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|
/******************************************************
The interface to the operating system file i/o primitives
(c) 1995 Innobase Oy
Created 10/21/1995 Heikki Tuuri
*******************************************************/
#include "os0file.h"
#include "os0sync.h"
#include "ut0mem.h"
#include "srv0srv.h"
#include "trx0sys.h"
#include "fil0fil.h"
#undef HAVE_FDATASYNC
#ifdef POSIX_ASYNC_IO
/* We assume in this case that the OS has standard Posix aio (at least SunOS
2.6, HP-UX 11i and AIX 4.3 have) */
#endif
/* We use these mutexes to protect lseek + file i/o operation, if the
OS does not provide an atomic pread or pwrite, or similar */
#define OS_FILE_N_SEEK_MUTEXES 16
os_mutex_t os_file_seek_mutexes[OS_FILE_N_SEEK_MUTEXES];
/* In simulated aio, merge at most this many consecutive i/os */
#define OS_AIO_MERGE_N_CONSECUTIVE 32
/* If this flag is TRUE, then we will use the native aio of the
OS (provided we compiled Innobase with it in), otherwise we will
use simulated aio we build below with threads */
ibool os_aio_use_native_aio = FALSE;
/* The aio array slot structure */
typedef struct os_aio_slot_struct os_aio_slot_t;
struct os_aio_slot_struct{
ibool is_read; /* TRUE if a read operation */
ulint pos; /* index of the slot in the aio
array */
ibool reserved; /* TRUE if this slot is reserved */
ulint len; /* length of the block to read or
write */
byte* buf; /* buffer used in i/o */
ulint type; /* OS_FILE_READ or OS_FILE_WRITE */
ulint offset; /* 32 low bits of file offset in
bytes */
ulint offset_high; /* 32 high bits of file offset */
os_file_t file; /* file where to read or write */
char* name; /* file name or path */
ibool io_already_done;/* used only in simulated aio:
TRUE if the physical i/o already
made and only the slot message
needs to be passed to the caller
of os_aio_simulated_handle */
void* message1; /* message which is given by the */
void* message2; /* the requester of an aio operation
and which can be used to identify
which pending aio operation was
completed */
#ifdef WIN_ASYNC_IO
OVERLAPPED control; /* Windows control block for the
aio request */
#elif defined(POSIX_ASYNC_IO)
struct aiocb control; /* Posix control block for aio
request */
#endif
};
/* The aio array structure */
typedef struct os_aio_array_struct os_aio_array_t;
struct os_aio_array_struct{
os_mutex_t mutex; /* the mutex protecting the aio array */
os_event_t not_full; /* The event which is set to the signaled
state when there is space in the aio
outside the ibuf segment */
os_event_t is_empty; /* The event which is set to the signaled
state when there are no pending i/os
in this array */
ulint n_slots; /* Total number of slots in the aio array.
This must be divisible by n_threads. */
ulint n_segments;/* Number of segments in the aio array of
pending aio requests. A thread can wait
separately for any one of the segments. */
ulint n_reserved;/* Number of reserved slots in the
aio array outside the ibuf segment */
os_aio_slot_t* slots; /* Pointer to the slots in the array */
os_event_t* events; /* Pointer to an array of event handles
where we copied the handles from slots,
in the same order. This can be used in
WaitForMultipleObjects; used only in
Windows */
};
/* Array of events used in simulated aio */
os_event_t* os_aio_segment_wait_events = NULL;
/* The aio arrays for non-ibuf i/o and ibuf i/o, as well as sync aio. These
are NULL when the module has not yet been initialized. */
os_aio_array_t* os_aio_read_array = NULL;
os_aio_array_t* os_aio_write_array = NULL;
os_aio_array_t* os_aio_ibuf_array = NULL;
os_aio_array_t* os_aio_log_array = NULL;
os_aio_array_t* os_aio_sync_array = NULL;
ulint os_aio_n_segments = ULINT_UNDEFINED;
ulint os_n_file_reads = 0;
ulint os_n_file_writes = 0;
ulint os_n_fsyncs = 0;
ulint os_n_file_reads_old = 0;
ulint os_n_file_writes_old = 0;
ulint os_n_fsyncs_old = 0;
time_t os_last_printout;
/***************************************************************************
Gets the operating system version. Currently works only on Windows. */
ulint
os_get_os_version(void)
/*===================*/
/* out: OS_WIN95, OS_WIN31, OS_WINNT (2000 == NT) */
{
#ifdef __WIN__
OSVERSIONINFO os_info;
os_info.dwOSVersionInfoSize = sizeof(OSVERSIONINFO);
ut_a(GetVersionEx(&os_info));
if (os_info.dwPlatformId == VER_PLATFORM_WIN32s) {
return(OS_WIN31);
} else if (os_info.dwPlatformId == VER_PLATFORM_WIN32_WINDOWS) {
return(OS_WIN95);
} else if (os_info.dwPlatformId == VER_PLATFORM_WIN32_NT) {
return(OS_WINNT);
} else {
ut_error;
return(0);
}
#else
ut_error;
return(0);
#endif
}
/***************************************************************************
Retrieves the last error number if an error occurs in a file io function.
The number should be retrieved before any other OS calls (because they may
overwrite the error number). If the number is not known to this program,
the OS error number + 100 is returned. */
ulint
os_file_get_last_error(void)
/*========================*/
/* out: error number, or OS error number + 100 */
{
ulint err;
#ifdef __WIN__
err = (ulint) GetLastError();
if (err != ERROR_FILE_EXISTS) {
fprintf(stderr,
"InnoDB: Warning: operating system error number %li in a file operation.\n",
(long) err);
}
if (err == ERROR_FILE_NOT_FOUND) {
return(OS_FILE_NOT_FOUND);
} else if (err == ERROR_DISK_FULL) {
return(OS_FILE_DISK_FULL);
} else if (err == ERROR_FILE_EXISTS) {
return(OS_FILE_ALREADY_EXISTS);
} else {
return(100 + err);
}
#else
err = (ulint) errno;
if (err != EEXIST) {
fprintf(stderr,
"InnoDB: Warning: operating system error number %i in a file operation.\n",
errno);
}
if (err == ENOSPC ) {
return(OS_FILE_DISK_FULL);
#ifdef POSIX_ASYNC_IO
} else if (err == EAGAIN) {
return(OS_FILE_AIO_RESOURCES_RESERVED);
#endif
} else if (err == ENOENT) {
return(OS_FILE_NOT_FOUND);
} else if (err == EEXIST) {
return(OS_FILE_ALREADY_EXISTS);
} else {
return(100 + err);
}
#endif
}
/********************************************************************
Does error handling when a file operation fails. If we have run out
of disk space, then the user can clean the disk. If we do not find
a specified file, then the user can copy it to disk. */
static
ibool
os_file_handle_error(
/*=================*/
/* out: TRUE if we should retry the operation */
os_file_t file, /* in: file pointer */
char* name) /* in: name of a file or NULL */
{
ulint err;
UT_NOT_USED(file);
err = os_file_get_last_error();
if (err == OS_FILE_DISK_FULL) {
fprintf(stderr, "\n");
if (name) {
fprintf(stderr,
"InnoDB: Encountered a problem with file %s.\n",
name);
}
fprintf(stderr,
"InnoDB: Cannot continue operation.\n"
"InnoDB: Disk is full. Try to clean the disk to free space.\n"
"InnoDB: Delete possible created file and restart.\n");
exit(1);
} else if (err == OS_FILE_AIO_RESOURCES_RESERVED) {
return(TRUE);
} else if (err == OS_FILE_ALREADY_EXISTS) {
return(FALSE);
} else {
fprintf(stderr, "InnoDB: Cannot continue operation.\n");
exit(1);
}
return(FALSE);
}
/********************************************************************
Opens an existing file or creates a new. */
os_file_t
os_file_create(
/*===========*/
/* out, own: handle to the file, not defined if error,
error number can be retrieved with os_get_last_error */
char* name, /* in: name of the file or path as a null-terminated
string */
ulint create_mode, /* in: OS_FILE_OPEN if an existing file is opened
(if does not exist, error), or OS_FILE_CREATE if a new
file is created (if exists, error), OS_FILE_OVERWRITE
if a new is created or an old overwritten */
ulint purpose,/* in: OS_FILE_AIO, if asynchronous, non-buffered i/o
is desired, OS_FILE_NORMAL, if any normal file */
ulint type, /* in: OS_DATA_FILE or OS_LOG_FILE */
ibool* success)/* out: TRUE if succeed, FALSE if error */
{
#ifdef __WIN__
os_file_t file;
DWORD create_flag;
DWORD attributes;
ibool retry;
try_again:
ut_a(name);
if (create_mode == OS_FILE_OPEN) {
create_flag = OPEN_EXISTING;
} else if (create_mode == OS_FILE_CREATE) {
create_flag = CREATE_NEW;
} else if (create_mode == OS_FILE_OVERWRITE) {
create_flag = CREATE_ALWAYS;
} else {
create_flag = 0;
ut_error;
}
if (purpose == OS_FILE_AIO) {
/* use asynchronous (overlapped) io and no buffering
of writes in the OS */
attributes = 0;
#ifdef WIN_ASYNC_IO
if (os_aio_use_native_aio) {
attributes = attributes | FILE_FLAG_OVERLAPPED;
}
#endif
#ifdef UNIV_NON_BUFFERED_IO
attributes = attributes | FILE_FLAG_NO_BUFFERING;
#endif
} else if (purpose == OS_FILE_NORMAL) {
attributes = 0
#ifdef UNIV_NON_BUFFERED_IO
| FILE_FLAG_NO_BUFFERING
#endif
;
} else {
attributes = 0;
ut_error;
}
file = CreateFile(name,
GENERIC_READ | GENERIC_WRITE, /* read and write
access */
FILE_SHARE_READ,/* file can be read by other
processes */
NULL, /* default security attributes */
create_flag,
attributes,
NULL); /* no template file */
if (file == INVALID_HANDLE_VALUE) {
*success = FALSE;
retry = os_file_handle_error(file, name);
if (retry) {
goto try_again;
}
} else {
*success = TRUE;
}
return(file);
#else
os_file_t file;
int create_flag;
ibool retry;
try_again:
ut_a(name);
if (create_mode == OS_FILE_OPEN) {
create_flag = O_RDWR;
} else if (create_mode == OS_FILE_CREATE) {
create_flag = O_RDWR | O_CREAT | O_EXCL;
} else if (create_mode == OS_FILE_OVERWRITE) {
create_flag = O_RDWR | O_CREAT | O_TRUNC;
} else {
create_flag = 0;
ut_error;
}
UT_NOT_USED(purpose);
#ifdef O_SYNC
if ((!srv_use_doublewrite_buf || type != OS_DATA_FILE)
&& srv_unix_file_flush_method == SRV_UNIX_O_DSYNC) {
create_flag = create_flag | O_SYNC;
}
#endif
if (create_mode == OS_FILE_CREATE) {
file = open(name, create_flag, S_IRUSR | S_IWUSR | S_IRGRP
| S_IWGRP | S_IROTH | S_IWOTH);
} else {
file = open(name, create_flag);
}
if (file == -1) {
*success = FALSE;
retry = os_file_handle_error(file, name);
if (retry) {
goto try_again;
}
} else {
*success = TRUE;
}
return(file);
#endif
}
/***************************************************************************
Closes a file handle. In case of error, error number can be retrieved with
os_file_get_last_error. */
ibool
os_file_close(
/*==========*/
/* out: TRUE if success */
os_file_t file) /* in, own: handle to a file */
{
#ifdef __WIN__
BOOL ret;
ut_a(file);
ret = CloseHandle(file);
if (ret) {
return(TRUE);
}
os_file_handle_error(file, NULL);
return(FALSE);
#else
int ret;
ret = close(file);
if (ret == -1) {
os_file_handle_error(file, NULL);
return(FALSE);
}
return(TRUE);
#endif
}
/***************************************************************************
Gets a file size. */
ibool
os_file_get_size(
/*=============*/
/* out: TRUE if success */
os_file_t file, /* in: handle to a file */
ulint* size, /* out: least significant 32 bits of file
size */
ulint* size_high)/* out: most significant 32 bits of size */
{
#ifdef __WIN__
DWORD high;
DWORD low;
low = GetFileSize(file, &high);
if ((low == 0xFFFFFFFF) && (GetLastError() != NO_ERROR)) {
return(FALSE);
}
*size = low;
*size_high = high;
return(TRUE);
#else
*size = (ulint) lseek(file, 0, SEEK_END);
*size_high = 0;
return(TRUE);
#endif
}
/***************************************************************************
Sets a file size. This function can be used to extend or truncate a file. */
ibool
os_file_set_size(
/*=============*/
/* out: TRUE if success */
char* name, /* in: name of the file or path as a
null-terminated string */
os_file_t file, /* in: handle to a file */
ulint size, /* in: least significant 32 bits of file
size */
ulint size_high)/* in: most significant 32 bits of size */
{
ulint offset;
ulint n_bytes;
ulint low;
ibool ret;
ibool retry;
ulint i;
byte* buf;
try_again:
/* We use a very big 8 MB buffer in writing because Linux may be
extremely slow in fdatasync on 1 MB writes */
buf = ut_malloc(UNIV_PAGE_SIZE * 512);
/* Write buffer full of zeros */
for (i = 0; i < UNIV_PAGE_SIZE * 512; i++) {
buf[i] = '\0';
}
offset = 0;
low = size;
#if (UNIV_WORD_SIZE == 8)
low = low + (size_high << 32);
#else
UT_NOT_USED(size_high);
#endif
while (offset < low) {
if (low - offset < UNIV_PAGE_SIZE * 512) {
n_bytes = low - offset;
} else {
n_bytes = UNIV_PAGE_SIZE * 512;
}
ret = os_file_write(name, file, buf, offset, 0, n_bytes);
if (!ret) {
ut_free(buf);
goto error_handling;
}
offset += n_bytes;
}
ut_free(buf);
ret = os_file_flush(file);
if (ret) {
return(TRUE);
}
error_handling:
retry = os_file_handle_error(file, name);
if (retry) {
goto try_again;
}
ut_error;
return(FALSE);
}
/***************************************************************************
Flushes the write buffers of a given file to the disk. */
ibool
os_file_flush(
/*==========*/
/* out: TRUE if success */
os_file_t file) /* in, own: handle to a file */
{
#ifdef __WIN__
BOOL ret;
ut_a(file);
ret = FlushFileBuffers(file);
if (ret) {
return(TRUE);
}
os_file_handle_error(file, NULL);
return(FALSE);
#else
int ret;
#ifdef HAVE_FDATASYNC
ret = fdatasync(file);
#else
ret = fsync(file);
#endif
os_n_fsyncs++;
if (ret == 0) {
return(TRUE);
}
fprintf(stderr,
"InnoDB: Error: the OS said file flush did not succeed\n");
os_file_handle_error(file, NULL);
return(FALSE);
#endif
}
#ifndef __WIN__
/***********************************************************************
Does a synchronous read operation in Posix. */
static
ssize_t
os_file_pread(
/*==========*/
/* out: number of bytes read, -1 if error */
os_file_t file, /* in: handle to a file */
void* buf, /* in: buffer where to read */
ulint n, /* in: number of bytes to read */
ulint offset) /* in: offset from where to read */
{
off_t offs = (off_t)offset;
os_n_file_reads++;
#ifdef HAVE_PREAD
return(pread(file, buf, n, offs));
#else
{
ssize_t ret;
ulint i;
/* Protect the seek / read operation with a mutex */
i = ((ulint) file) % OS_FILE_N_SEEK_MUTEXES;
os_mutex_enter(os_file_seek_mutexes[i]);
ret = lseek(file, offs, 0);
if (ret < 0) {
os_mutex_exit(os_file_seek_mutexes[i]);
return(ret);
}
ret = read(file, buf, n);
os_mutex_exit(os_file_seek_mutexes[i]);
return(ret);
}
#endif
}
/***********************************************************************
Does a synchronous write operation in Posix. */
static
ssize_t
os_file_pwrite(
/*===========*/
/* out: number of bytes written, -1 if error */
os_file_t file, /* in: handle to a file */
void* buf, /* in: buffer from where to write */
ulint n, /* in: number of bytes to write */
ulint offset) /* in: offset where to write */
{
ssize_t ret;
off_t offs = (off_t)offset;
os_n_file_writes++;
#ifdef HAVE_PWRITE
ret = pwrite(file, buf, n, offs);
if (srv_unix_file_flush_method != SRV_UNIX_LITTLESYNC
&& srv_unix_file_flush_method != SRV_UNIX_NOSYNC
&& !trx_doublewrite) {
/* Always do fsync to reduce the probability that when
the OS crashes, a database page is only partially
physically written to disk. */
ut_a(TRUE == os_file_flush(file));
}
return(ret);
#else
{
ulint i;
/* Protect the seek / write operation with a mutex */
i = ((ulint) file) % OS_FILE_N_SEEK_MUTEXES;
os_mutex_enter(os_file_seek_mutexes[i]);
ret = lseek(file, offs, 0);
if (ret < 0) {
os_mutex_exit(os_file_seek_mutexes[i]);
return(ret);
}
ret = write(file, buf, n);
if (srv_unix_file_flush_method != SRV_UNIX_LITTLESYNC
&& srv_unix_file_flush_method != SRV_UNIX_NOSYNC
&& !trx_doublewrite) {
/* Always do fsync to reduce the probability that when
the OS crashes, a database page is only partially
physically written to disk. */
ut_a(TRUE == os_file_flush(file));
}
os_mutex_exit(os_file_seek_mutexes[i]);
return(ret);
}
#endif
}
#endif
/***********************************************************************
Requests a synchronous positioned read operation. */
ibool
os_file_read(
/*=========*/
/* out: TRUE if request was
successful, FALSE if fail */
os_file_t file, /* in: handle to a file */
void* buf, /* in: buffer where to read */
ulint offset, /* in: least significant 32 bits of file
offset where to read */
ulint offset_high, /* in: most significant 32 bits of
offset */
ulint n) /* in: number of bytes to read */
{
#ifdef __WIN__
BOOL ret;
DWORD len;
DWORD ret2;
DWORD low;
DWORD high;
ibool retry;
ulint i;
os_n_file_reads++;
try_again:
ut_ad(file);
ut_ad(buf);
ut_ad(n > 0);
low = offset;
high = offset_high;
/* Protect the seek / read operation with a mutex */
i = ((ulint) file) % OS_FILE_N_SEEK_MUTEXES;
os_mutex_enter(os_file_seek_mutexes[i]);
ret2 = SetFilePointer(file, low, &high, FILE_BEGIN);
if (ret2 == 0xFFFFFFFF && GetLastError() != NO_ERROR) {
os_mutex_exit(os_file_seek_mutexes[i]);
goto error_handling;
}
ret = ReadFile(file, buf, n, &len, NULL);
os_mutex_exit(os_file_seek_mutexes[i]);
if (ret && len == n) {
return(TRUE);
}
#else
ibool retry;
ssize_t ret;
#if (UNIV_WORD_SIZE == 8)
offset = offset + (offset_high << 32);
#else
UT_NOT_USED(offset_high);
#endif
try_again:
ret = os_file_pread(file, buf, n, offset);
if ((ulint)ret == n) {
return(TRUE);
}
#endif
error_handling:
retry = os_file_handle_error(file, NULL);
if (retry) {
goto try_again;
}
ut_error;
return(FALSE);
}
/***********************************************************************
Requests a synchronous write operation. */
ibool
os_file_write(
/*==========*/
/* out: TRUE if request was
successful, FALSE if fail */
char* name, /* in: name of the file or path as a
null-terminated string */
os_file_t file, /* in: handle to a file */
void* buf, /* in: buffer from which to write */
ulint offset, /* in: least significant 32 bits of file
offset where to write */
ulint offset_high, /* in: most significant 32 bits of
offset */
ulint n) /* in: number of bytes to write */
{
#ifdef __WIN__
BOOL ret;
DWORD len;
DWORD ret2;
DWORD low;
DWORD high;
ibool retry;
ulint i;
os_n_file_writes++;
try_again:
ut_ad(file);
ut_ad(buf);
ut_ad(n > 0);
low = offset;
high = offset_high;
/* Protect the seek / write operation with a mutex */
i = ((ulint) file) % OS_FILE_N_SEEK_MUTEXES;
os_mutex_enter(os_file_seek_mutexes[i]);
ret2 = SetFilePointer(file, low, &high, FILE_BEGIN);
if (ret2 == 0xFFFFFFFF && GetLastError() != NO_ERROR) {
os_mutex_exit(os_file_seek_mutexes[i]);
goto error_handling;
}
ret = WriteFile(file, buf, n, &len, NULL);
/* Always do fsync to reduce the probability that when the OS crashes,
a database page is only partially physically written to disk. */
if (!trx_doublewrite) {
ut_a(TRUE == os_file_flush(file));
}
os_mutex_exit(os_file_seek_mutexes[i]);
if (ret && len == n) {
return(TRUE);
}
#else
ibool retry;
ssize_t ret;
#if (UNIV_WORD_SIZE == 8)
offset = offset + (offset_high << 32);
#else
UT_NOT_USED(offset_high);
#endif
try_again:
ret = os_file_pwrite(file, buf, n, offset);
if ((ulint)ret == n) {
return(TRUE);
}
#endif
error_handling:
retry = os_file_handle_error(file, name);
if (retry) {
goto try_again;
}
ut_error;
return(FALSE);
}
/********************************************************************
Returns a pointer to the nth slot in the aio array. */
static
os_aio_slot_t*
os_aio_array_get_nth_slot(
/*======================*/
/* out: pointer to slot */
os_aio_array_t* array, /* in: aio array */
ulint index) /* in: index of the slot */
{
ut_a(index < array->n_slots);
return((array->slots) + index);
}
/****************************************************************************
Creates an aio wait array. */
static
os_aio_array_t*
os_aio_array_create(
/*================*/
/* out, own: aio array */
ulint n, /* in: maximum number of pending aio operations
allowed; n must be divisible by n_segments */
ulint n_segments) /* in: number of segments in the aio array */
{
os_aio_array_t* array;
ulint i;
os_aio_slot_t* slot;
#ifdef WIN_ASYNC_IO
OVERLAPPED* over;
#endif
ut_a(n > 0);
ut_a(n_segments > 0);
ut_a(n % n_segments == 0);
array = ut_malloc(sizeof(os_aio_array_t));
array->mutex = os_mutex_create(NULL);
array->not_full = os_event_create(NULL);
array->is_empty = os_event_create(NULL);
os_event_set(array->is_empty);
array->n_slots = n;
array->n_segments = n_segments;
array->n_reserved = 0;
array->slots = ut_malloc(n * sizeof(os_aio_slot_t));
array->events = ut_malloc(n * sizeof(os_event_t));
for (i = 0; i < n; i++) {
slot = os_aio_array_get_nth_slot(array, i);
slot->pos = i;
slot->reserved = FALSE;
#ifdef WIN_ASYNC_IO
over = &(slot->control);
over->hEvent = os_event_create(NULL);
*((array->events) + i) = over->hEvent;
#endif
}
return(array);
}
/****************************************************************************
Initializes the asynchronous io system. Creates separate aio array for
non-ibuf read and write, a third aio array for the ibuf i/o, with just one
segment, two aio arrays for log reads and writes with one segment, and a
synchronous aio array of the specified size. The combined number of segments
in the three first aio arrays is the parameter n_segments given to the
function. The caller must create an i/o handler thread for each segment in
the four first arrays, but not for the sync aio array. */
void
os_aio_init(
/*========*/
ulint n, /* in: maximum number of pending aio operations
allowed; n must be divisible by n_segments */
ulint n_segments, /* in: combined number of segments in the four
first aio arrays; must be >= 4 */
ulint n_slots_sync) /* in: number of slots in the sync aio array */
{
ulint n_read_segs;
ulint n_write_segs;
ulint n_per_seg;
ulint i;
#ifdef POSIX_ASYNC_IO
sigset_t sigset;
#endif
ut_ad(n % n_segments == 0);
ut_ad(n_segments >= 4);
n_per_seg = n / n_segments;
n_write_segs = (n_segments - 2) / 2;
n_read_segs = n_segments - 2 - n_write_segs;
/* printf("Array n per seg %lu\n", n_per_seg); */
os_aio_read_array = os_aio_array_create(n_read_segs * n_per_seg,
n_read_segs);
os_aio_write_array = os_aio_array_create(n_write_segs * n_per_seg,
n_write_segs);
os_aio_ibuf_array = os_aio_array_create(n_per_seg, 1);
os_aio_log_array = os_aio_array_create(n_per_seg, 1);
os_aio_sync_array = os_aio_array_create(n_slots_sync, 1);
os_aio_n_segments = n_segments;
os_aio_validate();
for (i = 0; i < OS_FILE_N_SEEK_MUTEXES; i++) {
os_file_seek_mutexes[i] = os_mutex_create(NULL);
}
os_aio_segment_wait_events = ut_malloc(n_segments * sizeof(void*));
for (i = 0; i < n_segments; i++) {
os_aio_segment_wait_events[i] = os_event_create(NULL);
}
os_last_printout = time(NULL);
#ifdef POSIX_ASYNC_IO
/* Block aio signals from the current thread and its children:
for this to work, the current thread must be the first created
in the database, so that all its children will inherit its
signal mask */
/* TODO: to work MySQL needs the SIGALARM signal; the following
will not work yet! */
sigemptyset(&sigset);
sigaddset(&sigset, SIGRTMIN + 1 + 0);
sigaddset(&sigset, SIGRTMIN + 1 + 1);
sigaddset(&sigset, SIGRTMIN + 1 + 2);
sigaddset(&sigset, SIGRTMIN + 1 + 3);
pthread_sigmask(SIG_BLOCK, &sigset, NULL); */
#endif
}
/****************************************************************************
Waits until there are no pending writes in os_aio_write_array. There can
be other, synchronous, pending writes. */
void
os_aio_wait_until_no_pending_writes(void)
/*=====================================*/
{
os_event_wait(os_aio_write_array->is_empty);
}
/**************************************************************************
Calculates segment number for a slot. */
static
ulint
os_aio_get_segment_no_from_slot(
/*============================*/
/* out: segment number (which is the number
used by, for example, i/o-handler threads) */
os_aio_array_t* array, /* in: aio wait array */
os_aio_slot_t* slot) /* in: slot in this array */
{
ulint segment;
ulint seg_len;
if (array == os_aio_ibuf_array) {
segment = 0;
} else if (array == os_aio_log_array) {
segment = 1;
} else if (array == os_aio_read_array) {
seg_len = os_aio_read_array->n_slots /
os_aio_read_array->n_segments;
segment = 2 + slot->pos / seg_len;
} else {
ut_a(array == os_aio_write_array);
seg_len = os_aio_write_array->n_slots /
os_aio_write_array->n_segments;
segment = os_aio_read_array->n_segments + 2
+ slot->pos / seg_len;
}
return(segment);
}
/**************************************************************************
Calculates local segment number and aio array from global segment number. */
static
ulint
os_aio_get_array_and_local_segment(
/*===============================*/
/* out: local segment number within
the aio array */
os_aio_array_t** array, /* out: aio wait array */
ulint global_segment)/* in: global segment number */
{
ulint segment;
ut_a(global_segment < os_aio_n_segments);
if (global_segment == 0) {
*array = os_aio_ibuf_array;
segment = 0;
} else if (global_segment == 1) {
*array = os_aio_log_array;
segment = 0;
} else if (global_segment < os_aio_read_array->n_segments + 2) {
*array = os_aio_read_array;
segment = global_segment - 2;
} else {
*array = os_aio_write_array;
segment = global_segment - (os_aio_read_array->n_segments + 2);
}
return(segment);
}
/***********************************************************************
Gets an integer value designating a specified aio array. This is used
to give numbers to signals in Posix aio. */
static
ulint
os_aio_get_array_no(
/*================*/
os_aio_array_t* array) /* in: aio array */
{
if (array == os_aio_ibuf_array) {
return(0);
} else if (array == os_aio_log_array) {
return(1);
} else if (array == os_aio_read_array) {
return(2);
} else if (array == os_aio_write_array) {
return(3);
} else {
ut_a(0);
return(0);
}
}
/***********************************************************************
Gets the aio array for its number. */
static
os_aio_array_t*
os_aio_get_array_from_no(
/*=====================*/
/* out: aio array */
ulint n) /* in: array number */
{
if (n == 0) {
return(os_aio_ibuf_array);
} else if (n == 1) {
return(os_aio_log_array);
} else if (n == 2) {
return(os_aio_read_array);
} else if (n == 3) {
return(os_aio_write_array);
} else {
ut_a(0);
return(NULL);
}
}
/***********************************************************************
Requests for a slot in the aio array. If no slot is available, waits until
not_full-event becomes signaled. */
static
os_aio_slot_t*
os_aio_array_reserve_slot(
/*======================*/
/* out: pointer to slot */
ulint type, /* in: OS_FILE_READ or OS_FILE_WRITE */
os_aio_array_t* array, /* in: aio array */
void* message1,/* in: message to be passed along with
the aio operation */
void* message2,/* in: message to be passed along with
the aio operation */
os_file_t file, /* in: file handle */
char* name, /* in: name of the file or path as a
null-terminated string */
void* buf, /* in: buffer where to read or from which
to write */
ulint offset, /* in: least significant 32 bits of file
offset */
ulint offset_high, /* in: most significant 32 bits of
offset */
ulint len) /* in: length of the block to read or write */
{
os_aio_slot_t* slot;
#ifdef WIN_ASYNC_IO
OVERLAPPED* control;
#elif defined(POSIX_ASYNC_IO)
struct aiocb* control;
#endif
ulint i;
loop:
os_mutex_enter(array->mutex);
if (array->n_reserved == array->n_slots) {
os_mutex_exit(array->mutex);
if (!os_aio_use_native_aio) {
/* If the handler threads are suspended, wake them
so that we get more slots */
os_aio_simulated_wake_handler_threads();
}
os_event_wait(array->not_full);
goto loop;
}
for (i = 0;; i++) {
slot = os_aio_array_get_nth_slot(array, i);
if (slot->reserved == FALSE) {
break;
}
}
array->n_reserved++;
if (array->n_reserved == 1) {
os_event_reset(array->is_empty);
}
if (array->n_reserved == array->n_slots) {
os_event_reset(array->not_full);
}
slot->reserved = TRUE;
slot->message1 = message1;
slot->message2 = message2;
slot->file = file;
slot->name = name;
slot->len = len;
slot->type = type;
slot->buf = buf;
slot->offset = offset;
slot->offset_high = offset_high;
slot->io_already_done = FALSE;
#ifdef WIN_ASYNC_IO
control = &(slot->control);
control->Offset = (DWORD)offset;
control->OffsetHigh = (DWORD)offset_high;
os_event_reset(control->hEvent);
#elif defined(POSIX_ASYNC_IO)
#if (UNIV_WORD_SIZE == 8)
offset = offset + (offset_high << 32);
#else
ut_a(offset_high == 0);
#endif
control = &(slot->control);
control->aio_fildes = file;
control->aio_buf = buf;
control->aio_nbytes = len;
control->aio_offset = offset;
control->aio_reqprio = 0;
control->aio_sigevent.sigev_notify = SIGEV_SIGNAL;
control->aio_sigevent.sigev_signo =
SIGRTMIN + 1 + os_aio_get_array_no(array);
/* TODO: How to choose the signal numbers? */
/*
printf("AIO signal number %lu\n", (ulint) control->aio_sigevent.sigev_signo);
*/
control->aio_sigevent.sigev_value.sival_ptr = slot;
#endif
os_mutex_exit(array->mutex);
return(slot);
}
/***********************************************************************
Frees a slot in the aio array. */
static
void
os_aio_array_free_slot(
/*===================*/
os_aio_array_t* array, /* in: aio array */
os_aio_slot_t* slot) /* in: pointer to slot */
{
ut_ad(array);
ut_ad(slot);
os_mutex_enter(array->mutex);
ut_ad(slot->reserved);
slot->reserved = FALSE;
array->n_reserved--;
if (array->n_reserved == array->n_slots - 1) {
os_event_set(array->not_full);
}
if (array->n_reserved == 0) {
os_event_set(array->is_empty);
}
#ifdef WIN_ASYNC_IO
os_event_reset(slot->control.hEvent);
#endif
os_mutex_exit(array->mutex);
}
/**************************************************************************
Wakes up a simulated aio i/o-handler thread if it has something to do. */
static
void
os_aio_simulated_wake_handler_thread(
/*=================================*/
ulint global_segment) /* in: the number of the segment in the aio
arrays */
{
os_aio_array_t* array;
ulint segment;
os_aio_slot_t* slot;
ulint n;
ulint i;
ut_ad(!os_aio_use_native_aio);
segment = os_aio_get_array_and_local_segment(&array, global_segment);
n = array->n_slots / array->n_segments;
/* Look through n slots after the segment * n'th slot */
os_mutex_enter(array->mutex);
for (i = 0; i < n; i++) {
slot = os_aio_array_get_nth_slot(array, i + segment * n);
if (slot->reserved) {
/* Found an i/o request */
break;
}
}
os_mutex_exit(array->mutex);
if (i < n) {
os_event_set(os_aio_segment_wait_events[global_segment]);
}
}
/**************************************************************************
Wakes up simulated aio i/o-handler threads if they have something to do. */
void
os_aio_simulated_wake_handler_threads(void)
/*=======================================*/
{
ulint i;
if (os_aio_use_native_aio) {
/* We do not use simulated aio: do nothing */
return;
}
for (i = 0; i < os_aio_n_segments; i++) {
os_aio_simulated_wake_handler_thread(i);
}
}
/***********************************************************************
Requests an asynchronous i/o operation. */
ibool
os_aio(
/*===*/
/* out: TRUE if request was queued
successfully, FALSE if fail */
ulint type, /* in: OS_FILE_READ or OS_FILE_WRITE */
ulint mode, /* in: OS_AIO_NORMAL, ..., possibly ORed
to OS_AIO_SIMULATED_WAKE_LATER: the
last flag advises this function not to wake
i/o-handler threads, but the caller will
do the waking explicitly later, in this
way the caller can post several requests in
a batch; NOTE that the batch must not be
so big that it exhausts the slots in aio
arrays! NOTE that a simulated batch
may introduce hidden chances of deadlocks,
because i/os are not actually handled until
all have been posted: use with great
caution! */
char* name, /* in: name of the file or path as a
null-terminated string */
os_file_t file, /* in: handle to a file */
void* buf, /* in: buffer where to read or from which
to write */
ulint offset, /* in: least significant 32 bits of file
offset where to read or write */
ulint offset_high, /* in: most significant 32 bits of
offset */
ulint n, /* in: number of bytes to read or write */
void* message1,/* in: messages for the aio handler (these
can be used to identify a completed aio
operation); if mode is OS_AIO_SYNC, these
are ignored */
void* message2)
{
os_aio_array_t* array;
os_aio_slot_t* slot;
#ifdef WIN_ASYNC_IO
BOOL ret = TRUE;
DWORD len = n;
void* dummy_mess1;
void* dummy_mess2;
ulint dummy_type;
#endif
ulint err = 0;
ibool retry;
ulint wake_later;
ut_ad(file);
ut_ad(buf);
ut_ad(n > 0);
ut_ad(n % OS_FILE_LOG_BLOCK_SIZE == 0);
ut_ad((ulint)buf % OS_FILE_LOG_BLOCK_SIZE == 0)
ut_ad(offset % OS_FILE_LOG_BLOCK_SIZE == 0);
ut_ad(os_aio_validate());
wake_later = mode & OS_AIO_SIMULATED_WAKE_LATER;
mode = mode & (~OS_AIO_SIMULATED_WAKE_LATER);
if (mode == OS_AIO_SYNC
#ifdef WIN_ASYNC_IO
&& !os_aio_use_native_aio
#endif
) {
/* This is actually an ordinary synchronous read or write:
no need to use an i/o-handler thread. NOTE that if we use
Windows async i/o, Windows does not allow us to use
ordinary synchronous os_file_read etc. on the same file,
therefore we have built a special mechanism for synchronous
wait in the Windows case. */
if (type == OS_FILE_READ) {
return(os_file_read(file, buf, offset, offset_high, n));
}
ut_a(type == OS_FILE_WRITE);
return(os_file_write(name, file, buf, offset, offset_high, n));
}
try_again:
if (mode == OS_AIO_NORMAL) {
if (type == OS_FILE_READ) {
array = os_aio_read_array;
} else {
array = os_aio_write_array;
}
} else if (mode == OS_AIO_IBUF) {
ut_ad(type == OS_FILE_READ);
/* Reduce probability of deadlock bugs in connection with ibuf:
do not let the ibuf i/o handler sleep */
wake_later = FALSE;
array = os_aio_ibuf_array;
} else if (mode == OS_AIO_LOG) {
array = os_aio_log_array;
} else if (mode == OS_AIO_SYNC) {
array = os_aio_sync_array;
} else {
array = NULL; /* Eliminate compiler warning */
ut_error;
}
slot = os_aio_array_reserve_slot(type, array, message1, message2, file,
name, buf, offset, offset_high, n);
if (type == OS_FILE_READ) {
if (os_aio_use_native_aio) {
#ifdef WIN_ASYNC_IO
os_n_file_reads++;
ret = ReadFile(file, buf, (DWORD)n, &len,
&(slot->control));
#elif defined(POSIX_ASYNC_IO)
slot->control.aio_lio_opcode = LIO_READ;
err = (ulint) aio_read(&(slot->control));
printf("Starting Posix aio read %lu\n", err);
#endif
} else {
if (!wake_later) {
os_aio_simulated_wake_handler_thread(
os_aio_get_segment_no_from_slot(array, slot));
}
}
} else if (type == OS_FILE_WRITE) {
if (os_aio_use_native_aio) {
#ifdef WIN_ASYNC_IO
os_n_file_writes++;
ret = WriteFile(file, buf, (DWORD)n, &len,
&(slot->control));
#elif defined(POSIX_ASYNC_IO)
slot->control.aio_lio_opcode = LIO_WRITE;
err = (ulint) aio_write(&(slot->control));
printf("Starting Posix aio write %lu\n", err);
#endif
} else {
if (!wake_later) {
os_aio_simulated_wake_handler_thread(
os_aio_get_segment_no_from_slot(array, slot));
}
}
} else {
ut_error;
}
#ifdef WIN_ASYNC_IO
if (os_aio_use_native_aio) {
if ((ret && len == n)
|| (!ret && GetLastError() == ERROR_IO_PENDING)) {
/* aio was queued successfully! */
if (mode == OS_AIO_SYNC) {
/* We want a synchronous i/o operation on a file
where we also use async i/o: in Windows we must
use the same wait mechanism as for async i/o */
return(os_aio_windows_handle(ULINT_UNDEFINED,
slot->pos,
&dummy_mess1, &dummy_mess2,
&dummy_type));
}
return(TRUE);
}
err = 1; /* Fall through the next if */
}
#endif
if (err == 0) {
/* aio was queued successfully! */
return(TRUE);
}
os_aio_array_free_slot(array, slot);
retry = os_file_handle_error(file, name);
if (retry) {
goto try_again;
}
ut_error;
return(FALSE);
}
#ifdef WIN_ASYNC_IO
/**************************************************************************
This function is only used in Windows asynchronous i/o.
Waits for an aio operation to complete. This function is used to wait the
for completed requests. The aio array of pending requests is divided
into segments. The thread specifies which segment or slot it wants to wait
for. NOTE: this function will also take care of freeing the aio slot,
therefore no other thread is allowed to do the freeing! */
ibool
os_aio_windows_handle(
/*==================*/
/* out: TRUE if the aio operation succeeded */
ulint segment, /* in: the number of the segment in the aio
arrays to wait for; segment 0 is the ibuf
i/o thread, segment 1 the log i/o thread,
then follow the non-ibuf read threads, and as
the last are the non-ibuf write threads; if
this is ULINT_UNDEFINED, then it means that
sync aio is used, and this parameter is
ignored */
ulint pos, /* this parameter is used only in sync aio:
wait for the aio slot at this position */
void** message1, /* out: the messages passed with the aio
request; note that also in the case where
the aio operation failed, these output
parameters are valid and can be used to
restart the operation, for example */
void** message2,
ulint* type) /* out: OS_FILE_WRITE or ..._READ */
{
ulint orig_seg = segment;
os_aio_array_t* array;
os_aio_slot_t* slot;
ulint n;
ulint i;
ibool ret_val;
BOOL ret;
DWORD len;
if (segment == ULINT_UNDEFINED) {
array = os_aio_sync_array;
segment = 0;
} else {
segment = os_aio_get_array_and_local_segment(&array, segment);
}
/* NOTE! We only access constant fields in os_aio_array. Therefore
we do not have to acquire the protecting mutex yet */
ut_ad(os_aio_validate());
ut_ad(segment < array->n_segments);
n = array->n_slots / array->n_segments;
if (array == os_aio_sync_array) {
srv_io_thread_op_info[orig_seg] = "wait windows aio for 1 page";
ut_ad(pos < array->n_slots);
os_event_wait(array->events[pos]);
i = pos;
} else {
srv_io_thread_op_info[orig_seg] =
"wait windows aio for n pages";
i = os_event_wait_multiple(n, (array->events) + segment * n);
}
os_mutex_enter(array->mutex);
slot = os_aio_array_get_nth_slot(array, i + segment * n);
ut_a(slot->reserved);
srv_io_thread_op_info[orig_seg] = "get windows aio return value";
ret = GetOverlappedResult(slot->file, &(slot->control), &len, TRUE);
*message1 = slot->message1;
*message2 = slot->message2;
*type = slot->type;
if (ret && len == slot->len) {
ret_val = TRUE;
if (slot->type == OS_FILE_WRITE && !trx_doublewrite) {
ut_a(TRUE == os_file_flush(slot->file));
}
} else {
os_file_get_last_error();
ut_error;
ret_val = FALSE;
}
os_mutex_exit(array->mutex);
os_aio_array_free_slot(array, slot);
return(ret_val);
}
#endif
#ifdef POSIX_ASYNC_IO
/**************************************************************************
This function is only used in Posix asynchronous i/o. Waits for an aio
operation to complete. */
ibool
os_aio_posix_handle(
/*================*/
/* out: TRUE if the aio operation succeeded */
ulint array_no, /* in: array number 0 - 3 */
void** message1, /* out: the messages passed with the aio
request; note that also in the case where
the aio operation failed, these output
parameters are valid and can be used to
restart the operation, for example */
void** message2)
{
os_aio_array_t* array;
os_aio_slot_t* slot;
siginfo_t info;
sigset_t sigset;
sigset_t proc_sigset;
sigset_t thr_sigset;
int ret;
int i;
int sig;
sigemptyset(&sigset);
sigaddset(&sigset, SIGRTMIN + 1 + array_no);
pthread_sigmask(SIG_UNBLOCK, &sigset, NULL);
/*
sigprocmask(0, NULL, &proc_sigset);
pthread_sigmask(0, NULL, &thr_sigset);
for (i = 32 ; i < 40; i++) {
printf("%lu : %lu %lu\n", (ulint)i,
(ulint)sigismember(&proc_sigset, i),
(ulint)sigismember(&thr_sigset, i));
}
*/
ret = sigwaitinfo(&sigset, &info);
if (sig != SIGRTMIN + 1 + array_no) {
ut_a(0);
return(FALSE);
}
printf("Handling Posix aio\n");
array = os_aio_get_array_from_no(array_no);
os_mutex_enter(array->mutex);
slot = info.si_value.sival_ptr;
ut_a(slot->reserved);
*message1 = slot->message1;
*message2 = slot->message2;
if (slot->type == OS_FILE_WRITE && !trx_doublewrite) {
ut_a(TRUE == os_file_flush(slot->file));
}
os_mutex_exit(array->mutex);
os_aio_array_free_slot(array, slot);
return(TRUE);
}
#endif
/**************************************************************************
Does simulated aio. This function should be called by an i/o-handler
thread. */
ibool
os_aio_simulated_handle(
/*====================*/
/* out: TRUE if the aio operation succeeded */
ulint global_segment, /* in: the number of the segment in the aio
arrays to wait for; segment 0 is the ibuf
i/o thread, segment 1 the log i/o thread,
then follow the non-ibuf read threads, and as
the last are the non-ibuf write threads */
void** message1, /* out: the messages passed with the aio
request; note that also in the case where
the aio operation failed, these output
parameters are valid and can be used to
restart the operation, for example */
void** message2,
ulint* type) /* out: OS_FILE_WRITE or ..._READ */
{
os_aio_array_t* array;
ulint segment;
os_aio_slot_t* slot;
os_aio_slot_t* slot2;
os_aio_slot_t* consecutive_ios[OS_AIO_MERGE_N_CONSECUTIVE];
ulint n_consecutive;
ulint total_len;
ulint offs;
ulint lowest_offset;
byte* combined_buf;
ibool ret;
ulint n;
ulint i;
segment = os_aio_get_array_and_local_segment(&array, global_segment);
restart:
/* Give other threads chance to add several i/os to the array
at once */
os_thread_yield();
/* NOTE! We only access constant fields in os_aio_array. Therefore
we do not have to acquire the protecting mutex yet */
ut_ad(os_aio_validate());
ut_ad(segment < array->n_segments);
n = array->n_slots / array->n_segments;
/* Look through n slots after the segment * n'th slot */
os_mutex_enter(array->mutex);
/* Check if there is a slot for which the i/o has already been
done */
for (i = 0; i < n; i++) {
slot = os_aio_array_get_nth_slot(array, i + segment * n);
if (slot->reserved && slot->io_already_done) {
ret = TRUE;
goto slot_io_done;
}
}
n_consecutive = 0;
/* Look for an i/o request at the lowest offset in the array */
lowest_offset = ULINT_MAX;
for (i = 0; i < n; i++) {
slot = os_aio_array_get_nth_slot(array, i + segment * n);
if (slot->reserved && slot->offset < lowest_offset) {
/* Found an i/o request */
consecutive_ios[0] = slot;
n_consecutive = 1;
lowest_offset = slot->offset;
}
}
if (n_consecutive == 0) {
/* No i/o requested at the moment */
goto wait_for_io;
}
slot = consecutive_ios[0];
/* Check if there are several consecutive blocks to read or write */
consecutive_loop:
for (i = 0; i < n; i++) {
slot2 = os_aio_array_get_nth_slot(array, i + segment * n);
if (slot2->reserved && slot2 != slot
&& slot2->offset == slot->offset + slot->len
&& slot->offset + slot->len > slot->offset /* check that
sum does not wrap over */
&& slot2->offset_high == slot->offset_high
&& slot2->type == slot->type
&& slot2->file == slot->file) {
/* Found a consecutive i/o request */
consecutive_ios[n_consecutive] = slot2;
n_consecutive++;
slot = slot2;
if (n_consecutive < OS_AIO_MERGE_N_CONSECUTIVE) {
goto consecutive_loop;
} else {
break;
}
}
}
/* We have now collected n_consecutive i/o requests in the array;
allocate a single buffer which can hold all data, and perform the
i/o */
total_len = 0;
slot = consecutive_ios[0];
for (i = 0; i < n_consecutive; i++) {
total_len += consecutive_ios[i]->len;
}
if (n_consecutive == 1) {
/* We can use the buffer of the i/o request */
combined_buf = slot->buf;
} else {
combined_buf = ut_malloc(total_len);
ut_a(combined_buf);
}
/* We release the array mutex for the time of the i/o: NOTE that
this assumes that there is just one i/o-handler thread serving
a single segment of slots! */
os_mutex_exit(array->mutex);
if (slot->type == OS_FILE_WRITE && n_consecutive > 1) {
/* Copy the buffers to the combined buffer */
offs = 0;
for (i = 0; i < n_consecutive; i++) {
ut_memcpy(combined_buf + offs, consecutive_ios[i]->buf,
consecutive_ios[i]->len);
offs += consecutive_ios[i]->len;
}
}
srv_io_thread_op_info[global_segment] = "doing file i/o";
/* Do the i/o with ordinary, synchronous i/o functions: */
if (slot->type == OS_FILE_WRITE) {
ret = os_file_write(slot->name, slot->file, combined_buf,
slot->offset, slot->offset_high, total_len);
} else {
ret = os_file_read(slot->file, combined_buf,
slot->offset, slot->offset_high, total_len);
}
ut_a(ret);
srv_io_thread_op_info[global_segment] = "file i/o done";
/* printf("aio: %lu consecutive %lu:th segment, first offs %lu blocks\n",
n_consecutive, global_segment, slot->offset
/ UNIV_PAGE_SIZE); */
if (slot->type == OS_FILE_READ && n_consecutive > 1) {
/* Copy the combined buffer to individual buffers */
offs = 0;
for (i = 0; i < n_consecutive; i++) {
ut_memcpy(consecutive_ios[i]->buf, combined_buf + offs,
consecutive_ios[i]->len);
offs += consecutive_ios[i]->len;
}
}
if (n_consecutive > 1) {
ut_free(combined_buf);
}
os_mutex_enter(array->mutex);
/* Mark the i/os done in slots */
for (i = 0; i < n_consecutive; i++) {
consecutive_ios[i]->io_already_done = TRUE;
}
/* We return the messages for the first slot now, and if there were
several slots, the messages will be returned with subsequent calls
of this function */
slot_io_done:
ut_a(slot->reserved);
*message1 = slot->message1;
*message2 = slot->message2;
*type = slot->type;
os_mutex_exit(array->mutex);
os_aio_array_free_slot(array, slot);
return(ret);
wait_for_io:
/* We wait here until there again can be i/os in the segment
of this thread */
os_event_reset(os_aio_segment_wait_events[global_segment]);
os_mutex_exit(array->mutex);
srv_io_thread_op_info[global_segment] = "waiting for i/o request";
os_event_wait(os_aio_segment_wait_events[global_segment]);
goto restart;
}
/**************************************************************************
Validates the consistency of an aio array. */
static
ibool
os_aio_array_validate(
/*==================*/
/* out: TRUE if ok */
os_aio_array_t* array) /* in: aio wait array */
{
os_aio_slot_t* slot;
ulint n_reserved = 0;
ulint i;
ut_a(array);
os_mutex_enter(array->mutex);
ut_a(array->n_slots > 0);
ut_a(array->n_segments > 0);
for (i = 0; i < array->n_slots; i++) {
slot = os_aio_array_get_nth_slot(array, i);
if (slot->reserved) {
n_reserved++;
ut_a(slot->len > 0);
}
}
ut_a(array->n_reserved == n_reserved);
os_mutex_exit(array->mutex);
return(TRUE);
}
/**************************************************************************
Validates the consistency the aio system. */
ibool
os_aio_validate(void)
/*=================*/
/* out: TRUE if ok */
{
os_aio_array_validate(os_aio_read_array);
os_aio_array_validate(os_aio_write_array);
os_aio_array_validate(os_aio_ibuf_array);
os_aio_array_validate(os_aio_log_array);
os_aio_array_validate(os_aio_sync_array);
return(TRUE);
}
/**************************************************************************
Prints info of the aio arrays. */
void
os_aio_print(void)
/*==============*/
{
os_aio_array_t* array;
os_aio_slot_t* slot;
ulint n_reserved;
time_t current_time;
double time_elapsed;
ulint i;
for (i = 0; i < srv_n_file_io_threads; i++) {
printf("I/O thread %lu state: %s\n", i,
srv_io_thread_op_info[i]);
}
printf("Pending normal aio reads:");
array = os_aio_read_array;
loop:
ut_a(array);
os_mutex_enter(array->mutex);
ut_a(array->n_slots > 0);
ut_a(array->n_segments > 0);
n_reserved = 0;
for (i = 0; i < array->n_slots; i++) {
slot = os_aio_array_get_nth_slot(array, i);
if (slot->reserved) {
n_reserved++;
/* printf("Reserved slot, messages %lx %lx\n",
(ulint)slot->message1,
(ulint)slot->message2);
*/ ut_a(slot->len > 0);
}
}
ut_a(array->n_reserved == n_reserved);
printf(" %lu", n_reserved);
os_mutex_exit(array->mutex);
if (array == os_aio_read_array) {
printf(", aio writes:");
array = os_aio_write_array;
goto loop;
}
if (array == os_aio_write_array) {
printf(",\n ibuf aio reads:");
array = os_aio_ibuf_array;
goto loop;
}
if (array == os_aio_ibuf_array) {
printf(", log i/o's:");
array = os_aio_log_array;
goto loop;
}
if (array == os_aio_log_array) {
printf(", sync i/o's:");
array = os_aio_sync_array;
goto loop;
}
printf("\n");
current_time = time(NULL);
time_elapsed = difftime(current_time, os_last_printout);
printf("Pending flushes (fsync) log: %lu; buffer pool: %lu\n",
fil_n_pending_log_flushes, fil_n_pending_tablespace_flushes);
printf("%lu OS file reads, %lu OS file writes, %lu OS fsyncs\n",
os_n_file_reads, os_n_file_writes, os_n_fsyncs);
printf("%.2f reads/s, %.2f writes/s, %.2f fsyncs/s\n",
(os_n_file_reads - os_n_file_reads_old)
/ time_elapsed,
(os_n_file_writes - os_n_file_writes_old)
/ time_elapsed,
(os_n_fsyncs - os_n_fsyncs_old)
/ time_elapsed);
os_n_file_reads_old = os_n_file_reads;
os_n_file_writes_old = os_n_file_writes;
os_n_fsyncs_old = os_n_fsyncs;
os_last_printout = current_time;
}
/**************************************************************************
Checks that all slots in the system have been freed, that is, there are
no pending io operations. */
ibool
os_aio_all_slots_free(void)
/*=======================*/
/* out: TRUE if all free */
{
os_aio_array_t* array;
ulint n_res = 0;
array = os_aio_read_array;
os_mutex_enter(array->mutex);
n_res += array->n_reserved;
os_mutex_exit(array->mutex);
array = os_aio_write_array;
os_mutex_enter(array->mutex);
n_res += array->n_reserved;
os_mutex_exit(array->mutex);
array = os_aio_ibuf_array;
os_mutex_enter(array->mutex);
n_res += array->n_reserved;
os_mutex_exit(array->mutex);
array = os_aio_log_array;
os_mutex_enter(array->mutex);
n_res += array->n_reserved;
os_mutex_exit(array->mutex);
array = os_aio_sync_array;
os_mutex_enter(array->mutex);
n_res += array->n_reserved;
os_mutex_exit(array->mutex);
if (n_res == 0) {
return(TRUE);
}
return(FALSE);
}
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