Your solution 2: using hash value doesn't force a memory problem. You just have to partition the hash space into slices that fits into memory. More precisely:

Consider a hash table storing the set of records, each record is only represented by its index in the table. Say for example that such a hash table will be 4GB. Then you split your hash space in k=4 slice. Depending on the two last digits of the hash value, each record goes into one of the slice. So the algorithm would go roughly as follows:

```
let k = 2^M
for i from 0 to k-1:
t = new table
for each record r on the disk:
h = hashvalue(r)
if (the M last bit of h == i) {
insert r into t with respect to hash value h >> M
}
search t for duplicate and remove them
delete t from memory
```

The drawback is that you have to hash each record k times. The advantage is that is it can trivially be distributed.

Here is a prototype in Python:

```
# Fake huge database on the disks
records = ["askdjlsd", "kalsjdld", "alkjdslad", "askdjlsd"]*100
M = 2
mask = 2**(M+1)-1
class HashLink(object):
def __init__(self, idx):
self._idx = idx
self._hash = hash(records[idx]) # file access
def __hash__(self):
return self._hash >> M
# hashlink are equal if they link to equal objects
def __eq__(self, other):
return records[self._idx] == records[other._idx] # file access
def __repr__(self):
return str(records[self._idx])
to_be_deleted = list()
for i in range(2**M):
t = set()
for idx, rec in enumerate(records):
h = hash(rec)
if (h & mask == i):
if HashLink(idx) in t:
to_be_deleted.append(idx)
else:
t.add(HashLink(idx))
```

The result is:

```
>>> [records[idx] for idx in range(len(records)) if idx not in to_be_deleted]
['askdjlsd', 'kalsjdld', 'alkjdslad']
```