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sync with LFR_basic-parameters
sync with LFR_basic-parameters
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fsw_processing.h
298 lines | 11.0 KiB | text/x-c | CLexer
/ header / processing / fsw_processing.h
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#ifndef FSW_PROCESSING_H_INCLUDED
#define FSW_PROCESSING_H_INCLUDED
#include <rtems.h>
#include <grspw.h>
#include <math.h>
#include <stdlib.h> // abs() is in the stdlib
#include <stdio.h> // printf()
#include <math.h>
#include <grlib_regs.h>
#include "fsw_params.h"
#include "fsw_spacewire.h"
typedef struct ring_node_asm
{
struct ring_node_asm *next;
float matrix[ TOTAL_SIZE_SM ];
unsigned int status;
} ring_node_asm;
typedef struct
{
unsigned char targetLogicalAddress;
unsigned char protocolIdentifier;
unsigned char reserved;
unsigned char userApplication;
unsigned char packetID[2];
unsigned char packetSequenceControl[2];
unsigned char packetLength[2];
// DATA FIELD HEADER
unsigned char spare1_pusVersion_spare2;
unsigned char serviceType;
unsigned char serviceSubType;
unsigned char destinationID;
unsigned char time[6];
// AUXILIARY HEADER
unsigned char sid;
unsigned char biaStatusInfo;
unsigned char acquisitionTime[6];
unsigned char pa_lfr_bp_blk_nr[2];
// SOURCE DATA
unsigned char data[ 30 * 22 ]; // MAX size is 22 * 30 [TM_LFR_SCIENCE_BURST_BP2_F1]
} bp_packet;
typedef struct
{
Header_TM_LFR_SCIENCE_BP_with_spare_t header;
unsigned char data[ 9 * 13 ]; // only for TM_LFR_SCIENCE_NORMAL_BP1_F0 and F1
} bp_packet_with_spare;
typedef struct
{
ring_node_asm *norm;
ring_node_asm *burst_sbm;
rtems_event_set event;
unsigned int coarseTimeNORM;
unsigned int fineTimeNORM;
unsigned int coarseTimeSBM;
unsigned int fineTimeSBM;
} asm_msg;
extern volatile int sm_f0[ ];
extern volatile int sm_f1[ ];
extern volatile int sm_f2[ ];
// parameters
extern struct param_local_str param_local;
// registers
extern time_management_regs_t *time_management_regs;
extern volatile spectral_matrix_regs_t *spectral_matrix_regs;
extern rtems_name misc_name[5];
extern rtems_id Task_id[20]; /* array of task ids */
//
ring_node * getRingNodeForAveraging( unsigned char frequencyChannel);
// ISR
rtems_isr spectral_matrices_isr( rtems_vector_number vector );
rtems_isr spectral_matrices_isr_simu( rtems_vector_number vector );
//******************
// Spectral Matrices
void reset_nb_sm( void );
// SM
void SM_init_rings( void );
void SM_reset_current_ring_nodes( void );
// ASM
void ASM_generic_init_ring(ring_node_asm *ring, unsigned char nbNodes );
//*****************
// Basic Parameters
void BP_reset_current_ring_nodes( void );
void BP_init_header(bp_packet *header,
unsigned int apid, unsigned char sid,
unsigned int packetLength , unsigned char blkNr);
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 );
void BP_send( char *data,
rtems_id queue_id ,
unsigned int nbBytesToSend , unsigned int sid );
//******************
// general functions
void reset_sm_status( void );
void reset_spectral_matrix_regs( void );
void set_time(unsigned char *time, unsigned char *timeInBuffer );
unsigned long long int get_acquisition_time( unsigned char *timePtr );
unsigned char getSID( rtems_event_set event );
extern rtems_status_code get_message_queue_id_prc1( rtems_id *queue_id );
extern rtems_status_code get_message_queue_id_prc2( rtems_id *queue_id );
//***************************************
// DEFINITIONS OF STATIC INLINE FUNCTIONS
static inline void SM_average(float *averaged_spec_mat_NORM, float *averaged_spec_mat_SBM,
ring_node *ring_node_tab[],
unsigned int nbAverageNORM, unsigned int nbAverageSBM,
asm_msg *msgForMATR );
static inline void SM_average_debug( float *averaged_spec_mat_NORM, float *averaged_spec_mat_SBM,
ring_node *ring_node_tab[],
unsigned int nbAverageNORM, unsigned int nbAverageSBM );
static inline void ASM_reorganize_and_divide(float *averaged_spec_mat, float *averaged_spec_mat_reorganized,
float divider );
static inline 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);
static inline void ASM_convert(volatile float *input_matrix, char *output_matrix);
void SM_average( float *averaged_spec_mat_NORM, float *averaged_spec_mat_SBM,
ring_node *ring_node_tab[],
unsigned int nbAverageNORM, unsigned int nbAverageSBM,
asm_msg *msgForMATR )
{
float sum;
unsigned int i;
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 ( (nbAverageNORM == 0) && (nbAverageSBM == 0) )
{
averaged_spec_mat_NORM[ i ] = sum;
averaged_spec_mat_SBM[ i ] = sum;
msgForMATR->coarseTimeNORM = ring_node_tab[0]->coarseTime;
msgForMATR->fineTimeNORM = ring_node_tab[0]->fineTime;
msgForMATR->coarseTimeSBM = ring_node_tab[0]->coarseTime;
msgForMATR->fineTimeSBM = ring_node_tab[0]->fineTime;
}
else if ( (nbAverageNORM != 0) && (nbAverageSBM != 0) )
{
averaged_spec_mat_NORM[ i ] = ( averaged_spec_mat_NORM[ i ] + sum );
averaged_spec_mat_SBM[ i ] = ( averaged_spec_mat_SBM[ i ] + sum );
}
else if ( (nbAverageNORM != 0) && (nbAverageSBM == 0) )
{
averaged_spec_mat_NORM[ i ] = ( averaged_spec_mat_NORM[ i ] + sum );
averaged_spec_mat_SBM[ i ] = sum;
msgForMATR->coarseTimeSBM = ring_node_tab[0]->coarseTime;
msgForMATR->fineTimeSBM = ring_node_tab[0]->fineTime;
}
else
{
PRINTF2("ERR *** in SM_average *** unexpected parameters %d %d\n", nbAverageNORM, nbAverageSBM)
}
}
}
void SM_average_debug( float *averaged_spec_mat_NORM, float *averaged_spec_mat_SBM,
ring_node *ring_node_tab[],
unsigned int nbAverageNORM, unsigned int nbAverageSBM )
{
float sum;
unsigned int i;
for(i=0; i<TOTAL_SIZE_SM; i++)
{
sum = ( (int *) (ring_node_tab[0]->buffer_address) ) [ i ];
if ( (nbAverageNORM == 0) && (nbAverageSBM == 0) )
{
averaged_spec_mat_NORM[ i ] = sum;
averaged_spec_mat_SBM[ i ] = sum;
}
else if ( (nbAverageNORM != 0) && (nbAverageSBM != 0) )
{
averaged_spec_mat_NORM[ i ] = sum;
averaged_spec_mat_SBM[ i ] = sum;
}
else if ( (nbAverageNORM != 0) && (nbAverageSBM == 0) )
{
averaged_spec_mat_NORM[ i ] = sum;
averaged_spec_mat_SBM[ i ] = sum;
}
else
{
PRINTF2("ERR *** in SM_average *** unexpected parameters %d %d\n", nbAverageNORM, nbAverageSBM)
}
}
}
void ASM_reorganize_and_divide( float *averaged_spec_mat, float *averaged_spec_mat_reorganized, float divider )
{
int frequencyBin;
int asmComponent;
unsigned int offsetASM;
unsigned int offsetASMReorganized;
// BUILD DATA
for (asmComponent = 0; asmComponent < NB_VALUES_PER_SM; asmComponent++)
{
for( frequencyBin = 0; frequencyBin < NB_BINS_PER_SM; frequencyBin++ )
{
offsetASMReorganized =
frequencyBin * NB_VALUES_PER_SM
+ asmComponent;
offsetASM =
asmComponent * NB_BINS_PER_SM
+ frequencyBin;
averaged_spec_mat_reorganized[offsetASMReorganized ] =
averaged_spec_mat[ offsetASM ] / 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;
// BUILD DATA
for (asmComponent = 0; asmComponent < NB_VALUES_PER_SM; asmComponent++)
{
for( frequencyBin = 0; frequencyBin < nbBinsCompressedMatrix; frequencyBin++ )
{
offsetCompressed = // NO TIME OFFSET
frequencyBin * NB_VALUES_PER_SM
+ asmComponent;
offsetASM = // NO 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 ] );
}
compressed_spec_mat[ offsetCompressed ] =
compressed_spec_mat[ offsetCompressed ] / (divider * nbBinsToAverage);
}
}
}
void ASM_convert( volatile float *input_matrix, char *output_matrix)
{
unsigned int frequencyBin;
unsigned int asmComponent;
char * pt_char_input;
char * pt_char_output;
unsigned int offsetInput;
unsigned int offsetOutput;
pt_char_input = (char*) &input_matrix;
pt_char_output = (char*) &output_matrix;
// convert all other data
for( frequencyBin=0; frequencyBin<NB_BINS_PER_SM; frequencyBin++)
{
for ( asmComponent=0; asmComponent<NB_VALUES_PER_SM; asmComponent++)
{
offsetInput = (frequencyBin*NB_VALUES_PER_SM) + asmComponent ;
offsetOutput = 2 * ( (frequencyBin*NB_VALUES_PER_SM) + asmComponent ) ;
pt_char_input = (char*) &input_matrix [ offsetInput ];
pt_char_output = (char*) &output_matrix[ offsetOutput ];
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
}
}
}
#endif // FSW_PROCESSING_H_INCLUDED