Bachelorthesis/Modbus-CAPL/include/CAPL/MakeConfig.can

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/*@!Encoding:1252*/
includes
{
#include "include/DeviceInformation.cin"
#include "include/ModbusUdp.cin"
#include "include/ModbusClient.cin"
}
variables
{
char[16] gIps[long]; // List of IP addresses. These will be analysed
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char gScanFirstIp[16]; // The first IP address that will be scanned
char gScanLastIp[16]; // The first IP address that will be scanned
byte skip255; // Whether the IP address .255 (broadcast in /24 nets) shall be skipped
char fnSysvar[100]; // Filename of Sysvars
char fnDbc[100]; // Filename of DBC
dword ips[50]; // detected IPs. We need this array for enumeration with integers (assoc. arrays cannot be enumerated with integers :( )
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file f; // The file we are writing to
struct device gIpsSorted[long]; // The final array with the devices
dword gScanCurr, gScanLast; // The first and last IP address as dword
word ADi, ADn, ADl; // Some variables for AnalyzeDevices() (event driven, so global)
byte ggMaxTransmissionCount; // temp var for gMaxTransmissionCount
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enum eNodeName {WholeIp, LastByte, TwoLastBytes, ThreeLastBytes};
enum eNodeName NodeNameStyle; // The style of the node name
}
on preStart
{
byte i = 0;
// List of IPs of devices goes here
///strncpy(gIps[i++], "192.168.1.100", elCount(gIps));
///strncpy(gIps[i++], "192.168.1.101", elCount(gIps));
// Scan a range of IPs for devices (if nothing was set above). Start and Stop go here
strncpy(gScanFirstIp, "192.168.1.2", elCount(gScanFirstIp));
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strncpy(gScanLastIp, "192.168.1.255", elCount(gScanLastIp));
// How the Node name shall be formatted
// LastByte: 192.168.12.34 --> Client_34
// TwoLastBytes: 192.168.12.34 --> Client_12_34
// ThreeLastBytes: 192.168.12.34 --> Client_168_12_34
// WholeIp: 192.168.12.34 --> Client_192_168_12_34
NodeNameStyle = LastByte;
// Whether the IP address .255 (broadcast in /24) shall be skipped
skip255 = 1;
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// Paths to the generated files relative to MakeConfig.cfg
strncpy(fnSysvar, "include/SysVars/Modbus.vsysvar", elCount(fnSysvar));
strncpy(fnDbc, "include/DBC/Modbus.dbc", elCount(fnDbc));
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OutputDebugLevel = Error;
}
on start
{
ggMaxTransmissionCount = @sysvar::Config::Modbus::MaxTransmissionCount; // save the value
DeviceInit(All);
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if (gIps.Size() == 0) // if no IP address were specified
DetectDevices(); // scan network for devices (Step1)
else
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MakeIpNets(); // else continue with Step2
}
/// <PutString>
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void PutString(char str[])
{
f.PutString(str, strlen(str));
}
/// <PutString>
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void PutString(word d)
{
char str[6];
ltoa(d, str, 10);
f.PutString(str, strlen(str));
}
/// <PutString>
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void PutString(byte d)
{
char str[4];
ltoa(d, str, 10);
f.PutString(str, strlen(str));
}
// Step 1: Detect active devices and collect IP addresses
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// This function will convert the IP address, open the socket and start the detection. The rest will be done by events
/// <Step1>
void DetectDevices()
{
writeLineEx(0, 1, "Scanning from %s to %s with timeout of %d ms", gScanFirstIp, gScanLastIp, @sysvar::Config::Modbus::RequestTimeout);
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gScanCurr = ipGetAddressAsNumber(gScanFirstIp); // We have to use big endian here
gScanLast = swapDWord(ipGetAddressAsNumber(gScanLastIp)); // But not here :)
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writeLineEx(0, 0, "%d.%d.%d.%d ", gScanCurr & 0xFF, (gScanCurr >> 8) & 0xFF, (gScanCurr >> 16) & 0xFF, gScanCurr >> 24);
ModbusInit(gScanFirstIp, @sysvar::Config::Modbus::Port, @sysvar::Config::Modbus::RequestTimeout, 1); // Open socket and set variables
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ModbusReadBits(0, 1); // Start device detection
}
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// This function will increment the IP address and continue the detection
/// <Step1>
void DetectDevicesNext()
{
gScanCurr = swapDWord(gScanCurr); // Swap to increment
gScanCurr++; // Increment
if ((gScanCurr & 0xFF) == 0xFF) // If .255
{
if (skip255) // If we shall skip .255
gScanCurr++;
writeLineEx(0, 0, "%d.%d.%d.%d ", gScanCurr >> 24, (gScanCurr >> 16) & 0xFF, (gScanCurr >> 8) & 0xFF, gScanCurr & 0xFF);
}
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if (gScanCurr > gScanLast) // If we are beyond the last ip address
{
@sysvar::Config::Modbus::MaxTransmissionCount = ggMaxTransmissionCount; // reset
MakeIpNets(); // Continue with Step 2
return;
}
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gScanCurr = swapDWord(gScanCurr); // Swap back
writeEx(0, 0, "."); // Write something so the user knows something is happening
gRemoteIP = gScanCurr; // Don't open new socket, it takes too much time. This means we should use UDP or EIL here!
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ModbusReadBits(0, 1); // Scan the next device
}
/// <Step1>
void OnModbusReadBitsFailed(enum ModbusRequestError error, enum ModbusException ex, struct ModbusApHeader mbap)
{
DetectDevicesNext(); // Timeout, NotSent or Exception! We will go to the next device
}
/// <Step1>
void OnModbusReadBitsSuccess(struct ModbusResReceiveBits mbres, byte bitStatus[], struct ModbusReqRead mbreq)
{
ipGetAddressAsString(gScanCurr, gIps[gScanCurr], 16); // store the detected device's IP address
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DetectDevicesNext(); // and continue
}
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// Step 2: Sort into subnets and create structure
// Sort the IPs from gIps to gIpsSorted
/// <Step2>
void MakeIpNets()
{
long ipNum;
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if (gIps.Size() == 0) // If no devices were specified and detected
{
writeDbg(MbError, "No devices found!");
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stop(); // Don't do anything
return;
}
for (long i : gIps) // Iterate all devices
{
ipNum = ipGetAddressAsNumber(gIps[i]); // convert IP to dword
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ips[gIpsSorted.size()] = ipNum; // add ip address to normal array
// fill the device structure array:
strncpy(gIpsSorted[ipNum].IP, gIps[i], 16); // set .IP
ltoa((ipNum ) & 0xFF, gIpsSorted[ipNum].Ip1, 10); // set .Ip1
ltoa((ipNum >> 8) & 0xFF, gIpsSorted[ipNum].Ip2, 10); // set .Ip2
ltoa((ipNum >> 16) & 0xFF, gIpsSorted[ipNum].Ip3, 10); // set .Ip3
ltoa((ipNum >> 24) & 0xFF, gIpsSorted[ipNum].Ip4, 10); // set .Ip4
gIps.Remove(i);
}
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AnalyzeDevices(); // Continue with step 3
}
// Step 3: Retreive configuration of devices
/// <Step3>
void AnalyzeDevices()
{
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// Init counters
ADn = 1; // expect 1 response
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ADi = 0; // First IP address
ADl = gIpsSorted.Size();
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writeLineEx(0, 1, "Analyzing %s", gIpsSorted[ips[ADi]].Ip);
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if (gRemoteIP != INVALID_IP) // If we already do have a socket
gRemoteIP = ips[ADi]; // use it
else // else create a new one
_ModbusConnectTo(ips[ADi], @sysvar::Config::Modbus::Port);
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// request something special to get the vendor
// since there is no common register that holds the vendor
// we have to send a request that only one device responds correctly.
// At 0x1000-0x1002 B&R devices return the MAC address, whereas Wago holds the WatchdogTime.
// As the watchdog time only consists of 1 word Wago will return a IllegalDataAddress exception (0x02)
ModbusReadRegisters(0x1000, 3); // Request B&R MAC address
}
/// <Step3>
void AnalyzeDevicesNext()
{
// clean up the string of the previous devices
if (strlen(gIpsSorted[ips[ADi]].DeviceIOs.Modules) > 0) // If we do have some Modules in this string
gIpsSorted[ips[ADi]].DeviceIOs.Modules[strlen(gIpsSorted[ips[ADi]].DeviceIOs.Modules)-1] = 0; // Remove the last comma (set the char to NUL)
// print the result
writeEx(0, 1, ": AOs: %d, AIs: %d, DOs: %d, DIs: %d --> %s", gIpsSorted[ips[ADi]].DeviceIOs.OutputRegisters, gIpsSorted[ips[ADi]].DeviceIOs.InputRegisters, gIpsSorted[ips[ADi]].DeviceIOs.OutputBits, gIpsSorted[ips[ADi]].DeviceIOs.InputBits, gIpsSorted[ips[ADi]].DeviceIOs.Modules);
if (++ADi >= ADl) // continue with the next device. If we have analyzed all devices
{
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MakeFiles(); // go to Step4
return;
}
ADn = 1; // expect 1 response again
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gRemoteIP = ips[ADi]; // Next IP address
writeLineEx(0, 1, "Analyzing %s", gIpsSorted[ips[ADi]].Ip);
// request something special to get the vendor
ModbusReadRegisters(0x1000, 3); // Request B&R MAC address
}
/// <Step3>
void OnModbusReadRegistersFailed(enum ModbusRequestError error, enum ModbusException ex, struct ModbusApHeader mbap)
{
struct ModbusReqRead mbreq;
switch (error)
{
case Exception:
memcpy_n2h(mbreq, gQueueAck[mbap.TxID].Buffer);
if (mbreq.Address == 0x1000 && ex == IllegalDataAddress) // We requested B&R MAC and it didn't work --> Not B&R --> Wago. Not future proof :(
{
gIpsSorted[ips[ADi]].Vendor = Wago;
// request information
ADn = _DeviceGetInformation(Wago);
return;
}
writeLineEx(0, 3, "Error while analyzing %s! The device respond with exception code %d! Ignoring...", gIpsSorted[ips[ADi]].IP, ex);
break;
case Timeout:
return; // Timeout is unimportant, it means the request will be resent
case FinalTimeout:
writeLineEx(0, 3, "Error while analyzing %s! The device did not respond! Ignoring...", gIpsSorted[ips[ADi]].IP);
break;
case NotSent:
writeLineEx(0, 3, "Error while analyzing %s! The device was not available! Ignoring...", gIpsSorted[ips[ADi]].IP);
break;
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default:
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writeLineEx(0, 3, "OnModbusReadRegistersFailed: Unknown error: %d", error);
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OnModbusClientPanics(SwitchArgumentInvalid);
return;
}
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gQueueAck.Clear(); // Clear all queues
gQueuePending.Clear();
gQueueSent.Clear();
gIpsSorted.Remove(ips[ADi]); // Remove the IP
AnalyzeDevicesNext(); // And go to the next device
}
/// <Step3>
void OnModbusReadRegistersSuccess(struct ModbusResReceiveRegisters mbres, struct ModbusReqRead mbreq)
{
if (mbreq.Address == 0x1000) // We detected a B&R device (from MAC address)
{
gIpsSorted[ips[ADi]].Vendor = BuR;
// request further information
ADn = _DeviceGetInformation(BuR);
return;
}
// else parse the received data
_DeviceParseRegister(gIpsSorted[ips[ADi]], mbreq.Address, mbres.Data, mbreq.Count);
if (--ADn == 0) // If we received all registers
AnalyzeDevicesNext(); // Continue with the next device
}
// Step 4: Create the files with the queried data
/// <Step4>
void MakeFiles()
{
GenSysvars();
GenDbc();
stop();
}
// Generate the SysVars XML
/// <Step4>
void GenSysvars()
{
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writeLineEx(0, 1, "GenSysvars() -> %s", fnSysvar);
f.Open(fnSysvar, 0, 0); // rewrite file in ASCII
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PutString("<?xml version=\"1.0\" encoding=\"utf-8\"?>\n");
PutString("<systemvariables version=\"4\">\n");
PutString(" <namespace name=\"\" comment=\"\">\n");
PutString(" <namespace name=\"Config\" comment=\"\">\n");
PutString(" <namespace name=\"Modbus\" comment=\"\">\n");
PutString(" <variable anlyzLocal=\"2\" readOnly=\"false\" valueSequence=\"false\" unit=\"ms\" name=\"RequestTimeout\" comment=\"The maximum duration for a Modbus-UDP/-TCP request in milliseconds. After timeout a retransmission may be started (see MaxRetransmissionCount). Use `ping` to get the maximum latency to a device, double it and add 2-3 ms for processing.\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"");
PutString((word)@sysvar::Config::Modbus::RequestTimeout);
PutString("\" minValue=\"1\" minValuePhys=\"1\" maxValue=\"1000\" maxValuePhys=\"1000\" />\n");
PutString(" <variable anlyzLocal=\"2\" readOnly=\"false\" valueSequence=\"false\" unit=\"\" name=\"Port\" comment=\"\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"");
PutString((word)@sysvar::Config::Modbus::Port);
PutString("\" minValue=\"1\" minValuePhys=\"1\" maxValue=\"65535\" maxValuePhys=\"65535\" />\n");
PutString(" <variable anlyzLocal=\"2\" readOnly=\"false\" valueSequence=\"false\" unit=\"times\" name=\"MaxTransmissionCount\" comment=\"How often a retransmission of a request will be sent until it gets discarded and an error is thrown.\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"");
PutString((byte)@sysvar::Config::Modbus::MaxTransmissionCount);
PutString("\" minValue=\"1\" minValuePhys=\"1\" maxValue=\"10\" maxValuePhys=\"10\" />\n");
PutString(" </namespace>\n");
PutString(" <namespace name=\"TcpIp\" comment=\"\">\n");
PutString(" <variable anlyzLocal=\"2\" readOnly=\"false\" valueSequence=\"false\" unit=\"\" name=\"AdapterIndex\" comment=\"Index of network interface to use\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"2\" minValue=\"1\" minValuePhys=\"1\" maxValue=\"20\" maxValuePhys=\"20\" />\n");
PutString(" </namespace>\n");
PutString(" </namespace>\n");
PutString(" <namespace name=\"Modbus\" comment=\"\">\n");
for (long ipN : gIpsSorted)
{
DeviceInit(gIpsSorted[ipN].Vendor);
PutString(" <namespace name=\"Client_");
switch (NodeNameStyle) // Add the IP bytes depending on the style. Don't break anywhere.
{
case WholeIp:
PutString(gIpsSorted[ipN].Ip1);
PutString("_");
case ThreeLastBytes:
PutString(gIpsSorted[ipN].Ip2);
PutString("_");
case TwoLastBytes:
PutString(gIpsSorted[ipN].Ip3);
PutString("_");
case LastByte:
PutString(gIpsSorted[ipN].Ip4);
return;
default:
writeDbg(MbError, "The NodeNameStyle %d is unknown, please use a value of the enum!", NodeNameStyle);
runError(1001, 0);
break;
}
PutString("\" comment=\"Server with ip address '");
PutString(gIpsSorted[ipN].Ip);
PutString("'\">\n");
// Namespace Config
PutString(" <namespace name=\"Config\" comment=\"Configuration section for this server\">\n");
// IP
PutString(" <variable anlyzLocal=\"2\" readOnly=\"false\" valueSequence=\"false\" unit=\"\" name=\"IP\" comment=\"The IP address of this server\" bitcount=\"8\" isSigned=\"true\" encoding=\"65001\" type=\"string\" startValue=\"");
PutString(gIpsSorted[ipN].Ip);
PutString("\" />\n");
// Intveral
PutString(" <variable anlyzLocal=\"2\" readOnly=\"false\" valueSequence=\"false\" unit=\"ms\" name=\"Interval\" comment=\"The interval with which the device will be queried\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"100\" minValue=\"10\" minValuePhys=\"10\" maxValue=\"10000\" maxValuePhys=\"10000\" />\n");
PutString(" </namespace>\n");
//Namespace Info
PutString(" <namespace name=\"Info\" comment=\"Some information about the device\">\n");
// Vendor
PutString(" <variable anlyzLocal=\"2\" readOnly=\"true\" valueSequence=\"false\" unit=\"\" name=\"Vendor\" comment=\"The vendor of the device\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"");
PutString((byte)gIpsSorted[ipN].Vendor);
PutString("\">\n");
PutString(" <valuetable definesMinMax=\"true\">\n");
PutString(" <valuetableentry value=\"2\" description=\"BuR\" />\n");
PutString(" <valuetableentry value=\"23\" description=\"Wago\" />\n");
PutString(" </valuetable>\n");
PutString(" </variable>\n");
// SerialCode
PutString(" <variable anlyzLocal=\"2\" readOnly=\"true\" valueSequence=\"false\" unit=\"\" name=\"SerialCode\" comment=\"The serial code of the server\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"");
PutString(gIpsSorted[ipN].SerialCode);
PutString("\" minValue=\"1\" minValuePhys=\"1\" maxValue=\"10000\" maxValuePhys=\"10000\" />\n");
// DeviceCode
PutString(" <variable anlyzLocal=\"2\" readOnly=\"true\" valueSequence=\"false\" unit=\"\" name=\"DeviceCode\" comment=\"The device code of the server\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"");
PutString(gIpsSorted[ipN].DeviceCode);
PutString("\" minValue=\"1\" minValuePhys=\"1\" maxValue=\"10000\" maxValuePhys=\"10000\" />\n");
// Modules
PutString(" <variable anlyzLocal=\"2\" readOnly=\"true\" valueSequence=\"false\" unit=\"\" name=\"Modules\" comment=\"The type and number of inputs of modules that are connected to the server\" bitcount=\"8\" isSigned=\"true\" encoding=\"65001\" type=\"string\" startValue=\"");
PutString(gIpsSorted[ipN].DeviceIOs.Modules);
PutString("\" />\n");
// InputRegisters
PutString(" <variable anlyzLocal=\"2\" readOnly=\"true\" valueSequence=\"false\" unit=\"\" name=\"InputRegisters\" comment=\"Number of input registers\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"");
PutString(gIpsSorted[ipN].DeviceIOs.InputRegisters);
PutString("\" minValue=\"0\" minValuePhys=\"0\" maxValue=\"");
PutString((word)thisDev.MaxRegisterCount);
PutString("\" maxValuePhys=\"");
PutString((word)thisDev.MaxRegisterCount);
PutString("\" />\n");
// InputBits
PutString(" <variable anlyzLocal=\"2\" readOnly=\"true\" valueSequence=\"false\" unit=\"\" name=\"InputBits\" comment=\"Number of input bits\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"");
PutString(gIpsSorted[ipN].DeviceIOs.InputBits);
PutString("\" minValue=\"0\" minValuePhys=\"0\" maxValue=\"");
PutString((word)thisDev.MaxBitCount);
PutString("\" maxValuePhys=\"");
PutString((word)thisDev.MaxBitCount);
PutString("\" />\n");
// OutputRegisters
PutString(" <variable anlyzLocal=\"2\" readOnly=\"true\" valueSequence=\"false\" unit=\"\" name=\"OutputRegisters\" comment=\"Number of output registers\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"");
PutString(gIpsSorted[ipN].DeviceIOs.OutputRegisters);
PutString("\" minValue=\"0\" minValuePhys=\"0\" maxValue=\"");
PutString((word)thisDev.MaxRegisterCount);
PutString("\" maxValuePhys=\"");
PutString((word)thisDev.MaxRegisterCount);
PutString("\" />\n");
// OutputBits
PutString(" <variable anlyzLocal=\"2\" readOnly=\"true\" valueSequence=\"false\" unit=\"\" name=\"OutputBits\" comment=\"Number of output bits\" bitcount=\"32\" isSigned=\"true\" encoding=\"65001\" type=\"int\" startValue=\"");
PutString(gIpsSorted[ipN].DeviceIOs.OutputBits);
PutString("\" minValue=\"0\" minValuePhys=\"0\" maxValue=\"");
PutString((word)thisDev.MaxBitCount);
PutString("\" maxValuePhys=\"");
PutString((word)thisDev.MaxBitCount);
PutString("\" />\n");
PutString(" </namespace>\n");
// Namespace Data
PutString(" <namespace name=\"Data\" comment=\"The actual process image\">\n");
// InputRegisters
PutString(" <variable anlyzLocal=\"2\" readOnly=\"false\" valueSequence=\"false\" unit=\"\" name=\"InputRegisters\" comment=\"The values of the input registers\" bitcount=\"17\" isSigned=\"true\" encoding=\"65001\" type=\"intarray\" arrayLength=\"");
PutString(gIpsSorted[ipN].DeviceIOs.InputRegisters);
PutString("\" />\n");
// InputBits
PutString(" <variable anlyzLocal=\"2\" readOnly=\"false\" valueSequence=\"false\" unit=\"\" name=\"InputBits\" comment=\"The state of the input bits\" bitcount=\"2\" isSigned=\"true\" encoding=\"65001\" type=\"intarray\" arrayLength=\"");
PutString(gIpsSorted[ipN].DeviceIOs.InputBits);
PutString("\" />\n");
// OutputRegisters
PutString(" <variable anlyzLocal=\"2\" readOnly=\"false\" valueSequence=\"false\" unit=\"\" name=\"OutputRegisters\" comment=\"The values of the output registers. Write here and the values will be sent to the device\" bitcount=\"17\" isSigned=\"true\" encoding=\"65001\" type=\"intarray\" arrayLength=\"");
PutString(gIpsSorted[ipN].DeviceIOs.OutputRegisters);
PutString("\" />\n");
// OutputBits
PutString(" <variable anlyzLocal=\"2\" readOnly=\"false\" valueSequence=\"false\" unit=\"\" name=\"OutputBits\" comment=\"The state of the output bits. Write here and the values will be sent to the device\" bitcount=\"2\" isSigned=\"true\" encoding=\"65001\" type=\"intarray\" arrayLength=\"");
PutString(gIpsSorted[ipN].DeviceIOs.OutputBits);
PutString("\" />\n");
PutString(" </namespace>\n");
PutString(" </namespace>\n");
}
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PutString(" </namespace>\n");
PutString("</systemvariables>\n");
f.Close();
}
// Generate the Database
/// <Step4>
void GenDbc()
{
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writeLineEx(0, 1, "GenDbc() -> %s", fnDbc);
f.Open(fnDbc, 0, 0); // rewrite file in ASCII
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PutString("VERSION \"\"\n\n\n");
PutString("NS_ :\n");
PutString(" NS_DESC_\n");
PutString(" CM_\n");
PutString(" BA_DEF_\n");
PutString(" BA_\n");
PutString(" VAL_\n");
PutString(" CAT_DEF_\n");
PutString(" CAT_\n");
PutString(" FILTER\n");
PutString(" BA_DEF_DEF_\n");
PutString(" EV_DATA_\n");
PutString(" ENVVAR_DATA_\n");
PutString(" SGTYPE_\n");
PutString(" SGTYPE_VAL_\n");
PutString(" BA_DEF_SGTYPE_\n");
PutString(" BA_SGTYPE_\n");
PutString(" SIG_TYPE_REF_\n");
PutString(" VAL_TABLE_\n");
PutString(" SIG_GROUP_\n");
PutString(" SIG_VALTYPE_\n");
PutString(" SIGTYPE_VALTYPE_\n");
PutString(" BO_TX_BU_\n");
PutString(" BA_DEF_REL_\n");
PutString(" BA_REL_\n");
PutString(" BA_DEF_DEF_REL_\n");
PutString(" BU_SG_REL_\n");
PutString(" BU_EV_REL_\n");
PutString(" BU_BO_REL_\n");
PutString(" SG_MUL_VAL_\n");
PutString("\n");
PutString("BS_:\n");
PutString("\nBU_:");
for (long ipN : gIpsSorted)
{
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PutString(" Client_");
switch (NodeNameStyle) // Add the IP bytes depending on the style. Don't break anywhere.
{
case WholeIp:
PutString(gIpsSorted[ipN].Ip1);
PutString("_");
case ThreeLastBytes:
PutString(gIpsSorted[ipN].Ip2);
PutString("_");
case TwoLastBytes:
PutString(gIpsSorted[ipN].Ip3);
PutString("_");
case LastByte:
PutString(gIpsSorted[ipN].Ip4);
break;
default:
writeDbg(MbError, "The NodeNameStyle %d is unknown, please use a value of the enum!", NodeNameStyle);
runError(1001, 0);
return;
}
}
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PutString("\n\n\n\n");
PutString("BA_DEF_ BU_ \"NodeLayerModules\" STRING ;\n");
PutString("BA_DEF_ \"DBName\" STRING ;\n");
PutString("BA_DEF_ \"BusType\" STRING ;\n");
PutString("BA_DEF_DEF_ \"NodeLayerModules\" \"Ethernet_IL.DLL\";\n");
PutString("BA_DEF_DEF_ \"DBName\" \"\";\n");
PutString("BA_DEF_DEF_ \"BusType\" \"Ethernet\";\n");
PutString("BA_ \"BusType\" \"Ethernet\";\n");
PutString("BA_ \"DBName\" \"Modbus\";\n");
f.Close();
}
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// The stuff below is not needed
/// <zzzModbus>
void OnModbusClientPanics(enum FatalErrors reason)
{
writeLineEx(0, 4, "<%NODE_NAME%> FATAL! %d", reason);
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/* switch(reason)
{
case ParsingBuffer:
case ModbusPackageWasSplit:
case DeviceCodeUnknown:
case VendorIdUnknown:
case ConnectionError:
break;
}
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*/
}
/// <zzzModbus>
void OnModbusWriteBitFailed(enum ModbusRequestError error, enum ModbusException ex, struct ModbusApHeader mbap){}
/// <zzzModbus>
void OnModbusWriteRegisterFailed(enum ModbusRequestError error, enum ModbusException ex, struct ModbusApHeader mbap){}
/// <zzzModbus>
void OnModbusWriteMasksFailed(enum ModbusRequestError error, enum ModbusException ex, struct ModbusApHeader mbap){}
/// <zzzModbus>
void OnModbusReadWriteRegistersFailed(enum ModbusRequestError error, enum ModbusException ex, struct ModbusApHeader mbap){}
/// <zzzModbus>
void OnModbusWriteBitsFailed(enum ModbusRequestError error, enum ModbusException ex, struct ModbusApHeader mbap){}
/// <zzzModbus>
void OnModbusWriteRegistersFailed(enum ModbusRequestError error, enum ModbusException ex, struct ModbusApHeader mbap){}
/// <zzzModbus>
void OnModbusWriteBitSuccess(struct ModbusResConfirmSingle mbc){}
/// <zzzModbus>
void OnModbusWriteRegisterSuccess(struct ModbusResConfirmSingle mbc){}
/// <zzzModbus>
void OnModbusWriteBitsSuccess(struct ModbusResConfirmMultiple mbc){}
/// <zzzModbus>
void OnModbusWriteRegistersSuccess(struct ModbusResConfirmMultiple mbc){}
/// <zzzModbus>
void OnModbusWriteMasksSuccess(struct ModbusResConfirmMasks mbc){}