WLG/jsonparse/cmt_parse.cpp

#include "communication_cmd.hpp"
#include "localserver/local_server.hpp"
#include "common/common_func.hpp"
#include "common/global.hpp"
#include <boost/algorithm/string.hpp>
#include "dbaccess/sql_db.hpp"
#include "scheduler/schedule.hpp"
#include "zlog.h"

extern zlog_category_t *zct;

char *JsonData::CmtCmd_80(int& return_length)
{
    zlog_info(zct,"CmtCmd_80");
    GatewayVersion gateway_ver;
    memcpy(gateway_ver.mac,GlobalConfig::MacAddr_G.c_str(),sizeof(gateway_ver.mac));
    memcpy(gateway_ver.web_ver,ReadStrByOpt(SYSTEMINFOFILE, "Version", "WebVersion").c_str(),sizeof(gateway_ver.web_ver));
    memcpy(gateway_ver.system_ver,ReadStrByOpt(SYSTEMINFOFILE, "Version", "SystemVersion").c_str(),sizeof(gateway_ver.system_ver));
    memcpy(gateway_ver.gateway_ver,ReadStrByOpt(SYSTEMINFOFILE, "Version", "GateWayVersion").c_str(),sizeof(gateway_ver.gateway_ver));
    memcpy(gateway_ver.localIP,GlobalConfig::IpAddr_G.c_str(),sizeof(gateway_ver.localIP));
    memcpy(gateway_ver.gateway_type,ReadStrByOpt(SYSTEMINFOFILE, "Version", "GateWayProduct").c_str(),sizeof(gateway_ver.gateway_type));
    memcpy(gateway_ver.geteway_hw_ver,ReadStrByOpt(SYSTEMINFOFILE, "Version", "GateWayHwVesion").c_str(),sizeof(gateway_ver.geteway_hw_ver));
#ifdef  NR5G_MODULE
    memcpy(gateway_ver.comm_mode,"5G",sizeof(gateway_ver.comm_mode));
#endif
#ifdef  Q4G_MODULE
    memcpy(gateway_ver.comm_mode,"4G",sizeof(gateway_ver.comm_mode));
#endif
#ifdef  WIFI_MODULE
    memcpy(gateway_ver.comm_mode,"WiFi",sizeof(gateway_ver.comm_mode));
#endif
    memcpy(gateway_ver.comm_mode,"有线",sizeof(gateway_ver.comm_mode));
    GetSysStatusCMT(gateway_ver.cpu_use,gateway_ver.memory_use,gateway_ver.harddisk_remain,gateway_ver.temperature);
    char *retData = NULL;
    retData = (char*)malloc(sizeof(GatewayVersion));
    memcpy(retData,&gateway_ver,sizeof(GatewayVersion));
    return_length = sizeof(GatewayVersion);
    return retData;
}

char *JsonData::CmtCmd_81(int& return_length)
{
    int featureInterVal;
    int featureInterTime;
    int waveInterVal;
    int waveInterTime;
    int maxSensorNum;
    int sensorCount;
    char *retData = NULL;
    array_t arrRes;
    arrRes = sqlite_db_ctrl::instance().GetDataMultiLineTransaction(T_SENSOR_INFO(TNAME), "*", NULL);
    int iResult = arrRes.size();
    size_t j = 0;
    if (iResult > 0) {
        SensorInfo sensor_info[iResult];
        for (; j < iResult; j++)
        {
            memcpy(sensor_info[j].mac,arrRes[j][44].c_str(),sizeof(sensor_info[j].mac));
            memcpy(sensor_info[j].short_addr,arrRes[j][30].c_str(),sizeof(sensor_info[j].short_addr));
            memcpy(sensor_info[j].hw_ver,arrRes[j][8].c_str(),sizeof(sensor_info[j].hw_ver));
            memcpy(sensor_info[j].soft_ver,arrRes[j][9].c_str(),sizeof(sensor_info[j].soft_ver));
            std::vector<std::string> vParamRSSI;
            boost::split(vParamRSSI, arrRes[j][40], boost::is_any_of(","), boost::token_compress_on);
            if (vParamRSSI.size() > 1) {
                memcpy(sensor_info[j].sensor_rssi,vParamRSSI[0].c_str(),sizeof(sensor_info[j].sensor_rssi));
                memcpy(sensor_info[j].gateway_rssi,vParamRSSI[1].c_str(),sizeof(sensor_info[j].gateway_rssi));
            } else {
                memcpy(sensor_info[j].sensor_rssi,vParamRSSI[0].c_str(),sizeof(sensor_info[j].sensor_rssi));
                memcpy(sensor_info[j].gateway_rssi,"80",sizeof(sensor_info[j].gateway_rssi));
            }
            std::vector<std::string> vParambattery;
            boost::split(vParambattery, arrRes[j][43], boost::is_any_of(","), boost::token_compress_on);
            if (vParambattery.size() > 1) {
                float battery = float(atof(vParambattery[1].c_str())/atof(vParambattery[0].c_str()));
                sprintf(sensor_info[j].battry,"%f",battery);
            } else {
                sprintf(sensor_info[j].battry ,"0.99",sizeof(sensor_info[j].battry));
            }
            std::vector<std::string> vParam;
            boost::split(vParam, arrRes[j][42], boost::is_any_of(","), boost::token_compress_on);
            if (vParam.size() > 1){
                if (vParam[1] != "0"){
                    sensor_info[j].loose_status = 1;
                }else{
                    sensor_info[j].loose_status = 0;
                }  
            }
            char whereCon[256]={0x00};
            sprintf(whereCon,"dataNodeNo = '%s'",arrRes[j][44].c_str());
            vec_t vecRes = sqlite_db_ctrl::instance().GetDataSingleLine(T_DATASTATIC_INFO(TNAME), "temTop,temBot",whereCon);
            if (vecRes.size() > 0)
            {
                sensor_info[j].temperature_top = atoi(vecRes[0].c_str());
                sensor_info[j].temperature_bot = atoi(vecRes[1].c_str());
            }else{
                sensor_info[j].temperature_top = 200;
                sensor_info[j].temperature_bot  = 200;
            }
            
            memcpy(sensor_info[j].product_no,arrRes[j][17].c_str(),sizeof(sensor_info[j].product_no));
            sensor_info[j].status = atoi(arrRes[j][37].c_str());

            char szTableName[100] = {0x00};
            memset(whereCon,0,sizeof(whereCon));
            sprintf(szTableName, " t_data_waveSend ");
            const char *sql = 
        	" timestamp >= strftime('%s', 'now', '-1 day', 'start of day','utc') "
        	"AND timestamp < strftime('%s', 'now', '-1 day','start of day','utc','+24 hours') ";
            sprintf(whereCon," and channelID = '%s-X'",arrRes[j][44].c_str());
			std::string	strsql = std::string(sql) + std::string(whereCon);
			int waveX_Count = sqlite_db_ctrl::instance().GetTableRows(szTableName,strsql.c_str());

            memset(whereCon,0,sizeof(whereCon));
            sprintf(whereCon," and channelID = '%s-Y'",arrRes[j][44].c_str());
			strsql = std::string(sql) + std::string(whereCon);
			int waveY_Count = sqlite_db_ctrl::instance().GetTableRows(szTableName,strsql.c_str());

            memset(whereCon,0,sizeof(whereCon));
            sprintf(whereCon," and channelID = '%s-Z'",arrRes[j][44].c_str());
			strsql = std::string(sql) + std::string(whereCon);
			int waveZ_Count = sqlite_db_ctrl::instance().GetTableRows(szTableName,strsql.c_str());

            memset(whereCon,0,sizeof(whereCon));
            memset(szTableName,0,sizeof(szTableName));
            sprintf(szTableName, " t_dataStatic_%s ",arrRes[j][44].c_str());
            sprintf(whereCon," and channelID = '%s-S'",arrRes[j][44].c_str());
			strsql = std::string(sql) + std::string(whereCon);
			int static_Count = sqlite_db_ctrl::instance().GetTableRows(szTableName,strsql.c_str());

            scheduler::instance().GetScheduleConfig(featureInterVal,waveInterVal,featureInterTime,waveInterTime,maxSensorNum);
            sensor_info[j].waveX_reportingrate = waveX_Count/(86400/waveInterVal);
            sensor_info[j].waveY_reportingrate = waveY_Count/(86400/waveInterVal);
            sensor_info[j].waveZ_reportingrate = waveZ_Count/(86400/waveInterVal);
            sensor_info[j].eigenvalue_reportingrate = static_Count/(86400/featureInterVal);

            memset(whereCon,0,sizeof(whereCon));
            sprintf(whereCon,"channelID = '%s-Z'",arrRes[j][44].c_str());
            std::string integratRMS = sqlite_db_ctrl::instance().GetData(T_DATA_INFO(TNAME), "integratRMS",whereCon);

            memcpy(sensor_info[j].integratRMS , integratRMS.c_str(),sizeof(sensor_info[j].integratRMS));;
            sensor_info[j].upgrade_status = 0;
            memcpy(sensor_info[j].upgrade_date,"2024-01-08 12:00:00",sizeof(sensor_info[j].upgrade_date));
        }   
        retData = (char*)malloc(sizeof(SensorInfo) * j);
        memcpy(retData,&sensor_info,sizeof(SensorInfo) * j);
        return_length = sizeof(SensorInfo) * j;
    }
    return retData;
    
}

char *JsonData::CmtCmd_82(char* MeasurementID,char* channel,int& return_length)
{
    FILE* pFile = NULL;
    char* buffer = NULL;
    char* retData = NULL;
    int  thisSize = 0;
    WaveRes wave;
    char whereCon[32]={0};
    sprintf(whereCon,"MeasurementID = '%s'",MeasurementID);
    vec_t vecRes = sqlite_db_ctrl::instance().GetDataSingleLine(T_SENSOR_INFO(TNAME), "samplingRate,ACCSampleTime",whereCon);
    std::string data_file = "/opt/data/" + std::string(MeasurementID) + "-" + std::string(channel);
    zlog_info(zct, "strFileName = %s", data_file.c_str());
    pFile = fopen(data_file.c_str(), "rb");
    if (pFile != NULL) {
        while (fgetc(pFile) != EOF) {
            ++thisSize;
        }
        rewind(pFile);
        buffer = (char*)malloc(thisSize);
        fread(buffer, sizeof(char), thisSize, pFile);
        fclose(pFile);
    }
    wave.sampling_rate = atoi(vecRes[0].c_str());
    wave.sampling_time = atoi(vecRes[1].c_str());
    return_length = sizeof(WaveRes) + thisSize;
    retData = (char*)malloc(return_length);
    memcpy(retData,(char*)&wave,sizeof(WaveRes));
    memcpy(retData + sizeof(WaveRes) ,&buffer,thisSize);
    free(buffer);
    return retData;
}
add manger code 2025-01-09 20:00:34 +08:00			`#include "communication_cmd.hpp"`
			`#include "localserver/local_server.hpp"`
			`#include "common/common_func.hpp"`
			`#include "common/global.hpp"`
			`#include <boost/algorithm/string.hpp>`
			`#include "dbaccess/sql_db.hpp"`
			`#include "scheduler/schedule.hpp"`
			`#include "zlog.h"`

			`extern zlog_category_t *zct;`

			`char *JsonData::CmtCmd_80(int& return_length)`
			`{`
			`zlog_info(zct,"CmtCmd_80");`
			`GatewayVersion gateway_ver;`
			`memcpy(gateway_ver.mac,GlobalConfig::MacAddr_G.c_str(),sizeof(gateway_ver.mac));`
			`memcpy(gateway_ver.web_ver,ReadStrByOpt(SYSTEMINFOFILE, "Version", "WebVersion").c_str(),sizeof(gateway_ver.web_ver));`
			`memcpy(gateway_ver.system_ver,ReadStrByOpt(SYSTEMINFOFILE, "Version", "SystemVersion").c_str(),sizeof(gateway_ver.system_ver));`
			`memcpy(gateway_ver.gateway_ver,ReadStrByOpt(SYSTEMINFOFILE, "Version", "GateWayVersion").c_str(),sizeof(gateway_ver.gateway_ver));`
			`memcpy(gateway_ver.localIP,GlobalConfig::IpAddr_G.c_str(),sizeof(gateway_ver.localIP));`
			`memcpy(gateway_ver.gateway_type,ReadStrByOpt(SYSTEMINFOFILE, "Version", "GateWayProduct").c_str(),sizeof(gateway_ver.gateway_type));`
			`memcpy(gateway_ver.geteway_hw_ver,ReadStrByOpt(SYSTEMINFOFILE, "Version", "GateWayHwVesion").c_str(),sizeof(gateway_ver.geteway_hw_ver));`
			`#ifdef NR5G_MODULE`
			`memcpy(gateway_ver.comm_mode,"5G",sizeof(gateway_ver.comm_mode));`
			`#endif`
			`#ifdef Q4G_MODULE`
			`memcpy(gateway_ver.comm_mode,"4G",sizeof(gateway_ver.comm_mode));`
			`#endif`
			`#ifdef WIFI_MODULE`
			`memcpy(gateway_ver.comm_mode,"WiFi",sizeof(gateway_ver.comm_mode));`
			`#endif`
			`memcpy(gateway_ver.comm_mode,"有线",sizeof(gateway_ver.comm_mode));`
			`GetSysStatusCMT(gateway_ver.cpu_use,gateway_ver.memory_use,gateway_ver.harddisk_remain,gateway_ver.temperature);`
			`char *retData = NULL;`
			`retData = (char*)malloc(sizeof(GatewayVersion));`
			`memcpy(retData,&gateway_ver,sizeof(GatewayVersion));`
			`return_length = sizeof(GatewayVersion);`
			`return retData;`
			`}`

			`char *JsonData::CmtCmd_81(int& return_length)`
			`{`
			`int featureInterVal;`
			`int featureInterTime;`
			`int waveInterVal;`
			`int waveInterTime;`
			`int maxSensorNum;`
			`int sensorCount;`
			`char *retData = NULL;`
			`array_t arrRes;`
			`arrRes = sqlite_db_ctrl::instance().GetDataMultiLineTransaction(T_SENSOR_INFO(TNAME), "*", NULL);`
			`int iResult = arrRes.size();`
			`size_t j = 0;`
			`if (iResult > 0) {`
			`SensorInfo sensor_info[iResult];`
			`for (; j < iResult; j++)`
			`{`
			`memcpy(sensor_info[j].mac,arrRes[j][44].c_str(),sizeof(sensor_info[j].mac));`
			`memcpy(sensor_info[j].short_addr,arrRes[j][30].c_str(),sizeof(sensor_info[j].short_addr));`
			`memcpy(sensor_info[j].hw_ver,arrRes[j][8].c_str(),sizeof(sensor_info[j].hw_ver));`
			`memcpy(sensor_info[j].soft_ver,arrRes[j][9].c_str(),sizeof(sensor_info[j].soft_ver));`
			`std::vector<std::string> vParamRSSI;`
			`boost::split(vParamRSSI, arrRes[j][40], boost::is_any_of(","), boost::token_compress_on);`
			`if (vParamRSSI.size() > 1) {`
			`memcpy(sensor_info[j].sensor_rssi,vParamRSSI[0].c_str(),sizeof(sensor_info[j].sensor_rssi));`
			`memcpy(sensor_info[j].gateway_rssi,vParamRSSI[1].c_str(),sizeof(sensor_info[j].gateway_rssi));`
			`} else {`
			`memcpy(sensor_info[j].sensor_rssi,vParamRSSI[0].c_str(),sizeof(sensor_info[j].sensor_rssi));`
			`memcpy(sensor_info[j].gateway_rssi,"80",sizeof(sensor_info[j].gateway_rssi));`
			`}`
			`std::vector<std::string> vParambattery;`
			`boost::split(vParambattery, arrRes[j][43], boost::is_any_of(","), boost::token_compress_on);`
			`if (vParambattery.size() > 1) {`
			`float battery = float(atof(vParambattery[1].c_str())/atof(vParambattery[0].c_str()));`
			`sprintf(sensor_info[j].battry,"%f",battery);`
			`} else {`
			`sprintf(sensor_info[j].battry ,"0.99",sizeof(sensor_info[j].battry));`
			`}`
			`std::vector<std::string> vParam;`
			`boost::split(vParam, arrRes[j][42], boost::is_any_of(","), boost::token_compress_on);`
			`if (vParam.size() > 1){`
			`if (vParam[1] != "0"){`
			`sensor_info[j].loose_status = 1;`
			`}else{`
			`sensor_info[j].loose_status = 0;`
			`}`
			`}`
			`char whereCon[256]={0x00};`
			`sprintf(whereCon,"dataNodeNo = '%s'",arrRes[j][44].c_str());`
			`vec_t vecRes = sqlite_db_ctrl::instance().GetDataSingleLine(T_DATASTATIC_INFO(TNAME), "temTop,temBot",whereCon);`
			`if (vecRes.size() > 0)`
			`{`
			`sensor_info[j].temperature_top = atoi(vecRes[0].c_str());`
			`sensor_info[j].temperature_bot = atoi(vecRes[1].c_str());`
			`}else{`
			`sensor_info[j].temperature_top = 200;`
			`sensor_info[j].temperature_bot = 200;`
			`}`

			`memcpy(sensor_info[j].product_no,arrRes[j][17].c_str(),sizeof(sensor_info[j].product_no));`
			`sensor_info[j].status = atoi(arrRes[j][37].c_str());`

			`char szTableName[100] = {0x00};`
			`memset(whereCon,0,sizeof(whereCon));`
			`sprintf(szTableName, " t_data_waveSend ");`
			`const char *sql =`
			`" timestamp >= strftime('%s', 'now', '-1 day', 'start of day','utc') "`
			`"AND timestamp < strftime('%s', 'now', '-1 day','start of day','utc','+24 hours') ";`
			`sprintf(whereCon," and channelID = '%s-X'",arrRes[j][44].c_str());`
			`std::string strsql = std::string(sql) + std::string(whereCon);`
			`int waveX_Count = sqlite_db_ctrl::instance().GetTableRows(szTableName,strsql.c_str());`

			`memset(whereCon,0,sizeof(whereCon));`
			`sprintf(whereCon," and channelID = '%s-Y'",arrRes[j][44].c_str());`
			`strsql = std::string(sql) + std::string(whereCon);`
			`int waveY_Count = sqlite_db_ctrl::instance().GetTableRows(szTableName,strsql.c_str());`

			`memset(whereCon,0,sizeof(whereCon));`
			`sprintf(whereCon," and channelID = '%s-Z'",arrRes[j][44].c_str());`
			`strsql = std::string(sql) + std::string(whereCon);`
			`int waveZ_Count = sqlite_db_ctrl::instance().GetTableRows(szTableName,strsql.c_str());`

			`memset(whereCon,0,sizeof(whereCon));`
			`memset(szTableName,0,sizeof(szTableName));`
			`sprintf(szTableName, " t_dataStatic_%s ",arrRes[j][44].c_str());`
			`sprintf(whereCon," and channelID = '%s-S'",arrRes[j][44].c_str());`
			`strsql = std::string(sql) + std::string(whereCon);`
			`int static_Count = sqlite_db_ctrl::instance().GetTableRows(szTableName,strsql.c_str());`

			`scheduler::instance().GetScheduleConfig(featureInterVal,waveInterVal,featureInterTime,waveInterTime,maxSensorNum);`
			`sensor_info[j].waveX_reportingrate = waveX_Count/(86400/waveInterVal);`
			`sensor_info[j].waveY_reportingrate = waveY_Count/(86400/waveInterVal);`
			`sensor_info[j].waveZ_reportingrate = waveZ_Count/(86400/waveInterVal);`
			`sensor_info[j].eigenvalue_reportingrate = static_Count/(86400/featureInterVal);`

			`memset(whereCon,0,sizeof(whereCon));`
			`sprintf(whereCon,"channelID = '%s-Z'",arrRes[j][44].c_str());`
			`std::string integratRMS = sqlite_db_ctrl::instance().GetData(T_DATA_INFO(TNAME), "integratRMS",whereCon);`

			`memcpy(sensor_info[j].integratRMS , integratRMS.c_str(),sizeof(sensor_info[j].integratRMS));;`
			`sensor_info[j].upgrade_status = 0;`
			`memcpy(sensor_info[j].upgrade_date,"2024-01-08 12:00:00",sizeof(sensor_info[j].upgrade_date));`
			`}`
			`retData = (char)malloc(sizeof(SensorInfo) j);`
			`memcpy(retData,&sensor_info,sizeof(SensorInfo) * j);`
			`return_length = sizeof(SensorInfo) * j;`
			`}`
			`return retData;`

			`}`

			`char JsonData::CmtCmd_82(char MeasurementID,char* channel,int& return_length)`
			`{`
			`FILE* pFile = NULL;`
			`char* buffer = NULL;`
			`char* retData = NULL;`
			`int thisSize = 0;`
			`WaveRes wave;`
			`char whereCon[32]={0};`
			`sprintf(whereCon,"MeasurementID = '%s'",MeasurementID);`
			`vec_t vecRes = sqlite_db_ctrl::instance().GetDataSingleLine(T_SENSOR_INFO(TNAME), "samplingRate,ACCSampleTime",whereCon);`
			`std::string data_file = "/opt/data/" + std::string(MeasurementID) + "-" + std::string(channel);`
			`zlog_info(zct, "strFileName = %s", data_file.c_str());`
			`pFile = fopen(data_file.c_str(), "rb");`
			`if (pFile != NULL) {`
			`while (fgetc(pFile) != EOF) {`
			`++thisSize;`
			`}`
			`rewind(pFile);`
			`buffer = (char*)malloc(thisSize);`
			`fread(buffer, sizeof(char), thisSize, pFile);`
			`fclose(pFile);`
			`}`
			`wave.sampling_rate = atoi(vecRes[0].c_str());`
			`wave.sampling_time = atoi(vecRes[1].c_str());`
			`return_length = sizeof(WaveRes) + thisSize;`
			`retData = (char*)malloc(return_length);`
			`memcpy(retData,(char*)&wave,sizeof(WaveRes));`
			`memcpy(retData + sizeof(WaveRes) ,&buffer,thisSize);`
			`free(buffer);`
			`return retData;`
			`}`