2012-11-29 18:26:11 +04:00
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NOTE (2012-11-29):
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2012-12-07 13:08:42 +04:00
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The functionality implemented by this extension has been superseded
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2012-11-29 18:26:11 +04:00
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by WAL-mode. This module is no longer supported or maintained. The
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code is retained for historical reference only.
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------------------------------------------------------------------------------
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2009-04-24 13:27:16 +04:00
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Normally, when SQLite writes to a database file, it waits until the write
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operation is finished before returning control to the calling application.
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Since writing to the file-system is usually very slow compared with CPU
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bound operations, this can be a performance bottleneck. This directory
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contains an extension that causes SQLite to perform all write requests
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using a separate thread running in the background. Although this does not
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reduce the overall system resources (CPU, disk bandwidth etc.) at all, it
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allows SQLite to return control to the caller quickly even when writing to
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the database, eliminating the bottleneck.
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1. Functionality
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1.1 How it Works
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1.2 Limitations
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1.3 Locking and Concurrency
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2. Compilation and Usage
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3. Porting
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1. FUNCTIONALITY
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With asynchronous I/O, write requests are handled by a separate thread
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running in the background. This means that the thread that initiates
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a database write does not have to wait for (sometimes slow) disk I/O
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to occur. The write seems to happen very quickly, though in reality
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it is happening at its usual slow pace in the background.
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Asynchronous I/O appears to give better responsiveness, but at a price.
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You lose the Durable property. With the default I/O backend of SQLite,
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once a write completes, you know that the information you wrote is
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safely on disk. With the asynchronous I/O, this is not the case. If
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your program crashes or if a power loss occurs after the database
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write but before the asynchronous write thread has completed, then the
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database change might never make it to disk and the next user of the
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database might not see your change.
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You lose Durability with asynchronous I/O, but you still retain the
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other parts of ACID: Atomic, Consistent, and Isolated. Many
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appliations get along fine without the Durablity.
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1.1 How it Works
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Asynchronous I/O works by creating a special SQLite "vfs" structure
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and registering it with sqlite3_vfs_register(). When files opened via
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this vfs are written to (using the vfs xWrite() method), the data is not
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written directly to disk, but is placed in the "write-queue" to be
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handled by the background thread.
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When files opened with the asynchronous vfs are read from
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(using the vfs xRead() method), the data is read from the file on
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disk and the write-queue, so that from the point of view of
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the vfs reader the xWrite() appears to have already completed.
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The special vfs is registered (and unregistered) by calls to the
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API functions sqlite3async_initialize() and sqlite3async_shutdown().
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See section "Compilation and Usage" below for details.
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1.2 Limitations
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In order to gain experience with the main ideas surrounding asynchronous
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IO, this implementation is deliberately kept simple. Additional
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capabilities may be added in the future.
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For example, as currently implemented, if writes are happening at a
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steady stream that exceeds the I/O capability of the background writer
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thread, the queue of pending write operations will grow without bound.
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If this goes on for long enough, the host system could run out of memory.
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A more sophisticated module could to keep track of the quantity of
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pending writes and stop accepting new write requests when the queue of
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pending writes grows too large.
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1.3 Locking and Concurrency
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Multiple connections from within a single process that use this
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implementation of asynchronous IO may access a single database
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file concurrently. From the point of view of the user, if all
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connections are from within a single process, there is no difference
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between the concurrency offered by "normal" SQLite and SQLite
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using the asynchronous backend.
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If file-locking is enabled (it is enabled by default), then connections
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from multiple processes may also read and write the database file.
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However concurrency is reduced as follows:
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* When a connection using asynchronous IO begins a database
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transaction, the database is locked immediately. However the
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lock is not released until after all relevant operations
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in the write-queue have been flushed to disk. This means
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(for example) that the database may remain locked for some
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time after a "COMMIT" or "ROLLBACK" is issued.
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* If an application using asynchronous IO executes transactions
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in quick succession, other database users may be effectively
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locked out of the database. This is because when a BEGIN
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is executed, a database lock is established immediately. But
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when the corresponding COMMIT or ROLLBACK occurs, the lock
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is not released until the relevant part of the write-queue
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has been flushed through. As a result, if a COMMIT is followed
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by a BEGIN before the write-queue is flushed through, the database
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is never unlocked,preventing other processes from accessing
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the database.
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File-locking may be disabled at runtime using the sqlite3async_control()
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API (see below). This may improve performance when an NFS or other
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network file-system, as the synchronous round-trips to the server be
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required to establish file locks are avoided. However, if multiple
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connections attempt to access the same database file when file-locking
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is disabled, application crashes and database corruption is a likely
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outcome.
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2. COMPILATION AND USAGE
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The asynchronous IO extension consists of a single file of C code
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(sqlite3async.c), and a header file (sqlite3async.h) that defines the
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C API used by applications to activate and control the modules
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functionality.
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To use the asynchronous IO extension, compile sqlite3async.c as
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part of the application that uses SQLite. Then use the API defined
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in sqlite3async.h to initialize and configure the module.
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The asynchronous IO VFS API is described in detail in comments in
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sqlite3async.h. Using the API usually consists of the following steps:
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1. Register the asynchronous IO VFS with SQLite by calling the
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sqlite3async_initialize() function.
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2. Create a background thread to perform write operations and call
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sqlite3async_run().
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3. Use the normal SQLite API to read and write to databases via
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the asynchronous IO VFS.
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Refer to sqlite3async.h for details.
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3. PORTING
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Currently the asynchronous IO extension is compatible with win32 systems
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and systems that support the pthreads interface, including Mac OSX, Linux,
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and other varieties of Unix.
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To port the asynchronous IO extension to another platform, the user must
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implement mutex and condition variable primitives for the new platform.
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Currently there is no externally available interface to allow this, but
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modifying the code within sqlite3async.c to include the new platforms
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concurrency primitives is relatively easy. Search within sqlite3async.c
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for the comment string "PORTING FUNCTIONS" for details. Then implement
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new versions of each of the following:
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static void async_mutex_enter(int eMutex);
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static void async_mutex_leave(int eMutex);
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static void async_cond_wait(int eCond, int eMutex);
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static void async_cond_signal(int eCond);
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static void async_sched_yield(void);
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The functionality required of each of the above functions is described
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in comments in sqlite3async.c.
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