# Lagged Fibonacci Rng For Project Euler #149

Hey guys, this is very likely a total brain fart on my part but I was hoping someone could have a look at the following statement which describes how to set up the lagged fibonacci rng:

First, generate four million pseudo-random numbers using a specific form of what is known as a "Lagged Fibonacci Generator":

For 1 ≤ k ≤ 55, s(k) = [100003 − 200003k + 300007k^(3)] (modulo 1000000) − 500000.

For 56 ≤ k ≤ 4000000, s(k) = [s(k−24) + s(k−55) + 1000000] (modulo 1000000) − 500000.

Thus, s(10) = −393027 and s(100) = 86613.

So seems pretty straightforward (this is used to generate the matrix, which is then the actual problem to be solved, this link has the question). Anyways, here is my implementation and its output for s(10) and s(100):

``````class lagged_fib
{
private:
typedef std::deque<int> seed_list;
seed_list seeds;
size_t k;

public:
lagged_fib()
{
k = 1;
}
int operator()()
{
if (k<56)
{
seeds.push_back(((100003 - 200003*k + 300007*k*k*k)%1000000) - 500000);
k++;
}
else
{
seeds.push_back(((seeds[31]+seeds[0]+1000000)%1000000) - 500000);
seeds.pop_front();
}
return seeds.back();
}
};
``````

Which yields:

``````s(10) = -393027
s(100) = -422827
``````

You'll note that s(10) is as expected (so assumably the first part of the algorithm is correct), but s(100) is not. So, hopefully someone can spot where I've gone wrong, this is driving me up the wall.

Thanks

-
Deleted my long answers since they were just adding confusion. I finally got it working when I stopped using 32-bit ints. –  Andy West Dec 11 '09 at 17:22

Looks like you're having integer overflows in your code.

Try using int64_t type instead of int.

-
Yup, that was it for my implementations. I tried it in JavaScript and it worked right away because JavaScript Numbers can handle it by default. But in C#, it didn't work until I converted everything to long. –  Andy West Dec 11 '09 at 17:12
Thanks a ton, I looked at the second part of the algorithm and assumed that there would be no overflow so went ahead and used ints... who knew it was actually the initialization! –  DeusAduro Dec 11 '09 at 20:02

Try performing the computation in `long` values rather than `int` values. The initialization is corrupted by a 32-bit integer overflow at `k` of `20`.

Here is an excerpt of the output for `int` and `long`, following by the source code. The initialization portion prints the internal values to show where the overflow occurs.

``````integer arithmetic
1:      200007  200007 -299993
2:     2100053  100053 -399947
3:     7600183  600183  100183
4:    18500439  500439     439
5:    36600863  600863  100863
6:    63701497  701497  201497
7:   101602383  602383  102383
8:   152103563  103563 -396437
9:   217005079    5079 -494921
10:   298106973  106973 -393027
11:   397209287  209287 -290713
12:   516112063  112063 -387937
13:   656615343  615343  115343
14:   820519169  519169   19169
15:  1009623583  623583  123583
16:  1225728627  728627  228627
17:  1470634343  634343  134343
18:  1746140773  140773 -359227
19:  2054047959   47959 -452041
20: -1898811353 -811353 -1311353
21: -1520702529 -702529 -1202529
22: -1104792823 -792823 -1292823
23:  -649282193 -282193 -782193
24:  -152370597 -370597 -870597
25:   387742007  742007  242007
...
55: -1636843089 -843089 -1343089
56:   94698
...
99: -596227
100: -357419

long arithmetic
1:      200007  200007 -299993
2:     2100053  100053 -399947
3:     7600183  600183  100183
4:    18500439  500439     439
5:    36600863  600863  100863
6:    63701497  701497  201497
7:   101602383  602383  102383
8:   152103563  103563 -396437
9:   217005079    5079 -494921
10:   298106973  106973 -393027
11:   397209287  209287 -290713
12:   516112063  112063 -387937
13:   656615343  615343  115343
14:   820519169  519169   19169
15:  1009623583  623583  123583
16:  1225728627  728627  228627
17:  1470634343  634343  134343
18:  1746140773  140773 -359227
19:  2054047959   47959 -452041
20:  2396155943  155943 -344057
21:  2774264767  264767 -235233
22:  3190174473  174473 -325527
23:  3645685103  685103  185103
24:  4142596699  596699   96699
25:  4682709303  709303  209303
...
55: 49902764463  764463  264463
56:   29290
...
99: -119491
100:   86613
``````

``````public class LaggedFib {

public static void main(String[] args) {
int[] buffer = new int[56];
computeInt(buffer);
computeLong(buffer);
}

private static void computeInt(int[] buffer) {
System.out.println("\n    integer arithmetic");
for (int k = 1; k < 56; ++k) {
int partial = 100003 - 200003 * k + 300007 * k * k * k;
int modded = partial % 1000000;
buffer[k] = modded - 500000;
System.out.printf("    %3d: %11d %7d %7d\n", k, partial, modded, buffer[k]);
}
for (int k = 56; k <= 100; ++k) {
int p24 = (k - 24) % 56;
int p55 = (k - 55) % 56;
int pk  = k % 56;
buffer[pk] = ((buffer[p24] + buffer[p55] + 1000000) % 1000000) - 500000;
System.out.printf("    %3d: %7d\n", k, buffer[pk]);
}
}

private static void computeLong(int[] buffer) {
System.out.println("\n    long arithmetic");
for (int k = 1; k < 56; ++k) {
long partial = 100003L - 200003L * k + 300007L * k * k * k;
long modded = partial % 1000000L;
buffer[k] = (int) (modded - 500000L);
System.out.printf("    %3d: %11d %7d %7d\n", k, partial, modded, buffer[k]);
}
for (int k = 56; k <= 100; ++k) {
int p24 = (k - 24) % 56;
int p55 = (k - 55) % 56;
int pk  = k % 56;
buffer[pk] = (int)(((buffer[p24] + buffer[p55] + 1000000L) % 1000000L) - 500000L);
System.out.printf("    %3d: %7d\n", k, buffer[pk]);
}
}

}
``````
-
+1 Don't know why this was downvoted - it can't be run for 4 million iterations, but it shows the problem with using ints and it gives the correct result. –  Andy West Dec 11 '09 at 17:18
@Andy, Not sure why you said "can't be run for 4 million iterations" unless it was the tracing output (added only to demonstrate the integer overflow problem). After wrapping the tracing output in appropriate conditions (e.g. only print for k equal to 10, 20, 1000, and 4000000 -- the points of interest), a run of 4000000 iterations took about 300ms. –  joel.neely Dec 12 '09 at 3:44