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pigweed / third_party / github / zephyrproject-rtos / zephyr / bd6e04411e6cfb34ff871b3436f7b05bdcd639fb / . / drivers / serial / uart_sam0.c
blob: 2e15e8642c4b69c6845be21ed1b230b9042ae604 [file] [log] [blame]
/*
* Copyright (c) 2017 Google LLC.
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <device.h>
#include <errno.h>
#include <init.h>
#include <sys/__assert.h>
#include <soc.h>
#include <drivers/uart.h>
#include <drivers/dma.h>
/* Device constant configuration parameters */
struct uart_sam0_dev_cfg {
SercomUsart *regs;
u32_t baudrate;
u32_t pads;
u32_t pm_apbcmask;
u16_t gclk_clkctrl_id;
#if CONFIG_UART_INTERRUPT_DRIVEN || CONFIG_UART_ASYNC_API
void (*irq_config_func)(struct device *dev);
#endif
#if CONFIG_UART_ASYNC_API
u8_t tx_dma_request;
u8_t tx_dma_channel;
u8_t rx_dma_request;
u8_t rx_dma_channel;
#endif
};
/* Device run time data */
struct uart_sam0_dev_data {
#ifdef CONFIG_UART_INTERRUPT_DRIVEN
uart_irq_callback_user_data_t cb;
void *cb_data;
#endif
#if CONFIG_UART_ASYNC_API
const struct uart_sam0_dev_cfg *cfg;
struct device *dma;
uart_callback_t async_cb;
void *async_cb_data;
struct k_delayed_work tx_timeout_work;
const u8_t *tx_buf;
size_t tx_len;
struct k_delayed_work rx_timeout_work;
size_t rx_timeout_time;
size_t rx_timeout_chunk;
u32_t rx_timeout_start;
u8_t *rx_buf;
size_t rx_len;
size_t rx_processed_len;
u8_t *rx_next_buf;
size_t rx_next_len;
bool rx_waiting_for_irq;
bool rx_timeout_from_isr;
#endif
};
#define DEV_CFG(dev) \
((const struct uart_sam0_dev_cfg *const)(dev)->config->config_info)
#define DEV_DATA(dev) ((struct uart_sam0_dev_data * const)(dev)->driver_data)
static void wait_synchronization(SercomUsart *const usart)
{
#if defined(SERCOM_USART_SYNCBUSY_MASK)
/* SYNCBUSY is a register */
while ((usart->SYNCBUSY.reg & SERCOM_USART_SYNCBUSY_MASK) != 0) {
}
#elif defined(SERCOM_USART_STATUS_SYNCBUSY)
/* SYNCBUSY is a bit */
while ((usart->STATUS.reg & SERCOM_USART_STATUS_SYNCBUSY) != 0) {
}
#else
#error Unsupported device
#endif
}
static int uart_sam0_set_baudrate(SercomUsart *const usart, u32_t baudrate,
u32_t clk_freq_hz)
{
u64_t tmp;
u16_t baud;
tmp = (u64_t)baudrate << 20;
tmp = (tmp + (clk_freq_hz >> 1)) / clk_freq_hz;
/* Verify that the calculated result is within range */
if (tmp < 1 || tmp > UINT16_MAX) {
return -ERANGE;
}
baud = 65536 - (u16_t)tmp;
usart->BAUD.reg = baud;
wait_synchronization(usart);
return 0;
}
#if CONFIG_UART_ASYNC_API
static void uart_sam0_dma_tx_done(void *arg, u32_t id, int error_code)
{
ARG_UNUSED(id);
ARG_UNUSED(error_code);
struct device *dev = arg;
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
k_delayed_work_cancel(&dev_data->tx_timeout_work);
int key = irq_lock();
struct uart_event evt = {
.type = UART_TX_DONE,
.data.tx = {
.buf = dev_data->tx_buf,
.len = dev_data->tx_len,
},
};
dev_data->tx_buf = NULL;
dev_data->tx_len = 0U;
if (evt.data.tx.len != 0U && dev_data->async_cb) {
dev_data->async_cb(&evt, dev_data->async_cb_data);
}
irq_unlock(key);
}
static int uart_sam0_tx_halt(struct uart_sam0_dev_data *dev_data)
{
const struct uart_sam0_dev_cfg *const cfg = dev_data->cfg;
int key = irq_lock();
size_t tx_active = dev_data->tx_len;
struct dma_status st;
struct uart_event evt = {
.type = UART_TX_ABORTED,
.data.tx = {
.buf = dev_data->tx_buf,
.len = 0U,
},
};
dev_data->tx_buf = NULL;
dev_data->tx_len = 0U;
dma_stop(dev_data->dma, cfg->tx_dma_channel);
irq_unlock(key);
if (dma_get_status(dev_data->dma, cfg->tx_dma_channel, &st) == 0) {
evt.data.tx.len = tx_active - st.pending_length;
}
if (tx_active) {
if (dev_data->async_cb) {
dev_data->async_cb(&evt, dev_data->async_cb_data);
}
} else {
return -EINVAL;
}
return 0;
}
static void uart_sam0_tx_timeout(struct k_work *work)
{
struct uart_sam0_dev_data *dev_data = CONTAINER_OF(work,
struct uart_sam0_dev_data, tx_timeout_work);
uart_sam0_tx_halt(dev_data);
}
static void uart_sam0_notify_rx_processed(struct uart_sam0_dev_data *dev_data,
size_t processed)
{
if (!dev_data->async_cb) {
return;
}
if (dev_data->rx_processed_len == processed) {
return;
}
struct uart_event evt = {
.type = UART_RX_RDY,
.data.rx = {
.buf = dev_data->rx_buf,
.offset = dev_data->rx_processed_len,
.len = processed - dev_data->rx_processed_len,
},
};
dev_data->rx_processed_len = processed;
dev_data->async_cb(&evt, dev_data->async_cb_data);
}
static void uart_sam0_dma_rx_done(void *arg, u32_t id, int error_code)
{
ARG_UNUSED(id);
ARG_UNUSED(error_code);
struct device *dev = arg;
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
const struct uart_sam0_dev_cfg *const cfg = dev_data->cfg;
SercomUsart * const regs = cfg->regs;
int key = irq_lock();
if (dev_data->rx_len == 0U) {
irq_unlock(key);
return;
}
uart_sam0_notify_rx_processed(dev_data, dev_data->rx_len);
if (dev_data->async_cb) {
struct uart_event evt = {
.type = UART_RX_BUF_RELEASED,
.data.rx_buf = {
.buf = dev_data->rx_buf,
},
};
dev_data->async_cb(&evt, dev_data->async_cb_data);
}
/* No next buffer, so end the transfer */
if (!dev_data->rx_next_len) {
dev_data->rx_buf = NULL;
dev_data->rx_len = 0U;
if (dev_data->async_cb) {
struct uart_event evt = {
.type = UART_RX_DISABLED,
};
dev_data->async_cb(&evt, dev_data->async_cb_data);
}
irq_unlock(key);
return;
}
dev_data->rx_buf = dev_data->rx_next_buf;
dev_data->rx_len = dev_data->rx_next_len;
dev_data->rx_next_buf = NULL;
dev_data->rx_next_len = 0U;
dev_data->rx_processed_len = 0U;
dma_reload(dev_data->dma, cfg->rx_dma_channel,
(u32_t)(&(regs->DATA.reg)),
(u32_t)dev_data->rx_buf, dev_data->rx_len);
/*
* If there should be a timeout, handle starting the DMA in the
* ISR, since reception resets it and DMA completion implies
* reception. This also catches the case of DMA completion during
* timeout handling.
*/
if (dev_data->rx_timeout_time != K_FOREVER) {
dev_data->rx_waiting_for_irq = true;
regs->INTENSET.reg = SERCOM_USART_INTENSET_RXC;
irq_unlock(key);
return;
}
/* Otherwise, start the transfer immediately. */
dma_start(dev_data->dma, cfg->rx_dma_channel);
struct uart_event evt = {
.type = UART_RX_BUF_REQUEST,
};
dev_data->async_cb(&evt, dev_data->async_cb_data);
irq_unlock(key);
}
static void uart_sam0_rx_timeout(struct k_work *work)
{
struct uart_sam0_dev_data *dev_data = CONTAINER_OF(work,
struct uart_sam0_dev_data, rx_timeout_work);
const struct uart_sam0_dev_cfg *const cfg = dev_data->cfg;
SercomUsart * const regs = cfg->regs;
struct dma_status st;
int key = irq_lock();
if (dev_data->rx_len == 0U) {
irq_unlock(key);
return;
}
/*
* Stop the DMA transfer and restart the interrupt read
* component (so the timeout restarts if there's still data).
* However, just ignore it if the transfer has completed (nothing
* pending) that means the DMA ISR is already pending, so just let
* it handle things instead when we re-enable IRQs.
*/
dma_stop(dev_data->dma, cfg->rx_dma_channel);
if (dma_get_status(dev_data->dma, cfg->rx_dma_channel,
&st) == 0 && st.pending_length == 0U) {
irq_unlock(key);
return;
}
u8_t *rx_dma_start = dev_data->rx_buf + dev_data->rx_len -
st.pending_length;
size_t rx_processed = rx_dma_start - dev_data->rx_buf;
/*
* We know we still have space, since the above will catch the
* empty buffer, so always restart the transfer.
*/
dma_reload(dev_data->dma, cfg->rx_dma_channel,
(u32_t)(&(regs->DATA.reg)),
(u32_t)rx_dma_start,
dev_data->rx_len - rx_processed);
dev_data->rx_waiting_for_irq = true;
regs->INTENSET.reg = SERCOM_USART_INTENSET_RXC;
/*
* Never do a notify on a timeout started from the ISR: timing
* granularity means the first timeout can be in the middle
* of reception but still have the total elapsed time exhausted.
* So we require a timeout chunk with no data seen at all
* (i.e. no ISR entry).
*/
if (dev_data->rx_timeout_from_isr) {
dev_data->rx_timeout_from_isr = false;
k_delayed_work_submit(&dev_data->rx_timeout_work,
dev_data->rx_timeout_chunk);
irq_unlock(key);
return;
}
u32_t now = k_uptime_get_32();
u32_t elapsed = now - dev_data->rx_timeout_start;
if (elapsed >= dev_data->rx_timeout_time) {
/*
* No time left, so call the handler, and let the ISR
* restart the timeout when it sees data.
*/
uart_sam0_notify_rx_processed(dev_data, rx_processed);
} else {
/*
* Still have time left, so start another timeout.
*/
u32_t remaining = MIN(dev_data->rx_timeout_time - elapsed,
dev_data->rx_timeout_chunk);
k_delayed_work_submit(&dev_data->rx_timeout_work, remaining);
}
irq_unlock(key);
}
#endif
static int uart_sam0_init(struct device *dev)
{
int retval;
const struct uart_sam0_dev_cfg *const cfg = DEV_CFG(dev);
SercomUsart *const usart = cfg->regs;
/* Enable the GCLK */
GCLK->CLKCTRL.reg =
cfg->gclk_clkctrl_id | GCLK_CLKCTRL_GEN_GCLK0 | GCLK_CLKCTRL_CLKEN;
/* Enable SERCOM clock in PM */
PM->APBCMASK.reg |= cfg->pm_apbcmask;
/* Disable all USART interrupts */
usart->INTENCLR.reg = SERCOM_USART_INTENCLR_MASK;
wait_synchronization(usart);
/* 8 bits of data, no parity, 1 stop bit in normal mode */
usart->CTRLA.reg =
cfg->pads |
/* Internal clock */
SERCOM_USART_CTRLA_MODE_USART_INT_CLK
#if defined(SERCOM_USART_CTRLA_SAMPR)
/* 16x oversampling with arithmetic baud rate generation */
| SERCOM_USART_CTRLA_SAMPR(0)
#endif
| SERCOM_USART_CTRLA_FORM(0) |
SERCOM_USART_CTRLA_CPOL | SERCOM_USART_CTRLA_DORD;
wait_synchronization(usart);
/* Enable receiver and transmitter */
usart->CTRLB.reg = SERCOM_SPI_CTRLB_CHSIZE(0) |
SERCOM_USART_CTRLB_RXEN | SERCOM_USART_CTRLB_TXEN;
wait_synchronization(usart);
retval = uart_sam0_set_baudrate(usart, cfg->baudrate,
SOC_ATMEL_SAM0_GCLK0_FREQ_HZ);
if (retval != 0) {
return retval;
}
#if CONFIG_UART_INTERRUPT_DRIVEN || CONFIG_UART_ASYNC_API
cfg->irq_config_func(dev);
#endif
#ifdef CONFIG_UART_ASYNC_API
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
dev_data->cfg = cfg;
dev_data->dma = device_get_binding(CONFIG_DMA_0_NAME);
k_delayed_work_init(&dev_data->tx_timeout_work, uart_sam0_tx_timeout);
k_delayed_work_init(&dev_data->rx_timeout_work, uart_sam0_rx_timeout);
if (cfg->tx_dma_channel != 0xFFU) {
struct dma_config dma_cfg = { 0 };
struct dma_block_config dma_blk = { 0 };
if (!dev_data->dma) {
return -ENOTSUP;
}
dma_cfg.channel_direction = MEMORY_TO_PERIPHERAL;
dma_cfg.source_data_size = 1;
dma_cfg.dest_data_size = 1;
dma_cfg.callback_arg = dev;
dma_cfg.dma_callback = uart_sam0_dma_tx_done;
dma_cfg.block_count = 1;
dma_cfg.head_block = &dma_blk;
dma_cfg.dma_slot = cfg->tx_dma_request;
dma_blk.block_size = 1;
dma_blk.dest_address = (u32_t)(&(usart->DATA.reg));
dma_blk.dest_addr_adj = DMA_ADDR_ADJ_NO_CHANGE;
retval = dma_config(dev_data->dma, cfg->tx_dma_channel,
&dma_cfg);
if (retval != 0) {
return retval;
}
}
if (cfg->rx_dma_channel != 0xFFU) {
struct dma_config dma_cfg = { 0 };
struct dma_block_config dma_blk = { 0 };
if (!dev_data->dma) {
return -ENOTSUP;
}
dma_cfg.channel_direction = PERIPHERAL_TO_MEMORY;
dma_cfg.source_data_size = 1;
dma_cfg.dest_data_size = 1;
dma_cfg.callback_arg = dev;
dma_cfg.dma_callback = uart_sam0_dma_rx_done;
dma_cfg.block_count = 1;
dma_cfg.head_block = &dma_blk;
dma_cfg.dma_slot = cfg->rx_dma_request;
dma_blk.block_size = 1;
dma_blk.source_address = (u32_t)(&(usart->DATA.reg));
dma_blk.source_addr_adj = DMA_ADDR_ADJ_NO_CHANGE;
retval = dma_config(dev_data->dma, cfg->rx_dma_channel,
&dma_cfg);
if (retval != 0) {
return retval;
}
}
#endif
usart->CTRLA.bit.ENABLE = 1;
wait_synchronization(usart);
return 0;
}
static int uart_sam0_poll_in(struct device *dev, unsigned char *c)
{
SercomUsart *const usart = DEV_CFG(dev)->regs;
if (!usart->INTFLAG.bit.RXC) {
return -EBUSY;
}
*c = (unsigned char)usart->DATA.reg;
return 0;
}
static void uart_sam0_poll_out(struct device *dev, unsigned char c)
{
SercomUsart *const usart = DEV_CFG(dev)->regs;
while (!usart->INTFLAG.bit.DRE) {
}
/* send a character */
usart->DATA.reg = c;
}
#if CONFIG_UART_INTERRUPT_DRIVEN || CONFIG_UART_ASYNC_API
static void uart_sam0_isr(void *arg)
{
struct device *dev = arg;
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
#if CONFIG_UART_INTERRUPT_DRIVEN
if (dev_data->cb) {
dev_data->cb(dev_data->cb_data);
}
#endif
#if CONFIG_UART_ASYNC_API
const struct uart_sam0_dev_cfg *const cfg = DEV_CFG(dev);
SercomUsart * const regs = cfg->regs;
if (dev_data->rx_len && regs->INTFLAG.bit.RXC &&
dev_data->rx_waiting_for_irq) {
dev_data->rx_waiting_for_irq = false;
regs->INTENCLR.reg = SERCOM_USART_INTENCLR_RXC;
/* Receive started, so request the next buffer */
if (dev_data->rx_next_len == 0U && dev_data->async_cb) {
struct uart_event evt = {
.type = UART_RX_BUF_REQUEST,
};
dev_data->async_cb(&evt, dev_data->async_cb_data);
}
/*
* If we have a timeout, restart the time remaining whenever
* we see data.
*/
if (dev_data->rx_timeout_time != K_FOREVER) {
dev_data->rx_timeout_from_isr = true;
dev_data->rx_timeout_start = k_uptime_get_32();
k_delayed_work_submit(&dev_data->rx_timeout_work,
dev_data->rx_timeout_chunk);
}
/* DMA will read the currently ready byte out */
dma_start(dev_data->dma, cfg->rx_dma_channel);
}
#endif
}
#endif
#if CONFIG_UART_INTERRUPT_DRIVEN
static int uart_sam0_fifo_fill(struct device *dev, const u8_t *tx_data, int len)
{
SercomUsart *regs = DEV_CFG(dev)->regs;
if (regs->INTFLAG.bit.DRE && len >= 1) {
regs->DATA.reg = tx_data[0];
return 1;
} else {
return 0;
}
}
static void uart_sam0_irq_tx_enable(struct device *dev)
{
SercomUsart *regs = DEV_CFG(dev)->regs;
regs->INTENSET.reg = SERCOM_USART_INTENCLR_DRE;
}
static void uart_sam0_irq_tx_disable(struct device *dev)
{
SercomUsart *const regs = DEV_CFG(dev)->regs;
regs->INTENCLR.reg = SERCOM_USART_INTENCLR_DRE;
}
static int uart_sam0_irq_tx_ready(struct device *dev)
{
SercomUsart *const regs = DEV_CFG(dev)->regs;
return regs->INTFLAG.bit.DRE != 0;
}
static void uart_sam0_irq_rx_enable(struct device *dev)
{
SercomUsart *const regs = DEV_CFG(dev)->regs;
regs->INTENSET.reg = SERCOM_USART_INTENSET_RXC;
}
static void uart_sam0_irq_rx_disable(struct device *dev)
{
SercomUsart *const regs = DEV_CFG(dev)->regs;
regs->INTENCLR.reg = SERCOM_USART_INTENCLR_RXC;
}
static int uart_sam0_irq_rx_ready(struct device *dev)
{
SercomUsart *const regs = DEV_CFG(dev)->regs;
return regs->INTFLAG.bit.RXC != 0;
}
static int uart_sam0_fifo_read(struct device *dev, u8_t *rx_data,
const int size)
{
SercomUsart *const regs = DEV_CFG(dev)->regs;
if (regs->INTFLAG.bit.RXC) {
u8_t ch = regs->DATA.reg;
if (size >= 1) {
*rx_data = ch;
return 1;
} else {
return -EINVAL;
}
}
return 0;
}
static int uart_sam0_irq_is_pending(struct device *dev)
{
SercomUsart *const regs = DEV_CFG(dev)->regs;
return (regs->INTENSET.reg & regs->INTFLAG.reg) != 0;
}
static int uart_sam0_irq_update(struct device *dev) { return 1; }
static void uart_sam0_irq_callback_set(struct device *dev,
uart_irq_callback_user_data_t cb,
void *cb_data)
{
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
dev_data->cb = cb;
dev_data->cb_data = cb_data;
}
#endif
#ifdef CONFIG_UART_ASYNC_API
static int uart_sam0_callback_set(struct device *dev, uart_callback_t callback,
void *user_data)
{
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
dev_data->async_cb = callback;
dev_data->async_cb_data = user_data;
return 0;
}
static int uart_sam0_tx(struct device *dev, const u8_t *buf, size_t len,
u32_t timeout)
{
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
const struct uart_sam0_dev_cfg *const cfg = DEV_CFG(dev);
SercomUsart *regs = DEV_CFG(dev)->regs;
int retval;
if (!dev_data->dma || cfg->tx_dma_channel == 0xFFU) {
return -ENOTSUP;
}
if (len > 0xFFFFU) {
return -EINVAL;
}
int key = irq_lock();
if (dev_data->tx_len != 0U) {
retval = -EBUSY;
goto err;
}
dev_data->tx_buf = buf;
dev_data->tx_len = len;
irq_unlock(key);
retval = dma_reload(dev_data->dma, cfg->tx_dma_channel, (u32_t)buf,
(u32_t)(&(regs->DATA.reg)), len);
if (retval != 0U) {
return retval;
}
if (timeout != K_FOREVER) {
k_delayed_work_submit(&dev_data->tx_timeout_work, timeout);
}
return dma_start(dev_data->dma, cfg->tx_dma_channel);
err:
irq_unlock(key);
return retval;
}
static int uart_sam0_tx_abort(struct device *dev)
{
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
const struct uart_sam0_dev_cfg *const cfg = DEV_CFG(dev);
if (!dev_data->dma || cfg->tx_dma_channel == 0xFFU) {
return -ENOTSUP;
}
k_delayed_work_cancel(&dev_data->tx_timeout_work);
return uart_sam0_tx_halt(dev_data);
}
static int uart_sam0_rx_enable(struct device *dev, u8_t *buf, size_t len,
u32_t timeout)
{
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
const struct uart_sam0_dev_cfg *const cfg = DEV_CFG(dev);
SercomUsart *regs = DEV_CFG(dev)->regs;
int retval;
if (!dev_data->dma || cfg->rx_dma_channel == 0xFFU) {
return -ENOTSUP;
}
if (len > 0xFFFFU) {
return -EINVAL;
}
int key = irq_lock();
if (dev_data->rx_len != 0U) {
retval = -EBUSY;
goto err;
}
/* Read off anything that was already there */
while (regs->INTFLAG.bit.RXC) {
char discard = regs->DATA.reg;
(void)discard;
}
retval = dma_reload(dev_data->dma, cfg->rx_dma_channel,
(u32_t)(&(regs->DATA.reg)),
(u32_t)buf, len);
if (retval != 0) {
return retval;
}
dev_data->rx_buf = buf;
dev_data->rx_len = len;
dev_data->rx_processed_len = 0U;
dev_data->rx_waiting_for_irq = true;
dev_data->rx_timeout_from_isr = true;
dev_data->rx_timeout_time = timeout;
dev_data->rx_timeout_chunk = MAX(timeout / 4U, 1);
regs->INTENSET.reg = SERCOM_USART_INTENSET_RXC;
irq_unlock(key);
return 0;
err:
irq_unlock(key);
return retval;
}
static int uart_sam0_rx_buf_rsp(struct device *dev, u8_t *buf, size_t len)
{
if (len > 0xFFFFU) {
return -EINVAL;
}
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
int key = irq_lock();
int retval = 0;
if (dev_data->rx_len == 0U) {
retval = -EACCES;
goto err;
}
if (dev_data->rx_next_len != 0U) {
retval = -EBUSY;
goto err;
}
dev_data->rx_next_buf = buf;
dev_data->rx_next_len = len;
irq_unlock(key);
return 0;
err:
irq_unlock(key);
return retval;
}
static int uart_sam0_rx_disable(struct device *dev)
{
struct uart_sam0_dev_data *const dev_data = DEV_DATA(dev);
const struct uart_sam0_dev_cfg *const cfg = DEV_CFG(dev);
SercomUsart *const regs = cfg->regs;
struct dma_status st;
k_delayed_work_cancel(&dev_data->rx_timeout_work);
int key = irq_lock();
if (dev_data->rx_len == 0U) {
irq_unlock(key);
return -EINVAL;
}
regs->INTENCLR.reg = SERCOM_USART_INTENCLR_RXC;
dma_stop(dev_data->dma, cfg->rx_dma_channel);
if (dev_data->rx_next_len) {
struct uart_event evt = {
.type = UART_RX_BUF_RELEASED,
.data.rx_buf = {
.buf = dev_data->rx_next_buf,
},
};
dev_data->rx_next_buf = NULL;
dev_data->rx_next_len = 0U;
if (dev_data->async_cb) {
dev_data->async_cb(&evt, dev_data->async_cb_data);
}
}
if (dma_get_status(dev_data->dma, cfg->rx_dma_channel,
&st) == 0 && st.pending_length != 0U) {
size_t rx_processed = dev_data->rx_len - st.pending_length;
uart_sam0_notify_rx_processed(dev_data, rx_processed);
}
struct uart_event evt = {
.type = UART_RX_BUF_RELEASED,
.data.rx_buf = {
.buf = dev_data->rx_buf,
},
};
dev_data->rx_buf = NULL;
dev_data->rx_len = 0U;
if (dev_data->async_cb) {
dev_data->async_cb(&evt, dev_data->async_cb_data);
}
evt.type = UART_RX_DISABLED;
if (dev_data->async_cb) {
dev_data->async_cb(&evt, dev_data->async_cb_data);
}
irq_unlock(key);
return 0;
}
#endif
static const struct uart_driver_api uart_sam0_driver_api = {
.poll_in = uart_sam0_poll_in,
.poll_out = uart_sam0_poll_out,
#if CONFIG_UART_INTERRUPT_DRIVEN
.fifo_fill = uart_sam0_fifo_fill,
.fifo_read = uart_sam0_fifo_read,
.irq_tx_enable = uart_sam0_irq_tx_enable,
.irq_tx_disable = uart_sam0_irq_tx_disable,
.irq_tx_ready = uart_sam0_irq_tx_ready,
.irq_rx_enable = uart_sam0_irq_rx_enable,
.irq_rx_disable = uart_sam0_irq_rx_disable,
.irq_rx_ready = uart_sam0_irq_rx_ready,
.irq_is_pending = uart_sam0_irq_is_pending,
.irq_update = uart_sam0_irq_update,
.irq_callback_set = uart_sam0_irq_callback_set,
#endif
#if CONFIG_UART_ASYNC_API
.callback_set = uart_sam0_callback_set,
.tx = uart_sam0_tx,
.tx_abort = uart_sam0_tx_abort,
.rx_enable = uart_sam0_rx_enable,
.rx_buf_rsp = uart_sam0_rx_buf_rsp,
.rx_disable = uart_sam0_rx_disable,
#endif
};
#if CONFIG_UART_INTERRUPT_DRIVEN || CONFIG_UART_ASYNC_API
#define UART_SAM0_IRQ_HANDLER_DECL(n) \
static void uart_sam0_irq_config_##n(struct device *dev)
#define UART_SAM0_IRQ_HANDLER_FUNC(n) \
.irq_config_func = uart_sam0_irq_config_##n,
#define UART_SAM0_IRQ_HANDLER(n) \
static void uart_sam0_irq_config_##n(struct device *dev) \
{ \
IRQ_CONNECT(DT_ATMEL_SAM0_UART_SERCOM_##n##_IRQ_0, \
DT_ATMEL_SAM0_UART_SERCOM_##n##_IRQ_0_PRIORITY, \
uart_sam0_isr, DEVICE_GET(uart_sam0_##n), \
0); \
irq_enable(DT_ATMEL_SAM0_UART_SERCOM_##n##_IRQ_0); \
}
#else
#define UART_SAM0_IRQ_HANDLER_DECL(n)
#define UART_SAM0_IRQ_HANDLER_FUNC(n)
#define UART_SAM0_IRQ_HANDLER(n)
#endif
#if CONFIG_UART_ASYNC_API
#ifndef DT_ATMEL_SAM0_UART_SERCOM_0_TXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_0_TXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_0_RXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_0_RXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_1_TXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_1_TXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_1_RXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_1_RXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_2_TXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_2_TXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_2_RXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_2_RXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_3_TXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_3_TXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_3_RXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_3_RXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_4_TXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_4_TXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_4_RXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_4_RXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_5_TXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_5_TXDMA 0xFFU
#endif
#ifndef DT_ATMEL_SAM0_UART_SERCOM_5_RXDMA
#define DT_ATMEL_SAM0_UART_SERCOM_5_RXDMA 0xFFU
#endif
#define UART_SAM0_DMA_CHANNELS(n) \
.tx_dma_request = SERCOM##n##_DMAC_ID_TX, \
.tx_dma_channel = DT_ATMEL_SAM0_UART_SERCOM_##n##_TXDMA, \
.rx_dma_request = SERCOM##n##_DMAC_ID_RX, \
.rx_dma_channel = DT_ATMEL_SAM0_UART_SERCOM_##n##_RXDMA
#else
#define UART_SAM0_DMA_CHANNELS(n)
#endif
#define UART_SAM0_SERCOM_PADS(n) \
(DT_ATMEL_SAM0_UART_SERCOM_##n##_RXPO << SERCOM_USART_CTRLA_RXPO_Pos) |\
(DT_ATMEL_SAM0_UART_SERCOM_##n##_TXPO << SERCOM_USART_CTRLA_TXPO_Pos)
#define UART_SAM0_CONFIG_DEFN(n) \
static const struct uart_sam0_dev_cfg uart_sam0_config_##n = { \
.regs = (SercomUsart *)DT_ATMEL_SAM0_UART_SERCOM_##n##_BASE_ADDRESS, \
.baudrate = DT_ATMEL_SAM0_UART_SERCOM_##n##_CURRENT_SPEED, \
.pm_apbcmask = PM_APBCMASK_SERCOM##n, \
.gclk_clkctrl_id = GCLK_CLKCTRL_ID_SERCOM##n##_CORE, \
.pads = UART_SAM0_SERCOM_PADS(n), \
UART_SAM0_IRQ_HANDLER_FUNC(n) \
UART_SAM0_DMA_CHANNELS(n) \
}
#define UART_SAM0_DEVICE_INIT(n) \
static struct uart_sam0_dev_data uart_sam0_data_##n; \
UART_SAM0_IRQ_HANDLER_DECL(n); \
UART_SAM0_CONFIG_DEFN(n); \
DEVICE_AND_API_INIT(uart_sam0_##n, DT_ATMEL_SAM0_UART_SERCOM_##n##_LABEL, \
uart_sam0_init, &uart_sam0_data_##n, \
&uart_sam0_config_##n, PRE_KERNEL_1, \
CONFIG_KERNEL_INIT_PRIORITY_DEVICE, \
&uart_sam0_driver_api); \
UART_SAM0_IRQ_HANDLER(n)
#if DT_ATMEL_SAM0_UART_SERCOM_0_BASE_ADDRESS
UART_SAM0_DEVICE_INIT(0)
#endif
#if DT_ATMEL_SAM0_UART_SERCOM_1_BASE_ADDRESS
UART_SAM0_DEVICE_INIT(1)
#endif
#if DT_ATMEL_SAM0_UART_SERCOM_2_BASE_ADDRESS
UART_SAM0_DEVICE_INIT(2)
#endif
#if DT_ATMEL_SAM0_UART_SERCOM_3_BASE_ADDRESS
UART_SAM0_DEVICE_INIT(3)
#endif
#if DT_ATMEL_SAM0_UART_SERCOM_4_BASE_ADDRESS
UART_SAM0_DEVICE_INIT(4)
#endif
#if DT_ATMEL_SAM0_UART_SERCOM_5_BASE_ADDRESS
UART_SAM0_DEVICE_INIT(5)
#endif