Commit 76d6da7c authored by Ivan Tyagov's avatar Ivan Tyagov

Separate OPC-UA's wrapper code for MOD-IO to a new file.

parent 3bab7efa
/*
* OPC-UA code representation of MOD-IOs connected to a Lime2
*/
void addIntegerVariableNode(UA_Server *server, char *node_id, char *node_description)
{
UA_Int32 myInteger = 0;
UA_NodeId parentNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_OBJECTSFOLDER);
UA_NodeId parentReferenceNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_ORGANIZES);
UA_VariableAttributes attr0 = UA_VariableAttributes_default;
UA_Variant_setScalar(&attr0.value, &myInteger, &UA_TYPES[UA_TYPES_INT32]);
attr0.description = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.displayName = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.dataType = UA_TYPES[UA_TYPES_INT32].typeId;
attr0.accessLevel = UA_ACCESSLEVELMASK_READ | UA_ACCESSLEVELMASK_WRITE;
UA_NodeId myIntegerNodeId0 = UA_NODEID_STRING(1, node_id);
UA_QualifiedName myIntegerName0 = UA_QUALIFIEDNAME(1, node_description);
UA_Server_addVariableNode(server, myIntegerNodeId0, parentNodeId,
parentReferenceNodeId, myIntegerName0,
UA_NODEID_NUMERIC(0, UA_NS0ID_BASEDATAVARIABLETYPE), attr0, NULL, NULL);
}
void addUIntegerVariableReadNode(UA_Server *server, char *node_id, char *node_description)
{
UA_UInt32 myInteger = 0;
UA_NodeId parentNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_OBJECTSFOLDER);
UA_NodeId parentReferenceNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_ORGANIZES);
UA_VariableAttributes attr0 = UA_VariableAttributes_default;
UA_Variant_setScalar(&attr0.value, &myInteger, &UA_TYPES[UA_TYPES_UINT32]);
attr0.description = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.displayName = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.dataType = UA_TYPES[UA_TYPES_UINT32].typeId;
attr0.accessLevel = UA_ACCESSLEVELMASK_READ;
UA_NodeId myIntegerNodeId0 = UA_NODEID_STRING(1, node_id);
UA_QualifiedName myIntegerName0 = UA_QUALIFIEDNAME(1, node_description);
UA_Server_addVariableNode(server, myIntegerNodeId0, parentNodeId,
parentReferenceNodeId, myIntegerName0,
UA_NODEID_NUMERIC(0, UA_NS0ID_BASEDATAVARIABLETYPE), attr0, NULL, NULL);
}
void addBooleanVariableReadNode(UA_Server *server, char *node_id, char *node_description)
{
UA_Boolean myBoolean = false;
UA_NodeId parentNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_OBJECTSFOLDER);
UA_NodeId parentReferenceNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_ORGANIZES);
UA_VariableAttributes attr0 = UA_VariableAttributes_default;
UA_Variant_setScalar(&attr0.value, &myBoolean, &UA_TYPES[UA_TYPES_BOOLEAN]);
attr0.description = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.displayName = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.dataType = UA_TYPES[UA_TYPES_BOOLEAN].typeId;
attr0.accessLevel = UA_ACCESSLEVELMASK_READ;
UA_NodeId myIntegerNodeId0 = UA_NODEID_STRING(1, node_id);
UA_QualifiedName myIntegerName0 = UA_QUALIFIEDNAME(1, node_description);
UA_Server_addVariableNode(server, myIntegerNodeId0, parentNodeId,
parentReferenceNodeId, myIntegerName0,
UA_NODEID_NUMERIC(0, UA_NS0ID_BASEDATAVARIABLETYPE), attr0, NULL, NULL);
}
static void addVariable(UA_Server *server)
{
/*
* Create all variables representing MOD-IO's relays
*/
int length = getI2CSlaveListLength();
if (length >= 1)
{
// IC2-0
addIntegerVariableNode(server, "i2c0.relay0", "I2C0 / Relay 0");
addIntegerVariableNode(server, "i2c0.relay1", "I2C0 / Relay 1");
addIntegerVariableNode(server, "i2c0.relay2", "I2C0 / Relay 2");
addIntegerVariableNode(server, "i2c0.relay3", "I2C0 / Relay 3");
addBooleanVariableReadNode(server, "i2c0.in0", "I2C0 / Digital Input 0");
addBooleanVariableReadNode(server, "i2c0.in1", "I2C0 / Digital Input 1");
addBooleanVariableReadNode(server, "i2c0.in2", "I2C0 / Digital Input 2");
addBooleanVariableReadNode(server, "i2c0.in3", "I2C0 / Digital Input 3");
addUIntegerVariableReadNode(server, "i2c0.ain0", "I2C0 / Analog Input 0");
addUIntegerVariableReadNode(server, "i2c0.ain1", "I2C0 / Analog Input 1");
addUIntegerVariableReadNode(server, "i2c0.ain2", "I2C0 / Analog Input 2");
addUIntegerVariableReadNode(server, "i2c0.ain3", "I2C0 / Analog Input 3");
}
if (length >= 2)
{
// IC2-1
addIntegerVariableNode(server, "i2c1.relay0", "I2C1 / Relay 0");
addIntegerVariableNode(server, "i2c1.relay1", "I2C1 / Relay 1");
addIntegerVariableNode(server, "i2c1.relay2", "I2C1 / Relay 2");
addIntegerVariableNode(server, "i2c1.relay3", "I2C1 / Relay 3");
addBooleanVariableReadNode(server, "i2c1.in0", "I2C1 / Digital Input 0");
addBooleanVariableReadNode(server, "i2c1.in1", "I2C1 / Digital Input 1");
addBooleanVariableReadNode(server, "i2c1.in2", "I2C1 / Digital Input 2");
addBooleanVariableReadNode(server, "i2c1.in3", "I2C1 / Digital Input 3");
addUIntegerVariableReadNode(server, "i2c1.ain0", "I2C1 / Analog Input 0");
addUIntegerVariableReadNode(server, "i2c1.ain1", "I2C1 / Analog Input 1");
addUIntegerVariableReadNode(server, "i2c1.ain2", "I2C1 / Analog Input 2");
addUIntegerVariableReadNode(server, "i2c1.ain3", "I2C1 / Analog Input 3");
}
}
/* Connect to variables to physical relays
*
*/
static void beforeReadTime(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
}
static void beforeReadTimeI2C0Ain0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
int *data_input = 0;
uint8_t read_addr =0x30;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C0Ain1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
int *data_input = 0;
uint8_t read_addr =0x31;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C0Ain2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
int *data_input = 0;
uint8_t read_addr =0x32;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C0Ain3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
int *data_input = 0;
uint8_t read_addr =0x33;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C1Ain0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
int *data_input = 0;
uint8_t read_addr =0x30;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C1Ain1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
int *data_input = 0;
uint8_t read_addr =0x31;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C1Ain2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
int *data_input = 0;
uint8_t read_addr =0x32;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C1Ain3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
int *data_input = 0;
uint8_t read_addr =0x33;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C0In0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 0))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C0In1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 1))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C0In2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 2))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C0In3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 3))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C1In0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 0))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C1In1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 1))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C1In2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 2))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C1In3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 3))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void afterWriteTime(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
// nothing to do as not yet needed.
}
// XXX: having afterWriteTime{0..3} is not needed and maybe with introspection of context we can
// write only one callback function
static void afterWriteTimeI2C0_0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[0];
if (hrValue > 0)
{
I2C_0_RELAYS_STATE |= 1UL << 0;
setRelayState(I2C_0_RELAYS_STATE, addr);
}
else
{
I2C_0_RELAYS_STATE &= ~(1UL << 0);
setRelayState(I2C_0_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C0_1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[0];
if (hrValue > 0)
{
I2C_0_RELAYS_STATE |= 1UL << 1;
setRelayState(I2C_0_RELAYS_STATE, addr);
}
else
{
I2C_0_RELAYS_STATE &= ~(1UL << 1);
setRelayState(I2C_0_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C0_2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[0];
if (hrValue > 0)
{
I2C_0_RELAYS_STATE |= 1UL << 2;
setRelayState(I2C_0_RELAYS_STATE, addr);
}
else
{
I2C_0_RELAYS_STATE &= ~(1UL << 2);
setRelayState(I2C_0_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C0_3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[0];
if (hrValue > 0)
{
I2C_0_RELAYS_STATE |= 1UL << 3;
setRelayState(I2C_0_RELAYS_STATE, addr);
}
else
{
I2C_0_RELAYS_STATE &= ~(1UL << 3);
setRelayState(I2C_0_RELAYS_STATE, addr);
}
}
}
// I2C1
static void afterWriteTimeI2C1_0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[1];
if (hrValue > 0)
{
I2C_1_RELAYS_STATE |= 1UL << 0;
setRelayState(I2C_1_RELAYS_STATE, addr);
}
else
{
I2C_1_RELAYS_STATE &= ~(1UL << 0);
setRelayState(I2C_1_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C1_1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[1];
if (hrValue > 0)
{
I2C_1_RELAYS_STATE |= 1UL << 1;
setRelayState(I2C_1_RELAYS_STATE, addr);
}
else
{
I2C_1_RELAYS_STATE &= ~(1UL << 1);
setRelayState(I2C_1_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C1_2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[1];
if (hrValue > 0)
{
I2C_1_RELAYS_STATE |= 1UL << 2;
setRelayState(I2C_1_RELAYS_STATE, addr);
}
else
{
I2C_1_RELAYS_STATE &= ~(1UL << 2);
setRelayState(I2C_1_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C1_3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[1];
if (hrValue > 0)
{
I2C_1_RELAYS_STATE |= 1UL << 3;
setRelayState(I2C_1_RELAYS_STATE, addr);
}
else
{
I2C_1_RELAYS_STATE &= ~(1UL << 3);
setRelayState(I2C_1_RELAYS_STATE, addr);
}
}
}
static void addValueCallbackToCurrentTimeVariable(UA_Server *server)
{
int length = getI2CSlaveListLength();
// I2C0
// relay 0
UA_NodeId currentNodeId0 = UA_NODEID_STRING(1, "i2c0.relay0");
UA_ValueCallback callback0;
callback0.onRead = beforeReadTime;
callback0.onWrite = afterWriteTimeI2C0_0;
UA_Server_setVariableNode_valueCallback(server, currentNodeId0, callback0);
// relay 1
UA_NodeId currentNodeId1 = UA_NODEID_STRING(1, "i2c0.relay1");
UA_ValueCallback callback1;
callback1.onRead = beforeReadTime;
callback1.onWrite = afterWriteTimeI2C0_1;
UA_Server_setVariableNode_valueCallback(server, currentNodeId1, callback1);
// relay 2
UA_NodeId currentNodeId2 = UA_NODEID_STRING(1, "i2c0.relay2");
UA_ValueCallback callback2;
callback2.onRead = beforeReadTime;
callback2.onWrite = afterWriteTimeI2C0_2;
UA_Server_setVariableNode_valueCallback(server, currentNodeId2, callback2);
// relay 3
UA_NodeId currentNodeId3 = UA_NODEID_STRING(1, "i2c0.relay3");
UA_ValueCallback callback3;
callback3.onRead = beforeReadTime;
callback3.onWrite = afterWriteTimeI2C0_3;
UA_Server_setVariableNode_valueCallback(server, currentNodeId3, callback3);
// Digital input 0
UA_NodeId currentNodeId4 = UA_NODEID_STRING(1, "i2c0.in0");
UA_ValueCallback callback4;
callback4.onRead = beforeReadTimeI2C0In0;
callback4.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId4, callback4);
// Digital input 1
UA_NodeId currentNodeId5 = UA_NODEID_STRING(1, "i2c0.in1");
UA_ValueCallback callback5;
callback5.onRead = beforeReadTimeI2C0In1;
callback5.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId5, callback5);
// Digital input 2
UA_NodeId currentNodeId6 = UA_NODEID_STRING(1, "i2c0.in2");
UA_ValueCallback callback6;
callback6.onRead = beforeReadTimeI2C0In2;
callback6.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId6, callback6);
// Digital input 3
UA_NodeId currentNodeId7 = UA_NODEID_STRING(1, "i2c0.in3");
UA_ValueCallback callback7;
callback7.onRead = beforeReadTimeI2C0In3;
callback7.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId7, callback7);
// Analog input 0
UA_NodeId currentNodeId8 = UA_NODEID_STRING(1, "i2c0.ain0");
UA_ValueCallback callback8;
callback8.onRead = beforeReadTimeI2C0Ain0;
callback8.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId8, callback8);
// Analog input 1
UA_NodeId currentNodeId9 = UA_NODEID_STRING(1, "i2c0.ain1");
UA_ValueCallback callback9;
callback9.onRead = beforeReadTimeI2C0Ain1;
callback9.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId9, callback9);
// Analog input 2
UA_NodeId currentNodeId10 = UA_NODEID_STRING(1, "i2c0.ain2");
UA_ValueCallback callback10;
callback10.onRead = beforeReadTimeI2C0Ain2;
callback10.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId10, callback10);
// Analog input 3
UA_NodeId currentNodeId11 = UA_NODEID_STRING(1, "i2c0.ain3");
UA_ValueCallback callback11;
callback11.onRead = beforeReadTimeI2C0Ain3;
callback11.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId11, callback11);
if (length > 1)
{
// I2C1
// relay 0
UA_NodeId currentNodeId12 = UA_NODEID_STRING(1, "i2c1.relay0");
UA_ValueCallback callback12;
callback12.onRead = beforeReadTime;
callback12.onWrite = afterWriteTimeI2C1_0;
UA_Server_setVariableNode_valueCallback(server, currentNodeId12, callback12);
// relay 1
UA_NodeId currentNodeId13 = UA_NODEID_STRING(1, "i2c1.relay1");
UA_ValueCallback callback13;
callback13.onRead = beforeReadTime;
callback13.onWrite = afterWriteTimeI2C1_1;
UA_Server_setVariableNode_valueCallback(server, currentNodeId13, callback13);
// relay 2
UA_NodeId currentNodeId14 = UA_NODEID_STRING(1, "i2c1.relay2");
UA_ValueCallback callback14;
callback14.onRead = beforeReadTime;
callback14.onWrite = afterWriteTimeI2C1_2;
UA_Server_setVariableNode_valueCallback(server, currentNodeId14, callback14);
// relay 2
UA_NodeId currentNodeId15 = UA_NODEID_STRING(1, "i2c1.relay3");
UA_ValueCallback callback15;
callback15.onRead = beforeReadTime;
callback15.onWrite = afterWriteTimeI2C1_3;
UA_Server_setVariableNode_valueCallback(server, currentNodeId15, callback15);
// Digital input 0
UA_NodeId currentNodeId16 = UA_NODEID_STRING(1, "i2c1.in0");
UA_ValueCallback callback16;
callback16.onRead = beforeReadTimeI2C1In0;
callback16.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId16, callback16);
// Digital input 1
UA_NodeId currentNodeId17 = UA_NODEID_STRING(1, "i2c1.in1");
UA_ValueCallback callback17;
callback17.onRead = beforeReadTimeI2C1In1;
callback17.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId17, callback17);
// Digital input 2
UA_NodeId currentNodeId18 = UA_NODEID_STRING(1, "i2c1.in2");
UA_ValueCallback callback18;
callback18.onRead = beforeReadTimeI2C1In2;
callback18.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId18, callback18);
// Digital input 3
UA_NodeId currentNodeId19 = UA_NODEID_STRING(1, "i2c1.in3");
UA_ValueCallback callback19;
callback19.onRead = beforeReadTimeI2C1In3;
callback19.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId19, callback19);
// Analog input 0
UA_NodeId currentNodeId20 = UA_NODEID_STRING(1, "i2c1.ain0");
UA_ValueCallback callback20;
callback20.onRead = beforeReadTimeI2C1Ain0;
callback20.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId20, callback20);
// Analog input 1
UA_NodeId currentNodeId21 = UA_NODEID_STRING(1, "i2c1.ain1");
UA_ValueCallback callback21;
callback21.onRead = beforeReadTimeI2C1Ain1;
callback21.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId21, callback21);
// Analog input 2
UA_NodeId currentNodeId22 = UA_NODEID_STRING(1, "i2c1.ain2");
UA_ValueCallback callback22;
callback22.onRead = beforeReadTimeI2C1Ain2;
callback22.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId22, callback22);
// Analog input 3
UA_NodeId currentNodeId23 = UA_NODEID_STRING(1, "i2c1.ain3");
UA_ValueCallback callback23;
callback23.onRead = beforeReadTimeI2C1Ain3;
callback23.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId23, callback23);
}
}
...@@ -25,6 +25,8 @@ ...@@ -25,6 +25,8 @@
#include <string.h> #include <string.h>
#include "common.h" #include "common.h"
#include "mod_io_i2c.h" #include "mod_io_i2c.h"
#include "mod_io_opc_ua.h"
// The default port of OPC-UA server // The default port of OPC-UA server
const int DEFAULT_OPC_UA_PORT = 4840; const int DEFAULT_OPC_UA_PORT = 4840;
...@@ -99,818 +101,6 @@ static error_t parse_opt(int key, char *arg, struct argp_state *state) ...@@ -99,818 +101,6 @@ static error_t parse_opt(int key, char *arg, struct argp_state *state)
static struct argp argp = {options, parse_opt, args_doc, doc, 0, 0, 0}; static struct argp argp = {options, parse_opt, args_doc, doc, 0, 0, 0};
void addIntegerVariableNode(UA_Server *server, char *node_id, char *node_description)
{
UA_Int32 myInteger = 0;
UA_NodeId parentNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_OBJECTSFOLDER);
UA_NodeId parentReferenceNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_ORGANIZES);
UA_VariableAttributes attr0 = UA_VariableAttributes_default;
UA_Variant_setScalar(&attr0.value, &myInteger, &UA_TYPES[UA_TYPES_INT32]);
attr0.description = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.displayName = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.dataType = UA_TYPES[UA_TYPES_INT32].typeId;
attr0.accessLevel = UA_ACCESSLEVELMASK_READ | UA_ACCESSLEVELMASK_WRITE;
UA_NodeId myIntegerNodeId0 = UA_NODEID_STRING(1, node_id);
UA_QualifiedName myIntegerName0 = UA_QUALIFIEDNAME(1, node_description);
UA_Server_addVariableNode(server, myIntegerNodeId0, parentNodeId,
parentReferenceNodeId, myIntegerName0,
UA_NODEID_NUMERIC(0, UA_NS0ID_BASEDATAVARIABLETYPE), attr0, NULL, NULL);
}
void addUIntegerVariableReadNode(UA_Server *server, char *node_id, char *node_description)
{
UA_UInt32 myInteger = 0;
UA_NodeId parentNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_OBJECTSFOLDER);
UA_NodeId parentReferenceNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_ORGANIZES);
UA_VariableAttributes attr0 = UA_VariableAttributes_default;
UA_Variant_setScalar(&attr0.value, &myInteger, &UA_TYPES[UA_TYPES_UINT32]);
attr0.description = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.displayName = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.dataType = UA_TYPES[UA_TYPES_UINT32].typeId;
attr0.accessLevel = UA_ACCESSLEVELMASK_READ;
UA_NodeId myIntegerNodeId0 = UA_NODEID_STRING(1, node_id);
UA_QualifiedName myIntegerName0 = UA_QUALIFIEDNAME(1, node_description);
UA_Server_addVariableNode(server, myIntegerNodeId0, parentNodeId,
parentReferenceNodeId, myIntegerName0,
UA_NODEID_NUMERIC(0, UA_NS0ID_BASEDATAVARIABLETYPE), attr0, NULL, NULL);
}
void addBooleanVariableReadNode(UA_Server *server, char *node_id, char *node_description)
{
UA_Boolean myBoolean = false;
UA_NodeId parentNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_OBJECTSFOLDER);
UA_NodeId parentReferenceNodeId = UA_NODEID_NUMERIC(0, UA_NS0ID_ORGANIZES);
UA_VariableAttributes attr0 = UA_VariableAttributes_default;
UA_Variant_setScalar(&attr0.value, &myBoolean, &UA_TYPES[UA_TYPES_BOOLEAN]);
attr0.description = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.displayName = UA_LOCALIZEDTEXT("en-US", node_description);
attr0.dataType = UA_TYPES[UA_TYPES_BOOLEAN].typeId;
attr0.accessLevel = UA_ACCESSLEVELMASK_READ;
UA_NodeId myIntegerNodeId0 = UA_NODEID_STRING(1, node_id);
UA_QualifiedName myIntegerName0 = UA_QUALIFIEDNAME(1, node_description);
UA_Server_addVariableNode(server, myIntegerNodeId0, parentNodeId,
parentReferenceNodeId, myIntegerName0,
UA_NODEID_NUMERIC(0, UA_NS0ID_BASEDATAVARIABLETYPE), attr0, NULL, NULL);
}
static void addVariable(UA_Server *server)
{
/*
* Create all variables representing MOD-IO's relays
*/
int length = getI2CSlaveListLength();
if (length >= 1)
{
// IC2-0
addIntegerVariableNode(server, "i2c0.relay0", "I2C0 / Relay 0");
addIntegerVariableNode(server, "i2c0.relay1", "I2C0 / Relay 1");
addIntegerVariableNode(server, "i2c0.relay2", "I2C0 / Relay 2");
addIntegerVariableNode(server, "i2c0.relay3", "I2C0 / Relay 3");
addBooleanVariableReadNode(server, "i2c0.in0", "I2C0 / Digital Input 0");
addBooleanVariableReadNode(server, "i2c0.in1", "I2C0 / Digital Input 1");
addBooleanVariableReadNode(server, "i2c0.in2", "I2C0 / Digital Input 2");
addBooleanVariableReadNode(server, "i2c0.in3", "I2C0 / Digital Input 3");
addUIntegerVariableReadNode(server, "i2c0.ain0", "I2C0 / Analog Input 0");
addUIntegerVariableReadNode(server, "i2c0.ain1", "I2C0 / Analog Input 1");
addUIntegerVariableReadNode(server, "i2c0.ain2", "I2C0 / Analog Input 2");
addUIntegerVariableReadNode(server, "i2c0.ain3", "I2C0 / Analog Input 3");
}
if (length >= 2)
{
// IC2-1
addIntegerVariableNode(server, "i2c1.relay0", "I2C1 / Relay 0");
addIntegerVariableNode(server, "i2c1.relay1", "I2C1 / Relay 1");
addIntegerVariableNode(server, "i2c1.relay2", "I2C1 / Relay 2");
addIntegerVariableNode(server, "i2c1.relay3", "I2C1 / Relay 3");
addBooleanVariableReadNode(server, "i2c1.in0", "I2C1 / Digital Input 0");
addBooleanVariableReadNode(server, "i2c1.in1", "I2C1 / Digital Input 1");
addBooleanVariableReadNode(server, "i2c1.in2", "I2C1 / Digital Input 2");
addBooleanVariableReadNode(server, "i2c1.in3", "I2C1 / Digital Input 3");
addUIntegerVariableReadNode(server, "i2c1.ain0", "I2C1 / Analog Input 0");
addUIntegerVariableReadNode(server, "i2c1.ain1", "I2C1 / Analog Input 1");
addUIntegerVariableReadNode(server, "i2c1.ain2", "I2C1 / Analog Input 2");
addUIntegerVariableReadNode(server, "i2c1.ain3", "I2C1 / Analog Input 3");
}
}
/* Connect to variables to physical relays
*
*/
static void beforeReadTime(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
}
static void beforeReadTimeI2C0Ain0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
int *data_input = 0;
uint8_t read_addr =0x30;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C0Ain1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
int *data_input = 0;
uint8_t read_addr =0x31;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C0Ain2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
int *data_input = 0;
uint8_t read_addr =0x32;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C0Ain3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
int *data_input = 0;
uint8_t read_addr =0x33;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C1Ain0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
int *data_input = 0;
uint8_t read_addr =0x30;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C1Ain1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
int *data_input = 0;
uint8_t read_addr =0x31;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C1Ain2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
int *data_input = 0;
uint8_t read_addr =0x32;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C1Ain3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
int *data_input = 0;
uint8_t read_addr =0x33;
if (!I2C_VIRTUAL_MODE) {
getAnalogInputStateAIN(addr, &data_input, read_addr);
if (data->value.type == &UA_TYPES[UA_TYPES_UINT32])
{
*(UA_UInt32 *)data->value.data = *data_input;
}
}
}
static void beforeReadTimeI2C0In0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 0))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C0In1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 1))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C0In2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 2))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C0In3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[0];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 3))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C1In0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 0))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C1In1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 1))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C1In2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 2))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void beforeReadTimeI2C1In3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeid, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
int addr = I2C_SLAVE_ADDR_LIST[1];
char *data_input = 0;
if (!I2C_VIRTUAL_MODE) {
getDigitalInputState(addr, &data_input);
if ((*data_input) & (1UL << 3))
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = true;
}
}
else
{
if (data->value.type == &UA_TYPES[UA_TYPES_BOOLEAN])
{
*(UA_Boolean *)data->value.data = false;
}
}
}
}
static void afterWriteTime(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
// nothing to do as not yet needed.
}
// XXX: having afterWriteTime{0..3} is not needed and maybe with introspection of context we can
// write only one callback function
static void afterWriteTimeI2C0_0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[0];
if (hrValue > 0)
{
I2C_0_RELAYS_STATE |= 1UL << 0;
setRelayState(I2C_0_RELAYS_STATE, addr);
}
else
{
I2C_0_RELAYS_STATE &= ~(1UL << 0);
setRelayState(I2C_0_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C0_1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[0];
if (hrValue > 0)
{
I2C_0_RELAYS_STATE |= 1UL << 1;
setRelayState(I2C_0_RELAYS_STATE, addr);
}
else
{
I2C_0_RELAYS_STATE &= ~(1UL << 1);
setRelayState(I2C_0_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C0_2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[0];
if (hrValue > 0)
{
I2C_0_RELAYS_STATE |= 1UL << 2;
setRelayState(I2C_0_RELAYS_STATE, addr);
}
else
{
I2C_0_RELAYS_STATE &= ~(1UL << 2);
setRelayState(I2C_0_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C0_3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[0];
if (hrValue > 0)
{
I2C_0_RELAYS_STATE |= 1UL << 3;
setRelayState(I2C_0_RELAYS_STATE, addr);
}
else
{
I2C_0_RELAYS_STATE &= ~(1UL << 3);
setRelayState(I2C_0_RELAYS_STATE, addr);
}
}
}
// I2C1
static void afterWriteTimeI2C1_0(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[1];
if (hrValue > 0)
{
I2C_1_RELAYS_STATE |= 1UL << 0;
setRelayState(I2C_1_RELAYS_STATE, addr);
}
else
{
I2C_1_RELAYS_STATE &= ~(1UL << 0);
setRelayState(I2C_1_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C1_1(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[1];
if (hrValue > 0)
{
I2C_1_RELAYS_STATE |= 1UL << 1;
setRelayState(I2C_1_RELAYS_STATE, addr);
}
else
{
I2C_1_RELAYS_STATE &= ~(1UL << 1);
setRelayState(I2C_1_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C1_2(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[1];
if (hrValue > 0)
{
I2C_1_RELAYS_STATE |= 1UL << 2;
setRelayState(I2C_1_RELAYS_STATE, addr);
}
else
{
I2C_1_RELAYS_STATE &= ~(1UL << 2);
setRelayState(I2C_1_RELAYS_STATE, addr);
}
}
}
static void afterWriteTimeI2C1_3(UA_Server *server,
const UA_NodeId *sessionId, void *sessionContext,
const UA_NodeId *nodeId, void *nodeContext,
const UA_NumericRange *range, const UA_DataValue *data)
{
if (data->value.type == &UA_TYPES[UA_TYPES_INT32])
{
UA_Int32 hrValue = *(UA_Int32 *)data->value.data;
int addr = I2C_SLAVE_ADDR_LIST[1];
if (hrValue > 0)
{
I2C_1_RELAYS_STATE |= 1UL << 3;
setRelayState(I2C_1_RELAYS_STATE, addr);
}
else
{
I2C_1_RELAYS_STATE &= ~(1UL << 3);
setRelayState(I2C_1_RELAYS_STATE, addr);
}
}
}
static void addValueCallbackToCurrentTimeVariable(UA_Server *server)
{
int length = getI2CSlaveListLength();
// I2C0
// relay 0
UA_NodeId currentNodeId0 = UA_NODEID_STRING(1, "i2c0.relay0");
UA_ValueCallback callback0;
callback0.onRead = beforeReadTime;
callback0.onWrite = afterWriteTimeI2C0_0;
UA_Server_setVariableNode_valueCallback(server, currentNodeId0, callback0);
// relay 1
UA_NodeId currentNodeId1 = UA_NODEID_STRING(1, "i2c0.relay1");
UA_ValueCallback callback1;
callback1.onRead = beforeReadTime;
callback1.onWrite = afterWriteTimeI2C0_1;
UA_Server_setVariableNode_valueCallback(server, currentNodeId1, callback1);
// relay 2
UA_NodeId currentNodeId2 = UA_NODEID_STRING(1, "i2c0.relay2");
UA_ValueCallback callback2;
callback2.onRead = beforeReadTime;
callback2.onWrite = afterWriteTimeI2C0_2;
UA_Server_setVariableNode_valueCallback(server, currentNodeId2, callback2);
// relay 3
UA_NodeId currentNodeId3 = UA_NODEID_STRING(1, "i2c0.relay3");
UA_ValueCallback callback3;
callback3.onRead = beforeReadTime;
callback3.onWrite = afterWriteTimeI2C0_3;
UA_Server_setVariableNode_valueCallback(server, currentNodeId3, callback3);
// Digital input 0
UA_NodeId currentNodeId4 = UA_NODEID_STRING(1, "i2c0.in0");
UA_ValueCallback callback4;
callback4.onRead = beforeReadTimeI2C0In0;
callback4.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId4, callback4);
// Digital input 1
UA_NodeId currentNodeId5 = UA_NODEID_STRING(1, "i2c0.in1");
UA_ValueCallback callback5;
callback5.onRead = beforeReadTimeI2C0In1;
callback5.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId5, callback5);
// Digital input 2
UA_NodeId currentNodeId6 = UA_NODEID_STRING(1, "i2c0.in2");
UA_ValueCallback callback6;
callback6.onRead = beforeReadTimeI2C0In2;
callback6.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId6, callback6);
// Digital input 3
UA_NodeId currentNodeId7 = UA_NODEID_STRING(1, "i2c0.in3");
UA_ValueCallback callback7;
callback7.onRead = beforeReadTimeI2C0In3;
callback7.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId7, callback7);
// Analog input 0
UA_NodeId currentNodeId8 = UA_NODEID_STRING(1, "i2c0.ain0");
UA_ValueCallback callback8;
callback8.onRead = beforeReadTimeI2C0Ain0;
callback8.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId8, callback8);
// Analog input 1
UA_NodeId currentNodeId9 = UA_NODEID_STRING(1, "i2c0.ain1");
UA_ValueCallback callback9;
callback9.onRead = beforeReadTimeI2C0Ain1;
callback9.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId9, callback9);
// Analog input 2
UA_NodeId currentNodeId10 = UA_NODEID_STRING(1, "i2c0.ain2");
UA_ValueCallback callback10;
callback10.onRead = beforeReadTimeI2C0Ain2;
callback10.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId10, callback10);
// Analog input 3
UA_NodeId currentNodeId11 = UA_NODEID_STRING(1, "i2c0.ain3");
UA_ValueCallback callback11;
callback11.onRead = beforeReadTimeI2C0Ain3;
callback11.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId11, callback11);
if (length > 1)
{
// I2C1
// relay 0
UA_NodeId currentNodeId12 = UA_NODEID_STRING(1, "i2c1.relay0");
UA_ValueCallback callback12;
callback12.onRead = beforeReadTime;
callback12.onWrite = afterWriteTimeI2C1_0;
UA_Server_setVariableNode_valueCallback(server, currentNodeId12, callback12);
// relay 1
UA_NodeId currentNodeId13 = UA_NODEID_STRING(1, "i2c1.relay1");
UA_ValueCallback callback13;
callback13.onRead = beforeReadTime;
callback13.onWrite = afterWriteTimeI2C1_1;
UA_Server_setVariableNode_valueCallback(server, currentNodeId13, callback13);
// relay 2
UA_NodeId currentNodeId14 = UA_NODEID_STRING(1, "i2c1.relay2");
UA_ValueCallback callback14;
callback14.onRead = beforeReadTime;
callback14.onWrite = afterWriteTimeI2C1_2;
UA_Server_setVariableNode_valueCallback(server, currentNodeId14, callback14);
// relay 2
UA_NodeId currentNodeId15 = UA_NODEID_STRING(1, "i2c1.relay3");
UA_ValueCallback callback15;
callback15.onRead = beforeReadTime;
callback15.onWrite = afterWriteTimeI2C1_3;
UA_Server_setVariableNode_valueCallback(server, currentNodeId15, callback15);
// Digital input 0
UA_NodeId currentNodeId16 = UA_NODEID_STRING(1, "i2c1.in0");
UA_ValueCallback callback16;
callback16.onRead = beforeReadTimeI2C1In0;
callback16.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId16, callback16);
// Digital input 1
UA_NodeId currentNodeId17 = UA_NODEID_STRING(1, "i2c1.in1");
UA_ValueCallback callback17;
callback17.onRead = beforeReadTimeI2C1In1;
callback17.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId17, callback17);
// Digital input 2
UA_NodeId currentNodeId18 = UA_NODEID_STRING(1, "i2c1.in2");
UA_ValueCallback callback18;
callback18.onRead = beforeReadTimeI2C1In2;
callback18.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId18, callback18);
// Digital input 3
UA_NodeId currentNodeId19 = UA_NODEID_STRING(1, "i2c1.in3");
UA_ValueCallback callback19;
callback19.onRead = beforeReadTimeI2C1In3;
callback19.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId19, callback19);
// Analog input 0
UA_NodeId currentNodeId20 = UA_NODEID_STRING(1, "i2c1.ain0");
UA_ValueCallback callback20;
callback20.onRead = beforeReadTimeI2C1Ain0;
callback20.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId20, callback20);
// Analog input 1
UA_NodeId currentNodeId21 = UA_NODEID_STRING(1, "i2c1.ain1");
UA_ValueCallback callback21;
callback21.onRead = beforeReadTimeI2C1Ain1;
callback21.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId21, callback21);
// Analog input 2
UA_NodeId currentNodeId22 = UA_NODEID_STRING(1, "i2c1.ain2");
UA_ValueCallback callback22;
callback22.onRead = beforeReadTimeI2C1Ain2;
callback22.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId22, callback22);
// Analog input 3
UA_NodeId currentNodeId23 = UA_NODEID_STRING(1, "i2c1.ain3");
UA_ValueCallback callback23;
callback23.onRead = beforeReadTimeI2C1Ain3;
callback23.onWrite = afterWriteTime;
UA_Server_setVariableNode_valueCallback(server, currentNodeId23, callback23);
}
}
void safeShutdownI2CSlaveList() void safeShutdownI2CSlaveList()
{ {
/* /*
......
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