static int uart_close(FAR struct file *filep)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
irqstate_t flags;
uart_takesem(&dev->closesem);
if (dev->open_count > 1)
{
dev->open_count--;
uart_givesem(&dev->closesem);
return OK;
}
/* There are no more references to the port */
dev->open_count = 0;
/* Stop accepting input */
uart_disablerxint(dev);
/* Now we wait for the transmit buffer to clear */
while (dev->xmit.head != dev->xmit.tail)
{
#ifndef CONFIG_DISABLE_SIGNALS
usleep(HALF_SECOND_USEC);
#else
up_mdelay(HALF_SECOND_MSEC);
#endif
}
/* And wait for the TX fifo to drain */
while (!uart_txempty(dev))
{
#ifndef CONFIG_DISABLE_SIGNALS
usleep(HALF_SECOND_USEC);
#else
up_mdelay(HALF_SECOND_MSEC);
#endif
}
/* Free the IRQ and disable the UART */
flags = irqsave(); /* Disable interrupts */
uart_detach(dev); /* Detach interrupts */
if (!dev->isconsole) /* Check for the serial console UART */
{
uart_shutdown(dev); /* Disable the UART */
}
irqrestore(flags);
uart_givesem(&dev->closesem);
return OK;
}
static void uart_putxmitchar(FAR uart_dev_t *dev, int ch)
{
irqstate_t flags;
int nexthead;
/* Increment to see what the next head pointer will be. We need to use the "next"
* head pointer to determine when the circular buffer would overrun
*/
nexthead = dev->xmit.head + 1;
if (nexthead >= dev->xmit.size)
{
nexthead = 0;
}
/* Loop until we are able to add the character to the TX buffer */
for (;;)
{
if (nexthead != dev->xmit.tail)
{
dev->xmit.buffer[dev->xmit.head] = ch;
dev->xmit.head = nexthead;
return;
}
else
{
/* Inform the interrupt level logic that we are waiting.
* This and the following steps must be atomic.
*/
flags = irqsave();
dev->xmitwaiting = true;
/* Wait for some characters to be sent from the buffer
* with the TX interrupt enabled. When the TX interrupt
* is enabled, uart_xmitchars should execute and remove
* some of the data from the TX buffer.
*/
uart_enabletxint(dev);
uart_takesem(&dev->xmitsem);
uart_disabletxint(dev);
irqrestore(flags);
}
}
}
static int uart_open(FAR struct file *filep)
{
struct inode *inode = filep->f_inode;
uart_dev_t *dev = inode->i_private;
uint8_t tmp;
int ret = OK;
/* If the port is the middle of closing, wait until the close is finished */
uart_takesem(&dev->closesem);
/* Start up serial port */
/* Increment the count of references to the device. */
tmp = dev->open_count + 1;
if (tmp == 0)
{
/* More than 255 opens; uint8_t overflows to zero */
ret = -EMFILE;
goto errout_with_sem;
}
/* Check if this is the first time that the driver has been opened. */
if (tmp == 1)
{
irqstate_t flags = irqsave();
/* If this is the console, then the UART has already been initialized. */
if (!dev->isconsole)
{
/* Perform one time hardware initialization */
ret = uart_setup(dev);
if (ret < 0)
{
irqrestore(flags);
goto errout_with_sem;
}
}
/* In any event, we do have to configure for interrupt driven mode of
* operation. Attach the hardware IRQ(s). Hmm.. should shutdown() the
* the device in the rare case that uart_attach() fails, tmp==1, and
* this is not the console.
*/
ret = uart_attach(dev);
if (ret < 0)
{
uart_shutdown(dev);
irqrestore(flags);
goto errout_with_sem;
}
/* Mark the io buffers empty */
dev->xmit.head = 0;
dev->xmit.tail = 0;
dev->recv.head = 0;
dev->recv.tail = 0;
/* Enable the RX interrupt */
uart_enablerxint(dev);
irqrestore(flags);
}
/* Save the new open count on success */
dev->open_count = tmp;
errout_with_sem:
uart_givesem(&dev->closesem);
return ret;
}
int uart_poll(FAR struct file *filep, FAR struct pollfd *fds, bool setup)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
pollevent_t eventset;
int ndx;
int ret = OK;
int i;
/* Some sanity checking */
#if CONFIG_DEBUG
if (!dev || !fds)
{
return -ENODEV;
}
#endif
/* Are we setting up the poll? Or tearing it down? */
uart_takesem(&dev->pollsem);
if (setup)
{
/* This is a request to set up the poll. Find an available
* slot for the poll structure reference
*/
for (i = 0; i < CONFIG_SERIAL_NPOLLWAITERS; i++)
{
/* Find an available slot */
if (!dev->fds[i])
{
/* Bind the poll structure and this slot */
dev->fds[i] = fds;
fds->priv = &dev->fds[i];
break;
}
}
if (i >= CONFIG_SERIAL_NPOLLWAITERS)
{
fds->priv = NULL;
ret = -EBUSY;
goto errout;
}
/* Should immediately notify on any of the requested events?
* First, check if the xmit buffer is full.
*/
eventset = 0;
uart_takesem(&dev->xmit.sem);
ndx = dev->xmit.head + 1;
if (ndx >= dev->xmit.size)
{
ndx = 0;
}
if (ndx != dev->xmit.tail)
{
eventset |= POLLOUT;
}
uart_givesem(&dev->xmit.sem);
/* Check if the receive buffer is empty */
uart_takesem(&dev->recv.sem);
if (dev->recv.head != dev->recv.tail)
{
eventset |= POLLIN;
}
uart_givesem(&dev->recv.sem);
if (eventset)
{
uart_pollnotify(dev, eventset);
}
}
else if (fds->priv)
{
/* This is a request to tear down the poll. */
struct pollfd **slot = (struct pollfd **)fds->priv;
#ifdef CONFIG_DEBUG
if (!slot)
{
ret = -EIO;
goto errout;
}
#endif
/* Remove all memory of the poll setup */
*slot = NULL;
fds->priv = NULL;
}
errout:
uart_givesem(&dev->pollsem);
return ret;
}
static ssize_t uart_read(FAR struct file *filep, FAR char *buffer, size_t buflen)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
irqstate_t flags;
ssize_t recvd = 0;
int16_t tail;
/* Only one user can be accessing dev->recv.tail at once */
uart_takesem(&dev->recv.sem);
/* Loop while we still have data to copy to the receive buffer.
* we add data to the head of the buffer; uart_xmitchars takes the
* data from the end of the buffer.
*/
while (recvd < buflen)
{
/* Check if there is more data to return in the circular buffer.
* NOTE: Rx interrupt handling logic may aynchronously increment
* the head index but must not modify the tail index. The tail
* index is only modified in this function. Therefore, no
* special handshaking is required here.
*
* The head and tail pointers are 16-bit values. The only time that
* the following could be unsafe is if the CPU made two non-atomic
* 8-bit accesses to obtain the 16-bit head index.
*/
tail = dev->recv.tail;
if (dev->recv.head != tail)
{
/* Take the next character from the tail of the buffer */
*buffer++ = dev->recv.buffer[tail];
recvd++;
/* Increment the tail index. Most operations are done using the
* local variable 'tail' so that the final dev->recv.tail update
* is atomic.
*/
if (++tail >= dev->recv.size)
{
tail = 0;
}
dev->recv.tail = tail;
}
#ifdef CONFIG_DEV_SERIAL_FULLBLOCKS
/* No... then we would have to wait to get receive more data.
* If the user has specified the O_NONBLOCK option, then just
* return what we have.
*/
else if (filep->f_oflags & O_NONBLOCK)
{
/* If nothing was transferred, then return the -EAGAIN
* error (not zero which means end of file).
*/
if (recvd < 1)
{
recvd = -EAGAIN;
}
break;
}
#else
/* No... the circular buffer is empty. Have we returned anything
* to the caller?
*/
else if (recvd > 0)
{
/* Yes.. break out of the loop and return the number of bytes
* received up to the wait condition.
*/
break;
}
/* No... then we would have to wait to get receive some data.
* If the user has specified the O_NONBLOCK option, then do not
* wait.
*/
else if (filep->f_oflags & O_NONBLOCK)
{
/* Break out of the loop returning -EAGAIN */
recvd = -EAGAIN;
break;
}
#endif
/* Otherwise we are going to have to wait for data to arrive */
else
{
/* Disable Rx interrupts and test again... */
uart_disablerxint(dev);
/* If the Rx ring buffer still empty? Bytes may have been addded
* between the last time that we checked and when we disabled Rx
* interrupts.
*/
if (dev->recv.head == dev->recv.tail)
{
/* Yes.. the buffer is still empty. Wait for some characters
* to be received into the buffer with the RX interrupt re-
* enabled. All interrupts are disabled briefly to assure
* that the following operations are atomic.
*/
flags = irqsave();
dev->recvwaiting = true;
uart_enablerxint(dev);
/* Now wait with the Rx interrupt re-enabled. NuttX will
* automatically re-enable global interrupts when this
* thread goes to sleep.
*/
uart_takesem(&dev->recvsem);
irqrestore(flags);
}
else
{
/* No... the ring buffer is no longer empty. Just re-enable Rx
* interrupts and accept the new data on the next time through
* the loop.
*/
uart_enablerxint(dev);
}
}
}
uart_givesem(&dev->recv.sem);
return recvd;
}
static ssize_t uart_write(FAR struct file *filep, FAR const char *buffer, size_t buflen)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
ssize_t ret = buflen;
/* We may receive console writes through this path from
* interrupt handlers and from debug output in the IDLE task!
* In these cases, we will need to do things a little
* differently.
*/
if (up_interrupt_context() || getpid() == 0)
{
if (dev->isconsole)
{
irqstate_t flags = irqsave();
ret = uart_irqwrite(dev, buffer, buflen);
irqrestore(flags);
return ret;
}
else
{
return ERROR;
}
}
/* Only one user can be accessing dev->xmit.head at once */
uart_takesem(&dev->xmit.sem);
/* Loop while we still have data to copy to the transmit buffer.
* we add data to the head of the buffer; uart_xmitchars takes the
* data from the end of the buffer.
*/
uart_disabletxint(dev);
for (; buflen; buflen--)
{
int ch = *buffer++;
/* Put the character into the transmit buffer */
uart_putxmitchar(dev, ch);
/* If this is the console, then we should replace LF with LF-CR */
if (dev->isconsole && ch == '\n')
{
uart_putxmitchar(dev, '\r');
}
}
if (dev->xmit.head != dev->xmit.tail)
{
uart_enabletxint(dev);
}
uart_givesem(&dev->xmit.sem);
return ret;
}
static int uart_close(FAR struct file *filep)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
irqstate_t flags;
/* Get exclusive access to the close semaphore (to synchronize open/close operations.
* NOTE: that we do not let this wait be interrupted by a signal. Technically, we
* should, but almost no one every checks the return value from close() so we avoid
* a potential memory leak by ignoring signals in this case.
*/
(void)uart_takesem(&dev->closesem, false);
if (dev->open_count > 1)
{
dev->open_count--;
uart_givesem(&dev->closesem);
return OK;
}
/* There are no more references to the port */
dev->open_count = 0;
/* Stop accepting input */
uart_disablerxint(dev);
/* Now we wait for the transmit buffer to clear */
while (dev->xmit.head != dev->xmit.tail)
{
#ifndef CONFIG_DISABLE_SIGNALS
usleep(HALF_SECOND_USEC);
#else
up_mdelay(HALF_SECOND_MSEC);
#endif
}
/* And wait for the TX fifo to drain */
while (!uart_txempty(dev))
{
#ifndef CONFIG_DISABLE_SIGNALS
usleep(HALF_SECOND_USEC);
#else
up_mdelay(HALF_SECOND_MSEC);
#endif
}
/* Free the IRQ and disable the UART */
flags = irqsave(); /* Disable interrupts */
uart_detach(dev); /* Detach interrupts */
if (!dev->isconsole) /* Check for the serial console UART */
{
uart_shutdown(dev); /* Disable the UART */
}
irqrestore(flags);
uart_givesem(&dev->closesem);
return OK;
}
static ssize_t uart_write(FAR struct file *filep, FAR const char *buffer, size_t buflen)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
ssize_t nread = buflen;
int ret;
/* We may receive console writes through this path from interrupt handlers and
* from debug output in the IDLE task! In these cases, we will need to do things
* a little differently.
*/
if (up_interrupt_context() || getpid() == 0)
{
/* up_putc() will be used to generate the output in a busy-wait loop.
* up_putc() is only available for the console device.
*/
if (dev->isconsole)
{
irqstate_t flags = irqsave();
ret = uart_irqwrite(dev, buffer, buflen);
irqrestore(flags);
return ret;
}
else
{
return -EPERM;
}
}
/* Only one user can access dev->xmit.head at a time */
ret = (ssize_t)uart_takesem(&dev->xmit.sem, true);
if (ret < 0)
{
/* A signal received while waiting for access to the xmit.head will
* abort the transfer. After the transfer has started, we are committed
* and signals will be ignored.
*/
return ret;
}
/* Loop while we still have data to copy to the transmit buffer.
* we add data to the head of the buffer; uart_xmitchars takes the
* data from the end of the buffer.
*/
uart_disabletxint(dev);
for (; buflen; buflen--)
{
int ch = *buffer++;
/* If the ONLCR flag is set, we should translate \n to \r\n */
ret = OK;
if ((ch == '\n') && (dev->termios_s.c_oflag && ONLCR))
{
ret = uart_putxmitchar(dev, '\r');
}
/* Put the character into the transmit buffer */
if (ret == OK)
{
ret = uart_putxmitchar(dev, ch);
}
/* Were we awakened by a signal? That should be the only condition that
* uart_putxmitchar() should return an error.
*/
if (ret < 0)
{
/* POSIX requires that we return -1 and errno set if no data was
* transferred. Otherwise, we return the number of bytes in the
* interrupted transfer.
*/
if (buflen < nread)
{
/* Some data was transferred. Return the number of bytes that were
* successfully transferred.
*/
nread -= buflen;
}
else
{
/* No data was transferred. Return -EINTR. The VFS layer will
* set the errno value appropriately).
*/
nread = -EINTR;
}
break;
}
}
if (dev->xmit.head != dev->xmit.tail)
{
uart_enabletxint(dev);
}
uart_givesem(&dev->xmit.sem);
return nread;
}
int uart_poll(FAR struct file *filep, FAR struct pollfd *fds, bool setup)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
pollevent_t eventset;
int ndx;
int ret;
int i;
/* Some sanity checking */
#if CONFIG_DEBUG
if (!dev || !fds)
{
return -ENODEV;
}
#endif
/* Are we setting up the poll? Or tearing it down? */
ret = uart_takesem(&dev->pollsem, true);
if (ret < 0)
{
/* A signal received while waiting for access to the poll data
* will abort the operation.
*/
return ret;
}
if (setup)
{
/* This is a request to set up the poll. Find an available
* slot for the poll structure reference
*/
for (i = 0; i < CONFIG_SERIAL_NPOLLWAITERS; i++)
{
/* Find an available slot */
if (!dev->fds[i])
{
/* Bind the poll structure and this slot */
dev->fds[i] = fds;
fds->priv = &dev->fds[i];
break;
}
}
if (i >= CONFIG_SERIAL_NPOLLWAITERS)
{
fds->priv = NULL;
ret = -EBUSY;
goto errout;
}
/* Should we immediately notify on any of the requested events?
* First, check if the xmit buffer is full.
*
* Get exclusive access to the xmit buffer indices. NOTE: that we do not
* let this wait be interrupted by a signal (we probably should, but that
* would be a little awkward).
*/
eventset = 0;
(void)uart_takesem(&dev->xmit.sem, false);
ndx = dev->xmit.head + 1;
if (ndx >= dev->xmit.size)
{
ndx = 0;
}
if (ndx != dev->xmit.tail)
{
eventset |= POLLOUT;
}
uart_givesem(&dev->xmit.sem);
/* Check if the receive buffer is empty
*
* Get exclusive access to the recv buffer indices. NOTE: that we do not
* let this wait be interrupted by a signal (we probably should, but that
* would be a little awkward).
*/
(void)uart_takesem(&dev->recv.sem, false);
if (dev->recv.head != dev->recv.tail)
{
eventset |= POLLIN;
}
uart_givesem(&dev->recv.sem);
if (eventset)
{
uart_pollnotify(dev, eventset);
}
}
else if (fds->priv)
{
/* This is a request to tear down the poll. */
struct pollfd **slot = (struct pollfd **)fds->priv;
#ifdef CONFIG_DEBUG
if (!slot)
{
ret = -EIO;
goto errout;
}
#endif
/* Remove all memory of the poll setup */
*slot = NULL;
fds->priv = NULL;
}
errout:
uart_givesem(&dev->pollsem);
return ret;
}
static ssize_t uart_read(FAR struct file *filep, FAR char *buffer, size_t buflen)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
irqstate_t flags;
ssize_t recvd = 0;
int16_t tail;
int ret;
char ch;
/* Only one user can access dev->recv.tail at a time */
ret = uart_takesem(&dev->recv.sem, true);
if (ret < 0)
{
/* A signal received while waiting for access to the recv.tail will avort
* the transfer. After the transfer has started, we are committed and
* signals will be ignored.
*/
return ret;
}
/* Loop while we still have data to copy to the receive buffer.
* we add data to the head of the buffer; uart_xmitchars takes the
* data from the end of the buffer.
*/
while (recvd < buflen)
{
#ifdef CONFIG_SERIAL_REMOVABLE
/* If the removable device is no longer connected, refuse to read any
* further from the device.
*/
if (dev->disconnected)
{
if (recvd == 0)
{
recvd = -ENOTCONN;
}
break;
}
#endif
/* Check if there is more data to return in the circular buffer.
* NOTE: Rx interrupt handling logic may aynchronously increment
* the head index but must not modify the tail index. The tail
* index is only modified in this function. Therefore, no
* special handshaking is required here.
*
* The head and tail pointers are 16-bit values. The only time that
* the following could be unsafe is if the CPU made two non-atomic
* 8-bit accesses to obtain the 16-bit head index.
*/
tail = dev->recv.tail;
if (dev->recv.head != tail)
{
/* Take the next character from the tail of the buffer */
ch = dev->recv.buffer[tail];
/* Increment the tail index. Most operations are done using the
* local variable 'tail' so that the final dev->recv.tail update
* is atomic.
*/
if (++tail >= dev->recv.size)
{
tail = 0;
}
dev->recv.tail = tail;
#ifdef CONFIG_SERIAL_TERMIOS
/* Do input processing if any is enabled */
if (dev->tc_iflag & (INLCR | IGNCR | ICRNL))
{
/* \n -> \r or \r -> \n translation? */
if ((ch == '\n') && (dev->tc_iflag & INLCR))
{
ch = '\r';
}
else if ((ch == '\r') && (dev->tc_iflag & ICRNL))
{
ch = '\n';
}
/* Discarding \r ? */
if ((ch == '\r') & (dev->tc_iflag & IGNCR))
{
continue;
}
}
/* Specifically not handled:
*
* All of the local modes; echo, line editing, etc.
* Anything to do with break or parity errors.
* ISTRIP - we should be 8-bit clean.
* IUCLC - Not Posix
* IXON/OXOFF - no xon/xoff flow control.
*/
#endif
/* Store the received character */
*buffer++ = ch;
recvd++;
}
#ifdef CONFIG_DEV_SERIAL_FULLBLOCKS
/* No... then we would have to wait to get receive more data.
* If the user has specified the O_NONBLOCK option, then just
* return what we have.
*/
else if ((filep->f_oflags & O_NONBLOCK) != 0)
{
/* If nothing was transferred, then return the -EAGAIN
* error (not zero which means end of file).
*/
if (recvd < 1)
{
recvd = -EAGAIN;
}
break;
}
#else
/* No... the circular buffer is empty. Have we returned anything
* to the caller?
*/
else if (recvd > 0)
{
/* Yes.. break out of the loop and return the number of bytes
* received up to the wait condition.
*/
break;
}
/* No... then we would have to wait to get receive some data.
* If the user has specified the O_NONBLOCK option, then do not
* wait.
*/
else if ((filep->f_oflags & O_NONBLOCK) != 0)
{
/* Break out of the loop returning -EAGAIN */
recvd = -EAGAIN;
break;
}
#endif
/* Otherwise we are going to have to wait for data to arrive */
else
{
/* Disable Rx interrupts and test again... */
uart_disablerxint(dev);
/* If the Rx ring buffer still empty? Bytes may have been addded
* between the last time that we checked and when we disabled Rx
* interrupts.
*/
if (dev->recv.head == dev->recv.tail)
{
/* Yes.. the buffer is still empty. Wait for some characters
* to be received into the buffer with the RX interrupt re-
* enabled. All interrupts are disabled briefly to assure
* that the following operations are atomic.
*/
flags = irqsave();
uart_enablerxint(dev);
#ifdef CONFIG_SERIAL_REMOVABLE
/* Check again if the removable device is still connected
* while we have interrupts off. We do not want the transition
* to occur as a race condition before we begin the wait.
*/
if (dev->disconnected)
{
ret = -ENOTCONN;
}
else
#endif
{
/* Now wait with the Rx interrupt re-enabled. NuttX will
* automatically re-enable global interrupts when this
* thread goes to sleep.
*/
dev->recvwaiting = true;
ret = uart_takesem(&dev->recvsem, true);
}
irqrestore(flags);
/* Was a signal received while waiting for data to be
* received? Was a removable device disconnected while
* we were waiting?
*/
#ifdef CONFIG_SERIAL_REMOVABLE
if (ret < 0 || dev->disconnected)
#else
if (ret < 0)
#endif
{
/* POSIX requires that we return after a signal is received.
* If some bytes were read, we need to return the number of bytes
* read; if no bytes were read, we need to return -1 with the
* errno set correctly.
*/
if (recvd == 0)
{
/* No bytes were read, return -EINTR (the VFS layer will
* set the errno value appropriately.
*/
#ifdef CONFIG_SERIAL_REMOVABLE
recvd = dev->disconnected ? -ENOTCONN : -EINTR;
#else
recvd = -EINTR;
#endif
}
break;
}
}
else
{
/* No... the ring buffer is no longer empty. Just re-enable Rx
* interrupts and accept the new data on the next time through
* the loop.
*/
uart_enablerxint(dev);
}
}
}
#ifdef CONFIG_SERIAL_IFLOWCONTROL
if (dev->recv.head == dev->recv.tail)
{
/* We might leave Rx interrupt disabled if full recv buffer was read
* empty. Enable Rx interrupt to make sure that more input is received.
*/
uart_enablerxint(dev);
}
#endif
uart_givesem(&dev->recv.sem);
return recvd;
}
static int uart_putxmitchar(FAR uart_dev_t *dev, int ch)
{
irqstate_t flags;
int nexthead;
int ret;
/* Increment to see what the next head pointer will be. We need to use the "next"
* head pointer to determine when the circular buffer would overrun
*/
nexthead = dev->xmit.head + 1;
if (nexthead >= dev->xmit.size)
{
nexthead = 0;
}
/* Loop until we are able to add the character to the TX buffer */
for (;;)
{
if (nexthead != dev->xmit.tail)
{
dev->xmit.buffer[dev->xmit.head] = ch;
dev->xmit.head = nexthead;
return OK;
}
else
{
/* Inform the interrupt level logic that we are waiting. This and
* the following steps must be atomic.
*/
flags = irqsave();
dev->xmitwaiting = true;
/* Wait for some characters to be sent from the buffer with the TX
* interrupt enabled. When the TX interrupt is enabled, uart_xmitchars
* should execute and remove some of the data from the TX buffer.
*/
uart_enabletxint(dev);
ret = uart_takesem(&dev->xmitsem, true);
uart_disabletxint(dev);
irqrestore(flags);
/* Check if we were awakened by signal. */
if (ret < 0)
{
/* A signal received while waiting for the xmit buffer to become
* non-full will abort the transfer.
*/
return -EINTR;
}
}
}
/* We won't get here */
return OK;
}
static ssize_t uart_write(FAR struct file *filep, FAR const char *buffer,
size_t buflen)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
ssize_t nwritten = buflen;
bool oktoblock;
int ret;
char ch;
/* We may receive console writes through this path from interrupt handlers and
* from debug output in the IDLE task! In these cases, we will need to do things
* a little differently.
*/
if (up_interrupt_context() || getpid() == 0)
{
#ifdef CONFIG_SERIAL_REMOVABLE
/* If the removable device is no longer connected, refuse to write to
* the device.
*/
if (dev->disconnected)
{
return -ENOTCONN;
}
#endif
/* up_putc() will be used to generate the output in a busy-wait loop.
* up_putc() is only available for the console device.
*/
if (dev->isconsole)
{
irqstate_t flags = irqsave();
ret = uart_irqwrite(dev, buffer, buflen);
irqrestore(flags);
return ret;
}
else
{
return -EPERM;
}
}
/* Only one user can access dev->xmit.head at a time */
ret = (ssize_t)uart_takesem(&dev->xmit.sem, true);
if (ret < 0)
{
/* A signal received while waiting for access to the xmit.head will
* abort the transfer. After the transfer has started, we are committed
* and signals will be ignored.
*/
return ret;
}
#ifdef CONFIG_SERIAL_REMOVABLE
/* If the removable device is no longer connected, refuse to write to the
* device. This check occurs after taking the xmit.sem because the
* disconnection event might have occurred while we were waiting for
* access to the transmit buffers.
*/
if (dev->disconnected)
{
uart_givesem(&dev->xmit.sem);
return -ENOTCONN;
}
#endif
/* Can the following loop block, waiting for space in the TX
* buffer?
*/
oktoblock = ((filep->f_oflags & O_NONBLOCK) == 0);
/* Loop while we still have data to copy to the transmit buffer.
* we add data to the head of the buffer; uart_xmitchars takes the
* data from the end of the buffer.
*/
uart_disabletxint(dev);
for (; buflen; buflen--)
{
ch = *buffer++;
ret = OK;
#ifdef CONFIG_SERIAL_TERMIOS
/* Do output post-processing */
if (dev->tc_oflag & OPOST)
{
/* Mapping CR to NL? */
if ((ch == '\r') && (dev->tc_oflag & OCRNL))
{
ch = '\n';
}
/* Are we interested in newline processing? */
if ((ch == '\n') && (dev->tc_oflag & (ONLCR | ONLRET)))
{
ret = uart_putxmitchar(dev, '\r', oktoblock);
if (ret < 0)
{
break;
}
}
/* Specifically not handled:
*
* OXTABS - primarily a full-screen terminal optimisation
* ONOEOT - Unix interoperability hack
* OLCUC - Not specified by Posix
* ONOCR - low-speed interactive optimisation
*/
}
#else /* !CONFIG_SERIAL_TERMIOS */
/* If this is the console, convert \n -> \r\n */
if (dev->isconsole && ch == '\n')
{
ret = uart_putxmitchar(dev, '\r', oktoblock);
}
#endif
/* Put the character into the transmit buffer */
if (ret == OK)
{
ret = uart_putxmitchar(dev, ch, oktoblock);
}
/* uart_putxmitchar() might return an error under one of two
* conditions: (1) The wait for buffer space might have been
* interrupted by a signal (ret should be -EINTR), (2) if
* CONFIG_SERIAL_REMOVABLE is defined, then uart_putxmitchar()
* might also return if the serial device was disconnected
* (with -ENOTCONN), or (3) if O_NONBLOCK is specified, then
* then uart_putxmitchar() might return -EAGAIN if the output
* TX buffer is full.
*/
if (ret < 0)
{
/* POSIX requires that we return -1 and errno set if no data was
* transferred. Otherwise, we return the number of bytes in the
* interrupted transfer.
*/
if (buflen < nwritten)
{
/* Some data was transferred. Return the number of bytes that
* were successfully transferred.
*/
nwritten -= buflen;
}
else
{
/* No data was transferred. Return the negated errno value.
* The VFS layer will set the errno value appropriately).
*/
nwritten = ret;
}
break;
}
}
if (dev->xmit.head != dev->xmit.tail)
{
uart_enabletxint(dev);
}
uart_givesem(&dev->xmit.sem);
return nwritten;
}
static int uart_putxmitchar(FAR uart_dev_t *dev, int ch, bool oktoblock)
{
irqstate_t flags;
int nexthead;
int ret;
/* Increment to see what the next head pointer will be. We need to use the "next"
* head pointer to determine when the circular buffer would overrun
*/
nexthead = dev->xmit.head + 1;
if (nexthead >= dev->xmit.size)
{
nexthead = 0;
}
/* Loop until we are able to add the character to the TX buffer */
for (;;)
{
if (nexthead != dev->xmit.tail)
{
dev->xmit.buffer[dev->xmit.head] = ch;
dev->xmit.head = nexthead;
return OK;
}
/* The buffer is full and no data is available now. Should be block,
* waiting for the hardware to remove some data from the TX
* buffer?
*/
else if (oktoblock)
{
/* Inform the interrupt level logic that we are waiting. This and
* the following steps must be atomic.
*/
flags = irqsave();
#ifdef CONFIG_SERIAL_REMOVABLE
/* Check if the removable device is no longer connected while we
* have interrupts off. We do not want the transition to occur
* as a race condition before we begin the wait.
*/
if (dev->disconnected)
{
ret = -ENOTCONN;
}
else
#endif
{
/* Wait for some characters to be sent from the buffer with
* the TX interrupt enabled. When the TX interrupt is
* enabled, uart_xmitchars should execute and remove some
* of the data from the TX buffer.
*/
dev->xmitwaiting = true;
uart_enabletxint(dev);
ret = uart_takesem(&dev->xmitsem, true);
uart_disabletxint(dev);
}
irqrestore(flags);
#ifdef CONFIG_SERIAL_REMOVABLE
/* Check if the removable device was disconnected while we were
* waiting.
*/
if (dev->disconnected)
{
return -ENOTCONN;
}
#endif
/* Check if we were awakened by signal. */
if (ret < 0)
{
/* A signal received while waiting for the xmit buffer to become
* non-full will abort the transfer.
*/
return -EINTR;
}
}
/* The caller has request that we not block for data. So return the
* EAGAIN error to signal this situation.
*/
else
{
return -EAGAIN;
}
}
/* We won't get here. Some compilers may complain that this code is
* unreachable.
*/
return OK;
}
static int uart_open(FAR struct file *filep)
{
struct inode *inode = filep->f_inode;
uart_dev_t *dev = inode->i_private;
uint8_t tmp;
int ret;
/* If the port is the middle of closing, wait until the close is finished.
* If a signal is received while we are waiting, then return EINTR.
*/
ret = uart_takesem(&dev->closesem, true);
if (ret < 0)
{
/* A signal received while waiting for the last close operation. */
return ret;
}
#ifdef CONFIG_SERIAL_REMOVABLE
/* If the removable device is no longer connected, refuse to open the
* device. We check this after obtaining the close semaphore because
* we might have been waiting when the device was disconnected.
*/
if (dev->disconnected)
{
ret = -ENOTCONN;
goto errout_with_sem;
}
#endif
/* Start up serial port */
/* Increment the count of references to the device. */
tmp = dev->open_count + 1;
if (tmp == 0)
{
/* More than 255 opens; uint8_t overflows to zero */
ret = -EMFILE;
goto errout_with_sem;
}
/* Check if this is the first time that the driver has been opened. */
if (tmp == 1)
{
irqstate_t flags = irqsave();
/* If this is the console, then the UART has already been initialized. */
if (!dev->isconsole)
{
/* Perform one time hardware initialization */
ret = uart_setup(dev);
if (ret < 0)
{
irqrestore(flags);
goto errout_with_sem;
}
}
/* In any event, we do have to configure for interrupt driven mode of
* operation. Attach the hardware IRQ(s). Hmm.. should shutdown() the
* the device in the rare case that uart_attach() fails, tmp==1, and
* this is not the console.
*/
ret = uart_attach(dev);
if (ret < 0)
{
uart_shutdown(dev);
irqrestore(flags);
goto errout_with_sem;
}
/* Mark the io buffers empty */
dev->xmit.head = 0;
dev->xmit.tail = 0;
dev->recv.head = 0;
dev->recv.tail = 0;
/* Initialise termios state */
#ifdef CONFIG_SERIAL_TERMIOS
dev->tc_iflag = 0;
if (dev->isconsole == true)
{
/* Enable \n -> \r\n translation for the console */
dev->tc_oflag = OPOST | ONLCR;
}
else
{
dev->tc_oflag = 0;
}
#endif
/* Enable the RX interrupt */
uart_enablerxint(dev);
irqrestore(flags);
}
/* Save the new open count on success */
dev->open_count = tmp;
errout_with_sem:
uart_givesem(&dev->closesem);
return ret;
}
static ssize_t uart_write(FAR struct file *filep, FAR const char *buffer, size_t buflen)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
ssize_t nread = buflen;
int ret;
char ch;
/* We may receive console writes through this path from interrupt handlers and
* from debug output in the IDLE task! In these cases, we will need to do things
* a little differently.
*/
if (up_interrupt_context() || getpid() == 0)
{
/* up_putc() will be used to generate the output in a busy-wait loop.
* up_putc() is only available for the console device.
*/
if (dev->isconsole)
{
irqstate_t flags = irqsave();
ret = uart_irqwrite(dev, buffer, buflen);
irqrestore(flags);
return ret;
}
else
{
return -EPERM;
}
}
/* Only one user can access dev->xmit.head at a time */
ret = (ssize_t)uart_takesem(&dev->xmit.sem, true);
if (ret < 0)
{
/* A signal received while waiting for access to the xmit.head will
* abort the transfer.
*/
return ret;
}
/* Loop while we still have data to copy to the transmit buffer.
* we add data to the head of the buffer; uart_xmitchars takes the
* data from the end of the buffer.
*/
uart_disabletxint(dev);
for (; buflen; buflen--)
{
ch = *buffer++;
/* Do output post-processing */
#ifdef CONFIG_SERIAL_TERMIOS
if (dev->tc_oflag & OPOST)
{
/* Mapping CR to NL? */
if ((ch == '\r') && (dev->tc_oflag & OCRNL))
{
ch = '\n';
}
/* Are we interested in newline processing? */
if ((ch == '\n') && (dev->tc_oflag & (ONLCR | ONLRET)))
{
ret = uart_putxmitchar(dev, '\r');
if (ret != OK)
{
break;
}
}
/* Specifically not handled:
*
* OXTABS - primarily a full-screen terminal optimisation
* ONOEOT - Unix interoperability hack
* OLCUC - Not specified by Posix
* ONOCR - low-speed interactive optimisation
*/
}
#else /* !CONFIG_SERIAL_TERMIOS */
/* If this is the console, convert \n -> \r\n */
if (dev->isconsole && ch == '\n')
{
ret = uart_putxmitchar(dev, '\r');
}
#endif
/* Put the character into the transmit buffer */
ret = uart_putxmitchar(dev, ch);
if (ret != OK)
{
break;
}
}
if (dev->xmit.head != dev->xmit.tail)
{
uart_enabletxint(dev);
}
uart_givesem(&dev->xmit.sem);
/* Were we interrupted by a signal? That should be the only condition that
* uart_putxmitchar() should return an error.
*/
if (ret < 0)
{
/* POSIX requires that we return -1 and errno set if no data was
* transferred. Otherwise, we return the number of bytes in the
* interrupted transfer.
*/
if (buflen < nread)
{
/* Some data was transferred. Return the number of bytes that were
* successfully transferred.
*/
nread -= buflen;
}
else
{
/* No data was transferred. Return -EINTR. The VFS layer will
* set the errno value appropriately).
*/
nread = -EINTR;
}
}
return nread;
}
static int uart_close(FAR struct file *filep)
{
FAR struct inode *inode = filep->f_inode;
FAR uart_dev_t *dev = inode->i_private;
irqstate_t flags;
/* Get exclusive access to the close semaphore (to synchronize open/close operations.
* NOTE: that we do not let this wait be interrupted by a signal. Technically, we
* should, but almost no one every checks the return value from close() so we avoid
* a potential memory leak by ignoring signals in this case.
*/
(void)uart_takesem(&dev->closesem, false);
if (dev->open_count > 1)
{
dev->open_count--;
uart_givesem(&dev->closesem);
return OK;
}
/* There are no more references to the port */
dev->open_count = 0;
/* Stop accepting input */
uart_disablerxint(dev);
/* Now we wait for the transmit buffer to clear */
while (dev->xmit.head != dev->xmit.tail)
{
#ifndef CONFIG_DISABLE_SIGNALS
usleep(HALF_SECOND_USEC);
#else
up_mdelay(HALF_SECOND_MSEC);
#endif
}
/* And wait for the TX fifo to drain */
while (!uart_txempty(dev))
{
#ifndef CONFIG_DISABLE_SIGNALS
usleep(HALF_SECOND_USEC);
#else
up_mdelay(HALF_SECOND_MSEC);
#endif
}
/* Free the IRQ and disable the UART */
flags = irqsave(); /* Disable interrupts */
uart_detach(dev); /* Detach interrupts */
if (!dev->isconsole) /* Check for the serial console UART */
{
uart_shutdown(dev); /* Disable the UART */
}
irqrestore(flags);
/* We need to re-initialize the semaphores if this is the last close
* of the device, as the close might be caused by pthread_cancel() of
* a thread currently blocking on any of them.
*
* REVISIT: This logic *only* works in the case where the cancelled
* thread had the only reference to the serial driver. If there other
* references, then the this logic will not be executed and the
* semaphore count will still be incorrect.
*/
sem_reinit(&dev->xmitsem, 0, 0);
sem_reinit(&dev->recvsem, 0, 0);
sem_reinit(&dev->xmit.sem, 0, 1);
sem_reinit(&dev->recv.sem, 0, 1);
#ifndef CONFIG_DISABLE_POLL
sem_reinit(&dev->pollsem, 0, 1);
#endif
uart_givesem(&dev->closesem);
return OK;
}
