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I have an English dictionary in a MySQL database with just over 250K entries, and I'm using a simple ruby front-end to search it using wildcards at the beginning of the strings. So far I've been doing it like this:

SELECT * FROM words WHERE word LIKE '_e__o'

or even

SELECT * FROM words WHERE word LIKE '____s'

I always know the exact length of the word, but all but a single character are potentially unknown.

This is slower than molasses, about fifteen times slower than a similar query without the leading wildcard because the index for the column cannot be used.

I've tried a few methods to narrow the scope of the search. For example, I've added 26 additional columns containing each word's individual letter counts and narrow the search using those first. I've also tried narrowing by word length. These methods made almost no difference, thanks to the inherent inefficiency of leading-wildcard searches. I've experimented with the REGEXP statement, which is even slower.

SQLite and PostgreSQL are just as limited as MySQL, and though I have limited experience with NoSQL systems, my research gives me the impression that they excel at scalability, not performance of the kind I need.

My question then, is where should I look for a solution? Should I continue trying to find a way to optimize my queries or add supplementary columns that can narrow my potential recordset? Are there systems designed specifically to accomplish fast wildcard searching in this vein?

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You probably want to explore FTS (full text search) options. SQLite FTS4 works well in my experience, dunno about others. –  ergosys Apr 11 '12 at 22:05
Are all your (slow) queries of this type? word LIKE '__e_b__on' ? –  ypercube Apr 11 '12 at 22:20
@ergosys - from what I understand, MySQL fts can't perform leading wildcard searches on single words. –  Daniel Apr 11 '12 at 22:23
@ypercube - yes, they are –  Daniel Apr 11 '12 at 22:27
I verified, SQLite has the same limitation. You might get some ideas from the article linked from code.google.com/p/codesearch which uses trigram indexing at its core. –  ergosys Apr 11 '12 at 22:42

8 Answers 8

up vote 4 down vote accepted

With PostgreSQL 9.1 and the pg_trgm extension you can create indexes that are usable for a like condition you are describing.

For an example see here: http://www.depesz.com/2011/02/19/waiting-for-9-1-faster-likeilike/

I verified it on a table with 300k rows using LIKE '____1' and it does use such an index. It took about 120ms to count the number of rows in that table (on an old laptop). Interesting enough the expression LIKE 'd___1' is not faster, it's about the same speed.

It also depends on the number of characters in the search term, the longe it gets, the slower it will be as far as I can tell.

You would need to check with your data if the performance is acceptable.

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Wow, this is exactly what I was looking for. The performance in most cases is phenomenal. There are still some queries that take a while, but overall this is the way to go in my case. –  Daniel Apr 12 '12 at 17:51
Postgres friggen rocks.. I don't understand why more people don't use it.. –  Mike Christensen Apr 13 '12 at 15:23

I'm assuming that the time initially taken to insert the words and set-up your indexing is inconsequential. Also, you would not do updates to the word list very often so it's basically static data.

You could try an approach like this:-

  • Since you always know the word length, create a table containing all the words of length 1, another table of words length 2, etc.
  • When you conduct a query, select out of the appropriate table based on word length. It will still need to do a full scan of that table.

If you RDBMS allows it, you would be better off with a single table and partitions by word length.

If that is still not fast enough, you could further split it by length and known letter. For example, you could have a table listing all 8 letter words containing a "Z".

When you query, you know you have a 8 letter word containing an "E" and "Z". First query the data dictionary to see which letter is rarest in 8 letter words, and then scan that table. By query the data dictionary, I mean figure out if table words_8E or table words_8z has the least number of records.

Regarding Normal Forms and Good Practice

This is not the sort of thing I would typically recommend when modelling data. In your particular case, storing the entire word in a single character column is not actually in 1st normal form. This is because you care about individual elements within the word. Given your use case, a word is a list of letters than a single word. As always, how to model depends on what you care about.

Your queries are giving you trouble because it's not in first normal form.

The fully normalised model for this problem would have two tables: word (WordId PK) and WordLetter (WordId PK, Position PK, Letter). You would then query for all words with multiple WHERE EXISTS a letter in the appropriate position.

While correct according to database theory, I do not think this will perform well.

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It all comes down to indexing.

You can create table like:

create table letter_index (
    id integer not null primary key,
    letter varchar(1),
    position integer

create unique index letter_index_i1 (letter, position)

create table letter_index_words (
    letter_index_id integer,
    word_id integer

Then index all of your words.

If you want a list of all words with an 'e' in the 2nd position:

select words.* from words, letter_index_word liw, letter_index li
where li.letter = 'e' and li.position = 2
and liw.letter_index_id = li.id
and words.id = liw.word_id

If you want all of the words with 'e' in the 2nd position, and 's' in the fifth position:

select words.* from words, letter_index_word liw, letter_index li
where li.letter = 'e' and li.position = 2
and liw.letter_index_id = li.id
and words.id = liw.word_id
and words.id in (
    select liw.word_id from letter_index_word liw, letter_index li
    where li.letter = 's' and li.position = 5
    and liw.letter_index_id = li.id

Or you can run two simple queries and merge the results yourself.

Of course, simply caching and iterating through the list in memory is likely faster than any of these. But not fast enough to be worth loading the 250K list from the DB every time.

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It's funny how at least 3 answers have the exact same idea :) –  ypercube Apr 11 '12 at 23:01

You can index this query fully without having to scan any more than the size of the result set which is optimal.

Create a lookup table like so:

Table:  lookup
pattern     word_id
_o_s_       1
_ous_       1

Which references your word table:

Table:  word
word_id     word
1           mouse

Put an index on pattern and execute a select like so:

select w.word
from lookup l, word w
where l.pattern = '_ous_' and
l.word_id = w.word_id;

Of course you'll need a little ruby script to create this lookup table where pattern is every possible pattern for every word in the dictionary. In other words the patterns for mouse would be:


The ruby to generate all patterns for a given word could look like:

def generate_patterns word
  return [word, '_'] if word.size == 1
  generate_patterns(word[1..-1]).map do |sub_word|
    [word[0] + sub_word, '_' + sub_word]

For example:

> generate_patterns 'mouse'
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A quick way to get it down by a factor of 10 or so is to create a column for string length, put an index on it, and use it in the where clause.

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This does help a lot in many cases, and combined with @a_horse_with_no_name's answer was able to provide me with the performance improvements I was looking for. Thanks! –  Daniel Apr 12 '12 at 17:53

You can try using Apache Lucene, a full text search engine. It was made to answer queries like this, so you might have more luck.

Wildcard searching with lucene.

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It appears you can't use a wildcard as a prefix in the search. I believe mySQL has the same limitation in its FTS, due to the way the index is stored. I would think the more letters you have up front, the faster the search will be, so _____s is probably going to be just as slow as not having an index at all. Doing s_____s would probably be pretty slow if you had thousands of s words. –  Mike Christensen Apr 11 '12 at 22:23
One could write a custom tokenizer for Lucene that emits tokens to be indexed based upon the reverse of each token, just the suffix fragments, or special sentinel fragments (if it is necessary to specifically handle s____s and similar wildcards. ex. word -> w~d, letter -> l~r; then alter a query against the index to look for s____s via indexed s~s). –  meklarian Apr 12 '12 at 0:19

Create an in memory lookup table solution: You could have a sorted table for each length.

Then to match, say you know 4th and 8th letter, loop through the words checking only each 4th letter. They are all same length so that will be quick. Only if letter matches check 8th letter.

it's brute force, but will be fast. Let's say worst case you have 50,000 8 letter words. Thats 50,000 comparisons. assuming ruby run time perf issues it should still be < 1sec.

Memory required would be 250k x 10. So 2.5 Meg.

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This is more of an exercise than a real-life solution. The idea is to split the words into characters.

Lets design the needed table first. I assume your words table has the columns word_id, word, size:

CREATE TABLE letter_search
( word_id INT NOT NULL
, letter CHAR(1) NOT NULL
, PRIMARY KEY (word_id, position)
, FOREIGN KEY (word_id)
    REFERENCES words (word_id)
, INDEX position_letter_idx (position, letter)
, INDEX letter_idx (letter)
) ENGINE = InnoDB ;

We'll need an auxilary "numbers" table:

) ;

INSERT INTO num (i)               --- I suppose you don't have
VALUES                            --- words with 100 letters
  (1), (2), ..., (100) ;

To populate our letter_search table:

INSERT INTO letter_search
  ( word_id, position, letter )
  , num.i
  , SUBSTRING( w.word, num.i, 1 ) 
    words AS w
       ON num.i <= w.size

The size of this search table will be about 10 * 250K rows (where 10, put the average size of your words).

Finally, the query:

SELECT * FROM words WHERE word LIKE '_e__o'

will be written as:

    words AS w
    letter_search AS s2
        ON (s2.position, s2.letter, s2.word_id) = (2, 'e', w.word_id)
    letter_search AS s5
        ON (s5.position, s5.letter, s5.word_id) = (5, 'o', w.word_id)
    w.size = 5
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