First off, I think that for code snippets in a paper, using
IORef is perfectly sensible, particularly if the paper isn't about best practices for mutable references or concurrency.
IORef is simple to understand, has straightfoward syntax and semantics (especially in a non-concurrent setting), and is a natural choice if you want the reader to concentrate on aspects of your examples other than the
IORefs. It's unfortunate that the author's approach has backfired for you -- just ignore the
IORefs and pay attention to what the rest of what the paper is saying.
(If the paper was about best practices for mutable references or concurrency, perhaps it was written before better alternatives were available.)
Anyway, to your larger question, the main objections to using
IORef would be:
- Like any other mechanism for introducing mutable state into your program, it makes your code more difficult to reason about, maintain, test, etc. -- all the usual things that functional programming proponents would say give FP an "edge" over mutation-intensive imperative algorithms.
- It's just a newtype wrapper around a specialized
STRef RealWorld, and the only thing it adds over
STRef are some atomic operations. In non-concurrent code, there's no good reason not to use
STRef s values in an
ST s monad, since they're more flexible -- you can run them in pure code with
runST or, if needed, in the IO monad with
- In concurrent code, there are more powerful abstractions, like
STM that are much easier to work with than
So, to the extent that mutable state is "bad" and -- if you really need it -- better alternatives are available depending on whether you do or don't need concurrency, there's not much to recommend
On the other hand, if you are already working on some non-concurrent code in the
IO monad because you need to perform actual IO operations, and you genuinely need some pervasive mutable state that isn't easy to disentangle from the IO, then using
IORefs seems legitimate.
With respect to your more specific questions:
I guess it would be safe to say that using
IORef is considered "bad practice" when a weaker tool would do the job. That weaker tool might be an
STRef s, or better yet a
State monad or better yet a rewritten higher-order algorithm that doesn't need any state at all. Because
IORef combines IO with mutable references, it's kind of an imperative sledgehammer that's likely to lead to the most unidiomatic Haskell code possible, so it's best avoided unless it's "obviously" the right solution for a particular problem.
State monad is usually the preferred idiomatic way to add state to a program, but it provides the "illusion" of a mutable state by threading a sequence of immutable state values through the computation, and not all algorithms can be efficiently implemented this way. Where true mutable state is required, an
STRef is usually the natural choice in a non-concurrent setting. Note that you probably wouldn't use
STM in a non-concurrent setting -- there's no reason to use them in this case, and they would force you into the
IO monad even if you didn't otherwise need it.
Yes, there are programming scenarios where either
STRef are preferable to
MVar, or pure
IO (see below). There are few scenarios where
IORef is obviously preferable to
STRef, but -- as mentioned above -- if you're already in the
IO monad and have a need for true mutable state that's entangled with IO operations, then
IORef probably has the edge over
STRef in terms of slightly cleaner syntax.
Some examples of cases where either
STRef is a good approach:
Data.Unique in the
base package uses an
IORef as a global counter for generating unique objects.
- In the
base library, the file handle internals make extensive use of
IORefs for attaching buffers to handles. This is a good example of "already being in the IO monad with entangled IO operations".
- Many vector algorithms are most efficiently implemented using mutable vectors (e.g., even something as simple as counting byte frequencies in a block of data). If you use mutable vectors from the
vector package, then technically you're using mutable byte arrays rather than
IORef, but it's still morally equivalent.
equivalence package uses
STRefs for an efficient implementation of the union-join algorithm.
- As a somewhat on-the-nose example, if you're implementing an interpreter for an imperative language, then using
STRef values for the mutable variables is generally going to be most efficient.