rt-thread-official/bsp/samd21/sam_d2x_asflib/sam0/drivers/can/can.c

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2017-08-30 12:18:28 +08:00
/**
* \file
*
* \brief SAM Control Area Network (CAN) Low Level Driver
*
* Copyright (C) 2015-2016 Atmel Corporation. All rights reserved.
*
* \asf_license_start
*
* \page License
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an
* Atmel microcontroller product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
* STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
* \asf_license_stop
*
*/
/*
* Support and FAQ: visit <a href="http://www.atmel.com/design-support/">Atmel Support</a>
*/
#include "can.h"
#include <string.h>
/* Instance for GCLK setting. */
struct system_gclk_chan_config gclk_chan_conf;
/* Message ram definition. */
COMPILER_ALIGNED(4)
static struct can_rx_element_buffer can0_rx_buffer[CONF_CAN0_RX_BUFFER_NUM];
COMPILER_ALIGNED(4)
static struct can_rx_element_fifo_0 can0_rx_fifo_0[CONF_CAN0_RX_FIFO_0_NUM];
COMPILER_ALIGNED(4)
static struct can_rx_element_fifo_1 can0_rx_fifo_1[CONF_CAN0_RX_FIFO_1_NUM];
COMPILER_ALIGNED(4)
static struct can_tx_element can0_tx_buffer[CONF_CAN0_TX_BUFFER_NUM + CONF_CAN0_TX_FIFO_QUEUE_NUM];
COMPILER_ALIGNED(4)
static struct can_tx_event_element can0_tx_event_fifo[CONF_CAN0_TX_EVENT_FIFO];
COMPILER_ALIGNED(4)
static struct can_standard_message_filter_element can0_rx_standard_filter[CONF_CAN0_RX_STANDARD_ID_FILTER_NUM];
COMPILER_ALIGNED(4)
static struct can_extended_message_filter_element can0_rx_extended_filter[CONF_CAN0_RX_EXTENDED_ID_FILTER_NUM];
COMPILER_ALIGNED(4)
static struct can_rx_element_buffer can1_rx_buffer[CONF_CAN1_RX_BUFFER_NUM];
COMPILER_ALIGNED(4)
static struct can_rx_element_fifo_0 can1_rx_fifo_0[CONF_CAN1_RX_FIFO_0_NUM];
COMPILER_ALIGNED(4)
static struct can_rx_element_fifo_1 can1_rx_fifo_1[CONF_CAN1_RX_FIFO_1_NUM];
COMPILER_ALIGNED(4)
static struct can_tx_element can1_tx_buffer[CONF_CAN1_TX_BUFFER_NUM + CONF_CAN1_TX_FIFO_QUEUE_NUM];
COMPILER_ALIGNED(4)
static struct can_tx_event_element can1_tx_event_fifo[CONF_CAN1_TX_EVENT_FIFO];
COMPILER_ALIGNED(4)
static struct can_standard_message_filter_element can1_rx_standard_filter[CONF_CAN1_RX_STANDARD_ID_FILTER_NUM];
COMPILER_ALIGNED(4)
static struct can_extended_message_filter_element can1_rx_extended_filter[CONF_CAN1_RX_EXTENDED_ID_FILTER_NUM];
static void _can_message_memory_init(Can *hw)
{
if (hw == CAN0) {
hw->SIDFC.reg = CAN_SIDFC_FLSSA((uint32_t)can0_rx_standard_filter) |
CAN_SIDFC_LSS(CONF_CAN0_RX_STANDARD_ID_FILTER_NUM);
hw->XIDFC.reg = CAN_XIDFC_FLESA((uint32_t)can0_rx_extended_filter) |
CAN_XIDFC_LSE(CONF_CAN0_RX_EXTENDED_ID_FILTER_NUM);
hw->RXF0C.reg = CAN_RXF0C_F0SA((uint32_t)can0_rx_fifo_0) |
CAN_RXF0C_F0S(CONF_CAN0_RX_FIFO_0_NUM);
hw->RXF1C.reg = CAN_RXF1C_F1SA((uint32_t)can0_rx_fifo_1) |
CAN_RXF1C_F1S(CONF_CAN0_RX_FIFO_1_NUM);
hw->RXBC.reg = CAN_RXBC_RBSA((uint32_t)can0_rx_buffer);
hw->TXBC.reg = CAN_TXBC_TBSA((uint32_t)can0_tx_buffer) |
CAN_TXBC_NDTB(CONF_CAN0_TX_BUFFER_NUM) |
CAN_TXBC_TFQS(CONF_CAN0_TX_FIFO_QUEUE_NUM);
hw->TXEFC.reg = CAN_TXEFC_EFSA((uint32_t)can0_tx_event_fifo) |
CAN_TXEFC_EFS(CONF_CAN0_TX_EVENT_FIFO);
} else if (hw == CAN1) {
hw->SIDFC.reg = CAN_SIDFC_FLSSA((uint32_t)can1_rx_standard_filter) |
CAN_SIDFC_LSS(CONF_CAN1_RX_STANDARD_ID_FILTER_NUM);
hw->XIDFC.reg = CAN_XIDFC_FLESA((uint32_t)can1_rx_extended_filter) |
CAN_XIDFC_LSE(CONF_CAN1_RX_EXTENDED_ID_FILTER_NUM);
hw->RXF0C.reg = CAN_RXF0C_F0SA((uint32_t)can1_rx_fifo_0) |
CAN_RXF0C_F0S(CONF_CAN1_RX_FIFO_0_NUM);
hw->RXF1C.reg = CAN_RXF1C_F1SA((uint32_t)can1_rx_fifo_1) |
CAN_RXF1C_F1S(CONF_CAN1_RX_FIFO_1_NUM);
hw->RXBC.reg = CAN_RXBC_RBSA((uint32_t)can1_rx_buffer);
hw->TXBC.reg = CAN_TXBC_TBSA((uint32_t)can1_tx_buffer) |
CAN_TXBC_NDTB(CONF_CAN1_TX_BUFFER_NUM) |
CAN_TXBC_TFQS(CONF_CAN1_TX_FIFO_QUEUE_NUM);
hw->TXEFC.reg = CAN_TXEFC_EFSA((uint32_t)can1_tx_event_fifo) |
CAN_TXEFC_EFS(CONF_CAN1_TX_EVENT_FIFO);
}
/**
* The data size in conf_can.h should be 8/12/16/20/24/32/48/64,
* The corresponding setting value in register is 0/1//2/3/4/5/6/7.
* To simplify the calculation, seperate to two group 8/12/16/20/24 which
* increased with 4 and 32/48/64 which increased with 16.
*/
if (CONF_CAN_ELEMENT_DATA_SIZE <= 24) {
hw->RXESC.reg = CAN_RXESC_RBDS((CONF_CAN_ELEMENT_DATA_SIZE - 8) / 4) |
CAN_RXESC_F0DS((CONF_CAN_ELEMENT_DATA_SIZE - 8) / 4) |
CAN_RXESC_F1DS((CONF_CAN_ELEMENT_DATA_SIZE - 8) / 4);
hw->TXESC.reg = CAN_TXESC_TBDS((CONF_CAN_ELEMENT_DATA_SIZE - 8) / 4);
} else {
hw->RXESC.reg = CAN_RXESC_RBDS((CONF_CAN_ELEMENT_DATA_SIZE - 32) / 16 + 5) |
CAN_RXESC_F0DS((CONF_CAN_ELEMENT_DATA_SIZE - 32) / 16 + 5) |
CAN_RXESC_F1DS((CONF_CAN_ELEMENT_DATA_SIZE - 32) / 16 + 5);
hw->TXESC.reg = CAN_TXESC_TBDS((CONF_CAN_ELEMENT_DATA_SIZE - 32) / 16 + 5);
}
}
static void _can_set_configuration(Can *hw, struct can_config *config)
{
/* Timing setting. */
hw->NBTP.reg = CAN_NBTP_NBRP(CONF_CAN_NBTP_NBRP_VALUE) |
CAN_NBTP_NSJW(CONF_CAN_NBTP_NSJW_VALUE) |
CAN_NBTP_NTSEG1(CONF_CAN_NBTP_NTSEG1_VALUE) |
CAN_NBTP_NTSEG2(CONF_CAN_NBTP_NTSEG2_VALUE);
hw->DBTP.reg = CAN_DBTP_DBRP(CONF_CAN_DBTP_DBRP_VALUE) |
CAN_DBTP_DSJW(CONF_CAN_DBTP_DSJW_VALUE) |
CAN_DBTP_DTSEG1(CONF_CAN_DBTP_DTSEG1_VALUE) |
CAN_DBTP_DTSEG2(CONF_CAN_DBTP_DTSEG2_VALUE);
if (config->tdc_enable) {
hw->DBTP.reg |= CAN_DBTP_TDC;
}
if (config->run_in_standby) {
hw->MRCFG.reg |= 0x01<<6;
}
hw->RWD.reg |= CAN_RWD_WDC(config->watchdog_configuration);
if (config->transmit_pause) {
hw->CCCR.reg |= CAN_CCCR_TXP;
}
if (config->edge_filtering) {
hw->CCCR.reg |= CAN_CCCR_EFBI;
}
if (config->protocol_exception_handling) {
hw->CCCR.reg |= CAN_CCCR_PXHD;
}
if (!config->automatic_retransmission) {
hw->CCCR.reg |= CAN_CCCR_DAR;
}
if (config->clock_stop_request) {
hw->CCCR.reg |= CAN_CCCR_CSR;
}
if (config->clock_stop_acknowledge) {
hw->CCCR.reg |= CAN_CCCR_CSA;
}
hw->TSCC.reg = CAN_TSCC_TCP(config->timestamp_prescaler) |
CAN_TSCC_TSS_INC_Val;
hw->TOCC.reg = CAN_TOCC_TOP(config->timeout_period) |
config->timeout_mode | config->timeout_enable;
hw->TDCR.reg = CAN_TDCR_TDCO(config->delay_compensation_offset) |
CAN_TDCR_TDCF(config->delay_compensation_filter_window_length);
hw->GFC.reg = CAN_GFC_ANFS(config->nonmatching_frames_action_standard) |
CAN_GFC_ANFE(config->nonmatching_frames_action_extended);
if (config->remote_frames_standard_reject) {
hw->GFC.reg |= CAN_GFC_RRFS;
}
if (config->remote_frames_extended_reject) {
hw->GFC.reg |= CAN_GFC_RRFE;
}
hw->XIDAM.reg = config->extended_id_mask;
if (config->rx_fifo_0_overwrite) {
hw->RXF0C.reg |= CAN_RXF0C_F0OM;
}
hw->RXF0C.reg |= CAN_RXF0C_F0WM(config->rx_fifo_0_watermark);
if (config->rx_fifo_1_overwrite) {
hw->RXF1C.reg |= CAN_RXF1C_F1OM;
}
hw->RXF1C.reg |= CAN_RXF1C_F1WM(config->rx_fifo_1_watermark);
if (config->tx_queue_mode) {
hw->TXBC.reg |= CAN_TXBC_TFQM;
}
hw->TXEFC.reg |= CAN_TXEFC_EFWM(config->tx_event_fifo_watermark);
}
static void _can_enable_peripheral_clock(struct can_module *const module_inst)
{
if (module_inst->hw == CAN0) {
/* Turn on the digital interface clock. */
system_ahb_clock_set_mask(MCLK_AHBMASK_CAN0);
} else if (module_inst->hw == CAN1) {
/* Turn on the digital interface clock. */
system_ahb_clock_set_mask(MCLK_AHBMASK_CAN1);
}
}
void can_init(struct can_module *const module_inst, Can *hw,
struct can_config *config)
{
/* Sanity check arguments */
Assert(module_inst);
Assert(hw);
Assert(config);
/* Associate the software module instance with the hardware module */
module_inst->hw = hw;
/* Enable peripheral clock */
_can_enable_peripheral_clock(module_inst);
/* Configure GCLK channel */
system_gclk_chan_get_config_defaults(&gclk_chan_conf);
gclk_chan_conf.source_generator = config->clock_source;
if (hw == CAN0) {
system_gclk_chan_set_config(CAN0_GCLK_ID, &gclk_chan_conf);
system_gclk_chan_enable(CAN0_GCLK_ID);
} else if (hw == CAN1) {
system_gclk_chan_set_config(CAN1_GCLK_ID, &gclk_chan_conf);
system_gclk_chan_enable(CAN1_GCLK_ID);
}
/* Configuration Change Enable. */
hw->CCCR.reg |= CAN_CCCR_CCE;
/* Initialize the message memory address. */
_can_message_memory_init(hw);
/* Set the configuration. */
_can_set_configuration(hw, config);
/* Enable the interrupt setting which no need change. */
hw->ILE.reg = CAN_ILE_EINT0 | CAN_ILE_EINT1;
hw->TXBTIE.reg = CAN_TXBTIE_MASK;
hw->TXBCIE.reg = CAN_TXBCIE_MASK;
}
void can_set_baudrate(Can *hw, uint32_t baudrate)
{
uint32_t gclk_can_value = 0;
uint32_t can_nbtp_nbrp_value;
uint32_t can_nbtp_nsgw_value = 3, can_nbtp_ntseg1_value = 10, can_nbtp_ntseg2_value = 3;
if (hw == CAN0) {
gclk_can_value = system_gclk_chan_get_hz(CAN0_GCLK_ID);
} else if (hw == CAN1) {
gclk_can_value = system_gclk_chan_get_hz(CAN1_GCLK_ID);
}
can_nbtp_nbrp_value = gclk_can_value / baudrate / (3 + can_nbtp_ntseg1_value + can_nbtp_ntseg2_value);
hw->NBTP.reg = CAN_NBTP_NBRP(can_nbtp_nbrp_value) |
CAN_NBTP_NSJW(can_nbtp_nsgw_value) |
CAN_NBTP_NTSEG1(can_nbtp_ntseg1_value) |
CAN_NBTP_NTSEG2(can_nbtp_ntseg2_value);
}
void can_fd_set_baudrate(Can *hw, uint32_t baudrate)
{
uint32_t gclk_can_fd_value = 0;
uint32_t can_fd_dbtp_dbrp_value;
uint32_t can_fd_dbtp_dsgw_value = 3, can_fd_dbtp_dtseg1_value = 10, can_fd_dbtp_dtseg2_value = 3;
if (hw == CAN0) {
gclk_can_fd_value = system_gclk_chan_get_hz(CAN0_GCLK_ID);
} else if (hw == CAN1) {
gclk_can_fd_value = system_gclk_chan_get_hz(CAN1_GCLK_ID);
}
can_fd_dbtp_dbrp_value = gclk_can_fd_value / baudrate / (3 + can_fd_dbtp_dtseg1_value + can_fd_dbtp_dtseg2_value);
hw->NBTP.reg = CAN_DBTP_DBRP(can_fd_dbtp_dbrp_value) |
CAN_DBTP_DSJW(can_fd_dbtp_dsgw_value) |
CAN_DBTP_DTSEG1(can_fd_dbtp_dtseg1_value) |
CAN_DBTP_DTSEG2(can_fd_dbtp_dtseg2_value);
}
void can_start(struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg &= ~CAN_CCCR_INIT;
/* Wait for the sync. */
while (module_inst->hw->CCCR.reg & CAN_CCCR_INIT);
}
void can_stop(struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg |= CAN_CCCR_INIT;
/* Wait for the sync. */
while (!(module_inst->hw->CCCR.reg & CAN_CCCR_INIT));
}
void can_enable_fd_mode(struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg |= CAN_CCCR_INIT;
/* Wait for the sync. */
while (!(module_inst->hw->CCCR.reg & CAN_CCCR_INIT));
module_inst->hw->CCCR.reg |= CAN_CCCR_CCE;
module_inst->hw->CCCR.reg |= CAN_CCCR_FDOE;
module_inst->hw->CCCR.reg |= CAN_CCCR_BRSE;
}
void can_disable_fd_mode(struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg &= ~CAN_CCCR_FDOE;
}
void can_enable_restricted_operation_mode(
struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg |= CAN_CCCR_INIT;
/* Wait for the sync. */
while (!(module_inst->hw->CCCR.reg & CAN_CCCR_INIT));
module_inst->hw->CCCR.reg |= CAN_CCCR_CCE;
module_inst->hw->CCCR.reg |= CAN_CCCR_ASM;
}
void can_disable_restricted_operation_mode(
struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg &= ~CAN_CCCR_ASM;
}
void can_enable_bus_monitor_mode(struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg |= CAN_CCCR_INIT;
/* Wait for the sync. */
while (!(module_inst->hw->CCCR.reg & CAN_CCCR_INIT));
module_inst->hw->CCCR.reg |= CAN_CCCR_CCE;
module_inst->hw->CCCR.reg |= CAN_CCCR_MON;
}
void can_disable_bus_monitor_mode(struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg &= ~CAN_CCCR_MON;
}
void can_enable_sleep_mode(struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg |= CAN_CCCR_CSR;
/* Wait for the sync. */
while (!(module_inst->hw->CCCR.reg & CAN_CCCR_INIT));
while (!(module_inst->hw->CCCR.reg & CAN_CCCR_CSA));
}
void can_disable_sleep_mode(struct can_module *const module_inst)
{
/* Enable peripheral clock */
_can_enable_peripheral_clock(module_inst);
if (module_inst->hw == CAN0) {
system_gclk_chan_set_config(CAN0_GCLK_ID, &gclk_chan_conf);
system_gclk_chan_enable(CAN0_GCLK_ID);
}
if (module_inst->hw == CAN1) {
system_gclk_chan_set_config(CAN1_GCLK_ID, &gclk_chan_conf);
system_gclk_chan_enable(CAN1_GCLK_ID);
}
module_inst->hw->CCCR.reg &= CAN_CCCR_CSR;
while ((module_inst->hw->CCCR.reg & CAN_CCCR_CSA));
}
void can_enable_test_mode(struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg |= CAN_CCCR_INIT;
/* Wait for the sync. */
while (!(module_inst->hw->CCCR.reg & CAN_CCCR_INIT));
module_inst->hw->CCCR.reg |= CAN_CCCR_CCE;
module_inst->hw->CCCR.reg |= CAN_CCCR_TEST;
module_inst->hw->TEST.reg |= CAN_TEST_LBCK;
}
void can_disable_test_mode(struct can_module *const module_inst)
{
module_inst->hw->CCCR.reg &= ~CAN_CCCR_TEST;
}
enum status_code can_set_rx_standard_filter(
struct can_module *const module_inst,
struct can_standard_message_filter_element *sd_filter, uint32_t index)
{
if (module_inst->hw == CAN0) {
can0_rx_standard_filter[index].S0.reg = sd_filter->S0.reg;
return STATUS_OK;
} else if (module_inst->hw == CAN1) {
can1_rx_standard_filter[index].S0.reg = sd_filter->S0.reg;
return STATUS_OK;
}
return STATUS_ERR_INVALID_ARG;
}
enum status_code can_set_rx_extended_filter(
struct can_module *const module_inst,
struct can_extended_message_filter_element *et_filter, uint32_t index)
{
if (module_inst->hw == CAN0) {
can0_rx_extended_filter[index].F0.reg = et_filter->F0.reg;
can0_rx_extended_filter[index].F1.reg = et_filter->F1.reg;
return STATUS_OK;
} else if (module_inst->hw == CAN1) {
can1_rx_extended_filter[index].F0.reg = et_filter->F0.reg;
can1_rx_extended_filter[index].F1.reg = et_filter->F1.reg;
return STATUS_OK;
}
return STATUS_ERR_INVALID_ARG;
}
enum status_code can_get_rx_buffer_element(
struct can_module *const module_inst,
struct can_rx_element_buffer *rx_element, uint32_t index)
{
if (module_inst->hw == CAN0) {
memcpy(rx_element, &can0_rx_buffer[index], sizeof(struct can_rx_element_buffer));
return STATUS_OK;
} else if (module_inst->hw == CAN1) {
memcpy(rx_element, &can1_rx_buffer[index], sizeof(struct can_rx_element_buffer));
return STATUS_OK;
}
return STATUS_ERR_INVALID_ARG;
}
enum status_code can_get_rx_fifo_0_element(
struct can_module *const module_inst,
struct can_rx_element_fifo_0 *rx_element, uint32_t index)
{
if (module_inst->hw == CAN0) {
memcpy(rx_element, &can0_rx_fifo_0[index], sizeof(struct can_rx_element_buffer));
return STATUS_OK;
} else if (module_inst->hw == CAN1) {
memcpy(rx_element, &can1_rx_fifo_0[index], sizeof(struct can_rx_element_buffer));
return STATUS_OK;
}
return STATUS_ERR_INVALID_ARG;
}
enum status_code can_get_rx_fifo_1_element(
struct can_module *const module_inst,
struct can_rx_element_fifo_1 *rx_element, uint32_t index)
{
if (module_inst->hw == CAN0) {
memcpy(rx_element, &can0_rx_fifo_1[index], sizeof(struct can_rx_element_buffer));
return STATUS_OK;
} else if (module_inst->hw == CAN1) {
memcpy(rx_element, &can1_rx_fifo_1[index], sizeof(struct can_rx_element_buffer));
return STATUS_OK;
}
return STATUS_ERR_INVALID_ARG;
}
enum status_code can_set_tx_buffer_element(
struct can_module *const module_inst,
struct can_tx_element *tx_element, uint32_t index)
{
uint32_t i;
if (module_inst->hw == CAN0) {
can0_tx_buffer[index].T0.reg = tx_element->T0.reg;
can0_tx_buffer[index].T1.reg = tx_element->T1.reg;
for (i = 0; i < CONF_CAN_ELEMENT_DATA_SIZE; i++) {
can0_tx_buffer[index].data[i] = tx_element->data[i];
}
return STATUS_OK;
} else if (module_inst->hw == CAN1) {
can1_tx_buffer[index].T0.reg = tx_element->T0.reg;
can1_tx_buffer[index].T1.reg = tx_element->T1.reg;
for (i = 0; i < CONF_CAN_ELEMENT_DATA_SIZE; i++) {
can1_tx_buffer[index].data[i] = tx_element->data[i];
}
return STATUS_OK;
}
return STATUS_ERR_INVALID_ARG;
}
enum status_code can_get_tx_event_fifo_element(
struct can_module *const module_inst,
struct can_tx_event_element *tx_event_element, uint32_t index)
{
if (module_inst->hw == CAN0) {
tx_event_element->E0.reg = can0_tx_event_fifo[index].E0.reg;
tx_event_element->E1.reg = can0_tx_event_fifo[index].E1.reg;
return STATUS_OK;
} else if (module_inst->hw == CAN1) {
tx_event_element->E0.reg = can1_tx_event_fifo[index].E0.reg;
tx_event_element->E1.reg = can1_tx_event_fifo[index].E1.reg;
return STATUS_OK;
}
return STATUS_ERR_INVALID_ARG;
}