In a recursive function, each time a recursive call occurs, the state of the caller is saved to a stack, then restored when the recursive call is complete. To convert a recursive function to an iterative one, you need to turn the state of the suspended function into an explicit data structure. Of course, you can create your own stack in software, but there are often tricks you can use to make your code more efficient.

This answer works through the transformation steps for this example. You can apply the same methods to other loops.

## Tail Recursion Transformation

Let's take a look at your code again:

```
def Trace(ray):
# Here was code to look for intersections
if not hit:
return Color(0, 0, 0)
return hit.diffuse * (Trace(ray) + hit.emittance)
```

In general, a recursive call has to go back to the calling function, so the caller can finish what it's doing. In this case, the caller "finishes" by performing an addition and a multiplication. This produces a computation like
`d1 * (d2 * (d3 * (... + e3) + e2) + e1))`

. We can take advantage of the distributive law of addition and the associative laws of multiplication and addition to transform the calculation into `[d1 * e1] + [(d1 * d2) * e2] + [(d1 * d2) * d3) * e3] + ... `

. Note that the first term in this series only refers to iteration 1, the second only refers to iterations 1 and 2, and so forth. That tells us that we can compute this series on the fly. Moreover, this series contains the series `(d1, d1*d2, d1*d2*d3, ...)`

, which we can also compute on the fly. Putting that back into the code:

```
def Trace(diffuse, emittance, ray):
# Here was code to look for intersections
if not hit: return emittance # The complete value has been computed
new_diffuse = diffuse * hit.diffuse # (...) * dN
new_emittance = emittance + new_diffuse * hit.emittance # (...) + [(d1 * ... * dN) + eN]
return Trace(new_diffuse, new_emittance, ray)
```

## Tail Recursion Elimination

In the new loop, the caller has no work to do after the callee finishes; it simply returns the callee's result. The caller has no work to finish, so it *doesn't have to save any of its state*! Instead of a call, we can overwrite the old parameters and go back to the beginning of the function (not valid Python, but it illustrates the point):

```
def Trace(diffuse, emittance, ray):
beginning:
# Here was code to look for intersections
if not hit: return emittance # The complete value has been computed
new_diffuse = diffuse * hit.diffuse # (...) * dN
new_emittance = emittance + new_diffuse * hit.emittance # (...) + [(d1 * ... * dN) + eN]
(diffuse, emittance) = (new_diffuse, new_emittance)
goto beginning
```

Finally, we have transformed the recursive function into an equivalent loop. All that's left is to express it in Python syntax.

```
def Trace(diffuse, emittance, ray):
while True:
# Here was code to look for intersections
if not hit: break
diffuse = diffuse * hit.diffuse # (...) * dN
emittance = emittance + diffuse * hit.emittance # (...) + [(d1 * ... * dN) + eN]
return emittance
```

`hit`

? – inspectorG4dget Jun 10 '11 at 0:29`hit`

is the object which the`ray`

passes through. It differs each time. – Blender Jun 10 '11 at 0:30`hit`

is constant throughout the entire recursion? Or does it change even within the trace of a recursion? – inspectorG4dget Jun 10 '11 at 0:32