/* Copyright (c) 2008, 2012, 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 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, 51 Franklin Street, Suite 500, Boston, MA 02110-1335 USA */ /** @file storage/perfschema/pfs_timer.cc Performance schema timers (implementation). */ #include "my_global.h" #include "pfs_timer.h" #include "my_rdtsc.h" enum_timer_name idle_timer= TIMER_NAME_MICROSEC; enum_timer_name wait_timer= TIMER_NAME_CYCLE; enum_timer_name stage_timer= TIMER_NAME_NANOSEC; enum_timer_name statement_timer= TIMER_NAME_NANOSEC; MY_TIMER_INFO pfs_timer_info; static ulonglong cycle_v0; static ulonglong nanosec_v0; static ulonglong microsec_v0; static ulonglong millisec_v0; static ulonglong tick_v0; static ulong cycle_to_pico; /* 1000 at 1 GHz, 333 at 3GHz, 250 at 4GHz */ static ulong nanosec_to_pico; /* In theory, 1 000 */ static ulong microsec_to_pico; /* In theory, 1 000 000 */ static ulong millisec_to_pico; /* In theory, 1 000 000 000, fits in uint32 */ static ulonglong tick_to_pico; /* 1e10 at 100 Hz, 1.666e10 at 60 Hz */ /* Indexed by enum enum_timer_name */ static struct time_normalizer to_pico_data[FIRST_TIMER_NAME + COUNT_TIMER_NAME]= { { 0, 0}, /* unused */ { 0, 0}, /* cycle */ { 0, 0}, /* nanosec */ { 0, 0}, /* microsec */ { 0, 0}, /* millisec */ { 0, 0} /* tick */ }; static inline ulong round_to_ulong(double value) { return (ulong) (value + 0.5); } static inline ulonglong round_to_ulonglong(double value) { return (ulonglong) (value + 0.5); } void init_timers(void) { double pico_frequency= 1.0e12; my_timer_init(&pfs_timer_info); cycle_v0= my_timer_cycles(); nanosec_v0= my_timer_nanoseconds(); microsec_v0= my_timer_microseconds(); millisec_v0= my_timer_milliseconds(); tick_v0= my_timer_ticks(); if (pfs_timer_info.cycles.frequency > 0) cycle_to_pico= round_to_ulong(pico_frequency/ (double)pfs_timer_info.cycles.frequency); else cycle_to_pico= 0; if (pfs_timer_info.nanoseconds.frequency > 0) nanosec_to_pico= round_to_ulong(pico_frequency/ (double)pfs_timer_info.nanoseconds.frequency); else nanosec_to_pico= 0; if (pfs_timer_info.microseconds.frequency > 0) microsec_to_pico= round_to_ulong(pico_frequency/ (double)pfs_timer_info.microseconds.frequency); else microsec_to_pico= 0; if (pfs_timer_info.milliseconds.frequency > 0) millisec_to_pico= round_to_ulong(pico_frequency/ (double)pfs_timer_info.milliseconds.frequency); else millisec_to_pico= 0; if (pfs_timer_info.ticks.frequency > 0) tick_to_pico= round_to_ulonglong(pico_frequency/ (double)pfs_timer_info.ticks.frequency); else tick_to_pico= 0; to_pico_data[TIMER_NAME_CYCLE].m_v0= cycle_v0; to_pico_data[TIMER_NAME_CYCLE].m_factor= cycle_to_pico; to_pico_data[TIMER_NAME_NANOSEC].m_v0= nanosec_v0; to_pico_data[TIMER_NAME_NANOSEC].m_factor= nanosec_to_pico; to_pico_data[TIMER_NAME_MICROSEC].m_v0= microsec_v0; to_pico_data[TIMER_NAME_MICROSEC].m_factor= microsec_to_pico; to_pico_data[TIMER_NAME_MILLISEC].m_v0= millisec_v0; to_pico_data[TIMER_NAME_MILLISEC].m_factor= millisec_to_pico; to_pico_data[TIMER_NAME_TICK].m_v0= tick_v0; to_pico_data[TIMER_NAME_TICK].m_factor= tick_to_pico; /* Depending on the platform and build options, some timers may not be available. Pick best replacements. */ /* For STAGE and STATEMENT, a timer with a fixed frequency is better. The prefered timer is nanosecond, or lower resolutions. */ if (nanosec_to_pico != 0) { /* Normal case. */ stage_timer= TIMER_NAME_NANOSEC; statement_timer= TIMER_NAME_NANOSEC; } else if (microsec_to_pico != 0) { /* Windows. */ stage_timer= TIMER_NAME_MICROSEC; statement_timer= TIMER_NAME_MICROSEC; } else if (millisec_to_pico != 0) { /* Robustness, no known cases. */ stage_timer= TIMER_NAME_MILLISEC; statement_timer= TIMER_NAME_MILLISEC; } else if (tick_to_pico != 0) { /* Robustness, no known cases. */ stage_timer= TIMER_NAME_TICK; statement_timer= TIMER_NAME_TICK; } else { /* Robustness, no known cases. */ stage_timer= TIMER_NAME_CYCLE; statement_timer= TIMER_NAME_CYCLE; } /* For IDLE, a timer with a fixed frequency is critical, as the CPU clock may slow down a lot if the server is completely idle. The prefered timer is microsecond, or lower resolutions. */ if (microsec_to_pico != 0) { /* Normal case. */ idle_timer= TIMER_NAME_MICROSEC; } else if (millisec_to_pico != 0) { /* Robustness, no known cases. */ idle_timer= TIMER_NAME_MILLISEC; } else if (tick_to_pico != 0) { /* Robustness, no known cases. */ idle_timer= TIMER_NAME_TICK; } else { /* Robustness, no known cases. */ idle_timer= TIMER_NAME_CYCLE; } } ulonglong get_timer_raw_value(enum_timer_name timer_name) { switch (timer_name) { case TIMER_NAME_CYCLE: return my_timer_cycles(); case TIMER_NAME_NANOSEC: return my_timer_nanoseconds(); case TIMER_NAME_MICROSEC: return my_timer_microseconds(); case TIMER_NAME_MILLISEC: return my_timer_milliseconds(); case TIMER_NAME_TICK: return my_timer_ticks(); default: DBUG_ASSERT(false); } return 0; } ulonglong get_timer_raw_value_and_function(enum_timer_name timer_name, timer_fct_t *fct) { switch (timer_name) { case TIMER_NAME_CYCLE: *fct= my_timer_cycles; return my_timer_cycles(); case TIMER_NAME_NANOSEC: *fct= my_timer_nanoseconds; return my_timer_nanoseconds(); case TIMER_NAME_MICROSEC: *fct= my_timer_microseconds; return my_timer_microseconds(); case TIMER_NAME_MILLISEC: *fct= my_timer_milliseconds; return my_timer_milliseconds(); case TIMER_NAME_TICK: *fct= my_timer_ticks; return my_timer_ticks(); default: *fct= NULL; DBUG_ASSERT(false); } return 0; } ulonglong get_timer_pico_value(enum_timer_name timer_name) { ulonglong result; switch (timer_name) { case TIMER_NAME_CYCLE: result= (my_timer_cycles() - cycle_v0) * cycle_to_pico; break; case TIMER_NAME_NANOSEC: result= (my_timer_nanoseconds() - nanosec_v0) * nanosec_to_pico; break; case TIMER_NAME_MICROSEC: result= (my_timer_microseconds() - microsec_v0) * microsec_to_pico; break; case TIMER_NAME_MILLISEC: result= (my_timer_milliseconds() - millisec_v0) * millisec_to_pico; break; case TIMER_NAME_TICK: result= (my_timer_ticks() - tick_v0) * tick_to_pico; break; default: result= 0; DBUG_ASSERT(false); } return result; } time_normalizer* time_normalizer::get(enum_timer_name timer_name) { uint index= static_cast (timer_name); DBUG_ASSERT(index >= FIRST_TIMER_NAME); DBUG_ASSERT(index <= LAST_TIMER_NAME); return & to_pico_data[index]; } void time_normalizer::to_pico(ulonglong start, ulonglong end, ulonglong *pico_start, ulonglong *pico_end, ulonglong *pico_wait) { if (start == 0) { *pico_start= 0; *pico_end= 0; *pico_wait= 0; } else { *pico_start= (start - m_v0) * m_factor; if (end == 0) { *pico_end= 0; *pico_wait= 0; } else { *pico_end= (end - m_v0) * m_factor; *pico_wait= (end - start) * m_factor; } } }