Use `itertools.permutations()`

on an increasing number of repeated digits, up to 9, combining these with all digits between 1 and 9 (to prevent generating numbers with a leading 0).

```
from itertools import permutations
def generate_unique_numbers():
yield 0
for i in range(10):
for leading in '123456789':
if not i: # 1-digit numbers
yield int(leading)
continue
remaining_digits = '0123456789'.replace(leading, '')
for combo in permutations(remaining_digits, i):
yield int(leading + ''.join(combo))
```

This generates all such valid numbers without having to skip anything. There are 8877691 such numbers, ranging from 0 to 9876543210:

```
>>> sum(1 for _ in generate_unique_numbers())
8877691
>>> next(generate_unique_numbers())
0
>>> for i in generate_unique_numbers(): pass
...
>>> i
9876543210
```

A few samples of the output:

```
>>> from itertools import islice
>>> gen = generate_unique_numbers()
>>> list(islice(gen, 15))
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 12, 13, 14, 15]
>>> list(islice(gen, 150, 165))
[204, 205, 206, 207, 208, 209, 210, 213, 214, 215, 216, 217, 218, 219, 230]
>>> list(islice(gen, 100000, 100015))
[542319, 542360, 542361, 542367, 542368, 542369, 542370, 542371, 542376, 542378, 542379, 542380, 542381, 542386, 542387]
>>> list(islice(gen, 1000000, 1000015))
[31279056, 31279058, 31279064, 31279065, 31279068, 31279084, 31279085, 31279086, 31279405, 31279406, 31279408, 31279450, 31279456, 31279458, 31279460]
```

This method is easily faster than generating all numbers with `range(9876543211)`

then filtering out those with repeated digits (which is what Moses Koledoye is doing):

```
>>> from timeit import timeit
>>> from itertools import islice
>>> def consume_n(it, n): next(islice(it, n, n), None)
...
>>> timeit('consume_n(gen(), 10000)', 'from __main__ import consume_n, unique_count as gen', number=100)
1.825788974761963
>>> timeit('consume_n(gen(), 10000)', 'from __main__ import consume_n, generate_unique_numbers as gen', number=100)
0.6307981014251709
```

The above code generates just the first 10000 numbers for each approach, and repeats those tests 100 times. My approach is easily 3 times faster!

Increase the count (and adjust the number of repetitions down to keep it manageable), and the contrast grows:

```
>>> timeit('consume_n(gen(), 100000)', 'from __main__ import consume_n, unique_count as gen', number=10)
4.125269889831543
>>> timeit('consume_n(gen(), 100000)', 'from __main__ import consume_n, generate_unique_numbers as gen', number=10)
0.6416079998016357
```

Now the difference has grown to 6x faster. Generating the first million numbers just once takes *23 seconds* with the `range`

version, .67 seconds with the above generator:

```
>>> timeit('consume_n(gen(), 1000000)', 'from __main__ import consume_n, unique_count as gen', number=1)
23.268329858779907
>>> timeit('consume_n(gen(), 1000000)', 'from __main__ import consume_n, generate_unique_numbers as gen', number=1)
0.6738729476928711
```

And the further along the series you go, the more natural numbers must be skipped and the speed difference only grows further; all numbers in the range 8800000000-8899999999 must be skipped for example, and the `range()`

approach will test *all* of those. That's 100 million wasted cycles!

The generator can produce all possible such numbers in 6.7 seconds on my laptop:

```
>>> from collections import deque
>>> def consume(it): deque(it, maxlen=0)
...
>>> timeit('consume(gen())', 'from __main__ import consume, generate_unique_numbers as gen', number=1)
6.6731719970703125
```

I didn't dare test how long the `range()`

approach takes; there are just under 9 million such numbers, but the `range()`

approach will test close to 10 billion possibilities, 10000 times more numbers than needed.

`len(str(i)) == len(set(str(i)))`

– joel goldstick Jul 27 '16 at 16:15