C++ runtime: add eRPC server, minimal CLI and Makefile. WIP.
/*
* Generated by erpcgen 1.11.0 on Wed Mar 27 13:43:44 2024.
*
* AUTOGENERATED - DO NOT EDIT
*/
#include "erpc_PLCObject_server.hpp"
#if ERPC_ALLOCATION_POLICY == ERPC_ALLOCATION_POLICY_DYNAMIC
#include <new>
#include "erpc_port.h"
#endif
#include "erpc_manually_constructed.hpp"
#if 11100 != ERPC_VERSION_NUMBER
#error "The generated shim code version is different to the rest of eRPC code."
#endif
using namespace erpc;
using namespace std;
using namespace erpcShim;
#if ERPC_NESTED_CALLS_DETECTION
extern bool nestingDetection;
#endif
//! @brief Function to read struct binary_t
static void read_binary_t_struct(erpc::Codec * codec, binary_t * data);
//! @brief Function to read struct extra_file
static void read_extra_file_struct(erpc::Codec * codec, extra_file * data);
//! @brief Function to read struct list_extra_file_1_t
static void read_list_extra_file_1_t_struct(erpc::Codec * codec, list_extra_file_1_t * data);
//! @brief Function to read struct trace_order
static void read_trace_order_struct(erpc::Codec * codec, trace_order * data);
//! @brief Function to read struct list_trace_order_1_t
static void read_list_trace_order_1_t_struct(erpc::Codec * codec, list_trace_order_1_t * data);
// Read struct binary_t function implementation
static void read_binary_t_struct(erpc::Codec * codec, binary_t * data)
{
if(NULL == data)
{
return;
}
uint8_t * data_local;
codec->readBinary(data->dataLength, &data_local);
if (data->dataLength > 0)
{
data->data = (uint8_t *) erpc_malloc(data->dataLength * sizeof(uint8_t));
if (data->data == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
else
{
memcpy(data->data, data_local, data->dataLength);
}
}
else
{
data->data = NULL;
}
}
// Read struct extra_file function implementation
static void read_extra_file_struct(erpc::Codec * codec, extra_file * data)
{
if(NULL == data)
{
return;
}
{
uint32_t fname_len;
char * fname_local;
codec->readString(fname_len, &fname_local);
data->fname = (char*) erpc_malloc((fname_len + 1) * sizeof(char));
if ((data->fname == NULL) || (fname_local == NULL))
{
codec->updateStatus(kErpcStatus_MemoryError);
}
else
{
memcpy(data->fname, fname_local, fname_len);
(data->fname)[fname_len] = 0;
}
}
read_binary_t_struct(codec, &(data->blobID));
}
// Read struct list_extra_file_1_t function implementation
static void read_list_extra_file_1_t_struct(erpc::Codec * codec, list_extra_file_1_t * data)
{
if(NULL == data)
{
return;
}
codec->startReadList(data->elementsCount);
data->elements = (extra_file *) erpc_malloc(data->elementsCount * sizeof(extra_file));
if ((data->elements == NULL) && (data->elementsCount > 0))
{
codec->updateStatus(kErpcStatus_MemoryError);
}
for (uint32_t listCount = 0U; listCount < data->elementsCount; ++listCount)
{
read_extra_file_struct(codec, &(data->elements[listCount]));
}
}
// Read struct trace_order function implementation
static void read_trace_order_struct(erpc::Codec * codec, trace_order * data)
{
if(NULL == data)
{
return;
}
codec->read(data->idx);
read_binary_t_struct(codec, &(data->force));
}
// Read struct list_trace_order_1_t function implementation
static void read_list_trace_order_1_t_struct(erpc::Codec * codec, list_trace_order_1_t * data)
{
if(NULL == data)
{
return;
}
codec->startReadList(data->elementsCount);
data->elements = (trace_order *) erpc_malloc(data->elementsCount * sizeof(trace_order));
if ((data->elements == NULL) && (data->elementsCount > 0))
{
codec->updateStatus(kErpcStatus_MemoryError);
}
for (uint32_t listCount = 0U; listCount < data->elementsCount; ++listCount)
{
read_trace_order_struct(codec, &(data->elements[listCount]));
}
}
//! @brief Function to write struct binary_t
static void write_binary_t_struct(erpc::Codec * codec, const binary_t * data);
//! @brief Function to write struct log_message
static void write_log_message_struct(erpc::Codec * codec, const log_message * data);
//! @brief Function to write struct PSKID
static void write_PSKID_struct(erpc::Codec * codec, const PSKID * data);
//! @brief Function to write struct PLCstatus
static void write_PLCstatus_struct(erpc::Codec * codec, const PLCstatus * data);
//! @brief Function to write struct trace_sample
static void write_trace_sample_struct(erpc::Codec * codec, const trace_sample * data);
//! @brief Function to write struct TraceVariables
static void write_TraceVariables_struct(erpc::Codec * codec, const TraceVariables * data);
//! @brief Function to write struct list_trace_sample_1_t
static void write_list_trace_sample_1_t_struct(erpc::Codec * codec, const list_trace_sample_1_t * data);
// Write struct binary_t function implementation
static void write_binary_t_struct(erpc::Codec * codec, const binary_t * data)
{
if(NULL == data)
{
return;
}
codec->writeBinary(data->dataLength, data->data);
}
// Write struct log_message function implementation
static void write_log_message_struct(erpc::Codec * codec, const log_message * data)
{
if(NULL == data)
{
return;
}
{
uint32_t msg_len = strlen((const char*)data->msg);
codec->writeString(msg_len, (const char*)data->msg);
}
codec->write(data->tick);
codec->write(data->sec);
codec->write(data->nsec);
}
// Write struct PSKID function implementation
static void write_PSKID_struct(erpc::Codec * codec, const PSKID * data)
{
if(NULL == data)
{
return;
}
{
uint32_t ID_len = strlen((const char*)data->ID);
codec->writeString(ID_len, (const char*)data->ID);
}
{
uint32_t PSK_len = strlen((const char*)data->PSK);
codec->writeString(PSK_len, (const char*)data->PSK);
}
}
// Write struct PLCstatus function implementation
static void write_PLCstatus_struct(erpc::Codec * codec, const PLCstatus * data)
{
if(NULL == data)
{
return;
}
codec->write(static_cast<int32_t>(data->PLCstatus));
for (uint32_t arrayCount0 = 0U; arrayCount0 < 4U; ++arrayCount0)
{
codec->write(data->logcounts[arrayCount0]);
}
}
// Write struct trace_sample function implementation
static void write_trace_sample_struct(erpc::Codec * codec, const trace_sample * data)
{
if(NULL == data)
{
return;
}
codec->write(data->tick);
write_binary_t_struct(codec, &(data->TraceBuffer));
}
// Write struct TraceVariables function implementation
static void write_TraceVariables_struct(erpc::Codec * codec, const TraceVariables * data)
{
if(NULL == data)
{
return;
}
codec->write(static_cast<int32_t>(data->PLCstatus));
write_list_trace_sample_1_t_struct(codec, &(data->traces));
}
// Write struct list_trace_sample_1_t function implementation
static void write_list_trace_sample_1_t_struct(erpc::Codec * codec, const list_trace_sample_1_t * data)
{
if(NULL == data)
{
return;
}
codec->startWriteList(data->elementsCount);
for (uint32_t listCount = 0U; listCount < data->elementsCount; ++listCount)
{
write_trace_sample_struct(codec, &(data->elements[listCount]));
}
}
//! @brief Function to free space allocated inside struct binary_t
static void free_binary_t_struct(binary_t * data);
//! @brief Function to free space allocated inside struct log_message
static void free_log_message_struct(log_message * data);
//! @brief Function to free space allocated inside struct PSKID
static void free_PSKID_struct(PSKID * data);
//! @brief Function to free space allocated inside struct trace_sample
static void free_trace_sample_struct(trace_sample * data);
//! @brief Function to free space allocated inside struct TraceVariables
static void free_TraceVariables_struct(TraceVariables * data);
//! @brief Function to free space allocated inside struct list_trace_sample_1_t
static void free_list_trace_sample_1_t_struct(list_trace_sample_1_t * data);
//! @brief Function to free space allocated inside struct extra_file
static void free_extra_file_struct(extra_file * data);
//! @brief Function to free space allocated inside struct list_extra_file_1_t
static void free_list_extra_file_1_t_struct(list_extra_file_1_t * data);
//! @brief Function to free space allocated inside struct trace_order
static void free_trace_order_struct(trace_order * data);
//! @brief Function to free space allocated inside struct list_trace_order_1_t
static void free_list_trace_order_1_t_struct(list_trace_order_1_t * data);
// Free space allocated inside struct binary_t function implementation
static void free_binary_t_struct(binary_t * data)
{
erpc_free(data->data);
}
// Free space allocated inside struct log_message function implementation
static void free_log_message_struct(log_message * data)
{
erpc_free(data->msg);
}
// Free space allocated inside struct PSKID function implementation
static void free_PSKID_struct(PSKID * data)
{
erpc_free(data->ID);
erpc_free(data->PSK);
}
// Free space allocated inside struct trace_sample function implementation
static void free_trace_sample_struct(trace_sample * data)
{
free_binary_t_struct(&data->TraceBuffer);
}
// Free space allocated inside struct TraceVariables function implementation
static void free_TraceVariables_struct(TraceVariables * data)
{
free_list_trace_sample_1_t_struct(&data->traces);
}
// Free space allocated inside struct list_trace_sample_1_t function implementation
static void free_list_trace_sample_1_t_struct(list_trace_sample_1_t * data)
{
for (uint32_t listCount = 0; listCount < data->elementsCount; ++listCount)
{
free_trace_sample_struct(&data->elements[listCount]);
}
erpc_free(data->elements);
}
// Free space allocated inside struct extra_file function implementation
static void free_extra_file_struct(extra_file * data)
{
erpc_free(data->fname);
free_binary_t_struct(&data->blobID);
}
// Free space allocated inside struct list_extra_file_1_t function implementation
static void free_list_extra_file_1_t_struct(list_extra_file_1_t * data)
{
for (uint32_t listCount = 0; listCount < data->elementsCount; ++listCount)
{
free_extra_file_struct(&data->elements[listCount]);
}
erpc_free(data->elements);
}
// Free space allocated inside struct trace_order function implementation
static void free_trace_order_struct(trace_order * data)
{
free_binary_t_struct(&data->force);
}
// Free space allocated inside struct list_trace_order_1_t function implementation
static void free_list_trace_order_1_t_struct(list_trace_order_1_t * data)
{
for (uint32_t listCount = 0; listCount < data->elementsCount; ++listCount)
{
free_trace_order_struct(&data->elements[listCount]);
}
erpc_free(data->elements);
}
BeremizPLCObjectService_service::BeremizPLCObjectService_service(BeremizPLCObjectService_interface *_BeremizPLCObjectService_interface)
: erpc::Service(BeremizPLCObjectService_interface::m_serviceId)
, m_handler(_BeremizPLCObjectService_interface)
{
}
BeremizPLCObjectService_service::~BeremizPLCObjectService_service()
{
}
// return service interface handler.
BeremizPLCObjectService_interface* BeremizPLCObjectService_service::getHandler(void)
{
return m_handler;
}
// Call the correct server shim based on method unique ID.
erpc_status_t BeremizPLCObjectService_service::handleInvocation(uint32_t methodId, uint32_t sequence, Codec * codec, MessageBufferFactory *messageFactory, Transport * transport)
{
erpc_status_t erpcStatus;
switch (methodId)
{
case BeremizPLCObjectService_interface::m_AppendChunkToBlobId:
{
erpcStatus = AppendChunkToBlob_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_GetLogMessageId:
{
erpcStatus = GetLogMessage_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_GetPLCIDId:
{
erpcStatus = GetPLCID_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_GetPLCstatusId:
{
erpcStatus = GetPLCstatus_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_GetTraceVariablesId:
{
erpcStatus = GetTraceVariables_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_MatchMD5Id:
{
erpcStatus = MatchMD5_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_NewPLCId:
{
erpcStatus = NewPLC_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_PurgeBlobsId:
{
erpcStatus = PurgeBlobs_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_RepairPLCId:
{
erpcStatus = RepairPLC_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_ResetLogCountId:
{
erpcStatus = ResetLogCount_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_SeedBlobId:
{
erpcStatus = SeedBlob_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_SetTraceVariablesListId:
{
erpcStatus = SetTraceVariablesList_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_StartPLCId:
{
erpcStatus = StartPLC_shim(codec, messageFactory, transport, sequence);
break;
}
case BeremizPLCObjectService_interface::m_StopPLCId:
{
erpcStatus = StopPLC_shim(codec, messageFactory, transport, sequence);
break;
}
default:
{
erpcStatus = kErpcStatus_InvalidArgument;
break;
}
}
return erpcStatus;
}
// Server shim for AppendChunkToBlob of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::AppendChunkToBlob_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
binary_t *data = NULL;
data = (binary_t *) erpc_malloc(sizeof(binary_t));
if (data == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
binary_t *blobID = NULL;
blobID = (binary_t *) erpc_malloc(sizeof(binary_t));
if (blobID == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
binary_t *newBlobID = NULL;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
read_binary_t_struct(codec, data);
read_binary_t_struct(codec, blobID);
newBlobID = (binary_t *) erpc_malloc(sizeof(binary_t));
if (newBlobID == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->AppendChunkToBlob(data, blobID, newBlobID);
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_AppendChunkToBlobId, sequence);
write_binary_t_struct(codec, newBlobID);
codec->write(result);
err = codec->getStatus();
}
if (data)
{
free_binary_t_struct(data);
}
erpc_free(data);
if (blobID)
{
free_binary_t_struct(blobID);
}
erpc_free(blobID);
if (newBlobID)
{
free_binary_t_struct(newBlobID);
}
erpc_free(newBlobID);
return err;
}
// Server shim for GetLogMessage of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::GetLogMessage_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
uint8_t level;
uint32_t msgID;
log_message *message = NULL;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
codec->read(level);
codec->read(msgID);
message = (log_message *) erpc_malloc(sizeof(log_message));
if (message == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->GetLogMessage(level, msgID, message);
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_GetLogMessageId, sequence);
write_log_message_struct(codec, message);
codec->write(result);
err = codec->getStatus();
}
if (message)
{
free_log_message_struct(message);
}
erpc_free(message);
return err;
}
// Server shim for GetPLCID of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::GetPLCID_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
PSKID *plcID = NULL;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
plcID = (PSKID *) erpc_malloc(sizeof(PSKID));
if (plcID == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->GetPLCID(plcID);
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_GetPLCIDId, sequence);
write_PSKID_struct(codec, plcID);
codec->write(result);
err = codec->getStatus();
}
if (plcID)
{
free_PSKID_struct(plcID);
}
erpc_free(plcID);
return err;
}
// Server shim for GetPLCstatus of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::GetPLCstatus_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
PLCstatus *status = NULL;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
status = (PLCstatus *) erpc_malloc(sizeof(PLCstatus));
if (status == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->GetPLCstatus(status);
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_GetPLCstatusId, sequence);
write_PLCstatus_struct(codec, status);
codec->write(result);
err = codec->getStatus();
}
erpc_free(status);
return err;
}
// Server shim for GetTraceVariables of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::GetTraceVariables_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
uint32_t debugToken;
TraceVariables *traces = NULL;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
codec->read(debugToken);
traces = (TraceVariables *) erpc_malloc(sizeof(TraceVariables));
if (traces == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->GetTraceVariables(debugToken, traces);
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_GetTraceVariablesId, sequence);
write_TraceVariables_struct(codec, traces);
codec->write(result);
err = codec->getStatus();
}
if (traces)
{
free_TraceVariables_struct(traces);
}
erpc_free(traces);
return err;
}
// Server shim for MatchMD5 of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::MatchMD5_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
char * MD5 = NULL;
bool match;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
{
uint32_t MD5_len;
char * MD5_local;
codec->readString(MD5_len, &MD5_local);
MD5 = (char*) erpc_malloc((MD5_len + 1) * sizeof(char));
if ((MD5 == NULL) || (MD5_local == NULL))
{
codec->updateStatus(kErpcStatus_MemoryError);
}
else
{
memcpy(MD5, MD5_local, MD5_len);
(MD5)[MD5_len] = 0;
}
}
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->MatchMD5(MD5, &match);
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_MatchMD5Id, sequence);
codec->write(match);
codec->write(result);
err = codec->getStatus();
}
erpc_free(MD5);
return err;
}
// Server shim for NewPLC of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::NewPLC_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
char * md5sum = NULL;
binary_t *plcObjectBlobID = NULL;
plcObjectBlobID = (binary_t *) erpc_malloc(sizeof(binary_t));
if (plcObjectBlobID == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
list_extra_file_1_t *extrafiles = NULL;
extrafiles = (list_extra_file_1_t *) erpc_malloc(sizeof(list_extra_file_1_t));
if (extrafiles == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
bool success;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
{
uint32_t md5sum_len;
char * md5sum_local;
codec->readString(md5sum_len, &md5sum_local);
md5sum = (char*) erpc_malloc((md5sum_len + 1) * sizeof(char));
if ((md5sum == NULL) || (md5sum_local == NULL))
{
codec->updateStatus(kErpcStatus_MemoryError);
}
else
{
memcpy(md5sum, md5sum_local, md5sum_len);
(md5sum)[md5sum_len] = 0;
}
}
read_binary_t_struct(codec, plcObjectBlobID);
read_list_extra_file_1_t_struct(codec, extrafiles);
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->NewPLC(md5sum, plcObjectBlobID, extrafiles, &success);
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_NewPLCId, sequence);
codec->write(success);
codec->write(result);
err = codec->getStatus();
}
erpc_free(md5sum);
if (plcObjectBlobID)
{
free_binary_t_struct(plcObjectBlobID);
}
erpc_free(plcObjectBlobID);
if (extrafiles)
{
free_list_extra_file_1_t_struct(extrafiles);
}
erpc_free(extrafiles);
return err;
}
// Server shim for PurgeBlobs of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::PurgeBlobs_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->PurgeBlobs();
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_PurgeBlobsId, sequence);
codec->write(result);
err = codec->getStatus();
}
return err;
}
// Server shim for RepairPLC of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::RepairPLC_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->RepairPLC();
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_RepairPLCId, sequence);
codec->write(result);
err = codec->getStatus();
}
return err;
}
// Server shim for ResetLogCount of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::ResetLogCount_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->ResetLogCount();
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_ResetLogCountId, sequence);
codec->write(result);
err = codec->getStatus();
}
return err;
}
// Server shim for SeedBlob of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::SeedBlob_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
binary_t *seed = NULL;
seed = (binary_t *) erpc_malloc(sizeof(binary_t));
if (seed == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
binary_t *blobID = NULL;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
read_binary_t_struct(codec, seed);
blobID = (binary_t *) erpc_malloc(sizeof(binary_t));
if (blobID == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->SeedBlob(seed, blobID);
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_SeedBlobId, sequence);
write_binary_t_struct(codec, blobID);
codec->write(result);
err = codec->getStatus();
}
if (seed)
{
free_binary_t_struct(seed);
}
erpc_free(seed);
if (blobID)
{
free_binary_t_struct(blobID);
}
erpc_free(blobID);
return err;
}
// Server shim for SetTraceVariablesList of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::SetTraceVariablesList_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
list_trace_order_1_t *orders = NULL;
orders = (list_trace_order_1_t *) erpc_malloc(sizeof(list_trace_order_1_t));
if (orders == NULL)
{
codec->updateStatus(kErpcStatus_MemoryError);
}
uint32_t debugtoken;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
read_list_trace_order_1_t_struct(codec, orders);
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->SetTraceVariablesList(orders, &debugtoken);
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_SetTraceVariablesListId, sequence);
codec->write(debugtoken);
codec->write(result);
err = codec->getStatus();
}
if (orders)
{
free_list_trace_order_1_t_struct(orders);
}
erpc_free(orders);
return err;
}
// Server shim for StartPLC of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::StartPLC_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->StartPLC();
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_StartPLCId, sequence);
codec->write(result);
err = codec->getStatus();
}
return err;
}
// Server shim for StopPLC of BeremizPLCObjectService interface.
erpc_status_t BeremizPLCObjectService_service::StopPLC_shim(Codec * codec, MessageBufferFactory *messageFactory, Transport * transport, uint32_t sequence)
{
erpc_status_t err = kErpcStatus_Success;
bool success;
uint32_t result;
// startReadMessage() was already called before this shim was invoked.
err = codec->getStatus();
if (err == kErpcStatus_Success)
{
// Invoke the actual served function.
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = true;
#endif
result = m_handler->StopPLC(&success);
#if ERPC_NESTED_CALLS_DETECTION
nestingDetection = false;
#endif
// preparing MessageBuffer for serializing data
err = messageFactory->prepareServerBufferForSend(codec->getBufferRef(), transport->reserveHeaderSize());
}
if (err == kErpcStatus_Success)
{
// preparing codec for serializing data
codec->reset(transport->reserveHeaderSize());
// Build response message.
codec->startWriteMessage(message_type_t::kReplyMessage, BeremizPLCObjectService_interface::m_serviceId, BeremizPLCObjectService_interface::m_StopPLCId, sequence);
codec->write(success);
codec->write(result);
err = codec->getStatus();
}
return err;
}