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The Database File</a></div> +<div class="fancy-toc2"><a href="#hot_journals">1.1. Hot Journals</a></div> +<div class="fancy-toc2"><a href="#pages">1.2. Pages</a></div> +<div class="fancy-toc2"><a href="#the_database_header">1.3. The Database Header</a></div> +<div class="fancy-toc3"><a href="#magic_header_string">1.3.1. Magic Header String</a></div> +<div class="fancy-toc3"><a href="#page_size">1.3.2. Page Size</a></div> +<div class="fancy-toc3"><a href="#file_format_version_numbers">1.3.3. File format version numbers</a></div> +<div class="fancy-toc3"><a href="#reserved_bytes_per_page">1.3.4. Reserved bytes per page</a></div> +<div class="fancy-toc3"><a href="#payload_fractions">1.3.5. Payload fractions</a></div> +<div class="fancy-toc3"><a href="#file_change_counter">1.3.6. File change counter</a></div> +<div class="fancy-toc3"><a href="#in_header_database_size">1.3.7. In-header database size</a></div> +<div class="fancy-toc3"><a href="#free_page_list">1.3.8. Free page list</a></div> +<div class="fancy-toc3"><a href="#schema_cookie">1.3.9. Schema cookie</a></div> +<div class="fancy-toc3"><a href="#schema_format_number">1.3.10. Schema format number</a></div> +<div class="fancy-toc3"><a href="#suggested_cache_size">1.3.11. Suggested cache size</a></div> +<div class="fancy-toc3"><a href="#incremental_vacuum_settings">1.3.12. Incremental vacuum settings</a></div> +<div class="fancy-toc3"><a href="#text_encoding">1.3.13. Text encoding</a></div> +<div class="fancy-toc3"><a href="#user_version_number">1.3.14. User version number</a></div> +<div class="fancy-toc3"><a href="#application_id">1.3.15. Application ID</a></div> +<div class="fancy-toc3"><a href="#write_library_version_number_and_version_valid_for_number">1.3.16. Write library version number and version-valid-for number</a></div> +<div class="fancy-toc3"><a href="#header_space_reserved_for_expansion">1.3.17. Header space reserved for expansion</a></div> +<div class="fancy-toc2"><a href="#the_lock_byte_page">1.4. The Lock-Byte Page</a></div> +<div class="fancy-toc2"><a href="#the_freelist">1.5. The Freelist</a></div> +<div class="fancy-toc2"><a href="#b_tree_pages">1.6. B-tree Pages</a></div> +<div class="fancy-toc2"><a href="#cell_payload_overflow_pages">1.7. Cell Payload Overflow Pages</a></div> +<div class="fancy-toc2"><a href="#pointer_map_or_ptrmap_pages">1.8. Pointer Map or Ptrmap Pages</a></div> +<div class="fancy-toc1"><a href="#schema_layer">2. Schema Layer</a></div> +<div class="fancy-toc2"><a href="#record_format">2.1. Record Format</a></div> +<div class="fancy-toc2"><a href="#record_sort_order">2.2. Record Sort Order</a></div> +<div class="fancy-toc2"><a href="#representation_of_sql_tables">2.3. Representation Of SQL Tables</a></div> +<div class="fancy-toc2"><a href="#representation_of_without_rowid_tables">2.4. Representation of WITHOUT ROWID Tables</a></div> +<div class="fancy-toc3"><a href="#suppression_of_redundant_columns_in_the_primary_key_of_without_rowid_tables">2.4.1. Suppression of redundant columns in the PRIMARY KEY +of WITHOUT ROWID tables</a></div> +<div class="fancy-toc2"><a href="#representation_of_sql_indices">2.5. Representation Of SQL Indices</a></div> +<div class="fancy-toc3"><a href="#suppression_of_redundant_columns_in_without_rowid_secondary_indexes_">2.5.1. Suppression of redundant columns in WITHOUT ROWID secondary indexes +</a></div> +<div class="fancy-toc2"><a href="#storage_of_the_sql_database_schema">2.6. Storage Of The SQL Database Schema</a></div> +<div class="fancy-toc3"><a href="#alternative_names_for_the_schema_table">2.6.1. Alternative Names For The Schema Table</a></div> +<div class="fancy-toc3"><a href="#internal_schema_objects">2.6.2. Internal Schema Objects</a></div> +<div class="fancy-toc3"><a href="#the_sqlite_sequence_table">2.6.3. The sqlite_sequence table</a></div> +<div class="fancy-toc3"><a href="#the_sqlite_stat1_table">2.6.4. The sqlite_stat1 table</a></div> +<div class="fancy-toc3"><a href="#the_sqlite_stat2_table">2.6.5. The sqlite_stat2 table</a></div> +<div class="fancy-toc3"><a href="#the_sqlite_stat3_table">2.6.6. The sqlite_stat3 table</a></div> +<div class="fancy-toc3"><a href="#the_sqlite_stat4_table">2.6.7. The sqlite_stat4 table</a></div> +<div class="fancy-toc1"><a href="#the_rollback_journal">3. The Rollback Journal</a></div> +<div class="fancy-toc1"><a href="#the_write_ahead_log">4. The Write-Ahead Log</a></div> +<div class="fancy-toc2"><a href="#wal_file_format">4.1. WAL File Format</a></div> +<div class="fancy-toc2"><a href="#checksum_algorithm">4.2. Checksum Algorithm</a></div> +<div class="fancy-toc2"><a href="#checkpoint_algorithm">4.3. Checkpoint Algorithm</a></div> +<div class="fancy-toc2"><a href="#wal_reset">4.4. WAL Reset</a></div> +<div class="fancy-toc2"><a href="#reader_algorithm">4.5. Reader Algorithm</a></div> +<div class="fancy-toc2"><a href="#wal_index_format">4.6. WAL-Index Format</a></div> +</div> +</div> +<script> +function toggle_toc(){ +var sub = document.getElementById("toc_sub") +var mk = document.getElementById("toc_mk") +if( sub.style.display!="block" ){ +sub.style.display = "block"; +mk.innerHTML = "▼"; +} else { +sub.style.display = "none"; +mk.innerHTML = "►"; +} +} +</script> +</div> + + + + + + +<p>This document describes and defines the on-disk database file +format used by all releases of SQLite since +version 3.0.0 (2004-06-18).</p> + +<h1 id="the_database_file"><span>1. </span>The Database File</h1> + +<p>The complete state of an SQLite database is usually +contained in a single file on disk called the "main database file".</p> + +<p>During a transaction, SQLite stores additional information +in a second file called the "rollback journal", or if SQLite is in +<a href="wal.html">WAL mode</a>, a write-ahead log file. + +<a name="hotjrnl"></a> + +</p><h2 id="hot_journals"><span>1.1. </span>Hot Journals</h2> +<p>If the application or +host computer crashes before the transaction completes, then the rollback +journal or write-ahead log contains information needed +to restore the main database file to a consistent state. When a rollback +journal or write-ahead log contains information necessary for recovering +the state of the database, they are called a "hot journal" or "hot WAL file". +Hot journals and WAL files are only a factor during error recovery +scenarios and so are uncommon, but they are part of the state of an SQLite +database and so cannot be ignored. This document defines the format +of a rollback journal and the write-ahead log file, but the focus is +on the main database file.</p> + +<h2 id="pages"><span>1.2. </span>Pages</h2> + +<p>The main database file consists of one or more pages. The size of a +page is a power of two between 512 and 65536 inclusive. All pages within +the same database are the same size. The page size for a database file +is determined by the 2-byte integer located at an offset of +16 bytes from the beginning of the database file.</p> + +<p>Pages are numbered beginning with 1. The maximum page number is +4294967294 (2<sup><small>32</small></sup> - 2). The minimum size +SQLite database is a single 512-byte page. +The maximum size database would be 4294967294 pages at 65536 bytes per +page or 281,474,976,579,584 bytes (about 281 terabytes). Usually SQLite will +hit the maximum file size limit of the underlying filesystem or disk +hardware long before it hits its own internal size limit.</p> + +<p>In common use, SQLite databases tend to range in size from a few kilobytes +to a few gigabytes, though terabyte-size SQLite databases are known to exist +in production.</p> + +<p>At any point in time, every page in the main database has a single +use which is one of the following: +</p><ul> +<li>The lock-byte page +</li><li>A freelist page +<ul> +<li>A freelist trunk page +</li><li>A freelist leaf page +</li></ul> +</li><li>A b-tree page +<ul> +<li>A table b-tree interior page +</li><li>A table b-tree leaf page +</li><li>An index b-tree interior page +</li><li>An index b-tree leaf page +</li></ul> +</li><li>A payload overflow page +</li><li>A pointer map page +</li></ul> + + +<p>All reads from and writes to the main database file begin at a page +boundary and all writes are an integer number of pages in size. Reads +are also usually an integer number of pages in size, with the one exception +that when the database is first opened, the first 100 bytes of the +database file (the database file header) are read as a sub-page size unit.</p> + +<p>Before any information-bearing page of the database is modified, +the original unmodified content of that page is written into the +rollback journal. If a transaction is interrupted and needs to be +rolled back, the rollback journal can then be used to restore the +database to its original state. Freelist leaf pages bear no +information that would need to be restored on a rollback and so they +are not written to the journal prior to modification, in order to +reduce disk I/O.</p> + +<a name="database_header"></a> + +<h2 id="the_database_header"><span>1.3. </span>The Database Header</h2> + +<p>The first 100 bytes of the database file comprise the database file +header. The database file header is divided into fields as shown by +the table below. All multibyte fields in the database file header are +stored with the most significant byte first (big-endian).</p> + +<center> +<i>Database Header Format</i><br> +<table width="80%" border="1"> +<tr><th>Offset</th><th>Size</th><th>Description +</th></tr><tr><td valign="top" align="center">0</td><td valign="top" align="center">16</td><td align="left"> +The header string: "SQLite format 3\000" +</td></tr><tr><td valign="top" align="center">16</td><td valign="top" align="center">2</td><td align="left"> +The database page size in bytes. Must be a power of two between 512 +and 32768 inclusive, or the value 1 representing a page size of 65536. +</td></tr><tr><td valign="top" align="center">18</td><td valign="top" align="center">1</td><td align="left"> +File format write version. 1 for legacy; 2 for <a href="wal.html">WAL</a>. +</td></tr><tr><td valign="top" align="center">19</td><td valign="top" align="center">1</td><td align="left"> +File format read version. 1 for legacy; 2 for <a href="wal.html">WAL</a>. +</td></tr><tr><td valign="top" align="center">20</td><td valign="top" align="center">1</td><td align="left"> +Bytes of unused "reserved" space at the end of each page. Usually 0. +</td></tr><tr><td valign="top" align="center">21</td><td valign="top" align="center">1</td><td align="left"> +Maximum embedded payload fraction. Must be 64. +</td></tr><tr><td valign="top" align="center">22</td><td valign="top" align="center">1</td><td align="left"> +Minimum embedded payload fraction. Must be 32. +</td></tr><tr><td valign="top" align="center">23</td><td valign="top" align="center">1</td><td align="left"> +Leaf payload fraction. Must be 32. +</td></tr><tr><td valign="top" align="center">24</td><td valign="top" align="center">4</td><td align="left"> +File change counter. +</td></tr><tr><td valign="top" align="center">28</td><td valign="top" align="center">4</td><td align="left"> +Size of the database file in pages. The "in-header database size". +</td></tr><tr><td valign="top" align="center">32</td><td valign="top" align="center">4</td><td align="left"> +Page number of the first freelist trunk page. +</td></tr><tr><td valign="top" align="center">36</td><td valign="top" align="center">4</td><td align="left"> +Total number of freelist pages. +</td></tr><tr><td valign="top" align="center">40</td><td valign="top" align="center">4</td><td align="left"> +The schema cookie. +</td></tr><tr><td valign="top" align="center">44</td><td valign="top" align="center">4</td><td align="left"> +The schema format number. Supported schema formats are 1, 2, 3, and 4. +</td></tr><tr><td valign="top" align="center">48</td><td valign="top" align="center">4</td><td align="left"> +Default page cache size. +</td></tr><tr><td valign="top" align="center">52</td><td valign="top" align="center">4</td><td align="left"> +The page number of the largest root b-tree page when in auto-vacuum or +incremental-vacuum modes, or zero otherwise. +</td></tr><tr><td valign="top" align="center">56</td><td valign="top" align="center">4</td><td align="left"> +The database text encoding. A value of 1 means UTF-8. A value of 2 +means UTF-16le. A value of 3 means UTF-16be. +</td></tr><tr><td valign="top" align="center">60</td><td valign="top" align="center">4</td><td align="left"> +The "user version" as read and set by the <a href="pragma.html#pragma_user_version">user_version pragma</a>. +</td></tr><tr><td valign="top" align="center">64</td><td valign="top" align="center">4</td><td align="left"> +True (non-zero) for incremental-vacuum mode. False (zero) otherwise. +</td></tr><tr><td valign="top" align="center">68</td><td valign="top" align="center">4</td><td align="left"> +The "Application ID" set by <a href="pragma.html#pragma_application_id">PRAGMA application_id</a>. +</td></tr><tr><td valign="top" align="center">72</td><td valign="top" align="center">20</td><td align="left"> +Reserved for expansion. Must be zero. +</td></tr><tr><td valign="top" align="center">92</td><td valign="top" align="center">4</td><td align="left"> +The <a href="fileformat2.html#validfor">version-valid-for number</a>. +</td></tr><tr><td valign="top" align="center">96</td><td valign="top" align="center">4</td><td align="left"> +<a href="c3ref/c_source_id.html">SQLITE_VERSION_NUMBER</a> +</td></tr></table></center> + +<h3 id="magic_header_string"><span>1.3.1. </span>Magic Header String</h3> + +<p>Every valid SQLite database file begins with the following 16 bytes +(in hex): 53 51 4c 69 74 65 20 66 6f 72 6d 61 74 20 33 00. This byte sequence +corresponds to the UTF-8 string "SQLite format 3" including the nul +terminator character at the end.</p> + +<h3 id="page_size"><span>1.3.2. </span>Page Size</h3> + +<p>The two-byte value beginning at offset 16 determines the page size of +the database. For SQLite versions 3.7.0.1 (2010-08-04) +and earlier, this value is +interpreted as a big-endian integer and must be a power of two between +512 and 32768, inclusive. Beginning with SQLite <a href="releaselog/3_7_1.html">version 3.7.1</a> +(2010-08-23), a page +size of 65536 bytes is supported. The value 65536 will not fit in a +two-byte integer, so to specify a 65536-byte page size, the value +at offset 16 is 0x00 0x01. +This value can be interpreted as a big-endian +1 and thought of as a magic number to represent the 65536 page size. +Or one can view the two-byte field as a little endian number and say +that it represents the page size divided by 256. These two +interpretations of the page-size field are equivalent.</p> + +<a name="vnums"></a> + +<h3 id="file_format_version_numbers"><span>1.3.3. </span>File format version numbers</h3> + +<p>The file format write version and file format read version at offsets +18 and 19 are intended to allow for enhancements of the file format +in future versions of SQLite. In current versions of SQLite, both of +these values are 1 for rollback journalling modes and 2 for <a href="wal.html">WAL</a> +journalling mode. If a version of SQLite coded to the current +file format specification encounters a database file where the read +version is 1 or 2 but the write version is greater than 2, then the database +file must be treated as read-only. If a database file with a read version +greater than 2 is encountered, then that database cannot be read or written.</p> + +<a name="resbyte"></a> + +<h3 id="reserved_bytes_per_page"><span>1.3.4. </span>Reserved bytes per page</h3> + +<p>SQLite has the ability to set aside a small number of extra bytes at +the end of every page for use by extensions. These extra bytes are +used, for example, by the SQLite Encryption Extension to store a nonce +and/or cryptographic checksum associated with each page. The +"reserved space" size in the 1-byte integer at offset 20 is the number +of bytes of space at the end of each page to reserve for extensions. +This value is usually 0. The value can be odd.</p> + +<a name="usable_size"></a> + +<p>The "usable size" of a database page is the page size specified by the +2-byte integer at offset 16 in the header less the "reserved" space size +recorded in the 1-byte integer at offset 20 in the header. The usable +size of a page might be an odd number. However, the usable size is not +allowed to be less than 480. In other words, if the page size is 512, +then the reserved space size cannot exceed 32.</p> + +<h3 id="payload_fractions"><span>1.3.5. </span>Payload fractions</h3> + +<p>The maximum and minimum embedded payload fractions and the leaf +payload fraction values must be 64, 32, and 32. These values were +originally intended to be tunable parameters that could be used to +modify the storage format of the b-tree algorithm. However, that +functionality is not supported and there are no current plans to add +support in the future. Hence, these three bytes are fixed at the +values specified.</p> + +<h3 id="file_change_counter"><span>1.3.6. </span>File change counter</h3> + +<a name="chngctr"></a> + +<p>The file change counter is a 4-byte big-endian integer at +offset 24 that is incremented whenever the database file is unlocked +after having been modified. +When two or more processes are reading the same database file, each +process can detect database changes from other processes by monitoring +the change counter. +A process will normally want to flush its database page cache when +another process modified the database, since the cache has become stale. +The file change counter facilitates this.</p> + +<p>In WAL mode, changes to the database are detected using the wal-index +and so the change counter is not needed. Hence, the change counter might +not be incremented on each transaction in WAL mode.</p> + +<h3 id="in_header_database_size"><span>1.3.7. </span>In-header database size</h3> + +<a name="filesize"></a> + +<p>The 4-byte big-endian integer at offset 28 into the header +stores the size of the database file in pages. If this in-header +datasize size is not valid (see the next paragraph), then the database +size is computed by looking +at the actual size of the database file. Older versions of SQLite +ignored the in-header database size and used the actual file size +exclusively. Newer versions of SQLite use the in-header database +size if it is available but fall back to the actual file size if +the in-header database size is not valid.</p> + +<p>The in-header database size is only considered to be valid if +it is non-zero and if the 4-byte <a href="fileformat2.html#chngctr">change counter</a> at offset 24 +exactly matches the 4-byte <a href="fileformat2.html#validfor">version-valid-for number</a> at offset 92. +The in-header database size is always valid +when the database is only modified using recent versions of SQLite, +versions 3.7.0 (2010-07-21) and later. +If a legacy version of SQLite writes to the database, it will not +know to update the in-header database size and so the in-header +database size could be incorrect. But legacy versions of SQLite +will also leave the version-valid-for number at offset 92 unchanged +so it will not match the change-counter. Hence, invalid in-header +database sizes can be detected (and ignored) by observing when +the change-counter does not match the version-valid-for number.</p> + +<h3 id="free_page_list"><span>1.3.8. </span>Free page list</h3> + +<p>Unused pages in the database file are stored on a freelist. The +4-byte big-endian integer at offset 32 stores the page number of +the first page of the freelist, or zero if the freelist is empty. +The 4-byte big-endian integer at offset 36 stores the total +number of pages on the freelist.</p> + +<h3 id="schema_cookie"><span>1.3.9. </span>Schema cookie</h3> + +<p>The schema cookie is a 4-byte big-endian integer at offset 40 +that is incremented whenever the database schema changes. A +prepared statement is compiled against a specific version of the +database schema. When the database schema changes, the statement +must be reprepared. When a prepared statement runs, it first checks +the schema cookie to ensure the value is the same as when the statement +was prepared and if the schema cookie has changed, the statement either +automatically reprepares and reruns or it aborts with an <a href="rescode.html#schema">SQLITE_SCHEMA</a> +error.</p> + +<a name="schemaformat"></a> + +<h3 id="schema_format_number"><span>1.3.10. </span>Schema format number</h3> + +<p>The schema format number is a 4-byte big-endian integer at offset 44. +The schema format number is similar to the file format read and write +version numbers at offsets 18 and 19 except that the schema format number +refers to the high-level SQL formatting rather than the low-level b-tree +formatting. Four schema format numbers are currently defined:</p> + +<ol> +<li value="1">Format 1 is understood by all versions of SQLite back to +<a href="releaselog/3_0_0.html">version 3.0.0</a> (2004-06-18).</li> +<li value="2">Format 2 adds the ability of rows within the same table +to have a varying number of columns, in order to support the +<a href="lang_altertable.html">ALTER TABLE ... ADD COLUMN</a> functionality. Support for +reading and writing format 2 was added in SQLite +<a href="releaselog/3_1_3.html">version 3.1.3</a> on 2005-02-20.</li> +<li value="3">Format 3 adds the ability of extra columns added by +<a href="lang_altertable.html">ALTER TABLE ... ADD COLUMN</a> to have non-NULL default +values. This capability was added in SQLite <a href="releaselog/3_1_4.html">version 3.1.4</a> +on 2005-03-11.</li> +<li value="4">Format 4 causes SQLite to respect the +<a href="lang_createindex.html#descidx">DESC keyword</a> on +index declarations. (The DESC keyword is ignored in indexes for +formats 1, 2, and 3.) +Format 4 also adds two new boolean record type values (<a href="fileformat2.html#serialtype">serial types</a> +8 and 9). Support for format 4 was added in SQLite 3.3.0 on +2006-01-10.</li> +</ol> + +<p>New database files created by SQLite use format 4 by default. +The <a href="pragma.html#pragma_legacy_file_format">legacy_file_format pragma</a> can be used to cause SQLite +to create new database files using format 1. +The format version number can be made to default to 1 instead of 4 by +setting <a href="compile.html#default_file_format">SQLITE_DEFAULT_FILE_FORMAT</a>=1 at compile-time. +</p> + +<h3 id="suggested_cache_size"><span>1.3.11. </span>Suggested cache size</h3> + +<p>The 4-byte big-endian signed integer at offset 48 is the suggested +cache size in pages for the database file. The value is a suggestion +only and SQLite is under no obligation to honor it. The absolute value +of the integer is used as the suggested size. The suggested cache size +can be set using the <a href="pragma.html#pragma_default_cache_size">default_cache_size pragma</a>.</p> + +<h3 id="incremental_vacuum_settings"><span>1.3.12. </span>Incremental vacuum settings</h3> + +<p>The two 4-byte big-endian integers at offsets 52 and 64 are used +to manage the <a href="pragma.html#pragma_auto_vacuum">auto_vacuum</a> and <a href="pragma.html#pragma_incremental_vacuum">incremental_vacuum</a> modes. If +the integer at offset 52 is zero then pointer-map (ptrmap) pages are +omitted from the database file and neither auto_vacuum nor +incremental_vacuum are supported. If the integer at offset 52 is +non-zero then it is the page number of the largest root page in the +database file, the database file will contain ptrmap pages, and the +mode must be either auto_vacuum or incremental_vacuum. In this latter +case, the integer at offset 64 is true for incremental_vacuum and +false for auto_vacuum. If the integer at offset 52 is zero then +the integer at offset 64 must also be zero.</p> + +<a name="enc"></a> + +<h3 id="text_encoding"><span>1.3.13. </span>Text encoding</h3> + +<p>The 4-byte big-endian integer at offset 56 determines the encoding +used for all text strings stored in the database. +A value of 1 means UTF-8. +A value of 2 means UTF-16le. +A value of 3 means UTF-16be. +No other values are allowed. +The sqlite3.h header file defines C-preprocessor macros SQLITE_UTF8 as 1, +SQLITE_UTF16LE as 2, and SQLITE_UTF16BE as 3, to use in place of +the numeric codes for the text encoding.</p> + +<h3 id="user_version_number"><span>1.3.14. </span>User version number</h3> + +<p>The 4-byte big-endian integer at offset 60 is the user version which +is set and queried by the <a href="pragma.html#pragma_user_version">user_version pragma</a>. The user version is +not used by SQLite.</p> + +<a name="appid"></a> + +<h3 id="application_id"><span>1.3.15. </span>Application ID</h3> + +<p>The 4-byte big-endian integer at offset 68 is an "Application ID" that +can be set by the <a href="pragma.html#pragma_application_id">PRAGMA application_id</a> command in order to identify the +database as belonging to or associated with a particular application. +The application ID is intended for database files used as an +<a href="appfileformat.html">application file-format</a>. The application ID can be used by utilities +such as <a href="http://www.darwinsys.com/file/">file(1)</a> to determine the specific +file type rather than just reporting "SQLite3 Database". A list of +assigned application IDs can be seen by consulting the +<a href="https://www.sqlite.org/src/artifact?ci=trunk&filename=magic.txt">magic.txt</a> +file in the SQLite source repository.</p> + +<a name="validfor"></a> + +<h3 id="write_library_version_number_and_version_valid_for_number"><span>1.3.16. </span>Write library version number and version-valid-for number</h3> + +<p>The 4-byte big-endian integer at offset 96 stores the +<a href="c3ref/c_source_id.html">SQLITE_VERSION_NUMBER</a> value for the SQLite library that most +recently modified the database file. The 4-byte big-endian integer at +offset 92 is the value of the <a href="fileformat2.html#chngctr">change counter</a> when the version number +was stored. The integer at offset 92 indicates which transaction +the version number is valid for and is sometimes called the +"version-valid-for number". + +</p><h3 id="header_space_reserved_for_expansion"><span>1.3.17. </span>Header space reserved for expansion</h3> + +<p>All other bytes of the database file header are reserved for +future expansion and must be set to zero.</p> + +<a name="lockbyte"></a> + +<h2 id="the_lock_byte_page"><span>1.4. </span>The Lock-Byte Page</h2> + +<p>The lock-byte page is the single page of the database file +that contains the bytes at offsets between 1073741824 and 1073742335, +inclusive. A database file that is less than or equal to 1073741824 bytes +in size contains no lock-byte page. A database file larger than +1073741824 contains exactly one lock-byte page. +</p> + +<p>The lock-byte page is set aside for use by the operating-system specific +<a href="vfs.html">VFS</a> implementation in implementing the database file locking primitives. +SQLite does not use the lock-byte page. The SQLite core +will never read or write the lock-byte page, +though operating-system specific <a href="vfs.html">VFS</a> +implementations may choose to read or write bytes on the lock-byte +page according to the +needs and proclivities of the underlying system. The unix and win32 +<a href="vfs.html">VFS</a> implementations that come built into SQLite do not write to the +lock-byte page, but third-party VFS implementations for +other operating systems might.</p> + +<p>The lock-byte page arose from the need to support Win95 which was the +predominant operating system when this file format was designed and which +only supported mandatory file locking. All modern operating systems that +we know of support advisory file locking, and so the lock-byte page is +not really needed any more, but is retained for backwards compatibility.</p> + +<a name="freelist"></a> + +<h2 id="the_freelist"><span>1.5. </span>The Freelist</h2> + +<p>A database file might contain one or more pages that are not in +active use. Unused pages can come about, for example, when information +is deleted from the database. Unused pages are stored on the freelist +and are reused when additional pages are required.</p> + +<p>The freelist is organized as a linked list of freelist trunk pages +with each trunk page containing page numbers for zero or more freelist +leaf pages.</p> + +<p>A freelist trunk page consists of an array of 4-byte big-endian integers. +The size of the array is as many integers as will fit in the usable space +of a page. The minimum usable space is 480 bytes so the array will always +be at least 120 entries in length. The first integer on a freelist trunk +page is the page number of the next freelist trunk page in the list or zero +if this is the last freelist trunk page. The second integer on a freelist +trunk page is the number of leaf page pointers to follow. +Call the second integer on a freelist trunk page L. +If L is greater than zero then integers with array indexes between 2 and +L+1 inclusive contain page numbers for freelist leaf pages.</p> + +<p>Freelist leaf pages contain no information. SQLite avoids reading or +writing freelist leaf pages in order to reduce disk I/O.</p> + +<p>A bug in SQLite versions prior to 3.6.0 (2008-07-16) +caused the database to be +reported as corrupt if any of the last 6 entries in the freelist trunk page +array contained non-zero values. Newer versions of SQLite do not have +this problem. However, newer versions of SQLite still avoid using the +last six entries in the freelist trunk page array in order that database +files created by newer versions of SQLite can be read by older versions +of SQLite.</p> + +<p>The number of freelist pages is stored as a 4-byte big-endian integer +in the database header at an offset of 36 from the beginning of the file. +The database header also stores the page number of the first freelist trunk +page as a 4-byte big-endian integer at an offset of 32 from the beginning +of the file.</p> + +<a name="btree"></a> + +<h2 id="b_tree_pages"><span>1.6. </span>B-tree Pages</h2> + +<p>The b-tree algorithm provides key/data storage with unique and +ordered keys on page-oriented storage devices. +For background information on b-trees, see +Knuth, <u>The Art Of Computer Programming</u>, Volume 3 "Sorting +and Searching", pages 471-479. Two variants of b-trees are used by +SQLite. "Table b-trees" use a 64-bit signed integer key and store +all data in the leaves. "Index b-trees" use arbitrary keys and store no +data at all. + +</p><p>A b-tree page is either an interior page or a leaf page. +A leaf page contains keys and in the case of a table b-tree each +key has associated data. An interior page contains +K keys together with K+1 pointers to child b-tree pages. +A "pointer" in an interior b-tree page is just the 32-bit +unsigned integer page number of the child page.</p><p> + +</p><p>The number of keys on an interior b-tree page, K, +is almost always at least 2 and is usually much more than 2. +The only exception is when page 1 is an interior b-tree page. +Page 1 has 100 fewer bytes of storage space available, +due to the presence of the database header at the beginning of that page, +and so sometimes (rarely) if page 1 is an interior b-tree page, it can +end up holding just a a single key. In all other cases, K is 2 or more. +The upper bound on K is as many keys as will fit on the page. Large keys +on index b-trees are split up into <a href="fileformat2.html#ovflpgs">overflow pages</a> so that no single key +uses more than one fourth of the available storage space on the page +and hence every internal page is able to store at least 4 keys. +The integer keys of table b-trees are never large enough to +require overflow, so key overflow only occurs on index b-trees.</p> + +<p>Define the depth +of a leaf b-tree to be 1 and the depth of any interior b-tree to be one +more than the maximum depth of any of its children. In a well-formed +database, all children of an interior b-tree have the same depth.</p> + +<p>In an interior b-tree page, the pointers and keys logically alternate +with a pointer on both ends. (The previous sentence is to be understood +conceptually - the actual layout of the keys and +pointers within the page is more complicated and will be described in +the sequel.) All keys within the same page are unique and are logically +organized in ascending order from left to right. (Again, this ordering +is logical, not physical. The actual location of keys within the page +is arbitrary.) For any key X, pointers to the left +of a X refer to b-tree pages on which all keys are less than or equal to X. +Pointers to the right of X refer to pages where all keys are +greater than X.</p> + +<p>Within an interior b-tree page, each key and the pointer to its +immediate left are combined into a structure called a "cell". The +right-most pointer is held separately. A leaf b-tree page has no +pointers, but it still uses the cell structure to hold keys for +index b-trees or keys and content for table b-trees. Data is also +contained in the cell. +</p> + +<p>Every b-tree page has at most one parent b-tree page. +A b-tree page without a parent is called a root page. A root b-tree page +together with the closure of its children form a complete b-tree. +It is possible (and in fact rather common) to have a complete b-tree +that consists of a single page that is both a leaf and the root. +Because there are pointers from parents to children, every page of a +complete b-tree can be located if only the root page is known. Hence, +b-trees are identified by their root page number.</p> + +<a name="btypes"></a> + +<p>A b-tree page is either a table b-tree page or an index b-tree page. +All pages within each complete b-tree are of the same type: either table +or index. There is one table b-trees in the database file +for each rowid table in the database schema, including system tables +such as <a href="schematab.html">sqlite_schema</a>. There is one index b-tree +in the database file for each index in the schema, including implied indexes +created by uniqueness constraints. There are no b-trees associated with +<a href="vtab.html">virtual tables</a>. Specific virtual table implementations might make use +of <a href="vtab.html#xshadowname">shadow tables</a> for storage, but those shadow tables will have separate +entries in the database schema. <a href="withoutrowid.html">WITHOUT ROWID</a> tables use index b-trees +rather than a table b-trees, so there is one +index b-tree in the database file for each <a href="withoutrowid.html">WITHOUT ROWID</a> table. +The b-tree corresponding to the sqlite_schema table is always a table +b-tree and always has a root page of 1. +The sqlite_schema table contains the root page number for every other +table and index in the database file.</p> + +<p>Each entry in a table b-tree consists of a 64-bit signed integer key +and up to 2147483647 bytes of arbitrary data. (The key of a table b-tree +corresponds to the <a href="lang_createtable.html#rowid">rowid</a> of the SQL table that the b-tree implements.) +Interior table b-trees hold only keys and pointers to children. +All data is contained in the table b-tree leaves.</p> + +<p>Each entry in an index b-tree consists of an arbitrary key of up +to 2147483647 bytes in length and no data.</p> + +<a name="cell_payload"></a> + +<p>Define the "payload" of a cell to be the arbitrary length section +of the cell. For an index b-tree, the key is always arbitrary in length +and hence the payload is the key. There are no arbitrary length elements +in the cells of interior table b-tree pages and so those cells have no +payload. Table b-tree leaf pages contain arbitrary length content and +so for cells on those pages the payload is the content. +</p><p>When the size of payload for a cell exceeds a certain threshold (to +be defined later) then only the first few bytes of the payload +are stored on the b-tree page and the balance is stored in a linked list +of content overflow pages.</p> + +<p>A b-tree page is divided into regions in the following order: + +</p><ol> +<li>The 100-byte database file header (found on page 1 only) +</li><li>The 8 or 12 byte b-tree page header +</li><li>The cell pointer array +</li><li>Unallocated space +</li><li>The cell content area +</li><li>The reserved region. +</li></ol> + + +<p>The 100-byte database file header is found only on page 1, which is +always a table b-tree page. All other b-tree pages in the database file +omit this 100-byte header.</p> + +<p>The reserved region is an area of unused space at the end of every +page (except the locking page) that extensions can use to hold per-page +information. The size of the reserved region is determined by the one-byte +unsigned integer found at an offset of 20 into the database file header. +The size of the reserved region is usually zero.</p> + +<p>The b-tree page header is 8 bytes in size for leaf pages and 12 +bytes for interior pages. All multibyte values in the page header +are big-endian. +The b-tree page header is composed of the following fields:</p> + +<center> +<i>B-tree Page Header Format</i><br> +<table border="1" width="80%"> +<tr><th>Offset</th><th>Size</th><th>Description +</th></tr><tr><td align="center" valign="top">0</td><td align="center" valign="top">1</td><td align="left"> +The one-byte flag at offset 0 indicating the b-tree page type.<ul> +<li>A value of 2 (0x02) means the page is an interior index b-tree page. +</li><li>A value of 5 (0x05) means the page is an interior table b-tree page. +</li><li>A value of 10 (0x0a) means the page is a leaf index b-tree page. +</li><li>A value of 13 (0x0d) means the page is a leaf table b-tree page.</li></ul> +Any other value for the b-tree page type is an error. +</td></tr><tr><td align="center" valign="top">1</td><td align="center" valign="top">2</td><td align="left"> +The two-byte integer at offset 1 gives the start of the +first freeblock on the page, or is zero if there are no freeblocks. +</td></tr><tr><td align="center" valign="top">3</td><td align="center" valign="top">2</td><td align="left"> +The two-byte integer at offset 3 gives the number of cells on the page. +</td></tr><tr><td align="center" valign="top">5</td><td align="center" valign="top">2</td><td align="left"> +The two-byte integer at offset 5 designates the start of the cell content +area. A zero value for this integer is interpreted as 65536. +</td></tr><tr><td align="center" valign="top">7</td><td align="center" valign="top">1</td><td align="left"> +The one-byte integer at offset 7 gives the number of fragmented free +bytes within the cell content area. +</td></tr><tr><td align="center" valign="top">8</td><td align="center" valign="top">4</td><td align="left"> +The four-byte page number at offset 8 is the right-most pointer. This +value appears in the header of interior b-tree pages only and is omitted from +all other pages. +</td></tr></table></center> + +<p>The cell pointer array of a b-tree page immediately follows the b-tree +page header. Let K be the number of cells on the btree. The cell pointer +array consists of K 2-byte integer offsets to the cell contents. The +cell pointers are arranged in key order with left-most cell (the cell with the +smallest key) first and the right-most cell (the cell with the largest +key) last.</p> + +<p>Cell content is stored in the cell content region of the b-tree page. +SQLite strives to place cells as far toward the end of the b-tree page as +it can, in order to leave space for future growth of the cell pointer array. +The area in between the last cell pointer array entry and the beginning of +the first cell is the unallocated region. +</p> + +<p>If a page contains no cells (which is only possible for a root page +of a table that contains no rows) then the offset to the +cell content area will equal the page size minus the bytes of reserved space. +If the database uses a 65536-byte page size and the reserved space is zero +(the usual value for reserved space) then the cell content offset of an +empty page wants to be 65536. +However, that integer is too large to be stored in a +2-byte unsigned integer, so a value of 0 is used in its place. + +</p><p>A freeblock is a structure used to identify unallocated space within +a b-tree page. Freeblocks are organized as a chain. The first 2 bytes of +a freeblock are a big-endian integer which is the offset in the b-tree page +of the next freeblock in the chain, or zero if the freeblock is the last on +the chain. The third and fourth bytes of each freeblock form +a big-endian integer which is the size of the freeblock in bytes, including +the 4-byte header. Freeblocks are always connected in order +of increasing offset. The second field of the b-tree page header is the +offset of the first freeblock, or zero if there are no freeblocks on the +page. In a well-formed b-tree page, there will always be at least one cell +before the first freeblock.</p> + +<p>A freeblock requires at least 4 bytes of space. If there is an isolated +group of 1, 2, or 3 unused bytes within the cell content area, those bytes +comprise a fragment. The total number of bytes in all fragments is stored +in the fifth field of the b-tree page header. In a well-formed b-tree page, +the total number of bytes in fragments may not exceed 60.</p> + +<p>The total amount of free space on a b-tree page consists of the size +of the unallocated region plus the total size of all freeblocks plus the +number of fragmented free bytes. SQLite may from time to time reorganize +a b-tree page so that there are no freeblocks or fragment bytes, all +unused bytes are contained in the unallocated space region, and all +cells are packed tightly at the end of the page. This is called +"defragmenting" the b-tree page.</p> + +<a name="varint"></a> + + +<p>A variable-length integer or "varint" is a static Huffman encoding +of 64-bit twos-complement integers that uses less space for small positive +values. +A varint is between 1 and 9 bytes in length. The varint consists of either +zero or more bytes which have the high-order bit set followed by a single byte +with the high-order bit clear, or nine bytes, whichever is shorter. +The lower seven bits of each of the first eight bytes and all 8 bits of +the ninth byte are used to reconstruct the 64-bit twos-complement integer. +Varints are big-endian: bits taken from the earlier byte of the varint +are more significant than bits taken from the later bytes. </p> + +<p>The format of a cell depends on which kind of b-tree page the cell +appears on. The following table shows the elements of a cell, in +order of appearance, for the various b-tree page types. + +</p><dl> +<dt><p>Table B-Tree Leaf Cell (header 0x0d):</p></dt> +<dd><p></p><ul> +<li>A varint which is the total number of bytes of payload, including any +overflow +</li><li>A varint which is the integer key, a.k.a. "<a href="lang_createtable.html#rowid">rowid</a>" +</li><li>The initial portion of the payload that does not spill to overflow +pages. +</li><li>A 4-byte big-endian integer page number for the first page of the +overflow page list - omitted if all payload fits on the b-tree page. +</li></ul></dd> + +<dt><p>Table B-Tree Interior Cell (header 0x05):</p></dt> +<dd><p></p><ul> +<li>A 4-byte big-endian page number which is the left child pointer. +</li><li>A varint which is the integer key +</li></ul></dd> + +<dt><p>Index B-Tree Leaf Cell (header 0x0a):</p></dt> +<dd><p></p><ul> +<li>A varint which is the total number of bytes of key payload, including any +overflow +</li><li>The initial portion of the payload that does not spill to overflow +pages. +</li><li>A 4-byte big-endian integer page number for the first page of the +overflow page list - omitted if all payload fits on the b-tree page. +</li></ul></dd> + +<dt><p>Index B-Tree Interior Cell (header 0x02):</p></dt> +<dd><p></p><ul> +<li>A 4-byte big-endian page number which is the left child pointer. +</li><li>A varint which is the total number of bytes of key payload, including any +overflow +</li><li>The initial portion of the payload that does not spill to overflow +pages. +</li><li>A 4-byte big-endian integer page number for the first page of the +overflow page list - omitted if all payload fits on the b-tree page. +</li></ul></dd> +</dl> + +<p>The information above can be recast into a table format as follows:</p> + +<a name="cellformat"></a> + +<center> +<i>B-tree Cell Format</i> +<table border="1" width="80%"> +<tr><th rowspan="2">Datatype + </th><th colspan="4">Appears in... + </th><th rowspan="2">Description +</th></tr><tr><th>Table Leaf (0x0d) + </th><th>Table Interior (0x05) + </th><th>Index Leaf (0x0a) + </th><th>Index Interior (0x02) +</th></tr><tr><td align="center" valign="top">4-byte integer + </td><td align="center" valign="top"> + </td><td align="center" valign="top">✔ + </td><td align="center" valign="top"> + </td><td align="center" valign="top">✔ + </td><td align="left">Page number of left child +</td></tr><tr><td align="center" valign="top">varint + </td><td align="center" valign="top">✔ + </td><td align="center" valign="top"> + </td><td align="center" valign="top">✔ + </td><td align="center" valign="top">✔ + </td><td align="left">Number of bytes of payload +</td></tr><tr><td align="center" valign="top">varint + </td><td align="center" valign="top">✔ + </td><td align="center" valign="top">✔ + </td><td align="center" valign="top"> + </td><td align="center" valign="top"> + </td><td align="left">Rowid +</td></tr><tr><td align="center" valign="top">byte array + </td><td align="center" valign="top">✔ + </td><td align="center" valign="top"> + </td><td align="center" valign="top">✔ + </td><td align="center" valign="top">✔ + </td><td align="left">Payload +</td></tr><tr><td align="center" valign="top">4-byte integer + </td><td align="center" valign="top">✔ + </td><td align="center" valign="top"> + </td><td align="center" valign="top">✔ + </td><td align="center" valign="top">✔ + </td><td align="left">Page number of first overflow page +</td></tr></table></center> + + +<p>The amount of payload that spills onto overflow pages also depends on +the page type. For the following computations, let U be the usable size +of a database page, the total page size less the reserved space at the +end of each page. And let P be the payload size. In the following, +symbol X represents the maximum amount of payload that can be stored directly +on the b-tree page without spilling onto an overflow page and symbol M +represents the minimum amount of payload that must be stored on the btree +page before spilling is allowed. + +</p><dl> +<dt><p>Table B-Tree Leaf Cell:</p></dt> +<dd><p> +Let X be U-35. If the payload size P is less than or equal to X then +the entire payload is stored on the b-tree leaf page. +Let M be ((U-12)*32/255)-23 and let K be M+((P-M)%(U-4)). +If P is greater than X +then the number of bytes stored on the table b-tree leaf page is K +if K is less or equal to X or M otherwise. +The number of bytes stored on the leaf page is never less than M. +</p></dd> + +<dt><p>Table B-Tree Interior Cell:</p></dt> +<dd><p> +Interior pages of table b-trees have no payload and so there is never +any payload to spill. +</p></dd> + +<dt><p>Index B-Tree Leaf Or Interior Cell:</p></dt> +<dd><p> +Let X be ((U-12)*64/255)-23. If the payload size P is less than +or equal to X then the entire payload is stored on the b-tree page. +Let M be ((U-12)*32/255)-23 and let K be M+((P-M)%(U-4)). +If P is greater than X then the number +of bytes stored on the index b-tree page is K if K is less than or +equal to X or M otherwise. +The number of bytes stored on the index page is never less than M. +</p></dd> +</dl> + +<p>Here is an alternative description of the same computation: + +</p><ul> +<li>X is U-35 for table btree leaf pages or + ((U-12)*64/255)-23 for index pages. +</li><li>M is always ((U-12)*32/255)-23. +</li><li>Let K be M+((P-M)%(U-4)). +</li><li>If P<=X then all P bytes of payload are stored directly on the + btree page without overflow. +</li><li>If P>X and K<=X then the first K bytes of P are stored on the + btree page and the remaining P-K bytes are stored on overflow pages. +</li><li>If P>X and K>X then the first M bytes of P are stored on the + btree page and the remaining P-M bytes are stored on overflow pages. +</li></ul> + +<p>The overflow thresholds are designed to give a minimum fanout of +4 for index b-trees and to make sure enough of the payload +is on the b-tree page that the record header can usually be accessed +without consulting an overflow page. In hindsight, the designer of +the SQLite b-tree logic realized that these thresholds could have been +made much simpler. However, the computations cannot be changed +without resulting in an incompatible file format. And the current computations +work well, even if they are a little complex.</p> + +<a name="ovflpgs"></a> + +<h2 id="cell_payload_overflow_pages"><span>1.7. </span>Cell Payload Overflow Pages</h2> + +<p>When the payload of a b-tree cell is too large for the b-tree page, +the surplus is spilled onto overflow pages. Overflow pages form a linked +list. The first four bytes of each overflow page are a big-endian +integer which is the page number of the next page in the chain, or zero +for the final page in the chain. The fifth byte through the last usable +byte are used to hold overflow content.</p> + +<h2 id="pointer_map_or_ptrmap_pages"><span>1.8. </span>Pointer Map or Ptrmap Pages</h2> + +<p>Pointer map or ptrmap pages are extra pages inserted into the database +to make the operation of <a href="pragma.html#pragma_auto_vacuum">auto_vacuum</a> and <a href="pragma.html#pragma_incremental_vacuum">incremental_vacuum</a> modes +more efficient. Other page types in the database typically have pointers +from parent to child. For example, an interior b-tree page contains pointers +to its child b-tree pages and an overflow chain has a pointer +from earlier to later links in the chain. A ptrmap page contains linkage +information going in the opposite direction, from child to parent.</p> + +<p>Ptrmap pages must exist in any database file which has a non-zero +largest root b-tree page value at offset 52 in the database header. +If the largest root b-tree page value is zero, then the database must not +contain ptrmap pages.</p> + +<p>In a database with ptrmap pages, the first ptrmap page is page 2. +A ptrmap page consists of an array of 5-byte entries. Let J be the +number of 5-byte entries that will fit in the usable space of a page. +(In other words, J=U/5.) The first ptrmap page will contain back pointer +information for pages 3 through J+2, inclusive. The second pointer map +page will be on page J+3 and that ptrmap page will provide back pointer +information for pages J+4 through 2*J+3 inclusive. And so forth for +the entire database file.</p> + +<p>In a database that uses ptrmap pages, all pages at locations identified +by the computation in the previous paragraph must be ptrmap page and no +other page may be a ptrmap page. Except, if the byte-lock page happens to +fall on the same page number as a ptrmap page, then the ptrmap is moved +to the following page for that one case.</p> + +<p>Each 5-byte entry on a ptrmap page provides back-link information about +one of the pages that immediately follow the pointer map. If page B is a +ptrmap page then back-link information about page B+1 is provided by +the first entry on the pointer map. Information about page B+2 is +provided by the second entry. And so forth.</p> + +<p>Each 5-byte ptrmap entry consists of one byte of "page type" information +followed by a 4-byte big-endian page number. Five page types are recognized: +</p> + +<ol> +<li>A b-tree root page. The +page number should be zero. +</li><li>A freelist page. The page number should be +zero. +</li><li>The first page of a +cell payload overflow chain. The page number is the b-tree page that +contains the cell whose content has overflowed. +</li><li>A page in an overflow chain +other than the first page. The page number is the prior page of the +overflow chain. +</li><li>A non-root b-tree page. The +page number is the parent b-tree page. +</li></ol> + +<p>In any database file that contains ptrmap pages, all b-tree root pages +must come before any non-root b-tree page, cell payload overflow page, or +freelist page. This restriction ensures that a root page will never +be moved during an auto-vacuum or incremental-vacuum. The auto-vacuum +logic does not know how to update the root_page field of the sqlite_schema +table and so it is necessary to prevent root pages from being moved +during an auto-vacuum in order to preserve the integrity of the +sqlite_schema table. Root pages are moved to the beginning of the +database file by the CREATE TABLE, CREATE INDEX, DROP TABLE, and +DROP INDEX operations.</p> + +<h1 id="schema_layer"><span>2. </span>Schema Layer</h1> + +<p>The foregoing text describes low-level aspects of the SQLite file +format. The b-tree mechanism provides a powerful and efficient means of +accessing a large data set. This section will describe how the +low-level b-tree layer is used to implement higher-level SQL +capabilities.</p> + +<a name="record_format"></a> + +<h2 id="record_format"><span>2.1. </span>Record Format</h2> + +<p>The data for a table b-tree leaf page and the key +of an index b-tree page was characterized above +as an arbitrary sequence of bytes. +The prior discussion mentioned one key being less than another, but +did not define what "less than" meant. The current section will address +these omissions.</p> + +<p>Payload, either table b-tree data or index b-tree keys, +is always in the "record format". +The record format defines a sequence of values corresponding +to columns in a table or index. The record format specifies the number +of columns, the datatype of each column, and the content of each column.</p> + +<p>The record format makes extensive use of the +<a href="fileformat2.html#varint">variable-length integer</a> or <a href="fileformat2.html#varint">varint</a> +representation of 64-bit signed integers defined above.</p> + +<a name="serialtype"></a> + +<p>A record contains a header and a body, in that order. +The header begins with a single varint which determines the total number +of bytes in the header. The varint value is the size of the header in +bytes including the size varint itself. Following the size varint are +one or more additional varints, one per column. These additional varints +are called "serial type" numbers and +determine the datatype of each column, according to the following chart:</p> + +<center> +<i>Serial Type Codes Of The Record Format</i><br> +<table width="80%" border="1"> +<tr><th>Serial Type</th><th>Content Size</th><th>Meaning +</th></tr><tr><td valign="top" align="center">0</td><td valign="top" align="center">0</td><td align="left"> +Value is a NULL. +</td></tr><tr><td valign="top" align="center">1</td><td valign="top" align="center">1</td><td align="left"> +Value is an 8-bit twos-complement integer. +</td></tr><tr><td valign="top" align="center">2</td><td valign="top" align="center">2</td><td align="left"> +Value is a big-endian 16-bit twos-complement integer. +</td></tr><tr><td valign="top" align="center">3</td><td valign="top" align="center">3</td><td align="left"> +Value is a big-endian 24-bit twos-complement integer. +</td></tr><tr><td valign="top" align="center">4</td><td valign="top" align="center">4</td><td align="left"> +Value is a big-endian 32-bit twos-complement integer. +</td></tr><tr><td valign="top" align="center">5</td><td valign="top" align="center">6</td><td align="left"> +Value is a big-endian 48-bit twos-complement integer. +</td></tr><tr><td valign="top" align="center">6</td><td valign="top" align="center">8</td><td align="left"> +Value is a big-endian 64-bit twos-complement integer. +</td></tr><tr><td valign="top" align="center">7</td><td valign="top" align="center">8</td><td align="left"> +Value is a big-endian IEEE 754-2008 64-bit floating point number. +</td></tr><tr><td valign="top" align="center">8</td><td valign="top" align="center">0</td><td align="left"> +Value is the integer 0. (Only available for <a href="fileformat2.html#schemaformat">schema format</a> 4 and higher.) +</td></tr><tr><td valign="top" align="center">9</td><td valign="top" align="center">0</td><td align="left"> +Value is the integer 1. (Only available for <a href="fileformat2.html#schemaformat">schema format</a> 4 and higher.) +</td></tr><tr><td valign="top" align="center">10,11 + </td><td valign="top" align="center"><i>variable</i></td><td align="left"> +<i>Reserved for internal use. These serial type codes will + never appear in a well-formed database file, but they + might be used in transient and temporary database files + that SQLite sometimes generates for its own use. + The meanings of these codes can shift from one release + of SQLite to the next.</i> +</td></tr><tr><td valign="top" align="center">N≥12 and even + </td><td valign="top" align="center">(N-12)/2</td><td align="left"> +Value is a BLOB that is (N-12)/2 bytes in length. +</td></tr><tr><td valign="top" align="center">N≥13 and odd + </td><td valign="top" align="center">(N-13)/2</td><td align="left"> +Value is a string in the <a href="fileformat2.html#enc">text encoding</a> and (N-13)/2 bytes in length. +The nul terminator is not stored. +</td></tr></table></center> + +<p>The header size varint +and serial type varints will usually consist of a single byte. The +serial type varints for large strings and BLOBs might extend to two or three +byte varints, but that is the exception rather than the rule. +The varint format is very efficient at coding the record header.</p> + +<p>The values for each column in the record immediately follow the header. +For serial types 0, 8, 9, 12, and 13, the value is zero bytes in +length. If all columns are of these types then the body section of the +record is empty.</p> + +<p>A record might have fewer values than the number of columns in the +corresponding table. This can happen, for example, after an +<a href="lang_altertable.html">ALTER TABLE ... ADD COLUMN</a> SQL statement has increased +the number of columns in the table schema without modifying preexisting rows +in the table. +Missing values at the end of the record are filled in using the +<a href="lang_createtable.html#dfltval">default value</a> for the corresponding columns defined in the table schema. +</p> + + +<h2 id="record_sort_order"><span>2.2. </span>Record Sort Order</h2> + +<p>The order of keys in an index b-tree is determined by the sort order of +the records that the keys represent. Record comparison progresses column +by column. Columns of a record are examined from left to right. The +first pair of columns that are not equal determines the relative order +of the two records. The sort order of individual columns is as +follows:</p> + +<ol> +<li>NULL values (serial type 0) sort first. +</li><li>Numeric values (serial types 1 through 9) sort after NULLs + and in numeric order. +</li><li>Text values (odd serial types 13 and larger) sort after numeric + values in the order determined by the columns <a href="datatype3.html#collation">collating function</a>. +</li><li>BLOB values (even serial types 12 and larger) sort last and in the order + determined by memcmp(). +</li></ol> + +<p>A <a href="datatype3.html#collation">collating function</a> for each column is necessary in order to compute +the order of text fields. +SQLite defines three built-in collating functions: +</p> + +<blockquote><table border="0" cellspacing="10"> +<tr><td valign="top">BINARY + </td><td> The built-in BINARY collation compares strings byte by byte + using the memcmp() function + from the standard C library. +</td></tr><tr><td valign="top">NOCASE + </td><td> The NOCASE collation is like BINARY except that uppercase + ASCII characters ('A' through 'Z') + are folded into their lowercase equivalents prior to running the + comparison. Only ASCII characters are case-folded. + NOCASE + does not implement a general purpose unicode caseless comparison. +</td></tr><tr><td valign="top">RTRIM + </td><td> RTRIM is like BINARY except that extra spaces at the end of either + string do not change the result. In other words, strings will + compare equal to one another as long as they + differ only in the number of spaces at the end. +</td></tr></table></blockquote> + +<p>Additional application-specific collating functions can be added to +SQLite using the <a href="c3ref/create_collation.html">sqlite3_create_collation()</a> interface.</p> + +<p>The default collating function for all strings is BINARY. +Alternative collating functions for table columns can be specified in the +<a href="lang_createtable.html">CREATE TABLE</a> statement using the COLLATE clause on the <a href="lang_createtable.html#tablecoldef">column definition</a>. +When a column is indexed, the same collating function specified in the +<a href="lang_createtable.html">CREATE TABLE</a> statement is used for the column in the index, by default, +though this can be overridden using a COLLATE clause in the +<a href="lang_createindex.html">CREATE INDEX</a> statement. + +<a name="#sqltab"></a> + +</p><h2 id="representation_of_sql_tables"><span>2.3. </span>Representation Of SQL Tables</h2> + +<p> Each ordinary SQL table in the database schema is represented on-disk +by a table b-tree. Each entry in the table b-tree corresponds to a row +of the SQL table. The <a href="lang_createtable.html#rowid">rowid</a> of the SQL table is the 64-bit signed +integer key for each entry in the table b-tree.</p> + +<p> The content of each SQL table row is stored in the database file by +first combining the values in the various columns into a byte array +in the record format, then storing that byte array as the payload in +an entry in the table b-tree. The order of values in the record is +the same as the order of columns in the SQL table definition. +When an SQL table includes an +<a href="lang_createtable.html#rowid">INTEGER PRIMARY KEY</a> column (which aliases the <a href="lang_createtable.html#rowid">rowid</a>) then that +column appears in the record as a NULL value. SQLite will always use +the table b-tree key rather than the NULL value when referencing the +<a href="lang_createtable.html#rowid">INTEGER PRIMARY KEY</a> column.</p> + +<p> If the <a href="datatype3.html#affinity">affinity</a> of a column is REAL and that column contains a +value that can be converted to an integer without loss of information +(if the value contains no fractional part and is not too large to be +represented as an integer) then the column may be stored in the record +as an integer. SQLite will convert the value back to floating +point when extracting it from the record.</p> + +<h2 id="representation_of_without_rowid_tables"><span>2.4. </span>Representation of WITHOUT ROWID Tables</h2> + +<p>If an SQL table is created using the "WITHOUT ROWID" clause at the +end of its CREATE TABLE statement, then that table is a <a href="withoutrowid.html">WITHOUT ROWID</a> +table and uses a different on-disk representation. A WITHOUT ROWID +table uses an index b-tree rather than a table b-tree for storage. +The key for each entry in the WITHOUT ROWID b-tree is a record composed +of the columns of the PRIMARY KEY followed by all remaining columns of +the table. The primary key columns appear in the order that they were +declared in the PRIMARY KEY clause and the remaining columns appear in +the order they occur in the CREATE TABLE statement. + +</p><p>Hence, the content encoding for a WITHOUT ROWID table is the same +as the content encoding for an ordinary rowid table, except that the +order of the columns is rearranged so that PRIMARY KEY columns come +first, and the content is used as the key in an index b-tree rather +than as the data in a table b-tree. +The special encoding rules for columns with REAL affinity +apply to WITHOUT ROWID tables the same as they do with rowid tables. + +</p><h3 id="suppression_of_redundant_columns_in_the_primary_key_of_without_rowid_tables"><span>2.4.1. </span>Suppression of redundant columns in the PRIMARY KEY + of WITHOUT ROWID tables</h3> + +<p>If the PRIMARY KEY of a WITHOUT ROWID tables uses the same columns +with the same collating sequence more than once, then the second and +subsequent occurrences of that column in the PRIMARY KEY definition are +ignored. For example, the following CREATE TABLE statements all specify +the same table, which will have the exact same representation on disk: + +</p><blockquote><pre> +CREATE TABLE t1(a,b,c,d,PRIMARY KEY(a,c)) WITHOUT ROWID; +CREATE TABLE t1(a,b,c,d,PRIMARY KEY(a,c,a,c)) WITHOUT ROWID; +CREATE TABLE t1(a,b,c,d,PRIMARY KEY(a,A,a,C)) WITHOUT ROWID; +CREATE TABLE t1(a,b,c,d,PRIMARY KEY(a,a,a,a,c)) WITHOUT ROWID; +</pre></blockquote> + +<p>The first example above is the preferred definition of the table, +of course. All of the examples create a WITHOUT ROWID table with +two PRIMARY KEY columns, "a" and "c", in that order, followed by +two data columns "b" and "d", also in that order. + +</p><h2 id="representation_of_sql_indices"><span>2.5. </span>Representation Of SQL Indices</h2> + +<p>Each SQL index, whether explicitly declared via a <a href="lang_createindex.html">CREATE INDEX</a> statement +or implied by a UNIQUE or PRIMARY KEY constraint, corresponds to an +index b-tree in the database file. +Each entry in the index b-tree corresponds to a single row in the +associated SQL table. +The key to an index b-tree is +a record composed of the columns that are being indexed followed by the +key of the corresponding table row. For ordinary tables, the row key is +the <a href="lang_createtable.html#rowid">rowid</a>, and for <a href="withoutrowid.html">WITHOUT ROWID</a> tables the row key is the PRIMARY KEY. +Because every row in the table has a unique row key, +all keys in an index are unique.</p> + +<p>In a normal index, there is a one-to-one mapping between rows in a +table and entries in each index associated with that table. +However, in a <a href="partialindex.html">partial index</a>, the index b-tree only contains entries +corresponding to table rows for which the WHERE clause expression on the +CREATE INDEX statement is true. +Corresponding rows in the index and table b-trees share the same rowid +or primary key values and contain the same value for all indexed columns.</p> + +<h3 id="suppression_of_redundant_columns_in_without_rowid_secondary_indexes_"><span>2.5.1. </span>Suppression of redundant columns in WITHOUT ROWID secondary indexes +</h3> + +<p> In an index on a WITHOUT ROWID table, if a column of the PRIMARY KEY +is also a column in the index and has a matching collating sequence, then the +indexed column is not repeated in the table-key suffix on the +end of the index record. As an example, consider the following SQL: + +</p><blockquote><pre> +CREATE TABLE ex25(a,b,c,d,e,PRIMARY KEY(d,c,a)) WITHOUT rowid; +CREATE INDEX ex25ce ON ex25(c,e); +CREATE INDEX ex25acde ON ex25(a,c,d,e); +CREATE INDEX ex25ae ON ex25(a COLLATE nocase,e); +</pre></blockquote> + +<p>Each row in the ex25ce index is a record +with these columns: c, e, d, a. The first two columns are +the columns being indexed, c and e. The remaining columns are the primary +key of the corresponding table row. Normally, the primary key would be +columns d, c, and a, but because column c already appears earlier in the +index, it is omitted from the key suffix.</p> + +<p>In the extreme case where the columns being indexed cover all columns +of the PRIMARY KEY, the index will consist of only the columns being +indexed. The ex25acde example above demonstrates this. Each entry in +the ex25acde index consists of only the columns a, c, d, and e, in that +order.</p> + +<p>Each row in ex25ae contains five columns: a, e, d, c, a. The "a" +column is repeated since the first occurrence of "a" has a collating +function of "nocase" and the second has a collating sequence of "binary". +If the "a" column is not repeated and if the table contains two or more +entries with the same "e" value and where "a" differs only in case, then +all of those table entries would correspond to a single entry in the +index, which would break the one-to-one correspondence between the table +and the index. + +</p><p> The suppression of redundant columns in the key suffix of an index +entry only occurs in WITHOUT ROWID tables. In an ordinary rowid table, +the index entry always ends with the rowid even if the <a href="lang_createtable.html#rowid">INTEGER PRIMARY KEY</a> +column is one of the columns being indexed.</p> + +<a name="ffschema"></a> + +<h2 id="storage_of_the_sql_database_schema"><span>2.6. </span>Storage Of The SQL Database Schema</h2> + +<p>Page 1 of a database file is the root page of a table b-tree that +holds a special table named "<a href="schematab.html">sqlite_schema</a>". This b-tree is known +as the "schema table" since it stores the complete +database schema. The structure of the sqlite_schema table is as +if it had been created using the following SQL:</p> + +<blockquote><pre> +CREATE TABLE sqlite_schema( + type text, + name text, + tbl_name text, + rootpage integer, + sql text +); +</pre></blockquote> + +<p>The sqlite_schema table contains one row for each table, index, view, +and trigger (collectively "objects") in the database schema, except there +is no entry for the sqlite_schema table itself. The sqlite_schema table +contains entries for <a href="fileformat2.html#intschema">internal schema objects</a> in addition to application- +and programmer-defined objects. + + +</p><p>The sqlite_schema.type column will be one +of the following text strings: 'table', 'index', 'view', or 'trigger' +according to the type of object defined. The 'table' string is used +for both ordinary and <a href="vtab.html">virtual tables</a>.</p> + +<p>The sqlite_schema.name column will hold the name of the object. +<a href="lang_createtable.html#uniqueconst">UNIQUE</a> and <a href="lang_createtable.html#primkeyconst">PRIMARY KEY</a> constraints on tables cause SQLite to create +<a href="fileformat2.html#intschema">internal indexes</a> with names of the form "sqlite_autoindex_TABLE_N" +where TABLE is replaced by the name of the table that contains the +constraint and N is an integer beginning with 1 and increasing by one +with each constraint seen in the table definition. +In a <a href="withoutrowid.html">WITHOUT ROWID</a> table, there is no sqlite_schema entry for the +PRIMARY KEY, but the "sqlite_autoindex_TABLE_N" name is set aside +for the PRIMARY KEY as if the sqlite_schema entry did exist. This +will affect the numbering of subsequent UNIQUE constraints. +The "sqlite_autoindex_TABLE_N" name is never allocated for an +<a href="lang_createtable.html#rowid">INTEGER PRIMARY KEY</a>, either in rowid tables or WITHOUT ROWID tables. +</p> + +<p>The sqlite_schema.tbl_name column holds the name of a table or view +that the object is associated with. For a table or view, the +tbl_name column is a copy of the name column. For an index, the tbl_name +is the name of the table that is indexed. For a trigger, the tbl_name +column stores the name of the table or view that causes the trigger +to fire.</p> + +<p>The sqlite_schema.rootpage column stores the page number of the root +b-tree page for tables and indexes. For rows that define views, triggers, +and virtual tables, the rootpage column is 0 or NULL.</p> + +<p>The sqlite_schema.sql column stores SQL text that describes the +object. This SQL text is a <a href="lang_createtable.html">CREATE TABLE</a>, <a href="lang_createvtab.html">CREATE VIRTUAL TABLE</a>, +<a href="lang_createindex.html">CREATE INDEX</a>, +<a href="lang_createview.html">CREATE VIEW</a>, or <a href="lang_createtrigger.html">CREATE TRIGGER</a> statement that if evaluated against +the database file when it is the main database of a <a href="c3ref/sqlite3.html">database connection</a> +would recreate the object. The text is usually a copy of the original +statement used to create the object but with normalizations applied so +that the text conforms to the following rules: + +</p><ul> +<li>The CREATE, TABLE, VIEW, TRIGGER, and INDEX keywords at the beginning +of the statement are converted to all upper case letters. +</li><li>The TEMP or TEMPORARY keyword is removed if it occurs after the +initial CREATE keyword. +</li><li>Any database name qualifier that occurs prior to the name of the +object being created is removed. +</li><li>Leading spaces are removed. +</li><li>All spaces following the first two keywords are converted into a single +space. +</li></ul> + +<p>The text in the sqlite_schema.sql column is a copy of the original +CREATE statement text that created the object, except normalized as +described above and as modified by subsequent <a href="lang_altertable.html">ALTER TABLE</a> statements. +The sqlite_schema.sql is NULL for the <a href="fileformat2.html#intschema">internal indexes</a> that are +automatically created by <a href="lang_createtable.html#uniqueconst">UNIQUE</a> or <a href="lang_createtable.html#primkeyconst">PRIMARY KEY</a> constraints.</p> + +<h3 id="alternative_names_for_the_schema_table"><span>2.6.1. </span>Alternative Names For The Schema Table</h3> + +<p>The name "sqlite_schema" does not appear anywhere in the file format. +That name is just a convention used by the database implementation. +Due to historical and operational considerations, the +"sqlite_schema" table can also sometimes be called by one of the +following aliases: + +</p><ol> +<li> sqlite_master +</li><li> sqlite_temp_schema +</li><li> sqlite_temp_master +</li></ol> + +<p>Because the name of the schema table does not appear anywhere in +the file format, the meaning of the database file is not changed if +the application chooses to refer to the schema table by one of +these alternative names. + +<a name="intschema"></a> + +</p><h3 id="internal_schema_objects"><span>2.6.2. </span>Internal Schema Objects</h3> + +<p>In addition to the tables, indexes, views, and triggers created by +the application and/or the developer using CREATE statements SQL, the +sqlite_schema table may contain zero or more entries for +<i>internal schema objects</i> that are created by SQLite for its +own internal use. The names of internal schema objects +always begin with "sqlite_" and any table, index, view, or trigger +whose name begins with "sqlite_" is an internal schema object. +SQLite prohibits applications from creating objects whose names begin +with "sqlite_". + +</p><p>Internal schema objects used by SQLite may include the following: + +</p><ul> +<li><p>Indices with names of the form "sqlite_autoindex_TABLE_N" that + are used to implement <a href="lang_createtable.html#uniqueconst">UNIQUE</a> and <a href="lang_createtable.html#primkeyconst">PRIMARY KEY</a> constraints on + ordinary tables. + +</p></li><li><p>A table with the name "sqlite_sequence" that is used to keep track + of the maximum historical <a href="lang_createtable.html#rowid">INTEGER PRIMARY KEY</a> for a table + using <a href="autoinc.html">AUTOINCREMENT</a>. + +</p></li><li><p>Tables with names of the form "sqlite_statN" where N is an integer. + Such tables store database statistics gathered by the <a href="lang_analyze.html">ANALYZE</a> + command and used by the query planner to help determine the best + algorithm to use for each query. +</p></li></ul> + +<p>New internal schema objects names, always beginning with "sqlite_", +may be added to the SQLite file format in future releases. + +<a name="seqtab"></a> + +</p><h3 id="the_sqlite_sequence_table"><span>2.6.3. </span>The sqlite_sequence table</h3> + +<p>The sqlite_sequence table is an internal table used to help implement +<a href="autoinc.html">AUTOINCREMENT</a>. The sqlite_sequence table is created automatically +whenever any ordinary table with an AUTOINCREMENT integer primary +key is created. Once created, the sqlite_sequence table exists in the +sqlite_schema table forever; it cannot be dropped. +The schema for the sqlite_sequence table is: + +</p><blockquote><pre> +CREATE TABLE sqlite_sequence(name,seq); +</pre></blockquote> + +<p>There is a single row in the sqlite_sequence table for each ordinary +table that uses AUTOINCREMENT. The name of the table (as it appears in +sqlite_schema.name) is in the sqlite_sequence.name field and the largest +<a href="lang_createtable.html#rowid">INTEGER PRIMARY KEY</a> ever inserted into that table is +in the sqlite_sequence.seq field. +New automatically generated integer primary keys for AUTOINCREMENT +tables are guaranteed to be larger than the sqlite_sequence.seq field for +that table. +If the sqlite_sequence.seq field of an AUTOINCREMENT table is already at +the largest integer value (9223372036854775807) then attempts to add new +rows to that table with an automatically generated integer primary will fail +with an <a href="rescode.html#full">SQLITE_FULL</a> error. +The sqlite_sequence.seq field is automatically updated if required when +new entries are inserted to an AUTOINCREMENT table. +The sqlite_sequence row for an AUTOINCREMENT table is automatically deleted +when the table is dropped. +If the sqlite_sequence row for an AUTOINCREMENT table does not exist when +the AUTOINCREMENT table is updated, then a new sqlite_sequence row is created. +If the sqlite_sequence.seq value for an AUTOINCREMENT table is manually +set to something other than an integer and there is a subsequent attempt to +insert the or update the AUTOINCREMENT table, then the behavior is undefined. + +</p><p>Application code is allowed to modify the sqlite_sequence table, to add +new rows, to delete rows, or to modify existing rows. However, application +code cannot create the sqlite_sequence table if it does not already exist. +Application code can delete all entries from the sqlite_sequence table, +but application code cannot drop the sqlite_sequence table. + +<a name="stat1tab"></a> + +</p><h3 id="the_sqlite_stat1_table"><span>2.6.4. </span>The sqlite_stat1 table</h3> + +<p>The sqlite_stat1 is an internal table created by the <a href="lang_analyze.html">ANALYZE</a> command +and used to hold supplemental information about tables and indexes that the +query planner can use to help it find better ways of performing queries. +Applications can update, delete from, insert into or drop the sqlite_stat1 +table, but may not create or alter the sqlite_stat1 table. +The schema of the sqlite_stat1 table is as follows: + +</p><blockquote><pre> +CREATE TABLE sqlite_stat1(tbl,idx,stat); +</pre></blockquote> + +<p> There is normally one row per index, with the index identified by the +name in the sqlite_stat1.idx column. The sqlite_stat1.tbl column is +the name of the table to which the index belongs. In each such row, +the sqlite_stat.stat column will be +a string consisting of a list of integers followed by zero or more +arguments. The first integer in this +list is the approximate number of rows in the index. (The number of +rows in the index is the same as the number of rows in the table, +except for <a href="partialindex.html">partial indexes</a>.) +The second integer is the approximate number of rows in the index +that have the same value in the first column of the index. The third +integer is the number of rows in the index that have +the same value for the first two columns. The N-th integer (for N>1) +is the estimated average number of rows in +the index which have the same value for the first N-1 columns. For +a K-column index, there will be K+1 integers in the stat column. If +the index is unique, then the last integer will be 1. + +</p><p>The list of integers in the stat column can optionally be followed +by arguments, each of which is a sequence of non-space characters. +All arguments are preceded by a single space. +Unrecognized arguments are silently ignored. + +</p><p>If the "unordered" argument is present, then the query planner assumes +that the index is unordered and will not use the index for a range query +or for sorting. + +</p><p>The "sz=NNN" argument (where NNN represents a sequence of 1 or more digits) +means that the average row size over all records of the table or +index is NNN bytes per row. The SQLite query planner might use the +estimated row size information provided by the "sz=NNN" token +to help it choose smaller tables and indexes that require less disk I/O. + +</p><p>The presence of the "noskipscan" token on the sqlite_stat1.stat field +of an index prevents that index from being used with the +<a href="optoverview.html#skipscan">skip-scan optimization</a>. + +</p><p>New text tokens may be added to the end of the stat column in future +enhancements to SQLite. For compatibility, unrecognized tokens at the end +of the stat column are silently ignored. + +</p><p>If the sqlite_stat1.idx column is NULL, then the sqlite_stat1.stat +column contains a single integer which is the approximate number of +rows in the table identified by sqlite_stat1.tbl. +If the sqlite_stat1.idx column is the same as the sqlite_stat1.tbl +column, then the table is a <a href="withoutrowid.html">WITHOUT ROWID</a> table and the sqlite_stat1.stat +field contains information about the index btree that implements the +WITHOUT ROWID table. + +<a name="stat2tab"></a> + +</p><h3 id="the_sqlite_stat2_table"><span>2.6.5. </span>The sqlite_stat2 table</h3> + +<p>The sqlite_stat2 is only created and is only used if SQLite is compiled +with SQLITE_ENABLE_STAT2 and if the SQLite version number is between +3.6.18 (2009-09-11) and 3.7.8 (2011-09-19). +The sqlite_stat2 table is neither read nor written by any +version of SQLite before 3.6.18 nor after 3.7.8. +The sqlite_stat2 table contains additional information +about the distribution of keys within an index. +The schema of the sqlite_stat2 table is as follows: + +</p><blockquote><pre> +CREATE TABLE sqlite_stat2(tbl,idx,sampleno,sample); +</pre></blockquote> + +<p>The sqlite_stat2.idx column and the sqlite_stat2.tbl column in each +row of the sqlite_stat2 table identify an index described by that row. +There are usually 10 rows in the sqlite_stat2 +table for each index. + +</p><p>The sqlite_stat2 entries for an index that have sqlite_stat2.sampleno +between 0 and 9 inclusive are samples of the left-most key value in the +index taken at evenly spaced points along the index. +Let C be the number of rows in the index. +Then the sampled rows are given by + +</p><blockquote> + rownumber = (i*C*2 + C)/20 +</blockquote> + +<p>The variable i in the previous expression varies between 0 and 9. +Conceptually, the index space is divided into +10 uniform buckets and the samples are the middle row from each bucket. + +</p><p>The format for sqlite_stat2 is recorded here for legacy reference. +Recent versions of SQLite no longer support sqlite_stat2 and the +sqlite_stat2 table, if is exists, is simply ignored. + +<a name="stat3tab"></a> + +</p><h3 id="the_sqlite_stat3_table"><span>2.6.6. </span>The sqlite_stat3 table</h3> + +<p>The sqlite_stat3 is only used if SQLite is compiled +with <a href="compile.html#enable_stat3">SQLITE_ENABLE_STAT3</a> or <a href="compile.html#enable_stat4">SQLITE_ENABLE_STAT4</a> +and if the SQLite version number is 3.7.9 (2011-11-01) or greater. +The sqlite_stat3 table is neither read nor written by any +version of SQLite before 3.7.9. +If the <a href="compile.html#enable_stat4">SQLITE_ENABLE_STAT4</a> compile-time option is used and the +SQLite version number is 3.8.1 (2013-10-17) or greater, +then sqlite_stat3 might be read but not written. +The sqlite_stat3 table contains additional information +about the distribution of keys within an index, information that the +query planner can use to devise better and faster query algorithms. +The schema of the sqlite_stat3 table is as follows: + +</p><blockquote><pre> +CREATE TABLE sqlite_stat3(tbl,idx,nEq,nLt,nDLt,sample); +</pre></blockquote> + +<p>There are usually multiple entries in the sqlite_stat3 table for each index. +The sqlite_stat3.sample column holds the value of the left-most field of an +index identified by sqlite_stat3.idx and sqlite_stat3.tbl. +The sqlite_stat3.nEq column holds the approximate +number of entries in the index whose left-most column exactly matches +the sample. +The sqlite_stat3.nLt holds the approximate number of entries in the +index whose left-most column is less than the sample. +The sqlite_stat3.nDLt column holds the approximate +number of distinct left-most entries in the index that are less than +the sample. + +</p><p>There can be an arbitrary number of sqlite_stat3 entries per index. +The <a href="lang_analyze.html">ANALYZE</a> command will typically generate sqlite_stat3 tables +that contain between 10 and 40 samples that are distributed across +the key space and with large nEq values. + +</p><p>In a well-formed sqlite_stat3 table, the samples for any single +index must appear in the same order that they occur in the index. +In other words, if the entry with left-most column S1 is earlier in +the index b-tree than the +entry with left-most column S2, then in the sqlite_stat3 table, +sample S1 must have a smaller rowid than sample S2. + +<a name="stat4tab"></a> + +</p><h3 id="the_sqlite_stat4_table"><span>2.6.7. </span>The sqlite_stat4 table</h3> + +<p>The sqlite_stat4 is only created and is only used if SQLite is compiled +with <a href="compile.html#enable_stat4">SQLITE_ENABLE_STAT4</a> and if the SQLite version number is +3.8.1 (2013-10-17) or greater. +The sqlite_stat4 table is neither read nor written by any +version of SQLite before 3.8.1. +The sqlite_stat4 table contains additional information +about the distribution of keys within an index or the distribution of +keys in the primary key of a <a href="withoutrowid.html">WITHOUT ROWID</a> table. +The query planner can sometimes use the additional information in +the sqlite_stat4 table to devise better and faster query algorithms. +The schema of the sqlite_stat4 table is as follows: + +</p><blockquote><pre> +CREATE TABLE sqlite_stat4(tbl,idx,nEq,nLt,nDLt,sample); +</pre></blockquote> + +<p>There are typically between 10 to 40 entries in the sqlite_stat4 table for +each index for which statistics are available, however these limits are +not hard bounds. +The meanings of the columns in the sqlite_stat4 table are as follows: + +</p><center> +<table border="0" width="100%" cellpadding="10"> +<tr><td valign="top" align="right">tbl:</td> + <td>The sqlite_stat4.tbl column holds name of the table that owns + the index that the row describes + +</td></tr><tr><td valign="top" align="right">idx:</td> + <td>The sqlite_stat4.idx column holds name of the index that the + row describes, or in the case of + an sqlite_stat4 entry for a <a href="withoutrowid.html">WITHOUT ROWID</a> table, the + name of the table itself. + +</td></tr><tr><td valign="top" align="right">sample:</td> + <td>The sqlite_stat4.sample column holds a BLOB + in the <a href="fileformat2.html#record_format">record format</a> that encodes the indexed columns followed by + the rowid for a rowid table or by the columns of the primary key + for a WITHOUT ROWID table. + The sqlite_stat4.sample BLOB for the WITHOUT ROWID table itself + contains just the columns of the primary key. + Let the number of columns encoded by the sqlite_stat4.sample blob be N. + For indexes on an ordinary rowid table, N will be one more than the number + of columns indexed. + For indexes on WITHOUT ROWID tables, N will be the number of columns + indexed plus the number of columns in the primary key. + For a WITHOUT ROWID table, N will be the number of columns in the + primary key. + +</td></tr><tr><td valign="top" align="right">nEq:</td> + <td>The sqlite_stat4.nEq column holds a list of N integers where + the K-th integer is the approximate number of entries in the index + whose left-most K columns exactly match the K left-most columns + of the sample. + +</td></tr><tr><td valign="top" align="right">nLt:</td> + <td>The sqlite_stat4.nLt column holds a list of N integers where + the K-th integer is the approximate number of entries in the + index whose K left-most columns are collectively less than the + K left-most columns of the sample. + +</td></tr><tr><td valign="top" align="right">nDLt:</td> + <td>The sqlite_stat4.nDLt column holds a list of N integers where + the K-th integer is the approximate + number of entries in the index that are distinct in the first K columns and + where the left-most K columns are collectively less than the left-most + K columns of the sample. +</td></tr></table> +</center> + +<p>The sqlite_stat4 is a generalization of the sqlite_stat3 table. The +sqlite_stat3 table provides information about the left-most column of an +index whereas the sqlite_stat4 table provides information about all columns +of the index. + +</p><p>There can be an arbitrary number of sqlite_stat4 entries per index. +The <a href="lang_analyze.html">ANALYZE</a> command will typically generate sqlite_stat4 tables +that contain between 10 and 40 samples that are distributed across +the key space and with large nEq values. + +</p><p>In a well-formed sqlite_stat4 table, the samples for any single +index must appear in the same order that they occur in the index. +In other words, if entry S1 is earlier in the index b-tree than +entry S2, then in the sqlite_stat4 table, sample S1 must have a +smaller rowid than sample S2. + +<a name="rollbackjournal"></a> + +</p><h1 id="the_rollback_journal"><span>3. </span>The Rollback Journal</h1> + +<p>The rollback journal is a file associated with each SQLite database +file that holds information used to restore the database file to its initial +state during the course of a transaction. +The rollback journal file is always located in the same +directory as the database +file and has the same name as the database file but with the string +"<tt>-journal</tt>" appended. There can only be a single rollback journal +associated with a give database and hence there can only be one write +transaction open against a single database at one time.</p> + +<p>If a transaction is aborted due to an application crash, an operating +system crash, or a hardware power failure or crash, then the database may +be left in an inconsistent state. The next time SQLite attempts to open +the database file, the presence of the rollback journal file will be +detected and the journal will be automatically played back to restore the +database to its state at the start of the incomplete transaction.</p> + +<p>A rollback journal is only considered to be valid if it exists and +contains a valid header. Hence a transaction can be committed in one +of three ways: +</p><ol> +<li>The rollback journal file can be deleted, +</li><li>The rollback journal file can be truncated to zero length, or +</li><li>The header of the rollback journal can be overwritten with +invalid header text (for example, all zeros). +</li></ol> +<p> +These three ways of committing a transaction correspond to the DELETE, +TRUNCATE, and PERSIST settings, respectively, of the <a href="pragma.html#pragma_journal_mode">journal_mode pragma</a>. +</p> + + +<p>A valid rollback journal begins with a header in the following format:</p> + +<center> +<i>Rollback Journal Header Format</i><br> +<table width="80%" border="1"> +<tr><th>Offset</th><th>Size</th><th>Description +</th></tr><tr><td valign="top" align="center">0 + </td><td valign="top" align="center">8 + </td><td>Header string: 0xd9, 0xd5, 0x05, 0xf9, 0x20, 0xa1, 0x63, 0xd7 +</td></tr><tr><td valign="top" align="center">8 + </td><td valign="top" align="center">4 + </td><td>The "Page Count" - The number of pages in the next segment of the + journal, or -1 to + mean all content to the end of the file +</td></tr><tr><td valign="top" align="center">12 + </td><td valign="top" align="center">4 + </td><td>A random nonce for the checksum +</td></tr><tr><td valign="top" align="center">16 + </td><td valign="top" align="center">4 + </td><td>Initial size of the database in pages +</td></tr><tr><td valign="top" align="center">20 + </td><td valign="top" align="center">4 + </td><td>Size of a disk sector assumed by the process that wrote this + journal. +</td></tr><tr><td valign="top" align="center">24 + </td><td valign="top" align="center">4 + </td><td>Size of pages in this journal. +</td></tr></table> +</center> + +<p>A rollback journal header is padded with zeros out to the size of a +single sector (as defined by the sector size integer at offset 20). +The header is in a sector by itself so that if a power loss occurs while +writing the sector, information that follows the header will be +(hopefully) undamaged.</p> + +<p>After the header and zero padding are zero or more page records. Each +page record stores a copy of the content of a page from the database file +before it was changed. The same page may not appear more than once +within a single rollback journal. +To rollback an incomplete transaction, a process +has merely to read the rollback journal from beginning to end and +write pages found in the journal back into the database file at the +appropriate location.</p> + +<p>Let the database page size (the value of the integer at offset 24 +in the journal header) be N. +Then the format of a page record is as follows:</p> + +<center> +<i>Rollback Journal Page Record Format</i><br> +<table width="80%" border="1"> +<tr><th>Offset</th><th>Size</th><th>Description +</th></tr><tr><td valign="top" align="center">0 + </td><td valign="top" align="center">4 + </td><td>The page number in the database file +</td></tr><tr><td valign="top" align="center">4 + </td><td valign="top" align="center">N + </td><td>Original content of the page prior to the start of the transaction +</td></tr><tr><td valign="top" align="center">N+4 + </td><td valign="top" align="center">4 + </td><td>Checksum +</td></tr></table> +</center> + + +<p>The checksum is an unsigned 32-bit integer computed as follows:</p> + +<ol> +<li>Initialize the checksum to the checksum nonce value found in the +journal header at offset 12. +</li><li>Initialize index X to be N-200 (where N is the size of a database page +in bytes. +</li><li>Interpret the byte at offset X into the page as an 8-bit unsigned integer + and add the value of that integer to the checksum. +</li><li>Subtract 200 from X. +</li><li>If X is greater than or equal to zero, go back to step 3. +</li></ol> + +<p>The checksum value is used to guard against incomplete writes of +a journal page record following a power failure. A different random nonce +is used each time a transaction is started in order to minimize the risk +that unwritten sectors might by chance contain data from the same page +that was a part of prior journals. By changing the nonce for each +transaction, stale data on disk will still generate an incorrect checksum +and be detected with high probability. The checksum only uses a sparse sample +of 32-bit words from the data record for performance reasons - design studies +during the planning phases of SQLite 3.0.0 showed +a significant performance hit in checksumming the entire page.</p> + +<p>Let the page count value at offset 8 in the journal header be M. +If M is greater than zero then after M page records the journal file +may be zero padded out to the next multiple of the sector size and another +journal header may be inserted. All journal headers within the same +journal must contain the same database page size and sector size.</p> + +<p>If M is -1 in the initial journal header, then the number of page records +that follow is computed by computing how many page records will fit in +the available space of the remainder of the journal file.</p> + +<a name="walformat"></a> + +<h1 id="the_write_ahead_log"><span>4. </span>The Write-Ahead Log</h1> + +<p>Beginning with <a href="releaselog/3_7_0.html">version 3.7.0</a> (2010-07-21), +SQLite supports a new transaction +control mechanism called "<a href="wal.html">write-ahead log</a>" or "<a href="wal.html">WAL</a>". +When a database is in WAL mode, all connections to that database must +use the WAL. A particular database will use either a rollback journal +or a WAL, but not both at the same time. +The WAL is always located in the same directory as the database +file and has the same name as the database file but with the string +"<tt>-wal</tt>" appended.</p> + +<h2 id="wal_file_format"><span>4.1. </span>WAL File Format</h2> + +<p>A <a href="wal.html#walfile">WAL file</a> consists of a header followed by zero or more "frames". +Each frame records the revised content of a single page from the +database file. All changes to the database are recorded by writing +frames into the WAL. Transactions commit when a frame is written that +contains a commit marker. A single WAL can and usually does record +multiple transactions. Periodically, the content of the WAL is +transferred back into the database file in an operation called a +"checkpoint".</p> + +<p>A single WAL file can be reused multiple times. In other words, the +WAL can fill up with frames and then be checkpointed and then new +frames can overwrite the old ones. A WAL always grows from beginning +toward the end. Checksums and counters attached to each frame are +used to determine which frames within the WAL are valid and which +are leftovers from prior checkpoints.</p> + +<p>The WAL header is 32 bytes in size and consists of the following eight +big-endian 32-bit unsigned integer values:</p> + +<center> +<i>WAL Header Format</i><br> +<table width="80%" border="1"> +<tr><th>Offset</th><th>Size</th><th>Description +</th></tr><tr><td valign="top" align="center">0</td><td valign="top" align="center">4 + </td><td>Magic number. 0x377f0682 or 0x377f0683 +</td></tr><tr><td valign="top" align="center">4</td><td valign="top" align="center">4 + </td><td>File format version. Currently 3007000. +</td></tr><tr><td valign="top" align="center">8</td><td valign="top" align="center">4 + </td><td>Database page size. Example: 1024 +</td></tr><tr><td valign="top" align="center">12</td><td valign="top" align="center">4 + </td><td>Checkpoint sequence number +</td></tr><tr><td valign="top" align="center">16</td><td valign="top" align="center">4 + </td><td>Salt-1: random integer incremented with each checkpoint +</td></tr><tr><td valign="top" align="center">20</td><td valign="top" align="center">4 + </td><td>Salt-2: a different random number for each checkpoint +</td></tr><tr><td valign="top" align="center">24</td><td valign="top" align="center">4 + </td><td>Checksum-1: First part of a checksum on the first 24 bytes of header +</td></tr><tr><td valign="top" align="center">28</td><td valign="top" align="center">4 + </td><td>Checksum-2: Second part of the checksum on the first 24 bytes of header +</td></tr></table> +</center> + +<p>Immediately following the wal-header are zero or more frames. Each +frame consists of a 24-byte frame-header followed by a <i>page-size</i> bytes +of page data. The frame-header is six big-endian 32-bit unsigned +integer values, as follows: + +</p><center> +<i>WAL Frame Header Format</i><br> +<table width="80%" border="1"> +<tr><th>Offset</th><th>Size</th><th>Description +</th></tr><tr><td valign="top" align="center">0</td><td valign="top" align="center">4 + </td><td>Page number +</td></tr><tr><td valign="top" align="center">4</td><td valign="top" align="center">4 + </td><td>For commit records, the size of the database file in pages + after the commit. For all other records, zero. +</td></tr><tr><td valign="top" align="center">8</td><td valign="top" align="center">4 + </td><td>Salt-1 copied from the WAL header +</td></tr><tr><td valign="top" align="center">12</td><td valign="top" align="center">4 + </td><td>Salt-2 copied from the WAL header +</td></tr><tr><td valign="top" align="center">16</td><td valign="top" align="center">4 + </td><td>Checksum-1: Cumulative checksum up through and including this page +</td></tr><tr><td valign="top" align="center">20</td><td valign="top" align="center">4 + </td><td>Checksum-2: Second half of the cumulative checksum. +</td></tr></table> +</center> + +<p>A frame is considered valid if and only if the following conditions are +true:</p> + +<ol> +<li><p>The salt-1 and salt-2 values in the frame-header match + salt values in the wal-header</p></li> + +<li><p>The checksum values in the final 8 bytes of the frame-header + exactly match the checksum computed consecutively on the + first 24 bytes of the WAL header and the first 8 bytes and + the content of all frames + up to and including the current frame.</p></li> +</ol> + +<a name="walcksm"></a> + +<h2 id="checksum_algorithm"><span>4.2. </span>Checksum Algorithm</h2> + +<p>The checksum is computed by interpreting the input as +an even number of unsigned 32-bit integers: x(0) through x(N). +The 32-bit integers are big-endian if the +magic number in the first 4 bytes of the WAL header is 0x377f0683 and +the integers are little-endian if the magic number is 0x377f0682. +The checksum values are always stored in the frame header in a +big-endian format regardless of which byte order is used to compute +the checksum.</p> + +<p>The checksum algorithm only works for content which is a multiple of +8 bytes in length. In other words, if the inputs are x(0) through x(N) +then N must be odd. +The checksum algorithm is as follows: + +</p><blockquote><pre> +s0 = s1 = 0 +for i from 0 to n-1 step 2: + s0 += x(i) + s1; + s1 += x(i+1) + s0; +endfor +# result in s0 and s1 +</pre></blockquote> + +<p>The outputs s0 and s1 are both weighted checksums using Fibonacci weights +in reverse order. (The largest Fibonacci weight occurs on the first element +of the sequence being summed.) The s1 value spans all 32-bit integer +terms of the sequence whereas s0 omits the final term.</p> + +<h2 id="checkpoint_algorithm"><span>4.3. </span>Checkpoint Algorithm</h2> + +<p>On a <a href="wal.html#ckpt">checkpoint</a>, the WAL is first flushed to persistent storage using +the xSync method of the <a href="c3ref/io_methods.html">VFS</a>. +Then valid content of the WAL is transferred into the database file. +Finally, the database is flushed to persistent storage using another +xSync method call. +The xSync operations serve as write barriers - all writes launched +before the xSync must complete before any write that launches after the +xSync begins.</p> + +<p>A checkpoint need not run to completion. It might be that some +readers are still using older transactions with data that is contained +in the database file. In that case, transferring content for newer +transactions from the WAL file into the database would delete the content +out from under readers still using the older transactions. To avoid that, +checkpoints only run to completion if all reader are using the +last transaction in the WAL. + +<a name="walreset"></a> + +</p><h2 id="wal_reset"><span>4.4. </span>WAL Reset</h2> + +<p>After a complete checkpoint, if no other connections are in transactions +that use the WAL, then subsequent write transactions can +overwrite the WAL file from the beginning. This is called "resetting the +WAL". At the start of the first new +write transaction, the WAL header salt-1 value is incremented +and the salt-2 value is randomized. These changes to the salts invalidate +old frames in the WAL that have already been checkpointed but not yet +overwritten, and prevent them from being checkpointed again.</p> + +<p>The WAL file can optionally be truncated on a reset, but it need not be. +Performance is usually a little better if the WAL is not truncated, since +filesystems generally will overwrite an existing file faster than they +will grow a file. + +<a name="walread"></a> + +</p><h2 id="reader_algorithm"><span>4.5. </span>Reader Algorithm</h2> + +<p>To read a page from the database (call it page number P), a reader +first checks the WAL to see if it contains page P. If so, then the +last valid instance of page P that is followed by a commit frame +or is a commit frame itself becomes the value read. If the WAL +contains no copies of page P that are valid and which are a commit +frame or are followed by a commit frame, then page P is read from +the database file.</p> + +<p>To start a read transaction, the reader records the number of value +frames in the WAL as "mxFrame". (<a href="walformat.html#mxframe">More detail</a>) +The reader uses this recorded mxFrame value +for all subsequent read operations. New transactions can be appended +to the WAL, but as long as the reader uses its original mxFrame value +and ignores subsequently appended content, the reader will see a +consistent snapshot of the database from a single point in time. +This technique allows multiple concurrent readers to view different +versions of the database content simultaneously.</p> + +<p>The reader algorithm in the previous paragraphs works correctly, but +because frames for page P can appear anywhere within the WAL, the +reader has to scan the entire WAL looking for page P frames. If the +WAL is large (multiple megabytes is typical) that scan can be slow, +and read performance suffers. To overcome this problem, a separate +data structure called the wal-index is maintained to expedite the +search for frames of a particular page.</p> + +<a name="walindexformat"></a> + +<h2 id="wal_index_format"><span>4.6. </span>WAL-Index Format</h2> + +<p>Conceptually, the wal-index is shared memory, though the current +VFS implementations use a memory-mapped file for operating-system +portability. The memory-mapped +file is in the same directory as the database and has the same name +as the database with a "<tt>-shm</tt>" suffix appended. Because +the wal-index is shared memory, SQLite does not support +<a href="pragma.html#pragma_journal_mode">journal_mode=WAL</a> +on a network filesystem when clients are on different machines, as +all clients of the database must be able to share the same memory.</p> + +<p>The purpose of the wal-index is to answer this question quickly:</p> + +<blockquote><i> +Given a page number P and a maximum WAL frame index M, +return the largest WAL frame index for page P that does not exceed M, +or return NULL if there are no frames for page P that do not exceed M. +</i></blockquote> + +<p>The <i>M</i> value in the previous paragraph is the "mxFrame" value +defined in <a href="fileformat2.html#walread">section 4.4</a> that is read at the start +of a transaction and which defines the maximum frame from the WAL that +the reader will use.</p> + +<p>The wal-index is transient. After a crash, the wal-index is +reconstructed from the original WAL file. The VFS is required +to either truncate or zero the header of the wal-index when the last +connection to it closes. Because the wal-index is transient, it can +use an architecture-specific format; it does not have to be cross-platform. +Hence, unlike the database and WAL file formats which store all values +as big endian, the wal-index stores multi-byte values in the native +byte order of the host computer.</p> + +<p>This document is concerned with the persistent state of the database +file, and since the wal-index is a transient structure, no further +information about the format of the wal-index will be provided here. +Additional details on the format of the wal-index are contained in +the separate <a href="walformat.html#walidxfmt">WAL-index File Format</a> document.</p> + + |