The thing is I need to do something that somehow uses the time
You could generate randomness based on a clock drift:
return struct.pack('!f', f)[-1] & 1
"Return k random bits using a relative drift of two clocks."
# assume time.sleep() and time.clock() use different clocks
# though it might work even if they use the same clock
#XXX it does not produce "good" random bits, see below for details
result = 0
for _ in range(k):
result <<= 1
result |= lastbit(time.clock())
Once you have
getrandbits(k), it is straigforward to get a random integer in range [a, b], including both end points. Based on CPython Lib/random.py:
def randint(a, b):
"Return random integer in range [a, b], including both end points."
return a + randbelow(b - a + 1)
"Return a random int in the range [0,n). Raises ValueError if n<=0."
# from Lib/random.py
if n <= 0:
k = n.bit_length() # don't use (n-1) here because n can be 1
r = getrandbits(k) # 0 <= r < 2**k
while r >= n: # avoid skew
r = getrandbits(k)
Example, to generate 20 random numbers from 10 to 110 including:
print(*[randint(10, 110) for _ in range(20)])
11 76 66 58 107 102 73 81 16 58 43 107 108 98 17 58 18 107 107 77
k random bits then
randint(a, b) should work as is (no skew due to modulo, etc).
To test the quality of
dieharder utility could be used:
$ python3 random-from-time.py | dieharder -a -g 200
random-from-time.py generates infinite (random) binary stream:
if __name__ == "__main__":
getrandbits(k) is defined above.
The above assumes that you are not allowed to use
ssl.RAND_bytes(), or some known PRNG algorithm such as Mersenne Twister to implement
getrandbits(n) implemented using "
dieharder tests (too many to be a coincidence).
The idea is still sound: a clock drift may be used as a source of randomness (entropy) but you can't use it directly (the distribution is not uniform and/or some bits are dependent); the bits could be passed as a seed to a PRNG that accepts an arbitrary entropy source instead. See "Mixing" section.