mariadb/storage/perfschema/pfs_user.cc

/* Copyright (c) 2010, 2015, 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 Street, Fifth Floor, Boston, MA 02110-1335  USA */

/**
  @file storage/perfschema/pfs_user.cc
  Performance schema user (implementation).
*/

#include "my_global.h"
#include "my_sys.h"
#include "pfs.h"
#include "pfs_stat.h"
#include "pfs_instr.h"
#include "pfs_setup_actor.h"
#include "pfs_user.h"
#include "pfs_global.h"
#include "pfs_instr_class.h"

/**
  @addtogroup Performance_schema_buffers
  @{
*/

ulong user_max;
ulong user_lost;

PFS_user *user_array= NULL;

static PFS_single_stat *user_instr_class_waits_array= NULL;
static PFS_stage_stat *user_instr_class_stages_array= NULL;
static PFS_statement_stat *user_instr_class_statements_array= NULL;

LF_HASH user_hash;
static bool user_hash_inited= false;

/**
  Initialize the user buffers.
  @param param                        sizing parameters
  @return 0 on success
*/
int init_user(const PFS_global_param *param)
{
  uint index;

  user_max= param->m_user_sizing;

  user_array= NULL;
  user_instr_class_waits_array= NULL;
  user_instr_class_stages_array= NULL;
  user_instr_class_statements_array= NULL;
  uint waits_sizing= user_max * wait_class_max;
  uint stages_sizing= user_max * stage_class_max;
  uint statements_sizing= user_max * statement_class_max;

  if (user_max > 0)
  {
    user_array= PFS_MALLOC_ARRAY(user_max, sizeof(PFS_user), PFS_user,
                                 MYF(MY_ZEROFILL));
    if (unlikely(user_array == NULL))
      return 1;
  }

  if (waits_sizing > 0)
  {
    user_instr_class_waits_array=
      PFS_connection_slice::alloc_waits_slice(waits_sizing);
    if (unlikely(user_instr_class_waits_array == NULL))
      return 1;
  }

  if (stages_sizing > 0)
  {
    user_instr_class_stages_array=
      PFS_connection_slice::alloc_stages_slice(stages_sizing);
    if (unlikely(user_instr_class_stages_array == NULL))
      return 1;
  }

  if (statements_sizing > 0)
  {
    user_instr_class_statements_array=
      PFS_connection_slice::alloc_statements_slice(statements_sizing);
    if (unlikely(user_instr_class_statements_array == NULL))
      return 1;
  }

  for (index= 0; index < user_max; index++)
  {
    user_array[index].m_instr_class_waits_stats=
      &user_instr_class_waits_array[index * wait_class_max];
    user_array[index].m_instr_class_stages_stats=
      &user_instr_class_stages_array[index * stage_class_max];
    user_array[index].m_instr_class_statements_stats=
      &user_instr_class_statements_array[index * statement_class_max];
  }

  return 0;
}

/** Cleanup all the user buffers. */
void cleanup_user(void)
{
  pfs_free(user_array);
  user_array= NULL;
  pfs_free(user_instr_class_waits_array);
  user_instr_class_waits_array= NULL;
  pfs_free(user_instr_class_stages_array);
  user_instr_class_stages_array= NULL;
  pfs_free(user_instr_class_statements_array);
  user_instr_class_statements_array= NULL;
  user_max= 0;
}

C_MODE_START
static uchar *user_hash_get_key(const uchar *entry, size_t *length,
                                my_bool)
{
  const PFS_user * const *typed_entry;
  const PFS_user *user;
  const void *result;
  typed_entry= reinterpret_cast<const PFS_user* const *> (entry);
  DBUG_ASSERT(typed_entry != NULL);
  user= *typed_entry;
  DBUG_ASSERT(user != NULL);
  *length= user->m_key.m_key_length;
  result= user->m_key.m_hash_key;
  return const_cast<uchar*> (reinterpret_cast<const uchar*> (result));
}
C_MODE_END

/**
  Initialize the user hash.
  @return 0 on success
*/
int init_user_hash(void)
{
  if ((! user_hash_inited) && (user_max > 0))
  {
    lf_hash_init(&user_hash, sizeof(PFS_user*), LF_HASH_UNIQUE,
                 0, 0, user_hash_get_key, &my_charset_bin);
    /* user_hash.size= user_max; */
    user_hash_inited= true;
  }
  return 0;
}

/** Cleanup the user hash. */
void cleanup_user_hash(void)
{
  if (user_hash_inited)
  {
    lf_hash_destroy(&user_hash);
    user_hash_inited= false;
  }
}

static LF_PINS* get_user_hash_pins(PFS_thread *thread)
{
  if (unlikely(thread->m_user_hash_pins == NULL))
  {
    if (! user_hash_inited)
      return NULL;
    thread->m_user_hash_pins= lf_hash_get_pins(&user_hash);
  }
  return thread->m_user_hash_pins;
}

static void set_user_key(PFS_user_key *key,
                         const char *user, uint user_length)
{
  DBUG_ASSERT(user_length <= USERNAME_LENGTH);

  char *ptr= &key->m_hash_key[0];
  if (user_length > 0)
  {
    memcpy(ptr, user, user_length);
    ptr+= user_length;
  }
  ptr[0]= 0;
  ptr++;
  key->m_key_length= (uint)(ptr - &key->m_hash_key[0]);
}

PFS_user *
find_or_create_user(PFS_thread *thread,
                    const char *username, uint username_length)
{
  if (user_max == 0)
  {
    user_lost++;
    return NULL;
  }

  LF_PINS *pins= get_user_hash_pins(thread);
  if (unlikely(pins == NULL))
  {
    user_lost++;
    return NULL;
  }

  PFS_user_key key;
  set_user_key(&key, username, username_length);

  PFS_user **entry;
  uint retry_count= 0;
  const uint retry_max= 3;

search:
  entry= reinterpret_cast<PFS_user**>
    (lf_hash_search(&user_hash, pins,
                    key.m_hash_key, key.m_key_length));
  if (entry && (entry != MY_ERRPTR))
  {
    PFS_user *pfs;
    pfs= *entry;
    pfs->inc_refcount();
    lf_hash_search_unpin(pins);
    return pfs;
  }

  lf_hash_search_unpin(pins);

  PFS_scan scan;
  uint random= randomized_index(username, user_max);

  for (scan.init(random, user_max);
       scan.has_pass();
       scan.next_pass())
  {
    PFS_user *pfs= user_array + scan.first();
    PFS_user *pfs_last= user_array + scan.last();
    for ( ; pfs < pfs_last; pfs++)
    {
      if (pfs->m_lock.is_free())
      {
        if (pfs->m_lock.free_to_dirty())
        {
          pfs->m_key= key;
          if (username_length > 0)
            pfs->m_username= &pfs->m_key.m_hash_key[0];
          else
            pfs->m_username= NULL;
          pfs->m_username_length= username_length;

          pfs->init_refcount();
          pfs->reset_stats();
          pfs->m_disconnected_count= 0;

          int res;
          res= lf_hash_insert(&user_hash, pins, &pfs);
          if (likely(res == 0))
          {
            pfs->m_lock.dirty_to_allocated();
            return pfs;
          }

          pfs->m_lock.dirty_to_free();

          if (res > 0)
          {
            if (++retry_count > retry_max)
            {
              user_lost++;
              return NULL;
            }
            goto search;
          }

          user_lost++;
          return NULL;
        }
      }
    }
  }

  user_lost++;
  return NULL;
}

void PFS_user::aggregate()
{
  aggregate_waits();
  aggregate_stages();
  aggregate_statements();
  aggregate_stats();
}

void PFS_user::aggregate_waits()
{
  /* No parent to aggregate to, clean the stats */
  reset_waits_stats();
}

void PFS_user::aggregate_stages()
{
  /* No parent to aggregate to, clean the stats */
  reset_stages_stats();
}

void PFS_user::aggregate_statements()
{
  /* No parent to aggregate to, clean the stats */
  reset_statements_stats();
}

void PFS_user::aggregate_stats()
{
  /* No parent to aggregate to, clean the stats */
  m_disconnected_count= 0;
}

void PFS_user::release()
{
  dec_refcount();
}

PFS_user *sanitize_user(PFS_user *unsafe)
{
  if ((&user_array[0] <= unsafe) &&
      (unsafe < &user_array[user_max]))
    return unsafe;
  return NULL;
}

void purge_user(PFS_thread *thread, PFS_user *user)
{
  LF_PINS *pins= get_user_hash_pins(thread);
  if (unlikely(pins == NULL))
    return;

  PFS_user **entry;
  entry= reinterpret_cast<PFS_user**>
    (lf_hash_search(&user_hash, pins,
                    user->m_key.m_hash_key, user->m_key.m_key_length));
  if (entry && (entry != MY_ERRPTR))
  {
    DBUG_ASSERT(*entry == user);
    if (user->get_refcount() == 0)
    {
      lf_hash_delete(&user_hash, pins,
                     user->m_key.m_hash_key, user->m_key.m_key_length);
      user->m_lock.allocated_to_free();
    }
  }

  lf_hash_search_unpin(pins);
}

/** Purge non connected users, reset stats of connected users. */
void purge_all_user(void)
{
  PFS_thread *thread= PFS_thread::get_current_thread();
  if (unlikely(thread == NULL))
    return;

  PFS_user *pfs= user_array;
  PFS_user *pfs_last= user_array + user_max;

  for ( ; pfs < pfs_last; pfs++)
  {
    if (pfs->m_lock.is_populated())
    {
      pfs->aggregate();
      if (pfs->get_refcount() == 0)
        purge_user(thread, pfs);
    }
  }
}

/** @} */