MEASURE_IDLE_INPUTPOWER, MEASURE_RUNNING_INPUTPOWER,
IF_MEASURE_IDLE_WAS_NOT_OK_GOTO, IF_INPUTPOWER_DELTA_GOTO,
UPDATE_CURRENT_ROTORPARAMS, INVALIDATE_CURRENT_ROTORPARMS,
- IF_ROTORPOS_VALID_GOTO
+ UPDATE_CURRENT_SWITCHPARMS, INVALIDATE_CURRENT_SWITCHPARMS,
+ IF_ROTORPOS_VALID_GOTO,
+ IF_TUNER_LOCKED_GOTO,
+ IF_TONE_GOTO, IF_NOT_TONE_GOTO,
+ START_TUNE_TIMEOUT,
+ SET_ROTOR_MOVING,
+ SET_ROTOR_STOPPED
};
int cmd;
struct rotor
{
- int deltaA; // difference in mA between running and stopped rotor
+ union {
+ int deltaA; // difference in mA between running and stopped rotor
+ int lastSignal;
+ };
int okcount; // counter
int steps; // goto steps
int direction;
};
struct pair
{
- int voltage;
+ union
+ {
+ int voltage;
+ int tone;
+ int val;
+ };
int steps;
};
union
#endif
public:
enum t_22khz_signal { HILO=0, ON=1, OFF=2 }; // 22 Khz
- enum t_voltage_mode { HV=0, _14V=1, _18V=2, _0V=3 }; // 14/18 V
+ enum t_voltage_mode { HV=0, _14V=1, _18V=2, _0V=3, HV_13=4 }; // 14/18 V
#ifndef SWIG
t_voltage_mode m_voltage_mode;
t_22khz_signal m_22khz_signal;
#endif
public:
enum { NORTH, SOUTH, EAST, WEST };
+ enum { FAST, SLOW };
#ifndef SWIG
eDVBSatelliteRotorParameters() { setDefaultOptions(); }
{
bool m_use; // can we use rotor inputpower to detect rotor running state ?
__u8 m_delta; // delta between running and stopped rotor
+ unsigned int m_turning_speed; // SLOW, FAST, or fast turning epoch
};
eDVBSatelliteRotorInputpowerParameters m_inputpower_parameters;
void setDefaultOptions() // set default rotor options
{
+ m_inputpower_parameters.m_turning_speed = FAST; // fast turning
m_inputpower_parameters.m_use = true;
m_inputpower_parameters.m_delta = 60;
m_gotoxx_parameters.m_lo_direction = EAST;
#ifndef SWIG
t_12V_relais_state m_12V_relais_state; // 12V relais output on/off
- __u8 tuner_mask; // useable by tuner ( 1 | 2 | 4...)
+ int m_slot_mask; // useable by slot ( 1 | 2 | 4...)
unsigned int m_lof_hi, // for 2 band universal lnb 10600 Mhz (high band offset frequency)
m_lof_lo, // for 2 band universal lnb 9750 Mhz (low band offset frequency)
std::map<int, eDVBSatelliteSwitchParameters> m_satellites;
eDVBSatelliteDiseqcParameters m_diseqc_parameters;
eDVBSatelliteRotorParameters m_rotor_parameters;
+
+ int m_prio; // to override automatic tuner management ... -1 is Auto
#endif
+public:
+#define guard_offset_min -8000
+#define guard_offset_max 8000
+#define guard_offset_step 8000
+#define MAX_SATCR 8
+#define MAX_LNBNUM 32
+
+ int SatCR_idx;
+ unsigned int SatCRvco;
+ unsigned int UnicableTuningWord;
+ unsigned int UnicableConfigWord;
+ int old_frequency;
+ int old_polarisation;
+ int old_orbital_position;
+ int guard_offset_old;
+ int guard_offset;
+ int LNBNum;
};
class eDVBRegisteredFrontend;
class eDVBSatelliteEquipmentControl: public iDVBSatelliteEquipmentControl
{
+ DECLARE_REF(eDVBSatelliteEquipmentControl);
+public:
+ enum {
+ DELAY_AFTER_CONT_TONE_DISABLE_BEFORE_DISEQC=0, // delay after continuous tone disable before diseqc command
+ DELAY_AFTER_FINAL_CONT_TONE_CHANGE, // delay after continuous tone change before tune
+ DELAY_AFTER_FINAL_VOLTAGE_CHANGE, // delay after voltage change at end of complete sequence
+ DELAY_BETWEEN_DISEQC_REPEATS, // delay between repeated diseqc commands
+ DELAY_AFTER_LAST_DISEQC_CMD, // delay after last diseqc command
+ DELAY_AFTER_TONEBURST, // delay after toneburst
+ DELAY_AFTER_ENABLE_VOLTAGE_BEFORE_SWITCH_CMDS, // delay after enable voltage before transmit toneburst/diseqc
+ DELAY_BETWEEN_SWITCH_AND_MOTOR_CMD, // delay after transmit toneburst / diseqc and before transmit motor command
+ DELAY_AFTER_VOLTAGE_CHANGE_BEFORE_MEASURE_IDLE_INPUTPOWER, // delay after voltage change before measure idle input power
+ DELAY_AFTER_ENABLE_VOLTAGE_BEFORE_MOTOR_CMD, // delay after enable voltage before transmit motor command
+ DELAY_AFTER_MOTOR_STOP_CMD, // delay after transmit motor stop
+ DELAY_AFTER_VOLTAGE_CHANGE_BEFORE_MOTOR_CMD, // delay after voltage change before transmit motor command
+ DELAY_BEFORE_SEQUENCE_REPEAT, // delay before the complete sequence is repeated (when enabled)
+ MOTOR_COMMAND_RETRIES, // max transmit tries of rotor command when the rotor dont start turning (with power measurement)
+ MOTOR_RUNNING_TIMEOUT, // max motor running time before timeout
+ DELAY_AFTER_VOLTAGE_CHANGE_BEFORE_SWITCH_CMDS, // delay after change voltage before transmit toneburst/diseqc
+ DELAY_AFTER_DISEQC_RESET_CMD,
+ DELAY_AFTER_DISEQC_PERIPHERIAL_POWERON_CMD,
+ MAX_PARAMS
+ };
+private:
#ifndef SWIG
static eDVBSatelliteEquipmentControl *instance;
- eDVBSatelliteLNBParameters m_lnbs[128]; // i think its enough
+ eDVBSatelliteLNBParameters m_lnbs[144]; // i think its enough
int m_lnbidx; // current index for set parameters
std::map<int, eDVBSatelliteSwitchParameters>::iterator m_curSat;
- eSmartPtrList<eDVBRegisteredFrontend> &m_avail_frontends;
- bool m_rotorMoving;
+ eSmartPtrList<eDVBRegisteredFrontend> &m_avail_frontends, &m_avail_simulate_frontends;
+ int m_rotorMoving;
+ int m_not_linked_slot_mask;
+ bool m_canMeasureInputPower;
#endif
#ifdef SWIG
eDVBSatelliteEquipmentControl();
~eDVBSatelliteEquipmentControl();
#endif
- // helper function for setTunerLinked and setTunerDepends
- RESULT setDependencyPointers( int no1, int no2, int dest_data_byte );
+ static int m_params[MAX_PARAMS];
public:
#ifndef SWIG
- eDVBSatelliteEquipmentControl(eSmartPtrList<eDVBRegisteredFrontend> &avail_frontends);
- DECLARE_REF(eDVBSatelliteEquipmentControl);
- RESULT prepare(iDVBFrontend &frontend, FRONTENDPARAMETERS &parm, eDVBFrontendParametersSatellite &sat, int frontend_id);
- int canTune(const eDVBFrontendParametersSatellite &feparm, iDVBFrontend *, int frontend_id);
+ eDVBSatelliteEquipmentControl(eSmartPtrList<eDVBRegisteredFrontend> &avail_frontends, eSmartPtrList<eDVBRegisteredFrontend> &avail_simulate_frontends);
+ RESULT prepare(iDVBFrontend &frontend, FRONTENDPARAMETERS &parm, const eDVBFrontendParametersSatellite &sat, int frontend_id, unsigned int tunetimeout);
+ int canTune(const eDVBFrontendParametersSatellite &feparm, iDVBFrontend *, int frontend_id, int *highest_score_lnb=0);
bool currentLNBValid() { return m_lnbidx > -1 && m_lnbidx < (int)(sizeof(m_lnbs) / sizeof(eDVBSatelliteLNBParameters)); }
#endif
static eDVBSatelliteEquipmentControl *getInstance() { return instance; }
+ static void setParam(int param, int value);
RESULT clear();
/* LNB Specific Parameters */
RESULT addLNB();
- RESULT setLNBTunerMask(int tunermask);
+ RESULT setLNBSlotMask(int slotmask);
RESULT setLNBLOFL(int lofl);
RESULT setLNBLOFH(int lofh);
RESULT setLNBThreshold(int threshold);
RESULT setLNBIncreasedVoltage(bool onoff);
+ RESULT setLNBPrio(int prio);
+ RESULT setLNBNum(int LNBNum);
/* DiSEqC Specific Parameters */
RESULT setDiSEqCMode(int diseqcmode);
RESULT setToneburst(int toneburst);
RESULT setLaDirection(int direction);
RESULT setUseInputpower(bool onoff);
RESULT setInputpowerDelta(int delta); // delta between running and stopped rotor
+ RESULT setRotorTurningSpeed(int speed); // set turning speed..
+/* Unicable Specific Parameters */
+ RESULT setLNBSatCR(int SatCR_idx);
+ RESULT setLNBSatCRvco(int SatCRvco);
+// RESULT checkGuardOffset(const eDVBFrontendParametersSatellite &sat);
+ RESULT getLNBSatCR();
+ RESULT getLNBSatCRvco();
/* Satellite Specific Parameters */
RESULT addSatellite(int orbital_position);
RESULT setVoltageMode(int mode);
/* Tuner Specific Parameters */
RESULT setTunerLinked(int from, int to);
RESULT setTunerDepends(int from, int to);
+ void setSlotNotLinked(int tuner_no);
- void setRotorMoving(bool); // called from the frontend's
+ void setRotorMoving(int, bool); // called from the frontend's
bool isRotorMoving();
+ bool canMeasureInputPower() { return m_canMeasureInputPower; }
};
#endif