Abstract in this sense is the opposite of concrete. This is probably one of the key things to understand about Haskell.

What is a concrete thing? Well, most values in Haskell are concrete. For example `'a' :: Char`

. The letter 'a' is a Char value, and it's a concrete value. `Char`

is a concrete type. But in `1 :: Num a => a`

, the number `1`

is actually a value of **any** type, so long as that type has the set of functions that the `Num`

typeclass sets out as mandatory. This is an abstract value! We can have abstract values, abstract types, and therefore abstract functions. When the program is compiled, the Haskell compiler will pick a particular concrete value that supports all of our requirements.

Haskell, at its core, has a very simple, small but incredibly flexible language. It's very similar to an expression of maths, actually. This makes it very powerful. Why? because most things that would be built in language constructs in other languages are not directly built into Haskell, but defined in terms of this simple core.

One of the core pieces is the function, which, it turns out, most of computation is expressible in terms of. Because so much of Haskell is just defined in terms of this small simple core, it means we can extend it to almost anywhere we can imagine.

Typeclasses are probably the best example of this. `Monoid`

, and `Num`

are examples of typeclasses. These are constructs that allow programmers to use an abstraction like a function across a great many types but only having to define it once. Typeclasses let us use the same function names across a whole range of types if we can define those functions for those types. Why is that important or useful? Well, if we can recognise a pattern across, for example, all numbers, and we have a mechanism for talking about all numbers in the language itself, then we can write functions that work with **all numbers** at once. This is an abstract pattern. You'll notice some Haskellers are quite interested in a branch of mathematics called Category Theory. This branch is pretty much the mathematical definition of abstract patterns. Contrast this ability to encode such things with the *inability* of other languages, where in other languages the patterns the community notice are often far less rigorous and have to be manually written out, and without any respect for its mathematical nature. The beauty of following the mathematics is the extremely large body of stuff we get for free by aligning our language closer with mathematics.

This is a good explanation of these basics including typeclasses in a book that I helped author: http://www.happylearnhaskelltutorial.com/1/output_other_things.html

Because functions are written in a very general way (because Haskell puts hardly any limits on our ability to express things generally), we can write functions that use types which express such things as "any type, so long as it's a `Monoid`

". These are called type constraints, as above.

Generally abstractions are very useful because we can, for example, write on single function to operate on an entire range of types which means we can often find functions that do exactly what we want on our types if we just make them instances of specific typeclasses. The `Ord`

typeclass is a great example of this. Making a type we define ourselves an instance of `Ord`

gives us a whole bunch of sorting and comparing functions for free.

This is, in my opinion, one of the most exciting parts about Haskell, because while most other languages also allow you to be very general, they mostly take an extreme dip in how expressive you can be with that generality, so therefore also are less powerful. (This is because they are less precise in what they talk about, because their types are less well "defined").

This is how we're able to reason about the "possible values" of a function, and it's not limited to Haskell. The more information we encode at the type level, the more toward the specificity end of the spectrum of expressivity we veer. For example, to take a classic case, the function `const :: a -> b -> a`

. This function requires that `a`

and `b`

can be of absolutely any type at all, including the same type if we like. From that, because the second parameter **can** be a different type than the first, we can work out that it really only has one possible functionality. It can't return an `Int`

, unless we **give** it an `Int`

as its first value, because that's not **any** type, right? So therefore we know the only value it can return is the first value! The functionality is defined right there in the type! If that's not mindblowing, then I don't know what is. :)

As we move to dependent types (that is, a type system where types are first class, which means also that ordinary values can be encoded in the type system), we can get closer and closer to having the type system specify specifically what the constraints of possible functionality are. However, the kicker is, it doesn't necessarily speak about the implementation of the functionality unless we want it to, because **we're** in control of how abstract it is, but while maintaining expressivity and much precision. That's pretty fascinating, and amazingly powerful.

Much math can be expressed in the language that underpins Haskell, the lambda calculus.

`future`

/`promise`

concepts? These are instances of more abstract`Monad`

concept. Or take`map`

function in JS or`Array.Select()`

method in C#. These are examples of abstract pattern called`Functor`

.`[] ++ [7]`

,`"" ++ "foo"`

,`0 + 3`

,`1 * 3`

. Do you recognize the recurring, reliable trait? This is a pattern and it has a nice representation in math. Patterns are inherently abstract and to call themabstract patternsmight be unnecessary.