Ok, so the graph displays a measurement of the cost of inserting `n`

elements into your tree, where the x axis is how many elements we've inserted, and the y axis is the total time.

Let's call the function that totals the time it takes to insert n elements into the tree `f(n)`

.

Then we can get a rough idea of what `f`

might look like:

```
f(1) < k*log(1) for some constant k.
f(2) < k*log(1) + k*log(2) for some constant k
...
f(n) < k * [log(1) + log(2) + ... + log(n)] for some constant k.
```

Due to how logs work, we can collapse `log(1) + ... + log(n)`

:

```
f(n) < k * [log(1*2*3*...*n)] for some constant k
f(n) < k * log(n!) for some constant k
```

We can take a look at Wikipedia to see a graph of what `log(n!)`

looks like. Take a look at the graph in the article. Should look pretty familiar to you. :)

That is, I think you've done this by accident:

```
for n in (5000, 50000, 500000):
startTime = ...
## .. make a fresh tree
## insert n elements into the tree
stopTime = ...
## record the tuple (n, stopTime - startTime) for plotting
```

and plotted total time to construct the tree of size n, rather than the individual cost of inserting one element into a tree of size n:

```
for n in range(50000):
startTime = ...
## insert an element into the tree
stopTime = ...
## record the tuple (n, stopTime - startTime) for plotting
```

Chris Taylor notes in the comments that if you plot `f(n)/n`

, you'll see a log graph. That's because a fairly tight approximation to `log(n!)`

is `n*log(n)`

(see the Wikipedia page). So we can go back to our bound:

```
f(n) < k * log(n!) for some constant k
```

and get:

```
f(n) < k * n * log(n) for some constant k
```

And now it's should be easier to see that if you divide `f(n)`

by `n`

, your graph will be bounded above by the shape of a logarithm.