The exact meaning of should in natural language is also not clear cut. When you say "the wheel should fit in the row" - what does that mean exactly? It may mean the same as must, but then there is no point in a construct for it. Else, at what confidence do you need to be for this to be satisfied? What is the action in case the wheel does not fit?
In the senses you referred to, there are some equivalents, though I do not know of language that use the word should for them:
ASSERT is often a language directive, macro, or testing library function. In the sense that
ASSERT corresponds to must, some languages and testing frameworks define macros for "warning assertions" which will spit a warning message if the check fails but not bail out or fail the test - that would correspond to should.
In some terms, you can consider exception thrown as analogues - if an exception is caught, the program can handle the case where something is not as it should be. But sometimes the exception describes the failure of something to be as it must be for the program to work, in which case the exception will not be caught or the handler will make the program fail gracefully. This is however not always the case - sometimes code is executed to test something that may be or perhaps is even unlikely to be, and an exception is caught expecting that it will usually be thrown.
One common meaning of must and should in various formal natural language documents is in terms of constraints - must specifying a constraint that you always have to satisfy, and if you cannot then your state is incompatible, while should means that you will always satisfy the constraint if it is possible given the state and the constraints implied by must, but if it is not possible that is still valid. In informal constraint logic, this occurs when there are "external constraints" in the context - so verifying that the "solution" is satisfactory with respect to the "should constraints" may be possible only with knowledge of the context, and given the context you may also be able to satisfy different subsets of the "should constraints" but not at the same time. For that reason, some constraint logic specification languages (whether you call them "programming languages" depends on your definition) have the concepts of ordering of constraints - the first level of constraints corresponds to must, the next level corresponds to should, and a constraint has to be satisfied if possible given all constraints external to it (in previous levels), even if that conflicts with some constraints in the next levels which will then not be satisfied.