**Equality is EVIL.** You rarely (if ever) need *structural equality*,
because it is *too strong*. You only want an *equivalence* that is *strong enough* for
what you're doing. This is particularly true for category theory.

In Haskell, `deriving Eq`

will give you structural equality, which means that you'll
often want to write your own implementation of `==`

/ `/=`

.

A simple example: Define rational number as pairs of integers,
`data Rat = Integer :/ Integer`

. If you use structural equality (what Haskell is
`deriving`

), you'll have `(1:/2) /= (2:/4)`

, but as a fraction `1/2 == 2/4`

. What
you really care about is the value that your tuples *denote*, not their
*representation*. This means you'll need an **equivalence** that compares *reduced
fractions*, so you should implement that instead.

Side note: If someone using the code assumes that you've defined a structural
equality test, i.e. that checking with `==`

justifies replacing data sub-components
through pattern matching, their code may break. If that is of importance,
you may hide the constructors to disallow pattern matching, or maybe define your
own `class`

(say, `Equiv`

with `===`

and `=/=`

) to separate both concepts. (This
is mostly important for theorem provers like Agda or Coq, in Haskell it's really
hard to get practical/real-world code so wrong that finally something breaks.)

Really Stupid(TM) example: Let's say that person wants to print long lists of huge
`Rat`

s and believes memoizing the string representations of the `Integer`

s will save
on binary-to-decimal conversion. There's a lookup table for `Rat`

s, such that equal
`Rat`

s will never be converted twice, and there's a lookup table for integers. If
`(a:/b) == (c:/d)`

, missing integer entries will be filled by copying between `a`

-`c`

/
`b`

-`d`

to skip conversion (ouch!). For the list `[ 1:/1, 2:/2, 2:/4 ]`

, `1`

gets
converted and then, because `1:/1 == 2:/2`

, the string for `1`

gets copied into the
`2`

lookup entry. The final result `"1/1, 1/1, 1/4"`

is borked.

`(==)`

as structural equality. If you want it to mean equivalence up to some isomorphism, that's fine. It's perhaps bad form to do so if equivalent but not identical values can be easily distinguished by other means, though. The same applies for the notion of "equality" in the type class laws. – C. A. McCann Sep 16 '12 at 23:39`Exp`

with arrow`<&>`

and identity`ETrue`

forms a Category. However, this does not rhyme well with the`Category`

type class in Haskell since it requires instances to be higher kinded. Proving the Monoid laws would have been a better choice for this data type. – esevelos Sep 17 '12 at 8:00isa monoid and as such a category too (each monoid is a category), but '<&>' is not an arrow. '<&>' is the arrow composition.`Exp`

s are arrows. – n.m. Sep 17 '12 at 9:28