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...or is it just a practice?

I'm asking this because of an argument with my professor: I lost credit for calling a function recursively on the basis that we did not cover recursion in class, and my argument is that we learned it implicitly by learning return and methods.

I'm asking here because I suspect someone has a definitive answer.

For example, what is the difference between the following two methods:

public static void a() {
    return a();
    }

public static void b() {
    return a();
    }

Other than "a continues forever" (in the actual program it is used correctly to prompt a user again when provided with invalid input), is there any fundamental difference between a and b? To an un-optimized compiler, how are they handled differently?

Ultimately it comes down to whether by learning to return a() from b that we therefor also learned to return a() from a. Did we?

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23  
Excellent debate. I wonder if you explained it like this to your professor. If you did, I think he should give you your lost credit. –  mike yaworski May 10 '14 at 18:46
57  
Recursion isn't even a concept exclusive to computer science. The Fibonacci function, the factorial operator and lots of other things from mathematics (and possibly other fields) are (or at least can be) expressed recursively. Does the professor demand that you're oblivious to these things as well? –  Theodoros Chatzigiannakis May 10 '14 at 18:46
33  
The professor should give him extra credit instead, for coming up with an elegant way to solve a problem, or for say out of the box thinking. –  kadaj May 10 '14 at 18:54
11  
What was the assignment? This is a problem I have often wondered about, when you submit a programming assignement, what is being marked, your ability to solve a problem or your ability to use what you have learnt. These two are not necessarily the same. –  Leon May 10 '14 at 18:57
34  
FWIW, prompting for input until it's right is not a good place to use recursion, it's too easy to overflow the stack. For this particular instance, it would be better to use something like a() { do { good = prompt(); } while (!good); }. –  Kevin May 11 '14 at 15:27

9 Answers 9

up vote 110 down vote accepted

To answer your specific question: No, from the standpoint of learning a language, recursion isn't a feature. If your professor really docked you marks for using a "feature" he hadn't taught yet, that was wrong.

Reading between the lines, one possibility is that by using recursion, you avoided ever using a feature that was supposed to be a learning outcome for his course. For example, maybe you didn't use iteration at all, or maybe you only used for loops instead of using both for and while. It's common that an assignment aims to test your ability to do certain things, and if you avoid doing them, your professor simply can't grant you the marks set aside for that feature. However, if that really was the cause of your lost marks, the professor should take this as a learning experience of his or her own- if demonstrating certain learning outcomes is one of the criteria for an assignment, that should be clearly explained to the students.

Having said that, I agree with most of the other comments and answers that iteration is a better choice than recursion here. There are a couple of reasons, and while other people have touched on them to some extent, I'm not sure they've fully explained the thought behind them.

Stack Overflows

The more obvious one is that you risk getting a stack overflow error. Realistically, the method you wrote is very unlikely to actually lead to one, since a user would have to give incorrect input many many times to actually trigger a stack overflow.

However, one thing to keep in mind is that not just the method itself, but other methods higher or lower in the call chain will be on the stack. Because of this, casually gobbling up available stack space is a pretty impolite thing for any method to do. Nobody wants to have to constantly worry about free stack space whenever they write code because of the risk that other code might have needlessly used a lot of it up.

This is part of a more general principle in software design called abstraction. Essentially, when you call DoThing(), all you should need to care about is that Thing is done. You shouldn't have to worry about the implementation details of how it's done. But greedy use of the stack breaks this principle, because every bit of code has to worry about how much stack it can safely assume it has left to it by code elsewhere in the call chain.

Readability

The other reason is readability. The ideal that code should aspire to is to be a human-readable document, where each line describes simply what it's doing. Take these two approaches:

private int getInput() {
    int input;
    do {
        input = promptForInput();
    } while (!inputIsValid(input))
    return input;
}

versus

private int getInput() {
    int input = promptForInput();
    if(inputIsValid(input)) {
        return input;
    }
    return getInput();
}

Yes, these both work, and yes they're both pretty easy to understand. But how might the two approaches be described in English? I think it'd be something like:

I will prompt for input until the input is valid, and then return it

versus

I will prompt for input, then if the input is valid I will return it, otherwise I get the input and return the result of that instead

Perhaps you can think of slightly less clunky wording for the latter, but I think you'll always find that the first one is going to be a more accurate description, conceptually, of what you are actually trying to do. This isn't to say recursion is always less readable. For situations where it shines, like tree traversal, you could do the same kind of side by side analysis between recursion and another approach and you'd almost certainly find recursion gives code which is more clearly self-describing, line by line.

In isolation, both of these are small points. It's very unlikely this would ever really lead to a stack overflow, and the gain in readability is minor. But any program is going to be a collection of many of these small decisions, so even if in isolation they don't matter much, it's important to learn the principles behind getting them right.

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8  
Can you expand on your assertion that recursion isn't a feature? I've argued in my answer that it is, because not all compilers necessarily support it. –  Harry Johnston May 11 '14 at 2:24
5  
Not all languages necessarily support recursion either, so it isn't necessarily just a question of choosing the right compiler - but you're quite right to say that "feature" is an inherently ambiguous description, so fair enough. Your second point is also fair from the perspective of someone learning to program (as is now usual) without having any background in machine code programming first. :-) –  Harry Johnston May 11 '14 at 2:38
2  
Note that the 'readability' problem is a problem with the syntax. There is nothing inherently "unreadable" about recursion. In fact, induction is the easiest way to express inductive data structures, like loops and lists and sequences and so on. And most data structures are inductive. –  nomen May 11 '14 at 6:52
6  
I think you've stacked the deck with your wording. You described the iterative version functionally and vice-versa. I think a fairer line-by-line description of both would be “I will prompt for input. If the input is not valid, I will keep repeating the prompt until I get valid input. Then I will return it.” vs “I will prompt for input. If the input is valid, I will return it. Otherwise I will return the result of a do-over.” (My kids understood the functional concept of a do-over when they were in pre-school, so I think it's a legitimate English summary of the recursive concept here.) –  pjs May 11 '14 at 23:09
2  
@HarryJohnston Lacking support for recursion would be an exception to existing features rather than a lack of a new feature. In particular, in the context of this question, a "new feature" means "useful behavior we haven't yet taught exists", which is not true of recursion because it's a logical extension of features that were taught (namely, that procedures contain instructions, and procedure calls are instructions). It's as if the professor taught a student addition, and then scolded him for adding the same value more than once because "we haven't covered multiplication". –  nmclean May 12 '14 at 15:16

To answer the literal question, rather than the meta-question: recursion is a feature, in the sense that not all compilers and/or languages necessarily permit it. In practice, it is expected of all (ordinary) modern compilers - and certainly all Java compilers! - but it is not universally true.

As a contrived example of why recursion might not be supported, consider a compiler that stores the return address for a function in a static location; this might be the case, for example, for a compiler for a microprocessor that does not have a stack.

For such a compiler, when you call a function like this

a();

it is implemented as

move the address of label 1 to variable return_from_a
jump to label function_a
label 1

and the definition of a(),

function a()
{
   var1 = 5;
   return;
}

is implemented as

label function_a
move 5 to variable var1
jump to the address stored in variable return_from_a

Hopefully the problem when you try to call a() recursively in such a compiler is obvious; the compiler no longer knows how to return from the outer call, because the return address has been overwritten.

For the compiler I actually used (late 70s or early 80s, I think) with no support for recursion the problem was slightly more subtle than that: the return address would be stored on the stack, just like in modern compilers, but local variables weren't. (Theoretically this should mean that recursion was possible for functions with no non-static local variables, but I don't remember whether the compiler explicitly supported that or not. It may have needed implicit local variables for some reason.)

Looking forwards, I can imagine specialized scenarios - heavily parallel systems, perhaps - where not having to provide a stack for every thread could be advantageous, and where therefore recursion is only permitted if the compiler can refactor it into a loop. (Of course the primitive compilers I discuss above were not capable of complicated tasks like refactoring code.)

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For example, the C preprocessor doesn't support recursion in macros. Macros definitions behave similarly to functions, but you can't call them recursively. –  sth May 11 '14 at 10:46
7  
Your "contrived example" isn't all that contrived: The Fortran 77 standard did not allow functions to call themselves recursively-- the reason being pretty much what you describe. (I believe the address to jump to when the function was done was stored at the end of the function code itself, or something equivalent to this arrangement.) See here for a bit about that. –  alexis May 11 '14 at 18:02
5  
Shader languages or GPGPU languages (say, GLSL, Cg, OpenCL C) don't support recursion, as an example. Insofar, the "not all languages support it" argument is certainly valid. Recursion presumes the equivalent of a stack (it needs not necessarily be a stack, but there needs to be a means to store return addresses and function frames somehow). –  Damon May 11 '14 at 20:19
    
A Fortran compiler I worked on a bit in the early 1970's did not have a call stack. Each subroutine or function had static memory areas for the return address, parameters, and its own variables. –  Patricia Shanahan May 12 '14 at 3:27
2  
Even some versions of Turbo Pascal disabled recursion by default, and you had to set a compiler directive to enable it. –  dan04 May 12 '14 at 5:55

The teacher wants to know whether you have studied or not. Apparently you didn't solve the problem the way he taught you (the good way; iteration), and thus, considers that you didn't. I'm all for creative solutions but in this case I have to agree with your teacher for a different reason:
If the user provides invalid input too many times (i.e. by keeping enter pressed), you'll have a stack overflow exception and your solution will crash. In addition, the iterative solution is more efficient and easier to maintain. I think that's the reason your teacher should have given you.

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2  
We weren't told to perform this task in any specific way; and we learned about methods, not just iteration. Also, I'd leave which one is easier to read up to personal preference: I chose what looked good to me. The SO error is new to me, though the idea that recursion is a feature in and of itself still doesn't seem founded. –  fay May 10 '14 at 19:51
3  
"I'd leave which one is easier to read up to personal preference". Agreed. Recursion is not a Java feature. These are. –  mike May 10 '14 at 20:07
2  
@Vality: Tail call elimination? Some JVMs might do it, but keep in mind it also needs to maintain a stack trace for exceptions. If it allows tail call elimination, the stack trace, generated naïvely, may become invalid, so some JVMs do not do TCE for that reason. –  icktoofay May 11 '14 at 2:56
5  
Either way, relying on optimization to make your broken code less broken, is pretty bad form. –  cHao May 11 '14 at 6:06
7  
+1, see that in Ubuntu recently the login screen was broken when the user hit the Enter button continuously, same happend to the XBox –  Sebastian Godelet May 11 '14 at 20:59

Deducting points because "we didn't cover recursion in class" is awful. If you learnt how to call function A which calls function B which calls function C which returns back to B which returns back to A which returns back to the caller, and the teacher didn't tell you explicitly that these must be different functions (which would be the case in old FORTRAN versions, for example), there is no reason that A, B and C cannot all be the same function.

On the other hand, we'd have to see the actual code to decide whether in your particular case using recursion is really the right thing to do. There are not many details, but it does sound wrong.

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There are many point of views to look at regarding the specific question you asked but what I can say is that from the standpoint of learning a language, recursion isn't a feature on its own. If your professor really docked you marks for using a "feature" he hadn't taught yet, that was wrong but like I said, there are other point of views to consider here which actually make the professor being right when deducting points.

From what I can deduce from your question, using a recursive function to ask for input in case of input failure is not a good practice since every recursive functions' call gets pushed on to the stack. Since this recursion is driven by user input it is possible to have an infinite recursive function and thus resulting in a StackOverflow.

There is no difference between these 2 examples you mentioned in your question in the sense of what they do (but do differ in other ways)- In both cases, a return address and all method info is being loaded to the stack. In a recursion case, the return address is simply the line right after the method calling (of course its not exactly what you see in the code itself, but rather in the code the compiler created). In Java, C, and Python, recursion is fairly expensive compared to iteration (in general) because it requires the allocation of a new stack frame. Not to mention you can get a stack overflow exception if the input is not valid too many times.

I believe the professor deducted points since recursion is considered a subject of its own and its unlikely that someone with no programming experience would think of recursion. (Of course it doesn't mean they won't, but it's unlikely).

IMHO, I think the professor is right by deducting you the points. You could have easily taken the validation part to a different method and use it like this:

public bool foo() 
{
  validInput = GetInput();
  while(!validInput)
  {
    MessageBox.Show("Wrong Input, please try again!");
    validInput = GetInput();
  }
  return hasWon(x, y, piece);
}

If what you did can indeed be solved in that manner then what you did was a bad practice and should be avoided.

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The purpose of the method itself is to validate the input, then call and return the result of another method (that's why it returns itself). To be specific, it checks if the move in a Tic-Tac-Toe game is valid, then returns hasWon(x, y, piece) (to only check the affected row and column). –  fay May 10 '14 at 18:46
    
you could easily just take the validation part ONLY and put it in another method called "GetInput" for example and then use it like I wrote in my answer. I have edited my answer with how it should look like. Of course you can make GetInput return a type which holds the information you need. –  Yonatan Nir May 10 '14 at 18:48
1  
Yonatan Nir: When was recursion a bad practice? Maybe JVM will blow up because the Hotspot VM couldn't optimize because of byte code security and stuff would be a nice argument. How is your code any different other than it uses a different approach? –  kadaj May 10 '14 at 18:52
1  
Recursion is not always a bad practice but if it can be avoided and keep the code clean and easy to maintain then it should be avoided. In Java, C, and Python, recursion is fairly expensive compared to iteration (in general) because it requires the allocation of a new stack frame. In some C compilers, one can use a compiler flag to eliminate this overhead, which transforms certain types of recursion (actually, certain types of tail calls) into jumps instead of function calls. –  Yonatan Nir May 10 '14 at 19:04
    
@kadaj and my code is different since it doesn't use recursion but gets the job done with clarity. –  Yonatan Nir May 10 '14 at 19:12

Maybe your professor hasn't taught it yet, but it sounds like you're ready to learn the advantages and disadvantages of recursion.

The main advantage of recursion is that recursive algorithms are often much easier and quicker to write.

The main disadvantage of recursion is that recursive algorithms can cause stack overflows, since each level of recursion requires an additional stack frame to be added to the stack.

For production code, where scaling can result in many more levels of recursion in production than in the programmer's unit tests, the disadvantage usually outweighs the advantage, and recursive code is often avoided when practical.

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1  
Any potentially risky recursive algorithm can always be trivially rewritten to use an explicit stack - the call stack is, after all, just a stack. In this case, if you rewrote the solution to use a stack, it would look ridiculous - further evidence that the recursive answer is not a very good one. –  Aaronaught May 11 '14 at 18:52
1  
If stack overflows are a problem, you should use a language/runtime which supports tail call optimisation, such as .NET 4.0 or any functional programming language –  Sebastian Godelet May 11 '14 at 20:57

From what I can deduce from your question, using a recursive function to ask for input in case of input failure is not a good practice. Why?

Because every recursive functions call gets pushed on to the stack. Since this recursion is driven by user input it is possible to have an infinite recursive function and thus resulting in a StackOverflow :-p

Having a non recursive loop to do this is the way to go.

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The bulk of the method in question, and the purpose of the method itself, is to validate input through various checks. The process begins all over again if the input is invalid until the input is correct (as instructed). –  fay May 10 '14 at 18:40
4  
@fay But if the input is invalid too many times, you will get a StackOverflowError. Recursion is more elegant, but in my eyes, usually more of a problem than a regular loop (due to stacks). –  mike yaworski May 10 '14 at 18:51
1  
That's an interesting and good point, then. I hadn't considered that error. Though, can the same effect can be achieved through while(true) calling the same method? If so, I wouldn't say this supports any difference between recursion, good to know as it is. –  fay May 10 '14 at 18:57
1  
@fay while(true) is an infinite loop. Unless you have a break statement, I don't see the point in it, unless you're trying to crash your program lol. My point is, if you call the same method (that's recursion), it will sometimes give you a StackOverflowError, but if you use a while or for loop, it will not. The problem simply doesn't exist with a regular loop. Maybe I misunderstood you, but my answer to you is no. –  mike yaworski May 10 '14 at 19:15
4  
This to me honestly seems like probably the real reason the professor took marks off =) He may not have explained it very well, but it's a valid complaint to say that you were using it in a way that would be considered very poor style if not outright flawed in more serious code. –  Commander Coriander Salamander May 11 '14 at 0:20

Regarding the specific question, is recursion a feature, I'm inclined to say yes, but after re-interpreting the question. There are common design choices of languages and compilers that make recursion possible, and Turing-complete languages do exist that don't allow recursion at all. In other words, recursion is an ability that is enabled by certain choices in language/compiler design.

  • Supporting first-class functions makes recursion possible under very minimal assumptions; see writing loops in Unlambda for an example, or this obtuse Python expression containing no self-references, loops or assignments:

    >>> map((lambda x: lambda f: x(lambda g: f(lambda v: g(g)(v))))(
    ...   lambda c: c(c))(lambda R: lambda n: 1 if n < 2 else n * R(n - 1)),
    ...   xrange(10))
    [1, 1, 2, 6, 24, 120, 720, 5040, 40320, 362880]
    
  • Languages/compilers that use late binding, or that define forward declarations, make recursion possible. For example, while Python allows the below code, that's a design choice (late binding), not a requirement for a Turing-complete system. Mutually recursive functions often depend on support for forward declarations.

    factorial = lambda n: 1 if n < 2 else n * factorial(n-1)
    
  • Statically typed languages that allow recursively defined types contribute to enabling recursion. See this implementation of the Y Combinator in Go. Without recursively-defined types, it would still be possible to use recursion in Go, but I believe the Y combinator specifically would be impossible.

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1  
This made my head explode, especially the Unlambda +1 –  John Barça May 13 '14 at 22:35
    
Fixed-point combinators are hard. When I decided to learn functional programming, I forced myself to study the Y combinator until I understood it, and then apply it to write other useful functions. Took me a while, but was well worth it. –  wberry May 15 '14 at 21:44

Recursion is a programming concept, a feature (like iteration), and a practice. As you can see from the link, there's a large domain of research dedicated to the subject. Perhaps we don't need to go that deep in the topic to understand these points.

Recursion as a feature

In plain terms, Java supports it implicitly, because it allows a method (which is basically a special function) to have "knowledge" of itself and of others methods composing the class it belongs to. Consider a language where this is not the case: you would be able to write the body of that method a, but you wouldn't be able to include a call to a within it. The only solution would be to use iteration to obtain the same result. In such a language, you would have to make a distinction between functions aware of their own existence (by using a specific syntax token), and those who don't! Actually, a whole group of languages do make that distinction (see the Lisp and ML families for instance). Interestingly, Perl does even allow anonymous functions (so called lambdas) to call themselves recursively (again, with a dedicated syntax).

no recursion?

For languages which don't even support the possibility of recursion, there is often another solution, in the form of the Fixed-point combinator, but it still requires the language to support functions as so called first class objects (i.e. objects which may be manipulated within the language itself).

Recursion as a practice

Having that feature available in a language doesn't necessary mean that it is idiomatic. In Java 8, lambda expressions have been included, so it might become easier to adopt a functional approach to programming. However, there are practical considerations:

  • the syntax is still not very recursion friendly
  • compilers may not be able to detect that practice and optimize it

The bottom line

Luckily (or more accurately, for ease of use), Java does let methods be aware of themselves by default, and thus support recursion, so this isn't really a practical problem, but it still remain a theoretical one, and I suppose that your teacher wanted to address it specifically. Besides, in the light of the recent evolution of the language, it might turn into something important in the future.

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