I have a list of 500000 randomly generated `Tuple<long,long,string>`

objects on which I am performing a simple "between" search:

```
var data = new List<Tuple<long,long,string>>(500000);
...
var cnt = data.Count(t => t.Item1 <= x && t.Item2 >= x);
```

When I generate my random array and run my search for 100 randomly generated values of `x`

, the searches complete in about four seconds. Knowing of the great wonders that sorting does to searching, however, I decided to sort my data - first by `Item1`

, then by `Item2`

, and finally by `Item3`

- before running my 100 searches. I expected the sorted version to perform a little faster because of branch prediction: my thinking has been that once we get to the point where `Item1 == x`

, all further checks of `t.Item1 <= x`

would predict the branch correctly as "no take", speeding up the tail portion of the search. Much to my surprise, **the searches took twice as long on a sorted array**!

I tried switching around the order in which I ran my experiments, and used different seed for the random number generator, but the effect has been the same: searches in an unsorted array ran nearly twice as fast as the searches in the same array, but sorted!

Does anyone have a good explanation of this strange effect? The source code of my tests follows; I am using .NET 4.0.

```
private const int TotalCount = 500000;
private const int TotalQueries = 100;
private static long NextLong(Random r) {
var data = new byte[8];
r.NextBytes(data);
return BitConverter.ToInt64(data, 0);
}
private class TupleComparer : IComparer<Tuple<long,long,string>> {
public int Compare(Tuple<long,long,string> x, Tuple<long,long,string> y) {
var res = x.Item1.CompareTo(y.Item1);
if (res != 0) return res;
res = x.Item2.CompareTo(y.Item2);
return (res != 0) ? res : String.CompareOrdinal(x.Item3, y.Item3);
}
}
static void Test(bool doSort) {
var data = new List<Tuple<long,long,string>>(TotalCount);
var random = new Random(1000000007);
var sw = new Stopwatch();
sw.Start();
for (var i = 0 ; i != TotalCount ; i++) {
var a = NextLong(random);
var b = NextLong(random);
if (a > b) {
var tmp = a;
a = b;
b = tmp;
}
var s = string.Format("{0}-{1}", a, b);
data.Add(Tuple.Create(a, b, s));
}
sw.Stop();
if (doSort) {
data.Sort(new TupleComparer());
}
Console.WriteLine("Populated in {0}", sw.Elapsed);
sw.Reset();
var total = 0L;
sw.Start();
for (var i = 0 ; i != TotalQueries ; i++) {
var x = NextLong(random);
var cnt = data.Count(t => t.Item1 <= x && t.Item2 >= x);
total += cnt;
}
sw.Stop();
Console.WriteLine("Found {0} matches in {1} ({2})", total, sw.Elapsed, doSort ? "Sorted" : "Unsorted");
}
static void Main() {
Test(false);
Test(true);
Test(false);
Test(true);
}
```

```
Populated in 00:00:01.3176257
Found 15614281 matches in 00:00:04.2463478 (Unsorted)
Populated in 00:00:01.3345087
Found 15614281 matches in 00:00:08.5393730 (Sorted)
Populated in 00:00:01.3665681
Found 15614281 matches in 00:00:04.1796578 (Unsorted)
Populated in 00:00:01.3326378
Found 15614281 matches in 00:00:08.6027886 (Sorted)
```

`Item1 == x`

, all further checks of`t.Item1 <= x`

would predict the branch correctly as "no take", speeding up the tail portion of the search. Obviously, that line of thinking has been proven wrong by the harsh reality :)This question isof an existing question here.NOTa duplicateDo not vote to close it as one.8more comments