Modification of the dictionnary to support NVRAM.
(Object 0x1010, 0x1011.)
/*
This file is part of CanFestival, a library implementing CanOpen Stack.
Author: CANopen Canada (canfestival@canopencanada.ca)
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 <applicfg.h>
#include <def.h>
#include <can.h>
#include <data.h>
#include <objdictdef.h>
#include <objacces.h>
#include "can_driver.h"
#ifdef LED_ENABLE
#include "led.h"
#else
#define led_set_state(a,b)
#endif
#include "lss.h"
/*
NOTES
1. since in the LSS protocol all LSS Slave use the same COB, only 1 Slave
must be allowed to communicate with the Master
2. the Master always take the iniative. the Slave is only allowed to transmit
within a confirmed service
3. requesting message (from the Master) using COB-ID 2021 and response messages
(from the Slave) using COB-ID 2020
*/
/*
0 = this slave is not talking to the master
1 = this slave is talking to the master (this slave has been selected via )
*/
int slave_selector;
int current_mode;
int lss_table_selector, lss_table_index;
/* slave storing the information sent by the master */
UNS32 lss_buffer[10];
/*
how this buffer is used
for a SLAVE
[0..3] used to store the LSS Address
[4..9] use by LSS Identify Remort Slave
for the MASTER
[0..3] hold the answer from the slave regarding its ID
*/
void lss_copy(UNS8 *data, UNS32 value)
/* transfert 32 bits value into uns8 data vector */
{
data[0] = value & 0xff;
data[1] = (value>>8) & 0xff;
data[2] = (value>>16) & 0xff;
data[3] = (value>>24) & 0xff;
}
UNS32 lss_get_value(UNS8 *data)
/* build a 'UNS32' value from a 'unsigned char' vector */
{
return data[0] + (data[1]<<8) + (data[2]<<16) + (data[3]<<24);
}
void lss_init_msg(Message *msg)
{
msg->cob_id.w = 0;
msg->rtr = 0;
msg->len = 0;
msg->data[0] = 0;
msg->data[1] = 0;
msg->data[2] = 0;
msg->data[3] = 0;
msg->data[4] = 0;
msg->data[5] = 0;
msg->data[6] = 0;
msg->data[7] = 0;
}
void lss_SwitchModeGlobal(CO_Data *d, UNS32 mode)
/*
this service is used to switch all LSS slaves in the network between operation
mode and configuration mode.
*/
{
Message msg;
lss_init_msg(&msg);
/*
sending a COB-ID 2021
[0] = 4 (for switch mode global)
[1] = 0 for operation mode, = 1 for configuration mode
[2..7] = 0 reserved
*/
if (!(d->iam_a_slave))
{
msg.cob_id.w = 0x07E5 /* 2021 */;
msg.len = 2;
msg.data[0] = 4;
msg.data[1] = (UNS8)mode;
/* transmit */
(*d->canSend)(&msg);
}
else
{
/* set mode global */
current_mode = mode;
}
}
void lss_SwitchModeSelective_master(CO_Data *d, UNS32 *LSSaddr)
/*
LSS address : <vendor-id> <product-code> <revision-number> <serial-number>
vendor-id : provided by CiA
identical to the CANopen identity object
select the slave corresponding to this ADDRESS
*/
{
Message msg;
lss_init_msg(&msg);
if (d->iam_a_slave) /* not the master */
return;
msg.cob_id.w = 0x07E5 /* 2021 */;
msg.len=5;
msg.data[0] = 64;
lss_copy(msg.data+1, LSSaddr[0]);
/* transmit */
(*d->canSend)(&msg);
msg.data[0] = 65;
lss_copy(msg.data+1, LSSaddr[1]);
/* transmit */
(*d->canSend)(&msg);
msg.data[0] = 66;
lss_copy(msg.data+1, LSSaddr[2]);
/* transmit */
(*d->canSend)(&msg);
msg.data[0] = 67;
lss_copy(msg.data+1, LSSaddr[3]);
/* transmit */
(*d->canSend)(&msg);
}
UNS32 lss_validate_address(CO_Data* d)
{
#if 0
extern s_identity obj1018;
/* maybe we should go throught getODentry but those
data are 1) RO and 2) the proper ID of this device */
#else
UNS32 r, vendor_id, product_code, revision_number, serial_number;
UNS8 sz = sizeof(UNS32), dt = int32;
r = getODentry(d, 0x1018, 1, (void *)&vendor_id, &sz, &dt, 0);
r = getODentry(d, 0x1018, 2, (void *)&product_code, &sz, &dt, 0);
r = getODentry(d, 0x1018, 3, (void *)&revision_number, &sz, &dt, 0);
r = getODentry(d, 0x1018, 4, (void *)&serial_number, &sz, &dt, 0);
#endif
/*
if
lss_buffer[0] == vendor-id
lss_buffer[1] == product code
lss_buffer[2] == revision
lss_buffer[3] == serial
then return 1
else return 0;
*/
if (lss_buffer[0] == vendor_id &&
lss_buffer[1] == product_code &&
lss_buffer[2] == revision_number &&
lss_buffer[3] == serial_number)
{
return 1;
}
return 0;
}
void lss_SwitchModeSelective_slave(CO_Data *d)
/*
SwitchModeSelective for the SLAVE
received the frames from the master and start building
the lss address
*/
{
Message msg;
lss_init_msg(&msg);
/*
the master broadcast the address of a particular slave
for 64,65 and 66 store the partial address
when 67 arrive process the call and asknowledge if necessary
*/
if (lss_validate_address(d))
{
/* slave should transmit cob_id 2020 */
msg.cob_id.w = 0x07E4 /* 2020 */;
msg.len = 2;
msg.data[0] = 68;
msg.data[1] = (UNS8)current_mode;
/* transmit */
(*d->canSend)(&msg);
}
/* reset the address */
lss_buffer[0] = 0;
lss_buffer[1] = 0;
lss_buffer[2] = 0;
lss_buffer[3] = 0;
}
void lss_ConfigureNode_ID(CO_Data *d, UNS32 node_id)
/*
through this service the LSS Master configures the NMT-address
parameter of a LSS slave.
*/
{
Message msg;
lss_init_msg(&msg);
if (!(d->iam_a_slave))
{
msg.cob_id.w = 0x07E5 /* 2021 */;
msg.len = 2;
msg.data[0] = 17;
msg.data[1] = (UNS8)node_id;
/* transmit */
(*d->canSend)(&msg);
}
else
{
/*
receiving NODE ID from the master
*/
/*
error code
0 = success
1 = node id out of range
2..254 = reserved
255 = implementation specific error occured
spec error = mode detailed error
*/
msg.cob_id.w = 0x07E4 /* 2020 */;
msg.len = 3;
msg.data[0] = 17;
/* msg.data[1] = error code */
/* msg.data[2] = spec error */
/* transmit */
(*d->canSend)(&msg);
}
}
void lss_ConfigureBitTimingParameters(CO_Data *d,
UNS32 table_selector,
UNS32 table_index)
/*
this service allows all LSS slaves in configuration mode.
must be followed by an Activate Bit Timing Parameters
*/
{
Message msg;
lss_init_msg(&msg);
if (!(d->iam_a_slave))
{
msg.cob_id.w = 0x07E5 /* 2021 */;
msg.len = 3;
msg.data[0] = 19;
msg.data[1] = (UNS8)table_selector;
msg.data[2] = (UNS8)table_index;
/* transmit */
(*d->canSend)(&msg);
}
else
{
UNS8 error_code;
/* validate if this baudrate is possible */
if (table_selector == 0 && baudrate_valid(table_index) == 1)
{
lss_table_selector = table_selector;
lss_table_index = table_index;
}
else
error_code = 1; /* bit timing not supported */
msg.cob_id.w = 0x07E4 /* 2020 */;
msg.len = 3;
msg.data[0] = 19;
msg.data[1] = error_code;
msg.data[2] = 0;
/* transmit */
(*d->canSend)(&msg);
}
led_set_state(d, LED_AUTOBITRATE);
}
void lss_ActivateBitTimingParameters_master(CO_Data *d, unsigned short switch_delay)
/*
switch_delay in ms
switch_delay has to be longer than the longest timeof any node
in the network to avoid that a node already switches while another
stills transmist the old bit timing parameters
*/
{
Message msg;
lss_init_msg(&msg);
if (d->iam_a_slave)
return;
msg.cob_id.w = 0x07E5 /* 2021 */;
msg.len = 3;
msg.data[0] = 21;
msg.data[1] = (UNS8)(switch_delay & 0xff);
msg.data[2] = (UNS8)((switch_delay >> 8) & 0xff);
#ifdef LED_ENABLE
led_set_state(LED_AUTOBITRATE);
#endif
/* transmit */
(*d->canSend)(&msg);
}
void lss_ActivateBitTimingParameters_slave(UNS8 byte_low, UNS8 byte_high)
{
/* rebuild the delay value (short) from the 2 (UNS8) data */
unsigned short switch_delay = byte_low + (((UNS16)byte_high)<<8);
/* set the baudrate to the value proposed by the master */
if (lss_table_selector == 0)
baudrate_set(lss_table_index);
/* wait for switch_delay ms before continuing */
}
void lss_StoreConfiguredParameters(CO_Data *d)
/*
store configured parameters into non-volatile storage
*/
{
Message msg;
lss_init_msg(&msg);
if (!(d->iam_a_slave))
{
msg.cob_id.w = 0x07E5 /* 2021 */;
msg.len = 1;
msg.data[0] = 23;
/* transmit */
(*d->canSend)(&msg);
}
else
{
msg.cob_id.w = 0x07E4 /* 2020 */;
msg.data[0] = 23;
/* msg.data[1] = error code; */
/* msg.data[2] = spec err */
/* transmit */
(*d->canSend)(&msg);
}
}
void lss_InquireLSSAddress_master(CO_Data *d, int flag)
/*
this service allows to determine the LSS-address parameters of a LSS-slave in
configuration mode
request 1 single item of the LSS address
0 = request vendor-id
1 = request product-id
2 = request revision
3 = request serial
*/
{
Message msg;
lss_init_msg(&msg);
if (!(d->iam_a_slave))
{
msg.cob_id.w = 0x07E5 /* 2021 */;
msg.len = 1;
msg.data[0] = 90 + flag;
/* transmit */
(*d->canSend)(&msg);
}
}
int lss_InquireLSSAddress_slave(CO_Data *d, int cs)
{
Message msg;
lss_init_msg(&msg);
if (!(d->iam_a_slave)) /* not a slave */
return -1;
UNS32 value = 0;
switch(cs)
{
case 90:
value = 0; /* = vendor id */
break;
case 91:
value = 0; /* = product code */
break;
case 92:
value = 0; /* = revision */
break;
case 93:
value = 0; /* = serial */
break;
}
if (value > 0)
{
msg.cob_id.w = 0x07E4 /* 2020 */;
msg.len=5;
msg.data[0] = cs;
lss_copy(msg.data+1, value);
/* transmit */
(*d->canSend)(&msg);
return 0;
}
return -1;
}
void lss_IdentifyRemoteSlaves(CO_Data *d,
UNS32 vendor_id,
UNS32 product_code,
UNS32 rev_low,
UNS32 rev_high,
UNS32 serial_low,
UNS32 serial_high)
/*
throught this service, the LSS Master requests all LSS slave whose LSS address
meets the LSSaddr_sel to idenfity themselves through LSS Identify Slave
*/
{
Message msg;
lss_init_msg(&msg);
if (!(d->iam_a_slave))
{
/*
request answers from all slaves corresponding
to the revision and serial range of values
*/
msg.cob_id.w = 0x07E5 /* 2021 */;
msg.len=5;
msg.data[0] = 70;
lss_copy(msg.data+1, vendor_id);
/* transmit */
(*d->canSend)(&msg);
msg.data[0] = 71;
lss_copy(msg.data+1, product_code);
/* transmit */
(*d->canSend)(&msg);
msg.data[0] = 72; /* revision number low */
lss_copy(msg.data+1, rev_low);
/* transmit */
(*d->canSend)(&msg);
msg.data[0] = 73; /* revision number high */
lss_copy(msg.data+1, rev_high);
/* transmit */
(*d->canSend)(&msg);
msg.data[0] = 74; /* serial number low */
lss_copy(msg.data+1, serial_low);
/* transmit */
(*d->canSend)(&msg);
msg.data[0] = 75; /* serial number high */
lss_copy(msg.data+1, serial_high);
/* transmit */
(*d->canSend)(&msg);
}
}
int lss_validate_range_addr(CO_Data *d)
{
/*
if
lss_buffer[4] == vendor_id
lss_buffer[5] == product code
lss_buffer[6] <= revision <= lss_buffer[7]
lss_buffer[8] <= serial <= lss_buffer[9]
then return 1
else return 0
*/
UNS32 r, vendor_id, product_code, revision_number, serial_number;
UNS8 sz = sizeof(UNS32), dt = int32;
r = getODentry(d, 0x1018, 1, (void *)&vendor_id, &sz, &dt, 0);
r = getODentry(d, 0x1018, 2, (void *)&product_code, &sz, &dt, 0);
r = getODentry(d, 0x1018, 3, (void *)&revision_number, &sz, &dt, 0);
r = getODentry(d, 0x1018, 4, (void *)&serial_number, &sz, &dt, 0);
if (lss_buffer[4] == vendor_id &&
lss_buffer[5] == product_code &&
lss_buffer[6] <= revision_number &&
revision_number <= lss_buffer[7] &&
lss_buffer[8] <= serial_number &&
serial_number <= lss_buffer[9])
{
return 1;
}
return 0;
}
void lss_IdentifySlave(CO_Data *d)
/*
through this service, an LSS slave indicates that it is a slave
with LSS address within the LSSaddr_sel
*/
{
Message msg;
lss_init_msg(&msg);
if (lss_validate_range_addr(d))
{
msg.cob_id.w = 0x07E4 /* 2020 */;
msg.len = 1;
msg.data[0] = 79;
/* transmit */
(*d->canSend)(&msg);
}
/* reset */
lss_buffer[4] = 0;
lss_buffer[5] = 0;
lss_buffer[6] = 0;
lss_buffer[7] = 0;
lss_buffer[8] = 0;
lss_buffer[9] = 0;
}
int lss_process_msg(CO_Data *d, Message *msg)
{
/* process the incoming message */
if (msg->cob_id.w == 0x07E4 /* 2020 */)
{
// should be the master
// a slave just answered
switch(msg->data[0])
{
/* slave acknowledging the SwitchModeSelective call */
case 68:
/* msg->data[1] contains the 'mode global' value from the slave*/
break;
/* a slave had acknowledged the call from LSS Identify Remote Slave */
case 79:
break;
/* the slave acknowledged and sent the requested data */
case 90:
lss_buffer[0] = lss_get_value(msg->data+1);
/* action ? */
break;
case 91:
lss_buffer[1] = lss_get_value(msg->data+1);
/* action ? */
break;
case 92:
lss_buffer[2] = lss_get_value(msg->data+1);
/* action ? */
break;
case 93:
lss_buffer[3] = lss_get_value(msg->data+1);
/* action ? */
break;
}
}
else if (msg->cob_id.w == 0x07E5 /* 2021 */)
{
// should be a slave
// the master sent a request
switch(msg->data[0])
{
case 4:
lss_SwitchModeGlobal(d, msg->data[1]);
break;
case 17:
lss_ConfigureNode_ID(d, msg->data[1]);
break;
case 19:
lss_ConfigureBitTimingParameters(d, msg->data[1], msg->data[2]);
break;
case 21:
lss_ActivateBitTimingParameters_slave(msg->data[1], msg->data[2]);
break;
/* Switch Mode Selective */
case 64:
lss_buffer[0] = lss_get_value(msg->data+1);
break;
case 65:
lss_buffer[1] = lss_get_value(msg->data+1);
break;
case 66:
lss_buffer[2] = lss_get_value(msg->data+1);
break;
case 67:
lss_buffer[3] = lss_get_value(msg->data+1);
lss_SwitchModeSelective_slave(d);
break;
/* Identify Remote Slave */
case 70:
lss_buffer[4] = lss_get_value(msg->data+1);
break;
case 71:
lss_buffer[5] = lss_get_value(msg->data+1);
break;
case 72:
lss_buffer[6] = lss_get_value(msg->data+1);
break;
case 73:
lss_buffer[7] = lss_get_value(msg->data+1);
break;
case 74:
lss_buffer[8] = lss_get_value(msg->data+1);
break;
case 75:
lss_buffer[9] = lss_get_value(msg->data+1);
lss_IdentifySlave(d);
break;
/* Inquire Identify of Slave */
case 90:
case 91:
case 92:
case 93:
lss_InquireLSSAddress_slave(d, msg->data[0]);
break;
}
}
return 0;
}