# Fibonacci Modified:How to fix this algorithm?

I have this problem in front of me and I can't figure out how to solve it. It's about the series `0,1,1,2,5,29,866...` (Every number besides the first two is the sum of the squares of the previous two numbers `(2^2+5^2=29)`). In the first part I had to write an algorithm (Not a native speaker so I don't really know the terminology) that would receive a place in the series and return it's value (`6 returned 29`) This is how I wrote it:

``````public static int mod(int n)
{
if (n==1)
return 0;
if (n==2)
return 1;
else
return (int)(Math.pow(mod(n-1), 2))+(int)(Math.pow(mod(n-2), 2));
}
``````

However, now I need that the algorithm will receive a number and return the total sum up to it in the series `(6- 29+5+2+1+1+0=38`) I have no idea how to do this, I am trying but I am really unable to understand recursion so far, even if I wrote something right, how can I check it to be sure? And how generally to reach the right algorithm?

Using any extra parameters is forbidden.

Thanks in advance!

• Put the funcion call inside a loop, no? or does it have to be recursive? – Óscar López Dec 6 '17 at 20:06
• Has to be recursive. – איתן לוי Dec 6 '17 at 20:09
• The example doesn't look right. `6-29+5+2+1+1+0` is not `38`, and I'm wondering, how did that `6-` end up there? – Óscar López Dec 6 '17 at 20:13
• I meant that if n=6 it return 38. – איתן לוי Dec 6 '17 at 20:14
• So you are saying that you have to calculate `sum(n) = mod(n) + sum(n-1)` with `mod(n) = mod(n-1)^2 + mod(n-2)^2`, but you have to do it with exactly one method with exactly one parameter? You can't create `mod` and `sum` as separate methods, or any other helper methods, and you can't add extra parameters as is often done for recursive methods. Did I understand that right? That constraints are that restrictive? – Andreas Dec 6 '17 at 20:30

## 5 Answers

We want:

``````mod(1) = 0
mod(2) = 0+1
mod(3) = 0+1+1
mod(4) = 0+1+1+2
mod(5) = 0+1+1+2+5
mod(6) = 0+1+1+2+5+29
``````

and we know that each term is defined as something like:

``````   2^2+5^2=29
``````

So to work out mod(7) we need to add the next term in the sequence x to mod(6).

Now we can work out the term using mod:

`````` x = term(5)^2 + term(6)^2
term(5) = mod(5) - mod(4)
term(6) = mod(6) - mod(5)
x = (mod(5)-mod(4))^2 + (mod(6)-mod(5))^2
``````

So we can work out mod(7) by evaluating mod(4),mod(5),mod(6) and combining the results.

Of course, this is going to be incredibly inefficient unless you memoize the function!

Example Python code:

``````def f(n):
if n<=0:
return 0
if n==1:
return 1
a=f(n-1)
b=f(n-2)
c=f(n-3)
return a+(a-b)**2+(b-c)**2

for n in range(10):
print f(n)
``````

prints:

``````0
1
2
4
9
38
904
751701
563697636866
317754178345850590849300
``````
• @TNguyen I've added an implementation – Peter de Rivaz Dec 6 '17 at 21:13
• Very nice approach - much more elegant than the hack I used! – sprinter Dec 6 '17 at 21:20

How about this? :)

``````class Main {

public static void main(String[] args) {
final int N = 6; // Your number here.
System.out.println(result(N));
}

private static long result(final int n) {
if (n == 0) {
return 0;
} else {
return element(n) + result(n - 1);
}
}

private static long element(final int n) {
if (n == 1) {
return 0L;
} else if (n == 2) {
return 1L;
} else {
return sqr(element(n - 2)) + sqr(element(n - 1));
}
}

private static long sqr(final long x) {
return x * x;
}
}
``````

Here is the idea that separate function (`element`) is responsible for finding n-th element in the sequence, and `result` is responsible for summing them up. Most probably there is a more efficient solution though. However, there is only one parameter.

• OP has said that adding extra method is not allowed. Stupid constraint in my opinion, but that's what OP said. – Andreas Dec 6 '17 at 21:09
• Well, had fun solving anyways :) Going with one method seems to be quite advanced approach. – PresentProgrammer Dec 6 '17 at 21:16

I can think of a way of doing this with the constraints in your comments but it's a total hack. You need one method to do two things: find the current value and add previous values. One option is to use negative numbers to flag one of those function:

``````int f(int n) {
if (n > 0)
return f(-n) + f(n-1);
else if (n > -2)
return 0;
else if (n == -2)
return 1;
else
return f(n+1)*f(n+1)+f(n+2)*f(n+2);
}
``````

The first 8 numbers output (before overflow) are:

``````0
1
2
4
9
38
904
751701
``````

I don't recommend this solution but it does meet your constraints of being a single recursive method with a single argument.

• That is an impressive solution! – PresentProgrammer Dec 6 '17 at 21:10
• this is incorrect: 0 -> 0 1 -> 0*0 + 1*1 = 1 2 -> 1*1 + 1*1 = 2 3 -> 2*2 + 1*1 = 5 4 -> 5*5 + 2*2 = 29 5-> 29*29 + 5*5 = 866 ... – zlakad Dec 6 '17 at 21:15
• @zlakad any further details? – sprinter Dec 6 '17 at 21:16
• @zlakad you haven't read the question properly. You are showing the terms but OP wants the sum of all terms. – sprinter Dec 6 '17 at 22:07
• @sprinter I apologize - I didn't read the question to the end. – zlakad Dec 6 '17 at 22:51

Here is my proposal.

We know that:

f(n) = 0; n < 2

f(n) = 1; 2 >= n <= 3

f(n) = f(n-1)^2 + f(n-2)^2; n>3

So:

``````f(0)= 0
f(1)= 0
f(2)= f(1) + f(0) = 1
f(3)= f(2) + f(1) = 1
f(4)= f(3) + f(2) = 2
f(5)= f(4) + f(3) = 5
and so on
``````

According with this behaivor we must implement a recursive function to return:

Total = sum f(n); n= 0:k; where k>0

I read you can use a static method but not use more than one parameter into the function. So, i used a static variable with the static method, just for control the execution of loop:

``````class Dummy
{

public static void main (String[] args) throws InterruptedException {

int n=10;

for(int i=1; i<=n; i++)
{
System.out.println("--------------------------");
System.out.println("Total for n:" + i +" = " + Dummy.f(i));
}
}

private static int counter = 0;
public static long f(int n)
{
counter++;

if(counter == 1)
{
long total = 0;
while(n>=0)
{
total +=  f(n);
n--;
}
counter--;
return total;
}

long result = 0;
long n1=0,n2=0;

if(n >= 2 && n <=3)
result++; //Increase 1
else if(n>3)
{
n1 = f(n-1);
n2 = f(n-2);

result = n1*n1 + n2*n2;
}

counter--;
return result;
}
}
``````

the output:

``````--------------------------
Total for n:1 = 0
--------------------------
Total for n:2 = 1
--------------------------
Total for n:3 = 2
--------------------------
Total for n:4 = 4
--------------------------
Total for n:5 = 9
--------------------------
Total for n:6 = 38
--------------------------
Total for n:7 = 904
--------------------------
Total for n:8 = 751701
--------------------------
Total for n:9 = 563697636866
--------------------------
Total for n:10 = 9011676203564263700
``````

I hope it helps you.

UPDATE: Here is another version without a static method and has the same output:

``````class Dummy
{

public static void main (String[] args) throws InterruptedException {

Dummy app = new Dummy();
int n=10;

for(int i=1; i<=n; i++)
{
System.out.println("--------------------------");
System.out.println("Total for n:" + i +" = " + app.mod(i));
}
}

private static int counter = 0;
public long mod(int n)
{
Dummy.counter++;

if(counter == 1)
{
long total = 0;
while(n>=0)
{
total +=  mod(n);
n--;
}
Dummy.counter--;
return total;
}

long result = 0;
long n1=0,n2=0;

if(n >= 2 && n <=3)
result++; //Increase 1
else if(n>3)
{
n1 = mod(n-1);
n2 = mod(n-2);

result = n1*n1 + n2*n2;
}

Dummy.counter--;
return result;
}
}
``````

Non-recursive|Memoized You should not use recursion since it will not be good in performance. Use memoization instead.

``````def FibonacciModified(n):
fib = [0]*n
fib[0],fib[1]=0,1
for idx in range(2,n):
fib[idx] = fib[idx-1]**2 + fib[idx-2]**2
return fib

if __name__ == '__main__':
fib = FibonacciModified(8)
for x in fib:
print x
``````

Output:

``````0
1
1
2
5
29
866
750797
``````

The above will calculate every number in the series once[not more than that]. While in recursion an element in the series will be calculated multiple times irrespective of the fact that the number was calculated before.

http://www.geeksforgeeks.org/program-for-nth-fibonacci-number/