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Sync BP parameters are set in accordance with TC_LFR_LOAD_NORMAL, BURST, SBM1 and SBM2 BP packets related to f0 data are sent in any mode
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r117:7ccc2641c507 VHDLib206
r117:7ccc2641c507 VHDLib206
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fsw_processing.c
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/** Functions related to data processing.
*
* @file
* @author P. LEROY
*
* These function are related to data processing, i.e. spectral matrices averaging and basic parameters computation.
*
*/
#include <fsw_processing.h>
#include "fsw_processing_globals.c"
//************************
// spectral matrices rings
ring_node_sm sm_ring_f0[ NB_RING_NODES_SM_F0 ];
ring_node_sm sm_ring_f1[ NB_RING_NODES_SM_F1 ];
ring_node_sm sm_ring_f2[ NB_RING_NODES_SM_F2 ];
ring_node_sm *current_ring_node_sm_f0;
ring_node_sm *ring_node_for_averaging_sm_f0;
ring_node_sm *current_ring_node_sm_f1;
ring_node_sm *current_ring_node_sm_f2;
ring_node_asm asm_ring_burst_sbm_f0[ NB_RING_NODES_ASM_BURST_SBM_F0 ];
ring_node_asm *current_ring_node_asm_burst_sbm_f0;
ring_node_asm *ring_node_for_processing_asm_burst_sbm_f0;
//*****
// NORM
// F0
float asm_norm_f0 [ TIME_OFFSET + TOTAL_SIZE_SM ];
float asm_f0_reorganized [ TIME_OFFSET + TOTAL_SIZE_SM ];
char asm_f0_char [ TIME_OFFSET_IN_BYTES + (TOTAL_SIZE_SM * 2) ];
float compressed_sm_norm_f0[ TIME_OFFSET + TOTAL_SIZE_COMPRESSED_ASM_F0 ];
//*****
// SBM1
float asm_sbm_f0 [ TIME_OFFSET + TOTAL_SIZE_SM ];
float compressed_sm_sbm[ TIME_OFFSET + TOTAL_SIZE_COMPRESSED_ASM_SBM1 ];
unsigned char LFR_BP1_F0[ TIME_OFFSET_IN_BYTES + TOTAL_SIZE_NORM_BP1_F0 * 2 ];
unsigned char LFR_BP1_F1[ TIME_OFFSET_IN_BYTES + TOTAL_SIZE_NORM_BP1_F1 ];
unsigned char LFR_BP1_F2[ TIME_OFFSET_IN_BYTES + TOTAL_SIZE_NORM_BP1_F2 ];
//***********************************************************
// Interrupt Service Routine for spectral matrices processing
void reset_nb_sm_f0( unsigned char lfrMode )
{
nb_sm.f0 = 0;
nb_sm.norm_bp1_f0 = 0;
nb_sm.norm_bp2_f0 = 0;
nb_sm.norm_asm_f0 = 0;
nb_sm.sbm_bp1_f0 = 0;
nb_sm.sbm_bp2_f0 = 0;
nb_sm_before_bp.norm_bp1_f0 = parameter_dump_packet.sy_lfr_n_bp_p0 * 96;
nb_sm_before_bp.norm_bp2_f0 = parameter_dump_packet.sy_lfr_n_bp_p1 * 96;
nb_sm_before_bp.norm_asm_f0 = (parameter_dump_packet.sy_lfr_n_asm_p[0] * 256 + parameter_dump_packet.sy_lfr_n_asm_p[1]) * 96;
nb_sm_before_bp.sbm1_bp1_f0 = parameter_dump_packet.sy_lfr_s1_bp_p0 * 24;
nb_sm_before_bp.sbm1_bp2_f0 = parameter_dump_packet.sy_lfr_s1_bp_p1 * 96;
nb_sm_before_bp.sbm2_bp1_f0 = parameter_dump_packet.sy_lfr_s2_bp_p0 * 96;
nb_sm_before_bp.sbm2_bp2_f0 = parameter_dump_packet.sy_lfr_s2_bp_p1 * 96;
nb_sm_before_bp.burst_bp1_f0 = parameter_dump_packet.sy_lfr_b_bp_p0 * 96;
nb_sm_before_bp.burst_bp2_f0 = parameter_dump_packet.sy_lfr_b_bp_p1 * 96;
if (lfrMode == LFR_MODE_SBM1)
{
nb_sm_before_bp.burst_sbm_bp1_f0 = nb_sm_before_bp.sbm1_bp1_f0;
nb_sm_before_bp.burst_sbm_bp2_f0 = nb_sm_before_bp.sbm1_bp2_f0;
}
else if (lfrMode == LFR_MODE_SBM2)
{
nb_sm_before_bp.burst_sbm_bp1_f0 = nb_sm_before_bp.sbm2_bp1_f0;
nb_sm_before_bp.burst_sbm_bp2_f0 = nb_sm_before_bp.sbm2_bp2_f0;
}
else if (lfrMode == LFR_MODE_BURST)
{
nb_sm_before_bp.burst_sbm_bp1_f0 = nb_sm_before_bp.burst_bp1_f0;
nb_sm_before_bp.burst_sbm_bp2_f0 = nb_sm_before_bp.burst_bp2_f0;
}
else
{
nb_sm_before_bp.burst_sbm_bp1_f0 = nb_sm_before_bp.burst_bp1_f0;
nb_sm_before_bp.burst_sbm_bp2_f0 = nb_sm_before_bp.burst_bp2_f0;
}
}
rtems_isr spectral_matrices_isr( rtems_vector_number vector )
{
// rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_8 );
// if ( (spectral_matrix_regs->status & 0x1) == 0x01)
// {
// current_ring_node_sm_f0 = current_ring_node_sm_f0->next;
// spectral_matrix_regs->matrixF0_Address0 = current_ring_node_sm_f0->buffer_address;
// spectral_matrix_regs->status = spectral_matrix_regs->status & 0xfffffffe; // 1110
// nb_sm_f0 = nb_sm_f0 + 1;
// }
// else if ( (spectral_matrix_regs->status & 0x2) == 0x02)
// {
// current_ring_node_sm_f0 = current_ring_node_sm_f0->next;
// spectral_matrix_regs->matrixFO_Address1 = current_ring_node_sm_f0->buffer_address;
// spectral_matrix_regs->status = spectral_matrix_regs->status & 0xfffffffd; // 1101
// nb_sm_f0 = nb_sm_f0 + 1;
// }
// if ( (spectral_matrix_regs->status & 0x30) != 0x00)
// {
// rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_8 );
// spectral_matrix_regs->status = spectral_matrix_regs->status & 0xffffffcf; // 1100 1111
// }
// spectral_matrix_regs->status = spectral_matrix_regs->status & 0xfffffff3; // 0011
// if (nb_sm_f0 == (NB_SM_BEFORE_AVF0-1) )
// {
// ring_node_for_averaging_sm_f0 = current_ring_node_sm_f0;
// if (rtems_event_send( Task_id[TASKID_AVF0], RTEMS_EVENT_0 ) != RTEMS_SUCCESSFUL)
// {
// rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_3 );
// }
// nb_sm_f0 = 0;
// }
// else
// {
// nb_sm.nb_sm_f0 = nb_sm.nb_sm_f0 + 1;
// }
}
rtems_isr spectral_matrices_isr_simu( rtems_vector_number vector )
{
if (nb_sm.f0 == (NB_SM_BEFORE_AVF0-1) )
{
ring_node_for_averaging_sm_f0 = current_ring_node_sm_f0;
if (rtems_event_send( Task_id[TASKID_AVF0], RTEMS_EVENT_0 ) != RTEMS_SUCCESSFUL)
{
rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_3 );
}
nb_sm.f0 = 0;
}
else
{
nb_sm.f0 = nb_sm.f0 + 1;
}
}
//************
// RTEMS TASKS
rtems_task smiq_task( rtems_task_argument argument ) // process the Spectral Matrices IRQ
{
rtems_event_set event_out;
BOOT_PRINTF("in SMIQ *** \n")
while(1){
rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out); // wait for an RTEMS_EVENT0
}
}
rtems_task avf0_task( rtems_task_argument lfrRequestedMode )
{
int i;
rtems_event_set event_out;
rtems_event_set event_for_matr;
rtems_status_code status;
ring_node_sm *ring_node_tab[8];
unsigned long long int localTime;
reset_nb_sm_f0( lfrRequestedMode ); // reset the sm counters that drive the BP and ASM computations / transmissions
BOOT_PRINTF1("in AVFO *** lfrRequestedMode = %d\n", lfrRequestedMode)
while(1){
rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out); // wait for an RTEMS_EVENT0
ring_node_tab[NB_SM_BEFORE_AVF0-1] = ring_node_for_averaging_sm_f0;
for ( i = 2; i < (NB_SM_BEFORE_AVF0+1); i++ )
{
ring_node_for_averaging_sm_f0 = ring_node_for_averaging_sm_f0->previous;
ring_node_tab[NB_SM_BEFORE_AVF0-i] = ring_node_for_averaging_sm_f0;
}
localTime = getTimeAsUnsignedLongLongInt( );
// compute the average and store it in the averaged_sm_f1 buffer
SM_average( asm_norm_f0, current_ring_node_asm_burst_sbm_f0->asm_burst_sbm_f0,
ring_node_tab,
nb_sm.norm_bp1_f0, nb_sm.sbm_bp1_f0 );
localTime = getTimeAsUnsignedLongLongInt( ) - localTime;
// update nb_average
nb_sm.norm_bp1_f0 = nb_sm.norm_bp1_f0 + NB_SM_BEFORE_AVF0;
nb_sm.norm_bp2_f0 = nb_sm.norm_bp2_f0 + NB_SM_BEFORE_AVF0;
nb_sm.norm_asm_f0 = nb_sm.norm_asm_f0 + NB_SM_BEFORE_AVF0;
nb_sm.sbm_bp1_f0 = nb_sm.sbm_bp1_f0 + NB_SM_BEFORE_AVF0;
nb_sm.sbm_bp2_f0 = nb_sm.sbm_bp2_f0 + NB_SM_BEFORE_AVF0;
//***********************************************************
// build a composite event that will be sent to the MATR task
event_for_matr = 0x00;
if (nb_sm.sbm_bp1_f0 == nb_sm_before_bp.burst_sbm_bp1_f0)
{
nb_sm.sbm_bp1_f0 = 0;
// the ring node is ready for BP calculations
ring_node_for_processing_asm_burst_sbm_f0 = current_ring_node_asm_burst_sbm_f0;
// set another ring for the ASM storage
current_ring_node_asm_burst_sbm_f0 = current_ring_node_asm_burst_sbm_f0->next;
if ( (lfrCurrentMode == LFR_MODE_BURST)
|| (lfrCurrentMode == LFR_MODE_SBM1) || (lfrCurrentMode == LFR_MODE_SBM2) )
{
event_for_matr = event_for_matr | RTEMS_EVENT_BURST_SBM_BP1_F0;
}
}
if (nb_sm.sbm_bp2_f0 == nb_sm_before_bp.burst_sbm_bp2_f0)
{
nb_sm.sbm_bp2_f0 = 0;
if ( (lfrCurrentMode == LFR_MODE_BURST)
|| (lfrCurrentMode == LFR_MODE_SBM1) || (lfrCurrentMode == LFR_MODE_SBM2) )
{
event_for_matr = event_for_matr | RTEMS_EVENT_BURST_SBM_BP2_F0;
}
}
if (nb_sm.norm_bp1_f0 == nb_sm_before_bp.norm_bp1_f0)
{
nb_sm.norm_bp1_f0 = 0;
if (lfrCurrentMode == LFR_MODE_NORMAL)
{
event_for_matr = event_for_matr | RTEMS_EVENT_NORM_BP1_F0;
}
}
if (nb_sm.norm_bp2_f0 == nb_sm_before_bp.norm_bp2_f0)
{
nb_sm.norm_bp2_f0 = 0;
if ( (lfrCurrentMode == LFR_MODE_NORMAL)
|| (lfrCurrentMode == LFR_MODE_SBM1) || (lfrCurrentMode == LFR_MODE_SBM2) )
{
event_for_matr = event_for_matr | RTEMS_EVENT_NORM_BP2_F0;
}
}
if (nb_sm.norm_asm_f0 == nb_sm_before_bp.norm_asm_f0)
{
nb_sm.norm_asm_f0 = 0;
if ( (lfrCurrentMode == LFR_MODE_NORMAL)
|| (lfrCurrentMode == LFR_MODE_SBM1) || (lfrCurrentMode == LFR_MODE_SBM2) )
{
// PRINTF1("%lld\n", localTime)
event_for_matr = event_for_matr | RTEMS_EVENT_NORM_ASM_F0;
}
}
//*********************************
// send the composite event to MATR
status = rtems_event_send( Task_id[TASKID_MATR], event_for_matr );
if (status != RTEMS_SUCCESSFUL) {
printf("in AVF0 *** Error sending RTEMS_EVENT_0, code %d\n", status);
}
}
}
rtems_task matr_task( rtems_task_argument lfrRequestedMode )
{
spw_ioctl_pkt_send spw_ioctl_send_ASM;
rtems_event_set event_out;
rtems_status_code status;
rtems_id queue_id;
Header_TM_LFR_SCIENCE_ASM_t headerASM;
bp_packet_with_spare current_node_norm_bp1_f0;
bp_packet current_node_norm_bp2_f0;
bp_packet current_node_sbm_bp1_f0;
bp_packet current_node_sbm_bp2_f0;
unsigned long long int localTime;
ASM_init_header( &headerASM );
//*************
// NORM headers
BP_init_header_with_spare( &current_node_norm_bp1_f0.header,
APID_TM_SCIENCE_NORMAL_BURST, SID_NORM_BP1_F0,
PACKET_LENGTH_TM_LFR_SCIENCE_NORM_BP1_F0, NB_BINS_COMPRESSED_SM_F0 );
BP_init_header( &current_node_norm_bp2_f0.header,
APID_TM_SCIENCE_NORMAL_BURST, SID_NORM_BP2_F0,
PACKET_LENGTH_TM_LFR_SCIENCE_NORM_BP2_F0, NB_BINS_COMPRESSED_SM_F0);
//****************************
// BURST SBM1 and SBM2 headers
if ( (lfrRequestedMode == LFR_MODE_BURST)
|| (lfrRequestedMode == LFR_MODE_NORMAL) || (lfrRequestedMode == LFR_MODE_STANDBY) )
{
BP_init_header( &current_node_sbm_bp1_f0.header,
APID_TM_SCIENCE_NORMAL_BURST, SID_BURST_BP1_F0,
PACKET_LENGTH_TM_LFR_SCIENCE_SBM_BP1_F0, NB_BINS_COMPRESSED_SM_SBM_F0);
BP_init_header( &current_node_sbm_bp2_f0.header,
APID_TM_SCIENCE_NORMAL_BURST, SID_BURST_BP2_F0,
PACKET_LENGTH_TM_LFR_SCIENCE_SBM_BP2_F0, NB_BINS_COMPRESSED_SM_SBM_F0);
}
else if ( lfrRequestedMode == LFR_MODE_SBM1 )
{
BP_init_header( &current_node_sbm_bp1_f0.header,
APID_TM_SCIENCE_SBM1_SBM2, SID_SBM1_BP1_F0,
PACKET_LENGTH_TM_LFR_SCIENCE_SBM_BP1_F0, NB_BINS_COMPRESSED_SM_SBM_F0);
BP_init_header( &current_node_sbm_bp2_f0.header,
APID_TM_SCIENCE_SBM1_SBM2, SID_SBM1_BP2_F0,
PACKET_LENGTH_TM_LFR_SCIENCE_SBM_BP2_F0, NB_BINS_COMPRESSED_SM_SBM_F0);
}
else if ( lfrRequestedMode == LFR_MODE_SBM2 )
{
BP_init_header( &current_node_sbm_bp1_f0.header,
APID_TM_SCIENCE_SBM1_SBM2, SID_SBM2_BP1_F0,
PACKET_LENGTH_TM_LFR_SCIENCE_SBM_BP1_F0, NB_BINS_COMPRESSED_SM_SBM_F0);
BP_init_header( &current_node_sbm_bp2_f0.header,
APID_TM_SCIENCE_SBM1_SBM2, SID_SBM2_BP2_F0,
PACKET_LENGTH_TM_LFR_SCIENCE_SBM_BP2_F0, NB_BINS_COMPRESSED_SM_SBM_F0);
}
else
{
PRINTF1("ERR *** in MATR *** unexpected lfrRequestedMode passed as argument = %d\n", (unsigned int) lfrRequestedMode)
}
status = get_message_queue_id_send( &queue_id );
if (status != RTEMS_SUCCESSFUL)
{
PRINTF1("in MATR *** ERR get_message_queue_id_send %d\n", status)
}
BOOT_PRINTF1("in MATR *** lfrRequestedMode = %d\n", lfrRequestedMode)
while(1){
rtems_event_receive( RTEMS_EVENT_NORM_BP1_F0 | RTEMS_EVENT_NORM_BP2_F0 | RTEMS_EVENT_NORM_ASM_F0
| RTEMS_EVENT_BURST_SBM_BP1_F0 | RTEMS_EVENT_BURST_SBM_BP2_F0,
RTEMS_WAIT | RTEMS_EVENT_ANY, RTEMS_NO_TIMEOUT, &event_out);
localTime = getTimeAsUnsignedLongLongInt( );
//****************
//****************
// BURST SBM1 SBM2
//****************
//****************
if ( event_out & RTEMS_EVENT_BURST_SBM_BP1_F0 )
{
// 1) compress the matrix for Basic Parameters calculation
ASM_compress_reorganize_and_divide( current_ring_node_asm_burst_sbm_f0->asm_burst_sbm_f0, compressed_sm_sbm,
nb_sm_before_bp.burst_sbm_bp1_f0,
NB_BINS_COMPRESSED_SM_SBM_F0, NB_BINS_TO_AVERAGE_ASM_SBM_F0,
ASM_F0_INDICE_START);
// 2) compute the BP1 set
// 3) send the BP1 set
set_time( current_node_sbm_bp1_f0.header.time, (unsigned char *) &compressed_sm_sbm );
set_time( current_node_sbm_bp1_f0.header.acquisitionTime, (unsigned char *) &compressed_sm_sbm );
BP_send( (char *) &current_node_sbm_bp1_f0.header, queue_id,
PACKET_LENGTH_TM_LFR_SCIENCE_SBM_BP1_F0 + PACKET_LENGTH_DELTA);
// 4) compute the BP2 set if needed
if ( event_out & RTEMS_EVENT_BURST_SBM_BP2_F0 )
{
// 1) compute the BP2 set
// 2) send the BP2 set
set_time( current_node_sbm_bp2_f0.header.time, (unsigned char *) &compressed_sm_sbm );
set_time( current_node_sbm_bp2_f0.header.acquisitionTime, (unsigned char *) &compressed_sm_sbm );
BP_send( (char *) &current_node_sbm_bp2_f0.header, queue_id,
PACKET_LENGTH_TM_LFR_SCIENCE_SBM_BP2_F0 + PACKET_LENGTH_DELTA);
}
}
//*****
//*****
// NORM
//*****
//*****
if (event_out & RTEMS_EVENT_NORM_BP1_F0)
{
// 1) compress the matrix for Basic Parameters calculation
ASM_compress_reorganize_and_divide( asm_norm_f0, compressed_sm_norm_f0,
nb_sm_before_bp.norm_bp1_f0,
NB_BINS_COMPRESSED_SM_F0, NB_BINS_TO_AVERAGE_ASM_F0,
ASM_F0_INDICE_START );
// 2) compute the BP1 set
// 3) send the BP1 set
set_time( current_node_norm_bp1_f0.header.time, (unsigned char *) &compressed_sm_norm_f0 );
set_time( current_node_norm_bp1_f0.header.acquisitionTime, (unsigned char *) &compressed_sm_norm_f0 );
BP_send( (char *) &current_node_norm_bp1_f0.header, queue_id,
PACKET_LENGTH_TM_LFR_SCIENCE_NORM_BP1_F0 + PACKET_LENGTH_DELTA);
if (event_out & RTEMS_EVENT_NORM_BP2_F0)
{
// 1) compute the BP2 set
// 2) send the BP2 set
set_time( current_node_norm_bp2_f0.header.time, (unsigned char *) &compressed_sm_norm_f0 );
set_time( current_node_norm_bp2_f0.header.acquisitionTime, (unsigned char *) &compressed_sm_norm_f0 );
BP_send( (char *) &current_node_norm_bp2_f0.header, queue_id,
PACKET_LENGTH_TM_LFR_SCIENCE_NORM_BP2_F0 + PACKET_LENGTH_DELTA);
}
}
if (event_out & RTEMS_EVENT_NORM_ASM_F0)
{
// 1) reorganize the ASM and divide
ASM_reorganize_and_divide( asm_norm_f0, asm_f0_reorganized, NB_SM_BEFORE_NORM_BP1_F0 );
// 2) convert the float array in a char array
ASM_convert( asm_f0_reorganized, asm_f0_char);
// 3) send the spectral matrix packets
ASM_send( &headerASM, asm_f0_char, SID_NORM_ASM_F0, &spw_ioctl_send_ASM, queue_id);
// localTime = getTimeAsUnsignedLongLongInt( ) - localTime;
// PRINTF1("in MATR *** %lld\n", localTime)
}
}
}
//******************
// Spectral Matrices
void SM_init_rings( void )
{
unsigned char i;
// F0 RING
sm_ring_f0[0].next = (ring_node_sm*) &sm_ring_f0[1];
sm_ring_f0[0].previous = (ring_node_sm*) &sm_ring_f0[NB_RING_NODES_SM_F0-1];
sm_ring_f0[0].buffer_address =
(int) &sm_f0[ 0 ];
sm_ring_f0[NB_RING_NODES_SM_F0-1].next = (ring_node_sm*) &sm_ring_f0[0];
sm_ring_f0[NB_RING_NODES_SM_F0-1].previous = (ring_node_sm*) &sm_ring_f0[NB_RING_NODES_SM_F0-2];
sm_ring_f0[NB_RING_NODES_SM_F0-1].buffer_address =
(int) &sm_f0[ (NB_RING_NODES_SM_F0-1) * TOTAL_SIZE_SM ];
for(i=1; i<NB_RING_NODES_SM_F0-1; i++)
{
sm_ring_f0[i].next = (ring_node_sm*) &sm_ring_f0[i+1];
sm_ring_f0[i].previous = (ring_node_sm*) &sm_ring_f0[i-1];
sm_ring_f0[i].buffer_address =
(int) &sm_f0[ i * TOTAL_SIZE_SM ];
}
// F1 RING
sm_ring_f1[0].next = (ring_node_sm*) &sm_ring_f1[1];
sm_ring_f1[0].previous = (ring_node_sm*) &sm_ring_f1[NB_RING_NODES_SM_F1-1];
sm_ring_f1[0].buffer_address =
(int) &sm_f1[ 0 ];
sm_ring_f1[NB_RING_NODES_SM_F1-1].next = (ring_node_sm*) &sm_ring_f1[0];
sm_ring_f1[NB_RING_NODES_SM_F1-1].previous = (ring_node_sm*) &sm_ring_f1[NB_RING_NODES_SM_F1-2];
sm_ring_f1[NB_RING_NODES_SM_F1-1].buffer_address =
(int) &sm_f1[ (NB_RING_NODES_SM_F1-1) * TOTAL_SIZE_SM ];
for(i=1; i<NB_RING_NODES_SM_F1-1; i++)
{
sm_ring_f1[i].next = (ring_node_sm*) &sm_ring_f1[i+1];
sm_ring_f1[i].previous = (ring_node_sm*) &sm_ring_f1[i-1];
sm_ring_f1[i].buffer_address =
(int) &sm_f1[ i * TOTAL_SIZE_SM ];
}
// F2 RING
sm_ring_f2[0].next = (ring_node_sm*) &sm_ring_f2[1];
sm_ring_f2[0].previous = (ring_node_sm*) &sm_ring_f2[NB_RING_NODES_SM_F2-1];
sm_ring_f2[0].buffer_address =
(int) &sm_f2[ 0 ];
sm_ring_f2[NB_RING_NODES_SM_F2-1].next = (ring_node_sm*) &sm_ring_f2[0];
sm_ring_f2[NB_RING_NODES_SM_F2-1].previous = (ring_node_sm*) &sm_ring_f2[NB_RING_NODES_SM_F2-2];
sm_ring_f2[NB_RING_NODES_SM_F2-1].buffer_address =
(int) &sm_f2[ (NB_RING_NODES_SM_F2-1) * TOTAL_SIZE_SM ];
for(i=1; i<NB_RING_NODES_SM_F2-1; i++)
{
sm_ring_f2[i].next = (ring_node_sm*) &sm_ring_f2[i+1];
sm_ring_f2[i].previous = (ring_node_sm*) &sm_ring_f2[i-1];
sm_ring_f2[i].buffer_address =
(int) &sm_f2[ i * TOTAL_SIZE_SM ];
}
DEBUG_PRINTF1("asm_ring_f0 @%x\n", (unsigned int) sm_ring_f0)
DEBUG_PRINTF1("asm_ring_f1 @%x\n", (unsigned int) sm_ring_f1)
DEBUG_PRINTF1("asm_ring_f2 @%x\n", (unsigned int) sm_ring_f2)
spectral_matrix_regs->matrixF0_Address0 = sm_ring_f0[0].buffer_address;
DEBUG_PRINTF1("spectral_matrix_regs->matrixF0_Address0 @%x\n", spectral_matrix_regs->matrixF0_Address0)
}
void ASM_init_ring( void )
{
unsigned char i;
asm_ring_burst_sbm_f0[0].next = (ring_node_asm*) &asm_ring_burst_sbm_f0[1];
asm_ring_burst_sbm_f0[0].previous = (ring_node_asm*) &asm_ring_burst_sbm_f0[NB_RING_NODES_ASM_BURST_SBM_F0-1];
asm_ring_burst_sbm_f0[NB_RING_NODES_ASM_BURST_SBM_F0-1].next
= (ring_node_asm*) &asm_ring_burst_sbm_f0[0];
asm_ring_burst_sbm_f0[NB_RING_NODES_ASM_BURST_SBM_F0-1].previous
= (ring_node_asm*) &asm_ring_burst_sbm_f0[NB_RING_NODES_ASM_BURST_SBM_F0-2];
for(i=1; i<NB_RING_NODES_ASM_BURST_SBM_F0-1; i++)
{
asm_ring_burst_sbm_f0[i].next = (ring_node_asm*) &asm_ring_burst_sbm_f0[i+1];
asm_ring_burst_sbm_f0[i].previous = (ring_node_asm*) &asm_ring_burst_sbm_f0[i-1];
}
}
void SM_reset_current_ring_nodes( void )
{
current_ring_node_sm_f0 = sm_ring_f0;
current_ring_node_sm_f1 = sm_ring_f1;
current_ring_node_sm_f2 = sm_ring_f2;
ring_node_for_averaging_sm_f0 = sm_ring_f0;
}
void ASM_reset_current_ring_node( void )
{
current_ring_node_asm_burst_sbm_f0 = asm_ring_burst_sbm_f0;
ring_node_for_processing_asm_burst_sbm_f0 = asm_ring_burst_sbm_f0;
}
void ASM_init_header( Header_TM_LFR_SCIENCE_ASM_t *header)
{
header->targetLogicalAddress = CCSDS_DESTINATION_ID;
header->protocolIdentifier = CCSDS_PROTOCOLE_ID;
header->reserved = 0x00;
header->userApplication = CCSDS_USER_APP;
header->packetID[0] = (unsigned char) (APID_TM_SCIENCE_NORMAL_BURST >> 8);
header->packetID[1] = (unsigned char) (APID_TM_SCIENCE_NORMAL_BURST);
header->packetSequenceControl[0] = 0xc0;
header->packetSequenceControl[1] = 0x00;
header->packetLength[0] = 0x00;
header->packetLength[1] = 0x00;
// DATA FIELD HEADER
header->spare1_pusVersion_spare2 = 0x10;
header->serviceType = TM_TYPE_LFR_SCIENCE; // service type
header->serviceSubType = TM_SUBTYPE_LFR_SCIENCE; // service subtype
header->destinationID = TM_DESTINATION_ID_GROUND;
// AUXILIARY DATA HEADER
header->sid = 0x00;
header->biaStatusInfo = 0x00;
header->pa_lfr_pkt_cnt_asm = 0x00;
header->pa_lfr_pkt_nr_asm = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->pa_lfr_asm_blk_nr[0] = 0x00; // BLK_NR MSB
header->pa_lfr_asm_blk_nr[1] = 0x00; // BLK_NR LSB
}
void SM_average( float *averaged_spec_mat_f0, float *averaged_spec_mat_f1,
ring_node_sm *ring_node_tab[],
unsigned int nbAverageNormF0, unsigned int nbAverageSBM1F0 )
{
float sum;
unsigned int i;
unsigned char *ptr;
for(i=0; i<TOTAL_SIZE_SM; i++)
{
sum = ( (int *) (ring_node_tab[0]->buffer_address) ) [ i ]
+ ( (int *) (ring_node_tab[1]->buffer_address) ) [ i ]
+ ( (int *) (ring_node_tab[2]->buffer_address) ) [ i ]
+ ( (int *) (ring_node_tab[3]->buffer_address) ) [ i ]
+ ( (int *) (ring_node_tab[4]->buffer_address) ) [ i ]
+ ( (int *) (ring_node_tab[5]->buffer_address) ) [ i ]
+ ( (int *) (ring_node_tab[6]->buffer_address) ) [ i ]
+ ( (int *) (ring_node_tab[7]->buffer_address) ) [ i ];
if ( (nbAverageNormF0 == 0) && (nbAverageSBM1F0 == 0) )
{
averaged_spec_mat_f0[ TIME_OFFSET + i ] = sum;
averaged_spec_mat_f1[ TIME_OFFSET + i ] = sum;
}
else if ( (nbAverageNormF0 != 0) && (nbAverageSBM1F0 != 0) )
{
averaged_spec_mat_f0[ TIME_OFFSET + i ] = ( averaged_spec_mat_f0[ TIME_OFFSET + i ] + sum );
averaged_spec_mat_f1[ TIME_OFFSET + i ] = ( averaged_spec_mat_f1[ TIME_OFFSET + i ] + sum );
}
else if ( (nbAverageNormF0 != 0) && (nbAverageSBM1F0 == 0) )
{
averaged_spec_mat_f0[ TIME_OFFSET + i ] = ( averaged_spec_mat_f0[ TIME_OFFSET + i ] + sum );
averaged_spec_mat_f1[ TIME_OFFSET + i ] = sum;
}
else
{
PRINTF2("ERR *** in SM_average *** unexpected parameters %d %d\n", nbAverageNormF0, nbAverageSBM1F0)
}
}
if ( (nbAverageNormF0 == 0) && (nbAverageSBM1F0 == 0) )
{
ptr = (unsigned char *) averaged_spec_mat_f0;
ptr[0] = (unsigned char) (time_management_regs->coarse_time >> 24);
ptr[1] = (unsigned char) (time_management_regs->coarse_time >> 16);
ptr[2] = (unsigned char) (time_management_regs->coarse_time >> 8 );
ptr[3] = (unsigned char) (time_management_regs->coarse_time );
ptr[4] = (unsigned char) (time_management_regs->fine_time >> 24);
ptr[5] = (unsigned char) (time_management_regs->fine_time >> 16);
ptr[6] = (unsigned char) (time_management_regs->fine_time >> 8 );
ptr[7] = (unsigned char) (time_management_regs->fine_time );
ptr = (unsigned char *) averaged_spec_mat_f1;
ptr[0] = (unsigned char) (time_management_regs->coarse_time >> 24);
ptr[1] = (unsigned char) (time_management_regs->coarse_time >> 16);
ptr[2] = (unsigned char) (time_management_regs->coarse_time >> 8 );
ptr[3] = (unsigned char) (time_management_regs->coarse_time );
ptr[4] = (unsigned char) (time_management_regs->fine_time >> 24);
ptr[5] = (unsigned char) (time_management_regs->fine_time >> 16);
ptr[6] = (unsigned char) (time_management_regs->fine_time >> 8 );
ptr[7] = (unsigned char) (time_management_regs->fine_time );
}
}
void ASM_reorganize_and_divide( float *averaged_spec_mat, float *averaged_spec_mat_reorganized, float divider )
{
int frequencyBin;
int asmComponent;
// copy the time information
averaged_spec_mat_reorganized[ 0 ] = averaged_spec_mat[ 0 ];
averaged_spec_mat_reorganized[ 1 ] = averaged_spec_mat[ 1 ];
for (asmComponent = 0; asmComponent < NB_VALUES_PER_SM; asmComponent++)
{
for( frequencyBin = 0; frequencyBin < NB_BINS_PER_SM; frequencyBin++ )
{
averaged_spec_mat_reorganized[ TIME_OFFSET + frequencyBin * NB_VALUES_PER_SM + asmComponent ] =
averaged_spec_mat[ TIME_OFFSET + asmComponent * NB_BINS_PER_SM + frequencyBin ] / divider;
}
}
}
void ASM_compress_reorganize_and_divide(float *averaged_spec_mat, float *compressed_spec_mat , float divider,
unsigned char nbBinsCompressedMatrix, unsigned char nbBinsToAverage, unsigned char ASMIndexStart )
{
int frequencyBin;
int asmComponent;
int offsetASM;
int offsetCompressed;
int k;
// copy the time information
compressed_spec_mat[ 0 ] = averaged_spec_mat[ 0 ];
compressed_spec_mat[ 1 ] = averaged_spec_mat[ 1 ];
// build data
for (asmComponent = 0; asmComponent < NB_VALUES_PER_SM; asmComponent++)
{
for( frequencyBin = 0; frequencyBin < nbBinsCompressedMatrix; frequencyBin++ )
{
offsetCompressed = TIME_OFFSET
+ frequencyBin * NB_VALUES_PER_SM
+ asmComponent;
offsetASM = TIME_OFFSET
+ asmComponent * NB_BINS_PER_SM
+ ASMIndexStart
+ frequencyBin * nbBinsToAverage;
compressed_spec_mat[ offsetCompressed ] = 0;
for ( k = 0; k < nbBinsToAverage; k++ )
{
compressed_spec_mat[offsetCompressed ] =
( compressed_spec_mat[ offsetCompressed ]
+ averaged_spec_mat[ offsetASM + k ] ) / (divider * nbBinsToAverage);
}
}
}
}
void ASM_convert( volatile float *input_matrix, char *output_matrix)
{
unsigned int i;
unsigned int frequencyBin;
unsigned int asmComponent;
char * pt_char_input;
char * pt_char_output;
pt_char_input = (char*) &input_matrix;
pt_char_output = (char*) &output_matrix;
// copy the time information
for (i=0; i<TIME_OFFSET_IN_BYTES; i++)
{
pt_char_output[ i ] = pt_char_output[ i ];
}
// convert all other data
for( frequencyBin=0; frequencyBin<NB_BINS_PER_SM; frequencyBin++)
{
for ( asmComponent=0; asmComponent<NB_VALUES_PER_SM; asmComponent++)
{
pt_char_input = (char*) &input_matrix [ (frequencyBin*NB_VALUES_PER_SM) + asmComponent + TIME_OFFSET ];
pt_char_output = (char*) &output_matrix[ 2 * ( (frequencyBin*NB_VALUES_PER_SM) + asmComponent ) + TIME_OFFSET_IN_BYTES ];
pt_char_output[0] = pt_char_input[0]; // bits 31 downto 24 of the float
pt_char_output[1] = pt_char_input[1]; // bits 23 downto 16 of the float
}
}
}
void ASM_send(Header_TM_LFR_SCIENCE_ASM_t *header, char *spectral_matrix,
unsigned int sid, spw_ioctl_pkt_send *spw_ioctl_send, rtems_id queue_id)
{
unsigned int i;
unsigned int length = 0;
rtems_status_code status;
for (i=0; i<2; i++)
{
// (1) BUILD THE DATA
switch(sid)
{
case SID_NORM_ASM_F0:
spw_ioctl_send->dlen = TOTAL_SIZE_ASM_F0_IN_BYTES / 2;
spw_ioctl_send->data = &spectral_matrix[
( (ASM_F0_INDICE_START + (i*NB_BINS_PER_PKT_ASM_F0) ) * NB_VALUES_PER_SM ) * 2
+ TIME_OFFSET_IN_BYTES
];
length = PACKET_LENGTH_TM_LFR_SCIENCE_ASM_F0;
header->pa_lfr_asm_blk_nr[0] = (unsigned char) ( (NB_BINS_PER_PKT_ASM_F0) >> 8 ); // BLK_NR MSB
header->pa_lfr_asm_blk_nr[1] = (unsigned char) (NB_BINS_PER_PKT_ASM_F0); // BLK_NR LSB
break;
case SID_NORM_ASM_F1:
break;
case SID_NORM_ASM_F2:
break;
default:
PRINTF1("ERR *** in ASM_send *** unexpected sid %d\n", sid)
break;
}
spw_ioctl_send->hlen = HEADER_LENGTH_TM_LFR_SCIENCE_ASM + CCSDS_PROTOCOLE_EXTRA_BYTES;
spw_ioctl_send->hdr = (char *) header;
spw_ioctl_send->options = 0;
// (2) BUILD THE HEADER
header->packetLength[0] = (unsigned char) (length>>8);
header->packetLength[1] = (unsigned char) (length);
header->sid = (unsigned char) sid; // SID
header->pa_lfr_pkt_cnt_asm = 2;
header->pa_lfr_pkt_nr_asm = (unsigned char) (i+1);
// (3) SET PACKET TIME
header->time[0] = (unsigned char) (time_management_regs->coarse_time>>24);
header->time[1] = (unsigned char) (time_management_regs->coarse_time>>16);
header->time[2] = (unsigned char) (time_management_regs->coarse_time>>8);
header->time[3] = (unsigned char) (time_management_regs->coarse_time);
header->time[4] = (unsigned char) (time_management_regs->fine_time>>8);
header->time[5] = (unsigned char) (time_management_regs->fine_time);
//
header->acquisitionTime[0] = (unsigned char) (time_management_regs->coarse_time>>24);
header->acquisitionTime[1] = (unsigned char) (time_management_regs->coarse_time>>16);
header->acquisitionTime[2] = (unsigned char) (time_management_regs->coarse_time>>8);
header->acquisitionTime[3] = (unsigned char) (time_management_regs->coarse_time);
header->acquisitionTime[4] = (unsigned char) (time_management_regs->fine_time>>8);
header->acquisitionTime[5] = (unsigned char) (time_management_regs->fine_time);
// (4) SEND PACKET
status = rtems_message_queue_send( queue_id, spw_ioctl_send, ACTION_MSG_SPW_IOCTL_SEND_SIZE);
if (status != RTEMS_SUCCESSFUL) {
printf("in ASM_send *** ERR %d\n", (int) status);
}
}
}
//*****************
// Basic Parameters
void BP_init_header( Header_TM_LFR_SCIENCE_BP_t *header,
unsigned int apid, unsigned char sid,
unsigned int packetLength, unsigned char blkNr )
{
header->targetLogicalAddress = CCSDS_DESTINATION_ID;
header->protocolIdentifier = CCSDS_PROTOCOLE_ID;
header->reserved = 0x00;
header->userApplication = CCSDS_USER_APP;
header->packetID[0] = (unsigned char) (apid >> 8);
header->packetID[1] = (unsigned char) (apid);
header->packetSequenceControl[0] = TM_PACKET_SEQ_CTRL_STANDALONE;
header->packetSequenceControl[1] = 0x00;
header->packetLength[0] = (unsigned char) (packetLength >> 8);
header->packetLength[1] = (unsigned char) (packetLength);
// DATA FIELD HEADER
header->spare1_pusVersion_spare2 = 0x10;
header->serviceType = TM_TYPE_LFR_SCIENCE; // service type
header->serviceSubType = TM_SUBTYPE_LFR_SCIENCE; // service subtype
header->destinationID = TM_DESTINATION_ID_GROUND;
// AUXILIARY DATA HEADER
header->sid = sid;
header->biaStatusInfo = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->pa_lfr_bp_blk_nr[0] = 0x00; // BLK_NR MSB
header->pa_lfr_bp_blk_nr[1] = blkNr; // BLK_NR LSB
}
void BP_init_header_with_spare(Header_TM_LFR_SCIENCE_BP_with_spare_t *header,
unsigned int apid, unsigned char sid,
unsigned int packetLength , unsigned char blkNr)
{
header->targetLogicalAddress = CCSDS_DESTINATION_ID;
header->protocolIdentifier = CCSDS_PROTOCOLE_ID;
header->reserved = 0x00;
header->userApplication = CCSDS_USER_APP;
header->packetID[0] = (unsigned char) (apid >> 8);
header->packetID[1] = (unsigned char) (apid);
header->packetSequenceControl[0] = TM_PACKET_SEQ_CTRL_STANDALONE;
header->packetSequenceControl[1] = 0x00;
header->packetLength[0] = (unsigned char) (packetLength >> 8);
header->packetLength[1] = (unsigned char) (packetLength);
// DATA FIELD HEADER
header->spare1_pusVersion_spare2 = 0x10;
header->serviceType = TM_TYPE_LFR_SCIENCE; // service type
header->serviceSubType = TM_SUBTYPE_LFR_SCIENCE; // service subtype
header->destinationID = TM_DESTINATION_ID_GROUND;
// AUXILIARY DATA HEADER
header->sid = sid;
header->biaStatusInfo = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->time[0] = 0x00;
header->pa_lfr_bp_blk_nr[0] = 0x00; // BLK_NR MSB
header->pa_lfr_bp_blk_nr[1] = blkNr; // BLK_NR LSB
}
void BP_send(char *data, rtems_id queue_id, unsigned int nbBytesToSend )
{
rtems_status_code status;
// SEND PACKET
status = rtems_message_queue_send( queue_id, data, nbBytesToSend);
if (status != RTEMS_SUCCESSFUL)
{
printf("ERR *** in BP_send *** ERR %d\n", (int) status);
}
}
//******************
// general functions
void reset_spectral_matrix_regs( void )
{
/** This function resets the spectral matrices module registers.
*
* The registers affected by this function are located at the following offset addresses:
*
* - 0x00 config
* - 0x04 status
* - 0x08 matrixF0_Address0
* - 0x10 matrixFO_Address1
* - 0x14 matrixF1_Address
* - 0x18 matrixF2_Address
*
*/
spectral_matrix_regs->config = 0x00;
spectral_matrix_regs->status = 0x00;
spectral_matrix_regs->matrixF0_Address0 = current_ring_node_sm_f0->buffer_address;
spectral_matrix_regs->matrixFO_Address1 = current_ring_node_sm_f0->buffer_address;
spectral_matrix_regs->matrixF1_Address = current_ring_node_sm_f1->buffer_address;
spectral_matrix_regs->matrixF2_Address = current_ring_node_sm_f2->buffer_address;
}
void set_time( unsigned char *time, unsigned char * timeInBuffer )
{
// time[0] = timeInBuffer[2];
// time[1] = timeInBuffer[3];
// time[2] = timeInBuffer[0];
// time[3] = timeInBuffer[1];
// time[4] = timeInBuffer[6];
// time[5] = timeInBuffer[7];
time[0] = timeInBuffer[0];
time[1] = timeInBuffer[1];
time[2] = timeInBuffer[2];
time[3] = timeInBuffer[3];
time[4] = timeInBuffer[6];
time[5] = timeInBuffer[7];
}