Using the usual multiplicative formula to compute the next number from the previous, but with keeping the numbers small. Let's first look at a naive version for clarity.

### Naive

```
def naive(n, m):
c = 1
yield c
for k in range(n):
c = c * (n-k) // (k+1)
yield c % m
n, m = map(int, input().split())
print(*naive(n, m))
```

Takes me ~30 seconds with n=200000. Because c grows very large, up to 60204 digits (199991 bits). And calculations with such large numbers are slow.

### Fast

Instead of naively computing those large c and using modulo m only for output, let's *keep* c small throughout, modulo m. Got accepted on the site, taking ~0.68 seconds.

```
from math import gcd
def fast(n, m):
c = 1
G = 1
yield c
for k in range(n):
mul = n - k
while (g := gcd(mul, m)) > 1:
mul //= g
G *= g
div = k + 1
while (g := gcd(div, m)) > 1:
div //= g
G //= g
c = c * mul * pow(div, -1, m) % m
yield c * G % m
n, m = map(int, input().split())
print(*fast(n, m))
```

Attempt This Online!

Multiplication is fine under modulo. If it were only `c = c * (n-k)`

, we could just do `c = c * (n-k) % m`

.

Division doesn't allow that. So instead of *dividing* by k+1, we *multiply* with its *inverse* (k+1)^{-1} modulo m. The inverse of some number x is the number x^{-1} so you get x·x^{-1} = 1. For example, 7^{-1} modulo 10 is 3. Because multiplying 7 and 3 gives you 21, which is 1 (modulo 10).

Next issue: Not all numbers *have* an inverse modulo m. For example, 6 doesn't have an inverse modulo 10. You can't multiply 6 with any integer and get 1 (modulo 10). Because 6 and 10 have common divisor 2. What we'll do is invert as much of 6 as possible. Extract the common divisor 2, leaving us with 3. That does have an inverse modulo 10 (namely 7).

So extract prime factors in the multipliers/divisors common with m into a separate number G. And update c with what remains, modulo m. Then combine c and G for output.

Rough times I get for n=200000, m=998244353 (the large prime from the question):

```
naive: 30.0 seconds
fast: 1.0 seconds
Matt's: 1.0 seconds
```

For n=200000, m=2*3*5*7*11*13*17*19*23:

```
naive: 30.0 seconds
fast: 1.2 seconds
Matt's: 4.8 seconds
```

I think worst case is a modulus with many primes like m=2*3*5*7*11*13*17*19*23, that maximizes my G. With n=200000, G grows up to 127 bits. Nothing to worry about.

My solution/explanation for a similar problem on Leetcode. That had modulus 10 and I hardcoded factors 2 and 5 and *counted* them instead of multiplying them into a number G like I did here. Maybe I'll revisit it with this general solution...

m, I strongly suspect that there is some math you can do here to convert it into an easy problem. If so, it is more a math problem than a programming problem. If you think I may be right, consider math.stackexchange.com .`m`

in the original question? If`m`

is a prime number, then this is definitely a question about using Lucas' theorem. Note that`998244353`

is, in fact, a prime number.21more comments