I've been using the `random_element()`

function provided by SAGE to generate random integer partitions for a given integer (`N`

) that are a particular length (`S`

). I'm trying to generate unbiased random samples from the set of all partitions for given values of `N`

and `S`

. SAGE's function quickly returns random partitions for N (i.e. `Partitions(N).random_element()`

).

However, it slows immensely when adding `S`

(i.e. `Partitions(N,length=S).random_element()`

). Likewise, filtering out random partitions of `N`

that are of length `S`

is incredibly slow.

However, and I hope this helps someone, I've found that in the case when the function returns a partition of `N`

not matching the length `S`

, that the conjugate partition is often of length S. That is:

```
S = 10
N = 100
part = list(Partitions(N).random_element())
if len(part) != S:
SAD = list(Partition(part).conjugate())
if len(SAD) != S:
continue
```

This increases the rate at which partitions of length `S`

are found and appears to produce unbiased samples (I've examined the results against entire sets of partitions for various values of `N`

and `S`

).

However, I'm using values of N (e.g. `10,000`

) and S (e.g. `300`

) that make even this approach impractically slow. The comment associated with SAGE's `random_element()`

function admits there is plenty of room for optimization. So, is there a way to more quickly generate unbiased (i.e. random uniform) samples of integer partitions matching given values of `N`

and `S`

, perhaps, by not generating partitions that do not match `S`

? Additionally, using conjugate partitions works well in many cases to produce unbiased samples, but I can't say that I precisely understand why.