Little bit off topic but say i want to remove all 2s from a list. Here's a very elegant way to do that.

```
void RemoveAll<T>(T item,List<T> list)
{
while(list.Contains(item)) list.Remove(item);
}
```

With predicate:

```
void RemoveAll<T>(Func<T,bool> predicate,List<T> list)
{
while(list.Any(predicate)) list.Remove(list.First(predicate));
}
```

+1 only to encourage you to leave your answer here for learning purposes. You're also right about it being off-topic, but I won't ding you for that because of there is significant value in leaving your examples here, again, strictly for learning purposes. I'm posting this response as an edit because posting it as a series of comments would be unruly.

Though your examples are short & compact, neither is elegant in terms of efficiency; the first is bad at O(n^{2}), the second, absolutely abysmal at O(n^{3}). Algorithmic efficiency of O(n^{2}) is bad and should be avoided whenever possible, especially in general-purpose code; efficiency of O(n^{3}) is horrible and should be avoided in all cases except when you know n will always be very small. Some might fling out their "premature optimization is the root of all evil" battle axes, but they do so naïvely because they do not truly understand the consequences of quadratic growth since they've never coded algorithms that have to process large datasets. As a result, their small-dataset-handling algorithms just run generally slower than they could, and they have no idea that they could run faster. The difference between an efficient algorithm and an inefficient algorithm is often subtle, but the performance difference can be dramatic. The key to understanding the performance of your algorithm is to understand the performance characteristics of the primitives you choose to use.

In your first example, `list.Contains()`

and `Remove()`

are both O(n), so a `while()`

loop with one in the predicate & the other in the body is O(n^{2}); well, technically O(m*n), but it approaches O(n^{2}) as the number of elements being removed (m) approaches the length of the list (n).

Your second example is even worse: O(n^{3}), because for every time you call `Remove()`

, you also call `First(predicate)`

, which is also O(n). Think about it: `Any(predicate)`

*loops over the list* looking for any element for which `predicate()`

returns true. Once it finds the first such element, it returns true. In the body of the `while()`

loop, you then call `list.First(predicate)`

which *loops over the list a second time* looking for the same element that had already been found by `list.Any(predicate)`

. Once `First()`

has found it, it returns that element which is passed to `list.Remove()`

, which *loops over the list a third time* to yet once again find that same element that was previously found by `Any()`

and `First()`

, in order to finally remove it. Once removed, the *whole process starts over at the beginning with a slightly shorter list*, doing all the looping *over and over and over again starting at the beginning every time* until finally no more elements matching the predicate remain. So the performance of your second example is O(m*m*n), or O(n^{3}) as m approaches n.

Your best bet for removing all items from a list that match some predicate is to use the generic list's own `List<T>.RemoveAll(predicate)`

method, which is O(n) as long as your predicate is O(1). A `for()`

loop technique that passes over the list only once, calling `list.RemoveAt()`

for each element to be removed, may *seem* to be O(n) since it appears to pass over the loop only once. Such a solution *is* more efficient than your first example, but only by a constant factor, which in terms of algorithmic efficiency is negligible. Even a `for()`

loop implementation is O(m*n) since each call to `Remove()`

is O(n). Since the `for()`

loop itself is O(n), and it calls `Remove()`

m times, the `for()`

loop's growth is O(n^{2}) as m approaches n.