let myMapFun funcx list =
[for elem in list -> funcx elem]
myMapFun ((+)1) [1;2;3]
let rec myMapFun2 f = function
| [] -> []
| h::t -> (f h)::myMapFun f t
myMapFun2 ((+)1) [1;2;3]
let myMapFun3 f xs =
let rec g f xs=
match xs with
| [] -> []
| h::t -> (f h)::g f t
g f xs
myMapFun3 ((+)1) [1;2;3]
(*
:
: a, b, c ..,
[1] roughly function is equivalent to the use of match. It the way they do it in
OCaml. There is no "match" in OCaml. So this is a more compatible way
of writing functions. With function, and the style that is used here, we can shave
off a whole two lines from our definitions(!) Therefore, readability is increased(!)
If you end up writing many functions scrolling less to be on top
of the breadth of what is happening is more desirable than the
niceties of using match. "Match" can be
a more "rounded" form. Sometimes I've found a glitch with function.
I tend to change to match, when readability is better served.
It a style thing.
[1b] when I discovered "function" in the F# compiler source code + it prevalence in OCaml,
I was a little annoyed that it took so long to discover it + that it is deemed such an
underground, confusing and divisive tool by our esteemed F# brethren.
[1c] "function" is arguably more flexible. You can also slot it into pipelines really
quickly. Whereas match requires assignment or a variable name (perhaps an argument).
If you are into pipelines |> and <| (and cousins such as ||> etc), then you should
check it out.
[1d] on style, typically, (fun x->x) is the standard way, however, if you've ever
appreciated the way you can slot in functions from Seq, List, and Module, then it
nice to skip the extra baggage. For me, function falls into this category.
[2a] "[]" is used in two ways, here. How annoying. Once it grows on you, it cool.
Firstly [] is an empty list. Visually, it a list without the stuff in it
(like [1;2;3], etc). Left of the "->" we're in the "pattern" part of the partern
matching expression. So, when the input to the function (lets call it "x" to stay
in tune with our earliest memories of maths or "math" classes) is an empty list,
follow the arrow and do the statement on the right.
Incidentally, sometimes it really nice to skip the definition of x altogether.
Behold, the built in "id" identity function (essentially fun (x)->x -- ie. do nothing).
It more useful than you realise, at first. I digress.
[2b] "[]" on the right of [] means return an empty list from this code block. Match or
function symantics being the expression "block" in this case. Block being the same
meaning as you'll have come across in other languages. The difference in F
that there *always* a return from any expression unless you return unit which is
defined as (). I digress, again.
[3a] "::" is the "cons" operator. Its history goes back a long way. F
implements two such operators (the other being append @). These operators are
list specific.
[3b] on the lhs of "->" we have a pattern match on a list. So the first element
on the lhs of :: goes into the value (h)ead, and the rest of the list, the tail,
goes into the (t)ail value.
[3c] Head/tail use is very specific in F
a nicer terminology for obviously interesting parts of a list, but, you know, it
nice to go with an opinionated simplification, sometimes.
[3d] on the rhs of the "->", the "::", surprisingly, means join a single element
to a list. In this case, the result of the function f or funcx.
[3e] when we are talking about lists, specifically, we're talking about a linked
structure with pointers behind the scenes. All we have the power to do is to
follow the cotton thread of pointers from structure to structure. So, with a
simple "match" based device, we abstract away from the messy .Value and .Next()
operations you may have to use in other languages (or which get hidden inside
an enumerator -- it'd be nice to have these operators for Seq, too, but
a Sequence could be an infinite sequence, on purpose, so these decisions for
List make sense). It all about increasing readability.
[3f] A list of "what". What it is is typically encoded into 't (or <T> in C#).
or also <T> in F#. Idiomatically, you tend to see 'someLowerCaseLetter in
F
i.e. the value x which is of type 'x.
[4a] move verbosely, ((+)1) is equivilent to (fun x->x+1). We rely on partial
composition, here. Although "+" is an operator, it is firstmost, also a
function... and functions... you get the picture.
[4b] partial composition is a topic that is more useful than it sounds, too.
[5] value Vs variable. As an often stated goal, we aim to have values that
never ever change, because, when a value doesn't change, it easier to
think and reason about. There are nice side-effects that flow from that
choice, that mean that threading and locking are a lot simpler. Now we
get into that "stateless" topic. More often than not, a value is all you
need. So, "value" it is for our cannon regarding sensible defaults.
A variable, implies, that it can be changed. Not strictly true, but in
the programming world this is the additional meaning that has been strapped
on to the notion of variable. Upon hearing the word variable, ones mind might
start jumping through the different kinds of variable "hoops". It more stuff
that you need to hold in the context of your mind. Apparently, western people
are only able to hold about 7 things in their minds at once. Introduce mutability
and value in the same context, and there goes two slots. I'm told that more uniform
languages like Chinese allow you to hold up to 10 things in your mind at once.
I can't verify the latter. I have a language with warlike Saxon and elegant
French blended together to use (which I love for other reasons).
Anyway, when I hear "value", I feel peace. That can only mean one thing.
[6] this variation really only achieves hiding of the recursive function. Perhaps
it nice to be a little terser inside the function, and more descriptive to
the outside world. Long names lead to bloat. Sometimes, it just simpler.
[7a] type inference and recursion. F
languages that I've come across for elegantly dealing with recursive algorithms.
Initially, it confusing, but once you get past that
[7b] If you are interested in solving real problems, forget about "tail"
recursion, for now. It a cool compiler trick. When you get performance conscious,
or on a rainy day, it
might be a useful thing to look up.
Look it up by all means if you are curious, though. If you are writing recursive
stuff, just be aware that the compiler geeks have you covered (sometimes), and
that horrible "recursive" performance hole (that is often associated with
recursive techniques -- ie. perhaps avoid at all costs in ancient programming
history) may just be turned into a regular loop for you, gratis. This auto-to-loop
conversion has always been a compiler geek promise. You can rely on it more though.
It more predictable in F# as to when "tail recursion" kicks in. I digress.
Step 1 correctly and elegantly solve useful problems.
Step 2 (or 3, etc) work out why the silicon is getting hot.
NB. depending on the context, performance may be an equally important thing
to think about. Many don't have that problem. Bear in mind that by writing
functionally, you are structuring solutions in such a way that they are
more easily streamlineable (in the cycling sense). So... it okay not to
get caught in the weeds. Probably best for another discussion.
[8] on the way the file system is top down and the way code is top down.
From day one we are encouraged in an opinionated (some might say coerced) into
writing code that has flow + code that is readable and easier to navigate.
There are some nice side-effects from this friendly coercion.