Well, that won't fit inside a comment, but here is the thing:
First, you write a correct static analyzer. "Correct", in this context, means that it won't remain silent if there is anything dubious about the analyzed code, so at this stage you merrily conflate undefined and unspecified behaviors. They are both bad and unacceptable in critical code, and you warn, rightly, for both of them.
But you only want to warn once for one possible bug, and also you know that your analyzer will be judged in benchmarks in terms of "precision" and "recall" when compared to other, possibly not correct, analyzers, so you mustn't warn twice about one same problem... Be it a true or false alarm (you don't know which. you never know which, otherwise it would be too easy).
So you want to emit a single warning for
*p = x;
y = *p;
Because as soon as
p is a valid pointer at the first statement, it can be assumed to be a valid pointer at the second statement. And not inferring this will lower your score on the precision metric.
So you teach your analyzer to assume that
p is a valid pointer as soon as you have warned about it the first time in the above code, so that you don't warn about it the second time. More generally, you learn to ignore values (and execution paths) that correspond to something you have already warned about.
Then, you realize that not many people are writing critical code, so you make other, lightweight analyses for the rest of them, based on the results of the initial, correct analysis. Say, a C program slicer.
And you tell "them": You don't have to check about all the (possibly, often false) alarms emitted by the first analysis. The sliced program behaves the same as the original program as long as none of them is triggered. The slicer produces programs that are equivalent for the slicing criterion for "defined" execution paths.
And users merrily ignore the alarms and use the slicer.
And then you realize that perhaps there is a misunderstanding. For instance, most implementations of
memmove (you know, the one that handles overlapping blocks) actually invoke unspecified behavior when called with pointers that do not point to the same block (comparing addresses that do not point to the same block). And your analyzer ignore both execution paths, because both are unspecified, but in reality both execution paths are equivalent and all is well.
So there shouldn't be any misunderstanding on the meaning of alarms, and if one intends to ignore them, only unmistakable undefined behaviors should be excluded.
And this is how you end up with a strong interest in distinguishing between unspecified behavior and undefined behavior. No-one can blame you for ignoring the latter. But programmers will write the former without even thinking about it, and when you say that your slicer excludes "wrong behaviors" of the program, they will not feel as they are concerned.
And this is the end of a story that definitely did not fit in a comment. Apologies to anyone who read that far.