# How to speed up series generation?

The problem requires to generate the `n-th` element of a sequence that is similar to Fibonacci sequence. However, it's a bit tricky because `n` is very large (1 <= n <= 10^9). The answer then modulo 1000000007. The sequence is defined as follows:

Using generating function, I obtain the following formula:

If I use the sequence approach then the answer can be modulo, but it run extremely slow. In fact, I got `time limit exceed` many times. I also tried to use a table to pre-generate some initial values (cache), still it was not fast enough. In addition, the maximum number of elements that I can store in an `array/vector` (C++) is too small compared with 10^9, so I guess this approach doesn't work either.
If I use the direct formula then it run extremely fast but only for `n` that is small. For `n` large, double will got truncated, plus I won't be able to mod my answer with that number because modulo only works with integer.
I ran out of idea, and I think there must be a very nice trick to work around this problem, unfortunately I just can't think of one. Any idea would be greatly appreciated.

Here's my initial approach:

``````#include <iostream>
#include <vector>
#include <string>
#include <algorithm>
#include <cmath>
#include <cassert>
#include <bitset>
#include <fstream>
#include <iomanip>
#include <set>
#include <stack>
#include <sstream>
#include <cstdio>
#include <map>
#include <cmath>

using namespace std;

typedef unsigned long long ull;

ull count_fair_coins_by_generating_function(ull n) {
n--;
return
(sqrt(3.0) + 1)/((sqrt(3.0) - 1) * 2 * sqrt(3.0)) * pow(2 / (sqrt(3.0) - 1), n * 1.0)
+
(1 - sqrt(3.0))/((sqrt(3.0) + 1) * 2 * sqrt(3.0)) * pow(-2 / (sqrt(3.0) + 1), n * 1.0);
}

ull count_fair_coins(ull n) {
if (n == 1) {
return 1;
}
else if (n == 2) {
return 3;
}
else {
ull a1 = 1;
ull a2 = 3;
ull result;
for (ull i = 3; i <= n; ++i) {
result = (2*a2 + 2*a1) % 1000000007;
a1 = a2;
a2 = result;
}

return result;
}
}

void inout_my_fair_coins() {
int test_cases;
cin >> test_cases;

map<ull, ull> cache;
ull n;
while (test_cases--) {
cin >> n;
cout << count_fair_coins_by_generating_function(n) << endl;
cout << count_fair_coins(n) << endl;
}
}

int main() {
inout_my_fair_coins();
return 0;
}
``````

Update Since the contest was over, I posted my solution based on `tskuzzy` idea for those who are interested. Once again, thanks `tskuzzy`. You can view the original problem statement here: http://www.codechef.com/problems/CSUMD
First, you need to figure out the probability of those `1 coin` and `2 coin`, then get some initial values to obtain the sequence. The complete solution is here:

``````#include <iostream>
#include <vector>
#include <string>
#include <algorithm>
#include <cmath>
#include <cassert>
#include <bitset>
#include <fstream>
#include <iomanip>
#include <set>
#include <stack>
#include <sstream>
#include <cstdio>
#include <map>
#include <cmath>

using namespace std;

typedef unsigned long long ull;

const ull special_prime = 1000000007;

/*
Using generating function for the recurrence:
| 1                     if n = 1
a_n =  | 3                     if n = 2
| 2a_{n-1} + 2a_{n-2}     if n > 2

This method is probably the fastest one but it won't work
because when n is large, double just can't afford it. Plus,
using this formula, we can't apply mod for floating point number.
1 <= n <= 21
*/
ull count_fair_coins_by_generating_function(ull n) {
n--;
return
(sqrt(3.0) + 1)/((sqrt(3.0) - 1) * 2 * sqrt(3.0)) * pow(2 / (sqrt(3.0) - 1), n * 1.0)
+
(1 - sqrt(3.0))/((sqrt(3.0) + 1) * 2 * sqrt(3.0)) * pow(-2 / (sqrt(3.0) + 1), n * 1.0);
}

/*
Naive approach, it works but very slow.
Useful for testing.
*/
ull count_fair_coins(ull n) {
if (n == 1) {
return 1;
}
else if (n == 2) {
return 3;
}
else {
ull a1 = 1;
ull a2 = 3;
ull result;
for (ull i = 3; i <= n; ++i) {
result = (2*a2 + 2*a1) % 1000000007;
a1 = a2;
a2 = result;
}

return result;
}
}

struct matrix_2_by_2 {
ull m[2][2];
ull a[2][2];
ull b[2][2];

explicit matrix_2_by_2(ull a00, ull a01, ull a10, ull a11) {
m[0][0] = a00;
m[0][1] = a01;
m[1][0] = a10;
m[1][1] = a11;
}

matrix_2_by_2 operator *(const matrix_2_by_2& rhs) const {
matrix_2_by_2 result(0, 0, 0, 0);
result.m[0][0] = (m[0][0] * rhs.m[0][0]) + (m[0][1] * rhs.m[1][0]);
result.m[0][1] = (m[0][0] * rhs.m[0][1]) + (m[0][1] * rhs.m[1][1]);
result.m[1][0] = (m[1][0] * rhs.m[0][0]) + (m[1][1] * rhs.m[1][0]);
result.m[1][1] = (m[1][0] * rhs.m[0][1]) + (m[1][1] * rhs.m[1][1]);
return result;
}

void square() {
a[0][0] = b[0][0] = m[0][0];
a[0][1] = b[0][1] = m[0][1];
a[1][0] = b[1][0] = m[1][0];
a[1][1] = b[1][1] = m[1][1];

m[0][0] = (a[0][0] * b[0][0]) + (a[0][1] * b[1][0]);
m[0][1] = (a[0][0] * b[0][1]) + (a[0][1] * b[1][1]);
m[1][0] = (a[1][0] * b[0][0]) + (a[1][1] * b[1][0]);
m[1][1] = (a[1][0] * b[0][1]) + (a[1][1] * b[1][1]);
}

void mod(ull n) {
m[0][0] %= n;
m[0][1] %= n;
m[1][0] %= n;
m[1][1] %= n;
}

/*
exponentiation by squaring algorithm
| 1                    if n = 0
| (1/x)^n              if n < 0
x^n =   | x.x^({(n-1)/2})^2    if n is odd
| (x^{n/2})^2          if n is even

The following algorithm calculate a^p % m
int modulo(int a, int p, int m){
long long x = 1;
long long y = a;

while (p > 0) {
if (p % 2 == 1){
x = (x * y) % m;
}

// squaring the base
y = (y * y) % m;
p /= 2;
}

return x % c;
}

To apply for matrix, we need an identity which is
equivalent to 1, then perform multiplication for matrix
in similar manner. Thus the algorithm is defined
as follows:
*/
void operator ^=(ull p) {
matrix_2_by_2 identity(1, 0, 0, 1);

while (p > 0) {
if (p % 2) {
identity = operator*(identity);
identity.mod(special_prime);
}

this->square();
this->mod(special_prime);
p /= 2;
}

m[0][0] = identity.m[0][0];
m[0][1] = identity.m[0][1];
m[1][0] = identity.m[1][0];
m[1][1] = identity.m[1][1];
}

friend
ostream& operator <<(ostream& out, const matrix_2_by_2& rhs) {
out << rhs.m[0][0] << ' ' << rhs.m[0][1] << '\n';
out << rhs.m[1][0] << ' ' << rhs.m[1][1] << '\n';
return out;
}
};

/*
|a_{n+2}| = |2 2|^n  x |3|
|a_{n+1}|   |1 0|      |1|
*/
ull count_fair_coins_by_matrix(ull n) {
if (n == 1) {
return 1;
} else {
matrix_2_by_2 m(2, 2, 1, 0);
m ^= (n - 1);
return (m.m[1][0] * 3 + m.m[1][1]) % 1000000007;
}
}

void inout_my_fair_coins() {
int test_cases;
scanf("%d", &test_cases);

ull n;
while (test_cases--) {
scanf("%llu", &n);
printf("%d\n", count_fair_coins_by_matrix(n));
}
}

int main() {
inout_my_fair_coins();
return 0;
}
``````
-
There have been about a hundred questions on this particular competition/project. But this is definitely one of the better written ones. +1 –  Mysticial Jul 8 '12 at 7:00
Why don't you cache the elements of the equations that are expensive and unchanging (e.g. the result of `sqrt(3.0)` and multiplications of it)? Otherwise you are paying for that runtime over and over again. –  Kevin Grant Jul 8 '12 at 7:00
@KevinGrant: Thanks for pointing that out, I was a bit sloppy on that. –  Chan Jul 8 '12 at 7:02
Btw, 2/(sqrt(3)-1) = sqrt(3)+1 and 2/(sqrt(3)+1) = sqrt(3)-1. –  Alexey Frunze Jul 8 '12 at 7:52
@Chan, You should name the contest: UVa, ACM-ICPC, TC, SPOJ or whatever it is –  Alexander Jul 8 '12 at 8:50

You can write the terms of the sequence in terms of matrix exponentials:

which can be quickly evaluated using exponentiation by squaring. This leads to an `O(log n)` solution which should solve the problem well within the time constraints.

Just for future reference, if you are required to do multiplication with large numbers (not applicable in this situation since the answer is taken modulo 1000000007), you should look into the Karatsuba algorithm. This gives you sub-quadratic time multiplication.

-
Problem solved! This technique is really clever. Thank you very much. –  Chan Jul 8 '12 at 9:11
By the way, could I ask you how did you get the values for the bottom row? The first row makes sense since a_{n} = 2a_{n-1} + 2a_{n-2}, but I couldn't figure out why the second row is `1, 0`. –  Chan Jul 8 '12 at 9:14
@Chan: It saves the value of a_{n-1} for the next "iteration" where it becomes a_{n-2}. –  tskuzzy Jul 8 '12 at 9:24
That makes sense. Thanks. –  Chan Jul 8 '12 at 9:30

Just thinking here but take a look at Duff's device for the count_fair_coins function as that will automatically unroll the loop to speed up that function.

Precomputing the sqrt's in the generating function seems like the easiest way to get any speed up. Which would reduce to just a single pow call and multiplication of constants. As well as precomuting the sqrt's another way to speed it up is to remove the divisions and use the inverse multiplication, although a very slight optimization it might help speed up when n is very large.

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