The challenge you are encountering is that you've got function calls and loop constructs intermingled. It is hard to disentangle those.

First let's start by replacing all control of flow operations with recursion.

```
// You'll want to start with getPermutionsR(v, n, 0, 0)
void getPermutationsR(int v[], int n, int i, int j)
{
if (i == n)
{
//Display contents of v
}
else if (j == n) {
// By doing nothing, we break out of the loop
}
else
{
// This was your recursive call inside of the loop.
// Note that I'm sending you to to the first loop iteration here.
swap (v, i, j);
getPermutationsR(v, n, i+1, i+1);
swap (v, i, j);
// And the next loop iteration
getPermutationsR(v, n, i, j+1);
}
}
```

Next let's add more state so that we only have one recursive call inside of an if condition.

```
// You'll want to start with getPermutionsR(v, n, 0, 0, 1)
void getPermutationsR(int v[], int n, int i, int j, bool firstCall)
{
if (i == n)
{
//Display contents of v
}
int x = i;
int y = j+1;
if (firstCall) {
swap (v, i, j);
x = i+1;
y = i+1;
}
// My one recursive call. Note that i=n implies j=n.
if (j < n) {
getPermutationsR(v, n, x, y, !firstCall);
}
if (firstCall) {
swap (v, i, j);
}
}
```

Now that we've accomplished this, we have it in a form where we can transform it into an iterative version in a straightforward way. Here is the transformation

```
void recursiveForm (params, recursiveState) {
topHalf...
if (cond) {
recursiveForm(...)
}
bottomHalf...
}
```

becomes

```
void iterativeForm(params) {
initializeStacks...
pushStacks...
topHalf...
while (stacks not empty) {
if (cond) {
pushStacks...
topHalf...
}
else {
bottomHalf...
popStacks...
}
}
}
```

So applying that pattern we get something like:

```
// You'll want to start with getPermutionsR(v, n, 0, 0, 1)
void getPermutationsI(int v[], int n)
{
stack<int> iStack;
stack<int> jStack;
stack<bool> firstCallStack;
// pushStacks with initial value
iStack.push(0);
jStack.push(0);
firstCallStack.push(1);
// topHalf...
if (iStack.top() == n)
{
//Display contents of v
}
int x = iStack.top();
int y = jStack.top()+1;
if (firstCallStack.top()) {
swap (v, iStack.top(), jStack.top());
x = iStack.top()+1;
y = iStack.top()+1;
}
while iStack.size() > 0) {
// if (cond) {
if (jStack.top() < n) {
//pushStacks...
iStack.push(x);
jStack.push(y);
firstCallStack.push(!firstCallStack.top());
// topHalf...
if (iStack.top() == n)
{
//Display contents of v
}
x = iStack.top();
y = jStack.top()+1;
if (firstCallStack.top()) {
swap (v, iStack.top(), jStack.top());
x = iStack.top()+1;
y = iStack.top()+1;
}
}
else {
// bottomHalf...
if (firstCallStack.top()) {
swap (v, iStack.top(), jStack.top());
}
}
}
}
```

(Warning, all code untested, and may well not even compile. But the idea is correct. And it is definitely the same algorithm.)