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APPLIES TO: SQL Server Azure SQL Database Azure Synapse Analytics Parallel Data Warehouse

Full-Text Search in SQL Server and Azure SQL Database lets users and applications run full-text queries against character-based data in SQL Server tables.

Basic tasks

This topic provides an overview of Full-Text Search and describes its components and its architecture. If you prefer to get started right away, here are the basic tasks.

Note

Full-Text Search is an optional component of the SQL Server Database Engine. If you didn't select Full-Text Search when you installed SQL Server, run SQL Server Setup again to add it.

Overview

A full-text index includes one or more character-based columns in a table. These columns can have any of the following data types: char, varchar, nchar, nvarchar, text, ntext, image, xml, or varbinary(max) and FILESTREAM. Each full-text index indexes one or more columns from the table, and each column can use a specific language.

Full-text queries perform linguistic searches against text data in full-text indexes by operating on words and phrases based on the rules of a particular language such as English or Japanese. Full-text queries can include simple words and phrases or multiple forms of a word or phrase. A full-text query returns any documents that contain at least one match (also known as a hit). A match occurs when a target document contains all the terms specified in the full-text query, and meets any other search conditions, such as the distance between the matching terms.

Full-Text Search queries

After columns have been added to a full-text index, users and applications can run full-text queries on the text in the columns. These queries can search for any of the following:

  • One or more specific words or phrases (simple term)

  • A word or a phrase where the words begin with specified text (prefix term)

  • Inflectional forms of a specific word (generation term)

  • A word or phrase close to another word or phrase (proximity term)

  • Synonymous forms of a specific word (thesaurus)

  • Words or phrases using weighted values (weighted term)

Full-text queries are not case-sensitive. For example, searching for 'Aluminum' or 'aluminum' returns the same results.

Full-text queries use a small set of Transact-SQL predicates (CONTAINS and FREETEXT) and functions (CONTAINSTABLE and FREETEXTTABLE). However, the search goals of a given business scenario influence the structure of the full-text queries. For example:

  • e-business-searching for a product on a website:

  • Recruitment scenario-searching for job candidates that have experience working with SQL Server:

For more information, see Query with Full-Text Search.

Compare Full-Text Search queries to the LIKE predicate

In contrast to full-text search, the LIKE Transact-SQL predicate works on character patterns only. Also, you cannot use the LIKE predicate to query formatted binary data. Furthermore, a LIKE query against a large amount of unstructured text data is much slower than an equivalent full-text query against the same data. A LIKE query against millions of rows of text data can take minutes to return; whereas a full-text query can take only seconds or less against the same data, depending on the number of rows that are returned.

Full-Text Search architecture

Full-text search architecture consists of the following processes:

  • The SQL Server process (sqlservr.exe).

  • The filter daemon host process (fdhost.exe).

    For security reasons, filters are loaded by separate processes called the filter daemon hosts. The fdhost.exe processes are created by an FDHOST launcher service (MSSQLFDLauncher), and they run under the security credentials of the FDHOST launcher service account. Therefore, the FDHOST launcher service must be running for full-text indexing and full-text querying to work. For information about setting the service account for this service, see Set the Service Account for the Full-text Filter Daemon Launcher.

These two processes contain the components of the full-text search architecture. These components and their relationships are summarized in the following illustration. The components are described after the illustration.

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SQL Server process

The SQL Server process uses the following components for full-text search:

  • User tables. These tables contain the data to be full-text indexed.

  • Full-text gatherer. The full-text gatherer works with the full-text crawl threads. It is responsible for scheduling and driving the population of full-text indexes, and also for monitoring full-text catalogs.

  • Thesaurus files. These files contain synonyms of search terms. For more information, see Configure and Manage Thesaurus Files for Full-Text Search.

  • Stoplist objects. Stoplist objects contain a list of common words that are not useful for the search. For more information, see Configure and Manage Stopwords and Stoplists for Full-Text Search.

  • SQL Server query processor. The query processor compiles and executes SQL queries. If a SQL query includes a full-text search query, the query is sent to the Full-Text Engine, both during compilation and during execution. The query result is matched against the full-text index.

  • Full-Text Engine. The Full-Text Engine in SQL Server is fully integrated with the query processor. The Full-Text Engine compiles and executes full-text queries. As part of query execution, the Full-Text Engine might receive input from the thesaurus and stoplist.

    Note

    In SQL Server 2008 and later versions, the Full-Text Engine resides in the SQL Server process, rather than in a separate service. Integrating the Full-Text Engine into the Database Engine improved full-text manageability, optimization of mixed query, and overall performance.

  • Index writer (indexer). The index writer builds the structure that is used to store the indexed tokens.

  • Filter daemon manager. The filter daemon manager is responsible for monitoring the status of the Full-Text Engine filter daemon host.

Filter Daemon Host process

The filter daemon host is a process that is started by the Full-Text Engine. It runs the following full-text search components, which are responsible for accessing, filtering, and word breaking data from tables, as well as for word breaking and stemming the query input.

The components of the filter daemon host are as follows:

  • Protocol handler. This component pulls the data from memory for further processing and accesses data from a user table in a specified database. One of its responsibilities is to gather data from the columns being full-text indexed and pass it to the filter daemon host, which will apply filtering and word breaker as required.

  • Filters. Some data types require filtering before the data in a document can be full-text indexed, including data in varbinary, varbinary(max), image, or xml columns. The filter used for a given document depends on its document type. For example, different filters are used for Microsoft Word (.doc) documents, Microsoft Excel (.xls) documents, and XML (.xml) documents. Then the filter extracts chunks of text from the document, removing embedded formatting and retaining the text and, potentially, information about the position of the text. The result is a stream of textual information. For more information, see Configure and Manage Filters for Search.

  • Word breakers and stemmers. A word breaker is a language-specific component that finds word boundaries based on the lexical rules of a given language (word breaking). Each word breaker is associated with a language-specific stemmer component that conjugates verbs and performs inflectional expansions. At indexing time, the filter daemon host uses a word breaker and stemmer to perform linguistic analysis on the textual data from a given table column. The language that is associated with a table column in the full-text index determines which word breaker and stemmer are used for indexing the column. For more information, see Configure and Manage Word Breakers and Stemmers for Search.

    Note

    SQL Server 2012 (11.x) installs a new version of the word breakers and stemmers for US English (LCID 1033) and UK English (LCID 2057).However you can switch to the previous version of these components if you want to retain the previous behavior. For more information, see Change the Word Breaker Used for US English and UK English.

Full-Text Search processing

Full-text search is powered by the Full-Text Engine. The Full-Text Engine has two roles: indexing support and querying support.

Full-Text indexing process

When a full-text population (also known as a crawl) is initiated, the Full-Text Engine pushes large batches of data into memory and notifies the filter daemon host. The host filters and word breaks the data and converts the converted data into inverted word lists. The full-text search then pulls the converted data from the word lists, processes the data to remove stopwords, and persists the word lists for a batch into one or more inverted indexes.

When indexing data stored in a varbinary(max) or image column, the filter, which implements the IFilter interface, extracts text based on the specified file format for that data (for example, Microsoft Word). In some cases, the filter components require the varbinary(max), or image data to be written out to the filterdata folder, instead of being pushed into memory.

As part of processing, the gathered text data is passed through a word breaker to separate the text into individual tokens, or keywords. The language used for tokenization is specified at the column level, or can be identified within varbinary(max), image, or xml data by the filter component.

Additional processing may be performed to remove stopwords, and to normalize tokens before they are stored in the full-text index or an index fragment.

When a population has completed, a final merge process is triggered that merges the index fragments together into one master full-text index. This results in improved query performance since only the master index needs to be queried rather than a number of index fragments, and better scoring statistics may be used for relevance ranking.

Full-Text querying process

The query processor passes the full-text portions of a query to the Full-Text Engine for processing. The Full-Text Engine performs word breaking and, optionally, thesaurus expansions, stemming, and stopword (noise-word) processing. Then the full-text portions of the query are represented in the form of SQL operators, primarily as streaming table-valued functions (STVFs). During query execution, these STVFs access the inverted index to retrieve the correct results. The results are either returned to the client at this point, or they are further processed before being returned to the client.

Full-text index architecture

The information in full-text indexes is used by the Full-Text Engine to compile full-text queries that can quickly search a table for particular words or combinations of words. A full-text index stores information about significant words and their location within one or more columns of a database table. A full-text index is a special type of token-based functional index that is built and maintained by the Full-Text Engine for SQL Server. The process of building a full-text index differs from building other types of indexes. Instead of constructing a B-tree structure based on a value stored in a particular row, the Full-Text Engine builds an inverted, stacked, compressed index structure based on individual tokens from the text being indexed. The size of a full-text index is limited only by the available memory resources of the computer on which the instance of SQL Server is running.

Beginning in SQL Server 2008, the full-text indexes are integrated with the Database Engine, instead of residing in the file system as in previous versions of SQL Server. For a new database, the full-text catalog is now a virtual object that does not belong to any filegroup; it is merely a logical concept that refers to a group of the full-text indexes. Note, however, that during upgrade of a SQL Server 2005 (9.x) database, any full-text catalog that contains data files, a new filegroup is created; for more information, see Upgrade Full-Text Search.

Only one full-text index is allowed per table. For a full-text index to be created on a table, the table must have a single, unique nonnull column. You can build a full-text index on columns of type char, varchar, nchar, nvarchar, text, ntext, image, xml, varbinary, and varbinary(max) can be indexed for full-text search. Creating a full-text index on a column whose data type is varbinary, varbinary(max), image, or xml requires that you specify a type column. A type column is a table column in which you store the file extension (.doc, .pdf, .xls, and so forth) of the document in each row.

Full-text index structure

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A good understanding of the structure of a full-text index will help you understand how the Full-Text Engine works. This topic uses the following excerpt of the Document table in Adventure Works as an example table. This excerpt shows only two columns, the DocumentID column and the Title column, and three rows from the table.

For this example, we will assume that a full-text index has been created on the Title column.

DocumentIDTitle
1Crank Arm and Tire Maintenance
2Front Reflector Bracket and Reflector Assembly 3
3Front Reflector Bracket Installation

For example, the following table, which shows Fragment 1, depicts the contents of the full-text index created on the Title column of the Document table. Full-text indexes contain more information than is presented in this table. The table is a logical representation of a full-text index and is provided for demonstration purposes only. The rows are stored in a compressed format to optimize disk usage.

Notice that the data has been inverted from the original documents. Inversion occurs because the keywords are mapped to the document IDs. For this reason, a full-text index is often referred to as an inverted index.

Also notice that the keyword 'and' has been removed from the full-text index. This is done because 'and' is a stopword, and removing stopwords from a full-text index can lead to substantial savings in disk space thereby improving query performance. For more information about stopwords, see Configure and Manage Stopwords and Stoplists for Full-Text Search.

Fragment 1

KeywordColIdDocIdOccurrence
Crank111
Arm112
Tire114
Maintenance115
Front121
Front131
Reflector122
Reflector125
Reflector132
Bracket123
Bracket133
Assembly126
3127
Installation134

The Keyword column contains a representation of a single token extracted at indexing time. Word breakers determine what makes up a token.

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The ColId column contains a value that corresponds to a particular column that is full-text indexed.

The DocId column contains values for an eight-byte integer that maps to a particular full-text key value in a full-text indexed table. This mapping is necessary when the full-text key is not an integer data type. In such cases, mappings between full-text key values and DocId values are maintained in a separate table called the DocId Mapping table. To query for these mappings use the sp_fulltext_keymappings system stored procedure. To satisfy a search condition, DocId values from the above table need to be joined with the DocId Mapping table to retrieve rows from the base table being queried. If the full-text key value of the base table is an integer type, the value directly serves as the DocId and no mapping is necessary. Therefore, using integer full-text key values can help optimize full-text queries.

The Occurrence column contains an integer value. For each DocId value, there is a list of occurrence values that correspond to the relative word offsets of the particular keyword within that DocId. Occurrence values are useful in determining phrase or proximity matches, for example, phrases have numerically adjacent occurrence values. They are also useful in computing relevance scores; for example, the number of occurrences of a keyword in a DocId may be used in scoring.

Full-text index fragments

The logical full-text index is usually split across multiple internal tables. Each internal table is called a full-text index fragment. Some of these fragments might contain newer data than others. For example, if a user updates the following row whose DocId is 3 and the table is auto change-tracked, a new fragment is created.

DocumentIDTitle
3Rear Reflector

In the following example, which shows Fragment 2, the fragment contains newer data about DocId 3 compared to Fragment 1. Therefore, when the user queries for 'Rear Reflector' the data from Fragment 2 is used for DocId 3. Each fragment is marked with a creation timestamp that can be queried by using the sys.fulltext_index_fragments catalog view.

Fragment 2

KeywordColIdDocIdOcc
Rear131
Reflector132

As can be seen from Fragment 2, full-text queries need to query each fragment internally and discard older entries. Therefore, too many full-text index fragments in the full-text index can lead to substantial degradation in query performance. To reduce the number of fragments, reorganize the fulltext catalog by using the REORGANIZE option of the ALTER FULLTEXT CATALOGTransact-SQL statement. This statement performs a master merge, which merges the fragments into a single larger fragment and removes all obsolete entries from the full-text index.

After being reorganized, the example index would contain the following rows:

KeywordColIdDocIdOcc
Crank111
Arm112
Tire114
Maintenance115
Front121
Rear131
Reflector122
Reflector125
Reflector132
Bracket123
Assembly126
3127

Differences between full-text indexes and regular SQL Server indexes:.

Full-text indexesRegular SQL Server indexes
Only one full-text index allowed per table.Several regular indexes allowed per table.
The addition of data to full-text indexes, called a population, can be requested through either a schedule or a specific request, or can occur automatically with the addition of new data.Updated automatically when the data upon which they are based is inserted, updated, or deleted.
Grouped within the same database into one or more full-text catalogs.Not grouped.

Full-Text search linguistic components and language support

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Full-text search supports almost 50 diverse languages, such as English, Spanish, Chinese, Japanese, Arabic, Bangla, and Hindi. For a complete list of the supported full-text languages, see sys.fulltext_languages (Transact-SQL). Each of the columns contained in the full-text index is associated with a Microsoft Windows locale identifier (LCID) that equates to a language that is supported by full-text search. For example, LCID 1033 equates to U.S English, and LCID 2057 equates to British English. For each supported full-text language, SQL Server provides linguistic components that support indexing and querying full-text data that is stored in that language.

Language-specific components include the following:

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  • Word breakers and stemmers. A word breaker finds word boundaries based on the lexical rules of a given language (word breaking). Each word breaker is associated with a stemmer that conjugates verbs for the same language. For more information, see Configure and Manage Word Breakers and Stemmers for Search.

  • Stoplists. A system stoplist is provided that contains a basic set stopwords (also known as noise words). A stopword is a word that does not help the search and is ignored by full-text queries. For example, for the English locale words such as 'a', 'and', 'is', and 'the' are considered stopwords. Typically, you will need to configure one or more thesaurus files and stoplists. For more information, see Configure and Manage Stopwords and Stoplists for Full-Text Search.

  • Thesaurus files. SQL Server also installs a thesaurus file for each full-text language, as well as a global thesaurus file. The installed thesaurus files are essentially empty, but you can edit them to define synonyms for a specific language or business scenario. By developing a thesaurus tailored to your full-text data, you can effectively broaden the scope of full-text queries on that data. For more information, see Configure and Manage Thesaurus Files for Full-Text Search.

  • Filters (iFilters). Indexing a document in a varbinary(max), image, or xml data type column requires a filter to perform extra processing. The filter must be specific to the document type (.doc, .pdf, .xls, .xml, and so forth). For more information, see Configure and Manage Filters for Search.

Word breakers (and stemmers) and filters run in the filter daemon host process (fdhost.exe).

A daemon process is a process which runs in background and has no controlling terminal.

Since a daemon process usually has no controlling terminal so almost no user interaction is required. Daemon processes are used to provide services that can well be done in background without any user interaction.

For example a process that runs in background and observes network activity and logs any suspicious communication can be developed as a daemon process.

Daemon Process Design

A daemon process can be developed just like any other process but there is one thing that differentiates it with any other normal process ie having no controlling terminal. This is a major design aspect in creating a daemon process. This can be achieved by :

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  • Create a normal process (Parent process)
  • Create a child process from within the above parent process
  • The process hierarchy at this stage looks like : TERMINAL -> PARENT PROCESS -> CHILD PROCESS
  • Terminate the the parent process.
  • The child process now becomes orphan and is taken over by the init process.
  • Call setsid() function to run the process in new session and have a new group.
  • After the above step we can say that now this process becomes a daemon process without having a controlling terminal.
  • Change the working directory of the daemon process to root and close stdin, stdout and stderr file descriptors.
  • Let the main logic of daemon process run.

So we see that above steps mark basic design steps for creating a daemon.

C fork() Function

Before creating an actual running daemon following the above stated design steps, lets first learn a bit about the fork() system call.

fork() system creates a child process that is exact replica of the parent process. This new process is referred as ‘child’ process.

This system call gets called once (in parent process) but returns twice (once in parent and second time in child). Note that after the fork() system call, whether the parent will run first or the child is non-deterministic. It purely depends on the context switch mechanism. This call returns zero in child while returns PID of child process in the parent process.

Following are some important aspects of this call :

  • The child has its own unique process ID, and this PID does not match the ID of any existing process group.
  • The child’s parent process ID is the same as the parent’s process ID.
  • The child does not inherit its parent’s memory locks.
  • Process resource utilization and CPU time counters are reset to zero in the child.
  • The child’s set of pending signals is initially empty.
  • The child does not inherit semaphore adjustments from its parent.
  • The child does not inherit record locks from its parent.
  • The child does not inherit timers from its parent.
  • The child does not inherit outstanding asynchronous I/O operations from its parent, nor does it inherit any asynchronous I/O contexts from its parent.

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For more insight information, please read the man page of this system call.

The Implementation

Based on the design as mentioned in the first section. Here is the complete implementation :

Following is the way through which the code was compiled and executed:

Just observe that the control immediately came back to the terminal ie the daemon is now not associated to any terminal.

When you check the log.txt file located in the root directory, you could see that this daemon process is running.