int modpow(int x, int n, int m) { if (n == 0) return 1%m; int u = modpow(x,n/2,m); u = (u*u)%m; if (n%2 == 1) u = (u*x)%m; return u; }
Please explain modpow(x, n/2, m) call again and again when below its code execute.
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int modpow(int x, int n, int m) { if (n == 0) return 1%m; int u = modpow(x,n/2,m); u = (u*u)%m; if (n%2 == 1) u = (u*x)%m; return u; }
Please explain modpow(x, n/2, m) call again and again when below its code execute.
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To understand how this works you need to know this following formula:
(A^n) % M = [ { (A^(n/2)) % M } * { (A^(n/2)) % M } ] % M [when n is even]
if n is odd then we can always write that
(A^n) % M = [ (A % M) * {(A^(n-1)) % M} ] % M [and now n-1 is even so we can apply the first formula]
This is the fundamental of binomial exponentiation. If you are required to calculate (A^N) % M in O(log N) time then this is the approach you should follow. If you still can't understand how that code works by calling itself in itself then I would suggest that you learn about recursions.
For more info: https://e-maxx-eng.appspot.com/algebra/binary-exp.html