Kenji Arai
mbed-os5 only for TYBLE16
Dependents: TYBLE16_simple_data_logger TYBLE16_MP3_Air
drivers/source/UARTSerial.cpp
- Committer:
- kenjiArai
- Date:
- 2019-12-31
- Revision:
- 1:9db0e321a9f4
File content as of revision 1:9db0e321a9f4:
/* mbed Microcontroller Library
* Copyright (c) 2006-2019 ARM Limited
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "drivers/UARTSerial.h"
#if (DEVICE_SERIAL && DEVICE_INTERRUPTIN)
#include "platform/mbed_poll.h"
#include "platform/mbed_thread.h"
namespace mbed {
UARTSerial::UARTSerial(PinName tx, PinName rx, int baud) :
SerialBase(tx, rx, baud),
_blocking(true),
_tx_irq_enabled(false),
_rx_irq_enabled(false),
_tx_enabled(true),
_rx_enabled(true),
_dcd_irq(NULL)
{
/* Attatch IRQ routines to the serial device. */
enable_rx_irq();
}
UARTSerial::UARTSerial(const serial_pinmap_t &static_pinmap, int baud) :
SerialBase(static_pinmap, baud),
_blocking(true),
_tx_irq_enabled(false),
_rx_irq_enabled(false),
_tx_enabled(true),
_rx_enabled(true),
_dcd_irq(NULL)
{
/* Attatch IRQ routines to the serial device. */
enable_rx_irq();
}
UARTSerial::~UARTSerial()
{
delete _dcd_irq;
}
void UARTSerial::dcd_irq()
{
wake();
}
void UARTSerial::set_baud(int baud)
{
SerialBase::baud(baud);
}
void UARTSerial::set_data_carrier_detect(PinName dcd_pin, bool active_high)
{
delete _dcd_irq;
_dcd_irq = NULL;
if (dcd_pin != NC) {
_dcd_irq = new InterruptIn(dcd_pin);
if (active_high) {
_dcd_irq->fall(callback(this, &UARTSerial::dcd_irq));
} else {
_dcd_irq->rise(callback(this, &UARTSerial::dcd_irq));
}
}
}
void UARTSerial::set_format(int bits, Parity parity, int stop_bits)
{
api_lock();
SerialBase::format(bits, parity, stop_bits);
api_unlock();
}
#if DEVICE_SERIAL_FC
void UARTSerial::set_flow_control(Flow type, PinName flow1, PinName flow2)
{
api_lock();
SerialBase::set_flow_control(type, flow1, flow2);
api_unlock();
}
#endif
int UARTSerial::close()
{
/* Does not let us pass a file descriptor. So how to close ?
* Also, does it make sense to close a device type file descriptor*/
return 0;
}
int UARTSerial::isatty()
{
return 1;
}
off_t UARTSerial::seek(off_t offset, int whence)
{
/*XXX lseek can be done theoratically, but is it sane to mark positions on a dynamically growing/shrinking
* buffer system (from an interrupt context) */
return -ESPIPE;
}
int UARTSerial::sync()
{
api_lock();
while (!_txbuf.empty()) {
api_unlock();
// Doing better than wait would require TxIRQ to also do wake() when becoming empty. Worth it?
thread_sleep_for(1);
api_lock();
}
api_unlock();
return 0;
}
void UARTSerial::sigio(Callback<void()> func)
{
core_util_critical_section_enter();
_sigio_cb = func;
if (_sigio_cb) {
short current_events = poll(0x7FFF);
if (current_events) {
_sigio_cb();
}
}
core_util_critical_section_exit();
}
/* Special synchronous write designed to work from critical section, such
* as in mbed_error_vprintf.
*/
ssize_t UARTSerial::write_unbuffered(const char *buf_ptr, size_t length)
{
while (!_txbuf.empty()) {
tx_irq();
}
for (size_t data_written = 0; data_written < length; data_written++) {
SerialBase::_base_putc(*buf_ptr++);
}
return length;
}
ssize_t UARTSerial::write(const void *buffer, size_t length)
{
size_t data_written = 0;
const char *buf_ptr = static_cast<const char *>(buffer);
if (length == 0) {
return 0;
}
if (core_util_in_critical_section()) {
return write_unbuffered(buf_ptr, length);
}
api_lock();
// Unlike read, we should write the whole thing if blocking. POSIX only
// allows partial as a side-effect of signal handling; it normally tries to
// write everything if blocking. Without signals we can always write all.
while (data_written < length) {
if (_txbuf.full()) {
if (!_blocking) {
break;
}
do {
api_unlock();
thread_sleep_for(1); // XXX todo - proper wait?
api_lock();
} while (_txbuf.full());
}
while (data_written < length && !_txbuf.full()) {
_txbuf.push(*buf_ptr++);
data_written++;
}
core_util_critical_section_enter();
if (_tx_enabled && !_tx_irq_enabled) {
UARTSerial::tx_irq(); // only write to hardware in one place
if (!_txbuf.empty()) {
enable_tx_irq();
}
}
core_util_critical_section_exit();
}
api_unlock();
return data_written != 0 ? (ssize_t) data_written : (ssize_t) - EAGAIN;
}
ssize_t UARTSerial::read(void *buffer, size_t length)
{
size_t data_read = 0;
char *ptr = static_cast<char *>(buffer);
if (length == 0) {
return 0;
}
api_lock();
while (_rxbuf.empty()) {
if (!_blocking) {
api_unlock();
return -EAGAIN;
}
api_unlock();
thread_sleep_for(1); // XXX todo - proper wait?
api_lock();
}
while (data_read < length && !_rxbuf.empty()) {
_rxbuf.pop(*ptr++);
data_read++;
}
core_util_critical_section_enter();
if (_rx_enabled && !_rx_irq_enabled) {
UARTSerial::rx_irq(); // only read from hardware in one place
if (!_rxbuf.full()) {
enable_rx_irq();
}
}
core_util_critical_section_exit();
api_unlock();
return data_read;
}
bool UARTSerial::hup() const
{
return _dcd_irq && _dcd_irq->read() != 0;
}
void UARTSerial::wake()
{
if (_sigio_cb) {
_sigio_cb();
}
}
short UARTSerial::poll(short events) const
{
short revents = 0;
/* Check the Circular Buffer if space available for writing out */
if (!_rxbuf.empty()) {
revents |= POLLIN;
}
/* POLLHUP and POLLOUT are mutually exclusive */
if (hup()) {
revents |= POLLHUP;
} else if (!_txbuf.full()) {
revents |= POLLOUT;
}
/*TODO Handle other event types */
return revents;
}
void UARTSerial::lock()
{
// This is the override for SerialBase.
// No lock required as we only use SerialBase from interrupt or from
// inside our own critical section.
}
void UARTSerial::unlock()
{
// This is the override for SerialBase.
}
void UARTSerial::api_lock(void)
{
_mutex.lock();
}
void UARTSerial::api_unlock(void)
{
_mutex.unlock();
}
void UARTSerial::rx_irq(void)
{
bool was_empty = _rxbuf.empty();
/* Fill in the receive buffer if the peripheral is readable
* and receive buffer is not full. */
while (!_rxbuf.full() && SerialBase::readable()) {
char data = SerialBase::_base_getc();
_rxbuf.push(data);
}
if (_rx_irq_enabled && _rxbuf.full()) {
disable_rx_irq();
}
/* Report the File handler that data is ready to be read from the buffer. */
if (was_empty && !_rxbuf.empty()) {
wake();
}
}
// Also called from write to start transfer
void UARTSerial::tx_irq(void)
{
bool was_full = _txbuf.full();
char data;
/* Write to the peripheral if there is something to write
* and if the peripheral is available to write. */
while (SerialBase::writeable() && _txbuf.pop(data)) {
SerialBase::_base_putc(data);
}
if (_tx_irq_enabled && _txbuf.empty()) {
disable_tx_irq();
}
/* Report the File handler that data can be written to peripheral. */
if (was_full && !_txbuf.full() && !hup()) {
wake();
}
}
/* These are all called from critical section */
void UARTSerial::enable_rx_irq()
{
SerialBase::attach(callback(this, &UARTSerial::rx_irq), RxIrq);
_rx_irq_enabled = true;
}
void UARTSerial::disable_rx_irq()
{
SerialBase::attach(NULL, RxIrq);
_rx_irq_enabled = false;
}
void UARTSerial::enable_tx_irq()
{
SerialBase::attach(callback(this, &UARTSerial::tx_irq), TxIrq);
_tx_irq_enabled = true;
}
void UARTSerial::disable_tx_irq()
{
SerialBase::attach(NULL, TxIrq);
_tx_irq_enabled = false;
}
int UARTSerial::enable_input(bool enabled)
{
api_lock();
SerialBase::enable_input(enabled);
api_unlock();
return 0;
}
int UARTSerial::enable_output(bool enabled)
{
api_lock();
SerialBase::enable_output(enabled);
api_unlock();
return 0;
}
} //namespace mbed
#endif //(DEVICE_SERIAL && DEVICE_INTERRUPTIN)