Okay, there are 26 possibilities for a 1-character string, 26^{2} for a 2-character string, and so on up to 26^{26} possibilities for a 26-character string.

That means there are 26 times as many possibilities for an (N)-character string than there are for an (N-1)-character string. You can use that fact to select your length:

```
def getlen(maxlen):
sz = maxlen
while sz != 1:
if rnd(27) != 1:
return sz
sz--;
return 1
```

I use 27 in the above code since the total sample space for selecting strings from "ab" is the 26 1-character possibilities and the 26^{2} 2-character possibilities. In other words, the ratio is 1:26 so 1-character has a probability of 1/27 (rather than 1/26 as I first answered).

This solution isn't *perfect* since you're calling `rnd`

multiple times and it would be better to call it once with an possible range of 26^{N}+26^{N-1}+26^{1} and select the length based on where your returned number falls within there but it may be difficult to find a random number generator that'll work on numbers that large (10 characters gives you a possible range of 26^{10}+...+26^{1} which, unless I've done the math wrong, is 146,813,779,479,510).

If you can limit the maximum size so that your `rnd`

function will work in the range, something like this should be workable:

```
def getlen(chars,maxlen):
assert maxlen >= 1
range = chars
sampspace = 0
for i in 1 .. maxlen:
sampspace = sampspace + range
range = range * chars
range = range / chars
val = rnd(sampspace)
sz = maxlen
while val < sampspace - range:
sampspace = sampspace - range
range = range / chars
sz = sz - 1
return sz
```

Once you have the length, I would then use your current algorithm to choose the actual characters to populate the string.

Explaining it further:

Let's say our alphabet only consists of "ab". The possible sets up to length 3 are `[ab]`

(2), `[ab][ab]`

(4) and `[ab][ab][ab]`

(8). So there is a 8/14 chance of getting a length of 3, 4/14 of length 2 and 2/14 of length 1.

The 14 is the magic figure: it's the sum of all 2^{n} for n = 1 to the maximum length. So, testing that pseudo-code above with `chars = 2`

and `maxlen = 3`

:

```
assert maxlen >= 1 [okay]
range = chars [2]
sampspace = 0
for i in 1 .. 3:
i = 1:
sampspace = sampspace + range [0 + 2 = 2]
range = range * chars [2 * 2 = 4]
i = 2:
sampspace = sampspace + range [2 + 4 = 6]
range = range * chars [4 * 2 = 8]
i = 3:
sampspace = sampspace + range [6 + 8 = 14]
range = range * chars [8 * 2 = 16]
range = range / chars [16 / 2 = 8]
val = rnd(sampspace) [number from 0 to 13 inclusive]
sz = maxlen [3]
while val < sampspace - range: [see below]
sampspace = sampspace - range
range = range / chars
sz = sz - 1
return sz
```

So, from that code, the first iteration of the final loop will exit with `sz = 3`

if `val`

is greater than or equal to `sampspace - range [14 - 8 = 6]`

. In other words, for the values 6 through 13 inclusive, 8 of the 14 possibilities.

Otherwise, `sampspace`

becomes `sampspace - range [14 - 8 = 6]`

and `range`

becomes `range / chars [8 / 2 = 4]`

.

Then the second iteration of the final loop will exit with `sz = 2`

if `val`

is greater than or equal to `sampspace - range [6 - 4 = 2]`

. In other words, for the values 2 through 5 inclusive, 4 of the 14 possibilities.

Otherwise, `sampspace`

becomes `sampspace - range [6 - 4 = 2]`

and `range`

becomes `range / chars [4 / 2 = 2]`

.

Then the third iteration of the final loop will exit with `sz = 1`

if `val`

is greater than or equal to `sampspace - range [2 - 2 = 0]`

. In other words, for the values 0 through 1 inclusive, 2 of the 14 possibilities (this iteration will *always* exit since the value must be greater than or equal to zero.

In retrospect, that second solution is a bit of a nightmare. In my personal opinion, I'd go for the first solution for its simplicity and to avoid the possibility of rather large numbers.

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