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7e0eed9235
zephyr/drivers/can/can_stm32.c
Martí Bolívar 7e0eed9235 devicetree: allow access to all nodes 
Usually, we want to operate only on "available" device
nodes ("available" means "status is okay and a matching binding is
found"), but that's not true in all cases.

Sometimes we want to operate on special nodes without matching
bindings, such as those describing memory.

To handle the distinction, change various additional devicetree APIs
making it clear that they operate only on available device nodes,
adjusting gen_defines and devicetree.h implementation details
accordingly:

- emit macros for all existing nodes in gen_defines.py, regardless
  of status or matching binding
- rename DT_NUM_INST to DT_NUM_INST_STATUS_OKAY
- rename DT_NODE_HAS_COMPAT to DT_NODE_HAS_COMPAT_STATUS_OKAY
- rename DT_INST_FOREACH to DT_INST_FOREACH_STATUS_OKAY
- rename DT_ANY_INST_ON_BUS to DT_ANY_INST_ON_BUS_STATUS_OKAY
- rewrite DT_HAS_NODE_STATUS_OKAY in terms of a new DT_NODE_HAS_STATUS
- resurrect DT_HAS_NODE in the form of DT_NODE_EXISTS
- remove DT_COMPAT_ON_BUS as a public API
- use the new default_prop_types edtlib parameter

Signed-off-by: Martí Bolívar <marti.bolivar@nordicsemi.no>
2020-05-08 19:37:18 -05:00

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/*
* Copyright (c) 2018 Alexander Wachter
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <drivers/clock_control/stm32_clock_control.h>
#include <drivers/clock_control.h>
#include <sys/util.h>
#include <string.h>
#include <kernel.h>
#include <soc.h>
#include <errno.h>
#include <stdbool.h>
#include <drivers/can.h>
#include "can_stm32.h"
#include <logging/log.h>
LOG_MODULE_DECLARE(can_driver, CONFIG_CAN_LOG_LEVEL);
#define CAN_INIT_TIMEOUT (10 * sys_clock_hw_cycles_per_sec() / MSEC_PER_SEC)
#if DT_HAS_NODE_STATUS_OKAY(DT_NODELABEL(can1)) && \
DT_NODE_HAS_COMPAT_STATUS_OKAY(DT_NODELABEL(can1), st_stm32_can) && \
DT_HAS_NODE_STATUS_OKAY(DT_NODELABEL(can2)) && \
DT_NODE_HAS_COMPAT_STATUS_OKAY(DT_NODELABEL(can2), st_stm32_can)
#error Simultaneous use of CAN_1 and CAN_2 not supported yet
#endif
/*
* Translation tables
* filter_in_bank[enum can_filter_type] = number of filters in bank for this type
* reg_demand[enum can_filter_type] = how many registers are used for this type
*/
static const u8_t filter_in_bank[] = {2, 4, 1, 2};
static const u8_t reg_demand[] = {2, 1, 4, 2};
static void can_stm32_signal_tx_complete(struct can_mailbox *mb)
{
if (mb->tx_callback) {
mb->tx_callback(mb->error_flags, mb->callback_arg);
} else {
k_sem_give(&mb->tx_int_sem);
}
}
static void can_stm32_get_msg_fifo(CAN_FIFOMailBox_TypeDef *mbox,
struct zcan_frame *msg)
{
if (mbox->RIR & CAN_RI0R_IDE) {
msg->ext_id = mbox->RIR >> CAN_RI0R_EXID_Pos;
msg->id_type = CAN_EXTENDED_IDENTIFIER;
} else {
msg->std_id = mbox->RIR >> CAN_RI0R_STID_Pos;
msg->id_type = CAN_STANDARD_IDENTIFIER;
}
msg->rtr = mbox->RIR & CAN_RI0R_RTR ? CAN_REMOTEREQUEST : CAN_DATAFRAME;
msg->dlc = mbox->RDTR & (CAN_RDT0R_DLC >> CAN_RDT0R_DLC_Pos);
msg->data_32[0] = mbox->RDLR;
msg->data_32[1] = mbox->RDHR;
#ifdef CONFIG_CAN_RX_TIMESTAMP
msg->timestamp = ((mbox->RDTR & CAN_RDT0R_TIME) >> CAN_RDT0R_TIME_Pos);
#endif
}
static inline
void can_stm32_rx_isr_handler(CAN_TypeDef *can, struct can_stm32_data *data)
{
CAN_FIFOMailBox_TypeDef *mbox;
int filter_match_index;
struct zcan_frame msg;
can_rx_callback_t callback;
while (can->RF0R & CAN_RF0R_FMP0) {
mbox = &can->sFIFOMailBox[0];
filter_match_index = ((mbox->RDTR & CAN_RDT0R_FMI)
>> CAN_RDT0R_FMI_Pos);
if (filter_match_index >= CONFIG_CAN_MAX_FILTER) {
break;
}
LOG_DBG("Message on filter index %d", filter_match_index);
can_stm32_get_msg_fifo(mbox, &msg);
callback = data->rx_cb[filter_match_index];
if (callback) {
callback(&msg, data->cb_arg[filter_match_index]);
}
/* Release message */
can->RF0R |= CAN_RF0R_RFOM0;
}
if (can->RF0R & CAN_RF0R_FOVR0) {
LOG_ERR("RX FIFO Overflow");
}
}
static inline void can_stm32_bus_state_change_isr(CAN_TypeDef *can,
struct can_stm32_data *data)
{
struct can_bus_err_cnt err_cnt;
enum can_state state;
if (!(can->ESR & CAN_ESR_EPVF) && !(can->ESR & CAN_ESR_BOFF)) {
return;
}
err_cnt.tx_err_cnt = ((can->ESR & CAN_ESR_TEC) >> CAN_ESR_TEC_Pos);
err_cnt.rx_err_cnt = ((can->ESR & CAN_ESR_REC) >> CAN_ESR_REC_Pos);
if (can->ESR & CAN_ESR_BOFF) {
state = CAN_BUS_OFF;
} else if (can->ESR & CAN_ESR_EPVF) {
state = CAN_ERROR_PASSIVE;
} else {
state = CAN_ERROR_ACTIVE;
}
if (data->state_change_isr) {
data->state_change_isr(state, err_cnt);
}
}
static inline
void can_stm32_tx_isr_handler(CAN_TypeDef *can, struct can_stm32_data *data)
{
u32_t bus_off;
bus_off = can->ESR & CAN_ESR_BOFF;
if ((can->TSR & CAN_TSR_RQCP0) | bus_off) {
data->mb0.error_flags =
can->TSR & CAN_TSR_TXOK0 ? CAN_TX_OK :
can->TSR & CAN_TSR_TERR0 ? CAN_TX_ERR :
can->TSR & CAN_TSR_ALST0 ? CAN_TX_ARB_LOST :
bus_off ? CAN_TX_BUS_OFF :
CAN_TX_UNKNOWN;
/* clear the request. */
can->TSR |= CAN_TSR_RQCP0;
can_stm32_signal_tx_complete(&data->mb0);
}
if ((can->TSR & CAN_TSR_RQCP1) | bus_off) {
data->mb1.error_flags =
can->TSR & CAN_TSR_TXOK1 ? CAN_TX_OK :
can->TSR & CAN_TSR_TERR1 ? CAN_TX_ERR :
can->TSR & CAN_TSR_ALST1 ? CAN_TX_ARB_LOST :
bus_off ? CAN_TX_BUS_OFF :
CAN_TX_UNKNOWN;
/* clear the request. */
can->TSR |= CAN_TSR_RQCP1;
can_stm32_signal_tx_complete(&data->mb1);
}
if ((can->TSR & CAN_TSR_RQCP2) | bus_off) {
data->mb2.error_flags =
can->TSR & CAN_TSR_TXOK2 ? CAN_TX_OK :
can->TSR & CAN_TSR_TERR2 ? CAN_TX_ERR :
can->TSR & CAN_TSR_ALST2 ? CAN_TX_ARB_LOST :
bus_off ? CAN_TX_BUS_OFF :
CAN_TX_UNKNOWN;
/* clear the request. */
can->TSR |= CAN_TSR_RQCP2;
can_stm32_signal_tx_complete(&data->mb2);
}
if (can->TSR & CAN_TSR_TME) {
k_sem_give(&data->tx_int_sem);
}
}
#ifdef CONFIG_SOC_SERIES_STM32F0X
static void can_stm32_isr(void *arg)
{
struct device *dev;
struct can_stm32_data *data;
const struct can_stm32_config *cfg;
CAN_TypeDef *can;
dev = (struct device *)arg;
data = DEV_DATA(dev);
cfg = DEV_CFG(dev);
can = cfg->can;
can_stm32_tx_isr_handler(can, data);
can_stm32_rx_isr_handler(can, data);
if (can->MSR & CAN_MSR_ERRI) {
can_stm32_bus_state_change_isr(can, data);
can->MSR |= CAN_MSR_ERRI;
}
}
#else
static void can_stm32_rx_isr(void *arg)
{
struct device *dev;
struct can_stm32_data *data;
const struct can_stm32_config *cfg;
CAN_TypeDef *can;
dev = (struct device *)arg;
data = DEV_DATA(dev);
cfg = DEV_CFG(dev);
can = cfg->can;
can_stm32_rx_isr_handler(can, data);
}
static void can_stm32_tx_isr(void *arg)
{
struct device *dev;
struct can_stm32_data *data;
const struct can_stm32_config *cfg;
CAN_TypeDef *can;
dev = (struct device *)arg;
data = DEV_DATA(dev);
cfg = DEV_CFG(dev);
can = cfg->can;
can_stm32_tx_isr_handler(can, data);
}
static void can_stm32_state_change_isr(void *arg)
{
struct device *dev;
struct can_stm32_data *data;
const struct can_stm32_config *cfg;
CAN_TypeDef *can;
dev = (struct device *)arg;
data = DEV_DATA(dev);
cfg = DEV_CFG(dev);
can = cfg->can;
/*Signal bus-off to waiting tx*/
if (can->MSR & CAN_MSR_ERRI) {
can_stm32_tx_isr_handler(can, data);
can_stm32_bus_state_change_isr(can, data);
can->MSR |= CAN_MSR_ERRI;
}
}
#endif
static int can_enter_init_mode(CAN_TypeDef *can)
{
u32_t start_time;
can->MCR |= CAN_MCR_INRQ;
start_time = k_cycle_get_32();
while ((can->MSR & CAN_MSR_INAK) == 0U) {
if (k_cycle_get_32() - start_time > CAN_INIT_TIMEOUT) {
can->MCR &= ~CAN_MCR_INRQ;
return CAN_TIMEOUT;
}
}
return 0;
}
static int can_leave_init_mode(CAN_TypeDef *can)
{
u32_t start_time;
can->MCR &= ~CAN_MCR_INRQ;
start_time = k_cycle_get_32();
while ((can->MSR & CAN_MSR_INAK) != 0U) {
if (k_cycle_get_32() - start_time > CAN_INIT_TIMEOUT) {
return CAN_TIMEOUT;
}
}
return 0;
}
static int can_leave_sleep_mode(CAN_TypeDef *can)
{
u32_t start_time;
can->MCR &= ~CAN_MCR_SLEEP;
start_time = k_cycle_get_32();
while ((can->MSR & CAN_MSR_SLAK) != 0) {
if (k_cycle_get_32() - start_time > CAN_INIT_TIMEOUT) {
return CAN_TIMEOUT;
}
}
return 0;
}
int can_stm32_runtime_configure(struct device *dev, enum can_mode mode,
u32_t bitrate)
{
CAN_HandleTypeDef hcan;
const struct can_stm32_config *cfg = DEV_CFG(dev);
CAN_TypeDef *can = cfg->can;
struct can_stm32_data *data = DEV_DATA(dev);
struct device *clock;
u32_t clock_rate;
u32_t prescaler;
u32_t reg_mode;
u32_t ts1;
u32_t ts2;
u32_t sjw;
int ret;
clock = device_get_binding(STM32_CLOCK_CONTROL_NAME);
__ASSERT_NO_MSG(clock);
hcan.Instance = can;
ret = clock_control_get_rate(clock, (clock_control_subsys_t *) &cfg->pclken,
&clock_rate);
if (ret != 0) {
LOG_ERR("Failed call clock_control_get_rate: return [%d]", ret);
return -EIO;
}
if (!bitrate) {
bitrate = cfg->bus_speed;
}
prescaler = clock_rate / (BIT_SEG_LENGTH(cfg) * bitrate);
if (prescaler == 0U || prescaler > 1024) {
LOG_ERR("HAL_CAN_Init failed: prescaler > max (%d > 1024)",
prescaler);
return -EINVAL;
}
if (clock_rate % (BIT_SEG_LENGTH(cfg) * bitrate)) {
LOG_ERR("Prescaler is not a natural number! "
"prescaler = clock_rate / ((PROP_SEG1 + SEG2 + 1)"
" * bus_speed); "
"prescaler = %d / ((%d + %d + 1) * %d)",
clock_rate,
cfg->prop_ts1,
cfg->ts2,
bitrate);
}
__ASSERT(cfg->sjw >= 1, "SJW minimum is 1");
__ASSERT(cfg->sjw <= 4, "SJW maximum is 4");
__ASSERT(cfg->prop_ts1 >= 1, "PROP_TS1 minimum is 1");
__ASSERT(cfg->prop_ts1 <= 16, "PROP_TS1 maximum is 16");
__ASSERT(cfg->ts2 >= 1, "TS2 minimum is 1");
__ASSERT(cfg->ts2 <= 8, "TS2 maximum is 8");
ts1 = ((cfg->prop_ts1 - 1) & 0x0F) << CAN_BTR_TS1_Pos;
ts2 = ((cfg->ts2 - 1) & 0x07) << CAN_BTR_TS2_Pos;
sjw = ((cfg->sjw - 1) & 0x07) << CAN_BTR_SJW_Pos;
reg_mode = (mode == CAN_NORMAL_MODE) ? 0U :
(mode == CAN_LOOPBACK_MODE) ? CAN_BTR_LBKM :
(mode == CAN_SILENT_MODE) ? CAN_BTR_SILM :
CAN_BTR_LBKM | CAN_BTR_SILM;
k_mutex_lock(&data->inst_mutex, K_FOREVER);
ret = can_enter_init_mode(can);
if (ret) {
LOG_ERR("Failed to enter init mode");
goto done;
}
can->BTR = reg_mode | sjw | ts1 | ts2 | (prescaler - 1U);
ret = can_leave_init_mode(can);
if (ret) {
LOG_ERR("Failed to leave init mode");
goto done;
}
LOG_DBG("Runtime configure of %s done", dev->name);
ret = 0;
done:
k_mutex_unlock(&data->inst_mutex);
return ret;
}
static int can_stm32_init(struct device *dev)
{
const struct can_stm32_config *cfg = DEV_CFG(dev);
struct can_stm32_data *data = DEV_DATA(dev);
CAN_TypeDef *can = cfg->can;
#if DT_HAS_NODE_STATUS_OKAY(DT_NODELABEL(can2))
CAN_TypeDef *master_can = cfg->master_can;
#endif
struct device *clock;
int ret;
k_mutex_init(&data->inst_mutex);
k_sem_init(&data->tx_int_sem, 0, 1);
k_sem_init(&data->mb0.tx_int_sem, 0, 1);
k_sem_init(&data->mb1.tx_int_sem, 0, 1);
k_sem_init(&data->mb2.tx_int_sem, 0, 1);
data->mb0.tx_callback = NULL;
data->mb1.tx_callback = NULL;
data->mb2.tx_callback = NULL;
data->state_change_isr = NULL;
data->filter_usage = (1ULL << CAN_MAX_NUMBER_OF_FILTERS) - 1ULL;
(void)memset(data->rx_cb, 0, sizeof(data->rx_cb));
(void)memset(data->cb_arg, 0, sizeof(data->cb_arg));
clock = device_get_binding(STM32_CLOCK_CONTROL_NAME);
__ASSERT_NO_MSG(clock);
ret = clock_control_on(clock, (clock_control_subsys_t *) &cfg->pclken);
if (ret != 0) {
LOG_ERR("HAL_CAN_Init clock control on failed: %d", ret);
return -EIO;
}
ret = can_leave_sleep_mode(can);
if (ret) {
LOG_ERR("Failed to exit sleep mode");
return ret;
}
ret = can_enter_init_mode(can);
if (ret) {
LOG_ERR("Failed to enter init mode");
return ret;
}
#if DT_HAS_NODE_STATUS_OKAY(DT_NODELABEL(can2))
master_can->FMR &= ~CAN_FMR_CAN2SB; /* Assign all filters to CAN2 */
#endif
/* Set TX priority to chronological order */
can->MCR |= CAN_MCR_TXFP;
can->MCR &= ~CAN_MCR_TTCM & ~CAN_MCR_TTCM & ~CAN_MCR_ABOM &
~CAN_MCR_AWUM & ~CAN_MCR_NART & ~CAN_MCR_RFLM;
#ifdef CONFIG_CAN_RX_TIMESTAMP
can->MCR |= CAN_MCR_TTCM;
#endif
#ifdef CONFIG_CAN_AUTO_BUS_OFF_RECOVERY
can->MCR |= CAN_MCR_ABOM;
#endif
ret = can_stm32_runtime_configure(dev, CAN_NORMAL_MODE, 0);
if (ret) {
return ret;
}
/* Leave sleep mode after reset*/
can->MCR &= ~CAN_MCR_SLEEP;
cfg->config_irq(can);
can->IER |= CAN_IER_TMEIE;
LOG_INF("Init of %s done", dev->name);
return 0;
}
static void can_stm32_register_state_change_isr(struct device *dev,
can_state_change_isr_t isr)
{
struct can_stm32_data *data = DEV_DATA(dev);
const struct can_stm32_config *cfg = DEV_CFG(dev);
CAN_TypeDef *can = cfg->can;
data->state_change_isr = isr;
if (isr == NULL) {
can->IER &= ~CAN_IER_EPVIE;
} else {
can->IER |= CAN_IER_EPVIE;
}
}
static enum can_state can_stm32_get_state(struct device *dev,
struct can_bus_err_cnt *err_cnt)
{
const struct can_stm32_config *cfg = DEV_CFG(dev);
CAN_TypeDef *can = cfg->can;
if (err_cnt) {
err_cnt->tx_err_cnt =
((can->ESR & CAN_ESR_TEC) >> CAN_ESR_TEC_Pos);
err_cnt->rx_err_cnt =
((can->ESR & CAN_ESR_REC) >> CAN_ESR_REC_Pos);
}
if (can->ESR & CAN_ESR_BOFF) {
return CAN_BUS_OFF;
}
if (can->ESR & CAN_ESR_EPVF) {
return CAN_ERROR_PASSIVE;
}
return CAN_ERROR_ACTIVE;
}
#ifndef CONFIG_CAN_AUTO_BUS_OFF_RECOVERY
int can_stm32_recover(struct device *dev, k_timeout_t timeout)
{
const struct can_stm32_config *cfg = DEV_CFG(dev);
struct can_stm32_data *data = DEV_DATA(dev);
CAN_TypeDef *can = cfg->can;
int ret = CAN_TIMEOUT;
s64_t start_time;
if (!(can->ESR & CAN_ESR_BOFF)) {
return 0;
}
if (k_mutex_lock(&data->inst_mutex, K_FOREVER)) {
return CAN_TIMEOUT;
}
ret = can_enter_init_mode(can);
if (ret) {
goto done;
}
can_leave_init_mode(can);
start_time = k_uptime_ticks();
while (can->ESR & CAN_ESR_BOFF) {
if (timeout != K_FOREVER &&
k_uptime_ticks() - start_time >= timeout.ticks) {
goto done;
}
}
ret = 0;
done:
k_mutex_unlock(&data->inst_mutex);
return ret;
}
#endif /* CONFIG_CAN_AUTO_BUS_OFF_RECOVERY */
int can_stm32_send(struct device *dev, const struct zcan_frame *msg,
k_timeout_t timeout, can_tx_callback_t callback,
void *callback_arg)
{
const struct can_stm32_config *cfg = DEV_CFG(dev);
struct can_stm32_data *data = DEV_DATA(dev);
CAN_TypeDef *can = cfg->can;
u32_t transmit_status_register = can->TSR;
CAN_TxMailBox_TypeDef *mailbox = NULL;
struct can_mailbox *mb = NULL;
LOG_DBG("Sending %d bytes on %s. "
"Id: 0x%x, "
"ID type: %s, "
"Remote Frame: %s"
, msg->dlc, dev->name
, msg->id_type == CAN_STANDARD_IDENTIFIER ?
msg->std_id : msg->ext_id
, msg->id_type == CAN_STANDARD_IDENTIFIER ?
"standard" : "extended"
, msg->rtr == CAN_DATAFRAME ? "no" : "yes");
__ASSERT(msg->dlc == 0U || msg->data != NULL, "Dataptr is null");
if (msg->dlc > CAN_MAX_DLC) {
LOG_ERR("DLC of %d exceeds maximum (%d)", msg->dlc, CAN_MAX_DLC);
return CAN_TX_EINVAL;
}
if (can->ESR & CAN_ESR_BOFF) {
return CAN_TX_BUS_OFF;
}
k_mutex_lock(&data->inst_mutex, K_FOREVER);
while (!(transmit_status_register & CAN_TSR_TME)) {
k_mutex_unlock(&data->inst_mutex);
LOG_DBG("Transmit buffer full");
if (k_sem_take(&data->tx_int_sem, timeout)) {
return CAN_TIMEOUT;
}
k_mutex_lock(&data->inst_mutex, K_FOREVER);
transmit_status_register = can->TSR;
}
if (transmit_status_register & CAN_TSR_TME0) {
LOG_DBG("Using mailbox 0");
mailbox = &can->sTxMailBox[0];
mb = &(data->mb0);
} else if (transmit_status_register & CAN_TSR_TME1) {
LOG_DBG("Using mailbox 1");
mailbox = &can->sTxMailBox[1];
mb = &data->mb1;
} else if (transmit_status_register & CAN_TSR_TME2) {
LOG_DBG("Using mailbox 2");
mailbox = &can->sTxMailBox[2];
mb = &data->mb2;
}
mb->tx_callback = callback;
mb->callback_arg = callback_arg;
k_sem_reset(&mb->tx_int_sem);
/* mailbix identifier register setup */
mailbox->TIR &= CAN_TI0R_TXRQ;
if (msg->id_type == CAN_STANDARD_IDENTIFIER) {
mailbox->TIR |= (msg->std_id << CAN_TI0R_STID_Pos);
} else {
mailbox->TIR |= (msg->ext_id << CAN_TI0R_EXID_Pos)
| CAN_TI0R_IDE;
}
if (msg->rtr == CAN_REMOTEREQUEST) {
mailbox->TIR |= CAN_TI1R_RTR;
}
mailbox->TDTR = (mailbox->TDTR & ~CAN_TDT1R_DLC) |
((msg->dlc & 0xF) << CAN_TDT1R_DLC_Pos);
mailbox->TDLR = msg->data_32[0];
mailbox->TDHR = msg->data_32[1];
mailbox->TIR |= CAN_TI0R_TXRQ;
k_mutex_unlock(&data->inst_mutex);
if (callback == NULL) {
k_sem_take(&mb->tx_int_sem, K_FOREVER);
return mb->error_flags;
}
return 0;
}
static inline int can_stm32_check_free(void **arr, int start, int end)
{
int i;
for (i = start; i <= end; i++) {
if (arr[i] != NULL) {
return 0;
}
}
return 1;
}
static int can_stm32_shift_arr(void **arr, int start, int count)
{
void **start_ptr = arr + start;
size_t cnt;
if (start > CONFIG_CAN_MAX_FILTER) {
return CAN_NO_FREE_FILTER;
}
if (count > 0) {
void *move_dest;
/* Check if nothing used will be overwritten */
if (!can_stm32_check_free(arr, CONFIG_CAN_MAX_FILTER - count,
CONFIG_CAN_MAX_FILTER - 1)) {
return CAN_NO_FREE_FILTER;
}
/* No need to shift. Destination is already outside the arr*/
if ((start + count) >= CONFIG_CAN_MAX_FILTER) {
return 0;
}
cnt = (CONFIG_CAN_MAX_FILTER - start - count) * sizeof(void *);
move_dest = start_ptr + count;
memmove(move_dest, start_ptr, cnt);
(void)memset(start_ptr, 0, count * sizeof(void *));
} else if (count < 0) {
count = -count;
if (start - count < 0) {
return CAN_NO_FREE_FILTER;
}
cnt = (CONFIG_CAN_MAX_FILTER - start) * sizeof(void *);
memmove(start_ptr - count, start_ptr, cnt);
(void)memset(arr + CONFIG_CAN_MAX_FILTER - count, 0,
count * sizeof(void *));
}
return 0;
}
enum can_filter_type can_stm32_get_filter_type(int bank_nr, u32_t mode_reg,
u32_t scale_reg)
{
u32_t mode_masked = (mode_reg >> bank_nr) & 0x01;
u32_t scale_masked = (scale_reg >> bank_nr) & 0x01;
enum can_filter_type type = (scale_masked << 1) | mode_masked;
return type;
}
static int can_calc_filter_index(int filter_nr, u32_t mode_reg, u32_t scale_reg)
{
int filter_bank = filter_nr / 4;
int cnt = 0;
u32_t mode_masked, scale_masked;
enum can_filter_type filter_type;
/*count filters in the banks before */
for (int i = 0; i < filter_bank; i++) {
filter_type = can_stm32_get_filter_type(i, mode_reg, scale_reg);
cnt += filter_in_bank[filter_type];
}
/* plus the filters in the same bank */
mode_masked = mode_reg & (1U << filter_bank);
scale_masked = scale_reg & (1U << filter_bank);
cnt += (!scale_masked && mode_masked) ? filter_nr & 0x03 :
(filter_nr & 0x03) >> 1;
return cnt;
}
static void can_stm32_set_filter_bank(int filter_nr,
CAN_FilterRegister_TypeDef *filter_reg,
enum can_filter_type filter_type,
u32_t id, u32_t mask)
{
switch (filter_type) {
case CAN_FILTER_STANDARD:
switch (filter_nr & 0x03) {
case 0:
filter_reg->FR1 = (filter_reg->FR1 & 0xFFFF0000) | id;
break;
case 1:
filter_reg->FR1 = (filter_reg->FR1 & 0x0000FFFF)
| (id << 16);
break;
case 2:
filter_reg->FR2 = (filter_reg->FR2 & 0xFFFF0000) | id;
break;
case 3:
filter_reg->FR2 = (filter_reg->FR2 & 0x0000FFFF)
| (id << 16);
break;
}
break;
case CAN_FILTER_STANDARD_MASKED:
switch (filter_nr & 0x02) {
case 0:
filter_reg->FR1 = id | (mask << 16);
break;
case 2:
filter_reg->FR2 = id | (mask << 16);
break;
}
break;
case CAN_FILTER_EXTENDED:
switch (filter_nr & 0x02) {
case 0:
filter_reg->FR1 = id;
break;
case 2:
filter_reg->FR2 = id;
break;
}
break;
case CAN_FILTER_EXTENDED_MASKED:
filter_reg->FR1 = id;
filter_reg->FR2 = mask;
break;
}
}
static inline void can_stm32_set_mode_scale(enum can_filter_type filter_type,
u32_t *mode_reg, u32_t *scale_reg,
int bank_nr)
{
u32_t mode_reg_bit = (filter_type & 0x01) << bank_nr;
u32_t scale_reg_bit = (filter_type >> 1) << bank_nr;
*mode_reg &= ~(1 << bank_nr);
*mode_reg |= mode_reg_bit;
*scale_reg &= ~(1 << bank_nr);
*scale_reg |= scale_reg_bit;
}
static inline u32_t can_generate_std_mask(const struct zcan_filter *filter)
{
return (filter->std_id_mask << CAN_FIRX_STD_ID_POS) |
(filter->rtr_mask << CAN_FIRX_STD_RTR_POS) |
(1U << CAN_FIRX_STD_IDE_POS);
}
static inline u32_t can_generate_ext_mask(const struct zcan_filter *filter)
{
return (filter->ext_id_mask << CAN_FIRX_EXT_EXT_ID_POS) |
(filter->rtr_mask << CAN_FIRX_EXT_RTR_POS) |
(1U << CAN_FIRX_EXT_IDE_POS);
}
static inline u32_t can_generate_std_id(const struct zcan_filter *filter)
{
return (filter->std_id << CAN_FIRX_STD_ID_POS) |
(filter->rtr << CAN_FIRX_STD_RTR_POS);
}
static inline u32_t can_generate_ext_id(const struct zcan_filter *filter)
{
return (filter->ext_id << CAN_FIRX_EXT_EXT_ID_POS) |
(filter->rtr << CAN_FIRX_EXT_RTR_POS) |
(1U << CAN_FIRX_EXT_IDE_POS);
}
static inline int can_stm32_set_filter(const struct zcan_filter *filter,
struct can_stm32_data *device_data,
CAN_TypeDef *can,
int *filter_index)
{
u32_t mask = 0U;
u32_t id = 0U;
int filter_nr = 0;
int filter_index_new = CAN_NO_FREE_FILTER;
int bank_nr;
u32_t bank_bit;
int register_demand;
enum can_filter_type filter_type;
enum can_filter_type bank_mode;
if (filter->id_type == CAN_STANDARD_IDENTIFIER) {
id = can_generate_std_id(filter);
filter_type = CAN_FILTER_STANDARD;
if (filter->std_id_mask != CAN_STD_ID_MASK) {
mask = can_generate_std_mask(filter);
filter_type = CAN_FILTER_STANDARD_MASKED;
}
} else {
id = can_generate_ext_id(filter);
filter_type = CAN_FILTER_EXTENDED;
if (filter->ext_id_mask != CAN_EXT_ID_MASK) {
mask = can_generate_ext_mask(filter);
filter_type = CAN_FILTER_EXTENDED_MASKED;
}
}
register_demand = reg_demand[filter_type];
LOG_DBG("Setting filter ID: 0x%x, mask: 0x%x", filter->ext_id,
filter->ext_id_mask);
LOG_DBG("Filter type: %s ID %s mask (%d)",
(filter_type == CAN_FILTER_STANDARD ||
filter_type == CAN_FILTER_STANDARD_MASKED) ?
"standard" : "extended",
(filter_type == CAN_FILTER_STANDARD_MASKED ||
filter_type == CAN_FILTER_EXTENDED_MASKED) ?
"with" : "without",
filter_type);
do {
u64_t usage_shifted = (device_data->filter_usage >> filter_nr);
u64_t usage_demand_mask = (1ULL << register_demand) - 1;
bool bank_is_empty;
bank_nr = filter_nr / 4;
bank_bit = (1U << bank_nr);
bank_mode = can_stm32_get_filter_type(bank_nr, can->FM1R,
can->FS1R);
bank_is_empty = CAN_BANK_IS_EMPTY(device_data->filter_usage,
bank_nr);
if (!bank_is_empty && bank_mode != filter_type) {
filter_nr = (bank_nr + 1) * 4;
} else if (usage_shifted & usage_demand_mask) {
device_data->filter_usage &=
~(usage_demand_mask << filter_nr);
break;
} else {
filter_nr += register_demand;
}
if (!usage_shifted) {
LOG_INF("No free filter bank found");
return CAN_NO_FREE_FILTER;
}
} while (filter_nr < CAN_MAX_NUMBER_OF_FILTERS);
/* set the filter init mode */
can->FMR |= CAN_FMR_FINIT;
can->FA1R &= ~bank_bit;
/* TODO fifo balancing */
if (filter_type != bank_mode) {
int shift_width, start_index;
int res;
u32_t mode_reg = can->FM1R;
u32_t scale_reg = can->FS1R;
can_stm32_set_mode_scale(filter_type, &mode_reg, &scale_reg,
bank_nr);
shift_width = filter_in_bank[filter_type] - filter_in_bank[bank_mode];
filter_index_new = can_calc_filter_index(filter_nr, mode_reg,
scale_reg);
start_index = filter_index_new + filter_in_bank[bank_mode];
if (shift_width && start_index <= CAN_MAX_NUMBER_OF_FILTERS) {
res = can_stm32_shift_arr((void **)device_data->rx_cb,
start_index,
shift_width);
res |= can_stm32_shift_arr(device_data->cb_arg,
start_index,
shift_width);
if (filter_index_new >= CONFIG_CAN_MAX_FILTER || res) {
LOG_INF("No space for a new filter!");
filter_nr = CAN_NO_FREE_FILTER;
goto done;
}
}
can->FM1R = mode_reg;
can->FS1R = scale_reg;
} else {
filter_index_new = can_calc_filter_index(filter_nr, can->FM1R,
can->FS1R);
if (filter_index_new >= CAN_MAX_NUMBER_OF_FILTERS) {
filter_nr = CAN_NO_FREE_FILTER;
goto done;
}
}
can_stm32_set_filter_bank(filter_nr, &can->sFilterRegister[bank_nr],
filter_type, id, mask);
done:
can->FA1R |= bank_bit;
can->FMR &= ~(CAN_FMR_FINIT);
LOG_DBG("Filter set! Filter number: %d (index %d)",
filter_nr, filter_index_new);
*filter_index = filter_index_new;
return filter_nr;
}
static inline int can_stm32_attach(struct device *dev, can_rx_callback_t cb,
void *cb_arg,
const struct zcan_filter *filter)
{
const struct can_stm32_config *cfg = DEV_CFG(dev);
struct can_stm32_data *data = DEV_DATA(dev);
CAN_TypeDef *can = cfg->master_can;
int filter_index = 0;
int filter_nr;
filter_nr = can_stm32_set_filter(filter, data, can, &filter_index);
if (filter_nr != CAN_NO_FREE_FILTER) {
data->rx_cb[filter_index] = cb;
data->cb_arg[filter_index] = cb_arg;
}
return filter_nr;
}
int can_stm32_attach_isr(struct device *dev, can_rx_callback_t isr,
void *cb_arg,
const struct zcan_filter *filter)
{
struct can_stm32_data *data = DEV_DATA(dev);
int filter_nr;
k_mutex_lock(&data->inst_mutex, K_FOREVER);
filter_nr = can_stm32_attach(dev, isr, cb_arg, filter);
k_mutex_unlock(&data->inst_mutex);
return filter_nr;
}
void can_stm32_detach(struct device *dev, int filter_nr)
{
const struct can_stm32_config *cfg = DEV_CFG(dev);
struct can_stm32_data *data = DEV_DATA(dev);
CAN_TypeDef *can = cfg->master_can;
int bank_nr;
int filter_index;
u32_t bank_bit;
u32_t mode_reg;
u32_t scale_reg;
enum can_filter_type type;
u32_t reset_mask;
__ASSERT_NO_MSG(filter_nr >= 0 && filter_nr < CAN_MAX_NUMBER_OF_FILTERS);
k_mutex_lock(&data->inst_mutex, K_FOREVER);
bank_nr = filter_nr / 4;
bank_bit = (1U << bank_nr);
mode_reg = can->FM1R;
scale_reg = can->FS1R;
filter_index = can_calc_filter_index(filter_nr, mode_reg, scale_reg);
type = can_stm32_get_filter_type(bank_nr, mode_reg, scale_reg);
LOG_DBG("Detatch filter number %d (index %d), type %d", filter_nr,
filter_index,
type);
reset_mask = ((1 << (reg_demand[type])) - 1) << filter_nr;
data->filter_usage |= reset_mask;
can->FMR |= CAN_FMR_FINIT;
can->FA1R &= ~bank_bit;
can_stm32_set_filter_bank(filter_nr, &can->sFilterRegister[bank_nr],
type, 0, 0xFFFFFFFF);
if (!CAN_BANK_IS_EMPTY(data->filter_usage, bank_nr)) {
can->FA1R |= bank_bit;
} else {
LOG_DBG("Bank number %d is empty -> deakivate", bank_nr);
}
can->FMR &= ~(CAN_FMR_FINIT);
data->rx_cb[filter_index] = NULL;
data->cb_arg[filter_index] = NULL;
k_mutex_unlock(&data->inst_mutex);
}
static const struct can_driver_api can_api_funcs = {
.configure = can_stm32_runtime_configure,
.send = can_stm32_send,
.attach_isr = can_stm32_attach_isr,
.detach = can_stm32_detach,
.get_state = can_stm32_get_state,
#ifndef CONFIG_CAN_AUTO_BUS_OFF_RECOVERY
.recover = can_stm32_recover,
#endif
.register_state_change_isr = can_stm32_register_state_change_isr
};
#if DT_HAS_NODE_STATUS_OKAY(DT_NODELABEL(can1)) && \
DT_NODE_HAS_COMPAT_STATUS_OKAY(DT_NODELABEL(can1), st_stm32_can)
static void config_can_1_irq(CAN_TypeDef *can);
static const struct can_stm32_config can_stm32_cfg_1 = {
.can = (CAN_TypeDef *)DT_REG_ADDR(DT_NODELABEL(can1)),
.master_can = (CAN_TypeDef *)DT_REG_ADDR(DT_NODELABEL(can1)),
.bus_speed = DT_PROP(DT_NODELABEL(can1), bus_speed),
.sjw = DT_PROP(DT_NODELABEL(can1), sjw),
.prop_ts1 = DT_PROP(DT_NODELABEL(can1), prop_seg) +
DT_PROP(DT_NODELABEL(can1), phase_seg1),
.ts2 = DT_PROP(DT_NODELABEL(can1), phase_seg2),
.pclken = {
.enr = DT_CLOCKS_CELL(DT_NODELABEL(can1), bits),
.bus = DT_CLOCKS_CELL(DT_NODELABEL(can1), bus),
},
.config_irq = config_can_1_irq
};
static struct can_stm32_data can_stm32_dev_data_1;
DEVICE_AND_API_INIT(can_stm32_1, DT_LABEL(DT_NODELABEL(can1)), &can_stm32_init,
&can_stm32_dev_data_1, &can_stm32_cfg_1,
POST_KERNEL, CONFIG_KERNEL_INIT_PRIORITY_DEVICE,
&can_api_funcs);
static void config_can_1_irq(CAN_TypeDef *can)
{
LOG_DBG("Enable CAN1 IRQ");
#ifdef CONFIG_SOC_SERIES_STM32F0X
IRQ_CONNECT(DT_IRQN(DT_NODELABEL(can1)),
DT_IRQ(DT_NODELABEL(can1), priority),
can_stm32_isr, DEVICE_GET(can_stm32_1), 0);
irq_enable(DT_IRQN(DT_NODELABEL(can1)));
#else
IRQ_CONNECT(DT_IRQ_BY_NAME(DT_NODELABEL(can1), rx0, irq),
DT_IRQ_BY_NAME(DT_NODELABEL(can1), rx0, priority),
can_stm32_rx_isr, DEVICE_GET(can_stm32_1), 0);
irq_enable(DT_IRQ_BY_NAME(DT_NODELABEL(can1), rx0, irq));
IRQ_CONNECT(DT_IRQ_BY_NAME(DT_NODELABEL(can1), tx, irq),
DT_IRQ_BY_NAME(DT_NODELABEL(can1), tx, priority),
can_stm32_tx_isr, DEVICE_GET(can_stm32_1), 0);
irq_enable(DT_IRQ_BY_NAME(DT_NODELABEL(can1), tx, irq));
IRQ_CONNECT(DT_IRQ_BY_NAME(DT_NODELABEL(can1), sce, irq),
DT_IRQ_BY_NAME(DT_NODELABEL(can1), sce, priority),
can_stm32_state_change_isr, DEVICE_GET(can_stm32_1), 0);
irq_enable(DT_IRQ_BY_NAME(DT_NODELABEL(can1), sce, irq));
#endif
can->IER |= CAN_IER_TMEIE | CAN_IER_ERRIE | CAN_IER_FMPIE0 |
CAN_IER_FMPIE1 | CAN_IER_BOFIE;
}
#if defined(CONFIG_NET_SOCKETS_CAN)
#include "socket_can_generic.h"
static int socket_can_init_1(struct device *dev)
{
struct device *can_dev = DEVICE_GET(can_stm32_1);
struct socket_can_context *socket_context = dev->driver_data;
LOG_DBG("Init socket CAN device %p (%s) for dev %p (%s)",
dev, dev->name, can_dev, can_dev->name);
socket_context->can_dev = can_dev;
socket_context->msgq = &socket_can_msgq;
socket_context->rx_tid =
k_thread_create(&socket_context->rx_thread_data,
rx_thread_stack,
K_THREAD_STACK_SIZEOF(rx_thread_stack),
rx_thread, socket_context, NULL, NULL,
RX_THREAD_PRIORITY, 0, K_NO_WAIT);
return 0;
}
NET_DEVICE_INIT(socket_can_stm32_1, SOCKET_CAN_NAME_1, socket_can_init_1,
device_pm_control_nop, &socket_can_context_1, NULL,
CONFIG_KERNEL_INIT_PRIORITY_DEVICE,
&socket_can_api,
CANBUS_RAW_L2, NET_L2_GET_CTX_TYPE(CANBUS_RAW_L2), CAN_MTU);
#endif /* CONFIG_NET_SOCKETS_CAN */
#endif /* DT_HAS_NODE_STATUS_OKAY(DT_NODELABEL(can1)) */
#if DT_HAS_NODE_STATUS_OKAY(DT_NODELABEL(can2)) && \
DT_NODE_HAS_COMPAT_STATUS_OKAY(DT_NODELABEL(can2), st_stm32_can)
static void config_can_2_irq(CAN_TypeDef *can);
static const struct can_stm32_config can_stm32_cfg_2 = {
.can = (CAN_TypeDef *)DT_REG_ADDR(DT_NODELABEL(can2)),
.master_can = (CAN_TypeDef *)DT_PROP(DT_NODELABEL(can2),
master_can_reg),
.bus_speed = DT_PROP(DT_NODELABEL(can2), bus_speed),
.sjw = DT_PROP(DT_NODELABEL(can2), sjw),
.prop_ts1 = DT_PROP(DT_NODELABEL(can2), prop_seg) +
DT_PROP(DT_NODELABEL(can2), phase_seg1),
.ts2 = DT_PROP(DT_NODELABEL(can2), phase_seg2),
.pclken = {
.enr = DT_CLOCKS_CELL(DT_NODELABEL(can2), bits),
.bus = DT_CLOCKS_CELL(DT_NODELABEL(can2), bus),
},
.config_irq = config_can_2_irq
};
static struct can_stm32_data can_stm32_dev_data_2;
DEVICE_AND_API_INIT(can_stm32_2, DT_LABEL(DT_NODELABEL(can2)), &can_stm32_init,
&can_stm32_dev_data_2, &can_stm32_cfg_2,
POST_KERNEL, CONFIG_KERNEL_INIT_PRIORITY_DEVICE,
&can_api_funcs);
static void config_can_2_irq(CAN_TypeDef *can)
{
LOG_DBG("Enable CAN2 IRQ");
IRQ_CONNECT(DT_IRQ_BY_NAME(DT_NODELABEL(can2), rx0, irq),
DT_IRQ_BY_NAME(DT_NODELABEL(can2), rx0, priority),
can_stm32_rx_isr, DEVICE_GET(can_stm32_2), 0);
irq_enable(DT_IRQ_BY_NAME(DT_NODELABEL(can2), rx0, irq));
IRQ_CONNECT(DT_IRQ_BY_NAME(DT_NODELABEL(can2), tx, irq),
DT_IRQ_BY_NAME(DT_NODELABEL(can2), tx, priority),
can_stm32_tx_isr, DEVICE_GET(can_stm32_2), 0);
irq_enable(DT_IRQ_BY_NAME(DT_NODELABEL(can2), tx, irq));
IRQ_CONNECT(DT_IRQ_BY_NAME(DT_NODELABEL(can2), sce, irq),
DT_IRQ_BY_NAME(DT_NODELABEL(can2), sce, priority),
can_stm32_state_change_isr, DEVICE_GET(can_stm32_2), 0);
irq_enable(DT_IRQ_BY_NAME(DT_NODELABEL(can2), sce, irq));
can->IER |= CAN_IER_TMEIE | CAN_IER_ERRIE | CAN_IER_FMPIE0 |
CAN_IER_FMPIE1 | CAN_IER_BOFIE;
}
#if defined(CONFIG_NET_SOCKETS_CAN)
#include "socket_can_generic.h"
static int socket_can_init_2(struct device *dev)
{
struct device *can_dev = DEVICE_GET(can_stm32_2);
struct socket_can_context *socket_context = dev->driver_data;
LOG_DBG("Init socket CAN device %p (%s) for dev %p (%s)",
dev, dev->name, can_dev, can_dev->name);
socket_context->can_dev = can_dev;
socket_context->msgq = &socket_can_msgq;
socket_context->rx_tid =
k_thread_create(&socket_context->rx_thread_data,
rx_thread_stack,
K_THREAD_STACK_SIZEOF(rx_thread_stack),
rx_thread, socket_context, NULL, NULL,
RX_THREAD_PRIORITY, 0, K_NO_WAIT);
return 0;
}
NET_DEVICE_INIT(socket_can_stm32_2, SOCKET_CAN_NAME_2, socket_can_init_2,
device_pm_control_nop, &socket_can_context_2, NULL,
CONFIG_KERNEL_INIT_PRIORITY_DEVICE,
&socket_can_api,
CANBUS_RAW_L2, NET_L2_GET_CTX_TYPE(CANBUS_RAW_L2), CAN_MTU);
#endif /* CONFIG_NET_SOCKETS_CAN */
#endif /* DT_HAS_NODE_STATUS_OKAY(DT_NODELABEL(can2)) */
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