# Convert numpy function to theano

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 = lambdas.shape - 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
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.

Using a switch function is not recommended, as it breaks the nice geometry of the parameters space and makes sampling using modern sampler like NUTS difficult.

Instead, you can try model it using a continuous relaxation of a switch function. The main idea here would be to model the rate before the first switch point as a baseline; and add the prediction from a logistic function after each switch point:

``````def logistic(L, x0, k=500, t=np.linspace(0., 1., 1000)):
return L/(1+tt.exp(-k*(t_-x0)))

with pm.Model() as m2:
lambda0 = pm.Normal('lambda0', mu, sd=sd)
trafo = Composed(pm.distributions.transforms.LogOdds(), Ordered())
b = pm.Beta('b', 1., 1., shape=nbreak-1, transform=trafo,
testval=[0.3, 0.5])
theta_ = pm.Deterministic('theta', tt.exp(lambda0 +