Representing these tokens in memory in 1 to 2Mb and also supporting
O(1) lookup will be really hard. None of the standard collection types would be able to do this for you,
and I'm not aware of any 3rd-party Java library that will either. (The S-Space project has a
TrieSet implementation, but I looked at the code, and I'm pretty sure it won't meet either your space or performance requirements ...)
Assuming that the characters in the string are ASCII, then turning them into String objects immediately doubles the size (
char), and then you need to add 32 bytes of overhead for each string. Then if you put the strings into a
HashSet you need roughly 32 additional bytes for each entry in the set.
ArrayList<String> the per-entry overhead is 4 bytes, but lookup is now
O(N) ... or
O(logN) if you keep the list ordered and use binary search. Either way you are still way over your memory budget.
To stay under your budget you are going to have to use a custom hash table data structure that is optimized for memory usage and hold your character data in memory as a single array of bytes.
Here is a hypothetical implementation.
- Allocate an
int to be hash array. The size should be a prime number that is roughly half to a fifth of the number of tokens.
- Allocate a
byte big enough to hold the file of tokens.
- For each slot in the hash array:
- scan the file byte-wise looking for all tokens whose hashcode maps to the slot,
- copy each token to the byte array and follow it with a terminator byte,
- if you found any tokens, write the byte array offset of the start of the first token to the hash array slot ... otherwise set it to
- To do a lookup:
- convert the test string to bytes,
- hash the bytes of your test string (using the same hash algorithm as above), and map it to a hash slot,
- starting at the offset in the hash slot, compare the bytes of the test string against the bytes in the
byte. Repeat until you get either a match, or you reach the offset in the next hash array element.
As you can see, the process of filling the
byte involves scanning the input file multiple times. However this could be done before hand, and the input file could then be updated to contain the bytes in the required order.
The space usage would be one byte per byte of string data + 1 byte overhead per string + 4 bytes for each slot in the primary hash array (+ sundry
O(1) overheads). Lookups are
O(1) on average, but the constant depends on the hash array size. (The larger, the better.)
The big drawbacks of the above design are:
- creating the data structure is expensive
- the data structure cannot be updated in a space or time efficient fashion
- if you iterate the set, you have to create a bunch of String objects to represent the entries ... or expose the byte array and offsets.