I am using `PyMC3`

to calculate something which I won't get into here but you can get the idea from this link if interested.

The '2-lambdas' case is basically a switch function, which needs to be compiled to a `Theano`

function to avoid `dtype`

errors and looks like this:

```
import theano
from theano.tensor import lscalar, dscalar, lvector, dvector, argsort
@theano.compile.ops.as_op(itypes=[lscalar, dscalar, dscalar], otypes=[dvector])
def lambda_2_distributions(tau, lambda_1, lambda_2):
"""
Return values of `lambda_` for each observation based on the
transition value `tau`.
"""
out = zeros(num_observations)
out[: tau] = lambda_1 # lambda before tau is lambda1
out[tau:] = lambda_2 # lambda after (and including) tau is lambda2
return out
```

I am trying to generalize this to apply to 'n-lambdas', where `taus.shape[0] = lambdas.shape[0] - 1`

, but I can only come up with this horribly slow `numpy`

implementation.

```
@theano.compile.ops.as_op(itypes=[lvector, dvector], otypes=[dvector])
def lambda_n_distributions(taus, lambdas):
out = zeros(num_observations)
np_tau_indices = argsort(taus).eval()
num_taus = taus.shape[0]
for t in range(num_taus):
if t == 0:
out[: taus[np_tau_indices[t]]] = lambdas[t]
elif t == num_taus - 1:
out[taus[np_tau_indices[t]]:] = lambdas[t + 1]
else:
out[taus[np_tau_indices[t]]: taus[np_tau_indices[t + 1]]] = lambdas[t]
return out
```

Any ideas on how to speed this up using pure `Theano`

(avoiding the call to `.eval()`

)? It's been a few years since I've used it and so don't know the right approach.