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|
/***********************************************************************
Copyright (c) 1995, 2014, Oracle and/or its affiliates. All Rights Reserved.
Copyright (c) 2009, Percona Inc.
Copyright (c) 2013, 2015, MariaDB Corporation.
Portions of this file contain modifications contributed and copyrighted
by Percona Inc.. Those modifications are
gratefully acknowledged and are described briefly in the InnoDB
documentation. The contributions by Percona Inc. are incorporated with
their permission, and subject to the conditions contained in the file
COPYING.Percona.
This program is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the
Free Software Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General
Public License for more details.
You should have received a copy of the GNU General Public License along with
this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Suite 500, Boston, MA 02110-1335 USA
***********************************************************************/
/**************************************************//**
@file os/os0file.cc
The interface to the operating system file i/o primitives
Created 10/21/1995 Heikki Tuuri
*******************************************************/
#include "os0file.h"
#ifdef UNIV_NONINL
#include "os0file.ic"
#endif
#include "ut0mem.h"
#include "srv0srv.h"
#include "srv0start.h"
#include "fil0fil.h"
#include "fsp0fsp.h"
#include "fil0pagecompress.h"
#include "fil0pageencryption.h"
#include "buf0buf.h"
#include "srv0mon.h"
#include "srv0srv.h"
#ifdef HAVE_POSIX_FALLOCATE
#include "unistd.h"
#include "fcntl.h"
#endif
#ifndef UNIV_HOTBACKUP
# include "os0sync.h"
# include "os0thread.h"
#else /* !UNIV_HOTBACKUP */
# ifdef __WIN__
/* Add includes for the _stat() call to compile on Windows */
# include <sys/types.h>
# include <sys/stat.h>
# include <errno.h>
# endif /* __WIN__ */
#endif /* !UNIV_HOTBACKUP */
#if defined(LINUX_NATIVE_AIO)
#include <libaio.h>
#endif
#if defined(UNIV_LINUX) && defined(HAVE_SYS_IOCTL_H)
# include <sys/ioctl.h>
# ifndef DFS_IOCTL_ATOMIC_WRITE_SET
# define DFS_IOCTL_ATOMIC_WRITE_SET _IOW(0x95, 2, uint)
# endif
#endif
#if defined(UNIV_LINUX) && defined(HAVE_SYS_STATVFS_H)
#include <sys/statvfs.h>
#endif
#if defined(UNIV_LINUX) && defined(HAVE_LINUX_FALLOC_H)
#include <linux/falloc.h>
#endif
#if defined(HAVE_FALLOCATE)
#ifndef FALLOC_FL_KEEP_SIZE
#define FALLOC_FL_KEEP_SIZE 0x01
#endif
#ifndef FALLOC_FL_PUNCH_HOLE
#define FALLOC_FL_PUNCH_HOLE 0x02
#endif
#endif
#ifdef HAVE_LZO
#include "lzo/lzo1x.h"
#endif
#ifdef HAVE_SNAPPY
#include "snappy-c.h"
#endif
/** Insert buffer segment id */
static const ulint IO_IBUF_SEGMENT = 0;
/** Log segment id */
static const ulint IO_LOG_SEGMENT = 1;
/* This specifies the file permissions InnoDB uses when it creates files in
Unix; the value of os_innodb_umask is initialized in ha_innodb.cc to
my_umask */
#ifndef __WIN__
/** Umask for creating files */
UNIV_INTERN ulint os_innodb_umask = S_IRUSR | S_IWUSR | S_IRGRP | S_IWGRP;
#else
/** Umask for creating files */
UNIV_INTERN ulint os_innodb_umask = 0;
#endif /* __WIN__ */
#ifndef UNIV_HOTBACKUP
/* 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
UNIV_INTERN os_ib_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 64
#ifdef WITH_INNODB_DISALLOW_WRITES
#define WAIT_ALLOW_WRITES() os_event_wait(srv_allow_writes_event)
#else
#define WAIT_ALLOW_WRITES() do { } while (0)
#endif /* WITH_INNODB_DISALLOW_WRITES */
/**********************************************************************
InnoDB AIO Implementation:
=========================
We support native AIO for windows and linux. For rest of the platforms
we simulate AIO by special io-threads servicing the IO-requests.
Simulated AIO:
==============
In platforms where we 'simulate' AIO following is a rough explanation
of the high level design.
There are four io-threads (for ibuf, log, read, write).
All synchronous IO requests are serviced by the calling thread using
os_file_write/os_file_read. The Asynchronous requests are queued up
in an array (there are four such arrays) by the calling thread.
Later these requests are picked up by the io-thread and are serviced
synchronously.
Windows native AIO:
==================
If srv_use_native_aio is not set then windows follow the same
code as simulated AIO. If the flag is set then native AIO interface
is used. On windows, one of the limitation is that if a file is opened
for AIO no synchronous IO can be done on it. Therefore we have an
extra fifth array to queue up synchronous IO requests.
There are innodb_file_io_threads helper threads. These threads work
on the four arrays mentioned above in Simulated AIO. No thread is
required for the sync array.
If a synchronous IO request is made, it is first queued in the sync
array. Then the calling thread itself waits on the request, thus
making the call synchronous.
If an AIO request is made the calling thread not only queues it in the
array but also submits the requests. The helper thread then collects
the completed IO request and calls completion routine on it.
Linux native AIO:
=================
If we have libaio installed on the system and innodb_use_native_aio
is set to TRUE we follow the code path of native AIO, otherwise we
do simulated AIO.
There are innodb_file_io_threads helper threads. These threads work
on the four arrays mentioned above in Simulated AIO.
If a synchronous IO request is made, it is handled by calling
os_file_write/os_file_read.
If an AIO request is made the calling thread not only queues it in the
array but also submits the requests. The helper thread then collects
the completed IO request and calls completion routine on it.
**********************************************************************/
/** Flag: enable debug printout for asynchronous i/o */
UNIV_INTERN ibool os_aio_print_debug = FALSE;
#ifdef UNIV_PFS_IO
/* Keys to register InnoDB I/O with performance schema */
UNIV_INTERN mysql_pfs_key_t innodb_file_data_key;
UNIV_INTERN mysql_pfs_key_t innodb_file_log_key;
UNIV_INTERN mysql_pfs_key_t innodb_file_temp_key;
#endif /* UNIV_PFS_IO */
/** The asynchronous i/o array slot structure */
struct os_aio_slot_t{
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 */
time_t reservation_time;/*!< time when 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 */
os_offset_t offset; /*!< file offset in bytes */
os_file_t file; /*!< file where to read or write */
const 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 */
fil_node_t* 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 */
ulint bitmap;
byte* page_compression_page; /*!< Memory allocated for
page compressed page and
freed after the write
has been completed */
byte* page_encryption_page; /*!< Memory allocated for
page encrypted page and
freed after the write
has been completed */
ibool page_compression;
ulint page_compression_level;
ibool page_encryption;
ulint page_encryption_key;
ulint* write_size; /*!< Actual write size initialized
after fist successfull trim
operation for this page and if
initialized we do not trim again if
actual page size does not decrease. */
byte* page_buf; /*!< Actual page buffer for
page compressed pages, do not
free this */
byte* page_buf2; /*!< Actual page buffer for
page encrypted pages, do not
free this */
byte* tmp_encryption_buf; /*!< a temporal buffer used by page encryption */
ibool page_compression_success;
/*!< TRUE if page compression was successfull, false if not */
ibool page_encryption_success;
/*!< TRUE if page encryption was successfull, false if not */
lsn_t lsn; /* lsn of the newest modification */
ulint file_block_size;/*!< file block size */
bool encrypt_later; /*!< should the page be encrypted
before write */
#ifdef WIN_ASYNC_IO
HANDLE handle; /*!< handle object we need in the
OVERLAPPED struct */
OVERLAPPED control; /*!< Windows control block for the
aio request */
#elif defined(LINUX_NATIVE_AIO)
struct iocb control; /* Linux control block for aio */
int n_bytes; /* bytes written/read. */
int ret; /* AIO return code */
#endif /* WIN_ASYNC_IO */
byte *lzo_mem; /* Temporal memory used by LZO */
};
/** The asynchronous i/o array structure */
struct os_aio_array_t{
os_ib_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 cur_seg;/*!< We reserve IO requests in round
robin fashion to different segments.
This points to the segment that is to
be used to service next IO request. */
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 */
#ifdef __WIN__
HANDLE* handles;
/*!< Pointer to an array of OS native
event handles where we copied the
handles from slots, in the same
order. This can be used in
WaitForMultipleObjects; used only in
Windows */
#endif /* __WIN__ */
#if defined(LINUX_NATIVE_AIO)
io_context_t* aio_ctx;
/* completion queue for IO. There is
one such queue per segment. Each thread
will work on one ctx exclusively. */
struct io_event* aio_events;
/* The array to collect completed IOs.
There is one such event for each
possible pending IO. The size of the
array is equal to n_slots. */
#endif /* LINUX_NATIV_AIO */
};
#if defined(LINUX_NATIVE_AIO)
/** timeout for each io_getevents() call = 500ms. */
#define OS_AIO_REAP_TIMEOUT (500000000UL)
/** time to sleep, in microseconds if io_setup() returns EAGAIN. */
#define OS_AIO_IO_SETUP_RETRY_SLEEP (500000UL)
/** number of attempts before giving up on io_setup(). */
#define OS_AIO_IO_SETUP_RETRY_ATTEMPTS 5
#endif
/** Array of events used in simulated aio */
static 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. @{ */
static os_aio_array_t* os_aio_read_array = NULL; /*!< Reads */
static os_aio_array_t* os_aio_write_array = NULL; /*!< Writes */
static os_aio_array_t* os_aio_ibuf_array = NULL; /*!< Insert buffer */
static os_aio_array_t* os_aio_log_array = NULL; /*!< Redo log */
static os_aio_array_t* os_aio_sync_array = NULL; /*!< Synchronous I/O */
/* @} */
/** Number of asynchronous I/O segments. Set by os_aio_init(). */
static ulint os_aio_n_segments = ULINT_UNDEFINED;
/** If the following is TRUE, read i/o handler threads try to
wait until a batch of new read requests have been posted */
static ibool os_aio_recommend_sleep_for_read_threads = FALSE;
#endif /* !UNIV_HOTBACKUP */
UNIV_INTERN ulint os_n_file_reads = 0;
UNIV_INTERN ulint os_bytes_read_since_printout = 0;
UNIV_INTERN ulint os_n_file_writes = 0;
UNIV_INTERN ulint os_n_fsyncs = 0;
UNIV_INTERN ulint os_n_file_reads_old = 0;
UNIV_INTERN ulint os_n_file_writes_old = 0;
UNIV_INTERN ulint os_n_fsyncs_old = 0;
UNIV_INTERN time_t os_last_printout;
UNIV_INTERN ibool os_has_said_disk_full = FALSE;
#if !defined(UNIV_HOTBACKUP) \
&& (!defined(HAVE_ATOMIC_BUILTINS) || UNIV_WORD_SIZE < 8)
/** The mutex protecting the following counts of pending I/O operations */
static os_ib_mutex_t os_file_count_mutex;
#endif /* !UNIV_HOTBACKUP && (!HAVE_ATOMIC_BUILTINS || UNIV_WORD_SIZE < 8) */
/** Number of pending os_file_pread() operations */
UNIV_INTERN ulint os_file_n_pending_preads = 0;
/** Number of pending os_file_pwrite() operations */
UNIV_INTERN ulint os_file_n_pending_pwrites = 0;
/** Number of pending write operations */
UNIV_INTERN ulint os_n_pending_writes = 0;
/** Number of pending read operations */
UNIV_INTERN ulint os_n_pending_reads = 0;
/** After first fallocate failure we will disable os_file_trim */
UNIV_INTERN ibool os_fallocate_failed = FALSE;
/**********************************************************************//**
Directly manipulate the allocated disk space by deallocating for the file referred to
by fd for the byte range starting at offset and continuing for len bytes.
Within the specified range, partial file system blocks are zeroed, and whole
file system blocks are removed from the file. After a successful call,
subsequent reads from this range will return zeroes.
@return true if success, false if error */
UNIV_INTERN
ibool
os_file_trim(
/*=========*/
os_aio_slot_t* slot); /*!< in: slot structure */
/**********************************************************************//**
Allocate memory for temporal buffer used for page compression. This
buffer is freed later. */
UNIV_INTERN
void
os_slot_alloc_page_buf(
/*===================*/
os_aio_slot_t* slot); /*!< in: slot structure */
#ifdef HAVE_LZO
/**********************************************************************//**
Allocate memory for temporal memory used for page compression when
LZO compression method is used */
UNIV_INTERN
void
os_slot_alloc_lzo_mem(
/*===================*/
os_aio_slot_t* slot); /*!< in: slot structure */
#endif
/**********************************************************************//**
Allocate memory for temporal buffer used for page encryption. This
buffer is freed later. */
UNIV_INTERN
void
os_slot_alloc_page_buf2(
os_aio_slot_t* slot); /*!< in: slot structure */
/**********************************************************************//**
Allocate memory for temporal buffer used for page encryption. */
UNIV_INTERN
void
os_slot_alloc_tmp_encryption_buf(
os_aio_slot_t* slot); /*!< in: slot structure */
/****************************************************************//**
Does error handling when a file operation fails.
@return TRUE if we should retry the operation */
ibool
os_file_handle_error_no_exit(
/*=========================*/
const char* name, /*!< in: name of a file or NULL */
const char* operation, /*!< in: operation */
ibool on_error_silent,/*!< in: if TRUE then don't print
any message to the log. */
const char* file, /*!< in: file name */
const ulint line); /*!< in: line */
/****************************************************************//**
Tries to enable the atomic write feature, if available, for the specified file
handle.
@return TRUE if success */
static __attribute__((warn_unused_result))
ibool
os_file_set_atomic_writes(
/*======================*/
const char* name /*!< in: name of the file */
__attribute__((unused)),
os_file_t file /*!< in: handle to the file */
__attribute__((unused)))
{
#ifdef DFS_IOCTL_ATOMIC_WRITE_SET
int atomic_option = 1;
if (ioctl(file, DFS_IOCTL_ATOMIC_WRITE_SET, &atomic_option)) {
fprintf(stderr, "InnoDB: Warning:Trying to enable atomic writes on "
"file %s on non-supported platform!\n", name);
os_file_handle_error_no_exit(name, "ioctl", FALSE, __FILE__, __LINE__);
return(FALSE);
}
return(TRUE);
#else
fprintf(stderr, "InnoDB: Error: trying to enable atomic writes on "
"file %s on non-supported platform!\n", name);
return(FALSE);
#endif
}
#ifdef UNIV_DEBUG
# ifndef UNIV_HOTBACKUP
/**********************************************************************//**
Validates the consistency the aio system some of the time.
@return TRUE if ok or the check was skipped */
UNIV_INTERN
ibool
os_aio_validate_skip(void)
/*======================*/
{
/** Try os_aio_validate() every this many times */
# define OS_AIO_VALIDATE_SKIP 13
/** The os_aio_validate() call skip counter.
Use a signed type because of the race condition below. */
static int os_aio_validate_count = OS_AIO_VALIDATE_SKIP;
/* There is a race condition below, but it does not matter,
because this call is only for heuristic purposes. We want to
reduce the call frequency of the costly os_aio_validate()
check in debug builds. */
if (--os_aio_validate_count > 0) {
return(TRUE);
}
os_aio_validate_count = OS_AIO_VALIDATE_SKIP;
return(os_aio_validate());
}
# endif /* !UNIV_HOTBACKUP */
#endif /* UNIV_DEBUG */
#ifdef __WIN__
/***********************************************************************//**
Gets the operating system version. Currently works only on Windows.
@return OS_WIN95, OS_WIN31, OS_WINNT, OS_WIN2000, OS_WINXP, OS_WINVISTA,
OS_WIN7. */
UNIV_INTERN
ulint
os_get_os_version(void)
/*===================*/
{
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) {
switch (os_info.dwMajorVersion) {
case 3:
case 4:
return(OS_WINNT);
case 5:
return (os_info.dwMinorVersion == 0)
? OS_WIN2000 : OS_WINXP;
case 6:
return (os_info.dwMinorVersion == 0)
? OS_WINVISTA : OS_WIN7;
default:
return(OS_WIN7);
}
} else {
ut_error;
return(0);
}
}
#endif /* __WIN__ */
/***********************************************************************//**
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.
@return error number, or OS error number + 100 */
static
ulint
os_file_get_last_error_low(
/*=======================*/
bool report_all_errors, /*!< in: TRUE if we want an error
message printed of all errors */
bool on_error_silent) /*!< in: TRUE then don't print any
diagnostic to the log */
{
#ifdef __WIN__
ulint err = (ulint) GetLastError();
if (err == ERROR_SUCCESS) {
return(0);
}
if (report_all_errors
|| (!on_error_silent
&& err != ERROR_DISK_FULL
&& err != ERROR_FILE_EXISTS)) {
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Operating system error number %lu"
" in a file operation.\n", (ulong) err);
if (err == ERROR_PATH_NOT_FOUND) {
fprintf(stderr,
"InnoDB: The error means the system"
" cannot find the path specified.\n");
if (srv_is_being_started) {
fprintf(stderr,
"InnoDB: If you are installing InnoDB,"
" remember that you must create\n"
"InnoDB: directories yourself, InnoDB"
" does not create them.\n");
}
} else if (err == ERROR_ACCESS_DENIED) {
fprintf(stderr,
"InnoDB: The error means mysqld does not have"
" the access rights to\n"
"InnoDB: the directory. It may also be"
" you have created a subdirectory\n"
"InnoDB: of the same name as a data file.\n");
} else if (err == ERROR_SHARING_VIOLATION
|| err == ERROR_LOCK_VIOLATION) {
fprintf(stderr,
"InnoDB: The error means that another program"
" is using InnoDB's files.\n"
"InnoDB: This might be a backup or antivirus"
" software or another instance\n"
"InnoDB: of MySQL."
" Please close it to get rid of this error.\n");
} else if (err == ERROR_WORKING_SET_QUOTA
|| err == ERROR_NO_SYSTEM_RESOURCES) {
fprintf(stderr,
"InnoDB: The error means that there are no"
" sufficient system resources or quota to"
" complete the operation.\n");
} else if (err == ERROR_OPERATION_ABORTED) {
fprintf(stderr,
"InnoDB: The error means that the I/O"
" operation has been aborted\n"
"InnoDB: because of either a thread exit"
" or an application request.\n"
"InnoDB: Retry attempt is made.\n");
} else if (err == ECANCELED || err == ENOTTY) {
if (strerror(err) != NULL) {
fprintf(stderr,
"InnoDB: Error number %d"
" means '%s'.\n",
err, strerror(err));
}
if(srv_use_atomic_writes) {
fprintf(stderr,
"InnoDB: Error trying to enable atomic writes on "
"non-supported destination!\n");
}
} else {
fprintf(stderr,
"InnoDB: Some operating system error numbers"
" are described at\n"
"InnoDB: "
REFMAN
"operating-system-error-codes.html\n");
}
}
fflush(stderr);
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 if (err == ERROR_SHARING_VIOLATION
|| err == ERROR_LOCK_VIOLATION) {
return(OS_FILE_SHARING_VIOLATION);
} else if (err == ERROR_WORKING_SET_QUOTA
|| err == ERROR_NO_SYSTEM_RESOURCES) {
return(OS_FILE_INSUFFICIENT_RESOURCE);
} else if (err == ERROR_OPERATION_ABORTED) {
return(OS_FILE_OPERATION_ABORTED);
} else if (err == ERROR_ACCESS_DENIED) {
return(OS_FILE_ACCESS_VIOLATION);
} else if (err == ERROR_BUFFER_OVERFLOW) {
return(OS_FILE_NAME_TOO_LONG);
} else {
return(OS_FILE_ERROR_MAX + err);
}
#else
int err = errno;
if (err == 0) {
return(0);
}
if (report_all_errors
|| (err != ENOSPC && err != EEXIST && !on_error_silent)) {
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Operating system error number %d"
" in a file operation.\n", err);
if (err == ENOENT) {
fprintf(stderr,
"InnoDB: The error means the system"
" cannot find the path specified.\n");
if (srv_is_being_started) {
fprintf(stderr,
"InnoDB: If you are installing InnoDB,"
" remember that you must create\n"
"InnoDB: directories yourself, InnoDB"
" does not create them.\n");
}
} else if (err == EACCES) {
fprintf(stderr,
"InnoDB: The error means mysqld does not have"
" the access rights to\n"
"InnoDB: the directory.\n");
} else if (err == ECANCELED || err == ENOTTY) {
if (strerror(err) != NULL) {
fprintf(stderr,
"InnoDB: Error number %d"
" means '%s'.\n",
err, strerror(err));
}
if(srv_use_atomic_writes) {
fprintf(stderr,
"InnoDB: Error trying to enable atomic writes on "
"non-supported destination!\n");
}
} else {
if (strerror(err) != NULL) {
fprintf(stderr,
"InnoDB: Error number %d"
" means '%s'.\n",
err, strerror(err));
}
fprintf(stderr,
"InnoDB: Some operating system"
" error numbers are described at\n"
"InnoDB: "
REFMAN
"operating-system-error-codes.html\n");
}
}
fflush(stderr);
switch (err) {
case ENOSPC:
return(OS_FILE_DISK_FULL);
case ENOENT:
return(OS_FILE_NOT_FOUND);
case EEXIST:
return(OS_FILE_ALREADY_EXISTS);
case ENAMETOOLONG:
return(OS_FILE_NAME_TOO_LONG);
case EXDEV:
case ENOTDIR:
case EISDIR:
return(OS_FILE_PATH_ERROR);
case ECANCELED:
case ENOTTY:
return(OS_FILE_OPERATION_NOT_SUPPORTED);
case EAGAIN:
if (srv_use_native_aio) {
return(OS_FILE_AIO_RESOURCES_RESERVED);
}
break;
case EINTR:
if (srv_use_native_aio) {
return(OS_FILE_AIO_INTERRUPTED);
}
break;
case EACCES:
return(OS_FILE_ACCESS_VIOLATION);
}
return(OS_FILE_ERROR_MAX + err);
#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.
@return error number, or OS error number + 100 */
UNIV_INTERN
ulint
os_file_get_last_error(
/*===================*/
bool report_all_errors) /*!< in: TRUE if we want an error
message printed of all errors */
{
return(os_file_get_last_error_low(report_all_errors, false));
}
/****************************************************************//**
Does error handling when a file operation fails.
Conditionally exits (calling exit(3)) based on should_exit value and the
error type, if should_exit is TRUE then on_error_silent is ignored.
@return TRUE if we should retry the operation */
static
ibool
os_file_handle_error_cond_exit(
/*===========================*/
const char* name, /*!< in: name of a file or NULL */
const char* operation, /*!< in: operation */
ibool should_exit, /*!< in: call exit(3) if unknown error
and this parameter is TRUE */
ibool on_error_silent,/*!< in: if TRUE then don't print
any message to the log iff it is
an unknown non-fatal error */
const char* file, /*!< in: file name */
const ulint line) /*!< in: line */
{
ulint err;
err = os_file_get_last_error_low(false, on_error_silent);
switch (err) {
case OS_FILE_DISK_FULL:
/* We only print a warning about disk full once */
if (os_has_said_disk_full) {
return(FALSE);
}
/* Disk full error is reported irrespective of the
on_error_silent setting. */
if (name) {
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Encountered a problem with"
" file %s\n", name);
}
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Disk is full. Try to clean the disk"
" to free space.\n");
fprintf(stderr,
" InnoDB: at file %s and at line %ld\n", file, line);
os_has_said_disk_full = TRUE;
fflush(stderr);
return(FALSE);
case OS_FILE_AIO_RESOURCES_RESERVED:
case OS_FILE_AIO_INTERRUPTED:
return(TRUE);
case OS_FILE_PATH_ERROR:
case OS_FILE_ALREADY_EXISTS:
case OS_FILE_ACCESS_VIOLATION:
return(FALSE);
case OS_FILE_SHARING_VIOLATION:
os_thread_sleep(10000000); /* 10 sec */
return(TRUE);
case OS_FILE_OPERATION_ABORTED:
case OS_FILE_INSUFFICIENT_RESOURCE:
os_thread_sleep(100000); /* 100 ms */
return(TRUE);
default:
/* If it is an operation that can crash on error then it
is better to ignore on_error_silent and print an error message
to the log. */
if (should_exit || !on_error_silent) {
fprintf(stderr,
" InnoDB: Operation %s to file %s and at line %ld\n",
operation, file, line);
}
if (should_exit || !on_error_silent) {
ib_logf(IB_LOG_LEVEL_ERROR, "File %s: '%s' returned OS "
"error " ULINTPF ".%s", name ? name : "(unknown)",
operation, err, should_exit
? " Cannot continue operation" : "");
}
if (should_exit) {
exit(1);
}
}
return(FALSE);
}
/****************************************************************//**
Does error handling when a file operation fails.
@return TRUE if we should retry the operation */
static
ibool
os_file_handle_error(
/*=================*/
const char* name, /*!< in: name of a file or NULL */
const char* operation, /*!< in: operation */
const char* file, /*!< in: file name */
const ulint line) /*!< in: line */
{
/* exit in case of unknown error */
return(os_file_handle_error_cond_exit(name, operation, TRUE, FALSE, file, line));
}
/****************************************************************//**
Does error handling when a file operation fails.
@return TRUE if we should retry the operation */
ibool
os_file_handle_error_no_exit(
/*=========================*/
const char* name, /*!< in: name of a file or NULL */
const char* operation, /*!< in: operation */
ibool on_error_silent,/*!< in: if TRUE then don't print
any message to the log. */
const char* file, /*!< in: file name */
const ulint line) /*!< in: line */
{
/* don't exit in case of unknown error */
return(os_file_handle_error_cond_exit(
name, operation, FALSE, on_error_silent, file, line));
}
#undef USE_FILE_LOCK
#define USE_FILE_LOCK
#if defined(UNIV_HOTBACKUP) || defined(__WIN__)
/* InnoDB Hot Backup does not lock the data files.
* On Windows, mandatory locking is used.
*/
# undef USE_FILE_LOCK
#endif
#ifdef USE_FILE_LOCK
/****************************************************************//**
Obtain an exclusive lock on a file.
@return 0 on success */
static
int
os_file_lock(
/*=========*/
int fd, /*!< in: file descriptor */
const char* name) /*!< in: file name */
{
struct flock lk;
ut_ad(!srv_read_only_mode);
lk.l_type = F_WRLCK;
lk.l_whence = SEEK_SET;
lk.l_start = lk.l_len = 0;
if (fcntl(fd, F_SETLK, &lk) == -1) {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unable to lock %s, error: %d", name, errno);
if (errno == EAGAIN || errno == EACCES) {
ib_logf(IB_LOG_LEVEL_INFO,
"Check that you do not already have "
"another mysqld process using the "
"same InnoDB data or log files.");
}
return(-1);
}
return(0);
}
#endif /* USE_FILE_LOCK */
#ifndef UNIV_HOTBACKUP
/****************************************************************//**
Creates the seek mutexes used in positioned reads and writes. */
UNIV_INTERN
void
os_io_init_simple(void)
/*===================*/
{
#if !defined(HAVE_ATOMIC_BUILTINS) || UNIV_WORD_SIZE < 8
os_file_count_mutex = os_mutex_create();
#endif /* !HAVE_ATOMIC_BUILTINS || UNIV_WORD_SIZE < 8 */
for (ulint i = 0; i < OS_FILE_N_SEEK_MUTEXES; i++) {
os_file_seek_mutexes[i] = os_mutex_create();
}
}
/***********************************************************************//**
Creates a temporary file. This function is like tmpfile(3), but
the temporary file is created in the MySQL temporary directory.
@return temporary file handle, or NULL on error */
UNIV_INTERN
FILE*
os_file_create_tmpfile(void)
/*========================*/
{
FILE* file = NULL;
int fd;
WAIT_ALLOW_WRITES();
fd = innobase_mysql_tmpfile();
ut_ad(!srv_read_only_mode);
if (fd >= 0) {
file = fdopen(fd, "w+b");
}
if (!file) {
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Error: unable to create temporary file;"
" errno: %d\n", errno);
if (fd >= 0) {
close(fd);
}
}
return(file);
}
#endif /* !UNIV_HOTBACKUP */
/***********************************************************************//**
The os_file_opendir() function opens a directory stream corresponding to the
directory named by the dirname argument. The directory stream is positioned
at the first entry. In both Unix and Windows we automatically skip the '.'
and '..' items at the start of the directory listing.
@return directory stream, NULL if error */
UNIV_INTERN
os_file_dir_t
os_file_opendir(
/*============*/
const char* dirname, /*!< in: directory name; it must not
contain a trailing '\' or '/' */
ibool error_is_fatal) /*!< in: TRUE if we should treat an
error as a fatal error; if we try to
open symlinks then we do not wish a
fatal error if it happens not to be
a directory */
{
os_file_dir_t dir;
#ifdef __WIN__
LPWIN32_FIND_DATA lpFindFileData;
char path[OS_FILE_MAX_PATH + 3];
ut_a(strlen(dirname) < OS_FILE_MAX_PATH);
strcpy(path, dirname);
strcpy(path + strlen(path), "\\*");
/* Note that in Windows opening the 'directory stream' also retrieves
the first entry in the directory. Since it is '.', that is no problem,
as we will skip over the '.' and '..' entries anyway. */
lpFindFileData = static_cast<LPWIN32_FIND_DATA>(
ut_malloc(sizeof(WIN32_FIND_DATA)));
dir = FindFirstFile((LPCTSTR) path, lpFindFileData);
ut_free(lpFindFileData);
if (dir == INVALID_HANDLE_VALUE) {
if (error_is_fatal) {
os_file_handle_error(dirname, "opendir", __FILE__, __LINE__);
}
return(NULL);
}
return(dir);
#else
dir = opendir(dirname);
if (dir == NULL && error_is_fatal) {
os_file_handle_error(dirname, "opendir", __FILE__, __LINE__);
}
return(dir);
#endif /* __WIN__ */
}
/***********************************************************************//**
Closes a directory stream.
@return 0 if success, -1 if failure */
UNIV_INTERN
int
os_file_closedir(
/*=============*/
os_file_dir_t dir) /*!< in: directory stream */
{
#ifdef __WIN__
BOOL ret;
ret = FindClose(dir);
if (!ret) {
os_file_handle_error_no_exit(NULL, "closedir", FALSE, __FILE__, __LINE__);
return(-1);
}
return(0);
#else
int ret;
ret = closedir(dir);
if (ret) {
os_file_handle_error_no_exit(NULL, "closedir", FALSE, __FILE__, __LINE__);
}
return(ret);
#endif /* __WIN__ */
}
/***********************************************************************//**
This function returns information of the next file in the directory. We jump
over the '.' and '..' entries in the directory.
@return 0 if ok, -1 if error, 1 if at the end of the directory */
UNIV_INTERN
int
os_file_readdir_next_file(
/*======================*/
const char* dirname,/*!< in: directory name or path */
os_file_dir_t dir, /*!< in: directory stream */
os_file_stat_t* info) /*!< in/out: buffer where the info is returned */
{
#ifdef __WIN__
LPWIN32_FIND_DATA lpFindFileData;
BOOL ret;
lpFindFileData = static_cast<LPWIN32_FIND_DATA>(
ut_malloc(sizeof(WIN32_FIND_DATA)));
next_file:
ret = FindNextFile(dir, lpFindFileData);
if (ret) {
ut_a(strlen((char*) lpFindFileData->cFileName)
< OS_FILE_MAX_PATH);
if (strcmp((char*) lpFindFileData->cFileName, ".") == 0
|| strcmp((char*) lpFindFileData->cFileName, "..") == 0) {
goto next_file;
}
strcpy(info->name, (char*) lpFindFileData->cFileName);
info->size = (ib_int64_t)(lpFindFileData->nFileSizeLow)
+ (((ib_int64_t)(lpFindFileData->nFileSizeHigh))
<< 32);
if (lpFindFileData->dwFileAttributes
& FILE_ATTRIBUTE_REPARSE_POINT) {
/* TODO: test Windows symlinks */
/* TODO: MySQL has apparently its own symlink
implementation in Windows, dbname.sym can
redirect a database directory:
REFMAN "windows-symbolic-links.html" */
info->type = OS_FILE_TYPE_LINK;
} else if (lpFindFileData->dwFileAttributes
& FILE_ATTRIBUTE_DIRECTORY) {
info->type = OS_FILE_TYPE_DIR;
} else {
/* It is probably safest to assume that all other
file types are normal. Better to check them rather
than blindly skip them. */
info->type = OS_FILE_TYPE_FILE;
}
}
ut_free(lpFindFileData);
if (ret) {
return(0);
} else if (GetLastError() == ERROR_NO_MORE_FILES) {
return(1);
} else {
os_file_handle_error_no_exit(NULL, "readdir_next_file", FALSE, __FILE__, __LINE__);
return(-1);
}
#else
struct dirent* ent;
char* full_path;
int ret;
struct stat statinfo;
#ifdef HAVE_READDIR_R
char dirent_buf[sizeof(struct dirent)
+ _POSIX_PATH_MAX + 100];
/* In /mysys/my_lib.c, _POSIX_PATH_MAX + 1 is used as
the max file name len; but in most standards, the
length is NAME_MAX; we add 100 to be even safer */
#endif
next_file:
#ifdef HAVE_READDIR_R
ret = readdir_r(dir, (struct dirent*) dirent_buf, &ent);
if (ret != 0
#ifdef UNIV_AIX
/* On AIX, only if we got non-NULL 'ent' (result) value and
a non-zero 'ret' (return) value, it indicates a failed
readdir_r() call. An NULL 'ent' with an non-zero 'ret'
would indicate the "end of the directory" is reached. */
&& ent != NULL
#endif
) {
fprintf(stderr,
"InnoDB: cannot read directory %s, error %lu\n",
dirname, (ulong) ret);
return(-1);
}
if (ent == NULL) {
/* End of directory */
return(1);
}
ut_a(strlen(ent->d_name) < _POSIX_PATH_MAX + 100 - 1);
#else
ent = readdir(dir);
if (ent == NULL) {
return(1);
}
#endif
ut_a(strlen(ent->d_name) < OS_FILE_MAX_PATH);
if (strcmp(ent->d_name, ".") == 0 || strcmp(ent->d_name, "..") == 0) {
goto next_file;
}
strcpy(info->name, ent->d_name);
full_path = static_cast<char*>(
ut_malloc(strlen(dirname) + strlen(ent->d_name) + 10));
sprintf(full_path, "%s/%s", dirname, ent->d_name);
ret = stat(full_path, &statinfo);
if (ret) {
if (errno == ENOENT) {
/* readdir() returned a file that does not exist,
it must have been deleted in the meantime. Do what
would have happened if the file was deleted before
readdir() - ignore and go to the next entry.
If this is the last entry then info->name will still
contain the name of the deleted file when this
function returns, but this is not an issue since the
caller shouldn't be looking at info when end of
directory is returned. */
ut_free(full_path);
goto next_file;
}
os_file_handle_error_no_exit(full_path, "stat", FALSE, __FILE__, __LINE__);
ut_free(full_path);
return(-1);
}
info->size = (ib_int64_t) statinfo.st_size;
if (S_ISDIR(statinfo.st_mode)) {
info->type = OS_FILE_TYPE_DIR;
} else if (S_ISLNK(statinfo.st_mode)) {
info->type = OS_FILE_TYPE_LINK;
} else if (S_ISREG(statinfo.st_mode)) {
info->type = OS_FILE_TYPE_FILE;
} else {
info->type = OS_FILE_TYPE_UNKNOWN;
}
ut_free(full_path);
return(0);
#endif
}
/*****************************************************************//**
This function attempts to create a directory named pathname. The new
directory gets default permissions. On Unix the permissions are
(0770 & ~umask). If the directory exists already, nothing is done and
the call succeeds, unless the fail_if_exists arguments is true.
If another error occurs, such as a permission error, this does not crash,
but reports the error and returns FALSE.
@return TRUE if call succeeds, FALSE on error */
UNIV_INTERN
ibool
os_file_create_directory(
/*=====================*/
const char* pathname, /*!< in: directory name as
null-terminated string */
ibool fail_if_exists) /*!< in: if TRUE, pre-existing directory
is treated as an error. */
{
#ifdef __WIN__
BOOL rcode;
rcode = CreateDirectory((LPCTSTR) pathname, NULL);
if (!(rcode != 0
|| (GetLastError() == ERROR_ALREADY_EXISTS
&& !fail_if_exists))) {
os_file_handle_error_no_exit(
pathname, "CreateDirectory", FALSE, __FILE__, __LINE__);
return(FALSE);
}
return(TRUE);
#else
int rcode;
WAIT_ALLOW_WRITES();
rcode = mkdir(pathname, 0770);
if (!(rcode == 0 || (errno == EEXIST && !fail_if_exists))) {
/* failure */
os_file_handle_error_no_exit(pathname, "mkdir", FALSE, __FILE__, __LINE__);
return(FALSE);
}
return (TRUE);
#endif /* __WIN__ */
}
/****************************************************************//**
NOTE! Use the corresponding macro os_file_create_simple(), not directly
this function!
A simple function to open or create a file.
@return own: handle to the file, not defined if error, error number
can be retrieved with os_file_get_last_error */
UNIV_INTERN
os_file_t
os_file_create_simple_func(
/*=======================*/
const char* name, /*!< in: name of the file or path as a
null-terminated string */
ulint create_mode,/*!< in: create mode */
ulint access_type,/*!< in: OS_FILE_READ_ONLY or
OS_FILE_READ_WRITE */
ibool* success)/*!< out: TRUE if succeed, FALSE if error */
{
os_file_t file;
ibool retry;
*success = FALSE;
#ifdef __WIN__
DWORD access;
DWORD create_flag;
DWORD attributes = 0;
ut_a(!(create_mode & OS_FILE_ON_ERROR_SILENT));
ut_a(!(create_mode & OS_FILE_ON_ERROR_NO_EXIT));
if (create_mode == OS_FILE_OPEN) {
create_flag = OPEN_EXISTING;
} else if (srv_read_only_mode) {
create_flag = OPEN_EXISTING;
} else if (create_mode == OS_FILE_CREATE) {
create_flag = CREATE_NEW;
} else if (create_mode == OS_FILE_CREATE_PATH) {
ut_a(!srv_read_only_mode);
/* Create subdirs along the path if needed */
*success = os_file_create_subdirs_if_needed(name);
if (!*success) {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unable to create subdirectories '%s'",
name);
return((os_file_t) -1);
}
create_flag = CREATE_NEW;
create_mode = OS_FILE_CREATE;
} else {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unknown file create mode (%lu) for file '%s'",
create_mode, name);
return((os_file_t) -1);
}
if (access_type == OS_FILE_READ_ONLY) {
access = GENERIC_READ;
} else if (srv_read_only_mode) {
ib_logf(IB_LOG_LEVEL_INFO,
"read only mode set. Unable to "
"open file '%s' in RW mode, trying RO mode", name);
access = GENERIC_READ;
} else if (access_type == OS_FILE_READ_WRITE) {
access = GENERIC_READ | GENERIC_WRITE;
} else {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unknown file access type (%lu) for file '%s'",
access_type, name);
return((os_file_t) -1);
}
do {
/* Use default security attributes and no template file. */
file = CreateFile(
(LPCTSTR) name, access, FILE_SHARE_READ, NULL,
create_flag, attributes, NULL);
if (file == INVALID_HANDLE_VALUE) {
*success = FALSE;
retry = os_file_handle_error(
name, create_mode == OS_FILE_OPEN ?
"open" : "create", __FILE__, __LINE__);
} else {
*success = TRUE;
retry = false;
}
} while (retry);
#else /* __WIN__ */
int create_flag;
if (create_mode != OS_FILE_OPEN && create_mode != OS_FILE_OPEN_RAW)
WAIT_ALLOW_WRITES();
ut_a(!(create_mode & OS_FILE_ON_ERROR_SILENT));
ut_a(!(create_mode & OS_FILE_ON_ERROR_NO_EXIT));
if (create_mode == OS_FILE_OPEN) {
if (access_type == OS_FILE_READ_ONLY) {
create_flag = O_RDONLY;
} else if (srv_read_only_mode) {
create_flag = O_RDONLY;
} else {
create_flag = O_RDWR;
}
} else if (srv_read_only_mode) {
create_flag = O_RDONLY;
} else if (create_mode == OS_FILE_CREATE) {
create_flag = O_RDWR | O_CREAT | O_EXCL;
} else if (create_mode == OS_FILE_CREATE_PATH) {
/* Create subdirs along the path if needed */
*success = os_file_create_subdirs_if_needed(name);
if (!*success) {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unable to create subdirectories '%s'",
name);
return((os_file_t) -1);
}
create_flag = O_RDWR | O_CREAT | O_EXCL;
create_mode = OS_FILE_CREATE;
} else {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unknown file create mode (%lu) for file '%s'",
create_mode, name);
return((os_file_t) -1);
}
do {
file = ::open(name, create_flag, os_innodb_umask);
if (file == -1) {
*success = FALSE;
retry = os_file_handle_error(
name,
create_mode == OS_FILE_OPEN
? "open" : "create", __FILE__, __LINE__);
} else {
*success = TRUE;
retry = false;
}
} while (retry);
#ifdef USE_FILE_LOCK
if (!srv_read_only_mode
&& *success
&& access_type == OS_FILE_READ_WRITE
&& os_file_lock(file, name)) {
*success = FALSE;
close(file);
file = -1;
}
#endif /* USE_FILE_LOCK */
#endif /* __WIN__ */
return(file);
}
/****************************************************************//**
NOTE! Use the corresponding macro
os_file_create_simple_no_error_handling(), not directly this function!
A simple function to open or create a file.
@return own: handle to the file, not defined if error, error number
can be retrieved with os_file_get_last_error */
UNIV_INTERN
os_file_t
os_file_create_simple_no_error_handling_func(
/*=========================================*/
const char* name, /*!< in: name of the file or path as a
null-terminated string */
ulint create_mode,/*!< in: create mode */
ulint access_type,/*!< in: OS_FILE_READ_ONLY,
OS_FILE_READ_WRITE, or
OS_FILE_READ_ALLOW_DELETE; the last option is
used by a backup program reading the file */
ibool* success,/*!< out: TRUE if succeed, FALSE if error */
ulint atomic_writes) /*! in: atomic writes table option
value */
{
os_file_t file;
atomic_writes_t awrites = (atomic_writes_t) atomic_writes;
*success = FALSE;
#ifdef __WIN__
DWORD access;
DWORD create_flag;
DWORD attributes = 0;
DWORD share_mode = FILE_SHARE_READ;
ut_a(name);
ut_a(!(create_mode & OS_FILE_ON_ERROR_SILENT));
ut_a(!(create_mode & OS_FILE_ON_ERROR_NO_EXIT));
if (create_mode == OS_FILE_OPEN) {
create_flag = OPEN_EXISTING;
} else if (srv_read_only_mode) {
create_flag = OPEN_EXISTING;
} else if (create_mode == OS_FILE_CREATE) {
create_flag = CREATE_NEW;
} else {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unknown file create mode (%lu) for file '%s'",
create_mode, name);
return((os_file_t) -1);
}
if (access_type == OS_FILE_READ_ONLY) {
access = GENERIC_READ;
} else if (srv_read_only_mode) {
access = GENERIC_READ;
} else if (access_type == OS_FILE_READ_WRITE) {
access = GENERIC_READ | GENERIC_WRITE;
} else if (access_type == OS_FILE_READ_ALLOW_DELETE) {
ut_a(!srv_read_only_mode);
access = GENERIC_READ;
/*!< A backup program has to give mysqld the maximum
freedom to do what it likes with the file */
share_mode |= FILE_SHARE_DELETE | FILE_SHARE_WRITE;
} else {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unknown file access type (%lu) for file '%s'",
access_type, name);
return((os_file_t) -1);
}
file = CreateFile((LPCTSTR) name,
access,
share_mode,
NULL, // Security attributes
create_flag,
attributes,
NULL); // No template file
/* If we have proper file handle and atomic writes should be used,
try to set atomic writes and if that fails when creating a new
table, produce a error. If atomic writes are used on existing
file, ignore error and use traditional writes for that file */
if (file != INVALID_HANDLE_VALUE
&& (awrites == ATOMIC_WRITES_ON ||
(srv_use_atomic_writes && awrites == ATOMIC_WRITES_DEFAULT))
&& !os_file_set_atomic_writes(name, file)) {
if (create_mode == OS_FILE_CREATE) {
fprintf(stderr, "InnoDB: Error: Can't create file using atomic writes\n");
CloseHandle(file);
os_file_delete_if_exists_func(name);
*success = FALSE;
file = INVALID_HANDLE_VALUE;
}
}
*success = (file != INVALID_HANDLE_VALUE);
#else /* __WIN__ */
int create_flag;
ut_a(name);
if (create_mode != OS_FILE_OPEN && create_mode != OS_FILE_OPEN_RAW)
WAIT_ALLOW_WRITES();
ut_a(!(create_mode & OS_FILE_ON_ERROR_SILENT));
ut_a(!(create_mode & OS_FILE_ON_ERROR_NO_EXIT));
if (create_mode == OS_FILE_OPEN) {
if (access_type == OS_FILE_READ_ONLY) {
create_flag = O_RDONLY;
} else if (srv_read_only_mode) {
create_flag = O_RDONLY;
} else {
ut_a(access_type == OS_FILE_READ_WRITE
|| access_type == OS_FILE_READ_ALLOW_DELETE);
create_flag = O_RDWR;
}
} else if (srv_read_only_mode) {
create_flag = O_RDONLY;
} else if (create_mode == OS_FILE_CREATE) {
create_flag = O_RDWR | O_CREAT | O_EXCL;
} else {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unknown file create mode (%lu) for file '%s'",
create_mode, name);
return((os_file_t) -1);
}
file = ::open(name, create_flag, os_innodb_umask);
*success = file == -1 ? FALSE : TRUE;
#ifdef USE_FILE_LOCK
if (!srv_read_only_mode
&& *success
&& access_type == OS_FILE_READ_WRITE
&& os_file_lock(file, name)) {
*success = FALSE;
close(file);
file = -1;
}
#endif /* USE_FILE_LOCK */
/* If we have proper file handle and atomic writes should be used,
try to set atomic writes and if that fails when creating a new
table, produce a error. If atomic writes are used on existing
file, ignore error and use traditional writes for that file */
if (file != -1
&& (awrites == ATOMIC_WRITES_ON ||
(srv_use_atomic_writes && awrites == ATOMIC_WRITES_DEFAULT))
&& !os_file_set_atomic_writes(name, file)) {
if (create_mode == OS_FILE_CREATE) {
fprintf(stderr, "InnoDB: Error: Can't create file using atomic writes\n");
close(file);
os_file_delete_if_exists_func(name);
*success = FALSE;
file = -1;
}
}
#endif /* __WIN__ */
return(file);
}
/****************************************************************//**
Tries to disable OS caching on an opened file descriptor. */
UNIV_INTERN
void
os_file_set_nocache(
/*================*/
int fd /*!< in: file descriptor to alter */
__attribute__((unused)),
const char* file_name /*!< in: used in the diagnostic
message */
__attribute__((unused)),
const char* operation_name __attribute__((unused)))
/*!< in: "open" or "create"; used
in the diagnostic message */
{
/* some versions of Solaris may not have DIRECTIO_ON */
#if defined(UNIV_SOLARIS) && defined(DIRECTIO_ON)
if (directio(fd, DIRECTIO_ON) == -1) {
int errno_save = errno;
ib_logf(IB_LOG_LEVEL_ERROR,
"Failed to set DIRECTIO_ON on file %s: %s: %s, "
"continuing anyway.",
file_name, operation_name, strerror(errno_save));
}
#elif defined(O_DIRECT)
if (fcntl(fd, F_SETFL, O_DIRECT) == -1) {
int errno_save = errno;
static bool warning_message_printed = false;
if (errno_save == EINVAL) {
if (!warning_message_printed) {
warning_message_printed = true;
# ifdef UNIV_LINUX
ib_logf(IB_LOG_LEVEL_WARN,
"Failed to set O_DIRECT on file "
"%s: %s: %s, continuing anyway. "
"O_DIRECT is known to result "
"in 'Invalid argument' on Linux on "
"tmpfs, see MySQL Bug#26662.",
file_name, operation_name,
strerror(errno_save));
# else /* UNIV_LINUX */
goto short_warning;
# endif /* UNIV_LINUX */
}
} else {
# ifndef UNIV_LINUX
short_warning:
# endif
ib_logf(IB_LOG_LEVEL_WARN,
"Failed to set O_DIRECT on file %s: %s: %s, "
"continuing anyway.",
file_name, operation_name, strerror(errno_save));
}
}
#endif /* defined(UNIV_SOLARIS) && defined(DIRECTIO_ON) */
}
/****************************************************************//**
NOTE! Use the corresponding macro os_file_create(), not directly
this function!
Opens an existing file or creates a new.
@return own: handle to the file, not defined if error, error number
can be retrieved with os_file_get_last_error */
UNIV_INTERN
os_file_t
os_file_create_func(
/*================*/
const char* name, /*!< in: name of the file or path as a
null-terminated string */
ulint create_mode,/*!< in: create mode */
ulint purpose,/*!< in: OS_FILE_AIO, if asynchronous,
non-buffered i/o is desired,
OS_FILE_NORMAL, if any normal file;
NOTE that it also depends on type, os_aio_..
and srv_.. variables whether we really use
async i/o or unbuffered i/o: look in the
function source code for the exact rules */
ulint type, /*!< in: OS_DATA_FILE or OS_LOG_FILE */
ibool* success,/*!< out: TRUE if succeed, FALSE if error */
ulint atomic_writes) /*! in: atomic writes table option
value */
{
os_file_t file;
ibool retry;
ibool on_error_no_exit;
ibool on_error_silent;
atomic_writes_t awrites = (atomic_writes_t) atomic_writes;
#ifdef __WIN__
DBUG_EXECUTE_IF(
"ib_create_table_fail_disk_full",
*success = FALSE;
SetLastError(ERROR_DISK_FULL);
return((os_file_t) -1);
);
#else /* __WIN__ */
DBUG_EXECUTE_IF(
"ib_create_table_fail_disk_full",
*success = FALSE;
errno = ENOSPC;
return((os_file_t) -1);
);
#endif /* __WIN__ */
#ifdef __WIN__
DWORD create_flag;
DWORD share_mode = FILE_SHARE_READ;
on_error_no_exit = create_mode & OS_FILE_ON_ERROR_NO_EXIT
? TRUE : FALSE;
on_error_silent = create_mode & OS_FILE_ON_ERROR_SILENT
? TRUE : FALSE;
create_mode &= ~OS_FILE_ON_ERROR_NO_EXIT;
create_mode &= ~OS_FILE_ON_ERROR_SILENT;
if (create_mode == OS_FILE_OPEN_RAW) {
ut_a(!srv_read_only_mode);
create_flag = OPEN_EXISTING;
/* On Windows Physical devices require admin privileges and
have to have the write-share mode set. See the remarks
section for the CreateFile() function documentation in MSDN. */
share_mode |= FILE_SHARE_WRITE;
} else if (create_mode == OS_FILE_OPEN
|| create_mode == OS_FILE_OPEN_RETRY) {
create_flag = OPEN_EXISTING;
} else if (srv_read_only_mode) {
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 {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unknown file create mode (%lu) for file '%s'",
create_mode, name);
return((os_file_t) -1);
}
DWORD attributes = 0;
#ifdef UNIV_HOTBACKUP
attributes |= FILE_FLAG_NO_BUFFERING;
#else
if (purpose == OS_FILE_AIO) {
#ifdef WIN_ASYNC_IO
/* If specified, use asynchronous (overlapped) io and no
buffering of writes in the OS */
if (srv_use_native_aio) {
attributes |= FILE_FLAG_OVERLAPPED;
}
#endif /* WIN_ASYNC_IO */
} else if (purpose == OS_FILE_NORMAL) {
/* Use default setting. */
} else {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unknown purpose flag (%lu) while opening file '%s'",
purpose, name);
return((os_file_t)(-1));
}
#ifdef UNIV_NON_BUFFERED_IO
// TODO: Create a bug, this looks wrong. The flush log
// parameter is dynamic.
if (type == OS_LOG_FILE && srv_flush_log_at_trx_commit == 2) {
/* Do not use unbuffered i/o for the log files because
value 2 denotes that we do not flush the log at every
commit, but only once per second */
} else if (srv_win_file_flush_method == SRV_WIN_IO_UNBUFFERED) {
attributes |= FILE_FLAG_NO_BUFFERING;
}
#endif /* UNIV_NON_BUFFERED_IO */
#endif /* UNIV_HOTBACKUP */
DWORD access = GENERIC_READ;
if (!srv_read_only_mode) {
access |= GENERIC_WRITE;
}
do {
/* Use default security attributes and no template file. */
file = CreateFile(
(LPCTSTR) name, access, share_mode, NULL,
create_flag, attributes, NULL);
if (file == INVALID_HANDLE_VALUE) {
const char* operation;
operation = (create_mode == OS_FILE_CREATE
&& !srv_read_only_mode)
? "create" : "open";
*success = FALSE;
if (on_error_no_exit) {
retry = os_file_handle_error_no_exit(
name, operation, on_error_silent, __FILE__, __LINE__);
} else {
retry = os_file_handle_error(name, operation, __FILE__, __LINE__);
}
} else {
*success = TRUE;
retry = FALSE;
}
} while (retry);
/* If we have proper file handle and atomic writes should be used,
try to set atomic writes and if that fails when creating a new
table, produce a error. If atomic writes are used on existing
file, ignore error and use traditional writes for that file */
if (file != INVALID_HANDLE_VALUE && type == OS_DATA_FILE
&& (awrites == ATOMIC_WRITES_ON ||
(srv_use_atomic_writes && awrites == ATOMIC_WRITES_DEFAULT))
&& !os_file_set_atomic_writes(name, file)) {
if (create_mode == OS_FILE_CREATE) {
fprintf(stderr, "InnoDB: Error: Can't create file using atomic writes\n");
CloseHandle(file);
os_file_delete_if_exists_func(name);
*success = FALSE;
file = INVALID_HANDLE_VALUE;
}
}
#else /* __WIN__ */
int create_flag;
const char* mode_str = NULL;
if (create_mode != OS_FILE_OPEN && create_mode != OS_FILE_OPEN_RAW)
WAIT_ALLOW_WRITES();
on_error_no_exit = create_mode & OS_FILE_ON_ERROR_NO_EXIT
? TRUE : FALSE;
on_error_silent = create_mode & OS_FILE_ON_ERROR_SILENT
? TRUE : FALSE;
create_mode &= ~OS_FILE_ON_ERROR_NO_EXIT;
create_mode &= ~OS_FILE_ON_ERROR_SILENT;
if (create_mode == OS_FILE_OPEN
|| create_mode == OS_FILE_OPEN_RAW
|| create_mode == OS_FILE_OPEN_RETRY) {
mode_str = "OPEN";
create_flag = srv_read_only_mode ? O_RDONLY : O_RDWR;
} else if (srv_read_only_mode) {
mode_str = "OPEN";
create_flag = O_RDONLY;
} else if (create_mode == OS_FILE_CREATE) {
mode_str = "CREATE";
create_flag = O_RDWR | O_CREAT | O_EXCL;
} else if (create_mode == OS_FILE_OVERWRITE) {
mode_str = "OVERWRITE";
create_flag = O_RDWR | O_CREAT | O_TRUNC;
} else {
ib_logf(IB_LOG_LEVEL_ERROR,
"Unknown file create mode (%lu) for file '%s'",
create_mode, name);
return((os_file_t) -1);
}
ut_a(type == OS_LOG_FILE || type == OS_DATA_FILE);
ut_a(purpose == OS_FILE_AIO || purpose == OS_FILE_NORMAL);
#ifdef O_SYNC
/* We let O_SYNC only affect log files; note that we map O_DSYNC to
O_SYNC because the datasync options seemed to corrupt files in 2001
in both Linux and Solaris */
if (!srv_read_only_mode
&& type == OS_LOG_FILE
&& srv_unix_file_flush_method == SRV_UNIX_O_DSYNC) {
create_flag |= O_SYNC;
}
#endif /* O_SYNC */
do {
file = ::open(name, create_flag, os_innodb_umask);
if (file == -1) {
const char* operation;
operation = (create_mode == OS_FILE_CREATE
&& !srv_read_only_mode)
? "create" : "open";
*success = FALSE;
if (on_error_no_exit) {
retry = os_file_handle_error_no_exit(
name, operation, on_error_silent, __FILE__, __LINE__);
} else {
retry = os_file_handle_error(name, operation, __FILE__, __LINE__);
}
} else {
*success = TRUE;
retry = false;
}
} while (retry);
/* We disable OS caching (O_DIRECT) only on data files */
if (!srv_read_only_mode
&& *success
&& type != OS_LOG_FILE
&& (srv_unix_file_flush_method == SRV_UNIX_O_DIRECT
|| srv_unix_file_flush_method == SRV_UNIX_O_DIRECT_NO_FSYNC)) {
os_file_set_nocache(file, name, mode_str);
}
#ifdef USE_FILE_LOCK
if (!srv_read_only_mode
&& *success
&& create_mode != OS_FILE_OPEN_RAW
&& os_file_lock(file, name)) {
if (create_mode == OS_FILE_OPEN_RETRY) {
ut_a(!srv_read_only_mode);
ib_logf(IB_LOG_LEVEL_INFO,
"Retrying to lock the first data file");
for (int i = 0; i < 100; i++) {
os_thread_sleep(1000000);
if (!os_file_lock(file, name)) {
*success = TRUE;
return(file);
}
}
ib_logf(IB_LOG_LEVEL_INFO,
"Unable to open the first data file");
}
*success = FALSE;
close(file);
file = -1;
}
#endif /* USE_FILE_LOCK */
/* If we have proper file handle and atomic writes should be used,
try to set atomic writes and if that fails when creating a new
table, produce a error. If atomic writes are used on existing
file, ignore error and use traditional writes for that file */
if (file != -1 && type == OS_DATA_FILE
&& (awrites == ATOMIC_WRITES_ON ||
(srv_use_atomic_writes && awrites == ATOMIC_WRITES_DEFAULT))
&& !os_file_set_atomic_writes(name, file)) {
if (create_mode == OS_FILE_CREATE) {
fprintf(stderr, "InnoDB: Error: Can't create file using atomic writes\n");
close(file);
os_file_delete_if_exists_func(name);
*success = FALSE;
file = -1;
}
}
#endif /* __WIN__ */
return(file);
}
/***********************************************************************//**
Deletes a file if it exists. The file has to be closed before calling this.
@return TRUE if success */
UNIV_INTERN
bool
os_file_delete_if_exists_func(
/*==========================*/
const char* name) /*!< in: file path as a null-terminated
string */
{
#ifdef __WIN__
bool ret;
ulint count = 0;
loop:
/* In Windows, deleting an .ibd file may fail if mysqlbackup is copying
it */
ret = DeleteFile((LPCTSTR) name);
if (ret) {
return(true);
}
DWORD lasterr = GetLastError();
if (lasterr == ERROR_FILE_NOT_FOUND
|| lasterr == ERROR_PATH_NOT_FOUND) {
/* the file does not exist, this not an error */
return(true);
}
count++;
if (count > 100 && 0 == (count % 10)) {
os_file_get_last_error(true); /* print error information */
ib_logf(IB_LOG_LEVEL_WARN, "Delete of file %s failed.", name);
}
os_thread_sleep(500000); /* sleep for 0.5 second */
if (count > 2000) {
return(false);
}
goto loop;
#else
int ret;
WAIT_ALLOW_WRITES();
ret = unlink(name);
if (ret != 0 && errno != ENOENT) {
os_file_handle_error_no_exit(name, "delete", FALSE, __FILE__, __LINE__);
return(false);
}
return(true);
#endif /* __WIN__ */
}
/***********************************************************************//**
Deletes a file. The file has to be closed before calling this.
@return TRUE if success */
UNIV_INTERN
bool
os_file_delete_func(
/*================*/
const char* name) /*!< in: file path as a null-terminated
string */
{
#ifdef __WIN__
BOOL ret;
ulint count = 0;
loop:
/* In Windows, deleting an .ibd file may fail if mysqlbackup is copying
it */
ret = DeleteFile((LPCTSTR) name);
if (ret) {
return(true);
}
if (GetLastError() == ERROR_FILE_NOT_FOUND) {
/* If the file does not exist, we classify this as a 'mild'
error and return */
return(false);
}
count++;
if (count > 100 && 0 == (count % 10)) {
os_file_get_last_error(true); /* print error information */
fprintf(stderr,
"InnoDB: Warning: cannot delete file %s\n"
"InnoDB: Are you running mysqlbackup"
" to back up the file?\n", name);
}
os_thread_sleep(1000000); /* sleep for a second */
if (count > 2000) {
return(false);
}
goto loop;
#else
int ret;
WAIT_ALLOW_WRITES();
ret = unlink(name);
if (ret != 0) {
os_file_handle_error_no_exit(name, "delete", FALSE, __FILE__, __LINE__);
return(false);
}
return(true);
#endif
}
/***********************************************************************//**
NOTE! Use the corresponding macro os_file_rename(), not directly this function!
Renames a file (can also move it to another directory). It is safest that the
file is closed before calling this function.
@return TRUE if success */
UNIV_INTERN
ibool
os_file_rename_func(
/*================*/
const char* oldpath,/*!< in: old file path as a null-terminated
string */
const char* newpath)/*!< in: new file path */
{
#ifdef UNIV_DEBUG
os_file_type_t type;
ibool exists;
/* New path must not exist. */
ut_ad(os_file_status(newpath, &exists, &type));
ut_ad(!exists);
/* Old path must exist. */
ut_ad(os_file_status(oldpath, &exists, &type));
ut_ad(exists);
#endif /* UNIV_DEBUG */
#ifdef __WIN__
BOOL ret;
ret = MoveFile((LPCTSTR) oldpath, (LPCTSTR) newpath);
if (ret) {
return(TRUE);
}
os_file_handle_error_no_exit(oldpath, "rename", FALSE, __FILE__, __LINE__);
return(FALSE);
#else
int ret;
WAIT_ALLOW_WRITES();
ret = rename(oldpath, newpath);
if (ret != 0) {
os_file_handle_error_no_exit(oldpath, "rename", FALSE, __FILE__, __LINE__);
return(FALSE);
}
return(TRUE);
#endif /* __WIN__ */
}
/***********************************************************************//**
NOTE! Use the corresponding macro os_file_close(), not directly this function!
Closes a file handle. In case of error, error number can be retrieved with
os_file_get_last_error.
@return TRUE if success */
UNIV_INTERN
ibool
os_file_close_func(
/*===============*/
os_file_t file) /*!< in, own: handle to a file */
{
#ifdef __WIN__
BOOL ret;
ret = CloseHandle(file);
if (ret) {
return(TRUE);
}
os_file_handle_error(NULL, "close", __FILE__, __LINE__);
return(FALSE);
#else
int ret;
ret = close(file);
if (ret == -1) {
os_file_handle_error(NULL, "close", __FILE__, __LINE__);
return(FALSE);
}
return(TRUE);
#endif /* __WIN__ */
}
#ifdef UNIV_HOTBACKUP
/***********************************************************************//**
Closes a file handle.
@return TRUE if success */
UNIV_INTERN
ibool
os_file_close_no_error_handling(
/*============================*/
os_file_t file) /*!< in, own: handle to a file */
{
#ifdef __WIN__
BOOL ret;
ret = CloseHandle(file);
if (ret) {
return(TRUE);
}
return(FALSE);
#else
int ret;
ret = close(file);
if (ret == -1) {
return(FALSE);
}
return(TRUE);
#endif /* __WIN__ */
}
#endif /* UNIV_HOTBACKUP */
/***********************************************************************//**
Gets a file size.
@return file size, or (os_offset_t) -1 on failure */
UNIV_INTERN
os_offset_t
os_file_get_size(
/*=============*/
os_file_t file) /*!< in: handle to a file */
{
#ifdef __WIN__
os_offset_t offset;
DWORD high;
DWORD low;
low = GetFileSize(file, &high);
if ((low == 0xFFFFFFFF) && (GetLastError() != NO_ERROR)) {
return((os_offset_t) -1);
}
offset = (os_offset_t) low | ((os_offset_t) high << 32);
return(offset);
#else
return((os_offset_t) lseek(file, 0, SEEK_END));
#endif /* __WIN__ */
}
/***********************************************************************//**
Write the specified number of zeros to a newly created file.
@return TRUE if success */
UNIV_INTERN
ibool
os_file_set_size(
/*=============*/
const char* name, /*!< in: name of the file or path as a
null-terminated string */
os_file_t file, /*!< in: handle to a file */
os_offset_t size) /*!< in: file size */
{
os_offset_t current_size;
ibool ret;
byte* buf;
byte* buf2;
ulint buf_size;
current_size = 0;
#ifdef HAVE_POSIX_FALLOCATE
if (srv_use_posix_fallocate) {
if (posix_fallocate(file, current_size, size) == -1) {
fprintf(stderr, "InnoDB: Error: preallocating file "
"space for file \'%s\' failed. Current size "
"%lu, desired size %lu\n",
name, current_size, size);
os_file_handle_error_no_exit(name, "posix_fallocate", FALSE, __FILE__, __LINE__);
return(FALSE);
}
return(TRUE);
}
#endif
/* Write up to 1 megabyte at a time. */
buf_size = ut_min(64, (ulint) (size / UNIV_PAGE_SIZE))
* UNIV_PAGE_SIZE;
buf2 = static_cast<byte*>(ut_malloc(buf_size + UNIV_PAGE_SIZE));
/* Align the buffer for possible raw i/o */
buf = static_cast<byte*>(ut_align(buf2, UNIV_PAGE_SIZE));
/* Write buffer full of zeros */
memset(buf, 0, buf_size);
if (size >= (os_offset_t) 100 << 20) {
fprintf(stderr, "InnoDB: Progress in MB:");
}
while (current_size < size) {
ulint n_bytes;
if (size - current_size < (os_offset_t) buf_size) {
n_bytes = (ulint) (size - current_size);
} else {
n_bytes = buf_size;
}
ret = os_file_write(name, file, buf, current_size, n_bytes);
if (!ret) {
ut_free(buf2);
goto error_handling;
}
/* Print about progress for each 100 MB written */
if ((current_size + n_bytes) / (100 << 20)
!= current_size / (100 << 20)) {
fprintf(stderr, " %lu00",
(ulong) ((current_size + n_bytes)
/ (100 << 20)));
}
current_size += n_bytes;
}
if (size >= (os_offset_t) 100 << 20) {
fprintf(stderr, "\n");
}
ut_free(buf2);
ret = os_file_flush(file);
if (ret) {
return(TRUE);
}
error_handling:
return(FALSE);
}
/***********************************************************************//**
Truncates a file at its current position.
@return TRUE if success */
UNIV_INTERN
ibool
os_file_set_eof(
/*============*/
FILE* file) /*!< in: file to be truncated */
{
#ifdef __WIN__
HANDLE h = (HANDLE) _get_osfhandle(fileno(file));
return(SetEndOfFile(h));
#else /* __WIN__ */
WAIT_ALLOW_WRITES();
return(!ftruncate(fileno(file), ftell(file)));
#endif /* __WIN__ */
}
#ifndef __WIN__
/***********************************************************************//**
Wrapper to fsync(2) that retries the call on some errors.
Returns the value 0 if successful; otherwise the value -1 is returned and
the global variable errno is set to indicate the error.
@return 0 if success, -1 otherwise */
static
int
os_file_fsync(
/*==========*/
os_file_t file) /*!< in: handle to a file */
{
int ret;
int failures;
ibool retry;
failures = 0;
do {
ret = fsync(file);
os_n_fsyncs++;
if (ret == -1 && errno == ENOLCK) {
if (failures % 100 == 0) {
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: fsync(): "
"No locks available; retrying\n");
}
os_thread_sleep(200000 /* 0.2 sec */);
failures++;
retry = TRUE;
} else {
retry = FALSE;
}
} while (retry);
return(ret);
}
#endif /* !__WIN__ */
/***********************************************************************//**
NOTE! Use the corresponding macro os_file_flush(), not directly this function!
Flushes the write buffers of a given file to the disk.
@return TRUE if success */
UNIV_INTERN
ibool
os_file_flush_func(
/*===============*/
os_file_t file) /*!< in, own: handle to a file */
{
#ifdef __WIN__
BOOL ret;
os_n_fsyncs++;
ret = FlushFileBuffers(file);
if (ret) {
return(TRUE);
}
/* Since Windows returns ERROR_INVALID_FUNCTION if the 'file' is
actually a raw device, we choose to ignore that error if we are using
raw disks */
if (srv_start_raw_disk_in_use && GetLastError()
== ERROR_INVALID_FUNCTION) {
return(TRUE);
}
os_file_handle_error(NULL, "flush", __FILE__, __LINE__);
/* It is a fatal error if a file flush does not succeed, because then
the database can get corrupt on disk */
ut_error;
return(FALSE);
#else
int ret;
WAIT_ALLOW_WRITES();
#if defined(HAVE_DARWIN_THREADS)
# ifndef F_FULLFSYNC
/* The following definition is from the Mac OS X 10.3 <sys/fcntl.h> */
# define F_FULLFSYNC 51 /* fsync + ask the drive to flush to the media */
# elif F_FULLFSYNC != 51
# error "F_FULLFSYNC != 51: ABI incompatibility with Mac OS X 10.3"
# endif
/* Apple has disabled fsync() for internal disk drives in OS X. That
caused corruption for a user when he tested a power outage. Let us in
OS X use a nonstandard flush method recommended by an Apple
engineer. */
if (!srv_have_fullfsync) {
/* If we are not on an operating system that supports this,
then fall back to a plain fsync. */
ret = os_file_fsync(file);
} else {
ret = fcntl(file, F_FULLFSYNC, NULL);
if (ret) {
/* If we are not on a file system that supports this,
then fall back to a plain fsync. */
ret = os_file_fsync(file);
}
}
#else
ret = os_file_fsync(file);
#endif
if (ret == 0) {
return(TRUE);
}
/* Since Linux returns EINVAL if the 'file' is actually a raw device,
we choose to ignore that error if we are using raw disks */
if (srv_start_raw_disk_in_use && errno == EINVAL) {
return(TRUE);
}
ib_logf(IB_LOG_LEVEL_ERROR, "The OS said file flush did not succeed");
os_file_handle_error(NULL, "flush", __FILE__, __LINE__);
/* It is a fatal error if a file flush does not succeed, because then
the database can get corrupt on disk */
ut_error;
return(FALSE);
#endif
}
#ifndef __WIN__
/*******************************************************************//**
Does a synchronous read operation in Posix.
@return number of bytes read, -1 if error */
static __attribute__((nonnull, warn_unused_result))
ssize_t
os_file_pread(
/*==========*/
os_file_t file, /*!< in: handle to a file */
void* buf, /*!< in: buffer where to read */
ulint n, /*!< in: number of bytes to read */
os_offset_t offset) /*!< in: file offset from where to read */
{
off_t offs;
#if defined(HAVE_PREAD) && !defined(HAVE_BROKEN_PREAD)
ssize_t n_bytes;
#endif /* HAVE_PREAD && !HAVE_BROKEN_PREAD */
ut_ad(n);
/* If off_t is > 4 bytes in size, then we assume we can pass a
64-bit address */
offs = (off_t) offset;
if (sizeof(off_t) <= 4) {
if (offset != (os_offset_t) offs) {
ib_logf(IB_LOG_LEVEL_ERROR,
"File read at offset > 4 GB");
}
}
os_n_file_reads++;
#if defined(HAVE_PREAD) && !defined(HAVE_BROKEN_PREAD)
#if defined(HAVE_ATOMIC_BUILTINS) && UNIV_WORD_SIZE == 8
(void) os_atomic_increment_ulint(&os_n_pending_reads, 1);
(void) os_atomic_increment_ulint(&os_file_n_pending_preads, 1);
MONITOR_ATOMIC_INC(MONITOR_OS_PENDING_READS);
#else
os_mutex_enter(os_file_count_mutex);
os_file_n_pending_preads++;
os_n_pending_reads++;
MONITOR_INC(MONITOR_OS_PENDING_READS);
os_mutex_exit(os_file_count_mutex);
#endif /* HAVE_ATOMIC_BUILTINS && UNIV_WORD == 8 */
n_bytes = pread(file, buf, n, offs);
#if defined(HAVE_ATOMIC_BUILTINS) && UNIV_WORD_SIZE == 8
(void) os_atomic_decrement_ulint(&os_n_pending_reads, 1);
(void) os_atomic_decrement_ulint(&os_file_n_pending_preads, 1);
MONITOR_ATOMIC_DEC(MONITOR_OS_PENDING_READS);
#else
os_mutex_enter(os_file_count_mutex);
os_file_n_pending_preads--;
os_n_pending_reads--;
MONITOR_DEC(MONITOR_OS_PENDING_READS);
os_mutex_exit(os_file_count_mutex);
#endif /* !HAVE_ATOMIC_BUILTINS || UNIV_WORD == 8 */
return(n_bytes);
#else
{
off_t ret_offset;
ssize_t ret;
#ifndef UNIV_HOTBACKUP
ulint i;
#endif /* !UNIV_HOTBACKUP */
#if defined(HAVE_ATOMIC_BUILTINS) && UNIV_WORD_SIZE == 8
(void) os_atomic_increment_ulint(&os_n_pending_reads, 1);
MONITOR_ATOMIC_INC(MONITOR_OS_PENDING_READS);
#else
os_mutex_enter(os_file_count_mutex);
os_n_pending_reads++;
MONITOR_INC(MONITOR_OS_PENDING_READS);
os_mutex_exit(os_file_count_mutex);
#endif /* HAVE_ATOMIC_BUILTINS && UNIV_WORD == 8 */
#ifndef UNIV_HOTBACKUP
/* Protect the seek / read operation with a mutex */
i = ((ulint) file) % OS_FILE_N_SEEK_MUTEXES;
os_mutex_enter(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
ret_offset = lseek(file, offs, SEEK_SET);
if (ret_offset < 0) {
ret = -1;
} else {
ret = read(file, buf, (ssize_t) n);
}
#ifndef UNIV_HOTBACKUP
os_mutex_exit(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
#if defined(HAVE_ATOMIC_BUILTINS) && UNIV_WORD_SIZE == 8
(void) os_atomic_decrement_ulint(&os_n_pending_reads, 1);
MONITOR_ATOIC_DEC(MONITOR_OS_PENDING_READS);
#else
os_mutex_enter(os_file_count_mutex);
os_n_pending_reads--;
MONITOR_DEC(MONITOR_OS_PENDING_READS);
os_mutex_exit(os_file_count_mutex);
#endif /* HAVE_ATOMIC_BUILTINS && UNIV_WORD_SIZE == 8 */
return(ret);
}
#endif
}
/*******************************************************************//**
Does a synchronous write operation in Posix.
@return number of bytes written, -1 if error */
static __attribute__((nonnull, warn_unused_result))
ssize_t
os_file_pwrite(
/*===========*/
os_file_t file, /*!< in: handle to a file */
const void* buf, /*!< in: buffer from where to write */
ulint n, /*!< in: number of bytes to write */
os_offset_t offset) /*!< in: file offset where to write */
{
ssize_t ret;
off_t offs;
ut_ad(n);
ut_ad(!srv_read_only_mode);
/* If off_t is > 4 bytes in size, then we assume we can pass a
64-bit address */
offs = (off_t) offset;
if (sizeof(off_t) <= 4) {
if (offset != (os_offset_t) offs) {
ib_logf(IB_LOG_LEVEL_ERROR,
"File write at offset > 4 GB.");
}
}
os_n_file_writes++;
#if defined(HAVE_PWRITE) && !defined(HAVE_BROKEN_PREAD)
#if !defined(HAVE_ATOMIC_BUILTINS) || UNIV_WORD_SIZE < 8
os_mutex_enter(os_file_count_mutex);
os_file_n_pending_pwrites++;
os_n_pending_writes++;
MONITOR_INC(MONITOR_OS_PENDING_WRITES);
os_mutex_exit(os_file_count_mutex);
#else
(void) os_atomic_increment_ulint(&os_n_pending_writes, 1);
(void) os_atomic_increment_ulint(&os_file_n_pending_pwrites, 1);
MONITOR_ATOMIC_INC(MONITOR_OS_PENDING_WRITES);
#endif /* !HAVE_ATOMIC_BUILTINS || UNIV_WORD < 8 */
ret = pwrite(file, buf, (ssize_t) n, offs);
#if !defined(HAVE_ATOMIC_BUILTINS) || UNIV_WORD_SIZE < 8
os_mutex_enter(os_file_count_mutex);
os_file_n_pending_pwrites--;
os_n_pending_writes--;
MONITOR_DEC(MONITOR_OS_PENDING_WRITES);
os_mutex_exit(os_file_count_mutex);
#else
(void) os_atomic_decrement_ulint(&os_n_pending_writes, 1);
(void) os_atomic_decrement_ulint(&os_file_n_pending_pwrites, 1);
MONITOR_ATOMIC_DEC(MONITOR_OS_PENDING_WRITES);
#endif /* !HAVE_ATOMIC_BUILTINS || UNIV_WORD < 8 */
return(ret);
#else
{
off_t ret_offset;
# ifndef UNIV_HOTBACKUP
ulint i;
# endif /* !UNIV_HOTBACKUP */
os_mutex_enter(os_file_count_mutex);
os_n_pending_writes++;
MONITOR_INC(MONITOR_OS_PENDING_WRITES);
os_mutex_exit(os_file_count_mutex);
# ifndef UNIV_HOTBACKUP
/* Protect the seek / write operation with a mutex */
i = ((ulint) file) % OS_FILE_N_SEEK_MUTEXES;
os_mutex_enter(os_file_seek_mutexes[i]);
# endif /* UNIV_HOTBACKUP */
ret_offset = lseek(file, offs, SEEK_SET);
if (ret_offset < 0) {
ret = -1;
goto func_exit;
}
ret = write(file, buf, (ssize_t) n);
func_exit:
# ifndef UNIV_HOTBACKUP
os_mutex_exit(os_file_seek_mutexes[i]);
# endif /* !UNIV_HOTBACKUP */
os_mutex_enter(os_file_count_mutex);
os_n_pending_writes--;
MONITOR_DEC(MONITOR_OS_PENDING_WRITES);
os_mutex_exit(os_file_count_mutex);
return(ret);
}
#endif /* !UNIV_HOTBACKUP */
}
#endif
/*******************************************************************//**
NOTE! Use the corresponding macro os_file_read(), not directly this
function!
Requests a synchronous positioned read operation.
@return TRUE if request was successful, FALSE if fail */
UNIV_INTERN
ibool
os_file_read_func(
/*==============*/
os_file_t file, /*!< in: handle to a file */
void* buf, /*!< in: buffer where to read */
os_offset_t offset, /*!< in: file offset where to read */
ulint n, /*!< in: number of bytes to read */
ibool compressed) /*!< in: is this file space
compressed ? */
{
#ifdef __WIN__
BOOL ret;
DWORD len;
DWORD ret2;
DWORD low;
DWORD high;
ibool retry;
#ifndef UNIV_HOTBACKUP
ulint i;
#endif /* !UNIV_HOTBACKUP */
/* On 64-bit Windows, ulint is 64 bits. But offset and n should be
no more than 32 bits. */
ut_a((n & 0xFFFFFFFFUL) == n);
os_n_file_reads++;
os_bytes_read_since_printout += n;
try_again:
ut_ad(buf);
ut_ad(n > 0);
low = (DWORD) offset & 0xFFFFFFFF;
high = (DWORD) (offset >> 32);
os_mutex_enter(os_file_count_mutex);
os_n_pending_reads++;
MONITOR_INC(MONITOR_OS_PENDING_READS);
os_mutex_exit(os_file_count_mutex);
#ifndef UNIV_HOTBACKUP
/* Protect the seek / read operation with a mutex */
i = ((ulint) file) % OS_FILE_N_SEEK_MUTEXES;
os_mutex_enter(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
ret2 = SetFilePointer(
file, low, reinterpret_cast<PLONG>(&high), FILE_BEGIN);
if (ret2 == 0xFFFFFFFF && GetLastError() != NO_ERROR) {
#ifndef UNIV_HOTBACKUP
os_mutex_exit(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
os_mutex_enter(os_file_count_mutex);
os_n_pending_reads--;
MONITOR_DEC(MONITOR_OS_PENDING_READS);
os_mutex_exit(os_file_count_mutex);
goto error_handling;
}
ret = ReadFile(file, buf, (DWORD) n, &len, NULL);
#ifndef UNIV_HOTBACKUP
os_mutex_exit(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
os_mutex_enter(os_file_count_mutex);
os_n_pending_reads--;
MONITOR_DEC(MONITOR_OS_PENDING_READS);
os_mutex_exit(os_file_count_mutex);
if (ret && len == n) {
return(TRUE);
}
#else /* __WIN__ */
ibool retry;
ssize_t ret;
os_bytes_read_since_printout += n;
try_again:
ret = os_file_pread(file, buf, n, offset);
if ((ulint) ret == n) {
return(TRUE);
} else if (ret == -1) {
ib_logf(IB_LOG_LEVEL_ERROR,
"Error in system call pread(). The operating"
" system error number is %lu.",(ulint) errno);
} else {
/* Partial read occured */
ib_logf(IB_LOG_LEVEL_ERROR,
"Tried to read " ULINTPF " bytes at offset "
UINT64PF ". Was only able to read %ld.",
n, offset, (lint) ret);
}
#endif /* __WIN__ */
#ifdef __WIN__
error_handling:
#endif
retry = os_file_handle_error(NULL, "read", __FILE__, __LINE__);
if (retry) {
goto try_again;
}
fprintf(stderr,
"InnoDB: Fatal error: cannot read from file."
" OS error number %lu.\n",
#ifdef __WIN__
(ulong) GetLastError()
#else
(ulong) errno
#endif /* __WIN__ */
);
fflush(stderr);
ut_error;
return(FALSE);
}
/*******************************************************************//**
NOTE! Use the corresponding macro os_file_read_no_error_handling(),
not directly this function!
Requests a synchronous positioned read operation. This function does not do
any error handling. In case of error it returns FALSE.
@return TRUE if request was successful, FALSE if fail */
UNIV_INTERN
ibool
os_file_read_no_error_handling_func(
/*================================*/
os_file_t file, /*!< in: handle to a file */
void* buf, /*!< in: buffer where to read */
os_offset_t offset, /*!< in: file offset where to read */
ulint n, /*!< in: number of bytes to read */
ibool compressed) /*!< in: is this file space
compressed ? */
{
#ifdef __WIN__
BOOL ret;
DWORD len;
DWORD ret2;
DWORD low;
DWORD high;
ibool retry;
#ifndef UNIV_HOTBACKUP
ulint i;
#endif /* !UNIV_HOTBACKUP */
/* On 64-bit Windows, ulint is 64 bits. But offset and n should be
no more than 32 bits. */
ut_a((n & 0xFFFFFFFFUL) == n);
os_n_file_reads++;
os_bytes_read_since_printout += n;
try_again:
ut_ad(buf);
ut_ad(n > 0);
low = (DWORD) offset & 0xFFFFFFFF;
high = (DWORD) (offset >> 32);
os_mutex_enter(os_file_count_mutex);
os_n_pending_reads++;
MONITOR_INC(MONITOR_OS_PENDING_READS);
os_mutex_exit(os_file_count_mutex);
#ifndef UNIV_HOTBACKUP
/* Protect the seek / read operation with a mutex */
i = ((ulint) file) % OS_FILE_N_SEEK_MUTEXES;
os_mutex_enter(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
ret2 = SetFilePointer(
file, low, reinterpret_cast<PLONG>(&high), FILE_BEGIN);
if (ret2 == 0xFFFFFFFF && GetLastError() != NO_ERROR) {
#ifndef UNIV_HOTBACKUP
os_mutex_exit(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
os_mutex_enter(os_file_count_mutex);
os_n_pending_reads--;
MONITOR_DEC(MONITOR_OS_PENDING_READS);
os_mutex_exit(os_file_count_mutex);
goto error_handling;
}
ret = ReadFile(file, buf, (DWORD) n, &len, NULL);
#ifndef UNIV_HOTBACKUP
os_mutex_exit(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
os_mutex_enter(os_file_count_mutex);
os_n_pending_reads--;
MONITOR_DEC(MONITOR_OS_PENDING_READS);
os_mutex_exit(os_file_count_mutex);
if (ret && len == n) {
return(TRUE);
}
#else /* __WIN__ */
ibool retry;
ssize_t ret;
os_bytes_read_since_printout += n;
try_again:
ret = os_file_pread(file, buf, n, offset);
if ((ulint) ret == n) {
return(TRUE);
} else if (ret == -1) {
ib_logf(IB_LOG_LEVEL_ERROR,
"Error in system call pread(). The operating"
" system error number is %lu.",(ulint) errno);
} else {
/* Partial read occured */
ib_logf(IB_LOG_LEVEL_ERROR,
"Tried to read " ULINTPF " bytes at offset "
UINT64PF ". Was only able to read %ld.",
n, offset, (lint) ret);
}
#endif /* __WIN__ */
#ifdef __WIN__
error_handling:
#endif
retry = os_file_handle_error_no_exit(NULL, "read", FALSE, __FILE__, __LINE__);
if (retry) {
goto try_again;
}
return(FALSE);
}
/*******************************************************************//**
Rewind file to its start, read at most size - 1 bytes from it to str, and
NUL-terminate str. All errors are silently ignored. This function is
mostly meant to be used with temporary files. */
UNIV_INTERN
void
os_file_read_string(
/*================*/
FILE* file, /*!< in: file to read from */
char* str, /*!< in: buffer where to read */
ulint size) /*!< in: size of buffer */
{
size_t flen;
if (size == 0) {
return;
}
rewind(file);
flen = fread(str, 1, size - 1, file);
str[flen] = '\0';
}
/*******************************************************************//**
NOTE! Use the corresponding macro os_file_write(), not directly
this function!
Requests a synchronous write operation.
@return TRUE if request was successful, FALSE if fail */
UNIV_INTERN
ibool
os_file_write_func(
/*===============*/
const char* name, /*!< in: name of the file or path as a
null-terminated string */
os_file_t file, /*!< in: handle to a file */
const void* buf, /*!< in: buffer from which to write */
os_offset_t offset, /*!< in: file offset where to write */
ulint n) /*!< in: number of bytes to write */
{
ut_ad(!srv_read_only_mode);
#ifdef __WIN__
BOOL ret;
DWORD len;
DWORD ret2;
DWORD low;
DWORD high;
ulint n_retries = 0;
ulint err;
DWORD saved_error = 0;
#ifndef UNIV_HOTBACKUP
ulint i;
#endif /* !UNIV_HOTBACKUP */
/* On 64-bit Windows, ulint is 64 bits. But offset and n should be
no more than 32 bits. */
ut_a((n & 0xFFFFFFFFUL) == n);
os_n_file_writes++;
ut_ad(buf);
ut_ad(n > 0);
retry:
low = (DWORD) offset & 0xFFFFFFFF;
high = (DWORD) (offset >> 32);
os_mutex_enter(os_file_count_mutex);
os_n_pending_writes++;
MONITOR_INC(MONITOR_OS_PENDING_WRITES);
os_mutex_exit(os_file_count_mutex);
#ifndef UNIV_HOTBACKUP
/* Protect the seek / write operation with a mutex */
i = ((ulint) file) % OS_FILE_N_SEEK_MUTEXES;
os_mutex_enter(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
ret2 = SetFilePointer(
file, low, reinterpret_cast<PLONG>(&high), FILE_BEGIN);
if (ret2 == 0xFFFFFFFF && GetLastError() != NO_ERROR) {
#ifndef UNIV_HOTBACKUP
os_mutex_exit(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
os_mutex_enter(os_file_count_mutex);
os_n_pending_writes--;
MONITOR_DEC(MONITOR_OS_PENDING_WRITES);
os_mutex_exit(os_file_count_mutex);
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Error: File pointer positioning to"
" file %s failed at\n"
"InnoDB: offset %llu. Operating system"
" error number %lu.\n"
"InnoDB: Some operating system error numbers"
" are described at\n"
"InnoDB: "
REFMAN "operating-system-error-codes.html\n",
name, offset, (ulong) GetLastError());
return(FALSE);
}
ret = WriteFile(file, buf, (DWORD) n, &len, NULL);
#ifndef UNIV_HOTBACKUP
os_mutex_exit(os_file_seek_mutexes[i]);
#endif /* !UNIV_HOTBACKUP */
os_mutex_enter(os_file_count_mutex);
os_n_pending_writes--;
MONITOR_DEC(MONITOR_OS_PENDING_WRITES);
os_mutex_exit(os_file_count_mutex);
if (ret && len == n) {
return(TRUE);
}
/* If some background file system backup tool is running, then, at
least in Windows 2000, we may get here a specific error. Let us
retry the operation 100 times, with 1 second waits. */
if (GetLastError() == ERROR_LOCK_VIOLATION && n_retries < 100) {
os_thread_sleep(1000000);
n_retries++;
goto retry;
}
if (!os_has_said_disk_full) {
char *winmsg = NULL;
saved_error = GetLastError();
err = (ulint) saved_error;
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Error: Write to file %s failed"
" at offset %llu.\n"
"InnoDB: %lu bytes should have been written,"
" only %lu were written.\n"
"InnoDB: Operating system error number %lu.\n"
"InnoDB: Check that your OS and file system"
" support files of this size.\n"
"InnoDB: Check also that the disk is not full"
" or a disk quota exceeded.\n",
name, offset,
(ulong) n, (ulong) len, (ulong) err);
/* Ask Windows to prepare a standard message for a
GetLastError() */
FormatMessage(FORMAT_MESSAGE_ALLOCATE_BUFFER |
FORMAT_MESSAGE_FROM_SYSTEM |
FORMAT_MESSAGE_IGNORE_INSERTS,
NULL, saved_error,
MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT),
(LPSTR)&winmsg, 0, NULL);
if (winmsg) {
fprintf(stderr,
"InnoDB: FormatMessage: Error number %lu means '%s'.\n",
(ulong) saved_error, winmsg);
LocalFree(winmsg);
}
if (strerror((int) err) != NULL) {
fprintf(stderr,
"InnoDB: Error number %lu means '%s'.\n",
(ulong) err, strerror((int) err));
}
fprintf(stderr,
"InnoDB: Some operating system error numbers"
" are described at\n"
"InnoDB: "
REFMAN "operating-system-error-codes.html\n");
os_has_said_disk_full = TRUE;
}
return(FALSE);
#else
ssize_t ret;
WAIT_ALLOW_WRITES();
ret = os_file_pwrite(file, buf, n, offset);
if ((ulint) ret == n) {
return(TRUE);
}
if (!os_has_said_disk_full) {
ut_print_timestamp(stderr);
if(ret == -1) {
ib_logf(IB_LOG_LEVEL_ERROR,
"Failure of system call pwrite(). Operating"
" system error number is %lu.",
(ulint) errno);
} else {
fprintf(stderr,
" InnoDB: Error: Write to file %s failed"
" at offset " UINT64PF ".\n"
"InnoDB: %lu bytes should have been written,"
" only %ld were written.\n"
"InnoDB: Operating system error number %lu.\n"
"InnoDB: Check that your OS and file system"
" support files of this size.\n"
"InnoDB: Check also that the disk is not full"
" or a disk quota exceeded.\n",
name, offset, n, (lint) ret,
(ulint) errno);
}
if (strerror(errno) != NULL) {
fprintf(stderr,
"InnoDB: Error number %d means '%s'.\n",
errno, strerror(errno));
}
fprintf(stderr,
"InnoDB: Some operating system error numbers"
" are described at\n"
"InnoDB: "
REFMAN "operating-system-error-codes.html\n");
os_has_said_disk_full = TRUE;
}
return(FALSE);
#endif
}
/*******************************************************************//**
Check the existence and type of the given file.
@return TRUE if call succeeded */
UNIV_INTERN
ibool
os_file_status(
/*===========*/
const char* path, /*!< in: pathname of the file */
ibool* exists, /*!< out: TRUE if file exists */
os_file_type_t* type) /*!< out: type of the file (if it exists) */
{
#ifdef __WIN__
int ret;
struct _stat64 statinfo;
ret = _stat64(path, &statinfo);
if (ret && (errno == ENOENT || errno == ENOTDIR || errno == ENAMETOOLONG)) {
/* file does not exist */
*exists = FALSE;
return(TRUE);
} else if (ret) {
/* file exists, but stat call failed */
os_file_handle_error_no_exit(path, "stat", FALSE, __FILE__, __LINE__);
return(FALSE);
}
if (_S_IFDIR & statinfo.st_mode) {
*type = OS_FILE_TYPE_DIR;
} else if (_S_IFREG & statinfo.st_mode) {
*type = OS_FILE_TYPE_FILE;
} else {
*type = OS_FILE_TYPE_UNKNOWN;
}
*exists = TRUE;
return(TRUE);
#else
int ret;
struct stat statinfo;
ret = stat(path, &statinfo);
if (ret && (errno == ENOENT || errno == ENOTDIR || errno == ENAMETOOLONG)) {
/* file does not exist */
*exists = FALSE;
return(TRUE);
} else if (ret) {
/* file exists, but stat call failed */
os_file_handle_error_no_exit(path, "stat", FALSE, __FILE__, __LINE__);
return(FALSE);
}
if (S_ISDIR(statinfo.st_mode)) {
*type = OS_FILE_TYPE_DIR;
} else if (S_ISLNK(statinfo.st_mode)) {
*type = OS_FILE_TYPE_LINK;
} else if (S_ISREG(statinfo.st_mode)) {
*type = OS_FILE_TYPE_FILE;
} else {
*type = OS_FILE_TYPE_UNKNOWN;
}
*exists = TRUE;
return(TRUE);
#endif
}
/*******************************************************************//**
This function returns information about the specified file
@return DB_SUCCESS if all OK */
UNIV_INTERN
dberr_t
os_file_get_status(
/*===============*/
const char* path, /*!< in: pathname of the file */
os_file_stat_t* stat_info, /*!< information of a file in a
directory */
bool check_rw_perm) /*!< in: for testing whether the
file can be opened in RW mode */
{
int ret;
#ifdef __WIN__
struct _stat64 statinfo;
ret = _stat64(path, &statinfo);
if (ret && (errno == ENOENT || errno == ENOTDIR)) {
/* file does not exist */
return(DB_NOT_FOUND);
} else if (ret) {
/* file exists, but stat call failed */
os_file_handle_error_no_exit(path, "stat", FALSE, __FILE__, __LINE__);
return(DB_FAIL);
} else if (_S_IFDIR & statinfo.st_mode) {
stat_info->type = OS_FILE_TYPE_DIR;
} else if (_S_IFREG & statinfo.st_mode) {
DWORD access = GENERIC_READ;
if (!srv_read_only_mode) {
access |= GENERIC_WRITE;
}
stat_info->type = OS_FILE_TYPE_FILE;
/* Check if we can open it in read-only mode. */
if (check_rw_perm) {
HANDLE fh;
fh = CreateFile(
(LPCTSTR) path, // File to open
access,
0, // No sharing
NULL, // Default security
OPEN_EXISTING, // Existing file only
FILE_ATTRIBUTE_NORMAL, // Normal file
NULL); // No attr. template
if (fh == INVALID_HANDLE_VALUE) {
stat_info->rw_perm = false;
} else {
stat_info->rw_perm = true;
CloseHandle(fh);
}
}
} else {
stat_info->type = OS_FILE_TYPE_UNKNOWN;
}
#else
struct stat statinfo;
ret = stat(path, &statinfo);
if (ret && (errno == ENOENT || errno == ENOTDIR)) {
/* file does not exist */
return(DB_NOT_FOUND);
} else if (ret) {
/* file exists, but stat call failed */
os_file_handle_error_no_exit(path, "stat", FALSE, __FILE__, __LINE__);
return(DB_FAIL);
}
switch (statinfo.st_mode & S_IFMT) {
case S_IFDIR:
stat_info->type = OS_FILE_TYPE_DIR;
break;
case S_IFLNK:
stat_info->type = OS_FILE_TYPE_LINK;
break;
case S_IFBLK:
stat_info->type = OS_FILE_TYPE_BLOCK;
break;
case S_IFREG:
stat_info->type = OS_FILE_TYPE_FILE;
break;
default:
stat_info->type = OS_FILE_TYPE_UNKNOWN;
}
if (check_rw_perm && (stat_info->type == OS_FILE_TYPE_FILE
|| stat_info->type == OS_FILE_TYPE_BLOCK)) {
int fh;
int access;
access = !srv_read_only_mode ? O_RDWR : O_RDONLY;
fh = ::open(path, access, os_innodb_umask);
if (fh == -1) {
stat_info->rw_perm = false;
} else {
stat_info->rw_perm = true;
close(fh);
}
}
#endif /* _WIN_ */
stat_info->ctime = statinfo.st_ctime;
stat_info->atime = statinfo.st_atime;
stat_info->mtime = statinfo.st_mtime;
stat_info->size = statinfo.st_size;
return(DB_SUCCESS);
}
/* path name separator character */
#ifdef __WIN__
# define OS_FILE_PATH_SEPARATOR '\\'
#else
# define OS_FILE_PATH_SEPARATOR '/'
#endif
/****************************************************************//**
This function returns a new path name after replacing the basename
in an old path with a new basename. The old_path is a full path
name including the extension. The tablename is in the normal
form "databasename/tablename". The new base name is found after
the forward slash. Both input strings are null terminated.
This function allocates memory to be returned. It is the callers
responsibility to free the return value after it is no longer needed.
@return own: new full pathname */
UNIV_INTERN
char*
os_file_make_new_pathname(
/*======================*/
const char* old_path, /*!< in: pathname */
const char* tablename) /*!< in: contains new base name */
{
ulint dir_len;
char* last_slash;
char* base_name;
char* new_path;
ulint new_path_len;
/* Split the tablename into its database and table name components.
They are separated by a '/'. */
last_slash = strrchr((char*) tablename, '/');
base_name = last_slash ? last_slash + 1 : (char*) tablename;
/* Find the offset of the last slash. We will strip off the
old basename.ibd which starts after that slash. */
last_slash = strrchr((char*) old_path, OS_FILE_PATH_SEPARATOR);
dir_len = last_slash ? last_slash - old_path : strlen(old_path);
/* allocate a new path and move the old directory path to it. */
new_path_len = dir_len + strlen(base_name) + sizeof "/.ibd";
new_path = static_cast<char*>(mem_alloc(new_path_len));
memcpy(new_path, old_path, dir_len);
ut_snprintf(new_path + dir_len,
new_path_len - dir_len,
"%c%s.ibd",
OS_FILE_PATH_SEPARATOR,
base_name);
return(new_path);
}
/****************************************************************//**
This function returns a remote path name by combining a data directory
path provided in a DATA DIRECTORY clause with the tablename which is
in the form 'database/tablename'. It strips the file basename (which
is the tablename) found after the last directory in the path provided.
The full filepath created will include the database name as a directory
under the path provided. The filename is the tablename with the '.ibd'
extension. All input and output strings are null-terminated.
This function allocates memory to be returned. It is the callers
responsibility to free the return value after it is no longer needed.
@return own: A full pathname; data_dir_path/databasename/tablename.ibd */
UNIV_INTERN
char*
os_file_make_remote_pathname(
/*=========================*/
const char* data_dir_path, /*!< in: pathname */
const char* tablename, /*!< in: tablename */
const char* extention) /*!< in: file extention; ibd,cfg */
{
ulint data_dir_len;
char* last_slash;
char* new_path;
ulint new_path_len;
ut_ad(extention && strlen(extention) == 3);
/* Find the offset of the last slash. We will strip off the
old basename or tablename which starts after that slash. */
last_slash = strrchr((char*) data_dir_path, OS_FILE_PATH_SEPARATOR);
data_dir_len = last_slash ? last_slash - data_dir_path : strlen(data_dir_path);
/* allocate a new path and move the old directory path to it. */
new_path_len = data_dir_len + strlen(tablename)
+ sizeof "/." + strlen(extention);
new_path = static_cast<char*>(mem_alloc(new_path_len));
memcpy(new_path, data_dir_path, data_dir_len);
ut_snprintf(new_path + data_dir_len,
new_path_len - data_dir_len,
"%c%s.%s",
OS_FILE_PATH_SEPARATOR,
tablename,
extention);
srv_normalize_path_for_win(new_path);
return(new_path);
}
/****************************************************************//**
This function reduces a null-terminated full remote path name into
the path that is sent by MySQL for DATA DIRECTORY clause. It replaces
the 'databasename/tablename.ibd' found at the end of the path with just
'tablename'.
Since the result is always smaller than the path sent in, no new memory
is allocated. The caller should allocate memory for the path sent in.
This function manipulates that path in place.
If the path format is not as expected, just return. The result is used
to inform a SHOW CREATE TABLE command. */
UNIV_INTERN
void
os_file_make_data_dir_path(
/*========================*/
char* data_dir_path) /*!< in/out: full path/data_dir_path */
{
char* ptr;
char* tablename;
ulint tablename_len;
/* Replace the period before the extension with a null byte. */
ptr = strrchr((char*) data_dir_path, '.');
if (!ptr) {
return;
}
ptr[0] = '\0';
/* The tablename starts after the last slash. */
ptr = strrchr((char*) data_dir_path, OS_FILE_PATH_SEPARATOR);
if (!ptr) {
return;
}
ptr[0] = '\0';
tablename = ptr + 1;
/* The databasename starts after the next to last slash. */
ptr = strrchr((char*) data_dir_path, OS_FILE_PATH_SEPARATOR);
if (!ptr) {
return;
}
tablename_len = ut_strlen(tablename);
ut_memmove(++ptr, tablename, tablename_len);
ptr[tablename_len] = '\0';
}
/****************************************************************//**
The function os_file_dirname returns a directory component of a
null-terminated pathname string. In the usual case, dirname returns
the string up to, but not including, the final '/', and basename
is the component following the final '/'. Trailing '/' characters
are not counted as part of the pathname.
If path does not contain a slash, dirname returns the string ".".
Concatenating the string returned by dirname, a "/", and the basename
yields a complete pathname.
The return value is a copy of the directory component of the pathname.
The copy is allocated from heap. It is the caller responsibility
to free it after it is no longer needed.
The following list of examples (taken from SUSv2) shows the strings
returned by dirname and basename for different paths:
path dirname basename
"/usr/lib" "/usr" "lib"
"/usr/" "/" "usr"
"usr" "." "usr"
"/" "/" "/"
"." "." "."
".." "." ".."
@return own: directory component of the pathname */
UNIV_INTERN
char*
os_file_dirname(
/*============*/
const char* path) /*!< in: pathname */
{
/* Find the offset of the last slash */
const char* last_slash = strrchr(path, OS_FILE_PATH_SEPARATOR);
if (!last_slash) {
/* No slash in the path, return "." */
return(mem_strdup("."));
}
/* Ok, there is a slash */
if (last_slash == path) {
/* last slash is the first char of the path */
return(mem_strdup("/"));
}
/* Non-trivial directory component */
return(mem_strdupl(path, last_slash - path));
}
/****************************************************************//**
Creates all missing subdirectories along the given path.
@return TRUE if call succeeded FALSE otherwise */
UNIV_INTERN
ibool
os_file_create_subdirs_if_needed(
/*=============================*/
const char* path) /*!< in: path name */
{
if (srv_read_only_mode) {
ib_logf(IB_LOG_LEVEL_ERROR,
"read only mode set. Can't create subdirectories '%s'",
path);
return(FALSE);
}
char* subdir = os_file_dirname(path);
if (strlen(subdir) == 1
&& (*subdir == OS_FILE_PATH_SEPARATOR || *subdir == '.')) {
/* subdir is root or cwd, nothing to do */
mem_free(subdir);
return(TRUE);
}
/* Test if subdir exists */
os_file_type_t type;
ibool subdir_exists;
ibool success = os_file_status(subdir, &subdir_exists, &type);
if (success && !subdir_exists) {
/* subdir does not exist, create it */
success = os_file_create_subdirs_if_needed(subdir);
if (!success) {
mem_free(subdir);
return(FALSE);
}
success = os_file_create_directory(subdir, FALSE);
}
mem_free(subdir);
return(success);
}
#ifndef UNIV_HOTBACKUP
/****************************************************************//**
Returns a pointer to the nth slot in the aio array.
@return pointer to slot */
static
os_aio_slot_t*
os_aio_array_get_nth_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]);
}
#if defined(LINUX_NATIVE_AIO)
/******************************************************************//**
Creates an io_context for native linux AIO.
@return TRUE on success. */
static
ibool
os_aio_linux_create_io_ctx(
/*=======================*/
ulint max_events, /*!< in: number of events. */
io_context_t* io_ctx) /*!< out: io_ctx to initialize. */
{
int ret;
ulint retries = 0;
retry:
memset(io_ctx, 0x0, sizeof(*io_ctx));
/* Initialize the io_ctx. Tell it how many pending
IO requests this context will handle. */
ret = io_setup(max_events, io_ctx);
if (ret == 0) {
#if defined(UNIV_AIO_DEBUG)
fprintf(stderr,
"InnoDB: Linux native AIO:"
" initialized io_ctx for segment\n");
#endif
/* Success. Return now. */
return(TRUE);
}
/* If we hit EAGAIN we'll make a few attempts before failing. */
switch (ret) {
case -EAGAIN:
if (retries == 0) {
/* First time around. */
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Warning: io_setup() failed"
" with EAGAIN. Will make %d attempts"
" before giving up.\n",
OS_AIO_IO_SETUP_RETRY_ATTEMPTS);
}
if (retries < OS_AIO_IO_SETUP_RETRY_ATTEMPTS) {
++retries;
fprintf(stderr,
"InnoDB: Warning: io_setup() attempt"
" %lu failed.\n",
retries);
os_thread_sleep(OS_AIO_IO_SETUP_RETRY_SLEEP);
goto retry;
}
/* Have tried enough. Better call it a day. */
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Error: io_setup() failed"
" with EAGAIN after %d attempts.\n",
OS_AIO_IO_SETUP_RETRY_ATTEMPTS);
break;
case -ENOSYS:
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Error: Linux Native AIO interface"
" is not supported on this platform. Please"
" check your OS documentation and install"
" appropriate binary of InnoDB.\n");
break;
default:
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Error: Linux Native AIO setup"
" returned following error[%d]\n", -ret);
break;
}
fprintf(stderr,
"InnoDB: You can disable Linux Native AIO by"
" setting innodb_use_native_aio = 0 in my.cnf\n");
return(FALSE);
}
/******************************************************************//**
Checks if the system supports native linux aio. On some kernel
versions where native aio is supported it won't work on tmpfs. In such
cases we can't use native aio as it is not possible to mix simulated
and native aio.
@return: TRUE if supported, FALSE otherwise. */
static
ibool
os_aio_native_aio_supported(void)
/*=============================*/
{
int fd;
io_context_t io_ctx;
char name[1000];
if (!os_aio_linux_create_io_ctx(1, &io_ctx)) {
/* The platform does not support native aio. */
return(FALSE);
} else if (!srv_read_only_mode) {
/* Now check if tmpdir supports native aio ops. */
fd = innobase_mysql_tmpfile();
if (fd < 0) {
ib_logf(IB_LOG_LEVEL_WARN,
"Unable to create temp file to check "
"native AIO support.");
return(FALSE);
}
} else {
srv_normalize_path_for_win(srv_log_group_home_dir);
ulint dirnamelen = strlen(srv_log_group_home_dir);
ut_a(dirnamelen < (sizeof name) - 10 - sizeof "ib_logfile");
memcpy(name, srv_log_group_home_dir, dirnamelen);
/* Add a path separator if needed. */
if (dirnamelen && name[dirnamelen - 1] != SRV_PATH_SEPARATOR) {
name[dirnamelen++] = SRV_PATH_SEPARATOR;
}
strcpy(name + dirnamelen, "ib_logfile0");
fd = ::open(name, O_RDONLY);
if (fd == -1) {
ib_logf(IB_LOG_LEVEL_WARN,
"Unable to open \"%s\" to check "
"native AIO read support.", name);
return(FALSE);
}
}
struct io_event io_event;
memset(&io_event, 0x0, sizeof(io_event));
byte* buf = static_cast<byte*>(ut_malloc(UNIV_PAGE_SIZE * 2));
byte* ptr = static_cast<byte*>(ut_align(buf, UNIV_PAGE_SIZE));
struct iocb iocb;
/* Suppress valgrind warning. */
memset(buf, 0x00, UNIV_PAGE_SIZE * 2);
memset(&iocb, 0x0, sizeof(iocb));
struct iocb* p_iocb = &iocb;
if (!srv_read_only_mode) {
io_prep_pwrite(p_iocb, fd, ptr, UNIV_PAGE_SIZE, 0);
} else {
ut_a(UNIV_PAGE_SIZE >= 512);
io_prep_pread(p_iocb, fd, ptr, 512, 0);
}
int err = io_submit(io_ctx, 1, &p_iocb);
if (err >= 1) {
/* Now collect the submitted IO request. */
err = io_getevents(io_ctx, 1, 1, &io_event, NULL);
}
ut_free(buf);
close(fd);
switch (err) {
case 1:
return(TRUE);
case -EINVAL:
case -ENOSYS:
ib_logf(IB_LOG_LEVEL_ERROR,
"Linux Native AIO not supported. You can either "
"move %s to a file system that supports native "
"AIO or you can set innodb_use_native_aio to "
"FALSE to avoid this message.",
srv_read_only_mode ? name : "tmpdir");
/* fall through. */
default:
ib_logf(IB_LOG_LEVEL_ERROR,
"Linux Native AIO check on %s returned error[%d]",
srv_read_only_mode ? name : "tmpdir", -err);
}
return(FALSE);
}
#endif /* LINUX_NATIVE_AIO */
/******************************************************************//**
Creates an aio wait array. Note that we return NULL in case of failure.
We don't care about freeing memory here because we assume that a
failure will result in server refusing to start up.
@return own: aio array, NULL on failure */
static
os_aio_array_t*
os_aio_array_create(
/*================*/
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;
#ifdef WIN_ASYNC_IO
OVERLAPPED* over;
#elif defined(LINUX_NATIVE_AIO)
struct io_event* io_event = NULL;
#endif /* WIN_ASYNC_IO */
ut_a(n > 0);
ut_a(n_segments > 0);
array = static_cast<os_aio_array_t*>(ut_malloc(sizeof(*array)));
memset(array, 0x0, sizeof(*array));
array->mutex = os_mutex_create();
array->not_full = os_event_create();
array->is_empty = os_event_create();
os_event_set(array->is_empty);
array->n_slots = n;
array->n_segments = n_segments;
array->slots = static_cast<os_aio_slot_t*>(
ut_malloc(n * sizeof(*array->slots)));
memset(array->slots, 0x0, n * sizeof(*array->slots));
#ifdef __WIN__
array->handles = static_cast<HANDLE*>(ut_malloc(n * sizeof(HANDLE)));
#endif /* __WIN__ */
#if defined(LINUX_NATIVE_AIO)
array->aio_ctx = NULL;
array->aio_events = NULL;
/* If we are not using native aio interface then skip this
part of initialization. */
if (!srv_use_native_aio) {
goto skip_native_aio;
}
/* Initialize the io_context array. One io_context
per segment in the array. */
array->aio_ctx = static_cast<io_context**>(
ut_malloc(n_segments * sizeof(*array->aio_ctx)));
for (ulint i = 0; i < n_segments; ++i) {
if (!os_aio_linux_create_io_ctx(n/n_segments,
&array->aio_ctx[i])) {
/* If something bad happened during aio setup
we disable linux native aio.
The disadvantage will be a small memory leak
at shutdown but that's ok compared to a crash
or a not working server.
This frequently happens when running the test suite
with many threads on a system with low fs.aio-max-nr!
*/
fprintf(stderr,
" InnoDB: Warning: Linux Native AIO disabled "
"because os_aio_linux_create_io_ctx() "
"failed. To get rid of this warning you can "
"try increasing system "
"fs.aio-max-nr to 1048576 or larger or "
"setting innodb_use_native_aio = 0 in my.cnf\n");
srv_use_native_aio = FALSE;
goto skip_native_aio;
}
}
/* Initialize the event array. One event per slot. */
io_event = static_cast<struct io_event*>(
ut_malloc(n * sizeof(*io_event)));
memset(io_event, 0x0, sizeof(*io_event) * n);
array->aio_events = io_event;
skip_native_aio:
#endif /* LINUX_NATIVE_AIO */
for (ulint i = 0; i < n; i++) {
os_aio_slot_t* slot;
slot = os_aio_array_get_nth_slot(array, i);
slot->pos = i;
slot->reserved = FALSE;
#ifdef WIN_ASYNC_IO
slot->handle = CreateEvent(NULL,TRUE, FALSE, NULL);
over = &slot->control;
over->hEvent = slot->handle;
array->handles[i] = over->hEvent;
#elif defined(LINUX_NATIVE_AIO)
memset(&slot->control, 0x0, sizeof(slot->control));
slot->n_bytes = 0;
slot->ret = 0;
#endif /* WIN_ASYNC_IO */
}
return(array);
}
/************************************************************************//**
Frees an aio wait array. */
static
void
os_aio_array_free(
/*==============*/
os_aio_array_t*& array) /*!< in, own: array to free */
{
ulint i;
#ifdef WIN_ASYNC_IO
for (i = 0; i < array->n_slots; i++) {
os_aio_slot_t* slot = os_aio_array_get_nth_slot(array, i);
CloseHandle(slot->handle);
}
#endif /* WIN_ASYNC_IO */
#ifdef __WIN__
ut_free(array->handles);
#endif /* __WIN__ */
os_mutex_free(array->mutex);
os_event_free(array->not_full);
os_event_free(array->is_empty);
#if defined(LINUX_NATIVE_AIO)
if (srv_use_native_aio) {
ut_free(array->aio_events);
ut_free(array->aio_ctx);
}
#endif /* LINUX_NATIVE_AIO */
for (i = 0; i < array->n_slots; i++) {
os_aio_slot_t* slot = os_aio_array_get_nth_slot(array, i);
if (slot->page_compression_page) {
ut_free(slot->page_compression_page);
slot->page_compression_page = NULL;
}
if (slot->lzo_mem) {
ut_free(slot->lzo_mem);
slot->lzo_mem = NULL;
}
if (slot->page_encryption_page) {
ut_free(slot->page_encryption_page);
slot->page_encryption_page = NULL;
}
if (slot->tmp_encryption_buf) {
ut_free(slot->tmp_encryption_buf);
slot->tmp_encryption_buf = NULL;
}
}
ut_free(array->slots);
ut_free(array);
array = 0;
}
/***********************************************************************
Initializes the asynchronous io system. Creates one array each for ibuf
and log i/o. Also creates one array each for read and write where each
array is divided logically into n_read_segs and n_write_segs
respectively. The caller must create an i/o handler thread for each
segment in these arrays. This function also creates the sync array.
No i/o handler thread needs to be created for that */
UNIV_INTERN
ibool
os_aio_init(
/*========*/
ulint n_per_seg, /*<! in: maximum number of pending aio
operations allowed per segment */
ulint n_read_segs, /*<! in: number of reader threads */
ulint n_write_segs, /*<! in: number of writer threads */
ulint n_slots_sync) /*<! in: number of slots in the sync aio
array */
{
os_io_init_simple();
#if defined(LINUX_NATIVE_AIO)
/* Check if native aio is supported on this system and tmpfs */
if (srv_use_native_aio && !os_aio_native_aio_supported()) {
ib_logf(IB_LOG_LEVEL_WARN, "Linux Native AIO disabled.");
srv_use_native_aio = FALSE;
}
#endif /* LINUX_NATIVE_AIO */
srv_reset_io_thread_op_info();
os_aio_read_array = os_aio_array_create(
n_read_segs * n_per_seg, n_read_segs);
if (os_aio_read_array == NULL) {
return(FALSE);
}
ulint start = (srv_read_only_mode) ? 0 : 2;
ulint n_segs = n_read_segs + start;
/* 0 is the ibuf segment and 1 is the insert buffer segment. */
for (ulint i = start; i < n_segs; ++i) {
ut_a(i < SRV_MAX_N_IO_THREADS);
srv_io_thread_function[i] = "read thread";
}
ulint n_segments = n_read_segs;
if (!srv_read_only_mode) {
os_aio_log_array = os_aio_array_create(n_per_seg, 1);
if (os_aio_log_array == NULL) {
return(FALSE);
}
++n_segments;
srv_io_thread_function[1] = "log thread";
os_aio_ibuf_array = os_aio_array_create(n_per_seg, 1);
if (os_aio_ibuf_array == NULL) {
return(FALSE);
}
++n_segments;
srv_io_thread_function[0] = "insert buffer thread";
os_aio_write_array = os_aio_array_create(
n_write_segs * n_per_seg, n_write_segs);
if (os_aio_write_array == NULL) {
return(FALSE);
}
n_segments += n_write_segs;
for (ulint i = start + n_read_segs; i < n_segments; ++i) {
ut_a(i < SRV_MAX_N_IO_THREADS);
srv_io_thread_function[i] = "write thread";
}
ut_ad(n_segments >= 4);
} else {
ut_ad(n_segments > 0);
}
os_aio_sync_array = os_aio_array_create(n_slots_sync, 1);
if (os_aio_sync_array == NULL) {
return(FALSE);
}
os_aio_n_segments = n_segments;
os_aio_validate();
os_aio_segment_wait_events = static_cast<os_event_t*>(
ut_malloc(n_segments * sizeof *os_aio_segment_wait_events));
for (ulint i = 0; i < n_segments; ++i) {
os_aio_segment_wait_events[i] = os_event_create();
}
os_last_printout = ut_time();
return(TRUE);
}
/***********************************************************************
Frees the asynchronous io system. */
UNIV_INTERN
void
os_aio_free(void)
/*=============*/
{
if (os_aio_ibuf_array != 0) {
os_aio_array_free(os_aio_ibuf_array);
}
if (os_aio_log_array != 0) {
os_aio_array_free(os_aio_log_array);
}
if (os_aio_write_array != 0) {
os_aio_array_free(os_aio_write_array);
}
if (os_aio_sync_array != 0) {
os_aio_array_free(os_aio_sync_array);
}
os_aio_array_free(os_aio_read_array);
for (ulint i = 0; i < os_aio_n_segments; i++) {
os_event_free(os_aio_segment_wait_events[i]);
}
ut_free(os_aio_segment_wait_events);
os_aio_segment_wait_events = 0;
os_aio_n_segments = 0;
}
#ifdef WIN_ASYNC_IO
/************************************************************************//**
Wakes up all async i/o threads in the array in Windows async i/o at
shutdown. */
static
void
os_aio_array_wake_win_aio_at_shutdown(
/*==================================*/
os_aio_array_t* array) /*!< in: aio array */
{
ulint i;
for (i = 0; i < array->n_slots; i++) {
SetEvent((array->slots + i)->handle);
}
}
#endif
/************************************************************************//**
Wakes up all async i/o threads so that they know to exit themselves in
shutdown. */
UNIV_INTERN
void
os_aio_wake_all_threads_at_shutdown(void)
/*=====================================*/
{
#ifdef WIN_ASYNC_IO
/* This code wakes up all ai/o threads in Windows native aio */
os_aio_array_wake_win_aio_at_shutdown(os_aio_read_array);
if (os_aio_write_array != 0) {
os_aio_array_wake_win_aio_at_shutdown(os_aio_write_array);
}
if (os_aio_ibuf_array != 0) {
os_aio_array_wake_win_aio_at_shutdown(os_aio_ibuf_array);
}
if (os_aio_log_array != 0) {
os_aio_array_wake_win_aio_at_shutdown(os_aio_log_array);
}
#elif defined(LINUX_NATIVE_AIO)
/* When using native AIO interface the io helper threads
wait on io_getevents with a timeout value of 500ms. At
each wake up these threads check the server status.
No need to do anything to wake them up. */
if (srv_use_native_aio) {
return;
}
/* Fall through to simulated AIO handler wakeup if we are
not using native AIO. */
#endif /* !WIN_ASYNC_AIO */
/* This loop wakes up all simulated ai/o threads */
for (ulint i = 0; i < os_aio_n_segments; i++) {
os_event_set(os_aio_segment_wait_events[i]);
}
}
/************************************************************************//**
Waits until there are no pending writes in os_aio_write_array. There can
be other, synchronous, pending writes. */
UNIV_INTERN
void
os_aio_wait_until_no_pending_writes(void)
/*=====================================*/
{
ut_ad(!srv_read_only_mode);
os_event_wait(os_aio_write_array->is_empty);
}
/**********************************************************************//**
Calculates segment number for a slot.
@return segment number (which is the number used by, for example,
i/o-handler threads) */
static
ulint
os_aio_get_segment_no_from_slot(
/*============================*/
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) {
ut_ad(!srv_read_only_mode);
segment = IO_IBUF_SEGMENT;
} else if (array == os_aio_log_array) {
ut_ad(!srv_read_only_mode);
segment = IO_LOG_SEGMENT;
} else if (array == os_aio_read_array) {
seg_len = os_aio_read_array->n_slots
/ os_aio_read_array->n_segments;
segment = (srv_read_only_mode ? 0 : 2) + slot->pos / seg_len;
} else {
ut_ad(!srv_read_only_mode);
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.
@return local segment number within the aio array */
static
ulint
os_aio_get_array_and_local_segment(
/*===============================*/
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 (srv_read_only_mode) {
*array = os_aio_read_array;
return(global_segment);
} else if (global_segment == IO_IBUF_SEGMENT) {
*array = os_aio_ibuf_array;
segment = 0;
} else if (global_segment == IO_LOG_SEGMENT) {
*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);
}
/*******************************************************************//**
Requests for a slot in the aio array. If no slot is available, waits until
not_full-event becomes signaled.
@return pointer to slot */
static
os_aio_slot_t*
os_aio_array_reserve_slot(
/*======================*/
ulint type, /*!< in: OS_FILE_READ or OS_FILE_WRITE */
os_aio_array_t* array, /*!< in: aio array */
fil_node_t* 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 */
const 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 */
os_offset_t offset, /*!< in: file offset */
ulint len, /*!< in: length of the block to read or write */
ulint* write_size,/*!< in/out: Actual write size initialized
after fist successfull trim
operation for this page and if
initialized we do not trim again if
actual page size does not decrease. */
ibool page_compression, /*!< in: is page compression used
on this file space */
ulint page_compression_level, /*!< page compression
level to be used */
ibool page_encryption, /*!< in: is page encryption used
on this file space */
ulint page_encryption_key, /*!< in: page encryption key
to be used */
lsn_t lsn, /*!< in: lsn of the newest modification */
bool encrypt_later) /*!< in: should we encrypt before
writing the page */
{
os_aio_slot_t* slot = NULL;
#ifdef WIN_ASYNC_IO
OVERLAPPED* control;
#elif defined(LINUX_NATIVE_AIO)
struct iocb* iocb;
off_t aio_offset;
#endif /* WIN_ASYNC_IO */
ulint i;
ulint counter;
ulint slots_per_seg;
ulint local_seg;
#ifdef WIN_ASYNC_IO
ut_a((len & 0xFFFFFFFFUL) == len);
#endif /* WIN_ASYNC_IO */
/* No need of a mutex. Only reading constant fields */
slots_per_seg = array->n_slots / array->n_segments;
/* We attempt to keep adjacent blocks in the same local
segment. This can help in merging IO requests when we are
doing simulated AIO */
local_seg = (offset >> (UNIV_PAGE_SIZE_SHIFT + 6))
% array->n_segments;
loop:
os_mutex_enter(array->mutex);
if (array->n_reserved == array->n_slots) {
os_mutex_exit(array->mutex);
if (!srv_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;
}
/* We start our search for an available slot from our preferred
local segment and do a full scan of the array. We are
guaranteed to find a slot in full scan. */
for (i = local_seg * slots_per_seg, counter = 0;
counter < array->n_slots;
i++, counter++) {
i %= array->n_slots;
slot = os_aio_array_get_nth_slot(array, i);
if (slot->reserved == FALSE) {
goto found;
}
}
/* We MUST always be able to get hold of a reserved slot. */
ut_error;
found:
ut_a(slot->reserved == FALSE);
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->reservation_time = ut_time();
slot->message1 = message1;
slot->message2 = message2;
slot->file = file;
slot->name = name;
slot->len = len;
slot->type = type;
slot->offset = offset;
slot->lsn = lsn;
slot->io_already_done = FALSE;
slot->page_compression_success = FALSE;
slot->page_encryption_success = FALSE;
slot->write_size = write_size;
slot->page_compression_level = page_compression_level;
slot->page_compression = page_compression;
slot->page_encryption_key = page_encryption_key;
slot->page_encryption = page_encryption;
slot->encrypt_later = encrypt_later;
if (message1) {
slot->file_block_size = fil_node_get_block_size(message1);
}
/* If the space is page compressed and this is write operation
then we compress the page */
if (message1 && type == OS_FILE_WRITE && page_compression ) {
ulint real_len = len;
byte* tmp = NULL;
/* Release the array mutex while compressing */
os_mutex_exit(array->mutex);
// We allocate memory for page compressed buffer if and only
// if it is not yet allocated.
os_slot_alloc_page_buf(slot);
#ifdef HAVE_LZO
if (innodb_compression_algorithm == 3) {
os_slot_alloc_lzo_mem(slot);
}
#endif
/* Call page compression */
tmp = fil_compress_page(
fil_node_get_space_id(slot->message1),
(byte *)buf,
slot->page_buf,
len,
page_compression_level,
fil_node_get_block_size(slot->message1),
&real_len,
slot->lzo_mem
);
/* If compression succeeded, set up the length and buffer */
if (tmp != buf) {
len = real_len;
buf = slot->page_buf;
slot->len = real_len;
slot->page_compression_success = TRUE;
} else {
slot->page_compression_success = FALSE;
}
/* Take array mutex back, not sure if this is really needed
below */
os_mutex_enter(array->mutex);
}
/* If the space is page encryption and this is write operation
then we encrypt the page */
if (message1 && type == OS_FILE_WRITE && (page_encryption == 1 || encrypt_later)) {
ut_a(page_encryption == 1 || srv_encrypt_tables == 1);
/* Release the array mutex while encrypting */
os_mutex_exit(array->mutex);
// We allocate memory for page encrypted buffer if and only
// if it is not yet allocated.
os_slot_alloc_page_buf2(slot);
fil_space_encrypt(
fil_node_get_space_id(slot->message1),
slot->offset,
slot->lsn,
(byte *)buf,
slot->len,
slot->page_buf2,
slot->page_encryption_key);
slot->page_encryption_success = TRUE;
buf = slot->page_buf2;
/* Take array mutex back */
os_mutex_enter(array->mutex);
}
slot->buf = static_cast<byte*>(buf);
#ifdef WIN_ASYNC_IO
control = &slot->control;
control->Offset = (DWORD) offset & 0xFFFFFFFF;
control->OffsetHigh = (DWORD) (offset >> 32);
ResetEvent(slot->handle);
#elif defined(LINUX_NATIVE_AIO)
/* If we are not using native AIO skip this part. */
if (!srv_use_native_aio) {
goto skip_native_aio;
}
/* Check if we are dealing with 64 bit arch.
If not then make sure that offset fits in 32 bits. */
aio_offset = (off_t) offset;
ut_a(sizeof(aio_offset) >= sizeof(offset)
|| ((os_offset_t) aio_offset) == offset);
iocb = &slot->control;
if (type == OS_FILE_READ) {
io_prep_pread(iocb, file, buf, len, aio_offset);
} else {
ut_a(type == OS_FILE_WRITE);
io_prep_pwrite(iocb, file, buf, len, aio_offset);
}
iocb->data = (void*) slot;
slot->n_bytes = 0;
slot->ret = 0;
skip_native_aio:
#endif /* LINUX_NATIVE_AIO */
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 */
{
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
ResetEvent(slot->handle);
#elif defined(LINUX_NATIVE_AIO)
if (srv_use_native_aio) {
memset(&slot->control, 0x0, sizeof(slot->control));
slot->n_bytes = 0;
slot->ret = 0;
/*fprintf(stderr, "Freed up Linux native slot.\n");*/
} else {
/* These fields should not be used if we are not
using native AIO. */
ut_ad(slot->n_bytes == 0);
ut_ad(slot->ret == 0);
}
#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;
ut_ad(!srv_use_native_aio);
segment = os_aio_get_array_and_local_segment(&array, global_segment);
ulint n = array->n_slots / array->n_segments;
segment *= n;
/* Look through n slots after the segment * n'th slot */
os_mutex_enter(array->mutex);
for (ulint i = 0; i < n; ++i) {
const os_aio_slot_t* slot;
slot = os_aio_array_get_nth_slot(array, segment + i);
if (slot->reserved) {
/* Found an i/o request */
os_mutex_exit(array->mutex);
os_event_t event;
event = os_aio_segment_wait_events[global_segment];
os_event_set(event);
return;
}
}
os_mutex_exit(array->mutex);
}
/**********************************************************************//**
Wakes up simulated aio i/o-handler threads if they have something to do. */
UNIV_INTERN
void
os_aio_simulated_wake_handler_threads(void)
/*=======================================*/
{
if (srv_use_native_aio) {
/* We do not use simulated aio: do nothing */
return;
}
os_aio_recommend_sleep_for_read_threads = FALSE;
for (ulint i = 0; i < os_aio_n_segments; i++) {
os_aio_simulated_wake_handler_thread(i);
}
}
/**********************************************************************//**
This function can be called if one wants to post a batch of reads and
prefers an i/o-handler thread to handle them all at once later. You must
call os_aio_simulated_wake_handler_threads later to ensure the threads
are not left sleeping! */
UNIV_INTERN
void
os_aio_simulated_put_read_threads_to_sleep(void)
/*============================================*/
{
/* The idea of putting background IO threads to sleep is only for
Windows when using simulated AIO. Windows XP seems to schedule
background threads too eagerly to allow for coalescing during
readahead requests. */
#ifdef __WIN__
os_aio_array_t* array;
if (srv_use_native_aio) {
/* We do not use simulated aio: do nothing */
return;
}
os_aio_recommend_sleep_for_read_threads = TRUE;
for (ulint i = 0; i < os_aio_n_segments; i++) {
os_aio_get_array_and_local_segment(&array, i);
if (array == os_aio_read_array) {
os_event_reset(os_aio_segment_wait_events[i]);
}
}
#endif /* __WIN__ */
}
#if defined(LINUX_NATIVE_AIO)
/*******************************************************************//**
Dispatch an AIO request to the kernel.
@return TRUE on success. */
static
ibool
os_aio_linux_dispatch(
/*==================*/
os_aio_array_t* array, /*!< in: io request array. */
os_aio_slot_t* slot) /*!< in: an already reserved slot. */
{
int ret;
ulint io_ctx_index;
struct iocb* iocb;
ut_ad(slot != NULL);
ut_ad(array);
ut_a(slot->reserved);
/* Find out what we are going to work with.
The iocb struct is directly in the slot.
The io_context is one per segment. */
iocb = &slot->control;
io_ctx_index = (slot->pos * array->n_segments) / array->n_slots;
ret = io_submit(array->aio_ctx[io_ctx_index], 1, &iocb);
#if defined(UNIV_AIO_DEBUG)
fprintf(stderr,
"io_submit[%c] ret[%d]: slot[%p] ctx[%p] seg[%lu]\n",
(slot->type == OS_FILE_WRITE) ? 'w' : 'r', ret, slot,
array->aio_ctx[io_ctx_index], (ulong) io_ctx_index);
#endif
/* io_submit returns number of successfully
queued requests or -errno. */
if (UNIV_UNLIKELY(ret != 1)) {
errno = -ret;
return(FALSE);
}
return(TRUE);
}
#endif /* LINUX_NATIVE_AIO */
/*******************************************************************//**
NOTE! Use the corresponding macro os_aio(), not directly this function!
Requests an asynchronous i/o operation.
@return TRUE if request was queued successfully, FALSE if fail */
UNIV_INTERN
ibool
os_aio_func(
/*========*/
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! */
const 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 */
os_offset_t offset, /*!< in: file offset where to read or write */
ulint n, /*!< in: number of bytes to read or write */
fil_node_t* message1,/*!< in: message for the aio handler
(can be used to identify a completed
aio operation); ignored if mode is
OS_AIO_SYNC */
void* message2,/*!< in: message for the aio handler
(can be used to identify a completed
aio operation); ignored if mode is
OS_AIO_SYNC */
ulint* write_size,/*!< in/out: Actual write size initialized
after fist successfull trim
operation for this page and if
initialized we do not trim again if
actual page size does not decrease. */
ibool page_compression, /*!< in: is page compression used
on this file space */
ulint page_compression_level, /*!< page compression
level to be used */
ibool page_encryption, /*!< in: is page encryption used
on this file space */
ulint page_encryption_key, /*!< in: page encryption key
to be used */
lsn_t lsn, /*!< in: lsn of the newest modification */
bool encrypt_later) /*!< in: should we encrypt page
before write */
{
os_aio_array_t* array;
os_aio_slot_t* slot;
#ifdef WIN_ASYNC_IO
void* buffer = NULL;
ibool retval;
BOOL ret = TRUE;
DWORD len = (DWORD) n;
struct fil_node_t* dummy_mess1;
void* dummy_mess2;
ulint dummy_type;
#endif /* WIN_ASYNC_IO */
ulint wake_later;
ut_ad(buf);
ut_ad(n > 0);
ut_ad(n % OS_FILE_LOG_BLOCK_SIZE == 0);
ut_ad(offset % OS_FILE_LOG_BLOCK_SIZE == 0);
ut_ad(os_aio_validate_skip());
#ifdef WIN_ASYNC_IO
ut_ad((n & 0xFFFFFFFFUL) == n);
#endif
wake_later = mode & OS_AIO_SIMULATED_WAKE_LATER;
mode = mode & (~OS_AIO_SIMULATED_WAKE_LATER);
DBUG_EXECUTE_IF("ib_os_aio_func_io_failure_28",
mode = OS_AIO_SYNC; os_has_said_disk_full = TRUE;);
if (mode == OS_AIO_SYNC
#ifdef WIN_ASYNC_IO
&& !srv_use_native_aio
#endif /* WIN_ASYNC_IO */
) {
ibool ret;
/* 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.
Also note that the Performance Schema instrumentation has
been performed by current os_aio_func()'s wrapper function
pfs_os_aio_func(). So we would no longer need to call
Performance Schema instrumented os_file_read() and
os_file_write(). Instead, we should use os_file_read_func()
and os_file_write_func() */
if (type == OS_FILE_READ) {
ret = os_file_read_func(file, buf, offset, n,
page_compression);
} else {
ut_ad(!srv_read_only_mode);
ut_a(type == OS_FILE_WRITE);
ret = os_file_write_func(name, file, buf, offset, n);
DBUG_EXECUTE_IF("ib_os_aio_func_io_failure_28",
os_has_said_disk_full = TRUE; ret = 0; errno = 28;);
}
return ret;
}
try_again:
switch (mode) {
case OS_AIO_NORMAL:
if (type == OS_FILE_READ) {
array = os_aio_read_array;
} else {
ut_ad(!srv_read_only_mode);
array = os_aio_write_array;
}
break;
case 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;
if (srv_read_only_mode) {
array = os_aio_read_array;
} else {
array = os_aio_ibuf_array;
}
break;
case OS_AIO_LOG:
if (srv_read_only_mode) {
array = os_aio_read_array;
} else {
array = os_aio_log_array;
}
break;
case OS_AIO_SYNC:
array = os_aio_sync_array;
#if defined(LINUX_NATIVE_AIO)
/* In Linux native AIO we don't use sync IO array. */
ut_a(!srv_use_native_aio);
#endif /* LINUX_NATIVE_AIO */
break;
default:
ut_error;
array = NULL; /* Eliminate compiler warning */
}
slot = os_aio_array_reserve_slot(type, array, message1, message2, file,
name, buf, offset, n, write_size,
page_compression, page_compression_level,
page_encryption, page_encryption_key, lsn, encrypt_later);
if (type == OS_FILE_READ) {
if (srv_use_native_aio) {
os_n_file_reads++;
os_bytes_read_since_printout += n;
#ifdef WIN_ASYNC_IO
ret = ReadFile(file, buf, (DWORD) n, &len,
&(slot->control));
#elif defined(LINUX_NATIVE_AIO)
if (!os_aio_linux_dispatch(array, slot)) {
goto err_exit;
}
#endif /* WIN_ASYNC_IO */
} 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) {
ut_ad(!srv_read_only_mode);
if (srv_use_native_aio) {
os_n_file_writes++;
#ifdef WIN_ASYNC_IO
if (page_encryption && slot->page_encryption_success) {
buffer = slot->page_buf2;
n = slot->len;
} else {
if (page_compression && slot->page_compression_success) {
buffer = slot->page_buf;
n = slot->len;
} else {
buffer = buf;
}
}
ret = WriteFile(file, buffer, (DWORD) n, &len,
&(slot->control));
#elif defined(LINUX_NATIVE_AIO)
if (!os_aio_linux_dispatch(array, slot)) {
goto err_exit;
}
#endif /* WIN_ASYNC_IO */
} 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 (srv_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 */
retval = os_aio_windows_handle(
ULINT_UNDEFINED, slot->pos,
&dummy_mess1, &dummy_mess2,
&dummy_type);
return(retval);
}
return(TRUE);
}
goto err_exit;
}
#endif /* WIN_ASYNC_IO */
/* aio was queued successfully! */
return(TRUE);
#if defined LINUX_NATIVE_AIO || defined WIN_ASYNC_IO
err_exit:
#endif /* LINUX_NATIVE_AIO || WIN_ASYNC_IO */
os_aio_array_free_slot(array, slot);
if (os_file_handle_error(
name,type == OS_FILE_READ ? "aio read" : "aio write", __FILE__, __LINE__)) {
goto try_again;
}
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!
@return TRUE if the aio operation succeeded */
UNIV_INTERN
ibool
os_aio_windows_handle(
/*==================*/
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 */
fil_node_t**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;
BOOL retry = FALSE;
if (segment == ULINT_UNDEFINED) {
segment = 0;
array = os_aio_sync_array;
} 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_skip());
ut_ad(segment < array->n_segments);
n = array->n_slots / array->n_segments;
if (array == os_aio_sync_array) {
WaitForSingleObject(
os_aio_array_get_nth_slot(array, pos)->handle,
INFINITE);
i = pos;
} else {
if (orig_seg != ULINT_UNDEFINED) {
srv_set_io_thread_op_info(orig_seg, "wait Windows aio");
}
i = WaitForMultipleObjects(
(DWORD) n, array->handles + segment * n,
FALSE, INFINITE);
}
os_mutex_enter(array->mutex);
if (srv_shutdown_state == SRV_SHUTDOWN_EXIT_THREADS
&& array->n_reserved == 0) {
*message1 = NULL;
*message2 = NULL;
os_mutex_exit(array->mutex);
return(TRUE);
}
ut_a(i >= WAIT_OBJECT_0 && i <= WAIT_OBJECT_0 + n);
slot = os_aio_array_get_nth_slot(array, i + segment * n);
ut_a(slot->reserved);
if (orig_seg != ULINT_UNDEFINED) {
srv_set_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;
} else if (!ret || (len != slot->len)) {
if (!ret) {
if (os_file_handle_error(slot->name, "Windows aio", __FILE__, __LINE__)) {
retry = TRUE;
} else {
ret_val = FALSE;
}
} else {
retry = TRUE;
}
} else {
ret_val = FALSE;
}
os_mutex_exit(array->mutex);
if (retry) {
/* retry failed read/write operation synchronously.
No need to hold array->mutex. */
#ifdef UNIV_PFS_IO
/* This read/write does not go through os_file_read
and os_file_write APIs, need to register with
performance schema explicitly here. */
struct PSI_file_locker* locker = NULL;
register_pfs_file_io_begin(locker, slot->file, slot->len,
(slot->type == OS_FILE_WRITE)
? PSI_FILE_WRITE
: PSI_FILE_READ,
__FILE__, __LINE__);
#endif
ut_a((slot->len & 0xFFFFFFFFUL) == slot->len);
switch (slot->type) {
case OS_FILE_WRITE:
if (slot->message1
&& slot->page_encryption
&& slot->page_encryption_success) {
ret_val = os_file_write(slot->name,
slot->file,
slot->page_buf2,
slot->offset,
slot->len);
} else {
if (slot->message1
&& slot->page_compression
&& slot->page_compression_success) {
ret = WriteFile(slot->file, slot->page_buf,
(DWORD) slot->len, &len,
&(slot->control));
} else {
ret = WriteFile(slot->file, slot->buf,
(DWORD) slot->len, &len,
&(slot->control));
}
}
break;
case OS_FILE_READ:
ret = ReadFile(slot->file, slot->buf,
(DWORD) slot->len, &len,
&(slot->control));
break;
default:
ut_error;
}
#ifdef UNIV_PFS_IO
register_pfs_file_io_end(locker, len);
#endif
if (!ret && GetLastError() == ERROR_IO_PENDING) {
/* aio was queued successfully!
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 */
ret = GetOverlappedResult(slot->file,
&(slot->control),
&len, TRUE);
}
ret_val = ret && len == slot->len;
}
if (slot->type == OS_FILE_READ) {
if (fil_page_is_compressed_encrypted(slot->buf) ||
fil_page_is_encrypted(slot->buf)) {
ut_ad(slot->message1 != NULL);
os_slot_alloc_page_buf2(slot);
os_slot_alloc_tmp_encryption_buf(slot);
// Decrypt the data
fil_space_decrypt(
fil_node_get_space_id(slot->message1),
slot->buf,
slot->len,
slot->page_buf2);
// Copy decrypted buffer back to buf
memcpy(slot->buf, slot->page_buf2, slot->len);
}
if (fil_page_is_compressed(slot->buf)) {
/* We allocate memory for page compressed buffer if
and only if it is not yet allocated. */
os_slot_alloc_page_buf(slot);
#ifdef HAVE_LZO
if (fil_page_is_lzo_compressed(slot->buf)) {
os_slot_alloc_lzo_mem(slot);
}
#endif
fil_decompress_page(
slot->page_buf,
slot->buf,
slot->len,
slot->write_size);
}
} else {
/* OS_FILE_WRITE */
if (slot->page_compression_success &&
(fil_page_is_compressed(slot->page_buf) ||
fil_page_is_compressed_encrypted(slot->buf))) {
if (srv_use_trim && os_fallocate_failed == FALSE) {
// Deallocate unused blocks from file system
os_file_trim(slot);
}
}
}
os_aio_array_free_slot(array, slot);
return(ret_val);
}
#endif
#if defined(LINUX_NATIVE_AIO)
/******************************************************************//**
This function is only used in Linux native asynchronous i/o. This is
called from within the io-thread. If there are no completed IO requests
in the slot array, the thread calls this function to collect more
requests from the kernel.
The io-thread waits on io_getevents(), which is a blocking call, with
a timeout value. Unless the system is very heavy loaded, keeping the
io-thread very busy, the io-thread will spend most of its time waiting
in this function.
The io-thread also exits in this function. It checks server status at
each wakeup and that is why we use timed wait in io_getevents(). */
static
void
os_aio_linux_collect(
/*=================*/
os_aio_array_t* array, /*!< in/out: slot array. */
ulint segment, /*!< in: local segment no. */
ulint seg_size) /*!< in: segment size. */
{
int i;
int ret;
ulint start_pos;
ulint end_pos;
struct timespec timeout;
struct io_event* events;
struct io_context* io_ctx;
/* sanity checks. */
ut_ad(array != NULL);
ut_ad(seg_size > 0);
ut_ad(segment < array->n_segments);
/* Which part of event array we are going to work on. */
events = &array->aio_events[segment * seg_size];
/* Which io_context we are going to use. */
io_ctx = array->aio_ctx[segment];
/* Starting point of the segment we will be working on. */
start_pos = segment * seg_size;
/* End point. */
end_pos = start_pos + seg_size;
retry:
/* Initialize the events. The timeout value is arbitrary.
We probably need to experiment with it a little. */
memset(events, 0, sizeof(*events) * seg_size);
timeout.tv_sec = 0;
timeout.tv_nsec = OS_AIO_REAP_TIMEOUT;
ret = io_getevents(io_ctx, 1, seg_size, events, &timeout);
if (ret > 0) {
for (i = 0; i < ret; i++) {
os_aio_slot_t* slot;
struct iocb* control;
control = (struct iocb*) events[i].obj;
ut_a(control != NULL);
slot = (os_aio_slot_t*) control->data;
/* Some sanity checks. */
ut_a(slot != NULL);
ut_a(slot->reserved);
#if defined(UNIV_AIO_DEBUG)
fprintf(stderr,
"io_getevents[%c]: slot[%p] ctx[%p]"
" seg[%lu]\n",
(slot->type == OS_FILE_WRITE) ? 'w' : 'r',
slot, io_ctx, segment);
#endif
/* We are not scribbling previous segment. */
ut_a(slot->pos >= start_pos);
/* We have not overstepped to next segment. */
ut_a(slot->pos < end_pos);
if (slot->type == OS_FILE_READ) {
/* If the page is page encrypted we encrypt */
if (fil_page_is_compressed_encrypted(slot->buf) ||
fil_page_is_encrypted(slot->buf)) {
os_slot_alloc_page_buf2(slot);
os_slot_alloc_tmp_encryption_buf(slot);
ut_ad(slot->message1 != NULL);
// Decrypt the data
fil_space_decrypt(
fil_node_get_space_id(slot->message1),
slot->buf,
slot->len,
slot->page_buf2);
// Copy decrypted buffer back to buf
memcpy(slot->buf, slot->page_buf2, slot->len);
}
/* If the table is page compressed and this
is read, we decompress before we announce
the read is complete. For writes, we free
the compressed page. */
if (fil_page_is_compressed(slot->buf)) {
// We allocate memory for page compressed buffer if and only
// if it is not yet allocated.
os_slot_alloc_page_buf(slot);
#ifdef HAVE_LZO
if (fil_page_is_lzo_compressed(slot->buf)) {
os_slot_alloc_lzo_mem(slot);
}
#endif
fil_decompress_page(slot->page_buf, slot->buf, slot->len, slot->write_size);
}
} else {
/* OS_FILE_WRITE */
if (slot->page_compression_success &&
(fil_page_is_compressed(slot->page_buf) ||
fil_page_is_compressed_encrypted(slot->buf))) {
if (srv_use_trim && os_fallocate_failed == FALSE) {
// Deallocate unused blocks from file system
os_file_trim(slot);
}
}
}
/* Mark this request as completed. The error handling
will be done in the calling function. */
os_mutex_enter(array->mutex);
slot->n_bytes = events[i].res;
slot->ret = events[i].res2;
slot->io_already_done = TRUE;
os_mutex_exit(array->mutex);
}
return;
}
if (UNIV_UNLIKELY(srv_shutdown_state == SRV_SHUTDOWN_EXIT_THREADS)) {
return;
}
/* This error handling is for any error in collecting the
IO requests. The errors, if any, for any particular IO
request are simply passed on to the calling routine. */
switch (ret) {
case -EAGAIN:
/* Not enough resources! Try again. */
case -EINTR:
/* Interrupted! I have tested the behaviour in case of an
interrupt. If we have some completed IOs available then
the return code will be the number of IOs. We get EINTR only
if there are no completed IOs and we have been interrupted. */
case 0:
/* No pending request! Go back and check again. */
goto retry;
}
/* All other errors should cause a trap for now. */
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: unexpected ret_code[%d] from io_getevents()!\n",
ret);
ut_error;
}
/**********************************************************************//**
This function is only used in Linux native asynchronous i/o.
Waits for an aio operation to complete. This function is used to wait for
the 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!
@return TRUE if the IO was successful */
UNIV_INTERN
ibool
os_aio_linux_handle(
/*================*/
ulint global_seg, /*!< in: segment number in the aio array
to wait for; segment 0 is the ibuf
i/o thread, segment 1 is log i/o thread,
then follow the non-ibuf read threads,
and the last are the non-ibuf write
threads. */
fil_node_t**message1, /*!< out: the messages passed with the */
void** message2, /*!< aio request; note that in case the
aio operation failed, these output
parameters are valid and can be used to
restart the operation. */
ulint* type) /*!< out: OS_FILE_WRITE or ..._READ */
{
ulint segment;
os_aio_array_t* array;
os_aio_slot_t* slot;
ulint n;
ulint i;
ibool ret = FALSE;
/* Should never be doing Sync IO here. */
ut_a(global_seg != ULINT_UNDEFINED);
/* Find the array and the local segment. */
segment = os_aio_get_array_and_local_segment(&array, global_seg);
n = array->n_slots / array->n_segments;
/* Loop until we have found a completed request. */
for (;;) {
ibool any_reserved = FALSE;
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) {
continue;
} else if (slot->io_already_done) {
/* Something for us to work on. */
goto found;
} else {
any_reserved = TRUE;
}
}
os_mutex_exit(array->mutex);
/* There is no completed request.
If there is no pending request at all,
and the system is being shut down, exit. */
if (UNIV_UNLIKELY
(!any_reserved
&& srv_shutdown_state == SRV_SHUTDOWN_EXIT_THREADS)) {
*message1 = NULL;
*message2 = NULL;
return(TRUE);
}
/* Wait for some request. Note that we return
from wait iff we have found a request. */
srv_set_io_thread_op_info(global_seg,
"waiting for completed aio requests");
os_aio_linux_collect(array, segment, n);
}
found:
/* Note that it may be that there are more then one completed
IO requests. We process them one at a time. We may have a case
here to improve the performance slightly by dealing with all
requests in one sweep. */
srv_set_io_thread_op_info(global_seg,
"processing completed aio requests");
/* Ensure that we are scribbling only our segment. */
ut_a(i < n);
ut_ad(slot != NULL);
ut_ad(slot->reserved);
ut_ad(slot->io_already_done);
*message1 = slot->message1;
*message2 = slot->message2;
*type = slot->type;
if (slot->ret == 0 && slot->n_bytes == (long) slot->len) {
ret = TRUE;
} else {
errno = -slot->ret;
if (slot->ret == 0) {
fprintf(stderr,
"InnoDB: Number of bytes after aio %d requested %lu\n"
"InnoDB: from file %s\n",
slot->n_bytes, slot->len, slot->name);
}
/* os_file_handle_error does tell us if we should retry
this IO. As it stands now, we don't do this retry when
reaping requests from a different context than
the dispatcher. This non-retry logic is the same for
windows and linux native AIO.
We should probably look into this to transparently
re-submit the IO. */
os_file_handle_error(slot->name, "Linux aio", __FILE__, __LINE__);
ret = FALSE;
}
os_mutex_exit(array->mutex);
os_aio_array_free_slot(array, slot);
return(ret);
}
#endif /* LINUX_NATIVE_AIO */
/**********************************************************************//**
Does simulated aio. This function should be called by an i/o-handler
thread.
@return TRUE if the aio operation succeeded */
UNIV_INTERN
ibool
os_aio_simulated_handle(
/*====================*/
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 */
fil_node_t**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* consecutive_ios[OS_AIO_MERGE_N_CONSECUTIVE];
ulint n_consecutive;
ulint total_len;
ulint offs;
os_offset_t lowest_offset;
ulint biggest_age;
ulint age;
byte* combined_buf;
byte* combined_buf2;
ibool ret;
ibool any_reserved;
ulint n;
os_aio_slot_t* aio_slot;
/* Fix compiler warning */
*consecutive_ios = NULL;
segment = os_aio_get_array_and_local_segment(&array, global_segment);
restart:
/* NOTE! We only access constant fields in os_aio_array. Therefore
we do not have to acquire the protecting mutex yet */
srv_set_io_thread_op_info(global_segment,
"looking for i/o requests (a)");
ut_ad(os_aio_validate_skip());
ut_ad(segment < array->n_segments);
n = array->n_slots / array->n_segments;
/* Look through n slots after the segment * n'th slot */
if (array == os_aio_read_array
&& os_aio_recommend_sleep_for_read_threads) {
/* Give other threads chance to add several i/os to the array
at once. */
goto recommended_sleep;
}
srv_set_io_thread_op_info(global_segment,
"looking for i/o requests (b)");
/* Check if there is a slot for which the i/o has already been
done */
any_reserved = FALSE;
os_mutex_enter(array->mutex);
for (ulint i = 0; i < n; i++) {
os_aio_slot_t* slot;
slot = os_aio_array_get_nth_slot(array, i + segment * n);
if (!slot->reserved) {
continue;
} else if (slot->io_already_done) {
if (os_aio_print_debug) {
fprintf(stderr,
"InnoDB: i/o for slot %lu"
" already done, returning\n",
(ulong) i);
}
aio_slot = slot;
ret = TRUE;
goto slot_io_done;
} else {
any_reserved = TRUE;
}
}
/* There is no completed request.
If there is no pending request at all,
and the system is being shut down, exit. */
if (!any_reserved && srv_shutdown_state == SRV_SHUTDOWN_EXIT_THREADS) {
os_mutex_exit(array->mutex);
*message1 = NULL;
*message2 = NULL;
return(TRUE);
}
n_consecutive = 0;
/* If there are at least 2 seconds old requests, then pick the oldest
one to prevent starvation. If several requests have the same age,
then pick the one at the lowest offset. */
biggest_age = 0;
lowest_offset = IB_UINT64_MAX;
for (ulint i = 0; i < n; i++) {
os_aio_slot_t* slot;
slot = os_aio_array_get_nth_slot(array, i + segment * n);
if (slot->reserved) {
age = (ulint) difftime(
ut_time(), slot->reservation_time);
if ((age >= 2 && age > biggest_age)
|| (age >= 2 && age == biggest_age
&& slot->offset < lowest_offset)) {
/* Found an i/o request */
consecutive_ios[0] = slot;
n_consecutive = 1;
biggest_age = age;
lowest_offset = slot->offset;
}
}
}
if (n_consecutive == 0) {
/* There were no old requests. Look for an i/o request at the
lowest offset in the array (we ignore the high 32 bits of the
offset in these heuristics) */
lowest_offset = IB_UINT64_MAX;
for (ulint i = 0; i < n; i++) {
os_aio_slot_t* slot;
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;
}
/* if n_consecutive != 0, then we have assigned
something valid to consecutive_ios[0] */
ut_ad(n_consecutive != 0);
ut_ad(consecutive_ios[0] != NULL);
aio_slot = consecutive_ios[0];
/* Check if there are several consecutive blocks to read or write */
consecutive_loop:
for (ulint i = 0; i < n; i++) {
os_aio_slot_t* slot;
slot = os_aio_array_get_nth_slot(array, i + segment * n);
if (slot->reserved
&& slot != aio_slot
&& slot->offset == aio_slot->offset + aio_slot->len
&& slot->type == aio_slot->type
&& slot->file == aio_slot->file) {
/* Found a consecutive i/o request */
consecutive_ios[n_consecutive] = slot;
n_consecutive++;
aio_slot = slot;
if (n_consecutive < OS_AIO_MERGE_N_CONSECUTIVE) {
goto consecutive_loop;
} else {
break;
}
}
}
srv_set_io_thread_op_info(global_segment, "consecutive i/o requests");
/* 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;
aio_slot = consecutive_ios[0];
for (ulint 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 = aio_slot->buf;
combined_buf2 = NULL;
} else {
combined_buf2 = static_cast<byte*>(
ut_malloc(total_len + UNIV_PAGE_SIZE));
ut_a(combined_buf2);
combined_buf = static_cast<byte*>(
ut_align(combined_buf2, UNIV_PAGE_SIZE));
}
/* 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 (aio_slot->type == OS_FILE_WRITE && n_consecutive > 1) {
/* Copy the buffers to the combined buffer */
offs = 0;
for (ulint 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_set_io_thread_op_info(global_segment, "doing file i/o");
/* Do the i/o with ordinary, synchronous i/o functions: */
if (aio_slot->type == OS_FILE_WRITE) {
ut_ad(!srv_read_only_mode);
ret = os_file_write(
aio_slot->name, aio_slot->file, combined_buf,
aio_slot->offset, total_len);
DBUG_EXECUTE_IF("ib_os_aio_func_io_failure_28",
os_has_said_disk_full = TRUE;
ret = 0;
errno = 28;);
} else {
ret = os_file_read(
aio_slot->file, combined_buf,
aio_slot->offset, total_len,
aio_slot->page_compression);
}
srv_set_io_thread_op_info(global_segment, "file i/o done");
if (aio_slot->type == OS_FILE_READ && n_consecutive > 1) {
/* Copy the combined buffer to individual buffers */
offs = 0;
for (ulint 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 (combined_buf2) {
ut_free(combined_buf2);
}
os_mutex_enter(array->mutex);
/* Mark the i/os done in slots */
for (ulint 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(aio_slot->reserved);
*message1 = aio_slot->message1;
*message2 = aio_slot->message2;
*type = aio_slot->type;
os_mutex_exit(array->mutex);
os_aio_array_free_slot(array, aio_slot);
return(ret);
wait_for_io:
srv_set_io_thread_op_info(global_segment, "resetting wait event");
/* 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);
recommended_sleep:
srv_set_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.
@return true if ok */
static
bool
os_aio_array_validate(
/*==================*/
os_aio_array_t* array) /*!< in: aio wait array */
{
ulint i;
ulint n_reserved = 0;
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++) {
os_aio_slot_t* slot;
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.
@return TRUE if ok */
UNIV_INTERN
ibool
os_aio_validate(void)
/*=================*/
{
os_aio_array_validate(os_aio_read_array);
if (os_aio_write_array != 0) {
os_aio_array_validate(os_aio_write_array);
}
if (os_aio_ibuf_array != 0) {
os_aio_array_validate(os_aio_ibuf_array);
}
if (os_aio_log_array != 0) {
os_aio_array_validate(os_aio_log_array);
}
if (os_aio_sync_array != 0) {
os_aio_array_validate(os_aio_sync_array);
}
return(TRUE);
}
/**********************************************************************//**
Prints pending IO requests per segment of an aio array.
We probably don't need per segment statistics but they can help us
during development phase to see if the IO requests are being
distributed as expected. */
static
void
os_aio_print_segment_info(
/*======================*/
FILE* file, /*!< in: file where to print */
ulint* n_seg, /*!< in: pending IO array */
os_aio_array_t* array) /*!< in: array to process */
{
ulint i;
ut_ad(array);
ut_ad(n_seg);
ut_ad(array->n_segments > 0);
if (array->n_segments == 1) {
return;
}
fprintf(file, " [");
for (i = 0; i < array->n_segments; i++) {
if (i != 0) {
fprintf(file, ", ");
}
fprintf(file, "%lu", n_seg[i]);
}
fprintf(file, "] ");
}
/**********************************************************************//**
Prints info about the aio array. */
UNIV_INTERN
void
os_aio_print_array(
/*==============*/
FILE* file, /*!< in: file where to print */
os_aio_array_t* array) /*!< in: aio array to print */
{
ulint n_reserved = 0;
ulint n_res_seg[SRV_MAX_N_IO_THREADS];
os_mutex_enter(array->mutex);
ut_a(array->n_slots > 0);
ut_a(array->n_segments > 0);
memset(n_res_seg, 0x0, sizeof(n_res_seg));
for (ulint i = 0; i < array->n_slots; ++i) {
os_aio_slot_t* slot;
ulint seg_no;
slot = os_aio_array_get_nth_slot(array, i);
seg_no = (i * array->n_segments) / array->n_slots;
if (slot->reserved) {
++n_reserved;
++n_res_seg[seg_no];
ut_a(slot->len > 0);
}
}
ut_a(array->n_reserved == n_reserved);
fprintf(file, " %lu", (ulong) n_reserved);
os_aio_print_segment_info(file, n_res_seg, array);
os_mutex_exit(array->mutex);
}
/**********************************************************************//**
Prints info of the aio arrays. */
UNIV_INTERN
void
os_aio_print(
/*=========*/
FILE* file) /*!< in: file where to print */
{
time_t current_time;
double time_elapsed;
double avg_bytes_read;
for (ulint i = 0; i < srv_n_file_io_threads; ++i) {
fprintf(file, "I/O thread %lu state: %s (%s)",
(ulong) i,
srv_io_thread_op_info[i],
srv_io_thread_function[i]);
#ifndef __WIN__
if (os_aio_segment_wait_events[i]->is_set) {
fprintf(file, " ev set");
}
#endif /* __WIN__ */
fprintf(file, "\n");
}
fputs("Pending normal aio reads:", file);
os_aio_print_array(file, os_aio_read_array);
if (os_aio_write_array != 0) {
fputs(", aio writes:", file);
os_aio_print_array(file, os_aio_write_array);
}
if (os_aio_ibuf_array != 0) {
fputs(",\n ibuf aio reads:", file);
os_aio_print_array(file, os_aio_ibuf_array);
}
if (os_aio_log_array != 0) {
fputs(", log i/o's:", file);
os_aio_print_array(file, os_aio_log_array);
}
if (os_aio_sync_array != 0) {
fputs(", sync i/o's:", file);
os_aio_print_array(file, os_aio_sync_array);
}
putc('\n', file);
current_time = ut_time();
time_elapsed = 0.001 + difftime(current_time, os_last_printout);
fprintf(file,
"Pending flushes (fsync) log: %lu; buffer pool: %lu\n"
"%lu OS file reads, %lu OS file writes, %lu OS fsyncs\n",
(ulong) fil_n_pending_log_flushes,
(ulong) fil_n_pending_tablespace_flushes,
(ulong) os_n_file_reads,
(ulong) os_n_file_writes,
(ulong) os_n_fsyncs);
if (os_file_n_pending_preads != 0 || os_file_n_pending_pwrites != 0) {
fprintf(file,
"%lu pending preads, %lu pending pwrites\n",
(ulong) os_file_n_pending_preads,
(ulong) os_file_n_pending_pwrites);
}
if (os_n_file_reads == os_n_file_reads_old) {
avg_bytes_read = 0.0;
} else {
avg_bytes_read = (double) os_bytes_read_since_printout
/ (os_n_file_reads - os_n_file_reads_old);
}
fprintf(file,
"%.2f reads/s, %lu avg bytes/read,"
" %.2f writes/s, %.2f fsyncs/s\n",
(os_n_file_reads - os_n_file_reads_old)
/ time_elapsed,
(ulong) avg_bytes_read,
(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_bytes_read_since_printout = 0;
os_last_printout = current_time;
}
/**********************************************************************//**
Refreshes the statistics used to print per-second averages. */
UNIV_INTERN
void
os_aio_refresh_stats(void)
/*======================*/
{
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_bytes_read_since_printout = 0;
os_last_printout = time(NULL);
}
#ifdef UNIV_DEBUG
/**********************************************************************//**
Checks that all slots in the system have been freed, that is, there are
no pending io operations.
@return TRUE if all free */
UNIV_INTERN
ibool
os_aio_all_slots_free(void)
/*=======================*/
{
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);
if (!srv_read_only_mode) {
ut_a(os_aio_write_array == 0);
array = os_aio_write_array;
os_mutex_enter(array->mutex);
n_res += array->n_reserved;
os_mutex_exit(array->mutex);
ut_a(os_aio_ibuf_array == 0);
array = os_aio_ibuf_array;
os_mutex_enter(array->mutex);
n_res += array->n_reserved;
os_mutex_exit(array->mutex);
}
ut_a(os_aio_log_array == 0);
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);
}
#endif /* UNIV_DEBUG */
#ifdef _WIN32
#include <winioctl.h>
#ifndef FSCTL_FILE_LEVEL_TRIM
#define FSCTL_FILE_LEVEL_TRIM CTL_CODE(FILE_DEVICE_FILE_SYSTEM, 130, METHOD_BUFFERED, FILE_WRITE_DATA)
typedef struct _FILE_LEVEL_TRIM_RANGE {
DWORDLONG Offset;
DWORDLONG Length;
} FILE_LEVEL_TRIM_RANGE, *PFILE_LEVEL_TRIM_RANGE;
typedef struct _FILE_LEVEL_TRIM {
DWORD Key;
DWORD NumRanges;
FILE_LEVEL_TRIM_RANGE Ranges[1];
} FILE_LEVEL_TRIM, *PFILE_LEVEL_TRIM;
#endif
#endif
/**********************************************************************//**
Directly manipulate the allocated disk space by deallocating for the file referred to
by fd for the byte range starting at offset and continuing for len bytes.
Within the specified range, partial file system blocks are zeroed, and whole
file system blocks are removed from the file. After a successful call,
subsequent reads from this range will return zeroes.
@return true if success, false if error */
UNIV_INTERN
ibool
os_file_trim(
/*=========*/
os_aio_slot_t* slot) /*!< in: slot structure */
{
size_t len = slot->len;
size_t trim_len = UNIV_PAGE_SIZE - len;
os_offset_t off = slot->offset + len;
size_t bsize = slot->file_block_size;
// len here should be alligned to sector size
ut_ad((trim_len % bsize) == 0);
ut_ad((len % bsize) == 0);
ut_ad(bsize != 0);
ut_ad((off % bsize) == 0);
#ifdef UNIV_TRIM_DEBUG
fprintf(stderr, "Note: TRIM: write_size %lu trim_len %lu len %lu off %lu bz %lu\n",
*slot->write_size, trim_len, len, off, bsize);
#endif
// Nothing to do if trim length is zero or if actual write
// size is initialized and it is smaller than current write size.
// In first write if we trim we set write_size to actual bytes
// written and rest of the page is trimmed. In following writes
// there is no need to trim again if write_size only increases
// because rest of the page is already trimmed. If actual write
// size decreases we need to trim again.
if (trim_len == 0 ||
(slot->write_size &&
*slot->write_size > 0 &&
len >= *slot->write_size)) {
#ifdef UNIV_PAGECOMPRESS_DEBUG
fprintf(stderr, "Note: TRIM: write_size %lu trim_len %lu len %lu\n",
*slot->write_size, trim_len, len);
#endif
if (*slot->write_size > 0 && len >= *slot->write_size) {
srv_stats.page_compressed_trim_op_saved.inc();
}
*slot->write_size = len;
return (TRUE);
}
#ifdef __linux__
#if defined(HAVE_FALLOCATE)
int ret = fallocate(slot->file, FALLOC_FL_PUNCH_HOLE | FALLOC_FL_KEEP_SIZE, off, trim_len);
if (ret) {
/* After first failure do not try to trim again */
os_fallocate_failed = TRUE;
srv_use_trim = FALSE;
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Warning: fallocate call failed with error code %d.\n"
" InnoDB: start: %lu len: %lu payload: %lu\n"
" InnoDB: Disabling fallocate for now.\n", errno, off, trim_len, len);
os_file_handle_error_no_exit(slot->name,
" fallocate(FALLOC_PUNCH_HOLE | FALLOC_FL_KEEP_SIZE) ",
FALSE, __FILE__, __LINE__);
if (slot->write_size) {
*slot->write_size = 0;
}
return (FALSE);
} else {
if (slot->write_size) {
*slot->write_size = len;
}
}
#else
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Warning: fallocate not supported on this installation."
" InnoDB: Disabling fallocate for now.");
os_fallocate_failed = TRUE;
srv_use_trim = FALSE;
if (slot->write_size) {
*slot->write_size = 0;
}
#endif /* HAVE_FALLOCATE ... */
#elif defined(_WIN32)
FILE_LEVEL_TRIM flt;
flt.Key = 0;
flt.NumRanges = 1;
flt.Ranges[0].Offset = off;
flt.Ranges[0].Length = trim_len;
BOOL ret = DeviceIoControl(slot->file, FSCTL_FILE_LEVEL_TRIM,
&flt, sizeof(flt), NULL, NULL, NULL, NULL);
if (!ret) {
/* After first failure do not try to trim again */
os_fallocate_failed = TRUE;
srv_use_trim=FALSE;
ut_print_timestamp(stderr);
fprintf(stderr,
" InnoDB: Warning: fallocate call failed with error.\n"
" InnoDB: start: %lu len: %lu payload: %lu\n"
" InnoDB: Disabling fallocate for now.\n", off, trim_len, len);
os_file_handle_error_no_exit(slot->name,
" DeviceIOControl(FSCTL_FILE_LEVEL_TRIM) ",
FALSE, __FILE__, __LINE__);
if (slot->write_size) {
*slot->write_size = 0;
}
return (FALSE);
} else {
if (slot->write_size) {
*slot->write_size = len;
}
}
#endif
switch(bsize) {
case 512:
srv_stats.page_compression_trim_sect512.add((trim_len / bsize));
break;
case 1024:
srv_stats.page_compression_trim_sect1024.add((trim_len / bsize));
break;
case 2948:
srv_stats.page_compression_trim_sect2048.add((trim_len / bsize));
break;
case 4096:
srv_stats.page_compression_trim_sect4096.add((trim_len / bsize));
break;
case 8192:
srv_stats.page_compression_trim_sect8192.add((trim_len / bsize));
break;
case 16384:
srv_stats.page_compression_trim_sect16384.add((trim_len / bsize));
break;
case 32768:
srv_stats.page_compression_trim_sect32768.add((trim_len / bsize));
break;
default:
break;
}
srv_stats.page_compressed_trim_op.inc();
return (TRUE);
}
#endif /* !UNIV_HOTBACKUP */
/**********************************************************************//**
Allocate memory for temporal buffer used for page encryption. This
buffer is freed later. */
UNIV_INTERN
void
os_slot_alloc_page_buf2(
/*===================*/
os_aio_slot_t* slot) /*!< in: slot structure */
{
ut_a(slot != NULL);
if(slot->page_buf2 == NULL) {
byte* cbuf2;
byte* cbuf;
cbuf2 = static_cast<byte *>(ut_malloc(UNIV_PAGE_SIZE*2));
cbuf = static_cast<byte *>(ut_align(cbuf2, UNIV_PAGE_SIZE));
slot->page_encryption_page = static_cast<byte *>(cbuf2);
slot->page_buf2 = static_cast<byte *>(cbuf);
memset(slot->page_encryption_page, 0, UNIV_PAGE_SIZE*2);
}
}
/**********************************************************************//**
Allocate memory for temporal buffer used for page compression. This
buffer is freed later. */
UNIV_INTERN
void
os_slot_alloc_page_buf(
/*===================*/
os_aio_slot_t* slot) /*!< in: slot structure */
{
ut_a(slot != NULL);
if (slot->page_buf == NULL) {
byte* cbuf2;
byte* cbuf;
ulint asize = UNIV_PAGE_SIZE;
#ifdef HAVE_SNAPPY
asize += snappy_max_compressed_length(asize) - UNIV_PAGE_SIZE;
#endif
/* We allocate extra to avoid memory overwrite on compression */
cbuf2 = static_cast<byte *>(ut_malloc(asize*2));
cbuf = static_cast<byte *>(ut_align(cbuf2, UNIV_PAGE_SIZE));
slot->page_compression_page = static_cast<byte *>(cbuf2);
slot->page_buf = static_cast<byte *>(cbuf);
ut_a(slot->page_buf != NULL);
memset(slot->page_compression_page, 0, asize*2);
}
}
#ifdef HAVE_LZO
/**********************************************************************//**
Allocate memory for temporal memory used for page compression when
LZO compression method is used */
UNIV_INTERN
void
os_slot_alloc_lzo_mem(
/*===================*/
os_aio_slot_t* slot) /*!< in: slot structure */
{
ut_a(slot != NULL);
if(slot->lzo_mem == NULL) {
slot->lzo_mem = static_cast<byte *>(ut_malloc(LZO1X_1_15_MEM_COMPRESS));
ut_a(slot->lzo_mem != NULL);
memset(slot->lzo_mem, 0, LZO1X_1_15_MEM_COMPRESS);
}
}
#endif
/**********************************************************************//**
Allocate memory for temporal buffer used for page encryption. */
UNIV_INTERN
void
os_slot_alloc_tmp_encryption_buf(
/*=============================*/
os_aio_slot_t* slot) /*!< in: slot structure */
{
ut_a(slot != NULL);
if (slot->tmp_encryption_buf == NULL) {
slot->tmp_encryption_buf = static_cast<byte *>(ut_malloc(64));
memset(slot->tmp_encryption_buf, 0, 64);
}
}
/***********************************************************************//**
Try to get number of bytes per sector from file system.
@return file block size */
UNIV_INTERN
ulint
os_file_get_block_size(
/*===================*/
os_file_t file, /*!< in: handle to a file */
const char* name) /*!< in: file name */
{
ulint fblock_size = 512;
#if defined(UNIV_LINUX) && defined(HAVE_SYS_STATVFS_H)
struct statvfs fstat;
int err;
err = fstatvfs(file, &fstat);
if (err != 0) {
fprintf(stderr, "InnoDB: Warning: fstatvfs() failed on file %s\n", name);
os_file_handle_error_no_exit(name, "fstatvfs()", FALSE, __FILE__, __LINE__);
} else {
fblock_size = fstat.f_bsize;
}
#endif /* UNIV_LINUX */
#ifdef __WIN__
{
DWORD SectorsPerCluster = 0;
DWORD BytesPerSector = 0;
DWORD NumberOfFreeClusters = 0;
DWORD TotalNumberOfClusters = 0;
/*
if (GetFreeSpace((LPCTSTR)name, &SectorsPerCluster, &BytesPerSector, &NumberOfFreeClusters, &TotalNumberOfClusters)) {
fblock_size = BytesPerSector;
} else {
fprintf(stderr, "InnoDB: Warning: GetFreeSpace() failed on file %s\n", name);
os_file_handle_error_no_exit(name, "GetFreeSpace()", FALSE, __FILE__, __LINE__);
}
*/
}
#endif /* __WIN__*/
if (fblock_size > UNIV_PAGE_SIZE/2 || fblock_size < 512) {
fprintf(stderr, "InnoDB: Note: File system for file %s has "
"file block size %lu not supported for page_size %lu\n",
name, fblock_size, UNIV_PAGE_SIZE);
if (fblock_size < 512) {
fblock_size = 512;
} else {
fblock_size = UNIV_PAGE_SIZE/2;
}
fprintf(stderr, "InnoDB: Note: Using file block size %ld for file %s\n",
fblock_size, name);
}
return fblock_size;
}
|