fsw_misc.c
983 lines
| 36.7 KiB
| text/x-c
|
CLexer
/ src / fsw_misc.c
paul
|
r45 | /** General usage functions and RTEMS tasks. | ||
* | ||||
* @file | ||||
* @author P. LEROY | ||||
* | ||||
*/ | ||||
paul
|
r40 | #include "fsw_misc.h" | ||
paul@pc-solar1.lab-lpp.local
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r5 | |||
paul
|
r239 | void timer_configure(unsigned char timer, unsigned int clock_divider, | ||
paul@pc-solar1.lab-lpp.local
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r5 | unsigned char interrupt_level, rtems_isr (*timer_isr)() ) | ||
paul
|
r45 | { | ||
/** This function configures a GPTIMER timer instantiated in the VHDL design. | ||||
* | ||||
* @param gptimer_regs points to the APB registers of the GPTIMER IP core. | ||||
* @param timer is the number of the timer in the IP core (several timers can be instantiated). | ||||
* @param clock_divider is the divider of the 1 MHz clock that will be configured. | ||||
* @param interrupt_level is the interrupt level that the timer drives. | ||||
* @param timer_isr is the interrupt subroutine that will be attached to the IRQ driven by the timer. | ||||
* | ||||
* Interrupt levels are described in the SPARC documentation sparcv8.pdf p.76 | ||||
* | ||||
*/ | ||||
paul@pc-solar1.lab-lpp.local
|
r21 | rtems_status_code status; | ||
paul@pc-solar1.lab-lpp.local
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r5 | rtems_isr_entry old_isr_handler; | ||
paul
|
r100 | gptimer_regs->timer[timer].ctrl = 0x00; // reset the control register | ||
paul@pc-solar1.lab-lpp.local
|
r21 | status = rtems_interrupt_catch( timer_isr, interrupt_level, &old_isr_handler) ; // see sparcv8.pdf p.76 for interrupt levels | ||
paul
|
r35 | if (status!=RTEMS_SUCCESSFUL) | ||
paul
|
r31 | { | ||
paul
|
r35 | PRINTF("in configure_timer *** ERR rtems_interrupt_catch\n") | ||
paul
|
r31 | } | ||
paul@pc-solar1.lab-lpp.local
|
r5 | |||
paul
|
r239 | timer_set_clock_divider( timer, clock_divider); | ||
paul
|
r31 | } | ||
paul
|
r239 | void timer_start(unsigned char timer) | ||
paul
|
r31 | { | ||
paul
|
r45 | /** This function starts a GPTIMER timer. | ||
* | ||||
* @param gptimer_regs points to the APB registers of the GPTIMER IP core. | ||||
* @param timer is the number of the timer in the IP core (several timers can be instantiated). | ||||
* | ||||
*/ | ||||
paul@pc-solar1.lab-lpp.local
|
r5 | gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl | 0x00000010; // clear pending IRQ if any | ||
gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl | 0x00000004; // LD load value from the reload register | ||||
gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl | 0x00000001; // EN enable the timer | ||||
gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl | 0x00000002; // RS restart | ||||
gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl | 0x00000008; // IE interrupt enable | ||||
} | ||||
paul
|
r239 | void timer_stop(unsigned char timer) | ||
paul
|
r31 | { | ||
paul
|
r45 | /** This function stops a GPTIMER timer. | ||
* | ||||
* @param gptimer_regs points to the APB registers of the GPTIMER IP core. | ||||
* @param timer is the number of the timer in the IP core (several timers can be instantiated). | ||||
* | ||||
*/ | ||||
paul
|
r31 | gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl & 0xfffffffe; // EN enable the timer | ||
gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl & 0xffffffef; // IE interrupt enable | ||||
gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl | 0x00000010; // clear pending IRQ if any | ||||
} | ||||
paul
|
r239 | void timer_set_clock_divider(unsigned char timer, unsigned int clock_divider) | ||
paul
|
r31 | { | ||
paul
|
r45 | /** This function sets the clock divider of a GPTIMER timer. | ||
* | ||||
* @param gptimer_regs points to the APB registers of the GPTIMER IP core. | ||||
* @param timer is the number of the timer in the IP core (several timers can be instantiated). | ||||
* @param clock_divider is the divider of the 1 MHz clock that will be configured. | ||||
* | ||||
*/ | ||||
paul
|
r31 | gptimer_regs->timer[timer].reload = clock_divider; // base clock frequency is 1 MHz | ||
} | ||||
paul
|
r239 | // WATCHDOG | ||
rtems_isr watchdog_isr( rtems_vector_number vector ) | ||||
{ | ||||
rtems_status_code status_code; | ||||
status_code = rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_12 ); | ||||
paul
|
r262 | |||
PRINTF("watchdog_isr *** this is the end, exit(0)\n"); | ||||
exit(0); | ||||
paul
|
r239 | } | ||
void watchdog_configure(void) | ||||
{ | ||||
/** This function configure the watchdog. | ||||
* | ||||
* @param gptimer_regs points to the APB registers of the GPTIMER IP core. | ||||
* @param timer is the number of the timer in the IP core (several timers can be instantiated). | ||||
* | ||||
* The watchdog is a timer provided by the GPTIMER IP core of the GRLIB. | ||||
* | ||||
*/ | ||||
LEON_Mask_interrupt( IRQ_GPTIMER_WATCHDOG ); // mask gptimer/watchdog interrupt during configuration | ||||
timer_configure( TIMER_WATCHDOG, CLKDIV_WATCHDOG, IRQ_SPARC_GPTIMER_WATCHDOG, watchdog_isr ); | ||||
LEON_Clear_interrupt( IRQ_GPTIMER_WATCHDOG ); // clear gptimer/watchdog interrupt | ||||
} | ||||
void watchdog_stop(void) | ||||
{ | ||||
LEON_Mask_interrupt( IRQ_GPTIMER_WATCHDOG ); // mask gptimer/watchdog interrupt line | ||||
timer_stop( TIMER_WATCHDOG ); | ||||
LEON_Clear_interrupt( IRQ_GPTIMER_WATCHDOG ); // clear gptimer/watchdog interrupt | ||||
} | ||||
void watchdog_reload(void) | ||||
{ | ||||
/** This function reloads the watchdog timer counter with the timer reload value. | ||||
* | ||||
paul
|
r251 | * @param void | ||
* | ||||
* @return void | ||||
paul
|
r239 | * | ||
*/ | ||||
gptimer_regs->timer[TIMER_WATCHDOG].ctrl = gptimer_regs->timer[TIMER_WATCHDOG].ctrl | 0x00000004; // LD load value from the reload register | ||||
} | ||||
void watchdog_start(void) | ||||
{ | ||||
/** This function starts the watchdog timer. | ||||
* | ||||
* @param gptimer_regs points to the APB registers of the GPTIMER IP core. | ||||
* @param timer is the number of the timer in the IP core (several timers can be instantiated). | ||||
* | ||||
*/ | ||||
LEON_Clear_interrupt( IRQ_GPTIMER_WATCHDOG ); | ||||
gptimer_regs->timer[TIMER_WATCHDOG].ctrl = gptimer_regs->timer[TIMER_WATCHDOG].ctrl | 0x00000010; // clear pending IRQ if any | ||||
gptimer_regs->timer[TIMER_WATCHDOG].ctrl = gptimer_regs->timer[TIMER_WATCHDOG].ctrl | 0x00000004; // LD load value from the reload register | ||||
gptimer_regs->timer[TIMER_WATCHDOG].ctrl = gptimer_regs->timer[TIMER_WATCHDOG].ctrl | 0x00000001; // EN enable the timer | ||||
gptimer_regs->timer[TIMER_WATCHDOG].ctrl = gptimer_regs->timer[TIMER_WATCHDOG].ctrl | 0x00000008; // IE interrupt enable | ||||
LEON_Unmask_interrupt( IRQ_GPTIMER_WATCHDOG ); | ||||
} | ||||
paul
|
r253 | int enable_apbuart_transmitter( void ) // set the bit 1, TE Transmitter Enable to 1 in the APBUART control register | ||
paul@pc-solar1.lab-lpp.local
|
r5 | { | ||
paul@pc-solar1.lab-lpp.local
|
r18 | struct apbuart_regs_str *apbuart_regs = (struct apbuart_regs_str *) REGS_ADDR_APBUART; | ||
paul@pc-solar1.lab-lpp.local
|
r21 | |||
paul
|
r95 | apbuart_regs->ctrl = APBUART_CTRL_REG_MASK_TE; | ||
paul
|
r94 | |||
return 0; | ||||
} | ||||
paul
|
r40 | void set_apbuart_scaler_reload_register(unsigned int regs, unsigned int value) | ||
paul@pc-solar1.lab-lpp.local
|
r17 | { | ||
paul
|
r40 | /** This function sets the scaler reload register of the apbuart module | ||
* | ||||
* @param regs is the address of the apbuart registers in memory | ||||
* @param value is the value that will be stored in the scaler register | ||||
* | ||||
* The value shall be set by the software to get data on the serial interface. | ||||
* | ||||
*/ | ||||
paul@pc-solar1.lab-lpp.local
|
r18 | struct apbuart_regs_str *apbuart_regs = (struct apbuart_regs_str *) regs; | ||
paul@pc-solar1.lab-lpp.local
|
r21 | |||
apbuart_regs->scaler = value; | ||||
paul
|
r253 | |||
paul
|
r35 | BOOT_PRINTF1("OK *** apbuart port scaler reload register set to 0x%x\n", value) | ||
paul@pc-solar1.lab-lpp.local
|
r17 | } | ||
//************ | ||||
// RTEMS TASKS | ||||
paul
|
r239 | rtems_task load_task(rtems_task_argument argument) | ||
paul@pc-solar1.lab-lpp.local
|
r21 | { | ||
paul
|
r239 | BOOT_PRINTF("in LOAD *** \n") | ||
rtems_status_code status; | ||||
unsigned int i; | ||||
unsigned int j; | ||||
rtems_name name_watchdog_rate_monotonic; // name of the watchdog rate monotonic | ||||
rtems_id watchdog_period_id; // id of the watchdog rate monotonic period | ||||
name_watchdog_rate_monotonic = rtems_build_name( 'L', 'O', 'A', 'D' ); | ||||
status = rtems_rate_monotonic_create( name_watchdog_rate_monotonic, &watchdog_period_id ); | ||||
if( status != RTEMS_SUCCESSFUL ) { | ||||
PRINTF1( "in LOAD *** rtems_rate_monotonic_create failed with status of %d\n", status ) | ||||
} | ||||
paul@pc-solar1.lab-lpp.local
|
r17 | i = 0; | ||
paul@pc-solar1.lab-lpp.local
|
r21 | j = 0; | ||
paul
|
r239 | |||
watchdog_configure(); | ||||
watchdog_start(); | ||||
paul
|
r262 | set_sy_lfr_watchdog_enabled( true ); | ||
paul@pc-solar1.lab-lpp.local
|
r21 | while(1){ | ||
paul
|
r239 | status = rtems_rate_monotonic_period( watchdog_period_id, WATCHDOG_PERIOD ); | ||
watchdog_reload(); | ||||
i = i + 1; | ||||
if ( i == 10 ) | ||||
{ | ||||
paul@pc-solar1.lab-lpp.local
|
r21 | i = 0; | ||
paul
|
r239 | j = j + 1; | ||
PRINTF1("%d\n", j) | ||||
paul@pc-solar1.lab-lpp.local
|
r21 | } | ||
paul
|
r246 | #ifdef DEBUG_WATCHDOG | ||
paul
|
r239 | if (j == 3 ) | ||
{ | ||||
status = rtems_task_delete(RTEMS_SELF); | ||||
} | ||||
paul
|
r246 | #endif | ||
paul@pc-solar1.lab-lpp.local
|
r21 | } | ||
paul@pc-solar1.lab-lpp.local
|
r5 | } | ||
paul@pc-solar1.lab-lpp.local
|
r21 | |||
rtems_task hous_task(rtems_task_argument argument) | ||||
paul@pc-solar1.lab-lpp.local
|
r17 | { | ||
paul@pc-solar1.lab-lpp.local
|
r18 | rtems_status_code status; | ||
paul
|
r166 | rtems_status_code spare_status; | ||
paul
|
r35 | rtems_id queue_id; | ||
paul
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r104 | rtems_rate_monotonic_period_status period_status; | ||
paul
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r33 | |||
paul
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r82 | status = get_message_queue_id_send( &queue_id ); | ||
paul
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r35 | if (status != RTEMS_SUCCESSFUL) | ||
{ | ||||
paul
|
r82 | PRINTF1("in HOUS *** ERR get_message_queue_id_send %d\n", status) | ||
paul
|
r35 | } | ||
paul
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r259 | BOOT_PRINTF("in HOUS ***\n"); | ||
paul@pc-solar1.lab-lpp.local
|
r17 | |||
paul
|
r46 | if (rtems_rate_monotonic_ident( name_hk_rate_monotonic, &HK_id) != RTEMS_SUCCESSFUL) { | ||
status = rtems_rate_monotonic_create( name_hk_rate_monotonic, &HK_id ); | ||||
paul@pc-solar1.lab-lpp.local
|
r18 | if( status != RTEMS_SUCCESSFUL ) { | ||
paul
|
r259 | PRINTF1( "rtems_rate_monotonic_create failed with status of %d\n", status ); | ||
paul@pc-solar1.lab-lpp.local
|
r18 | } | ||
paul@pc-solar1.lab-lpp.local
|
r17 | } | ||
status = rtems_rate_monotonic_cancel(HK_id); | ||||
paul@pc-solar1.lab-lpp.local
|
r23 | if( status != RTEMS_SUCCESSFUL ) { | ||
paul
|
r259 | PRINTF1( "ERR *** in HOUS *** rtems_rate_monotonic_cancel(HK_id) ***code: %d\n", status ); | ||
paul@pc-solar1.lab-lpp.local
|
r23 | } | ||
else { | ||||
paul
|
r259 | DEBUG_PRINTF("OK *** in HOUS *** rtems_rate_monotonic_cancel(HK_id)\n"); | ||
paul@pc-solar1.lab-lpp.local
|
r23 | } | ||
paul@pc-solar1.lab-lpp.local
|
r21 | |||
paul
|
r104 | // startup phase | ||
status = rtems_rate_monotonic_period( HK_id, SY_LFR_TIME_SYN_TIMEOUT_in_ticks ); | ||||
status = rtems_rate_monotonic_get_status( HK_id, &period_status ); | ||||
DEBUG_PRINTF1("startup HK, HK_id status = %d\n", period_status.state) | ||||
while(period_status.state != RATE_MONOTONIC_EXPIRED ) // after SY_LFR_TIME_SYN_TIMEOUT ms, starts HK anyway | ||||
{ | ||||
if ((time_management_regs->coarse_time & 0x80000000) == 0x00000000) // check time synchronization | ||||
{ | ||||
break; // break if LFR is synchronized | ||||
} | ||||
else | ||||
{ | ||||
status = rtems_rate_monotonic_get_status( HK_id, &period_status ); | ||||
paul
|
r128 | // sched_yield(); | ||
status = rtems_task_wake_after( 10 ); // wait SY_LFR_DPU_CONNECT_TIMEOUT 100 ms = 10 * 10 ms | ||||
paul
|
r104 | } | ||
} | ||||
status = rtems_rate_monotonic_cancel(HK_id); | ||||
DEBUG_PRINTF1("startup HK, HK_id status = %d\n", period_status.state) | ||||
paul
|
r280 | set_hk_lfr_reset_cause( POWER_ON ); | ||
paul
|
r226 | |||
paul@pc-solar1.lab-lpp.local
|
r17 | while(1){ // launch the rate monotonic task | ||
paul@pc-solar1.lab-lpp.local
|
r21 | status = rtems_rate_monotonic_period( HK_id, HK_PERIOD ); | ||
paul@pc-solar1.lab-lpp.local
|
r23 | if ( status != RTEMS_SUCCESSFUL ) { | ||
paul
|
r50 | PRINTF1( "in HOUS *** ERR period: %d\n", status); | ||
paul
|
r166 | spare_status = rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_6 ); | ||
paul@pc-solar1.lab-lpp.local
|
r17 | } | ||
paul@pc-solar1.lab-lpp.local
|
r23 | else { | ||
paul
|
r151 | housekeeping_packet.packetSequenceControl[0] = (unsigned char) (sequenceCounterHK >> 8); | ||
housekeeping_packet.packetSequenceControl[1] = (unsigned char) (sequenceCounterHK ); | ||||
paul
|
r149 | increment_seq_counter( &sequenceCounterHK ); | ||
paul
|
r33 | housekeeping_packet.time[0] = (unsigned char) (time_management_regs->coarse_time>>24); | ||
housekeeping_packet.time[1] = (unsigned char) (time_management_regs->coarse_time>>16); | ||||
housekeeping_packet.time[2] = (unsigned char) (time_management_regs->coarse_time>>8); | ||||
housekeeping_packet.time[3] = (unsigned char) (time_management_regs->coarse_time); | ||||
housekeeping_packet.time[4] = (unsigned char) (time_management_regs->fine_time>>8); | ||||
housekeeping_packet.time[5] = (unsigned char) (time_management_regs->fine_time); | ||||
paul@pc-solar1.lab-lpp.local
|
r23 | |||
paul
|
r279 | spacewire_update_hk_lfr_link_state( &housekeeping_packet.lfr_status_word[0] ); | ||
paul
|
r264 | spacewire_read_statistics(); | ||
paul@pc-solar1.lab-lpp.local
|
r23 | |||
paul
|
r264 | update_hk_with_grspw_stats(); | ||
paul
|
r263 | |||
paul
|
r249 | set_hk_lfr_time_not_synchro(); | ||
paul
|
r197 | housekeeping_packet.hk_lfr_q_sd_fifo_size_max = hk_lfr_q_sd_fifo_size_max; | ||
housekeeping_packet.hk_lfr_q_rv_fifo_size_max = hk_lfr_q_rv_fifo_size_max; | ||||
housekeeping_packet.hk_lfr_q_p0_fifo_size_max = hk_lfr_q_p0_fifo_size_max; | ||||
housekeeping_packet.hk_lfr_q_p1_fifo_size_max = hk_lfr_q_p1_fifo_size_max; | ||||
housekeeping_packet.hk_lfr_q_p2_fifo_size_max = hk_lfr_q_p2_fifo_size_max; | ||||
paul
|
r195 | housekeeping_packet.sy_lfr_common_parameters_spare = parameter_dump_packet.sy_lfr_common_parameters_spare; | ||
housekeeping_packet.sy_lfr_common_parameters = parameter_dump_packet.sy_lfr_common_parameters; | ||||
paul
|
r185 | get_temperatures( housekeeping_packet.hk_lfr_temp_scm ); | ||
get_v_e1_e2_f3( housekeeping_packet.hk_lfr_sc_v_f3 ); | ||||
paul
|
r134 | get_cpu_load( (unsigned char *) &housekeeping_packet.hk_lfr_cpu_load ); | ||
paul
|
r129 | |||
paul
|
r261 | hk_lfr_le_me_he_update(); | ||
paul
|
r283 | housekeeping_packet.hk_lfr_sc_rw_f_flags = cp_rpw_sc_rw_f_flags; | ||
paul
|
r31 | // SEND PACKET | ||
paul
|
r172 | status = rtems_message_queue_send( queue_id, &housekeeping_packet, | ||
paul
|
r46 | PACKET_LENGTH_HK + CCSDS_TC_TM_PACKET_OFFSET + CCSDS_PROTOCOLE_EXTRA_BYTES); | ||
paul
|
r33 | if (status != RTEMS_SUCCESSFUL) { | ||
paul
|
r50 | PRINTF1("in HOUS *** ERR send: %d\n", status) | ||
paul@pc-solar1.lab-lpp.local
|
r17 | } | ||
paul@pc-solar1.lab-lpp.local
|
r21 | } | ||
} | ||||
paul@pc-solar1.lab-lpp.local
|
r5 | |||
paul@pc-solar1.lab-lpp.local
|
r17 | PRINTF("in HOUS *** deleting task\n") | ||
paul@pc-solar1.lab-lpp.local
|
r21 | |||
status = rtems_task_delete( RTEMS_SELF ); // should not return | ||||
paul
|
r227 | |||
paul
|
r45 | return; | ||
paul@pc-solar1.lab-lpp.local
|
r16 | } | ||
paul
|
r298 | rtems_task avgv_task(rtems_task_argument argument) | ||
{ | ||||
#define MOVING_AVERAGE 16 | ||||
rtems_status_code status; | ||||
unsigned int v[MOVING_AVERAGE]; | ||||
unsigned int e1[MOVING_AVERAGE]; | ||||
unsigned int e2[MOVING_AVERAGE]; | ||||
float average_v; | ||||
float average_e1; | ||||
float average_e2; | ||||
unsigned char k; | ||||
unsigned char indexOfOldValue; | ||||
BOOT_PRINTF("in AVGV ***\n"); | ||||
if (rtems_rate_monotonic_ident( name_avgv_rate_monotonic, &HK_id) != RTEMS_SUCCESSFUL) { | ||||
status = rtems_rate_monotonic_create( name_avgv_rate_monotonic, &AVGV_id ); | ||||
if( status != RTEMS_SUCCESSFUL ) { | ||||
PRINTF1( "rtems_rate_monotonic_create failed with status of %d\n", status ); | ||||
} | ||||
} | ||||
status = rtems_rate_monotonic_cancel(AVGV_id); | ||||
if( status != RTEMS_SUCCESSFUL ) { | ||||
PRINTF1( "ERR *** in AVGV *** rtems_rate_monotonic_cancel(AVGV_id) ***code: %d\n", status ); | ||||
} | ||||
else { | ||||
DEBUG_PRINTF("OK *** in AVGV *** rtems_rate_monotonic_cancel(AVGV_id)\n"); | ||||
} | ||||
// initialize values | ||||
k = 0; | ||||
indexOfOldValue = MOVING_AVERAGE - 1; | ||||
for (k = 0; k < MOVING_AVERAGE; k++) | ||||
{ | ||||
v[k] = 0; | ||||
e1[k] = 0; | ||||
e2[k] = 0; | ||||
average_v = 0.; | ||||
average_e1 = 0.; | ||||
average_e2 = 0.; | ||||
} | ||||
k = 0; | ||||
while(1){ // launch the rate monotonic task | ||||
status = rtems_rate_monotonic_period( AVGV_id, AVGV_PERIOD ); | ||||
if ( status != RTEMS_SUCCESSFUL ) { | ||||
PRINTF1( "in AVGV *** ERR period: %d\n", status); | ||||
} | ||||
else { | ||||
// store new value in buffer | ||||
v[k] = waveform_picker_regs->v; | ||||
e1[k] = waveform_picker_regs->e1; | ||||
e2[k] = waveform_picker_regs->e2; | ||||
if (k == (MOVING_AVERAGE - 1)) | ||||
{ | ||||
indexOfOldValue = 0; | ||||
} | ||||
else | ||||
{ | ||||
indexOfOldValue = k + 1; | ||||
} | ||||
average_v = average_v + v[k] - v[indexOfOldValue]; | ||||
average_e1 = average_e1 + e1[k] - e1[indexOfOldValue]; | ||||
average_e2 = average_e2 + e2[k] - e2[indexOfOldValue]; | ||||
} | ||||
if (k == (MOVING_AVERAGE-1)) | ||||
{ | ||||
k = 0; | ||||
printf("tick\n"); | ||||
} | ||||
else | ||||
{ | ||||
k++; | ||||
} | ||||
} | ||||
PRINTF("in AVGV *** deleting task\n") | ||||
status = rtems_task_delete( RTEMS_SELF ); // should not return | ||||
return; | ||||
} | ||||
paul
|
r45 | rtems_task dumb_task( rtems_task_argument unused ) | ||
paul
|
r33 | { | ||
paul
|
r45 | /** This RTEMS taks is used to print messages without affecting the general behaviour of the software. | ||
* | ||||
* @param unused is the starting argument of the RTEMS task | ||||
* | ||||
* The DUMB taks waits for RTEMS events and print messages depending on the incoming events. | ||||
* | ||||
*/ | ||||
paul
|
r35 | |||
paul
|
r45 | unsigned int i; | ||
unsigned int intEventOut; | ||||
unsigned int coarse_time = 0; | ||||
unsigned int fine_time = 0; | ||||
rtems_event_set event_out; | ||||
paul
|
r33 | |||
paul
|
r259 | char *DumbMessages[15] = {"in DUMB *** default", // RTEMS_EVENT_0 | ||
paul
|
r77 | "in DUMB *** timecode_irq_handler", // RTEMS_EVENT_1 | ||
paul
|
r150 | "in DUMB *** f3 buffer changed", // RTEMS_EVENT_2 | ||
paul
|
r77 | "in DUMB *** in SMIQ *** Error sending event to AVF0", // RTEMS_EVENT_3 | ||
"in DUMB *** spectral_matrices_isr *** Error sending event to SMIQ", // RTEMS_EVENT_4 | ||||
"in DUMB *** waveforms_simulator_isr", // RTEMS_EVENT_5 | ||||
paul
|
r174 | "VHDL SM *** two buffers f0 ready", // RTEMS_EVENT_6 | ||
paul
|
r103 | "ready for dump", // RTEMS_EVENT_7 | ||
paul
|
r150 | "VHDL ERR *** spectral matrix", // RTEMS_EVENT_8 | ||
"tick", // RTEMS_EVENT_9 | ||||
"VHDL ERR *** waveform picker", // RTEMS_EVENT_10 | ||||
paul
|
r239 | "VHDL ERR *** unexpected ready matrix values", // RTEMS_EVENT_11 | ||
paul
|
r248 | "WATCHDOG timer", // RTEMS_EVENT_12 | ||
paul
|
r259 | "TIMECODE timer", // RTEMS_EVENT_13 | ||
"TIMECODE ISR" // RTEMS_EVENT_14 | ||||
paul
|
r77 | }; | ||
paul
|
r45 | BOOT_PRINTF("in DUMB *** \n") | ||
paul
|
r35 | |||
paul
|
r45 | while(1){ | ||
paul
|
r55 | rtems_event_receive(RTEMS_EVENT_0 | RTEMS_EVENT_1 | RTEMS_EVENT_2 | RTEMS_EVENT_3 | ||
paul
|
r103 | | RTEMS_EVENT_4 | RTEMS_EVENT_5 | RTEMS_EVENT_6 | RTEMS_EVENT_7 | ||
paul
|
r259 | | RTEMS_EVENT_8 | RTEMS_EVENT_9 | RTEMS_EVENT_12 | RTEMS_EVENT_13 | ||
| RTEMS_EVENT_14, | ||||
paul
|
r45 | RTEMS_WAIT | RTEMS_EVENT_ANY, RTEMS_NO_TIMEOUT, &event_out); // wait for an RTEMS_EVENT | ||
intEventOut = (unsigned int) event_out; | ||||
for ( i=0; i<32; i++) | ||||
paul
|
r34 | { | ||
paul
|
r45 | if ( ((intEventOut >> i) & 0x0001) != 0) | ||
paul
|
r35 | { | ||
paul
|
r45 | coarse_time = time_management_regs->coarse_time; | ||
fine_time = time_management_regs->fine_time; | ||||
paul
|
r239 | if (i==12) | ||
paul
|
r135 | { | ||
paul
|
r239 | PRINTF1("%s\n", DumbMessages[12]) | ||
paul
|
r135 | } | ||
paul
|
r248 | if (i==13) | ||
{ | ||||
PRINTF1("%s\n", DumbMessages[13]) | ||||
} | ||||
paul
|
r259 | if (i==14) | ||
{ | ||||
PRINTF1("%s\n", DumbMessages[1]) | ||||
} | ||||
paul
|
r34 | } | ||
} | ||||
paul
|
r33 | } | ||
} | ||||
paul
|
r34 | |||
paul
|
r46 | //***************************** | ||
// init housekeeping parameters | ||||
paul
|
r34 | |||
paul
|
r46 | void init_housekeeping_parameters( void ) | ||
{ | ||||
/** This function initialize the housekeeping_packet global variable with default values. | ||||
* | ||||
*/ | ||||
unsigned int i = 0; | ||||
paul
|
r92 | unsigned char *parameters; | ||
paul
|
r197 | unsigned char sizeOfHK; | ||
paul
|
r34 | |||
paul
|
r197 | sizeOfHK = sizeof( Packet_TM_LFR_HK_t ); | ||
parameters = (unsigned char*) &housekeeping_packet; | ||||
for(i = 0; i< sizeOfHK; i++) | ||||
paul
|
r46 | { | ||
parameters[i] = 0x00; | ||||
} | ||||
paul
|
r197 | |||
housekeeping_packet.targetLogicalAddress = CCSDS_DESTINATION_ID; | ||||
housekeeping_packet.protocolIdentifier = CCSDS_PROTOCOLE_ID; | ||||
housekeeping_packet.reserved = DEFAULT_RESERVED; | ||||
housekeeping_packet.userApplication = CCSDS_USER_APP; | ||||
housekeeping_packet.packetID[0] = (unsigned char) (APID_TM_HK >> 8); | ||||
housekeeping_packet.packetID[1] = (unsigned char) (APID_TM_HK); | ||||
housekeeping_packet.packetSequenceControl[0] = TM_PACKET_SEQ_CTRL_STANDALONE; | ||||
housekeeping_packet.packetSequenceControl[1] = TM_PACKET_SEQ_CNT_DEFAULT; | ||||
housekeeping_packet.packetLength[0] = (unsigned char) (PACKET_LENGTH_HK >> 8); | ||||
housekeeping_packet.packetLength[1] = (unsigned char) (PACKET_LENGTH_HK ); | ||||
housekeeping_packet.spare1_pusVersion_spare2 = DEFAULT_SPARE1_PUSVERSION_SPARE2; | ||||
housekeeping_packet.serviceType = TM_TYPE_HK; | ||||
housekeeping_packet.serviceSubType = TM_SUBTYPE_HK; | ||||
housekeeping_packet.destinationID = TM_DESTINATION_ID_GROUND; | ||||
housekeeping_packet.sid = SID_HK; | ||||
paul
|
r46 | // init status word | ||
housekeeping_packet.lfr_status_word[0] = DEFAULT_STATUS_WORD_BYTE0; | ||||
housekeeping_packet.lfr_status_word[1] = DEFAULT_STATUS_WORD_BYTE1; | ||||
// init software version | ||||
housekeeping_packet.lfr_sw_version[0] = SW_VERSION_N1; | ||||
housekeeping_packet.lfr_sw_version[1] = SW_VERSION_N2; | ||||
housekeeping_packet.lfr_sw_version[2] = SW_VERSION_N3; | ||||
housekeeping_packet.lfr_sw_version[3] = SW_VERSION_N4; | ||||
paul
|
r92 | // init fpga version | ||
paul
|
r144 | parameters = (unsigned char *) (REGS_ADDR_VHDL_VERSION); | ||
paul
|
r92 | housekeeping_packet.lfr_fpga_version[0] = parameters[1]; // n1 | ||
housekeeping_packet.lfr_fpga_version[1] = parameters[2]; // n2 | ||||
housekeeping_packet.lfr_fpga_version[2] = parameters[3]; // n3 | ||||
paul
|
r197 | |||
housekeeping_packet.hk_lfr_q_sd_fifo_size = MSG_QUEUE_COUNT_SEND; | ||||
housekeeping_packet.hk_lfr_q_rv_fifo_size = MSG_QUEUE_COUNT_RECV; | ||||
housekeeping_packet.hk_lfr_q_p0_fifo_size = MSG_QUEUE_COUNT_PRC0; | ||||
housekeeping_packet.hk_lfr_q_p1_fifo_size = MSG_QUEUE_COUNT_PRC1; | ||||
housekeeping_packet.hk_lfr_q_p2_fifo_size = MSG_QUEUE_COUNT_PRC2; | ||||
paul
|
r46 | } | ||
paul
|
r34 | |||
paul
|
r149 | void increment_seq_counter( unsigned short *packetSequenceControl ) | ||
{ | ||||
paul
|
r194 | /** This function increment the sequence counter passes in argument. | ||
paul
|
r149 | * | ||
* The increment does not affect the grouping flag. In case of an overflow, the counter is reset to 0. | ||||
* | ||||
*/ | ||||
paul
|
r151 | unsigned short segmentation_grouping_flag; | ||
paul
|
r149 | unsigned short sequence_cnt; | ||
segmentation_grouping_flag = TM_PACKET_SEQ_CTRL_STANDALONE << 8; // keep bits 7 downto 6 | ||||
paul
|
r151 | sequence_cnt = (*packetSequenceControl) & 0x3fff; // [0011 1111 1111 1111] | ||
paul
|
r149 | |||
if ( sequence_cnt < SEQ_CNT_MAX) | ||||
{ | ||||
sequence_cnt = sequence_cnt + 1; | ||||
} | ||||
else | ||||
{ | ||||
sequence_cnt = 0; | ||||
} | ||||
*packetSequenceControl = segmentation_grouping_flag | sequence_cnt ; | ||||
} | ||||
paul
|
r75 | void getTime( unsigned char *time) | ||
{ | ||||
paul
|
r77 | /** This function write the current local time in the time buffer passed in argument. | ||
* | ||||
*/ | ||||
paul
|
r75 | time[0] = (unsigned char) (time_management_regs->coarse_time>>24); | ||
time[1] = (unsigned char) (time_management_regs->coarse_time>>16); | ||||
time[2] = (unsigned char) (time_management_regs->coarse_time>>8); | ||||
time[3] = (unsigned char) (time_management_regs->coarse_time); | ||||
time[4] = (unsigned char) (time_management_regs->fine_time>>8); | ||||
time[5] = (unsigned char) (time_management_regs->fine_time); | ||||
} | ||||
paul
|
r56 | |||
paul
|
r117 | unsigned long long int getTimeAsUnsignedLongLongInt( ) | ||
{ | ||||
/** This function write the current local time in the time buffer passed in argument. | ||||
* | ||||
*/ | ||||
unsigned long long int time; | ||||
time = ( (unsigned long long int) (time_management_regs->coarse_time & 0x7fffffff) << 16 ) | ||||
+ time_management_regs->fine_time; | ||||
return time; | ||||
} | ||||
paul
|
r110 | void send_dumb_hk( void ) | ||
{ | ||||
Packet_TM_LFR_HK_t dummy_hk_packet; | ||||
unsigned char *parameters; | ||||
unsigned int i; | ||||
rtems_id queue_id; | ||||
dummy_hk_packet.targetLogicalAddress = CCSDS_DESTINATION_ID; | ||||
dummy_hk_packet.protocolIdentifier = CCSDS_PROTOCOLE_ID; | ||||
dummy_hk_packet.reserved = DEFAULT_RESERVED; | ||||
dummy_hk_packet.userApplication = CCSDS_USER_APP; | ||||
paul
|
r116 | dummy_hk_packet.packetID[0] = (unsigned char) (APID_TM_HK >> 8); | ||
dummy_hk_packet.packetID[1] = (unsigned char) (APID_TM_HK); | ||||
paul
|
r110 | dummy_hk_packet.packetSequenceControl[0] = TM_PACKET_SEQ_CTRL_STANDALONE; | ||
dummy_hk_packet.packetSequenceControl[1] = TM_PACKET_SEQ_CNT_DEFAULT; | ||||
dummy_hk_packet.packetLength[0] = (unsigned char) (PACKET_LENGTH_HK >> 8); | ||||
dummy_hk_packet.packetLength[1] = (unsigned char) (PACKET_LENGTH_HK ); | ||||
dummy_hk_packet.spare1_pusVersion_spare2 = DEFAULT_SPARE1_PUSVERSION_SPARE2; | ||||
dummy_hk_packet.serviceType = TM_TYPE_HK; | ||||
dummy_hk_packet.serviceSubType = TM_SUBTYPE_HK; | ||||
dummy_hk_packet.destinationID = TM_DESTINATION_ID_GROUND; | ||||
paul
|
r113 | dummy_hk_packet.time[0] = (unsigned char) (time_management_regs->coarse_time>>24); | ||
dummy_hk_packet.time[1] = (unsigned char) (time_management_regs->coarse_time>>16); | ||||
dummy_hk_packet.time[2] = (unsigned char) (time_management_regs->coarse_time>>8); | ||||
dummy_hk_packet.time[3] = (unsigned char) (time_management_regs->coarse_time); | ||||
dummy_hk_packet.time[4] = (unsigned char) (time_management_regs->fine_time>>8); | ||||
dummy_hk_packet.time[5] = (unsigned char) (time_management_regs->fine_time); | ||||
paul
|
r110 | dummy_hk_packet.sid = SID_HK; | ||
// init status word | ||||
dummy_hk_packet.lfr_status_word[0] = 0xff; | ||||
dummy_hk_packet.lfr_status_word[1] = 0xff; | ||||
// init software version | ||||
dummy_hk_packet.lfr_sw_version[0] = SW_VERSION_N1; | ||||
dummy_hk_packet.lfr_sw_version[1] = SW_VERSION_N2; | ||||
dummy_hk_packet.lfr_sw_version[2] = SW_VERSION_N3; | ||||
dummy_hk_packet.lfr_sw_version[3] = SW_VERSION_N4; | ||||
// init fpga version | ||||
paul
|
r111 | parameters = (unsigned char *) (REGS_ADDR_WAVEFORM_PICKER + 0xb0); | ||
paul
|
r110 | dummy_hk_packet.lfr_fpga_version[0] = parameters[1]; // n1 | ||
dummy_hk_packet.lfr_fpga_version[1] = parameters[2]; // n2 | ||||
dummy_hk_packet.lfr_fpga_version[2] = parameters[3]; // n3 | ||||
parameters = (unsigned char *) &dummy_hk_packet.hk_lfr_cpu_load; | ||||
for (i=0; i<100; i++) | ||||
{ | ||||
parameters[i] = 0xff; | ||||
} | ||||
get_message_queue_id_send( &queue_id ); | ||||
paul
|
r172 | rtems_message_queue_send( queue_id, &dummy_hk_packet, | ||
paul
|
r110 | PACKET_LENGTH_HK + CCSDS_TC_TM_PACKET_OFFSET + CCSDS_PROTOCOLE_EXTRA_BYTES); | ||
} | ||||
paul
|
r129 | |||
paul
|
r185 | void get_temperatures( unsigned char *temperatures ) | ||
{ | ||||
unsigned char* temp_scm_ptr; | ||||
unsigned char* temp_pcb_ptr; | ||||
unsigned char* temp_fpga_ptr; | ||||
paul
|
r187 | // SEL1 SEL0 | ||
// 0 0 => PCB | ||||
// 0 1 => FPGA | ||||
// 1 0 => SCM | ||||
paul
|
r185 | temp_scm_ptr = (unsigned char *) &time_management_regs->temp_scm; | ||
temp_pcb_ptr = (unsigned char *) &time_management_regs->temp_pcb; | ||||
temp_fpga_ptr = (unsigned char *) &time_management_regs->temp_fpga; | ||||
temperatures[0] = temp_scm_ptr[2]; | ||||
temperatures[1] = temp_scm_ptr[3]; | ||||
temperatures[2] = temp_pcb_ptr[2]; | ||||
temperatures[3] = temp_pcb_ptr[3]; | ||||
temperatures[4] = temp_fpga_ptr[2]; | ||||
temperatures[5] = temp_fpga_ptr[3]; | ||||
} | ||||
paul
|
r135 | void get_v_e1_e2_f3( unsigned char *spacecraft_potential ) | ||
{ | ||||
paul
|
r179 | unsigned char* v_ptr; | ||
unsigned char* e1_ptr; | ||||
unsigned char* e2_ptr; | ||||
paul
|
r171 | |||
paul
|
r179 | v_ptr = (unsigned char *) &waveform_picker_regs->v; | ||
e1_ptr = (unsigned char *) &waveform_picker_regs->e1; | ||||
e2_ptr = (unsigned char *) &waveform_picker_regs->e2; | ||||
paul
|
r171 | |||
paul
|
r179 | spacecraft_potential[0] = v_ptr[2]; | ||
spacecraft_potential[1] = v_ptr[3]; | ||||
spacecraft_potential[2] = e1_ptr[2]; | ||||
spacecraft_potential[3] = e1_ptr[3]; | ||||
spacecraft_potential[4] = e2_ptr[2]; | ||||
spacecraft_potential[5] = e2_ptr[3]; | ||||
paul
|
r171 | } | ||
paul
|
r134 | void get_cpu_load( unsigned char *resource_statistics ) | ||
{ | ||||
unsigned char cpu_load; | ||||
cpu_load = lfr_rtems_cpu_usage_report(); | ||||
// HK_LFR_CPU_LOAD | ||||
resource_statistics[0] = cpu_load; | ||||
// HK_LFR_CPU_LOAD_MAX | ||||
if (cpu_load > resource_statistics[1]) | ||||
{ | ||||
resource_statistics[1] = cpu_load; | ||||
} | ||||
// CPU_LOAD_AVE | ||||
resource_statistics[2] = 0; | ||||
#ifndef PRINT_TASK_STATISTICS | ||||
rtems_cpu_usage_reset(); | ||||
#endif | ||||
} | ||||
paul
|
r212 | void set_hk_lfr_sc_potential_flag( bool state ) | ||
{ | ||||
if (state == true) | ||||
{ | ||||
housekeeping_packet.lfr_status_word[1] = housekeeping_packet.lfr_status_word[1] | 0x40; // [0100 0000] | ||||
} | ||||
else | ||||
{ | ||||
housekeeping_packet.lfr_status_word[1] = housekeeping_packet.lfr_status_word[1] & 0xbf; // [1011 1111] | ||||
} | ||||
} | ||||
paul
|
r129 | |||
paul
|
r295 | void set_sy_lfr_pas_filter_enabled( bool state ) | ||
{ | ||||
if (state == true) | ||||
{ | ||||
housekeeping_packet.lfr_status_word[1] = housekeeping_packet.lfr_status_word[1] | 0x20; // [0010 0000] | ||||
} | ||||
else | ||||
{ | ||||
housekeeping_packet.lfr_status_word[1] = housekeeping_packet.lfr_status_word[1] & 0xdf; // [1101 1111] | ||||
} | ||||
} | ||||
paul
|
r262 | void set_sy_lfr_watchdog_enabled( bool state ) | ||
{ | ||||
if (state == true) | ||||
{ | ||||
housekeeping_packet.lfr_status_word[1] = housekeeping_packet.lfr_status_word[1] | 0x10; // [0001 0000] | ||||
} | ||||
else | ||||
{ | ||||
housekeeping_packet.lfr_status_word[1] = housekeeping_packet.lfr_status_word[1] & 0xef; // [1110 1111] | ||||
} | ||||
} | ||||
paul
|
r212 | void set_hk_lfr_calib_enable( bool state ) | ||
{ | ||||
if (state == true) | ||||
{ | ||||
housekeeping_packet.lfr_status_word[1] = housekeeping_packet.lfr_status_word[1] | 0x08; // [0000 1000] | ||||
} | ||||
else | ||||
{ | ||||
housekeeping_packet.lfr_status_word[1] = housekeeping_packet.lfr_status_word[1] & 0xf7; // [1111 0111] | ||||
} | ||||
} | ||||
paul
|
r224 | |||
paul
|
r226 | void set_hk_lfr_reset_cause( enum lfr_reset_cause_t lfr_reset_cause ) | ||
{ | ||||
paul
|
r279 | housekeeping_packet.lfr_status_word[1] = housekeeping_packet.lfr_status_word[1] & 0xf8; // [1111 1000] | ||
paul
|
r226 | housekeeping_packet.lfr_status_word[1] = housekeeping_packet.lfr_status_word[1] | ||
| (lfr_reset_cause & 0x07 ); // [0000 0111] | ||||
paul
|
r279 | |||
paul
|
r226 | } | ||
paul
|
r240 | |||
paul
|
r317 | void increment_hk_counter( unsigned char newValue, unsigned char oldValue, unsigned int *counter ) | ||
paul
|
r240 | { | ||
paul
|
r317 | int delta; | ||
delta = 0; | ||||
paul
|
r240 | |||
paul
|
r317 | if (newValue >= oldValue) | ||
{ | ||||
delta = newValue - oldValue; | ||||
} | ||||
else | ||||
{ | ||||
delta = 255 - oldValue + newValue; | ||||
} | ||||
*counter = *counter + delta; | ||||
} | ||||
paul
|
r240 | |||
paul
|
r317 | void hk_lfr_le_update( void ) | ||
{ | ||||
static hk_lfr_le_t old_hk_lfr_le = {0}; | ||||
hk_lfr_le_t new_hk_lfr_le; | ||||
unsigned int counter; | ||||
counter = ((unsigned int) housekeeping_packet.hk_lfr_le_cnt[0]) * 256 + housekeeping_packet.hk_lfr_le_cnt[1]; | ||||
// DPU | ||||
new_hk_lfr_le.dpu_spw_parity = housekeeping_packet.hk_lfr_dpu_spw_parity; | ||||
new_hk_lfr_le.dpu_spw_disconnect= housekeeping_packet.hk_lfr_dpu_spw_disconnect; | ||||
new_hk_lfr_le.dpu_spw_escape = housekeeping_packet.hk_lfr_dpu_spw_escape; | ||||
new_hk_lfr_le.dpu_spw_credit = housekeeping_packet.hk_lfr_dpu_spw_credit; | ||||
new_hk_lfr_le.dpu_spw_write_sync= housekeeping_packet.hk_lfr_dpu_spw_write_sync; | ||||
// TIMECODE | ||||
new_hk_lfr_le.timecode_erroneous= housekeeping_packet.hk_lfr_timecode_erroneous; | ||||
new_hk_lfr_le.timecode_missing = housekeeping_packet.hk_lfr_timecode_missing; | ||||
new_hk_lfr_le.timecode_invalid = housekeeping_packet.hk_lfr_timecode_invalid; | ||||
// TIME | ||||
new_hk_lfr_le.time_timecode_it = housekeeping_packet.hk_lfr_time_timecode_it; | ||||
new_hk_lfr_le.time_not_synchro = housekeeping_packet.hk_lfr_time_not_synchro; | ||||
new_hk_lfr_le.time_timecode_ctr = housekeeping_packet.hk_lfr_time_timecode_ctr; | ||||
//AHB | ||||
new_hk_lfr_le.ahb_correctable = housekeeping_packet.hk_lfr_ahb_correctable; | ||||
paul
|
r261 | // housekeeping_packet.hk_lfr_dpu_spw_rx_ahb => not handled by the grspw driver | ||
// housekeeping_packet.hk_lfr_dpu_spw_tx_ahb => not handled by the grspw driver | ||||
paul
|
r240 | |||
paul
|
r317 | // update the le counter | ||
// DPU | ||||
increment_hk_counter( new_hk_lfr_le.dpu_spw_parity, old_hk_lfr_le.dpu_spw_parity, counter ); | ||||
increment_hk_counter( new_hk_lfr_le.dpu_spw_disconnect,old_hk_lfr_le.dpu_spw_disconnect, counter ); | ||||
increment_hk_counter( new_hk_lfr_le.dpu_spw_escape, old_hk_lfr_le.dpu_spw_escape, counter ); | ||||
increment_hk_counter( new_hk_lfr_le.dpu_spw_credit, old_hk_lfr_le.dpu_spw_credit, counter ); | ||||
increment_hk_counter( new_hk_lfr_le.dpu_spw_write_sync,old_hk_lfr_le.dpu_spw_write_sync, counter ); | ||||
// TIMECODE | ||||
increment_hk_counter( new_hk_lfr_le.timecode_erroneous,old_hk_lfr_le.timecode_erroneous, counter ); | ||||
increment_hk_counter( new_hk_lfr_le.timecode_missing, old_hk_lfr_le.timecode_missing, counter ); | ||||
increment_hk_counter( new_hk_lfr_le.timecode_invalid, old_hk_lfr_le.timecode_invalid, counter ); | ||||
// TIME | ||||
increment_hk_counter( new_hk_lfr_le.time_timecode_it, old_hk_lfr_le.time_timecode_it, counter ); | ||||
increment_hk_counter( new_hk_lfr_le.time_not_synchro, old_hk_lfr_le.time_not_synchro, counter ); | ||||
increment_hk_counter( new_hk_lfr_le.time_timecode_ctr, old_hk_lfr_le.time_timecode_ctr, counter ); | ||||
// AHB | ||||
increment_hk_counter( new_hk_lfr_le.ahb_correctable, old_hk_lfr_le.ahb_correctable, counter ); | ||||
// DPU | ||||
old_hk_lfr_le.dpu_spw_parity = new_hk_lfr_le.dpu_spw_parity; | ||||
old_hk_lfr_le.dpu_spw_disconnect= new_hk_lfr_le.dpu_spw_disconnect; | ||||
old_hk_lfr_le.dpu_spw_escape = new_hk_lfr_le.dpu_spw_escape; | ||||
old_hk_lfr_le.dpu_spw_credit = new_hk_lfr_le.dpu_spw_credit; | ||||
old_hk_lfr_le.dpu_spw_write_sync= new_hk_lfr_le.dpu_spw_write_sync; | ||||
// TIMECODE | ||||
old_hk_lfr_le.timecode_erroneous= new_hk_lfr_le.timecode_erroneous; | ||||
old_hk_lfr_le.timecode_missing = new_hk_lfr_le.timecode_missing; | ||||
old_hk_lfr_le.timecode_invalid = new_hk_lfr_le.timecode_invalid; | ||||
// TIME | ||||
old_hk_lfr_le.time_timecode_it = new_hk_lfr_le.time_timecode_it; | ||||
old_hk_lfr_le.time_not_synchro = new_hk_lfr_le.time_not_synchro; | ||||
old_hk_lfr_le.time_timecode_ctr = new_hk_lfr_le.time_timecode_ctr; | ||||
//AHB | ||||
old_hk_lfr_le.ahb_correctable = new_hk_lfr_le.ahb_correctable; | ||||
// housekeeping_packet.hk_lfr_dpu_spw_rx_ahb => not handled by the grspw driver | ||||
// housekeeping_packet.hk_lfr_dpu_spw_tx_ahb => not handled by the grspw driver | ||||
// update housekeeping packet counters, convert unsigned int numbers in 2 bytes numbers | ||||
// LE | ||||
housekeeping_packet.hk_lfr_le_cnt[0] = (unsigned char) ((hk_lfr_le_cnt & 0xff00) >> 8); | ||||
housekeeping_packet.hk_lfr_le_cnt[1] = (unsigned char) (hk_lfr_le_cnt & 0x00ff); | ||||
} | ||||
void hk_lfr_me_update( void ) | ||||
{ | ||||
static hk_lfr_me_t old_hk_lfr_me = {0}; | ||||
hk_lfr_me_t new_hk_lfr_me; | ||||
unsigned int counter; | ||||
counter = ((unsigned int) housekeeping_packet.hk_lfr_me_cnt[0]) * 256 + housekeeping_packet.hk_lfr_me_cnt[1]; | ||||
// get the current values | ||||
new_hk_lfr_me.dpu_spw_early_eop = housekeeping_packet.hk_lfr_dpu_spw_early_eop; | ||||
new_hk_lfr_me.dpu_spw_invalid_addr = housekeeping_packet.hk_lfr_dpu_spw_invalid_addr; | ||||
new_hk_lfr_me.dpu_spw_eep = housekeeping_packet.hk_lfr_dpu_spw_eep; | ||||
new_hk_lfr_me.dpu_spw_rx_too_big = housekeeping_packet.hk_lfr_dpu_spw_rx_too_big; | ||||
// update the me counter | ||||
increment_hk_counter( new_hk_lfr_me.dpu_spw_early_eop, old_hk_lfr_me.dpu_spw_early_eop, counter ); | ||||
increment_hk_counter( new_hk_lfr_me.dpu_spw_invalid_addr, old_hk_lfr_me.dpu_spw_invalid_addr, counter ); | ||||
increment_hk_counter( new_hk_lfr_me.dpu_spw_eep, old_hk_lfr_me.dpu_spw_eep, counter ); | ||||
increment_hk_counter( new_hk_lfr_me.dpu_spw_rx_too_big, old_hk_lfr_me.dpu_spw_rx_too_big, counter ); | ||||
// store the counters for the next time | ||||
old_hk_lfr_me.dpu_spw_early_eop = new_hk_lfr_me.dpu_spw_early_eop; | ||||
old_hk_lfr_me.dpu_spw_invalid_addr = new_hk_lfr_me.dpu_spw_invalid_addr; | ||||
old_hk_lfr_me.dpu_spw_eep = new_hk_lfr_me.dpu_spw_eep; | ||||
old_hk_lfr_me.dpu_spw_rx_too_big = new_hk_lfr_me.dpu_spw_rx_too_big; | ||||
// update housekeeping packet counters, convert unsigned int numbers in 2 bytes numbers | ||||
// ME | ||||
housekeeping_packet.hk_lfr_me_cnt[0] = (unsigned char) ((hk_lfr_me_cnt & 0xff00) >> 8); | ||||
housekeeping_packet.hk_lfr_me_cnt[1] = (unsigned char) (hk_lfr_me_cnt & 0x00ff); | ||||
} | ||||
void hk_lfr_le_me_he_update() | ||||
{ | ||||
unsigned int hk_lfr_he_cnt; | ||||
hk_lfr_he_cnt = ((unsigned int) housekeeping_packet.hk_lfr_he_cnt[0]) * 256 + housekeeping_packet.hk_lfr_he_cnt[1]; | ||||
//update the low severity error counter | ||||
hk_lfr_le_update( ); | ||||
paul
|
r240 | //update the medium severity error counter | ||
paul
|
r317 | hk_lfr_me_update(); | ||
paul
|
r240 | |||
//update the high severity error counter | ||||
hk_lfr_he_cnt = 0; | ||||
// update housekeeping packet counters, convert unsigned int numbers in 2 bytes numbers | ||||
// HE | ||||
housekeeping_packet.hk_lfr_he_cnt[0] = (unsigned char) ((hk_lfr_he_cnt & 0xff00) >> 8); | ||||
housekeeping_packet.hk_lfr_he_cnt[1] = (unsigned char) (hk_lfr_he_cnt & 0x00ff); | ||||
} | ||||
paul
|
r249 | |||
void set_hk_lfr_time_not_synchro() | ||||
{ | ||||
paul
|
r252 | static unsigned char synchroLost = 1; | ||
paul
|
r249 | int synchronizationBit; | ||
// get the synchronization bit | ||||
synchronizationBit = (time_management_regs->coarse_time & 0x80000000) >> 31; // 1000 0000 0000 0000 | ||||
switch (synchronizationBit) | ||||
{ | ||||
case 0: | ||||
if (synchroLost == 1) | ||||
{ | ||||
synchroLost = 0; | ||||
} | ||||
break; | ||||
case 1: | ||||
if (synchroLost == 0 ) | ||||
{ | ||||
synchroLost = 1; | ||||
increase_unsigned_char_counter(&housekeeping_packet.hk_lfr_time_not_synchro); | ||||
paul
|
r263 | update_hk_lfr_last_er_fields( RID_LE_LFR_TIME, CODE_NOT_SYNCHRO ); | ||
paul
|
r249 | } | ||
break; | ||||
default: | ||||
PRINTF1("in hk_lfr_time_not_synchro *** unexpected value for synchronizationBit = %d\n", synchronizationBit); | ||||
break; | ||||
} | ||||
} | ||||
paul
|
r259 | |||
paul
|
r290 | void set_hk_lfr_ahb_correctable() // CRITICITY L | ||
paul
|
r259 | { | ||
/** This function builds the error counter hk_lfr_ahb_correctable using the statistics provided | ||||
* by the Cache Control Register (ASI 2, offset 0) and in the Register Protection Control Register (ASR16) on the | ||||
* detected errors in the cache, in the integer unit and in the floating point unit. | ||||
* | ||||
* @param void | ||||
* | ||||
* @return void | ||||
* | ||||
* All errors are summed to set the value of the hk_lfr_ahb_correctable counter. | ||||
* | ||||
*/ | ||||
unsigned int ahb_correctable; | ||||
unsigned int instructionErrorCounter; | ||||
unsigned int dataErrorCounter; | ||||
unsigned int fprfErrorCounter; | ||||
unsigned int iurfErrorCounter; | ||||
CCR_getInstructionAndDataErrorCounters( &instructionErrorCounter, &dataErrorCounter); | ||||
ASR16_get_FPRF_IURF_ErrorCounters( &fprfErrorCounter, &iurfErrorCounter); | ||||
ahb_correctable = instructionErrorCounter | ||||
+ dataErrorCounter | ||||
+ fprfErrorCounter | ||||
+ iurfErrorCounter | ||||
+ housekeeping_packet.hk_lfr_ahb_correctable; | ||||
paul
|
r278 | housekeeping_packet.hk_lfr_ahb_correctable = (unsigned char) (ahb_correctable & 0xff); // [1111 1111] | ||
paul
|
r259 | |||
} | ||||