Joe correctly states in his answer that one would expect a binary search technique to be faster than `Select`

, which seem to just do a linear search even if the list is sorted:

```
ClearAll[selectTiming]
selectTiming[length_, iterations_] := Module[
{lst},
lst = Sort[RandomInteger[{0, 100}, length]];
(Do[Select[lst, # == 2 &, 1], {i, 1, iterations}] // Timing //
First)/iterations
]
```

(I arbitrarily put the threshold at 2 for demonstration purposes).

However, the `BinarySearch`

function in Combinatorica is a) not appropriate (it returns an element which does match the requested one, but not the first (leftmost), which is what the question is asking.

To obtain the leftmost element that is larger than a threshold, given an ordered list, we may proceed either recursively:

```
binSearch[lst_,threshold_]:= binSearchRec[lst,threshold,1,Length@lst]
(*
return position of leftmost element greater than threshold
breaks if the first element is greater than threshold
lst must be sorted
*)
binSearchRec[lst_,threshold_,min_,max_] :=
Module[{i=Floor[(min+max)/2],element},
element=lst[[i]];
Which[
min==max,max,
element <= threshold,binSearchRec[lst,threshold,i+1,max],
(element > threshold) && ( lst[[i-1]] <= threshold ), i,
True, binSearchRec[lst,threshold,min,i-1]
]
]
```

or iteratively:

```
binSearchIterative[lst_,threshold_]:=Module[
{min=1,max=Length@lst,i,element},
While[
min<=max,
i=Floor[(min+max)/2];
element=lst[[i]];
Which[
min==max, Break[],
element<=threshold, min=i+1,
(element>threshold) && (lst[[i-1]] <= threshold), Break[],
True, max=i-1
]
];
i
]
```

The recursive approach is clearer but I'll stick to the iterative one.

To test its speed,

```
ClearAll[binSearchTiming]
binSearchTiming[length_, iterations_] := Module[
{lst},
lst = Sort[RandomInteger[{0, 100}, length]];
(Do[binSearchIterative[lst, 2], {i, 1, iterations}] // Timing //
First)/iterations
]
```

which produces

so, much faster and with better scaling behaviour.

Actually it's not necessary to compile it but I did anyway.

In conclusion, then, don't use `Select`

for long lists.

This concludes my answer. There follow some comments on doing a binary search by hand or via the Combinatorica package.

I compared the speed of a (compiled) short routine to do binary search vs the `BinarySearch`

from `Combinatorica`

. Note that this does not do what the question asks (and neither does `BinarySearch`

from `Combinatorica`

); the code I gave above does.

The binary search may be implemented iteratively as

```
binarySearch = Compile[{{arg, _Integer}, {list, _Integer, 1}},
Module[ {min = 1, max = Length@list,
i, x},
While[
min <= max,
i = Floor[(min + max)/2];
x = list[[i]];
Which[
x == arg, min = max = i; Break[],
x < arg, min = i + 1,
True, max = i - 1
]
];
If[ 0 == max,
0,
max
]
],
CompilationTarget -> "C",
RuntimeOptions -> "Speed"
];
```

and we can now compare this and `BinarySearch`

from `Combinatorica`

. Note that a) the list must be sorted b) this will not return the *first* matching element, but *a* matching element.

```
lst = Sort[RandomInteger[{0, 100}, 1000000]];
```

Let us compare the two binary search routines. Repeating 50000 times:

```
Needs["Combinatorica`"]
Do[binarySearch[2, lst], {i, 50000}] // Timing
Do[BinarySearch[lst, 2], {i, 50000}] // Timing
(*
{0.073437, Null}
{4.8354, Null}
*)
```

So the handwritten one is faster. Now since in fact a binary search just visits 6-7 points in the list for these parameters (something like `{500000, 250000, 125000, 62500, 31250, 15625, 23437}`

for instance), clearly the difference is simply overhead; perhaps `BinarySearch`

is more general, for instance, or not compiled.