This spellfix1 virtual table can be used to search a large vocabulary for close matches. For example, spellfix1 can be used to suggest corrections to misspelled words. Or, it could be used with FTS4 to do full-text search using potentially misspelled words.
The implementation for the spellfix1 virtual table is held in the SQLite source tree in the miscellaneous extensions folder and in particular in the file ext/misc/spellfix1.c. The spellfix1 virtual table is not included in the SQLite amalgamation and is not a part of any standard SQLite build. It is a loadable extension.
Once the spellfix1 extension is loaded, an instance of the spellfix1 virtual table is created like this:
CREATE VIRTUAL TABLE demo USING spellfix1;
The "spellfix1" term is the name of the spellfix module and must be entered as shown. The "demo" term is the name of the virtual table you will be creating and can be altered to suit the needs of your application. The virtual table is initially empty. In order for the virtual table to be useful, you will need to populate it with your vocabulary. Suppose you have a list of words in a table named "big_vocabulary". Then do this:
INSERT INTO demo(word) SELECT word FROM big_vocabulary;
INSERT INTO demo(word) SELECT term FROM search_aux WHERE col='*';
You can also provide the virtual table with a "rank" for each word. The "rank" is an estimate of how common the word is. Larger numbers mean the word is more common. If you omit the rank when populating the table, then a rank of 1 is assumed. But if you have rank information, you can supply it and the virtual table will show a slight preference for selecting more commonly used terms. To populate the rank from an fts4aux table "search_aux" do something like this:
INSERT INTO demo(word,rank) SELECT term, documents FROM search_aux WHERE col='*';
To query the virtual table, include a MATCH operator in the WHERE clause. For example:
SELECT word FROM demo WHERE word MATCH 'kennasaw';
Using a dataset of American place names (derived from http://geonames.usgs.gov/domestic/download_data.htm) the query above returns 20 results beginning with:
kennesaw kenosha kenesaw kenaga keanak
If you append the character '*' to the end of the pattern, then a prefix search is performed. For example:
SELECT word FROM demo WHERE word MATCH 'kennes*';
Yields 20 results beginning with:
kennesaw kennestone kenneson kenneys keanes keenes
By default, the spellfix1 table returns no more than 20 results. (It might return less than 20 if there were fewer good matches.) You can change the upper bound on the number of returned rows by adding a "top=N" term to the WHERE clause of your query, where N is the new maximum. For example, to see the 5 best matches:
SELECT word FROM demo WHERE word MATCH 'kennes*' AND top=5;
Each entry in the spellfix1 virtual table is associated with a particular language, identified by the integer "langid" column. The default langid is 0 and if no other actions are taken, the entire vocabulary is a part of the 0 language. But if your application needs to operate in multiple languages, then you can specify different vocabulary items for each language by specifying the langid field when populating the table. For example:
INSERT INTO demo(word,langid) SELECT word, 0 FROM en_vocabulary; INSERT INTO demo(word,langid) SELECT word, 1 FROM de_vocabulary; INSERT INTO demo(word,langid) SELECT word, 2 FROM fr_vocabulary; INSERT INTO demo(word,langid) SELECT word, 3 FROM ru_vocabulary; INSERT INTO demo(word,langid) SELECT word, 4 FROM cn_vocabulary;
After the virtual table has been populated with items from multiple languages, specify the language of interest using a "langid=N" term in the WHERE clause of the query:
SELECT word FROM demo WHERE word MATCH 'hildes*' AND langid=1;
Note that if you do not include the "langid=N" term in the WHERE clause, the search will be against language 0 (English in the example above.) All spellfix1 searches are against a single language id. There is no way to search all languages at once.
Each row in the spellfix1 virtual table has a unique rowid with seven columns plus five extra hidden columns. The columns are as follows:
The spellfix1 virtual table creates a single shadow table named "%_vocab" (where the % is replaced by the name of the virtual table; Ex: "demo_vocab" for the "demo" virtual table). the shadow table contains the following columns:
There is also a function for computing the Wagner edit distance or the Levenshtein distance between a pattern and a word. This function is exposed as spellfix1_editdist(X,Y). The edit distance function returns the "cost" of converting X into Y. Some transformations cost more than others. Changing one vowel into a different vowel, for example is relatively cheap, as is doubling a constant, or omitting the second character of a double-constant. Other transformations or more expensive. The idea is that the edit distance function returns a low cost for words that are similar and a higher cost for words that are further apart. In this implementation, the maximum cost of any single-character edit (delete, insert, or substitute) is 100, with lower costs for some edits (such as transforming vowels).
The "score" for a comparison is the edit distance between the pattern and the word, adjusted down by the base-2 logarithm of the word rank. For example, a match with distance 100 but rank 1000 would have a score of 122 (= 100 - log2(1000) + 32) whereas a match with distance 100 with a rank of 1 would have a score of 131 (100 - log2(1) + 32). (NB: The constant 32 is added to each score to keep it from going negative in case the edit distance is zero.) In this way, frequently used words get a slightly lower cost which tends to move them toward the top of the list of alternative spellings.
A straightforward implementation of a spelling corrector would be to compare the search term against every word in the vocabulary and select the 20 with the lowest scores. However, there will typically be hundreds of thousands or millions of words in the vocabulary, and so this approach is not fast enough.
Suppose the term that is being spell-corrected is X. To limit the search space, X is converted to a k2-like key using the equivalent of:
key = spellfix1_phonehash(lower(spellfix1_translit(X)))
This key is then limited to "scope" characters. The default scope value is 4, but an alternative scope can be specified using the "scope=N" term in the WHERE clause. After the key has been truncated, the edit distance is run against every term in the vocabulary that has a k2 value that begins with the abbreviated key.
For example, suppose the input word is "Paskagula". The phonetic key is "BACACALA" which is then truncated to 4 characters "BACA". The edit distance is then run on the 4980 entries (out of 272,597 entries total) of the vocabulary whose k2 values begin with BACA, yielding "Pascagoula" as the best match.
Only terms of the vocabulary with a matching langid are searched. Hence, the same table can contain entries from multiple languages and only the requested language will be used. The default langid is 0.
The built-in Wagner edit-distance function with fixed weights can be replaced by the editdist3() edit-distance function with application-defined weights and support for unicode, by specifying the "edit_cost_table=TABLENAME" parameter to the spellfix1 module when the virtual table is created. For example:
CREATE VIRTUAL TABLE demo2 USING spellfix1(edit_cost_table=APPCOST);
The editdist3() edit-distance function can also be selected or deselected at run-time by inserting an appropriate string into the "command" column of the virtual table:
INSERT INTO demo2(command) VALUES('edit_cost_table=APPCOST');
In the examples above, the APPCOST table would be interrogated to find the edit distance coefficients. It is the presence of the "edit_cost_table=" parameter to the spellfix1 module name that causes editdist3() to be used in place of the built-in edit distance function. If APPCOST is an empty string, then the built-in Wagner edit-distance function is used.
The edit distance coefficients are normally read from the APPCOST table once and there after stored in memory. Hence, run-time changes to the APPCOST table will not normally affect the edit distance results. However, inserting the special string 'reset' into the "command" column of the virtual table causes the edit distance coefficients to be reread the APPCOST table. Hence, applications should run a SQL statement similar to the following when changes to the APPCOST table occur:
INSERT INTO demo2(command) VALUES("reset");
The algorithm above works quite well for most cases, but there are exceptions. These exceptions can be dealt with by making additional entries in the virtual table using the "soundslike" column.
For example, many words of Greek origin begin with letters "ps" where the "p" is silent. Ex: psalm, pseudonym, psoriasis, psyche. In another example, many Scottish surnames can be spelled with an initial "Mac" or "Mc". Thus, "MacKay" and "McKay" are both pronounced the same.
Accommodation can be made for words that are not spelled as they sound by making additional entries into the virtual table for the same word, but adding an alternative spelling in the "soundslike" column. For example, the canonical entry for "psalm" would be this:
INSERT INTO demo(word) VALUES('psalm');
To enhance the ability to correct the spelling of "salm" into "psalm", make an addition entry like this:
INSERT INTO demo(word,soundslike) VALUES('psalm','salm');
It is ok to make multiple entries for the same word as long as each entry has a different soundslike value. Note that if no soundslike value is specified, the soundslike defaults to the word itself.
Listed below are some cases where it might make sense to add additional soundslike entries. The specific entries will depend on the application and the target language.
The source code module that implements the spellfix1 virtual table also implements several SQL functions that might be useful to applications that employ spellfix1 or for testing or diagnostic work while developing applications that use spellfix1. The following auxiliary functions are available:
The editdist3 algorithm is a function that computes the minimum edit distance (a.k.a. the Levenshtein distance) between two input strings. The editdist3 algorithm is a configurable alternative to the default edit distance function of spellfix1. Features of editdist3 include:
It works with unicode (UTF8) text.
A table of insertion, deletion, and substitution costs can be provided by the application.
Multi-character insertions, deletions, and substitutions can be enumerated in the cost table.
To program the costs of editdist3, create a table such as the following:
CREATE TABLE editcost( iLang INT, -- The language ID cFrom TEXT, -- Convert text from this cTo TEXT, -- Convert text into this iCost INT -- The cost of doing the conversion );
The cost table can be named anything you want - it does not have to be called "editcost". And the table can contain additional columns. The only requirement is that the table must contain the four columns show above, with exactly the names shown.
The iLang column is a non-negative integer that identifies a set of costs appropriate for a particular language. The editdist3 function will only use a single iLang value for any given edit-distance computation. The default value is 0. It is recommended that applications that only need to use a single language always use iLang==0 for all entries.
The iCost column is the numeric cost of transforming cFrom into cTo. This value should be a non-negative integer, and should probably be less than 100. The default single-character insertion and deletion costs are 100 and the default single-character to single-character substitution cost is 150. A cost of 10000 or more is considered "infinite" and causes the rule to be ignored.
The cFrom and cTo columns show edit transformation strings. Either or both columns may contain more than one character. Or either column (but not both) may hold an empty string. When cFrom is empty, that is the cost of inserting cTo. When cTo is empty, that is the cost of deleting cFrom.
In the spellfix1 algorithm, cFrom is the text as the user entered it and cTo is the correctly spelled text as it exists in the database. The goal of the editdist3 algorithm is to determine how close the user-entered text is to the dictionary text.
There are three special-case entries in the cost table:
|The default insertion cost
|The default deletion cost
|The default substitution cost
If any of the special-case entries shows above are omitted, then the value of 100 is used for insertion and deletion and 150 is used for substitution. To disable the default insertion, deletion, and/or substitution set their respective cost to 10000 or more.
Other entries in the cost table specific transforms for particular characters. The cost of specific transforms should be less than the default costs, or else the default costs will take precedence and the specific transforms will never be used.
Some example, cost table entries:
INSERT INTO editcost(iLang, cFrom, cTo, iCost) VALUES(0, 'a', 'ä', 5);
The rule above says that the letter "a" in user input can be matched against the letter "ä" in the dictionary with a penalty of 5.
INSERT INTO editcost(iLang, cFrom, cTo, iCost) VALUES(0, 'ss', 'ß', 8);
The number of characters in cFrom and cTo do not need to be the same. The rule above says that "ss" on user input will match "ß" with a penalty of 8.
The spellfix1 virtual table uses editdist3 if the "edit_cost_table=TABLE" option is specified as an argument when the spellfix1 virtual table is created. But editdist3 can also be tested directly using the built-in "editdist3()" SQL function. The editdist3() SQL function has 3 forms:
The first form loads the edit distance coefficients from a table called 'TABLENAME'. Any prior coefficients are discarded. So when experimenting with weights and the weight table changes, simply rerun the single-argument form of editdist3() to reload revised coefficients. Note that the edit distance weights used by the editdist3() SQL function are independent from the weights used by the spellfix1 virtual table.
The second and third forms return the computed edit distance between strings 'string1' and "string2'. In the second form, a language id of 0 is used. The language id is specified in the third form.
This page last modified on 2023-10-10 17:29:48 UTC