *= tb;
tb += ta;
tb %= mod;
ta += 2 * (tlong)(a) * (tlong)(b);
ta %= mod;
b = tb;
a = ta;//Using F(2*n) = F(N)*(F(N) + 2*F(N-1)) identity
M <<= 1;
n2 >>= 1;
}
return a;
};

int power_fib ( int N,int M ) {
unsigned a,b;
const unsigned int mod = 10000103;
a = 1;
b = 1;
if(N == 0)return 0;
if(N == 1)return 1;
if(M == 0)return 1;

unsigned int NN;
NN = Reduce((unsigned int)N,(unsigned int)M);
return (int)Fn((unsigned int)NN);
}
``````

What do you think could be wrong with this solution?

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I have just compared the results with those of a program that I have written, and they are the same. –  Carsten Schultz Aug 25 '13 at 16:22

It looks like you're overflowing the int value for the return type of ModFib and for the modfib variable. Try using a long instead.

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Well the solution requires that power_fib returns an int.... x mod 10000103 should be a valid int –  kev847382 Feb 24 '12 at 23:41