I am trying to create an HOF in typed racket which will allow me to express the idea, "at evaluation time, roll the dice and pick the procedure to apply".

Currently, I am working with the following:

(: odds-on ((Any * -> Any) (Any * -> Any) Real -> (Any * -> Any)))
(define (odds-on choice alternative odds)
  (cond [(< (random) odds) choice]
    [else alternative]))

with the idea being I could use it like this:

> ((odds-on do-a-common-thing do-a-rarer-thing .75) 'x '(a b c) (set z))

where do-a-common-thing and do-a-rarer-thing are defined elsewhere, and may have arbitrary argument arity and types. So that about 3/4 of the time the first function would be called, and 1/4 the second would.

But I'm running into type-checking and arity issues left and right... Based on the docs, I need heterogenous rest arguments, but I don't follow the docs very well, not being a scholar of type systems... I simply want to be able to specify two functions and a probability, and have the function which is called be determined at runtime!

And, overall, maybe a macro/syntax form would be a more sensible way to create this effect? From an interface design standpoint, this capability is exactly what I need in my program, but I don't know how to implement it with static types... But I want the static types to help keep a handle on other parts of the program.

2 Answers 2


Let me propose a simpler (in some ways) type for your example:

(: odds-on (All (X Y) (X Y Real -> (U X Y))))
(define (odds-on choice alternative odds) 
  (cond [(< (random) odds) choice]
        [else alternative]))

and using it like this:

-> ((odds-on (lambda () (displayln "hi"))
             (lambda () (displayln "bye"))
-> ((odds-on (lambda ([x : String]) (string-append x "1"))
             (lambda ([x : String]) (string-append x "2"))
- : String

There's a bit of a tradeoff here though, since now you can pass odds-on things that aren't actually functions. If you do happen to pass odds-on some non-function values, you won't be able to call the returned value though (i.e., the type-checker will catch it later anyway).

(Note: as an aside, if Typed Racket supported bounded polymorphism you would be able to express a constraint that X and Y must be functions in this example. That's potentially future work for TR.)

There's also the (U X Y) in the return type that you have to be careful about. If you pass odds-on two functions with incompatible argument arities, it will be more difficult to call the resulting function.

-> ((odds-on (lambda () (displayln "hi"))
             (lambda (x) (displayln "bye"))
; readline-input:10:0: Type Checker: could not apply function;
;  wrong number of arguments provided
;   expected: 1
;   given: 0
;   in: ((odds-on (lambda () (displayln "hi")) (lambda (x) (displayln "bye"))
;     0.75))
; [,bt for context]

(Note: your error message may look different. I'm running Racket v6.0.0.4. Also, this error message is not so great.)


I'm still new to Typed Racket so I don't think this is a great answer.

The type (Any * -> Any) is for a homogenous rest argument. So the function need to actually take a rest argument, e.g. (define (f . xs) ...) or (lambda xs ...). If I change your example accordingly, it type checks for me:

#lang typed/racket

(: odds-on ((Any * -> Any) (Any * -> Any) Real -> (Any * -> Any)))
(define (odds-on choice alternative odds)
  (cond [(< (random) odds) choice]
        [else alternative]))

((odds-on (lambda xs (second xs)) ;; <--
          (lambda xs (third xs))  ;; <--
 'x 'y 'z)

Of course, you may not really want the functions to take a rest argument like xs instead of normal arguments like x y z. You might be using rest arguments only in an attempt to find something that will type check. In that case I don't know what to tell you (yet).

UPDATE: In light of your comment, I took another crack at this, using the Procedure type, but it didn't turn out very well.

#lang typed/racket

(: odds-on (Procedure Procedure Real -> Procedure))
(define (odds-on choice alternative odds)
  (cond [(< (random) odds) choice]
        [else alternative]))

(define x (odds-on (lambda () #t)
                   (lambda () #f)

; - : Procedure
; #<procedure:/tmp/tr.rkt:9:10>

; stdin::12271: Type Checker: Cannot apply expression of type Procedure, since it is not a function type
;   in: (x)

On the one hand, x is a Procedure. On the other hand, x can't be applied because it's not a Procedure. And on the third hand, I am confuse.

UPDATE: The reason this doesn't work is that Procedure is a sort of "opaque" type that means, "This thing satisfies procedure? but we won't know anything more -- and therefore don't know how to call it safely". That is the sense in which the error message's Zen koan, "Procedure is not a function type", actually does make sense.

Asumu's answer is better.

  • That's helpful, but I think not quite the issue. Maybe I need to re-write this question, because really, I want the odds-on function to work for arbitrary functions, of any arity and type. It would be cool if that could be type-checked, but at least for that part of the program I don't really care...
    – Ben
    Mar 22, 2014 at 0:01

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge that you have read and understand our privacy policy and code of conduct.

Not the answer you're looking for? Browse other questions tagged or ask your own question.