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/******************************************************************************* * Pupe.cc Pupe process * T.Barnaby, BEAM Ltd, 2007-02-13 * * Removed 128 offset and changed sign of frefPhaseDelay. JMB - 20110608 * Increased max value of orbitNumber to 1M5. JMB - 20110713 * Added state-qualified trigger bit to DIAG_CTRL JMB - 20130111 ******************************************************************************* */ #include <stdio.h> #include <stdlib.h> #include <unistd.h> #include <string.h> #include <math.h> #include <syslog.h> #include <Pupe.h> #include <SigGen.h> #include <Control.h> #include <TmsD.h> #include <Debug.h> #include <signal.h> #include <sys/time.h> #include <sys/ioctl.h> #include <sys/fcntl.h> #include <errno.h> #include <main.h> #include <TmsLib.h> #include <BFile.h> /* Build Options */ #define USE_DMA 1 #define LOAD_USE_DMA 1 #define NEW_BUNCH_MEAN 1
#define NEW_CYCLE_INFO 1
/* Debug options */ #define SYSCLK_INTERNAL 0 #define DEBUG_CTRL 0
#define DEBUG_INFO_TABLE 1
#define DEBUG_DATA 0 #define DEBUG_DATA_ERROR 1 #define DEBUG_DATA_TIME 0 #define DEBUG_CONTROL_TIME 0
#define DEBUG_DISABLE_ERROR_IRQ 1
struct MeanValue { int32_t sigma; int32_t deltaX; int32_t deltaY; int32_t numSamples; }; struct MeanValueSmall { int16_t sigma; ///< The Sigma value int16_t deltaX; ///< The DeltaX value int16_t deltaY; ///< The DeltaY value int16_t numSamples; ///< The number of samples averaged }; // FPGA Control Registers const int IMEM_REG = 0x0000 >> 2; // Block RAM Index const int LOCKED = 0x0008 >> 2; // DCM Locked Status const int ADDR_REG = 0x0010 >> 2; // PAGE Register for SDRAM access const int MEM_REG = 0x0018 >> 2; // SDRAM Bank Select Register and BlockRam enable const int IER = 0x0020 >> 2; // Interrupt Enable Register const int ISR = 0x0028 >> 2; // Interrupt Status Register const int MEM_RAS = 0x0030 >> 2; // SDRAM Read Address Scaling const int MEM_RAO = 0x0038 >> 2; // SDRAM Read Address Offset const int SYNTH_CNTRL_REG = 0x0080 >> 2; // ADC PLL Registers const int SYNTH_STRB_REG = 0x0088 >> 2; // ADC PLL Registers const int SYNTH_RESET = 0x0090 >> 2; // ADC PLL Registers const int MEM_GNT0 = 0x0400 >> 2; // Memory Grant Registers const int MEM_GNT1 = 0x0408 >> 2; // Memory Grant Registers const int MEM_GNT2 = 0x0410 >> 2; // Memory Grant Registers const int MEM_GNT3 = 0x0408 >> 2; // Memory Grant Registers const int FIRMWARE = 0x0800 >> 2; // Firmware ID code "CN" + version numbers const int ADC = 0x0808 >> 2; // ADC Control Register const int TIMING_IO = 0x0810 >> 2; // Timing I/O Register const int TESTCTRL = 0x0818 >> 2; // Test Data Control Register const int TESTLEN = 0x0820 >> 2; // Test Data Pattern Length // Per Pick-Up registers const int PU0_REG_BASE = 0x0880 >> 2; // PickUp 0 Register Base const int PU1_REG_BASE = 0x0900 >> 2; // PickUp 1 Register Base const int PU2_REG_BASE = 0x0980 >> 2; // PickUp 2 Register Base const int CONTROL = 0x0000 >> 2; // PU General Control and Status register const int CYCLE = 0x0008 >> 2; // Cycle number const int TIME = 0x0010 >> 2; // Time in ms from start of cycle const int TIME_TBLADDR = 0x0018 >> 2; // Last write address in timing table const int PLL_FREQUENCY = 0x0020 >> 2; // PLL Reference orbit frequency const int PLL_FREQDELAY = 0x0028 >> 2; // PLL frequency load delay const int PLL_PHASEDELAY = 0x0030 >> 2; // PLL phase delay const int PLL_GAIN = 0x0038 >> 2; // PLL gain const int DDS_FREQ_MIN = 0x0040 >> 2; // PLL DDS minimum frequency const int DDS_FREQ_MAX = 0x0048 >> 2; // PLL DDS maximum frequency const int DIAG_CTRL = 0x0050 >> 2; // Diagnostics Control/Status const int DIAG_TRIGGER = 0x0058 >> 2; // Diagnostics Trigger const int DIAG_DELAY = 0x0060 >> 2; // Diagnostics Capture Delay const int TEST = 0x0068 >> 2; // Timing Test
const int EVENT_DELAY = 0x0070 >> 2; // Programable event delay
// Memory access window const int FPGA_DATA_ADDRESS = 0x200000; // The FPGA memory const int FPGA_MEM = 0x200000 >> 2; // The FPGA memory // SDRAM Data Banks const int SDRAM_DATA_PU0 = 0x08; // PickUp 0 data const int SDRAM_DATA_PU1 = 0x09; // PickUp 1 data const int SDRAM_DATA_PU2 = 0x0A; // PickUp 2 data const int SDRAM_DATA_TEST = 0x0B; // Test input data const int SDRAM_BLOCKRAM = 0x00; // FPGA Memory #if NEW_BUNCH_MEAN const uint32_t SDRAM_DATA_TOP = (254*1024*1024); // The SDRAM bank size minus the area for bunch mean tables #else const uint32_t SDRAM_DATA_TOP = (256*1024*1024); // The SDRAM bank size in words #endif const int PU0_BRAM_BASE = 0; // PickUp 0 Block Ram ID base const int PU1_BRAM_BASE = 8; // PickUp 0 Block Ram ID base const int PU2_BRAM_BASE = 16; // PickUp 0 Block Ram ID base const int BRAM_CYCLE_TIMING = 0; // Cycle Timing Table const int BRAM_CYCLE_INFO = 1; // Cycle Information Table const int BRAM_PHASE_TABLE = 2; // Timing Phase Table const int BRAM_SWITCH_TABLE = 3; // Timing Switch Table const int BRAM_DIAG_TABLE = 4; // Diagnostics table const int BRAM_BUNCH_MEAN0 = 5; // Bunch Mean Table #0 const int BRAM_BUNCH_MEAN1 = 6; // Bunch Mean Table #1 // Control register bits const int CONTROL_INIT = 0x01; // Reset's PLL and State/Phase tables const int CONTROL_LOOP_CONTROL = 0x02; // Disables PLL feedback const int CONTROL_DDS_FREQUENCY_LIMIT_ENABLE = 0x04; // Enables PLL frequency limits const int CONTROL_BLR_DISABLE = 0x08; // Disables the BLR algorithm // Interrupt bits const int INT_PU0_CYCLE_START = (1<<0); // 0 PU #0 CYCLE_START const int INT_PU0_CYCLE_STOP = (1<<1); // 1 PU #0 CYCLE_STOP const int INT_PU0_ERROR = (1<<2); // 2 PU #0 ERROR const int INT_PU0_DIAG = (1<<3); // 3 PU #0 DIAGNOSTIC INFO CAPTURED const int INT_PU0_WRITE_FIFO = (1<<4); // 4 PU #0 SDRAM Write FIFO Half Full const int INT_PU0_USER0 = (1<<5); // 5 PU #0 User Interrupts (Switch Table bits 5) const int INT_PU0_USER1 = (1<<6); // 6 PU #0 User Interrupts (Switch Table bits 6) const int INT_PU0_USER2 = (1<<7); // 7 PU #0 User Interrupts (Switch Table bits 7) const int INT_PU1_CYCLE_START = (1<<8); // 8 PU #1 CYCLE_START const int INT_PU1_CYCLE_STOP = (1<<9); // 9 PU #1 CYCLE_STOP const int INT_PU1_ERROR = (1<<10); // 10 PU #1 ERROR const int INT_PU1_DIAG = (1<<11); // 11 PU #1 DIAGNOSTIC INFO CAPTURED const int INT_PU1_WRITE_FIFO = (1<<12); // 12 PU #1 SDRAM Write FIFO Half Full const int INT_PU1_USER0 = (1<<13); // 13 PU #1 User Interrupts (Switch Table bits 5) const int INT_PU1_USER1 = (1<<14); // 14 PU #1 User Interrupts (Switch Table bits 6) const int INT_PU1_USER2 = (1<<15); // 15 PU #1 User Interrupts (Switch Table bits 7) const int INT_PU2_CYCLE_START = (1<<16); // 16 PU #2 CYCLE_START const int INT_PU2_CYCLE_STOP = (1<<17); // 17 PU #2 CYCLE_STOP const int INT_PU2_ERROR = (1<<18); // 18 PU #2 ERROR const int INT_PU2_DIAG = (1<<19); // 19 PU #2 DIAGNOSTIC INFO CAPTURED const int INT_PU2_WRITE_FIFO = (1<<20); // 20 PU #2 SDRAM Write FIFO Half Full const int INT_PU2_USER0 = (1<<21); // 21 PU #2 User Interrupts (Switch Table bits 5) const int INT_PU2_USER1 = (1<<22); // 22 PU #2 User Interrupts (Switch Table bits 6) const int INT_PU2_USER2 = (1<<23); // 23 PU #2 User Interrupts (Switch Table bits 7) // ADC register bits const int ADC_LED_YELLOW = (1 << 10); ///< The Yellow LED const int ADC_LED_RED = (1 << 11); ///< The Red LED // FPGA Control Space Registers const int SYSMON_CTL = (0x00400 >> 2); const int SYSMON_BUF = (0x00500 >> 2); const int SYSMON_SMB_ERROR = (0x10000000);
const int TIMING_FREF = (143 << 16); // The FREF frequency for timing simulation
const int minTimingDiff = 500; // The minimum time difference in the timing table const int diagnosticsNumSamples = 4096; // The number of diagnostics samples const int diagnosticsTimeout = 800; // The diagnostics timeout in 10ms steps const uint32_t maxNumValues = (SDRAM_DATA_TOP / 2 / 8); // Maximum number of samples to return
// System information factors const float sysFactors[10] = { 0.0130, 0.0141, 0.0172, 0.0260, 0.0625, 0.0141, 1.0000, 1.0000, 0.0098, 0.0098 };
int compare(double v1, double v2, double diff){ if(v1 >= 0){ if(v1 > (v2 + (v2 * diff))) return 1; if(v1 < (v2 - (v2 * diff))) return 1; } else { if(v1 < (v2 + (v2 * diff))) return 1; if(v1 > (v2 - (v2 * diff))) return 1; } return 0; } /// 64bit memory copy function for PUPE board 64bit data access static inline int memcpy_64(void* to, const void* from, size_t len){ size_t i; // Check alignment and size if(((unsigned int)to & 0x07) || ((unsigned int)from & 0x07) || (len & 0x07)){ fprintf(stderr, "memcpy_mmx: Memory pointers and length need to be aligned to 64bit boundary\n"); return 1; } i = len / 8; while(i--){ __asm__ __volatile__ ( "movq (%0), %%mm0\n" "movq %%mm0, (%1)\n" :: "r" (from), "r" (to) : "memory"); from = ((const unsigned char *)from) + 8; to = ((unsigned char *)to) + 8; } __asm__ __volatile__ ("emms":::"memory"); return 0; } uint32_t sdramAddressRange(uint32_t start, uint32_t end){
if(start == end) return 0; else if(end > start)
return end - start; else return (SDRAM_DATA_TOP / 8) - start + end; } uint32_t sdramAddressAdd(uint32_t address, uint32_t offset){ address += offset; if(address > (SDRAM_DATA_TOP / 8)) address -= (SDRAM_DATA_TOP / 8); return address; } uint32_t sdramAddressByteAdd(uint32_t address, uint32_t offset){ address += offset; if(address >= SDRAM_DATA_TOP) address -= SDRAM_DATA_TOP; return address; } PupeInterruptThread::PupeInterruptThread(Pupe& pupe) : opupe(pupe){ } void* PupeInterruptThread::function(){ dprintf(DBG_THREADS, "InterruptThread Thread: %d\n", gettid()); opupe.fpgaInterruptLoop(); return 0; } Pupe::Pupe(Control& control, int slot, int board) : ocontrol(control), ointerruptThread(*this){ osimulate = 0; oinitialised = 0; omaster = 0; oboard = board; oslot = slot; ofpgaCard = 0; ofpga = 0; ofpgaControl = 0; ocycleNumberNext = 0; ocycleNumber = 0; ocycleCompletedNumber = 0; opuCycleNumbers[0] = 0; opuCycleNumbers[1] = 0; opuCycleNumbers[2] = 0; opageSize = 2*1024*1024; odmaBufferSize = opageSize; odmaBuffer = new UInt64 [odmaBufferSize/sizeof(UInt64)]; odmabuf = 0; opllRefErrors = 0; opllLocked = 0; oprocessingCycle = 0; memset(&opupeConfig, 0, sizeof(opupeConfig)); memset(ocycleParams, 0, sizeof(ocycleParams)); ostatus.set(ErrorFpga, "Not initialised"); ocycleCount = 0; } Pupe::~Pupe(){ if(!osimulate){ fpgaClose(); } } BString Pupe::getName(){ return BString("Pupe: ") + (oslot + 1) + ": "; } BError Pupe::init(){ BError err; BUInt32 simulateTiming; BString s; ostatus.set(ErrorFpga, "Not initialised"); if(config.findValue("SimulateFpga:").retInt() == 1) osimulate = 1; olock.lock(); memset(&opupeConfig, 0, sizeof(opupeConfig)); s = config.findValue("SimulateTiming:"); if(s != "") simulateTiming = s.retInt(); else simulateTiming = 0; opupeConfig.internalTimingMask = simulateTiming; if(!osimulate){ if(oinitialised){ fpgaClose(); oinitialised = 0; } if(oboard >= 0){ if(!(err = fpgaInit())){ // Set up Pll Synthesisor opllSynth.init(ofpga); // opllSynth.displayRegisters(); // Clear CycleInfo table ofpga[MEM_REG] = SDRAM_BLOCKRAM; memset(ocycleInfoTable, 0, sizeof(ocycleInfoTable)); ofpga[IMEM_REG] = PU0_BRAM_BASE + BRAM_CYCLE_INFO; fpgaWriteData64(ocycleInfoTable, 0, sizeof(ocycleInfoTable)); ofpga[IMEM_REG] = PU1_BRAM_BASE + BRAM_CYCLE_INFO; fpgaWriteData64(ocycleInfoTable, 0, sizeof(ocycleInfoTable)); ofpga[IMEM_REG] = PU2_BRAM_BASE + BRAM_CYCLE_INFO; fpgaWriteData64(ocycleInfoTable, 0, sizeof(ocycleInfoTable)); oinitialised = 1; } } else { err.set(ErrorFpga, getName() + "Not present"); } } else { oinitialised = 1; } ostatus = err; olock.unlock(); return err; } int Pupe::getSlot(){ return oslot; } BError Pupe::status(){ BError err; olock.lock(); err = ostatus.copy(); olock.unlock(); return err; }
void Pupe::setStatus(BError err, int powerOff){ olock.lock(); ostatus = err.copy(); fpgaShutdown(); olock.unlock(); }
BError Pupe::setMaster(int on){ BError err; if(!oinitialised){ return err.set(ErrorFpga, getName() + "Not present"); } if(!osimulate){ if(on) ofpga[TIMING_IO] = ofpga[TIMING_IO] | (1 << 29); else
ofpga[TIMING_IO] = ofpga[TIMING_IO] & ~0xF0000000;
} omaster = on; return err; } BError Pupe::setNextCycle(PuChannel puChannel, UInt32 cycleNumber, BString cycleType, CycleParam& params){ BError err; dprintf(DBG_SETNEXTCYCLE, "Pupe::setNextCycle: %u\n", cycleNumber); olock.lock(); ocycleNumberNext = cycleNumber; ocycleTypeNext = cycleType; if(puChannel.pupeChan == 0){ ocycleParams[0][cycleNumber % 8] = &params; ocycleParams[1][cycleNumber % 8] = &params; ocycleParams[2][cycleNumber % 8] = &params; } else { ocycleParams[puChannel.pupeChan - 1][cycleNumber % 8] = &params; } if(!oprocessingCycle){ err = setControlInfo(puChannel, cycleNumber, params); if(!err && oprocessingCycle){ err.set(ErrorCycleNumber, getName() + "The next cycle has already started"); } } olock.unlock(); dprintf(DBG_SETNEXTCYCLE, "Pupe::setNextCycle: %u: End\n", cycleNumber); return err; } BError Pupe::setControlInfo(PuChannel puChannel, UInt32 cycleNumber, CycleParam& params){ BError err; int n;
dprintf(DBG_PUPE, "Pupe::setControlInfo: %u.%u.%u %u %s %s\n", puChannel.moduleNum, puChannel.pupeNum, puChannel.pupeChan, cycleNumber, params.cycleType.retStr(), params.name.retStr());
if(ofpgaCard){ if(puChannel.pupeChan == 0){ for(n = 1; (n < numChan + 1) && !err; n++){ puChannel.pupeChan = n; err = setControlInfoPickUp(puChannel, cycleNumber, params); } } else if((puChannel.pupeChan > 0) && (puChannel.pupeChan < numChan + 1)){ err = setControlInfoPickUp(puChannel, cycleNumber, params); } else { return err.set(ErrorParam, getName() + "Incorrect puChannel"); } } return err; } BError Pupe::setControlInfoPickUp(PuChannel puChannel, UInt32 cycleNumber, CycleParam& params){ BError err; UInt32 regBase = 0; UInt32 brBase = 0; UInt32 n;
UInt32 ring = 0;
UInt32 logicalPuChannel = 1;
UInt32 stateTable[16];
UInt8 phaseTables[14][512]; #if DEBUG_CONTROL_TIME double t1 = 0, t2 = 0, t3 = 0, t4 = 0, t5 = 0; t1 = getTime(); #endif dprintf(DBG_CYCLEPARAM, "Pupe::setControlInfoPickUp: PupeNum: %d PupeChan: %d Type: %s\n", puChannel.pupeNum, puChannel.pupeChan, params.cycleType.retStr());
if(ostatus) return ostatus;
switch(puChannel.pupeChan){ case 1: regBase = PU0_REG_BASE; brBase = PU0_BRAM_BASE; break; case 2: regBase = PU1_REG_BASE; brBase = PU1_BRAM_BASE; break; case 3: regBase = PU2_REG_BASE; brBase = PU2_BRAM_BASE; break; default: return err.set(ErrorFpga, getName() + "Incorrect puChannel"); } dprintf(DBG_CYCLEPARAM, "Load Cycle Information: %d %s\n", puChannel.pupeChan, ocycleTypeNext.retStr()); #ifdef ZAP if(puChannel.pupeChan == 1) dumpState(); #endif puChannel.moduleNum = ocontrol.moduleNum(); puChannel.pupeNum = (oslot + 1);
if(ocontrol.getPuChannel(puChannel, ring, logicalPuChannel)){ ring = 1;
logicalPuChannel = 1;
}
#if DEBUG_CTRL //params.pllGain = 10; //params.frefPhaseDelay[logicalPuChannel - 1] = 128; printf("pllInitialFrequencyDelay: %d\n", params.pllInitialFrequencyDelay); printf("pllFrefGain: %d\n", params.pllFrefGain); printf("pllGain: %d\n", params.pllGain); printf("frefPhaseDelay: %d\n", params.frefPhaseDelay[logicalPuChannel - 1]); printf("FrefMsbSource: %d\n", params.stateTable[0].state & 0x10); #endif if(!osimulate){ // ofpga[regBase + PLL_PHASEDELAY] = 128 - params.frefPhaseDelay[logicalPuChannel - 1]; ofpga[regBase + PLL_PHASEDELAY] = params.frefPhaseDelay[logicalPuChannel - 1]; ofpga[regBase + PLL_FREQUENCY] = params.pllCycleStartFrequency; ofpga[regBase + PLL_FREQDELAY] = params.pllInitialFrequencyDelay; ofpga[regBase + PLL_GAIN] = (params.pllGain << 16) | (params.pllFrefGain & 0xFFFF); ofpga[regBase + DDS_FREQ_MIN] = params.pllDdsMinimum; ofpga[regBase + DDS_FREQ_MAX] = params.pllDdsMaximum;
ofpga[regBase + EVENT_DELAY] = params.stateDelay;
#if DEBUG_CONTROL_TIME t2 = getTime(); #endif // Write State and Phase Tables ofpga[MEM_REG] = SDRAM_BLOCKRAM; ofpga[IMEM_REG] = brBase + BRAM_SWITCH_TABLE;
for(n = 0; n < 16; n++){
if(n < params.stateTable.size()) stateTable[n] = params.stateTable[n].state;
else if(n == 15) stateTable[n] = 0xffffff00;
else
stateTable[n] = (n << 28) | 0x0eeeee00;
} fpgaWriteData64(stateTable, 0, sizeof(stateTable)); #if DEBUG_CONTROL_TIME t3 = getTime(); #endif ofpga[IMEM_REG] = brBase + BRAM_PHASE_TABLE; for(n = 0; (n < 14) && (n < params.stateTable.size()); n++){ memcpy(phaseTables[n], params.stateTable[n].phaseTable.data(), 512); } fpgaWriteData64(phaseTables, 0, 512 * params.stateTable.size()); #if DEBUG_CONTROL_TIME t4 = getTime(); #endif if(params.pllDdsMinimum || params.pllDdsMaximum){ if(! (ofpga[regBase + CONTROL] & CONTROL_DDS_FREQUENCY_LIMIT_ENABLE)) ofpga[regBase + CONTROL] |= CONTROL_DDS_FREQUENCY_LIMIT_ENABLE; } else { if(ofpga[regBase + CONTROL] & CONTROL_DDS_FREQUENCY_LIMIT_ENABLE) ofpga[regBase + CONTROL] &= ~CONTROL_DDS_FREQUENCY_LIMIT_ENABLE; } } #ifdef ZAP if(puChannel.pupeChan == 1) dumpState(); #endif opuCycleTypes[puChannel.pupeChan - 1] = ocycleTypeNext; #if DEBUG_CONTROL_TIME t5 = getTime(); printf("SetControlInfoPickUp: Times: %f, %f, %f, %f, %f Total: %f\n", t2 - t1, t3 - t2, t4 - t3, t5 - t4, t5 - t4, t5 - t1); #endif dprintf(DBG_FPGA, "Pupe::setControlInfoPickUp: End\n"); return err; } PuStateTable* Pupe::getPuStateTable(CycleParam* params, UInt32 period){ UInt32 s; for(s = 0; s < params->stateTable.size(); s++){ if(params->stateTable[s].period == period){ return &params->stateTable[s]; } } return 0; } BError Pupe::getStatusList(PuChannel puChannel, BList<NameValue>& statusList){ BError err; BString baseName = BString("Module") + ocontrol.moduleNum() + "_Pupe" + (oslot + 1); BList<NameValue> il; BIter i; err = status(); olock.lock(); statusList.append(NameValue(baseName + "_SerialNumber", ocardInfo.SerialNum)); if(!err) statusList.append(NameValue(baseName + "_Running", "1")); else statusList.append(NameValue(baseName + "_Running", "0")); statusList.append(NameValue(baseName + "_Error", err.getString())); statusList.append(NameValue(baseName + "_AdcPllLock", opllLocked)); statusList.append(NameValue(baseName + "_AdcPllLockErrors", opllRefErrors)); fpgaGetInfo(il); for(il.start(i); !il.isEnd(i); il.next(i)){ statusList.append(NameValue(baseName + "_" + il[i].name, il[i].value)); } olock.unlock(); return err; } BError Pupe::getStatus(PuChannel puChannel, PuStatus& puStatus){ BError err; err = status(); olock.lock(); if(!err) puStatus.running = 1; else puStatus.running = 0; puStatus.error = err; olock.unlock(); return err; } BError Pupe::checkData(UInt32 cycleNumber){ BError err; Int32 diff; // In the initial state we need to check if we have actually captured the cycle // We also need to check here when the cycle number wraps. // First check if we are within the possible cycle range diff = cycleNumber - ocycleCompletedNumber; if(diff < -3) return err.set(ErrorDataGone, getName() + "Cycle's data has already been overwritten: Current: " + ocycleCompletedNumber + " Requested: " + cycleNumber); if(diff > 1) return err.set(ErrorDataFuture, getName() + "Cycle data required is to far in the future: Current: " + ocycleCompletedNumber + " Requested: " + cycleNumber); while(diff == 1){ olock.unlock(); usleep(1000); olock.lock(); diff = cycleNumber - ocycleCompletedNumber; } return err; } BError Pupe::getEventList(BUInt32 pupeCycleNumber, BList<PupeEvent>& events){ BError err; int i; PupeEvent event; PupeEvent eventPrev = { 0, 0, 0, 0 }; BUInt a;
BUInt eventNext;
events.clear(); pupeCycleNumber &= 0x03; #if DEBUG_INFO_TABLE printf("Pupe::getEventList\n");
printf("CycleInfoTable Entry: %d\n", pupeCycleNumber); hd64(ocycleInfoTable, 4 * 16);
#endif
// First look for CYCLE_START event in first entry i = 0;
event.event = (ocycleInfoTable[(pupeCycleNumber << 4) + i] >> 24) & 0xFF; event.statePre = (ocycleInfoTable[(pupeCycleNumber << 4) + i] >> 20) & 0x0F; event.statePost = (ocycleInfoTable[(pupeCycleNumber << 4) + i] >> 16) & 0x0F;
event.timingAddress = ocycleInfoTable[(pupeCycleNumber << 4) + i] & FpgaCycleTimingTableMask; event.time = ocycleTimingTable[event.timingAddress] & 0xFFFFFFFF; event.dataAddress = ocycleInfoTable[(pupeCycleNumber << 4) + i] >> 32;
if(event.event != EventCycleStart){
return err.set(ErrorFpga, getName() + "No CYCLE_START event at start of cycle"); } // Now look for first valid timing table entry, this is where the time is 1ms for(a = 0; a < 4; a++){ if((ocycleTimingTable[(event.timingAddress + a) & FpgaCycleTimingTableMask] & 0xFFFFFFFF) == 1) break; } if(a >= 4) return err.set(ErrorFpga, getName() + "No 1ms timing table entry for CYCLE_START event"); // Set the Timing Address to be one before the 1ms timing table entry. This is not actually a valid // entry for the CYCLE, but it allows time offsets in later code to work correctly. event.timingAddress = (event.timingAddress + a - 1) & FpgaCycleTimingTableMask; event.time = 0; #if DEBUG_INFO_TABLE
printf("%d: Event: %x States(%d,%d) TimingAddress: %x Time: %d (NextTime: %d) DataAddress: %x\n", i, event.event, event.statePre, event.statePost, event.timingAddress, event.time, int(ocycleTimingTable[event.timingAddress + 1] & 0xFFFFFFFF), event.dataAddress);
#endif // Add the event to the events list events.append(event); eventPrev = event; // Gather the rest of the events from Cycle Information table for(i = 1; i < 16; i++){
event.event = (ocycleInfoTable[(pupeCycleNumber << 4) + i] >> 24) & 0xFF; event.statePre = (ocycleInfoTable[(pupeCycleNumber << 4) + i] >> 20) & 0x0F; event.statePost = (ocycleInfoTable[(pupeCycleNumber << 4) + i] >> 16) & 0x0F;
#ifdef ZAP
event.timingAddress = ocycleInfoTable[(pupeCycleNumber << 4) + i] & FpgaCycleTimingTableMask; event.time = ocycleTimingTable[event.timingAddress] & 0xFFFFFFFF;
#else event.timingAddress = (ocycleInfoTable[(pupeCycleNumber << 4) + i] - 1) & FpgaCycleTimingTableMask; event.time = (ocycleTimingTable[event.timingAddress] & 0xFFFFFFFF) + 1; #endif
event.dataAddress = ocycleInfoTable[(pupeCycleNumber << 4) + i] >> 32;
eventNext = (ocycleInfoTable[(pupeCycleNumber << 4) + i + 1] >> 24) & 0xFF;
if(event.event == 0){ return err.set(ErrorFpga, "No CYCLE_STOP event during cycle"); }
#if DEBUG_INFO_TABLE printf("%d: Event: %x States(%d,%d) TimingAddress: %x Time: %d (NextTime: %d) DataAddress: %x\n", i, event.event, event.statePre, event.statePost, event.timingAddress, event.time, int(ocycleTimingTable[event.timingAddress + 1] & 0xFFFFFFFF), event.dataAddress); #endif
// Check validity of events if(eventPrev.event && (event.time < eventPrev.time)){ #if DEBUG_DATA_ERROR
printf("Event timing backwards in CycleInfoTable Entry: %d Event: %x Times: %d <= %d\n", i, event.event, event.time, eventPrev.time);
hd64(ocycleInfoTable, 4 * 16); #endif return err.set(ErrorFpga, getName() + "Multiple events at the same time or later events have time before previous events"); } events.append(event); eventPrev = event;
if(event.event & EventCycleStop)
break; } return err; }
BError Pupe::eventsToPeriods(UInt32 cycleNumber, BList<PupeEvent>& events, BList<CycleInformationPeriodInternal>& periods){ BError err; BIter i; BIter i1; int h; CycleParam* param; CycleInformationPeriodInternal period; PupeEvent eventNull = { 0, 0, 0, 0, 0, 0 };
// Find CyclePeriods in Cycle Information table param = ocycleParams[0][cycleNumber % 8]; if(param == 0){ return err.set(ErrorParam, BString("Cycle parameters not set for Cycle number: ") + cycleNumber); }
period.cyclePeriod = 0; period.startTime = 0; period.endTime = 0; period.harmonic = 0; period.bunchMask = 0; period.numBunches = 0; period.numValues = 0; period.dataAddress = 0; period.eventStart = eventNull; period.eventEnd = eventNull; period.eventStop = eventNull;
// Get Cycle parameters for the given cycle for(events.start(i), h = 0; !events.isEnd(i); events.next(i)){
if(events[i].event == 0){ return err.set(ErrorFpga, "No CYCLE_STOP event during cycle"); } else if(events[i].event & EventCycleStart){
period.cyclePeriod = CyclePeriodAll;
period.startTime = events[i].time; period.dataAddress = events[i].dataAddress; period.eventStart = events[i];
periods.append(period);
period.cyclePeriod = 0;
}
else if(events[i].event & EventCycleStop){ if(period.cyclePeriod){ // Save period period.endTime = events[i].time; period.numValues = sdramAddressRange(period.dataAddress, events[i].dataAddress); period.eventEnd = events[i]; period.eventStop = events[i]; periods.append(period); period.cyclePeriod = 0;
}
periods[0].endTime = events[i].time; periods[0].numValues = sdramAddressRange(periods[0].dataAddress, events[i].dataAddress); periods[0].eventEnd = events[i]; periods[0].eventStop = events[i]; for(periods.start(i1); !periods.isEnd(i1); periods.next(i1)){ periods[i1].eventStop = events[i];
}
break;
}
else if(events[i].event & EventDelay){ // Ignore these } else if((events[i].event & EventInjection) && (period.cyclePeriod == CyclePeriodEvent0)){ // Ignore these multiple injections } else { // Save period if needed if(period.cyclePeriod){ period.endTime = events[i].time; period.numValues = sdramAddressRange(period.dataAddress, events[i].dataAddress); period.eventEnd = events[i]; periods.append(period); period.cyclePeriod = 0;
}
if(events[i].event & EventCalibrationStart){ period.cyclePeriod = CyclePeriodCalibration;
}
else if(events[i].event & EventInjection){ period.cyclePeriod = CyclePeriodEvent0; } else if(events[i].event & EventHChange){ period.cyclePeriod = CyclePeriodEvent1 + h++; } else { period.cyclePeriod = 0; } period.eventStart = events[i]; period.startTime = events[i].time;
if(events[i].statePost < 14){ period.harmonic = param->stateTable[events[i].statePost].harmonic; period.numBunches = param->stateTable[events[i].statePost].numBunches; period.bunchMask = param->stateTable[events[i].statePost].bunchMask; } else { period.harmonic = 0; period.numBunches = 0; period.bunchMask = 0x00; }
period.dataAddress = events[i].dataAddress;
} }
#if DEBUG_INFO_TABLE for(periods.start(i); !periods.isEnd(i); periods.next(i)){ CycleInformationPeriodInternal& p = periods[i]; printf("Period: %2d: StartTime: %4d EndTime: %4d Harm: %2d NumBunch: %d BunchMask: %4x NumValues: %8d Address: 0x%08x\n", p.cyclePeriod, p.startTime, p.endTime, p.harmonic, p.numBunches, p.bunchMask, p.numValues, p.dataAddress); } #endif
return err; }
void Pupe::printEventList(BList<PupeEvent>& events){ BIter i; int n; for(events.start(i), n = 0; !events.isEnd(i); events.next(i), n++){ printf("Event: %d Type: %x TimingAddress: %x Time: %d DataAddress: %x\n", n, events[i].event, events[i].timingAddress, events[i].time, events[i].dataAddress); } } BError Pupe::getCycleInformation(UInt32 cycleNumber, CycleInformation& cycleInformation){
BError err; int timeOut; uint32_t pupeCycleNumber; int32_t diff; BList<PupeEvent> events; BIter i; BIter n; int h; BList<CycleInformationPeriodInternal> periods; CycleInformationPeriodInternal period; CycleParam* param; uint32_t s;
dprintf(DBG_FPGA, "Pupe::getCycleInformation: Cycle: %u\n", cycleNumber);
if(ostatus) return ostatus;
olock.lock(); // Return an error if already gone or to far in the future if(err = checkData(cycleNumber)){ olock.unlock(); return err; } // Get Cycle parameters for the given cycle param = ocycleParams[0][cycleNumber % 8]; if(param == 0){ olock.unlock(); return err.set(ErrorParam, BString("Cycle parameters not set for Cycle number: ") + cycleNumber); } cycleInformation.cycleNumber = cycleNumber; cycleInformation.cycleType = param->cycleType; ofpga[MEM_REG] = SDRAM_BLOCKRAM; // Need to test if the cycle number has changed while we read the following two data tables timeOut = 2; do { pupeCycleNumber = ofpga[PU0_REG_BASE + CYCLE]; ofpga[IMEM_REG] = PU0_BRAM_BASE + BRAM_CYCLE_INFO; fpgaReadData64(0, ocycleInfoTable, sizeof(ocycleInfoTable)); ofpga[IMEM_REG] = PU0_BRAM_BASE + BRAM_CYCLE_TIMING; fpgaReadData64(0, ocycleTimingTable, sizeof(ocycleTimingTable)); } while(timeOut-- && (pupeCycleNumber != ofpga[PU0_REG_BASE + CYCLE])); if(timeOut < 0){ olock.unlock(); return err.set(ErrorFpga, getName() + "Timed out while getting Cycle Information tables"); } // Return an error if already gone or to far in the future if(err = checkData(cycleNumber)){ olock.unlock(); return err; } // Calculate actual Pupe Cycle number required diff = ocycleNumber - cycleNumber; pupeCycleNumber = (opuCycleNumbers[0] - diff) & 0x03; #if DEBUG_DATA printf("CycleInfoTable Entry: %d\n", pupeCycleNumber); hd64(ocycleInfoTable, 4 * 16); #endif if(err = getEventList(pupeCycleNumber, events)){ olock.unlock(); return err; }
#if NEW_CYCLE_INFO if(err = eventsToPeriods(pupeCycleNumber, events, periods)){ olock.unlock(); return err; } // Find required CyclePeriod in Events list for(periods.start(i); !periods.isEnd(i); periods.next(i)){ cycleInformation.periods.append(periods[i]); } #else
// Find CyclePeriods in Cycle Information table for(events.start(i), h = 0; !events.isEnd(i); events.next(i)){ n = i; events.next(n); period.cyclePeriod = 0; period.startTime = events[i].time; period.endTime = 0; period.harmonic = 0; period.bunchMask = 0; period.numBunches = 0; period.numValues = 0; if(events[i].event & 0x01){ period.cyclePeriod = CyclePeriodAll; cycleInformation.periods.append(period); } else if(events[i].event & 0x04){ period.cyclePeriod = CyclePeriodCalibration; if(!events.isEnd(n)){ period.endTime = events[n].time; period.numValues = sdramAddressRange(events[i].dataAddress, events[n].dataAddress); } for(s = 0; s < param->stateTable.size(); s++){ if(param->stateTable[s].period == period.cyclePeriod){ period.harmonic = param->stateTable[s].harmonic; period.numBunches = param->stateTable[s].numBunches; period.bunchMask = param->stateTable[s].bunchMask; break; } } cycleInformation.periods.append(period); } else if((events[i].event & 0x10) || (events[i].event & 0x20)){ period.cyclePeriod = CyclePeriodEvent0 + h; if(!events.isEnd(n)){ period.endTime = events[n].time; period.numValues = sdramAddressRange(events[i].dataAddress, events[n].dataAddress); } for(s = 0; s < param->stateTable.size(); s++){ if(param->stateTable[s].period == period.cyclePeriod){ period.harmonic = param->stateTable[s].harmonic; period.numBunches = param->stateTable[s].numBunches; period.bunchMask = param->stateTable[s].bunchMask; break; } } cycleInformation.periods.append(period); h++; } else if(events[i].event & 0x02){ events.start(n); cycleInformation.periods[0].endTime = events[i].time; cycleInformation.periods[0].numValues = sdramAddressRange(events[n].dataAddress, events[i].dataAddress); break; } }
#endif
if(!err){ // Need to check the FPGA has not overwritten the data while we were reading it. #ifdef ZAP printf("CheckTime: cycleTimingAddressStart: %u TIME_TBLADDR: %u\n", events.front().timingAddress, ofpga[PU0_REG_BASE + TIME_TBLADDR]); #endif diff = (events.front().timingAddress - ofpga[PU0_REG_BASE + TIME_TBLADDR]) & FpgaCycleTimingTableMask; if(diff < minTimingDiff) err.set(ErrorDataGone, getName() + "Data has already gone"); } olock.unlock(); return err; } void Pupe::dataAverage(uint32_t timeMs, Data& data){ BUInt32 n; MeanValueSmall* v; int s; for(n = 0; n < data.dataValues.size(); n++){ v = (MeanValueSmall*)&data.dataValues[n]; if(v->numSamples != 0){ if(v->numSamples < 256) s = 256; else if(v->numSamples < 512) s = 512; else if(v->numSamples < 1024) s = 1024; else if(v->numSamples < 2048) s = 2048; else s = 4096; data.dataValues[n].sigma = (int(v->sigma) * s) / v->numSamples; data.dataValues[n].deltaX = (int(v->deltaX) * s) / v->numSamples; data.dataValues[n].deltaY = (int(v->deltaY) * s) / v->numSamples; data.dataValues[n].time = timeMs + n; } else { data.dataValues[n].sigma = 0; data.dataValues[n].deltaX = 0; data.dataValues[n].deltaY = 0; data.dataValues[n].time = 0; } } } BError Pupe::getData(PuChannel puChannel, DataInfo dataInfo, Data& data, UInt32& orbitNumber){ BError err; int regBase; int brBase; BList<PupeEvent> events;
BList<CycleInformationPeriodInternal> periods; CycleInformationPeriodInternal period;
BIter i; BIter n; PupeEvent eventStart = { 0, 0, 0, 0 }; PupeEvent eventEnd = { 0, 0, 0, 0 }; PupeEvent eventStop = { 0, 0, 0, 0 }; uint32_t p; int32_t diff; uint32_t timingAddress = 0; uint32_t dataAddress = 0; int h; int found = 0; uint32_t numBunches = 0; uint32_t pupeCycleNumber; int timeOut; uint32_t numValues; CycleParam* cycleParam = 0; PuStateTable* stateTable = 0; #if DEBUG_DATA_TIME double t1 = 0, t2 = 0, t3 = 0, t4 = 0, t5 = 0; t1 = getTime(); #endif dprintf(DBG_FPGA, "Pupe::getData: PuChannel: %d.%d RequiredCycleNumber: %u CurrentCycleNumber: %u LastCompletedCycle: %u\n", puChannel.pupeNum, puChannel.pupeChan, dataInfo.cycleNumber, ocycleNumber, ocycleCompletedNumber); // printf("Pupe::getData: PuChannel: %d.%d RequiredCycleNumber: %u CurrentCycleNumber: %u LastCompletedCycle: %u\n", puChannel.pupeNum, puChannel.pupeChan, dataInfo.cycleNumber, ocycleNumber, ocycleCompletedNumber);
// printf("Pupe::getData: PuChannel: %d.%d startTime: %d orbitNumber: %d\n", puChannel.pupeNum, puChannel.pupeChan, dataInfo.startTime, dataInfo.orbitNumber);
if(!oinitialised){ return err.set(ErrorFpga, getName() + "Not present"); }
if(ostatus) return ostatus;
// Basic parameter validation if(dataInfo.startTime > 4000){ return err.set(ErrorParam, getName() + "Start time beyond 4000ms"); } if((dataInfo.cyclePeriod == CyclePeriodAll) && (dataInfo.function != DataFunctionRaw) && (dataInfo.startTime == 0)){ return err.set(ErrorParam, getName() + "Cannot return data with time offset 0 from CYCLE_START when using averaged data"); } if(dataInfo.orbitNumber > 1500000){ return err.set(ErrorParam, getName() + "Orbit number beyond 1500000"); } if(dataInfo.numValues > (40 * 8 * 500000)){ return err.set(ErrorParam, getName() + "NumValues number beyond (40 * 8 * 500000)"); } switch(puChannel.pupeChan){ case 1: regBase = PU0_REG_BASE; brBase = PU0_BRAM_BASE; break; case 2: regBase = PU1_REG_BASE; brBase = PU1_BRAM_BASE; break; case 3: regBase = PU2_REG_BASE; brBase = PU2_BRAM_BASE; break; default: return err.set(ErrorParam, getName() + "Incorrect puChan"); } olock.lock(); // Return an error if already gone or to far in the future if(err = checkData(dataInfo.cycleNumber)){ olock.unlock(); return err; } cycleParam = ocycleParams[puChannel.pupeChan - 1][dataInfo.cycleNumber % 8]; if(cycleParam == 0){ olock.unlock(); return err.set(ErrorParam, "Cycle parameters have not been set for this cycle"); } if(osimulate){ err = getSimData(dataInfo, data); if(dataInfo.startTime) orbitNumber = dataInfo.startTime * 2000; else orbitNumber = dataInfo.orbitNumber; } else { #if DEBUG_DATA_TIME t2 = getTime(); #endif // Get Cycle information ofpga[MEM_REG] = SDRAM_BLOCKRAM; // Need to test if the cycle number has changed while we read the following two data tables timeOut = 2; do { pupeCycleNumber = ofpga[PU0_REG_BASE + CYCLE]; ofpga[IMEM_REG] = brBase + BRAM_CYCLE_INFO; fpgaReadData64(0, ocycleInfoTable, sizeof(ocycleInfoTable)); ofpga[IMEM_REG] = brBase + BRAM_CYCLE_TIMING; fpgaReadData64(0, ocycleTimingTable, sizeof(ocycleTimingTable)); } while(timeOut-- && (pupeCycleNumber != ofpga[PU0_REG_BASE + CYCLE])); if(timeOut < 0){ olock.unlock(); return err.set(ErrorFpga, getName() + "Timed out while getting Cycle Information tables"); } #if DEBUG_DATA_TIME t3 = getTime(); #endif // Return an error if already gone or to far in the future if(err = checkData(dataInfo.cycleNumber)){ olock.unlock(); return err; } // Calculate actual Pupe Cycle number required diff = ocycleNumber - dataInfo.cycleNumber; pupeCycleNumber = opuCycleNumbers[puChannel.pupeChan - 1] - diff; #if DEBUG_DATA printf("GetData: CycleWanted: %u CurrentCycle: %u Diff: %d PupeCycle: %u CurrentPupeCycle: %u Period: %d\n", dataInfo.cycleNumber, ocycleNumber, diff,pupeCycleNumber, ofpga[PU0_REG_BASE + CYCLE], dataInfo.cyclePeriod); #endif if(err = getEventList(pupeCycleNumber, events)){ olock.unlock(); return err; }
#if NEW_CYCLE_INFO if(err = eventsToPeriods(pupeCycleNumber, events, periods)){ olock.unlock(); return err; } // Find required CyclePeriod in Events list for(periods.start(i), found = 0; !periods.isEnd(i); periods.next(i)){ if(periods[i].cyclePeriod == dataInfo.cyclePeriod){ period = periods[i]; found = 1; break; } } eventStart = period.eventStart; eventEnd = period.eventEnd; eventStop = period.eventStop; numBunches = period.numBunches; #else
// Find required CyclePeriod in Events list for(events.start(i), h = 0, p = CyclePeriodAll, found = 0; !events.isEnd(i); events.next(i)){ n = i; events.next(n); p = 0xFFFF; if(events[i].event == 0x01){ p = CyclePeriodAll; } else if(events[i].event == 0x04){ p = CyclePeriodCalibration; } else if((events[i].event == 0x10) || (events[i].event == 0x20)){ p = CyclePeriodEvent0 + h; h++; } else if(events[i].event == 0x02){ eventStop = events[i]; break; } if(events.isEnd(n)) break; if(p == dataInfo.cyclePeriod){ eventStart = events[i]; eventEnd = events[n]; found = 1; } } if(!found){ err.set(ErrorDataNotAvailable, getName() + "The CyclePeriod required could not be found"); olock.unlock(); return err; }
if(stateTable = getPuStateTable(cycleParam, dataInfo.cyclePeriod)) numBunches = stateTable->numBunches; else numBunches = 0; #endif
// Default is to limit data to this Cycle if(dataInfo.beyondPeriod || (dataInfo.cyclePeriod == CyclePeriodAll)){ eventEnd = eventStop; } #if DEBUG_DATA printf("\n"); printf("CycleInfoTable Entry: %d\n", pupeCycleNumber & 0x03); hd64(ocycleInfoTable, 4 * 16); printf("\n"); printf("CyclePeriod: %d Found: %d\n", dataInfo.cyclePeriod, p); printf("EventStart: %x Time: %d TimingAddress: %x DataAddress: %x\n", eventStart.event, eventStart.time, eventStart.timingAddress, eventStart.dataAddress); printf("EventEnd: %x Time: %d TimingAddress: %x DataAddress: %x\n", eventEnd.event, eventEnd.time, eventEnd.timingAddress, eventEnd.dataAddress); printf("EventStop: %x Time: %d TimingAddress: %x DataAddress: %x\n", eventStop.event, eventStop.time, eventStop.timingAddress, eventStop.dataAddress); #endif // Offset by Start time timingAddress = (eventStart.timingAddress + dataInfo.startTime) & FpgaCycleTimingTableMask; #ifdef ZAP_TIME if(dataInfo.startTime) dataAddress = ocycleTimingTable[timingAddress] >> 32; else dataAddress = eventStart.dataAddress; #else if(dataInfo.startTime){ uint32_t dataAddressOffset; // Validate startTime if(dataInfo.startTime > (eventEnd.time - eventStart.time)){ err.set(ErrorParam, getName() + "Start time beyond cycle period's end time: " + (eventEnd.time - eventStart.time) + "ms"); olock.unlock(); return err; } // Get appoximate data position within an orbits data if((ocycleTimingTable[timingAddress] >> 32) > eventStart.dataAddress){ dataAddressOffset = (ocycleTimingTable[timingAddress] >> 32) - eventStart.dataAddress; } else { dataAddressOffset = (ocycleTimingTable[timingAddress] >> 32) + (SDRAM_DATA_TOP / 8) - eventStart.dataAddress; } // Round down to the nearest orbit start if(numBunches) dataAddress = eventStart.dataAddress + (numBunches * (dataAddressOffset / numBunches)); else dataAddress = eventStart.dataAddress + dataAddressOffset; } else { dataAddress = eventStart.dataAddress; } #endif // Offset by orbit number if(numBunches){ dataAddress = sdramAddressAdd(dataAddress, numBunches * dataInfo.orbitNumber); if(dataAddress > eventStart.dataAddress){ orbitNumber = (dataAddress - eventStart.dataAddress) / numBunches; } else { orbitNumber = (dataAddress + (SDRAM_DATA_TOP / 8) - eventStart.dataAddress) / numBunches; } } else { dataAddress = sdramAddressAdd(dataAddress, dataInfo.orbitNumber); if(dataAddress > eventStart.dataAddress){ orbitNumber = (dataAddress - eventStart.dataAddress); } else { orbitNumber = (dataAddress + (SDRAM_DATA_TOP / 8) - eventStart.dataAddress); } } // Make sure data is within cycle period numValues = sdramAddressRange(dataAddress, eventEnd.dataAddress); if(numValues > maxNumValues){ err.set(ErrorDataNotAvailable, getName() + "CycleTable Error: Data beyond cycle period or the amount of data for a period exceeds a maximum cycle period");
#if DEBUG_INFO_TABLE
printf("CycleInfoTable Entry: %d\n", pupeCycleNumber & 0x03); hd64(ocycleInfoTable, 4 * 16); printf("\n"); printf("EventStart: %x Time: %d TimingAddress: %x DataAddress: %x\n", eventStart.event, eventStart.time, eventStart.timingAddress, eventStart.dataAddress); printf("EventEnd: %x Time: %d TimingAddress: %x DataAddress: %x\n", eventEnd.event, eventEnd.time, eventEnd.timingAddress, eventEnd.dataAddress); printf("EventStop: %x Time: %d TimingAddress: %x DataAddress: %x\n", eventStop.event, eventStop.time, eventStop.timingAddress, eventStop.dataAddress); printf("NumValues: %d %d:%x %d:%x\n", numValues, dataAddress, dataAddress, eventEnd.dataAddress, eventEnd.dataAddress); printf("Range: %d %d\n", SDRAM_DATA_TOP, SDRAM_DATA_TOP - dataAddress + eventEnd.dataAddress); #endif olock.unlock(); return err; } // Perform data access functions depending on type if(dataInfo.function == DataFunctionRaw){ if((dataInfo.bunchNumber == 0) && (dataInfo.numValues < numBunches)){ err.set(ErrorParam, getName() + "NumValues to small for request"); olock.unlock(); return err; } if(dataInfo.bunchNumber){ if(numBunches) numValues /= numBunches; } // Set up return data size if(numValues < dataInfo.numValues){ dataInfo.numValues = numValues; } data.dataValues.resize(dataInfo.numValues); data.numValues = dataInfo.numValues; if(dataInfo.bunchNumber) data.numBunches = 1; else data.numBunches = numBunches; data.numChannels = 1; #if DEBUG_DATA printf("Data: TimingAddress: %d Orbits: %d DataStart: %d DataEnd: %d NumValues: %d\n", timingAddress, dataInfo.orbitNumber, dataAddress, eventEnd.dataAddress, numValues); printf("BunchNumber: %d NumBunches: %d\n", dataInfo.bunchNumber, numBunches); printf("CycleTimingAddress: %u(%x) CycleTime: %u CycleDataAddress: %u(%x)\n", timingAddress, timingAddress, uint32_t(ocycleTimingTable[timingAddress] & 0xFFFFFFFF), dataAddress, dataAddress); printf("CycleTimingTable:\n"); hd64(&ocycleTimingTable[timingAddress], 16); #endif #if DEBUG_DATA_TIME t4 = getTime(); #endif if(dataInfo.bunchNumber && numBunches){ ofpga[MEM_RAO] = (dataAddress % numBunches) + dataInfo.bunchNumber - 1; ofpga[MEM_RAS] = numBunches; dataAddress = dataAddress / numBunches; } else { ofpga[MEM_RAO] = 0; ofpga[MEM_RAS] = 1; } // Read the Data err = fpgaCopyData(puChannel.pupeChan, dataAddress * 8, dataInfo.numValues, data); } else if(dataInfo.function == DataFunctionMean){ if(dataInfo.bunchNumber > 24){ err.set(ErrorParam, getName() + "Can only return average for up to bunch 24"); olock.unlock(); return err; } if(dataInfo.orbitNumber != 0){ err.set(ErrorNotImplemented, getName() + "Cannot offset by orbit"); olock.unlock(); return err; } if((dataInfo.bunchNumber == 0) && (dataInfo.numValues < numBunches)){ err.set(ErrorParam, getName() + "NumValues to small for request"); olock.unlock(); return err; } numValues = (eventEnd.timingAddress - timingAddress) & FpgaCycleTimingTableMask; if(dataInfo.bunchNumber == 0) numValues *= numBunches; // Set up return data size if(numValues < dataInfo.numValues){ dataInfo.numValues = numValues; } data.dataValues.resize(dataInfo.numValues); data.numValues = dataInfo.numValues; data.numChannels = 1; if(dataInfo.bunchNumber == 0){ data.numBunches = numBunches; err = fpgaGetAverageDataAll(puChannel.pupeChan, eventStart.time, timingAddress, numBunches, data.numValues, data); } else { data.numBunches = 1; err = fpgaGetAverageData(puChannel.pupeChan, eventStart.time, timingAddress, dataInfo.bunchNumber, data.numValues, data); } } else if(dataInfo.function == DataFunctionMeanAll){ if(dataInfo.bunchNumber != 0){ err.set(ErrorParam, getName() + "Can only return average for all bunches"); olock.unlock(); return err; } if(dataInfo.orbitNumber != 0){ err.set(ErrorNotImplemented, getName() + "Cannot offset by orbit"); olock.unlock(); return err; } numValues = (eventEnd.timingAddress - timingAddress) & FpgaCycleTimingTableMask; // Set up return data size if(numValues < dataInfo.numValues){ dataInfo.numValues = numValues; } data.dataValues.resize(dataInfo.numValues); data.numValues = dataInfo.numValues; data.numBunches = 0; data.numChannels = 1; err = fpgaGetAverageData(puChannel.pupeChan, eventStart.time, timingAddress, 0, data.numValues, data); } else if(dataInfo.function == DataFunctionMean0){ if(dataInfo.bunchNumber != 0){ err.set(ErrorNotImplemented, getName() + "Can only return average for all bunches"); olock.unlock(); return err; } if(dataInfo.orbitNumber != 0){ err.set(ErrorNotImplemented, getName() + "Cannot offset by orbit"); olock.unlock(); return err; } numValues = (eventEnd.timingAddress - timingAddress) & FpgaCycleTimingTableMask; // Set up return data size if(numValues < dataInfo.numValues){ dataInfo.numValues = numValues; } data.dataValues.resize(dataInfo.numValues); data.numValues = dataInfo.numValues; data.numBunches = 1; data.numChannels = 1; ofpga[IMEM_REG] = brBase + BRAM_BUNCH_MEAN0; fpgaReadData64(timingAddress * sizeof(uint64_t), data.dataValues.data(), dataInfo.numValues * sizeof(uint64_t)); dataAverage(eventStart.time, data); } else if(dataInfo.function == DataFunctionMean1){ if(dataInfo.orbitNumber != 0){ err.set(ErrorNotImplemented, getName() + "Cannot offset by orbit"); olock.unlock(); return err; } numValues = (eventEnd.timingAddress - timingAddress) & FpgaCycleTimingTableMask; // Set up return data size if(numValues < dataInfo.numValues){ dataInfo.numValues = numValues; } data.dataValues.resize(dataInfo.numValues); data.numValues = dataInfo.numValues; data.numBunches = 1; data.numChannels = 1; ofpga[IMEM_REG] = brBase + BRAM_BUNCH_MEAN1; fpgaReadData64(timingAddress * sizeof(uint64_t), data.dataValues.data(), dataInfo.numValues * sizeof(uint64_t)); dataAverage(eventStart.time, data); } else { err.set(ErrorNotImplemented, getName() + "Data function: " + dataInfo.function + " has not been implemented"); } #if DEBUG_DATA_TIME t5 = getTime(); #endif #if DEBUG_DATA printf("CycleDataTable: %x %d\n", dataAddress, data.dataValues.size()); if(data.dataValues.size() >= 16) hd64(data.dataValues.data(), 16); #endif if(!err){ // Need to check the FPGA has not overwritten the data while we were reading it. diff = (timingAddress - ofpga[regBase + TIME_TBLADDR]) & FpgaCycleTimingTableMask; if(diff < minTimingDiff){ err.set(ErrorDataGone, getName() + "Data has already gone: Difference: " + diff + " StartTimingAddress: " + timingAddress + " PupeWriteTimingAddress: " + ofpga[regBase + TIME_TBLADDR]); #if DEBUG_DATA_ERROR printf("Data has already gone: Difference: %d StartTimingAddress: %x PupeWriteTimingAddress: %x\n", diff, timingAddress, ofpga[regBase + TIME_TBLADDR]); printf("PupeCycle: %d PupeTime: %d PupeTimingAddress: %x\n", ofpga[regBase + CYCLE], ofpga[regBase + TIME], ofpga[regBase + TIME_TBLADDR]); printf("GetData: CycleWanted: %u CurrentCycle: %u Diff: %d PupeCycle: %u CurrentPupeCycle: %u Period: %d\n", dataInfo.cycleNumber, ocycleNumber, diff,pupeCycleNumber, ofpga[regBase + CYCLE], dataInfo.cyclePeriod); printEventList(events); printf("CycleInfoTable Entry: %d\n", pupeCycleNumber & 0x03); hd64(ocycleInfoTable, 4 * 16); #endif } } } olock.unlock(); #if DEBUG_DATA_TIME printf("GetData: Times: %f, %f, %f, %f, %f Total: %f\n", t2 - t1, t3 - t2, t4 - t3, t5 - t4, t5 - t4, t5 - t1); #endif
dprintf(DBG_FPGA, "Pupe::getData: End\n", puChannel.pupeNum, puChannel.pupeChan, dataInfo.cycleNumber, ocycleNumber, ocycleCompletedNumber);
return err; } BError Pupe::fpgaGetAverageData(int pupeChan, uint32_t timeMs, uint32_t timingAddress, uint32_t bunch, uint32_t numValues, Data& data){ BError err; MeanValue* v; uint32_t nr; uint32_t address; uint32_t n; dprintf(DBG_FPGA, "Pupe::fpgaGetAverageData: Chan: %d StartTime: %d TimingAddress: %x\n", pupeChan, timeMs, timingAddress);
if(ostatus) return ostatus;
switch(pupeChan){ case 1: ofpga[MEM_REG] = SDRAM_DATA_PU0; break; case 2: ofpga[MEM_REG] = SDRAM_DATA_PU1; break; case 3: ofpga[MEM_REG] = SDRAM_DATA_PU2; break; default: return err.set(ErrorFpga, "Incorrect puChannel"); } v = new MeanValue[numValues]; // Set up access to the top page of SDRAM ofpga[ADDR_REG] = 0x7F << 19; ofpga[MEM_RAO] = 0; ofpga[MEM_RAS] = 1; // Read the BunchMean Data nr = numValues; if((timingAddress + nr) > FpgaCycleTimingTableSize) nr = FpgaCycleTimingTableSize - timingAddress; // Set up base access address address = (bunch << 16) | (timingAddress << 4); // Fetch the data, possibly in two chunks to handle buffer wrap around if(err = fpgaReadData64(address, v, nr * sizeof(MeanValue))){ ofpga[MEM_REG] = SDRAM_BLOCKRAM; return err; } if(nr != numValues){ address = (bunch << 16) | (0 << 4); if(err = fpgaReadData64(address, &v[nr], (numValues - nr) * sizeof(MeanValue))){ ofpga[MEM_REG] = SDRAM_BLOCKRAM; return err; } } ofpga[MEM_REG] = SDRAM_BLOCKRAM; // Copy and scale data for(n = 0; n < numValues; n++){ if(v[n].numSamples == 0){ data.dataValues[n].sigma = 0; data.dataValues[n].deltaX = 0; data.dataValues[n].deltaY = 0; data.dataValues[n].time = 0; } else { data.dataValues[n].sigma = v[n].sigma / v[n].numSamples; data.dataValues[n].deltaX = v[n].deltaX / v[n].numSamples; data.dataValues[n].deltaY = v[n].deltaY / v[n].numSamples; data.dataValues[n].time = timeMs + n; } } delete [] v; return err; } BError Pupe::fpgaGetAverageDataAll(int pupeChan, uint32_t timeMs, uint32_t timingAddress, uint32_t numBunches, uint32_t numValues, Data& data){ BError err; MeanValue* v; uint32_t nr; uint32_t address; uint32_t n; uint32_t b; uint32_t numPerBunch; dprintf(DBG_FPGA, "Pupe::fpgaGetAverageDataAll: Chan: %d StartTime: %d TimingAddress: %x\n", pupeChan, timeMs, timingAddress);
if(ostatus) return ostatus;
switch(pupeChan){ case 1: ofpga[MEM_REG] = SDRAM_DATA_PU0; break; case 2: ofpga[MEM_REG] = SDRAM_DATA_PU1; break; case 3: ofpga[MEM_REG] = SDRAM_DATA_PU2; break; default: return err.set(ErrorParam, "Incorrect puChannel"); } if(numBunches == 0) return err.set(ErrorFpga, "Number of bunches is 0"); numPerBunch = numValues / numBunches; data.dataValues.resize(numPerBunch * numBunches); data.numValues = numPerBunch * numBunches; v = new MeanValue[numPerBunch]; // Set up access to the top page of SDRAM ofpga[MEM_RAO] = 0; ofpga[MEM_RAS] = 1; // Read the BunchMean Data for(b = 0; b < numBunches; b++){ nr = numPerBunch; if((timingAddress + nr) > FpgaCycleTimingTableSize) nr = FpgaCycleTimingTableSize - timingAddress; // Set up base access address address = ((b + 1) << 16) | (timingAddress << 4); // Fetch the data, possibly in two chunks to handle buffer wrap around ofpga[ADDR_REG] = 0x7F << 19; if(err = fpgaReadData64(address, v, nr * sizeof(MeanValue))){ ofpga[MEM_REG] = SDRAM_BLOCKRAM; return err; } if(nr != numPerBunch){ address = ((b + 1) << 16) | (0 << 4); ofpga[ADDR_REG] = 0x7F << 19; if(err = fpgaReadData64(address, &v[nr], (numPerBunch - nr) * sizeof(MeanValue))){ ofpga[MEM_REG] = SDRAM_BLOCKRAM; return err; } } // Copy and scale data for(n = 0; n < numPerBunch; n++){ if(v[n].numSamples == 0){ data.dataValues[n * numBunches + b].sigma = 0; data.dataValues[n * numBunches + b].deltaX = 0; data.dataValues[n * numBunches + b].deltaY = 0; data.dataValues[n * numBunches + b].time = 0; } else { data.dataValues[n * numBunches + b].sigma = v[n].sigma / v[n].numSamples; data.dataValues[n * numBunches + b].deltaX = v[n].deltaX / v[n].numSamples; data.dataValues[n * numBunches + b].deltaY = v[n].deltaY / v[n].numSamples; data.dataValues[n * numBunches + b].time = timeMs + n; } } } ofpga[MEM_REG] = SDRAM_BLOCKRAM; delete [] v; return err; } BError Pupe::getSimData(DataInfo dataInfo, Data& data){ BError err; SigGenBeam sigBeam; UInt32 i; Sample* samples; static Data dataCache; double t; double tend; struct timespec treq; t = getTime(); tend = t + (dataInfo.numValues * sizeof(DataValue)) / 100e6; if(dataCache.dataValues.size() != dataInfo.numValues){ samples = new Sample[dataInfo.numValues]; sigBeam.config(125000000, 437000, 8, 0x3C, 0.0, 0, 1.0); sigBeam.generateIntegrated(samples, dataInfo.numValues); dataCache.numValues = dataInfo.numValues; dataCache.dataType = 0; dataCache.numBunches = 4; dataCache.numChannels = 1; dataCache.dataValues.resize(dataInfo.numValues); for(i = 0; i < dataInfo.numValues; i++){ dataCache.dataValues[i].sigma = Int16(32767.0 * samples[i]); dataCache.dataValues[i].deltaX = Int16(0.2 * 32767.0 * samples[i]); dataCache.dataValues[i].deltaY = Int16(-0.1 * 32767.0 * samples[i]); } delete [] samples; } data = dataCache; // Delay to get data rate while((t = getTime()) < tend){ if((tend - t) > 0.01){ treq.tv_sec = 0; treq.tv_nsec = long((tend - t) * 1e9); nanosleep(&treq, 0); } } return err; } BError Pupe::setTestMode(PuChannel puChannel, UInt32 testOutput, UInt32 timingDisableMask){ BError err; int regBase = 0; int brBase = 0; if(!oinitialised){ return err.set(ErrorFpga, getName() + "Not present"); }
if(ostatus) return ostatus;
if(osimulate){ err.set(ErrorNotImplemented, getName() + "Not Implemented"); } else { switch(puChannel.pupeChan){ case 1: regBase = PU0_REG_BASE; brBase = PU0_BRAM_BASE; break; case 2: regBase = PU1_REG_BASE; brBase = PU1_BRAM_BASE; break; case 3: regBase = PU2_REG_BASE; brBase = PU2_BRAM_BASE; break; default: return err.set(ErrorFpga, getName() + "Incorrect puChannel"); } olock.lock();
ofpga[TIMING_IO] = (ofpga[TIMING_IO] & ~0x0FFFFF00) | TIMING_FREF | ((timingDisableMask & 0xFF) << 8);
olock.unlock(); } return err; } BError Pupe::setTimingSignals(PuChannel puChannel, UInt32 timingSignals){ BError err; if(!oinitialised){ return err.set(ErrorFpga, getName() + "Not present"); }
if(ostatus) return ostatus;
if(osimulate){ err.set(ErrorNotImplemented, getName() + "Not Implemented"); } else { olock.lock();
dprintf(DBG_FPGA, "Pupe::setTimingSignals: %x\n", timingSignals);
ofpga[TIMING_IO] = (ofpga[TIMING_IO] & ~0xFF) | (timingSignals & 0xFF); olock.unlock(); } return err; } BError Pupe::captureDiagnostics(PuChannel puChannel, TestCaptureInfo captureInfo, BArray<UInt64>& data){ BError err; int regBase = 0; int brBase = 0; UInt32 v = 0; int num = diagnosticsNumSamples; int timeOut; dprintf(DBG_FPGA, "Pupe::captureDiagnostics\n"); if(!oinitialised){ return err.set(ErrorFpga, getName() + "Not present"); }
if(ostatus) return ostatus;
// Check Parameters if(captureInfo.startTime && captureInfo.postTriggerDelay) return err.set(ErrorParam, getName() + "Parameter error: Can only have startTime or postTriggerDelay not both"); if(osimulate){ data.resize(num); } else { switch(puChannel.pupeChan){ case 1: regBase = PU0_REG_BASE; brBase = PU0_BRAM_BASE; break; case 2: regBase = PU1_REG_BASE; brBase = PU1_BRAM_BASE; break; case 3: regBase = PU2_REG_BASE; brBase = PU2_BRAM_BASE; break; default: return err.set(ErrorFpga, getName() + "Incorrect puChannel"); } #if DEBUG_CTRL printf("TIMING_IO: %x\n", ofpga[TIMING_IO]); printf("TEST: %x\n", ofpga[regBase + TEST]); printf("ADC: %x\n", ofpga[ADC]); #endif odiagLock.lock(); v |= ((captureInfo.source & 0x03) << 2); v |= ((captureInfo.triggerStore & 0x01) << 4); v |= ((captureInfo.triggerAnd & 0x1) << 5); v |= ((captureInfo.triggerSourceData & 0x1) << 6); v |= ((captureInfo.clock & 0x1F) << 8);
v |= ((captureInfo.triggerStateEnable) << 13); // State-qualified trigger enable - JMB
if(captureInfo.startTime){ v |= ((captureInfo.startTime & 0xFFFF) << 16); v |= ((0x1) << 7); ofpga[regBase + DIAG_DELAY] = 0; } else { ofpga[regBase + DIAG_DELAY] = captureInfo.postTriggerDelay; } // Trigger the data capture v |= ((0x1) << 0);
ofpga[regBase + DIAG_TRIGGER] = (captureInfo.triggerState << 8) | captureInfo.triggerMask;
ofpga[regBase + DIAG_CTRL] = v; timeOut = diagnosticsTimeout; while(((ofpga[regBase + DIAG_CTRL] & 0x01) || ((ofpga[regBase + DIAG_CTRL] & 0x02) & 0x02)) && timeOut--){ usleep(10000); } if(timeOut <= 0){ odiagLock.unlock(); return err.set(ErrorTimeout, getName() + "Diagnostics capture timed out"); } olock.lock(); ofpga[MEM_REG] = SDRAM_BLOCKRAM; ofpga[IMEM_REG] = brBase + BRAM_DIAG_TABLE; data.resize(num); // Fetch data fpgaReadData64(0, data.data(), data.size() * sizeof(UInt64)); olock.unlock(); odiagLock.unlock(); }
dprintf(DBG_FPGA, "Pupe::captureDiagnostics: End\n");
return err; } BError Pupe::setTestData(PuChannel puChannel, Int32 on, BArray<UInt32> data){ BError err; int regBase = 0; int brBase = 0; BArray<UInt32> rdata; uint32_t i; dprintf(DBG_FPGA, "Pupe::setTestData: Len: %d\n", data.size()); if(!oinitialised){ return err.set(ErrorFpga, getName() + "Not present"); }
if(ostatus) return ostatus;
switch(puChannel.pupeChan){ case 1: regBase = PU0_REG_BASE; brBase = PU0_BRAM_BASE; break; case 2: regBase = PU1_REG_BASE; brBase = PU1_BRAM_BASE; break; case 3: regBase = PU2_REG_BASE; brBase = PU2_BRAM_BASE; break; default: return err.set(ErrorFpga, getName() + "Incorrect puChannel"); } if(data.size() > (opageSize / sizeof(UInt32))){ return err.set(ErrorParam, getName() + "Data length is to long"); } if(data.size() % 1){ // Round down to a multiple of 64bits data.resize(data.size() - 1); } if(osimulate){ err.set(ErrorNotImplemented, getName() + "Not Implemented"); } else { olock.lock(); if(on){ ofpga[TESTCTRL] = 0; ofpga[MEM_RAO] = 0; ofpga[MEM_RAS] = 1; ofpga[MEM_REG] = SDRAM_DATA_TEST; ofpga[ADDR_REG] = 0; // Delay needed so that TEST DATA engine has released access to SDRAM usleep(20000); // Write to test data SDRAM fpgaWriteData64(data.data(), 0x0, data.size() * sizeof(UInt32)); // Check data read ofpga[MEM_REG] = SDRAM_DATA_TEST; ofpga[ADDR_REG] = 0; rdata.resize(data.size()); fpgaReadData64(0x0, rdata.data(), rdata.size() * sizeof(UInt32)); for(i = 0; i < data.size(); i++){ if(data[i] != rdata[i]){ printf("ERROR TestData ERROR: %d %x %x\n", i, data[i], rdata[i]); ofpga[MEM_REG] = SDRAM_BLOCKRAM; olock.unlock(); return err.set(ErrorFpga, getName() + "Error setting test data"); } } ofpga[MEM_REG] = SDRAM_BLOCKRAM; ofpga[TESTLEN] = data.size() / 2; ofpga[TESTCTRL] = (1 << 25); switch(puChannel.pupeChan){ case 1: ofpga[ADC] &= ~0x007; break; case 2: ofpga[ADC] &= ~0x038; break; case 3: ofpga[ADC] &= ~0x1C0; break; } ofpga[regBase + TEST] = ofpga[regBase + TEST] | 0x8000; } else { ofpga[regBase + TEST] = ofpga[regBase + TEST] & ~0x8000; switch(puChannel.pupeChan){ case 1: ofpga[ADC] |= 0x007; break; case 2: ofpga[ADC] |= 0x038; break; case 3: ofpga[ADC] |= 0x1C0; break; } } olock.unlock(); } return err; } BError Pupe::setPupeConfig(PuChannel puChannel, PupeConfig pupeConfig){ BError err; int regBase = 0; int brBase = 0; dprintf(DBG_FPGA, "Pupe::setPupeConfig: %d,%d,%d\n", pupeConfig.adcSysclkSync, pupeConfig.internalTimingMask, pupeConfig.disableBlr); if(!oinitialised){ return err.set(ErrorFpga, getName() + "Not present"); }
if(ostatus) return ostatus;
switch(puChannel.pupeChan){ case 1: regBase = PU0_REG_BASE; brBase = PU0_BRAM_BASE; break; case 2: regBase = PU1_REG_BASE; brBase = PU1_BRAM_BASE; break; case 3: regBase = PU2_REG_BASE; brBase = PU2_BRAM_BASE; break; default: return err.set(ErrorFpga, getName() + "Incorrect puChannel"); } if(!osimulate){ // Enable timing bus simulation if(pupeConfig.internalTimingMask){
ofpga[TIMING_IO] = (ofpga[TIMING_IO] & ~0x0FFFFF00) | TIMING_FREF | (pupeConfig.internalTimingMask << 8);
} else {
ofpga[TIMING_IO] = ofpga[TIMING_IO] & ~0x0FFFFF00;
} if(pupeConfig.disableBlr){ ofpga[regBase + CONTROL] |= CONTROL_BLR_DISABLE; } else { ofpga[regBase + CONTROL] &= ~CONTROL_BLR_DISABLE; } // This sets up the ADC Clock if(pupeConfig.adcSysclkSync != opupeConfig.adcSysclkSync){ if(pupeConfig.adcSysclkSync){ opllSynth.setMode(PllSynth::VCXO_REF); } else { opllSynth.setMode(PllSynth::VCXO); } // opllSynth.displayRegisters(); // Reset memory DCM's ofpga[LOCKED] = 0x01; } } opupeConfig = pupeConfig; return err; } BError Pupe::getPupeConfig(PuChannel puChannel, PupeConfig& pupeConfig){ BError err; int regBase = 0; int brBase = 0; dprintf(DBG_FPGA, "Pupe::getPupeConfig: %d.%d.%d\n", puChannel.moduleNum, puChannel.pupeNum, puChannel.pupeChan); if(!oinitialised){ return err.set(ErrorFpga, getName() + "Not present"); }
if(ostatus) return ostatus;
switch(puChannel.pupeChan){ case 1: regBase = PU0_REG_BASE; brBase = PU0_BRAM_BASE; break; case 2: regBase = PU1_REG_BASE; brBase = PU1_BRAM_BASE; break; case 3: regBase = PU2_REG_BASE; brBase = PU2_BRAM_BASE; break; default: return err.set(ErrorFpga, getName() + "Incorrect puChannel"); } pupeConfig = opupeConfig; return err; } int Pupe::adcPllLockCheck(){ int v;
if(ostatus) return ostatus;
if(oinitialised && opupeConfig.adcSysclkSync){ v = opllSynth.lockStatus(); dprintf(DBG_FPGA, "LockStatus: %d Count: %d\n", v, opllRefErrors); if(!v){ opllRefErrors++; opllSynth.lockReset(); } opllLocked = opllSynth.lockStatus(); } else { opllLocked = 0; } return opllLocked; } void Pupe::cycleStart(){
if(ostatus) return;
if(osimulate){ dprintf(DBG_FPGA, "Pupe::cycleStart\n"); } else { dprintf(DBG_FPGA, "Pupe::cycleStart: PupeCycle: %u Ctime: %u\n", ofpga[PU0_REG_BASE + CYCLE], ofpga[PU0_REG_BASE + TIME]); } olock.lock(); oprocessingCycle = 1; ocycleNumber = ocycleNumberNext; // Clear the Cycle Parameters for the next cycle ocycleParams[0][(ocycleNumber + 1) % 8] = 0; ocycleParams[1][(ocycleNumber + 1) % 8] = 0; ocycleParams[2][(ocycleNumber + 1) % 8] = 0; if(osimulate){ opuCycleNumbers[0]++; opuCycleNumbers[1]++; opuCycleNumbers[2]++; } else { opuCycleNumbers[0] = ofpga[PU0_REG_BASE + CYCLE]; opuCycleNumbers[1] = ofpga[PU1_REG_BASE + CYCLE]; opuCycleNumbers[2] = ofpga[PU2_REG_BASE + CYCLE]; // Set up initial frequency for injection if(ocycleParams[0][ocycleNumber % 8]){ ofpga[PU0_REG_BASE + PLL_FREQUENCY] = ocycleParams[0][ocycleNumber % 8]->pllInitialFrequency; } if(ocycleParams[1][ocycleNumber % 8]){ ofpga[PU1_REG_BASE + PLL_FREQUENCY] = ocycleParams[1][ocycleNumber % 8]->pllInitialFrequency; } if(ocycleParams[2][ocycleNumber % 8]){ ofpga[PU2_REG_BASE + PLL_FREQUENCY] = ocycleParams[2][ocycleNumber % 8]->pllInitialFrequency; } ofpga[ADC] |= ADC_LED_YELLOW; } olock.unlock(); // Only master should send this if(omaster) ocontrol.cycleStart(ocycleNumber); } void Pupe::cycleStop(){ UInt32 currentCycle;
if(ostatus) return;
olock.lock(); oprocessingCycle = 0; currentCycle = ocycleNumber; ocycleCompletedNumber = ocycleNumber; // Load the Cycle Parameters if they are known if(ocycleParams[0][(currentCycle + 1) % 8]){ setControlInfo(PuChannel(0, 0, 0), currentCycle + 1, *(ocycleParams[0][(currentCycle + 1) % 8])); } if(ocycleParams[1][(currentCycle + 1) % 8]){ setControlInfo(PuChannel(0, 0, 1), currentCycle + 1, *(ocycleParams[1][(currentCycle + 1) % 8])); } if(ocycleParams[2][(currentCycle + 1) % 8]){ setControlInfo(PuChannel(0, 0, 2), currentCycle + 1, *(ocycleParams[2][(currentCycle + 1) % 8])); } olock.unlock(); if(osimulate){ dprintf(DBG_FPGA, "Pupe::cycleStop\n"); } else { dprintf(DBG_FPGA, "Pupe::cycleStop: PupeCycle: %u Ctime: %u\n", ofpga[PU0_REG_BASE + CYCLE], ofpga[PU0_REG_BASE + TIME]); ofpga[ADC] &= ~ADC_LED_YELLOW; } // Only master should send this if(omaster) ocontrol.cycleStop(currentCycle); dprintf(DBG_FPGA, "Pupe::cycleStop: %d %d %d %d\n", ocycleNumber, opuCycleNumbers[0], opuCycleNumbers[1], opuCycleNumbers[2]); } void Pupe::cycleError(int puChan){ dprintf(DBG_FPGA, "Pupe::cycleError: %d\n", puChan);
#if DEBUG_INFO_TABLE
printf("Pupe::cycleError: %d\n", puChan);
dumpState(); #endif
// Clear the error ocontrol.cycleError(ocycleNumber, BError(ErrorStateTable, "FPGA State table transition error"));
dprintf(DBG_FPGA, "Pupe::cycleError: End\n");
} /******************************************************************************* * FPGA access functions ******************************************************************************* */ void Pupe::dumpState(){ int regBase = 0; int brBase = 0;
UInt32 switchTable[16];
UInt8 phaseTables[16][512]; int s; int n; int pupeChan = 1; switch(pupeChan){ case 1: regBase = PU0_REG_BASE; brBase = PU0_BRAM_BASE; break; case 2: regBase = PU1_REG_BASE; brBase = PU1_BRAM_BASE; break; case 3: regBase = PU2_REG_BASE; brBase = PU2_BRAM_BASE; break; } printf("CycleNumber: %u\n", ocycleNumber); printf("CycleCompletedNumber: %u\n", ocycleCompletedNumber); printf("CycleType: %u\n", ocycleNumber); if(!osimulate){ ofpga[MEM_REG] = SDRAM_BLOCKRAM;
ofpga[IMEM_REG] = brBase + BRAM_CYCLE_INFO; fpgaReadData64(0, ocycleInfoTable, sizeof(ocycleInfoTable));
ofpga[IMEM_REG] = brBase + BRAM_SWITCH_TABLE; fpgaReadData64(0, switchTable, sizeof(switchTable)); ofpga[IMEM_REG] = brBase + BRAM_PHASE_TABLE; fpgaReadData64(0, phaseTables, sizeof(phaseTables));
printf("CYCLE: 0x%x\n", ofpga[regBase + CYCLE]); printf("CONTROL: 0x%x\n", ofpga[regBase + CONTROL]);
printf("PLL_PHASEDELAY: %d\n", ofpga[regBase + PLL_PHASEDELAY]); printf("PLL_FREQUENCY: %d\n", ofpga[regBase + PLL_FREQUENCY]); printf("PLL_FREQDELAY: %d\n", ofpga[regBase + PLL_FREQDELAY]); printf("PLL_GAIN: %d\n", ofpga[regBase + PLL_GAIN]); printf("DDS_FREQ_MIN: %d\n", ofpga[regBase + DDS_FREQ_MIN]); printf("DDS_FREQ_MAX: %d\n", ofpga[regBase + DDS_FREQ_MAX]);
printf("CycleInformationTable:\n"); hd64(ocycleInfoTable, 4 * 16);
printf("SwitchTable:\n");
for(n = 0; n < 16; n++){
printf("%4.4x, ", switchTable[n]); } printf("\n"); printf("PhaseTables:\n"); for(s = 0; s < 14; s++){ for(n = 0; n < 16; n++){ printf("%2.2x,", phaseTables[s][n]); }
printf(" ...\n");
} } } BError Pupe::fpgaInit(){ BError err; ADMXRC2_STATUS status; BString s; double lclk = 50.0e6; double mclk = 125.0e6; dprintf(DBG_FPGA, "Pupe::fpgaInit\n"); s = config.findValue("FpgaLclk:"); if(s != "") lclk = atof(s) * 1e6; s = config.findValue("FpgaMclk:"); if(s != "") mclk = atof(s) * 1e6; nprintf("Pupe: Setting LClk: %f Mhz, MClk: %f MHz\n", lclk/1e6, mclk/1e6); // Open FPGA Card if((status = ADMXRC2_OpenCardByIndex(oboard, &ofpgaCard)) != ADMXRC2_SUCCESS){ err.set(Tms::ErrorFpga, getName() + ADMXRC2_GetStatusString(status)); return err; } if((status = ADMXRC2_GetCardInfo(ofpgaCard, &ocardInfo)) != ADMXRC2_SUCCESS){ err.set(Tms::ErrorFpga, getName() + ADMXRC2_GetStatusString(status)); return err; } if((status = ADMXRC2_SetClockRate(ofpgaCard, 0, lclk, NULL)) != ADMXRC2_SUCCESS){ err.set(Tms::ErrorFpga, getName() + ADMXRC2_GetStatusString(status)); return err; } if((status = ADMXRC2_SetClockRate(ofpgaCard, 1, mclk, NULL)) != ADMXRC2_SUCCESS){ err.set(Tms::ErrorFpga, getName() + ADMXRC2_GetStatusString(status)); return err; } if(err = fpgaLoad()) return err; return fpgaConfig(); } BError Pupe::fpgaLoad(){ BError err; ADMXRC2_STATUS status; ADMXRC2_SPACE_INFO spInfo; BString fileName = "/usr/tms/fpga/tms-fpga.bit"; BString s; uint32_t v; dprintf(DBG_FPGA, "Pupe::fpgaLoad\n"); s = config.findValue("FpgaFirmwareFile:"); if(s != "") fileName = s; // Load FPGA if(!access(fileName, R_OK)){ // Try to load file. #if LOAD_USE_DMA if((status = ADMXRC2_ConfigureFromFileDMA(ofpgaCard, fileName, ADMXRC2_DMACHAN_ANY, 0)) != ADMXRC2_SUCCESS){ #else if((status = ADMXRC2_ConfigureFromFile(ofpgaCard, fileName)) != ADMXRC2_SUCCESS){ #endif return err.set(Tms::ErrorFpga, getName() + "Fpga Error: " + "Configuring FPGA from File: " + ADMXRC2_GetStatusString(status)); } } else { return err.set(Tms::ErrorFpga, getName() + "Fpga Error: " + "File: " + fileName + " not found"); } if((status = ADMXRC2_GetSpaceInfo(ofpgaCard, 0, &spInfo)) != ADMXRC2_SUCCESS){ err.set(Tms::ErrorFpga, getName() + "Fpga Error: " + ADMXRC2_GetStatusString(status)); return err; } ofpga = (volatile uint32_t*)spInfo.VirtualBase; if((status = ADMXRC2_GetSpaceInfo(ofpgaCard, 1, &spInfo)) != ADMXRC2_SUCCESS){ err.set(Tms::ErrorFpga, getName() + "Fpga Error: " + ADMXRC2_GetStatusString(status)); return err; } ofpgaControl = (volatile uint32_t*)spInfo.VirtualBase; v = ofpga[FIRMWARE]; if(((v >> 24) & 0xFF) != 'C'){ err.set(ErrorFpga, getName() + "FPGA Firmware type incorrect"); } else { nprintf("Pupe: FpgaVersion: %d.%d.%d\n", ((v >> 16) & 0xFF), ((v >> 8) & 0xFF), (v & 0xFF)); } return err; } BError Pupe::fpgaInterruptLoop(){ BError err; uint i; while(1){ dprintf(DBG_INTERRUPT, "Pupe::fpgaInterruptLoop\n"); ADMXRC2_WaitForInterrupt(ofpgaCard, 0, 0, 0); pthread_testcancel(); dprintf(DBG_INTERRUPT, "Interrupt: %x !!\n", ofpga[ISR]); // Check for interrupts i = ofpga[ISR]; if(i & INT_PU0_ERROR) cycleError(0); if(i & INT_PU1_ERROR) cycleError(1); if(i & INT_PU2_ERROR) cycleError(2); if(i & INT_PU0_CYCLE_STOP) cycleStop(); if(i & INT_PU0_CYCLE_START) cycleStart(); if(i & ~(INT_PU0_CYCLE_START|INT_PU0_CYCLE_STOP|INT_PU0_ERROR|INT_PU1_ERROR|INT_PU2_ERROR)){ nprintf("Unknown interrupt: %x\n", i); } // Clear all interrupts ofpga[ISR] = 0xFFFFFFFF; ofpga[ISR] = 0x0; } return err; } void Pupe::fpgaTriggerTimingInputs(TimingSig input){ dprintf(DBG_FPGA, "Pupe::fpgaTriggerTimingInput: %d\n", input); if(ofpga){ dprintf(DBG_FPGA_TIMING, "Pupe::Trigger: %x PupeCycle: %u Ctime: %u\n", input, ofpga[PU0_REG_BASE + CYCLE], ofpga[PU0_REG_BASE + TIME]); ofpga[TIMING_IO] = ofpga[TIMING_IO] | (input & 0xFF); usleep(100); ofpga[TIMING_IO] = (ofpga[TIMING_IO] & ~0xFF); } if(input & 0x04) ocycleCount++; } BError Pupe::fpgaConfig(){ BError err; ADMXRC2_STATUS status; UInt32 n;
UInt32 stateTable[16];
int data; dprintf(DBG_FPGA, "Pupe::fpgaConfig:\n"); status = ADMXRC2_SetupDMA(ofpgaCard, odmaBuffer, odmaBufferSize, 0, &odmabuf); if(status != ADMXRC2_SUCCESS){ err.set(Tms::ErrorFpga, getName() + "Failed to set up DMA buffer"); return err; } #ifdef ZAP // Reset ADC PLL clock source ofpga[ADC] = 0x200 | 0x1FF; usleep(1000); ofpga[ADC] = 0x000 | 0x1FF; usleep(10000); #endif // Reset FPGA data = 1; ADMXRC2_Write(ofpgaCard, ADMXRC2_IOWIDTH_32, ADMXRC2_IOADAPTER, 0x28, &data, 4); usleep(10000); data = 0; ADMXRC2_Write(ofpgaCard, ADMXRC2_IOWIDTH_32, ADMXRC2_IOADAPTER, 0x28, &data, 4); usleep(100000); ofpga[ADC] = 0x1FF; // Set State tables so that all paths lead to cycle stop
for(n = 0; n < 16; n++){ stateTable[n] = 0xffffff00;
} ofpga[MEM_REG] = SDRAM_BLOCKRAM; ofpga[IMEM_REG] = PU0_REG_BASE + BRAM_SWITCH_TABLE; fpgaWriteData64(stateTable, 0, sizeof(stateTable)); ofpga[IMEM_REG] = PU1_REG_BASE + BRAM_SWITCH_TABLE; fpgaWriteData64(stateTable, 0, sizeof(stateTable)); ofpga[IMEM_REG] = PU2_REG_BASE + BRAM_SWITCH_TABLE; fpgaWriteData64(stateTable, 0, sizeof(stateTable)); // Reset PLL's ofpga[PU0_REG_BASE + CONTROL] = CONTROL_INIT; ofpga[PU1_REG_BASE + CONTROL] = CONTROL_INIT; ofpga[PU2_REG_BASE + CONTROL] = CONTROL_INIT; usleep(1000); ofpga[PU0_REG_BASE + CONTROL] = 0; ofpga[PU1_REG_BASE + CONTROL] = 0; ofpga[PU2_REG_BASE + CONTROL] = 0; if(opupeConfig.disableBlr){ wprintf("BLR is disabled\n"); ofpga[PU0_REG_BASE + CONTROL] = CONTROL_BLR_DISABLE; ofpga[PU1_REG_BASE + CONTROL] = CONTROL_BLR_DISABLE; ofpga[PU2_REG_BASE + CONTROL] = CONTROL_BLR_DISABLE; } // Setup Interrupt handler ointerruptThread.start();
#if DEBUG_DISABLE_ERROR_IRQ ofpga[IER] = INT_PU0_CYCLE_START | INT_PU0_CYCLE_STOP; #else
ofpga[IER] = INT_PU0_CYCLE_START | INT_PU0_CYCLE_STOP | INT_PU0_ERROR | INT_PU1_ERROR | INT_PU2_ERROR;
#endif
// Enable timing bus simulation if(opupeConfig.internalTimingMask){
ofpga[TIMING_IO] = TIMING_FREF | (opupeConfig.internalTimingMask << 8);
} else { ofpga[TIMING_IO] = 0x0000; } #if SYSCLK_INTERNAL ofpga[TIMING_IO] |= 0x0100; // Force internal SysClock printf("TIMING_IO: %x\n", ofpga[TIMING_IO]); printf("TEST: %x\n", ofpga[PU0_REG_BASE + TEST]); #endif dprintf(DBG_FPGA, "TIMING_IO: %x\n", ofpga[TIMING_IO]); ofpga[PU0_REG_BASE + CYCLE] = 0; ofpga[PU1_REG_BASE + CYCLE] = 0; ofpga[PU2_REG_BASE + CYCLE] = 0; #ifdef ZAP { uint8_t data[2*1024*1024]; uint32_t p = 0; printf("Clear memory\n"); memset(data, 0x55, sizeof(data)); ofpga[MEM_REG] = SDRAM_DATA_PU0; for(p = 0; p < 1; p++){ ofpga[ADDR_REG] = p << 19; fpgaWriteData64(data, 0, sizeof(data)); } ofpga[MEM_REG] = SDRAM_DATA_PU1; for(p = 0; p < 1; p++){ ofpga[ADDR_REG] = p << 19; fpgaWriteData64(data, 0, sizeof(data)); } ofpga[MEM_REG] = SDRAM_DATA_PU2; for(p = 0; p < 1; p++){ ofpga[ADDR_REG] = p << 19; fpgaWriteData64(data, 0, sizeof(data)); } printf("Clear memory: Done\n"); } #endif #ifdef ZAP { BArray<UInt32> data; BFile file; BString fileName = "../datasrc/beam3-437000-8.psd"; int nb; printf("Load Test Data\n"); if(err = file.open(fileName, "r")){ printf("Error: Opening file:\n"); } data.resize(1024); if((nb = file.read(&data[0], 1024 * sizeof(UInt32))) <= 0){ printf("Error: Reading file:\n"); } data.resize(nb / sizeof(UInt32)); olock.unlock(); setTestData(PuChannel(1,1,1), 1, data); olock.lock(); printf("Load Test Data: Done\n"); } #endif #ifdef ZAP dprintf(DBG_FPGA, "Pupe::fpgaConfig: DumpState\n"); dumpState(); #endif #ifdef ZAP BIter i; BList<NameValue> infoList; fpgaGetInfo(infoList); for(infoList.start(i); !infoList.isEnd(i); infoList.next(i)){ printf("%s: %s\n", infoList[i].name.retStr(), infoList[i].value.retStr()); } #endif dprintf(DBG_FPGA, "Pupe::fpgaConfig: End\n"); return err; } BError Pupe::fpgaReadData64(uint32_t fpgaOffset, void* toAddress, int nbytes){ BError err; ADMXRC2_STATUS status; uint32_t dmaMode; dprintf(DBG_FPGA, "Pupe::fpgaReadData64\n"); dmaMode = ADMXRC2_BuildDMAModeWord(ocardInfo.BoardType, ADMXRC2_IOWIDTH_64, 0, ADMXRC2_DMAMODE_USEREADY | ADMXRC2_DMAMODE_USEBTERM | ADMXRC2_DMAMODE_BURSTENABLE); dprintf(DBG_FPGA, "fpgaReadData64: Offset: 0x%x MEM_REG: 0x%x, ADDR_REG: 0x%x, MEM_RAO: 0x%x, MEM_RAS: 0x%x NBytes: %d\n", fpgaOffset, ofpga[MEM_REG], ofpga[ADDR_REG], ofpga[MEM_RAO], ofpga[MEM_RAS], nbytes); ocontrol.odmaLock.lock(); status = ADMXRC2_DoDMA(ofpgaCard, odmabuf, 0, nbytes, FPGA_DATA_ADDRESS + fpgaOffset, ADMXRC2_LOCALTOPCI, 0, dmaMode, 0, 0, 0); ocontrol.odmaLock.unlock(); memcpy(toAddress, odmaBuffer, nbytes); if(status){ err.set(ErrorFpga, getName() + "Fpga: DMA Error"); } return err; } BError Pupe::fpgaReadData32(uint32_t fpgaOffset, void* toAddress, int nbytes){ BError err; ADMXRC2_STATUS status; uint32_t dmaMode; dprintf(DBG_FPGA, "Pupe::fpgaReadData32\n"); dmaMode = ADMXRC2_BuildDMAModeWord(ocardInfo.BoardType, ADMXRC2_IOWIDTH_32, 0, ADMXRC2_DMAMODE_USEREADY | ADMXRC2_DMAMODE_USEBTERM | ADMXRC2_DMAMODE_BURSTENABLE); ocontrol.odmaLock.lock(); status = ADMXRC2_DoDMA(ofpgaCard, odmabuf, 0, nbytes, FPGA_DATA_ADDRESS + fpgaOffset, ADMXRC2_LOCALTOPCI, 0, dmaMode, 0, 0, 0); ocontrol.odmaLock.unlock(); memcpy(toAddress, odmaBuffer, nbytes); if(status){ err.set(ErrorFpga, getName() + "Fpga: DMA Error"); } return err; } BError Pupe::fpgaWriteData64(void* fromAddress, uint32_t fpgaOffset, int nbytes){ BError err; ADMXRC2_STATUS status; uint32_t dmaMode; dprintf(DBG_FPGA, "Pupe::fpgaWriteData64\n"); dmaMode = ADMXRC2_BuildDMAModeWord(ocardInfo.BoardType, ADMXRC2_IOWIDTH_64, 0, ADMXRC2_DMAMODE_USEREADY | ADMXRC2_DMAMODE_USEBTERM | ADMXRC2_DMAMODE_BURSTENABLE); memcpy(odmaBuffer, fromAddress, nbytes); ocontrol.odmaLock.lock(); status = ADMXRC2_DoDMA(ofpgaCard, odmabuf, 0, nbytes, FPGA_DATA_ADDRESS + fpgaOffset, ADMXRC2_PCITOLOCAL, 0, dmaMode, 0, 0, 0); ocontrol.odmaLock.unlock(); if(status){ err.set(ErrorFpga, getName() + "Fpga: DMA Error"); } return err; } BError Pupe::fpgaCopyData(int pupeChan, uint32_t address, uint32_t nsamples, Data& data){ BError err; uint32_t pageSize = 2*1024*1024; uint32_t dataTablePage; uint32_t dataTableOffset; uint32_t ncopy; uint32_t addressOut = 0; dprintf(DBG_FPGA, "Pupe::fpgaCopyData: %d\n", pupeChan); switch(pupeChan){ case 1: ofpga[MEM_REG] = SDRAM_DATA_PU0; break; case 2: ofpga[MEM_REG] = SDRAM_DATA_PU1; break; case 3: ofpga[MEM_REG] = SDRAM_DATA_PU2; break; default: return err.set(ErrorFpga, "Incorrect puChannel"); } while(nsamples){ dataTablePage = address >> 21; // 2MByte Region dataTableOffset = address & 0x001FFFFF; // Offset ncopy = nsamples * 8; if(ncopy > (pageSize - dataTableOffset)){ ncopy = pageSize - dataTableOffset; } ofpga[ADDR_REG] = dataTablePage << 19; #if DEBUG_DATA printf("MEM_RAO: %d MEM_RAS: %d\n", ofpga[MEM_RAO], ofpga[MEM_RAS]); printf("ReadData: Chan: %d Address: %x Page: %x Offset: %x NBytes: %d\n", pupeChan, address, dataTablePage, dataTableOffset, ncopy); #endif #if USE_DMA if(err = fpgaReadData64(dataTableOffset, &data.dataValues[addressOut], ncopy)){ ofpga[MEM_REG] = SDRAM_BLOCKRAM; return err; } #else uint64_t* dataTable = (uint64_t*)&ofpga[FPGA_MEM]; memcpy_64(&data.dataValues[addressOut], &dataTable[dataTableOffset/8], ncopy); #endif dataTableOffset = 0; address = sdramAddressByteAdd(address, ncopy); addressOut += (ncopy / 8); nsamples -= (ncopy / 8); } ofpga[MEM_REG] = SDRAM_BLOCKRAM; dprintf(DBG_FPGA, "Pupe::fpgaCopyData: End\n"); return err; } void Pupe::fpgaClose(){ dprintf(DBG_FPGA, "Pupe::fpgaClose\n"); if(ofpgaCard){ // Stop interrupt thread ointerruptThread.cancel(); ADMXRC2_CancelWaitForInterrupt(ofpgaCard); ointerruptThread.waitForCompletion(); // Disable interrupts ofpga[IER] = 0; // Release DMA if(odmabuf){ ADMXRC2_UnsetupDMA(ofpgaCard, odmabuf); odmabuf = 0; } ofpga = 0; // Close card ADMXRC2_CloseCard(ofpgaCard); } }
BError Pupe::fpgaShutdown(){ BError err; // Disable interrupts ofpga[IER] = 0; // Clear FPGA ADMXRC2_ConfigureFromBuffer(ofpgaCard, 0, 0); return err; }
BError Pupe::fpgaGetInfo(BList<NameValue>& infoList){ BError err; uint8_t* p; if(ofpgaControl){ ofpgaControl[SYSMON_CTL] = 0x042D0000; usleep(1000); if(ofpgaControl[SYSMON_CTL] & SYSMON_SMB_ERROR){ printf("\nSMB Serial Bus Error - Shadow Read Failed\n"); return err.set(ErrorFpga, getName() + "SMB Serial Bus Error - Shadow Read Failed"); } p = (uint8_t*)&ofpgaControl[SYSMON_BUF] + 0x20; infoList.append(NameValue("+1V2", p[8] * sysFactors[8])); infoList.append(NameValue("+1V5", p[1] * sysFactors[1])); infoList.append(NameValue("+1V8", p[9] * sysFactors[9])); infoList.append(NameValue("+2V5", p[0] * sysFactors[0])); infoList.append(NameValue("+3V3", p[2] * sysFactors[2])); infoList.append(NameValue("+5V", p[3] * sysFactors[3])); infoList.append(NameValue("Vio", p[4] * sysFactors[4])); infoList.append(NameValue("FPIO", p[5] * sysFactors[5])); infoList.append(NameValue("TempInternal", p[7] * sysFactors[7])); infoList.append(NameValue("TempFpga", p[6] * sysFactors[6])); } return err; }
BError Pupe::getTemperatures(double& tempInternal, double& tempFpga){ BError err; uint8_t* p; if(ofpgaControl){ ofpgaControl[SYSMON_CTL] = 0x042D0000; usleep(1000); if(ofpgaControl[SYSMON_CTL] & SYSMON_SMB_ERROR){ printf("\nSMB Serial Bus Error - Shadow Read Failed\n"); return err.set(ErrorFpga, getName() + "SMB Serial Bus Error - Shadow Read Failed"); } p = (uint8_t*)&ofpgaControl[SYSMON_BUF] + 0x20; tempInternal = p[7] * sysFactors[7]; tempFpga = p[6] * sysFactors[6]; } return err; }