I don't understand what you mean by "pick a measure" but maybe the "it’s a straw man here" (that I don't really understand either) indicates that looking at the other two options is enough.

B> Pick a fully specified model. This is a model that, up front, you could ask what is the probability of event E? For a normal distribution, this would require choosing concrete mean and standard deviation.

Ok. That seems to describe a simple classical null hypothesis like the example I gave in my previous comment. The underlying thing of interest is zero and the sampling distribution for the data is normally distributed around zero.

C> Pick an under-specified model. This would be that it’s normal, but you don’t pick the mean and standard deviation. You pull them from the sample. As I’ve described it here, you can’t get P(E) from that.

That is not the kind of null hypothesis I gave in my example, I think we can agree on that.

> The expectation from our alternative hypothesis and model is that it’s fully formed before we look at the data.

I don't understand that sentence. What is "it" that is fully formed before we look at the data? The alternative hypothesis and model?

> It’s a choice whether you want that to be the case or not with the null model.

What is "that"? Being formed before we look at the data? (In that case I hope that the null model I described would satisfy that.)

> “Fair” as I’m describing it is that you would pick something.

Pick something of what? I'm completely lost, I'm afraid.

I'm just saying that I can have a null model of the form B like in the example "the underlying thing is zero and the data generated by this model has a probability distribution p(x)=exp(-x^2/2)".

And I can compare that model it with any other model described by a distribution probability for the underlying thing which, taking into account the measurement error, results in a probability distribution p'(x) for the data generated.