Sorting a collection and adding elements to a collection are, often, two separate functions. It is, of course, possible to add elements to a collection in a manner such that the elements are sorted ... but this is a very different task from simply sorting an array of elements.

If you are simply trying to implement a simple sorting algorithm, a simple (but not optimal) algorithm that is easy to code is the "delayed replacement sort". Pseudocode fpr the algorithm to sort into ascending order is described succinctly below:

```
Begin DELAYEDSORT
For ITEM=1 to maximum number of items in list-1
LOWEST=ITEM
For N=ITEM+1 to maximum number of items in list
Is entry at position N lower than entry at position LOWEST?
If so, LOWEST=N
Next N
Is ITEM different from LOWEST
If so, swap entry at LOWEST with entry in ITEM
Next ITEM
End DELAYEDSORT
```

The delayed replacement sorting algorithm is simple to understand and easy to code. It is typically faster than the bubble sort (fewer swaps), but still has bad time complexity O(n^2) and so it is not appropriate for sorting very large datasets.

If you really want to add items to a sorted collection, then you can add the new item to the end of your collection, and resort it using the above. If you are working with data sets larger than a few hundred or thousand elements, then efficiency will be poor.

An alternate solution that still has O(n^2) time complexity but which can be adapted to combine the adding and sorting is the "insertion sort" whose pseudocode appears below:

```
// The values in A[i] are checked in-order, starting at the second one
for i ← 1 to i ← length(A)
{
// at the start of the iteration, A[0..i-1] are in sorted order
// this iteration will insert A[i] into that sorted order
// save A[i], the value that will be inserted into the array on this iteration
valueToInsert ← A[i]
// now mark position i as the hole; A[i]=A[holePos] is now empty
holePos ← i
// keep moving the hole down until the valueToInsert is larger than
// what's just below the hole or the hole has reached the beginning of the array
while holePos > 0 and valueToInsert < A[holePos - 1]
{ //value to insert doesn't belong where the hole currently is, so shift
A[holePos] ← A[holePos - 1] //shift the larger value up
holePos ← holePos - 1 //move the hole position down
}
// hole is in the right position, so put valueToInsert into the hole
A[holePos] ← valueToInsert
// A[0..i] are now in sorted order
}
```