Validation: Caller vs. Called
The TLDR version is both.
The long version involves who, why, when, how, and what.
Both should be ready to answer the question "can this data be operated on reliably?" Do we know enough about this data to do something meaningful with it? Many will suggest that the reliability of the data should never be trusted, but that only leads to a chicken and egg problem. Chasing it endlessly from both ends will not provide for meaningful value, but to some degree it essential.
Both must validate the shape of the data to ensure base usability. If either one does not recognize or understand the shape of the data, there is no way to know how to further handle it with any reliability. Depending on the environment, the data may need to be a particular 'type', which is often an easy way to validate shape. We often consider types that present evidence of common linage back to a particular ancestor and retain the crucial traits to possess the right shape. Other characteristics might be important if the data is anything other than an in memory structure, for instance if it is a stream or some other resource external the running context.
Many languages include data shape checking as a built-in language feature through type or interface checking. However, when favoring composition over inheritance, providing a good mechanism to verify trait existence is incumbent on the implementer. One strategy to achieve this is through dynamic programming, or particularly via type introspection, inference, or reflection.
The called must validate the domain (the set of inputs) of the given context to which it will operate on. The design of the called always suggests it can handle only so many cases of input. Usually these values are broken up into certain subclasses or categories of input. We verify the domain in the called because the called is intimate with the localized constraints. It knows better than anyone else what is good input, and what is not.
Normal values: These values of the domain map to a range. For every
foo there is one and only one
Out of range/out of scope values: These values are part of the general domain, but will not map to a range in the context of the called. No defined behavior exists for these values, and thus no valid output is possible. Frequently out-of-range checking entails range, limit, or allowed characters (or digits, or composite values). A cardinality check (multiplicity) and subsequently a presence check (null or empty), are special forms of a range checking.
Values that lead to Illogical or undefined behavior: These values are special values, or edge cases, that are otherwise normal, but because of the algorithm design and known environment constraints, would produce unexpected results. For instance, a function that operates on numbers should guard against division by zero or accumulators that would overflow, or unintended loss of precision. Sometimes the operating environment or compiler can warn that these situations may happen, but relying on the runtime or compiler is not good practice as it may not always be capable of deducing what is possible and what is not. This stage should be largely verification, through secondary validation, that the caller provided good, usable, meaningful input.
The caller is special. The caller has two situations in which it should validate data.
The first situation is on assignment or explicit state changes, where a change happens to at least one element of the data by some explicit mechanism, internally, or externally by something in its container. This is somewhat out of scope of the question, but something to keep in mind. The important thing is to consider the context when a state change occurs, and one or more elements that describe the state are affected.
- Self/Referential Integrity: Consider using an internal mechanism to validate state if other actors can reference the data. When the data has no consistency checks, it is only safe to assume it is in an indeterminate state. That is not intermediate, but indeterminate. Know thyself. When you do not use a mechanism to validate internal consistency on state change, then the data is not reliable and that leads to problems in the second situation. Make sure the data for the caller is in a known, good state; alternatively, in a known transition/recovery state. Do not make the call until you are ready.
The second situation is when the data calls a function. A caller can expect only so much from the called. The caller must know and respect that the called recognizes only a certain domain. The caller also must be self-interested, as it may continue and persist long after the called completes. This means the caller must help the called be not only successful, but also appropriate for the task: bad data in produces bad data out. On the same token, even good data in and out with respect to the called may not be appropriate for the next thing in terms of the caller. The good data out may actually be bad data in for the caller. The output of the called may invalidate the caller for the caller's current state.
Ok, so enough commentary, what should a caller validate specifically?
Logical and normal: given the data, is the called a good strategy that fits the purpose and intent? If we know it will fail with certain values, there is no point in performing the call without the appropriate guards most times. If we know the called cannot handle zero, do not ask it to as it will never succeed. What is more expensive and harder to manage: a [redundant (do we know?)] guard clause, or an exception [that occurs late in a possibly long running, externally available resource dependent process]? Implementations can change, and change suddenly. Providing the protection in the caller reduces the impact and risk in changing that implementation.
Return values: check for unsuccessful completion. This is something that a caller may or may not need to do. Before using or relying upon the returned data, check for alternative outcomes, if the system design incorporates success and failure values that may accompany the actual return value.
Footnote: In case it wasn't clear. Null is a domain issue. It may or may not be logical and normal, so it depends. If null is a natural input to a function, and the function could be reasonably expected to produce meaningful output, then leave it to the caller to use it. If the domain of the caller is such that null is not logical, then guard against it in both places.
An important question: if you are passing null to the called, and the called is producing something, isn't that a hidden creational pattern, creating something from nothing?