void removeNode(const char* safName)
{
ClRcT rc;
ClAmsEntityConfigT entity;
if (ccbHandle==CL_HANDLE_INVALID_VALUE) initHandles();
initEntity(&entity,safName,CL_AMS_ENTITY_TYPE_NODE);
entityStop(entity);
ClCpmSlotInfoT slotInfo;
saNameSet(&slotInfo.nodeName,safName);
if ((rc = clCpmSlotGet(CL_CPM_NODENAME, &slotInfo)) != CL_OK) checkError("Get node address",rc);
if ((rc = clCpmNodeShutDown(slotInfo.nodeIocAddress)) != CL_OK) checkError("shutdown ASP on node",rc);
ClAmsNodeStatusT* ns;
bool done = false;
do
{
ns = clAmsMgmtNodeGetStatus( mgmtHandle ,safName);
sleep(1);
if (!ns) done = true;
else
{
if (ns->isClusterMember == CL_AMS_NODE_IS_NOT_CLUSTER_MEMBER) done=true;
clHeapFree(ns);
}
} while (!done);
if ((rc = clAmsMgmtCCBEntityDelete(ccbHandle,&entity)) != CL_OK) checkError("Delete node",rc);
if ((rc = clAmsMgmtCCBCommit(ccbHandle) ) != CL_OK) checkError("Committing deletion of node", rc);
}
// Stop this app container from running on these nodes (1+N redundancy)
void acRetract(const char* appCnt, const char* nodeNames[], int numNodes,const char* nameModifier)
{
ClRcT rc;
ClAmsEntityConfigT su;
ClAmsEntityConfigT comp;
char eName[SA_MAX_NAME_LENGTH];
if (ccbHandle==CL_HANDLE_INVALID_VALUE) initHandles();
strncpy(eName,appCnt,SA_MAX_NAME_LENGTH-1);
eName[SA_MAX_NAME_LENGTH-1] = 0;
if (nameModifier != NULL)
{
strncat(eName,nameModifier,SA_MAX_NAME_LENGTH-1);
eName[SA_MAX_NAME_LENGTH-1] = 0;
}
for (int i=0;i<numNodes;i++)
{
initEntity(&su,eName,CL_AMS_ENTITY_TYPE_SU,nodeNames[i]);
entityStop(su);
initEntity(&comp,eName,CL_AMS_ENTITY_TYPE_COMP,nodeNames[i]);
// comps are implicitly started/stopped when SU is
//entityStop(comp);
if ((rc = clAmsMgmtCCBEntityDelete(ccbHandle,&comp)) != CL_OK) checkError("Delete COMP",rc);
if ((rc = clAmsMgmtCCBEntityDelete(ccbHandle,&su)) != CL_OK) checkError("Delete SU",rc);
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle) ) != CL_OK) checkError("Committing deletion of COMP/SU", rc);
}
void removeAppCnt(const char* name)
{
ClRcT rc;
ClAmsEntityConfigT sg;
// Create the SG object
if (ccbHandle==CL_HANDLE_INVALID_VALUE) initHandles();
initEntity(&sg,name,CL_AMS_ENTITY_TYPE_SG);
entityStop(sg);
if ((rc = clAmsMgmtCCBEntityDelete(ccbHandle,&sg)) != CL_OK) checkError("Delete SG",rc);
if ((rc = clAmsMgmtCCBCommit(ccbHandle) ) != CL_OK) checkError("Committing deletion of SG", rc);
}
// Remove an application from this container.
// The effect of this is to delete the SAF Service Instance that represents this
// application
void acRemoveApp(const char* appCnt, const char* appName)
{
ClRcT rc;
//ClAmsEntityConfigT sg;
ClAmsEntityConfigT si;
ClAmsEntityConfigT csi;
if (ccbHandle==CL_HANDLE_INVALID_VALUE) initHandles();
//initEntity(&sg,appCnt,CL_AMS_ENTITY_TYPE_SG);
initEntity(&si,appName,CL_AMS_ENTITY_TYPE_SI);
initEntity(&csi,appName,CL_AMS_ENTITY_TYPE_CSI);
entityStop(si);
entityStop(csi);
if ((rc = clAmsMgmtCCBEntityDelete(ccbHandle,&csi)) != CL_OK) checkError("Delete CSI",rc);
if ((rc = clAmsMgmtCCBEntityDelete(ccbHandle,&si)) != CL_OK) checkError("Delete SI",rc);
if ((rc = clAmsMgmtCCBCommit(ccbHandle) ) != CL_OK) checkError("Committing deletion of SI/CSI", rc);
}
eventNotify_t::eventNotify_t(QObject* p) : QObject(p), m_handle(nullptr), m_notify(nullptr), m_dll(nullptr), m_stop(false)
{
DWORD status = ERROR_SUCCESS;
qRegisterMetaType< eventLogEntry_t::log_ptr_t >();
if (false == initHandles()) {
emit errorMessage("Error in eventNotify_t::eventNotify_t()", "Error while initializing event log handles", true);
throw std::runtime_error("eventNotify_t::eventNotify_t(): Error while initializing event log handles");
}
status = seekToLastRecord();
if (ERROR_SUCCESS != status) {
emit errorMessage("Error in eventNotify_t::eventNotify_t()", "Error while seeking to the end of the event log stream", true);
throw std::runtime_error("eventNotify_t::eventNotify_t(): Error while seeking to the end of the event log stream");
}
return;
}
// Stop this app container from running on these nodes (1+N redundancy)
void acRetract(const char* appCnt, const char* nodeName,const char* compName)
{
ClRcT rc;
ClAmsEntityConfigT su;
ClAmsEntityConfigT comp;
if (ccbHandle==CL_HANDLE_INVALID_VALUE) initHandles();
if (1)
{
initEntity(&su,compName,CL_AMS_ENTITY_TYPE_SU);
entityStop(su);
initEntity(&comp,compName,CL_AMS_ENTITY_TYPE_COMP);
// Comps are implicitly stopped when SU is stopped
//entityStop(comp);
if ((rc = clAmsMgmtCCBEntityDelete(ccbHandle,&comp)) != CL_OK) checkError("Delete COMP",rc);
if ((rc = clAmsMgmtCCBEntityDelete(ccbHandle,&su)) != CL_OK) checkError("Delete SU",rc);
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle) ) != CL_OK) checkError("Committing deletion of COMP/SU", rc);
}
// Create a new Node in the AMF
void addNode(const char* safName)
{
ClRcT rc;
ClAmsEntityConfigT entity;
if (ccbHandle==CL_HANDLE_INVALID_VALUE) initHandles();
initEntity(&entity,safName,CL_AMS_ENTITY_TYPE_NODE);
if ((rc = clAmsMgmtCCBEntityCreate(ccbHandle,&entity)) != CL_OK)
{
checkError("Create node",rc);
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle)) != CL_OK)
{
checkError("Commit create node",rc);
}
entityStart(entity);
}
bool GFXGLShader::_init()
{
// Don't initialize empty shaders.
if ( mVertexFile.isEmpty() && mPixelFile.isEmpty() )
return false;
clearShaders();
mProgram = glCreateProgram();
// Set the macros and add the global ones.
Vector<GFXShaderMacro> macros;
macros.merge( mMacros );
macros.merge( smGlobalMacros );
// Add the shader version to the macros.
const U32 mjVer = (U32)mFloor( mPixVersion );
const U32 mnVer = (U32)( ( mPixVersion - F32( mjVer ) ) * 10.01f );
macros.increment();
macros.last().name = "TORQUE_SM";
macros.last().value = String::ToString( mjVer * 10 + mnVer );
// Default to true so we're "successful" if a vertex/pixel shader wasn't specified.
bool compiledVertexShader = true;
bool compiledPixelShader = true;
// Compile the vertex and pixel shaders if specified.
if(!mVertexFile.isEmpty())
compiledVertexShader = initShader(mVertexFile, true, macros);
if(!mPixelFile.isEmpty())
compiledPixelShader = initShader(mPixelFile, false, macros);
// If either shader was present and failed to compile, bail.
if(!compiledVertexShader || !compiledPixelShader)
return false;
// Link it!
glLinkProgram( mProgram );
GLint linkStatus;
glGetProgramiv( mProgram, GL_LINK_STATUS, &linkStatus );
// Dump the info log to the console
U32 logLength = 0;
glGetProgramiv(mProgram, GL_INFO_LOG_LENGTH, (GLint*)&logLength);
if ( logLength )
{
FrameAllocatorMarker fam;
char* log = (char*)fam.alloc( logLength );
glGetProgramInfoLog( mProgram, logLength, NULL, log );
if ( linkStatus == GL_FALSE )
{
if ( smLogErrors )
{
Con::errorf( "GFXGLShader::init - Error linking shader!" );
Con::errorf( "Program %s / %s: %s",
mVertexFile.getFullPath().c_str(), mPixelFile.getFullPath().c_str(), log);
}
}
else if ( smLogWarnings )
{
Con::warnf( "Program %s / %s: %s",
mVertexFile.getFullPath().c_str(), mPixelFile.getFullPath().c_str(), log);
}
}
// If we failed to link, bail.
if ( linkStatus == GL_FALSE )
return false;
initConstantDescs();
initHandles();
// Notify Buffers we might have changed in size.
// If this was our first init then we won't have any activeBuffers
// to worry about unnecessarily calling.
Vector<GFXShaderConstBuffer*>::iterator biter = mActiveBuffers.begin();
for ( ; biter != mActiveBuffers.end(); biter++ )
((GFXGLShaderConstBuffer*)(*biter))->onShaderReload( this );
return true;
}
bool GFXGLShader::_init()
{
PROFILE_SCOPE(GFXGLShader_Init);
// Don't initialize empty shaders.
if ( mVertexFile.isEmpty() && mPixelFile.isEmpty() )
return false;
clearShaders();
mProgram = glCreateProgram();
// Set the macros and add the global ones.
Vector<GFXShaderMacro> macros;
macros.merge( mMacros );
macros.merge( smGlobalMacros );
// Add the shader version to the macros.
const U32 mjVer = (U32)mFloor( mPixVersion );
const U32 mnVer = (U32)( ( mPixVersion - F32( mjVer ) ) * 10.01f );
macros.increment();
macros.last().name = "TORQUE_SM";
macros.last().value = String::ToString( mjVer * 10 + mnVer );
macros.increment();
macros.last().name = "TORQUE_VERTEX_SHADER";
macros.last().value = "";
// Default to true so we're "successful" if a vertex/pixel shader wasn't specified.
bool compiledVertexShader = true;
bool compiledPixelShader = true;
// Compile the vertex and pixel shaders if specified.
if(!mVertexFile.isEmpty())
compiledVertexShader = initShader(mVertexFile, true, macros);
macros.last().name = "TORQUE_PIXEL_SHADER";
if(!mPixelFile.isEmpty())
compiledPixelShader = initShader(mPixelFile, false, macros);
// If either shader was present and failed to compile, bail.
if(!compiledVertexShader || !compiledPixelShader)
return false;
//bind vertex attributes
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_Position, "vPosition");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_Normal, "vNormal");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_Color, "vColor");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_Tangent, "vTangent");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TangentW, "vTangentW");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_Binormal, "vBinormal");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TexCoord0, "vTexCoord0");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TexCoord1, "vTexCoord1");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TexCoord2, "vTexCoord2");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TexCoord3, "vTexCoord3");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TexCoord4, "vTexCoord4");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TexCoord5, "vTexCoord5");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TexCoord6, "vTexCoord6");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TexCoord7, "vTexCoord7");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TexCoord8, "vTexCoord8");
glBindAttribLocation(mProgram, Torque::GL_VertexAttrib_TexCoord9, "vTexCoord9");
//bind fragment out color
glBindFragDataLocation(mProgram, 0, "OUT_col");
glBindFragDataLocation(mProgram, 1, "OUT_col1");
glBindFragDataLocation(mProgram, 2, "OUT_col2");
glBindFragDataLocation(mProgram, 3, "OUT_col3");
// Link it!
glLinkProgram( mProgram );
GLint linkStatus;
glGetProgramiv( mProgram, GL_LINK_STATUS, &linkStatus );
// Dump the info log to the console
U32 logLength = 0;
glGetProgramiv(mProgram, GL_INFO_LOG_LENGTH, (GLint*)&logLength);
if ( logLength )
{
FrameAllocatorMarker fam;
char* log = (char*)fam.alloc( logLength );
glGetProgramInfoLog( mProgram, logLength, NULL, log );
if ( linkStatus == GL_FALSE )
{
if ( smLogErrors )
{
Con::errorf( "GFXGLShader::init - Error linking shader!" );
Con::errorf( "Program %s / %s: %s",
mVertexFile.getFullPath().c_str(), mPixelFile.getFullPath().c_str(), log);
}
}
else if ( smLogWarnings )
{
Con::warnf( "Program %s / %s: %s",
mVertexFile.getFullPath().c_str(), mPixelFile.getFullPath().c_str(), log);
}
}
// If we failed to link, bail.
if ( linkStatus == GL_FALSE )
return false;
initConstantDescs();
initHandles();
// Notify Buffers we might have changed in size.
// If this was our first init then we won't have any activeBuffers
// to worry about unnecessarily calling.
Vector<GFXShaderConstBuffer*>::iterator biter = mActiveBuffers.begin();
for ( ; biter != mActiveBuffers.end(); biter++ )
((GFXGLShaderConstBuffer*)(*biter))->onShaderReload( this );
return true;
}
// Start this app container running on these nodes (1+N redundancy). This will
// start a SAF-aware process on each node specified.
// Create SU and Comp
void acExtend(const char* appCnt, const char* nodeName, const char* compName,SafConfig* cfg)
{
ClRcT rc;
ClAmsEntityConfigT sg;
ClAmsEntityConfigT comp;
ClAmsEntityConfigT su;
ClUint64T changeMask = 0;
ClAmsSGConfigT sgConfig;
ClAmsEntityConfigT* pEntityConfig = NULL;
if (ccbHandle==CL_HANDLE_INVALID_VALUE) initHandles();
initEntity(&sg,appCnt,CL_AMS_ENTITY_TYPE_SG);
if ((rc = clAmsMgmtEntityGetConfig(mgmtHandle,&sg,&pEntityConfig)) != CL_OK)
{
checkError("Get SG configuration", rc);
}
memcpy(&sgConfig, pEntityConfig, sizeof(sgConfig));
clHeapFree(pEntityConfig);
//Fix bug: recovery policy
if (cfg && cfg->compRestartCountMax > 0 && cfg->compRestartDuration > 0)
{
sgConfig.compRestartCountMax = cfg->compRestartCountMax;
sgConfig.compRestartDuration = cfg->compRestartDuration;
changeMask |= SG_CONFIG_COMP_RESTART_DURATION | SG_CONFIG_COMP_RESTART_COUNT_MAX;
if ((rc = clAmsMgmtCCBEntitySetConfig(ccbHandle,&sgConfig.entity,changeMask) ) != CL_OK)
{
checkError("Set SG config", rc);
}
}
// Create SU and component per node
if (1)
{
initEntity(&su,compName,CL_AMS_ENTITY_TYPE_SU);
if ((rc = clAmsMgmtCCBEntityCreate(ccbHandle,&su)) != CL_OK)
{
checkError("Create SU", rc);
}
initEntity(&comp,compName,CL_AMS_ENTITY_TYPE_COMP);
if ((rc = clAmsMgmtCCBEntityCreate(ccbHandle,&comp)) != CL_OK)
{
checkError("Create Comp", rc);
}
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle)) != CL_OK)
{
checkError("Commit creation of SU and Component", rc);
}
SaNameT supportedCSIType;
saNameSet(&supportedCSIType, CSI_TYPE_APP);
supportedCSIType.length += 1;
// Configure components
if (1)
{
ClAmsCompConfigT compConfig;
ClUint64T bitMask = 0;
if ((rc = clAmsMgmtEntityGetConfig(mgmtHandle,&comp,&pEntityConfig)) != CL_OK)
{
checkError("Retrieve component config", rc);
}
memcpy(&compConfig, pEntityConfig, sizeof(compConfig));
clHeapFree(pEntityConfig);
bitMask |= COMP_CONFIG_CAPABILITY_MODEL | COMP_CONFIG_TIMEOUTS;
compConfig.capabilityModel = CL_AMS_COMP_CAP_X_ACTIVE_OR_Y_STANDBY;
compConfig.timeouts.instantiate = 30000;
compConfig.timeouts.terminate = 30000;
compConfig.timeouts.cleanup = 30000;
compConfig.timeouts.quiescingComplete = 30000;
compConfig.timeouts.csiSet = 30000;
compConfig.timeouts.csiRemove = 30000;
compConfig.timeouts.instantiateDelay = 1000;
if (!strncmp(nodeName, "sc", 2))
{
if (cfg && cfg->compRestartCountMax == 0)
{
bitMask |= COMP_CONFIG_IS_RESTARTABLE | COMP_CONFIG_RECOVERY_ON_TIMEOUT;
compConfig.isRestartable = false;
compConfig.recoveryOnTimeout = CL_AMS_RECOVERY_NODE_FAILOVER;
}
else
{
bitMask |= COMP_CONFIG_RECOVERY_ON_TIMEOUT;
compConfig.recoveryOnTimeout = CL_AMS_RECOVERY_NO_RECOMMENDATION;
}
}
else
{
if (cfg && cfg->compRestartCountMax == 0)
{
bitMask |= COMP_CONFIG_IS_RESTARTABLE | COMP_CONFIG_RECOVERY_ON_TIMEOUT;
compConfig.isRestartable = false;
compConfig.recoveryOnTimeout = CL_AMS_RECOVERY_COMP_FAILOVER;
}
else
{
bitMask |= COMP_CONFIG_RECOVERY_ON_TIMEOUT;
compConfig.recoveryOnTimeout = CL_AMS_RECOVERY_NO_RECOMMENDATION;
}
}
if ((rc = clAmsMgmtCCBEntitySetConfig(ccbHandle,&compConfig.entity,bitMask) ) != CL_OK)
{
checkError("Set component config", rc);
}
bitMask = COMP_CONFIG_INSTANTIATE_COMMAND;
if (cfg&&cfg->binName)
{
snprintf(compConfig.instantiateCommand, sizeof(compConfig.instantiateCommand), cfg->binName);
}
else
{
snprintf(compConfig.instantiateCommand, sizeof(compConfig.instantiateCommand), APP_CNT_CMD);
}
if ((rc = clAmsMgmtCCBEntitySetConfig(ccbHandle,&compConfig.entity,bitMask) ) != CL_OK)
{
checkError("Set component instantiate command", rc);
}
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle)) != CL_OK)
{
checkError("Commit configure of components", rc);
}
// Configure components
if (1)
{
ClAmsCompConfigT compConfig;
ClUint64T bitMask = 0;
if ((rc = clAmsMgmtEntityGetConfig(mgmtHandle,&comp,&pEntityConfig)) != CL_OK)
{
checkError("Retrieve component config", rc);
}
memcpy(&compConfig, pEntityConfig, sizeof(compConfig));
clHeapFree(pEntityConfig);
bitMask |= COMP_CONFIG_SUPPORTED_CSI_TYPE | COMP_CONFIG_NUM_MAX_ACTIVE_CSIS | COMP_CONFIG_NUM_MAX_STANDBY_CSIS;
if(compConfig.pSupportedCSITypes)
clHeapFree(compConfig.pSupportedCSITypes);
compConfig.numSupportedCSITypes = 1;
compConfig.pSupportedCSITypes = &supportedCSIType;
compConfig.numMaxActiveCSIs = 10000;
compConfig.numMaxStandbyCSIs = 10000;
if ((rc = clAmsMgmtCCBEntitySetConfig(ccbHandle,&compConfig.entity,bitMask) ) != CL_OK)
{
checkError("Setting supported CSI types", rc);
}
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle)) != CL_OK)
{
checkError("Configuring components supported CSI type", rc);
}
// Configure SUs
if (1)
{
ClUint64T bitMask = 0;
ClAmsSUConfigT suConfig;
if ((rc = clAmsMgmtEntityGetConfig(mgmtHandle,&su,&pEntityConfig)) != CL_OK)
{
checkError("Get SU", rc);
}
memcpy(&suConfig, pEntityConfig, sizeof(suConfig));
clHeapFree(pEntityConfig);
bitMask |= SU_CONFIG_NUM_COMPONENTS | SU_CONFIG_ADMIN_STATE;
// set number of components (processes) per SU to 1
suConfig.numComponents = 1;
//suConfig.adminState = CL_AMS_ADMIN_STATE_UNLOCKED;
suConfig.adminState = CL_AMS_ADMIN_STATE_LOCKED_I;
if ((rc = clAmsMgmtCCBEntitySetConfig(ccbHandle,&suConfig.entity,bitMask)) != CL_OK)
{
checkError("Configure SU", rc);
}
// attach the comp to the su
if ((rc = clAmsMgmtCCBSetSUCompList(ccbHandle,&su,&comp)) != CL_OK)
{
checkError("Link COMP to SU", rc);
}
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle)) != CL_OK)
{
checkError("Commit SU configuration", rc);
}
// Add the SU to SG's and Node's list
if (1)
{
ClAmsEntityConfigT node;
initEntity(&node,nodeName,CL_AMS_ENTITY_TYPE_NODE);
if ((rc = clAmsMgmtCCBSetSGSUList(ccbHandle,&sg,&su)) != CL_OK)
{
checkError("Add SU to SG", rc);
}
if ((rc = clAmsMgmtCCBSetNodeSUList(ccbHandle,&node,&su)) != CL_OK)
{
checkError("Add SU to Node", rc);
}
/*
if ((rc = clAmsMgmtCCBCommit(ccbHandle) ) != CL_OK)
{
checkError("Committing addition of SU to node and SG", rc);
}
*/
if ((rc = clAmsMgmtCCBCommit(ccbHandle) ) != CL_OK)
{
checkError("Committing addition of SU to node and SG", rc);
}
}
// Now that all is configured, start them up
entityStart(su);
}
// Create a new application container in the AMF
void addAppCnt(const char* safName,SafConfig* cfg)
{
ClRcT rc;
ClAmsEntityConfigT sg;
// Create the SG object
if (ccbHandle==CL_HANDLE_INVALID_VALUE) initHandles();
initEntity(&sg,safName,CL_AMS_ENTITY_TYPE_SG);
if ((rc = clAmsMgmtCCBEntityCreate(ccbHandle,&sg)) != CL_OK)
{
checkError("Create SG",rc);
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle)) != CL_OK)
{
checkError("Commit create SG",rc);
}
// Now configure it -- for now just use the defaults
if (1)
{
ClAmsSGConfigT sgConfig;
ClAmsEntityConfigT* pEntityConfig = NULL;
ClUint64T changeMask = 0;
if ((rc = clAmsMgmtEntityGetConfig(mgmtHandle,&sg,&pEntityConfig)) != CL_OK)
{
checkError("Get SG config",rc);
}
memcpy(&sgConfig, pEntityConfig, sizeof(sgConfig));
clHeapFree(pEntityConfig);
changeMask |= SG_CONFIG_REDUNDANCY_MODEL | SG_CONFIG_NUM_PREF_ACTIVE_SUS
| SG_CONFIG_NUM_PREF_STANDBY_SUS | SG_CONFIG_NUM_PREF_INSERVICE_SUS
| SG_CONFIG_MAX_ACTIVE_SIS_PER_SU | SG_CONFIG_MAX_STANDBY_SIS_PER_SU
| SG_CONFIG_INSTANTIATE_DURATION;
sgConfig.redundancyModel = CL_AMS_SG_REDUNDANCY_MODEL_TWO_N;
sgConfig.numPrefActiveSUs = 1; // Just a very large number, so the check does not occur in the custom model
sgConfig.numPrefStandbySUs = 1;
sgConfig.numPrefInserviceSUs = 2;
sgConfig.maxActiveSIsPerSU = 1;
sgConfig.maxStandbySIsPerSU = 1;
sgConfig.instantiateDuration = 1000;
//Recovery policy
if (cfg && cfg->compRestartCountMax > 0 && cfg->compRestartDuration > 0)
{
sgConfig.compRestartCountMax = cfg->compRestartCountMax;
sgConfig.compRestartDuration = cfg->compRestartDuration;
changeMask |= SG_CONFIG_COMP_RESTART_DURATION | SG_CONFIG_COMP_RESTART_COUNT_MAX;
}
if ((rc = clAmsMgmtCCBEntitySetConfig(ccbHandle,&sgConfig.entity,changeMask) ) != CL_OK)
{
checkError("Set SG config", rc);
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle) ) != CL_OK)
{
checkError("Commit change SG config",rc);
}
}
// Add the scheduler application in.
// In particular this defines the CSI TYPE in the SG so it will work when used during component addition.
//acAddApp(safName,"scheduler","");
}
// Add an application to this app container.
// The effect of this is to create a new SAF Service Instance (SI) and CSI
// This SI will be assigned to the SG and therefore a process running on the cluster
// This process shall use the information in the SI to start the appropriate
// application running.
void acAddApp(const char* appCnt,const char* appName, const char* activeXml, const char* standbyXml)
{
ClRcT rc;
ClAmsEntityConfigT sg;
ClAmsEntityConfigT si;
ClAmsEntityConfigT csi;
if (ccbHandle==CL_HANDLE_INVALID_VALUE) initHandles();
initEntity(&sg,appCnt,CL_AMS_ENTITY_TYPE_SG);
initEntity(&si,appName,CL_AMS_ENTITY_TYPE_SI);
initEntity(&csi,appName,CL_AMS_ENTITY_TYPE_CSI);
// Create the new entities
if ((rc = clAmsMgmtCCBEntityCreate(ccbHandle,&si)) != CL_OK)
{
checkError("Create SI",rc);
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle)) != CL_OK)
{
checkError("Commit SI creation", rc);
}
if ((rc = clAmsMgmtCCBEntityCreate(ccbHandle,&csi)) != CL_OK)
{
checkError("Create CSI",rc);
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle)) != CL_OK)
{
checkError("Commit CSI creation", rc);
}
// Configure the new entities
if (1) // configure the SI
{
ClUint64T changeMask = 0;
ClAmsEntityConfigT *pEntityConfig = NULL;
ClAmsSIConfigT siConfig;
// Grab the SI object
if ((rc = clAmsMgmtEntityGetConfig(mgmtHandle,&si,&pEntityConfig)) != CL_OK)
{
checkError("Get SI config", rc);
}
memcpy(&siConfig, pEntityConfig, sizeof(siConfig));
clHeapFree(pEntityConfig);
// Configure SI state
siConfig.numCSIs = 1;
siConfig.numStandbyAssignments = 1;
changeMask |= SI_CONFIG_NUM_CSIS | SI_CONFIG_NUM_STANDBY_ASSIGNMENTS;
if ((rc = clAmsMgmtCCBEntitySetConfig(ccbHandle,&siConfig.entity,changeMask)) != CL_OK)
{
checkError("Set SI config", rc);
}
// Link SI to the CSI
if ((rc = clAmsMgmtCCBSetSICSIList(ccbHandle,&si,&csi)) != CL_OK)
{
checkError("Change SI config", rc);
}
// Commit SI
if ((rc = clAmsMgmtCCBCommit(ccbHandle)) != CL_OK)
{
checkError("Commit SI configuration", rc);
}
}
if (1) // configure the CSI
{
ClAmsEntityConfigT *pEntityConfig = NULL;
ClUint64T changeMask = 0;
ClAmsCSIConfigT csiConfig;
ClAmsCSINVPT nvp;
// Grab the CSI object
if ((rc = clAmsMgmtEntityGetConfig(mgmtHandle,&csi,&pEntityConfig)) != CL_OK)
{
checkError("Get CSI configuration", rc);
}
memcpy(&csiConfig, pEntityConfig, sizeof(csiConfig));
clHeapFree(pEntityConfig);
// Specify a unique CSI type
changeMask |= CSI_CONFIG_TYPE;
saNameSet(&csiConfig.type, CSI_TYPE_APP);
csiConfig.type.length += 1;
if ((rc = clAmsMgmtCCBEntitySetConfig(ccbHandle,&csiConfig.entity,changeMask)) != CL_OK)
{
checkError("Set CSI type", rc);
}
// Set the name/value pairs
saNameSet(&nvp.paramName,"activexml");
saNameSet(&nvp.paramValue,activeXml);
if ((rc = clAmsMgmtCCBCSISetNVP(ccbHandle,&csi,&nvp)) != CL_OK)
{
checkError("Set CSI NVP", rc);
}
// Set the name/value pairs
saNameSet(&nvp.paramName,"standbyxml");
saNameSet(&nvp.paramValue,standbyXml);
if ((rc = clAmsMgmtCCBCSISetNVP(ccbHandle,&csi,&nvp)) != CL_OK)
{
checkError("Set CSI NVP", rc);
}
// Commit CSI
if ((rc = clAmsMgmtCCBCommit(ccbHandle)) != CL_OK)
{
checkError("Commit CSI",rc);
}
}
if (1) // Link the SI to the SG
{
if ((rc = clAmsMgmtCCBSetSGSIList(ccbHandle,&sg,&si)) != CL_OK)
{
checkError("Add SI to SG", rc);
}
if ((rc = clAmsMgmtCCBCommit(ccbHandle) ) != CL_OK)
{
checkError("Commit adding SI to SG", rc);
}
}
/*
* Unlock or start the SI
*/
if((rc = clAmsMgmtEntityUnlock(mgmtHandle, &si)) != CL_OK
&&
CL_GET_ERROR_CODE(rc) != CL_ERR_NO_OP)
{
checkError("SI unlock failed", rc);
}
}
