```
lst = [ ('Orange', 0.10), ('Apple', 0.05), ('Mango', 0.15), ('etc', 0.69) ]
x = 0.0
lst2 = []
for fruit, chance in lst:
tup = (x, fruit)
lst2.append(tup)
x += chance
tup = (x, None)
lst2.append(tup)
import random
def pick_one(lst2):
if lst2[0][1] is None:
raise ValueError, "no valid values to choose"
while True:
r = random.random()
for x, fruit in reversed(lst2):
if x <= r:
if fruit is None:
break # try again with a different random value
else:
return fruit
pick_one(lst2)
```

This builds a new list, with ascending values representing the range of values that choose a fruit; then pick_one() walks backward down the list, looking for a value that is <= the current random value. We put a "sentinel" value on the end of the list; if the values don't reach 1.0, there is a chance of a random value that shouldn't match anything, and it will match the sentinel value and then be rejected. random.random() returns a random value in the range [0.0, 1.0) so it is certain to match something in the list eventually.

The nice thing here is that you should be able to have one value with a 0.000001 chance of matching, and it should actually match with that frequency; the other solutions, where you make a list with the items repeated and just use random.choice() to choose one, would require a list with a million items in it to handle this case.