Whilst starting to learn lisp, I've come across the term tailrecursive. What does it mean?

Tail recursion is welldescribed in previous answers, but I think an example in action would help to illustrate the concept. Consider a simple function that adds the first N integers. (e.g. Here is a simple Python implementation that uses recursion:
If you called
Note how every recursive call has to complete before the Python interpreter begins to actually do the work of calculating the sum. Here's a tailrecursive version of the same function:
Here's the sequence of events that would occur if you called
In the tailrecursive case, with each evaluation of the recursive call, the Note: As mentioned in the comments, Python doesn't have builtin support for optimizing away tail calls, so there's no advantage to doing this in Python. However, you can use a decorator to achieve the optimization. 


In traditional recursion, the typical model is that you perform your recursive calls first, and then you take the return value of the recursive call and calculate the result. In this manner, you don't get the result of your calculation until you have returned from every recursive call. In tail recursion, you perform your calculations first, and then you execute the recursive call, passing the results of your current step to the next recursive step. This results in the last statement being in the form of "(return (recursivefunction params))" (I think that's the syntax for Lisp). Basically, the return value of any given recursive step is the same as the return value of the next recursive call. The consequence of this is that once you are ready to perform your next recursive step, you don't need the current stack frame any more. This allows for some optimization. In fact, with an appropriately written compiler, you should never have a stack overflow snicker with a tail recursive call. Simply reuse the current stack frame for the next recursive step. I'm pretty sure Lisp does this. 


An important point is that tail recursion is essentially equivalent to looping. It's not just a matter of compiler optimization, but a fundamental fact about expressiveness. This goes both ways: you can take any loop of the form
where
Of course,
is equivalent to the tailrecursive function(s)
(This "wrapping" of the tailrecursive function with a function with fewer parameters is a common functional idiom.) 


This excerpt from the book Programming in Lua shows how to make a proper tail recursion (in Lua, but should apply to Lisp too) and why it's better.
So you see, when you make a recursive call like:
This is not tail recursive because you still have things to do (add 1) in that function after the recursive call is made. If you input a very high number it will probably cause a stack overflow. 


Instead of explaining it with words, here's an example. This is a Scheme version of the factorial function:
Here is a version of factorial that is tailrecursive:
You will notice in the first version that the recursive call to fact is fed into the multiplication expression, and therefore the state has to be saved on the stack when making the recursive call. In the tailrecursive version there is no other Sexpression waiting for the value of the recursive call, and since there is no further work to do, the state doesn't have to be saved on the stack. As a rule, Scheme tailrecursive functions use constant stack space. 


Using regular recursion, each recursive call pushes another entry onto the call stack. When the recursion is completed, the app then has to pop each entry off all the way back down. With tail recursion, the compiler is able to collapse the stack down to one entry, so you save stack space...A large recursive query can actually cause a stack overflow. Basically Tail recursions are able to be optimized into iteration. 


The jargon file has this to say about the definition of tail recursion: tail recursion /n./ If you aren't sick of it already, see tail recursion. 


It means that rather than needing to push the instruction pointer on the stack, you can simply jump to the top of a recursive function and continue execution. This allows for functions to recurse indefinitely without overflowing the stack. I wrote a blog post on the subject, which has graphical examples of what the stack frames look like. 


In Java, here's a possible tail recursive implementation of the Fibonacci function:
Contrast this with the standard recursive implementation:



Here is a quick code snippet comparing two functions. The first is traditional recursion for finding the factorial of a given number. The second uses tail recursion. Very simple and intuitive to understand. Easy way to tell if a recursive function is tail recursive, is if it returns a concrete value in the base case. Meaning that it doesn't return 1 or true or anything like that. It will more then likely return some variant of one of the method paramters. Another way is to tell is if the recursive call is free of any addition, arithmetic, modification, etc... Meaning its nothing but a pure recursive call.



Tail recursion refers to the recursive call being last in the last logic instruction in the recursive algorithm. Typically in recursion you have a basecase which is what stops the recursive calls and begins popping the call stack. To use a classic example, though more Cish than Lisp, the factorial function illustrates tail recursion. The recursive call occurs after checking the basecase condition.
Note, the initial call to factorial must be factorial(n, 1) where n is the number for which the factorial is to be calculated. 


I'm not a Lisp programmer, but I think this will help. Basically it's a style of programming such that the recursive call is the last thing you do. 


Here is a Common Lisp example that does factorials using tailrecursion. Due to the stackless nature, one could perform insanely large factorial computations ...
And then for fun you could try 


here is a Perl 5 version of the



Recursion means a function calling itself. For example: (define (unended name) (unended 'me) (print "How can I get here?")) TailRecursion means the recursion that conclude the function: (define (unended name) (print "hello") (unended 'me)) See, the last thing unended function (procedure, in Scheme jargon) does is to call itself. Another (more useful) example is: (define (map lst op) (define (helper done left) (if (nil? left) done (helper (cons (op (car left)) done) (cdr left)))) (reverse (helper '() lst))) In the helper procedure, the LAST thing it does if left is not nil is to call itself (AFTER cons something and cdr something). This is basically how you map a list. The tailrecursion has a great advantage that the interperter (or compiler, dependent on the language and vendor) can optimize it, and transform it into something equivalent to a while loop. As matter of fact, in Scheme tradition, most "for" and "while" loop is done in tailrecursion manner (there is no for and while, as far as I know). 


Shameless plug of an old blog post: Recursion is the New Iteration 


To understand some of the core differences between tailcall recursion and nontailcall recursion we can explore the .NET implementations of these techniques. Here is an article with some examples in C#, F#, and C++\CLI: Adventures in Tail Recursion in C#, F#, and C++\CLI. C# does not optimize for tailcall recursion whereas F# does. The differences of principle involve loops vs. Lambda calculus. C# is designed with loops in mind whereas F# is built from the principles of Lambda calculus. For a very good (and free) book on the principles of Lambda calculus, see: Structure and Interpretation of Computer Programs, by Abelson, Sussman, and Sussman. Regarding tail calls in F#, for a very good introductory article , see: Detailed Introduction to Tail Calls in F#. Finally, here is an article that covers the difference between nontail recursion and tailcall recursion (in F#): Tailrecursion vs. nontail recursion in F sharp. If you want to read about some of the design differences of tailcall recursion between C# and F#, see: Generating TailCall Opcode in C# and F#. If you care enough to want to know what conditions prevent the C# compiler from performing tailcall optimizations, see this article: JIT CLR tailcall conditions. 


protected by Srikar Appal Aug 4 '13 at 15:27
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