Understanding Recursion to generate permutations

I find recursion, apart from very straight forward ones like factorial, very difficult to understand. The following snippet prints all permutations of a string. Can anyone help me understand it. What is the way to go about to understand recursion properly.

``````void permute(char a[], int i, int n)
{
int j;
if (i == n)
cout << a << endl;
else
{
for (j = i; j <= n; j++)
{
swap(a[i], a[j]);
permute(a, i+1, n);
swap(a[i], a[j]);
}
}
}

int main()
{
char a[] = "ABCD";
permute(a, 0, 3);
getchar();
return 0;
}
``````
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Try sketching it out on paper, or you can also try single-stepping through the code in a debugger. –  Paul R Sep 24 '11 at 8:08
Adding for some one new: Write a C program to print all permutations of a given string –  Grijesh Chauhan Sep 30 '13 at 8:41

PaulR has the right suggestion. You have to run through the code by "hand" (using whatever tools you want - debuggers, paper, logging function calls and variables at certain points) until you understand it. For an explanation of the code I'll refer you to quasiverse's excellent answer.

Perhaps this visualization of the call graph with a slightly smaller string makes it more obvious how it works:

The graph was made with graphviz.

``````// x.dot
// dot x.dot -Tpng -o x.png
digraph x {
rankdir=LR
size="16,10"

node [label="permute(\"ABC\", 0, 2)"] n0;
node [label="permute(\"ABC\", 1, 2)"] n1;
node [label="permute(\"ABC\", 2, 2)"] n2;
node [label="permute(\"ACB\", 2, 2)"] n3;
node [label="permute(\"BAC\", 1, 2)"] n4;
node [label="permute(\"BAC\", 2, 2)"] n5;
node [label="permute(\"BCA\", 2, 2)"] n6;
node [label="permute(\"CBA\", 1, 2)"] n7;
node [label="permute(\"CBA\", 2, 2)"] n8;
node [label="permute(\"CAB\", 2, 2)"] n9;

n0 -> n1 [label="swap(0, 0)"];
n0 -> n4 [label="swap(0, 1)"];
n0 -> n7 [label="swap(0, 2)"];

n1 -> n2 [label="swap(1, 1)"];
n1 -> n3 [label="swap(1, 2)"];

n4 -> n5 [label="swap(1, 1)"];
n4 -> n6 [label="swap(1, 2)"];

n7 -> n8 [label="swap(1, 1)"];
n7 -> n9 [label="swap(1, 2)"];
}
``````
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It chooses each character from all the possible characters left:

``````void permute(char a[], int i, int n)
{
int j;
if (i == n)                  // If we've chosen all the characters then:
cout << a << endl;        // we're done, so output it
else
{
for (j = i; j <= n; j++) // Otherwise, we've chosen characters a[0] to a[j-1]
{                        // so let's try all possible characters for a[j]
swap(a[i], a[j]);    // Choose which one out of a[j] to a[n] you will choose
permute(a, i+1, n);  // Choose the remaining letters
swap(a[i], a[j]);    // Undo the previous swap so we can choose the next possibility for a[j]
}
}
}
``````
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excellent answer –  nikhil Sep 24 '11 at 8:38
@quasiverse your comments in the code was really helpful for me thanks :) –  alireza sanaee Sep 21 '13 at 19:10

To use recursion effectively in design, you solve the problem by assuming you've already solved it. The mental springboard for the current problem is "if I could calculate the permutations of n-1 characters, then I could calculate the permutations of n characters by choosing each one in turn and appending the permutations of the remaining n-1 characters, which I'm pretending I already know how to do".

Then you need a way to do what's called "bottoming out" the recursion. Since each new sub-problem is smaller than the last, perhaps you'll eventually get to a sub-sub-problem that you REALLY know how to solve.

In this case, you already know all the permutations of ONE character - it's just the character. So you know how to solve it for n=1 and for every number that's one more than a number you can solve it for, and you're done. This is very closely related to something called mathematical induction.

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Though it is little old question and already answered thought of adding my inputs to help new visitors. Also planning to explain the running time without focusing on Recursive Reconciliation.

I have written the sample in C# but easy to understand for most of the programmers.

``````static int noOfFunctionCalls = 0;
static int noOfCharDisplayCalls = 0;
static int noOfBaseCaseCalls = 0;
static int noOfRecursiveCaseCalls = 0;
static int noOfSwapCalls = 0;
static int noOfForLoopCalls = 0;

static string Permute(char[] elementsList, int currentIndex)
{
++noOfFunctionCalls;

if (currentIndex == elementsList.Length)
{
++noOfBaseCaseCalls;
foreach (char element in elementsList)
{
++noOfCharDisplayCalls;

strBldr.Append(" " + element);
}
strBldr.AppendLine("");
}
else
{
++noOfRecursiveCaseCalls;

for (int lpIndex = currentIndex; lpIndex < elementsList.Length; lpIndex++)
{
++noOfForLoopCalls;

if (lpIndex != currentIndex)
{
++noOfSwapCalls;
Swap(ref elementsList[currentIndex], ref elementsList[lpIndex]);
}

Permute(elementsList, (currentIndex + 1));

if (lpIndex != currentIndex)
{
Swap(ref elementsList[currentIndex], ref elementsList[lpIndex]);
}
}
}
return strBldr.ToString();
}

static void Swap(ref char Char1, ref char Char2)
{
char tempElement = Char1;
Char1 = Char2;
Char2 = tempElement;
}

public static void StringPermutationsTest()
{
strBldr = new StringBuilder();
Debug.Flush();

noOfFunctionCalls = 0;
noOfCharDisplayCalls = 0;
noOfBaseCaseCalls = 0;
noOfRecursiveCaseCalls = 0;
noOfSwapCalls = 0;
noOfForLoopCalls = 0;

//string resultString = Permute("A".ToCharArray(), 0);
//string resultString = Permute("AB".ToCharArray(), 0);
string resultString = Permute("ABC".ToCharArray(), 0);
//string resultString = Permute("ABCD".ToCharArray(), 0);
//string resultString = Permute("ABCDE".ToCharArray(), 0);

resultString += "\nNo of Function Calls : " + noOfFunctionCalls;
resultString += "\nNo of Base Case Calls : " + noOfBaseCaseCalls;
resultString += "\nNo of General Case Calls : " + noOfRecursiveCaseCalls;
resultString += "\nNo of For Loop Calls : " + noOfForLoopCalls;
resultString += "\nNo of Char Display Calls : " + noOfCharDisplayCalls;
resultString += "\nNo of Swap Calls : " + noOfSwapCalls;

Debug.WriteLine(resultString);
MessageBox.Show(resultString);
}
``````

Steps: For e.g. when we pass input as "ABC".

1. Permutations method called from Main for first time. So calling with Index 0 and that is first call.
2. In the else part in for loop we are repeating from 0 to 2 making 1 call each time.
3. Under each loop we are recursively calling with LpCnt + 1. 4.1 When index is 1 then 2 recursive calls. 4.2 When index is 2 then 1 recursive calls.

So from point 2 to 4.2 total calls are 5 for each loop and total is 15 calls + main entry call = 16. Each time loopCnt is 3 then if condition gets executed.

From the diagram we can see loop count becoming 3 total 6 times i.e. Factorial value of 3 i.e. Input "ABC" length.

If statement's for loop repeats 'n' times to display chars from the example "ABC" i.e. 3. Total 6 times (Factorial times) we enter into if to display the permutations. So the total running time = n X n!.

I have given some static CallCnt variables and the table to understand each line execution in detail.

Experts, feel free to edit my answer or comment if any of my details are not clear or incorrect, I am happy correct them.

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