I'll see what I can do for you. The code, for reference:

```
def my_sort(array):
length_of_array = range(1, len(array))
for i in length_of_array:
value = array[i]
last_value = array[i-1]
if value<last_value:
array[i]=last_value
array[i-1]=value
my_sort(array)
return array
```

`def my_sort(array):`

A function that takes an array as an argument.

`length_of_array = range(1, len(array))`

We set the variable `length_of_array`

to a `range`

of numbers that we can iterate over, based on the number of items in `array`

. I assume you know what `range`

does, but if you don't, in short you can iterate over it in the same way you'd iterate over a list. (You could also use `xrange()`

here.)

```
for i in length_of_array:
value = array[i]
last_value = array[-1]
```

What we're doing is using the `range`

to indirectly traverse the array because there's the same total of items in each. If we look closely, though, `value`

uses the `i`

as its index, which starts off at 1, so `value`

is actually array[1], and `last_value`

is `array[1-1]`

or `array[0]`

.

```
if value<last_value:
array[i]=last_value
array[i-1]=value
```

So now we're comparing the values. Let's say we passed in `[3, 1, 3, 2, 6, 4]`

. We're at the first iteration of the loop, so we're essentially saying, if `array[1]`

, which is 1, is less than `array[0]`

, which is 3, swap them. Of course 1 is less than 3, so swap them we do. But since the code can only compare each item to the previous item, there's no guarantee that `array`

will be properly sorted from lowest to highest. Each iteration could unswap a properly swapped item if the item following it is larger (e.g. [2,5,6,4] will remain the same on the first two iterations -- they will be skipped over by the `if`

test -- but when it hits the third, 6 will swap with 4, which is still wrong). In fact, if we were to finish this out without the call to `my_sort(array)`

directly below it, our original `array`

would evaluate to `[1, 3, 2, 3, 4, 6]`

. Not quite right.

```
my_sort(array)
```

So we call `my_sort()`

recursively. What we're basically saying is, if on the first iteration something is wrong, correct it, then pass the new `array`

back to `my_sort()`

. This sounds weird at first, but it works. If the `if`

test was never satisfied at all, that would mean each item in our original list was smaller than the next, which is another way (the computer's way, really) of saying it was sorted in ascending order to begin with. *That's the key.* So if any list item is smaller than the preceding item, we jerk it one index left. But we don't really know if *that's* correct -- maybe it needs to go further still. So we have to go back to the beginning and (i.e., call `my_sort()`

again on our newly-minted list), and recheck to see if we should pull it left again. If we can't, the `if`

test fails (each item is smaller than the next) until it hits the next error. On each iteration, this teases the same smaller number leftward by one index until it's in its correct position. This sounds more confusing than it is, so let's just look at the output for each iteration:

```
[3, 1, 3, 2, 6, 4]
[1, 3, 3, 2, 6, 4]
[1, 3, 2, 3, 6, 4]
[1, 2, 3, 3, 6, 4]
[1, 2, 3, 3, 4, 6]
```

Are you seeing what's going on? How about if we only look at what's changing on each iteration:

```
[3, 1, ... # Wrong; swap. Further work ceases; recur (return to beginning with a fresh call to my_sort()).
[1, 3, 3, 2, ... # Wrong; swap. Further work ceases; recur
[1, 3, 2, ... # Wrong; swap. Further work ceases; recur
[1, 2, 3, 3, 6, 4 # Wrong; swap. Further work ceases; recur
[1, 2, 3, 3, 4, 6] # All numbers all smaller than following number; correct.
```

This allows the function to call itself as many times as it needs to pull a number from the back to the front. Again, each time it's called, it focuses on the first wrong instance, pulling it one left until it puts it in its proper position. Hope that helps! Let me know if you're still having trouble.