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//========================================================================== // // time.cxx // // POSIX time functions implementation // //========================================================================== // ####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Free Software Foundation, Inc. // // eCos 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; either version 2 or (at your option) any later // version. // // eCos 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 eCos; if not, write to the Free Software Foundation, Inc., // 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. // // As a special exception, if other files instantiate templates or use // macros or inline functions from this file, or you compile this file // and link it with other works to produce a work based on this file, // this file does not by itself cause the resulting work to be covered by // the GNU General Public License. However the source code for this file // must still be made available in accordance with section (3) of the GNU // General Public License v2. // // This exception does not invalidate any other reasons why a work based // on this file might be covered by the GNU General Public License. // ------------------------------------------- // ####ECOSGPLCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): nickg // Contributors: nickg // Date: 2000-03-27 // Purpose: POSIX time functions implementation // Description: This file contains the implementation of the POSIX time // functions. // // // //####DESCRIPTIONEND#### // //========================================================================== #include <pkgconf/posix.h> #include <pkgconf/hal.h> #include <pkgconf/kernel.h> #include <cyg/kernel/ktypes.h> // base kernel types #include <cyg/infra/cyg_trac.h> // tracing macros #include <cyg/infra/cyg_ass.h> // assertion macros #include "pprivate.h" // POSIX private header #include <time.h> // our header #include <sys/time.h> #include <cyg/kernel/thread.hxx> #include <cyg/kernel/clock.hxx> #include <cyg/kernel/kapi.h> #include <cyg/kernel/thread.inl> #include <cyg/kernel/clock.inl> // ------------------------------------------------------------------------- // Internal definitions // Handle entry to a pthread package function. #define TIME_ENTRY() CYG_REPORT_FUNCTYPE( "returning %d" ); // Do a time package defined return. This requires the error code // to be placed in errno, and if it is non-zero, -1 returned as the // result of the function. This also gives us a place to put any // generic tidyup handling needed for things like signal delivery and // cancellation. #define TIME_RETURN(err) \ CYG_MACRO_START \ int __retval = 0; \ if( err != 0 ) __retval = -1, errno = err; \ CYG_REPORT_RETVAL( __retval ); \ return __retval; \ CYG_MACRO_END //========================================================================== // Timer control structures #ifdef CYGPKG_POSIX_TIMERS typedef struct { timer_t id; // id value for checking Cyg_Alarm *alarm; // eCos alarm object cyg_bool armed; // is alarm enabled? cyg_bool pending; // is expiry pending? int overrun; // Overrun count struct sigevent sigev; // Sigevent to raise on expiry // Space for alarm object cyg_uint8 alarm_obj[sizeof(Cyg_Alarm)]; } posix_timer; // Mutex for controlling access to shared data structures static Cyg_Mutex timer_mutex CYGBLD_POSIX_INIT; // Array of timer objects static posix_timer timer_table[_POSIX_TIMER_MAX]; // Index of next timer to allocate from array static int timer_next = 0; // This is used to make timer_t values unique even when reusing // a table slot. This allows _POSIX_TIMER_MAX to range // up to 1024. #define TIMER_ID_COOKIE_INC 0x00000400 #define TIMER_ID_COOKIE_MASK (TIMER_ID_COOKIE_INC-1) static timer_t timer_id_cookie = TIMER_ID_COOKIE_INC; #endif // ifdef CYGPKG_POSIX_TIMERS //----------------------------------------------------------------------------- // new operator to allow us to invoke the constructor on // posix_timer.alarm_obj. inline void *operator new(size_t size, cyg_uint8 *ptr) { return (void *)ptr; }; //========================================================================== // Time conversion variables // These are used to interconvert between ticks and POSIX timespecs. // Converters from sec and ns to ticks static struct Cyg_Clock::converter ns_converter, sec_converter; // Converters from ticks to sec and ns static struct Cyg_Clock::converter ns_inverter, sec_inverter; // tickns is the number of nanoseconds per tick. static cyg_tick_count tickns; static cyg_bool converters_initialized = false; //========================================================================== // Local functions static void init_converters() { if( !converters_initialized ) { // Create the converters we need. Cyg_Clock::real_time_clock->get_other_to_clock_converter( 1, &ns_converter ); Cyg_Clock::real_time_clock->get_other_to_clock_converter( 1000000000, &sec_converter ); Cyg_Clock::real_time_clock->get_clock_to_other_converter( 1, &ns_inverter ); Cyg_Clock::real_time_clock->get_clock_to_other_converter( 1000000000, &sec_inverter ); tickns = Cyg_Clock::convert( 1, &ns_inverter ); converters_initialized = true; } } static cyg_bool valid_timespec( const struct timespec *tp ) { // Fail a NULL pointer if( tp == NULL ) return false; // Fail illegal nanosecond values if( tp->tv_nsec < 0 || tp->tv_nsec > 1000000000 ) return false; return true; } externC cyg_tick_count cyg_timespec_to_ticks( const struct timespec *tp, cyg_bool roundup) { init_converters(); // Short circuit zero timespecs if( tp->tv_sec == 0 && tp->tv_nsec == 0 ) { return 0; } // Convert the seconds field to ticks. cyg_tick_count ticks = Cyg_Clock::convert( tp->tv_sec, &sec_converter ); if( roundup ) { // Convert the nanoseconds. We add (tickns-1) to round the value up // to the next whole tick. ticks += Cyg_Clock::convert( (cyg_tick_count)tp->tv_nsec+tickns-1, &ns_converter ); } else { // Convert the nanoseconds. This will round down to nearest whole tick. ticks += Cyg_Clock::convert( (cyg_tick_count)tp->tv_nsec, &ns_converter ); } return ticks; } externC void cyg_ticks_to_timespec( cyg_tick_count ticks, struct timespec *tp ) { init_converters(); // short circuit zero ticks values if( ticks == 0 ) { tp->tv_sec = 0; tp->tv_nsec = 0; return; } // Convert everything to nanoseconds with a long long. For 64-bits, // this is safe for 544 years. We'll think about it more closer to // the time... unsigned long long nsecs = Cyg_Clock::convert( ticks, &ns_inverter ); tp->tv_sec = (long)(nsecs / 1000000000ll); tp->tv_nsec = (long)(nsecs % 1000000000ll); CYG_POSTCONDITION(valid_timespec(tp), "Failed to make valid timespec!"); } //========================================================================== // Startup routine. externC void cyg_posix_clock_start() { init_converters(); } #ifdef CYGPKG_POSIX_TIMERS //========================================================================== // Alarm action routine // This is called each time an alarm set up by a timer expires. static void alarm_action( Cyg_Alarm *alarm, CYG_ADDRWORD data ) { posix_timer *timer = (posix_timer *)data; if( timer->pending ) { // If the pending flag is already set, count an overrun and // do not bother to try and deliver the expiry. timer->overrun++; } else { if( timer->sigev.sigev_notify == SIGEV_SIGNAL ) { // Set the expiry pending and wake a thread to // deliver the signal. timer->pending = true; sigset_t mask; sigemptyset( &mask ); sigaddset( &mask, timer->sigev.sigev_signo ); cyg_posix_signal_sigwait(); cyg_posix_pthread_release_thread( &mask ); } else if( timer->sigev.sigev_notify == SIGEV_THREAD ) { // Thread style notification // FIXME: implement SIGEV_THREAD } // else do nothing } } //========================================================================== // Timer ASR routine externC void cyg_posix_timer_asr( pthread_info *self ) { // Loop over the timers looking for any that have an // expiry pending and call cyg_sigqueue() for each. for( int i = 0; i < _POSIX_TIMER_MAX; i++ ) { posix_timer *timer = &timer_table[i]; if( timer->id != 0 && timer->pending ) { timer->pending = false; // Call into signal subsystem... cyg_sigqueue( &timer->sigev, SI_TIMER ); timer->overrun = 0; } } } #endif // ifdef CYGPKG_POSIX_TIMERS //========================================================================== // Clock functions //----------------------------------------------------------------------------- // Set the clocks current time externC int clock_settime( clockid_t clock_id, const struct timespec *tp) { TIME_ENTRY(); if( clock_id != CLOCK_REALTIME ) TIME_RETURN(EINVAL); if( !valid_timespec( tp ) ) TIME_RETURN(EINVAL); cyg_tick_count ticks = cyg_timespec_to_ticks( tp ); Cyg_Clock::real_time_clock->set_value( ticks ); TIME_RETURN(0); } //----------------------------------------------------------------------------- // Get the clocks current time externC int clock_gettime( clockid_t clock_id, struct timespec *tp) { TIME_ENTRY(); if( clock_id != CLOCK_REALTIME ) TIME_RETURN(EINVAL); if( tp == NULL ) TIME_RETURN(EINVAL); cyg_tick_count ticks = Cyg_Clock::real_time_clock->current_value(); cyg_ticks_to_timespec( ticks, tp ); TIME_RETURN(0); } //----------------------------------------------------------------------------- // Get the clocks resolution externC int clock_getres( clockid_t clock_id, struct timespec *tp) { TIME_ENTRY(); if( clock_id != CLOCK_REALTIME ) TIME_RETURN(EINVAL); if( tp == NULL ) TIME_RETURN(EINVAL); // Get the resolution of 1 tick cyg_ticks_to_timespec( 1, tp ); TIME_RETURN(0); } //========================================================================== // Timer functions #ifdef CYGPKG_POSIX_TIMERS //----------------------------------------------------------------------------- // Create a timer based on the given clock. externC int timer_create( clockid_t clock_id, struct sigevent *evp, timer_t *timer_id) { TIME_ENTRY(); if( clock_id != CLOCK_REALTIME ) TIME_RETURN(EINVAL); timer_mutex.lock(); posix_timer *timer; int next = timer_next; // Look for an unused slot in the table while( timer_table[next].id != 0 ) { next++; if( next >= _POSIX_TIMER_MAX ) next = 0; if( next == timer_next ) { timer_mutex.unlock(); TIME_RETURN(EAGAIN); } } timer = &timer_table[next]; timer_next = next; // Make sure we never allocate a zero timer id. while( timer->id == 0 ) { timer_id_cookie += TIMER_ID_COOKIE_INC; timer->id = next+timer_id_cookie; } if( evp == NULL ) { // If no evp is supplied, set up the timer // to use a default set. timer->sigev.sigev_notify = SIGEV_SIGNAL; timer->sigev.sigev_signo = SIGALRM; timer->sigev.sigev_value.sival_int = timer->id; } else timer->sigev = *evp; timer->alarm = new( timer->alarm_obj ) Cyg_Alarm( Cyg_Clock::real_time_clock, alarm_action, (CYG_ADDRWORD)timer ); timer->armed = false; timer->overrun = 0; *timer_id = timer->id; timer_mutex.unlock(); TIME_RETURN(0); } //----------------------------------------------------------------------------- // Delete the timer externC int timer_delete( timer_t timerid ) { int err = EINVAL; TIME_ENTRY(); posix_timer *timer = &timer_table[timerid & TIMER_ID_COOKIE_MASK]; timer_mutex.lock(); if( timer->id == timerid ) { // This is a valid timer, disable the kernel // alarm and delete it. // disable alarm timer->alarm->disable(); // destroy it timer->alarm->~Cyg_Alarm(); // Mark POSIX timer free timer->id = 0; err = 0; } timer_mutex.unlock(); TIME_RETURN( err ); } //----------------------------------------------------------------------------- // Set the expiration time of the timer. externC int timer_settime( timer_t timerid, int flags, const struct itimerspec *value, struct itimerspec *ovalue ) { int err = EINVAL; TIME_ENTRY(); if( value == NULL ) TIME_RETURN(EINVAL); // convert trigger and interval values to ticks. cyg_tick_count trigger = cyg_timespec_to_ticks( &value->it_value, true ); cyg_tick_count interval = cyg_timespec_to_ticks( &value->it_interval, true ); posix_timer *timer = &timer_table[timerid & TIMER_ID_COOKIE_MASK]; timer_mutex.lock(); if( timer->id == timerid ) { // disable the timer timer->alarm->disable(); if( ovalue != NULL ) { cyg_tick_count otrigger, ointerval; timer->alarm->get_times( &otrigger, &ointerval ); if( timer->armed ) { // convert absolute trigger time to interval until next trigger otrigger -= Cyg_Clock::real_time_clock->current_value(); } else otrigger = 0; // convert ticks to timespecs cyg_ticks_to_timespec( otrigger, &ovalue->it_value ); cyg_ticks_to_timespec( ointerval, &ovalue->it_interval ); } if( trigger == 0 ) { // Mark timer disarmed timer->armed = false; } else { // If the ABSTIME flag is not set, add the current time if( (flags & TIMER_ABSTIME) == 0 ) trigger += Cyg_Clock::real_time_clock->current_value(); // Set the alarm running. timer->alarm->initialize( trigger, interval ); // Mark timer armed timer->armed = true; } err = 0; } timer_mutex.unlock(); TIME_RETURN(err); } //----------------------------------------------------------------------------- // Get current timer values externC int timer_gettime( timer_t timerid, struct itimerspec *value ) { int err = EINVAL; TIME_ENTRY(); if( value == NULL ) TIME_RETURN(EINVAL); posix_timer *timer = &timer_table[timerid & TIMER_ID_COOKIE_MASK]; timer_mutex.lock(); if( timer->id == timerid ) { cyg_tick_count trigger, interval; timer->alarm->get_times( &trigger, &interval ); if( timer->armed ) { // convert absolute trigger time to interval until next trigger trigger -= Cyg_Clock::real_time_clock->current_value(); } else trigger = 0; // convert ticks to timespecs cyg_ticks_to_timespec( trigger, &value->it_value ); cyg_ticks_to_timespec( interval, &value->it_interval ); err = 0; } timer_mutex.unlock(); TIME_RETURN(err); } //----------------------------------------------------------------------------- // Get number of missed triggers externC int timer_getoverrun( timer_t timerid ) { int overrun = 0; TIME_ENTRY(); posix_timer *timer = &timer_table[timerid & TIMER_ID_COOKIE_MASK]; timer_mutex.lock(); if( timer->id == timerid ) { overrun = timer->overrun; } timer_mutex.unlock(); CYG_REPORT_RETVAL(overrun); return overrun; } #endif // ifdef CYGPKG_POSIX_TIMERS //========================================================================== // Nanosleep // Sleep for the given time. externC int nanosleep( const struct timespec *rqtp, struct timespec *rmtp) { cyg_tick_count ticks, now, then; TIME_ENTRY(); // check for cancellation first. PTHREAD_TESTCANCEL(); // Fail an invalid timespec if( !valid_timespec( rqtp ) ) TIME_RETURN(EINVAL); // Return immediately for a zero delay. if( rqtp->tv_sec == 0 && rqtp->tv_nsec == 0 ) TIME_RETURN(0); // Convert timespec to ticks ticks = cyg_timespec_to_ticks( rqtp, true ); CYG_ASSERT( ticks != 0, "Zero tick count"); Cyg_Thread *self = Cyg_Thread::self(); // Do the delay, keeping track of how long we actually slept for. then = Cyg_Clock::real_time_clock->current_value(); self->delay( ticks ); now = Cyg_Clock::real_time_clock->current_value(); if( rmtp != NULL && (then+ticks) > now ) { // We woke up early, return the time left. // FIXME: strictly we only need to do this if we were woken // by a signal. // Calculate remaining number of ticks. ticks -= (now-then); cyg_ticks_to_timespec( ticks, rmtp ); // Check for cancellation and then notify the caller that we // were interrupted. PTHREAD_TESTCANCEL(); TIME_RETURN(EINTR); } // check if we were woken up because we were cancelled. PTHREAD_TESTCANCEL(); TIME_RETURN(0); } // ------------------------------------------------------------------------- // Wait for a signal, or the given number of seconds externC unsigned int sleep( unsigned int seconds ) { TIME_ENTRY(); struct timespec timeout; timeout.tv_sec = seconds; timeout.tv_nsec = 0; if( nanosleep( &timeout, &timeout ) != 0 ) { CYG_REPORT_RETVAL(timeout.tv_sec); return timeout.tv_sec; } TIME_RETURN(0); } // ------------------------------------------------------------------------- // gettimeofday() // Get the current time in a struct timeval externC int gettimeofday(struct timeval* tv, struct timezone* tz) { int ticks_per_second = 1000000000/ (CYGNUM_HAL_RTC_NUMERATOR/CYGNUM_HAL_RTC_DENOMINATOR); cyg_tick_count_t cur_time = cyg_current_time(); int tix = cur_time % ticks_per_second; tv->tv_sec = cur_time / ticks_per_second; tv->tv_usec = (tix * 1000000)/ticks_per_second; return 0; } // ------------------------------------------------------------------------- // EOF time.cxx