At work we used to program our Python in a pretty standard OO way. Lately, a couple guys got on the functional bandwagon. And their code now contains lots more lambdas, maps and reduces. I understand that functional languages are good for concurrency but does programming Python functionally really help with concurrency? I am just trying to understand what I get if I start using more of Python's functional features.
Edit: I've been taken to task in the comments (in part, it seems, by fanatics of FP in Python, but not exclusively) for not providing more explanations/examples, so, expanding the answer to supply some.
Consider what's probably the single most idiotic idiom you sometimes see used in "Python" (Python with "scare quotes", because it's obviously not idiomatic Python -- it's a bad transliteration from idiomatic Scheme or the like, just like the more frequent overuse of OOP in Python is a bad transliteration from Java or the like):
by assigning the lambda to a name, this approach immediately throws away the above-mentioned "advantage" -- and doesn't lose any of the DISadvantages! For example,
Moving on to
so the simple, elementary, trivial loop is about twice as fast (as well as more concise) than the "best way" to perform the task?-) I guess the advantages of speed and conciseness must therefore make the trivial loop the "bestest" way, right?-)
By further sacrificing compactness and readability...:
...we can get almost back to the easily obtained performance of the simplest and most obvious, compact, and readable approach (the simple, elementary, trivial loop). This points out another problem with
Perhaps even worse than the above-berated "assign a lambda to a name" anti-idiom is actually the following anti-idiom, e.g. to sort a list of strings by their lengths:
instead of the obvious, readable, compact, speedier
Here, the use of
The motivation for using
Perfectly proper functional approaches in Python often include list comprehensions, generator expressions,
Writing your own higher-order functions is often useful, especially when they're suitable for use as decorators (both function decorators, as explained in that part of the docs, and class decorators, introduced in Python 2.6). Do remember to use functools.wraps on your function decorators (to keep the metadata of the function getting wrapped)!
So, summarizing...: anything you can code with
FP is important not only for concurrency; in fact, there's virtually no concurrency in the canonical Python implementation (maybe 3.x changes that?). in any case, FP lends itself well to concurrency because it leads to programs with no or fewer (explicit) states. states are troublesome for a few reasons. one is that they make distributing the computation hard(er) (that's the concurrency argument), another, far more important in most cases, is the tendency to inflict bugs. the biggest source of bugs in contemporary software is variables (there's a close relationship between variables and states). FP may reduce the number of variables in a program: bugs squashed!
see how many bugs can you introduce by mixing the variables up in these versions:
as you can see, it's a matter of fact that FP gives you fewer opportunities to shoot yourself in the foot with a variables-related bug.
also, readability: it may take a bit of training, but
then there's succintness and flexibility. you give me
what can you do to reduce the duplication? well, if operators were values, you could do something like
is the FP version any better? surely you'd need to copy-paste as well?
well, that's just an artifact of the half-assed approach! abandoning the imperative
what about runtime speed? yes, using FP in a language like Python will incur some overhead. here i'll just parrot what a few professors have to say about this:
I'm not very good at explaining things. Don't let me muddy the water too much, read the first half of the speech John Backus gave on the occasion of receiving the Turing Award in 1977. Quote:
I program in Python everyday, and I have to say that too much 'bandwagoning' toward OO or functional could lead toward missing elegant solutions. I believe that both paradigms have their advantages to certain problems - and I think that's when you know what approach to use. Use a functional approach when it leaves you with a clean, readable, and efficient solution. Same goes for OO.
And that's one of the reasons I love Python - the fact that it is multi-paradigm and lets the developer choose how to solve his/her problem.
This answer is completely re-worked. It incorporates a lot of observations from the other answers.
As you can see, there is a lot of strong feelings surrounding the use of functional programming constructs in Python. There are three major groups of ideas here.
First, almost everybody but the people who are most wedded to the purest expression of the functional paradigm agree that list and generator comprehensions are better and clearer than using
Secondly, there is a lot of ambivalence in the community as a whole about
Lastly, most (meaning > 50%, but most likely not 90%) people think that
As for myself, I fall in the camp of people who think the functional style is often very useful. But balancing that thought is the fact that Python is not at heart a functional language. And overuse of functional constructs can make programs seem strangely contorted and difficult for people to understand.
To understand when and where the functional style is very helpful and improves readability, consider this function in C++:
This loop seems very simple and easy to understand. And in this case it is. But its seeming simplicity is a trap for the unwary. Consider this alternate means of writing the loop:
Suddenly, the loop control variable no longer varies in an obvious way. You are reduced to looking through the code and reasoning carefully about what happens with the loop control variable. Now this example is a bit pathological, but there are real-world examples that are not. And the problem is with the fact that the idea is repeated assignment to an existing variable. You can't trust the variable's value is the same throughout the entire body of the loop.
This is a long recognized problem, and in Python writing a loop like this is fairly unnatural. You have to use a while loop, and it just looks wrong. Instead, in Python you would write something like this:
As you can see, the way you talk about the loop control variable in Python is not amenable to fooling with it inside the loop. This eliminates a lot of the problems with 'clever' loops in other imperative languages. Unfortunately, it's an idea that's semi-borrowed from functional languages.
Even this lends itself to strange fiddling. For example, this loop:
Oops, we again have a loop that is difficult to understand. It superficially resembles a really simple and obvious loop, and you have to read it carefully to realize that one of the variables used in the loop's computation is being messed with in a way that will effect future runs of the loop.
Again, a more functional approach to the rescue:
Now by looking at the code we have some strong indication (partly by the fact that the person is using this functional style) that the lists a and b are not modified during the execution of the loop. One less thing to think about.
The last thing to be worried about is c being modified in strange ways. Perhaps it is a global variable and is being modified by some roundabout function call. To rescue us from this mental worry, here is a purely function approach:
Very concise, and the structure tells us that x is purely an accumulator. It is a local variable everywhere it appear. The final result is unambiguously assigned to c. Now there is much less to worry about. The structure of the code removes several classes of possible error.
That is why people might choose a functional style. It is concise and clear, at least if you understand what
In the case of factorial, there is a very simple and clear way to write this function in Python in a functional style:
The question, which seems to be mostly ignored here:
No. The value FP brings to concurrency is in eliminating state in computation, which is ultimately responsible for the hard-to-grasp nastiness of unintended errors in concurrent computation. But it depends on the concurrent programming idioms not themselves being stateful, something that doesn't apply to Twisted. If there are concurrency idioms for Python that leverage stateless programming, I don't know of them.
Here's a short summary of positive answers when/why to program functionally.
than to use an imperative construct (loop).
You should NOT overuse those features - there are many traps, see Alex Martelli's post. I'd subjectively say the most serious danger is that excessive use of those features will destroy readability of your code, which is a core attribute of Python.
The standard functions filter(), map() and reduce() are used for various operations on a list and all of the three functions expect two arguments: A function and a list
We could define a separate function and use it as an argument to filter() etc., and its probably a good idea if that function is used several times, or if the function is too complex to be written in a single line. However, if it's needed only once and it's quite simple, it's more convenient to use a lambda construct to generate a (temporary) anonymous function and pass it to filter().
This helps in
Using these function, would also turn out to be
And object oriented way is forcibly needed when states are to be maintained, apart from abstraction, grouping, etc., If the requirement is pretty simple, I would stick with functional than to Object Oriented programming.
Map and Filter have their place in OO programming. Right next to list comprehensions and generator functions.
Reduce less so. The algorithm for reduce can rapidly suck down more time than it deserves; with a tiny bit of thinking, a manually-written reduce-loop will be more efficient than a reduce which applies a poorly-thought-out looping function to a sequence.
Lambda never. Lambda is useless. One can make the argument that it actually does something, so it's not completely useless. First: Lambda is not syntactic "sugar"; it makes things bigger and uglier. Second: the one time in 10,000 lines of code that think you need an "anonymous" function turns into two times in 20,000 lines of code, which removes the value of anonymity, making it into a maintenance liability.
The functional style of no-object-state-change programming is still OO in nature. You just do more object creation and fewer object updates. Once you start using generator functions, much OO programming drifts in a functional direction.
Each state change appears to translate into a generator function that builds a new object in the new state from old object(s). It's an interesting world view because reasoning about the algorithm is much, much simpler.
But that's no call to use reduce or lambda.