I was intrigued by this problem and wanted to explore generating arbitrary ranges.
I found that hex formatting seems to be the bottleneck and string formatting/concatenation in general.

There are ways that this code below could be further optimized. Aside from that I wanted dable with lookup tables and bitwise operations.

These solutions use about 10MB of ram at runtime. If the list was materialized using a list comprehension it uses over 1GB and takes longer...

My best solution so far, pre computes hex encodings into a list. 2 Hex ranges are encoded per lookup table to avoid the hit of string formatting. If I tried to use more Hex digits in a string the lookup table got too big and also tool longer to generate than the functions took to run.

**Fastest one because it handles about half as many strings**

```
from itertools import product
def generate_macs(first, last):
begin = int(first.replace(':', ''), 16)
end = int(last.replace(':', ''), 16) + 1
look_co = ['%02X:%02X:' % i for i in product(xrange(0x00, 0x100), repeat=2)]
look_ln = ['%02X:%02X\n' % i for i in product(xrange(0x00, 0x100), repeat=2)]
return ( look_co[i >> 32 & 0xFFFF] + \
look_co[i >> 16 & 0xFFFF] + \
look_ln[i & 0xFFFF] for i in xrange(begin, end))
```

Other versions use string formatting or 2hexdigit groupings string concatenated.

**Pure Hex Formatting**

```
def generate_macs(first, last):
begin = int(first.replace(':', ''), 16)
end = int(last.replace(':', ''), 16) + 1
return ( '%02X:%02X:%02X:%02X:%02X:%02X\n' % (
i >> 40 & 0xFF,
i >> 32 & 0xFF,
i >> 24 & 0xFF,
i >> 16 & 0xFF,
i >> 8 & 0xFF,
i & 0xFF) for i in xrange(begin, end))
```

**2Hex Digits per lookup string concated**

```
def generate_macs(first, last):
begin = int(first.replace(':', ''), 16)
end = int(last.replace(':', ''), 16) + 1
look_co = ['%02X:' % i for i in xrange(0x00, 0x100)]
look_ln = ['%02X\n' % i for i in xrange(0x00, 0x100)]
return ( look_co[i >> 40 & 0xFF] + \
look_co[i >> 32 & 0xFF] + \
look_co[i >> 24 & 0xFF] + \
look_co[i >> 16 & 0xFF] + \
look_co[i >> 8 & 0xFF] + \
look_ln[i & 0xFF] for i in xrange(begin, end))
```

**2Hex Digits per lookup string join**

```
def generate_macs(first, last):
begin = int(first.replace(':', ''), 16)
end = int(last.replace(':', ''), 16) + 1
look_co = ['%02X:' % i for i in xrange(0x00, 0x100)]
look_ln = ['%02X\n' % i for i in xrange(0x00, 0x100)]
return ( ''.join((look_co[i >> 40 & 0xFF],
look_co[i >> 32 & 0xFF],
look_co[i >> 24 & 0xFF],
look_co[i >> 16 & 0xFF],
look_co[i >> 8 & 0xFF],
look_ln[i & 0xFF])) for i in xrange(begin, end))
```

Code used to run it

```
f = open('foobar.txt', 'w')
f.writelines(generate_macs('E8:06:88:00:00:00', 'E8:06:88:FF:FF:FF'))
f.close()
```

The other solutions offered by Justin and Michael are both infinitely more readable/maintainable.
Michaels uses 4MB or ram on my machine. Justin's uses 1GB with it's List Comprehension and only 4MB if replaced with a Generator Expression (as he mentioned).
Mine use 10MB and runs about Twice fast, cost the Client probably 10 times as much and will continue to in the future.

The metrics used for performance was disk i/o in os/x's Activity Monitor and Mississippis.

**EDIT: New winner.**

**Fastest**
This one really screams and uses 4.1MB of ram. Generates output to /dev/null in 2 seconds.

```
def generate_macs():
from operator import add
from itertools import product
heads = [ 'E8:06:88:%02X:%01X' % i for i in product(xrange(0, 0x100), xrange(0, 0x10))]
tails = [ '%01X:%02X\n' % i for i in product(xrange(0, 0x10), xrange(0, 0x100))]
return starmap(add, product(heads, tails))
```

**Second Fastest**
almost as fast as the one above, arguably more readable. 4.1MB. Generates output to /dev/null in 3 seconds

```
def generate_macs():
from itertools import product
hexs = [':%02X' % h for h in xrange(0, 0x100)]
return imap(''.join, product(('E8:06:88',), hexs, hexs, hexs, ('\n',)))
```

**Conclusion**

- My final solutions have no lookup tables and no bitwise operations.
- There are interesting uses for
*product* as introduced by the other posters.
- Any time you can use implied loops and push things down to c (as I understand it) do.
- Format less, often.