Haskell has a magical function named `seq`, which takes an argument of any type and reduces it to Weak Head Normal Form (WHNF).

I've read a couple of sources [not that I can remember who they were now...] which claim that "polymorphic `seq` is bad". In what way are they "bad"?

Similarly, there is the `rnf` function, which reduces an argument to Normal Form (NF). But this is a class method; it does not work for arbitrary types. It seems "obvious" to me that one could alter the language spec to provide this as a built-in primitive, similar to `seq`. This, presumably, would be "even more bad" than just having `seq`. In what way is this so?

Finally, somebody suggested that giving `seq`, `rnf`, `par` and similars the same type as the `id` function, rather than the `const` function as it is now, would be an improvement. How so?

• The `seq` function is not lambda definable (i.r., cannot be defined in the lambda-calculus), which means that that all the results from lambda calculus can no longer be trusted when we have `seq`. Oct 2 '12 at 22:52
• Patricia Johann and Janis Voigtlander provide details in their paper The Impact of seq on Free Theorems-Based Program Transformations. Oct 6 '20 at 10:20

As far as I know a polymorphic `seq` function is bad because it weakens free theorems or, in other words, some equalities that are valid without `seq` are no longer valid with `seq`. For example, the equality

``````map g (f xs) = f (map g xs)
``````

holds for all functions `g :: tau -> tau'`, all lists `xs :: [tau]` and all polymorphic functions `f :: [a] -> [a]`. Basically, this equality states that `f` can only reorder the elements of its argument list or drop or duplicate elements but cannot invent new elements.

To be honest, it can invent elements as it could "insert" a non-terminating computation/run-time error into the lists, as the type of an error is polymorphic. That is, this equality already breaks in a programming language like Haskell without `seq`. The following function definitions provide a counter example to the equation. Basically, on the left hand side `g` "hides" the error.

``````g _ = True
f _ = [undefined]
``````

In order to fix the equation, `g` has to be strict, that is, it has to map an error to an error. In this case, the equality holds again.

If you add a polymorphic `seq` operator, the equation breaks again, for example, the following instantiation is a counter example.

``````g True = True
f (x:y:_) = [seq x y]
``````

If we consider the list `xs = [False, True]`, we have

``````map g (f [False, True]) = map g [True] = [True]
``````

but, on the other hand

``````f (map g [False, True]) = f [undefined, True] = [undefined]
``````

That is, you can use `seq` to make the element of a certain position of the list depend on the definedness of another element in the list. The equality holds again if `g` is total. If you are intereseted in free theorems check out the free theorem generator, which allows you to specify whether you are considering a language with errors or even a language with `seq`. Although, this might seem to be of less practical relevance, `seq` breaks some transformations that are used to improve the performence of functional programs, for example, `foldr`/`build` fusion fails in the presence of `seq`. If you are intereseted in more details about free theorems in the presence of `seq`, take a look into Free Theorems in the Presence of seq.

As far as I know it had been known that a polymorphic `seq` breaks certain transformations, when it was added to the language. However, the althernatives have disadvantages as well. If you add a type class based `seq`, you might have to add lots of type class constraints to your program, if you add a `seq` somewhere deep down. Furthermore, it had not been a choice to omit `seq` as it had already been known that there are space leaks that can be fixed using `seq`.

Finally, I might miss something, but I don't see how a `seq` operator of type `a -> a` would work. The clue of `seq` is that it evaluates an expression to head normal form, if another expression is evaluated to head normal form. If `seq` has type `a -> a` there is no way of making the evaluation of one expression depend on the evaluation of another expression.

• `map g (f xs) = f (map g xs)` Uhh... Even in a total language with no `undefined` or `seq` that does not hold. `f = map (1 :)` `g = (2 :)` `xs = [, ]` involves nothing fancy at all but it absolutely does break that equality. Am I missing something really obvious or is basically this entire answer deeply flawed? Aug 17 '16 at 14:43
• @semicolon The theorem is taking about polymorphic `f`, which couldn't invent new elements because it doesn't know what type it's operating on. Your `f` needs at least a `Num` constraint, it can't be `[a] -> [a]`.
– Ben
Aug 17 '16 at 21:47
• @Ben Ah ok, my bad, that makes sense. Aug 18 '16 at 3:29

Another counterexample is given in this answer - monads fail to satisfy monad laws with `seq` and `undefined`. And since `undefined` cannot be avoided in a Turing-complete language, the one to blame is `seq`.