Trie fields make range queries faster by precomputing certain range results and storing them as a single record in the index. For clarity, my example will use integers in base ten. The same concept applies to all trie types. This includes dates, since a date can be represented as the number of seconds since, say, 1970.
Let's say we index the number
12345678. We can tokenize this into the following tokens.
12345678 token represents the actual integer value. The tokens with the
x digits represent ranges.
123456xx represents the range
12345699, and matches all the documents that contain a token in that range.
Notice how in each token on the list has successively more
x digits. This is controlled by the precision step. In my example, you could say that I was using a precision step of 2, since I trim 2 digits to create each extra token. If I were to use a precision step of 3, I would get these tokens.
A precision step of 4:
A precision step of 1:
It's easy to see how a smaller precision step results in more tokens and increases the size of the index. However, it also speeds up range queries.
Without the trie field, if I wanted to query a range from 1250 to 1275, Lucene would have to fetch 25 entries (
1275) and combine search results. With a trie field (and precision step of 1), we could get away with fetching 8 entries (
125x is a precomputed aggregation of
1259. If I were to use a precision step larger than 1, the query would go back to fetching all 25 individual entries.
Note: In reality, the precision step refers to the number of bits trimmed for each token. If you were to write your numbers in hexadecimal, a precision step of 4 would trim one hex digit for each token. A precision step of 8 would trim two hex digits.