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WLG/uart/uart_feature_parse.cpp
zhangsheng fad8c2928c modify table name
2024-11-21 20:34:56 +08:00

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#include "uart.hpp"
#include <stdio.h>
#include <fcntl.h>
#include <unistd.h>
#include <termios.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <boost/algorithm/string.hpp>
#include <zlog.h>
#include <json/json.h>
#include "mqttclient/mqtt_client.h"
#include "minilzo/minilzo.h"
extern zlog_category_t *zct;
extern zlog_category_t *zbt;
std::vector<RecvData> g_VecWaveDataX;
std::vector<RecvData> g_VecWaveDataY;
std::vector<RecvData> g_VecWaveDataZ;
std::map<std::string, compressWaveChannel> g_mapCompress;
std::map<std::string, WaveChannel> g_mapWaveChannel;
unsigned char data[1024 * 30] = {0x00};
unsigned char outdata[1024 * 50] = {0x00};
unsigned char dealdata[1024 * 30] = {0x00};
char mqttData[512000] = {0};
void Uart::RecordBattery(std::string &strLongAddr, DataRecvStatic &dataStatic, std::string &nowTimetamp) {
char insertSql[1024] = {0};
sprintf(insertSql, "'%s','%d','%f','%f','%f','%d','','','%s'", strLongAddr.c_str(), dataStatic.Dip, dataStatic.TemBot, dataStatic.nodeWorkTime, dataStatic.nodeSendTime, dataStatic.Voltage, nowTimetamp.c_str());
sqlite_db_ctrl::instance().InsertData(T_BATTERY_INFO(TNAME), insertSql);
}
void Uart::DataExtract(RecvData *p, int id, unsigned int &lowbit, float &n) {
char buf[20] = {0};
sprintf(buf, "%02x%02x", p->Data[id+1], p->Data[id]);
int temp = (unsigned int)strtol(buf, NULL, 16);
unsigned char highbit = temp >> 14 & 0x3;
lowbit = temp & 0x3fff;
n = ScaleConvert(highbit);
}
void Uart::DealDataNodeFeature(const char *pData, int flag) {
RecvData *pRecvData = (RecvData *)pData;
char whereCon[1024] = {0};
char updateSql[1024] = {0};
char buf[20] = {0x00};
int nodeResend = 0, timing = 0;
long staticIndex = 0;
sprintf(buf, "%02x%02x", pRecvData->ShortAddr[0], pRecvData->ShortAddr[1]);
if (flag == 1) {
zlog_info(zct, "DealDataNodeFeature %02x%02x, %d", pRecvData->ShortAddr[0], pRecvData->ShortAddr[1], flag);
}
if (bSendTimeStamp) //波形处理中
return;
std::string strShortAddr = std::string(buf);
zlog_info(zct, "zigbeeShortAddr='%s'", strShortAddr.c_str());
char getLongAddr_sql[32] = {0};
//根据数据包中的传感器的短地址获取数据库中长地址MAC在下面判断该传感器是否存在如果不存在则把数据包丢弃
sprintf(getLongAddr_sql, "zigbeeShortAddr='%s'", strShortAddr.c_str());
vec_t vecResult = sqlite_db_ctrl::instance().GetDataSingleLine(T_SENSOR_INFO(TNAME), " softVersion,dataNodeNo,MeasurementID,ProductNo ", getLongAddr_sql);
if (vecResult.size() < 1) {
zlog_warn(zct, "device info not found %02x%02x ", pRecvData->ShortAddr[0], pRecvData->ShortAddr[1]);
return;
}
zlog_info(zct, "--------->the remote sensor short addr:%s strLongAddr=%s,softVersion = %s", buf, vecResult[1].c_str(), vecResult[0].c_str());
std::string strLongAddr = vecResult[1];
std::string strMeasurementID = vecResult[2];
std::string strProductNo = vecResult[3];
memset(whereCon, 0x00, sizeof(whereCon));
memset(updateSql, 0x00, sizeof(updateSql));
sprintf(whereCon, "zigbeeShortAddr='%s'", strShortAddr.c_str());
sprintf(updateSql, " StaticTime = StaticTime + 1");
sqlite_db_ctrl::instance().UpdateTableData(T_SENSOR_INFO(TNAME), updateSql, whereCon);
if (vecResult[0] == "3.0" || vecResult[0] == "4.0") {
return;
}
long nodetimestamp = BUILD_UINT32(pRecvData->Data[29], pRecvData->Data[28], pRecvData->Data[27], pRecvData->Data[26]);
char localtimestamp[32] = {0};
sprintf(localtimestamp,"%ld",nodetimestamp);
std::string nowTimetamp = std::string(localtimestamp);
strTimetamp = nowTimetamp;
int iTemp = 0;
// unsigned char highbit = 0;
unsigned int lowbit = 0;
float n = 0;
DataRecvStatic dataStatic;
memset(buf, 0, sizeof(buf));
sprintf(buf, "%02x%02x", pRecvData->Data[5], pRecvData->Data[4]);
iTemp = (int)strtol(buf, NULL, 16);
dataStatic.Dip = iTemp;
int fTemp = 0;
memset(buf, 0, sizeof(buf));
sprintf(buf, "%02x%02x", pRecvData->Data[1], pRecvData->Data[0]);
iTemp = (int)strtol(buf, NULL, 16);
if (iTemp < 0x8000) {
fTemp = iTemp;
} else {
fTemp = (((~iTemp) & 0xffff) + 1) * (-1);
}
dataStatic.TemBot = fTemp * 0.0625; //设备温度
fTemp = 0;
memset(buf, 0, sizeof(buf));
sprintf(buf, "%02x%02x", pRecvData->Data[3], pRecvData->Data[2]);
iTemp = (int)strtol(buf, NULL, 16);
if (iTemp < 0x8000) {
fTemp = iTemp;
} else {
fTemp = (((~iTemp) & 0xffff) + 1) * (-1);
}
dataStatic.TemTop = fTemp * 0.0625; //环境温度
memset(buf, 0, sizeof(buf));
sprintf(buf, "%02x%02x", pRecvData->Data[7], pRecvData->Data[6]);
iTemp = (int)strtol(buf, NULL, 16);
dataStatic.Voltage = iTemp;
DataExtract(pRecvData, 30, lowbit, n);
dataStatic.nodeWorkTime = lowbit * n;
DataExtract(pRecvData, 32, lowbit, n);
dataStatic.nodeSendTime = lowbit * n;
dataStatic.nodeWorkTime = dataStatic.nodeWorkTime - dataStatic.nodeSendTime;
RecordBattery(strMeasurementID, dataStatic, nowTimetamp);
char szTableName[50] = {0x00}, szTableNameStatic[50] = {0x00}, szTableNameData[50] = {0x00};
sprintf(szTableName, "t_dataStatic_%s", strMeasurementID.c_str());
memcpy(szTableNameStatic, szTableName, sizeof(szTableNameStatic));
memset(whereCon, 0x00, sizeof(whereCon));
// sprintf(whereCon, "StaticIndex = %ld", staticIndex);
// int count = sqlite_db_ctrl::instance().GetTableRows(szTableNameStatic, whereCon); //避免重复数据
// sprintf(szTableNameData, "t_data_%s", strMeasurementID.c_str());
// int count2 = sqlite_db_ctrl::instance().GetTableRows(szTableNameData, whereCon);
// if (count > 0 || count2 > 0) {
// char logInfo[100] = {0x00};
// sprintf(logInfo, "ShortAddr = %s,staticIndex = %ld,staticData = %d, data = %d", strShortAddr.c_str(), staticIndex, count, count2);
// zlog_info(zct, logInfo);
// return;
// }
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(szTableNameData, "t_data_%s", strMeasurementID.c_str());
///////////////////////////////////////////////////////////// for V2.0.3 upgrade to V3.0
////////////////////////////////////////////////////////////更换电池判断
// sprintf(whereCon, " dataNodeNo = '%s' and StaticIndex > 0 order by StaticIndex desc LIMIT 0 , 1 ", strLongAddr.c_str());
// std::string strStaticIndex = sqlite_db_ctrl::instance().GetData(szTableNameStatic, "StaticIndex", whereCon);
// if (atol(strStaticIndex.c_str()) - staticIndex > 100) {
// sqlite_db_ctrl::instance().Deletetable(szTableNameStatic);
// sqlite_db_ctrl::instance().Deletetable(szTableNameData);
// zlog_info(zct, "staticIndexNOW = %ld,strStaticIndexLast = %s", staticIndex, strStaticIndex.c_str());
// }
// zlog_info(zct, "NowstaticIndex = %ld,RecordStaticIndex = %ld", staticIndex, atol(strStaticIndex.c_str()));
// if (staticIndex != atol(strStaticIndex.c_str() + 1) && strStaticIndex != "" && staticIndex < atol(strStaticIndex.c_str())) {
// sprintf(whereCon, "StaticIndex = %ld order by StaticIndex desc LIMIT 0 , 1", atol(strStaticIndex.c_str()));
// vec_t vecResult = sqlite_db_ctrl::instance().GetDataSingleLine(szTableNameStatic, "timeStamp,StaticIndex", whereCon);
// if (vecResult.size() > 0) {
// memset(whereCon, 0x00, sizeof(whereCon));
// sprintf(whereCon, "dataNodeNo = '%s'", strLongAddr.c_str());
// std::string staticInterval = sqlite_db_ctrl::instance().GetData(T_SENSOR_INFO(TNAME), "featureInterval", whereCon);
// long nNowTimetamp = atol(vecResult[0].c_str()) - (atol(staticInterval.c_str()) * (atol(vecResult[1].c_str()) - staticIndex)) * 60;
// char tmp[10] = {0x00};
// sprintf(tmp, "%ld", nNowTimetamp);
// nowTimetamp = std::string(tmp);
// nodeResend = 1;
// }
// }
zlog_info(zct, "nowTimetamp = %s", nowTimetamp.c_str());
sprintf(whereCon, "channelID='%s' ", (strMeasurementID + "-S").c_str());
int Count = sqlite_db_ctrl::instance().GetTableRows(szTableName, whereCon);
if (Count == -1) {
sqlite_db_ctrl::instance().CreatedataStatictable(szTableName);
sqlite_db_ctrl::instance().Createtable(szTableNameData);
}
std::string strTmp = "";
char sztmp[100] = {0x00};
strTmp = "name = '" + std::string(szTableNameStatic) + "' and sql LIKE '%nodeResend%' ";
int row = sqlite_db_ctrl::instance().GetTableRows(" sqlite_master ", strTmp.c_str());
zlog_info(zct, "row1 = %d", row);
if (row == 0) {
memset(sztmp, 0x00, sizeof(sztmp));
sprintf(sztmp, "ALTER TABLE %s ADD COLUMN 'nodeResend'", szTableNameStatic);
sqlite_db_ctrl::instance().CreateTable(sztmp);
}
strTmp = "name = '" + std::string(szTableNameData) + "' and sql LIKE '%nodeResend%' ";
row = sqlite_db_ctrl::instance().GetTableRows(" sqlite_master ", strTmp.c_str());
zlog_info(zct, "row2 = %d", row);
if (row == 0) {
memset(sztmp, 0x00, sizeof(sztmp));
sprintf(sztmp, "ALTER TABLE %s ADD COLUMN 'nodeResend'", szTableNameData);
sqlite_db_ctrl::instance().CreateTable(sztmp);
}
char selectCon[128] = {0};
sprintf(selectCon, "channelID='%s' ORDER BY timeStamp ASC LIMIT 0,1", (strMeasurementID + "-S").c_str());
std::string strTime = sqlite_db_ctrl::instance().GetData(szTableName, "timeStamp", selectCon);
zlog_info(zct, "strLongAddr = %s,strTime = %s", strLongAddr.c_str(), strTime.c_str());
long lTime = atol(nowTimetamp.c_str()) - atol(strTime.c_str());
zlog_info(zct, "lTime = %ld,OneWeek = %d", lTime, OneWeek);
zlog_info(zct, "dataStatic.TemTop : %f dataStatic.TemBot : %f dataStatic.Dip :%d dataStatic.Voltage : %d", dataStatic.TemTop, dataStatic.TemBot, dataStatic.Dip, dataStatic.Voltage);
sprintf(updateSql, "temTop='%f',temBot='%f',dip='%d',voltage='%d',timeStamp='%s',StaticIndex = %ld, nodeResend = %d,zigbeeSignal = '',zigbeeSignalNode = '',statisticType = '%d',timing = '%d' ", dataStatic.TemTop, dataStatic.TemBot, dataStatic.Dip, dataStatic.Voltage,
nowTimetamp.c_str(), staticIndex, nodeResend, flag, timing);
sprintf(whereCon, "channelID='%s' ", (strMeasurementID + "-S").c_str());
if (/*0 == sqlite_db_ctrl::instance().GetTableRows(T_DATASTATIC_INFO(TNAME), whereCon)*/ (Count * 3 < SAVE_COUNT && lTime < OneWeek) || strTime.size() == 0) {
zlog_info(zct, "insert static data to sql");
char insertSql[1024] = {0};
sprintf(insertSql, "'%s','%s','%f','%f','%d','%d','',%ld,'%s','1',%d,'','%d','%d'", strMeasurementID.c_str(), (strMeasurementID + "-S").c_str(), dataStatic.TemTop, dataStatic.TemBot, dataStatic.Dip, dataStatic.Voltage, staticIndex, nowTimetamp.c_str(), nodeResend, flag,
timing);
sqlite_db_ctrl::instance().InsertData(szTableName, insertSql);
if (0 == sqlite_db_ctrl::instance().GetTableRows(T_DATASTATIC_INFO(TNAME), whereCon)) { // First Connect
char insertSql[1024] = {0};
sprintf(insertSql, "'%s','%s','%f','%f','%d','%d','',%ld,'%s','1',%d", strMeasurementID.c_str(), (strMeasurementID + "-S").c_str(), dataStatic.TemTop, dataStatic.TemBot, dataStatic.Dip, dataStatic.Voltage, staticIndex, nowTimetamp.c_str(), nodeResend);
sqlite_db_ctrl::instance().InsertData(T_DATASTATIC_INFO(TNAME), insertSql);
sqlite_db_ctrl::instance().CalculateBattery();
} else {
memset(updateSql, 0x00, sizeof(updateSql));
sprintf(updateSql, "temTop='%f',temBot='%f',dip='%d',voltage='%d',timeStamp='%s',StaticIndex = %ld ", dataStatic.TemTop, dataStatic.TemBot, dataStatic.Dip, dataStatic.Voltage, nowTimetamp.c_str(), staticIndex);
sqlite_db_ctrl::instance().UpdateTableData(T_DATASTATIC_INFO(TNAME), updateSql, whereCon);
}
} else {
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(whereCon, "channelID='%s' and timeStamp = '%s'", (strMeasurementID + "-S").c_str(), strTime.c_str());
zlog_info(zct, "update static data to sql");
sqlite_db_ctrl::instance().UpdateTableData(szTableName, updateSql, whereCon);
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(whereCon, "channelID='%s' ", (strMeasurementID + "-S").c_str());
memset(updateSql, 0x00, sizeof(updateSql));
sprintf(updateSql, "temTop='%f',temBot='%f',dip='%d',voltage='%d',timeStamp='%s',StaticIndex = %ld ", dataStatic.TemTop, dataStatic.TemBot, dataStatic.Dip, dataStatic.Voltage, nowTimetamp.c_str(), staticIndex);
sqlite_db_ctrl::instance().UpdateTableData(T_DATASTATIC_INFO(TNAME), updateSql, whereCon);
}
memset(szTableName, 0x00, sizeof(szTableName));
sprintf(szTableName, "t_data_%s", strMeasurementID.c_str());
DataRecvDym dataDymX;
DataExtract(pRecvData, 8, lowbit, n);
dataDymX.DiagnosisPk = lowbit * n;
DataExtract(pRecvData, 10, lowbit, n);
dataDymX.RmsValues = lowbit * n;
DataExtract(pRecvData, 12, lowbit, n);
dataDymX.IntegratPk = lowbit * n;
DataExtract(pRecvData, 14, lowbit, n);
dataDymX.IntegratRMS = lowbit * n;
DataExtract(pRecvData, 16, lowbit, n);
dataDymX.Amp1 = lowbit * n;
DataExtract(pRecvData, 18, lowbit, n);
dataDymX.Amp2 = lowbit * n;
DataExtract(pRecvData, 20, lowbit, n);
dataDymX.Amp3 = lowbit * n;
DataExtract(pRecvData, 22, lowbit, n);
dataDymX.Amp4 = lowbit * n;
DataExtract(pRecvData, 24, lowbit, n);
dataDymX.Amp5 = lowbit * n;
memset(buf, 0, sizeof(buf));
dataDymX.EnvelopEnergy = 0;
memset(buf, 0, sizeof(buf));
dataDymX.Phase1 = 0;
memset(buf, 0, sizeof(buf));
dataDymX.Phase2 = 0;
memset(buf, 0, sizeof(buf));
memset(buf, 0, 8);
dataDymX.Phase3 = 0;
memset(buf, 0, sizeof(buf));
sprintf(buf, "%02x%02x", pRecvData->Data[35], pRecvData->Data[34]);
dataDymX.Phase4 = 0;
memset(whereCon, 0, 1024);
sprintf(whereCon, "channelID='%s' ", (strMeasurementID + "-X").c_str());
memset(updateSql, 0, 1024);
sprintf(updateSql, "diagnosisPk='%f',integratPk='%f',integratRMS='%f',rmsValues='%f',envelopEnergy='%f',\
Amp1='%f',Amp2='%f',Amp3='%f',Amp4='%f',Amp5='%f',Phase1='%f',Phase2='%f',Phase3='%f',Phase4='%f',timeStamp='%s',StaticIndex = %ld,nodeResend = %d ",
dataDymX.DiagnosisPk, dataDymX.IntegratPk, dataDymX.IntegratRMS, dataDymX.RmsValues, dataDymX.EnvelopEnergy, dataDymX.Amp1, dataDymX.Amp2, dataDymX.Amp3, dataDymX.Amp4, dataDymX.Amp5, dataDymX.Phase1, dataDymX.Phase2, dataDymX.Phase3, dataDymX.Phase4,
nowTimetamp.c_str(), staticIndex, nodeResend);
if ((Count * 3 < SAVE_COUNT && lTime < OneWeek) || strTime.size() == 0) { // 1 week
char insertSql[1024] = {0};
memset(insertSql, 0x00, sizeof(insertSql));
sprintf(insertSql, "'%s','%s','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f',%ld,'%s','1',%d", strMeasurementID.c_str(), (strMeasurementID + "-X").c_str(), dataDymX.DiagnosisPk, dataDymX.IntegratPk, dataDymX.IntegratRMS, dataDymX.RmsValues,
dataDymX.EnvelopEnergy, dataDymX.Amp1, dataDymX.Amp2, dataDymX.Amp3, dataDymX.Amp4, dataDymX.Amp5, dataDymX.Phase1, dataDymX.Phase2, dataDymX.Phase3, dataDymX.Phase4, staticIndex, nowTimetamp.c_str(), nodeResend);
sqlite_db_ctrl::instance().InsertData(szTableName, insertSql);
if (0 == sqlite_db_ctrl::instance().GetTableRows(T_DATA_INFO(TNAME), whereCon))
sqlite_db_ctrl::instance().InsertData(T_DATA_INFO(TNAME), insertSql);
else
sqlite_db_ctrl::instance().UpdateTableData(T_DATA_INFO(TNAME), updateSql, whereCon);
} else {
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(whereCon, "channelID='%s' and timeStamp = '%s'", (strMeasurementID + "-X").c_str(), strTime.c_str());
sqlite_db_ctrl::instance().UpdateTableData(szTableName, updateSql, whereCon);
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(whereCon, "channelID='%s' ", (strMeasurementID + "-X").c_str());
sqlite_db_ctrl::instance().UpdateTableData(T_DATA_INFO(TNAME), updateSql, whereCon);
}
zlog_info(zct, "x:%s,%s,diagnosisPk=%f,integratPk=%f,integratRMS=%f,rmsValues=%f,envelopEnergy=%f,Amp1=%f,Amp2=%f,Amp3=%f,Amp4=%f,Amp5=%f,Phase1=%f,Phase2=%f,Phase3=%f,Phase4=%f,timeStamp=%s", strMeasurementID.c_str(), (strMeasurementID + "-X").c_str(), dataDymX.DiagnosisPk,
dataDymX.IntegratPk, dataDymX.IntegratRMS, dataDymX.RmsValues, dataDymX.EnvelopEnergy, dataDymX.Amp1, dataDymX.Amp2, dataDymX.Amp3, dataDymX.Amp4, dataDymX.Amp5, dataDymX.Phase1, dataDymX.Phase2, dataDymX.Phase3, dataDymX.Phase4, nowTimetamp.c_str());
Json::Value valNodeData;
Json::Value valNodeFeature;
valNodeFeature["dataNodeNo"] = strMeasurementID;
valNodeFeature["ChannelId"] = strMeasurementID + "-X";
valNodeFeature["diagnosisPk"] = dataDymX.DiagnosisPk;
valNodeFeature["integratPk"] = dataDymX.IntegratPk;
valNodeFeature["integratRMS"] = dataDymX.IntegratRMS;
valNodeFeature["rmsValues"] = dataDymX.RmsValues;
valNodeFeature["envelopEnergy"] = dataDymX.EnvelopEnergy;
valNodeFeature["Amp1"] = dataDymX.Amp1;
valNodeFeature["Amp2"] = dataDymX.Amp2;
valNodeFeature["Amp3"] = dataDymX.Amp3;
valNodeFeature["Amp4"] = dataDymX.Amp4;
valNodeFeature["Amp5"] = dataDymX.Amp5;
valNodeFeature["Phase1"] = dataDymX.Phase1;
valNodeFeature["Phase2"] = dataDymX.Phase2;
valNodeFeature["Phase3"] = dataDymX.Phase3;
valNodeFeature["Phase4"] = dataDymX.Phase4;
valNodeFeature["timeStamp"] = nowTimetamp;
valNodeData.append(valNodeFeature);
DataRecvDym dataDymY;
DataExtract(pRecvData, 34, lowbit, n);
dataDymY.DiagnosisPk = lowbit * n;
DataExtract(pRecvData, 36, lowbit, n);
dataDymY.RmsValues = lowbit * n;
DataExtract(pRecvData, 38, lowbit, n);
dataDymY.IntegratPk = lowbit * n;
DataExtract(pRecvData, 40, lowbit, n);
dataDymY.IntegratRMS = lowbit * n;
DataExtract(pRecvData, 42, lowbit, n);
dataDymY.Amp1 = lowbit * n;
DataExtract(pRecvData, 44, lowbit, n);
dataDymY.Amp2 = lowbit * n;
DataExtract(pRecvData, 46, lowbit, n);
dataDymY.Amp3 = lowbit * n;
DataExtract(pRecvData, 48, lowbit, n);
dataDymY.Amp4 = lowbit * n;
DataExtract(pRecvData, 50, lowbit, n);
dataDymY.Amp5 = lowbit * n;
memset(buf, 0, sizeof(buf));
dataDymY.EnvelopEnergy = 0;
memset(buf, 0, sizeof(buf));
dataDymY.Phase1 = 0;
memset(buf, 0, sizeof(buf));
dataDymY.Phase2 = 0;
memset(buf, 0, sizeof(buf));
dataDymY.Phase3 = 0;
memset(buf, 0, sizeof(buf));
dataDymY.Phase4 = 0;
memset(whereCon, 0, 1024);
sprintf(whereCon, "channelID='%s' ", (strMeasurementID + "-Y").c_str());
memset(updateSql, 0, 1024);
sprintf(updateSql, "diagnosisPk='%f',integratPk='%f',integratRMS='%f',rmsValues='%f',envelopEnergy='%f',\
Amp1='%f',Amp2='%f',Amp3='%f',Amp4='%f',Amp5='%f',Phase1='%f',Phase2='%f',Phase3='%f',Phase4='%f',timeStamp='%s',StaticIndex = %ld,nodeResend = %d ",
dataDymY.DiagnosisPk, dataDymY.IntegratPk, dataDymY.IntegratRMS, dataDymY.RmsValues, dataDymY.EnvelopEnergy, dataDymY.Amp1, dataDymY.Amp2, dataDymY.Amp3, dataDymY.Amp4, dataDymY.Amp5, dataDymY.Phase1, dataDymY.Phase2, dataDymY.Phase3, dataDymY.Phase4,
nowTimetamp.c_str(), staticIndex, nodeResend);
if (/*0 == sqlite_db_ctrl::instance().GetTableRows(T_DATA_INFO(TNAME), whereCon)*/ (Count * 3 < SAVE_COUNT && lTime < OneWeek) || strTime.size() == 0) {
char insertSql[1024] = {0};
memset(insertSql, 0x00, sizeof(insertSql));
sprintf(insertSql, "'%s','%s','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f',%ld,'%s','1',%d", strMeasurementID.c_str(), (strMeasurementID + "-Y").c_str(), dataDymY.DiagnosisPk, dataDymY.IntegratPk, dataDymY.IntegratRMS, dataDymY.RmsValues,
dataDymY.EnvelopEnergy, dataDymY.Amp1, dataDymY.Amp2, dataDymY.Amp3, dataDymY.Amp4, dataDymY.Amp5, dataDymY.Phase1, dataDymY.Phase2, dataDymY.Phase3, dataDymY.Phase4, staticIndex, nowTimetamp.c_str(), nodeResend);
sqlite_db_ctrl::instance().InsertData(szTableName, insertSql);
if (0 == sqlite_db_ctrl::instance().GetTableRows(T_DATA_INFO(TNAME), whereCon))
sqlite_db_ctrl::instance().InsertData(T_DATA_INFO(TNAME), insertSql);
else
sqlite_db_ctrl::instance().UpdateTableData(T_DATA_INFO(TNAME), updateSql, whereCon);
} else {
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(whereCon, "channelID='%s' and timeStamp = '%s'", (strMeasurementID + "-Y").c_str(), strTime.c_str());
sqlite_db_ctrl::instance().UpdateTableData(szTableName, updateSql, whereCon);
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(whereCon, "channelID='%s' ", (strMeasurementID + "-Y").c_str());
sqlite_db_ctrl::instance().UpdateTableData(T_DATA_INFO(TNAME), updateSql, whereCon);
}
zlog_info(zct, "y: %s,%s,diagnosisPk=%f,integratPk=%f,integratRMS=%f,rmsValues=%f,envelopEnergy=%f,Amp1=%f,Amp2=%f,Amp3=%f,Amp4=%f,Amp5=%f,Phase1=%f,Phase2=%f,Phase3=%f,Phase4=%f,timeStamp=%s", strMeasurementID.c_str(), (strMeasurementID + "-Y").c_str(), dataDymY.DiagnosisPk,
dataDymY.IntegratPk, dataDymY.IntegratRMS, dataDymY.RmsValues, dataDymY.EnvelopEnergy, dataDymY.Amp1, dataDymY.Amp2, dataDymY.Amp3, dataDymY.Amp4, dataDymY.Amp5, dataDymY.Phase1, dataDymY.Phase2, dataDymY.Phase3, dataDymY.Phase4, nowTimetamp.c_str());
valNodeFeature["dataNodeNo"] = strMeasurementID;
valNodeFeature["ChannelId"] = strMeasurementID + "-Y";
valNodeFeature["diagnosisPk"] = dataDymY.DiagnosisPk;
valNodeFeature["integratPk"] = dataDymY.IntegratPk;
valNodeFeature["integratRMS"] = dataDymY.IntegratRMS;
valNodeFeature["rmsValues"] = dataDymY.RmsValues;
valNodeFeature["envelopEnergy"] = dataDymY.EnvelopEnergy;
valNodeFeature["Amp1"] = dataDymY.Amp1;
valNodeFeature["Amp2"] = dataDymY.Amp2;
valNodeFeature["Amp3"] = dataDymY.Amp3;
valNodeFeature["Amp4"] = dataDymY.Amp4;
valNodeFeature["Amp5"] = dataDymY.Amp5;
valNodeFeature["Phase1"] = dataDymY.Phase1;
valNodeFeature["Phase2"] = dataDymY.Phase2;
valNodeFeature["Phase3"] = dataDymY.Phase3;
valNodeFeature["Phase4"] = dataDymY.Phase4;
valNodeFeature["timeStamp"] = nowTimetamp;
valNodeData.append(valNodeFeature);
DataRecvDym dataDymZ;
DataExtract(pRecvData, 52, lowbit, n);
dataDymZ.DiagnosisPk = lowbit * n;
DataExtract(pRecvData, 54, lowbit, n);
dataDymZ.RmsValues = lowbit * n;
DataExtract(pRecvData, 56, lowbit, n);
dataDymZ.IntegratPk = lowbit * n;
DataExtract(pRecvData, 58, lowbit, n);
dataDymZ.IntegratRMS = lowbit * n;
DataExtract(pRecvData, 60, lowbit, n);
dataDymZ.Amp1 = lowbit * n;
DataExtract(pRecvData, 62, lowbit, n);
dataDymZ.Amp2 = lowbit * n;
DataExtract(pRecvData, 64, lowbit, n);
dataDymZ.Amp3 = lowbit * n;
DataExtract(pRecvData, 66, lowbit, n);
dataDymZ.Amp4 = lowbit * n;
DataExtract(pRecvData, 68, lowbit, n);
dataDymZ.Amp5 = lowbit * n;
DataExtract(pRecvData, 70, lowbit, n);
dataDymZ.EnvelopEnergy = lowbit * n;
DataExtract(pRecvData, 72, lowbit, n);
dataDymZ.Phase1 = lowbit * n;
DataExtract(pRecvData, 74, lowbit, n);
dataDymZ.Phase2 = lowbit * n;
DataExtract(pRecvData, 76, lowbit, n);
dataDymZ.Phase3 = lowbit * n;
DataExtract(pRecvData, 78, lowbit, n);
dataDymZ.Phase4 = lowbit * n;
memset(whereCon, 0, 1024);
sprintf(whereCon, "channelID='%s' ", (strMeasurementID + "-Z").c_str());
memset(updateSql, 0, 1024);
sprintf(updateSql, "diagnosisPk='%f',integratPk='%f',integratRMS='%f',rmsValues='%f',envelopEnergy='%f',\
Amp1='%f',Amp2='%f',Amp3='%f',Amp4='%f',Amp5='%f',Phase1='%f',Phase2='%f',Phase3='%f',Phase4='%f',timeStamp='%s',StaticIndex = %ld,nodeResend = %d ",
dataDymZ.DiagnosisPk, dataDymZ.IntegratPk, dataDymZ.IntegratRMS, dataDymZ.RmsValues, dataDymZ.EnvelopEnergy, dataDymZ.Amp1, dataDymZ.Amp2, dataDymZ.Amp3, dataDymZ.Amp4, dataDymZ.Amp5, dataDymZ.Phase1, dataDymZ.Phase2, dataDymZ.Phase3, dataDymZ.Phase4,
nowTimetamp.c_str(), staticIndex, nodeResend);
if (/*0 == sqlite_db_ctrl::instance().GetTableRows(T_DATA_INFO(TNAME), whereCon)*/ Count * 3 < SAVE_COUNT && (lTime < OneWeek || strTime.size() == 0)) {
char insertSql[1024] = {0};
memset(insertSql, 0x00, sizeof(insertSql));
sprintf(insertSql, "'%s','%s','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f','%f',%ld,'%s','1',%d", strMeasurementID.c_str(), (strMeasurementID + "-Z").c_str(), dataDymZ.DiagnosisPk, dataDymZ.IntegratPk, dataDymZ.IntegratRMS, dataDymZ.RmsValues,
dataDymZ.EnvelopEnergy, dataDymZ.Amp1, dataDymZ.Amp2, dataDymZ.Amp3, dataDymZ.Amp4, dataDymZ.Amp5, dataDymZ.Phase1, dataDymZ.Phase2, dataDymZ.Phase3, dataDymZ.Phase4, staticIndex, nowTimetamp.c_str(), nodeResend);
sqlite_db_ctrl::instance().InsertData(szTableName, insertSql);
if (0 == sqlite_db_ctrl::instance().GetTableRows(T_DATA_INFO(TNAME), whereCon))
sqlite_db_ctrl::instance().InsertData(T_DATA_INFO(TNAME), insertSql);
else
sqlite_db_ctrl::instance().UpdateTableData(T_DATA_INFO(TNAME), updateSql, whereCon);
} else {
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(whereCon, "channelID='%s' and timeStamp = '%s'", (strMeasurementID + "-Z").c_str(), strTime.c_str());
sqlite_db_ctrl::instance().UpdateTableData(szTableName, updateSql, whereCon);
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(whereCon, "channelID='%s' ", (strMeasurementID + "-Z").c_str());
sqlite_db_ctrl::instance().UpdateTableData(T_DATA_INFO(TNAME), updateSql, whereCon);
}
zlog_info(zct, "Z: %s,%s,diagnosisPk=%f,integratPk=%f,integratRMS=%f,rmsValues=%f,envelopEnergy=%f,Amp1=%f,Amp2=%f,Amp3=%f,Amp4=%f,Amp5=%f,Phase1=%f,Phase2=%f,Phase3=%f,Phase4=%f,timeStamp=%s", strMeasurementID.c_str(), (strMeasurementID + "-Z").c_str(), dataDymZ.DiagnosisPk,
dataDymZ.IntegratPk, dataDymZ.IntegratRMS, dataDymZ.RmsValues, dataDymZ.EnvelopEnergy, dataDymZ.Amp1, dataDymZ.Amp2, dataDymZ.Amp3, dataDymZ.Amp4, dataDymZ.Amp5, dataDymZ.Phase1, dataDymZ.Phase2, dataDymZ.Phase3, dataDymZ.Phase4, nowTimetamp.c_str());
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(whereCon, "MeasurementID='%s'", strMeasurementID.c_str());
sqlite_db_ctrl::instance().UpdateTableData(T_SENSOR_INFO(TNAME), "status='1'", whereCon);
//无线传感器Z信息
valNodeFeature["dataNodeNo"] = strMeasurementID;
valNodeFeature["ChannelId"] = strMeasurementID + "-Z";
valNodeFeature["diagnosisPk"] = dataDymZ.DiagnosisPk;
valNodeFeature["integratPk"] = dataDymZ.IntegratPk;
valNodeFeature["integratRMS"] = dataDymZ.IntegratRMS;
valNodeFeature["rmsValues"] = dataDymZ.RmsValues;
valNodeFeature["envelopEnergy"] = dataDymZ.EnvelopEnergy;
valNodeFeature["Amp1"] = dataDymZ.Amp1;
valNodeFeature["Amp2"] = dataDymZ.Amp2;
valNodeFeature["Amp3"] = dataDymZ.Amp3;
valNodeFeature["Amp4"] = dataDymZ.Amp4;
valNodeFeature["Amp5"] = dataDymZ.Amp5;
valNodeFeature["Phase1"] = dataDymZ.Phase1;
valNodeFeature["Phase2"] = dataDymZ.Phase2;
valNodeFeature["Phase3"] = dataDymZ.Phase3;
valNodeFeature["Phase4"] = dataDymZ.Phase4;
valNodeFeature["timeStamp"] = nowTimetamp;
valNodeData.append(valNodeFeature);
memset(whereCon, 0, 1024);
sprintf(whereCon, "MeasurementID='%s'", strMeasurementID.c_str());
std::string strBattery = sqlite_db_ctrl::instance().GetData(T_SENSOR_INFO(TNAME), "batteryPower", whereCon);
std::vector<std::string> vBattery;
vBattery.push_back("0");
vBattery.push_back("0");
if (strBattery.length() > 0) {
boost::split(vBattery, strBattery, boost::is_any_of(","), boost::token_compress_on);
}
//无线传感器信息
Json::Value root;
Json::Value valdatastatic;
valdatastatic["TemperatureTop"] = dataStatic.TemTop;
valdatastatic["TemperatureBot"] = dataStatic.TemBot;
valdatastatic["WorkTime"] = dataStatic.nodeWorkTime;
valdatastatic["SendTime"] = dataStatic.nodeSendTime;
valdatastatic["Dip"] = dataStatic.Dip;
valdatastatic["Voltage"] = dataStatic.Voltage;
valdatastatic["ChannelType"] = "STATUS";
valdatastatic["ChannelId"] = strMeasurementID + "-S";
valdatastatic["TimeStamp"] = nowTimetamp;
valdatastatic["bateryProportion"] = atof(vBattery[1].c_str()) / atof(vBattery[0].c_str());
valdatastatic["batteryRemainDay"] = atof(vBattery[1].c_str());
valdatastatic["dataNodeNo"] = strMeasurementID;
valNodeData.append(valdatastatic);
root["data"] = valNodeData;
root["TimeStamp"] = nowTimetamp;
root["dataNodeNo"] = strMeasurementID;
root["dataNodeGatewayNo"] = GlobalConfig::MacAddr_G;
Json::FastWriter featureValue;
std::string strstatisticData = featureValue.write(root);
int iRet = data_publish(strstatisticData.c_str(), GlobalConfig::Topic_G.mPubData.c_str());
zlog_info(zct, "dataNodeNo = '%s' and TimeStamp = '%s',MQTT ret = %d", strMeasurementID.c_str(), nowTimetamp.c_str(), iRet);
if (iRet != 0) {
char updateSql[1024] = {0};
memset(whereCon, 0, 1024);
sprintf(whereCon, "dataNodeNo = '%s' and TimeStamp = '%s'", strMeasurementID.c_str(), nowTimetamp.c_str());
memcpy(updateSql, "sendMsg='0'", 11);
sqlite_db_ctrl::instance().UpdateTableData(szTableNameStatic, updateSql, whereCon);
sqlite_db_ctrl::instance().UpdateTableData(szTableNameData, updateSql, whereCon);
}
//综上代码把静态数据x y z轴的特征值存放到sql数据库中如果数据原来不存在则插入新数据如果存在则更新数据
zlog_info(zct, "Dip : %d TemBot : %f TemBot : %f Voltage : %d", dataStatic.Dip, dataStatic.TemBot, dataStatic.TemTop, dataStatic.Voltage);
memset(selectCon, 0x00, sizeof(selectCon));
sprintf(selectCon, "zigbeeSignal <> '' ORDER BY timeStamp desc LIMIT 0,1");
strTime = sqlite_db_ctrl::instance().GetData(szTableNameStatic, "timeStamp", selectCon);
if (flag == 1) {
zlog_info(zct, "DealDataNodeFeature end %02x%02x", pRecvData->ShortAddr[0], pRecvData->ShortAddr[1]);
}
}
float Uart::ScaleConvert(int highbit) { return 0.0001f * pow(100.0f, highbit); }
void Uart::DealDataNodeWave(const char *pData, int comand) {
RecvData *pRecvData = (RecvData *)pData;
if (wave_trans_) {
if (comand == WAVE_X) {
VecWaveDataX.push_back(*pRecvData);
} else if (comand == WAVE_Y) {
VecWaveDataY.push_back(*pRecvData);
} else if (comand == WAVE_Z) {
VecWaveDataZ.push_back(*pRecvData);
}
} else {
if (comand == WAVE_X) {
g_VecWaveDataX[m_waveCountX] = *pRecvData;
m_waveCountX++;
} else if (comand == WAVE_Y) {
g_VecWaveDataY[m_waveCountY] = *pRecvData;
m_waveCountY++;
} else if (comand == WAVE_Z) {
g_VecWaveDataZ[m_waveCountZ] = *pRecvData;
m_waveCountZ++;
}
}
char localtimestamp[32] = {0};
GetTimeNet(localtimestamp, 1);
// 接收到原始数据信息,则更新时间戳,如果三秒种未收到原始数据,则重新从短地址 9999 切换回 短地址 8888
m_TimeStamp = strtol(localtimestamp, NULL, 10);
}
void Uart::DealWaveThread() {
while (1) {
DealWave();
sleep(1);
}
}
std::vector<float> Uart::DealData(int iChannel, float coe, unsigned int sampleRate, int ACCSampleTime, std::string strProduct) {
memset(data,0,sizeof(data));
memset(dealdata,0,sizeof(dealdata));
memset(outdata,0,sizeof(outdata));
size_t waveCount = 0;
long unsigned int new_len = 0, deallen = 0;
int compress = 0;
size_t count = 0;
long iTemp = 0;
char buf[8] = {0x00};
std::vector<float> vecData;
size_t j = 0;
std::string strShortAddr = "";
if (iChannel == WAVE_X) {
if (VecWaveDataX.size() > 0) {
g_VecWaveDataX.assign(VecWaveDataX.begin(), VecWaveDataX.end());
waveCount = VecWaveDataX.size();
}
waveCount = m_waveCountX;
for (; j < waveCount; j++) {
RecvData recvData = g_VecWaveDataX[j];
memcpy(data + j * 92, recvData.Data, 92);
}
memset(buf, 0x00, sizeof(buf));
sprintf(buf, "%02x%02x", g_VecWaveDataX[0].ShortAddr[0], g_VecWaveDataX[0].ShortAddr[1]);
strShortAddr = std::string(buf);
compress = g_mapCompress[strShortAddr].compressChannelX;
count = g_mapCompress[strShortAddr].CountX;
}
if (iChannel == WAVE_Y) {
if (VecWaveDataY.size() > 0) {
g_VecWaveDataY.assign(VecWaveDataY.begin(), VecWaveDataY.end());
waveCount = VecWaveDataY.size();
}
waveCount = m_waveCountY;
for (; j < waveCount; j++) {
RecvData recvData = g_VecWaveDataY[j];
memcpy(data + j * 92, recvData.Data, 92);
}
memset(buf, 0x00, sizeof(buf));
sprintf(buf, "%02x%02x", g_VecWaveDataY[0].ShortAddr[0], g_VecWaveDataY[0].ShortAddr[1]);
strShortAddr = std::string(buf);
compress = g_mapCompress[strShortAddr].compressChannelY;
count = g_mapCompress[strShortAddr].CountY;
}
if (iChannel == WAVE_Z) {
if (VecWaveDataZ.size() > 0) {
g_VecWaveDataZ.assign(VecWaveDataZ.begin(), VecWaveDataZ.end());
waveCount = VecWaveDataZ.size();
}
waveCount = m_waveCountZ;
for (; j < waveCount; j++) {
RecvData recvData = g_VecWaveDataZ[j];
memcpy(data + j * 92, recvData.Data, 92);
}
memset(buf, 0x00, sizeof(buf));
sprintf(buf, "%02x%02x", g_VecWaveDataZ[0].ShortAddr[0], g_VecWaveDataZ[0].ShortAddr[1]);
strShortAddr = std::string(buf);
compress = g_mapCompress[strShortAddr].compressChannelZ;
count = g_mapCompress[strShortAddr].CountZ;
}
zlog_info(zct, "len = %d,data = %02x,iChannel = %d,compress = %d,count = %d", j, data[0], iChannel, compress, count);
if (j * 92 < count) return vecData;
if (compress) {
zlog_info(zct, "iChannel = %d,compress = %d", iChannel, compress);
int r = lzo1x_decompress(data, count, outdata, &new_len, NULL);
zlog_info(zct, "lzo1x_decompress end");
if (r == LZO_E_OK) {
zlog_warn(zct, "iChannel = %d ,ShortAddr = %s decompressed %lu bytes back into %lu bytes", iChannel, strShortAddr.c_str(), (unsigned long)j * 92, (unsigned long)new_len);
} else {
zlog_error(zct, "internal error - decompression failed: %d,channel = %d,ShortAddr = %s", r, iChannel, strShortAddr.c_str());
return vecData;
}
memcpy(dealdata, outdata, new_len);
deallen = new_len;
} else {
memcpy(dealdata, data, j * 92);
deallen = j * 92;
}
for (size_t i = 0; i < deallen; i++) {
float fTemp = 0.0f;
memset(buf, 0, 8);
sprintf(buf, "%02x%02x", dealdata[2 * i + 1], dealdata[i * 2]);
iTemp = strtol(buf, NULL, 16);
if (iTemp < 0x8000) {
fTemp = iTemp * coe * 9.8f; // convert to m/s2
} else {
fTemp = (((~iTemp) & 0xffff) + 1) * -coe * 9.8f; // convert to m/s2
}
vecData.push_back(fTemp);
if (strProduct == "01") {
if (vecData.size() == sampleRate * ACCSampleTime && iChannel == WAVE_X) { //过滤数据包结尾空数据
zlog_info(zct, "%d vecData.size() == %d,sampleRate * ACCSampleTime = %d", iChannel, vecData.size(), sampleRate * ACCSampleTime);
break;
}
if (vecData.size() == sampleRate * ACCSampleTime && iChannel == WAVE_Y) { //过滤数据包结尾空数据
zlog_info(zct, "%d vecData.size() == %d,sampleRate * ACCSampleTime = %d", iChannel, vecData.size(), sampleRate * ACCSampleTime);
break;
}
if (vecData.size() == sampleRate * ACCSampleTime && iChannel == WAVE_Z) { //过滤数据包结尾空数据
zlog_info(zct, "%d vecData.size() == %d,sampleRate * ACCSampleTime = %d", iChannel, vecData.size(), sampleRate * ACCSampleTime);
break;
}
} else if (strProduct == "02") {
if (vecData.size() == 8192 && iChannel == WAVE_X) { //过滤数据包结尾空数据
break;
}
if (vecData.size() == 8192 && iChannel == WAVE_Y) { //过滤数据包结尾空数据
break;
}
if (vecData.size() == sampleRate * ACCSampleTime && iChannel == WAVE_Z) { //过滤数据包结尾空数据
break;
}
}
}
return vecData;
}
void Uart::DealWave() {
std::string strShortAddr = "";
std::string strShortAddrTemp;
std::string strLongAddr = "";
std::string strMeasurementID = "";
std::string strFileName = "";
std::string strProduct = "";
std::vector<float> vecData;
if (wave_trans_) { //对每个传感器的每个通道进行遍历然后处理数据例如传感器1x轴的数据处理完后再去处理y轴的。传感器1的所有数据处理完后再处理传感器2的
char getzigbeeShortAddr[32] = {0};
sprintf(getzigbeeShortAddr, "zigbeeShortAddr='%02x%02x'", (wave_shortAddr >> 8) & 0xFF,wave_shortAddr & 0xFF);
vec_t res = sqlite_db_ctrl::instance().GetDataSingleLine(T_SENSOR_INFO(TNAME), " * ", getzigbeeShortAddr);
if (res.size() < 0)
{
wave_trans_ = false;
return;
}
strLongAddr = res[0];
strMeasurementID = res[44];
if (0 == strLongAddr.length()) {
sleep(1);
wave_trans_ = false;
return;
}
std::string ran = "";
int n = 0;
int range = 0;
float coe = 0;
int sampleRate = 0, ACCSampleTime = 0;
char getrange[32] = {0};
std::string str = "range";
sprintf(getrange, "zigbeeShortAddr='%s'", strShortAddr.c_str());
ran = res[25];
sampleRate = atoi(res[23].c_str());
ACCSampleTime = atoi(res[36].c_str());
strProduct = res[17];
memset(getrange, 0, 32);
sprintf(getrange, "%s", ran.c_str());
n = (int)strtol(getrange, NULL, 32);
if (m_waveCountX > 0 || VecWaveDataX.size() > 0) {
zlog_info(zct, "m_waveCountX = %d,VecWaveData = %d", m_waveCountX, VecWaveDataX.size());
coe = Calcoe(n, WAVE_X, strProduct, range);
vecData = DealData(WAVE_X, coe, sampleRate, ACCSampleTime, strProduct);
WriteDatFile(sampleRate, strMeasurementID, WAVE_X, vecData);
m_waveCountX = 0;
g_VecWaveDataX.clear();
VecWaveDataX.clear();
}
if (m_waveCountY > 0 || VecWaveDataY.size() > 0) {
zlog_info(zct, "m_waveCountY = %d,VecWaveData = %d", m_waveCountY, VecWaveDataY.size());
coe = Calcoe(n, WAVE_Y, strProduct, range);
vecData = DealData(WAVE_Y, coe, sampleRate, ACCSampleTime, strProduct);
WriteDatFile(sampleRate, strMeasurementID, WAVE_Y, vecData);
m_waveCountY = 0;
g_VecWaveDataY.clear();
VecWaveDataY.clear();
}
if (m_waveCountZ > 0 || VecWaveDataZ.size() > 0) {
zlog_info(zct, "m_waveCountZ = %d,VecWaveDataZ = %d", m_waveCountZ, VecWaveDataZ.size());
coe = Calcoe(n, WAVE_Z, strProduct, range);
vecData = DealData(WAVE_Z, coe, sampleRate, ACCSampleTime, strProduct);
WriteDatFile(sampleRate, strMeasurementID, WAVE_Z, vecData);
m_waveCountZ = 0;
g_VecWaveDataZ.clear();
VecWaveDataZ.clear();
}
if (m_waveCountX > 0 || m_waveCountY > 0 || m_waveCountZ > 0)
{
char localtimestamp[32] = {0};
GetTimeNet(localtimestamp, 1);
char insertSql[100] = {0x00};
char whereCon[50] = {0x00};
sprintf(whereCon, "MeasurementID='%s'",strMeasurementID.c_str());
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(insertSql, "'%s','%02x%02x','%s',0,'1','%s' ", strMeasurementID.c_str(),(wave_shortAddr >> 8) & 0xFF,wave_shortAddr & 0xFF,localtimestamp,"");
sqlite_db_ctrl::instance().InsertData(" receive_wave_status ", insertSql);
}
wave_trans_ = false;
}
}
float Uart::Calcoe(int ran, int iChannel, std::string &product, int range) {
float coe = 0.0f;
if (product == "01") {
switch (ran) {
case 0: {
range = 8;
coe = 8 * 1.0f / 32767;
} break;
case 1: {
range = 16;
coe = 16 * 1.0f / 32767;
} break;
case 2: {
range = 32;
coe = 32 * 1.0f / 32767;
} break;
case 3: {
range = 64;
coe = 64 * 1.0f / 32767;
} break;
}
} else if (product == "02") {
if (iChannel == WAVE_X || iChannel == WAVE_Y) {
coe = 0.00048828125f;
}
if (iChannel == WAVE_Z) {
coe = 0.00172607421875f;
}
}
return coe;
}
void Uart::WriteDatFile(int sampleRate, std::string &strMeasurementID, int iChannel, std::vector<float> &vecData) {
if (vecData.size() <= 0) return;
std::string strFileName = "";
char localtimestamp[32] = {0};
GetTimeNet(localtimestamp, 1);
std::string nowTimetamp = std::string(localtimestamp);
std::string strChannelID = "";
float mean = Calculation::mean(vecData);
float frTemp;
char buf[33] = {0x00};
std::string strWaveData = "";
WaveChannel wave_channel;
memset(mqttData,0,sizeof(mqttData));
switch (iChannel) {
case WAVE_X: {
strFileName = "/opt/data/" + strMeasurementID + "-X.dat";
strChannelID = strMeasurementID + "-X";
} break;
case WAVE_Y: {
strFileName = "/opt/data/" + strMeasurementID + "-Y.dat";
strChannelID = strMeasurementID + "-Y";
} break;
case WAVE_Z: {
strFileName = "/opt/data/" + strMeasurementID + "-Z.dat";
strChannelID = strMeasurementID + "-Z";
} break;
default: break;
}
FILE *fp = fopen(strFileName.c_str(), "w");
fwrite(localtimestamp,sizeof(localtimestamp),1,fp);
zlog_info(zct, " vecData.size : %d,start ", vecData.size());
int id = 0;
for (size_t i = 0; i < vecData.size(); i++) {
frTemp = vecData[i] - mean;
memset(buf, 0x00, sizeof(buf));
sprintf(buf, "%.2f", frTemp);
fwrite(&frTemp,sizeof(float),1,fp);
if (iChannel == WAVE_X){
wave_channel.WaveChannelX[i] = frTemp;
}else if (iChannel == WAVE_Y){
wave_channel.WaveChannelY[i] = frTemp;
}else if (iChannel == WAVE_Z){
wave_channel.WaveChannelZ[i] = frTemp;
}
if (i != vecData.size() -1){
strncpy(mqttData + id ,buf,strlen(buf));
id = id + strlen(buf);
strncpy(mqttData + id,",",1);
id = id + 1;
}else{
strncpy(mqttData + id ,buf,strlen(buf));
}
}
fclose(fp);
zlog_info(zct, "fopen FIle vecData.size : %d end ", vecData.size());
wave_channel.wave_timestamp = nowTimetamp;
g_mapWaveChannel[strMeasurementID] = wave_channel;
Json::Value valWaveData;
valWaveData["number"] = sampleRate;
valWaveData["channelId"] = strChannelID;
valWaveData["dataNodeNo"] = strMeasurementID;
valWaveData["dataNodeGatewayNo"] = GlobalConfig::MacAddr_G;
valWaveData["SensorEngineeringUnit"] = "";
valWaveData["timeStamp"] = nowTimetamp;
valWaveData["waveData"] = mqttData;
valWaveData["mean"] = mean;
Json::FastWriter WaveValue;
std::string WaveData = WaveValue.write(valWaveData);
char selectCon[128] = {0};
sprintf(selectCon, "channelID='%s' ORDER BY timeStamp ASC LIMIT 0,1", strChannelID.c_str());
std::string strTime = sqlite_db_ctrl::instance().GetData("t_data_waveSend", "timeStamp", selectCon);
long lTime = atol(nowTimetamp.c_str()) - atol(strTime.c_str());
int Count = sqlite_db_ctrl::instance().GetTableRows("t_data_waveSend", NULL);
std::string strFileName_Record = strFileName + "_" + nowTimetamp;
if ((Count * 3 < SAVE_COUNT && lTime < OneWeek) || strTime.size() == 0) {
char insertSql[128] = {0x00};
sprintf(insertSql, "'%s','%s','%s',1,0,0", strChannelID.c_str(), strFileName_Record.c_str(), nowTimetamp.c_str());
sqlite_db_ctrl::instance().InsertData("t_data_waveSend", insertSql);
} else {
char updateSql[128] = {0}, whereCon[128] = {0};
sprintf(updateSql, "waveName='%s',timeStamp='%s'", strFileName_Record.c_str(), nowTimetamp.c_str());
memset(whereCon, 0x00, sizeof(whereCon));
sprintf(whereCon, "channelID='%s' and timeStamp = '%s'", strChannelID.c_str(), strTime.c_str());
zlog_info(zct, "update static data to sql");
sqlite_db_ctrl::instance().UpdateTableData("t_data_waveSend", updateSql, whereCon);
}
//传感器发来的数据包中的表示设备信息的数据转化为json格式后通过调用data_publish将数据传给mqttclient Topicwireless/cmd/60294D203717
int iRet = data_publish(WaveData.c_str(), GlobalConfig::Topic_G.mPubWaveData.c_str());
if (iRet != 0) {
char whereCon[1024] = {0x00};
char updateSql[1024] = {0x00};
char tmpWhere[128] = {0x00};
sprintf(tmpWhere, "channelID = '%s' and sendMsg = 0 ", strChannelID.c_str());
int count = sqlite_db_ctrl::instance().GetTableRows("t_data_waveSend", tmpWhere);
zlog_info(zct, "save channlID %s dat count = %d", strChannelID.c_str(), count);
zlog_warn(zct, "send failed,filename %s,iRet = %d", strFileName.c_str(), iRet);
if (count <= 3) {
sprintf(whereCon, "channelID='%s' and timeStamp = '%s' ", strChannelID.c_str(), nowTimetamp.c_str());
sprintf(updateSql, "SendMsg = 0 , error_code = %d",iRet);
sqlite_db_ctrl::instance().UpdateTableData("t_data_waveSend", updateSql, whereCon);
std::string strFileName_failed = strFileName + "_" + nowTimetamp;
char tmpCmd[128] = {0x00};
sprintf(tmpCmd, "cp %s %s", strFileName.c_str(), strFileName_failed.c_str());
system(tmpCmd);
} else {
memset(tmpWhere, 0x00, sizeof(tmpWhere));
memset(updateSql, 0x00, sizeof(updateSql));
sprintf(tmpWhere, " sendMsg = 0 and channelID='%s' ORDER BY timeStamp ASC LIMIT 0,1", strChannelID.c_str());
vec_t vecRet = sqlite_db_ctrl::instance().GetDataSingleLine("t_data_waveSend", "*", tmpWhere);
memset(tmpWhere, 0x00, sizeof(tmpWhere));
sprintf(tmpWhere, " sendMsg = 0 and timeStamp = '%s' and channelID = '%s' ", vecRet[2].c_str(), vecRet[0].c_str());
sprintf(updateSql, " sendMsg = 3 ");
sqlite_db_ctrl::instance().UpdateTableData("t_data_waveSend", updateSql, tmpWhere);
memset(tmpWhere, 0x00, sizeof(tmpWhere));
memset(updateSql, 0x00, sizeof(updateSql));
sprintf(whereCon, " channelID='%s' and timeStamp = '%s' ", strChannelID.c_str(), nowTimetamp.c_str());
sprintf(updateSql, " sendMsg = 0 , error_code = %d ",iRet);
sqlite_db_ctrl::instance().UpdateTableData("t_data_waveSend", updateSql, whereCon);
std::string strFileName_failed = strFileName + "_" + nowTimetamp;
char tmpCmd[128] = {0x00};
sprintf(tmpCmd, "cp %s %s", strFileName.c_str(), strFileName_failed.c_str());
system(tmpCmd);
zlog_info(zct, "cp dat file %s \n", tmpCmd);
memset(tmpWhere, 0x00, sizeof(tmpWhere));
sprintf(tmpWhere, " channelID = '%s' and sendMsg = 0 ", strChannelID.c_str());
sqlite_db_ctrl::instance().GetTableRows("t_data_waveSend", tmpWhere);
memset(tmpCmd, 0x00, sizeof(tmpCmd));
sprintf(tmpCmd, "rm %s ", vecRet[1].c_str());
system(tmpCmd);
zlog_info(zct, "rm dat file %s \n", tmpCmd);
}
} else {
zlog_warn(zct, "send data , filename %s,size = %d\n", strFileName.c_str(), vecData.size());
}
char whereCon[1024] = {0x00};
char updateSql[1024] = {0x00};
char tmpWhere[128] = {0x00};
sprintf(tmpWhere, "channelID = '%s' and save = 1 ", strChannelID.c_str());
int count = sqlite_db_ctrl::instance().GetTableRows("t_data_waveSend", tmpWhere);
zlog_info(zct, "save channlID %s dat count = %d\n", strChannelID.c_str(), count);
if (count <= 5) {
sprintf(whereCon, "channelID='%s' and timeStamp = '%s' ", strChannelID.c_str(), nowTimetamp.c_str());
sprintf(updateSql, "save = 1 ");
sqlite_db_ctrl::instance().UpdateTableData("t_data_waveSend", updateSql, whereCon);
std::string strFileName_save = strFileName + "_" + nowTimetamp + "_save";
char tmpCmd[128] = {0x00};
sprintf(tmpCmd, "cp %s %s", strFileName.c_str(), strFileName_save.c_str());
system(tmpCmd);
} else {
memset(tmpWhere, 0x00, sizeof(tmpWhere));
memset(updateSql, 0x00, sizeof(updateSql));
sprintf(tmpWhere, " save = 1 and channelID='%s' ORDER BY timeStamp ASC LIMIT 0,1", strChannelID.c_str());
vec_t vecRet = sqlite_db_ctrl::instance().GetDataSingleLine("t_data_waveSend", "*", tmpWhere);
memset(tmpWhere, 0x00, sizeof(tmpWhere));
sprintf(tmpWhere, " save = 1 and timeStamp = '%s' and channelID = '%s' ", vecRet[2].c_str(), vecRet[0].c_str());
sprintf(updateSql, "save = 0 ");
sqlite_db_ctrl::instance().UpdateTableData("t_data_waveSend", updateSql, tmpWhere);
memset(tmpWhere, 0x00, sizeof(tmpWhere));
memset(updateSql, 0x00, sizeof(updateSql));
sprintf(whereCon, "channelID='%s' and timeStamp = '%s' ", strChannelID.c_str(), nowTimetamp.c_str());
sprintf(updateSql, "save = 1");
sqlite_db_ctrl::instance().UpdateTableData("t_data_waveSend", updateSql, whereCon);
std::string strFileName_save = strFileName + "_" + nowTimetamp + "_save";
char tmpCmd[128] = {0x00};
sprintf(tmpCmd, "cp %s %s", strFileName.c_str(), strFileName_save.c_str());
system(tmpCmd);
memset(tmpWhere, 0x00, sizeof(tmpWhere));
sprintf(tmpWhere, " channelID = '%s' and save = 1 ", strChannelID.c_str());
sqlite_db_ctrl::instance().GetTableRows("t_data_waveSend", tmpWhere);
memset(tmpCmd, 0x00, sizeof(tmpCmd));
sprintf(tmpCmd, "rm %s ", (vecRet[1] + "_save").c_str());
system(tmpCmd);
zlog_info(zct, "rm dat file %s ", tmpCmd);
}
zlog_info(zct, "write data to filename %s", strFileName.c_str());
std::vector<float>().swap(vecData);
sleep(1);
}
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