examples/TestMasterSlaveLSS/Master.c
author fbeaulier
Tue, 16 Aug 2011 14:15:52 +0200
changeset 663 70fc3603e36f
parent 517 003679edc437
child 717 cfb4f62f35af
permissions -rw-r--r--
timers_unix.c : remove sigint and sigterm catch
sdo : Allow multiple servers
The sdo transfer struct is not anymore referenced by server's node id but by
client or server number in the OD. Node id is not relevant in SDO transfert.
/*
This file is part of CanFestival, a library implementing CanOpen Stack. 

Copyright (C): Edouard TISSERANT , Francis DUPIN and Jorge BERZOSA

See COPYING file for copyrights details.

This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.

This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
Lesser General Public License for more details.

You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
*/

#include "Master.h"
#include "SlaveA.h"
#include "SlaveB.h"
#include "TestMasterSlaveLSS.h" 

extern s_BOARD MasterBoard;
/*****************************************************************************/
void TestMaster_heartbeatError(CO_Data* d, UNS8 heartbeatID)
{
	eprintf("TestMaster_heartbeatError %d\n", heartbeatID);
}

/********************************************************
 * TestMaster_initialisation is responsible to
 *  - setup master RPDO 1 to receive TPDO 1 from id 2
 *  - setup master RPDO 2 to receive TPDO 1 from id 3
 ********************************************************/
void TestMaster_initialisation(CO_Data* d)
{
	UNS32 PDO1_COBID = 0x0182; 
	UNS32 PDO2_COBID = 0x0183;
	UNS8 size = sizeof(UNS32); 
	
	eprintf("TestMaster_initialisation\n");

	/*****************************************
	 * Define RPDO to match slave ID=2 TPDO1*
	 *****************************************/
	writeLocalDict( &TestMaster_Data, /*CO_Data* d*/
			0x1400, /*UNS16 index*/
			0x01, /*UNS8 subind*/ 
			&PDO1_COBID, /*void * pSourceData,*/ 
			&size, /* UNS8 * pExpectedSize*/
			RW);  /* UNS8 checkAccess */
			
	/*****************************************
	 * Define RPDO to match slave ID=3 TPDO1*
	 *****************************************/		
	writeLocalDict( &TestMaster_Data, /*CO_Data* d*/
			0x1401, /*UNS16 index*/
			0x01, /*UNS8 subind*/ 
			&PDO2_COBID, /*void * pSourceData,*/ 
			&size, /* UNS8 * pExpectedSize*/
			RW);  /* UNS8 checkAccess */

}

// Step counts number of times ConfigureSlaveNode is called
// There is one per each slave
static init_step[] ={0,0};

/*Forward declaration*/
static void ConfigureSlaveNode(CO_Data* d, UNS8 nodeId);

static void CheckSDOAndContinue(CO_Data* d, UNS8 nodeId)
{
	UNS32 abortCode;	
	if(getWriteResultNetworkDict (d, nodeId, &abortCode) != SDO_FINISHED)
		eprintf("Master : Failed in initializing slave %2.2x, step %d, AbortCode :%4.4x \n", nodeId, init_step, abortCode);

	/* Finalise last SDO transfer with this node */
	closeSDOtransfer(&TestMaster_Data, nodeId, SDO_CLIENT);

	ConfigureSlaveNode(d, nodeId);
}

/********************************************************
 * ConfigureSlaveNode is responsible to
 *  - setup slave 'n' TPDO 1 transmit type
 *  - setup slave 'n' Producer Hertbeat Time
 *  - setup the Consumer Heartbeat Time for slave 'n'
 *  - switch to operational mode
 *  - send NMT to slave
 ********************************************************
 * This an example of :
 * Network Dictionary Access (SDO) with Callback 
 * Slave node state change request (NMT) 
 ********************************************************
 * This is called first by TestMaster_post_SlaveBootup
 * after the LSS configuration has been done
 * then it called again each time a SDO exchange is
 * finished.
 ********************************************************/
 
static void ConfigureSlaveNode(CO_Data* d, UNS8 nodeId)
{
	/* Master configure heartbeat producer time at 0 ms 
	 * for slaves node-id 0x02 and 0x03 by DCF concise */
	 
	UNS8 Transmission_Type = 0x01;
	UNS16 Slave_Prod_Heartbeat_T=1000;//ms
	UNS32 Master_Cons_Heartbeat_Base=0x05DC; //1500ms
	UNS32 abortCode;
	UNS8 res;
	eprintf("Master : ConfigureSlaveNode %2.2x\n", nodeId);

	switch(++init_step[nodeId-2]){
		case 1: /*First step : setup Slave's TPDO 1 to be transmitted on SYNC*/
			eprintf("Master : set slave %2.2x TPDO 1 transmit type\n", nodeId);
			res = writeNetworkDictCallBack (d, /*CO_Data* d*/
					nodeId, /*UNS8 nodeId*/
					0x1800, /*UNS16 index*/
					0x02, /*UNS8 subindex*/
					1, /*UNS8 count*/
					0, /*UNS8 dataType*/
					&Transmission_Type,/*void *data*/
					CheckSDOAndContinue); /*SDOCallback_t Callback*/
					break;
		case 2: /* Second step : Set the new heartbeat producer time in the slave */
		{
			UNS32 Master_Cons_Heartbeat_T=Master_Cons_Heartbeat_Base + (nodeId * 0x10000);
			UNS8 size = sizeof(UNS32); 
			
			eprintf("Master : set slave %2.2x Producer Heartbeat Time = %d\n", nodeId,Slave_Prod_Heartbeat_T);
			res = writeNetworkDictCallBack (d, /*CO_Data* d*/
					nodeId, /*UNS8 nodeId*/
					0x1017, /*UNS16 index*/
					0x00, /*UNS8 subindex*/
					2, /*UNS8 count*/
					0, /*UNS8 dataType*/
					&Slave_Prod_Heartbeat_T,/*void *data*/
					CheckSDOAndContinue); /*SDOCallback_t Callback*/
					break;
					
			/* Set the new heartbeat consumer time in the master*/
			eprintf("Master : set Consumer Heartbeat Time for slave %2.2x = %d\n", nodeId,Master_Cons_Heartbeat_T);
			writeLocalDict( &TestMaster_Data, /*CO_Data* d*/
				0x1016, /*UNS16 index*/
				nodeId-1, /*UNS8 subind*/ 
				&Master_Cons_Heartbeat_T, /*void * pSourceData,*/ 
				&size, /* UNS8 * pExpectedSize*/
				RW);  /* UNS8 checkAccess */
		}		
		break;
		case 3: 
		
		/****************************** START *******************************/
		
			/* Put the master in operational mode */
			setState(d, Operational);
		 
			/* Ask slave node to go in operational mode */
			masterSendNMTstateChange (d, nodeId, NMT_Start_Node);
	}
}

static void ConfigureLSSNode(CO_Data* d);
// Step counts number of times ConfigureLSSNode is called
UNS8 init_step_LSS=1;

static void CheckLSSAndContinue(CO_Data* d, UNS8 command)
{
	UNS32 dat1;
	UNS8 dat2;
	
	printf("CheckLSS->");
	if(getConfigResultNetworkNode (d, command, &dat1, &dat2) != LSS_FINISHED){
			eprintf("Master : Failed in LSS comand %d.  Trying again\n", command);
	}
	else
	{
		init_step_LSS++;
	
		switch(command){
		case LSS_CONF_NODE_ID:
   			switch(dat1){
   				case 0: printf("Node ID change succesful\n");break;
   				case 1: printf("Node ID change error:out of range\n");break;
   				case 0xFF:printf("Node ID change error:specific error\n");break;
   				default:break;
   			}
   			break;
   		case LSS_CONF_BIT_TIMING:
   			switch(dat1){
   				case 0: printf("Baud rate change succesful\n");break;
   				case 1: printf("Baud rate change error: change baud rate not supported\n");break;
   				case 0xFF:printf("Baud rate change error:specific error\n");break;
   				default:break;
   			}
   			break;
   		case LSS_CONF_STORE:
   			switch(dat1){
   				case 0: printf("Store configuration succesful\n");break;
   				case 1: printf("Store configuration error:not supported\n");break;
   				case 0xFF:printf("Store configuration error:specific error\n");break;
   				default:break;
   			}
   			break;
   		case LSS_CONF_ACT_BIT_TIMING:
   			if(dat1==0){
   				UNS8 LSS_mode=LSS_WAITING_MODE;
				UNS32 SINC_cicle=50000;// us
				UNS8 size = sizeof(UNS32); 
	
				/* The slaves are now configured (nodeId and Baudrate) via the LSS services.
   			 	* Switch the LSS state to WAITING and restart the slaves. */
				
				/*TODO: change the baud rate of the master!!*/
   			 	MasterBoard.baudrate="250K";
   			 	
   			 	
	   			printf("Master : Switch Delay period finished. Switching to LSS WAITING state\n");
   				configNetworkNode(d,LSS_SM_GLOBAL,&LSS_mode,0,NULL);
	   			
   				printf("Master : Restarting all the slaves\n");
   				masterSendNMTstateChange (d, 0x00, NMT_Reset_Comunication);
	   			
   				printf("Master : Starting the SYNC producer\n");
   				writeLocalDict( d, /*CO_Data* d*/
					0x1006, /*UNS16 index*/
					0x00, /*UNS8 subind*/ 
					&SINC_cicle, /*void * pSourceData,*/ 
					&size, /* UNS8 * pExpectedSize*/
					RW);  /* UNS8 checkAccess */
					
				return;
			}
   			else{
   				UNS16 Switch_delay=1;
				UNS8 LSS_mode=LSS_CONFIGURATION_MODE;
				
	   			eprintf("Master : unable to activate bit timing. trying again\n");
				configNetworkNode(d,LSS_CONF_ACT_BIT_TIMING,&Switch_delay,0,CheckLSSAndContinue);
				return;
   			}
   			break;	
		case LSS_SM_SELECTIVE_SERIAL:
   			printf("Slave in LSS CONFIGURATION state\n");
   			break;
   		case LSS_IDENT_REMOTE_SERIAL_HIGH:
   			printf("node identified\n");
   			break;
   		case LSS_IDENT_REMOTE_NON_CONF:
   			if(dat1==0)
   				eprintf("There are no-configured remote slave(s) in the net\n");
   			else
   			{
   				UNS16 Switch_delay=1;
				UNS8 LSS_mode=LSS_CONFIGURATION_MODE;
			
				/*The configuration of the slaves' nodeId ended.
				 * Start the configuration of the baud rate. */
				eprintf("Master : There are not no-configured slaves in the net\n", command);
				eprintf("Switching all the nodes to LSS CONFIGURATION state\n");
				configNetworkNode(d,LSS_SM_GLOBAL,&LSS_mode,0,NULL);
				eprintf("LSS=>Activate Bit Timing\n");
				configNetworkNode(d,LSS_CONF_ACT_BIT_TIMING,&Switch_delay,0,CheckLSSAndContinue);
				return;
   			}
   			break;
   		case LSS_INQ_VENDOR_ID:
   			printf("Slave VendorID %x\n", dat1);
   			break;
   		case LSS_INQ_PRODUCT_CODE:
   			printf("Slave Product Code %x\n", dat1);
   			break;
   		case LSS_INQ_REV_NUMBER:
   			printf("Slave Revision Number %x\n", dat1);
   			break;
   		case LSS_INQ_SERIAL_NUMBER:
   			printf("Slave Serial Number %x\n", dat1);
   			break;
   		case LSS_INQ_NODE_ID:
   			printf("Slave nodeid %x\n", dat1);
   			break;
#ifdef CO_ENABLE_LSS_FS
   		case LSS_IDENT_FASTSCAN:
   			if(dat1==0)
   				printf("Slave node identified with FastScan\n");
   			else
   			{
   				printf("There is not unconfigured node in the net\n");
   				return;
   			}	
   			init_step_LSS++;
   			break;
#endif	
	
		}
	}

	printf("\n");
	ConfigureLSSNode(d);
}

/* Initial nodeID and VendorID. They are incremented by one for each slave*/
UNS8 NodeID=0x02;
UNS32 Vendor_ID=0x12345678;

/* Configuration of the nodeID and baudrate with LSS services:
 * --First ask if there is a node with an invalid nodeID.
 * --If FastScan is activated it is used to put the slave in the state “configuration”.
 * --If FastScan is not activated, identification services are used to identify the slave. Then 
 * 	 switch mode service is used to put it in configuration state.
 * --Next, all the inquire services are used (only for example) and a valid nodeId and a
 * 	 new baudrate are assigned to the slave.
 * --Finally, the slave's LSS state is restored to “waiting” and all the process is repeated 
 * 	 again until there isn't any node with an invalid nodeID.
 * --After the configuration of all the slaves finished the LSS state of all of them is switched 
 * 	 again to "configuration" and the Activate Bit Timing service is requested. On sucessfull, the 
 * 	 LSS state is restored to "waiting" and NMT state is changed to reset (by means of the NMT services).
 * */
static void ConfigureLSSNode(CO_Data* d)
{
	UNS32 Product_Code=0x90123456;
	UNS32 Revision_Number=0x78901234;
	UNS32 Serial_Number=0x56789012;
	UNS32 Revision_Number_high=0x78901240;
	UNS32 Revision_Number_low=0x78901230;
	UNS32 Serial_Number_high=0x56789020;
	UNS32 Serial_Number_low=0x56789010;
	UNS8 LSS_mode=LSS_WAITING_MODE;
	UNS8 Baud_Table=0;
	//UNS8 Baud_BitTiming=3;
	char* Baud_BitTiming="250K";
	UNS8 res;
	eprintf("ConfigureLSSNode step %d -> ",init_step_LSS);

	switch(init_step_LSS){
		case 1:	/* LSS=>identify non-configured remote slave */
			eprintf("LSS=>identify no-configured remote slave(s)\n");
			res=configNetworkNode(&TestMaster_Data,LSS_IDENT_REMOTE_NON_CONF,0,0,CheckLSSAndContinue);
			break;
#ifdef CO_ENABLE_LSS_FS
		case 2:	/* LSS=>FastScan */
		{
			lss_fs_transfer_t lss_fs;
			eprintf("LSS=>FastScan\n");
			/* The VendorID and ProductCode are partialy known, except the last two digits (8 bits). */
			lss_fs.FS_LSS_ID[0]=Vendor_ID;
			lss_fs.FS_BitChecked[0]=8;
			lss_fs.FS_LSS_ID[1]=Product_Code;
			lss_fs.FS_BitChecked[1]=8;
			/* serialNumber and RevisionNumber are unknown, i.e. the 8 digits (32bits) are unknown. */
			lss_fs.FS_BitChecked[2]=32;
			lss_fs.FS_BitChecked[3]=32;
			res=configNetworkNode(&TestMaster_Data,LSS_IDENT_FASTSCAN,&lss_fs,0,CheckLSSAndContinue);
		}
		break;
#else
		case 2:	/* LSS=>identify node */
			eprintf("LSS=>identify node\n");
			res=configNetworkNode(&TestMaster_Data,LSS_IDENT_REMOTE_VENDOR,&Vendor_ID,0,NULL);
			res=configNetworkNode(&TestMaster_Data,LSS_IDENT_REMOTE_PRODUCT,&Product_Code,0,NULL);
			res=configNetworkNode(&TestMaster_Data,LSS_IDENT_REMOTE_REV_LOW,&Revision_Number_low,0,NULL);
			res=configNetworkNode(&TestMaster_Data,LSS_IDENT_REMOTE_REV_HIGH,&Revision_Number_high,0,NULL);
			res=configNetworkNode(&TestMaster_Data,LSS_IDENT_REMOTE_SERIAL_LOW,&Serial_Number_low,0,NULL);
			res=configNetworkNode(&TestMaster_Data,LSS_IDENT_REMOTE_SERIAL_HIGH,&Serial_Number_high,0,CheckLSSAndContinue);
			break;
		case 3: /*LSS=>put in configuration mode*/
			eprintf("LSS=>put in configuration mode\n");
			res=configNetworkNode(&TestMaster_Data,LSS_SM_SELECTIVE_VENDOR,&Vendor_ID,0,NULL);
			res=configNetworkNode(&TestMaster_Data,LSS_SM_SELECTIVE_PRODUCT,&Product_Code,0,NULL);
			res=configNetworkNode(&TestMaster_Data,LSS_SM_SELECTIVE_REVISION,&Revision_Number,0,NULL);
			res=configNetworkNode(&TestMaster_Data,LSS_SM_SELECTIVE_SERIAL,&Serial_Number,0,CheckLSSAndContinue);
			Vendor_ID++;
			break;
#endif
		case 4:	/* LSS=>inquire nodeID */
			eprintf("LSS=>inquire nodeID\n");
			res=configNetworkNode(&TestMaster_Data,LSS_INQ_NODE_ID,0,0,CheckLSSAndContinue);
			break;
		case 5:	/* LSS=>inquire VendorID */
			eprintf("LSS=>inquire VendorID\n");
			res=configNetworkNode(&TestMaster_Data,LSS_INQ_VENDOR_ID,0,0,CheckLSSAndContinue);
			break;
		case 6:	/* LSS=>inquire Product code */
			eprintf("LSS=>inquire Product code\n");
			res=configNetworkNode(&TestMaster_Data,LSS_INQ_PRODUCT_CODE,0,0,CheckLSSAndContinue);
			break;
		case 7:	/* LSS=>inquire Revision Number */
			eprintf("LSS=>inquire Revision Number\n");
			res=configNetworkNode(&TestMaster_Data,LSS_INQ_REV_NUMBER,0,0,CheckLSSAndContinue);
			break;
		case 8:	/* LSS=>inquire Serial Number */
			eprintf("LSS=>inquire Serial Number\n");
			res=configNetworkNode(&TestMaster_Data,LSS_INQ_SERIAL_NUMBER,0,0,CheckLSSAndContinue);
			break;
		case 9:	/* LSS=>change the nodeID */
			eprintf("LSS=>change the nodeId\n");
			res=configNetworkNode(&TestMaster_Data,LSS_CONF_NODE_ID,&NodeID,0,CheckLSSAndContinue);
			NodeID++;
			break;
		case 10:	/* LSS=>change the Baud rate */
			eprintf("LSS=>change the Baud rate\n");
			res=configNetworkNode(&TestMaster_Data,LSS_CONF_BIT_TIMING,&Baud_Table,&Baud_BitTiming,CheckLSSAndContinue);
			break;
		case 11:
			/*LSS=>store configuration*/
			eprintf("LSS=>store configuration\n");
			res=configNetworkNode(&TestMaster_Data,LSS_CONF_STORE,0,0,CheckLSSAndContinue);
			break;
		case 12: /* LSS=>put in waiting mode */
			eprintf("LSS=>put in waiting mode\n");
			res=configNetworkNode(&TestMaster_Data,LSS_SM_GLOBAL,&LSS_mode,0,NULL);
			/* Search again for no-configured slaves*/
			eprintf("LSS=>identify no-configured remote slave(s)\n");
			res=configNetworkNode(&TestMaster_Data,LSS_IDENT_REMOTE_NON_CONF,0,0,CheckLSSAndContinue);
			init_step_LSS=1;
			break;
	}
}

void TestMaster_preOperational(CO_Data* d)
{
	eprintf("TestMaster_preOperational\n");

	/* Ask slaves to go in stop mode */
	masterSendNMTstateChange (d, 0, NMT_Stop_Node);
	ConfigureLSSNode(&TestMaster_Data);
}

void TestMaster_operational(CO_Data* d)
{
	eprintf("TestMaster_operational\n");
}

void TestMaster_stopped(CO_Data* d)
{
	eprintf("TestMaster_stopped\n");
}

void TestMaster_post_sync(CO_Data* d)
{
	eprintf("TestMaster_post_sync\n");
	eprintf("Master: %d %d %d\n",
		MasterMap1,
		MasterMap2,
		MasterMap3);
}

void TestMaster_post_emcy(CO_Data* d, UNS8 nodeID, UNS16 errCode, UNS8 errReg)
{
	eprintf("Master received EMCY message. Node: %2.2x  ErrorCode: %4.4x  ErrorRegister: %2.2x\n", nodeID, errCode, errReg);
}

void TestMaster_post_TPDO(CO_Data* d)
{
	eprintf("TestMaster_post_TPDO\n");
}

void TestMaster_post_SlaveBootup(CO_Data* d, UNS8 nodeid)
{
	eprintf("TestMaster_post_SlaveBootup %x\n", nodeid);
	/* Wait until the new baud rate is stored before configure the slaves*/
	if(MasterBoard.baudrate=="250K")
		ConfigureSlaveNode(d, nodeid);
}