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

121For curious: both while and whilst have been in the language for a very long time. While was in use in Old English; whilst is a Middle English development of while. As conjunctions they are interchangeable in meaning, but whilst has not survived in standard American English. – Filip Bartuzi Oct 18 '14 at 23:02

7Maybe it is late, but this is a pretty good article about tail recursive:programmerinterview.com/index.php/recursion/tailrecursion – Sam003 Aug 8 '15 at 18:14

58First, you need to understand recursion. A good comment explaining it is here: stackoverflow.com/questions/33923/… – joe_young Jan 16 '16 at 21:08

1One of the great benefits of identifying a tailrecursive function is that it can be converted into an iterative form and thus reliving the algorithm from methodstackoverhead. Might like to visit response from @Kyle Cronin and few others below – KGhatak May 25 '17 at 16:57

This link from @yesudeep is the best, most detailed description I've found  lua.org/pil/6.3.html – Jeff Fischer Jan 2 at 16:43
Consider a simple function that adds the first N integers. (e.g. sum(5) = 1 + 2 + 3 + 4 + 5 = 15
).
Here is a simple JavaScript implementation that uses recursion:
function recsum(x) {
if (x===1) {
return x;
} else {
return x + recsum(x1);
}
}
If you called recsum(5)
, this is what the JavaScript interpreter would evaluate:
recsum(5)
5 + recsum(4)
5 + (4 + recsum(3))
5 + (4 + (3 + recsum(2)))
5 + (4 + (3 + (2 + recsum(1))))
5 + (4 + (3 + (2 + 1)))
15
Note how every recursive call has to complete before the JavaScript interpreter begins to actually do the work of calculating the sum.
Here's a tailrecursive version of the same function:
function tailrecsum(x, running_total=0) {
if (x===0) {
return running_total;
} else {
return tailrecsum(x1, running_total+x);
}
}
Here's the sequence of events that would occur if you called tailrecsum(5)
, (which would effectively be tailrecsum(5, 0)
, because of the default second argument).
tailrecsum(5, 0)
tailrecsum(4, 5)
tailrecsum(3, 9)
tailrecsum(2, 12)
tailrecsum(1, 14)
tailrecsum(0, 15)
15
In the tailrecursive case, with each evaluation of the recursive call, the running_total
is updated.
Note: The original answer used examples from Python. These have been changed to JavaScript, since modern JavaScript interpreters support tail call optimization but Python interpreters don't.

4Can I say that with tail recursion the final answer is calculated by the LAST invocation of the method alone? If it is NOT tail recursion you need all the results for all method to calculate the answer. – chrisapotek Dec 8 '12 at 20:34

2Here's an addendum that presents a few examples in Lua: lua.org/pil/6.3.html May be useful to go through that as well! :) – yesudeep Feb 28 '13 at 7:24

2Can someone please address chrisapotek's question? I'm confused how
tail recursion
can be achieved in a language that doesn't optimize away tail calls. – Kevin Meredith May 15 '13 at 19:29 
2So in python there is no advantage because with every call to tailrecsum function, a new stack frame is created  right? – Quazi Irfan Jun 17 '17 at 0:28

2@iamcreasy Correct. You are better off writing an iterative solution. Good news! Tail Call recursive functions are trivially translated into recursive functions. example function as a loop:
def sum(x):
sum=0
while x: (sum, x) = (sum+x, x=1)
return sum
 see? – Baldrickk Jul 19 '17 at 15:35
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))
. 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.

14"I'm pretty sure Lisp does this"  Scheme does, but Common Lisp doesn't always. – Aaron Jan 2 '09 at 23:51

2@Daniel "Basically, the return value of any given recursive step is the same as the return value of the next recursive call." I fail to see this argument holding true for the code snippet posted by Lorin Hochstein. Can you please elaborate? – Geek Mar 20 '13 at 19:16

8@Geek This is a really late response, but that is actually true in Lorin Hochstein's example. The calculation for each step is done before the recursive call, rather than after it. As a result, each stop just returns the value directly from the previous step. The last recursive call finishes the computation and then returns the final result unmodified all the way back down the call stack. – reirab Apr 23 '14 at 22:58

1

2"In this manner, you don't get the result of your calculation until you have returned from every recursive call."  maybe I misunderstood this, but this isn't particularly true for lazy languages where the traditional recursion is the only way to actually get a result without calling all recursions (e.g. folding over an infinite list of Bools with &&). – hasufell Jun 30 '15 at 21:12
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
while(E) { S }; return Q
where E
and Q
are expressions and S
is a sequence of statements, and turn it into a tail recursive function
f() = if E then { S; return f() } else { return Q }
Of course, E
, S
, and Q
have to be defined to compute some interesting value over some variables. For example, the looping function
sum(n) {
int i = 1, k = 0;
while( i <= n ) {
k += i;
++i;
}
return k;
}
is equivalent to the tailrecursive function(s)
sum_aux(n,i,k) {
if( i <= n ) {
return sum_aux(n,i+1,k+i);
} else {
return k;
}
}
sum(n) {
return sum_aux(n,1,0);
}
(This "wrapping" of the tailrecursive function with a function with fewer parameters is a common functional idiom.)

In the answer by @LorinHochstein I understood, based on his explanation, that tail recursion to be when the recursive portion follows "Return", however in yours, the tail recursive is not. Are you sure your example is properly considered tail recursion? – CodyBugstein Mar 10 '13 at 22:44

1@Imray The tailrecursive part is the "return sum_aux" statement inside sum_aux. – Chris Conway Mar 11 '13 at 4:51

@lmray: Chris's code is essentially equivalent. The order of the if/then and style of the limiting test...if x == 0 versus if(i<=n)...is not something to get hung up on. The point is that each iteration passes its result to the next. – Taylor Sep 27 '13 at 18:24

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.
A tail call [tail recursion] is a kind of goto dressed as a call. A tail call happens when a function calls another as its last action, so it has nothing else to do. For instance, in the following code, the call to
g
is a tail call:function f (x) return g(x) end
After
f
callsg
, it has nothing else to do. In such situations, the program does not need to return to the calling function when the called function ends. Therefore, after the tail call, the program does not need to keep any information about the calling function in the stack. ...Because a proper tail call uses no stack space, there is no limit on the number of "nested" tail calls that a program can make. For instance, we can call the following function with any number as argument; it will never overflow the stack:
function foo (n) if n > 0 then return foo(n  1) end end
... As I said earlier, a tail call is a kind of goto. As such, a quite useful application of proper tail calls in Lua is for programming state machines. Such applications can represent each state by a function; to change state is to go to (or to call) a specific function. As an example, let us consider a simple maze game. The maze has several rooms, each with up to four doors: north, south, east, and west. At each step, the user enters a movement direction. If there is a door in that direction, the user goes to the corresponding room; otherwise, the program prints a warning. The goal is to go from an initial room to a final room.
This game is a typical state machine, where the current room is the state. We can implement such maze with one function for each room. We use tail calls to move from one room to another. A small maze with four rooms could look like this:
function room1 () local move = io.read() if move == "south" then return room3() elseif move == "east" then return room2() else print("invalid move") return room1()  stay in the same room end end function room2 () local move = io.read() if move == "south" then return room4() elseif move == "west" then return room1() else print("invalid move") return room2() end end function room3 () local move = io.read() if move == "north" then return room1() elseif move == "east" then return room4() else print("invalid move") return room3() end end function room4 () print("congratulations!") end
So you see, when you make a recursive call like:
function x(n)
if n==0 then return 0
n= n2
return x(n) + 1
end
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.

7This is a great answer because it explains the implications of tail calls upon stack size. – Andrew Swan Aug 22 '14 at 7:32

@AndrewSwan Indeed, although I believe that the original asker and the occasional reader who might stumble into this question might be better served with the accepted answer (since he might not know what the stack actually is.) By the way I use Jira, big fan. – Hoffmann Aug 22 '14 at 13:47

1My favourite answer as well due to including the implication for the stack size. – njk2015 Jul 17 '17 at 13:26
Instead of explaining it with words, here's an example. This is a Scheme version of the factorial function:
(define (factorial x)
(if (= x 0) 1
(* x (factorial ( x 1)))))
Here is a version of factorial that is tailrecursive:
(define factorial
(letrec ((fact (lambda (x accum)
(if (= x 0) accum
(fact ( x 1) (* accum x))))))
(lambda (x)
(fact x 1))))
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.

3+1 for mentioning the most important aspect of tailrecursions that they can be converted into an iterative form and thereby turning it into an O(1) memory complexity form. – KGhatak May 25 '17 at 16:54

@KGhatak not exactly; the answer correctly speaks about "constant stack space", not memory in general. not to be nitpicking, just to make sure there's no misunderstanding. e.g. tailrecursive listtailmutating
listreverse
procedure will run in constant stack space but will create and grow a data structure on the heap. A tree traversal could use a simulated stack, in an additional argument. etc. – Will Ness Oct 6 '17 at 23:32
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, depending on language the compiler may be 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.
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.
factorial(x, fac) {
if (x == 1)
return fac;
else
return factorial(x1, x*fac);
}
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 found your explanation easiest to understand, but if it's anything to go by, then tail recursion is only useful for functions with one statement base cases. Consider a method such as this postimg.cc/5Yg3Cdjn. Note: the outer
else
is the step you might call a "base case" but spans across several lines. Am I misunderstanding you or is my assumption correct? Tail recursion is only good for one liners? – I Want Answers Oct 23 '18 at 19:27
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.
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.
An easy way to tell if a recursive function is a 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 than likely return some variant of one of the method parameters.
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.
public static int factorial(int mynumber) {
if (mynumber == 1) {
return 1;
} else {
return mynumber * factorial(mynumber);
}
}
public static int tail_factorial(int mynumber, int sofar) {
if (mynumber == 1) {
return sofar;
} else {
return tail_factorial(mynumber, sofar * mynumber);
}
}

3
The best way for me to understand tail call recursion
is a special case of recursion where the last call(or the tail call) is the function itself.
Comparing the examples provided in Python:
def recsum(x):
if x == 1:
return x
else:
return x + recsum(x  1)
^RECURSION
def tailrecsum(x, running_total=0):
if x == 0:
return running_total
else:
return tailrecsum(x  1, running_total + x)
^TAIL RECURSION
As you can see in the general recursive version, the final call in the code block is x + recsum(x  1)
. So after calling the recsum
method, there is another operation which is x + ..
.
However, in the tail recursive version, the final call(or the tail call) in the code block is tailrecsum(x  1, running_total + x)
which means the last call is made to the method itself and no operation after that.
This point is important because tail recursion as seen here is not making the memory grow because when the underlying VM sees a function calling itself in a tail position (the last expression to be evaluated in a function), it eliminates the current stack frame, which is known as Tail Call Optimization(TCO).
EDIT
NB. Do bear in mind that the example above is written in Python whose runtime does not support TCO. This is just an example to explain the point. TCO is supported in languages like Scheme, Haskell etc
In Java, here's a possible tail recursive implementation of the Fibonacci function:
public int tailRecursive(final int n) {
if (n <= 2)
return 1;
return tailRecursiveAux(n, 1, 1);
}
private int tailRecursiveAux(int n, int iter, int acc) {
if (iter == n)
return acc;
return tailRecursiveAux(n, ++iter, acc + iter);
}
Contrast this with the standard recursive implementation:
public int recursive(final int n) {
if (n <= 2)
return 1;
return recursive(n  1) + recursive(n  2);
}

1This is returning wrong results for me, for input 8 I get 36, it has to be 21. Am I missing something? I'm using java and copy pasted it. – Alberto Zaccagni Nov 28 '11 at 21:21

1This returns SUM(i) for i in [1, n]. Nothing to do with Fibbonacci. For a Fibbo, you need a tests which substracts
iter
toacc
wheniter < (n1)
. – Askolein Mar 15 '13 at 13:44
Here is a Common Lisp example that does factorials using tailrecursion. Due to the stackless nature, one could perform insanely large factorial computations ...
(defun ! (n &optional (product 1))
(if (zerop n) product
(! (1 n) (* product n))))
And then for fun you could try (format nil "~R" (! 25))
In short, a tail recursion has the recursive call as the last statement in the function so that it doesn't have to wait for the recursive call.
So this is a tail recursion i.e. N(x  1, p * x) is the last statement in the function where the compiler is clever to figure out that it can be optimised to a forloop (factorial). The second parameter p carries the intermediate product value.
function N(x, p) {
return x == 1 ? p : N(x  1, p * x);
}
This is the nontailrecursive way of writing the above factorial function (although some C++ compilers may be able to optimise it anyway).
function N(x) {
return x == 1 ? 1 : x * N(x  1);
}
but this is not:
function F(x) {
if (x == 1) return 0;
if (x == 2) return 1;
return F(x  1) + F(x  2);
}
I did write a long post titled "Understanding Tail Recursion – Visual Studio C++ – Assembly View"

1

N(x1) is the last statement in the function where the compiler is clever to figure out that it can be optimised to a forloop (factorial) – justyy Dec 31 '16 at 10:28

My concern is that your function N is exactly the function recsum from the accepted answer of this topic (except that it is a sum and not a product), and that recsum is said to be non tailrecursive ? – Fabian Pijcke Dec 31 '16 at 12:04
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 Perl 5 version of the tailrecsum
function mentioned earlier.
sub tail_rec_sum($;$){
my( $x,$running_total ) = (@_,0);
return $running_total unless $x;
@_ = ($x1,$running_total+$x);
goto &tail_rec_sum; # throw away current stack frame
}
This is an excerpt from Structure and Interpretation of Computer Programs about tail recursion.
In contrasting iteration and recursion, we must be careful not to confuse the notion of a recursive process with the notion of a recursive procedure. When we describe a procedure as recursive, we are referring to the syntactic fact that the procedure definition refers (either directly or indirectly) to the procedure itself. But when we describe a process as following a pattern that is, say, linearly recursive, we are speaking about how the process evolves, not about the syntax of how a procedure is written. It may seem disturbing that we refer to a recursive procedure such as factiter as generating an iterative process. However, the process really is iterative: Its state is captured completely by its three state variables, and an interpreter need keep track of only three variables in order to execute the process.
One reason that the distinction between process and procedure may be confusing is that most implementations of common languages (including Ada, Pascal, and C) are designed in such a way that the interpretation of any recursive procedure consumes an amount of memory that grows with the number of procedure calls, even when the process described is, in principle, iterative. As a consequence, these languages can describe iterative processes only by resorting to specialpurpose “looping constructs” such as do, repeat, until, for, and while. The implementation of Scheme does not share this defect. It will execute an iterative process in constant space, even if the iterative process is described by a recursive procedure. An implementation with this property is called tailrecursive. With a tailrecursive implementation, iteration can be expressed using the ordinary procedure call mechanism, so that special iteration constructs are useful only as syntactic sugar.

1I read through all answers here, and yet this is the most clear explanation which touches the really deep core of this concept. It explains it in such a straight way which makes everything looks so simple and so clear. Forgive my rudeness please. It somehow makes me feel like the other answers just do not hit the nail on the head. I think that is why SICP matters. – englealuze Jan 24 '18 at 20:58
Tail recursion is the life you are living right now. You constantly recycle the same stack frame, over and over, because there's no reason or means to return to a "previous" frame. The past is over and done with so it can be discarded. You get one frame, forever moving into the future, until your process inevitably dies.
_{The analogy breaks down when you consider some processes might utilize additional frames but are still considered tailrecursive if the stack does not grow infinitely.}

1it doesn't break under split personality disorder interpretation. :) A Society of Mind; a Mind as a Society. :) – Will Ness Oct 4 '18 at 14:08
A tail recursion is a recursive function where the function calls itself at the end ("tail") of the function in which no computation is done after the return of recursive call. Many compilers optimize to change a recursive call to a tail recursive or an iterative call.
Consider the problem of computing factorial of a number.
A straightforward approach would be:
factorial(n):
if n==0 then 1
else n*factorial(n1)
Suppose you call factorial(4). The recursion tree would be:
factorial(4)
/ \
4 factorial(3)
/ \
3 factorial(2)
/ \
2 factorial(1)
/ \
1 factorial(0)
\
1
The maximum recursion depth in the above case is O(n).
However, consider the following example:
factAux(m,n):
if n==0 then m;
else factAux(m*n,n1);
factTail(n):
return factAux(1,n);
Recursion tree for factTail(4) would be:
factTail(4)

factAux(1,4)

factAux(4,3)

factAux(12,2)

factAux(24,1)

factAux(24,0)

24
Here also, maximum recursion depth is O(n) but none of the calls adds any extra variable to the stack. Hence the compiler can do away with a stack.
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.
There are two basic kinds of recursions: head recursion and tail recursion.
In head recursion, a function makes its recursive call and then performs some more calculations, maybe using the result of the recursive call, for example.
In a tail recursive function, all calculations happen first and the recursive call is the last thing that happens.
Taken from this super awesome post. Please consider reading it.
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 the 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 interpreter (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 a tailrecursion manner (there is no for and while, as far as I know).
This question has a lot of great answers... but I cannot help but chime in with an alternative take on how to define "tail recursion", or at least "proper tail recursion." Namely: should one look at it as a property of a particular expression in a program? Or should one look at it as a property of an implementation of a programming language?
For more on the latter view, there is a classic paper by Will Clinger, "Proper Tail Recursion and Space Efficiency" (PLDI 1998), that defined "proper tail recursion" as a property of a programming language implementation. The definition is constructed to allow one to ignore implementation details (such as whether the call stack is actually represented via the runtime stack or via a heapallocated linked list of frames).
To accomplish this, it uses asymptotic analysis: not of program execution time as one usually sees, but rather of program space usage. This way, the space usage of a heapallocated linked list vs a runtime call stack ends up being asymptotically equivalent; so one gets to ignore that programming language implementation detail (a detail which certainly matters quite a bit in practice, but can muddy the waters quite a bit when one attempts to determine whether a given implementation is satisfying the requirement to be "property tail recursive")
The paper is worth careful study for a number of reasons:
It gives an inductive definition of the tail expressions and tail calls of a program. (Such a definition, and why such calls are important, seems to be the subject of most of the other answers given here.)
Here are those definitions, just to provide a flavor of the text:
Definition 1 The tail expressions of a program written in Core Scheme are defined inductively as follows.
 The body of a lambda expression is a tail expression
 If
(if E0 E1 E2)
is a tail expression, then bothE1
andE2
are tail expressions.  Nothing else is a tail expression.
Definition 2 A tail call is a tail expression that is a procedure call.
(a tail recursive call, or as the paper says, "selftail call" is a special case of a tail call where the procedure is invoked itself.)
It provides formal definitions for six different "machines" for evaluating Core Scheme, where each machine has the same observable behavior except for the asymptotic space complexity class that each is in.
For example, after giving definitions for machines with respectively, 1. stackbased memory management, 2. garbage collection but no tail calls, 3. garbage collection and tail calls, the paper continues onward with even more advanced storage management strategies, such as 4. "evlis tail recursion", where the environment does not need to be preserved across the evaluation of the last subexpression argument in a tail call, 5. reducing the environment of a closure to just the free variables of that closure, and 6. socalled "safeforspace" semantics as defined by Appel and Shao.
In order to prove that the machines actually belong to six distinct space complexity classes, the paper, for each pair of machines under comparison, provides concrete examples of programs that will expose asymptotic space blowup on one machine but not the other.
(Reading over my answer now, I'm not sure if I'm managed to actually capture the crucial points of the Clinger paper. But, alas, I cannot devote more time to developing this answer right now.)
Many people have already explained recursion here. I would like to cite a couple of thoughts about some advantages that recursion gives from the book “Concurrency in .NET, Modern patterns of concurrent and parallel programming” by Riccardo Terrell:
“Functional recursion is the natural way to iterate in FP because it avoids mutation of state. During each iteration, a new value is passed into the loop constructor instead to be updated (mutated). In addition, a recursive function can be composed, making your program more modular, as well as introducing opportunities to exploit parallelization."
Here also are some interesting notes from the same book about tail recursion:
Tailcall recursion is a technique that converts a regular recursive function into an optimized version that can handle large inputs without any risks and side effects.
NOTE The primary reason for a tail call as an optimization is to improve data locality, memory usage, and cache usage. By doing a tail call, the callee uses the same stack space as the caller. This reduces memory pressure. It marginally improves the cache because the same memory is reused for subsequent callers and can stay in the cache, rather than evicting an older cache line to make room for a new cache line.
The recursive function is a function which calls by itself
It allows programmers to write efficient programs using a minimal amount of code.
The downside is that they can cause infinite loops and other unexpected results if not written properly.
I will explain both Simple Recursive function and Tail Recursive function
In order to write a Simple recursive function
 The first point to consider is when should you decide on coming out of the loop which is the if loop
 The second is what process to do if we are our own function
From the given example:
public static int fact(int n){
if(n <=1)
return 1;
else
return n * fact(n1);
}
From the above example
if(n <=1)
return 1;
Is the deciding factor when to exit the loop
else
return n * fact(n1);
Is the actual processing to be done
Let me the break the task one by one for easy understanding.
Let us see what happens internally if I run fact(4)
 Substituting n=4
public static int fact(4){
if(4 <=1)
return 1;
else
return 4 * fact(41);
}
If
loop fails so it goes to else
loop
so it returns 4 * fact(3)
In stack memory, we have
4 * fact(3)
Substituting n=3
public static int fact(3){
if(3 <=1)
return 1;
else
return 3 * fact(31);
}
If
loop fails so it goes to else
loop
so it returns 3 * fact(2)
Remember we called ```4 * fact(3)``
The output for fact(3) = 3 * fact(2)
So far the stack has 4 * fact(3) = 4 * 3 * fact(2)
In stack memory, we have
4 * 3 * fact(2)
Substituting n=2
public static int fact(2){
if(2 <=1)
return 1;
else
return 2 * fact(21);
}
If
loop fails so it goes to else
loop
so it returns 2 * fact(1)
Remember we called 4 * 3 * fact(2)
The output for fact(2) = 2 * fact(1)
So far the stack has 4 * 3 * fact(2) = 4 * 3 * 2 * fact(1)
In stack memory, we have
4 * 3 * 2 * fact(1)
Substituting n=1
public static int fact(1){
if(1 <=1)
return 1;
else
return 1 * fact(11);
}
If
loop is true
so it returns 1
Remember we called 4 * 3 * 2 * fact(1)
The output for fact(1) = 1
So far the stack has 4 * 3 * 2 * fact(1) = 4 * 3 * 2 * 1
Finally, the result of fact(4) = 4 * 3 * 2 * 1 = 24
The Tail Recursion would be
public static int fact(x, running_total=1) {
if (x==1) {
return running_total;
} else {
return fact(x1, running_total*x);
}
}
 Substituting n=4
public static int fact(4, running_total=1) {
if (x==1) {
return running_total;
} else {
return fact(41, running_total*4);
}
}
If
loop fails so it goes to else
loop
so it returns fact(3, 4)
In stack memory, we have
fact(3, 4)
Substituting n=3
public static int fact(3, running_total=4) {
if (x==1) {
return running_total;
} else {
return fact(31, 4*3);
}
}
If
loop fails so it goes to else
loop
so it returns fact(2, 12)
In stack memory, we have
fact(2, 12)
Substituting n=2
public static int fact(2, running_total=12) {
if (x==1) {
return running_total;
} else {
return fact(21, 12*2);
}
}
If
loop fails so it goes to else
loop
so it returns fact(1, 24)
In stack memory, we have
fact(1, 24)
Substituting n=1
public static int fact(1, running_total=24) {
if (x==1) {
return running_total;
} else {
return fact(11, 24*1);
}
}
If
loop is true
so it returns running_total
The output for running_total = 24
Finally, the result of fact(4,1) = 24
Tail recursion (also called tail call optimization or tail call elimination) is when the last thing your recursive function does is make the recursive function call. For example, your code would look like this:
def recursiveFunction(some_params):
# some code here
return recursiveFunction(some_args)
# no code after the return statement
Compilers that are aware of tail call recursion can optimize recursive code to prevent stack overflows.
For example, this is a standard recursive factorial function in Python:
def factorial(number):
if number == 1:
# BASE CASE
return 1
else:
# RECURSIVE CASE
# Note that `number *` happens *after* the recursive call.
# This means that this is *not* tail call recursion.
return number * factorial(number  1)
And this is a tail call recursive version of the factorial function:
def factorial(number, accumulator=1):
if number == 0:
# BASE CASE
return accumulator
else:
# RECURSIVE CASE
# There's no code after the recursive call.
# This is tail call recursion:
return factorial(number  1, number * accumulator)
print(factorial(5))
(Note that even though this is Python code, the CPython interpreter doesn't do tail call optimization, so arranging your code like this confers no runtime benefit.)
You may have to make your code a bit more unreadable to make use of tail call optimization, as shown in the factorial example. (For example, the base case is now a bit unintuitive, and the accumulator
parameter is effectively used as a sort of global variable.)
But the benefit of tail call optimization is that it prevents stack overflow errors. (I'll note that you can get this same benefit by using an iterative algorithm instead of a recursive one.)
Stack overflows are caused when the call stack has had too many frame objects pushed onto. A frame object is pushed onto the call stack when a function is called, and popped off the call stack when the function returns. Frame objects contain info such as local variables and what line of code to return to when the function returns.
If your recursive function makes too many recursive calls without returning, the call stack can exceed its frame object limit. (The number varies by platform; in Python it is 1000 frame objects by default.) This causes a stack overflow error. (Hey, that's where the name of this website comes from!)
However, if the last thing your recursive function does is make the recursive call and return its return value, then there's no reason it needs to keep the current frame object needs to stay on the call stack. After all, if there's no code after the recursive function call, there's no reason to hang on to the current frame object's local variables. So we can get rid of the current frame object immediately rather than keep it on the call stack. The end result of this is that your call stack doesn't grow in size, and thus cannot stack overflow.
A compiler or interpreter must have tail call optimization as a feature for it to be able to recognize when tail call optimization can be applied. Even then, you may have rearrange the code in your recursive function to make use of tail call optimization, and it's up to you if this potential decrease in readability is worth the optimization.
protected by Srikar Appalaraju Aug 4 '13 at 15:27
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