Layed out device ID functionality in own files.
/******************************************************************************
*
* $Id$
*
* 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 slave state machines.
*/
/*****************************************************************************/
#include "globals.h"
#include "master.h"
#include "mailbox.h"
#include "fsm_slave.h"
/*****************************************************************************/
void ec_fsm_slave_scan_state_start(ec_fsm_slave_t *);
void ec_fsm_slave_scan_state_address(ec_fsm_slave_t *);
void ec_fsm_slave_scan_state_state(ec_fsm_slave_t *);
void ec_fsm_slave_scan_state_base(ec_fsm_slave_t *);
void ec_fsm_slave_scan_state_datalink(ec_fsm_slave_t *);
void ec_fsm_slave_scan_state_eeprom_size(ec_fsm_slave_t *);
void ec_fsm_slave_scan_state_eeprom_data(ec_fsm_slave_t *);
void ec_fsm_slave_conf_state_start(ec_fsm_slave_t *);
void ec_fsm_slave_conf_state_init(ec_fsm_slave_t *);
void ec_fsm_slave_conf_state_clear_fmmus(ec_fsm_slave_t *);
void ec_fsm_slave_conf_state_sync(ec_fsm_slave_t *);
void ec_fsm_slave_conf_state_preop(ec_fsm_slave_t *);
void ec_fsm_slave_conf_state_sync2(ec_fsm_slave_t *);
void ec_fsm_slave_conf_state_fmmu(ec_fsm_slave_t *);
void ec_fsm_slave_conf_state_sdoconf(ec_fsm_slave_t *);
void ec_fsm_slave_conf_state_saveop(ec_fsm_slave_t *);
void ec_fsm_slave_conf_state_op(ec_fsm_slave_t *);
void ec_fsm_slave_conf_enter_sync(ec_fsm_slave_t *);
void ec_fsm_slave_conf_enter_preop(ec_fsm_slave_t *);
void ec_fsm_slave_conf_enter_sync2(ec_fsm_slave_t *);
void ec_fsm_slave_conf_enter_fmmu(ec_fsm_slave_t *);
void ec_fsm_slave_conf_enter_sdoconf(ec_fsm_slave_t *);
void ec_fsm_slave_conf_enter_saveop(ec_fsm_slave_t *);
void ec_fsm_slave_state_end(ec_fsm_slave_t *);
void ec_fsm_slave_state_error(ec_fsm_slave_t *);
/*****************************************************************************/
/**
Constructor.
*/
void ec_fsm_slave_init(ec_fsm_slave_t *fsm, /**< slave state machine */
ec_datagram_t *datagram /**< datagram structure to use */
)
{
fsm->datagram = datagram;
// 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);
}
/*****************************************************************************/
/**
Destructor.
*/
void ec_fsm_slave_clear(ec_fsm_slave_t *fsm /**< slave 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);
}
/*****************************************************************************/
/**
* Start slave scan state machine.
*/
void ec_fsm_slave_start_scan(ec_fsm_slave_t *fsm, /**< slave state machine */
ec_slave_t *slave /**< slave to configure */
)
{
fsm->slave = slave;
fsm->state = ec_fsm_slave_scan_state_start;
}
/*****************************************************************************/
/**
* Start slave configuration state machine.
*/
void ec_fsm_slave_start_conf(ec_fsm_slave_t *fsm, /**< slave state machine */
ec_slave_t *slave /**< slave to configure */
)
{
fsm->slave = slave;
fsm->state = ec_fsm_slave_conf_state_start;
}
/*****************************************************************************/
/**
\return false, if state machine has terminated
*/
int ec_fsm_slave_running(const ec_fsm_slave_t *fsm /**< slave state machine */)
{
return fsm->state != ec_fsm_slave_state_end
&& fsm->state != ec_fsm_slave_state_error;
}
/*****************************************************************************/
/**
Executes the current state of the state machine.
If the state machine's datagram is not sent or received yet, the execution
of the state machine is delayed to the next cycle.
\return false, if state machine has terminated
*/
int ec_fsm_slave_exec(ec_fsm_slave_t *fsm /**< slave state machine */)
{
if (fsm->datagram->state == EC_DATAGRAM_SENT
|| fsm->datagram->state == EC_DATAGRAM_QUEUED) {
// datagram was not sent or received yet.
return ec_fsm_slave_running(fsm);
}
fsm->state(fsm);
return ec_fsm_slave_running(fsm);
}
/*****************************************************************************/
/**
\return true, if the state machine terminated gracefully
*/
int ec_fsm_slave_success(const ec_fsm_slave_t *fsm /**< slave state machine */)
{
return fsm->state == ec_fsm_slave_state_end;
}
/******************************************************************************
* 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_slave_scan_state_start(ec_fsm_slave_t *fsm /**< slave state machine */)
{
// write station address
ec_datagram_apwr(fsm->datagram, fsm->slave->ring_position, 0x0010, 2);
EC_WRITE_U16(fsm->datagram->data, fsm->slave->station_address);
ec_master_queue_datagram(fsm->slave->master, fsm->datagram);
fsm->retries = EC_FSM_RETRIES;
fsm->state = ec_fsm_slave_scan_state_address;
}
/*****************************************************************************/
/**
Slave scan state: ADDRESS.
*/
void ec_fsm_slave_scan_state_address(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_datagram_t *datagram = fsm->datagram;
if (datagram->state == EC_DATAGRAM_TIMED_OUT && fsm->retries--) {
ec_master_queue_datagram(fsm->slave->master, fsm->datagram);
return;
}
if (datagram->state != EC_DATAGRAM_RECEIVED) {
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to receive station address datagram for slave %i.\n",
fsm->slave->ring_position);
return;
}
if (datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to write station address - slave %i did not respond.\n",
fsm->slave->ring_position);
return;
}
// Read AL state
ec_datagram_nprd(datagram, fsm->slave->station_address, 0x0130, 2);
ec_master_queue_datagram(fsm->slave->master, datagram);
fsm->retries = EC_FSM_RETRIES;
fsm->state = ec_fsm_slave_scan_state_state;
}
/*****************************************************************************/
/**
Slave scan state: STATE.
*/
void ec_fsm_slave_scan_state_state(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_datagram_t *datagram = fsm->datagram;
ec_slave_t *slave = fsm->slave;
if (datagram->state == EC_DATAGRAM_TIMED_OUT && fsm->retries--) {
ec_master_queue_datagram(fsm->slave->master, datagram);
return;
}
if (datagram->state != EC_DATAGRAM_RECEIVED) {
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to receive AL state datagram from slave %i.\n",
fsm->slave->ring_position);
return;
}
if (datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to read AL state - slave %i did not respond.\n",
fsm->slave->ring_position);
return;
}
slave->current_state = EC_READ_U8(datagram->data);
if (slave->current_state & EC_SLAVE_STATE_ACK_ERR) {
char state_str[EC_STATE_STRING_SIZE];
ec_state_string(slave->current_state, state_str);
EC_WARN("Slave %i has state error bit set (%s)!\n",
slave->ring_position, state_str);
}
// read base data
ec_datagram_nprd(datagram, fsm->slave->station_address, 0x0000, 6);
ec_master_queue_datagram(fsm->slave->master, datagram);
fsm->retries = EC_FSM_RETRIES;
fsm->state = ec_fsm_slave_scan_state_base;
}
/*****************************************************************************/
/**
Slave scan state: BASE.
*/
void ec_fsm_slave_scan_state_base(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_datagram_t *datagram = fsm->datagram;
ec_slave_t *slave = fsm->slave;
if (datagram->state == EC_DATAGRAM_TIMED_OUT && fsm->retries--) {
ec_master_queue_datagram(fsm->slave->master, datagram);
return;
}
if (datagram->state != EC_DATAGRAM_RECEIVED) {
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to receive base data datagram for slave %i.\n",
slave->ring_position);
return;
}
if (datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to read base data - slave %i did not respond.\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->retries = EC_FSM_RETRIES;
fsm->state = ec_fsm_slave_scan_state_datalink;
}
/*****************************************************************************/
/**
Slave scan state: DATALINK.
*/
void ec_fsm_slave_scan_state_datalink(ec_fsm_slave_t *fsm /**< slave 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_TIMED_OUT && fsm->retries--) {
ec_master_queue_datagram(fsm->slave->master, datagram);
return;
}
if (datagram->state != EC_DATAGRAM_RECEIVED) {
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to receive DL status datagram from slave %i.\n",
slave->ring_position);
return;
}
if (datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to read DL status - slave %i did not respond.\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->state = ec_fsm_slave_scan_state_eeprom_size;
fsm->state(fsm); // execute state immediately
}
/*****************************************************************************/
/**
Slave scan state: EEPROM SIZE.
*/
void ec_fsm_slave_scan_state_eeprom_size(ec_fsm_slave_t *fsm /**< slave 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->state = ec_fsm_slave_state_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->state = ec_fsm_slave_state_error;
EC_ERR("Failed to allocate EEPROM data on slave %i.\n",
slave->ring_position);
return;
}
// Start fetching EEPROM contents
fsm->state = ec_fsm_slave_scan_state_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_slave_scan_state_eeprom_data(ec_fsm_slave_t *fsm /**< slave 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->state = ec_fsm_slave_state_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:
if (fsm->slave->master->debug_level)
EC_WARN("Unknown category type 0x%04X in slave %i.\n",
cat_type, slave->ring_position);
}
cat_word += cat_size + 2;
}
fsm->state = ec_fsm_slave_state_end;
return;
end:
EC_ERR("Failed to analyze category data.\n");
fsm->slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_error;
}
/******************************************************************************
* slave configuration state machine
*****************************************************************************/
/**
Slave configuration state: START.
*/
void ec_fsm_slave_conf_state_start(ec_fsm_slave_t *fsm /**< slave state machine */)
{
if (fsm->slave->master->debug_level) {
EC_DBG("Configuring slave %i...\n", fsm->slave->ring_position);
}
ec_fsm_change_start(&fsm->fsm_change, fsm->slave, EC_SLAVE_STATE_INIT);
ec_fsm_change_exec(&fsm->fsm_change);
fsm->state = ec_fsm_slave_conf_state_init;
}
/*****************************************************************************/
/**
Slave configuration state: INIT.
*/
void ec_fsm_slave_conf_state_init(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_master_t *master = fsm->slave->master;
ec_slave_t *slave = fsm->slave;
ec_datagram_t *datagram = fsm->datagram;
if (ec_fsm_change_exec(&fsm->fsm_change)) return;
if (!ec_fsm_change_success(&fsm->fsm_change)) {
slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_error;
return;
}
slave->self_configured = 1;
if (master->debug_level) {
EC_DBG("Slave %i is now in INIT.\n", slave->ring_position);
}
// check and reset CRC fault counters
//ec_slave_check_crc(slave);
// TODO: Implement state machine for CRC checking.
if (!slave->base_fmmu_count) { // skip FMMU configuration
ec_fsm_slave_conf_enter_sync(fsm);
return;
}
if (master->debug_level)
EC_DBG("Clearing FMMU configurations of slave %i...\n",
slave->ring_position);
// clear FMMU configurations
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);
ec_master_queue_datagram(master, datagram);
fsm->retries = EC_FSM_RETRIES;
fsm->state = ec_fsm_slave_conf_state_clear_fmmus;
}
/*****************************************************************************/
/**
Slave configuration state: CLEAR FMMU.
*/
void ec_fsm_slave_conf_state_clear_fmmus(ec_fsm_slave_t *fsm
/**< slave state machine */)
{
ec_datagram_t *datagram = fsm->datagram;
if (datagram->state == EC_DATAGRAM_TIMED_OUT && fsm->retries--) {
ec_master_queue_datagram(fsm->slave->master, datagram);
return;
}
if (datagram->state != EC_DATAGRAM_RECEIVED) {
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed receive FMMU clearing datagram for slave %i.\n",
fsm->slave->ring_position);
return;
}
if (datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to clear FMMUs - slave %i did not respond.\n",
fsm->slave->ring_position);
return;
}
ec_fsm_slave_conf_enter_sync(fsm);
}
/*****************************************************************************/
/**
*/
void ec_fsm_slave_conf_enter_sync(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_master_t *master = fsm->slave->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;
// slave is now in INIT
if (slave->current_state == slave->requested_state) {
fsm->state = ec_fsm_slave_state_end; // successful
if (master->debug_level) {
EC_DBG("Finished configuration of slave %i.\n",
slave->ring_position);
}
return;
}
if (!slave->base_sync_count) { // no sync managers
ec_fsm_slave_conf_enter_preop(fsm);
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_slave_sync_config(slave, &mbox_sync,
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_slave_sync_config(slave, &mbox_sync,
datagram->data + EC_SYNC_SIZE * mbox_sync.index);
}
}
else if (slave->sii_mailbox_protocols) { // mailboxes present
list_for_each_entry(sync, &slave->sii_syncs, list) {
// only configure mailbox sync-managers
if (sync->index != 0 && sync->index != 1) continue;
ec_slave_sync_config(slave, sync,
datagram->data + EC_SYNC_SIZE * sync->index);
}
}
ec_master_queue_datagram(fsm->slave->master, datagram);
fsm->retries = EC_FSM_RETRIES;
fsm->state = ec_fsm_slave_conf_state_sync;
}
/*****************************************************************************/
/**
Slave configuration state: SYNC.
*/
void ec_fsm_slave_conf_state_sync(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_datagram_t *datagram = fsm->datagram;
ec_slave_t *slave = fsm->slave;
if (datagram->state == EC_DATAGRAM_TIMED_OUT && fsm->retries--) {
ec_master_queue_datagram(fsm->slave->master, datagram);
return;
}
if (datagram->state != EC_DATAGRAM_RECEIVED) {
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to receive sync manager configuration datagram for"
" slave %i.\n", slave->ring_position);
return;
}
if (datagram->working_counter != 1) {
slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to set sync managers - slave %i did not respond.\n",
slave->ring_position);
return;
}
ec_fsm_slave_conf_enter_preop(fsm);
}
/*****************************************************************************/
/**
*/
void ec_fsm_slave_conf_enter_preop(ec_fsm_slave_t *fsm /**< slave state machine */)
{
fsm->state = ec_fsm_slave_conf_state_preop;
ec_fsm_change_start(&fsm->fsm_change, fsm->slave, EC_SLAVE_STATE_PREOP);
ec_fsm_change_exec(&fsm->fsm_change); // execute immediately
}
/*****************************************************************************/
/**
Slave configuration state: PREOP.
*/
void ec_fsm_slave_conf_state_preop(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_slave_t *slave = fsm->slave;
ec_master_t *master = fsm->slave->master;
if (ec_fsm_change_exec(&fsm->fsm_change)) return;
if (!ec_fsm_change_success(&fsm->fsm_change)) {
slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_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->state = ec_fsm_slave_state_end; // successful
if (master->debug_level) {
EC_DBG("Finished configuration of slave %i.\n",
slave->ring_position);
}
return;
}
ec_fsm_slave_conf_enter_sync2(fsm);
}
/*****************************************************************************/
/**
*/
void ec_fsm_slave_conf_enter_sync2(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_slave_t *slave = fsm->slave;
ec_datagram_t *datagram = fsm->datagram;
ec_sii_sync_t *sync;
if (list_empty(&slave->sii_syncs)) {
ec_fsm_slave_conf_enter_fmmu(fsm);
return;
}
// configure sync managers for process data
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);
list_for_each_entry(sync, &slave->sii_syncs, list) {
ec_slave_sync_config(slave, sync,
datagram->data + EC_SYNC_SIZE * sync->index);
}
ec_master_queue_datagram(fsm->slave->master, datagram);
fsm->retries = EC_FSM_RETRIES;
fsm->state = ec_fsm_slave_conf_state_sync2;
}
/*****************************************************************************/
/**
Slave configuration state: SYNC2.
*/
void ec_fsm_slave_conf_state_sync2(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_datagram_t *datagram = fsm->datagram;
ec_slave_t *slave = fsm->slave;
if (datagram->state == EC_DATAGRAM_TIMED_OUT && fsm->retries--) {
ec_master_queue_datagram(fsm->slave->master, datagram);
return;
}
if (datagram->state != EC_DATAGRAM_RECEIVED) {
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to receive process data sync manager configuration"
" datagram for slave %i.\n",
slave->ring_position);
return;
}
if (datagram->working_counter != 1) {
slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to set process data sync managers - slave %i did not"
" respond.\n", slave->ring_position);
return;
}
ec_fsm_slave_conf_enter_fmmu(fsm);
}
/*****************************************************************************/
/**
*/
void ec_fsm_slave_conf_enter_fmmu(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_slave_t *slave = fsm->slave;
ec_master_t *master = slave->master;
ec_datagram_t *datagram = fsm->datagram;
unsigned int j;
if (!slave->base_fmmu_count) { // skip FMMU configuration
ec_fsm_slave_conf_enter_sdoconf(fsm);
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_slave_fmmu_config(slave, &slave->fmmus[j],
datagram->data + EC_FMMU_SIZE * j);
}
ec_master_queue_datagram(master, datagram);
fsm->retries = EC_FSM_RETRIES;
fsm->state = ec_fsm_slave_conf_state_fmmu;
}
/*****************************************************************************/
/**
Slave configuration state: FMMU.
*/
void ec_fsm_slave_conf_state_fmmu(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_datagram_t *datagram = fsm->datagram;
ec_slave_t *slave = fsm->slave;
if (datagram->state == EC_DATAGRAM_TIMED_OUT && fsm->retries--) {
ec_master_queue_datagram(fsm->slave->master, datagram);
return;
}
if (datagram->state != EC_DATAGRAM_RECEIVED) {
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to receive FMMUs datagram for slave %i.\n",
fsm->slave->ring_position);
return;
}
if (datagram->working_counter != 1) {
fsm->slave->error_flag = 1;
fsm->state = ec_fsm_slave_state_error;
EC_ERR("Failed to set FMMUs - slave %i did not respond.\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
ec_fsm_slave_conf_enter_saveop(fsm);
return;
}
ec_fsm_slave_conf_enter_sdoconf(fsm);
}
/*****************************************************************************/
/**
*/
void ec_fsm_slave_conf_enter_sdoconf(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_slave_t *slave = fsm->slave;
if (list_empty(&slave->sdo_confs)) { // skip SDO configuration
ec_fsm_slave_conf_enter_saveop(fsm);
return;
}
// start SDO configuration
fsm->state = ec_fsm_slave_conf_state_sdoconf;
fsm->sdodata = list_entry(fsm->slave->sdo_confs.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
}
/*****************************************************************************/
/**
Slave configuration state: SDOCONF.
*/
void ec_fsm_slave_conf_state_sdoconf(ec_fsm_slave_t *fsm /**< slave 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->state = ec_fsm_slave_state_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
ec_fsm_slave_conf_enter_saveop(fsm);
}
/*****************************************************************************/
/**
*/
void ec_fsm_slave_conf_enter_saveop(ec_fsm_slave_t *fsm /**< slave state machine */)
{
fsm->state = ec_fsm_slave_conf_state_saveop;
ec_fsm_change_start(&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_slave_conf_state_saveop(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_master_t *master = fsm->slave->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->state = ec_fsm_slave_state_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->state = ec_fsm_slave_state_end; // successful
if (master->debug_level) {
EC_DBG("Finished configuration of slave %i.\n",
slave->ring_position);
}
return;
}
// set state to OP
fsm->state = ec_fsm_slave_conf_state_op;
ec_fsm_change_start(&fsm->fsm_change, slave, EC_SLAVE_STATE_OP);
ec_fsm_change_exec(&fsm->fsm_change); // execute immediately
}
/*****************************************************************************/
/**
Slave configuration state: OP
*/
void ec_fsm_slave_conf_state_op(ec_fsm_slave_t *fsm /**< slave state machine */)
{
ec_master_t *master = fsm->slave->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->state = ec_fsm_slave_state_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->state = ec_fsm_slave_state_end; // successful
}
/******************************************************************************
* Common state functions
*****************************************************************************/
/**
State: ERROR.
*/
void ec_fsm_slave_state_error(ec_fsm_slave_t *fsm /**< slave state machine */)
{
}
/*****************************************************************************/
/**
State: END.
*/
void ec_fsm_slave_state_end(ec_fsm_slave_t *fsm /**< slave state machine */)
{
}
/*****************************************************************************/