Compiler flag -DSVNREV only for module.c to avoid unnecessary recompiling.
/******************************************************************************
*
* $Id$
*
* Copyright (C) 2006 Florian Pose, Ingenieurgemeinschaft IgH
*
* This file is part of the IgH EtherCAT Master.
*
* The IgH EtherCAT Master is free software; you can redistribute it
* and/or modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2 of the
* License, or (at your option) any later version.
*
* The IgH EtherCAT Master 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with the IgH EtherCAT Master; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*
* The right to use EtherCAT Technology is granted and comes free of
* charge under condition of compatibility of product made by
* Licensee. People intending to distribute/sell products based on the
* code, have to sign an agreement to guarantee that products using
* software based on IgH EtherCAT master stay compatible with the actual
* EtherCAT specification (which are released themselves as an open
* standard) as the (only) precondition to have the right to use EtherCAT
* Technology, IP and trade marks.
*
*****************************************************************************/
/**
\file
EtherCAT finite state machines.
*/
/*****************************************************************************/
#include "globals.h"
#include "fsm.h"
#include "master.h"
#include "mailbox.h"
/*****************************************************************************/
void ec_fsm_master_start(ec_fsm_t *);
void ec_fsm_master_broadcast(ec_fsm_t *);
void ec_fsm_master_read_states(ec_fsm_t *);
void ec_fsm_master_validate_vendor(ec_fsm_t *);
void ec_fsm_master_validate_product(ec_fsm_t *);
void ec_fsm_master_rewrite_addresses(ec_fsm_t *);
void ec_fsm_master_configure_slave(ec_fsm_t *);
void ec_fsm_master_scan_slaves(ec_fsm_t *);
void ec_fsm_master_write_eeprom(ec_fsm_t *);
void ec_fsm_master_sdodict(ec_fsm_t *);
void ec_fsm_master_sdo_request(ec_fsm_t *);
void ec_fsm_startup_start(ec_fsm_t *);
void ec_fsm_startup_broadcast(ec_fsm_t *);
void ec_fsm_startup_scan(ec_fsm_t *);
void ec_fsm_configuration_start(ec_fsm_t *);
void ec_fsm_configuration_conf(ec_fsm_t *);
void ec_fsm_slavescan_start(ec_fsm_t *);
void ec_fsm_slavescan_address(ec_fsm_t *);
void ec_fsm_slavescan_state(ec_fsm_t *);
void ec_fsm_slavescan_base(ec_fsm_t *);
void ec_fsm_slavescan_datalink(ec_fsm_t *);
void ec_fsm_slavescan_eeprom_size(ec_fsm_t *);
void ec_fsm_slavescan_eeprom_data(ec_fsm_t *);
void ec_fsm_slaveconf_init(ec_fsm_t *);
void ec_fsm_slaveconf_sync(ec_fsm_t *);
void ec_fsm_slaveconf_preop(ec_fsm_t *);
void ec_fsm_slaveconf_fmmu(ec_fsm_t *);
void ec_fsm_slaveconf_sdoconf(ec_fsm_t *);
void ec_fsm_slaveconf_saveop(ec_fsm_t *);
void ec_fsm_slaveconf_op(ec_fsm_t *);
void ec_fsm_end(ec_fsm_t *);
void ec_fsm_error(ec_fsm_t *);
/*****************************************************************************/
/**
Constructor.
*/
int ec_fsm_init(ec_fsm_t *fsm, /**< finite state machine */
ec_master_t *master /**< EtherCAT master */
)
{
fsm->master = master;
fsm->master_state = ec_fsm_master_start;
fsm->master_slaves_responding = 0;
fsm->master_slave_states = EC_SLAVE_STATE_UNKNOWN;
fsm->master_validation = 0;
ec_datagram_init(&fsm->datagram);
if (ec_datagram_prealloc(&fsm->datagram, EC_MAX_DATA_SIZE)) {
EC_ERR("Failed to allocate FSM datagram.\n");
return -1;
}
// init sub-state-machines
ec_fsm_sii_init(&fsm->fsm_sii, &fsm->datagram);
ec_fsm_change_init(&fsm->fsm_change, &fsm->datagram);
ec_fsm_coe_init(&fsm->fsm_coe, &fsm->datagram);
return 0;
}
/*****************************************************************************/
/**
Destructor.
*/
void ec_fsm_clear(ec_fsm_t *fsm /**< finite state machine */)
{
// clear sub-state machines
ec_fsm_sii_clear(&fsm->fsm_sii);
ec_fsm_change_clear(&fsm->fsm_change);
ec_fsm_coe_clear(&fsm->fsm_coe);
ec_datagram_clear(&fsm->datagram);
}
/*****************************************************************************/
/**
Resets the state machine.
*/
void ec_fsm_reset(ec_fsm_t *fsm /**< finite state machine */)
{
fsm->master_state = ec_fsm_master_start;
fsm->master_slaves_responding = 0;
fsm->master_slave_states = EC_SLAVE_STATE_UNKNOWN;
}
/*****************************************************************************/
/**
Executes the current state of the state machine.
\return false, if state machine has terminated
*/
int ec_fsm_exec(ec_fsm_t *fsm /**< finite state machine */)
{
fsm->master_state(fsm);
return fsm->master_state != ec_fsm_end &&
fsm->master_state != ec_fsm_error;
}
/*****************************************************************************/
/**
Initializes the master startup state machine.
*/
void ec_fsm_startup(ec_fsm_t *fsm)
{
fsm->master_state = ec_fsm_startup_start;
}
/*****************************************************************************/
/**
Returns, if the master startup state machine terminated with success.
\return non-zero if successful.
*/
int ec_fsm_startup_success(ec_fsm_t *fsm /**< Finite state machine */)
{
return fsm->master_state == ec_fsm_end;
}
/*****************************************************************************/
/**
Initializes the master configuration state machine.
*/
void ec_fsm_configuration(ec_fsm_t *fsm)
{
fsm->master_state = ec_fsm_configuration_start;
}
/*****************************************************************************/
/**
Returns, if the master confuguration state machine terminated with success.
\return non-zero if successful.
*/
int ec_fsm_configuration_success(ec_fsm_t *fsm /**< Finite state machine */)
{
return fsm->master_state == ec_fsm_end;
}
/******************************************************************************
* master startup state machine
*****************************************************************************/
/**
Master state: START.
Starts with getting slave count and slave states.
*/
void ec_fsm_startup_start(ec_fsm_t *fsm)
{
ec_datagram_brd(&fsm->datagram, 0x0130, 2);
ec_master_queue_datagram(fsm->master, &fsm->datagram);
fsm->master_state = ec_fsm_startup_broadcast;
}
/*****************************************************************************/
/**
Master state: BROADCAST.
Processes the broadcast read slave count and slaves states.
*/
void ec_fsm_startup_broadcast(ec_fsm_t *fsm /**< finite state machine */)
{
ec_datagram_t *datagram = &fsm->datagram;
unsigned int i;
ec_slave_t *slave;
ec_master_t *master = fsm->master;
if (datagram->state != EC_DATAGRAM_RECEIVED) {
EC_ERR("Failed to receive broadcast datagram.\n");
fsm->master_state = ec_fsm_error;
return;
}
EC_INFO("Scanning bus.\n");
ec_master_clear_slaves(master);
master->slave_count = datagram->working_counter;
if (!master->slave_count) {
// no slaves present -> finish state machine.
fsm->master_state = ec_fsm_end;
return;
}
// init slaves
for (i = 0; i < master->slave_count; i++) {
if (!(slave = (ec_slave_t *) kmalloc(sizeof(ec_slave_t),
GFP_KERNEL))) {
EC_ERR("Failed to allocate slave %i!\n", i);
fsm->master_state = ec_fsm_error;
return;
}
if (ec_slave_init(slave, master, i, i + 1)) {
fsm->master_state = ec_fsm_error;
return;
}
if (kobject_add(&slave->kobj)) {
EC_ERR("Failed to add kobject.\n");
kobject_put(&slave->kobj); // free
fsm->master_state = ec_fsm_error;
return;
}
list_add_tail(&slave->list, &master->slaves);
}
// begin scanning of slaves
fsm->slave = list_entry(master->slaves.next, ec_slave_t, list);
fsm->slave_state = ec_fsm_slavescan_start;
fsm->master_state = ec_fsm_startup_scan;
fsm->master_state(fsm); // execute immediately
return;
}
/*****************************************************************************/
/**
Master state: SCAN.
Executes the sub-statemachine for the scanning of a slave.
*/
void ec_fsm_startup_scan(ec_fsm_t *fsm /**< finite state machine */)
{
ec_master_t *master = fsm->master;
ec_slave_t *slave = fsm->slave;
fsm->slave_state(fsm); // execute slave state machine
if (fsm->slave_state == ec_fsm_error) {
EC_ERR("Slave scanning failed.\n");
fsm->master_state = ec_fsm_error;
return;
}
if (fsm->slave_state != ec_fsm_end) return;
// another slave to scan?
if (slave->list.next != &master->slaves) {
fsm->slave = list_entry(fsm->slave->list.next, ec_slave_t, list);
fsm->slave_state = ec_fsm_slavescan_start;
fsm->slave_state(fsm); // execute immediately
return;
}
EC_INFO("Bus scanning completed.\n");
ec_master_calc_addressing(master);
fsm->master_state = ec_fsm_end;
}
/******************************************************************************
* master configuration state machine
*****************************************************************************/
/**
Master configuration state machine: START.
*/
void ec_fsm_configuration_start(ec_fsm_t *fsm /**< finite state machine */)
{
ec_master_t *master = fsm->master;
if (list_empty(&master->slaves)) {
fsm->master_state = ec_fsm_end;
return;
}
// begin configuring slaves
fsm->slave = list_entry(master->slaves.next, ec_slave_t, list);
fsm->slave_state = ec_fsm_slaveconf_init;
ec_fsm_change(&fsm->fsm_change, fsm->slave, EC_SLAVE_STATE_INIT);
fsm->master_state = ec_fsm_configuration_conf;
fsm->master_state(fsm); // execute immediately
}
/*****************************************************************************/
/**
Master state: CONF.
*/
void ec_fsm_configuration_conf(ec_fsm_t *fsm /**< finite state machine */)
{
ec_master_t *master = fsm->master;
ec_slave_t *slave = fsm->slave;
fsm->slave_state(fsm); // execute slave's state machine
if (fsm->slave_state == ec_fsm_error) {
fsm->master_state = ec_fsm_error;
return;
}
if (fsm->slave_state != ec_fsm_end) return;
// another slave to configure?
if (slave->list.next != &master->slaves) {
fsm->slave = list_entry(fsm->slave->list.next, ec_slave_t, list);
fsm->slave_state = ec_fsm_slaveconf_init;
ec_fsm_change(&fsm->fsm_change, fsm->slave, EC_SLAVE_STATE_INIT);
fsm->master_state(fsm); // execute immediately
return;
}
fsm->master_state = ec_fsm_end;
}
/******************************************************************************
* operation / idle state machine
*****************************************************************************/
/**
Master state: START.
Starts with getting slave count and slave states.
*/
void ec_fsm_master_start(ec_fsm_t *fsm)
{
ec_datagram_brd(&fsm->datagram, 0x0130, 2);
ec_master_queue_datagram(fsm->master, &fsm->datagram);
fsm->master_state = ec_fsm_master_broadcast;
}
/*****************************************************************************/
/**
Master state: BROADCAST.
Processes the broadcast read slave count and slaves states.
*/
void ec_fsm_master_broadcast(ec_fsm_t *fsm /**< finite state machine */)
{
ec_datagram_t *datagram = &fsm->datagram;
unsigned int topology_change, states_change, i;
ec_slave_t *slave;
ec_master_t *master = fsm->master;
if (datagram->state != EC_DATAGRAM_RECEIVED) {
if (!master->device->link_state) {
fsm->master_slaves_responding = 0;
list_for_each_entry(slave, &master->slaves, list) {
slave->online = 0;
}
}
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
topology_change = (datagram->working_counter !=
fsm->master_slaves_responding);
states_change = (EC_READ_U8(datagram->data) != fsm->master_slave_states);
fsm->master_slave_states = EC_READ_U8(datagram->data);
fsm->master_slaves_responding = datagram->working_counter;
if (topology_change) {
EC_INFO("%i slave%s responding.\n",
fsm->master_slaves_responding,
fsm->master_slaves_responding == 1 ? "" : "s");
if (master->mode == EC_MASTER_MODE_OPERATION) {
if (fsm->master_slaves_responding == master->slave_count) {
fsm->master_validation = 1; // start validation later
}
else {
EC_WARN("Invalid slave count. Bus in tainted state.\n");
}
}
}
if (states_change) {
char states[EC_STATE_STRING_SIZE];
ec_state_string(fsm->master_slave_states, states);
EC_INFO("Slave states: %s.\n", states);
}
// topology change in idle mode: clear all slaves and scan the bus
if (topology_change && master->mode == EC_MASTER_MODE_IDLE) {
EC_INFO("Scanning bus.\n");
ec_master_eoe_stop(master);
ec_master_clear_slaves(master);
master->slave_count = datagram->working_counter;
if (!master->slave_count) {
// no slaves present -> finish state machine.
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
// init slaves
for (i = 0; i < master->slave_count; i++) {
if (!(slave = (ec_slave_t *) kmalloc(sizeof(ec_slave_t),
GFP_ATOMIC))) {
EC_ERR("Failed to allocate slave %i!\n", i);
ec_master_clear_slaves(master);
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
if (ec_slave_init(slave, master, i, i + 1)) {
// freeing of "slave" already done
ec_master_clear_slaves(master);
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
if (kobject_add(&slave->kobj)) {
EC_ERR("Failed to add kobject.\n");
kobject_put(&slave->kobj); // free
ec_master_clear_slaves(master);
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
list_add_tail(&slave->list, &master->slaves);
}
// begin scanning of slaves
fsm->slave = list_entry(master->slaves.next, ec_slave_t, list);
fsm->slave_state = ec_fsm_slavescan_start;
fsm->master_state = ec_fsm_master_scan_slaves;
fsm->master_state(fsm); // execute immediately
return;
}
// fetch state from each slave
fsm->slave = list_entry(master->slaves.next, ec_slave_t, list);
ec_datagram_nprd(&fsm->datagram, fsm->slave->station_address, 0x0130, 2);
ec_master_queue_datagram(master, &fsm->datagram);
fsm->master_state = ec_fsm_master_read_states;
}
/*****************************************************************************/
/**
Master action: PROC_STATES.
Processes the slave states.
*/
void ec_fsm_master_action_process_states(ec_fsm_t *fsm
/**< finite state machine */
)
{
ec_master_t *master = fsm->master;
ec_slave_t *slave;
char old_state[EC_STATE_STRING_SIZE], new_state[EC_STATE_STRING_SIZE];
// check if any slaves are not in the state, they're supposed to be
list_for_each_entry(slave, &master->slaves, list) {
if (slave->error_flag
|| !slave->online
|| slave->requested_state == EC_SLAVE_STATE_UNKNOWN
|| (slave->current_state == slave->requested_state
&& (slave->configured
|| slave->current_state == EC_SLAVE_STATE_INIT))) continue;
ec_state_string(slave->current_state, old_state);
ec_state_string(slave->requested_state, new_state);
if (!slave->configured
&& slave->current_state != EC_SLAVE_STATE_INIT) {
EC_INFO("Reconfiguring slave %i (%s -> %s).\n",
slave->ring_position, old_state, new_state);
}
else if (slave->current_state != slave->requested_state) {
EC_INFO("Changing state of slave %i (%s -> %s).\n",
slave->ring_position, old_state, new_state);
}
fsm->slave = slave;
fsm->slave_state = ec_fsm_slaveconf_init;
ec_fsm_change(&fsm->fsm_change, fsm->slave, EC_SLAVE_STATE_INIT);
fsm->master_state = ec_fsm_master_configure_slave;
fsm->master_state(fsm); // execute immediately
return;
}
// Check, if EoE processing has to be started
ec_master_eoe_start(master);
if (master->mode == EC_MASTER_MODE_IDLE) {
// Check for a pending SDO request
if (master->sdo_seq_master != master->sdo_seq_user) {
if (master->debug_level)
EC_DBG("Processing SDO request...\n");
slave = master->sdo_request->sdo->slave;
if (slave->current_state == EC_SLAVE_STATE_INIT
|| !slave->online
|| slave->error_flag) {
EC_ERR("Failed to process SDO request, slave %i not ready.\n",
slave->ring_position);
master->sdo_request->return_code = -1;
master->sdo_seq_master++;
}
else {
// start uploading SDO
fsm->slave = slave;
fsm->master_state = ec_fsm_master_sdo_request;
fsm->sdo_request = master->sdo_request;
ec_fsm_coe_upload(&fsm->fsm_coe, slave, fsm->sdo_request);
ec_fsm_coe_exec(&fsm->fsm_coe); // execute immediately
return;
}
}
// check, if slaves have an SDO dictionary to read out.
list_for_each_entry(slave, &master->slaves, list) {
if (!(slave->sii_mailbox_protocols & EC_MBOX_COE)
|| slave->sdo_dictionary_fetched
|| slave->current_state == EC_SLAVE_STATE_INIT
|| jiffies - slave->jiffies_preop < EC_WAIT_SDO_DICT * HZ
|| !slave->online
|| slave->error_flag) continue;
if (master->debug_level) {
EC_DBG("Fetching SDO dictionary from slave %i.\n",
slave->ring_position);
}
if (kobject_add(&slave->sdo_kobj)) {
EC_ERR("Failed to add SDO kobj of slave %i.\n",
slave->ring_position);
slave->error_flag = 1;
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
slave->sdo_dictionary_fetched = 1;
// start fetching SDO dictionary
fsm->slave = slave;
fsm->master_state = ec_fsm_master_sdodict;
ec_fsm_coe_dictionary(&fsm->fsm_coe, slave);
ec_fsm_coe_exec(&fsm->fsm_coe); // execute immediately
return;
}
// check for pending EEPROM write operations.
list_for_each_entry(slave, &master->slaves, list) {
if (!slave->new_eeprom_data) continue;
if (!slave->online || slave->error_flag) {
kfree(slave->new_eeprom_data);
slave->new_eeprom_data = NULL;
EC_ERR("Discarding EEPROM data, slave %i not ready.\n",
slave->ring_position);
continue;
}
// found pending EEPROM write operation. execute it!
EC_INFO("Writing EEPROM of slave %i...\n", slave->ring_position);
fsm->sii_offset = 0x0000;
ec_fsm_sii_write(&fsm->fsm_sii, slave, fsm->sii_offset,
slave->new_eeprom_data, EC_FSM_SII_NODE);
fsm->master_state = ec_fsm_master_write_eeprom;
fsm->master_state(fsm); // execute immediately
return;
}
}
// nothing to do. restart master state machine.
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
}
/*****************************************************************************/
/**
Master action: Get state of next slave.
*/
void ec_fsm_master_action_next_slave_state(ec_fsm_t *fsm
/**< finite state machine */)
{
ec_master_t *master = fsm->master;
ec_slave_t *slave = fsm->slave;
// is there another slave to query?
if (slave->list.next != &master->slaves) {
// process next slave
fsm->slave = list_entry(fsm->slave->list.next, ec_slave_t, list);
ec_datagram_nprd(&fsm->datagram, fsm->slave->station_address,
0x0130, 2);
ec_master_queue_datagram(master, &fsm->datagram);
fsm->master_state = ec_fsm_master_read_states;
return;
}
// all slave states read
// check, if a bus validation has to be done
if (fsm->master_validation) {
fsm->master_validation = 0;
list_for_each_entry(slave, &master->slaves, list) {
if (slave->online) continue;
// At least one slave is offline. validate!
EC_INFO("Validating bus.\n");
fsm->slave = list_entry(master->slaves.next, ec_slave_t, list);
fsm->master_state = ec_fsm_master_validate_vendor;
ec_fsm_sii_read(&fsm->fsm_sii, slave, 0x0008, EC_FSM_SII_POSITION);
ec_fsm_sii_exec(&fsm->fsm_sii); // execute immediately
return;
}
}
ec_fsm_master_action_process_states(fsm);
}
/*****************************************************************************/
/**
Master state: READ STATES.
Fetches the AL- and online state of a slave.
*/
void ec_fsm_master_read_states(ec_fsm_t *fsm /**< finite state machine */)
{
ec_slave_t *slave = fsm->slave;
ec_datagram_t *datagram = &fsm->datagram;
uint8_t new_state;
if (datagram->state != EC_DATAGRAM_RECEIVED) {
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
// did the slave not respond to its station address?
if (datagram->working_counter != 1) {
if (slave->online) {
slave->online = 0;
EC_INFO("Slave %i: offline.\n", slave->ring_position);
}
ec_fsm_master_action_next_slave_state(fsm);
return;
}
// slave responded
new_state = EC_READ_U8(datagram->data);
if (!slave->online) { // slave was offline before
char cur_state[EC_STATE_STRING_SIZE];
slave->online = 1;
slave->error_flag = 0; // clear error flag
slave->current_state = new_state;
ec_state_string(slave->current_state, cur_state);
EC_INFO("Slave %i: online (%s).\n", slave->ring_position, cur_state);
}
else if (new_state != slave->current_state) {
char old_state[EC_STATE_STRING_SIZE], cur_state[EC_STATE_STRING_SIZE];
ec_state_string(slave->current_state, old_state);
ec_state_string(new_state, cur_state);
EC_INFO("Slave %i: %s -> %s.\n",
slave->ring_position, old_state, cur_state);
slave->current_state = new_state;
}
ec_fsm_master_action_next_slave_state(fsm);
}
/*****************************************************************************/
/**
Master state: VALIDATE_VENDOR.
Validates the vendor ID of a slave.
*/
void ec_fsm_master_validate_vendor(ec_fsm_t *fsm /**< finite state machine */)
{
ec_slave_t *slave = fsm->slave;
if (ec_fsm_sii_exec(&fsm->fsm_sii)) return;
if (!ec_fsm_sii_success(&fsm->fsm_sii)) {
fsm->slave->error_flag = 1;
EC_ERR("Failed to validate vendor ID of slave %i.\n",
slave->ring_position);
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
if (EC_READ_U32(fsm->fsm_sii.value) != slave->sii_vendor_id) {
EC_ERR("Slave %i: invalid vendor ID!\n", slave->ring_position);
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
// vendor ID is ok. check product code.
fsm->master_state = ec_fsm_master_validate_product;
ec_fsm_sii_read(&fsm->fsm_sii, slave, 0x000A, EC_FSM_SII_POSITION);
ec_fsm_sii_exec(&fsm->fsm_sii); // execute immediately
}
/*****************************************************************************/
/**
Master action: ADDRESS.
Looks for slave, that have lost their configuration and writes
their station address, so that they can be reconfigured later.
*/
void ec_fsm_master_action_addresses(ec_fsm_t *fsm /**< finite state machine */)
{
ec_datagram_t *datagram = &fsm->datagram;
while (fsm->slave->online) {
if (fsm->slave->list.next == &fsm->master->slaves) { // last slave?
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
// check next slave
fsm->slave = list_entry(fsm->slave->list.next, ec_slave_t, list);
}
EC_INFO("Reinitializing slave %i.\n", fsm->slave->ring_position);
// write station address
ec_datagram_apwr(datagram, fsm->slave->ring_position, 0x0010, 2);
EC_WRITE_U16(datagram->data, fsm->slave->station_address);
ec_master_queue_datagram(fsm->master, datagram);
fsm->master_state = ec_fsm_master_rewrite_addresses;
}
/*****************************************************************************/
/**
Master state: VALIDATE_PRODUCT.
Validates the product ID of a slave.
*/
void ec_fsm_master_validate_product(ec_fsm_t *fsm /**< finite state machine */)
{
ec_slave_t *slave = fsm->slave;
if (ec_fsm_sii_exec(&fsm->fsm_sii)) return;
if (!ec_fsm_sii_success(&fsm->fsm_sii)) {
fsm->slave->error_flag = 1;
EC_ERR("Failed to validate product code of slave %i.\n",
slave->ring_position);
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
if (EC_READ_U32(fsm->fsm_sii.value) != slave->sii_product_code) {
EC_ERR("Slave %i: invalid product code!\n", slave->ring_position);
EC_ERR("expected 0x%08X, got 0x%08X.\n", slave->sii_product_code,
EC_READ_U32(fsm->fsm_sii.value));
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
// have all states been validated?
if (slave->list.next == &fsm->master->slaves) {
fsm->slave = list_entry(fsm->master->slaves.next, ec_slave_t, list);
// start writing addresses to offline slaves
ec_fsm_master_action_addresses(fsm);
return;
}
// validate next slave
fsm->slave = list_entry(fsm->slave->list.next, ec_slave_t, list);
fsm->master_state = ec_fsm_master_validate_vendor;
ec_fsm_sii_read(&fsm->fsm_sii, slave, 0x0008, EC_FSM_SII_POSITION);
ec_fsm_sii_exec(&fsm->fsm_sii); // execute immediately
}
/*****************************************************************************/
/**
Master state: REWRITE ADDRESS.
Checks, if the new station address has been written to the slave.
*/
void ec_fsm_master_rewrite_addresses(ec_fsm_t *fsm
/**< finite state machine */
)
{
ec_slave_t *slave = fsm->slave;
ec_datagram_t *datagram = &fsm->datagram;
if (datagram->state != EC_DATAGRAM_RECEIVED
|| datagram->working_counter != 1) {
EC_ERR("Failed to write station address on slave %i.\n",
slave->ring_position);
}
if (fsm->slave->list.next == &fsm->master->slaves) { // last slave?
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
// check next slave
fsm->slave = list_entry(fsm->slave->list.next, ec_slave_t, list);
// Write new station address to slave
ec_fsm_master_action_addresses(fsm);
}
/*****************************************************************************/
/**
Master state: SCAN SLAVES.
Executes the sub-statemachine for the scanning of a slave.
*/
void ec_fsm_master_scan_slaves(ec_fsm_t *fsm /**< finite state machine */)
{
ec_master_t *master = fsm->master;
ec_slave_t *slave = fsm->slave;
fsm->slave_state(fsm); // execute slave state machine
if (fsm->slave_state != ec_fsm_end
&& fsm->slave_state != ec_fsm_error) return;
// another slave to fetch?
if (slave->list.next != &master->slaves) {
fsm->slave = list_entry(fsm->slave->list.next, ec_slave_t, list);
fsm->slave_state = ec_fsm_slavescan_start;
fsm->slave_state(fsm); // execute immediately
return;
}
EC_INFO("Bus scanning completed.\n");
ec_master_calc_addressing(master);
// set initial states of all slaves to PREOP to make mailbox
// communication possible
list_for_each_entry(slave, &master->slaves, list) {
slave->requested_state = EC_SLAVE_STATE_PREOP;
}
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
}
/*****************************************************************************/
/**
Master state: CONFIGURE SLAVES.
Starts configuring a slave.
*/
void ec_fsm_master_configure_slave(ec_fsm_t *fsm
/**< finite state machine */
)
{
fsm->slave_state(fsm); // execute slave's state machine
if (fsm->slave_state != ec_fsm_end
&& fsm->slave_state != ec_fsm_error) return;
ec_fsm_master_action_process_states(fsm);
}
/*****************************************************************************/
/**
Master state: WRITE EEPROM.
*/
void ec_fsm_master_write_eeprom(ec_fsm_t *fsm /**< finite state machine */)
{
ec_slave_t *slave = fsm->slave;
if (ec_fsm_sii_exec(&fsm->fsm_sii)) return;
if (!ec_fsm_sii_success(&fsm->fsm_sii)) {
fsm->slave->error_flag = 1;
EC_ERR("Failed to write EEPROM contents to slave %i.\n",
slave->ring_position);
kfree(slave->new_eeprom_data);
slave->new_eeprom_data = NULL;
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
fsm->sii_offset++;
if (fsm->sii_offset < slave->new_eeprom_size) {
ec_fsm_sii_write(&fsm->fsm_sii, slave, fsm->sii_offset,
slave->new_eeprom_data + fsm->sii_offset,
EC_FSM_SII_NODE);
ec_fsm_sii_exec(&fsm->fsm_sii); // execute immediately
return;
}
// finished writing EEPROM
EC_INFO("Finished writing EEPROM of slave %i.\n", slave->ring_position);
kfree(slave->new_eeprom_data);
slave->new_eeprom_data = NULL;
// TODO: Evaluate new EEPROM contents!
// restart master state machine.
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
}
/*****************************************************************************/
/**
Master state: SDODICT.
*/
void ec_fsm_master_sdodict(ec_fsm_t *fsm /**< finite state machine */)
{
ec_slave_t *slave = fsm->slave;
ec_master_t *master = fsm->master;
if (ec_fsm_coe_exec(&fsm->fsm_coe)) return;
if (!ec_fsm_coe_success(&fsm->fsm_coe)) {
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
// SDO dictionary fetching finished
if (master->debug_level) {
unsigned int sdo_count, entry_count;
ec_slave_sdo_dict_info(slave, &sdo_count, &entry_count);
EC_DBG("Fetched %i SDOs and %i entries from slave %i.\n",
sdo_count, entry_count, slave->ring_position);
}
// restart master state machine.
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
}
/*****************************************************************************/
/**
Master state: SDO REQUEST.
*/
void ec_fsm_master_sdo_request(ec_fsm_t *fsm /**< finite state machine */)
{
ec_master_t *master = fsm->master;
ec_sdo_request_t *request = fsm->sdo_request;
if (ec_fsm_coe_exec(&fsm->fsm_coe)) return;
if (!ec_fsm_coe_success(&fsm->fsm_coe)) {
request->return_code = -1;
master->sdo_seq_master++;
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
return;
}
// SDO dictionary fetching finished
request->return_code = 1;
master->sdo_seq_master++;
// restart master state machine.
fsm->master_state = ec_fsm_master_start;
fsm->master_state(fsm); // execute immediately
}
/******************************************************************************
* slave scan state machine
*****************************************************************************/
/**
Slave scan state: START.
First state of the slave state machine. Writes the station address to the
slave, according to its ring position.
*/
void ec_fsm_slavescan_start(ec_fsm_t *fsm /**< finite state machine */)
{
ec_datagram_t *datagram = &fsm->datagram;
// write station address
ec_datagram_apwr(datagram, fsm->slave->ring_position, 0x0010, 2);
EC_WRITE_U16(datagram->data, fsm->slave->station_address);
ec_master_queue_datagram(fsm->master, datagram);
fsm->slave_state = ec_fsm_slavescan_address;
}
/*****************************************************************************/
/**
Slave scan state: ADDRESS.
*/
void ec_fsm_slavescan_address(ec_fsm_t *fsm /**< finite state machine */)
{
ec_datagram_t *datagram = &fsm->datagram;
if (datagram->state != EC_DATAGRAM_RECEIVED
|| datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
EC_ERR("Failed to write station address of slave %i.\n",
fsm->slave->ring_position);
return;
}
// Read AL state
ec_datagram_nprd(datagram, fsm->slave->station_address, 0x0130, 2);
ec_master_queue_datagram(fsm->master, datagram);
fsm->slave_state = ec_fsm_slavescan_state;
}
/*****************************************************************************/
/**
Slave scan state: STATE.
*/
void ec_fsm_slavescan_state(ec_fsm_t *fsm /**< finite state machine */)
{
ec_datagram_t *datagram = &fsm->datagram;
ec_slave_t *slave = fsm->slave;
if (datagram->state != EC_DATAGRAM_RECEIVED
|| datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
EC_ERR("Failed to read AL state of slave %i.\n",
fsm->slave->ring_position);
return;
}
slave->current_state = EC_READ_U8(datagram->data);
if (slave->current_state & EC_SLAVE_STATE_ACK_ERR) {
EC_WARN("Slave %i has state error bit set (0x%02X)!\n",
slave->ring_position, slave->current_state);
}
// read base data
ec_datagram_nprd(datagram, fsm->slave->station_address, 0x0000, 6);
ec_master_queue_datagram(fsm->master, datagram);
fsm->slave_state = ec_fsm_slavescan_base;
}
/*****************************************************************************/
/**
Slave scan state: BASE.
*/
void ec_fsm_slavescan_base(ec_fsm_t *fsm /**< finite state machine */)
{
ec_datagram_t *datagram = &fsm->datagram;
ec_slave_t *slave = fsm->slave;
if (datagram->state != EC_DATAGRAM_RECEIVED
|| datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
EC_ERR("Failed to read base data of slave %i.\n",
slave->ring_position);
return;
}
slave->base_type = EC_READ_U8 (datagram->data);
slave->base_revision = EC_READ_U8 (datagram->data + 1);
slave->base_build = EC_READ_U16(datagram->data + 2);
slave->base_fmmu_count = EC_READ_U8 (datagram->data + 4);
slave->base_sync_count = EC_READ_U8 (datagram->data + 5);
if (slave->base_fmmu_count > EC_MAX_FMMUS)
slave->base_fmmu_count = EC_MAX_FMMUS;
// read data link status
ec_datagram_nprd(datagram, slave->station_address, 0x0110, 2);
ec_master_queue_datagram(slave->master, datagram);
fsm->slave_state = ec_fsm_slavescan_datalink;
}
/*****************************************************************************/
/**
Slave scan state: DATALINK.
*/
void ec_fsm_slavescan_datalink(ec_fsm_t *fsm /**< finite state machine */)
{
ec_datagram_t *datagram = &fsm->datagram;
ec_slave_t *slave = fsm->slave;
uint16_t dl_status;
unsigned int i;
if (datagram->state != EC_DATAGRAM_RECEIVED
|| datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
EC_ERR("Failed to read DL status of slave %i.\n",
slave->ring_position);
return;
}
dl_status = EC_READ_U16(datagram->data);
for (i = 0; i < 4; i++) {
slave->dl_link[i] = dl_status & (1 << (4 + i)) ? 1 : 0;
slave->dl_loop[i] = dl_status & (1 << (8 + i * 2)) ? 1 : 0;
slave->dl_signal[i] = dl_status & (1 << (9 + i * 2)) ? 1 : 0;
}
// Start fetching EEPROM size
fsm->sii_offset = 0x0040; // first category header
ec_fsm_sii_read(&fsm->fsm_sii, slave, fsm->sii_offset, EC_FSM_SII_NODE);
fsm->slave_state = ec_fsm_slavescan_eeprom_size;
fsm->slave_state(fsm); // execute state immediately
}
/*****************************************************************************/
/**
Slave scan state: EEPROM SIZE.
*/
void ec_fsm_slavescan_eeprom_size(ec_fsm_t *fsm /**< finite state machine */)
{
ec_slave_t *slave = fsm->slave;
uint16_t cat_type, cat_size;
if (ec_fsm_sii_exec(&fsm->fsm_sii)) return;
if (!ec_fsm_sii_success(&fsm->fsm_sii)) {
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
EC_ERR("Failed to read EEPROM size of slave %i.\n",
slave->ring_position);
return;
}
cat_type = EC_READ_U16(fsm->fsm_sii.value);
cat_size = EC_READ_U16(fsm->fsm_sii.value + 2);
if (cat_type != 0xFFFF) { // not the last category
fsm->sii_offset += cat_size + 2;
ec_fsm_sii_read(&fsm->fsm_sii, slave, fsm->sii_offset,
EC_FSM_SII_NODE);
ec_fsm_sii_exec(&fsm->fsm_sii); // execute state immediately
return;
}
slave->eeprom_size = (fsm->sii_offset + 1) * 2;
if (slave->eeprom_data) {
EC_INFO("Freeing old EEPROM data on slave %i...\n",
slave->ring_position);
kfree(slave->eeprom_data);
}
if (!(slave->eeprom_data =
(uint8_t *) kmalloc(slave->eeprom_size, GFP_ATOMIC))) {
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
EC_ERR("Failed to allocate EEPROM data on slave %i.\n",
slave->ring_position);
return;
}
// Start fetching EEPROM contents
fsm->slave_state = ec_fsm_slavescan_eeprom_data;
fsm->sii_offset = 0x0000;
ec_fsm_sii_read(&fsm->fsm_sii, slave, fsm->sii_offset, EC_FSM_SII_NODE);
ec_fsm_sii_exec(&fsm->fsm_sii); // execute state immediately
}
/*****************************************************************************/
/**
Slave scan state: EEPROM DATA.
*/
void ec_fsm_slavescan_eeprom_data(ec_fsm_t *fsm /**< finite state machine */)
{
ec_slave_t *slave = fsm->slave;
uint16_t *cat_word, cat_type, cat_size;
if (ec_fsm_sii_exec(&fsm->fsm_sii)) return;
if (!ec_fsm_sii_success(&fsm->fsm_sii)) {
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
EC_ERR("Failed to fetch EEPROM contents of slave %i.\n",
slave->ring_position);
return;
}
// 2 words fetched
if (fsm->sii_offset + 2 <= slave->eeprom_size / 2) { // 2 words fit
memcpy(slave->eeprom_data + fsm->sii_offset * 2,
fsm->fsm_sii.value, 4);
}
else { // copy the last word
memcpy(slave->eeprom_data + fsm->sii_offset * 2,
fsm->fsm_sii.value, 2);
}
if (fsm->sii_offset + 2 < slave->eeprom_size / 2) {
// fetch the next 2 words
fsm->sii_offset += 2;
ec_fsm_sii_read(&fsm->fsm_sii, slave, fsm->sii_offset,
EC_FSM_SII_NODE);
ec_fsm_sii_exec(&fsm->fsm_sii); // execute state immediately
return;
}
// Evaluate EEPROM contents
slave->sii_alias =
EC_READ_U16(slave->eeprom_data + 2 * 0x0004);
slave->sii_vendor_id =
EC_READ_U32(slave->eeprom_data + 2 * 0x0008);
slave->sii_product_code =
EC_READ_U32(slave->eeprom_data + 2 * 0x000A);
slave->sii_revision_number =
EC_READ_U32(slave->eeprom_data + 2 * 0x000C);
slave->sii_serial_number =
EC_READ_U32(slave->eeprom_data + 2 * 0x000E);
slave->sii_rx_mailbox_offset =
EC_READ_U16(slave->eeprom_data + 2 * 0x0018);
slave->sii_rx_mailbox_size =
EC_READ_U16(slave->eeprom_data + 2 * 0x0019);
slave->sii_tx_mailbox_offset =
EC_READ_U16(slave->eeprom_data + 2 * 0x001A);
slave->sii_tx_mailbox_size =
EC_READ_U16(slave->eeprom_data + 2 * 0x001B);
slave->sii_mailbox_protocols =
EC_READ_U16(slave->eeprom_data + 2 * 0x001C);
// evaluate category data
cat_word = (uint16_t *) slave->eeprom_data + 0x0040;
while (EC_READ_U16(cat_word) != 0xFFFF) {
cat_type = EC_READ_U16(cat_word) & 0x7FFF;
cat_size = EC_READ_U16(cat_word + 1);
switch (cat_type) {
case 0x000A:
if (ec_slave_fetch_strings(slave, (uint8_t *) (cat_word + 2)))
goto end;
break;
case 0x001E:
ec_slave_fetch_general(slave, (uint8_t *) (cat_word + 2));
break;
case 0x0028:
break;
case 0x0029:
if (ec_slave_fetch_sync(slave, (uint8_t *) (cat_word + 2),
cat_size))
goto end;
break;
case 0x0032:
if (ec_slave_fetch_pdo(slave, (uint8_t *) (cat_word + 2),
cat_size, EC_TX_PDO))
goto end;
break;
case 0x0033:
if (ec_slave_fetch_pdo(slave, (uint8_t *) (cat_word + 2),
cat_size, EC_RX_PDO))
goto end;
break;
default:
EC_WARN("Unknown category type 0x%04X in slave %i.\n",
cat_type, slave->ring_position);
}
cat_word += cat_size + 2;
}
fsm->slave_state = ec_fsm_end;
return;
end:
EC_ERR("Failed to analyze category data.\n");
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
}
/******************************************************************************
* slave configuration state machine
*****************************************************************************/
/**
Slave configuration state: INIT.
*/
void ec_fsm_slaveconf_init(ec_fsm_t *fsm /**< finite state machine */)
{
ec_master_t *master = fsm->master;
ec_slave_t *slave = fsm->slave;
ec_datagram_t *datagram = &fsm->datagram;
const ec_sii_sync_t *sync;
ec_sii_sync_t mbox_sync;
if (ec_fsm_change_exec(&fsm->fsm_change)) return;
if (!ec_fsm_change_success(&fsm->fsm_change)) {
slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
return;
}
slave->configured = 1;
if (master->debug_level) {
EC_DBG("Slave %i is now in INIT.\n", slave->ring_position);
}
// slave is now in INIT
if (slave->current_state == slave->requested_state) {
fsm->slave_state = ec_fsm_end; // successful
if (master->debug_level) {
EC_DBG("Finished configuration of slave %i.\n",
slave->ring_position);
}
return;
}
// check and reset CRC fault counters
//ec_slave_check_crc(slave);
// TODO: Implement state machine for CRC checking.
if (!slave->base_sync_count) { // no sync managers
fsm->slave_state = ec_fsm_slaveconf_preop;
ec_fsm_change(&fsm->fsm_change, slave, EC_SLAVE_STATE_PREOP);
ec_fsm_change_exec(&fsm->fsm_change); // execute immediately
return;
}
if (master->debug_level) {
EC_DBG("Configuring sync managers of slave %i.\n",
slave->ring_position);
}
// configure sync managers
ec_datagram_npwr(datagram, slave->station_address, 0x0800,
EC_SYNC_SIZE * slave->base_sync_count);
memset(datagram->data, 0x00, EC_SYNC_SIZE * slave->base_sync_count);
if (list_empty(&slave->sii_syncs)) {
if (slave->sii_rx_mailbox_offset && slave->sii_tx_mailbox_offset) {
if (slave->master->debug_level)
EC_DBG("Guessing sync manager settings for slave %i.\n",
slave->ring_position);
mbox_sync.index = 0;
mbox_sync.physical_start_address = slave->sii_tx_mailbox_offset;
mbox_sync.length = slave->sii_tx_mailbox_size;
mbox_sync.control_register = 0x26;
mbox_sync.enable = 0x01;
mbox_sync.est_length = 0;
ec_sync_config(&mbox_sync, slave,
datagram->data + EC_SYNC_SIZE * mbox_sync.index);
mbox_sync.index = 1;
mbox_sync.physical_start_address = slave->sii_rx_mailbox_offset;
mbox_sync.length = slave->sii_rx_mailbox_size;
mbox_sync.control_register = 0x22;
mbox_sync.enable = 0x01;
mbox_sync.est_length = 0;
ec_sync_config(&mbox_sync, slave,
datagram->data + EC_SYNC_SIZE * mbox_sync.index);
}
}
else {
list_for_each_entry(sync, &slave->sii_syncs, list) {
if (sync->index >= slave->base_sync_count) {
EC_ERR("Invalid sync manager configuration found!");
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
return;
}
ec_sync_config(sync, slave,
datagram->data + EC_SYNC_SIZE * sync->index);
}
}
ec_master_queue_datagram(fsm->master, datagram);
fsm->slave_state = ec_fsm_slaveconf_sync;
}
/*****************************************************************************/
/**
Slave configuration state: SYNC.
*/
void ec_fsm_slaveconf_sync(ec_fsm_t *fsm /**< finite state machine */)
{
ec_datagram_t *datagram = &fsm->datagram;
ec_slave_t *slave = fsm->slave;
if (datagram->state != EC_DATAGRAM_RECEIVED
|| datagram->working_counter != 1) {
slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
EC_ERR("Failed to set sync managers on slave %i.\n",
slave->ring_position);
return;
}
fsm->slave_state = ec_fsm_slaveconf_preop;
ec_fsm_change(&fsm->fsm_change, slave, EC_SLAVE_STATE_PREOP);
ec_fsm_change_exec(&fsm->fsm_change); // execute immediately
}
/*****************************************************************************/
/**
Slave configuration state: PREOP.
*/
void ec_fsm_slaveconf_preop(ec_fsm_t *fsm /**< finite state machine */)
{
ec_slave_t *slave = fsm->slave;
ec_master_t *master = fsm->master;
ec_datagram_t *datagram = &fsm->datagram;
unsigned int j;
if (ec_fsm_change_exec(&fsm->fsm_change)) return;
if (!ec_fsm_change_success(&fsm->fsm_change)) {
slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
return;
}
// slave is now in PREOP
slave->jiffies_preop = fsm->datagram.jiffies_received;
if (master->debug_level) {
EC_DBG("Slave %i is now in PREOP.\n", slave->ring_position);
}
if (slave->current_state == slave->requested_state) {
fsm->slave_state = ec_fsm_end; // successful
if (master->debug_level) {
EC_DBG("Finished configuration of slave %i.\n",
slave->ring_position);
}
return;
}
if (!slave->base_fmmu_count) { // skip FMMU configuration
if (list_empty(&slave->sdo_confs)) { // skip SDO configuration
fsm->slave_state = ec_fsm_slaveconf_saveop;
ec_fsm_change(&fsm->fsm_change, slave, EC_SLAVE_STATE_SAVEOP);
ec_fsm_change_exec(&fsm->fsm_change); // execute immediately
return;
}
// start SDO configuration
fsm->slave_state = ec_fsm_slaveconf_sdoconf;
fsm->sdodata = list_entry(slave->sdo_confs.next, ec_sdo_data_t, list);
ec_fsm_coe_download(&fsm->fsm_coe, slave, fsm->sdodata);
ec_fsm_coe_exec(&fsm->fsm_coe); // execute immediately
return;
}
// configure FMMUs
ec_datagram_npwr(datagram, slave->station_address,
0x0600, EC_FMMU_SIZE * slave->base_fmmu_count);
memset(datagram->data, 0x00, EC_FMMU_SIZE * slave->base_fmmu_count);
for (j = 0; j < slave->fmmu_count; j++) {
ec_fmmu_config(&slave->fmmus[j], slave,
datagram->data + EC_FMMU_SIZE * j);
}
ec_master_queue_datagram(master, datagram);
fsm->slave_state = ec_fsm_slaveconf_fmmu;
}
/*****************************************************************************/
/**
Slave configuration state: FMMU.
*/
void ec_fsm_slaveconf_fmmu(ec_fsm_t *fsm /**< finite state machine */)
{
ec_datagram_t *datagram = &fsm->datagram;
ec_slave_t *slave = fsm->slave;
if (datagram->state != EC_DATAGRAM_RECEIVED
|| datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
EC_ERR("Failed to set FMMUs on slave %i.\n",
fsm->slave->ring_position);
return;
}
// No CoE configuration to be applied? Jump to SAVEOP state.
if (list_empty(&slave->sdo_confs)) { // skip SDO configuration
// set state to SAVEOP
fsm->slave_state = ec_fsm_slaveconf_saveop;
ec_fsm_change(&fsm->fsm_change, slave, EC_SLAVE_STATE_SAVEOP);
ec_fsm_change_exec(&fsm->fsm_change); // execute immediately
return;
}
// start SDO configuration
fsm->slave_state = ec_fsm_slaveconf_sdoconf;
fsm->sdodata = list_entry(slave->sdo_confs.next, ec_sdo_data_t, list);
ec_fsm_coe_download(&fsm->fsm_coe, slave, fsm->sdodata);
ec_fsm_coe_exec(&fsm->fsm_coe); // execute immediately
}
/*****************************************************************************/
/**
Slave configuration state: SDOCONF.
*/
void ec_fsm_slaveconf_sdoconf(ec_fsm_t *fsm /**< finite state machine */)
{
if (ec_fsm_coe_exec(&fsm->fsm_coe)) return;
if (!ec_fsm_coe_success(&fsm->fsm_coe)) {
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
return;
}
// Another SDO to configure?
if (fsm->sdodata->list.next != &fsm->slave->sdo_confs) {
fsm->sdodata = list_entry(fsm->sdodata->list.next,
ec_sdo_data_t, list);
ec_fsm_coe_download(&fsm->fsm_coe, fsm->slave, fsm->sdodata);
ec_fsm_coe_exec(&fsm->fsm_coe); // execute immediately
return;
}
// All SDOs are now configured.
// set state to SAVEOP
fsm->slave_state = ec_fsm_slaveconf_saveop;
ec_fsm_change(&fsm->fsm_change, fsm->slave, EC_SLAVE_STATE_SAVEOP);
ec_fsm_change_exec(&fsm->fsm_change); // execute immediately
}
/*****************************************************************************/
/**
Slave configuration state: SAVEOP.
*/
void ec_fsm_slaveconf_saveop(ec_fsm_t *fsm /**< finite state machine */)
{
ec_master_t *master = fsm->master;
ec_slave_t *slave = fsm->slave;
if (ec_fsm_change_exec(&fsm->fsm_change)) return;
if (!ec_fsm_change_success(&fsm->fsm_change)) {
fsm->slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
return;
}
// slave is now in SAVEOP
if (master->debug_level) {
EC_DBG("Slave %i is now in SAVEOP.\n", slave->ring_position);
}
if (fsm->slave->current_state == fsm->slave->requested_state) {
fsm->slave_state = ec_fsm_end; // successful
if (master->debug_level) {
EC_DBG("Finished configuration of slave %i.\n",
slave->ring_position);
}
return;
}
// set state to OP
fsm->slave_state = ec_fsm_slaveconf_op;
ec_fsm_change(&fsm->fsm_change, slave, EC_SLAVE_STATE_OP);
ec_fsm_change_exec(&fsm->fsm_change); // execute immediately
}
/*****************************************************************************/
/**
Slave configuration state: OP
*/
void ec_fsm_slaveconf_op(ec_fsm_t *fsm /**< finite state machine */)
{
ec_master_t *master = fsm->master;
ec_slave_t *slave = fsm->slave;
if (ec_fsm_change_exec(&fsm->fsm_change)) return;
if (!ec_fsm_change_success(&fsm->fsm_change)) {
slave->error_flag = 1;
fsm->slave_state = ec_fsm_error;
return;
}
// slave is now in OP
if (master->debug_level) {
EC_DBG("Slave %i is now in OP.\n", slave->ring_position);
EC_DBG("Finished configuration of slave %i.\n", slave->ring_position);
}
fsm->slave_state = ec_fsm_end; // successful
}
/******************************************************************************
* Common state functions
*****************************************************************************/
/**
State: ERROR.
*/
void ec_fsm_error(ec_fsm_t *fsm /**< finite state machine */)
{
}
/*****************************************************************************/
/**
State: END.
*/
void ec_fsm_end(ec_fsm_t *fsm /**< finite state machine */)
{
}
/*****************************************************************************/