**[Edit]** One last thought, which (IMO) is important enough that I'll put it at the beginning: if you're collecting a bunch of totients at once, you can avoid a lot of redundant work. Don't bother starting from large numbers to find their smaller factors -- instead, iterate over the smaller factors and accumulate results for the larger numbers.

```
class Totient:
def __init__(self, n):
self.totients = [1 for i in range(n)]
for i in range(2, n):
if self.totients[i] == 1:
for j in range(i, n, i):
self.totients[j] *= i - 1
k = j / i
while k % i == 0:
self.totients[j] *= i
k /= i
def __call__(self, i):
return self.totients[i]
if __name__ == '__main__':
from itertools import imap
totient = Totient(10000)
print sum(imap(totient, range(10000)))
```

This takes just 8ms on my desktop.

The Wikipedia page on the Euler totient function has some nice mathematical results.

counts the numbers coprime to and smaller than each divisor of : this has a trivial* mapping to counting the integers from to , so the sum total is .

** by the second definition of* trivial

This is perfect for an application of the Möbius inversion formula, a clever trick for inverting sums of this exact form.

This leads naturally to the code

```
def totient(n):
if n == 1: return 1
return sum(d * mobius(n / d) for d in range(1, n+1) if n % d == 0)
def mobius(n):
result, i = 1, 2
while n >= i:
if n % i == 0:
n = n / i
if n % i == 0:
return 0
result = -result
i = i + 1
return result
```

There exist better implementations of the Möbius function, and it could be memoized for speed, but this should be easy enough to follow.

The more obvious computation of the totient function is

In other words, fully factor the number into unique primes and exponents, and do a simple multiplication from there.

```
from operator import mul
def totient(n):
return int(reduce(mul, (1 - 1.0 / p for p in prime_factors(n)), n))
def primes_factors(n):
i = 2
while n >= i:
if n % i == 0:
yield i
n = n / i
while n % i == 0:
n = n / i
i = i + 1
```

Again, there exist better implementations of `prime_factors`

, but this is meant for easy reading.

`# helper functions`

```
from collections import defaultdict
from itertools import count
from operator import mul
def gcd(a, b):
while a != 0: a, b = b % a, a
return b
def lcm(a, b): return a * b / gcd(a, b)
primes_cache, prime_jumps = [], defaultdict(list)
def primes():
prime = 1
for i in count():
if i < len(primes_cache): prime = primes_cache[i]
else:
prime += 1
while prime in prime_jumps:
for skip in prime_jumps[prime]:
prime_jumps[prime + skip] += [skip]
del prime_jumps[prime]
prime += 1
prime_jumps[prime + prime] += [prime]
primes_cache.append(prime)
yield prime
def factorize(n):
for prime in primes():
if prime > n: return
exponent = 0
while n % prime == 0:
exponent, n = exponent + 1, n / prime
if exponent != 0:
yield prime, exponent
```

`# OP's first attempt`

```
def totient1(n):
counter = 0
for i in xrange(1, n):
if gcd(i, n) == 1:
counter += 1
return counter
```

`# OP's second attempt`

```
# I don't understand the algorithm, and just copying it yields inaccurate results
```

`# Möbius inversion`

```
def totient2(n):
if n == 1: return 1
return sum(d * mobius(n / d) for d in xrange(1, n+1) if n % d == 0)
mobius_cache = {}
def mobius(n):
result, stack = 1, [n]
for prime in primes():
if n in mobius_cache:
result = mobius_cache[n]
break
if n % prime == 0:
n /= prime
if n % prime == 0:
result = 0
break
stack.append(n)
if prime > n: break
for n in stack[::-1]:
mobius_cache[n] = result
result = -result
return -result
```

`# traditional formula`

```
def totient3(n):
return int(reduce(mul, (1 - 1.0 / p for p, exp in factorize(n)), n))
```

`# traditional formula, no division`

```
def totient4(n):
return reduce(mul, ((p-1) * p ** (exp-1) for p, exp in factorize(n)), 1)
```

Using this code to calculate the totients of all numbers from 1 to 9999 on my desktop, averaging over 5 runs,

`totient1`

takes forever
`totient2`

takes 10s
`totient3`

takes 1.3s
`totient4`

takes 1.3s