284 lines
9.3 KiB
C++
284 lines
9.3 KiB
C++
#ifndef EVENT_H
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#define EVENT_H
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#include <stdio.h>
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#include <cstdlib>
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#include <stdint.h>
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#define MaxTraceLenght 8100
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enum DataFormat{
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ALL = 0,
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OneTrace = 1,
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NoTrace = 2,
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Minimum = 3,
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RAW = 0x0A,
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};
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namespace DPPType{
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const std::string PHA = "DPP_PHA";
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const std::string PSD = "DPP_PSD";
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};
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class Event {
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public:
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unsigned short dataType;
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std::string DPPType;
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///============= for dpp-pha
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uint8_t channel; // 6 bit
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uint16_t energy; // 16 bit
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uint16_t energy_short; // 16 bit, only for PSD
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uint64_t timestamp; // 48 bit
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uint16_t fine_timestamp; // 16 bit
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uint16_t flags_low_priority; // 12 bit
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uint16_t flags_high_priority; // 8 bit
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size_t traceLenght; // 64 bit
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uint8_t downSampling; // 8 bit
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bool board_fail;
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bool flush;
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uint8_t analog_probes_type[2]; // 3 bit for PHA, 4 bit for PSD
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uint8_t digital_probes_type[4]; // 4 bit for PHA, 5 bit for PSD
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int32_t * analog_probes[2]; // 18 bit
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uint8_t * digital_probes[4]; // 1 bit
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uint16_t trigger_threashold; // 16 bit
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size_t event_size; // 64 bit
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uint32_t aggCounter; // 32 bit
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///============= for raw
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uint8_t * data;
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size_t dataSize; /// number of byte of the data, size/8 = word [64 bits]
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uint32_t n_events;
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bool isTraceAllZero;
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Event(){
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Init();
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}
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~Event(){
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ClearMemory();
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}
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void Init(){
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DPPType = DPPType::PHA;
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dataType = DataFormat::ALL;
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channel = 0;
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energy = 0;
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energy_short = 0;
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timestamp = 0;
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fine_timestamp = 0;
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downSampling = 0;
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board_fail = false;
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flush = false;
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flags_low_priority = 0;
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flags_high_priority = 0;
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trigger_threashold = 0;
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event_size = 0;
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aggCounter = 0;
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analog_probes[0] = NULL;
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analog_probes[1] = NULL;
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digital_probes[0] = NULL;
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digital_probes[1] = NULL;
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digital_probes[2] = NULL;
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digital_probes[3] = NULL;
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analog_probes_type[0] = 0xFF;
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analog_probes_type[1] = 0xFF;
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digital_probes_type[0] = 0xFF;
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digital_probes_type[1] = 0xFF;
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digital_probes_type[2] = 0xFF;
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digital_probes_type[3] = 0xFF;
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data = NULL;
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isTraceAllZero = true; // indicate trace are all zero
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}
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void ClearMemory(){
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if( data != NULL ) delete data;
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if( analog_probes[0] != NULL) delete analog_probes[0];
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if( analog_probes[1] != NULL) delete analog_probes[1];
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if( digital_probes[0] != NULL) delete digital_probes[0];
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if( digital_probes[1] != NULL) delete digital_probes[1];
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if( digital_probes[2] != NULL) delete digital_probes[2];
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if( digital_probes[3] != NULL) delete digital_probes[3];
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isTraceAllZero = true;
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}
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void SetDataType(unsigned int type, std::string dppType){
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dataType = type;
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DPPType = dppType;
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ClearMemory();
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if( dataType == DataFormat::RAW){
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data = new uint8_t[20*1024*1024];
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}else{
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analog_probes[0] = new int32_t[MaxTraceLenght];
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analog_probes[1] = new int32_t[MaxTraceLenght];
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digital_probes[0] = new uint8_t[MaxTraceLenght];
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digital_probes[1] = new uint8_t[MaxTraceLenght];
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digital_probes[2] = new uint8_t[MaxTraceLenght];
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digital_probes[3] = new uint8_t[MaxTraceLenght];
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isTraceAllZero = true;
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}
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}
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void ClearTrace(){
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if( isTraceAllZero ) return; // no need to clear again
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for( int i = 0; i < MaxTraceLenght; i++){
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analog_probes[0][i] = 0;
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analog_probes[1][i] = 0;
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digital_probes[0][i] = 0;
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digital_probes[1][i] = 0;
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digital_probes[2][i] = 0;
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digital_probes[3][i] = 0;
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}
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isTraceAllZero = true;
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}
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void PrintEnergyTimeStamp(){
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printf("ch: %2d, energy: %u, timestamp: %lu ch, traceLenght: %lu\n", channel, energy, timestamp, traceLenght);
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}
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std::string AnaProbeType(uint8_t probeType){
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if( DPPType == DPPType::PHA){
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switch(probeType){
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case 0: return "ADC";
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case 1: return "Time filter";
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case 2: return "Energy filter";
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default : return "none";
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}
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}else if (DPPType == DPPType::PSD){
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switch(probeType){
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case 0: return "ADC";
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case 9: return "Baseline";
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case 10: return "CFD";
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default : return "none";
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}
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}else{
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return "none";
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}
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}
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std::string DigiProbeType(uint8_t probeType){
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if( DPPType == DPPType::PHA){
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switch(probeType){
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case 0: return "Trigger";
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case 1: return "Time filter armed";
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case 2: return "Re-trigger guard";
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case 3: return "Energy filter baseline freeze";
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case 4: return "Energy filter peaking";
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case 5: return "Energy filter peaking ready";
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case 6: return "Energy filter pile-up guard";
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case 7: return "Event pile-up";
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case 8: return "ADC saturation";
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case 9: return "ADC saturation protection";
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case 10: return "Post-saturation event";
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case 11: return "Energy filter saturation";
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case 12: return "Signal inhibit";
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default : return "none";
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}
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}else if (DPPType == DPPType::PSD){
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switch(probeType){
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case 0: return "Trigger";
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case 1: return "CFD Filter Armed";
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case 2: return "Re-trigger guard";
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case 3: return "ADC Input Baseline freeze";
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case 20: return "ADC Input OverThreshold";
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case 21: return "Charge Ready";
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case 22: return "Long Gate";
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case 7: return "Pile-Up Trig.";
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case 24: return "Short Gate";
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case 25: return "Energy Saturation";
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case 26: return "Charge over-range";
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case 27: return "ADC Input Neg. OverThreshold";
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default : return "none";
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}
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}else{
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return "none";
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}
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}
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std::string HighPriority(uint16_t prio){
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std::string output;
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bool pileup = prio & 0x1;
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//bool pileupGuard = (prio >> 1) & 0x1;
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//bool eventSaturated = (prio >> 2) & 0x1;
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//bool postSatEvent = (prio >> 3) & 0x1;
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//bool trapSatEvent = (prio >> 4) & 0x1;
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//bool SCA_Event = (prio >> 5) & 0x1;
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output = std::string("Pile-up: ") + (pileup ? "Yes" : "No");
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return output;
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}
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//TODO LowPriority
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void PrintAll(){
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switch(dataType){
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case DataFormat::ALL : printf("============= Type : ALL\n"); break;
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case DataFormat::OneTrace : printf("============= Type : OneTrace\n"); break;
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case DataFormat::NoTrace : printf("============= Type : NoTrace\n"); break;
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case DataFormat::Minimum : printf("============= Type : Minimum\n"); break;
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case DataFormat::RAW : printf("============= Type : RAW\n"); return; break;
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default : return;
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}
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printf("ch : %2d (0x%02X), fail: %d, flush: %d\n", channel, channel, board_fail, flush);
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if( DPPType == DPPType::PHA ) printf("energy: %u, timestamp: %lu, fine_timestamp: %u \n", energy, timestamp, fine_timestamp);
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if( DPPType == DPPType::PSD ) printf("energy: %u, energy_S : %u, timestamp: %lu, fine_timestamp: %u \n", energy, energy_short, timestamp, fine_timestamp);
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printf("flag (high): 0x%02X, (low): 0x%03X, traceLength: %lu\n", flags_high_priority, flags_low_priority, traceLenght);
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printf("Agg counter : %u, trigger Thr.: %u, downSampling: %u \n", aggCounter, trigger_threashold, downSampling);
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printf("AnaProbe Type: %s(%u), %s(%u)\n", AnaProbeType(analog_probes_type[0]).c_str(), analog_probes_type[0],
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AnaProbeType(analog_probes_type[1]).c_str(), analog_probes_type[1]);
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printf("DigProbe Type: %s(%u), %s(%u), %s(%u), %s(%u)\n", DigiProbeType(digital_probes_type[0]).c_str(), digital_probes_type[0],
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DigiProbeType(digital_probes_type[1]).c_str(), digital_probes_type[1],
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DigiProbeType(digital_probes_type[2]).c_str(), digital_probes_type[2],
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DigiProbeType(digital_probes_type[3]).c_str(), digital_probes_type[3]);
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}
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void PrintTrace(unsigned short ID){
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for(unsigned short i = 0; i < (unsigned short)traceLenght; i++){
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if( ID == 0 ) printf("%4d| %6d\n", i, analog_probes[0][i]);
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if( ID == 1 ) printf("%4d| %6d\n", i, analog_probes[1][i]);
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if( ID == 2 ) printf("%4d| %u\n", i, digital_probes[0][i]);
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if( ID == 3 ) printf("%4d| %u\n", i, digital_probes[1][i]);
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if( ID == 4 ) printf("%4d| %u\n", i, digital_probes[2][i]);
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if( ID == 5 ) printf("%4d| %u\n", i, digital_probes[3][i]);
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}
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}
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void PrintAllTrace(){
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for(unsigned short i = 0; i < (unsigned short)traceLenght; i++){
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printf("%4d| %6d %6d %1d %1d %1d %1d\n", i, analog_probes[0][i],
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analog_probes[1][i],
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digital_probes[0][i],
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digital_probes[1][i],
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digital_probes[2][i],
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digital_probes[3][i]);
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}
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}
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};
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#endif |