# if statement considered beneficial

## Summary

a statement of the form `if (a > max) max = a`

is the fastest way to determine the maximum of a set of numbers. However the loop infrastructure itself takes most of the CPU time, so this optimization is questionable in the end.

## Details

The answer by luisperezphd is interesting because it provides numbers, however I believe the method is flawed: the compiler will most likely move the comparison out of the loop, so the answer doesn't measure what it wants to measure. This explains the negligible timing difference between control loop and measurement loops.

To avoid this loop optimization, I added an operation that depends on the loop variable, to the empty control loop as well as to all measurement loops. I simulate the common use case of finding the maximum in a list of numbers, and used three data sets:

- best case: the first number is the maximum, all numbers after it are smaller
- worst case: every number is bigger than the previous, so the max changes each iteration
- average case: a set of random numbers

See below for the code.

The result was rather surprising to me. On my Core i5 2520M laptop I got the following for 1 billion iterations (the empty control took about 2.6 sec in all cases):

`max = Math.Max(max, a)`

: 2.0 sec best case / 1.3 sec worst case / 2.0 sec average case
`max = Math.Max(a, max)`

: 1.6 sec best case / 2.0 sec worst case / 1.5 sec average case
`max = max > a ? max : a`

: 1.2 sec best case / 1.2 sec worst case / 1.2 sec average case
`if (a > max) max = a`

: 0.2 sec best case / 0.9 sec worst case / 0.3 sec average case

So despite long CPU pipelines and the resulting penalties for branching, the good old `if`

statement is the clear winner for all simulated data sets; in the best case it is 10 times faster than `Math.Max`

, and in the worst case still more than 30% faster.

Another surprise is that the order of the arguments to `Math.Max`

matters. Presumably this is because of CPU branch prediction logic working differently for the two cases, and mispredicting branches more or less depending on the order of arguments.

However, the majority of the CPU time is spent in the loop infrastructure, so in the end this optimization is questionable at best. It provides a measurable but minor reduction in overall execution time.

## Code

```
using System;
using System.Diagnostics;
namespace ProfileMathMax
{
class Program
{
static double controlTotalSeconds;
const int InnerLoopCount = 100000;
const int OuterLoopCount = 1000000000 / InnerLoopCount;
static int[] values = new int[InnerLoopCount];
static int total = 0;
static void ProfileBase()
{
Stopwatch stopwatch = new Stopwatch();
stopwatch.Start();
int maxValue;
for (int j = 0; j < OuterLoopCount; j++)
{
maxValue = 0;
for (int i = 0; i < InnerLoopCount; i++)
{
// baseline
total += values[i];
}
}
stopwatch.Stop();
controlTotalSeconds = stopwatch.Elapsed.TotalSeconds;
Console.WriteLine("Control - Empty Loop - " + controlTotalSeconds + " seconds");
}
static void ProfileMathMax()
{
int maxValue;
Stopwatch stopwatch = new Stopwatch();
stopwatch.Start();
for (int j = 0; j < OuterLoopCount; j++)
{
maxValue = 0;
for (int i = 0; i < InnerLoopCount; i++)
{
maxValue = Math.Max(values[i], maxValue);
total += values[i];
}
}
stopwatch.Stop();
Console.WriteLine("Math.Max(a, max) - " + stopwatch.Elapsed.TotalSeconds + " seconds");
Console.WriteLine("Relative: " + (stopwatch.Elapsed.TotalSeconds - controlTotalSeconds) + " seconds");
}
static void ProfileMathMaxReverse()
{
int maxValue;
Stopwatch stopwatch = new Stopwatch();
stopwatch.Start();
for (int j = 0; j < OuterLoopCount; j++)
{
maxValue = 0;
for (int i = 0; i < InnerLoopCount; i++)
{
maxValue = Math.Max(maxValue, values[i]);
total += values[i];
}
}
stopwatch.Stop();
Console.WriteLine("Math.Max(max, a) - " + stopwatch.Elapsed.TotalSeconds + " seconds");
Console.WriteLine("Relative: " + (stopwatch.Elapsed.TotalSeconds - controlTotalSeconds) + " seconds");
}
static void ProfileInline()
{
int maxValue = 0;
Stopwatch stopwatch = new Stopwatch();
stopwatch.Start();
for (int j = 0; j < OuterLoopCount; j++)
{
maxValue = 0;
for (int i = 0; i < InnerLoopCount; i++)
{
maxValue = maxValue > values[i] ? values[i] : maxValue;
total += values[i];
}
}
stopwatch.Stop();
Console.WriteLine("max = max > a ? a : max: " + stopwatch.Elapsed.TotalSeconds + " seconds");
Console.WriteLine("Relative: " + (stopwatch.Elapsed.TotalSeconds - controlTotalSeconds) + " seconds");
}
static void ProfileIf()
{
int maxValue = 0;
Stopwatch stopwatch = new Stopwatch();
stopwatch.Start();
for (int j = 0; j < OuterLoopCount; j++)
{
maxValue = 0;
for (int i = 0; i < InnerLoopCount; i++)
{
if (values[i] > maxValue)
maxValue = values[i];
total += values[i];
}
}
stopwatch.Stop();
Console.WriteLine("if (a > max) max = a: " + stopwatch.Elapsed.TotalSeconds + " seconds");
Console.WriteLine("Relative: " + (stopwatch.Elapsed.TotalSeconds - controlTotalSeconds) + " seconds");
}
static void Main(string[] args)
{
Random rnd = new Random();
for (int i = 0; i < InnerLoopCount; i++)
{
//values[i] = i; // worst case: every new number biggest than the previous
//values[i] = i == 0 ? 1 : 0; // best case: first number is the maximum
values[i] = rnd.Next(int.MaxValue); // average case: random numbers
}
ProfileBase();
Console.WriteLine();
ProfileMathMax();
Console.WriteLine();
ProfileMathMaxReverse();
Console.WriteLine();
ProfileInline();
Console.WriteLine();
ProfileIf();
Console.ReadLine();
}
}
}
```

`Math.Max(a, b)`

,`Math.Max(b, a)`

,`a > b ? a : b`

,`a < b ? b : a`

,`b > a ? b : a`

,`b < a ? a : a`

. – BoltClock♦ Mar 29 '11 at 21:07`Math.Max()`

is more readable, so I'd prefer that. – BrokenGlass Mar 29 '11 at 21:08`Math.Max(a,b)`

is the same as`Math.Max(b,a)`

, just as`a+b`

is the same as`b+a`

– chezy525 Mar 29 '11 at 21:13