Not set in stone, but current best practice is to make all fields in data structures strict, but take function arguments and return results lazily (except accumulators).
The net effect is that as long as you don't touch a piece of return value, nothing is evaluated. As soon as you strictly need a tiny bit from it, the whole structure is evaluated at once, leading to more predictable memory/cpu usage patterns than if they were lazily evaluated throughout execution.
The performance guidelines by Johan Tibell are the best to point out subtleties: http://johantibell.com/files/haskell-performance-patterns.html#(1) . Note that recent GHCs perform small strict field unpacking automatically without the need to annotate. Also see the Strict pragmas.
About when to introduce the strict fields: do it right from the beginning, since it's much harder to bolt it retrospectively. You can still use lazy fields, but only when you explicitly want them.
 is lazy, and is more used as a control structure that is expected to inline, than as a container. Use
vector etc for the latter.
Note 2: there are specialized libs to let you deal with strict folding (see foldl), or with streaming computations (conduit, pipes).
A bit of elaboration on the rationale, so that 1) you know this is not just for the rubber duck from the sky 2) know when/why to deviate.
Why to evaluate strict?
One case is strict accumulation, as outlined in the question. This comes in less obvious forms too - such as keeping count of certain events happening in the state of the app. If you don't store a strict count, you can get a long chain of
+1 thunks build up, which consumes a lot of memory for no good reason (vs storing just the updated count).
Above is called a
memory leak informally, even if it's not technically a leak (no memory is lost, it is just held longer than needed).
An other case is concurrent computation, where the work is divided across multiple threads. Now, it is easy to run into situations where you think you forked out a computation to a separate thread (making your program very efficiently concurrent), only to realize later that the concurrent thread only computes the outermost layer of a lazy data structure, and the bulk of the computation still happens on your main thread when the value is forced.
A solution path for this is using
NFData from deepseq. But imagine having a final data structure layered
A (B (C)), where each layer is computed by a separate thread, deep forcing the structure before returning. Now
C is deep forced (in effect traversed in memory) three times,
B two times. If
C is a deep/large structure, this is a waste. At this point you can either add the Once trick, or just use a deeply strict data structure, where doing shallow forcing to WHNF (instead of to deep NF) has the same effect of deep forcing, but the Once-trick is taken care by the compiler, so to speak.
Now, if you are consistent and aware, you might be doing ok with deepseq+Once.
Note: a usecase very similar to concurrent evaluation is single-threaded evaluation in the scary case of pure errors, such as
error. These are ideally not used, but if are, the ways to attack the problem are very similar to the above outlined (see by the way the spoon package).