It's an interview question:
There are 1 billion cell-phone numbers which has 11 digits, they are stored randomly in a file, for example 12345678910, the first digit gotta be 1. Go through these numbers to see whether there is one with duplicate, just see if duplicate exists, if duplicate found, return True, or return False. Only 10 MB memory allowed.
Here is my solution:
Hash all these numbers into 1000 files using
hash(num)%1000, then the duplicates should fall into the same file.
After the hashing, I got 1000 small files, each of which contains
1 million numbers
at most, right? I'm not sure about this, I simply do it
1 billion / 1000 = 1 million.
Then for each file, build a hash table to store each number and a
flag representing its occurrence.
I guess, it will take
5 B to represent the number,
4 B for the lower
8 digits and
1 B for the upper
3 digits; and actually
1 bit will suffice the
flag, because I just need to find out whether duplicate exists, only how many times. But how can I apply the
1 bit flag to each number? I'm stumbled, so I choose
bool to be the flag,
1 B is taken.
So finally, each number in the hash table will take
5B<for number> + 1B<for flag> + 4B<for the next-pointer> = 10B, then each file will take
10M for the hash table.
That's my stupid solution, Please give me a better one.
If there are
no duplicatesin these 1 billion phone numbers, given one phone number, how to find out the given one
is or is not inthese 1 billion numbers? Use as few memory as possible.
I came up with 2 solutions,
The phone number can be represented using 5B as I said above, scan through the file, read one number a time, and
xor the given number with the one read from the file, if the result is
0, then the given one is in the file, it'll take
Partitionthese numbers into
2 small filesaccording to the
leading bit, which means, those numbers with a
leading 1-bitgo to a file,
leading 0-bitgo to another file, meanwhile count how many numbers in each file, if the given number fall into the 1-bit file and the 1-bit file's
not full, then
again partitionthe 1-bit file according to the
secondary leading-bit, and check the given number recursively; if the 1-bit file
is full, then the given number gotta be in the file, it'll take