This document was originally created in early 2004 when SQLite version 2 was still in widespread use and was written to introduce the new concepts of SQLite version 3 to readers who were already familiar with SQLite version 2. But these days, most readers of this document have probably never seen SQLite version 2 and are only familiar with SQLite version 3. Nevertheless, this document continues to serve as an authoritative reference to how database file locking works in SQLite version 3.
SQLite Version 3.0.0 introduced a new locking and journaling mechanism designed to improve concurrency over SQLite version 2 and to reduce the writer starvation problem. The new mechanism also allows atomic commits of transactions involving multiple database files. This document describes the new locking mechanism. The intended audience is programmers who want to understand and/or modify the pager code and reviewers working to verify the design of SQLite version 3.
Locking and concurrency control are handled by the pager module. The pager module is responsible for making SQLite "ACID" (Atomic, Consistent, Isolated, and Durable). The pager module makes sure changes happen all at once, that either all changes occur or none of them do, that two or more processes do not try to access the database in incompatible ways at the same time, and that once changes have been written they persist until explicitly deleted. The pager also provides a memory cache of some of the contents of the disk file.
The pager is unconcerned with the details of B-Trees, text encodings, indices, and so forth. From the point of view of the pager the database consists of a single file of uniform-sized blocks. Each block is called a "page" and is usually 1024 bytes in size. The pages are numbered beginning with 1. So the first 1024 bytes of the database are called "page 1" and the second 1024 bytes are call "page 2" and so forth. All other encoding details are handled by higher layers of the library. The pager communicates with the operating system using one of several modules (Examples: os_unix.c, os_win.c) that provides a uniform abstraction for operating system services.
The pager module effectively controls access for separate threads, or separate processes, or both. Throughout this document whenever the word "process" is written you may substitute the word "thread" without changing the truth of the statement.
From the point of view of a single process, a database file can be in one of five locking states:
|UNLOCKED||No locks are held on the database. The database may be neither read nor written. Any internally cached data is considered suspect and subject to verification against the database file before being used. Other processes can read or write the database as their own locking states permit. This is the default state.|
|SHARED||The database may be read but not written. Any number of processes can hold SHARED locks at the same time, hence there can be many simultaneous readers. But no other thread or process is allowed to write to the database file while one or more SHARED locks are active.|
|RESERVED||A RESERVED lock means that the process is planning on writing to the database file at some point in the future but that it is currently just reading from the file. Only a single RESERVED lock may be active at one time, though multiple SHARED locks can coexist with a single RESERVED lock. RESERVED differs from PENDING in that new SHARED locks can be acquired while there is a RESERVED lock.|
|PENDING||A PENDING lock means that the process holding the lock wants to write to the database as soon as possible and is just waiting on all current SHARED locks to clear so that it can get an EXCLUSIVE lock. No new SHARED locks are permitted against the database if a PENDING lock is active, though existing SHARED locks are allowed to continue.|
|EXCLUSIVE||An EXCLUSIVE lock is needed in order to write to the database file. Only one EXCLUSIVE lock is allowed on the file and no other locks of any kind are allowed to coexist with an EXCLUSIVE lock. In order to maximize concurrency, SQLite works to minimize the amount of time that EXCLUSIVE locks are held.|
The operating system interface layer understands and tracks all five locking states described above. The pager module only tracks four of the five locking states. A PENDING lock is always just a temporary stepping stone on the path to an EXCLUSIVE lock and so the pager module does not track PENDING locks.
When a process wants to change a database file (and it is not in WAL mode), it first records the original unchanged database content in a rollback journal. The rollback journal is an ordinary disk file that is always located in the same directory or folder as the database file and has the same name as the database file with the addition of a
-journal suffix. The rollback journal also records the initial size of the database so that if the database file grows it can be truncated back to its original size on a rollback.
If SQLite is working with multiple databases at the same time (using the ATTACH command) then each database has its own rollback journal. But there is also a separate aggregate journal called the super-journal. The super-journal does not contain page data used for rolling back changes. Instead the super-journal contains the names of the individual database rollback journals for each of the ATTACHed databases. Each of the individual database rollback journals also contain the name of the super-journal. If there are no ATTACHed databases (or if none of the ATTACHed database is participating in the current transaction) no super-journal is created and the normal rollback journal contains an empty string in the place normally reserved for recording the name of the super-journal.
A rollback journal is said to be hot if it needs to be rolled back in order to restore the integrity of its database. A hot journal is created when a process is in the middle of a database update and a program or operating system crash or power failure prevents the update from completing. Hot journals are an exception condition. Hot journals exist to recover from crashes and power failures. If everything is working correctly (that is, if there are no crashes or power failures) you will never get a hot journal.
If no super-journal is involved, then a journal is hot if it exists and has a non-zero header and its corresponding database file does not have a RESERVED lock. If a super-journal is named in the file journal, then the file journal is hot if its super-journal exists and there is no RESERVED lock on the corresponding database file. It is important to understand when a journal is hot so the preceding rules will be repeated in bullets:
Before reading from a database file, SQLite always checks to see if that database file has a hot journal. If the file does have a hot journal, then the journal is rolled back before the file is read. In this way, we ensure that the database file is in a consistent state before it is read.
When a process wants to read from a database file, it followed the following sequence of steps:
After the algorithm above completes successfully, it is safe to read from the database file. Once all reading has completed, the SHARED lock is dropped.
A stale super-journal is a super-journal that is no longer being used for anything. There is no requirement that stale super-journals be deleted. The only reason for doing so is to free up disk space.
A super-journal is stale if no individual file journals are pointing to it. To figure out if a super-journal is stale, we first read the super-journal to obtain the names of all of its file journals. Then we check each of those file journals. If any of the file journals named in the super-journal exists and points back to the super-journal, then the super-journal is not stale. If all file journals are either missing or refer to other super-journals or no super-journal at all, then the super-journal we are testing is stale and can be safely deleted.
To write to a database, a process must first acquire a SHARED lock as described above (possibly rolling back incomplete changes if there is a hot journal). After a SHARED lock is obtained, a RESERVED lock must be acquired. The RESERVED lock signals that the process intends to write to the database at some point in the future. Only one process at a time can hold a RESERVED lock. But other processes can continue to read the database while the RESERVED lock is held.
If the process that wants to write is unable to obtain a RESERVED lock, it must mean that another process already has a RESERVED lock. In that case, the write attempt fails and returns SQLITE_BUSY.
After obtaining a RESERVED lock, the process that wants to write creates a rollback journal. The header of the journal is initialized with the original size of the database file. Space in the journal header is also reserved for a super-journal name, though the super-journal name is initially empty.
Before making changes to any page of the database, the process writes the original content of that page into the rollback journal. Changes to pages are held in memory at first and are not written to the disk. The original database file remains unaltered, which means that other processes can continue to read the database.
Eventually, the writing process will want to update the database file, either because its memory cache has filled up or because it is ready to commit its changes. Before this happens, the writer must make sure no other process is reading the database and that the rollback journal data is safely on the disk surface so that it can be used to rollback incomplete changes in the event of a power failure. The steps are as follows:
If the reason for writing to the database file is because the memory cache was full, then the writer will not commit right away. Instead, the writer might continue to make changes to other pages. Before subsequent changes are written to the database file, the rollback journal must be flushed to disk again. Note also that the EXCLUSIVE lock that the writer obtained in order to write to the database initially must be held until all changes are committed. That means that no other processes are able to access the database from the time the memory cache first spills to disk until the transaction commits.
When a writer is ready to commit its changes, it executes the following steps:
As soon as the PENDING lock is released from the database file, other processes can begin reading the database again. In the current implementation, the RESERVED lock is also released, but that is not essential for correct operation.
If a transaction involves multiple databases, then a more complex commit sequence is used, as follows:
In SQLite version 2, if many processes are reading from the database, it might be the case that there is never a time when there are no active readers. And if there is always at least one read lock on the database, no process would ever be able to make changes to the database because it would be impossible to acquire a write lock. This situation is called writer starvation.
SQLite version 3 seeks to avoid writer starvation through the use of the PENDING lock. The PENDING lock allows existing readers to continue but prevents new readers from connecting to the database. So when a process wants to write a busy database, it can set a PENDING lock which will prevent new readers from coming in. Assuming existing readers do eventually complete, all SHARED locks will eventually clear and the writer will be given a chance to make its changes.
Clearly, a hardware or operating system fault that introduces incorrect data into the middle of the database file or journal will cause problems. Likewise, if a rogue process opens a database file or journal and writes malformed data into the middle of it, then the database will become corrupt. There is not much that can be done about these kinds of problems so they are given no further attention.
SQLite uses POSIX advisory locks to implement locking on Unix. On Windows it uses the LockFile(), LockFileEx(), and UnlockFile() system calls. SQLite assumes that these system calls all work as advertised. If that is not the case, then database corruption can result. One should note that POSIX advisory locking is known to be buggy or even unimplemented on many NFS implementations (including recent versions of Mac OS X) and that there are reports of locking problems for network filesystems under Windows. Your best defense is to not use SQLite for files on a network filesystem.
SQLite uses the fsync() system call to flush data to the disk under Unix and it uses the FlushFileBuffers() to do the same under Windows. Once again, SQLite assumes that these operating system services function as advertised. But it has been reported that fsync() and FlushFileBuffers() do not always work correctly, especially with inexpensive IDE disks. Apparently some manufactures of IDE disks have controller chips that report that data has reached the disk surface when in fact the data is still in volatile cache memory in the disk drive electronics. There are also reports that Windows sometimes chooses to ignore FlushFileBuffers() for unspecified reasons. The author cannot verify any of these reports. But if they are true, it means that database corruption is a possibility following an unexpected power loss. These are hardware and/or operating system bugs that SQLite is unable to defend against.
If a Linux ext3 filesystem is mounted without the "barrier=1" option in the /etc/fstab and the disk drive write cache is enabled then filesystem corruption can occur following a power loss or OS crash. Whether or not corruption can occur depends on the details of the disk control hardware; corruption is more likely with inexpensive consumer-grade disks and less of a problem for enterprise-class storage devices with advanced features such as non-volatile write caches. Various ext3 experts confirm this behavior. We are told that most Linux distributions do not use barrier=1 and do not disable the write cache so most Linux distributions are vulnerable to this problem. Note that this is an operating system and hardware issue and that there is nothing that SQLite can do to work around it. Other database engines have also run into this same problem.
If a crash or power failure occurs and results in a hot journal but that journal is deleted, the next process to open the database will not know that it contains changes that need to be rolled back. The rollback will not occur and the database will be left in an inconsistent state. Rollback journals might be deleted for any number of reasons:
The last (fourth) bullet above merits additional comment. When SQLite creates a journal file on Unix, it opens the directory that contains that file and calls fsync() on the directory, in an effort to push the directory information to disk. But suppose some other process is adding or removing unrelated files to the directory that contains the database and journal at the moment of a power failure. The supposedly unrelated actions of this other process might result in the journal file being dropped from the directory and moved into "lost+found". This is an unlikely scenario, but it could happen. The best defenses are to use a journaling filesystem or to keep the database and journal in a directory by themselves.
For a commit involving multiple databases and a super-journal, if the various databases were on different disk volumes and a power failure occurs during the commit, then when the machine comes back up the disks might be remounted with different names. Or some disks might not be mounted at all. When this happens the individual file journals and the super-journal might not be able to find each other. The worst outcome from this scenario is that the commit ceases to be atomic. Some databases might be rolled back and others might not. All databases will continue to be self-consistent. To defend against this problem, keep all databases on the same disk volume and/or remount disks using exactly the same names after a power failure.
The changes to locking and concurrency control in SQLite version 3 also introduce some subtle changes in the way transactions work at the SQL language level. By default, SQLite version 3 operates in autocommit mode. In autocommit mode, all changes to the database are committed as soon as all operations associated with the current database connection complete.
The SQL command "BEGIN TRANSACTION" (the TRANSACTION keyword is optional) is used to take SQLite out of autocommit mode. Note that the BEGIN command does not acquire any locks on the database. After a BEGIN command, a SHARED lock will be acquired when the first SELECT statement is executed. A RESERVED lock will be acquired when the first INSERT, UPDATE, or DELETE statement is executed. No EXCLUSIVE lock is acquired until either the memory cache fills up and must be spilled to disk or until the transaction commits. In this way, the system delays blocking read access to the file file until the last possible moment.
The SQL command "COMMIT" does not actually commit the changes to disk. It just turns autocommit back on. Then, at the conclusion of the command, the regular autocommit logic takes over and causes the actual commit to disk to occur. The SQL command "ROLLBACK" also operates by turning autocommit back on, but it also sets a flag that tells the autocommit logic to rollback rather than commit.
If the SQL COMMIT command turns autocommit on and the autocommit logic then tries to commit change but fails because some other process is holding a SHARED lock, then autocommit is turned back off automatically. This allows the user to retry the COMMIT at a later time after the SHARED lock has had an opportunity to clear.
If multiple commands are being executed against the same SQLite database connection at the same time, the autocommit is deferred until the very last command completes. For example, if a SELECT statement is being executed, the execution of the command will pause as each row of the result is returned. During this pause other INSERT, UPDATE, or DELETE commands can be executed against other tables in the database. But none of these changes will commit until the original SELECT statement finishes.
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