**What takes so much time?**

To account for relations between variables NumPy computes the singular value decomposition of your covariance matrix and this takes the majority of the time (the underlying GESDD is in general Θ(n^{3}), and 5000^{3} is already a bit).

**How can things be sped up?**

In the simplest case with all variables independent, you could just use `random.normal`

:

```
from numpy.random import normal
sample = normal(means, deviations, len(means))
```

Otherwise, if your covariance matrix happens to be full rank (hence positive-definite), supplant `svd`

with `cholesky`

(still Θ(n^{3}) in general, but with a smaller constant):

```
from numpy.random import standard_normal
from scipy.linalg import cholesky
l = cholesky(covariances, check_finite=False, overwrite_a=True)
sample = means + l.dot(standard_normal(len(means)))
```

If the matrix may be singular (as is sometimes the case), then either wrap SPSTRF or consider helping with scipy#6202.

Cholesky will likely be noticeably faster, but if that's not sufficient, then further you could research if if it wouldn't be possible to decompose the matrix analytically, or try using a different base library (such as ACML, MKL, or cuSOLVER).

`beta_true = np.random.multivariate_normal(mean_true, cov_true, size=1).T`

`--- 15.3049829006 seconds ---`

`from np.random import multivariate_normal`

, yes, I mean using 100% CPU, on my 13' MacBook pro,`real 0m53.319s, user 1m40.845s, sys 0m2.128s`

, and on a modern workstation, it is slightly better, but it uses all 48 cores, I can't understand why. @Yugi`p=5000`

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