shubham c
I2C code testing
Dependencies: FreescaleIAP SimpleDMA mbed-rtos mbed
Fork of
COM_MNG_TMTC_SIMPLE_pl123
by 
Siva ram
ThreadsAndFunctions.h
- Committer:
- shreeshas95
- Date:
- 2015-12-23
- Revision:
- 3:6c81fc8834e2
- Parent:
- 2:2caf2a9a13aa
- Child:
- 4:104dd82c99b8
File content as of revision 3:6c81fc8834e2:
// UART ISR
void rx_read(){
gRX_CURRENT_DATA_NODE->values[gRX_COUNT] = RX1M.getc();
gFLAGS = gFLAGS | UART_INT_FLAG;
gCOM_MNG_TMTC_THREAD->signal_set(COM_MNG_TMTC_SIGNAL_UART_INT);
}
// RX_TIMEOUT ISR
void after_receive(){
gRX_TIMEOUT.detach();
gFLAGS = gFLAGS | NEW_TC_RECEIVED;
gCOM_MNG_TMTC_THREAD->signal_set(COM_MNG_TMTC_SIGNAL_UART_INT);
}
// SESSION_TIMOUT ISR
void after_session(){
gSESSION_TIMEOUT.detach();
gFLAGS = gFLAGS & (~COM_SESSION_FLAG);
gCOM_MNG_TMTC_THREAD->signal_set(COM_MNG_TMTC_SIGNAL_UART_INT);
}
#define reset_all {\
Base_tc *tcp = gHEAD_NODE_TCL;\
while(tcp != NULL){\
Base_tc *temp = tcp->next_TC;\
delete tcp;\
tcp = temp;\
}\
rx_tc_frames = 0;\
rx_tc_frames = 0;\
gTOTAL_INCORRECT_SIZE_TC = 0;\
gTOTAL_CRC_FAIL_TC = 0;\
gTOTAL_REPEATED_TC = 0;\
COM_RX_DATA_NODE *dataptr = gRX_HEAD_DATA_NODE;\
while( dataptr != NULL ){\
COM_RX_DATA_NODE *temp = dataptr->next_node;\
delete dataptr;\
dataptr = temp;\
}\
gRX_HEAD_DATA_NODE = new COM_RX_DATA_NODE;\
gRX_HEAD_DATA_NODE->next_node = NULL;\
gRX_CURRENT_DATA_NODE = gRX_HEAD_DATA_NODE;\
gRX_COUNT = 0;\
/*PENDING : ALL GLOBAL VAARIABLES AND FLAGS*/\
}
#define PUT_RAW_BYTE {\
if( gRX_COUNT < (RX_BUFFER_LENGTH-1) ){\
++gRX_COUNT;\
}\
else{\
gRX_COUNT = 0;\
gRX_CURRENT_DATA_NODE->next_node = new COM_RX_DATA_NODE;\
gRX_CURRENT_DATA_NODE = gRX_CURRENT_DATA_NODE->next_node;\
gRX_CURRENT_DATA_NODE->next_node = NULL;\
}\
gRX_TIMEOUT.attach(&after_receive, RX_TIMEOUT_LIMIT);\
}
void COM_MNG_TMTC_FUN(void const *args){
while(true){
Thread::signal_wait( COM_MNG_TMTC_SIGNAL_UART_INT );
if( gFLAGS & UART_INT_FLAG ){
gFLAGS = gFLAGS & (~UART_INT_FLAG);
if( !(gFLAGS & COM_SESSION_FLAG) ){
// PENDING : DISABLE THREADS
gFLAGS = gFLAGS | COM_SESSION_FLAG;
gSESSION_TIMEOUT.attach(&after_session, SESSION_TIME_LIMIT);
gFLAGS = gFLAGS | COM_RX_FLAG;
PUT_RAW_BYTE;
// PENDING : MEASURE RSSI
}
else if( gFLAGS & COM_RX_FLAG ){
PUT_RAW_BYTE;
}
else{
gFLAGS = gFLAGS | COM_RX_FLAG;
PUT_RAW_BYTE;
}
}
else if( (gFLAGS & NEW_TC_RECEIVED) && (gFLAGS & COM_MNG_TMTC_RUNNING_FLAG) ){
gFLAGS = gFLAGS & (~NEW_TC_RECEIVED);
gFLAGS = gFLAGS & (~COM_RX_FLAG);
// DISABLE THE RX1M INTERRUPT
RX1M.attach(NULL);
while(gRX_COUNT < (RX_BUFFER_LENGTH)){
gRX_CURRENT_DATA_NODE->values[gRX_COUNT] = 0x00;
++gRX_COUNT;
}
gRX_COUNT = 0;
// VERIFY CRC, REPEATED PSC AND UPDATE TOTAL_VALID_TC, INCORRECT SIZE TC, CRC FAIL TC
raw_data_to_tc();
if( gTOTAL_VALID_TC > 0 ){
// CHECK WEATHER TC LIST HAS MISSING TC OR WEATHER LAST FRAME BIT IS HIGH IN THE LAST PSC-TC
uint8_t tempContinue = 0xFF;
continueToExecute(tempContinue);
if(tempContinue == 0x00){
// CHECK WEATHER GS VERIFICATION CODE MATCHES
uint8_t tempGSver = 0x00;
GScodeVerification(tempGSver);
if( tempGSver ){
gFLAGS = gFLAGS | COM_SESSION_VALIDITY;
// PENDING : COM_POWER_ON_TX
EXECUTE_OBOSC_ONLY;
EXECUTE_TC;
}
else{
gFLAGS = gFLAGS & (~COM_SESSION_VALIDITY);
// PENDING : ENABLE THREADS
gSESSION_TIMEOUT.detach();
gFLAGS = gFLAGS & (~COM_SESSION_FLAG);
}
}
else{
// PENDING : COM_POWER_ON_TX
// PENDING : POWER OFF TX
RX1M.attach(&rx_read, Serial::RxIrq);
}
}
else if( !(gFLAGS & COM_TX_FLAG) ){
RX1M.attach(&rx_read, Serial::RxIrq);
// PENDING : ENABLE THREADS
gSESSION_TIMEOUT.detach();
gFLAGS = gFLAGS & (~COM_SESSION_FLAG);
}
}
else if( gFLAGS & COM_PA_HOT_FLAG ){
uint8_t tempPA = 0xFF;
isPAhot(tempPA);
if( tempPA == 0x00 ){
gCOM_PA_COOLING_TIMER.attach(&after_cooling_pa, COM_PA_COOLING_TIME_LIMIT);
}
else{
gFLAGS = gFLAGS & (~COM_PA_HOT_FLAG);
gCOM_PA_COOLING_TIMER.detach();
// PENDING : COM POWER ON TX
EXECUTE_OBOSC_ONLY;
EXECUTE_TC;
}
}
else{
// SOME INVALID SIGNAL RECEIVED
// PENDING : COM_POWER_OFF_TX
reset_all;
// PENDING : ENABLE THREADS
gSESSION_TIMEOUT.detach();
gFLAGS = gFLAGS & (~COM_SESSION_FLAG);
}
}
}
void SCIENCE_FUN(void const *args){
// SPIpayload.format(8,0);
// SPIpayload.frequency(1000000);
for ( int i = 0 ; i < PAYLOAD_BUFFER_LENGTH ; i++ ){
gPAYLOAD_BUFFER[i] = 1;
}
// initialise the buffer for dma
// SPIpayload.bulkRead_init(VAR_SPACE::payload_dma_buffer, PAYLOAD_DMA_SIZE, &payload_interrupt_fun);
// start dma read
// SPIpayload.bulkRead_start();
// attach DMA interrupt
while(true){
gSCIENCE_THREAD->signal_wait(0x01);
//*********************************************************THE TEST
//read rtc time later
uint64_t RTC_time = 0;
Science_Data_Compression::complete_compression( gPAYLOAD_BUFFER , RTC_time);
// SPI_mutex.lock();
// disk_write(SDcard_lastWritten , 5);
// SPI_mutex.unlock();
//**********************************************THE TEST
// counter_for_payload++;
// if(counter_for_payload == 10){
// payload_ticker.detach();
// ledg = 0;
// PC.puts("its over\r\n");
// }
// SPIpayload.bulkRead_start();
}
}