+ case frontendNumber:
+ return m_fe;
+ }
+ return 0;
+}
+
+void PutToDict(PyObject *dict, const char*key, long value)
+{
+ PyObject *item = PyInt_FromLong(value);
+ if (item)
+ {
+ if (PyDict_SetItemString(dict, key, item))
+ eDebug("put %s to dict failed", key);
+ Py_DECREF(item);
+ }
+ else
+ eDebug("could not create PyObject for %s", key);
+}
+
+void PutToDict(PyObject *dict, const char*key, const char *value)
+{
+ PyObject *item = PyString_FromString(value);
+ if (item)
+ {
+ if (PyDict_SetItemString(dict, key, item))
+ eDebug("put %s to dict failed", key);
+ Py_DECREF(item);
+ }
+ else
+ eDebug("could not create PyObject for %s", key);
+}
+
+void fillDictWithSatelliteData(PyObject *dict, const FRONTENDPARAMETERS &parm, eDVBFrontend *fe)
+{
+ int freq_offset=0;
+ int csw=0;
+ const char *tmp=0;
+ fe->getData(eDVBFrontend::CSW, csw);
+ fe->getData(eDVBFrontend::FREQ_OFFSET, freq_offset);
+ int frequency = parm_frequency + freq_offset;
+ PutToDict(dict, "frequency", frequency);
+ PutToDict(dict, "symbol_rate", parm_u_qpsk_symbol_rate);
+ switch(parm_u_qpsk_fec_inner)
+ {
+ case FEC_1_2:
+ tmp = "FEC_1_2";
+ break;
+ case FEC_2_3:
+ tmp = "FEC_2_3";
+ break;
+ case FEC_3_4:
+ tmp = "FEC_3_4";
+ break;
+ case FEC_5_6:
+ tmp = "FEC_5_6";
+ break;
+ case FEC_7_8:
+ tmp = "FEC_7_8";
+ break;
+ case FEC_NONE:
+ tmp = "FEC_NONE";
+ default:
+ case FEC_AUTO:
+ tmp = "FEC_AUTO";
+ break;
+#if HAVE_DVB_API_VERSION >=3
+ case FEC_S2_8PSK_1_2:
+ case FEC_S2_QPSK_1_2:
+ tmp = "FEC_1_2";
+ break;
+ case FEC_S2_8PSK_2_3:
+ case FEC_S2_QPSK_2_3:
+ tmp = "FEC_2_3";
+ break;
+ case FEC_S2_8PSK_3_4:
+ case FEC_S2_QPSK_3_4:
+ tmp = "FEC_3_4";
+ break;
+ case FEC_S2_8PSK_5_6:
+ case FEC_S2_QPSK_5_6:
+ tmp = "FEC_5_6";
+ break;
+ case FEC_S2_8PSK_7_8:
+ case FEC_S2_QPSK_7_8:
+ tmp = "FEC_7_8";
+ break;
+ case FEC_S2_8PSK_8_9:
+ case FEC_S2_QPSK_8_9:
+ tmp = "FEC_8_9";
+ break;
+ case FEC_S2_8PSK_3_5:
+ case FEC_S2_QPSK_3_5:
+ tmp = "FEC_3_5";
+ break;
+ case FEC_S2_8PSK_4_5:
+ case FEC_S2_QPSK_4_5:
+ tmp = "FEC_4_5";
+ break;
+ case FEC_S2_8PSK_9_10:
+ case FEC_S2_QPSK_9_10:
+ tmp = "FEC_9_10";
+ break;
+#endif
+ }
+#if HAVE_DVB_API_VERSION >=3
+ PutToDict(dict, "modulation",
+ parm_u_qpsk_fec_inner > FEC_S2_QPSK_9_10 ? "8PSK": "QPSK" );
+#else
+ PutToDict(dict, "modulation", "QPSK" );
+#endif
+ PutToDict(dict, "fec_inner", tmp);
+ tmp = parm_u_qpsk_fec_inner > FEC_AUTO ?
+ "DVB-S2" : "DVB-S";
+ PutToDict(dict, "system", tmp);
+}
+
+void fillDictWithCableData(PyObject *dict, const FRONTENDPARAMETERS &parm)
+{
+ const char *tmp=0;
+ PutToDict(dict, "frequency", parm_frequency/1000);
+ PutToDict(dict, "symbol_rate", parm_u_qam_symbol_rate);
+ switch(parm_u_qam_fec_inner)
+ {
+ case FEC_NONE:
+ tmp = "FEC_NONE";
+ break;
+ case FEC_1_2:
+ tmp = "FEC_1_2";
+ break;
+ case FEC_2_3:
+ tmp = "FEC_2_3";
+ break;
+ case FEC_3_4:
+ tmp = "FEC_3_4";
+ break;
+ case FEC_5_6:
+ tmp = "FEC_5_6";
+ break;
+ case FEC_7_8:
+ tmp = "FEC_7_8";
+ break;
+#if HAVE_DVB_API_VERSION >= 3
+ case FEC_8_9:
+ tmp = "FEC_8_9";
+ break;
+#endif
+ default:
+ case FEC_AUTO:
+ tmp = "FEC_AUTO";
+ break;
+ }
+ PutToDict(dict, "fec_inner", tmp);
+ switch(parm_u_qam_modulation)
+ {
+ case QAM_16:
+ tmp = "QAM_16";
+ break;
+ case QAM_32:
+ tmp = "QAM_32";
+ break;
+ case QAM_64:
+ tmp = "QAM_64";
+ break;
+ case QAM_128:
+ tmp = "QAM_128";
+ break;
+ case QAM_256:
+ tmp = "QAM_256";
+ break;
+ default:
+ case QAM_AUTO:
+ tmp = "QAM_AUTO";
+ break;
+ }
+ PutToDict(dict, "modulation", tmp);
+}
+
+void fillDictWithTerrestrialData(PyObject *dict, const FRONTENDPARAMETERS &parm)
+{
+ const char *tmp=0;
+ PutToDict(dict, "frequency", parm_frequency);
+ switch (parm_u_ofdm_bandwidth)
+ {
+ case BANDWIDTH_8_MHZ:
+ tmp = "BANDWIDTH_8_MHZ";
+ break;
+ case BANDWIDTH_7_MHZ:
+ tmp = "BANDWIDTH_7_MHZ";
+ break;
+ case BANDWIDTH_6_MHZ:
+ tmp = "BANDWIDTH_6_MHZ";
+ break;
+ default:
+ case BANDWIDTH_AUTO:
+ tmp = "BANDWIDTH_AUTO";
+ break;
+ }
+ PutToDict(dict, "bandwidth", tmp);
+ switch (parm_u_ofdm_code_rate_LP)
+ {
+ case FEC_1_2:
+ tmp = "FEC_1_2";
+ break;
+ case FEC_2_3:
+ tmp = "FEC_2_3";
+ break;
+ case FEC_3_4:
+ tmp = "FEC_3_4";
+ break;
+ case FEC_5_6:
+ tmp = "FEC_5_6";
+ break;
+ case FEC_7_8:
+ tmp = "FEC_7_8";
+ break;
+ default:
+ case FEC_AUTO:
+ tmp = "FEC_AUTO";
+ break;
+ }
+ PutToDict(dict, "code_rate_lp", tmp);
+ switch (parm_u_ofdm_code_rate_HP)
+ {
+ case FEC_1_2:
+ tmp = "FEC_1_2";
+ break;
+ case FEC_2_3:
+ tmp = "FEC_2_3";
+ break;
+ case FEC_3_4:
+ tmp = "FEC_3_4";
+ break;
+ case FEC_5_6:
+ tmp = "FEC_5_6";
+ break;
+ case FEC_7_8:
+ tmp = "FEC_7_8";
+ break;
+ default:
+ case FEC_AUTO:
+ tmp = "FEC_AUTO";
+ break;
+ }
+ PutToDict(dict, "code_rate_hp", tmp);
+ switch (parm_u_ofdm_constellation)
+ {
+ case QPSK:
+ tmp = "QPSK";
+ break;
+ case QAM_16:
+ tmp = "QAM_16";
+ break;
+ case QAM_64:
+ tmp = "QAM_64";
+ break;
+ default:
+ case QAM_AUTO:
+ tmp = "QAM_AUTO";
+ break;
+ }
+ PutToDict(dict, "constellation", tmp);
+ switch (parm_u_ofdm_transmission_mode)
+ {
+ case TRANSMISSION_MODE_2K:
+ tmp = "TRANSMISSION_MODE_2K";
+ break;
+ case TRANSMISSION_MODE_8K:
+ tmp = "TRANSMISSION_MODE_8K";
+ break;
+ default:
+ case TRANSMISSION_MODE_AUTO:
+ tmp = "TRANSMISSION_MODE_AUTO";
+ break;
+ }
+ PutToDict(dict, "transmission_mode", tmp);
+ switch (parm_u_ofdm_guard_interval)
+ {
+ case GUARD_INTERVAL_1_32:
+ tmp = "GUARD_INTERVAL_1_32";
+ break;
+ case GUARD_INTERVAL_1_16:
+ tmp = "GUARD_INTERVAL_1_16";
+ break;
+ case GUARD_INTERVAL_1_8:
+ tmp = "GUARD_INTERVAL_1_8";
+ break;
+ case GUARD_INTERVAL_1_4:
+ tmp = "GUARD_INTERVAL_1_4";
+ break;
+ default:
+ case GUARD_INTERVAL_AUTO:
+ tmp = "GUARD_INTERVAL_AUTO";
+ break;
+ }
+ PutToDict(dict, "guard_interval", tmp);
+ switch (parm_u_ofdm_hierarchy_information)
+ {
+ case HIERARCHY_NONE:
+ tmp = "HIERARCHY_NONE";
+ break;
+ case HIERARCHY_1:
+ tmp = "HIERARCHY_1";
+ break;
+ case HIERARCHY_2:
+ tmp = "HIERARCHY_2";
+ break;
+ case HIERARCHY_4:
+ tmp = "HIERARCHY_4";
+ break;
+ default:
+ case HIERARCHY_AUTO:
+ tmp = "HIERARCHY_AUTO";
+ break;
+ }
+ PutToDict(dict, "hierarchy_information", tmp);
+}
+
+PyObject *eDVBFrontend::readTransponderData(bool original)
+{
+ PyObject *ret=PyDict_New();
+
+ if (ret)
+ {
+ bool read=m_fd != -1;
+ const char *tmp=0;
+
+ PutToDict(ret, "tuner_number", m_fe);
+
+ switch(m_type)
+ {
+ case feSatellite:
+ tmp = "DVB-S";
+ break;
+ case feCable:
+ tmp = "DVB-C";
+ break;
+ case feTerrestrial:
+ tmp = "DVB-T";
+ break;
+ default:
+ tmp = "UNKNOWN";
+ read=false;
+ break;
+ }
+ PutToDict(ret, "tuner_type", tmp);
+
+ if (read)
+ {
+ FRONTENDPARAMETERS front;
+
+ tmp = "UNKNOWN";
+ switch(m_state)
+ {
+ case stateIdle:
+ tmp="IDLE";
+ break;
+ case stateTuning:
+ tmp="TUNING";
+ break;
+ case stateFailed:
+ tmp="FAILED";
+ break;
+ case stateLock:
+ tmp="LOCKED";
+ break;
+ case stateLostLock:
+ tmp="LOSTLOCK";
+ break;
+ default:
+ break;
+ }
+ PutToDict(ret, "tuner_state", tmp);
+
+ PutToDict(ret, "tuner_locked", readFrontendData(locked));
+ PutToDict(ret, "tuner_synced", readFrontendData(synced));
+ PutToDict(ret, "tuner_bit_error_rate", readFrontendData(bitErrorRate));
+ PutToDict(ret, "tuner_signal_power", readFrontendData(signalPower));
+ PutToDict(ret, "tuner_signal_quality", readFrontendData(signalQuality));
+
+ if (!original && ioctl(m_fd, FE_GET_FRONTEND, &front)<0)
+ eDebug("FE_GET_FRONTEND (%m)");
+ else
+ {
+ const FRONTENDPARAMETERS &parm = original ? this->parm : front;
+ tmp = "INVERSION_AUTO";
+ switch(parm_inversion)
+ {
+ case INVERSION_ON:
+ tmp = "INVERSION_ON";
+ break;
+ case INVERSION_OFF:
+ tmp = "INVERSION_OFF";
+ break;
+ default:
+ break;
+ }
+ if (tmp)
+ PutToDict(ret, "inversion", tmp);
+
+ switch(m_type)
+ {
+ case feSatellite:
+ fillDictWithSatelliteData(ret, original?parm:front, this);
+ break;
+ case feCable:
+ fillDictWithCableData(ret, original?parm:front);
+ break;
+ case feTerrestrial:
+ fillDictWithTerrestrialData(ret, original?parm:front);
+ break;
+ }
+ }
+ }
+ }
+ else
+ {
+ Py_INCREF(Py_None);
+ ret = Py_None;
+ }
+ return ret;
+}
+
+#ifndef FP_IOCTL_GET_ID
+#define FP_IOCTL_GET_ID 0
+#endif
+int eDVBFrontend::readInputpower()
+{
+ int power=m_fe; // this is needed for read inputpower from the correct tuner !
+
+ // open front prozessor
+ int fp=::open("/dev/dbox/fp0", O_RDWR);
+ if (fp < 0)
+ {
+ eDebug("couldn't open fp");
+ return -1;
+ }
+ static bool old_fp = (::ioctl(fp, FP_IOCTL_GET_ID) < 0);
+ if ( ioctl( fp, old_fp ? 9 : 0x100, &power ) < 0 )
+ {
+ eDebug("FP_IOCTL_GET_LNB_CURRENT failed (%m)");
+ return -1;
+ }
+ ::close(fp);
+
+ return power;
+}
+
+bool eDVBFrontend::setSecSequencePos(int steps)
+{
+ eDebug("set sequence pos %d", steps);
+ if (!steps)
+ return false;
+ while( steps > 0 )
+ {
+ if (m_sec_sequence.current() != m_sec_sequence.end())
+ ++m_sec_sequence.current();
+ --steps;
+ }
+ while( steps < 0 )
+ {
+ if (m_sec_sequence.current() != m_sec_sequence.begin() && m_sec_sequence.current() != m_sec_sequence.end())
+ --m_sec_sequence.current();
+ ++steps;
+ }
+ return true;
+}
+
+void eDVBFrontend::tuneLoop() // called by m_tuneTimer
+{
+ int delay=0;
+ if ( m_sec_sequence && m_sec_sequence.current() != m_sec_sequence.end() )
+ {
+// eDebug("tuneLoop %d\n", m_sec_sequence.current()->cmd);
+ switch (m_sec_sequence.current()->cmd)
+ {
+ case eSecCommand::SLEEP:
+ delay = m_sec_sequence.current()++->msec;
+ eDebug("[SEC] sleep %dms", delay);
+ break;
+ case eSecCommand::GOTO:
+ if ( !setSecSequencePos(m_sec_sequence.current()->steps) )
+ ++m_sec_sequence.current();
+ break;
+ case eSecCommand::SET_VOLTAGE:
+ {
+ int voltage = m_sec_sequence.current()++->voltage;
+ eDebug("[SEC] setVoltage %d", voltage);
+ setVoltage(voltage);
+ break;
+ }
+ case eSecCommand::IF_VOLTAGE_GOTO:
+ {
+ eSecCommand::pair &compare = m_sec_sequence.current()->compare;
+ if ( compare.voltage == m_curVoltage && setSecSequencePos(compare.steps) )
+ break;
+ ++m_sec_sequence.current();
+ break;
+ }
+ case eSecCommand::IF_NOT_VOLTAGE_GOTO:
+ {
+ eSecCommand::pair &compare = m_sec_sequence.current()->compare;
+ if ( compare.voltage != m_curVoltage && setSecSequencePos(compare.steps) )
+ break;
+ ++m_sec_sequence.current();
+ break;
+ }
+ case eSecCommand::SET_TONE:
+ eDebug("[SEC] setTone %d", m_sec_sequence.current()->tone);
+ setTone(m_sec_sequence.current()++->tone);
+ break;
+ case eSecCommand::SEND_DISEQC:
+ sendDiseqc(m_sec_sequence.current()->diseqc);
+ eDebugNoNewLine("[SEC] sendDiseqc: ");
+ for (int i=0; i < m_sec_sequence.current()->diseqc.len; ++i)
+ eDebugNoNewLine("%02x", m_sec_sequence.current()->diseqc.data[i]);
+ eDebug("");
+ ++m_sec_sequence.current();
+ break;
+ case eSecCommand::SEND_TONEBURST:
+ eDebug("[SEC] sendToneburst: %d", m_sec_sequence.current()->toneburst);
+ sendToneburst(m_sec_sequence.current()++->toneburst);
+ break;
+ case eSecCommand::SET_FRONTEND:
+ eDebug("[SEC] setFrontend");
+ setFrontend();
+ ++m_sec_sequence.current();
+ break;
+ case eSecCommand::START_TUNE_TIMEOUT:
+ m_timeout->start(5000, 1); // 5 sec timeout. TODO: symbolrate dependent
+ ++m_sec_sequence.current();
+ break;
+ case eSecCommand::SET_TIMEOUT:
+ m_timeoutCount = m_sec_sequence.current()++->val;
+ eDebug("[SEC] set timeout %d", m_timeoutCount);
+ break;
+ case eSecCommand::IF_TIMEOUT_GOTO:
+ if (!m_timeoutCount)
+ {
+ eDebug("[SEC] rotor timout");
+ m_sec->setRotorMoving(false);
+ setSecSequencePos(m_sec_sequence.current()->steps);
+ }
+ else
+ ++m_sec_sequence.current();
+ break;
+ case eSecCommand::MEASURE_IDLE_INPUTPOWER:
+ {
+ int idx = m_sec_sequence.current()++->val;
+ if ( idx == 0 || idx == 1 )
+ {
+ m_idleInputpower[idx] = readInputpower();
+ eDebug("[SEC] idleInputpower[%d] is %d", idx, m_idleInputpower[idx]);
+ }
+ else
+ eDebug("[SEC] idleInputpower measure index(%d) out of bound !!!", idx);
+ break;
+ }
+ case eSecCommand::IF_MEASURE_IDLE_WAS_NOT_OK_GOTO:
+ {
+ eSecCommand::pair &compare = m_sec_sequence.current()->compare;
+ int idx = compare.voltage;
+ if ( idx == 0 || idx == 1 )
+ {
+ int idle = readInputpower();
+ int diff = abs(idle-m_idleInputpower[idx]);
+ if ( diff > 0)
+ {
+ eDebug("measure idle(%d) was not okay.. (%d - %d = %d) retry", idx, m_idleInputpower[idx], idle, diff);
+ setSecSequencePos(compare.steps);
+ break;
+ }
+ }
+ ++m_sec_sequence.current();
+ break;
+ }
+ case eSecCommand::IF_TUNER_LOCKED_GOTO:
+ {
+ eSecCommand::rotor &cmd = m_sec_sequence.current()->measure;
+ if (readFrontendData(locked))
+ {
+ eDebug("[SEC] locked step %d ok", cmd.okcount);
+ ++cmd.okcount;
+ if (cmd.okcount > 12)
+ {
+ eDebug("ok > 12 .. goto %d\n",m_sec_sequence.current()->steps);
+ setSecSequencePos(cmd.steps);
+ break;
+ }
+ }
+ else
+ {
+ eDebug("[SEC] rotor locked step %d failed", cmd.okcount);
+ --m_timeoutCount;
+ if (!m_timeoutCount && m_retryCount > 0)
+ --m_retryCount;
+ cmd.okcount=0;
+ }
+ ++m_sec_sequence.current();
+ break;
+ }
+ case eSecCommand::MEASURE_RUNNING_INPUTPOWER:
+ m_runningInputpower = readInputpower();
+ eDebug("[SEC] runningInputpower is %d", m_runningInputpower);
+ ++m_sec_sequence.current();
+ break;
+ case eSecCommand::IF_INPUTPOWER_DELTA_GOTO:
+ {
+ int idleInputpower = m_idleInputpower[ (m_curVoltage&1) ? 0 : 1];
+ eSecCommand::rotor &cmd = m_sec_sequence.current()->measure;
+ const char *txt = cmd.direction ? "running" : "stopped";
+ eDebug("[SEC] waiting for rotor %s %d, idle %d, delta %d",
+ txt,
+ m_runningInputpower,
+ idleInputpower,
+ cmd.deltaA);
+ if ( (cmd.direction && abs(m_runningInputpower - idleInputpower) >= cmd.deltaA)
+ || (!cmd.direction && abs(m_runningInputpower - idleInputpower) <= cmd.deltaA) )
+ {
+ ++cmd.okcount;
+ eDebug("[SEC] rotor %s step %d ok", txt, cmd.okcount);
+ if ( cmd.okcount > 6 )
+ {
+ m_sec->setRotorMoving(cmd.direction);
+ eDebug("[SEC] rotor is %s", txt);
+ if (setSecSequencePos(cmd.steps))
+ break;
+ }
+ }
+ else
+ {
+ eDebug("[SEC] rotor not %s... reset counter.. increase timeout", txt);
+ --m_timeoutCount;
+ if (!m_timeoutCount && m_retryCount > 0)
+ --m_retryCount;
+ cmd.okcount=0;
+ }
+ ++m_sec_sequence.current();
+ break;
+ }
+ case eSecCommand::IF_ROTORPOS_VALID_GOTO:
+ if (m_data[ROTOR_CMD] != -1 && m_data[ROTOR_POS] != -1)
+ setSecSequencePos(m_sec_sequence.current()->steps);
+ else
+ ++m_sec_sequence.current();
+ break;
+ case eSecCommand::INVALIDATE_CURRENT_ROTORPARMS:
+ m_data[ROTOR_CMD] = m_data[ROTOR_POS] = -1;
+ eDebug("[SEC] invalidate current rotorparams");
+ ++m_sec_sequence.current();
+ break;
+ case eSecCommand::UPDATE_CURRENT_ROTORPARAMS:
+ m_data[ROTOR_CMD] = m_data[NEW_ROTOR_CMD];
+ m_data[ROTOR_POS] = m_data[NEW_ROTOR_POS];
+ eDebug("[SEC] update current rotorparams %d %04x %d", m_timeoutCount, m_data[5], m_data[6]);
+ ++m_sec_sequence.current();
+ break;
+ case eSecCommand::SET_ROTOR_DISEQC_RETRYS:
+ m_retryCount = m_sec_sequence.current()++->val;
+ eDebug("[SEC] set rotor retries %d", m_retryCount);
+ break;
+ case eSecCommand::IF_NO_MORE_ROTOR_DISEQC_RETRYS_GOTO:
+ if (!m_retryCount)
+ {
+ eDebug("[SEC] no more rotor retrys");
+ setSecSequencePos(m_sec_sequence.current()->steps);
+ }
+ else
+ ++m_sec_sequence.current();
+ break;
+ case eSecCommand::SET_POWER_LIMITING_MODE:
+ {
+ int fd = m_fe ?
+ ::open("/dev/i2c/1", O_RDWR) :
+ ::open("/dev/i2c/0", O_RDWR);
+
+ unsigned char data[2];
+ ::ioctl(fd, I2C_SLAVE_FORCE, 0x10 >> 1);
+ if(::read(fd, data, 1) != 1)
+ eDebug("[SEC] error read lnbp (%m)");
+ if ( m_sec_sequence.current()->mode == eSecCommand::modeStatic )
+ {
+ data[0] |= 0x80; // enable static current limiting
+ eDebug("[SEC] set static current limiting");
+ }
+ else
+ {
+ data[0] &= ~0x80; // enable dynamic current limiting
+ eDebug("[SEC] set dynamic current limiting");
+ }
+ if(::write(fd, data, 1) != 1)
+ eDebug("[SEC] error write lnbp (%m)");
+ ::close(fd);
+ ++m_sec_sequence.current();
+ break;
+ }
+ default:
+ ++m_sec_sequence.current();
+ eDebug("[SEC] unhandled sec command");
+ }
+ m_tuneTimer->start(delay,true);
+ }
+}
+
+void eDVBFrontend::setFrontend()
+{
+ eDebug("setting frontend %d", m_fe);
+ m_sn->start();
+ feEvent(-1);
+ if (ioctl(m_fd, FE_SET_FRONTEND, &parm) == -1)
+ {
+ perror("FE_SET_FRONTEND failed");
+ return;
+ }