HG_REPOSITORIES/LPP/INSTRUMENTATION/USERS/JEANDET/LFR_FSW Commit - r31:bd675edcd40d

SID corrected in TM_LFR_TC_EXE packets...

paul -

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r31:bd675edcd40d

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header/fsw_params_processing.h created 644 +26 0

@@ -0,0 +1,26
	1	#ifndef FSW_PARAMS_PROCESSING_H
	2	#define FSW_PARAMS_PROCESSING_H
	3
	4	#define NB_BINS_PER_SM 128
	5	#define NB_VALUES_PER_SM 25
	6	#define TOTAL_SIZE_SM (NB_BINS_PER_SM * NB_VALUES_PER_SM)
	7
	8	#define NB_BINS_COMPRESSED_SM_F0 11
	9	#define NB_BINS_COMPRESSED_SM_F1 13
	10	#define NB_BINS_COMPRESSED_SM_F2 12
	11	#define TOTAL_SIZE_COMPRESSED_MATRIX_f0 (NB_BINS_COMPRESSED_SM_F0 * NB_VALUES_PER_SM)
	12	#define NB_AVERAGE_NORMAL_f0 96*4
	13	#define NB_SM_TO_RECEIVE_BEFORE_AVF0 8
	14
	15	struct BP1_str{
	16	volatile unsigned char PE[2];
	17	volatile unsigned char PB[2];
	18	volatile unsigned char V0;
	19	volatile unsigned char V1;
	20	volatile unsigned char V2_ELLIP_DOP;
	21	volatile unsigned char SZ;
	22	volatile unsigned char VPHI;
	23	};
	24	typedef struct BP1_str BP1_t;
	25
	26	#endif // FSW_PARAMS_PROCESSING_H

FSW-qt/Makefile +7 -7

             #############################################################################
-            # Makefile for building: bin/fsw
+            # Makefile for building: bin/fsw-gsa
-            # Generated by qmake (2.01a) (Qt 4.8.4) on: Fri Jul 19 08:56:46 2013
+            # Generated by qmake (2.01a) (Qt 4.8.4) on: Thu Jul 25 10:29:57 2013
             # Project:  fsw-qt.pro
             # Template: app
             # Command: /usr/bin/qmake-qt4 -spec /usr/lib64/qt4/mkspecs/linux-g++ -o Makefile fsw-qt.pro
             CC            = sparc-rtems-gcc
             CXX           = sparc-rtems-g++
-            DEFINES       = -DSW_VERSION_N1=0 -DSW_VERSION_N2=0 -DSW_VERSION_N3=0 -DSW_VERSION_N4=9 -DPRINT_MESSAGES_ON_CONSOLE
+            DEFINES       = -DSW_VERSION_N1=0 -DSW_VERSION_N2=0 -DSW_VERSION_N3=0 -DSW_VERSION_N4=11 -DPRINT_MESSAGES_ON_CONSOLE -DGSA
             CFLAGS        = -pipe -O3 -Wall $(DEFINES)
             CXXFLAGS      = -pipe -O3 -Wall $(DEFINES)
             INCPATH       = -I/usr/lib64/qt4/mkspecs/linux-g++ -I. -I../src -I../header
             		/usr/lib64/qt4/mkspecs/features/lex.prf \
             		/usr/lib64/qt4/mkspecs/features/include_source_dir.prf \
             		fsw-qt.pro
-            QMAKE_TARGET  = fsw
+            QMAKE_TARGET  = fsw-gsa
             DESTDIR       = bin/
-            TARGET        = bin/fsw
+            TARGET        = bin/fsw-gsa
             first: all
             ####### Implicit rules
             	@$(QMAKE) -spec /usr/lib64/qt4/mkspecs/linux-g++ -o Makefile fsw-qt.pro
             dist:
-            	@$(CHK_DIR_EXISTS) obj/fsw1.0.0 || $(MKDIR) obj/fsw1.0.0
+            	@$(CHK_DIR_EXISTS) obj/fsw-gsa1.0.0 || $(MKDIR) obj/fsw-gsa1.0.0
-            	$(COPY_FILE) --parents $(SOURCES) $(DIST) obj/fsw1.0.0/ && (cd `dirname obj/fsw1.0.0` && $(TAR) fsw1.0.0.tar fsw1.0.0 && $(COMPRESS) fsw1.0.0.tar) && $(MOVE) `dirname obj/fsw1.0.0`/fsw1.0.0.tar.gz . && $(DEL_FILE) -r obj/fsw1.0.0
+            	$(COPY_FILE) --parents $(SOURCES) $(DIST) obj/fsw-gsa1.0.0/ && (cd `dirname obj/fsw-gsa1.0.0` && $(TAR) fsw-gsa1.0.0.tar fsw-gsa1.0.0 && $(COMPRESS) fsw-gsa1.0.0.tar) && $(MOVE) `dirname obj/fsw-gsa1.0.0`/fsw-gsa1.0.0.tar.gz . && $(DEL_FILE) -r obj/fsw-gsa1.0.0
             clean:compiler_clean

FSW-qt/bin/fsw binary modified 0 0

NO CONTENT: modified file, binary diff hidden

FSW-qt/bin/fsw-gsa binary modified 0 0

NO CONTENT: modified file, binary diff hidden

FSW-qt/fsw-qt.pro +5 -4

             TEMPLATE = app
             # CONFIG += console v8 sim
             # CONFIG options = verbose *** cpu_usage_report *** gsa
-            CONFIG += console verbose
+            CONFIG += console verbose gsa
             CONFIG -= qt
             include(./sparc.pri)
             # flight software version
-            SWVERSION=-0-9
+            SWVERSION=-0-11
             DEFINES += SW_VERSION_N1=0
             DEFINES += SW_VERSION_N2=0
             DEFINES += SW_VERSION_N3=0
-            DEFINES += SW_VERSION_N4=9
+            DEFINES += SW_VERSION_N4=11
             contains( CONFIG, verbose ) {
                 DEFINES += PRINT_MESSAGES_ON_CONSOLE
                 ../header/fsw_params.h \
                 ../header/fsw_misc.h \
                 ../header/fsw_init.h \
-                ../header/ccsds_types.h
+                ../header/ccsds_types.h \
+                ../header/fsw_params_processing.h

FSW-qt/fsw-qt.pro.user +1 -1

             <?xml version="1.0" encoding="UTF-8"?>
             <!DOCTYPE QtCreatorProject>
-            <!-- Written by QtCreator 2.7.0, 2013-07-19T08:53:16. -->
+            <!-- Written by QtCreator 2.7.0, 2013-07-25T07:26:34. -->
             <qtcreator>
              <data>
               <variable>ProjectExplorer.Project.ActiveTarget</variable>

header/ccsds_types.h +36 -8

             #ifndef CCSDS_H_INCLUDED
             #define CCSDS_H_INCLUDED
+            #define CCSDS_PROTOCOLE_EXTRA_BYTES 4
             #define CCSDS_TELEMETRY_HEADER_LENGTH 16+4
             #define CCSDS_TM_PKT_MAX_SIZE 4412
             #define CCSDS_TELECOMMAND_HEADER_LENGTH 10+4
             #define TM_PACKET_SEQ_CTRL_LAST 2
             #define TM_PACKET_SEQ_CTRL_STANDALONE 3
-            // FAILURE CODES
-            #define FAILURE_CODE_INCONSISTENT       5       // 0x00 0x05
-            #define FAILURE_CODE_NOT_EXECUTABLE     42000   // 0xa4 0x10
-            #define FAILURE_CODE_NOT_IMPLEMENTED    42002   // 0xa4 0x12
-            #define FAILURE_CODE_ERROR              42003   // 0xa4 0x13
-            #define FAILURE_CODE_CORRUPTED          42005   // 0xa4 0x15
             //
             #define TM_DESTINATION_ID_GROUND 0
             #define TM_DESTINATION_ID_MISSION_TIMELINE 110
             #define TM_SUBTYPE_SCIENCE 3
             #define TM_SUBTYPE_LFR_SCIENCE 3
+            // FAILURE CODES
+            #define FAILURE_CODE_INCONSISTENT       5       // 0x00 0x05
+            #define FAILURE_CODE_NOT_EXECUTABLE     42000   // 0xa4 0x10
+            #define FAILURE_CODE_NOT_IMPLEMENTED    42002   // 0xa4 0x12
+            #define FAILURE_CODE_ERROR              42003   // 0xa4 0x13
+            #define FAILURE_CODE_CORRUPTED          42005   // 0xa4 0x15
             // TM SID
             #define SID_DEFAULT 0
             #define SID_EXE_INC 5
             #define LENGTH_TM_LFR_TC_EXE_MAX 32
             #define LENGTH_TM_LFR_HK 126
+            // HEADER_LENGTH
+            #define TM_HEADER_LEN 16
+            #define HEADER_LENGTH_TM_LFR_SCIENCE_ASM 28
             // PACKET_LENGTH
             #define PACKET_LENGTH_TC_EXE_SUCCESS            (20 - CCSDS_TC_TM_PACKET_OFFSET)
             #define PACKET_LENGTH_TC_EXE_INCONSISTENT       (26 - CCSDS_TC_TM_PACKET_OFFSET)
             #define PACKET_LENGTH_TC_EXE_CORRUPTED          (32 - CCSDS_TC_TM_PACKET_OFFSET)
             #define PACKET_LENGTH_HK                        (126 - CCSDS_TC_TM_PACKET_OFFSET)
             #define PACKET_LENGTH_PARAMETER_DUMP            (34 - CCSDS_TC_TM_PACKET_OFFSET)
-            #define TM_HEADER_LEN 16
+            #define PACKET_LENGTH_TM_LFR_SCIENCE_ASM        (TOTAL_SIZE_SM + HEADER_LENGTH_TM_LFR_SCIENCE_ASM - CCSDS_TC_TM_PACKET_OFFSET)
             #define SPARE1_PUSVERSION_SPARE2 0x10
             };
             typedef struct Header_TM_LFR_SCIENCE_CWF_str Header_TM_LFR_SCIENCE_CWF_t;
+            struct Header_TM_LFR_SCIENCE_ASM_str
+            {
+                volatile unsigned char targetLogicalAddress;
+                volatile unsigned char protocolIdentifier;
+                volatile unsigned char reserved;
+                volatile unsigned char userApplication;
+                volatile unsigned char packetID[2];
+                volatile unsigned char packetSequenceControl[2];
+                volatile unsigned char packetLength[2];
+                // DATA FIELD HEADER
+                volatile unsigned char spare1_pusVersion_spare2;
+                volatile unsigned char serviceType;
+                volatile unsigned char serviceSubType;
+                volatile unsigned char destinationID;
+                volatile unsigned char time[6];
+                // AUXILIARY HEADER
+                volatile unsigned char sid;
+                volatile unsigned char biaStatusInfo;
+                volatile unsigned char cntASM;
+                volatile unsigned char nrASM;
+                volatile unsigned char acquisitionTime[6];
+                volatile unsigned char blkNr[2];
+            };
+            typedef struct Header_TM_LFR_SCIENCE_ASM_str Header_TM_LFR_SCIENCE_ASM_t;
             struct ccsdsTelecommandPacket_str
             {
                 //unsigned char targetLogicalAddress; // removed by the grspw module

header/fsw_misc.h +3 0

             int configure_timer(gptimer_regs_t *gptimer_regs, unsigned char timer, unsigned int clock_divider,
                                 unsigned char interrupt_level, rtems_isr (*timer_isr)() );
+            int timer_start( gptimer_regs_t *gptimer_regs, unsigned char timer );
+            int timer_stop( gptimer_regs_t *gptimer_regs, unsigned char timer );
+            int timer_set_clock_divider(gptimer_regs_t *gptimer_regs, unsigned char timer, unsigned int clock_divider);
             void update_spacewire_statistics();
             // SERIAL LINK

header/fsw_params.h +14 -5

             #ifndef FSW_RTEMS_CONFIG_H_INCLUDED
             #define FSW_RTEMS_CONFIG_H_INCLUDED
+            #include <fsw_params_processing.h>
             #define GRSPW_DEVICE_NAME "/dev/grspw0"
             #define UART_DEVICE_NAME "/dev/console"
             // NORM
             #define DEFAULT_SY_LFR_N_SWF_L 2048 // nb sample
             #define DEFAULT_SY_LFR_N_SWF_P 16   // sec
-            #define DEFAULT_SY_LFR_N_ASM_P 3600 // sec
+            #define DEFAULT_SY_LFR_N_ASM_P 16 // sec
             #define DEFAULT_SY_LFR_N_BP_P0 4    // sec
             #define DEFAULT_SY_LFR_N_BP_P1 20   // sec
             // BURST
             #define REGS_ADDR_GPTIMER 0x80000300
             #define REGS_ADDR_GRSPW 0x80000500
             #define REGS_ADDR_TIME_MANAGEMENT 0x80000600
-            #define REGS_ADDR_SPECTRAL_MATRICES 0x80000700
+            #define REGS_ADDR_SPECTRAL_MATRIX 0x80000f00
-            #define REGS_ADDR_WAVEFORM_PICKER 0x80000f20
+            #ifdef GSA
+            #else
+                #define REGS_ADDR_WAVEFORM_PICKER 0x80000f20
+            #endif
             #define APBUART_CTRL_REG_MASK_DB 0xfffff7ff
             #define APBUART_SCALER_RELOAD_VALUE 0x00000050      // 25 MHz => about 38400 (0x50)
             #define IRQ_SPARC_TIME2 0x1d            // see sparcv8.pdf p.76 for interrupt levels
             #define IRQ_WAVEFORM_PICKER 14
             #define IRQ_SPARC_WAVEFORM_PICKER 0x1e  // see sparcv8.pdf p.76 for interrupt levels
+            #define IRQ_SPECTRAL_MATRIX 6
+            #define IRQ_SPARC_SPECTRAL_MATRIX 0x16  // see sparcv8.pdf p.76 for interrupt levels
             //*****
             // TIME
-            #define CLKDIV_SM_SIMULATOR 9999
+            #define CLKDIV_SM_SIMULATOR (10000 - 1)     // 10 ms
-            #define CLKDIV_WF_SIMULATOR 9999999
+            #define CLKDIV_WF_SIMULATOR (10000000 - 1)  // 10 000 000 * 1 us = 10 s
             #define TIMER_SM_SIMULATOR 1
             #define TIMER_WF_SIMULATOR 2
             #define HK_PERIOD 100 // 100 * 10ms => 1sec
             #define TASKID_WFRM 8
             #define TASKID_DUMB 9
             #define TASKID_HOUS 10
+            #define TASKID_MATR 11
             #define ACTION_MSG_QUEUE_COUNT 10

header/fsw_processing.h +30 -41

@@ -1,33 +1,17
1	#ifndef FSW_RTEMS_PROCESSING_H_INCLUDED	1	#ifndef FSW_RTEMS_PROCESSING_H_INCLUDED
2	#define FSW_RTEMS_PROCESSING_H_INCLUDED	2	#define FSW_RTEMS_PROCESSING_H_INCLUDED
3
4	#define NB_BINS_spec_mat 128
5	#define NB_VALUES_PER_spec_mat 25
6	#define TOTAL_SIZE_SPEC_MAT NB_BINS_spec_mat * NB_VALUES_PER_spec_mat
7	#define NB_BINS_COMPRESSED_MATRIX_f0 11
8	#define SIZE_COMPRESSED_spec_mat_f1 13
9	#define SIZE_COMPRESSED_spec_mat_f2 12
10	#define TOTAL_SIZE_COMPRESSED_MATRIX_f0 NB_BINS_COMPRESSED_MATRIX_f0 * NB_VALUES_PER_spec_mat
11	#define NB_AVERAGE_NORMAL_f0 96*4
12	#define NB_SM_TO_RECEIVE_BEFORE_AVF0 8
13		3
14	#include <rtems.h>	4	#include <rtems.h>
15	#include <gr~~lib_reg~~s.h>	5	#include <grspw.h>
		6	#include <leon.h>
		7
		8	#include <fsw_init.h>
16	#include <fsw_params.h>	9	#include <fsw_params.h>
17	#include <s~~tdio~~.h>	10	#include <grlib_regs.h>
		11	#include <ccsds_types.h>
		12
		13	#include <stdio.h>
18	#include <stdlib.h>	14	#include <stdlib.h>
19	#include <leon.h>
20
21	struct BP1_str{
22	volatile unsigned char PE[2];
23	volatile unsigned char PB[2];
24	volatile unsigned char V0;
25	volatile unsigned char V1;
26	volatile unsigned char V2_ELLIP_DOP;
27	volatile unsigned char SZ;
28	volatile unsigned char VPHI;
29	};
30	typedef struct BP1_str BP1_t;
31		15
32	extern volatile int spec_mat_f0_a[ ];	16	extern volatile int spec_mat_f0_a[ ];
33	extern volatile int spec_mat_f0_b[ ];	17	extern volatile int spec_mat_f0_b[ ];
@@ -37,30 +21,35 extern volatile int spec_mat_f0_e[ ];
37	extern volatile int spec_mat_f0_f[ ];	21	extern volatile int spec_mat_f0_f[ ];
38	extern volatile int spec_mat_f0_g[ ];	22	extern volatile int spec_mat_f0_g[ ];
39	extern volatile int spec_mat_f0_h[ ];	23	extern volatile int spec_mat_f0_h[ ];
40	extern float averaged_spec_mat_f0[ ];
41	extern float compressed_spec_mat_f0[ ];
42	extern unsigned char LFR_BP1_F0[ ];
43
44	extern BP1_t data_BP1[ ];
45		24
46	extern rtems_id Task_id[ ]; /* array of task ids */	25	extern rtems_id Task_id[ ]; /* array of task ids */
47		26
48	extern spectral_matrices_regs_t *spectral_matrices_regs;	27	extern time_management_regs_t *time_management_regs;
49		28	extern spectral_matrix_regs_t *spectral_matrix_regs;
		29
50	// ISR	30	// ISR
51	rtems_isr spectral_matrices_isr( rtems_vector_number vector );	31	rtems_isr spectral_matrices_isr( rtems_vector_number vector );
52		32
53	// RTEMS TASKS	33	// RTEMS TASKS
54	rtems_task spw_bppr_task(rtems_task_argument argument);	34	rtems_task spw_bppr_task(rtems_task_argument argument);
55	rtems_task avf0_task(rtems_task_argument argument);	35	rtems_task avf0_task(rtems_task_argument argument);
56	rtems_task bpf0_task(rtems_task_argument argument);	36	rtems_task bpf0_task(rtems_task_argument argument);
57	rtems_task smiq_task(rtems_task_argument argument); // added to test the spectral matrix simulator	37	rtems_task smiq_task(rtems_task_argument argument); // added to test the spectral matrix simulator
		38	rtems_task matr_task(rtems_task_argument argument);
58		39
59	rtems_task spw_bppr_task_rate_monotonic(rtems_task_argument argument);	40	rtems_task spw_bppr_task_rate_monotonic(rtems_task_argument argument);
60	void matrix_average(volatile int spec_mat, float averaged_spec_mat);	41
61	void matrix_compression(float averaged_spec_mat, unsigned char fChannel, float compressed_spec_mat);	42	void matrix_average(volatile int spec_mat, volatile float averaged_spec_mat);
62	void matrix_reset(float *averaged_spec_mat);	43	void matrix_compression(volatile float averaged_spec_mat, unsigned char fChannel, float compressed_spec_mat);
		44	void matrix_reset(volatile float *averaged_spec_mat);
63	void BP1_set(float * compressed_spec_mat, unsigned char nb_bins_compressed_spec_mat, unsigned char * LFR_BP1);	45	void BP1_set(float * compressed_spec_mat, unsigned char nb_bins_compressed_spec_mat, unsigned char * LFR_BP1);
64	void BP2_set(float * compressed_spec_mat, unsigned char nb_bins_compressed_spec_mat);	46	void BP2_set(float * compressed_spec_mat, unsigned char nb_bins_compressed_spec_mat);
		47	//
		48	void init_header_asm( Header_TM_LFR_SCIENCE_ASM_t *header);
		49	void send_spectral_matrix(Header_TM_LFR_SCIENCE_ASM_t header, char spectral_matrix,
		50	unsigned int sid, spw_ioctl_pkt_send *spw_ioctl_send);
		51	void convert_averaged_spectral_matrix(volatile float input_matrix, char output_matrix);
		52	void init_averaged_spectral_matrix();
		53	void reset_spectral_matrix_regs();
65		54
66	#endif // FSW_RTEMS_PROCESSING_H_INCLUDED	55	#endif // FSW_RTEMS_PROCESSING_H_INCLUDED

header/grlib_regs.h +10 -7

@@ -37,13 +37,6 struct gptimer_regs_str
37	};	37	};
38	typedef struct gptimer_regs_str gptimer_regs_t;	38	typedef struct gptimer_regs_str gptimer_regs_t;
39		39
40	struct spectral_matrices_regs_str{
41	volatile int ctrl;
42	volatile int address0;
43	volatile int address1;
44	};
45	typedef struct spectral_matrices_regs_str spectral_matrices_regs_t;
46
47	struct time_management_regs_str{	40	struct time_management_regs_str{
48	volatile int ctrl; // bit 0 forces the load of the coarse_time_load value and resets the fine_time	41	volatile int ctrl; // bit 0 forces the load of the coarse_time_load value and resets the fine_time
49	volatile int coarse_time_load;	42	volatile int coarse_time_load;
@@ -68,4 +61,14 struct waveform_picker_regs_str{
68	};	61	};
69	typedef struct waveform_picker_regs_str waveform_picker_regs_t;	62	typedef struct waveform_picker_regs_str waveform_picker_regs_t;
70		63
		64	struct spectral_matrix_regs_str{
		65	volatile int config;
		66	volatile int status;
		67	volatile int matrixF0_Address0;
		68	volatile int matrixFO_Address1;
		69	volatile int matrixF1_Address;
		70	volatile int matrixF2_Address;
		71	};
		72	typedef struct spectral_matrix_regs_str spectral_matrix_regs_t;
		73
71	#endif // GRLIBREGS_H_INCLUDED	74	#endif // GRLIBREGS_H_INCLUDED

header/wf_handler.h +1 -1

             void set_wfp_data_shaping(unsigned char data_shaping);
             void set_wfp_delta_snapshot(unsigned int delta_snapshot);
             void reset_wfp_burst_enable();
-            void reset_wfp_regs();
+            void reset_waveform_picker_regs();
             //
             int build_value(int value1, int value0);

src/fsw_globals.c +22 -17

-            #include <fsw_processing.h>
+            //#include <fsw_processing.h>
             #include <rtems.h>
             #include <grspw.h>
             #include <ccsds_types.h>
+            #include <grlib_regs.h>
+            #include <fsw_params.h>
             // RTEMS GLOBAL VARIABLES
             rtems_name misc_name[5];
             int fdSPW = 0;
             int fdUART = 0;
-            spectral_matrices_regs_t *spectral_matrices_regs = NULL;
             // APB CONFIGURATION REGISTERS
             time_management_regs_t *time_management_regs = (time_management_regs_t*) REGS_ADDR_TIME_MANAGEMENT;
-            waveform_picker_regs_t *waveform_picker_regs = (waveform_picker_regs_t*) REGS_ADDR_WAVEFORM_PICKER;
             gptimer_regs_t         *gptimer_regs         = (gptimer_regs_t *)        REGS_ADDR_GPTIMER;
+            #ifdef GSA
+            #else
+                waveform_picker_regs_t *waveform_picker_regs = (waveform_picker_regs_t*) REGS_ADDR_WAVEFORM_PICKER;
+            #endif
+            spectral_matrix_regs_t *spectral_matrix_regs = (spectral_matrix_regs_t*) REGS_ADDR_SPECTRAL_MATRIX;
             // WAVEFORMS GLOBAL VARIABLES // 2048 * 3 * 4 + 2 * 4 = 24576 + 8 bytes
             volatile int wf_snap_f0[ NB_SAMPLES_PER_SNAPSHOT * NB_WORDS_SWF_BLK + TIME_OFFSET];
             volatile int wf_cont_f3[ NB_SAMPLES_PER_SNAPSHOT * NB_WORDS_SWF_BLK + TIME_OFFSET];
             // SPECTRAL MATRICES GLOBAL VARIABLES
-            volatile int spec_mat_f0_a[ TOTAL_SIZE_SPEC_MAT ];
+            volatile int spec_mat_f0_a[ TOTAL_SIZE_SM ];
-            volatile int spec_mat_f0_b[ TOTAL_SIZE_SPEC_MAT ];
+            volatile int spec_mat_f0_b[ TOTAL_SIZE_SM ];
-            volatile int spec_mat_f0_c[ TOTAL_SIZE_SPEC_MAT ];
+            volatile int spec_mat_f0_c[ TOTAL_SIZE_SM ];
-            volatile int spec_mat_f0_d[ TOTAL_SIZE_SPEC_MAT ];
+            volatile int spec_mat_f0_d[ TOTAL_SIZE_SM ];
-            volatile int spec_mat_f0_e[ TOTAL_SIZE_SPEC_MAT ];
+            volatile int spec_mat_f0_e[ TOTAL_SIZE_SM ];
-            volatile int spec_mat_f0_f[ TOTAL_SIZE_SPEC_MAT ];
+            volatile int spec_mat_f0_f[ TOTAL_SIZE_SM ];
-            volatile int spec_mat_f0_g[ TOTAL_SIZE_SPEC_MAT ];
+            volatile int spec_mat_f0_g[ TOTAL_SIZE_SM ];
-            volatile int spec_mat_f0_h[ TOTAL_SIZE_SPEC_MAT ];
+            volatile int spec_mat_f0_h[ TOTAL_SIZE_SM ];
             //
-            float averaged_spec_mat_f0[ TOTAL_SIZE_SPEC_MAT ];
+            volatile int spec_mat_f1_a[ TOTAL_SIZE_SM ];
-            float compressed_spec_mat_f0[ TOTAL_SIZE_COMPRESSED_MATRIX_f0 ];
+            volatile int spec_mat_f2_a[ TOTAL_SIZE_SM ];
+            //
+            volatile int spec_mat_f0_a_bis[ TOTAL_SIZE_SM ];
+            volatile int spec_mat_f1_a_bis[ TOTAL_SIZE_SM ];
+            volatile int spec_mat_f2_a_bis[ TOTAL_SIZE_SM ];
             // MODE PARAMETERS
             Packet_TM_LFR_PARAMETER_DUMP_t parameter_dump_packet;
             spw_stats spacewire_stats;
             spw_stats spacewire_stats_backup;
-            // BASIC PARAMETERS GLOBAL VARIABLES
-            unsigned char LFR_BP1_F0[ NB_BINS_COMPRESSED_MATRIX_f0 * 9 ];
-            BP1_t data_BP1[ NB_BINS_COMPRESSED_MATRIX_f0 ];

src/fsw_init.c +22 -32

             rtems_task Init( rtems_task_argument ignored )
             {
                 rtems_status_code status;
-                rtems_isr_entry old_isr_handler;
+                rtems_isr_entry  old_isr_handler;
                 PRINTF("\n\n\n\n\n")
                 PRINTF("***************************\n")
             #ifdef GSA
                 // simulator
-                PRINTF("GSA is defined *** fsw-gsa is running \n")
                 configure_timer((gptimer_regs_t*) REGS_ADDR_GPTIMER, TIMER_WF_SIMULATOR, CLKDIV_WF_SIMULATOR,
                                 IRQ_SPARC_WF, waveforms_simulator_isr );
+                LEON_Mask_interrupt( IRQ_WF );
             #else
-                // configure the registers of the waveform picker
+                // configure the waveform picker
-                reset_wfp_regs();
+                reset_waveform_picker_regs();
-                // configure the waveform picker interrupt service routine
                 status = rtems_interrupt_catch( waveforms_isr,
                                                IRQ_SPARC_WAVEFORM_PICKER,
                                                &old_isr_handler) ;
                 LEON_Mask_interrupt( IRQ_WAVEFORM_PICKER );
+                // configure the spectral matrix
+                reset_spectral_matrix_regs();
+                status = rtems_interrupt_catch( waveforms_isr,
+                                               IRQ_SPARC_SPECTRAL_MATRIX,
+                                               &old_isr_handler) ;
+                LEON_Mask_interrupt( IRQ_SPECTRAL_MATRIX );
             #endif
                 //**********
-                //*****************************************
-                // irq handling of the time management unit
-                status = rtems_interrupt_catch( commutation_isr1,
-                                               IRQ_SPARC_TIME1,
-                                               &old_isr_handler) ; // see sparcv8.pdf p.76 for interrupt levels
-                if (status==RTEMS_SUCCESSFUL) {
-                    PRINTF("OK  *** commutation_isr1 *** rtems_interrupt_catch successfullly configured\n")
-                status = rtems_interrupt_catch( commutation_isr2,
-                                               IRQ_SPARC_TIME2,
-                                               &old_isr_handler) ; // see sparcv8.pdf p.76 for interrupt levels
-                if (status==RTEMS_SUCCESSFUL) {
-                    PRINTF("OK  *** commutation_isr2 *** rtems_interrupt_catch successfullly configured\n")
-                LEON_Unmask_interrupt( IRQ_TIME1 );
-                LEON_Unmask_interrupt( IRQ_TIME2 );
-            #ifdef GSA
-                if (rtems_event_send( Task_id[TASKID_WFRM], RTEMS_EVENT_MODE_NORMAL ) != RTEMS_SUCCESSFUL) {
-                    PRINTF("in INIT *** Error sending event to WFRM\n")
-            #endif
-                LEON_Force_interrupt(IRQ_WF);
                 status = rtems_task_delete(RTEMS_SELF);
             }
                 Task_name[TASKID_WFRM] = rtems_build_name( 'W', 'F', 'R', 'M' );
                 Task_name[TASKID_DUMB] = rtems_build_name( 'D', 'U', 'M', 'B' );
                 Task_name[TASKID_HOUS] = rtems_build_name( 'H', 'O', 'U', 'S' );
+                Task_name[TASKID_MATR] = rtems_build_name( 'M', 'A', 'T', 'R' );
                 // rate monotonic period name
                 HK_name = rtems_build_name( 'H', 'O', 'U', 'S' );
                     RTEMS_DEFAULT_MODES,
                     RTEMS_DEFAULT_ATTRIBUTES, &Task_id[TASKID_HOUS]
                 );
+                // MATR
+                status = rtems_task_create(
+                    Task_name[TASKID_MATR], 250, RTEMS_MINIMUM_STACK_SIZE * 2,
+                    RTEMS_DEFAULT_MODES,
+                    RTEMS_DEFAULT_ATTRIBUTES | RTEMS_FLOATING_POINT, &Task_id[TASKID_MATR]
+                );
                 return 0;
             }
                     PRINTF("In INIT *** Error starting TASK_HOUS\n")
                 }
+                status = rtems_task_start( Task_id[TASKID_MATR], matr_task, 1 );
+                if (status!=RTEMS_SUCCESSFUL) {
+                    PRINTF("In INIT *** Error starting TASK_MATR\n")
+                }
                 return 0;
             }

src/fsw_misc.c +40 -4

@@ -14,9 +14,18 int configure_timer(gptimer_regs_t *gpti
14	rtems_isr_entry old_isr_handler;	14	rtems_isr_entry old_isr_handler;
15		15
16	status = rtems_interrupt_catch( timer_isr, interrupt_level, &old_isr_handler) ; // see sparcv8.pdf p.76 for interrupt levels	16	status = rtems_interrupt_catch( timer_isr, interrupt_level, &old_isr_handler) ; // see sparcv8.pdf p.76 for interrupt levels
17	//if (status==RTEMS_SUCCESSFUL) PRINTF("In configure_timer_for_wf_simulation *** rtems_interrupt_catch successfullly configured\n")	17	if (status==RTEMS_SUCCESSFUL)
		18	{
		19	PRINTF("In configure_timer *** rtems_interrupt_catch successfullly configured\n")
		20	}
18		21
19	gptimer_regs->timer[timer].reload = clock_divider; // base clock frequency is 1 MHz	22	timer_set_clock_divider( gptimer_regs, timer, clock_divider);
		23
		24	return 1;
		25	}
		26
		27	int timer_start(gptimer_regs_t *gptimer_regs, unsigned char timer)
		28	{
20	gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl \| 0x00000010; // clear pending IRQ if any	29	gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl \| 0x00000010; // clear pending IRQ if any
21	gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl \| 0x00000004; // LD load value from the reload register	30	gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl \| 0x00000004; // LD load value from the reload register
22	gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl \| 0x00000001; // EN enable the timer	31	gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl \| 0x00000001; // EN enable the timer
@@ -26,6 +35,22 int configure_timer(gptimer_regs_t *gpti
26	return 1;	35	return 1;
27	}	36	}
28		37
		38	int timer_stop(gptimer_regs_t *gptimer_regs, unsigned char timer)
		39	{
		40	gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl & 0xfffffffe; // EN enable the timer
		41	gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl & 0xffffffef; // IE interrupt enable
		42	gptimer_regs->timer[timer].ctrl = gptimer_regs->timer[timer].ctrl \| 0x00000010; // clear pending IRQ if any
		43
		44	return 1;
		45	}
		46
		47	int timer_set_clock_divider(gptimer_regs_t *gptimer_regs, unsigned char timer, unsigned int clock_divider)
		48	{
		49	gptimer_regs->timer[timer].reload = clock_divider; // base clock frequency is 1 MHz
		50
		51	return 1;
		52	}
		53
29	void update_spacewire_statistics()	54	void update_spacewire_statistics()
30	{	55	{
31	rtems_status_code status;	56	rtems_status_code status;
@@ -189,9 +214,20 rtems_task hous_task(rtems_task_argument
189		214
190	update_spacewire_statistics();	215	update_spacewire_statistics();
191		216
		217	// SEND PACKET
192	result = write ( fdSPW, &housekeeping_packet, LEN_TM_LFR_HK);	218	result = write ( fdSPW, &housekeeping_packet, LEN_TM_LFR_HK);
193	if (~~result~~==-1) {	219	if (status == -1) {
194	PRINTF("ERR * in HOUS * HK send\n");	220	while (true) {
		221	if (status != RTEMS_SUCCESSFUL) {
		222	result = write ( fdSPW, &housekeeping_packet, LEN_TM_LFR_HK);
		223	PRINTF("x")
		224	sched_yield();
		225	}
		226	else {
		227	PRINTF("\n")
		228	break;
		229	}
		230	}
195	}	231	}
196	}	232	}
197	}	233	}

src/fsw_processing.c +246 -34

@@ -3,6 +3,12
3		3
4	#include <fsw_processing_globals.c>	4	#include <fsw_processing_globals.c>
5		5
		6	unsigned char LFR_BP1_F0[ NB_BINS_COMPRESSED_SM_F0 * 9 ];
		7	BP1_t data_BP1[ NB_BINS_COMPRESSED_SM_F0 ];
		8	float averaged_spec_mat_f0[ TOTAL_SIZE_SM ];
		9	char averaged_spec_mat_f0_char[ TOTAL_SIZE_SM * 2 ];
		10	float compressed_spec_mat_f0[ TOTAL_SIZE_COMPRESSED_MATRIX_f0 ];
		11
6	//***********************************************************	12	//***********************************************************
7	// Interrupt Service Routine for spectral matrices processing	13	// Interrupt Service Routine for spectral matrices processing
8	rtems_isr spectral_matrices_isr( rtems_vector_number vector )	14	rtems_isr spectral_matrices_isr( rtems_vector_number vector )
@@ -17,15 +23,19 rtems_isr spectral_matrices_isr( rtems_v
17	rtems_task smiq_task(rtems_task_argument argument) // process the Spectral Matrices IRQ	23	rtems_task smiq_task(rtems_task_argument argument) // process the Spectral Matrices IRQ
18	{	24	{
19	rtems_event_set event_out;	25	rtems_event_set event_out;
20	unsigned ~~char~~ nb_interrupt_f0 = 0;	26	unsigned int nb_interrupt_f0 = 0;
		27	unsigned int nb_interrupt_f0_MAX = 0;
		28
		29	nb_interrupt_f0_MAX = ( (parameter_dump_packet.sy_lfr_n_asm_p[0]) * 256
		30	+ parameter_dump_packet.sy_lfr_n_asm_p[1] ) * 100;
21		31
22	PRINTF("in SMIQ *** \n")	32	PRINTF("in SMIQ *** \n")
23		33
24	while(1){	34	while(1){
25	rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out); // wait for an RTEMS_EVENT0	35	rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out); // wait for an RTEMS_EVENT0
26	nb_interrupt_f0 = nb_interrupt_f0 + 1;	36	nb_interrupt_f0 = nb_interrupt_f0 + 1;
27	if (nb_interrupt_f0 == (~~NB_SM_TO_RECEIVE_BEFORE_AVF0~~-1) ){	37	if (nb_interrupt_f0 == nb_interrupt_f0_MAX ){
28	if (rtems_event_send( Task_id[TASKID_~~AVF0~~], RTEMS_EVENT_0 ) != RTEMS_SUCCESSFUL)	38	if (rtems_event_send( Task_id[TASKID_MATR], RTEMS_EVENT_0 ) != RTEMS_SUCCESSFUL)
29	{	39	{
30	rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_3 );	40	rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_3 );
31	}	41	}
@@ -42,24 +52,20 rtems_task spw_bppr_task(rtems_task_argu
42	//static int nb_average_f1 = 0;	52	//static int nb_average_f1 = 0;
43	//static int nb_average_f2 = 0;	53	//static int nb_average_f2 = 0;
44		54
45	spectral_matrices_regs = (struct spectral_matrices_regs_str *) REGS_ADDR_SPECTRAL_MATRICES;
46	spectral_matrices_regs->address0 = (volatile int) spec_mat_f0_a;
47	spectral_matrices_regs->address1 = (volatile int) spec_mat_f0_b;
48
49	printf("in BPPR ***\n");	55	printf("in BPPR ***\n");
50		56
51	while(true){ // wait for an event to begin with the processing	57	while(true){ // wait for an event to begin with the processing
52	status = rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out);	58	status = rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out);
53	if (status == RTEMS_SUCCESSFUL) {	59	if (status == RTEMS_SUCCESSFUL) {
54	if ((spectral_matri~~ces~~_regs->~~ctrl~~ & 0x00000001)==1) {	60	if ((spectral_matrix_regs->status & 0x00000001)==1) {
55	matrix_average(spec_mat_f0_a, averaged_spec_mat_f0);	61	matrix_average(spec_mat_f0_a, averaged_spec_mat_f0);
56	spectral_matri~~ces~~_regs->~~ctrl~~ = spectral_matri~~ces~~_regs->~~ctrl~~ & 0xfffffffe;	62	spectral_matrix_regs->status = spectral_matrix_regs->status & 0xfffffffe;
57	//printf("f0_a\n");	63	//printf("f0_a\n");
58	Nb_average_f0++;	64	Nb_average_f0++;
59	}	65	}
60	if (((spectral_matri~~ces~~_regs->~~ctrl~~>>1) & 0x00000001)==1) {	66	if (((spectral_matrix_regs->status>>1) & 0x00000001)==1) {
61	matrix_average(spec_mat_f0_b, compressed_spec_mat_f0);	67	matrix_average(spec_mat_f0_b, compressed_spec_mat_f0);
62	spectral_matri~~ces~~_regs->~~ctrl~~ = spectral_matri~~ces~~_regs->~~ctrl~~ & 0xfffffffd;	68	spectral_matrix_regs->status = spectral_matrix_regs->status & 0xfffffffd;
63	//printf("f0_b\n");	69	//printf("f0_b\n");
64	Nb_average_f0++;	70	Nb_average_f0++;
65	}	71	}
@@ -73,23 +79,20 rtems_task spw_bppr_task(rtems_task_argu
73	}	79	}
74	}	80	}
75		81
76	rtems_task avf0_task(rtems_task_argument argument){	82	rtems_task avf0_task(rtems_task_argument argument)
77	int i;	83	{
		84	//int i;
78	static int nb_average;	85	static int nb_average;
79	rtems_event_set event_out;	86	rtems_event_set event_out;
80	rtems_status_code status;	87	rtems_status_code status;
81		88
82	spectral_matrices_regs = (struct spectral_matrices_regs_str *) REGS_ADDR_SPECTRAL_MATRICES;
83	spectral_matrices_regs->address0 = (volatile int) spec_mat_f0_a;
84	spectral_matrices_regs->address1 = (volatile int) spec_mat_f0_b;
85
86	nb_average = 0;	89	nb_average = 0;
87		90
88	PRINTF("in AVFO *** \n")	91	PRINTF("in AVFO *** \n")
89		92
90	while(1){	93	while(1){
91	rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out); // wait for an RTEMS_EVENT0	94	rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out); // wait for an RTEMS_EVENT0
92	for(i=0; i<TOTAL_SIZE_S~~PEC_~~MAT; i++){	95	/*for(i=0; i<TOTAL_SIZE_SM; i++){
93	averaged_spec_mat_f0[i] = averaged_spec_mat_f0[i] + spec_mat_f0_a[i]	96	averaged_spec_mat_f0[i] = averaged_spec_mat_f0[i] + spec_mat_f0_a[i]
94	+ spec_mat_f0_b[i]	97	+ spec_mat_f0_b[i]
95	+ spec_mat_f0_c[i]	98	+ spec_mat_f0_c[i]
@@ -98,20 +101,20 rtems_task avf0_task(rtems_task_argument
98	+ spec_mat_f0_f[i]	101	+ spec_mat_f0_f[i]
99	+ spec_mat_f0_g[i]	102	+ spec_mat_f0_g[i]
100	+ spec_mat_f0_h[i];	103	+ spec_mat_f0_h[i];
101	}	104	}*/
102	spectral_matrices_regs->ctrl = spectral_matrices_regs->ctrl & 0xfffffffe; // reset the appropriate bit in the register
103	nb_average = nb_average + NB_SM_TO_RECEIVE_BEFORE_AVF0;	105	nb_average = nb_average + NB_SM_TO_RECEIVE_BEFORE_AVF0;
104	if (nb_average == NB_AVERAGE_NORMAL_f0) {	106	if (nb_average == NB_AVERAGE_NORMAL_f0) {
105	nb_average = 0;	107	nb_average = 0;
106	status = rtems_event_send( Task_id[7], RTEMS_EVENT_0 ); // sending an event to the task 7, BPF0	108	status = rtems_event_send( Task_id[TASKID_MATR], RTEMS_EVENT_0 ); // sending an event to the task 7, BPF0
107	if (status != RTEMS_SUCCESSFUL) {	109	if (status != RTEMS_SUCCESSFUL) {
108	printf("i~~N TASK~~ AVF0 *** Error sending RTEMS_EVENT_0, code %d\n", status);	110	printf("in AVF0 *** Error sending RTEMS_EVENT_0, code %d\n", status);
109	}	111	}
110	}	112	}
111	}	113	}
112	}	114	}
113		115
114	rtems_task bpf0_task(rtems_task_argument argument){	116	rtems_task bpf0_task(rtems_task_argument argument)
		117	{
115	rtems_event_set event_out;	118	rtems_event_set event_out;
116		119
117	PRINTF("in BPFO *** \n")	120	PRINTF("in BPFO *** \n")
@@ -119,17 +122,38 rtems_task bpf0_task(rtems_task_argument
119	while(1){	122	while(1){
120	rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out); // wait for an RTEMS_EVENT0	123	rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out); // wait for an RTEMS_EVENT0
121	matrix_compression(averaged_spec_mat_f0, 0, compressed_spec_mat_f0);	124	matrix_compression(averaged_spec_mat_f0, 0, compressed_spec_mat_f0);
122	BP1_set(compressed_spec_mat_f0, NB_BINS_COMPRESSED_~~MATRIX_f~~0, LFR_BP1_F0);	125	BP1_set(compressed_spec_mat_f0, NB_BINS_COMPRESSED_SM_F0, LFR_BP1_F0);
123	//PRINTF("IN TASK BPF0 *** Matrix compressed, parameters calculated\n")	126	//PRINTF("IN TASK BPF0 *** Matrix compressed, parameters calculated\n")
124	}	127	}
125	}	128	}
126		129
		130	rtems_task matr_task(rtems_task_argument argument)
		131	{
		132	spw_ioctl_pkt_send spw_ioctl_send_ASM;
		133	rtems_event_set event_out;
		134	Header_TM_LFR_SCIENCE_ASM_t headerASM;
		135
		136	init_header_asm( &headerASM );
		137
		138	PRINTF("in MATR *** \n")
		139
		140	init_averaged_spectral_matrix( );
		141
		142	while(1){
		143	rtems_event_receive(RTEMS_EVENT_0, RTEMS_WAIT, RTEMS_NO_TIMEOUT, &event_out); // wait for an RTEMS_EVENT0
		144
		145	convert_averaged_spectral_matrix( averaged_spec_mat_f0, averaged_spec_mat_f0_char);
		146
		147	send_spectral_matrix( &headerASM, averaged_spec_mat_f0_char, SID_NORM_ASM_F0, &spw_ioctl_send_ASM);
		148	}
		149	}
		150
127	//*****************************	151	//*****************************
128	// Spectral matrices processing	152	// Spectral matrices processing
129	void matrix_average(volatile int spec_mat, float averaged_spec_mat)	153	void matrix_average(volatile int spec_mat, volatile float averaged_spec_mat)
130	{	154	{
131	int i;	155	int i;
132	for(i=0; i<TOTAL_SIZE_S~~PEC_~~MAT; i++){	156	for(i=0; i<TOTAL_SIZE_SM; i++){
133	averaged_spec_mat[i] = averaged_spec_mat[i] + spec_mat_f0_a[i]	157	averaged_spec_mat[i] = averaged_spec_mat[i] + spec_mat_f0_a[i]
134	+ spec_mat_f0_b[i]	158	+ spec_mat_f0_b[i]
135	+ spec_mat_f0_c[i]	159	+ spec_mat_f0_c[i]
@@ -141,21 +165,21 void matrix_average(volatile int *spec_m
141	}	165	}
142	}	166	}
143		167
144	void matrix_reset(float *averaged_spec_mat)	168	void matrix_reset(volatile float *averaged_spec_mat)
145	{	169	{
146	int i;	170	// int i;
147	for(i=0; i<TOTAL_SIZE_S~~PEC_~~MAT; i++){	171	// for(i=0; i<TOTAL_SIZE_SM; i++){
148	averaged_spec_mat_f0[i] = 0;	172	// averaged_spec_mat_f0[i] = 0;
149	}	173	// }
150	}	174	}
151		175
152	void matrix_compression(float averaged_spec_mat, unsigned char fChannel, float compressed_spec_mat)	176	void matrix_compression(volatile float averaged_spec_mat, unsigned char fChannel, float compressed_spec_mat)
153	{	177	{
154	int i;	178	int i;
155	int j;	179	int j;
156	switch (fChannel){	180	switch (fChannel){
157	case 0:	181	case 0:
158	for(i=0;i<NB_BINS_COMPRESSED_~~MATRIX_f~~0;i++){	182	for(i=0;i<NB_BINS_COMPRESSED_SM_F0;i++){
159	j = 17 + (i * 8);	183	j = 17 + (i * 8);
160	compressed_spec_mat[i] = (averaged_spec_mat[j]	184	compressed_spec_mat[i] = (averaged_spec_mat[j]
161	+ averaged_spec_mat[j+1]	185	+ averaged_spec_mat[j+1]
@@ -241,7 +265,7 void BP1_set(float * compressed_spec_mat
241	LFR_BP1[i9+6] = LFR_BP1[i9+6] \| ((tmp_u_char&0x0f)<<3); // keeps 4 bits of the resulting unsigned char	265	LFR_BP1[i9+6] = LFR_BP1[i9+6] \| ((tmp_u_char&0x0f)<<3); // keeps 4 bits of the resulting unsigned char
242	//==============================================================	266	//==============================================================
243	// BP1 degree of polarization == PAR_LFR_SC_BP1_DOP_F0 == 3 bits	267	// BP1 degree of polarization == PAR_LFR_SC_BP1_DOP_F0 == 3 bits
244	for(j = 0; j<NB_VALUES_PER_~~spec_mat~~;j++){	268	for(j = 0; j<NB_VALUES_PER_SM;j++){
245	tr_SB_SB = compressed_spec_mat[i30] compressed_spec_mat[i*30]	269	tr_SB_SB = compressed_spec_mat[i30] compressed_spec_mat[i*30]
246	+ compressed_spec_mat[(i30) + 10] compressed_spec_mat[(i*30) + 10]	270	+ compressed_spec_mat[(i30) + 10] compressed_spec_mat[(i*30) + 10]
247	+ compressed_spec_mat[(i30) + 18] compressed_spec_mat[(i*30) + 18]	271	+ compressed_spec_mat[(i30) + 18] compressed_spec_mat[(i*30) + 18]
@@ -361,3 +385,191 void BP2_set(float * compressed_spec_mat
361	}	385	}
362	}	386	}
363		387
		388	void init_header_asm( Header_TM_LFR_SCIENCE_ASM_t *header)
		389	{
		390	header->targetLogicalAddress = CCSDS_DESTINATION_ID;
		391	header->protocolIdentifier = CCSDS_PROTOCOLE_ID;
		392	header->reserved = 0x00;
		393	header->userApplication = CCSDS_USER_APP;
		394	header->packetID[0] = (unsigned char) (TM_PACKET_ID_SCIENCE_NORMAL >> 8);
		395	header->packetID[1] = (unsigned char) (TM_PACKET_ID_SCIENCE_NORMAL);
		396	header->packetSequenceControl[0] = 0xc0;
		397	header->packetSequenceControl[1] = 0x00;
		398	header->packetLength[0] = 0x00;
		399	header->packetLength[1] = 0x00;
		400	// DATA FIELD HEADER
		401	header->spare1_pusVersion_spare2 = 0x10;
		402	header->serviceType = TM_TYPE_LFR_SCIENCE; // service type
		403	header->serviceSubType = TM_SUBTYPE_LFR_SCIENCE; // service subtype
		404	header->destinationID = TM_DESTINATION_ID_GROUND;
		405	// AUXILIARY DATA HEADER
		406	header->sid = 0x00;
		407	header->biaStatusInfo = 0x00;
		408	header->cntASM = 0x00;
		409	header->nrASM = 0x00;
		410	header->time[0] = 0x00;
		411	header->time[0] = 0x00;
		412	header->time[0] = 0x00;
		413	header->time[0] = 0x00;
		414	header->time[0] = 0x00;
		415	header->time[0] = 0x00;
		416	header->blkNr[0] = 0x00; // BLK_NR MSB
		417	header->blkNr[1] = 0x00; // BLK_NR LSB
		418	}
		419
		420	void send_spectral_matrix(Header_TM_LFR_SCIENCE_ASM_t header, char spectral_matrix,
		421	unsigned int sid, spw_ioctl_pkt_send *spw_ioctl_send)
		422	{
		423	unsigned int i;
		424	unsigned int length = 0;
		425	rtems_status_code status;
		426
		427	header->sid = (unsigned char) sid;
		428
		429	for (i=0; i<2; i++)
		430	{
		431	// BUILD THE DATA
		432	spw_ioctl_send->dlen = TOTAL_SIZE_SM;
		433	spw_ioctl_send->data = &spectral_matrix[ i * TOTAL_SIZE_SM];
		434	spw_ioctl_send->hlen = HEADER_LENGTH_TM_LFR_SCIENCE_ASM + CCSDS_PROTOCOLE_EXTRA_BYTES;
		435	spw_ioctl_send->hdr = (char *) header;
		436	spw_ioctl_send->options = 0;
		437
		438	// BUILD THE HEADER
		439	length = PACKET_LENGTH_TM_LFR_SCIENCE_ASM;
		440	header->packetLength[0] = (unsigned char) (length>>8);
		441	header->packetLength[1] = (unsigned char) (length);
		442	header->sid = (unsigned char) sid; // SID
		443	header->cntASM = 2;
		444	header->nrASM = (unsigned char) (i+1);
		445	header->blkNr[0] =(unsigned char) ( (NB_BINS_PER_SM/2) >> 8 ); // BLK_NR MSB
		446	header->blkNr[1] = (unsigned char) (NB_BINS_PER_SM/2); // BLK_NR LSB
		447	// SET PACKET TIME
		448	header->time[0] = (unsigned char) (time_management_regs->coarse_time>>24);
		449	header->time[1] = (unsigned char) (time_management_regs->coarse_time>>16);
		450	header->time[2] = (unsigned char) (time_management_regs->coarse_time>>8);
		451	header->time[3] = (unsigned char) (time_management_regs->coarse_time);
		452	header->time[4] = (unsigned char) (time_management_regs->fine_time>>8);
		453	header->time[5] = (unsigned char) (time_management_regs->fine_time);
		454	header->acquisitionTime[0] = (unsigned char) (time_management_regs->coarse_time>>24);
		455	header->acquisitionTime[1] = (unsigned char) (time_management_regs->coarse_time>>16);
		456	header->acquisitionTime[2] = (unsigned char) (time_management_regs->coarse_time>>8);
		457	header->acquisitionTime[3] = (unsigned char) (time_management_regs->coarse_time);
		458	header->acquisitionTime[4] = (unsigned char) (time_management_regs->fine_time>>8);
		459	header->acquisitionTime[5] = (unsigned char) (time_management_regs->fine_time);
		460	// SEND PACKET
		461	status = write_spw(spw_ioctl_send);
		462	if (status != RTEMS_SUCCESSFUL) {
		463	while (true) {
		464	if (status != RTEMS_SUCCESSFUL) {
		465	status = write_spw(spw_ioctl_send);
		466	//PRINTF1("%d", i)
		467	sched_yield();
		468	}
		469	else {
		470	//PRINTF("\n")
		471	break;
		472	}
		473	}
		474	}
		475	}
		476	}
		477
		478	void convert_averaged_spectral_matrix( volatile float input_matrix, char output_matrix)
		479	{
		480	unsigned int i;
		481	unsigned int j;
		482	char * pt_char_input;
		483	char * pt_char_output;
		484
		485	pt_char_input = NULL;
		486	pt_char_output = NULL;
		487
		488	for( i=0; i<NB_BINS_PER_SM; i++)
		489	{
		490	for ( j=0; j<NB_VALUES_PER_SM; j++)
		491	{
		492	pt_char_input = (char) &input_matrix[ (iNB_VALUES_PER_SM) + j ];
		493	pt_char_output = (char) &output_matrix[ 2 ( (i*NB_VALUES_PER_SM) + j ) ];
		494	pt_char_output[0] = pt_char_input[0]; // bits 31 downto 24 of the float
		495	pt_char_output[1] = pt_char_input[1]; // bits 23 downto 16 of the float
		496	}
		497	}
		498	}
		499
		500	void init_averaged_spectral_matrix( )
		501	{
		502	float offset = 10.;
		503	float coeff = 100000.;
		504	averaged_spec_mat_f0[ 0 + 25 * 0 ] = 0. + offset;
		505	averaged_spec_mat_f0[ 0 + 25 * 1 ] = 1. + offset;
		506	averaged_spec_mat_f0[ 0 + 25 * 2 ] = 2. + offset;
		507	averaged_spec_mat_f0[ 0 + 25 * 3 ] = 3. + offset;
		508	averaged_spec_mat_f0[ 0 + 25 * 4 ] = 4. + offset;
		509	averaged_spec_mat_f0[ 0 + 25 * 5 ] = 5. + offset;
		510	averaged_spec_mat_f0[ 0 + 25 * 6 ] = 6. + offset;
		511	averaged_spec_mat_f0[ 0 + 25 * 7 ] = 7. + offset;
		512	averaged_spec_mat_f0[ 0 + 25 * 8 ] = 8. + offset;
		513	averaged_spec_mat_f0[ 0 + 25 * 9 ] = 9. + offset;
		514	averaged_spec_mat_f0[ 0 + 25 * 10 ] = 10. + offset;
		515	averaged_spec_mat_f0[ 0 + 25 * 11 ] = 11. + offset;
		516	averaged_spec_mat_f0[ 0 + 25 * 12 ] = 12. + offset;
		517	averaged_spec_mat_f0[ 0 + 25 * 13 ] = 13. + offset;
		518	averaged_spec_mat_f0[ 0 + 25 * 14 ] = 14. + offset;
		519	averaged_spec_mat_f0[ 9 + 25 * 0 ] = -(0. + offset)* coeff;
		520	averaged_spec_mat_f0[ 9 + 25 * 1 ] = -(1. + offset)* coeff;
		521	averaged_spec_mat_f0[ 9 + 25 * 2 ] = -(2. + offset)* coeff;
		522	averaged_spec_mat_f0[ 9 + 25 * 3 ] = -(3. + offset)* coeff;
		523	averaged_spec_mat_f0[ 9 + 25 * 4 ] = -(4. + offset)* coeff;
		524	averaged_spec_mat_f0[ 9 + 25 * 5 ] = -(5. + offset)* coeff;
		525	averaged_spec_mat_f0[ 9 + 25 * 6 ] = -(6. + offset)* coeff;
		526	averaged_spec_mat_f0[ 9 + 25 * 7 ] = -(7. + offset)* coeff;
		527	averaged_spec_mat_f0[ 9 + 25 * 8 ] = -(8. + offset)* coeff;
		528	averaged_spec_mat_f0[ 9 + 25 * 9 ] = -(9. + offset)* coeff;
		529	averaged_spec_mat_f0[ 9 + 25 * 10 ] = -(10. + offset)* coeff;
		530	averaged_spec_mat_f0[ 9 + 25 * 11 ] = -(11. + offset)* coeff;
		531	averaged_spec_mat_f0[ 9 + 25 * 12 ] = -(12. + offset)* coeff;
		532	averaged_spec_mat_f0[ 9 + 25 * 13 ] = -(13. + offset)* coeff;
		533	averaged_spec_mat_f0[ 9 + 25 * 14 ] = -(14. + offset)* coeff;
		534	offset = 10000000;
		535	averaged_spec_mat_f0[ 16 + 25 * 0 ] = (0. + offset)* coeff;
		536	averaged_spec_mat_f0[ 16 + 25 * 1 ] = (1. + offset)* coeff;
		537	averaged_spec_mat_f0[ 16 + 25 * 2 ] = (2. + offset)* coeff;
		538	averaged_spec_mat_f0[ 16 + 25 * 3 ] = (3. + offset)* coeff;
		539	averaged_spec_mat_f0[ 16 + 25 * 4 ] = (4. + offset)* coeff;
		540	averaged_spec_mat_f0[ 16 + 25 * 5 ] = (5. + offset)* coeff;
		541	averaged_spec_mat_f0[ 16 + 25 * 6 ] = (6. + offset)* coeff;
		542	averaged_spec_mat_f0[ 16 + 25 * 7 ] = (7. + offset)* coeff;
		543	averaged_spec_mat_f0[ 16 + 25 * 8 ] = (8. + offset)* coeff;
		544	averaged_spec_mat_f0[ 16 + 25 * 9 ] = (9. + offset)* coeff;
		545	averaged_spec_mat_f0[ 16 + 25 * 10 ] = (10. + offset)* coeff;
		546	averaged_spec_mat_f0[ 16 + 25 * 11 ] = (11. + offset)* coeff;
		547	averaged_spec_mat_f0[ 16 + 25 * 12 ] = (12. + offset)* coeff;
		548	averaged_spec_mat_f0[ 16 + 25 * 13 ] = (13. + offset)* coeff;
		549	averaged_spec_mat_f0[ 16 + 25 * 14 ] = (14. + offset)* coeff;
		550
		551	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 0 ] = averaged_spec_mat_f0[ 0 ];
		552	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 1 ] = averaged_spec_mat_f0[ 1 ];
		553	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 2 ] = averaged_spec_mat_f0[ 2 ];
		554	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 3 ] = averaged_spec_mat_f0[ 3 ];
		555	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 4 ] = averaged_spec_mat_f0[ 4 ];
		556	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 5 ] = averaged_spec_mat_f0[ 5 ];
		557	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 6 ] = averaged_spec_mat_f0[ 6 ];
		558	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 7 ] = averaged_spec_mat_f0[ 7 ];
		559	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 8 ] = averaged_spec_mat_f0[ 8 ];
		560	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 9 ] = averaged_spec_mat_f0[ 9 ];
		561	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 10 ] = averaged_spec_mat_f0[ 10 ];
		562	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 11 ] = averaged_spec_mat_f0[ 11 ];
		563	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 12 ] = averaged_spec_mat_f0[ 12 ];
		564	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 13 ] = averaged_spec_mat_f0[ 13 ];
		565	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 14 ] = averaged_spec_mat_f0[ 14 ];
		566	averaged_spec_mat_f0[ (TOTAL_SIZE_SM/2) + 15 ] = averaged_spec_mat_f0[ 15 ];
		567	}
		568
		569	void reset_spectral_matrix_regs()
		570	{
		571	#ifdef GSA
		572	#else
		573
		574	#endif
		575	}

src/tc_handler.c +18 -7

                 TMHeader->packetLength[0] = (unsigned char) (packetLength>>8);
                 TMHeader->packetLength[1] = (unsigned char) packetLength;
                 TMHeader->spare1_pusVersion_spare2 = 0x10;
-                TMHeader->destinationID = CCSDS_DESTINATION_ID;    // default destination id
+                TMHeader->destinationID = TM_DESTINATION_ID_GROUND;    // default destination id
                 switch (tm_type){
                     case(TM_LFR_TC_EXE_OK):
                         TMHeader->packetID[1] = (unsigned char) TM_PACKET_ID_TC_EXE;
                         TMHeader->packetID[1] = (unsigned char) TM_PACKET_ID_TC_EXE;
                         TMHeader->serviceType = TM_TYPE_TC_EXE;      // type
                         TMHeader->serviceSubType = TM_SUBTYPE_EXE_NOK;  // subtype
+                        TMHeader->destinationID = tc_sid;
                         break;
                     case(TM_LFR_HK):
                         TMHeader->packetID[1] = (unsigned char) TM_PACKET_ID_HK;
                 lfrMode = (housekeeping_packet.lfr_status_word[0] & 0xf0) >> 4; // get the current mode
                 // mask all IRQ lines related to signal processing
-                LEON_Mask_interrupt( IRQ_WF );                  // mask waveform interrupt (coming from the timer VHDL IP)
                 LEON_Mask_interrupt( IRQ_SM );                  // mask spectral matrices interrupt (coming from the timer VHDL IP)
-                LEON_Mask_interrupt( IRQ_WAVEFORM_PICKER );     // mask waveform picker interrupt
+                LEON_Clear_interrupt( IRQ_SM );                  // clear spectral matrices interrupt (coming from the timer VHDL IP)
-                // clear all pending interruptions related to signal processing
+            #ifdef GSA
+                LEON_Mask_interrupt( IRQ_WF );                  // mask waveform interrupt (coming from the timer VHDL IP)
                 LEON_Clear_interrupt( IRQ_WF );                  // clear waveform interrupt (coming from the timer VHDL IP)
-                LEON_Clear_interrupt( IRQ_SM );                  // clear spectral matrices interrupt (coming from the timer VHDL IP)
+                timer_stop( (gptimer_regs_t*) REGS_ADDR_GPTIMER, TIMER_WF_SIMULATOR );
+            #else
+                LEON_Mask_interrupt( IRQ_WAVEFORM_PICKER );     // mask waveform picker interrupt
                 LEON_Clear_interrupt( IRQ_WAVEFORM_PICKER );     // clear waveform picker interrupt
+            #endif
                 // suspend several tasks
                 if (lfrMode != LFR_MODE_STANDBY) {
                 }
                 // initialize the registers
+            #ifdef GSA
+            #else
                 waveform_picker_regs->burst_enable = 0x00;      // initialize
+            #endif
                 return status;
             }
                 }
             #ifdef GSA
+                timer_start( (gptimer_regs_t*) REGS_ADDR_GPTIMER, TIMER_WF_SIMULATOR );
+                timer_start( (gptimer_regs_t*) REGS_ADDR_GPTIMER, TIMER_SM_SIMULATOR );
                 LEON_Clear_interrupt( IRQ_WF );
                 LEON_Unmask_interrupt( IRQ_WF );
+                LEON_Clear_interrupt( IRQ_SM ); // the IRQ_SM seems to be incompatible with the IRQ_WF on the xilinx board
+                LEON_Unmask_interrupt( IRQ_SM );
             #else
                 LEON_Clear_interrupt( IRQ_WAVEFORM_PICKER );
                 LEON_Unmask_interrupt( IRQ_WAVEFORM_PICKER );
                 waveform_picker_regs->burst_enable = 0x07;
                 waveform_picker_regs->addr_data_f1 = (int) wf_snap_f1;
                 waveform_picker_regs->status = 0x00;
+                LEON_Clear_interrupt( IRQ_SM ); // the IRQ_SM seems to be incompatible with the IRQ_WF on the xilinx board
+                LEON_Unmask_interrupt( IRQ_SM );
             #endif
-                LEON_Unmask_interrupt( IRQ_SM );
                 return status;
             }

src/wf_handler.c +43 -44

                 unsigned char lfrMode;
                 lfrMode = (housekeeping_packet.lfr_status_word[0] & 0xf0) >> 4;
-                switch(lfrMode)
+                switch(lfrMode) {
+                case (LFR_MODE_STANDBY):
-                    //********
+                    break;
-                    // STANDBY
+                case (LFR_MODE_NORMAL):
-                    case(LFR_MODE_STANDBY):
+                    if (rtems_event_send( Task_id[TASKID_WFRM], RTEMS_EVENT_MODE_NORMAL ) != RTEMS_SUCCESSFUL) {
-                        rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_5 );
-                        break;
-                    //******
-                    // NORMAL
-                    case(LFR_MODE_NORMAL):
                         rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_5 );
-                        if (rtems_event_send( Task_id[TASKID_WFRM], RTEMS_EVENT_MODE_NORMAL ) != RTEMS_SUCCESSFUL) {
-                            rtems_event_send( Task_id[TASKID_DUMB], RTEMS_EVENT_5 );
+                    break;
+                case (LFR_MODE_BURST):
-                        break;
+                    break;
+                case (LFR_MODE_SBM1):
-                    //******
+                    break;
-                    // BURST
+                case (LFR_MODE_SBM2):
-                    case(LFR_MODE_BURST):
+                    break;
-                        break;
-                    //*****
-                    // SBM1
-                    case(LFR_MODE_SBM1):
-                        break;
-                    //*****
-                    // SBM2
-                    case(LFR_MODE_SBM2):
-                        break;
-                    //********
-                    // DEFAULT
-                    default:
-                        break;
                 }
             }
                                 break;
                             case(LFR_MODE_SBM1):
                                 send_waveform_sbm1( &headerCWF, &spw_ioctl_send_CWF);
+            #ifdef GSA
+            #else
                                 param_local.local_sbm1_nb_cwf_sent ++;
                                 if ( param_local.local_sbm1_nb_cwf_sent == (param_local.local_sbm1_nb_cwf_max-1) ) {
                                     // send the f1 buffer as a NORM snapshot
                                         send_waveform_SWF( &headerSWF, wf_snap_f1, SID_NORM_SWF_F1, &spw_ioctl_send_SWF );
                                     }
                                 }
+            #endif
                                 break;
                             case(LFR_MODE_SBM2):
                                 send_waveform_sbm2( &headerCWF, &spw_ioctl_send_CWF);
+            #ifdef GSA
+            #else
                                 param_local.local_sbm2_nb_cwf_sent ++;
                                 if ( param_local.local_sbm2_nb_cwf_sent == (param_local.local_sbm2_nb_cwf_max-1) ) {
                                     // send the f2 buffer as a NORM snapshot
                                         send_waveform_SWF( &headerSWF, wf_snap_f2, SID_NORM_SWF_F2, &spw_ioctl_send_SWF );
                                     }
                                 }
+            #endif
                                 break;
                             default:
                                 break;
                 // irq processed, reset the related register of the timer unit
                 gptimer_regs->timer[TIMER_WF_SIMULATOR].ctrl = gptimer_regs->timer[TIMER_WF_SIMULATOR].ctrl | 0x00000010;
                 // clear the interruption
-                LEON_Clear_interrupt(IRQ_WF);
+                LEON_Unmask_interrupt( IRQ_WF );
             #else
                 // irq processed, reset the related register of the waveform picker
                 if (lfrMode == LFR_MODE_SBM1) {
                     waveform_picker_regs->status = waveform_picker_regs->status & 0x00;
                     waveform_picker_regs->burst_enable = 0x07; // [0111] enable f2 f1 f0
                 }
+            #endif
-            #endif
             }
             void send_waveform_burst(Header_TM_LFR_SCIENCE_CWF_t *header, spw_ioctl_pkt_send *spw_ioctl_send)
                 // ACQUISITION TIME
                 // F2
+            #ifdef GSA
+            #else
                 if (waveform_picker_regs->addr_data_f2 == (int) wf_snap_f2) {
                    send_waveform_CWF( header, wf_snap_f2_bis, SID_BURST_CWF_F2, spw_ioctl_send);
                 }
                 else {
                     send_waveform_CWF( header, wf_snap_f2, SID_BURST_CWF_F2, spw_ioctl_send);
                 }
+            #endif
             }
             void send_waveform_sbm1(Header_TM_LFR_SCIENCE_CWF_t *header, spw_ioctl_pkt_send *spw_ioctl_send)
                 header->time[5] = (unsigned char) (time_management_regs->fine_time);
                 // F1
+            #ifdef GSA
+            #else
                 if (waveform_picker_regs->addr_data_f1 == (int) wf_snap_f1) {
                    send_waveform_CWF( header, wf_snap_f1_bis, SID_SBM1_CWF_F1, spw_ioctl_send );
                 }
                 else {
                     send_waveform_CWF( header, wf_snap_f1, SID_SBM1_CWF_F1, spw_ioctl_send );
                 }
+            #endif
             }
             void send_waveform_sbm2(Header_TM_LFR_SCIENCE_CWF_t *header, spw_ioctl_pkt_send *spw_ioctl_send)
                 header->time[5] = (unsigned char) (time_management_regs->fine_time);
                 // F2
+            #ifdef GSA
+            #else
                 if (waveform_picker_regs->addr_data_f2 == (int) wf_snap_f2) {
                     send_waveform_CWF( header, wf_snap_f2_bis, SID_SBM2_CWF_F2, spw_ioctl_send);
                 }
                 else {
                     send_waveform_CWF( header, wf_snap_f2, SID_SBM2_CWF_F2, spw_ioctl_send);
                 }
+            #endif
             }
             //**************
             {
                 // get the parameters for the data shaping [BW SP0 SP1 R0 R1] in sy_lfr_common1 and configure the register
                 // waveform picker : [R1 R0 SP1 SP0 BW]
+            #ifdef GSA
+            #else
                 waveform_picker_regs->data_shaping =
                           ( (data_shaping & 0x10) >> 4 )     // BW
                         + ( (data_shaping & 0x08) >> 2 )     // SP0
                         + ( (data_shaping & 0x04)      )     // SP1
                         + ( (data_shaping & 0x02) << 2 )     // R0
                         + ( (data_shaping & 0x01) << 4 );    // R1
+            #endif
             }
             void set_wfp_delta_snapshot(unsigned int delta_snapshot)
             {
+            #ifdef GSA
+            #else
                 unsigned char aux = 0;
                 aux = delta_snapshot / 2 ;
                 waveform_picker_regs->delta_snapshot = aux;             // max 2 bytes
-                //waveform_picker_regs->delta_snapshot = 0x5;             // max 2 bytes
+            #endif
             }
             void reset_wfp_burst_enable()
             {
+            #ifdef GSA
+            #else
                 waveform_picker_regs->burst_enable = 0x00;              // burst f2, f1, f0     enable f3, f2, f1, f0
+            #endif
             }
-            void reset_wfp_regs()
+            void reset_waveform_picker_regs()
             {
+            #ifdef GSA
+            #else
                 set_wfp_data_shaping(parameter_dump_packet.bw_sp0_sp1_r0_r1);
                 reset_wfp_burst_enable();
                 waveform_picker_regs->addr_data_f0 = (int) (wf_snap_f0);    //
                 waveform_picker_regs->delta_f2_f0 = 0x17c00;            // max 5 bytes
                 waveform_picker_regs->nb_burst_available = 0x180;       // max 3 bytes, size of the buffer in burst (1 burst = 16 x 4 octets)
                 waveform_picker_regs->nb_snapshot_param = 0x7ff;        // max 3 octets, 2048 - 1
-                //waveform_picker_regs->delta_snapshot = 0x2;         // max 2 bytes, = period / 2
+            #endif
-                //waveform_picker_regs->delta_f2_f1 = 0x2d00;         // max 4 bytes
-                //waveform_picker_regs->delta_f2_f0 = 0x2f80;         // max 5 bytes
-                //waveform_picker_regs->nb_burst_available = 0x30;    // max 3 bytes, size of the buffer in burst (1 burst = 16 x 4 octets)
-                //waveform_picker_regs->nb_snapshot_param = 0xff;     // max 3 octets, 256 - 1
             }

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