# Rationale for number of pymc function evaluations

I am analysing data with code similar to that asked in this non linear curvefitting question:

``````# define the model/function to be fitted.
def model(x, f):
amp = pymc.Uniform('amp', 0.05, 0.4, value= 0.15)
size = pymc.Uniform('size', 0.5, 2.5, value= 1.0)
ps = pymc.Normal('ps', 0.13, 40, value=0.15)

@pymc.deterministic(plot=False)
def gauss(x=x, amp=amp, size=size, ps=ps):
e = -1*(np.pi**2*size*x/(3600.*180.))**2/(4.*np.log(2.))
return amp*np.exp(e)+ps
y = pymc.Normal('y', mu=gauss, tau=1.0/f_error**2, value=f, observed=True)
return locals()

MDL = pymc.MCMC(model(x,f))
MDL.sample(1e4)
``````

In that example I would say that there were three fitting parameters, amp, size and ps. Let us call the number of parameters being examined N. Now let us call the number of samples to be drawn, P (1e4 in this case). I have observed that the `@deterministic` function `gauss` is called roughly N x P times.

1. I would like to know the reason why it is N x P?
2. Is there an attribute inside `MDL` to find out how many times `gauss` has been called?

`gauss` is called any time its log-probability is needed. PyMC tries to be smart about this, and caches values so that they are only re-calculated when a node's parents change their values. So, `gauss` will be evaluated every time `amp`, `size` and `ps` changes.

• I'm going to look into the AdaptiveMetropolis. Whilst the likelihood isn't super expensive it is still the limiting computational factor in my real-life calculations, @~10mins for 40000 samples. Significant reductions in numbers of calls to the likelihood function will save a lot of time, especially when I triple the length of P. I'm looking forward to be able to do parallel calculations in pymc3, when it gets out of beta. – Andrew Nelson Jan 1 '15 at 6:18