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Linux asynchronous I/O is a relatively recent addition to the Linux kernel. It's a standard feature of the 2.6 kernel, but you can find patches for 2.4. The basic idea behind AIO is to allow a process to initiate a number of I/O operations without having to block or wait for any to complete. At some later time, or after being notified of I/O completion, the process can retrieve the results of the I/O.
Before digging into the AIO API, let's explore the different I/O models that are available under Linux. This isn't intended as an exhaustive review, but rather aims to cover the most common models to illustrate their differences from asynchronous I/O. Figure 1 shows synchronous and asynchronous models, as well as blocking and non-blocking models.
Figure 1. Simplified matrix of basic Linux I/O models
Each of these I/O models has usage patterns that are advantageous for particular applications. This section briefly explores each one.
One of the most common models is the synchronous blocking I/O model. In this model, the user-space application performs a system call that results in the application blocking. This means that the application blocks until the system call is complete (data transferred or error). The calling application is in a state where it consumes no CPU and simply awaits the response, so it is efficient from a processing perspective.
Figure 2 illustrates the traditional blocking I/O model, which is also the
most common model used in applications today. Its behaviors are well
understood, and its usage is efficient for typical applications. When the
read system call is invoked, the application blocks
and the context switches to the kernel. The read is then initiated, and when
the response returns (from the device from which you're reading), the data is
moved to the user-space buffer. Then the application is unblocked (and the
read call returns).
Figure 2. Typical flow of the synchronous blocking I/O model
From the application's perspective, the read call
spans a long duration. But, in fact, the application is actually blocked while
the read is multiplexed with other work in the kernel.
A less efficient variant of synchronous blocking is synchronous non-blocking
I/O. In this model, a device is opened as non-blocking. This means that instead of completing an I/O immediately, a
read may return an error code indicating that the command could not be immediately
satisfied (EAGAIN or
EWOULDBLOCK), as shown in Figure 3.
Figure 3. Typical flow of the synchronous non-blocking I/O model
The implication of non-blocking is that an I/O command may not be satisfied
immediately, requiring that the application make numerous calls to await
completion. This can be extremely inefficient because in many cases the application
must busy-wait until the data is available or attempt to do other work while
the command is performed in the kernel. As also shown in Figure 3,
this method can introduce latency in the I/O because any gap between the data
becoming available in the kernel and the user calling
read to return it can reduce the overall data
throughput.
Another blocking paradigm is non-blocking I/O with blocking notifications.
In this model, non-blocking I/O is configured, and then the blocking
select system call is used to determine when there's
any activity for an I/O descriptor. What makes the
select call interesting is that it can be used to
provide notification for not just one descriptor, but many. For each
descriptor, you can request notification of the descriptor's ability to write
data, availability of read data, and also whether an error has occurred.
Figure 4. Typical flow of the asynchronous blocking I/O model (select)
The primary issue with the select call is that it's not
very efficient. While it's a convenient model for asynchronous
notification, its use for high-performance I/O is not advised.
Asynchronous non-blocking I/O (AIO)
Finally, the asynchronous non-blocking I/O model is one of overlapping
processing with I/O. The read request returns immediately, indicating that the
read was successfully initiated. The application
can then perform other processing while the background read operation completes.
When the read response arrives, a signal or a thread-based callback can be generated to complete the I/O transaction.
Figure 5. Typical flow of the asynchronous non-blocking I/O model
The ability to overlap computation and I/O processing in a single process for potentially multiple I/O requests exploits the gap between processing speed and I/O speed. While one or more slow I/O requests are pending, the CPU can perform other tasks or, more commonly, operate on already completed I/Os while other I/Os are initiated.
The next section examines this model further, explores the API, and then demonstrates a number of the commands.
Motivation for asynchronous I/O
From the previous taxonomy of I/O models, you can see the motivation for AIO. The blocking models require the initiating application to block when the I/O has started. This means that it isn't possible to overlap processing and I/O at the same time. The synchronous non-blocking model allows overlap of processing and I/O, but it requires that the application check the status of the I/O on a recurring basis. This leaves asynchronous non-blocking I/O, which permits overlap of processing and I/O, including notification of I/O completion.
The functionality provided by the select function
(asynchronous blocking I/O) is similar to AIO, except that it still
blocks. However, it blocks on notifications instead of the I/O call.
This section explores the asynchronous I/O model for Linux to help you understand how to apply it in your applications.
In a traditional I/O model, there is an I/O channel that is identified by a unique handle. In UNIX®, these are file descriptors (which are the same for files, pipes, sockets, and so on). In blocking I/O, you initiate a transfer and the system call returns when it's complete or an error has occurred.
In asynchronous non-blocking I/O, you have the ability to initiate multiple
transfers at the same time. This requires a unique context for each transfer so you can identify it when it completes. In
AIO, this is an aiocb (AIO I/O Control Block)
structure. This structure contains all of the information about a transfer,
including a user buffer for data. When notification for an I/O occurs (called
a completion), the aiocb structure is provided to
uniquely identify the completed I/O. The API
demonstration shows how to do this.
The AIO interface API is quite simple, but it provides the necessary functions for data transfer with a couple of different notification models. Table 1 shows the AIO interface functions, which are further explained later in this section.
Table 1. AIO interface APIs
| API function | Description |
|---|---|
aio_read | Request an asynchronous read operation |
aio_error | Check the status of an asynchronous request |
aio_return | Get the return status of a completed asynchronous request |
aio_write | Request an asynchronous operation |
aio_suspend | Suspend the calling process until one or more asynchronous requests have completed (or failed) |
aio_cancel | Cancel an asynchronous I/O request |
lio_listio | Initiate a list of I/O operations |
Each of these API functions uses the aiocb
structure for initiating or checking. This structure has a number of
elements, but Listing 1 shows only the ones that you'll need to
(or can) use.
Listing 1. The aiocb structure showing the relevant fields
struct aiocb {
int aio_fildes; // File Descriptor
int aio_lio_opcode; // Valid only for lio_listio (r/w/nop)
volatile void *aio_buf; // Data Buffer
size_t aio_nbytes; // Number of Bytes in Data Buffer
struct sigevent aio_sigevent; // Notification Structure
/* Internal fields */
...
};
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The sigevent structure tells AIO what to do when
the I/O completes. You'll explore this structure in the AIO demonstration.
Now I'll show you how the individual API functions for AIO work
and how you can use them.
The aio_read function requests an asynchronous
read operation for a valid file descriptor. The file descriptor can represent
a file, a socket, or even a pipe. The aio_read
function has the following prototype:
int aio_read( struct aiocb *aiocbp ); |
The aio_read function returns immediately after
the request has been queued. The return value is zero on success or -1
on error, where errno is defined.
To perform a read, the application must initialize the
aiocb structure. The following short example
illustrates filling in the
aiocb request structure and using
aio_read to perform an asynchronous read request (ignore notification for now).
It also shows use of the aio_error function, but
I'll explain that later.
Listing 2. Sample code for an asynchronous read with aio_read
#include <aio.h>
...
int fd, ret;
struct aiocb my_aiocb;
fd = open( "file.txt", O_RDONLY );
if (fd < 0) perror("open");
/* Zero out the aiocb structure (recommended) */
bzero( (char *)&my_aiocb, sizeof(struct aiocb) );
/* Allocate a data buffer for the aiocb request */
my_aiocb.aio_buf = malloc(BUFSIZE+1);
if (!my_aiocb.aio_buf) perror("malloc");
/* Initialize the necessary fields in the aiocb */
my_aiocb.aio_fildes = fd;
my_aiocb.aio_nbytes = BUFSIZE;
my_aiocb.aio_offset = 0;
ret = aio_read( &my_aiocb );
if (ret < 0) perror("aio_read");
while ( aio_error( &my_aiocb ) == EINPROGRESS ) ;
if ((ret = aio_return( &my_iocb )) > 0) {
/* got ret bytes on the read */
} else {
/* read failed, consult errno */
}
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In Listing 2, after the file from which you're reading data is opened, you zero
out your aiocb structure, and then allocate a data
buffer. The reference to the data buffer is placed into
aio_buf. Subsequently, you initialize the size
of the buffer into aio_nbytes. The
aio_offset is set to zero (the first offset in
the file). You set the file descriptor from which you're reading into
aio_fildes. After these fields are set, you call
aio_read to request the read. You can then make a
call to aio_error to determine the status of the
aio_read. As long as the status is
EINPROGRESS, you busy-wait until the status
changes. At this point, your request has either succeeded or failed.
Note the similarities to reading from the file with the standard library functions. In addition to the
asynchronous nature of aio_read, another
difference is setting the offset for the read. In a typical
read call, the offset is maintained for you in the
file descriptor context. For each read, the offset is updated so that
subsequent reads address the next block of data. This isn't possible with
asynchronous I/O because you can perform many read requests simultaneously, so
you must specify the offset for each particular read request.
The aio_error function is used to determine the
status of a request. Its prototype is:
int aio_error( struct aiocb *aiocbp ); |
This function can return the following:
EINPROGRESS, indicating the request has not yet completedECANCELLED, indicating the request was cancelled by the application-1, indicating that an error occurred for which you can consulterrno
Another difference between asynchronous I/O and standard blocking I/O is that you don't
have immediate access to the return status of your function because you're not blocking on the read call. In a standard
read call, the return status is provided upon
return of the function. With asynchronous I/O, you use the
aio_return function. This function has the following
prototype:
ssize_t aio_return( struct aiocb *aiocbp ); |
This function is called only after the aio_error
call has determined that your request has completed (either successfully or
in error). The return value of aio_return is
identical to that of the read or
write system call in a synchronous context (number
of bytes transferred or -1 for error).
The aio_write function is used to request an
asynchronous write. Its function prototype is:
int aio_write( struct aiocb *aiocbp ); |
The aio_write function returns immediately,
indicating that the request has been enqueued (with a return of 0 on success
and -1 on failure, with errno properly set).
This is similar to the read system call, but
one behavior difference is worth noting. Recall that the offset to be used
is important with the read call. However, with
write, the offset is important only if used in a
file context where the O_APPEND option is not set.
If O_APPEND is set, then the offset is ignored
and the data is appended to the end of the file. Otherwise, the aio_offset field
determines the offset at which the data is written to the file.
You can use the aio_suspend function to suspend (or block)
the calling process until an asynchronous I/O request has completed, a signal
is raised, or an optional timeout occurs. The caller provides a list of
aiocb references for which the completion of at
least one will cause aio_suspend to return. The
function prototype for aio_suspend is:
int aio_suspend( const struct aiocb *const cblist[],
int n, const struct timespec *timeout );
|
Using aio_suspend is quite simple. A list of
aiocb references is provided. If any of
them complete, the call returns with 0. Otherwise, -1 is returned, indicating
an error occurred. See Listing 3.
Listing 3. Using the aio_suspend function to block on asynchronous I/Os
struct aioct *cblist[MAX_LIST] /* Clear the list. */ bzero( (char *)cblist, sizeof(cblist) ); /* Load one or more references into the list */ cblist[0] = &my_aiocb; ret = aio_read( &my_aiocb ); ret = aio_suspend( cblist, MAX_LIST, NULL ); |
Note that the second argument of aio_suspend is
the number of elements in cblist, not the
number of aiocb references. Any NULL element in the
cblist is ignored by
aio_suspend.
If a timeout is provided to aio_suspend and
the timeout occurs, then -1is returned and errno contains
EAGAIN.
The aio_cancel function allows you to cancel one
or all outstanding I/O requests for a given file descriptor. Its prototype
is:
int aio_cancel( int fd, struct aiocb *aiocbp ); |
To cancel a single request, provide the file descriptor and the
aiocb
reference. If the request is successfully cancelled, the function returns AIO_CANCELED. If the request completes, the function returns AIO_NOTCANCELED.
To cancel all requests for a given file descriptor, provide that file
descriptor and a NULL reference for aiocbp. The
function returns AIO_CANCELED if all requests
are canceled, AIO_NOT_CANCELED if at least one
request couldn't be canceled, and AIO_ALLDONE if none of the requests
could be canceled. You can then evaluate each individual AIO request using
aio_error. If the request was canceled,
aio_error returns -1, and
errno is set to
ECANCELED.
Finally, AIO provides a way to initiate multiple transfers at the same time
using the lio_listio API function. This function
is important because it means you can start lots of I/Os in the context of a
single system call (meaning one kernel context switch). This is great from a
performance perspective, so it's worth exploring. The
lio_listio API function has the following prototype:
int lio_listio( int mode, struct aiocb *list[], int nent,
struct sigevent *sig );
|
The mode argument can be
LIO_WAIT or LIO_NOWAIT. LIO_WAIT blocks the call until all I/O has completed. LIO_NOWAIT returns after
the operations have been queued. The list is a
list of aiocb references, with the maximum number of
elements defined by nent. Note that elements of
list may be NULL, which
lio_listio ignores. The
sigevent reference defines the method for signal
notification when all I/O is complete.
The request for lio_listio is slightly
different than the typical read or
write request in that the operation must be
specified. This is illustrated in Listing 4.
Listing 4. Using the lio_listio function to initiate a list of requests
struct aiocb aiocb1, aiocb2; struct aiocb *list[MAX_LIST]; ... /* Prepare the first aiocb */ aiocb1.aio_fildes = fd; aiocb1.aio_buf = malloc( BUFSIZE+1 ); aiocb1.aio_nbytes = BUFSIZE; aiocb1.aio_offset = next_offset; aiocb1.aio_lio_opcode = LIO_READ; ... bzero( (char *)list, sizeof(list) ); list[0] = &aiocb1; list[1] = &aiocb2; ret = lio_listio( LIO_WAIT, list, MAX_LIST, NULL ); |
The read operation is noted in the aio_lio_opcode
field with LIO_READ. For a write operation,
LIO_WRITE is used, but
LIO_NOP is also valid for no operation.
Now that you've seen the AIO functions that are available, this section digs into the methods that you can use for asynchronous notification. I'll explore asynchronous notification through signals and function callbacks.
Asynchronous notification with signals
The use of signals for interprocess communication (IPC) is a traditional mechanism in UNIX and is
also supported by AIO. In this paradigm, the application defines a signal
handler that is invoked when a specified signal occurs. The application then
specifies that an asynchronous request will raise a signal when the request
has completed. As part of the signal context, the particular
aiocb request is provided to keep track of
multiple potentially outstanding requests. Listing 5
demonstrates this notification method.
Listing 5. Using signals as notification for AIO requests
void setup_io( ... )
{
int fd;
struct sigaction sig_act;
struct aiocb my_aiocb;
...
/* Set up the signal handler */
sigemptyset(&sig_act.sa_mask);
sig_act.sa_flags = SA_SIGINFO;
sig_act.sa_sigaction = aio_completion_handler;
/* Set up the AIO request */
bzero( (char *)&my_aiocb, sizeof(struct aiocb) );
my_aiocb.aio_fildes = fd;
my_aiocb.aio_buf = malloc(BUF_SIZE+1);
my_aiocb.aio_nbytes = BUF_SIZE;
my_aiocb.aio_offset = next_offset;
/* Link the AIO request with the Signal Handler */
my_aiocb.aio_sigevent.sigev_notify = SIGEV_SIGNAL;
my_aiocb.aio_sigevent.sigev_signo = SIGIO;
my_aiocb.aio_sigevent.sigev_value.sival_ptr = &my_aiocb;
/* Map the Signal to the Signal Handler */
ret = sigaction( SIGIO, &sig_act, NULL );
...
ret = aio_read( &my_aiocb );
}
void aio_completion_handler( int signo, siginfo_t *info, void *context )
{
struct aiocb *req;
/* Ensure it's our signal */
if (info->si_signo == SIGIO) {
req = (struct aiocb *)info->si_value.sival_ptr;
/* Did the request complete? */
if (aio_error( req ) == 0) {
/* Request completed successfully, get the return status */
ret = aio_return( req );
}
}
return;
}
|
In Listing 5, you set up your signal handler to catch the SIGIO signal
in the aio_completion_handler function. You then initialize the
aio_sigevent structure to raise
SIGIO for notification (which is specified via the
SIGEV_SIGNAL definition in
sigev_notify). When your read completes, your signal
handler extracts the particular aiocb from the
signal's si_value structure and checks the error
status and return status to determine I/O completion.
For performance, the completion handler is an ideal spot to continue the I/O by requesting the next asynchronous transfer. In this way, when completion of one transfer has completed, you immediately start the next.
Asynchronous notification with callbacks
An alternative notification mechanism is the system callback. Instead of
raising a signal for notification, this mechanism calls a function in
user-space for notification. You initialize the
aiocb reference into the
sigevent structure to uniquely identify the
particular request being completed; see Listing 6.
Listing 6. Using thread callback notification for AIO requests
void setup_io( ... )
{
int fd;
struct aiocb my_aiocb;
...
/* Set up the AIO request */
bzero( (char *)&my_aiocb, sizeof(struct aiocb) );
my_aiocb.aio_fildes = fd;
my_aiocb.aio_buf = malloc(BUF_SIZE+1);
my_aiocb.aio_nbytes = BUF_SIZE;
my_aiocb.aio_offset = next_offset;
/* Link the AIO request with a thread callback */
my_aiocb.aio_sigevent.sigev_notify = SIGEV_THREAD;
my_aiocb.aio_sigevent.notify_function = aio_completion_handler;
my_aiocb.aio_sigevent.notify_attributes = NULL;
my_aiocb.aio_sigevent.sigev_value.sival_ptr = &my_aiocb;
...
ret = aio_read( &my_aiocb );
}
void aio_completion_handler( sigval_t sigval )
{
struct aiocb *req;
req = (struct aiocb *)sigval.sival_ptr;
/* Did the request complete? */
if (aio_error( req ) == 0) {
/* Request completed successfully, get the return status */
ret = aio_return( req );
}
return;
}
|
In Listing 6, after creating your aiocb request, you request a thread callback
using SIGEV_THREAD for the notification method.
You then specify the particular notification handler and load the context
to be passed to the handler (in this case, a reference to the
aiocb request itself). In the handler, you simply
cast the incoming sigval pointer and use the AIO
functions to validate the completion of the request.
The proc file system contains two virtual files that can be tuned for asynchronous I/O performance:
- The /proc/sys/fs/aio-nr file provides the current number of system-wide asynchronous I/O requests.
- The /proc/sys/fs/aio-max-nr file is the maximum number of allowable concurrent requests. The maximum is commonly 64KB, which is adequate for most applications.
Using asynchronous I/O can help you build faster and more efficient I/O applications. If your application can overlap processing and I/O, then AIO can help you build an application that more efficiently uses the CPU resources available to you. While this I/O model differs from the traditional blocking patterns found in most Linux applications, the asynchronous notification model is conceptually simple and can simplify your design.
Learn
-
The POSIX.1b implementation explains the internal details of AIO from the GNU
Library perspective.
- Realtime
Support in Linux explains more about AIO and a number of real-time extensions, from scheduling and
POSIX I/O to POSIX threads and high resolution timers (HRT).
-
In the Design Notes
for the 2.5 integration, learn about the design and implementation of AIO in Linux.
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In the developerWorks Linux zone, find more resources for Linux developers.
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Stay current with developerWorks technical events and Webcasts.
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M. Tim Jones is an embedded software architect and the author of GNU/Linux Application Programming, AI Application Programming, and BSD Sockets Programming from a Multilanguage Perspective. His engineering background ranges from the development of kernels for geosynchronous spacecraft to embedded systems architecture and networking protocols development. Tim is a Consultant Engineer for Emulex Corp. in Longmont, Colorado.
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