In support of Petr Pudlák's answer, here is an argument concerning the origin of the broader notion of "effect" espoused there.
The phrase "effectful programming" shows up in the abstract of McBride and Patterson's Applicative Programming with Effects, the paper which introduced applicative functors:
In this paper, we introduce
Applicative functors — an abstract characterisation of an applicative style of effectful programming, weaker than
Monads and hence more widespread.
"Effect" and "effectful" appear in a handful of other passages of the paper; these ocurrences are deemed unremarkable enough not to require an explicit clarification. For instance, this remark is made just after the definition of
Applicative is presented (p. 3):
In each example, there is a type constructor
f that embeds the usual
notion of value, but supports its own peculiar way of giving meaning to the usual applicative language [...] We correspondingly introduce the
[A Haskell definition of
This class generalises S and K [i.e. the S and K combinators, which show up in the
Applicative instance] from threading an environment to threading an effect in general.
From these quotes, we can infer that, in this context:
Effects are the things that
Applicative threads "in general".
Effects are associated with the type constructors that are given
Monad also deals with effects.
Following these leads, we can trace back this usage of "effect" back to at least Wadler's papers on monads. For instance, here is a quote from page 6 of Monads for functional programming:
In general, a function of type a → b is replaced by a function of type a
→ M b. This can be read as a function that accepts an argument of type a
and returns a result of type b, with a possible additional effect captured by
M. This effect may be to act on state, generate output, raise an exception, or what have you.
And from the same paper, page 21:
If monads encapsulate effects and lists form a monad, do lists correspond to some effect? Indeed they do, and the effect they correspond to is choice. One can think of a computation of type [a] as offering a choice of values, one for each element of the list. The monadic equivalent of a function of type a → b is a function of type a → [b].
The "correspond to some effect" turn of phrase here is key. It ties back to the more straightforward claim in the abstract:
Monads provide a convenient framework for simulating effects found in other languages, such as global state, exception handling, output, or non-determinism.
The pitch is that monads can be used to express things that, in "other languages", are typically encoded as side-effects -- that is, as Petr Pudlák puts it in his answer here, "an observable interaction with [a function's] environment (apart from computing its result value)". Through metonymy, that has readily led to "effect" acquiring a second meaning, broader than that of "side-effect" -- namely, whatever is introduced through a type constructor which is a
Monad instance. Over time, this meaning was further generalised to cover other functor classes such as
Applicative, as seen in McBride and Patterson's work.
In summary, I consider "effect" to have two reasonable meanings in Haskell parlance:
On occasion, avoidable disagreements over terminology happen when each of the involved parties implicitly assumes a different meaning of "effect". Another possible point of contention involves whether it is legitimate to speak of effects when dealing with
Functor alone, as opposed to subclasses such as
Monad (I believe it is okay to do so, in agreement with Petr Pudlák's answer to Why can applicative functors have side effects, but functors can't?).