In haskell a lot of things are done via pattern matching, which requires a little bit of relearning at the start
so a list comprehension that just clones a list would looks like so: [x | x<-myList]
but if the elements of myList are tuples, and you want the tuples where e.g. the first entry is 42 you could just write [(42, x) | (42, x) <- myList] (of course this particular example is a bit uselss, but I hope it illustrates what you can do:)
or many functions you define will process a list, and you usually do this by using multiple definitions with pattern matching: first you define what happens with the empty list, then you define what happens if there is at least one element in the list:
sum [] = 0
sum (x:xs) = x + sum xs
(x:xs) is another way of writing a list where x is the first element and xs is the remainder of the list.
In python you can do some pattern matching too, but only with tuples and lists, and only with referring to the structure, not the actual values
def sum(l):
if not l:
return 0
else:
x, *xs = l
return x + sum(xs)
That PEP is actually quite useful. I thought Python had as philosophy that there should be only one obvious way to do something. Obviously they need to keep adding to the language to allow for more ways to do the same thing! :D
Haskell really looks like a totally different paradigm than what I'm used to. Maybe I should learn a bit, like I did with APL. Just to broaden my perspectives on programming.
I'm not a huge fan because elif should be good enough for anybody :P But, unlike asspressions, this is harder to abuse.
and instead of having to do elif isinstance(p, Point) and p.y == 42: you can do case Point(x, 42): which I have to admit is nice (not nice and common enough to add new syntax, but nice)
In C and C++ all assignments are expressions, and it's hugely useful.
In Python they could probably have changed the assignment operator to return its value, would have been more useful and more understandable. Python's a = b = c is wonky anyway.
I love doing while(data = read(...)) { /* use data */ }
PEP 43251: Allow for curly braces for flow control, instead of stupid indents. So we can write code with misleading indentation.
@CrisLuengo I didn't see the answer(has not refreshed the page I guess) and found the answer on my own, so wouldn't waste anybody's time :) — sdsad asdasd33 mins ago
@flawr Don't know. I presume there's always a dialog box "are you sure?". I don't think I've ever deleted a question of my own.
@flawr Then they should have seen the answer. SO always updates the page, or at least says "there's a new answer, click here to refresh". And they should also have gotten a notification.
@CrisLuengo I couldn't find anything that assumes some programming experience right now. But the universally recommended book is learnyouahaskell.com which I used too. But for the first chapters I'd just look at the code snippets and ignore the text unless there is somethign you don't get.
And for fiddling around you can use TIO, but more helpful is having GHCI on your computer. This is an interpreter that easily lets you load a file in there (:l file.hs, or reload it using :r) and play with the definitions. It is exceptionally handy to inspect types (:t yourVarOrExpression, or alternatively :i) to get what's going on, because everything in haskell is types and functions.
Also don't start by trying to write full programs that print stuff or interact with stuff, you first need a grasp on the typeclasses to do that (especially the "IO-Monad"), so first I'd just stick to writing stuff that you interact with on the interpreter.
@AndrasDeak I really liked the programming part, but then they wanted us to compile and execute stuff...
@CrisLuengo That's only a problem for people who actually want to execute their programs and do something useful.:P
But it is a really nice abstraction that still makes sense. You can imagine that writing your program is basically building a huge pure function, and whatever is spit out when applying the function to inputs will be the outputs.
Oh, you said that something is spit out when the function is applied to inputs. So it's not the function spitting out something, but the system? What is the mental model here?
So the idea of e.g. the IO monad is that whenever you get some input from the "outside world" or print some output to the outside world, the outside world is basically an additional object that gets passed into your function, and the output of the function is a new outside world
so a print() function in python just takes a string and does nothing
in haskell you could think of it as taking a string AND the state of the outisde world, and it returns the new modified state of the outside world
or similarly if you use an RNG you always need some state to generate the next random number
so get_random_number() would similarly take the rng_state as an argument, and return the number plust the new state
@CrisLuengo exactly, you can't change stuff you can just define new stuff:)
@CrisLuengo well there is not much choice:)
but it shows how the imperative paradigm was dictated from how the machines operate
but the functional paradigm was modelled from a way (one of many) how you can think about things
this is broadly generalized but I think it is nice to consider languages that didn't slowly grow by checking what the machines can do and then simplifying or abstracting things away, but that come from the completely opposite end in that we first think about how we'd like to reason, and then try to get the machines to do the stuff for us
Yes, I agree. This is why I'm interested in learning a bit more about these languages. APL has a similar background: it originally was a notation to reason about algorithms, it was only turned into a programming language later.
@flawr Haskell is disappointing... I'm following the tutorial, it explains how to find right triangles with a given perimeter. But this never completes:
let triangles = [ (a,b,c) | c <- [1..], b <- [1..c], a <- [1..b], a^2 + b^2 == c^2, a+b+c == 24 ]
It can't tell that if c>24, then a+b+c==24 can never be met, so it can stop iterating. So sad... :(
As you noticed this can't possibly terminate the way it is written here. You'd have to use 24 as an uppe rlimit for c.
is that in this tutorial???
Ah in the example it shows [ (a,b,c) | c <- [1..10], b <- [1..c], a <- [1..b], a^2 + b^2 == c^2, a+b+c == 24]
for some curious reason the upper limit for c is set to 10
@CrisLuengo It's not Prolog:)
but if you know a solution exists and you just want to find one, then it woudl be quite idiomatic to write
oneTriangle = head [ (a,b,c) | c <- [1..], b <- [1..c], a <- [1..b], a^2 + b^2 == c^2, a+b+c == 24 ]
even though we have a list that might possibly be infinite (or doesn't even terminate) due to the lazy evaluation it will just stop after finding the first solution
or instead of head you can use take 5 to just get 5 possible solutions
anyway, the following chapters are hopefully a little bit more fun:)