#include "xsync_v2.hpp" #include #include #include "xsync_errcode.hpp" #include "xsync_regs.hpp" #include "xsync_utils.hpp" #include "xsync_v2_sig_type.hpp" #define TAG "XSYNC" using namespace xsync; using namespace std; /** * @brief XSYNC协议端口 */ #define IFLYTOP_XSYNC_SERVICE_XSYNC_PORT 19900 // xsync端端口 #define IFLYTOP_XSYNC_SERVICE_PC_PORT 19901 // pc 端端口 #define IFLYTOP_XSYNC_TIMECODE_REPORT_XSYNC_PORT 19902 // xsync端端口 #define IFLYTOP_XSYNC_TIMECODE_REPORT_PC_PORT 19903 // pc端端口 #define IFLYTOP_XSYNC_CAMERA_SYNC_PACKET_XSYNC_PORT 13013 // xsync端端口 #define IFLYTOP_XSYNC_CAMERA_SYNC_PACKET_PC_PORT 13014 // pc端端口 #define DO_XSYNC(exptr) \ { \ xs_error_code_t ecode = exptr; \ if (ecode != kxs_ec_success) return ecode; \ } #define REG_WRITE(reg, value) \ { \ DO_XSYNC(reg_write(reg, value, 10)); \ return kxs_ec_success; \ } #define REG_READ(reg, value) \ { \ uint32_t readbak = 0; \ DO_XSYNC(reg_read(reg, readbak, 10)); \ value = (decltype(value))readbak; \ return kxs_ec_success; \ } class Xsync : public IXsync { private: /* data */ I_XSUDPFactory *m_xsync_udp_factory = nullptr; shared_ptr m_xsync_reg_udp = nullptr; shared_ptr m_xsync_timecode_udp_listener = nullptr; shared_ptr m_xsync_camera_sync_udp_listener = nullptr; string m_xsync_ip; bool m_is_connected = false; xsync_on_camera_sync_msg_t m_on_camera_sync_msg_cb = nullptr; xsync_on_timecode_msg_t m_on_timecode_msg_cb = nullptr; xsync_on_record_sig_change_msg_t m_on_record_sig_change_msg_cb = nullptr; int txpacket_index = 0; uint8_t m_xync_cmd_rxdata_cache[2560]; std::recursive_mutex lock_; public: static Xsync &Ins(); Xsync(/* args */); virtual ~Xsync() {} void initialize(I_XSUDPFactory *xsync_udp_factory); xs_error_code_t connect(string xsync_ip); xs_error_code_t disConnect(); virtual xs_error_code_t changeXsyncIp(string xsync_ip) override; virtual bool ping() override; virtual void registerOnTimecodeMsgCallback(xsync_on_timecode_msg_t cb) override; virtual void registerOnCameraSyncMsgCallback(xsync_on_camera_sync_msg_t cb) override; virtual void registerOnRecordSigChangeMsgCallback(xsync_on_record_sig_change_msg_t cb) override; virtual xs_error_code_t generatorNewMac() override; virtual xs_error_code_t factoryReset() override; virtual xs_error_code_t reboot() override; virtual xs_error_code_t changeNetworkConfig(string ip, string mask, string gateway) override; virtual xs_error_code_t readSn(string &sn) override; virtual xs_error_code_t readMac(string &mac) override; public: virtual xs_error_code_t reg_write(uint32_t regadd, uint32_t regvalue, uint32_t ®backvalue, int32_t overtime_ms = 100) override; virtual xs_error_code_t reg_read(uint32_t regadd, uint32_t ®value, int32_t overtime_ms = 100) override; public: virtual xs_error_code_t ExternalTimecode_setSource(InputInterface_t src) override; virtual xs_error_code_t ExternalTimecode_getSource(InputInterface_t &timecode_select) override; virtual xs_error_code_t ExternalTimecode_setFormat(TimecodeFormat_t format) override; virtual xs_error_code_t ExternalTimecode_getFormat(TimecodeFormat_t &format) override; virtual xs_error_code_t ExternalTimecode_readCode(XsyncTimecode_t &timecode) override; virtual xs_error_code_t TTLInputModule1_detectFreq(float &freq) override; virtual xs_error_code_t TTLInputModule2_detectFreq(float &freq) override; virtual xs_error_code_t TTLInputModule3_detectFreq(float &freq) override; virtual xs_error_code_t TTLInputModule4_detectFreq(float &freq) override; virtual xs_error_code_t ExternalGenlock_detectFreq(float &freq) override; virtual xs_error_code_t InternalTimecode_setFormat(TimecodeFormat_t format) override; virtual xs_error_code_t InternalTimecode_getFormat(TimecodeFormat_t &format) override; virtual xs_error_code_t InternalTimecode_setCode(XsyncTimecode_t timecode) override; virtual xs_error_code_t InternalTimecode_getCode(XsyncTimecode_t &timecode) override; virtual xs_error_code_t InternalGenlock_setFormat(GenlockFormat_t format) override; virtual xs_error_code_t InternalGenlock_getFormat(GenlockFormat_t &format) override; virtual xs_error_code_t InternalClock_setFreq(float freq) override; virtual xs_error_code_t InternalClock_getFreq(float &freq) override; virtual xs_error_code_t SysTimecode_setSource(uint32_t sig) override; virtual xs_error_code_t SysTimecode_getSource(uint32_t &sig) override; virtual xs_error_code_t SysTimecode_readFormat(TimecodeFormat_t &format) override; virtual xs_error_code_t SysTimecode_readCode(XsyncTimecode_t &timecode) override; virtual xs_error_code_t SysGenlock_setSrc(uint32_t source) override; virtual xs_error_code_t SysGenlock_getSrc(uint32_t &source) override; virtual xs_error_code_t SysGenlock_readFreq(float &freq) override; virtual xs_error_code_t SysClock_setSrc(SignalType_t sig) override; virtual xs_error_code_t SysClock_getSrc(SignalType_t &sig) override; virtual xs_error_code_t SysClock_setTriggerEdge(TriggerEdge_t edge) override; virtual xs_error_code_t SysClock_getTriggerEdge(TriggerEdge_t &edge) override; virtual xs_error_code_t SysClock_setFreqDivision(uint32_t div) override; virtual xs_error_code_t SysClock_geFreqtDivision(uint32_t &div) override; virtual xs_error_code_t SysClock_setFreqMultiplication(uint32_t muti) override; virtual xs_error_code_t SysClock_getFreqMultiplication(uint32_t &muti) override; virtual xs_error_code_t SysClock_readOutSigFreq(float &freq) override; virtual xs_error_code_t SysClock_readInSigFreq(float &freq) override; virtual xs_error_code_t RecordSigGenerator_setContrlMode(ControlMode_t mode) override; virtual xs_error_code_t RecordSigGenerator_getContrlMode(ControlMode_t &mode) override; virtual xs_error_code_t RecordSigGenerator_manualStart() override; virtual xs_error_code_t RecordSigGenerator_manualStop() override; virtual xs_error_code_t RecordSigGenerator_setAutoStartTimecode(XsyncTimecode_t timecode) override; virtual xs_error_code_t RecordSigGenerator_setAutoStopTimecode(XsyncTimecode_t timecode) override; virtual xs_error_code_t RecordSigGenerator_getAutoStartTimecode(XsyncTimecode_t &timecode) override; virtual xs_error_code_t RecordSigGenerator_getAutoStopTimecode(XsyncTimecode_t &timecode) override; virtual xs_error_code_t RecordSigGenerator_setTimecodeCtrlFlag(uint32_t autoStart, uint32_t autoStop) override; virtual xs_error_code_t RecordSigGenerator_getTimecodeCtrlFlag(uint32_t &autoStart, uint32_t &autoStop) override; virtual xs_error_code_t RecordSigGenerator_setExternalTTLTriggerSrc(InputInterface_t ttlPortNum); // 1- override4 virtual xs_error_code_t RecordSigGenerator_getExternalTTLTriggerSrc(InputInterface_t &ttlPortNum) override; virtual xs_error_code_t RecordSigGenerator_setExternalTTLTriggerPolarity(uint32_t polarity) override; virtual xs_error_code_t RecordSigGenerator_getExternalTTLTriggerPolarity(uint32_t &polarity) override; virtual xs_error_code_t RecordSigGenerator_setRecordExposureTime(uint32_t us) override; virtual xs_error_code_t RecordSigGenerator_getRecordExposureTime(uint32_t &us) override; virtual xs_error_code_t RecordSigGenerator_setRecordExposureOffsetTime(uint32_t us) override; virtual xs_error_code_t RecordSigGenerator_getRecordExposureOffsetTime(uint32_t &us) override; virtual xs_error_code_t RecordSigGenerator_getRecordState(uint32_t &state) override; virtual xs_error_code_t RecordSigGenerator_readTimecodeSnapshot(XsyncTimecode_t &timecode) override; xs_error_code_t TimecodeOutputModule_setBncOutputLevel(int level); // 0:line,1:mi overridec xs_error_code_t TimecodeOutputModule_getBncOutputLevel(int &level); xs_error_code_t TimecodeOutputModule_setHeadphoneOutputLevel(int level); // 0:line,1:mi overridec xs_error_code_t TimecodeOutputModule_getHeadphoneOutputLevel(int &level); virtual xs_error_code_t TTLOutputModule1_setSrcSigType(SignalType_t source) override; virtual xs_error_code_t TTLOutputModule1_getSrcSigType(SignalType_t &source) override; virtual xs_error_code_t TTLOutputModule1_setFreqDivision(uint32_t div) override; virtual xs_error_code_t TTLOutputModule1_getFreqDivision(uint32_t &div) override; virtual xs_error_code_t TTLOutputModule1_setFreqMultiplication(uint32_t multi) override; virtual xs_error_code_t TTLOutputModule1_getFreqMultiplication(uint32_t &multi) override; virtual xs_error_code_t TTLOutputModule1_readInFreq(float &freq) override; virtual xs_error_code_t TTLOutputModule1_readOutFreq(float &freq) override; virtual xs_error_code_t TTLOutputModule2_setSrcSigType(SignalType_t source) override; virtual xs_error_code_t TTLOutputModule2_getSrcSigType(SignalType_t &source) override; virtual xs_error_code_t TTLOutputModule2_setFreqDivision(uint32_t div) override; virtual xs_error_code_t TTLOutputModule2_getFreqDivision(uint32_t &div) override; virtual xs_error_code_t TTLOutputModule2_setFreqMultiplication(uint32_t multi) override; virtual xs_error_code_t TTLOutputModule2_getFreqMultiplication(uint32_t &multi) override; virtual xs_error_code_t TTLOutputModule2_readInFreq(float &freq) override; virtual xs_error_code_t TTLOutputModule2_readOutFreq(float &freq) override; virtual xs_error_code_t TTLOutputModule3_setSrcSigType(SignalType_t source) override; virtual xs_error_code_t TTLOutputModule3_getSrcSigType(SignalType_t &source) override; virtual xs_error_code_t TTLOutputModule3_setFreqDivision(uint32_t div) override; virtual xs_error_code_t TTLOutputModule3_getFreqDivision(uint32_t &div) override; virtual xs_error_code_t TTLOutputModule3_setFreqMultiplication(uint32_t multi) override; virtual xs_error_code_t TTLOutputModule3_getFreqMultiplication(uint32_t &multi) override; virtual xs_error_code_t TTLOutputModule3_readInFreq(float &freq) override; virtual xs_error_code_t TTLOutputModule3_readOutFreq(float &freq) override; virtual xs_error_code_t TTLOutputModule4_setSrcSigType(SignalType_t source) override; virtual xs_error_code_t TTLOutputModule4_getSrcSigType(SignalType_t &source) override; virtual xs_error_code_t TTLOutputModule4_setFreqDivision(uint32_t div) override; virtual xs_error_code_t TTLOutputModule4_getFreqDivision(uint32_t &div) override; virtual xs_error_code_t TTLOutputModule4_setFreqMultiplication(uint32_t multi) override; virtual xs_error_code_t TTLOutputModule4_getFreqMultiplication(uint32_t &multi) override; virtual xs_error_code_t TTLOutputModule4_readInFreq(float &freq) override; virtual xs_error_code_t TTLOutputModule4_readOutFreq(float &freq) override; private: xs_error_code_t doaction(uint32_t action, uint32_t actionval, uint32_t *ackreturn, int32_t overtime_ms = 100); xs_error_code_t storageConfig(); xs_error_code_t xsync_send_cmd_block(iflytop_xsync_packet_header_t *cmd, iflytop_xsync_packet_header_t *rx_data, int32_t buffersize, int32_t overtime_ms); xs_error_code_t readtimecode(uint32_t reg0, uint32_t reg1, XsyncTimecode_t &timecode); xs_error_code_t writetimecode(uint32_t reg0, uint32_t reg1, XsyncTimecode_t timecode); xs_error_code_t readfreq(uint32_t reg, float &freq); xs_error_code_t reg_write(uint32_t regadd, uint32_t regvalue, int32_t overtime_ms = 100); xs_error_code_t reg_read_muti(uint32_t regadd, uint32_t nreg, vector ®values, int32_t overtime_ms = 100); template xs_error_code_t _reg_read(uint32_t regadd, T ®value, int32_t overtime_ms = 100) { uint32_t regvalue_u32; xs_error_code_t ret = reg_read(regadd, regvalue_u32, overtime_ms); if (ret == kxs_ec_success) { regvalue = (T)regvalue_u32; } return ret; } void parseTimecodeMsgAndReport(XsyncNetAdd &from, uint8_t *data, size_t length); void parseCameraSyncMsgAndReport(XsyncNetAdd &from, uint8_t *data, size_t length); }; /******************************************************************************* * Xsync * *******************************************************************************/ Xsync::Xsync(/* args */) {} Xsync &Xsync::Ins() { static Xsync xsync; return xsync; } void Xsync::initialize(I_XSUDPFactory *xsync_udp_factory) { m_xsync_udp_factory = xsync_udp_factory; } xs_error_code_t Xsync::changeXsyncIp(string xsync_ip) { disConnect(); return connect(xsync_ip); } bool Xsync::ping() { uint32_t readbak; xs_error_code_t ecode = reg_read(reg::kproduct_type_id, readbak, 10); if (ecode != kxs_ec_success) { return false; } return true; } xs_error_code_t Xsync::connect(string xsync_ip) { lock_guard lock(lock_); m_xsync_ip = xsync_ip; disConnect(); /** * @brief 创建 m_xsync_reg_udp */ xs_error_code_t ecode = kxs_ec_success; auto xsync_reg_udp = m_xsync_udp_factory->createXSUDP(); ecode = xsync_reg_udp->initialize("0.0.0.0", IFLYTOP_XSYNC_SERVICE_PC_PORT); if (ecode != kxs_ec_success) { return ecode; } /** * @brief 创建 m_xsync_timecode_udp_listener */ auto xsync_timecode_udp_listener = m_xsync_udp_factory->createXSUDP(); ecode = xsync_timecode_udp_listener->initialize("0.0.0.0", IFLYTOP_XSYNC_TIMECODE_REPORT_PC_PORT); if (ecode != kxs_ec_success) { return ecode; } ecode = xsync_timecode_udp_listener->startReceive([this](XsyncNetAdd &from, uint8_t *data, size_t length) { parseTimecodeMsgAndReport(from, data, length); }); if (ecode != kxs_ec_success) { return ecode; } /** * @brief 创建 m_xsync_camera_sync_udp_listener */ auto xsync_camera_sync_udp_listener = m_xsync_udp_factory->createXSUDP(); ecode = xsync_camera_sync_udp_listener->initialize("0.0.0.0", IFLYTOP_XSYNC_CAMERA_SYNC_PACKET_PC_PORT); if (ecode != kxs_ec_success) { return ecode; } ecode = xsync_camera_sync_udp_listener->startReceive([this](XsyncNetAdd &from, uint8_t *data, size_t length) { parseCameraSyncMsgAndReport(from, data, length); }); if (ecode != kxs_ec_success) { return ecode; } m_xsync_reg_udp = xsync_reg_udp; m_xsync_timecode_udp_listener = xsync_timecode_udp_listener; m_xsync_camera_sync_udp_listener = xsync_camera_sync_udp_listener; return ecode; } xs_error_code_t Xsync::disConnect() { lock_guard lock(lock_); if (m_xsync_reg_udp != nullptr) { m_xsync_reg_udp->stopReceive(); m_xsync_reg_udp = nullptr; } if (m_xsync_timecode_udp_listener != nullptr) { m_xsync_timecode_udp_listener->stopReceive(); m_xsync_timecode_udp_listener = nullptr; } if (m_xsync_camera_sync_udp_listener != nullptr) { m_xsync_camera_sync_udp_listener->stopReceive(); m_xsync_camera_sync_udp_listener = nullptr; } return kxs_ec_success; } void Xsync::registerOnTimecodeMsgCallback(xsync_on_timecode_msg_t cb) { m_on_timecode_msg_cb = cb; } void Xsync::registerOnCameraSyncMsgCallback(xsync_on_camera_sync_msg_t cb) { m_on_camera_sync_msg_cb = cb; } void Xsync::registerOnRecordSigChangeMsgCallback(xsync_on_record_sig_change_msg_t cb) { m_on_record_sig_change_msg_cb = cb; } xs_error_code_t Xsync::readSn(string &sn) { sn = "X1001000000000"; return kxs_ec_success; } xs_error_code_t Xsync::readMac(string &mac) { // mac = ""; uint32_t mac0; uint32_t mac1; DO_XSYNC(reg_read(reg::kmac0, mac0)); DO_XSYNC(reg_read(reg::kmac1, mac1)); char buf[128] = {0}; sprintf(buf, "%02x-%02x-%02x-%02x-%02x-%02x", (mac0 >> 0) & 0xff, (mac0 >> 8) & 0xff, (mac0 >> 16) & 0xff, (mac0 >> 24) & 0xff, (mac1 >> 0) & 0xff, (mac1 >> 8) & 0xff); mac = buf; return kxs_ec_success; } xs_error_code_t Xsync::xsync_send_cmd_block(iflytop_xsync_packet_header_t *cmd, iflytop_xsync_packet_header_t *rx_data, int32_t buffersize, int32_t overtime_ms) { lock_guard lock(lock_); if (!m_xsync_reg_udp) return kxs_ec_lose_connect; m_xsync_reg_udp->clearRxBuffer(); cmd->index = txpacket_index++; XsyncNetAdd toadd = {m_xsync_ip, IFLYTOP_XSYNC_SERVICE_XSYNC_PORT}; xs_error_code_t ecode = // m_xsync_reg_udp->sendto(toadd, (const char *)cmd, sizeof(iflytop_xsync_packet_header_t) + cmd->ndata * 4, nullptr); if (ecode != kxs_ec_success) { return ecode; } XsyncNetAdd fromadd; while (true) { ecode = m_xsync_reg_udp->receive((char *)rx_data, buffersize, fromadd, overtime_ms); if (ecode != kxs_ec_success) { return ecode; } if (rx_data->index != cmd->index) { continue; } break; } return (xs_error_code_t)rx_data->data[0]; } xs_error_code_t Xsync::reg_write(uint32_t regadd, uint32_t regvalue, int32_t overtime_ms) { // uint32_t readbak = 0; return reg_write(regadd, regvalue, readbak, overtime_ms); } xs_error_code_t Xsync::reg_write(uint32_t regadd, uint32_t regvalue, uint32_t ®backvalue, int32_t overtime_ms) { /** * @brief * 协议说明 * * kxsync_packet_type_reg_write * tx: regadd,regdata * rx: ecode,regdata */ uint8_t txdata[128] = {0}; uint8_t rxdata[128] = {0}; iflytop_xsync_packet_header_t *txpacket = (iflytop_xsync_packet_header_t *)txdata; iflytop_xsync_packet_header_t *rxpacket = (iflytop_xsync_packet_header_t *)rxdata; txpacket->type = kxsync_packet_type_cmd; txpacket->index = txpacket_index++; txpacket->cmd = kxsync_packet_type_reg_write; txpacket->ndata = 2; txpacket->data[0] = regadd; txpacket->data[1] = regvalue; auto ecode = xsync_send_cmd_block(txpacket, rxpacket, sizeof(rxdata), overtime_ms); if (ecode != kxs_ec_success) { return ecode; } regbackvalue = rxpacket->data[1]; return ecode; } xs_error_code_t Xsync::reg_read(uint32_t regadd, uint32_t ®value, int32_t overtime_ms) { /** * @brief * 协议说明 * * kxsync_packet_type_reg_write * tx: regadd,regdata * rx: ecode,regdata */ uint8_t txdata[128] = {0}; uint8_t rxdata[128] = {0}; iflytop_xsync_packet_header_t *txpacket = (iflytop_xsync_packet_header_t *)txdata; iflytop_xsync_packet_header_t *rxpacket = (iflytop_xsync_packet_header_t *)rxdata; txpacket->type = kxsync_packet_type_cmd; txpacket->index = txpacket_index++; txpacket->cmd = kxsync_packet_type_reg_read; txpacket->ndata = 2; txpacket->data[0] = regadd; txpacket->data[1] = regvalue; auto ecode = xsync_send_cmd_block(txpacket, rxpacket, sizeof(rxdata), overtime_ms); if (ecode != kxs_ec_success) { return ecode; } regvalue = rxpacket->data[1]; return ecode; } xs_error_code_t Xsync::reg_read_muti(uint32_t regadd, uint32_t nreg, vector ®values, int32_t overtime_ms) { /** * @brief * 协议说明 * * kxsync_packet_type_reg_read_regs * tx: regstartadd,nreg * rx: ecode,regdatas */ uint8_t txdata[128] = {0}; uint8_t rxdata[1280] = {0}; iflytop_xsync_packet_header_t *txpacket = (iflytop_xsync_packet_header_t *)txdata; iflytop_xsync_packet_header_t *rxpacket = (iflytop_xsync_packet_header_t *)rxdata; txpacket->type = kxsync_packet_type_cmd; txpacket->index = txpacket_index++; txpacket->cmd = kxsync_packet_type_reg_read_regs; txpacket->ndata = 2; txpacket->data[0] = regadd; txpacket->data[1] = nreg; auto ecode = xsync_send_cmd_block(txpacket, rxpacket, sizeof(rxdata), overtime_ms); if (ecode != kxs_ec_success) { return ecode; } if (rxpacket->ndata > 0) { for (int i = 0; i < rxpacket->ndata - 1; i++) { regvalues.push_back(rxpacket->data[i + 1]); } } return ecode; } xs_error_code_t Xsync::readtimecode(uint32_t reg0, uint32_t reg1, XsyncTimecode_t &timecode) { uint32_t readbak = 0; xs_error_code_t ecode = kxs_ec_success; uint32_t tc0 = 0; uint32_t tc1 = 0; ecode = reg_read(reg0, tc0, 10); if (ecode != kxs_ec_success) return ecode; ecode = reg_read(reg1, tc1, 10); if (ecode != kxs_ec_success) return ecode; Timecode64_t tc64; tc64.tc0 = tc0; tc64.tc1 = tc1; timecode = timecode64ToXsyncTimeCode(tc64); return ecode; } xs_error_code_t Xsync::writetimecode(uint32_t reg0, uint32_t reg1, XsyncTimecode_t timecode) { uint32_t readbak = 0; xs_error_code_t ecode = kxs_ec_success; Timecode64_t tc64 = timecodeTo64(timecode); ecode = reg_write(reg0, tc64.tc0, readbak, 10); if (ecode != kxs_ec_success) return ecode; ecode = reg_write(reg1, tc64.tc1, readbak, 10); if (ecode != kxs_ec_success) return ecode; return ecode; } xs_error_code_t Xsync::readfreq(uint32_t reg, float &freqfloat) { uint32_t freq_cnt = 0; DO_XSYNC(reg_read(reg, freq_cnt)); if (freq_cnt == 0) { freqfloat = 0; } if (freq_cnt != 0) { uint32_t freq_1000x = ((1.0 / (freq_cnt * 1.0 / (10 * 1000 * 1000))) * 1000 + 0.5); //+0.5是因为c++ 小数强转成整数时是取整，而非四舍五入 // ZLOGI(TAG, "freq_10x %f", freq_10x); freqfloat = freq_1000x / 1000.0; } else { freqfloat = 0; } return kxs_ec_success; } void Xsync::parseTimecodeMsgAndReport(XsyncNetAdd &from, uint8_t *data, size_t length) { iflytop_xsync_event_report_packet_t *packet = (iflytop_xsync_event_report_packet_t *)data; if (packet->eventid == ktimecode_report_event) { Timecode64_t tc64; tc64.tc0 = packet->data[0]; tc64.tc1 = packet->data[1]; XsyncTimecode_t timecode = timecode64ToXsyncTimeCode(tc64); if (m_on_timecode_msg_cb) m_on_timecode_msg_cb(&timecode); } else if (packet->eventid == kxsync_work_state_report_event) { // 信号发生器状态改变 Timecode64_t tc64; tc64.tc0 = packet->data[1]; tc64.tc1 = packet->data[2]; XsyncTimecode_t timecode = timecode64ToXsyncTimeCode(tc64); if (m_on_record_sig_change_msg_cb) m_on_record_sig_change_msg_cb(packet->data[0], &timecode); } } void Xsync::parseCameraSyncMsgAndReport(XsyncNetAdd &from, uint8_t *data, size_t length) { uint32_t count = 0; uint32_t data0 = data[7]; uint32_t data1 = data[6]; uint32_t data2 = data[5]; uint32_t data3 = data[4]; count = data0 + (data1 << 8) + (data2 << 16) + (data3 << 24); xysnc_camera_sync_data_t camera_sync_data; camera_sync_data.frameIndex = count; if (m_on_camera_sync_msg_cb) m_on_camera_sync_msg_cb(&camera_sync_data); } xs_error_code_t Xsync::generatorNewMac() { return doaction(xsync_stm32_action_generator_new_mac, 0, nullptr, 2000); } xs_error_code_t Xsync::factoryReset() { return doaction(xsync_stm32_action_factory_reset, 0, nullptr, 1000); } xs_error_code_t Xsync::reboot() { return doaction(xsync_stm32_action_reboot, 0, nullptr); } xs_error_code_t Xsync::storageConfig() { return doaction(xsync_stm32_action_storage_cfg, 0, nullptr, 1000); } xs_error_code_t Xsync::changeNetworkConfig(string ip, string mask, string gateway) { uint32_t ip32 = 0; uint32_t mask32 = 0; uint32_t gateway32 = 0; xs_error_code_t ecode; bool suc = false; ip32 = (uint32_t)ipToUint32(ip.c_str(), suc); if (!suc) return kxs_ec_param_error; mask32 = (uint32_t)ipToUint32(mask.c_str(), suc); if (!suc) return kxs_ec_param_error; gateway32 = (uint32_t)ipToUint32(gateway.c_str(), suc); if (!suc) return kxs_ec_param_error; uint32_t readbak = 0; ecode = reg_write(reg::kstm32_ip, ip32, readbak); if (ecode != kxs_ec_success) return ecode; ecode = reg_write(reg::kstm32_netmask, mask32, readbak); if (ecode != kxs_ec_success) return ecode; ecode = reg_write(reg::kstm32_gw, gateway32, readbak); if (ecode != kxs_ec_success) return ecode; ecode = storageConfig(); if (ecode != kxs_ec_success) return ecode; return kxs_ec_success; } xs_error_code_t Xsync::doaction(uint32_t action, uint32_t actionval, uint32_t *ackreturn, int32_t overtime_ms) { // uint32_t readbak = 0; xs_error_code_t ecode; ecode = reg_write(reg::kstm32_action_val0, actionval, readbak); if (ecode != kxs_ec_success) return ecode; ecode = reg_write(reg::kstm32_action0, action, readbak, overtime_ms); if (ecode != kxs_ec_success) return ecode; if (ackreturn) *ackreturn = readbak; return ecode; } /******************************************************************************* * TTLInputModule * *******************************************************************************/ #define FREQ_CNT_TO_FREQ(cnt) ((cnt != 0) ? (uint32_t)(1.0 / (cnt * 1.0 / (10 * 1000 * 1000)) + 0.5) : 0) //+0.5是因为c++ 小数强转成整数时是取整，而非四舍五入 xs_error_code_t Xsync::TTLInputModule1_detectFreq(float &freq) { return readfreq(reg::k_ttlin1_freq_detector_reg, freq); } xs_error_code_t Xsync::TTLInputModule2_detectFreq(float &freq) { return readfreq(reg::k_ttlin2_freq_detector_reg, freq); } xs_error_code_t Xsync::TTLInputModule3_detectFreq(float &freq) { return readfreq(reg::k_ttlin3_freq_detector_reg, freq); } xs_error_code_t Xsync::TTLInputModule4_detectFreq(float &freq) { return readfreq(reg::k_ttlin4_freq_detector_reg, freq); } /******************************************************************************* * TTLOutputModule * *******************************************************************************/ // 0:固定输出低电平，1:固定输出高电平，2:分频倍频模式，3:转发模式，4:测试模式 xs_error_code_t Xsync::TTLOutputModule1_setSrcSigType(SignalType_t source) { if (source != SIGNAL_LOGIC0 && // source != SIGNAL_LOGIC1 && // source != SIGNAL_TTLIN1 && // source != SIGNAL_TTLIN2 && // source != SIGNAL_TTLIN3 && // source != SIGNAL_TTLIN4 && // source != SIGNAL_SYS_CLK_OUTPUT && // source != SIGNAL_SYS_GENLOCK_OUTPUT && // source != SIGNAL_SYS_TIMECODE_FREQ_OUTPUT && // source != SIGNAL_BUSINESS_RECORD_SIG && // source != SIGNAL_BUSINESS_RECORD_EXPOSURE_SIG // ) { return kxs_ec_param_error; } if (source == SIGNAL_TTLIN1 || // source == SIGNAL_TTLIN2 || // source == SIGNAL_TTLIN3 || // source == SIGNAL_TTLIN4 || // source == SIGNAL_SYS_CLK_OUTPUT || // source == SIGNAL_SYS_GENLOCK_OUTPUT || // source == SIGNAL_SYS_TIMECODE_FREQ_OUTPUT // ) { DO_XSYNC(reg_write(reg::kreg_ttlout1_signal_process_mode, 2, 10)); // 分频倍频模式 } else { DO_XSYNC(reg_write(reg::kreg_ttlout1_signal_process_mode, 3, 10)); // 转发模式 } REG_WRITE(reg::kreg_ttlout1_input_signal_select, source); } xs_error_code_t Xsync::TTLOutputModule2_setSrcSigType(SignalType_t source) { if (source != SIGNAL_LOGIC0 && // source != SIGNAL_LOGIC1 && // source != SIGNAL_TTLIN1 && // source != SIGNAL_TTLIN2 && // source != SIGNAL_TTLIN3 && // source != SIGNAL_TTLIN4 && // source != SIGNAL_SYS_CLK_OUTPUT && // source != SIGNAL_SYS_GENLOCK_OUTPUT && // source != SIGNAL_SYS_TIMECODE_FREQ_OUTPUT && // source != SIGNAL_BUSINESS_RECORD_SIG && // source != SIGNAL_BUSINESS_RECORD_EXPOSURE_SIG // ) { return kxs_ec_param_error; } if (source == SIGNAL_TTLIN1 || // source == SIGNAL_TTLIN2 || // source == SIGNAL_TTLIN3 || // source == SIGNAL_TTLIN4 || // source == SIGNAL_SYS_CLK_OUTPUT || // source == SIGNAL_SYS_GENLOCK_OUTPUT || // source == SIGNAL_SYS_TIMECODE_FREQ_OUTPUT // ) { DO_XSYNC(reg_write(reg::kreg_ttlout2_signal_process_mode, 2, 10)); // 分频倍频模式 } else { DO_XSYNC(reg_write(reg::kreg_ttlout2_signal_process_mode, 3, 10)); // 转发模式 } REG_WRITE(reg::kreg_ttlout2_input_signal_select, source); } xs_error_code_t Xsync::TTLOutputModule3_setSrcSigType(SignalType_t source) { if (source != SIGNAL_LOGIC0 && // source != SIGNAL_LOGIC1 && // source != SIGNAL_TTLIN1 && // source != SIGNAL_TTLIN2 && // source != SIGNAL_TTLIN3 && // source != SIGNAL_TTLIN4 && // source != SIGNAL_SYS_CLK_OUTPUT && // source != SIGNAL_SYS_GENLOCK_OUTPUT && // source != SIGNAL_SYS_TIMECODE_FREQ_OUTPUT && // source != SIGNAL_BUSINESS_RECORD_SIG && // source != SIGNAL_BUSINESS_RECORD_EXPOSURE_SIG // ) { return kxs_ec_param_error; } if (source == SIGNAL_TTLIN1 || // source == SIGNAL_TTLIN2 || // source == SIGNAL_TTLIN3 || // source == SIGNAL_TTLIN4 || // source == SIGNAL_SYS_CLK_OUTPUT || // source == SIGNAL_SYS_GENLOCK_OUTPUT || // source == SIGNAL_SYS_TIMECODE_FREQ_OUTPUT // ) { DO_XSYNC(reg_write(reg::kreg_ttlout3_signal_process_mode, 2, 10)); // 分频倍频模式 } else { DO_XSYNC(reg_write(reg::kreg_ttlout3_signal_process_mode, 3, 10)); // 转发模式 } REG_WRITE(reg::kreg_ttlout3_input_signal_select, source); } xs_error_code_t Xsync::TTLOutputModule4_setSrcSigType(SignalType_t source) { if (source != SIGNAL_LOGIC0 && // source != SIGNAL_LOGIC1 && // source != SIGNAL_TTLIN1 && // source != SIGNAL_TTLIN2 && // source != SIGNAL_TTLIN3 && // source != SIGNAL_TTLIN4 && // source != SIGNAL_SYS_CLK_OUTPUT && // source != SIGNAL_SYS_GENLOCK_OUTPUT && // source != SIGNAL_SYS_TIMECODE_FREQ_OUTPUT && // source != SIGNAL_BUSINESS_RECORD_SIG && // source != SIGNAL_BUSINESS_RECORD_EXPOSURE_SIG // ) { return kxs_ec_param_error; } if (source == SIGNAL_TTLIN1 || source == SIGNAL_TTLIN2 || source == SIGNAL_TTLIN3 || source == SIGNAL_TTLIN4) { DO_XSYNC(reg_write(reg::kreg_ttlout4_signal_process_mode, 2, 10)); // 分频倍频模式 } else { DO_XSYNC(reg_write(reg::kreg_ttlout4_signal_process_mode, 3, 10)); // 转发模式 } REG_WRITE(reg::kreg_ttlout4_input_signal_select, source); } xs_error_code_t Xsync::TTLOutputModule1_getSrcSigType(SignalType_t &source) { REG_READ(reg::kreg_ttlout1_input_signal_select, source); } xs_error_code_t Xsync::TTLOutputModule2_getSrcSigType(SignalType_t &source) { REG_READ(reg::kreg_ttlout2_input_signal_select, source); } xs_error_code_t Xsync::TTLOutputModule3_getSrcSigType(SignalType_t &source) { REG_READ(reg::kreg_ttlout3_input_signal_select, source); } xs_error_code_t Xsync::TTLOutputModule4_getSrcSigType(SignalType_t &source) { REG_READ(reg::kreg_ttlout4_input_signal_select, source); } xs_error_code_t Xsync::TTLOutputModule1_setFreqDivision(uint32_t div) { REG_WRITE(reg::kreg_ttlout1_pllout_freq_division_ctrl, div); } xs_error_code_t Xsync::TTLOutputModule2_setFreqDivision(uint32_t div) { REG_WRITE(reg::kreg_ttlout2_pllout_freq_division_ctrl, div); } xs_error_code_t Xsync::TTLOutputModule3_setFreqDivision(uint32_t div) { REG_WRITE(reg::kreg_ttlout3_pllout_freq_division_ctrl, div); } xs_error_code_t Xsync::TTLOutputModule4_setFreqDivision(uint32_t div) { REG_WRITE(reg::kreg_ttlout4_pllout_freq_division_ctrl, div); } xs_error_code_t Xsync::TTLOutputModule1_getFreqDivision(uint32_t &div) { REG_READ(reg::kreg_ttlout1_pllout_freq_division_ctrl, div); } xs_error_code_t Xsync::TTLOutputModule2_getFreqDivision(uint32_t &div) { REG_READ(reg::kreg_ttlout2_pllout_freq_division_ctrl, div); } xs_error_code_t Xsync::TTLOutputModule3_getFreqDivision(uint32_t &div) { REG_READ(reg::kreg_ttlout3_pllout_freq_division_ctrl, div); } xs_error_code_t Xsync::TTLOutputModule4_getFreqDivision(uint32_t &div) { REG_READ(reg::kreg_ttlout4_pllout_freq_division_ctrl, div); } xs_error_code_t Xsync::TTLOutputModule1_setFreqMultiplication(uint32_t multi) { REG_WRITE(reg::kreg_ttlout1_pllout_freq_multiplication_ctrl, multi); } xs_error_code_t Xsync::TTLOutputModule2_setFreqMultiplication(uint32_t multi) { REG_WRITE(reg::kreg_ttlout2_pllout_freq_multiplication_ctrl, multi); } xs_error_code_t Xsync::TTLOutputModule3_setFreqMultiplication(uint32_t multi) { REG_WRITE(reg::kreg_ttlout3_pllout_freq_multiplication_ctrl, multi); } xs_error_code_t Xsync::TTLOutputModule4_setFreqMultiplication(uint32_t multi) { REG_WRITE(reg::kreg_ttlout4_pllout_freq_multiplication_ctrl, multi); } xs_error_code_t Xsync::TTLOutputModule1_getFreqMultiplication(uint32_t &multi) { REG_READ(reg::kreg_ttlout1_pllout_freq_multiplication_ctrl, multi); } xs_error_code_t Xsync::TTLOutputModule2_getFreqMultiplication(uint32_t &multi) { REG_READ(reg::kreg_ttlout2_pllout_freq_multiplication_ctrl, multi); } xs_error_code_t Xsync::TTLOutputModule3_getFreqMultiplication(uint32_t &multi) { REG_READ(reg::kreg_ttlout3_pllout_freq_multiplication_ctrl, multi); } xs_error_code_t Xsync::TTLOutputModule4_getFreqMultiplication(uint32_t &multi) { REG_READ(reg::kreg_ttlout4_pllout_freq_multiplication_ctrl, multi); } xs_error_code_t Xsync::TTLOutputModule1_readInFreq(float &freq) { return readfreq(reg::kreg_ttlout1_sig_in_freq_detect, freq); } xs_error_code_t Xsync::TTLOutputModule2_readInFreq(float &freq) { return readfreq(reg::kreg_ttlout2_sig_in_freq_detect, freq); } xs_error_code_t Xsync::TTLOutputModule3_readInFreq(float &freq) { return readfreq(reg::kreg_ttlout3_sig_in_freq_detect, freq); } xs_error_code_t Xsync::TTLOutputModule4_readInFreq(float &freq) { return readfreq(reg::kreg_ttlout4_sig_in_freq_detect, freq); } xs_error_code_t Xsync::TTLOutputModule1_readOutFreq(float &freq) { return readfreq(reg::kreg_ttlout1_sig_out_freq_detect, freq); } xs_error_code_t Xsync::TTLOutputModule2_readOutFreq(float &freq) { return readfreq(reg::kreg_ttlout2_sig_out_freq_detect, freq); } xs_error_code_t Xsync::TTLOutputModule3_readOutFreq(float &freq) { return readfreq(reg::kreg_ttlout3_sig_out_freq_detect, freq); } xs_error_code_t Xsync::TTLOutputModule4_readOutFreq(float &freq) { return readfreq(reg::kreg_ttlout4_sig_out_freq_detect, freq); } /******************************************************************************* * TimecodeInputModule * *******************************************************************************/ xs_error_code_t Xsync::ExternalTimecode_setSource(InputInterface_t src) { if (src == INPUT_IF_TIMECODE_BNC) { DO_XSYNC(reg_write(reg::external_timecode_sig_selt, 1, 10)); // 0:off,1:bnc,2:headphone } else if (src == INPUT_IF_TIMECODE_HEADPHONE) { DO_XSYNC(reg_write(reg::external_timecode_sig_selt, 2, 10)); // 0:off,1:bnc,2:headphone } else if (src == INPUT_IF_OFF) { DO_XSYNC(reg_write(reg::external_timecode_sig_selt, 0, 10)); // 0:off,1:bnc,2:headphone } else { return kxs_ec_param_error; } return kxs_ec_success; } xs_error_code_t Xsync::ExternalTimecode_getSource(InputInterface_t &timecode_select) { uint32_t readbak = 0; DO_XSYNC(reg_read(reg::external_timecode_sig_selt, readbak, 10)); if (readbak == 1) { timecode_select = INPUT_IF_TIMECODE_BNC; } else if (readbak == 2) { timecode_select = INPUT_IF_TIMECODE_HEADPHONE; } else if (readbak == 0) { timecode_select = INPUT_IF_OFF; } else { timecode_select = INPUT_IF_OFF; } return kxs_ec_success; } xs_error_code_t Xsync::ExternalTimecode_setFormat(TimecodeFormat_t format) { REG_WRITE(reg::external_timecode_format, format); } xs_error_code_t Xsync::ExternalTimecode_getFormat(TimecodeFormat_t &format) { REG_READ(reg::external_timecode_format, format); } xs_error_code_t Xsync::ExternalTimecode_readCode(XsyncTimecode_t &timecode) { return readtimecode(reg::external_timecode_code0, reg::external_timecode_code1, timecode); } /******************************************************************************* * InternalTimecode * *******************************************************************************/ xs_error_code_t Xsync::InternalTimecode_setFormat(TimecodeFormat_t format) { REG_WRITE(reg::internal_timecode_format, format); } xs_error_code_t Xsync::InternalTimecode_getFormat(TimecodeFormat_t &format) { REG_READ(reg::internal_timecode_format, format); } xs_error_code_t Xsync::InternalTimecode_setCode(XsyncTimecode_t timecode) { DO_XSYNC(reg_write(reg::internal_timecode_en, 0)); DO_XSYNC(writetimecode(reg::internal_timecode_data0, reg::internal_timecode_data1, timecode)); DO_XSYNC(reg_write(reg::internal_timecode_en, 1)); return kxs_ec_success; } xs_error_code_t Xsync::InternalTimecode_getCode(XsyncTimecode_t &timecode) { return readtimecode(reg::internal_timecode_data0, reg::internal_timecode_data1, timecode); } /******************************************************************************* * SysTimecode * *******************************************************************************/ xs_error_code_t Xsync::SysTimecode_setSource(uint32_t sig) { REG_WRITE(reg::sys_timecode_select, sig); } xs_error_code_t Xsync::SysTimecode_getSource(uint32_t &sig) { REG_READ(reg::sys_timecode_select, sig); } xs_error_code_t Xsync::SysTimecode_readFormat(TimecodeFormat_t &format) { REG_READ(reg::sys_timecode_format, format); } xs_error_code_t Xsync::SysTimecode_readCode(XsyncTimecode_t &timecode) { return readtimecode(reg::sys_timecode_data0, reg::sys_timecode_data1, timecode); } /******************************************************************************* * TimecodeOutputModule * *******************************************************************************/ xs_error_code_t Xsync::TimecodeOutputModule_setBncOutputLevel(int level) { REG_WRITE(reg::timecode_output_bnc_outut_level_select, level); } xs_error_code_t Xsync::TimecodeOutputModule_getBncOutputLevel(int &level) { REG_READ(reg::timecode_output_bnc_outut_level_select, level); } xs_error_code_t Xsync::TimecodeOutputModule_setHeadphoneOutputLevel(int level) { REG_WRITE(reg::timecode_output_headphone_outut_level_select, level); } xs_error_code_t Xsync::TimecodeOutputModule_getHeadphoneOutputLevel(int &level) { REG_READ(reg::timecode_output_headphone_outut_level_select, level); } /******************************************************************************* * GENLOCK * *******************************************************************************/ xs_error_code_t Xsync::ExternalGenlock_detectFreq(float &freq) { return readfreq(reg::external_genlock_freq, freq); } xs_error_code_t Xsync::InternalGenlock_setFormat(GenlockFormat_t format) { return reg_write(reg::internal_genlock_format, format); } xs_error_code_t Xsync::InternalGenlock_getFormat(GenlockFormat_t &format) { REG_READ(reg::internal_genlock_format, format); } xs_error_code_t Xsync::SysGenlock_setSrc(uint32_t source) { return reg_write(reg::sys_genlock_source, source); } xs_error_code_t Xsync::SysGenlock_getSrc(uint32_t &extern_or_internal) { REG_READ(reg::sys_genlock_source, extern_or_internal); return kxs_ec_success; } xs_error_code_t Xsync::SysGenlock_readFreq(float &freq) { return readfreq(reg::sys_genlock_freq, freq); } /******************************************************************************* * INTERNAL_CLOCK * *******************************************************************************/ xs_error_code_t Xsync::InternalClock_setFreq(float freq) { double T = 1.0 / freq; double T_ns = T * 1000 * 1000 * 1000; double cnt = T_ns / 100 + 0.5; // 10MHZ <=> 100ns uint32_t cnt_u32 = uint32_t(cnt); return reg_write(reg::internal_clock_freq, cnt_u32); return kxs_ec_success; } xs_error_code_t Xsync::InternalClock_getFreq(float &freq) { return readfreq(reg::internal_clock_freq, freq); } /******************************************************************************* * SysClock * *******************************************************************************/ xs_error_code_t Xsync::SysClock_setSrc(SignalType_t sig) { if (sig != SIGNAL_TTLIN1 && // sig != SIGNAL_TTLIN2 && // sig != SIGNAL_TTLIN3 && // sig != SIGNAL_TTLIN4 && // sig != SIGNAL_SYS_CLK_OUTPUT && // sig != SIGNAL_SYS_GENLOCK_OUTPUT && // sig != SIGNAL_SYS_TIMECODE_FREQ_OUTPUT) { return kxs_ec_param_error; } return reg_write(reg::sys_clock_source, sig); } xs_error_code_t Xsync::SysClock_getSrc(SignalType_t &sig) { REG_READ(reg::sys_clock_source, sig); } xs_error_code_t Xsync::SysClock_setTriggerEdge(TriggerEdge_t edge) { if (edge != TRIGGER_EDGE_RISING && edge != TRIGGER_EDGE_FALLING) { return kxs_ec_param_error; } return reg_write(reg::sys_clock_trigger_edge_select, edge); } xs_error_code_t Xsync::SysClock_getTriggerEdge(TriggerEdge_t &edge) { return _reg_read(reg::sys_clock_trigger_edge_select, edge); } xs_error_code_t Xsync::SysClock_setFreqDivision(uint32_t div) { return reg_write(reg::sys_clock_freq_division_ctrl, div); } xs_error_code_t Xsync::SysClock_geFreqtDivision(uint32_t &div) { return _reg_read(reg::sys_clock_freq_division_ctrl, div); } xs_error_code_t Xsync::SysClock_setFreqMultiplication(uint32_t muti) { return reg_write(reg::sys_clock_freq_multiplication_ctrl, muti); } xs_error_code_t Xsync::SysClock_getFreqMultiplication(uint32_t &muti) { return _reg_read(reg::sys_clock_freq_multiplication_ctrl, muti); } xs_error_code_t Xsync::SysClock_readOutSigFreq(float &freq) { return readfreq(reg::sys_clock_outfreq_detect, freq); } xs_error_code_t Xsync::SysClock_readInSigFreq(float &freq) { return readfreq(reg::sys_clock_infreq_detect, freq); } xs_error_code_t Xsync::RecordSigGenerator_setContrlMode(ControlMode_t mode) { if (mode != CONTROLMODE_MANUAL_TRIGGER && mode != CONTROLMODE_TIMECODE_TRIGGER && mode != CONTROLMODE_EXTERNALTTL_TRIGGER) { return kxs_ec_param_error; } return reg_write(reg::record_sig_gen_ctrl_control_mode, mode); } xs_error_code_t Xsync::RecordSigGenerator_getContrlMode(ControlMode_t &mode) { // return _reg_read(reg::record_sig_gen_ctrl_control_mode, mode); } xs_error_code_t Xsync::RecordSigGenerator_manualStart() { return reg_write(reg::record_sig_gen_manual_ctrl, 1, 10); } xs_error_code_t Xsync::RecordSigGenerator_manualStop() { return reg_write(reg::record_sig_gen_manual_ctrl, 0, 10); } xs_error_code_t Xsync::RecordSigGenerator_setAutoStartTimecode(XsyncTimecode_t timecode) { // return writetimecode(reg::record_sig_gen_timecode_start0, reg::record_sig_gen_timecode_start1, timecode); } xs_error_code_t Xsync::RecordSigGenerator_setAutoStopTimecode(XsyncTimecode_t timecode) { // return writetimecode(reg::record_sig_gen_timecode_stop0, reg::record_sig_gen_timecode_stop1, timecode); } xs_error_code_t Xsync::RecordSigGenerator_getAutoStartTimecode(XsyncTimecode_t &timecode) { // return readtimecode(reg::record_sig_gen_timecode_start0, reg::record_sig_gen_timecode_start1, timecode); } xs_error_code_t Xsync::RecordSigGenerator_getAutoStopTimecode(XsyncTimecode_t &timecode) { return readtimecode(reg::record_sig_gen_timecode_stop0, reg::record_sig_gen_timecode_stop1, timecode); } xs_error_code_t Xsync::RecordSigGenerator_setExternalTTLTriggerSrc(InputInterface_t ttlPortNum) { if (ttlPortNum != INPUT_IF_TTL1 && ttlPortNum != INPUT_IF_TTL2 && ttlPortNum != INPUT_IF_TTL3 && ttlPortNum != INPUT_IF_TTL4) { return kxs_ec_param_error; } return reg_write(reg::record_sig_gen_ttlin_trigger_sig_source, ttlPortNum); } xs_error_code_t Xsync::RecordSigGenerator_getExternalTTLTriggerSrc(InputInterface_t &ttlPortNum) { // return _reg_read(reg::record_sig_gen_ttlin_trigger_sig_source, ttlPortNum); } xs_error_code_t Xsync::RecordSigGenerator_setExternalTTLTriggerPolarity(uint32_t polarity) { // return reg_write(reg::record_sig_gen_ttlin_trigger_level, polarity); } xs_error_code_t Xsync::RecordSigGenerator_getExternalTTLTriggerPolarity(uint32_t &polarity) { // return _reg_read(reg::record_sig_gen_ttlin_trigger_level, polarity); } xs_error_code_t Xsync::RecordSigGenerator_setRecordExposureTime(uint32_t us) { // return reg_write(reg::record_sig_gen_exposure_time, us); } xs_error_code_t Xsync::RecordSigGenerator_getRecordExposureTime(uint32_t &us) { auto ret = reg_read(reg::record_sig_gen_exposure_time, us); // us = us / 10;1 return ret; } xs_error_code_t Xsync::RecordSigGenerator_setRecordExposureOffsetTime(uint32_t us) { return reg_write(reg::record_sig_gen_exposure_offset_time, us); } xs_error_code_t Xsync::RecordSigGenerator_getRecordExposureOffsetTime(uint32_t &us) { auto ret = reg_read(reg::record_sig_gen_exposure_offset_time, us); // us = us / 10; return ret; } xs_error_code_t Xsync::RecordSigGenerator_setTimecodeCtrlFlag(uint32_t autoStart, uint32_t autoStop) { // uint32_t flag = (autoStart & 0x01) | ((autoStop & 0x01) << 1); return reg_write(reg::record_sig_gen_timecode_control_flag, flag); } xs_error_code_t Xsync::RecordSigGenerator_getTimecodeCtrlFlag(uint32_t &autoStart, uint32_t &autoStop) { uint32_t flag = 0; auto ret = reg_read(reg::record_sig_gen_timecode_control_flag, flag); autoStart = flag & 0x01; autoStop = (flag >> 1) & 0x01; return ret; } xs_error_code_t Xsync::RecordSigGenerator_getRecordState(uint32_t &state) { return _reg_read(reg::record_sig_gen_record_state, state); } xs_error_code_t Xsync::RecordSigGenerator_readTimecodeSnapshot(XsyncTimecode_t &timecode) { // return readtimecode(reg::record_sig_gen_timecode_snapshot0, reg::record_sig_gen_timecode_snapshot1, timecode); } namespace xsync { void XsyncInit(I_XSUDPFactory *xsync_udp_factory, string xsyncIp) { Xsync::Ins().initialize(xsync_udp_factory); Xsync::Ins().changeXsyncIp(xsyncIp); } IXsync *XsyncIns() { return &Xsync::Ins(); } } // namespace xsync