My question addresses both mathematical and CS issues, but since I need a performant implementation I am posting it here.

**Problem:**

I have an estimated normal bivariate distribution, defined as a python matrix, but then I will need to transpose the same computation in Java. (dummy values here)

```
mean = numpy.matrix([[0],[0]])
cov = numpy.matrix([[1,0],[0,1]])
```

When I receive in inupt a column vector of **integers** values (x,y) I want to compute the probability of that given tuple.

```
value = numpy.matrix([[4],[3]])
probability_of_value_given_the_distribution = ???
```

Now, from a matematical point of view, this would be the integral for `3.5 < x < 4.5`

and `2.5 < y < 3.5`

over the probability density function of my normal.

**What I want to know:**

Is there a way to avoid the effective implementation of this, that implies dealing with expressions defined over matrices and with double integrals? Besides that it will take me a while if I had to implement it by myself, this would be computationally expensive. An approximate solution would be perfectly fine for me.

**My reasonings:**

In an univariate normal, one could simply use the cumulative distribution function (or even store its values for the standard one and then normalize), but unfortunately there appears not to be a closed cdf form for multivariates.

Another approach for univariate is to use the inverse of bivariate approximation (so, approximate a normal as a binomial), but extending this to the multivariate I can't figure out how to keep in count the covariances.

I really hope someone has already implemented this, I need it soon (finishing my thesis) and I couldn't find anything.