## Code size

Regarding code size, I put the first implementation into file `f1.c`

and the second into `f2.c`

.

```
$ gcc -c f1.c f2.c
$ size f1.o f2.o
__TEXT __DATA __OBJC others dec hex
123 0 0 0 123 7b f1.o
119 0 0 0 119 77 f2.o
$ gcc -O3 -c f1.c f2.c
$ size f1.o f2.o
__TEXT __DATA __OBJC others dec hex
372 0 0 0 372 174 f1.o
362 0 0 0 362 16a f2.o
$
```

Note that there is very little difference in the code size for either implementation. Intriguingly though, the optimized code is a lot bigger (about three times as big) as the unoptimized code.

(Compiler: GCC 4.7.1 on Mac OS X 10.7.5.)

You should note that the factorials (which is what these functions implement) grow very fast. In fact, 13! is too big to fit into a 32-bit unsigned integer, 21! is too big to fit into a 64-bit unsigned integer, and 35! is too big to fit into a 128-bit unsigned integer (if you can find a computer with such a type).

## Code speed — a contrarian finding!

Also, beware assumptions. I expected the iterative solution to be faster than the recursive solution. However, measurement suggests otherwise.

The tests were run on a MacBook Pro with 2.3 GHz Intel Core i7 (and 16 GiB memory, but memory isn't a factor in this calculation).

Measurement shows that when the code is optimized, the recursive solution is consistently a little faster than the pure iterative solution, which is absolutely contrary to what I expected, but shows why performance measurements are necessary.

### Optimized code

```
# iteration
# Count = 10
# Mean = 0.799869
# Variance = 0.000011
# recursion
# Count = 10
# Mean = 0.750904
# Variance = 0.000014
```

I later added a lookup table function and the times for that were:

```
# lookuptab
# Count = 10
# Mean = 0.213836
# Variance = 0.000004
```

And I added a function that simply returned its input parameter to measure the test harness overhead, and that gave:

```
# over-head
# Count = 10
# Mean = 0.211325
# Variance = 0.000001
```

So the computational cost of the array lookup is very small.

### Unoptimized code

If you ever doubted the power of the optimizer, then compare the optimized times with these, for the unoptimized build.

```
# iteration
# Count = 10
# Mean = 1.852833
# Variance = 0.000020
# recursion
# Count = 10
# Mean = 2.937954
# Variance = 0.000059
```

And the lookup table version:

```
# lookuptab
# Count = 10
# Mean = 0.730275
# Variance = 0.000026
```

And the overhead version:

```
# over-head
# Count = 10
# Mean = 0.633132
# Variance = 0.000009
```

## General Observations

- Simple 'lines of code' is not sufficient to tell you anything about performance.
- Measurement trumps guesswork.
- Optimizers are good.

The reason why simply counting lines of code is not a good guideline is that different lines have different costs. For example, a single line of code containing calls to functions like `sin()`

, `cos()`

and `tan()`

will (probably) be vastly more expensive than 20 lines of code containing single integer arithmetic operations and assignments.

When comparing two very similar functions — as in the question — then more complex recursion tends to be slower than simple iteration. But, as demonstrated, such guessed results can be wrong when the compiler manages to optimize, especially for a simple tail-recursive function such as factorials.

## Timing details

Here's a test program:

```
static int fun1(int num)
{
if (num == 1)
return 1;
else
return num * fun1(num - 1);
}
static int fun2(int num)
{
int i=1;
do{
i = i * num;
num--;
} while (num);
return i;
}
static int fun3(int num)
{
static const int factorial[] =
{ 1, 1, 2, 6, 24, 120, 720, 5040, 40320,
362880, 3628800, 39916800, 479001600,
};
enum { MAX_FACTORIAL_NUM = (sizeof(factorial)/sizeof(factorial[0])) };
if (num < 0 || num >= MAX_FACTORIAL_NUM)
return 0;
else
return factorial[num];
}
static int fun4(int num)
{
return num;
}
#include "timer.h"
#include <stdio.h>
static void tester(char const *name, int (*function)(int))
{
char buffer[32];
Clock clk;
unsigned long long sumfact = 0;
clk_init(&clk);
clk_start(&clk);
for (int i = 0; i < 100000000; i++)
sumfact += (*function)(i % 12 + 1);
clk_stop(&clk);
printf("%s: %s (%llu)\n", name, clk_elapsed_us(&clk, buffer, sizeof(buffer)), sumfact);
}
int main(void)
{
for (int i = 0; i < 10; i++)
{
tester("recursion", fun1);
tester("iteration", fun2);
tester("lookuptab", fun3);
tester("over-head", fun4);
}
return(0);
}
```

The test code is careful to treat the two functions as symmetrically as possible, and alternately tests each function to reduce the chance of background processes interfering with performance. (The BOINC processes normally running in the background were turned off for these tests; experience with timing for previous questions shows they seriously affect the results and introduce much more variability into the results.)

### Raw times for optimized (`-O3`

) build

Early version of program without lookup table or over-head functions.

```
recursion: 0.754428 (4357969100681262)
iteration: 0.799330 (4357969100681262)
recursion: 0.749773 (4357969100681262)
iteration: 0.798897 (4357969100681262)
recursion: 0.747794 (4357969100681262)
iteration: 0.800977 (4357969100681262)
recursion: 0.748282 (4357969100681262)
iteration: 0.792708 (4357969100681262)
recursion: 0.748342 (4357969100681262)
iteration: 0.798776 (4357969100681262)
recursion: 0.748377 (4357969100681262)
iteration: 0.801641 (4357969100681262)
recursion: 0.750115 (4357969100681262)
iteration: 0.802468 (4357969100681262)
recursion: 0.750807 (4357969100681262)
iteration: 0.802829 (4357969100681262)
recursion: 0.751296 (4357969100681262)
iteration: 0.796841 (4357969100681262)
recursion: 0.759823 (4357969100681262)
iteration: 0.804221 (4357969100681262)
real 0m15.575s
user 0m15.556s
sys 0m0.027s
```

### Raw times for unoptimized build

Early version of program without lookup table or over-head functions.

```
recursion: 2.951282 (4357969100681262)
iteration: 1.852239 (4357969100681262)
recursion: 2.932758 (4357969100681262)
iteration: 1.851512 (4357969100681262)
recursion: 2.924796 (4357969100681262)
iteration: 1.862686 (4357969100681262)
recursion: 2.946792 (4357969100681262)
iteration: 1.846961 (4357969100681262)
recursion: 2.941705 (4357969100681262)
iteration: 1.849099 (4357969100681262)
recursion: 2.938599 (4357969100681262)
iteration: 1.852089 (4357969100681262)
recursion: 2.930713 (4357969100681262)
iteration: 1.854765 (4357969100681262)
recursion: 2.935669 (4357969100681262)
iteration: 1.851478 (4357969100681262)
recursion: 2.938975 (4357969100681262)
iteration: 1.856979 (4357969100681262)
recursion: 2.938250 (4357969100681262)
iteration: 1.850521 (4357969100681262)
real 0m47.980s
user 0m47.939s
sys 0m0.041s
```

I note that there's a bug in the code of both the factorial functions; both go into long-running loops (and invoke all sorts of undefined behaviour by overflowing the 32-bit `int`

type) when asked to calculate 0!, which is actually well defined and has the value 1. That's why the invocation in the test harness is `(*function)(i % 12 + 1)`

rather than `(*function)(i % 13)`

as I originally wrote.

`size`

command on Unix (applied to the object files). There wouldn't be much difference in the size, though; the code is too simple. The recursive version will be slower because it uses more function calls and hence more stack space (for the return addresses and function arguments, etc). It is likely that a faster version still would use a lookup table since you can't represent factorial 13 in a 32-bit int. – Jonathan Leffler Feb 9 '13 at 16:16Recursion vs. Iterationsecond isWhich is better RECURSION or ITERATION?– Grijesh Chauhan Feb 9 '13 at 16:18