There's no built-in function that I know of, and the binomial probabilities do not generalize (you need to normalise over a different set of possible outcomes, since the sum of all the counts must be n which won't be taken care of by independent binomials). However, it's fairly straightforward to implement yourself, for example:

```
import math
class Multinomial(object):
def __init__(self, params):
self._params = params
def pmf(self, counts):
if not(len(counts)==len(self._params)):
raise ValueError("Dimensionality of count vector is incorrect")
prob = 1.
for i,c in enumerate(counts):
prob *= self._params[i]**counts[i]
return prob * math.exp(self._log_multinomial_coeff(counts))
def log_pmf(self,counts):
if not(len(counts)==len(self._params)):
raise ValueError("Dimensionality of count vector is incorrect")
prob = 0.
for i,c in enumerate(counts):
prob += counts[i]*math.log(self._params[i])
return prob + self._log_multinomial_coeff(counts)
def _log_multinomial_coeff(self, counts):
return self._log_factorial(sum(counts)) - sum(self._log_factorial(c)
for c in counts)
def _log_factorial(self, num):
if not round(num)==num and num > 0:
raise ValueError("Can only compute the factorial of positive ints")
return sum(math.log(n) for n in range(1,num+1))
m = Multinomial([0.1, 0.1, 0.8])
print m.pmf([4,4,2])
>>2.016e-05
```

My implementation of the multinomial coefficient is somewhat naive, and works in log space to prevent overflow. Also be aware that n is superfluous as a parameter, since it's given by the sum of the counts (and the same parameter set works for any n). Furthermore, since this will quickly underflow for moderate n or large dimensionality, you're better working in log space (logPMF provided here too!)