/** \file \section general General The SOEM is a library that provides the user application with the means to send and receive EtherCAT frames. It is up to the application to provide means for: - Reading and writing process data to be sent/received by SOEM - Keeping local IO data synchronised with the global IOmap - Detecting errors reported by SOEM - Managing errors reported by SOEM The following sections show some basic examples on how to get the SOEM up and running, as well as making use of the process data and checking for errors. Since all code is local to the application or global variables, it is possible to tweak and optimize when possible. The following example shows how to add a main function that will be called by startup code. In this example main's only purpose is to spawn a new task that executes SOEM. \code int main (void) { rprintp("SOEM (Simple Open EtherCAT Master)\nSimple test\n"); task_spawn ("simpletest", simpletest, 9, 8192, NULL); \endcode \section configuration Configuration Followed by start of the application we need to set up the NIC to be used as EtherCAT Ethernet interface. In a simple setup we call ec_init(ifname) and if SOEM comes with support for cable redundancy we call ec_init_redundant that will open a second port as backup. You can send NULL as ifname if you have a dedicated NIC selected in the nicdrv.c. It returns >0 if succeeded. \code /* initialise SOEM, bind socket to ifname */ if (ec_init(ifname) > 0) \endcode SOEM is a light weight ethercat master library used in embedded systems, It supports only runtime configuration. It requests a BRD (Broad Cast Read) of address 0, all fully functional slaves in the network will respond to this request, and therefore we will get a working counter equal to the number of slaves in the network. ec_config_init also sets up the mailboxes for slaves that support it. When ec_config_init finishes it will have requested all slaves to state PRE_OP. All data read and configured are stored in a global array which acts as a placeholder for key values, consult ec_slave for detailed information. \code /* find and auto-config slaves */ if ( ec_config_init(FALSE) > 0 ) { rprintp("%d slaves found and configured.\n",ec_slavecount); \endcode SOEM has now discovered and configured the network it is connected to. Now we can verify that all slaves are present as expected. These definitions could be generated by an external tool in an offline .h file. The definitions could be replaced by a struct keeping slave number. \code #define EK1100_1 1 #define EL4001_1 2 ... #define EL2622_3 8 #define EL2622_4 9 #define NUMBER_OF_SLAVES 9 snippet ... uint32 network_configuration(void) { /* Do we got expected number of slaves from config */ if (ec_slavecount < NUMBER_OF_SLAVES) return 0; /* Verify slave by slave that it is correct*/ if (strcmp(ec_slave[EK1100_1].name,"EK1100")) return 0; else if (strcmp(ec_slave[EL4001_1].name,"EL4001")) return 0; ... else if (strcmp(ec_slave[EL2622_4].name,"EL2622")) return 0; return 1; } simpletest ... if (network_configuration()) ... else rprintp("Mismatch of network units!\n"); \endcode We now have the network up and configured. Mailboxes are up for slaves that support it. Next we will create an IOmap and configure the SyncManager's and FMMU's to link the EtherCAT master and the slaves. The IO mapping is done automatically, SOEM strives to keep the logical process image as compact as possible. It is done by trying to fit Bit oriented slaves together in single bytes. Below is an example of 8 slaves and how they are ordered. During mapping SOEM also calculates an expected WKC for the IO mapped together. That is the primary key to detect errors. - Outputs are placed together in the beginning of the IOmap - Inputs follow When the mapping is done SOEM requests slaves to enter SAFE_OP. \code char IOmap[128]; int usedmem; ... usedmem = ec_config_map(&IOmap); if (usedmem <= sizeof(IOmap)) ... \endcode \image html memory_layout.png "memory layout, mapping between physical and logical" \image latex memory_layout.png "memory layout, mapping between physical and logical" width=15cm To enter state OP we need to send valid data to outputs. The EtherCAT frame handling is split into ec_send_processdata and ec_receive_processdata. - ec_send_processdata sends the frame on the NIC and saves the frame on the stack for receive to fetch. - ec_receive_processdata(EC_TIMEOUTRET) tries to fetch the frames on the stack. We send an argument for how long we will try to fetch the frame. ec_receive_processdata returns the working counter. \code /* send one valid process data to make outputs in slaves happy*/ ec_send_processdata(); wkc = ec_receive_processdata(EC_TIMEOUTRET); ... ec_writestate(0); /* wait for all slaves to reach OP state */ ec_statecheck(0, EC_STATE_OPERATIONAL, EC_TIMEOUTSTATE); \endcode - Now we have a system up and running, all slaves are in state operational. \section application Application IO data is accessed through the IOmap, the ec_slave struct keep pointers to the start byte in the IO map on slave level together with start bit within the start byte. This way we can bit mask IO on bit level even though SOEM has combined slave data to minimize the frame size to be sent. We'll use slave 8 in the picture above as an example. From a printout from ec_slave we have the following: - Slave:8 - Name:EL2622 - Output size: 2bits - Input size: 0bits - Configured address: 1008 - Outputs address: 18cf6 - Inputs address: 0 - FMMU0 Ls:2 Ll: 1 Lsb:4 Leb:5 Ps:f00 Psb:0 Ty:2 Act:1 The Outputs address: 18cf6 is the pointer to slave 8's start byte. The FMMU's Lsb:4 (LogicalStartBit) = ec_slave.Ostartbit telling us how to mask for the individual bits in the combined byte. The same goes for byte addressed slaves, but byte slaves only need the byte start address since they are byte aligned, the start bit will be 0. Some example on how to access different types of data Set an output int 16 value when memory alignment needs to be considered, arguments is: - slave number in ethercat network - module index as index internal to the slave in case more than one channel - value to write \code #define EL4001_1 2 ... void set_output_int16 (uint16 slave_no, uint8 module_index, int16 value) { uint8 *data_ptr; data_ptr = ec_slave[slave_no].outputs; /* Move pointer to correct module index*/ data_ptr += module_index * 2; /* Read value byte by byte since all targets can't handle misaligned * addresses */ *data_ptr++ = (value >> 0) & 0xFF; *data_ptr++ = (value >> 8) & 0xFF; } ... set_output_int16(EL4001_1,0,slave_EL4001_1.out1); \endcode Target can handle non aligned pointers to the IOmap \code typedef struct PACKED { int16 outvalue1; int16 outvalue2; } out_EL4132t; out_EL4132t *out_EL4132; ... /* connect struct pointers to slave I/O pointers */ out_EL4132 = (out_EL4132t*) ec_slave[3].outputs; out_EL4132->outvalue2 = 0x3FFF; ... \endcode Identify and manage errors. The key is the Working Counter, CRC errors and errors local to the slave causing a state change can be detected by loss of Working Counter since the syncmanagers won't get updated. When returning Working Counter don't match Expected Working Counter something is wrong, then it is up to an error handler to act, locate the erroneous slave and decide what action to perform. The error may not be fatal. Some basic code from simple_test. \code wkc = ec_receive_processdata(EC_TIMEOUTRET); expectedWKC = (ec_group[0].outputsWKC * 2) + ec_group[0].inputsWKC; if( inOP && ((wkc < expectedWKC) || ec_group[currentgroup].docheckstate)) { if (needlf) { needlf = FALSE; printf("\n"); } /* one ore more slaves are not responding */ ec_group[currentgroup].docheckstate = FALSE; ec_readstate(); for (slave = 1; slave <= ec_slavecount; slave++) { if ((ec_slave[slave].group == currentgroup) && (ec_slave[slave].state != EC_STATE_OPERATIONAL)) { ec_group[currentgroup].docheckstate = TRUE; if (ec_slave[slave].state == (EC_STATE_SAFE_OP + EC_STATE_ERROR)) { printf("ERROR : slave %d is in SAFE_OP + ERROR, attempting ack.\n", slave); ec_slave[slave].state = (EC_STATE_SAFE_OP + EC_STATE_ACK); ec_writestate(slave); } else if(ec_slave[slave].state == EC_STATE_SAFE_OP) { printf("WARNING : slave %d is in SAFE_OP, change to OPERATIONAL.\n", slave); ec_slave[slave].state = EC_STATE_OPERATIONAL; ec_writestate(slave); } else if(ec_slave[slave].state > EC_STATE_NONE) { if (ec_reconfig_slave(slave, EC_TIMEOUTMON)) { ec_slave[slave].islost = FALSE; printf("MESSAGE : slave %d reconfigured\n",slave); } } else if(!ec_slave[slave].islost) { /* re-check state */ ec_statecheck(slave, EC_STATE_OPERATIONAL, EC_TIMEOUTRET); if (ec_slave[slave].state == EC_STATE_NONE) { ec_slave[slave].islost = TRUE; printf("ERROR : slave %d lost\n",slave); } } } if (ec_slave[slave].islost) { if(ec_slave[slave].state == EC_STATE_NONE) { if (ec_recover_slave(slave, EC_TIMEOUTMON)) { ec_slave[slave].islost = FALSE; printf("MESSAGE : slave %d recovered\n",slave); } } else { ec_slave[slave].islost = FALSE; printf("MESSAGE : slave %d found\n",slave); } } } if(!ec_group[currentgroup].docheckstate) printf("OK : all slaves resumed OPERATIONAL.\n"); } \endcode This tutorial is just one way of doing it. Enjoy and happy coding! Andreas Karlsson, rt-labs AB, www.rt-labs.com */