S K UCI / Mbed 2 deprecated AutonomousDAQ

Arianna autonomous DAQ firmware

Dependencies:   mbed SDFileSystemFilinfo AriSnProtocol NetServicesMin AriSnComm MODSERIAL PowerControlClkPatch DS1820OW

SnConfigFrame.h@39:2f17131d22a5, 2013-07-30 (annotated)

Committer:
uci1
Date:
Tue Jul 30 02:03:21 2013 +0000
Revision:
39:2f17131d22a5
Parent:
31:b5bd3b189150
Child:
40:1324da35afd4
Temp commit so we can revert to other revisions. Changed some dynamic_casts to static_casts. Added NULL char to config label writing and updated io versions. Added battery hysteresis.

Who changed what in which revision?

UserRevisionLine numberNew contents of line
uci1 3:24c5f0f50bf1 1 #ifndef SN_SnConfigFrame
uci1 3:24c5f0f50bf1 2 #define SN_SnConfigFrame
uci1 3:24c5f0f50bf1 3
uci1 3:24c5f0f50bf1 4 #include <stdint.h>
uci1 3:24c5f0f50bf1 5 #include "SnConstants.h"
uci1 3:24c5f0f50bf1 6 #include "SnBitUtils.h"
uci1 3:24c5f0f50bf1 7
uci1 16:744ce85aede2 8 //#define DEBUG
uci1 16:744ce85aede2 9
uci1 3:24c5f0f50bf1 10 class SnConfigFrame {
uci1 3:24c5f0f50bf1 11 public:
uci1 31:b5bd3b189150 12 static bool fgApplySafetyNets; // whether to apply safety bounds on certain parameters in ReadFrom (default: true)
uci1 31:b5bd3b189150 13
uci1 3:24c5f0f50bf1 14 static const uint32_t kMinCommWinPrdLowPwr; // exclusive min low power comm win period (s)
uci1 3:24c5f0f50bf1 15 static const uint32_t kMaxCommWinPrdLowPwr; // exclusive max low power comm win period (s)
uci1 3:24c5f0f50bf1 16 static const uint32_t kMinCommWinDurLowPwr; // exclusive min low power comm win duration (s)
uci1 3:24c5f0f50bf1 17 static const uint32_t kMaxCommWinDurLowPwr; // exclusive max low power comm win duration (s)
uci1 3:24c5f0f50bf1 18 static const uint8_t kConfLblLen=64; // length of configuration label char array (63+'\0')
uci1 8:95a325df1f6b 19 static const uint8_t kIPLen=16; // length of IP string. matches MBED's Socket class (so no ipv6)
uci1 3:24c5f0f50bf1 20
uci1 3:24c5f0f50bf1 21 static const char* const kDefConfFile; // default configuration file
uci1 28:484943132bb0 22 static const char* const kDefIPflag; // flag to use IP default
uci1 3:24c5f0f50bf1 23
uci1 8:95a325df1f6b 24 static const uint32_t kMaxSizeOfV1 =
uci1 8:95a325df1f6b 25 + (9u*sizeof(uint32_t)) + (6u*sizeof(uint16_t))
uci1 8:95a325df1f6b 26 + (10u*sizeof(uint8_t)) + (3u*kNplas*sizeof(uint16_t))
uci1 3:24c5f0f50bf1 27 + (kTotDacs*sizeof(uint16_t))
uci1 3:24c5f0f50bf1 28 + (kConfLblLen*sizeof(uint8_t));
uci1 8:95a325df1f6b 29 static const uint32_t kMaxSizeOfV2 =
uci1 8:95a325df1f6b 30 kMaxSizeOfV1 + sizeof(uint32_t) + sizeof(uint8_t);
uci1 8:95a325df1f6b 31 static const uint32_t kMaxSizeOfV3 =
uci1 8:95a325df1f6b 32 kMaxSizeOfV2 + (2u*sizeof(uint16_t)) + (4u*kIPLen*sizeof(char));
uci1 18:55f1581f2ee4 33 static const uint32_t kMaxSizeOfV4 = kMaxSizeOfV3 + (sizeof(float)-sizeof(uint16_t));
uci1 39:2f17131d22a5 34 static const uint32_t kMaxSizeOfV5 = kMaxSizeOfV4;
uci1 39:2f17131d22a5 35 static const uint32_t kMaxSizeOfV6 = kMaxSizeOfV5 + sizeof(int16_t);
uci1 39:2f17131d22a5 36 static const uint32_t kMaxSizeOf = kMaxSizeOfV6;
uci1 3:24c5f0f50bf1 37
uci1 3:24c5f0f50bf1 38 enum EDatPackBit {
uci1 3:24c5f0f50bf1 39 kSDcard = BIT(0),
uci1 3:24c5f0f50bf1 40 kIrid = BIT(1),
uci1 3:24c5f0f50bf1 41 kAfar = BIT(2),
uci1 3:24c5f0f50bf1 42 kUSB = BIT(3)
uci1 3:24c5f0f50bf1 43 };
uci1 3:24c5f0f50bf1 44
uci1 3:24c5f0f50bf1 45 enum ESendDataBit {
uci1 3:24c5f0f50bf1 46 // can't use BIT(0)! (-0 = 0 => send nothing)
uci1 13:7a1fb885a8e4 47 kAllFiles = BIT(1), // if bit=0 => send most recent file
uci1 13:7a1fb885a8e4 48 kTimeout = BIT(2), // if bit=0 => ignore timeout
uci1 13:7a1fb885a8e4 49 kDelete = BIT(3), // if bit=0 => do not delete sent files
uci1 13:7a1fb885a8e4 50 kForceSBDdata = BIT(4), // if bit=0 => do not send data over SBD
uci1 39:2f17131d22a5 51 kUseBits = static_cast<int16_t>(-BIT(14)) // useful to initialize fCommSendData as a bit word
uci1 3:24c5f0f50bf1 52 };
uci1 3:24c5f0f50bf1 53
uci1 4:a91682e19d6b 54 enum EPowerModeBit {
uci1 4:a91682e19d6b 55 kAmpsDatTak = BIT(0),
uci1 4:a91682e19d6b 56 kCardDatTak = BIT(1),
uci1 4:a91682e19d6b 57 kIridDatTak = BIT(2),
uci1 4:a91682e19d6b 58 kAfarDatTak = BIT(3),
uci1 4:a91682e19d6b 59 kAmpsComWin = BIT(4),
uci1 4:a91682e19d6b 60 kCardComWin = BIT(5),
uci1 4:a91682e19d6b 61 kIridComWin = BIT(6),
uci1 4:a91682e19d6b 62 kAfarComWin = BIT(7)
uci1 4:a91682e19d6b 63 };
uci1 4:a91682e19d6b 64
uci1 3:24c5f0f50bf1 65 enum ERunMode {
uci1 8:95a325df1f6b 66 kSingleSeqBit = BIT(0), // if 0, infinite sequences
uci1 8:95a325df1f6b 67 kCountPowerBit = BIT(1), // if 0, count events
uci1 3:24c5f0f50bf1 68 };
uci1 3:24c5f0f50bf1 69
uci1 3:24c5f0f50bf1 70 // i/o version
uci1 3:24c5f0f50bf1 71 static const uint8_t kIOVers; // MUST BE INCREASED if any member var changes (==> also if kNchans, etc. change!)
uci1 3:24c5f0f50bf1 72
uci1 3:24c5f0f50bf1 73 private:
uci1 3:24c5f0f50bf1 74 // !!
uci1 3:24c5f0f50bf1 75 // !! If any member variables change, update: SizeOf function and kIOVers value! (also if kNchans, etc. change!)
uci1 3:24c5f0f50bf1 76 // !!
uci1 3:24c5f0f50bf1 77
uci1 3:24c5f0f50bf1 78 // mbed mac address
uci1 3:24c5f0f50bf1 79 static uint64_t fgMacAdr; // mbed mac address
uci1 3:24c5f0f50bf1 80 // conf header
uci1 3:24c5f0f50bf1 81 char fLabel[kConfLblLen]; // configuration label
uci1 3:24c5f0f50bf1 82 uint32_t fConfTime; // cpu config time
uci1 3:24c5f0f50bf1 83 uint32_t fRun; // run number
uci1 3:24c5f0f50bf1 84 uint32_t fFirstEvt; // starting event number
uci1 3:24c5f0f50bf1 85 uint32_t fEvtsPerSeq; // number of events per file
uci1 3:24c5f0f50bf1 86 uint8_t fRunMode; // mode of running (see ERunMode)
uci1 3:24c5f0f50bf1 87 uint8_t fStreamHiLoPlas; // (1byte bool) if true, add the separated hi/lo thresh PLA patterns to the i/o
uci1 3:24c5f0f50bf1 88 // data packing
uci1 3:24c5f0f50bf1 89 uint8_t fWvLoseLSB; // number of least significant bits to lose when packing waveform data
uci1 3:24c5f0f50bf1 90 uint8_t fWvLoseMSB; // number of most significant bits to lose when packing waveform data
uci1 3:24c5f0f50bf1 91 uint16_t fWvBaseline; // global baseline to use when packing data (useful to reduce clipping on the high end)
uci1 3:24c5f0f50bf1 92 uint8_t fDatPackType; // type of data packing. OR'd bitword: if bit 1, will pack for writing. see EDatPackBit. default: always pack (all 1's)
uci1 3:24c5f0f50bf1 93 // trigger setup
uci1 3:24c5f0f50bf1 94 uint16_t fDAC[kNchans][kNfpgaDacs]; //[card id][dac id] values should be 0-4095 here (not checked tho)
uci1 3:24c5f0f50bf1 95 uint8_t fNumPlas; // number of patterns to use. must be <= kNplas.
uci1 3:24c5f0f50bf1 96 uint16_t fPLA[kNplas]; //[pattern id] (same for each card)
uci1 3:24c5f0f50bf1 97 uint8_t fNumCardsMajLog; // number of cards participating in the MajLogic trigger (1 to 4)
uci1 3:24c5f0f50bf1 98 uint8_t fEnableThermTrig; // (1byte bool) whether or not to allow thermal triggers
uci1 18:55f1581f2ee4 99 float fForceTrigPeriod; // number of seconds between force triggers (0=none)
uci1 3:24c5f0f50bf1 100 uint16_t fHeartBeatPeriod; // number of seconds between heartbeats (0=none)
uci1 3:24c5f0f50bf1 101 uint8_t fAmpsOn; // which amps are on (bit word. uint8_t => 8 amps max)
uci1 3:24c5f0f50bf1 102 uint16_t fEvtThrtlPeriodMs; // throttle period to write events (ms)
uci1 3:24c5f0f50bf1 103 // power
uci1 4:a91682e19d6b 104 uint8_t fPowerMode; // power mode bit word: see EPowerModeBit
uci1 39:2f17131d22a5 105 //int16_t fBatVoltLowPwr; // battery level at which to switch to low power (not used?) deprecated for hysteresis
uci1 39:2f17131d22a5 106 int16_t fBatVoltToLowPwr; // battery level at which to switch to low power (not used?)
uci1 39:2f17131d22a5 107 int16_t fBatVoltFromLowPwr; // battery level at which to switch back from low power (not used?)
uci1 8:95a325df1f6b 108 uint16_t fVoltCheckPeriod; // how often to check the voltages (s)
uci1 3:24c5f0f50bf1 109 // communication
uci1 3:24c5f0f50bf1 110 uint32_t fCommWinPeriod; // seconds between communication window startup (0=always on)
uci1 3:24c5f0f50bf1 111 uint32_t fCommWinDuration; // seconds that communication window stays open (0=always open)
uci1 3:24c5f0f50bf1 112 int16_t fCommSendData; // data to send during comm win (=0: none, >0=send up to x events from last file until comm win closes, <0=see ESendDataBit)
uci1 3:24c5f0f50bf1 113 uint32_t fCommWinPrdLowPwr; // low power communication window period (seconds) (range enforced)
uci1 3:24c5f0f50bf1 114 uint32_t fCommWinDurLowPwr; // low power communication window duration (seconds) (range enforced)
uci1 8:95a325df1f6b 115 char fRemoteServer[kIPLen]; // IP address of remote server (for afar)
uci1 8:95a325df1f6b 116 uint16_t fRemotePort; // port number of remote server (for afar)
uci1 8:95a325df1f6b 117 char fMbedIP[kIPLen]; // IP address of this mbed
uci1 8:95a325df1f6b 118 char fMbedMask[kIPLen]; // IP address of this mbed mask
uci1 8:95a325df1f6b 119 char fMbedGate[kIPLen]; // IP address of this mbed gateway
uci1 3:24c5f0f50bf1 120 // watchdog
uci1 3:24c5f0f50bf1 121 uint32_t fWatchDogPeriod; // number of seconds of inactivity for watchdog to issue a reset
uci1 3:24c5f0f50bf1 122
uci1 8:95a325df1f6b 123 // in case of low power, store regular settings
uci1 8:95a325df1f6b 124 // these are not sent over i/o or stored in the file
uci1 8:95a325df1f6b 125 // so they are not included in SizeOf
uci1 8:95a325df1f6b 126 bool fIsLowPower;
uci1 8:95a325df1f6b 127 char fNormLabel[kConfLblLen];
uci1 8:95a325df1f6b 128 uint8_t fNormPowerMode;
uci1 8:95a325df1f6b 129
uci1 3:24c5f0f50bf1 130 void SetHardDefaults();
uci1 3:24c5f0f50bf1 131
uci1 3:24c5f0f50bf1 132 static
uci1 8:95a325df1f6b 133 uint32_t SizeOf(const uint8_t rv,
uci1 8:95a325df1f6b 134 const bool streamHiLoPlas,
uci1 3:24c5f0f50bf1 135 const uint8_t nplas,
uci1 3:24c5f0f50bf1 136 const uint8_t lblLen) {
uci1 3:24c5f0f50bf1 137 // private because it cannot be used to read from a buffer
uci1 3:24c5f0f50bf1 138 // (the label length and fStreamHiLoPlas are not known a priori)
uci1 3:24c5f0f50bf1 139 // returns the num of bytes needed to stream this object
uci1 3:24c5f0f50bf1 140 // = size of member vars + 1 for i/o version + extra PLA strings (maybe)
uci1 8:95a325df1f6b 141 uint32_t maxsize = kMaxSizeOf;
uci1 8:95a325df1f6b 142 if (rv==1) {
uci1 8:95a325df1f6b 143 maxsize = kMaxSizeOfV1;
uci1 8:95a325df1f6b 144 } else if (rv==2) {
uci1 8:95a325df1f6b 145 maxsize = kMaxSizeOfV2;
uci1 19:74155d652c37 146 } else if (rv==3) {
uci1 19:74155d652c37 147 maxsize = kMaxSizeOfV3;
uci1 39:2f17131d22a5 148 } else if (rv==4) {
uci1 39:2f17131d22a5 149 maxsize = kMaxSizeOfV4;
uci1 39:2f17131d22a5 150 } else if (rv==5) {
uci1 39:2f17131d22a5 151 maxsize = kMaxSizeOfV5;
uci1 39:2f17131d22a5 152 } else if (rv==6) {
uci1 39:2f17131d22a5 153 maxsize = kMaxSizeOfV6;
uci1 8:95a325df1f6b 154 }
uci1 39:2f17131d22a5 155 const int32_t lbldiff = kConfLblLen - lblLen;
uci1 39:2f17131d22a5 156 uint32_t sz = maxsize - lbldiff;
uci1 39:2f17131d22a5 157 if ((lbldiff!=0) && (rv>=4)) {
uci1 39:2f17131d22a5 158 sz += 1; // the \0 at the end of the string
uci1 39:2f17131d22a5 159 }
uci1 3:24c5f0f50bf1 160 static const uint32_t mhlp = 2u*kNplas*sizeof(uint16_t);
uci1 3:24c5f0f50bf1 161 const int32_t dp = (nplas-kNplas)*sizeof(uint16_t);
uci1 3:24c5f0f50bf1 162 const uint8_t fac = (streamHiLoPlas) ? 3u : 1u;
uci1 3:24c5f0f50bf1 163 sz += (fac*dp);
uci1 3:24c5f0f50bf1 164 if (streamHiLoPlas==false) {
uci1 3:24c5f0f50bf1 165 sz -= mhlp;
uci1 3:24c5f0f50bf1 166 }
uci1 3:24c5f0f50bf1 167 return sz;
uci1 3:24c5f0f50bf1 168 }
uci1 28:484943132bb0 169
uci1 28:484943132bb0 170 void SetDefaultIPs();
uci1 28:484943132bb0 171 void SetDefaultRemoteServ();
uci1 28:484943132bb0 172 void SetDefaultRemotePort();
uci1 28:484943132bb0 173 void SetDefaultMbedIP();
uci1 28:484943132bb0 174 void SetDefaultMaskIP();
uci1 28:484943132bb0 175 void SetDefaultGateIP();
uci1 28:484943132bb0 176 void ApplySafetyNets();
uci1 28:484943132bb0 177
uci1 3:24c5f0f50bf1 178 public:
uci1 31:b5bd3b189150 179 SnConfigFrame(const bool applySafety=true) : fIsLowPower(false) {
uci1 31:b5bd3b189150 180 fgApplySafetyNets = applySafety;
uci1 31:b5bd3b189150 181 Reset();
uci1 31:b5bd3b189150 182 }
uci1 3:24c5f0f50bf1 183 virtual ~SnConfigFrame() {}
uci1 3:24c5f0f50bf1 184
uci1 8:95a325df1f6b 185 bool IsCountingPowerReadings() const { return ((fRunMode & kCountPowerBit)!=0); }
uci1 8:95a325df1f6b 186 bool IsSingleSeqRunMode() const { return ((fRunMode & kSingleSeqBit)!=0); }
uci1 8:95a325df1f6b 187 bool IsLowPowerMode() const { return fIsLowPower; }
uci1 3:24c5f0f50bf1 188 const char* GetLabel() const { return fLabel; }
uci1 3:24c5f0f50bf1 189 uint32_t GetLabelStrLen() const { return strlen(fLabel); }
uci1 3:24c5f0f50bf1 190 uint32_t GetRun() const { return fRun; }
uci1 3:24c5f0f50bf1 191 uint32_t GetFirstEvt() const { return fFirstEvt; }
uci1 3:24c5f0f50bf1 192 uint32_t GetEvtsPerFile() const { return fEvtsPerSeq; }
uci1 3:24c5f0f50bf1 193 uint16_t GetEvtThrtlPeriodMs() const { return fEvtThrtlPeriodMs; }
uci1 18:55f1581f2ee4 194 float GetForceTrigPeriod() const { return fForceTrigPeriod; }
uci1 3:24c5f0f50bf1 195 uint16_t GetHeartbeatPeriod() const { return fHeartBeatPeriod; }
uci1 39:2f17131d22a5 196 uint16_t GetBatVoltToLowPwr() const { return fBatVoltToLowPwr; }
uci1 39:2f17131d22a5 197 uint16_t GetBatVoltFromLowPwr() const { return fBatVoltFromLowPwr; }
uci1 8:95a325df1f6b 198 uint16_t GetVoltCheckPeriod() const { return fVoltCheckPeriod; }
uci1 3:24c5f0f50bf1 199 uint32_t GetWatchdogPeriod() const { return fWatchDogPeriod; }
uci1 3:24c5f0f50bf1 200 uint16_t GetDac(const uint8_t ch, const uint8_t dn) const { return fDAC[ch][dn]; }
uci1 3:24c5f0f50bf1 201 uint8_t GetNumPlas() const { return fNumPlas; }
uci1 3:24c5f0f50bf1 202 uint16_t GetPla(const uint8_t pn) const { return fPLA[pn]; }
uci1 3:24c5f0f50bf1 203 uint8_t GetNumCardsMajLog() const { return fNumCardsMajLog; }
uci1 3:24c5f0f50bf1 204 bool IsThermTrigEnabled() const { return fEnableThermTrig!=0; }
uci1 3:24c5f0f50bf1 205 bool IsEachAmpOn() const {
uci1 3:24c5f0f50bf1 206 bool allon=true;
uci1 3:24c5f0f50bf1 207 for (uint8_t i=0; (i<kNchans) && allon; i++) {
uci1 3:24c5f0f50bf1 208 allon = (fAmpsOn & BIT(i))!=0;
uci1 3:24c5f0f50bf1 209 }
uci1 3:24c5f0f50bf1 210 return allon;
uci1 3:24c5f0f50bf1 211 }
uci1 3:24c5f0f50bf1 212 // TODO: allow check for individual amps, when they can be turned on individually
uci1 3:24c5f0f50bf1 213
uci1 8:95a325df1f6b 214 const char* GetRemoteServer() const { return fRemoteServer; }
uci1 8:95a325df1f6b 215 uint16_t GetRemotePort() const { return fRemotePort; }
uci1 8:95a325df1f6b 216 const char* GetMbedIP() const { return fMbedIP; }
uci1 8:95a325df1f6b 217 const char* GetMbedMask() const { return fMbedMask; }
uci1 8:95a325df1f6b 218 const char* GetMbedGate() const { return fMbedGate; }
uci1 8:95a325df1f6b 219 uint32_t GetCommWinPeriod() const { return fIsLowPower ? fCommWinPrdLowPwr : fCommWinPeriod; }
uci1 8:95a325df1f6b 220 uint32_t GetCommWinDuration() const { return fIsLowPower ? fCommWinDurLowPwr : fCommWinDuration; }
uci1 3:24c5f0f50bf1 221 int16_t GetCommSendData() const { return fCommSendData; }
uci1 3:24c5f0f50bf1 222
uci1 3:24c5f0f50bf1 223 bool IsSendingAllFiles() const
uci1 3:24c5f0f50bf1 224 { return (fCommSendData<0) && ((fCommSendData & kAllFiles)!=0); }
uci1 3:24c5f0f50bf1 225 bool IsObeyingTimeout() const
uci1 3:24c5f0f50bf1 226 { return (fCommSendData<0) && ((fCommSendData & kTimeout)!=0); }
uci1 3:24c5f0f50bf1 227 bool IsDeletingFiles() const
uci1 3:24c5f0f50bf1 228 { return (fCommSendData<0) && ((fCommSendData & kDelete)!=0); }
uci1 15:f2569d8e4176 229 bool IsForcingSBDdata() const
uci1 15:f2569d8e4176 230 { return (fCommSendData<0) && ((fCommSendData & kForceSBDdata)!=0); }
uci1 3:24c5f0f50bf1 231
uci1 4:a91682e19d6b 232 uint8_t GetPowerMode() const { return fPowerMode; }
uci1 30:f869ed4bcc08 233 int GetPowPinSetting(const EPowerModeBit p, const bool isOn) const {
uci1 5:9cea89700c66 234 if (p==kCardDatTak || p==kCardComWin ||
uci1 5:9cea89700c66 235 p==kAmpsDatTak || p==kAmpsComWin) {
uci1 30:f869ed4bcc08 236 return isOn ? 0 : 1;
uci1 5:9cea89700c66 237 } else {
uci1 30:f869ed4bcc08 238 return isOn ? 1 : 0;
uci1 5:9cea89700c66 239 }
uci1 5:9cea89700c66 240 }
uci1 30:f869ed4bcc08 241 int GetPowPinSetting(const EPowerModeBit p) const {
uci1 30:f869ed4bcc08 242 // return int to correspond to what DigitalOut::operator= expects
uci1 30:f869ed4bcc08 243 return GetPowPinSetting(p, IsPoweredFor(p));
uci1 30:f869ed4bcc08 244 }
uci1 8:95a325df1f6b 245 bool IsPoweredFor(const EPowerModeBit p) const {
uci1 8:95a325df1f6b 246 return ((fPowerMode & p)!=0);
uci1 8:95a325df1f6b 247 }
uci1 8:95a325df1f6b 248
uci1 8:95a325df1f6b 249 void EnablePowerFor(const EPowerModeBit p) { fPowerMode |= p; }
uci1 8:95a325df1f6b 250 void DisablePowerFor(const EPowerModeBit p) { fPowerMode &= ~p; }
uci1 8:95a325df1f6b 251
uci1 8:95a325df1f6b 252 void ChangeToLowPower();
uci1 8:95a325df1f6b 253 void ChangeToNormPower();
uci1 3:24c5f0f50bf1 254
uci1 3:24c5f0f50bf1 255 const char* GetOutFileName(const char* dir) const;
uci1 3:24c5f0f50bf1 256
uci1 21:ce51bb0ba4a5 257 uint32_t GetTimeoutTime(const uint32_t startTime,
uci1 21:ce51bb0ba4a5 258 const uint32_t delta) const;
uci1 21:ce51bb0ba4a5 259
uci1 21:ce51bb0ba4a5 260
uci1 3:24c5f0f50bf1 261 // waveform packing info
uci1 3:24c5f0f50bf1 262 uint16_t GetWvBaseline() const { return fWvBaseline; }
uci1 3:24c5f0f50bf1 263 uint8_t GetWvLoseLSB() const { return fWvLoseLSB; }
uci1 3:24c5f0f50bf1 264 uint8_t GetWvLoseMSB() const { return fWvLoseMSB; }
uci1 3:24c5f0f50bf1 265 bool IsDatPackedFor(const EDatPackBit d) const { return (fDatPackType & d)!=0; }
uci1 3:24c5f0f50bf1 266 void GetPackParsFor(const EDatPackBit d,
uci1 3:24c5f0f50bf1 267 uint8_t& loseLSB, uint8_t& loseMSB,
uci1 3:24c5f0f50bf1 268 uint16_t& wvBase) const;
uci1 3:24c5f0f50bf1 269
uci1 3:24c5f0f50bf1 270 // i/o
uci1 3:24c5f0f50bf1 271 template<class T>
uci1 3:24c5f0f50bf1 272 void ReadFrom(T& b) {
uci1 3:24c5f0f50bf1 273 // no check on the length of buf is done here
uci1 3:24c5f0f50bf1 274 // that should be been done already
uci1 3:24c5f0f50bf1 275 //
uci1 3:24c5f0f50bf1 276 // must match WriteTo
uci1 3:24c5f0f50bf1 277
uci1 3:24c5f0f50bf1 278 uint8_t Rv=0;
uci1 3:24c5f0f50bf1 279 b = SnBitUtils::ReadFrom(b, Rv); // i/o version
uci1 12:d472f9811262 280 #ifdef DEBUG
uci1 3:24c5f0f50bf1 281 printf("Rv=%hhu\r\n",Rv);
uci1 12:d472f9811262 282 #endif
uci1 3:24c5f0f50bf1 283 if (Rv>0) {
uci1 3:24c5f0f50bf1 284 uint32_t llen=kConfLblLen;
uci1 3:24c5f0f50bf1 285 b = SnBitUtils::ReadFrom(b, llen);
uci1 12:d472f9811262 286 #ifdef DEBUG
uci1 3:24c5f0f50bf1 287 printf("llen=%u\r\n",llen);
uci1 12:d472f9811262 288 #endif
uci1 3:24c5f0f50bf1 289 b = SnBitUtils::ReadFrom(b, fLabel, llen);
uci1 12:d472f9811262 290 #ifdef DEBUG
uci1 3:24c5f0f50bf1 291 printf("lbl=%s\r\n",fLabel);
uci1 12:d472f9811262 292 #endif
uci1 3:24c5f0f50bf1 293 b = SnBitUtils::ReadFrom(b, fConfTime);
uci1 12:d472f9811262 294 #ifdef DEBUG
uci1 3:24c5f0f50bf1 295 printf("ct=%u\r\n",fConfTime);
uci1 12:d472f9811262 296 #endif
uci1 3:24c5f0f50bf1 297 b = SnBitUtils::ReadFrom(b, fRun);
uci1 12:d472f9811262 298 #ifdef DEBUG
uci1 3:24c5f0f50bf1 299 printf("run=%u\r\n",fRun);
uci1 12:d472f9811262 300 #endif
uci1 3:24c5f0f50bf1 301 b = SnBitUtils::ReadFrom(b, fFirstEvt);
uci1 12:d472f9811262 302 #ifdef DEBUG
uci1 3:24c5f0f50bf1 303 printf("fe=%u\r\n",fFirstEvt);
uci1 12:d472f9811262 304 #endif
uci1 3:24c5f0f50bf1 305 if (Rv>1) {
uci1 3:24c5f0f50bf1 306 b = SnBitUtils::ReadFrom(b, fEvtsPerSeq);
uci1 12:d472f9811262 307 #ifdef DEBUG
uci1 3:24c5f0f50bf1 308 printf("eps=%u\r\n",fEvtsPerSeq);
uci1 12:d472f9811262 309 #endif
uci1 3:24c5f0f50bf1 310 b = SnBitUtils::ReadFrom(b, fRunMode);
uci1 12:d472f9811262 311 #ifdef DEBUG
uci1 3:24c5f0f50bf1 312 printf("rm=%hhu\r\n",fRunMode);
uci1 12:d472f9811262 313 #endif
uci1 3:24c5f0f50bf1 314 }
uci1 3:24c5f0f50bf1 315 b = SnBitUtils::ReadFrom(b, fStreamHiLoPlas);
uci1 12:d472f9811262 316 #ifdef DEBUG
uci1 3:24c5f0f50bf1 317 printf("shilo=%d\r\n",(int)fStreamHiLoPlas);
uci1 12:d472f9811262 318 #endif
uci1 3:24c5f0f50bf1 319 b = SnBitUtils::ReadFrom(b, fWvLoseLSB);
uci1 12:d472f9811262 320 #ifdef DEBUG
uci1 3:24c5f0f50bf1 321 printf("lsb=%hhu\r\n",fWvLoseLSB);
uci1 12:d472f9811262 322 #endif
uci1 3:24c5f0f50bf1 323 b = SnBitUtils::ReadFrom(b, fWvLoseMSB);
uci1 12:d472f9811262 324 #ifdef DEBUG
uci1 3:24c5f0f50bf1 325 printf("msb=%hhu\r\n",fWvLoseMSB);
uci1 12:d472f9811262 326 #endif
uci1 3:24c5f0f50bf1 327 b = SnBitUtils::ReadFrom(b, fWvBaseline);
uci1 12:d472f9811262 328 #ifdef DEBUG
uci1 3:24c5f0f50bf1 329 printf("bl=%hu\r\n",fWvBaseline);
uci1 12:d472f9811262 330 #endif
uci1 3:24c5f0f50bf1 331 b = SnBitUtils::ReadFrom(b, fDatPackType);
uci1 12:d472f9811262 332 #ifdef DEBUG
uci1 3:24c5f0f50bf1 333 printf("dp=%hhu\r\n",fDatPackType);
uci1 12:d472f9811262 334 #endif
uci1 3:24c5f0f50bf1 335 uint16_t* dc = &(fDAC[0][0]);
uci1 3:24c5f0f50bf1 336 for (uint16_t i=0; i<kTotDacs; i++, dc++) {
uci1 3:24c5f0f50bf1 337 b = SnBitUtils::ReadFrom(b, *dc);
uci1 12:d472f9811262 338 #ifdef DEBUG
uci1 3:24c5f0f50bf1 339 printf("dac[%hu]=%hu\r\n",i,*dc);
uci1 12:d472f9811262 340 #endif
uci1 3:24c5f0f50bf1 341 }
uci1 3:24c5f0f50bf1 342 b = SnBitUtils::ReadFrom(b, fNumPlas);
uci1 12:d472f9811262 343 #ifdef DEBUG
uci1 3:24c5f0f50bf1 344 printf("npla=%hhu\r\n",fNumPlas);
uci1 12:d472f9811262 345 #endif
uci1 3:24c5f0f50bf1 346 uint16_t* pl = &(fPLA[0]);
uci1 3:24c5f0f50bf1 347 for (uint8_t j=0; j<fNumPlas; j++, pl++) {
uci1 3:24c5f0f50bf1 348 b = SnBitUtils::ReadFrom(b, *pl);
uci1 12:d472f9811262 349 #ifdef DEBUG
uci1 3:24c5f0f50bf1 350 printf("pla[%hhu]=%hu\r\n",j,*pl);
uci1 12:d472f9811262 351 #endif
uci1 3:24c5f0f50bf1 352 }
uci1 3:24c5f0f50bf1 353 b = SnBitUtils::ReadFrom(b, fNumCardsMajLog);
uci1 12:d472f9811262 354 #ifdef DEBUG
uci1 3:24c5f0f50bf1 355 printf("mj=%hhu\r\n",fNumCardsMajLog);
uci1 12:d472f9811262 356 #endif
uci1 3:24c5f0f50bf1 357 b = SnBitUtils::ReadFrom(b, fEnableThermTrig);
uci1 12:d472f9811262 358 #ifdef DEBUG
uci1 3:24c5f0f50bf1 359 printf("thm=%d\r\n",(int)fEnableThermTrig);
uci1 12:d472f9811262 360 #endif
uci1 18:55f1581f2ee4 361 if (Rv>3) {
uci1 18:55f1581f2ee4 362 b = SnBitUtils::ReadFrom(b, fForceTrigPeriod);
uci1 18:55f1581f2ee4 363 } else {
uci1 18:55f1581f2ee4 364 uint16_t ftrg(0);
uci1 18:55f1581f2ee4 365 b = SnBitUtils::ReadFrom(b, ftrg);
uci1 18:55f1581f2ee4 366 fForceTrigPeriod = ftrg;
uci1 18:55f1581f2ee4 367 }
uci1 12:d472f9811262 368 #ifdef DEBUG
uci1 18:55f1581f2ee4 369 printf("force=%g\r\n",fForceTrigPeriod);
uci1 12:d472f9811262 370 #endif
uci1 3:24c5f0f50bf1 371 b = SnBitUtils::ReadFrom(b, fHeartBeatPeriod);
uci1 12:d472f9811262 372 #ifdef DEBUG
uci1 3:24c5f0f50bf1 373 printf("heart=%hu\r\n",fHeartBeatPeriod);
uci1 12:d472f9811262 374 #endif
uci1 3:24c5f0f50bf1 375 b = SnBitUtils::ReadFrom(b, fAmpsOn);
uci1 12:d472f9811262 376 #ifdef DEBUG
uci1 3:24c5f0f50bf1 377 printf("amps=%hhu\r\n",fAmpsOn);
uci1 12:d472f9811262 378 #endif
uci1 3:24c5f0f50bf1 379 b = SnBitUtils::ReadFrom(b, fEvtThrtlPeriodMs);
uci1 12:d472f9811262 380 #ifdef DEBUG
uci1 3:24c5f0f50bf1 381 printf("throt=%hu\r\n",fEvtThrtlPeriodMs);
uci1 12:d472f9811262 382 #endif
uci1 3:24c5f0f50bf1 383 b = SnBitUtils::ReadFrom(b, fPowerMode);
uci1 12:d472f9811262 384 #ifdef DEBUG
uci1 3:24c5f0f50bf1 385 printf("pow=%hhu\r\n",fPowerMode);
uci1 12:d472f9811262 386 #endif
uci1 39:2f17131d22a5 387 if (Rv<6) {
uci1 39:2f17131d22a5 388 b = SnBitUtils::ReadFrom(b, fBatVoltToLowPwr);
uci1 12:d472f9811262 389 #ifdef DEBUG
uci1 39:2f17131d22a5 390 printf("batlow=%hd\r\n",fBatVoltToLowPwr);
uci1 39:2f17131d22a5 391 #endif
uci1 39:2f17131d22a5 392 } else {
uci1 39:2f17131d22a5 393 b = SnBitUtils::ReadFrom(b, fBatVoltToLowPwr);
uci1 39:2f17131d22a5 394 b = SnBitUtils::ReadFrom(b, fBatVoltFromLowPwr);
uci1 39:2f17131d22a5 395 }
uci1 39:2f17131d22a5 396 #ifdef DEBUG
uci1 39:2f17131d22a5 397 printf("batlow(to,from)=(%hd,%hd)\r\n",fBatVoltToLowPwr,fBatVoltFromLowPwr);
uci1 12:d472f9811262 398 #endif
uci1 8:95a325df1f6b 399 if (Rv>2) {
uci1 8:95a325df1f6b 400 b = SnBitUtils::ReadFrom(b, fVoltCheckPeriod);
uci1 12:d472f9811262 401 #ifdef DEBUG
uci1 8:95a325df1f6b 402 printf("vltchk=%hu\r\n",fVoltCheckPeriod);
uci1 12:d472f9811262 403 #endif
uci1 8:95a325df1f6b 404 }
uci1 3:24c5f0f50bf1 405 b = SnBitUtils::ReadFrom(b, fCommWinPeriod);
uci1 12:d472f9811262 406 #ifdef DEBUG
uci1 3:24c5f0f50bf1 407 printf("cmper=%u\r\n",fCommWinPeriod);
uci1 12:d472f9811262 408 #endif
uci1 3:24c5f0f50bf1 409 b = SnBitUtils::ReadFrom(b, fCommWinDuration);
uci1 12:d472f9811262 410 #ifdef DEBUG
uci1 3:24c5f0f50bf1 411 printf("cmdur=%u\r\n",fCommWinDuration);
uci1 12:d472f9811262 412 #endif
uci1 3:24c5f0f50bf1 413 b = SnBitUtils::ReadFrom(b, fCommSendData);
uci1 12:d472f9811262 414 #ifdef DEBUG
uci1 3:24c5f0f50bf1 415 printf("send=%d\r\n",fCommSendData);
uci1 12:d472f9811262 416 #endif
uci1 3:24c5f0f50bf1 417 b = SnBitUtils::ReadFrom(b, fCommWinPrdLowPwr);
uci1 12:d472f9811262 418 #ifdef DEBUG
uci1 3:24c5f0f50bf1 419 printf("cmperlp=%u\r\n",fCommWinPrdLowPwr);
uci1 12:d472f9811262 420 #endif
uci1 3:24c5f0f50bf1 421 b = SnBitUtils::ReadFrom(b, fCommWinDurLowPwr);
uci1 12:d472f9811262 422 #ifdef DEBUG
uci1 3:24c5f0f50bf1 423 printf("cmdurlp=%u\r\n",fCommWinDurLowPwr);
uci1 12:d472f9811262 424 #endif
uci1 8:95a325df1f6b 425 if (Rv>2) {
uci1 8:95a325df1f6b 426 b = SnBitUtils::ReadFrom(b, fRemoteServer, kIPLen);
uci1 28:484943132bb0 427 if (strncmp(fRemoteServer, kDefIPflag,kIPLen)==0) {
uci1 28:484943132bb0 428 SetDefaultRemoteServ();
uci1 28:484943132bb0 429 }
uci1 12:d472f9811262 430 #ifdef DEBUG
uci1 8:95a325df1f6b 431 printf("rserv=%s\r\n",fRemoteServer);
uci1 12:d472f9811262 432 #endif
uci1 8:95a325df1f6b 433 b = SnBitUtils::ReadFrom(b, fRemotePort);
uci1 28:484943132bb0 434 if (fRemotePort==0) {
uci1 28:484943132bb0 435 SetDefaultRemotePort();
uci1 28:484943132bb0 436 }
uci1 12:d472f9811262 437 #ifdef DEBUG
uci1 8:95a325df1f6b 438 printf("rport=%hu\r\n",fRemotePort);
uci1 12:d472f9811262 439 #endif
uci1 8:95a325df1f6b 440 b = SnBitUtils::ReadFrom(b, fMbedIP, kIPLen);
uci1 28:484943132bb0 441 if (strncmp(fMbedIP, kDefIPflag,kIPLen)==0) {
uci1 28:484943132bb0 442 SetDefaultMbedIP();
uci1 28:484943132bb0 443 }
uci1 12:d472f9811262 444 #ifdef DEBUG
uci1 8:95a325df1f6b 445 printf("mbedip=%s\r\n",fMbedIP);
uci1 12:d472f9811262 446 #endif
uci1 8:95a325df1f6b 447 b = SnBitUtils::ReadFrom(b, fMbedMask, kIPLen);
uci1 28:484943132bb0 448 if (strncmp(fMbedMask, kDefIPflag,kIPLen)==0) {
uci1 28:484943132bb0 449 SetDefaultMaskIP();
uci1 28:484943132bb0 450 }
uci1 12:d472f9811262 451 #ifdef DEBUG
uci1 8:95a325df1f6b 452 printf("mbedmask=%s\r\n",fMbedMask);
uci1 12:d472f9811262 453 #endif
uci1 8:95a325df1f6b 454 b = SnBitUtils::ReadFrom(b, fMbedGate, kIPLen);
uci1 28:484943132bb0 455 if (strncmp(fMbedGate, kDefIPflag,kIPLen)==0) {
uci1 28:484943132bb0 456 SetDefaultGateIP();
uci1 28:484943132bb0 457 }
uci1 12:d472f9811262 458 #ifdef DEBUG
uci1 8:95a325df1f6b 459 printf("mbedgate=%s\r\n",fMbedGate);
uci1 12:d472f9811262 460 #endif
uci1 8:95a325df1f6b 461 }
uci1 3:24c5f0f50bf1 462 b = SnBitUtils::ReadFrom(b, fWatchDogPeriod);
uci1 12:d472f9811262 463 #ifdef DEBUG
uci1 3:24c5f0f50bf1 464 printf("watch=%u\r\n",fWatchDogPeriod);
uci1 12:d472f9811262 465 #endif
uci1 3:24c5f0f50bf1 466 if (fStreamHiLoPlas!=0) {
uci1 3:24c5f0f50bf1 467 uint16_t hi, lo;
uci1 3:24c5f0f50bf1 468 for (uint8_t j=0; j<fNumPlas; j++) {
uci1 3:24c5f0f50bf1 469 b = SnBitUtils::ReadFrom(b, hi);
uci1 12:d472f9811262 470 #ifdef DEBUG
uci1 3:24c5f0f50bf1 471 printf("hi=%hu\r\n",hi);
uci1 12:d472f9811262 472 #endif
uci1 3:24c5f0f50bf1 473 b = SnBitUtils::ReadFrom(b, lo);
uci1 12:d472f9811262 474 #ifdef DEBUG
uci1 3:24c5f0f50bf1 475 printf("lo=%hu\r\n",lo);
uci1 12:d472f9811262 476 #endif
uci1 3:24c5f0f50bf1 477 // don't save these
uci1 3:24c5f0f50bf1 478 }
uci1 3:24c5f0f50bf1 479 }
uci1 3:24c5f0f50bf1 480 }
uci1 28:484943132bb0 481
uci1 31:b5bd3b189150 482 if (fgApplySafetyNets) {
uci1 31:b5bd3b189150 483 ApplySafetyNets();
uci1 31:b5bd3b189150 484 }
uci1 28:484943132bb0 485
uci1 12:d472f9811262 486 #ifdef DEBUG
uci1 3:24c5f0f50bf1 487 printf("read from done\r\n");
uci1 12:d472f9811262 488 #endif
uci1 3:24c5f0f50bf1 489 }
uci1 3:24c5f0f50bf1 490
uci1 3:24c5f0f50bf1 491 template <class T>
uci1 3:24c5f0f50bf1 492 void WriteTo(T& b) const {
uci1 3:24c5f0f50bf1 493 // no check on the length of the buf is done here
uci1 3:24c5f0f50bf1 494 // that should be done already
uci1 3:24c5f0f50bf1 495 //
uci1 3:24c5f0f50bf1 496 // must match ReadFromBuf
uci1 3:24c5f0f50bf1 497 //
uci1 3:24c5f0f50bf1 498 // intentionally not writing mac address here, so we don't have to read it in
uci1 3:24c5f0f50bf1 499
uci1 3:24c5f0f50bf1 500 const uint32_t llen = strlen(fLabel);
uci1 3:24c5f0f50bf1 501 b = SnBitUtils::WriteTo(b, kIOVers); // i/o version
uci1 3:24c5f0f50bf1 502 b = SnBitUtils::WriteTo(b, llen);
uci1 3:24c5f0f50bf1 503 b = SnBitUtils::WriteTo(b, fLabel, llen);
uci1 39:2f17131d22a5 504 b = SnBitUtils::WriteTo(b, char('\0'));
uci1 3:24c5f0f50bf1 505 b = SnBitUtils::WriteTo(b, fConfTime);
uci1 3:24c5f0f50bf1 506 b = SnBitUtils::WriteTo(b, fRun);
uci1 3:24c5f0f50bf1 507 b = SnBitUtils::WriteTo(b, fFirstEvt);
uci1 3:24c5f0f50bf1 508 b = SnBitUtils::WriteTo(b, fEvtsPerSeq);
uci1 3:24c5f0f50bf1 509 b = SnBitUtils::WriteTo(b, fRunMode);
uci1 3:24c5f0f50bf1 510 b = SnBitUtils::WriteTo(b, fStreamHiLoPlas);
uci1 3:24c5f0f50bf1 511 b = SnBitUtils::WriteTo(b, fWvLoseLSB);
uci1 3:24c5f0f50bf1 512 b = SnBitUtils::WriteTo(b, fWvLoseMSB);
uci1 3:24c5f0f50bf1 513 b = SnBitUtils::WriteTo(b, fWvBaseline);
uci1 3:24c5f0f50bf1 514 b = SnBitUtils::WriteTo(b, fDatPackType);
uci1 3:24c5f0f50bf1 515 const uint16_t* dc = &(fDAC[0][0]);
uci1 3:24c5f0f50bf1 516 for (uint16_t i=0; i<kTotDacs; i++, dc++) {
uci1 3:24c5f0f50bf1 517 b = SnBitUtils::WriteTo(b, *dc);
uci1 3:24c5f0f50bf1 518 }
uci1 3:24c5f0f50bf1 519 b = SnBitUtils::WriteTo(b, fNumPlas);
uci1 3:24c5f0f50bf1 520 const uint16_t* pl = &(fPLA[0]);
uci1 3:24c5f0f50bf1 521 for (uint8_t j=0; j<fNumPlas; j++, pl++) {
uci1 3:24c5f0f50bf1 522 b = SnBitUtils::WriteTo(b, *pl);
uci1 3:24c5f0f50bf1 523 }
uci1 3:24c5f0f50bf1 524 b = SnBitUtils::WriteTo(b, fNumCardsMajLog);
uci1 3:24c5f0f50bf1 525 b = SnBitUtils::WriteTo(b, fEnableThermTrig);
uci1 3:24c5f0f50bf1 526 b = SnBitUtils::WriteTo(b, fForceTrigPeriod);
uci1 3:24c5f0f50bf1 527 b = SnBitUtils::WriteTo(b, fHeartBeatPeriod);
uci1 3:24c5f0f50bf1 528 b = SnBitUtils::WriteTo(b, fAmpsOn);
uci1 3:24c5f0f50bf1 529 b = SnBitUtils::WriteTo(b, fEvtThrtlPeriodMs);
uci1 3:24c5f0f50bf1 530 b = SnBitUtils::WriteTo(b, fPowerMode);
uci1 39:2f17131d22a5 531 b = SnBitUtils::WriteTo(b, fBatVoltToLowPwr);
uci1 39:2f17131d22a5 532 b = SnBitUtils::WriteTo(b, fBatVoltFromLowPwr);
uci1 8:95a325df1f6b 533 b = SnBitUtils::WriteTo(b, fVoltCheckPeriod);
uci1 3:24c5f0f50bf1 534 b = SnBitUtils::WriteTo(b, fCommWinPeriod);
uci1 3:24c5f0f50bf1 535 b = SnBitUtils::WriteTo(b, fCommWinDuration);
uci1 3:24c5f0f50bf1 536 b = SnBitUtils::WriteTo(b, fCommSendData);
uci1 3:24c5f0f50bf1 537 b = SnBitUtils::WriteTo(b, fCommWinPrdLowPwr);
uci1 3:24c5f0f50bf1 538 b = SnBitUtils::WriteTo(b, fCommWinDurLowPwr);
uci1 8:95a325df1f6b 539 b = SnBitUtils::WriteTo(b, fRemoteServer, kIPLen);
uci1 8:95a325df1f6b 540 b = SnBitUtils::WriteTo(b, fRemotePort);
uci1 8:95a325df1f6b 541 b = SnBitUtils::WriteTo(b, fMbedIP, kIPLen);
uci1 8:95a325df1f6b 542 b = SnBitUtils::WriteTo(b, fMbedMask, kIPLen);
uci1 8:95a325df1f6b 543 b = SnBitUtils::WriteTo(b, fMbedGate, kIPLen);
uci1 3:24c5f0f50bf1 544 b = SnBitUtils::WriteTo(b, fWatchDogPeriod);
uci1 3:24c5f0f50bf1 545 if (fStreamHiLoPlas!=0) {
uci1 3:24c5f0f50bf1 546 pl = fPLA;
uci1 3:24c5f0f50bf1 547 uint16_t hi, lo;
uci1 3:24c5f0f50bf1 548 for (uint8_t j=0; j<fNumPlas; j++, pl++) {
uci1 3:24c5f0f50bf1 549 GetHiLoPlas(*pl, hi, lo);
uci1 3:24c5f0f50bf1 550 b = SnBitUtils::WriteTo(b, hi);
uci1 3:24c5f0f50bf1 551 b = SnBitUtils::WriteTo(b, lo);
uci1 3:24c5f0f50bf1 552 }
uci1 3:24c5f0f50bf1 553 }
uci1 3:24c5f0f50bf1 554 }
uci1 3:24c5f0f50bf1 555
uci1 3:24c5f0f50bf1 556 bool ReadFromFile(const char* cfile);
uci1 3:24c5f0f50bf1 557 bool WriteToFile(const char* cfile) const;
uci1 3:24c5f0f50bf1 558
uci1 3:24c5f0f50bf1 559 void Reset() {
uci1 3:24c5f0f50bf1 560 memset(fLabel, 0, sizeof(char)*kConfLblLen);
uci1 3:24c5f0f50bf1 561 if (ReadFromFile(kDefConfFile)==false) {
uci1 3:24c5f0f50bf1 562 // couldn't get default. use hardcoded version.
uci1 3:24c5f0f50bf1 563 SetHardDefaults();
uci1 3:24c5f0f50bf1 564 }
uci1 16:744ce85aede2 565 #ifdef DEBUG
uci1 16:744ce85aede2 566 printf("config reset to %s\r\n",fLabel);
uci1 16:744ce85aede2 567 #endif
uci1 3:24c5f0f50bf1 568 }
uci1 3:24c5f0f50bf1 569
uci1 8:95a325df1f6b 570 uint32_t SizeOf(const uint8_t rv) const {
uci1 3:24c5f0f50bf1 571 // returns the num of bytes needed to stream this object
uci1 3:24c5f0f50bf1 572 // = size of member vars + 1 for i/o version + extra PLA strings (maybe)
uci1 3:24c5f0f50bf1 573 // + length of label string
uci1 8:95a325df1f6b 574 return SizeOf(rv, fStreamHiLoPlas!=0, fNumPlas, strlen(fLabel));
uci1 3:24c5f0f50bf1 575 }
uci1 3:24c5f0f50bf1 576
uci1 3:24c5f0f50bf1 577 static void SetMacAddress();
uci1 3:24c5f0f50bf1 578 static uint64_t GetMacAddress() {
uci1 3:24c5f0f50bf1 579 if (fgMacAdr==0) {
uci1 3:24c5f0f50bf1 580 SetMacAddress();
uci1 3:24c5f0f50bf1 581 }
uci1 3:24c5f0f50bf1 582 return fgMacAdr;
uci1 3:24c5f0f50bf1 583 }
uci1 3:24c5f0f50bf1 584
uci1 3:24c5f0f50bf1 585 static uint32_t GetLabelMaxLen() { return kConfLblLen; }
uci1 3:24c5f0f50bf1 586
uci1 3:24c5f0f50bf1 587 static void GetHiLoPlas(const uint16_t pla,
uci1 3:24c5f0f50bf1 588 uint16_t& hiPla,
uci1 3:24c5f0f50bf1 589 uint16_t& loPla,
uci1 3:24c5f0f50bf1 590 const bool r2l=false);
uci1 3:24c5f0f50bf1 591 };
uci1 3:24c5f0f50bf1 592
uci1 3:24c5f0f50bf1 593 #endif // SN_SnConfigFrame