/* Clock * * This routine initializes the interval timer on the * PA-RISC CPU. The tick frequency is specified by the bsp. * * COPYRIGHT (c) 1989-1999. * On-Line Applications Research Corporation (OAR). * * The license and distribution terms for this file may be * found in the file LICENSE in this distribution or at * http://www.OARcorp.com/rtems/license.html. * * $Id$ */ #include #include /* should get this from bsp.h, but it is not installed yet */ rtems_isr_entry set_vector(rtems_isr_entry, rtems_vector_number, int); #include /* for atexit() */ typedef unsigned long long hppa_click_count_t; /* * These are set by clock driver during its init */ rtems_device_major_number rtems_clock_major = ~0; rtems_device_minor_number rtems_clock_minor; /* * CPU_HPPA_CLICKS_PER_TICK is either a #define or an rtems_unsigned32 * allocated and set by bsp_start() */ #ifndef CPU_HPPA_CLICKS_PER_TICK extern rtems_unsigned32 CPU_HPPA_CLICKS_PER_TICK; #endif volatile rtems_unsigned32 Clock_driver_ticks; rtems_unsigned32 Clock_isrs; /* ISRs until next tick */ rtems_unsigned32 most_recent_itimer_value; rtems_unsigned64 Clock_clicks; /* running total of cycles */ rtems_unsigned32 Clock_clicks_interrupt; void Clock_exit(void); void ReInstall_clock(rtems_isr_entry new_clock_isr) { rtems_unsigned32 isrlevel = 0; rtems_interrupt_disable(isrlevel); (void) set_vector( new_clock_isr, HPPA_INTERRUPT_EXTERNAL_INTERVAL_TIMER, 1 ); rtems_interrupt_enable(isrlevel); } /* * read itimer and update Clock_clicks as appropriate */ rtems_unsigned32 Clock_read_itimer() { rtems_unsigned32 isrlevel; rtems_unsigned32 itimer_value; rtems_unsigned32 wrap_count; rtems_unsigned32 recent_count; rtems_interrupt_disable(isrlevel); wrap_count = (Clock_clicks & 0xFFFFFFFF00000000ULL) >> 32; recent_count = (rtems_unsigned32) Clock_clicks; itimer_value = get_itimer(); if (itimer_value < recent_count) wrap_count++; Clock_clicks = (((rtems_unsigned64) wrap_count) << 32) + itimer_value; rtems_interrupt_enable(isrlevel); return itimer_value; } void Install_clock(rtems_isr_entry clock_isr) { Clock_driver_ticks = 0; Clock_clicks_interrupt = 0; Clock_clicks = 0; Clock_isrs = rtems_configuration_get_milliseconds_per_tick(); /* * initialize the interval here * First tick is set to right amount of time in the future * Future ticks will be incremented over last value set * in order to provide consistent clicks in the face of * interrupt overhead */ Clock_clicks_interrupt = Clock_read_itimer() + CPU_HPPA_CLICKS_PER_TICK; set_itimer((rtems_unsigned32) Clock_clicks_interrupt); (void) set_vector(clock_isr, HPPA_INTERRUPT_EXTERNAL_INTERVAL_TIMER, 1); atexit(Clock_exit); } rtems_isr Clock_isr(rtems_vector_number vector) { rtems_unsigned32 clicks_til_next_interrupt; rtems_unsigned32 itimer_value; /* * setup for next interrupt; making sure the new value is reasonably * in the future.... in case we lost out on an interrupt somehow */ itimer_value = Clock_read_itimer(); Clock_clicks_interrupt += CPU_HPPA_CLICKS_PER_TICK; /* * how far away is next interrupt *really* * It may be a long time; this subtraction works even if * Clock_clicks_interrupt < Clock_clicks_low_order via * the miracle of unsigned math. */ clicks_til_next_interrupt = Clock_clicks_interrupt - itimer_value; /* * If it is too soon then bump it up. * This should only happen if CPU_HPPA_CLICKS_PER_TICK is too small. * But setting it low is useful for debug, so... */ if (clicks_til_next_interrupt < 400) { Clock_clicks_interrupt = itimer_value + 1000; /* XXX: count these! this should be rare */ } /* * If it is too late, that means we missed the interrupt somehow. * Rather than wait 35-50s for a wrap, we just fudge it here. */ if (clicks_til_next_interrupt > CPU_HPPA_CLICKS_PER_TICK) { Clock_clicks_interrupt = itimer_value + 1000; /* XXX: count these! this should never happen :-) */ } set_itimer((rtems_unsigned32) Clock_clicks_interrupt); Clock_driver_ticks++; if (Clock_isrs == 1) { rtems_clock_tick(); Clock_isrs = rtems_configuration_get_milliseconds_per_tick(); if (Clock_isrs == 0) Clock_isrs = 1; } else Clock_isrs--; } /* * Called via atexit() * Remove the clock interrupt handler by setting handler to NULL */ void Clock_exit(void) { (void) set_vector(0, HPPA_INTERRUPT_EXTERNAL_INTERVAL_TIMER, 1); } /* * spin delay for specified number of microseconds * used by RTEMS delay macro */ void Clock_delay(rtems_unsigned32 microseconds) { rtems_unsigned64 future_time; (void) Clock_read_itimer(); future_time = Clock_clicks + ((rtems_unsigned64) microseconds) * rtems_cpu_configuration_get_itimer_clicks_per_microsecond(); for (;;) { (void) Clock_read_itimer(); if (future_time <= Clock_clicks) break; } } rtems_device_driver Clock_initialize( rtems_device_major_number major, rtems_device_minor_number minor, void *pargp ) { Install_clock(Clock_isr); /* * make major/minor avail to others such as shared memory driver */ rtems_clock_major = major; rtems_clock_minor = minor; return RTEMS_SUCCESSFUL; } rtems_device_driver Clock_control( rtems_device_major_number major, rtems_device_minor_number minor, void *pargp ) { rtems_libio_ioctl_args_t *args = pargp; if (args == 0) goto done; /* * This is hokey, but until we get a defined interface * to do this, it will just be this simple... */ if (args->command == rtems_build_name('I', 'S', 'R', ' ')) { Clock_isr(HPPA_INTERRUPT_EXTERNAL_INTERVAL_TIMER); } else if (args->command == rtems_build_name('N', 'E', 'W', ' ')) { ReInstall_clock(args->buffer); } done: return RTEMS_SUCCESSFUL; }