# Tag Info

## Hot answers tagged functor

18

I think it's a shame that people are treating this question as dumb, especially because contrary to the strongest opinions being expressed here, the answer is yes, there can be an advantage to avoiding the do-sugar. Simon Marlow gives an excellent example of this in his talk about the Facebook Haxl project that he's working on. Here's a short, undoubtedly ...

17

Yes. In fact we can make the stronger statement that all function with the type fmap :: (a -> b) -> (F a -> F b) such that fmap id = id are equivalent. This actually just falls out of the type of fmap with something called parametricity. In your case, if >>= and return satisfy the monad laws, then mFmap f a = a >>= return . f ...

7

In this answer I give a quick explanation of why Writes isn't a functor—i.e., why if we have a Writes[A] and a function A => B we can't create a Writes[B] in the same way that we could with Reads. As I note in that answer, Writes isn't an ordinary (covariant) functor, but it is a contravariant functor, which means that if we have a Writes[A] and a ...

5

Well no. The whole point of sugaring is that it desugars to exactly the desugared version, so there can't be any non-stylistic advantage. It might be good for you to get used to the desugared notation so that you can follow it when it is stylistically clearer, but you won't get any performance benefits or anything, because the code is identical.

5

The main place where I see functor but not applicatives is in large product types. Consider something like data Mean where Unfair :: Monad a => a () -> Mean data Foo a = Bar Int Mean a This is easily a functor, but there's no way to make this an applicative because (Bar i g f) (Bar i' g' a) = Bar ??? ??? (f a) We can only fill in our ???s ...

4

First of all, there are two levels: types and values. As objects of Hask are types, you can map them only with type constructors, which have the * -> * kind: α -> F α (for Functor F), β -> M β (for Monad M). Then for a functor you need a map on morphisms (i.e. functions, which are values): it's just fmap :: (α -> β) -> (F α -> F β). ...

4

The state and reader monad both depend on the value of whatever state we're interested in. We need to be able to access it otherwise how could we write something like foo = do i <- get return \$ if i == 1 then 2 else 3 So our state monad naturally looks like something that takes in a state, does stuff, and produces a new one. Likewise with the reader ...

2

It appears that you want to pass two input vectors to thrust::transform and then do an in-place transform (i.e. no output vector is specified). There is no such incarnation of thrust::transform Since you have passed: thrust::transform(vector_first, vector_last, vector_first, operator); The closest matching prototype is a version of transform that takes ...

2

Evaluating a run-time constructed function is not going to be “quick” in any reasonable sense of the word, unless you go full out and compile it, e.g. to a dynamic library. Barring that you can just construct a dynamic expression tree. You will probably want to add a bit of syntactic sugar compared to the code below, but it shows the basics: ...

2

A similar feature exists for member variables. Maybe you confused it with that. struct foo { int bar; }; If you have a class with public member variables, you can use std::mem_fn and std::bind to create functors returning the value of the variable. auto f = std::mem_fn(&foo::bar); std::cout << f(foo{42}) << '\n'; auto g = ...

2

(I was originally just going to write an answer, but it exploded into a blog post.) From every-time checks, to Functors, to Java 8 Lambdas (well, sort of) The problem Take this example class, which adapts an Appendable into a Writer: import java.io.Closeable; import java.io.Flushable; import java.io.IOException; import java.io.Writer; ...

2

That's because a pair of ML and MLI file acts like a structure and a corresponding signature it is matched against. The usual way to avoid writing out the module type twice is to define it in a separate ML file. For example, (* sig.ml *) module type A = sig type a end module type B = sig type b val identity : b -> b end (* make.mli *) module ...

1

This is syntactic sugar, similar to that for functions (ie, let f x y = ... is shorthand for let f = fun x -> fun y -> ...). The motivation is presumably that in the long form multiple argument functors become quite hard to read: module type A = sig end module type B = sig end module type C = sig end module Foo (A:A) (B:B) (C:C) = struct end module ...

1

Here's a standard place where Invariant shows up---higher order abstract syntax (HOAS) for embedding lambda calculus. In HOAS we like to write expression types like data ExpF a = App a a | Lam (a -> a) -- ((\x . x) (\x . x)) is sort of like ex :: ExpF (ExpF a) ex = App (Lam id) (Lam id) -- we can use tricky types to make this repeat layering of ...

1

The behavior that Herb is talking about with respect to the standard library's guarantees on data race safety is specified in C++11 §17.6.5.9: 17.6.5.9 Data race avoidance [res.on.data.races] 1 This section specifies requirements that implementations shall meet to prevent data races (1.10). Every standard library function shall meet each requirement ...

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