用于EagleEye3.0 规则集漏报和误报测试的示例项目,项目收集于github和gitee
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/* Copyright (c) 2012, 2019, Oracle and/or its affiliates. All rights reserved.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License, version 2.0,
as published by the Free Software Foundation.
This program is also distributed with certain software (including
but not limited to OpenSSL) that is licensed under separate terms,
as designated in a particular file or component or in included license
documentation. The authors of MySQL hereby grant you an additional
permission to link the program and your derivative works with the
separately licensed software that they have included with MySQL.
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, version 2.0, 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 St, Fifth Floor, Boston, MA 02110-1301 USA */
#include <stdio.h>
#include <string.h>
#include <sys/types.h>
#include <algorithm>
#include <atomic>
#include "libbinlogevents/include/control_events.h"
#include "m_string.h"
#include "my_dbug.h"
#include "my_inttypes.h"
#include "my_macros.h"
#include "my_thread.h"
#include "mysql/psi/mysql_mutex.h"
#include "sql/rpl_gtid.h"
#include "typelib.h"
struct mysql_mutex_t;
#ifdef MYSQL_SERVER
#include "mysql/thread_type.h"
#include "mysqld_error.h" // ER_*
#include "sql/binlog.h"
#include "sql/current_thd.h"
#include "sql/rpl_msr.h"
#include "sql/sql_class.h" // THD
#include "sql/sql_error.h"
#include "storage/perfschema/pfs_instr_class.h" // gtid_monitoring_getsystime
#endif // ifdef MYSQL_SERVER
#ifndef MYSQL_SERVER
#include "client/mysqlbinlog.h"
#endif
// Todo: move other global gtid variable declarations here.
Checkable_rwlock *gtid_mode_lock = nullptr;
std::atomic<ulong> gtid_mode_counter;
ulong _gtid_mode;
const char *gtid_mode_names[] = {"OFF", "OFF_PERMISSIVE", "ON_PERMISSIVE", "ON",
NullS};
TYPELIB gtid_mode_typelib = {array_elements(gtid_mode_names) - 1, "",
gtid_mode_names, nullptr};
#ifdef MYSQL_SERVER
enum_gtid_mode get_gtid_mode(enum_gtid_mode_lock have_lock) {
switch (have_lock) {
case GTID_MODE_LOCK_NONE:
global_sid_lock->rdlock();
break;
case GTID_MODE_LOCK_SID:
global_sid_lock->assert_some_lock();
break;
case GTID_MODE_LOCK_CHANNEL_MAP:
channel_map.assert_some_lock();
break;
case GTID_MODE_LOCK_GTID_MODE:
gtid_mode_lock->assert_some_lock();
/*
This lock is currently not used explicitly by any of the places
that calls get_gtid_mode. Still it would be valid for a caller to
use it to protect reads of GTID_MODE, so we keep the code here in
case it is needed in the future.
case GTID_MODE_LOCK_LOG:
mysql_mutex_assert_owner(mysql_bin_log.get_log_lock());
break;
*/
}
enum_gtid_mode ret = (enum_gtid_mode)_gtid_mode;
if (have_lock == GTID_MODE_LOCK_NONE) global_sid_lock->unlock();
return ret;
}
#endif
ulong _gtid_consistency_mode;
const char *gtid_consistency_mode_names[] = {"OFF", "ON", "WARN", NullS};
TYPELIB gtid_consistency_mode_typelib = {
array_elements(gtid_consistency_mode_names) - 1, "",
gtid_consistency_mode_names, nullptr};
#ifdef MYSQL_SERVER
enum_gtid_consistency_mode get_gtid_consistency_mode() {
global_sid_lock->assert_some_lock();
return (enum_gtid_consistency_mode)_gtid_consistency_mode;
}
#endif
enum_return_status Gtid::parse(Sid_map *sid_map, const char *text) {
DBUG_TRACE;
rpl_sid sid;
const char *s = text;
SKIP_WHITESPACE();
// parse sid
if (sid.parse(s, binary_log::Uuid::TEXT_LENGTH) == 0) {
rpl_sidno sidno_var = sid_map->add_sid(sid);
if (sidno_var <= 0) RETURN_REPORTED_ERROR;
s += binary_log::Uuid::TEXT_LENGTH;
SKIP_WHITESPACE();
// parse colon
if (*s == ':') {
s++;
SKIP_WHITESPACE();
// parse gno
rpl_gno gno_var = parse_gno(&s);
if (gno_var > 0) {
SKIP_WHITESPACE();
if (*s == '\0') {
sidno = sidno_var;
gno = gno_var;
RETURN_OK;
} else
DBUG_PRINT("info", ("expected end of string, found garbage '%.80s' "
"at char %d in '%s'",
s, (int)(s - text), text));
} else
DBUG_PRINT("info", ("GNO was zero or invalid (%lld) at char %d in '%s'",
gno_var, (int)(s - text), text));
} else
DBUG_PRINT("info",
("missing colon at char %d in '%s'", (int)(s - text), text));
} else
DBUG_PRINT("info",
("not a uuid at char %d in '%s'", (int)(s - text), text));
BINLOG_ERROR(("Malformed GTID specification: %.200s", text),
(ER_MALFORMED_GTID_SPECIFICATION, MYF(0), text));
RETURN_REPORTED_ERROR;
}
int Gtid::to_string(const rpl_sid &sid, char *buf) const {
DBUG_TRACE;
char *s = buf + sid.to_string(buf);
*s = ':';
s++;
s += format_gno(s, gno);
return (int)(s - buf);
}
int Gtid::to_string(const Sid_map *sid_map, char *buf, bool need_lock) const {
DBUG_TRACE;
int ret;
if (sid_map != nullptr) {
Checkable_rwlock *lock = sid_map->get_sid_lock();
if (lock) {
if (need_lock)
lock->rdlock();
else
lock->assert_some_lock();
}
const rpl_sid &sid = sid_map->sidno_to_sid(sidno);
if (lock && need_lock) lock->unlock();
ret = to_string(sid, buf);
} else {
#ifdef DBUG_OFF
/*
NULL is only allowed in debug mode, since the sidno does not
make sense for users but is useful to include in debug
printouts. Therefore, we want to ASSERT(0) in non-debug mode.
Since there is no ASSERT in non-debug mode, we use abort
instead.
*/
abort();
#endif
ret = sprintf(buf, "%d:%lld", sidno, gno);
}
return ret;
}
bool Gtid::is_valid(const char *text) {
DBUG_TRACE;
const char *s = text;
SKIP_WHITESPACE();
if (!rpl_sid::is_valid(s, binary_log::Uuid::TEXT_LENGTH)) {
DBUG_PRINT("info",
("not a uuid at char %d in '%s'", (int)(s - text), text));
return false;
}
s += binary_log::Uuid::TEXT_LENGTH;
SKIP_WHITESPACE();
if (*s != ':') {
DBUG_PRINT("info",
("missing colon at char %d in '%s'", (int)(s - text), text));
return false;
}
s++;
SKIP_WHITESPACE();
if (parse_gno(&s) <= 0) {
DBUG_PRINT("info", ("GNO was zero or invalid at char %d in '%s'",
(int)(s - text), text));
return false;
}
SKIP_WHITESPACE();
if (*s != 0) {
DBUG_PRINT("info", ("expected end of string, found garbage '%.80s' "
"at char %d in '%s'",
s, (int)(s - text), text));
return false;
}
return true;
}
#ifndef DBUG_OFF
void check_return_status(enum_return_status status, const char *action,
const char *status_name, int allow_unreported) {
if (status != RETURN_STATUS_OK) {
DBUG_ASSERT(allow_unreported || status == RETURN_STATUS_REPORTED_ERROR);
if (status == RETURN_STATUS_REPORTED_ERROR) {
#if defined(MYSQL_SERVER) && !defined(DBUG_OFF)
THD *thd = current_thd;
/*
We create a new system THD with 'SYSTEM_THREAD_COMPRESS_GTID_TABLE'
when initializing gtid state by fetching gtids during server startup,
so we can check on it before diagnostic area is active and skip the
assert in this case. We assert that diagnostic area logged the error
outside server startup since the assert is realy useful.
*/
DBUG_ASSERT(thd == nullptr ||
thd->get_stmt_da()->status() == Diagnostics_area::DA_ERROR ||
(thd->get_stmt_da()->status() == Diagnostics_area::DA_EMPTY &&
thd->system_thread == SYSTEM_THREAD_COMPRESS_GTID_TABLE));
#endif
}
DBUG_PRINT("info", ("%s error %d (%s)", action, status, status_name));
}
}
#endif // ! DBUG_OFF
#ifdef MYSQL_SERVER
rpl_sidno get_sidno_from_global_sid_map(rpl_sid sid) {
DBUG_TRACE;
global_sid_lock->rdlock();
rpl_sidno sidno = global_sid_map->add_sid(sid);
global_sid_lock->unlock();
return sidno;
}
rpl_gno get_last_executed_gno(rpl_sidno sidno) {
DBUG_TRACE;
global_sid_lock->rdlock();
rpl_gno gno = gtid_state->get_last_executed_gno(sidno);
global_sid_lock->unlock();
return gno;
}
Trx_monitoring_info::Trx_monitoring_info() { clear(); }
Trx_monitoring_info::Trx_monitoring_info(const Trx_monitoring_info &info) {
if ((is_info_set = info.is_info_set)) {
gtid = info.gtid;
original_commit_timestamp = info.original_commit_timestamp;
immediate_commit_timestamp = info.immediate_commit_timestamp;
start_time = info.start_time;
end_time = info.end_time;
skipped = info.skipped;
last_transient_error_number = info.last_transient_error_number;
strcpy(last_transient_error_message, info.last_transient_error_message);
last_transient_error_timestamp = info.last_transient_error_timestamp;
transaction_retries = info.transaction_retries;
is_retrying = info.is_retrying;
}
}
void Trx_monitoring_info::clear() {
gtid = {0, 0};
original_commit_timestamp = 0;
immediate_commit_timestamp = 0;
start_time = 0;
end_time = 0;
skipped = false;
is_info_set = false;
last_transient_error_number = 0;
last_transient_error_message[0] = '\0';
last_transient_error_timestamp = 0;
transaction_retries = 0;
is_retrying = false;
}
void Trx_monitoring_info::copy_to_ps_table(Sid_map *sid_map, char *gtid_arg,
uint *gtid_length_arg,
ulonglong *original_commit_ts_arg,
ulonglong *immediate_commit_ts_arg,
ulonglong *start_time_arg) {
DBUG_ASSERT(sid_map);
DBUG_ASSERT(gtid_arg);
DBUG_ASSERT(gtid_length_arg);
DBUG_ASSERT(original_commit_ts_arg);
DBUG_ASSERT(immediate_commit_ts_arg);
DBUG_ASSERT(start_time_arg);
if (is_info_set) {
// The trx_monitoring_info is populated
if (gtid.is_empty()) {
// The transaction is anonymous
memcpy(gtid_arg, "ANONYMOUS", 10);
*gtid_length_arg = 9;
} else {
// The GTID is set
Checkable_rwlock *sid_lock = sid_map->get_sid_lock();
sid_lock->rdlock();
*gtid_length_arg = gtid.to_string(sid_map, gtid_arg);
sid_lock->unlock();
}
*original_commit_ts_arg = original_commit_timestamp;
*immediate_commit_ts_arg = immediate_commit_timestamp;
*start_time_arg = start_time / 10;
} else {
// This monitoring info is not populated, so let's zero the input
memcpy(gtid_arg, "", 1);
*gtid_length_arg = 0;
*original_commit_ts_arg = 0;
*immediate_commit_ts_arg = 0;
*start_time_arg = 0;
}
}
void Trx_monitoring_info::copy_to_ps_table(Sid_map *sid_map, char *gtid_arg,
uint *gtid_length_arg,
ulonglong *original_commit_ts_arg,
ulonglong *immediate_commit_ts_arg,
ulonglong *start_time_arg,
ulonglong *end_time_arg) {
DBUG_ASSERT(end_time_arg);
*end_time_arg = is_info_set ? end_time / 10 : 0;
copy_to_ps_table(sid_map, gtid_arg, gtid_length_arg, original_commit_ts_arg,
immediate_commit_ts_arg, start_time_arg);
}
void Trx_monitoring_info::copy_to_ps_table(
Sid_map *sid_map, char *gtid_arg, uint *gtid_length_arg,
ulonglong *original_commit_ts_arg, ulonglong *immediate_commit_ts_arg,
ulonglong *start_time_arg, uint *last_transient_errno_arg,
char *last_transient_errmsg_arg, uint *last_transient_errmsg_length_arg,
ulonglong *last_transient_timestamp_arg, ulong *retries_count_arg) {
DBUG_ASSERT(last_transient_errno_arg);
DBUG_ASSERT(last_transient_errmsg_arg);
DBUG_ASSERT(last_transient_errmsg_length_arg);
DBUG_ASSERT(last_transient_timestamp_arg);
DBUG_ASSERT(retries_count_arg);
if (is_info_set) {
*last_transient_errno_arg = last_transient_error_number;
strcpy(last_transient_errmsg_arg, last_transient_error_message);
*last_transient_errmsg_length_arg = strlen(last_transient_error_message);
*last_transient_timestamp_arg = last_transient_error_timestamp / 10;
*retries_count_arg = transaction_retries;
} else {
*last_transient_errno_arg = 0;
memcpy(last_transient_errmsg_arg, "", 1);
*last_transient_errmsg_length_arg = 0;
*last_transient_timestamp_arg = 0;
*retries_count_arg = 0;
}
copy_to_ps_table(sid_map, gtid_arg, gtid_length_arg, original_commit_ts_arg,
immediate_commit_ts_arg, start_time_arg);
}
void Trx_monitoring_info::copy_to_ps_table(
Sid_map *sid_map, char *gtid_arg, uint *gtid_length_arg,
ulonglong *original_commit_ts_arg, ulonglong *immediate_commit_ts_arg,
ulonglong *start_time_arg, ulonglong *end_time_arg,
uint *last_transient_errno_arg, char *last_transient_errmsg_arg,
uint *last_transient_errmsg_length_arg,
ulonglong *last_transient_timestamp_arg, ulong *retries_count_arg) {
DBUG_ASSERT(end_time_arg);
*end_time_arg = is_info_set ? end_time / 10 : 0;
copy_to_ps_table(sid_map, gtid_arg, gtid_length_arg, original_commit_ts_arg,
immediate_commit_ts_arg, start_time_arg,
last_transient_errno_arg, last_transient_errmsg_arg,
last_transient_errmsg_length_arg,
last_transient_timestamp_arg, retries_count_arg);
}
Gtid_monitoring_info::Gtid_monitoring_info(mysql_mutex_t *atomic_mutex_arg)
: atomic_mutex(atomic_mutex_arg) {
processing_trx = new Trx_monitoring_info;
last_processed_trx = new Trx_monitoring_info;
}
Gtid_monitoring_info::~Gtid_monitoring_info() {
delete last_processed_trx;
delete processing_trx;
}
void Gtid_monitoring_info::atomic_lock() {
if (atomic_mutex == nullptr) {
bool expected = false;
while (!atomic_locked.compare_exchange_weak(expected, true)) {
/*
On exchange failures, the atomic_locked value (true) is set
to the expected variable. It needs to be reset again.
*/
expected = false;
/*
All "atomic" operations on this object are based on copying
variable contents and setting values. They should not take long.
*/
my_thread_yield();
}
#ifndef DBUG_OFF
DBUG_ASSERT(!is_locked);
is_locked = true;
#endif
} else {
// If this object is relying on a mutex, just ensure it was acquired.
mysql_mutex_assert_owner(atomic_mutex)
}
}
void Gtid_monitoring_info::atomic_unlock() {
if (atomic_mutex == nullptr) {
#ifndef DBUG_OFF
DBUG_ASSERT(is_locked);
is_locked = false;
#endif
atomic_locked = false;
} else
mysql_mutex_assert_owner(atomic_mutex)
}
void Gtid_monitoring_info::clear() {
atomic_lock();
processing_trx->clear();
last_processed_trx->clear();
atomic_unlock();
}
void Gtid_monitoring_info::clear_processing_trx() {
atomic_lock();
processing_trx->clear();
atomic_unlock();
}
void Gtid_monitoring_info::clear_last_processed_trx() {
atomic_lock();
last_processed_trx->clear();
atomic_unlock();
}
void Gtid_monitoring_info::start(Gtid gtid_arg, ulonglong original_ts_arg,
ulonglong immediate_ts_arg, bool skipped_arg) {
/**
When a new transaction starts processing, we reset all the information from
the previous processing_trx and fetch the current timestamp as the new
start_time.
*/
if (!processing_trx->gtid.equals(gtid_arg) || !processing_trx->is_retrying) {
/* Collect current timestamp before the atomic operation */
ulonglong start_time = gtid_monitoring_getsystime();
atomic_lock();
processing_trx->gtid = gtid_arg;
processing_trx->original_commit_timestamp = original_ts_arg;
processing_trx->immediate_commit_timestamp = immediate_ts_arg;
processing_trx->start_time = start_time;
processing_trx->end_time = 0;
processing_trx->skipped = skipped_arg;
processing_trx->is_info_set = true;
processing_trx->last_transient_error_number = 0;
processing_trx->last_transient_error_message[0] = '\0';
processing_trx->last_transient_error_timestamp = 0;
processing_trx->transaction_retries = 0;
atomic_unlock();
} else {
/**
If the transaction is being retried, only update the skipped field
because it determines if the information will be kept after it finishes
executing.
*/
atomic_lock();
processing_trx->skipped = skipped_arg;
atomic_unlock();
}
}
void Gtid_monitoring_info::finish() {
/* Collect current timestamp before the atomic operation */
ulonglong end_time = gtid_monitoring_getsystime();
atomic_lock();
processing_trx->end_time = end_time;
/*
We only swap if the transaction was not skipped.
Notice that only applier thread set the skipped variable to true.
*/
if (!processing_trx->skipped) std::swap(processing_trx, last_processed_trx);
processing_trx->clear();
atomic_unlock();
}
void Gtid_monitoring_info::copy_info_to(
Trx_monitoring_info *processing_dest,
Trx_monitoring_info *last_processed_dest) {
atomic_lock();
*processing_dest = *processing_trx;
*last_processed_dest = *last_processed_trx;
atomic_unlock();
}
void Gtid_monitoring_info::copy_info_to(Gtid_monitoring_info *dest) {
copy_info_to(dest->processing_trx, dest->last_processed_trx);
}
bool Gtid_monitoring_info::is_processing_trx_set() {
/*
This function is only called by threads about to update the monitoring
information. It should be safe to collect this information without
acquiring locks.
*/
return processing_trx->is_info_set;
}
const Gtid *Gtid_monitoring_info::get_processing_trx_gtid() {
/*
This function is only called by relay log recovery/queuing.
*/
DBUG_ASSERT(atomic_mutex != nullptr);
mysql_mutex_assert_owner(atomic_mutex);
return &processing_trx->gtid;
}
void Gtid_monitoring_info::store_transient_error(
uint transient_errno_arg, const char *transient_err_message_arg,
ulong trans_retries_arg) {
ulonglong retry_timestamp = gtid_monitoring_getsystime();
processing_trx->is_retrying = true;
atomic_lock();
processing_trx->transaction_retries = trans_retries_arg;
processing_trx->last_transient_error_number = transient_errno_arg;
snprintf(processing_trx->last_transient_error_message,
sizeof(processing_trx->last_transient_error_message), "%.*s",
MAX_SLAVE_ERRMSG - 1, transient_err_message_arg);
processing_trx->last_transient_error_timestamp = retry_timestamp;
atomic_unlock();
}
#endif // ifdef MYSQL_SERVER