WSL2-Linux-Kernel/drivers/tty/serial/atmel_serial.c

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/*
* Driver for Atmel AT91 / AT32 Serial ports
* Copyright (C) 2003 Rick Bronson
*
* Based on drivers/char/serial_sa1100.c, by Deep Blue Solutions Ltd.
* Based on drivers/char/serial.c, by Linus Torvalds, Theodore Ts'o.
*
* DMA support added by Chip Coldwell.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
#include <linux/module.h>
#include <linux/tty.h>
#include <linux/ioport.h>
#include <linux/slab.h>
#include <linux/init.h>
#include <linux/serial.h>
#include <linux/clk.h>
#include <linux/console.h>
#include <linux/sysrq.h>
#include <linux/tty_flip.h>
#include <linux/platform_device.h>
#include <linux/of.h>
#include <linux/of_device.h>
#include <linux/of_gpio.h>
#include <linux/dma-mapping.h>
#include <linux/dmaengine.h>
#include <linux/atmel_pdc.h>
#include <linux/atmel_serial.h>
#include <linux/uaccess.h>
#include <linux/platform_data/atmel.h>
#include <linux/timer.h>
#include <linux/gpio.h>
#include <linux/gpio/consumer.h>
#include <linux/err.h>
#include <linux/irq.h>
#include <linux/suspend.h>
#include <asm/io.h>
#include <asm/ioctls.h>
#define PDC_BUFFER_SIZE 512
/* Revisit: We should calculate this based on the actual port settings */
#define PDC_RX_TIMEOUT (3 * 10) /* 3 bytes */
tty/serial: at91: add support to FIFOs Depending on the hardware, TX and RX FIFOs may be available. The RX FIFO can avoid receive overruns, especially when DMA transfers are not used to read data from the Receive Holding Register. For heavy system load, The CPU is likely not be able to fetch data fast enough from the RHR. In addition, the RX FIFO can supersede the DMA/PDC to control the RTS line when the Hardware Handshaking mode is enabled. Two thresholds are to be set for that purpose: - When the number of data in the RX FIFO crosses and becomes lower than or equal to the low threshold, the RTS line is set to low level: the remote peer is requested to send data. - When the number of data in the RX FIFO crosses and becomes greater than or equal to the high threshold, the RTS line is set to high level: the remote peer should stop sending new data. - low threshold <= high threshold Once these two thresholds are set properly, this new feature is enabled by setting the FIFO RTS Control bit of the FIFO Mode Register. FIFOs also introduce a new multiple data mode: the USART works either in multiple data mode or in single data (legacy) mode. If MODE9 bit is set into the Mode Register or if USMODE is set to either LIN_MASTER, LIN_SLAVE or LON_MODE, FIFOs operate in single data mode. Otherwise, they operate in multiple data mode. In this new multiple data mode, accesses to the Receive Holding Register or Transmit Holding Register slightly change. Since this driver implements neither the 9bit data feature (MODE9 bit set into the Mode Register) nor LIN modes, the USART works in multiple data mode whenever FIFOs are available and enabled. We also assume that data are 8bit wide. In single data mode, 32bit access CAN be used to read a single data from RHR or write a single data into THR. However in multiple data mode, a 32bit access to RHR now allows us to read four consecutive data from RX FIFO. Also a 32bit access to THR now allows to write four consecutive data into TX FIFO. So we MUST use 8bit access whenever only one data have to be read/written at a time. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:12 +03:00
/* The minium number of data FIFOs should be able to contain */
#define ATMEL_MIN_FIFO_SIZE 8
/*
* These two offsets are substracted from the RX FIFO size to define the RTS
* high and low thresholds
*/
#define ATMEL_RTS_HIGH_OFFSET 16
#define ATMEL_RTS_LOW_OFFSET 20
#if defined(CONFIG_SERIAL_ATMEL_CONSOLE) && defined(CONFIG_MAGIC_SYSRQ)
#define SUPPORT_SYSRQ
#endif
#include <linux/serial_core.h>
#include "serial_mctrl_gpio.h"
static void atmel_start_rx(struct uart_port *port);
static void atmel_stop_rx(struct uart_port *port);
#ifdef CONFIG_SERIAL_ATMEL_TTYAT
/* Use device name ttyAT, major 204 and minor 154-169. This is necessary if we
* should coexist with the 8250 driver, such as if we have an external 16C550
* UART. */
#define SERIAL_ATMEL_MAJOR 204
#define MINOR_START 154
#define ATMEL_DEVICENAME "ttyAT"
#else
/* Use device name ttyS, major 4, minor 64-68. This is the usual serial port
* name, but it is legally reserved for the 8250 driver. */
#define SERIAL_ATMEL_MAJOR TTY_MAJOR
#define MINOR_START 64
#define ATMEL_DEVICENAME "ttyS"
#endif
#define ATMEL_ISR_PASS_LIMIT 256
struct atmel_dma_buffer {
unsigned char *buf;
dma_addr_t dma_addr;
unsigned int dma_size;
unsigned int ofs;
};
struct atmel_uart_char {
u16 status;
u16 ch;
};
#define ATMEL_SERIAL_RINGSIZE 1024
/*
* at91: 6 USARTs and one DBGU port (SAM9260)
* avr32: 4
*/
#define ATMEL_MAX_UART 7
/*
* We wrap our port structure around the generic uart_port.
*/
struct atmel_uart_port {
struct uart_port uart; /* uart */
struct clk *clk; /* uart clock */
int may_wakeup; /* cached value of device_may_wakeup for times we need to disable it */
u32 backup_imr; /* IMR saved during suspend */
int break_active; /* break being received */
bool use_dma_rx; /* enable DMA receiver */
bool use_pdc_rx; /* enable PDC receiver */
short pdc_rx_idx; /* current PDC RX buffer */
struct atmel_dma_buffer pdc_rx[2]; /* PDC receier */
bool use_dma_tx; /* enable DMA transmitter */
bool use_pdc_tx; /* enable PDC transmitter */
struct atmel_dma_buffer pdc_tx; /* PDC transmitter */
spinlock_t lock_tx; /* port lock */
spinlock_t lock_rx; /* port lock */
struct dma_chan *chan_tx;
struct dma_chan *chan_rx;
struct dma_async_tx_descriptor *desc_tx;
struct dma_async_tx_descriptor *desc_rx;
dma_cookie_t cookie_tx;
dma_cookie_t cookie_rx;
struct scatterlist sg_tx;
struct scatterlist sg_rx;
struct tasklet_struct tasklet;
unsigned int irq_status;
unsigned int irq_status_prev;
unsigned int status_change;
tty/serial: at91: use 32bit writes into TX FIFO when DMA is enabled For now this improvement is only used with TX DMA transfers. The data width must be set properly when configuring the DMA controller. Also the FIFO configuration must be set to match the DMA transfer data width: TXRDYM (Transmitter Ready Mode) and RXRDYM (Receiver Ready Mode) must be set into the FIFO Mode Register. These values are used by the USART to trigger the DMA controller. In single data mode they are not used and should be reset to 0. So the TXRDYM bits are changed to FOUR_DATA; then USART triggers the DMA controller when at least 4 data can be written into the TX FIFO througth the THR. On the other hand the RXRDYM bits are left unchanged to ONE_DATA. Atmel eXtended DMA controller allows us to set a different data width for each part of a scatter-gather transfer. So when calling dmaengine_slave_config() to configure the TX path, we just need to set dst_addr_width to the maximum data width. Then DMA writes into THR are split into up to two parts. The first part carries the first data to be sent and has a length equal to the greatest multiple of 4 (bytes) lower than or equal to the total length of the TX DMA transfer. The second part carries the trailing data (up to 3 bytes). The first part is written by the DMA into THR using 32 bit accesses, whereas 8bit accesses are used for the second part. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:13 +03:00
unsigned int tx_len;
struct circ_buf rx_ring;
struct mctrl_gpios *gpios;
int gpio_irq[UART_GPIO_MAX];
unsigned int tx_done_mask;
tty/serial: at91: add support to FIFOs Depending on the hardware, TX and RX FIFOs may be available. The RX FIFO can avoid receive overruns, especially when DMA transfers are not used to read data from the Receive Holding Register. For heavy system load, The CPU is likely not be able to fetch data fast enough from the RHR. In addition, the RX FIFO can supersede the DMA/PDC to control the RTS line when the Hardware Handshaking mode is enabled. Two thresholds are to be set for that purpose: - When the number of data in the RX FIFO crosses and becomes lower than or equal to the low threshold, the RTS line is set to low level: the remote peer is requested to send data. - When the number of data in the RX FIFO crosses and becomes greater than or equal to the high threshold, the RTS line is set to high level: the remote peer should stop sending new data. - low threshold <= high threshold Once these two thresholds are set properly, this new feature is enabled by setting the FIFO RTS Control bit of the FIFO Mode Register. FIFOs also introduce a new multiple data mode: the USART works either in multiple data mode or in single data (legacy) mode. If MODE9 bit is set into the Mode Register or if USMODE is set to either LIN_MASTER, LIN_SLAVE or LON_MODE, FIFOs operate in single data mode. Otherwise, they operate in multiple data mode. In this new multiple data mode, accesses to the Receive Holding Register or Transmit Holding Register slightly change. Since this driver implements neither the 9bit data feature (MODE9 bit set into the Mode Register) nor LIN modes, the USART works in multiple data mode whenever FIFOs are available and enabled. We also assume that data are 8bit wide. In single data mode, 32bit access CAN be used to read a single data from RHR or write a single data into THR. However in multiple data mode, a 32bit access to RHR now allows us to read four consecutive data from RX FIFO. Also a 32bit access to THR now allows to write four consecutive data into TX FIFO. So we MUST use 8bit access whenever only one data have to be read/written at a time. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:12 +03:00
u32 fifo_size;
u32 rts_high;
u32 rts_low;
bool ms_irq_enabled;
bool is_usart; /* usart or uart */
struct timer_list uart_timer; /* uart timer */
bool suspended;
unsigned int pending;
unsigned int pending_status;
spinlock_t lock_suspended;
int (*prepare_rx)(struct uart_port *port);
int (*prepare_tx)(struct uart_port *port);
void (*schedule_rx)(struct uart_port *port);
void (*schedule_tx)(struct uart_port *port);
void (*release_rx)(struct uart_port *port);
void (*release_tx)(struct uart_port *port);
};
static struct atmel_uart_port atmel_ports[ATMEL_MAX_UART];
static DECLARE_BITMAP(atmel_ports_in_use, ATMEL_MAX_UART);
#ifdef SUPPORT_SYSRQ
static struct console atmel_console;
#endif
#if defined(CONFIG_OF)
static const struct of_device_id atmel_serial_dt_ids[] = {
{ .compatible = "atmel,at91rm9200-usart" },
{ .compatible = "atmel,at91sam9260-usart" },
{ /* sentinel */ }
};
MODULE_DEVICE_TABLE(of, atmel_serial_dt_ids);
#endif
static inline struct atmel_uart_port *
to_atmel_uart_port(struct uart_port *uart)
{
return container_of(uart, struct atmel_uart_port, uart);
}
static inline u32 atmel_uart_readl(struct uart_port *port, u32 reg)
{
return __raw_readl(port->membase + reg);
}
static inline void atmel_uart_writel(struct uart_port *port, u32 reg, u32 value)
{
__raw_writel(value, port->membase + reg);
}
#ifdef CONFIG_AVR32
/* AVR32 cannot handle 8 or 16bit I/O accesses but only 32bit I/O accesses */
static inline u8 atmel_uart_read_char(struct uart_port *port)
{
return __raw_readl(port->membase + ATMEL_US_RHR);
}
static inline void atmel_uart_write_char(struct uart_port *port, u8 value)
tty/serial: at91: add support to FIFOs Depending on the hardware, TX and RX FIFOs may be available. The RX FIFO can avoid receive overruns, especially when DMA transfers are not used to read data from the Receive Holding Register. For heavy system load, The CPU is likely not be able to fetch data fast enough from the RHR. In addition, the RX FIFO can supersede the DMA/PDC to control the RTS line when the Hardware Handshaking mode is enabled. Two thresholds are to be set for that purpose: - When the number of data in the RX FIFO crosses and becomes lower than or equal to the low threshold, the RTS line is set to low level: the remote peer is requested to send data. - When the number of data in the RX FIFO crosses and becomes greater than or equal to the high threshold, the RTS line is set to high level: the remote peer should stop sending new data. - low threshold <= high threshold Once these two thresholds are set properly, this new feature is enabled by setting the FIFO RTS Control bit of the FIFO Mode Register. FIFOs also introduce a new multiple data mode: the USART works either in multiple data mode or in single data (legacy) mode. If MODE9 bit is set into the Mode Register or if USMODE is set to either LIN_MASTER, LIN_SLAVE or LON_MODE, FIFOs operate in single data mode. Otherwise, they operate in multiple data mode. In this new multiple data mode, accesses to the Receive Holding Register or Transmit Holding Register slightly change. Since this driver implements neither the 9bit data feature (MODE9 bit set into the Mode Register) nor LIN modes, the USART works in multiple data mode whenever FIFOs are available and enabled. We also assume that data are 8bit wide. In single data mode, 32bit access CAN be used to read a single data from RHR or write a single data into THR. However in multiple data mode, a 32bit access to RHR now allows us to read four consecutive data from RX FIFO. Also a 32bit access to THR now allows to write four consecutive data into TX FIFO. So we MUST use 8bit access whenever only one data have to be read/written at a time. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:12 +03:00
{
__raw_writel(value, port->membase + ATMEL_US_THR);
tty/serial: at91: add support to FIFOs Depending on the hardware, TX and RX FIFOs may be available. The RX FIFO can avoid receive overruns, especially when DMA transfers are not used to read data from the Receive Holding Register. For heavy system load, The CPU is likely not be able to fetch data fast enough from the RHR. In addition, the RX FIFO can supersede the DMA/PDC to control the RTS line when the Hardware Handshaking mode is enabled. Two thresholds are to be set for that purpose: - When the number of data in the RX FIFO crosses and becomes lower than or equal to the low threshold, the RTS line is set to low level: the remote peer is requested to send data. - When the number of data in the RX FIFO crosses and becomes greater than or equal to the high threshold, the RTS line is set to high level: the remote peer should stop sending new data. - low threshold <= high threshold Once these two thresholds are set properly, this new feature is enabled by setting the FIFO RTS Control bit of the FIFO Mode Register. FIFOs also introduce a new multiple data mode: the USART works either in multiple data mode or in single data (legacy) mode. If MODE9 bit is set into the Mode Register or if USMODE is set to either LIN_MASTER, LIN_SLAVE or LON_MODE, FIFOs operate in single data mode. Otherwise, they operate in multiple data mode. In this new multiple data mode, accesses to the Receive Holding Register or Transmit Holding Register slightly change. Since this driver implements neither the 9bit data feature (MODE9 bit set into the Mode Register) nor LIN modes, the USART works in multiple data mode whenever FIFOs are available and enabled. We also assume that data are 8bit wide. In single data mode, 32bit access CAN be used to read a single data from RHR or write a single data into THR. However in multiple data mode, a 32bit access to RHR now allows us to read four consecutive data from RX FIFO. Also a 32bit access to THR now allows to write four consecutive data into TX FIFO. So we MUST use 8bit access whenever only one data have to be read/written at a time. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:12 +03:00
}
#else
static inline u8 atmel_uart_read_char(struct uart_port *port)
tty/serial: at91: add support to FIFOs Depending on the hardware, TX and RX FIFOs may be available. The RX FIFO can avoid receive overruns, especially when DMA transfers are not used to read data from the Receive Holding Register. For heavy system load, The CPU is likely not be able to fetch data fast enough from the RHR. In addition, the RX FIFO can supersede the DMA/PDC to control the RTS line when the Hardware Handshaking mode is enabled. Two thresholds are to be set for that purpose: - When the number of data in the RX FIFO crosses and becomes lower than or equal to the low threshold, the RTS line is set to low level: the remote peer is requested to send data. - When the number of data in the RX FIFO crosses and becomes greater than or equal to the high threshold, the RTS line is set to high level: the remote peer should stop sending new data. - low threshold <= high threshold Once these two thresholds are set properly, this new feature is enabled by setting the FIFO RTS Control bit of the FIFO Mode Register. FIFOs also introduce a new multiple data mode: the USART works either in multiple data mode or in single data (legacy) mode. If MODE9 bit is set into the Mode Register or if USMODE is set to either LIN_MASTER, LIN_SLAVE or LON_MODE, FIFOs operate in single data mode. Otherwise, they operate in multiple data mode. In this new multiple data mode, accesses to the Receive Holding Register or Transmit Holding Register slightly change. Since this driver implements neither the 9bit data feature (MODE9 bit set into the Mode Register) nor LIN modes, the USART works in multiple data mode whenever FIFOs are available and enabled. We also assume that data are 8bit wide. In single data mode, 32bit access CAN be used to read a single data from RHR or write a single data into THR. However in multiple data mode, a 32bit access to RHR now allows us to read four consecutive data from RX FIFO. Also a 32bit access to THR now allows to write four consecutive data into TX FIFO. So we MUST use 8bit access whenever only one data have to be read/written at a time. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:12 +03:00
{
return __raw_readb(port->membase + ATMEL_US_RHR);
tty/serial: at91: add support to FIFOs Depending on the hardware, TX and RX FIFOs may be available. The RX FIFO can avoid receive overruns, especially when DMA transfers are not used to read data from the Receive Holding Register. For heavy system load, The CPU is likely not be able to fetch data fast enough from the RHR. In addition, the RX FIFO can supersede the DMA/PDC to control the RTS line when the Hardware Handshaking mode is enabled. Two thresholds are to be set for that purpose: - When the number of data in the RX FIFO crosses and becomes lower than or equal to the low threshold, the RTS line is set to low level: the remote peer is requested to send data. - When the number of data in the RX FIFO crosses and becomes greater than or equal to the high threshold, the RTS line is set to high level: the remote peer should stop sending new data. - low threshold <= high threshold Once these two thresholds are set properly, this new feature is enabled by setting the FIFO RTS Control bit of the FIFO Mode Register. FIFOs also introduce a new multiple data mode: the USART works either in multiple data mode or in single data (legacy) mode. If MODE9 bit is set into the Mode Register or if USMODE is set to either LIN_MASTER, LIN_SLAVE or LON_MODE, FIFOs operate in single data mode. Otherwise, they operate in multiple data mode. In this new multiple data mode, accesses to the Receive Holding Register or Transmit Holding Register slightly change. Since this driver implements neither the 9bit data feature (MODE9 bit set into the Mode Register) nor LIN modes, the USART works in multiple data mode whenever FIFOs are available and enabled. We also assume that data are 8bit wide. In single data mode, 32bit access CAN be used to read a single data from RHR or write a single data into THR. However in multiple data mode, a 32bit access to RHR now allows us to read four consecutive data from RX FIFO. Also a 32bit access to THR now allows to write four consecutive data into TX FIFO. So we MUST use 8bit access whenever only one data have to be read/written at a time. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:12 +03:00
}
static inline void atmel_uart_write_char(struct uart_port *port, u8 value)
{
__raw_writeb(value, port->membase + ATMEL_US_THR);
}
#endif
#ifdef CONFIG_SERIAL_ATMEL_PDC
static bool atmel_use_pdc_rx(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
return atmel_port->use_pdc_rx;
}
static bool atmel_use_pdc_tx(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
return atmel_port->use_pdc_tx;
}
#else
static bool atmel_use_pdc_rx(struct uart_port *port)
{
return false;
}
static bool atmel_use_pdc_tx(struct uart_port *port)
{
return false;
}
#endif
static bool atmel_use_dma_tx(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
return atmel_port->use_dma_tx;
}
static bool atmel_use_dma_rx(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
return atmel_port->use_dma_rx;
}
static unsigned int atmel_get_lines_status(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
unsigned int status, ret = 0;
status = atmel_uart_readl(port, ATMEL_US_CSR);
mctrl_gpio_get(atmel_port->gpios, &ret);
if (!IS_ERR_OR_NULL(mctrl_gpio_to_gpiod(atmel_port->gpios,
UART_GPIO_CTS))) {
if (ret & TIOCM_CTS)
status &= ~ATMEL_US_CTS;
else
status |= ATMEL_US_CTS;
}
if (!IS_ERR_OR_NULL(mctrl_gpio_to_gpiod(atmel_port->gpios,
UART_GPIO_DSR))) {
if (ret & TIOCM_DSR)
status &= ~ATMEL_US_DSR;
else
status |= ATMEL_US_DSR;
}
if (!IS_ERR_OR_NULL(mctrl_gpio_to_gpiod(atmel_port->gpios,
UART_GPIO_RI))) {
if (ret & TIOCM_RI)
status &= ~ATMEL_US_RI;
else
status |= ATMEL_US_RI;
}
if (!IS_ERR_OR_NULL(mctrl_gpio_to_gpiod(atmel_port->gpios,
UART_GPIO_DCD))) {
if (ret & TIOCM_CD)
status &= ~ATMEL_US_DCD;
else
status |= ATMEL_US_DCD;
}
return status;
}
/* Enable or disable the rs485 support */
static int atmel_config_rs485(struct uart_port *port,
struct serial_rs485 *rs485conf)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
unsigned int mode;
/* Disable interrupts */
atmel_uart_writel(port, ATMEL_US_IDR, atmel_port->tx_done_mask);
mode = atmel_uart_readl(port, ATMEL_US_MR);
/* Resetting serial mode to RS232 (0x0) */
mode &= ~ATMEL_US_USMODE;
port->rs485 = *rs485conf;
if (rs485conf->flags & SER_RS485_ENABLED) {
dev_dbg(port->dev, "Setting UART to RS485\n");
atmel_port->tx_done_mask = ATMEL_US_TXEMPTY;
atmel_uart_writel(port, ATMEL_US_TTGR,
rs485conf->delay_rts_after_send);
mode |= ATMEL_US_USMODE_RS485;
} else {
dev_dbg(port->dev, "Setting UART to RS232\n");
if (atmel_use_pdc_tx(port))
atmel_port->tx_done_mask = ATMEL_US_ENDTX |
ATMEL_US_TXBUFE;
else
atmel_port->tx_done_mask = ATMEL_US_TXRDY;
}
atmel_uart_writel(port, ATMEL_US_MR, mode);
/* Enable interrupts */
atmel_uart_writel(port, ATMEL_US_IER, atmel_port->tx_done_mask);
return 0;
}
/*
* Return TIOCSER_TEMT when transmitter FIFO and Shift register is empty.
*/
static u_int atmel_tx_empty(struct uart_port *port)
{
return (atmel_uart_readl(port, ATMEL_US_CSR) & ATMEL_US_TXEMPTY) ?
TIOCSER_TEMT :
0;
}
/*
* Set state of the modem control output lines
*/
static void atmel_set_mctrl(struct uart_port *port, u_int mctrl)
{
unsigned int control = 0;
unsigned int mode = atmel_uart_readl(port, ATMEL_US_MR);
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
unsigned int rts_paused, rts_ready;
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
/* override mode to RS485 if needed, otherwise keep the current mode */
if (port->rs485.flags & SER_RS485_ENABLED) {
atmel_uart_writel(port, ATMEL_US_TTGR,
port->rs485.delay_rts_after_send);
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
mode &= ~ATMEL_US_USMODE;
mode |= ATMEL_US_USMODE_RS485;
}
/* set the RTS line state according to the mode */
if ((mode & ATMEL_US_USMODE) == ATMEL_US_USMODE_HWHS) {
/* force RTS line to high level */
rts_paused = ATMEL_US_RTSEN;
/* give the control of the RTS line back to the hardware */
rts_ready = ATMEL_US_RTSDIS;
} else {
/* force RTS line to high level */
rts_paused = ATMEL_US_RTSDIS;
/* force RTS line to low level */
rts_ready = ATMEL_US_RTSEN;
}
if (mctrl & TIOCM_RTS)
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
control |= rts_ready;
else
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
control |= rts_paused;
if (mctrl & TIOCM_DTR)
control |= ATMEL_US_DTREN;
else
control |= ATMEL_US_DTRDIS;
atmel_uart_writel(port, ATMEL_US_CR, control);
mctrl_gpio_set(atmel_port->gpios, mctrl);
/* Local loopback mode? */
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
mode &= ~ATMEL_US_CHMODE;
if (mctrl & TIOCM_LOOP)
mode |= ATMEL_US_CHMODE_LOC_LOOP;
else
mode |= ATMEL_US_CHMODE_NORMAL;
atmel_uart_writel(port, ATMEL_US_MR, mode);
}
/*
* Get state of the modem control input lines
*/
static u_int atmel_get_mctrl(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
unsigned int ret = 0, status;
status = atmel_uart_readl(port, ATMEL_US_CSR);
/*
* The control signals are active low.
*/
if (!(status & ATMEL_US_DCD))
ret |= TIOCM_CD;
if (!(status & ATMEL_US_CTS))
ret |= TIOCM_CTS;
if (!(status & ATMEL_US_DSR))
ret |= TIOCM_DSR;
if (!(status & ATMEL_US_RI))
ret |= TIOCM_RI;
return mctrl_gpio_get(atmel_port->gpios, &ret);
}
/*
* Stop transmitting.
*/
static void atmel_stop_tx(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
if (atmel_use_pdc_tx(port)) {
/* disable PDC transmit */
atmel_uart_writel(port, ATMEL_PDC_PTCR, ATMEL_PDC_TXTDIS);
}
/* Disable interrupts */
atmel_uart_writel(port, ATMEL_US_IDR, atmel_port->tx_done_mask);
if ((port->rs485.flags & SER_RS485_ENABLED) &&
!(port->rs485.flags & SER_RS485_RX_DURING_TX))
atmel_start_rx(port);
}
/*
* Start transmitting.
*/
static void atmel_start_tx(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
if (atmel_use_pdc_tx(port)) {
if (atmel_uart_readl(port, ATMEL_PDC_PTSR) & ATMEL_PDC_TXTEN)
/* The transmitter is already running. Yes, we
really need this.*/
return;
if ((port->rs485.flags & SER_RS485_ENABLED) &&
!(port->rs485.flags & SER_RS485_RX_DURING_TX))
atmel_stop_rx(port);
/* re-enable PDC transmit */
atmel_uart_writel(port, ATMEL_PDC_PTCR, ATMEL_PDC_TXTEN);
}
/* Enable interrupts */
atmel_uart_writel(port, ATMEL_US_IER, atmel_port->tx_done_mask);
}
/*
* start receiving - port is in process of being opened.
*/
static void atmel_start_rx(struct uart_port *port)
{
/* reset status and receiver */
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_RSTSTA);
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_RXEN);
if (atmel_use_pdc_rx(port)) {
/* enable PDC controller */
atmel_uart_writel(port, ATMEL_US_IER,
ATMEL_US_ENDRX | ATMEL_US_TIMEOUT |
port->read_status_mask);
atmel_uart_writel(port, ATMEL_PDC_PTCR, ATMEL_PDC_RXTEN);
} else {
atmel_uart_writel(port, ATMEL_US_IER, ATMEL_US_RXRDY);
}
}
/*
* Stop receiving - port is in process of being closed.
*/
static void atmel_stop_rx(struct uart_port *port)
{
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_RXDIS);
if (atmel_use_pdc_rx(port)) {
/* disable PDC receive */
atmel_uart_writel(port, ATMEL_PDC_PTCR, ATMEL_PDC_RXTDIS);
atmel_uart_writel(port, ATMEL_US_IDR,
ATMEL_US_ENDRX | ATMEL_US_TIMEOUT |
port->read_status_mask);
} else {
atmel_uart_writel(port, ATMEL_US_IDR, ATMEL_US_RXRDY);
}
}
/*
* Enable modem status interrupts
*/
static void atmel_enable_ms(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
uint32_t ier = 0;
/*
* Interrupt should not be enabled twice
*/
if (atmel_port->ms_irq_enabled)
return;
atmel_port->ms_irq_enabled = true;
if (atmel_port->gpio_irq[UART_GPIO_CTS] >= 0)
enable_irq(atmel_port->gpio_irq[UART_GPIO_CTS]);
else
ier |= ATMEL_US_CTSIC;
if (atmel_port->gpio_irq[UART_GPIO_DSR] >= 0)
enable_irq(atmel_port->gpio_irq[UART_GPIO_DSR]);
else
ier |= ATMEL_US_DSRIC;
if (atmel_port->gpio_irq[UART_GPIO_RI] >= 0)
enable_irq(atmel_port->gpio_irq[UART_GPIO_RI]);
else
ier |= ATMEL_US_RIIC;
if (atmel_port->gpio_irq[UART_GPIO_DCD] >= 0)
enable_irq(atmel_port->gpio_irq[UART_GPIO_DCD]);
else
ier |= ATMEL_US_DCDIC;
atmel_uart_writel(port, ATMEL_US_IER, ier);
}
/*
* Disable modem status interrupts
*/
static void atmel_disable_ms(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
uint32_t idr = 0;
/*
* Interrupt should not be disabled twice
*/
if (!atmel_port->ms_irq_enabled)
return;
atmel_port->ms_irq_enabled = false;
if (atmel_port->gpio_irq[UART_GPIO_CTS] >= 0)
disable_irq(atmel_port->gpio_irq[UART_GPIO_CTS]);
else
idr |= ATMEL_US_CTSIC;
if (atmel_port->gpio_irq[UART_GPIO_DSR] >= 0)
disable_irq(atmel_port->gpio_irq[UART_GPIO_DSR]);
else
idr |= ATMEL_US_DSRIC;
if (atmel_port->gpio_irq[UART_GPIO_RI] >= 0)
disable_irq(atmel_port->gpio_irq[UART_GPIO_RI]);
else
idr |= ATMEL_US_RIIC;
if (atmel_port->gpio_irq[UART_GPIO_DCD] >= 0)
disable_irq(atmel_port->gpio_irq[UART_GPIO_DCD]);
else
idr |= ATMEL_US_DCDIC;
atmel_uart_writel(port, ATMEL_US_IDR, idr);
}
/*
* Control the transmission of a break signal
*/
static void atmel_break_ctl(struct uart_port *port, int break_state)
{
if (break_state != 0)
/* start break */
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_STTBRK);
else
/* stop break */
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_STPBRK);
}
/*
* Stores the incoming character in the ring buffer
*/
static void
atmel_buffer_rx_char(struct uart_port *port, unsigned int status,
unsigned int ch)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct circ_buf *ring = &atmel_port->rx_ring;
struct atmel_uart_char *c;
if (!CIRC_SPACE(ring->head, ring->tail, ATMEL_SERIAL_RINGSIZE))
/* Buffer overflow, ignore char */
return;
c = &((struct atmel_uart_char *)ring->buf)[ring->head];
c->status = status;
c->ch = ch;
/* Make sure the character is stored before we update head. */
smp_wmb();
ring->head = (ring->head + 1) & (ATMEL_SERIAL_RINGSIZE - 1);
}
/*
* Deal with parity, framing and overrun errors.
*/
static void atmel_pdc_rxerr(struct uart_port *port, unsigned int status)
{
/* clear error */
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_RSTSTA);
if (status & ATMEL_US_RXBRK) {
/* ignore side-effect */
status &= ~(ATMEL_US_PARE | ATMEL_US_FRAME);
port->icount.brk++;
}
if (status & ATMEL_US_PARE)
port->icount.parity++;
if (status & ATMEL_US_FRAME)
port->icount.frame++;
if (status & ATMEL_US_OVRE)
port->icount.overrun++;
}
/*
* Characters received (called from interrupt handler)
*/
IRQ: Maintain regs pointer globally rather than passing to IRQ handlers Maintain a per-CPU global "struct pt_regs *" variable which can be used instead of passing regs around manually through all ~1800 interrupt handlers in the Linux kernel. The regs pointer is used in few places, but it potentially costs both stack space and code to pass it around. On the FRV arch, removing the regs parameter from all the genirq function results in a 20% speed up of the IRQ exit path (ie: from leaving timer_interrupt() to leaving do_IRQ()). Where appropriate, an arch may override the generic storage facility and do something different with the variable. On FRV, for instance, the address is maintained in GR28 at all times inside the kernel as part of general exception handling. Having looked over the code, it appears that the parameter may be handed down through up to twenty or so layers of functions. Consider a USB character device attached to a USB hub, attached to a USB controller that posts its interrupts through a cascaded auxiliary interrupt controller. A character device driver may want to pass regs to the sysrq handler through the input layer which adds another few layers of parameter passing. I've build this code with allyesconfig for x86_64 and i386. I've runtested the main part of the code on FRV and i386, though I can't test most of the drivers. I've also done partial conversion for powerpc and MIPS - these at least compile with minimal configurations. This will affect all archs. Mostly the changes should be relatively easy. Take do_IRQ(), store the regs pointer at the beginning, saving the old one: struct pt_regs *old_regs = set_irq_regs(regs); And put the old one back at the end: set_irq_regs(old_regs); Don't pass regs through to generic_handle_irq() or __do_IRQ(). In timer_interrupt(), this sort of change will be necessary: - update_process_times(user_mode(regs)); - profile_tick(CPU_PROFILING, regs); + update_process_times(user_mode(get_irq_regs())); + profile_tick(CPU_PROFILING); I'd like to move update_process_times()'s use of get_irq_regs() into itself, except that i386, alone of the archs, uses something other than user_mode(). Some notes on the interrupt handling in the drivers: (*) input_dev() is now gone entirely. The regs pointer is no longer stored in the input_dev struct. (*) finish_unlinks() in drivers/usb/host/ohci-q.c needs checking. It does something different depending on whether it's been supplied with a regs pointer or not. (*) Various IRQ handler function pointers have been moved to type irq_handler_t. Signed-Off-By: David Howells <dhowells@redhat.com> (cherry picked from 1b16e7ac850969f38b375e511e3fa2f474a33867 commit)
2006-10-05 17:55:46 +04:00
static void atmel_rx_chars(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
unsigned int status, ch;
status = atmel_uart_readl(port, ATMEL_US_CSR);
while (status & ATMEL_US_RXRDY) {
ch = atmel_uart_read_char(port);
/*
* note that the error handling code is
* out of the main execution path
*/
if (unlikely(status & (ATMEL_US_PARE | ATMEL_US_FRAME
| ATMEL_US_OVRE | ATMEL_US_RXBRK)
|| atmel_port->break_active)) {
/* clear error */
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_RSTSTA);
if (status & ATMEL_US_RXBRK
&& !atmel_port->break_active) {
atmel_port->break_active = 1;
atmel_uart_writel(port, ATMEL_US_IER,
ATMEL_US_RXBRK);
} else {
/*
* This is either the end-of-break
* condition or we've received at
* least one character without RXBRK
* being set. In both cases, the next
* RXBRK will indicate start-of-break.
*/
atmel_uart_writel(port, ATMEL_US_IDR,
ATMEL_US_RXBRK);
status &= ~ATMEL_US_RXBRK;
atmel_port->break_active = 0;
}
}
atmel_buffer_rx_char(port, status, ch);
status = atmel_uart_readl(port, ATMEL_US_CSR);
}
tasklet_schedule(&atmel_port->tasklet);
}
/*
* Transmit characters (called from tasklet with TXRDY interrupt
* disabled)
*/
static void atmel_tx_chars(struct uart_port *port)
{
struct circ_buf *xmit = &port->state->xmit;
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
if (port->x_char &&
(atmel_uart_readl(port, ATMEL_US_CSR) & atmel_port->tx_done_mask)) {
atmel_uart_write_char(port, port->x_char);
port->icount.tx++;
port->x_char = 0;
}
if (uart_circ_empty(xmit) || uart_tx_stopped(port))
return;
while (atmel_uart_readl(port, ATMEL_US_CSR) &
atmel_port->tx_done_mask) {
atmel_uart_write_char(port, xmit->buf[xmit->tail]);
xmit->tail = (xmit->tail + 1) & (UART_XMIT_SIZE - 1);
port->icount.tx++;
if (uart_circ_empty(xmit))
break;
}
if (uart_circ_chars_pending(xmit) < WAKEUP_CHARS)
uart_write_wakeup(port);
if (!uart_circ_empty(xmit))
/* Enable interrupts */
atmel_uart_writel(port, ATMEL_US_IER,
atmel_port->tx_done_mask);
}
static void atmel_complete_tx_dma(void *arg)
{
struct atmel_uart_port *atmel_port = arg;
struct uart_port *port = &atmel_port->uart;
struct circ_buf *xmit = &port->state->xmit;
struct dma_chan *chan = atmel_port->chan_tx;
unsigned long flags;
spin_lock_irqsave(&port->lock, flags);
if (chan)
dmaengine_terminate_all(chan);
tty/serial: at91: use 32bit writes into TX FIFO when DMA is enabled For now this improvement is only used with TX DMA transfers. The data width must be set properly when configuring the DMA controller. Also the FIFO configuration must be set to match the DMA transfer data width: TXRDYM (Transmitter Ready Mode) and RXRDYM (Receiver Ready Mode) must be set into the FIFO Mode Register. These values are used by the USART to trigger the DMA controller. In single data mode they are not used and should be reset to 0. So the TXRDYM bits are changed to FOUR_DATA; then USART triggers the DMA controller when at least 4 data can be written into the TX FIFO througth the THR. On the other hand the RXRDYM bits are left unchanged to ONE_DATA. Atmel eXtended DMA controller allows us to set a different data width for each part of a scatter-gather transfer. So when calling dmaengine_slave_config() to configure the TX path, we just need to set dst_addr_width to the maximum data width. Then DMA writes into THR are split into up to two parts. The first part carries the first data to be sent and has a length equal to the greatest multiple of 4 (bytes) lower than or equal to the total length of the TX DMA transfer. The second part carries the trailing data (up to 3 bytes). The first part is written by the DMA into THR using 32 bit accesses, whereas 8bit accesses are used for the second part. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:13 +03:00
xmit->tail += atmel_port->tx_len;
xmit->tail &= UART_XMIT_SIZE - 1;
tty/serial: at91: use 32bit writes into TX FIFO when DMA is enabled For now this improvement is only used with TX DMA transfers. The data width must be set properly when configuring the DMA controller. Also the FIFO configuration must be set to match the DMA transfer data width: TXRDYM (Transmitter Ready Mode) and RXRDYM (Receiver Ready Mode) must be set into the FIFO Mode Register. These values are used by the USART to trigger the DMA controller. In single data mode they are not used and should be reset to 0. So the TXRDYM bits are changed to FOUR_DATA; then USART triggers the DMA controller when at least 4 data can be written into the TX FIFO througth the THR. On the other hand the RXRDYM bits are left unchanged to ONE_DATA. Atmel eXtended DMA controller allows us to set a different data width for each part of a scatter-gather transfer. So when calling dmaengine_slave_config() to configure the TX path, we just need to set dst_addr_width to the maximum data width. Then DMA writes into THR are split into up to two parts. The first part carries the first data to be sent and has a length equal to the greatest multiple of 4 (bytes) lower than or equal to the total length of the TX DMA transfer. The second part carries the trailing data (up to 3 bytes). The first part is written by the DMA into THR using 32 bit accesses, whereas 8bit accesses are used for the second part. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:13 +03:00
port->icount.tx += atmel_port->tx_len;
spin_lock_irq(&atmel_port->lock_tx);
async_tx_ack(atmel_port->desc_tx);
atmel_port->cookie_tx = -EINVAL;
atmel_port->desc_tx = NULL;
spin_unlock_irq(&atmel_port->lock_tx);
if (uart_circ_chars_pending(xmit) < WAKEUP_CHARS)
uart_write_wakeup(port);
/*
* xmit is a circular buffer so, if we have just send data from
* xmit->tail to the end of xmit->buf, now we have to transmit the
* remaining data from the beginning of xmit->buf to xmit->head.
*/
if (!uart_circ_empty(xmit))
tasklet_schedule(&atmel_port->tasklet);
spin_unlock_irqrestore(&port->lock, flags);
}
static void atmel_release_tx_dma(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct dma_chan *chan = atmel_port->chan_tx;
if (chan) {
dmaengine_terminate_all(chan);
dma_release_channel(chan);
dma_unmap_sg(port->dev, &atmel_port->sg_tx, 1,
DMA_TO_DEVICE);
}
atmel_port->desc_tx = NULL;
atmel_port->chan_tx = NULL;
atmel_port->cookie_tx = -EINVAL;
}
/*
* Called from tasklet with TXRDY interrupt is disabled.
*/
static void atmel_tx_dma(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct circ_buf *xmit = &port->state->xmit;
struct dma_chan *chan = atmel_port->chan_tx;
struct dma_async_tx_descriptor *desc;
tty/serial: at91: use 32bit writes into TX FIFO when DMA is enabled For now this improvement is only used with TX DMA transfers. The data width must be set properly when configuring the DMA controller. Also the FIFO configuration must be set to match the DMA transfer data width: TXRDYM (Transmitter Ready Mode) and RXRDYM (Receiver Ready Mode) must be set into the FIFO Mode Register. These values are used by the USART to trigger the DMA controller. In single data mode they are not used and should be reset to 0. So the TXRDYM bits are changed to FOUR_DATA; then USART triggers the DMA controller when at least 4 data can be written into the TX FIFO througth the THR. On the other hand the RXRDYM bits are left unchanged to ONE_DATA. Atmel eXtended DMA controller allows us to set a different data width for each part of a scatter-gather transfer. So when calling dmaengine_slave_config() to configure the TX path, we just need to set dst_addr_width to the maximum data width. Then DMA writes into THR are split into up to two parts. The first part carries the first data to be sent and has a length equal to the greatest multiple of 4 (bytes) lower than or equal to the total length of the TX DMA transfer. The second part carries the trailing data (up to 3 bytes). The first part is written by the DMA into THR using 32 bit accesses, whereas 8bit accesses are used for the second part. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:13 +03:00
struct scatterlist sgl[2], *sg, *sg_tx = &atmel_port->sg_tx;
unsigned int tx_len, part1_len, part2_len, sg_len;
dma_addr_t phys_addr;
/* Make sure we have an idle channel */
if (atmel_port->desc_tx != NULL)
return;
if (!uart_circ_empty(xmit) && !uart_tx_stopped(port)) {
/*
* DMA is idle now.
* Port xmit buffer is already mapped,
* and it is one page... Just adjust
* offsets and lengths. Since it is a circular buffer,
* we have to transmit till the end, and then the rest.
* Take the port lock to get a
* consistent xmit buffer state.
*/
tty/serial: at91: use 32bit writes into TX FIFO when DMA is enabled For now this improvement is only used with TX DMA transfers. The data width must be set properly when configuring the DMA controller. Also the FIFO configuration must be set to match the DMA transfer data width: TXRDYM (Transmitter Ready Mode) and RXRDYM (Receiver Ready Mode) must be set into the FIFO Mode Register. These values are used by the USART to trigger the DMA controller. In single data mode they are not used and should be reset to 0. So the TXRDYM bits are changed to FOUR_DATA; then USART triggers the DMA controller when at least 4 data can be written into the TX FIFO througth the THR. On the other hand the RXRDYM bits are left unchanged to ONE_DATA. Atmel eXtended DMA controller allows us to set a different data width for each part of a scatter-gather transfer. So when calling dmaengine_slave_config() to configure the TX path, we just need to set dst_addr_width to the maximum data width. Then DMA writes into THR are split into up to two parts. The first part carries the first data to be sent and has a length equal to the greatest multiple of 4 (bytes) lower than or equal to the total length of the TX DMA transfer. The second part carries the trailing data (up to 3 bytes). The first part is written by the DMA into THR using 32 bit accesses, whereas 8bit accesses are used for the second part. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:13 +03:00
tx_len = CIRC_CNT_TO_END(xmit->head,
xmit->tail,
UART_XMIT_SIZE);
if (atmel_port->fifo_size) {
/* multi data mode */
part1_len = (tx_len & ~0x3); /* DWORD access */
part2_len = (tx_len & 0x3); /* BYTE access */
} else {
/* single data (legacy) mode */
part1_len = 0;
part2_len = tx_len; /* BYTE access only */
}
sg_init_table(sgl, 2);
sg_len = 0;
phys_addr = sg_dma_address(sg_tx) + xmit->tail;
if (part1_len) {
sg = &sgl[sg_len++];
sg_dma_address(sg) = phys_addr;
sg_dma_len(sg) = part1_len;
phys_addr += part1_len;
}
if (part2_len) {
sg = &sgl[sg_len++];
sg_dma_address(sg) = phys_addr;
sg_dma_len(sg) = part2_len;
}
/*
* save tx_len so atmel_complete_tx_dma() will increase
* xmit->tail correctly
*/
atmel_port->tx_len = tx_len;
desc = dmaengine_prep_slave_sg(chan,
tty/serial: at91: use 32bit writes into TX FIFO when DMA is enabled For now this improvement is only used with TX DMA transfers. The data width must be set properly when configuring the DMA controller. Also the FIFO configuration must be set to match the DMA transfer data width: TXRDYM (Transmitter Ready Mode) and RXRDYM (Receiver Ready Mode) must be set into the FIFO Mode Register. These values are used by the USART to trigger the DMA controller. In single data mode they are not used and should be reset to 0. So the TXRDYM bits are changed to FOUR_DATA; then USART triggers the DMA controller when at least 4 data can be written into the TX FIFO througth the THR. On the other hand the RXRDYM bits are left unchanged to ONE_DATA. Atmel eXtended DMA controller allows us to set a different data width for each part of a scatter-gather transfer. So when calling dmaengine_slave_config() to configure the TX path, we just need to set dst_addr_width to the maximum data width. Then DMA writes into THR are split into up to two parts. The first part carries the first data to be sent and has a length equal to the greatest multiple of 4 (bytes) lower than or equal to the total length of the TX DMA transfer. The second part carries the trailing data (up to 3 bytes). The first part is written by the DMA into THR using 32 bit accesses, whereas 8bit accesses are used for the second part. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:13 +03:00
sgl,
sg_len,
DMA_MEM_TO_DEV,
DMA_PREP_INTERRUPT |
DMA_CTRL_ACK);
if (!desc) {
dev_err(port->dev, "Failed to send via dma!\n");
return;
}
tty/serial: at91: use 32bit writes into TX FIFO when DMA is enabled For now this improvement is only used with TX DMA transfers. The data width must be set properly when configuring the DMA controller. Also the FIFO configuration must be set to match the DMA transfer data width: TXRDYM (Transmitter Ready Mode) and RXRDYM (Receiver Ready Mode) must be set into the FIFO Mode Register. These values are used by the USART to trigger the DMA controller. In single data mode they are not used and should be reset to 0. So the TXRDYM bits are changed to FOUR_DATA; then USART triggers the DMA controller when at least 4 data can be written into the TX FIFO througth the THR. On the other hand the RXRDYM bits are left unchanged to ONE_DATA. Atmel eXtended DMA controller allows us to set a different data width for each part of a scatter-gather transfer. So when calling dmaengine_slave_config() to configure the TX path, we just need to set dst_addr_width to the maximum data width. Then DMA writes into THR are split into up to two parts. The first part carries the first data to be sent and has a length equal to the greatest multiple of 4 (bytes) lower than or equal to the total length of the TX DMA transfer. The second part carries the trailing data (up to 3 bytes). The first part is written by the DMA into THR using 32 bit accesses, whereas 8bit accesses are used for the second part. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:13 +03:00
dma_sync_sg_for_device(port->dev, sg_tx, 1, DMA_TO_DEVICE);
atmel_port->desc_tx = desc;
desc->callback = atmel_complete_tx_dma;
desc->callback_param = atmel_port;
atmel_port->cookie_tx = dmaengine_submit(desc);
} else {
if (port->rs485.flags & SER_RS485_ENABLED) {
/* DMA done, stop TX, start RX for RS485 */
atmel_start_rx(port);
}
}
if (uart_circ_chars_pending(xmit) < WAKEUP_CHARS)
uart_write_wakeup(port);
}
static int atmel_prepare_tx_dma(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
dma_cap_mask_t mask;
struct dma_slave_config config;
int ret, nent;
dma_cap_zero(mask);
dma_cap_set(DMA_SLAVE, mask);
atmel_port->chan_tx = dma_request_slave_channel(port->dev, "tx");
if (atmel_port->chan_tx == NULL)
goto chan_err;
dev_info(port->dev, "using %s for tx DMA transfers\n",
dma_chan_name(atmel_port->chan_tx));
spin_lock_init(&atmel_port->lock_tx);
sg_init_table(&atmel_port->sg_tx, 1);
/* UART circular tx buffer is an aligned page. */
BUG_ON(!PAGE_ALIGNED(port->state->xmit.buf));
sg_set_page(&atmel_port->sg_tx,
virt_to_page(port->state->xmit.buf),
UART_XMIT_SIZE,
(unsigned long)port->state->xmit.buf & ~PAGE_MASK);
nent = dma_map_sg(port->dev,
&atmel_port->sg_tx,
1,
DMA_TO_DEVICE);
if (!nent) {
dev_dbg(port->dev, "need to release resource of dma\n");
goto chan_err;
} else {
dev_dbg(port->dev, "%s: mapped %d@%p to %pad\n", __func__,
sg_dma_len(&atmel_port->sg_tx),
port->state->xmit.buf,
&sg_dma_address(&atmel_port->sg_tx));
}
/* Configure the slave DMA */
memset(&config, 0, sizeof(config));
config.direction = DMA_MEM_TO_DEV;
tty/serial: at91: use 32bit writes into TX FIFO when DMA is enabled For now this improvement is only used with TX DMA transfers. The data width must be set properly when configuring the DMA controller. Also the FIFO configuration must be set to match the DMA transfer data width: TXRDYM (Transmitter Ready Mode) and RXRDYM (Receiver Ready Mode) must be set into the FIFO Mode Register. These values are used by the USART to trigger the DMA controller. In single data mode they are not used and should be reset to 0. So the TXRDYM bits are changed to FOUR_DATA; then USART triggers the DMA controller when at least 4 data can be written into the TX FIFO througth the THR. On the other hand the RXRDYM bits are left unchanged to ONE_DATA. Atmel eXtended DMA controller allows us to set a different data width for each part of a scatter-gather transfer. So when calling dmaengine_slave_config() to configure the TX path, we just need to set dst_addr_width to the maximum data width. Then DMA writes into THR are split into up to two parts. The first part carries the first data to be sent and has a length equal to the greatest multiple of 4 (bytes) lower than or equal to the total length of the TX DMA transfer. The second part carries the trailing data (up to 3 bytes). The first part is written by the DMA into THR using 32 bit accesses, whereas 8bit accesses are used for the second part. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:13 +03:00
config.dst_addr_width = (atmel_port->fifo_size) ?
DMA_SLAVE_BUSWIDTH_4_BYTES :
DMA_SLAVE_BUSWIDTH_1_BYTE;
config.dst_addr = port->mapbase + ATMEL_US_THR;
config.dst_maxburst = 1;
ret = dmaengine_slave_config(atmel_port->chan_tx,
&config);
if (ret) {
dev_err(port->dev, "DMA tx slave configuration failed\n");
goto chan_err;
}
return 0;
chan_err:
dev_err(port->dev, "TX channel not available, switch to pio\n");
atmel_port->use_dma_tx = 0;
if (atmel_port->chan_tx)
atmel_release_tx_dma(port);
return -EINVAL;
}
static void atmel_complete_rx_dma(void *arg)
{
struct uart_port *port = arg;
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
tasklet_schedule(&atmel_port->tasklet);
}
static void atmel_release_rx_dma(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct dma_chan *chan = atmel_port->chan_rx;
if (chan) {
dmaengine_terminate_all(chan);
dma_release_channel(chan);
dma_unmap_sg(port->dev, &atmel_port->sg_rx, 1,
DMA_FROM_DEVICE);
}
atmel_port->desc_rx = NULL;
atmel_port->chan_rx = NULL;
atmel_port->cookie_rx = -EINVAL;
}
static void atmel_rx_from_dma(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct tty_port *tport = &port->state->port;
struct circ_buf *ring = &atmel_port->rx_ring;
struct dma_chan *chan = atmel_port->chan_rx;
struct dma_tx_state state;
enum dma_status dmastat;
size_t count;
/* Reset the UART timeout early so that we don't miss one */
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_STTTO);
dmastat = dmaengine_tx_status(chan,
atmel_port->cookie_rx,
&state);
/* Restart a new tasklet if DMA status is error */
if (dmastat == DMA_ERROR) {
dev_dbg(port->dev, "Get residue error, restart tasklet\n");
atmel_uart_writel(port, ATMEL_US_IER, ATMEL_US_TIMEOUT);
tasklet_schedule(&atmel_port->tasklet);
return;
}
/* CPU claims ownership of RX DMA buffer */
dma_sync_sg_for_cpu(port->dev,
&atmel_port->sg_rx,
1,
DMA_FROM_DEVICE);
/*
* ring->head points to the end of data already written by the DMA.
* ring->tail points to the beginning of data to be read by the
* framework.
* The current transfer size should not be larger than the dma buffer
* length.
*/
ring->head = sg_dma_len(&atmel_port->sg_rx) - state.residue;
BUG_ON(ring->head > sg_dma_len(&atmel_port->sg_rx));
/*
* At this point ring->head may point to the first byte right after the
* last byte of the dma buffer:
* 0 <= ring->head <= sg_dma_len(&atmel_port->sg_rx)
*
* However ring->tail must always points inside the dma buffer:
* 0 <= ring->tail <= sg_dma_len(&atmel_port->sg_rx) - 1
*
* Since we use a ring buffer, we have to handle the case
* where head is lower than tail. In such a case, we first read from
* tail to the end of the buffer then reset tail.
*/
if (ring->head < ring->tail) {
count = sg_dma_len(&atmel_port->sg_rx) - ring->tail;
tty_insert_flip_string(tport, ring->buf + ring->tail, count);
ring->tail = 0;
port->icount.rx += count;
}
/* Finally we read data from tail to head */
if (ring->tail < ring->head) {
count = ring->head - ring->tail;
tty_insert_flip_string(tport, ring->buf + ring->tail, count);
/* Wrap ring->head if needed */
if (ring->head >= sg_dma_len(&atmel_port->sg_rx))
ring->head = 0;
ring->tail = ring->head;
port->icount.rx += count;
}
/* USART retreives ownership of RX DMA buffer */
dma_sync_sg_for_device(port->dev,
&atmel_port->sg_rx,
1,
DMA_FROM_DEVICE);
/*
* Drop the lock here since it might end up calling
* uart_start(), which takes the lock.
*/
spin_unlock(&port->lock);
tty_flip_buffer_push(tport);
spin_lock(&port->lock);
atmel_uart_writel(port, ATMEL_US_IER, ATMEL_US_TIMEOUT);
}
static int atmel_prepare_rx_dma(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct dma_async_tx_descriptor *desc;
dma_cap_mask_t mask;
struct dma_slave_config config;
struct circ_buf *ring;
int ret, nent;
ring = &atmel_port->rx_ring;
dma_cap_zero(mask);
dma_cap_set(DMA_CYCLIC, mask);
atmel_port->chan_rx = dma_request_slave_channel(port->dev, "rx");
if (atmel_port->chan_rx == NULL)
goto chan_err;
dev_info(port->dev, "using %s for rx DMA transfers\n",
dma_chan_name(atmel_port->chan_rx));
spin_lock_init(&atmel_port->lock_rx);
sg_init_table(&atmel_port->sg_rx, 1);
/* UART circular rx buffer is an aligned page. */
BUG_ON(!PAGE_ALIGNED(ring->buf));
sg_set_page(&atmel_port->sg_rx,
virt_to_page(ring->buf),
sizeof(struct atmel_uart_char) * ATMEL_SERIAL_RINGSIZE,
(unsigned long)ring->buf & ~PAGE_MASK);
nent = dma_map_sg(port->dev,
&atmel_port->sg_rx,
1,
DMA_FROM_DEVICE);
if (!nent) {
dev_dbg(port->dev, "need to release resource of dma\n");
goto chan_err;
} else {
dev_dbg(port->dev, "%s: mapped %d@%p to %pad\n", __func__,
sg_dma_len(&atmel_port->sg_rx),
ring->buf,
&sg_dma_address(&atmel_port->sg_rx));
}
/* Configure the slave DMA */
memset(&config, 0, sizeof(config));
config.direction = DMA_DEV_TO_MEM;
config.src_addr_width = DMA_SLAVE_BUSWIDTH_1_BYTE;
config.src_addr = port->mapbase + ATMEL_US_RHR;
config.src_maxburst = 1;
ret = dmaengine_slave_config(atmel_port->chan_rx,
&config);
if (ret) {
dev_err(port->dev, "DMA rx slave configuration failed\n");
goto chan_err;
}
/*
* Prepare a cyclic dma transfer, assign 2 descriptors,
* each one is half ring buffer size
*/
desc = dmaengine_prep_dma_cyclic(atmel_port->chan_rx,
sg_dma_address(&atmel_port->sg_rx),
sg_dma_len(&atmel_port->sg_rx),
sg_dma_len(&atmel_port->sg_rx)/2,
DMA_DEV_TO_MEM,
DMA_PREP_INTERRUPT);
desc->callback = atmel_complete_rx_dma;
desc->callback_param = port;
atmel_port->desc_rx = desc;
atmel_port->cookie_rx = dmaengine_submit(desc);
return 0;
chan_err:
dev_err(port->dev, "RX channel not available, switch to pio\n");
atmel_port->use_dma_rx = 0;
if (atmel_port->chan_rx)
atmel_release_rx_dma(port);
return -EINVAL;
}
static void atmel_uart_timer_callback(unsigned long data)
{
struct uart_port *port = (void *)data;
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
tasklet_schedule(&atmel_port->tasklet);
mod_timer(&atmel_port->uart_timer, jiffies + uart_poll_timeout(port));
}
/*
* receive interrupt handler.
*/
static void
atmel_handle_receive(struct uart_port *port, unsigned int pending)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
if (atmel_use_pdc_rx(port)) {
/*
* PDC receive. Just schedule the tasklet and let it
* figure out the details.
*
* TODO: We're not handling error flags correctly at
* the moment.
*/
if (pending & (ATMEL_US_ENDRX | ATMEL_US_TIMEOUT)) {
atmel_uart_writel(port, ATMEL_US_IDR,
(ATMEL_US_ENDRX | ATMEL_US_TIMEOUT));
tasklet_schedule(&atmel_port->tasklet);
}
if (pending & (ATMEL_US_RXBRK | ATMEL_US_OVRE |
ATMEL_US_FRAME | ATMEL_US_PARE))
atmel_pdc_rxerr(port, pending);
}
if (atmel_use_dma_rx(port)) {
if (pending & ATMEL_US_TIMEOUT) {
atmel_uart_writel(port, ATMEL_US_IDR,
ATMEL_US_TIMEOUT);
tasklet_schedule(&atmel_port->tasklet);
}
}
/* Interrupt receive */
if (pending & ATMEL_US_RXRDY)
atmel_rx_chars(port);
else if (pending & ATMEL_US_RXBRK) {
/*
* End of break detected. If it came along with a
* character, atmel_rx_chars will handle it.
*/
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_RSTSTA);
atmel_uart_writel(port, ATMEL_US_IDR, ATMEL_US_RXBRK);
atmel_port->break_active = 0;
}
}
/*
* transmit interrupt handler. (Transmit is IRQF_NODELAY safe)
*/
static void
atmel_handle_transmit(struct uart_port *port, unsigned int pending)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
if (pending & atmel_port->tx_done_mask) {
/* Either PDC or interrupt transmission */
atmel_uart_writel(port, ATMEL_US_IDR,
atmel_port->tx_done_mask);
tasklet_schedule(&atmel_port->tasklet);
}
}
/*
* status flags interrupt handler.
*/
static void
atmel_handle_status(struct uart_port *port, unsigned int pending,
unsigned int status)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
if (pending & (ATMEL_US_RIIC | ATMEL_US_DSRIC | ATMEL_US_DCDIC
| ATMEL_US_CTSIC)) {
atmel_port->irq_status = status;
atmel_port->status_change = atmel_port->irq_status ^
atmel_port->irq_status_prev;
atmel_port->irq_status_prev = status;
tasklet_schedule(&atmel_port->tasklet);
}
}
/*
* Interrupt handler
*/
IRQ: Maintain regs pointer globally rather than passing to IRQ handlers Maintain a per-CPU global "struct pt_regs *" variable which can be used instead of passing regs around manually through all ~1800 interrupt handlers in the Linux kernel. The regs pointer is used in few places, but it potentially costs both stack space and code to pass it around. On the FRV arch, removing the regs parameter from all the genirq function results in a 20% speed up of the IRQ exit path (ie: from leaving timer_interrupt() to leaving do_IRQ()). Where appropriate, an arch may override the generic storage facility and do something different with the variable. On FRV, for instance, the address is maintained in GR28 at all times inside the kernel as part of general exception handling. Having looked over the code, it appears that the parameter may be handed down through up to twenty or so layers of functions. Consider a USB character device attached to a USB hub, attached to a USB controller that posts its interrupts through a cascaded auxiliary interrupt controller. A character device driver may want to pass regs to the sysrq handler through the input layer which adds another few layers of parameter passing. I've build this code with allyesconfig for x86_64 and i386. I've runtested the main part of the code on FRV and i386, though I can't test most of the drivers. I've also done partial conversion for powerpc and MIPS - these at least compile with minimal configurations. This will affect all archs. Mostly the changes should be relatively easy. Take do_IRQ(), store the regs pointer at the beginning, saving the old one: struct pt_regs *old_regs = set_irq_regs(regs); And put the old one back at the end: set_irq_regs(old_regs); Don't pass regs through to generic_handle_irq() or __do_IRQ(). In timer_interrupt(), this sort of change will be necessary: - update_process_times(user_mode(regs)); - profile_tick(CPU_PROFILING, regs); + update_process_times(user_mode(get_irq_regs())); + profile_tick(CPU_PROFILING); I'd like to move update_process_times()'s use of get_irq_regs() into itself, except that i386, alone of the archs, uses something other than user_mode(). Some notes on the interrupt handling in the drivers: (*) input_dev() is now gone entirely. The regs pointer is no longer stored in the input_dev struct. (*) finish_unlinks() in drivers/usb/host/ohci-q.c needs checking. It does something different depending on whether it's been supplied with a regs pointer or not. (*) Various IRQ handler function pointers have been moved to type irq_handler_t. Signed-Off-By: David Howells <dhowells@redhat.com> (cherry picked from 1b16e7ac850969f38b375e511e3fa2f474a33867 commit)
2006-10-05 17:55:46 +04:00
static irqreturn_t atmel_interrupt(int irq, void *dev_id)
{
struct uart_port *port = dev_id;
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
unsigned int status, pending, mask, pass_counter = 0;
bool gpio_handled = false;
spin_lock(&atmel_port->lock_suspended);
do {
status = atmel_get_lines_status(port);
mask = atmel_uart_readl(port, ATMEL_US_IMR);
pending = status & mask;
if (!gpio_handled) {
/*
* Dealing with GPIO interrupt
*/
if (irq == atmel_port->gpio_irq[UART_GPIO_CTS])
pending |= ATMEL_US_CTSIC;
if (irq == atmel_port->gpio_irq[UART_GPIO_DSR])
pending |= ATMEL_US_DSRIC;
if (irq == atmel_port->gpio_irq[UART_GPIO_RI])
pending |= ATMEL_US_RIIC;
if (irq == atmel_port->gpio_irq[UART_GPIO_DCD])
pending |= ATMEL_US_DCDIC;
gpio_handled = true;
}
if (!pending)
break;
if (atmel_port->suspended) {
atmel_port->pending |= pending;
atmel_port->pending_status = status;
atmel_uart_writel(port, ATMEL_US_IDR, mask);
pm_system_wakeup();
break;
}
atmel_handle_receive(port, pending);
atmel_handle_status(port, pending, status);
atmel_handle_transmit(port, pending);
} while (pass_counter++ < ATMEL_ISR_PASS_LIMIT);
spin_unlock(&atmel_port->lock_suspended);
return pass_counter ? IRQ_HANDLED : IRQ_NONE;
}
static void atmel_release_tx_pdc(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct atmel_dma_buffer *pdc = &atmel_port->pdc_tx;
dma_unmap_single(port->dev,
pdc->dma_addr,
pdc->dma_size,
DMA_TO_DEVICE);
}
/*
* Called from tasklet with ENDTX and TXBUFE interrupts disabled.
*/
static void atmel_tx_pdc(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct circ_buf *xmit = &port->state->xmit;
struct atmel_dma_buffer *pdc = &atmel_port->pdc_tx;
int count;
/* nothing left to transmit? */
if (atmel_uart_readl(port, ATMEL_PDC_TCR))
return;
xmit->tail += pdc->ofs;
xmit->tail &= UART_XMIT_SIZE - 1;
port->icount.tx += pdc->ofs;
pdc->ofs = 0;
/* more to transmit - setup next transfer */
/* disable PDC transmit */
atmel_uart_writel(port, ATMEL_PDC_PTCR, ATMEL_PDC_TXTDIS);
if (!uart_circ_empty(xmit) && !uart_tx_stopped(port)) {
dma_sync_single_for_device(port->dev,
pdc->dma_addr,
pdc->dma_size,
DMA_TO_DEVICE);
count = CIRC_CNT_TO_END(xmit->head, xmit->tail, UART_XMIT_SIZE);
pdc->ofs = count;
atmel_uart_writel(port, ATMEL_PDC_TPR,
pdc->dma_addr + xmit->tail);
atmel_uart_writel(port, ATMEL_PDC_TCR, count);
/* re-enable PDC transmit */
atmel_uart_writel(port, ATMEL_PDC_PTCR, ATMEL_PDC_TXTEN);
/* Enable interrupts */
atmel_uart_writel(port, ATMEL_US_IER,
atmel_port->tx_done_mask);
} else {
if ((port->rs485.flags & SER_RS485_ENABLED) &&
!(port->rs485.flags & SER_RS485_RX_DURING_TX)) {
/* DMA done, stop TX, start RX for RS485 */
atmel_start_rx(port);
}
}
if (uart_circ_chars_pending(xmit) < WAKEUP_CHARS)
uart_write_wakeup(port);
}
static int atmel_prepare_tx_pdc(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct atmel_dma_buffer *pdc = &atmel_port->pdc_tx;
struct circ_buf *xmit = &port->state->xmit;
pdc->buf = xmit->buf;
pdc->dma_addr = dma_map_single(port->dev,
pdc->buf,
UART_XMIT_SIZE,
DMA_TO_DEVICE);
pdc->dma_size = UART_XMIT_SIZE;
pdc->ofs = 0;
return 0;
}
static void atmel_rx_from_ring(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct circ_buf *ring = &atmel_port->rx_ring;
unsigned int flg;
unsigned int status;
while (ring->head != ring->tail) {
struct atmel_uart_char c;
/* Make sure c is loaded after head. */
smp_rmb();
c = ((struct atmel_uart_char *)ring->buf)[ring->tail];
ring->tail = (ring->tail + 1) & (ATMEL_SERIAL_RINGSIZE - 1);
port->icount.rx++;
status = c.status;
flg = TTY_NORMAL;
/*
* note that the error handling code is
* out of the main execution path
*/
if (unlikely(status & (ATMEL_US_PARE | ATMEL_US_FRAME
| ATMEL_US_OVRE | ATMEL_US_RXBRK))) {
if (status & ATMEL_US_RXBRK) {
/* ignore side-effect */
status &= ~(ATMEL_US_PARE | ATMEL_US_FRAME);
port->icount.brk++;
if (uart_handle_break(port))
continue;
}
if (status & ATMEL_US_PARE)
port->icount.parity++;
if (status & ATMEL_US_FRAME)
port->icount.frame++;
if (status & ATMEL_US_OVRE)
port->icount.overrun++;
status &= port->read_status_mask;
if (status & ATMEL_US_RXBRK)
flg = TTY_BREAK;
else if (status & ATMEL_US_PARE)
flg = TTY_PARITY;
else if (status & ATMEL_US_FRAME)
flg = TTY_FRAME;
}
if (uart_handle_sysrq_char(port, c.ch))
continue;
uart_insert_char(port, status, ATMEL_US_OVRE, c.ch, flg);
}
/*
* Drop the lock here since it might end up calling
* uart_start(), which takes the lock.
*/
spin_unlock(&port->lock);
tty_flip_buffer_push(&port->state->port);
spin_lock(&port->lock);
}
static void atmel_release_rx_pdc(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
int i;
for (i = 0; i < 2; i++) {
struct atmel_dma_buffer *pdc = &atmel_port->pdc_rx[i];
dma_unmap_single(port->dev,
pdc->dma_addr,
pdc->dma_size,
DMA_FROM_DEVICE);
kfree(pdc->buf);
}
}
static void atmel_rx_from_pdc(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct tty_port *tport = &port->state->port;
struct atmel_dma_buffer *pdc;
int rx_idx = atmel_port->pdc_rx_idx;
unsigned int head;
unsigned int tail;
unsigned int count;
do {
/* Reset the UART timeout early so that we don't miss one */
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_STTTO);
pdc = &atmel_port->pdc_rx[rx_idx];
head = atmel_uart_readl(port, ATMEL_PDC_RPR) - pdc->dma_addr;
tail = pdc->ofs;
/* If the PDC has switched buffers, RPR won't contain
* any address within the current buffer. Since head
* is unsigned, we just need a one-way comparison to
* find out.
*
* In this case, we just need to consume the entire
* buffer and resubmit it for DMA. This will clear the
* ENDRX bit as well, so that we can safely re-enable
* all interrupts below.
*/
head = min(head, pdc->dma_size);
if (likely(head != tail)) {
dma_sync_single_for_cpu(port->dev, pdc->dma_addr,
pdc->dma_size, DMA_FROM_DEVICE);
/*
* head will only wrap around when we recycle
* the DMA buffer, and when that happens, we
* explicitly set tail to 0. So head will
* always be greater than tail.
*/
count = head - tail;
tty_insert_flip_string(tport, pdc->buf + pdc->ofs,
count);
dma_sync_single_for_device(port->dev, pdc->dma_addr,
pdc->dma_size, DMA_FROM_DEVICE);
port->icount.rx += count;
pdc->ofs = head;
}
/*
* If the current buffer is full, we need to check if
* the next one contains any additional data.
*/
if (head >= pdc->dma_size) {
pdc->ofs = 0;
atmel_uart_writel(port, ATMEL_PDC_RNPR, pdc->dma_addr);
atmel_uart_writel(port, ATMEL_PDC_RNCR, pdc->dma_size);
rx_idx = !rx_idx;
atmel_port->pdc_rx_idx = rx_idx;
}
} while (head >= pdc->dma_size);
/*
* Drop the lock here since it might end up calling
* uart_start(), which takes the lock.
*/
spin_unlock(&port->lock);
tty_flip_buffer_push(tport);
spin_lock(&port->lock);
atmel_uart_writel(port, ATMEL_US_IER,
ATMEL_US_ENDRX | ATMEL_US_TIMEOUT);
}
static int atmel_prepare_rx_pdc(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
int i;
for (i = 0; i < 2; i++) {
struct atmel_dma_buffer *pdc = &atmel_port->pdc_rx[i];
pdc->buf = kmalloc(PDC_BUFFER_SIZE, GFP_KERNEL);
if (pdc->buf == NULL) {
if (i != 0) {
dma_unmap_single(port->dev,
atmel_port->pdc_rx[0].dma_addr,
PDC_BUFFER_SIZE,
DMA_FROM_DEVICE);
kfree(atmel_port->pdc_rx[0].buf);
}
atmel_port->use_pdc_rx = 0;
return -ENOMEM;
}
pdc->dma_addr = dma_map_single(port->dev,
pdc->buf,
PDC_BUFFER_SIZE,
DMA_FROM_DEVICE);
pdc->dma_size = PDC_BUFFER_SIZE;
pdc->ofs = 0;
}
atmel_port->pdc_rx_idx = 0;
atmel_uart_writel(port, ATMEL_PDC_RPR, atmel_port->pdc_rx[0].dma_addr);
atmel_uart_writel(port, ATMEL_PDC_RCR, PDC_BUFFER_SIZE);
atmel_uart_writel(port, ATMEL_PDC_RNPR,
atmel_port->pdc_rx[1].dma_addr);
atmel_uart_writel(port, ATMEL_PDC_RNCR, PDC_BUFFER_SIZE);
return 0;
}
/*
* tasklet handling tty stuff outside the interrupt handler.
*/
static void atmel_tasklet_func(unsigned long data)
{
struct uart_port *port = (struct uart_port *)data;
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
unsigned int status = atmel_port->irq_status;
unsigned int status_change = atmel_port->status_change;
/* The interrupt handler does not take the lock */
spin_lock(&port->lock);
atmel_port->schedule_tx(port);
if (status_change & (ATMEL_US_RI | ATMEL_US_DSR
| ATMEL_US_DCD | ATMEL_US_CTS)) {
/* TODO: All reads to CSR will clear these interrupts! */
if (status_change & ATMEL_US_RI)
port->icount.rng++;
if (status_change & ATMEL_US_DSR)
port->icount.dsr++;
if (status_change & ATMEL_US_DCD)
uart_handle_dcd_change(port, !(status & ATMEL_US_DCD));
if (status_change & ATMEL_US_CTS)
uart_handle_cts_change(port, !(status & ATMEL_US_CTS));
wake_up_interruptible(&port->state->port.delta_msr_wait);
atmel_port->status_change = 0;
}
atmel_port->schedule_rx(port);
spin_unlock(&port->lock);
}
static void atmel_init_property(struct atmel_uart_port *atmel_port,
struct platform_device *pdev)
{
struct device_node *np = pdev->dev.of_node;
struct atmel_uart_data *pdata = dev_get_platdata(&pdev->dev);
if (np) {
/* DMA/PDC usage specification */
if (of_get_property(np, "atmel,use-dma-rx", NULL)) {
if (of_get_property(np, "dmas", NULL)) {
atmel_port->use_dma_rx = true;
atmel_port->use_pdc_rx = false;
} else {
atmel_port->use_dma_rx = false;
atmel_port->use_pdc_rx = true;
}
} else {
atmel_port->use_dma_rx = false;
atmel_port->use_pdc_rx = false;
}
if (of_get_property(np, "atmel,use-dma-tx", NULL)) {
if (of_get_property(np, "dmas", NULL)) {
atmel_port->use_dma_tx = true;
atmel_port->use_pdc_tx = false;
} else {
atmel_port->use_dma_tx = false;
atmel_port->use_pdc_tx = true;
}
} else {
atmel_port->use_dma_tx = false;
atmel_port->use_pdc_tx = false;
}
} else {
atmel_port->use_pdc_rx = pdata->use_dma_rx;
atmel_port->use_pdc_tx = pdata->use_dma_tx;
atmel_port->use_dma_rx = false;
atmel_port->use_dma_tx = false;
}
}
static void atmel_init_rs485(struct uart_port *port,
struct platform_device *pdev)
{
struct device_node *np = pdev->dev.of_node;
struct atmel_uart_data *pdata = dev_get_platdata(&pdev->dev);
if (np) {
struct serial_rs485 *rs485conf = &port->rs485;
u32 rs485_delay[2];
/* rs485 properties */
if (of_property_read_u32_array(np, "rs485-rts-delay",
rs485_delay, 2) == 0) {
rs485conf->delay_rts_before_send = rs485_delay[0];
rs485conf->delay_rts_after_send = rs485_delay[1];
rs485conf->flags = 0;
}
if (of_get_property(np, "rs485-rx-during-tx", NULL))
rs485conf->flags |= SER_RS485_RX_DURING_TX;
if (of_get_property(np, "linux,rs485-enabled-at-boot-time",
NULL))
rs485conf->flags |= SER_RS485_ENABLED;
} else {
port->rs485 = pdata->rs485;
}
}
static void atmel_set_ops(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
if (atmel_use_dma_rx(port)) {
atmel_port->prepare_rx = &atmel_prepare_rx_dma;
atmel_port->schedule_rx = &atmel_rx_from_dma;
atmel_port->release_rx = &atmel_release_rx_dma;
} else if (atmel_use_pdc_rx(port)) {
atmel_port->prepare_rx = &atmel_prepare_rx_pdc;
atmel_port->schedule_rx = &atmel_rx_from_pdc;
atmel_port->release_rx = &atmel_release_rx_pdc;
} else {
atmel_port->prepare_rx = NULL;
atmel_port->schedule_rx = &atmel_rx_from_ring;
atmel_port->release_rx = NULL;
}
if (atmel_use_dma_tx(port)) {
atmel_port->prepare_tx = &atmel_prepare_tx_dma;
atmel_port->schedule_tx = &atmel_tx_dma;
atmel_port->release_tx = &atmel_release_tx_dma;
} else if (atmel_use_pdc_tx(port)) {
atmel_port->prepare_tx = &atmel_prepare_tx_pdc;
atmel_port->schedule_tx = &atmel_tx_pdc;
atmel_port->release_tx = &atmel_release_tx_pdc;
} else {
atmel_port->prepare_tx = NULL;
atmel_port->schedule_tx = &atmel_tx_chars;
atmel_port->release_tx = NULL;
}
}
/*
* Get ip name usart or uart
*/
static void atmel_get_ip_name(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
int name = atmel_uart_readl(port, ATMEL_US_NAME);
u32 version;
int usart, uart;
/* usart and uart ascii */
usart = 0x55534152;
uart = 0x44424755;
atmel_port->is_usart = false;
if (name == usart) {
dev_dbg(port->dev, "This is usart\n");
atmel_port->is_usart = true;
} else if (name == uart) {
dev_dbg(port->dev, "This is uart\n");
atmel_port->is_usart = false;
} else {
/* fallback for older SoCs: use version field */
version = atmel_uart_readl(port, ATMEL_US_VERSION);
switch (version) {
case 0x302:
case 0x10213:
dev_dbg(port->dev, "This version is usart\n");
atmel_port->is_usart = true;
break;
case 0x203:
case 0x10202:
dev_dbg(port->dev, "This version is uart\n");
atmel_port->is_usart = false;
break;
default:
dev_err(port->dev, "Not supported ip name nor version, set to uart\n");
}
}
}
static void atmel_free_gpio_irq(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
enum mctrl_gpio_idx i;
for (i = 0; i < UART_GPIO_MAX; i++)
if (atmel_port->gpio_irq[i] >= 0)
free_irq(atmel_port->gpio_irq[i], port);
}
static int atmel_request_gpio_irq(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
int *irq = atmel_port->gpio_irq;
enum mctrl_gpio_idx i;
int err = 0;
for (i = 0; (i < UART_GPIO_MAX) && !err; i++) {
if (irq[i] < 0)
continue;
irq_set_status_flags(irq[i], IRQ_NOAUTOEN);
err = request_irq(irq[i], atmel_interrupt, IRQ_TYPE_EDGE_BOTH,
"atmel_serial", port);
if (err)
dev_err(port->dev, "atmel_startup - Can't get %d irq\n",
irq[i]);
}
/*
* If something went wrong, rollback.
*/
while (err && (--i >= 0))
if (irq[i] >= 0)
free_irq(irq[i], port);
return err;
}
/*
* Perform initialization and enable port for reception
*/
static int atmel_startup(struct uart_port *port)
{
struct platform_device *pdev = to_platform_device(port->dev);
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
struct tty_struct *tty = port->state->port.tty;
int retval;
/*
* Ensure that no interrupts are enabled otherwise when
* request_irq() is called we could get stuck trying to
* handle an unexpected interrupt
*/
atmel_uart_writel(port, ATMEL_US_IDR, -1);
atmel_port->ms_irq_enabled = false;
/*
* Allocate the IRQ
*/
retval = request_irq(port->irq, atmel_interrupt,
IRQF_SHARED | IRQF_COND_SUSPEND,
tty ? tty->name : "atmel_serial", port);
if (retval) {
dev_err(port->dev, "atmel_startup - Can't get irq\n");
return retval;
}
/*
* Get the GPIO lines IRQ
*/
retval = atmel_request_gpio_irq(port);
if (retval)
goto free_irq;
tasklet_enable(&atmel_port->tasklet);
/*
* Initialize DMA (if necessary)
*/
atmel_init_property(atmel_port, pdev);
atmel_set_ops(port);
if (atmel_port->prepare_rx) {
retval = atmel_port->prepare_rx(port);
if (retval < 0)
atmel_set_ops(port);
}
if (atmel_port->prepare_tx) {
retval = atmel_port->prepare_tx(port);
if (retval < 0)
atmel_set_ops(port);
}
tty/serial: at91: add support to FIFOs Depending on the hardware, TX and RX FIFOs may be available. The RX FIFO can avoid receive overruns, especially when DMA transfers are not used to read data from the Receive Holding Register. For heavy system load, The CPU is likely not be able to fetch data fast enough from the RHR. In addition, the RX FIFO can supersede the DMA/PDC to control the RTS line when the Hardware Handshaking mode is enabled. Two thresholds are to be set for that purpose: - When the number of data in the RX FIFO crosses and becomes lower than or equal to the low threshold, the RTS line is set to low level: the remote peer is requested to send data. - When the number of data in the RX FIFO crosses and becomes greater than or equal to the high threshold, the RTS line is set to high level: the remote peer should stop sending new data. - low threshold <= high threshold Once these two thresholds are set properly, this new feature is enabled by setting the FIFO RTS Control bit of the FIFO Mode Register. FIFOs also introduce a new multiple data mode: the USART works either in multiple data mode or in single data (legacy) mode. If MODE9 bit is set into the Mode Register or if USMODE is set to either LIN_MASTER, LIN_SLAVE or LON_MODE, FIFOs operate in single data mode. Otherwise, they operate in multiple data mode. In this new multiple data mode, accesses to the Receive Holding Register or Transmit Holding Register slightly change. Since this driver implements neither the 9bit data feature (MODE9 bit set into the Mode Register) nor LIN modes, the USART works in multiple data mode whenever FIFOs are available and enabled. We also assume that data are 8bit wide. In single data mode, 32bit access CAN be used to read a single data from RHR or write a single data into THR. However in multiple data mode, a 32bit access to RHR now allows us to read four consecutive data from RX FIFO. Also a 32bit access to THR now allows to write four consecutive data into TX FIFO. So we MUST use 8bit access whenever only one data have to be read/written at a time. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:12 +03:00
/*
* Enable FIFO when available
*/
if (atmel_port->fifo_size) {
unsigned int txrdym = ATMEL_US_ONE_DATA;
unsigned int rxrdym = ATMEL_US_ONE_DATA;
unsigned int fmr;
atmel_uart_writel(port, ATMEL_US_CR,
ATMEL_US_FIFOEN |
ATMEL_US_RXFCLR |
ATMEL_US_TXFLCLR);
tty/serial: at91: use 32bit writes into TX FIFO when DMA is enabled For now this improvement is only used with TX DMA transfers. The data width must be set properly when configuring the DMA controller. Also the FIFO configuration must be set to match the DMA transfer data width: TXRDYM (Transmitter Ready Mode) and RXRDYM (Receiver Ready Mode) must be set into the FIFO Mode Register. These values are used by the USART to trigger the DMA controller. In single data mode they are not used and should be reset to 0. So the TXRDYM bits are changed to FOUR_DATA; then USART triggers the DMA controller when at least 4 data can be written into the TX FIFO througth the THR. On the other hand the RXRDYM bits are left unchanged to ONE_DATA. Atmel eXtended DMA controller allows us to set a different data width for each part of a scatter-gather transfer. So when calling dmaengine_slave_config() to configure the TX path, we just need to set dst_addr_width to the maximum data width. Then DMA writes into THR are split into up to two parts. The first part carries the first data to be sent and has a length equal to the greatest multiple of 4 (bytes) lower than or equal to the total length of the TX DMA transfer. The second part carries the trailing data (up to 3 bytes). The first part is written by the DMA into THR using 32 bit accesses, whereas 8bit accesses are used for the second part. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:13 +03:00
if (atmel_use_dma_tx(port))
txrdym = ATMEL_US_FOUR_DATA;
tty/serial: at91: add support to FIFOs Depending on the hardware, TX and RX FIFOs may be available. The RX FIFO can avoid receive overruns, especially when DMA transfers are not used to read data from the Receive Holding Register. For heavy system load, The CPU is likely not be able to fetch data fast enough from the RHR. In addition, the RX FIFO can supersede the DMA/PDC to control the RTS line when the Hardware Handshaking mode is enabled. Two thresholds are to be set for that purpose: - When the number of data in the RX FIFO crosses and becomes lower than or equal to the low threshold, the RTS line is set to low level: the remote peer is requested to send data. - When the number of data in the RX FIFO crosses and becomes greater than or equal to the high threshold, the RTS line is set to high level: the remote peer should stop sending new data. - low threshold <= high threshold Once these two thresholds are set properly, this new feature is enabled by setting the FIFO RTS Control bit of the FIFO Mode Register. FIFOs also introduce a new multiple data mode: the USART works either in multiple data mode or in single data (legacy) mode. If MODE9 bit is set into the Mode Register or if USMODE is set to either LIN_MASTER, LIN_SLAVE or LON_MODE, FIFOs operate in single data mode. Otherwise, they operate in multiple data mode. In this new multiple data mode, accesses to the Receive Holding Register or Transmit Holding Register slightly change. Since this driver implements neither the 9bit data feature (MODE9 bit set into the Mode Register) nor LIN modes, the USART works in multiple data mode whenever FIFOs are available and enabled. We also assume that data are 8bit wide. In single data mode, 32bit access CAN be used to read a single data from RHR or write a single data into THR. However in multiple data mode, a 32bit access to RHR now allows us to read four consecutive data from RX FIFO. Also a 32bit access to THR now allows to write four consecutive data into TX FIFO. So we MUST use 8bit access whenever only one data have to be read/written at a time. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:12 +03:00
fmr = ATMEL_US_TXRDYM(txrdym) | ATMEL_US_RXRDYM(rxrdym);
if (atmel_port->rts_high &&
atmel_port->rts_low)
fmr |= ATMEL_US_FRTSC |
ATMEL_US_RXFTHRES(atmel_port->rts_high) |
ATMEL_US_RXFTHRES2(atmel_port->rts_low);
atmel_uart_writel(port, ATMEL_US_FMR, fmr);
}
atmel_serial might lose modem status change I found a problem of handling of modem status of atmel_serial driver. With the commit 1ecc26 ("atmel_serial: split the interrupt handler"), handling of modem status signal was splitted into two parts. The atmel_tasklet_func() compares new status with irq_status_prev, but irq_status_prev is not correct if signal status was changed while the port is closed. Here is a sequence to cause problem: 1. Remote side sets CTS (and DSR). 2. Local side close the port. 3. Local side clears RTS and DTR. 4. Remote side clears CTS and DSR. 5. Local side reopen the port. hw_stopped becomes 1. 6. Local side sets RTS and DTR. 7. Remote side sets CTS and DSR. Then CTS change interrupt can be received, but since CTS bit in irq_status_prev and new status is same, uart_handle_cts_change() will not be called (so hw_stopped will not be cleared, i.e. cannot send any data). I suppose irq_status_prev should be initialized at somewhere in open sequence. Itai Levi pointed out that we need to initialize atmel_port->irq_status as well here. His analysis is as follows: > Regarding the second part of the patch (which resets irq_status_prev), > it turns out that both versions of the patch (mine and Atsushi's) > still leave enough room for faulty behavior when opening the port. > > This is because we are not resetting both irq_status_prev and > irq_status in atmel_startup() to CSR, which leads faulty behavior in > the following sequences: > > First case: > 1. closing the port while CTS line = 1 (TX not allowed) > 2. setting CTS line = 0 (TX allowed) > 3. opening the port > 4. transmitting one char > 5. Cannot transmit more chars, although CTS line is 0 > > Second case: > 1. closing the port while CTS line = 0 (TX allowed) > 2. setting CTS line = 1 (TX not allowed) > 3. opening the port > 4. receiving some chars > 5. Now we can transmit, although CTS line is 1 > > This reason for this is that the tasklet is scheduled as a result of > TX or RX interrupts (not a status change!), in steps 4 above. Inside > the tasklet, the atmel_port->irq_status (which holds the value from > the previous session) is compared to atmel_port->irq_status_prev. > Hence, a status-change of the CTS line is faultily detected. > > Both cases were verified on 9260 hardware. [haavard.skinnemoen@atmel.com: folded with patch from Itai Levi] Signed-off-by: Atsushi Nemoto <anemo@mba.ocn.ne.jp> Signed-off-by: Haavard Skinnemoen <haavard.skinnemoen@atmel.com> Cc: Remy Bohmer <linux@bohmer.net> Cc: Marc Pignat <marc.pignat@hevs.ch> Cc: Itai Levi <itai.levi.devel@gmail.com> Cc: Alan Cox <alan@lxorguk.ukuu.org.uk> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2009-02-19 01:48:28 +03:00
/* Save current CSR for comparison in atmel_tasklet_func() */
atmel_port->irq_status_prev = atmel_get_lines_status(port);
atmel_serial might lose modem status change I found a problem of handling of modem status of atmel_serial driver. With the commit 1ecc26 ("atmel_serial: split the interrupt handler"), handling of modem status signal was splitted into two parts. The atmel_tasklet_func() compares new status with irq_status_prev, but irq_status_prev is not correct if signal status was changed while the port is closed. Here is a sequence to cause problem: 1. Remote side sets CTS (and DSR). 2. Local side close the port. 3. Local side clears RTS and DTR. 4. Remote side clears CTS and DSR. 5. Local side reopen the port. hw_stopped becomes 1. 6. Local side sets RTS and DTR. 7. Remote side sets CTS and DSR. Then CTS change interrupt can be received, but since CTS bit in irq_status_prev and new status is same, uart_handle_cts_change() will not be called (so hw_stopped will not be cleared, i.e. cannot send any data). I suppose irq_status_prev should be initialized at somewhere in open sequence. Itai Levi pointed out that we need to initialize atmel_port->irq_status as well here. His analysis is as follows: > Regarding the second part of the patch (which resets irq_status_prev), > it turns out that both versions of the patch (mine and Atsushi's) > still leave enough room for faulty behavior when opening the port. > > This is because we are not resetting both irq_status_prev and > irq_status in atmel_startup() to CSR, which leads faulty behavior in > the following sequences: > > First case: > 1. closing the port while CTS line = 1 (TX not allowed) > 2. setting CTS line = 0 (TX allowed) > 3. opening the port > 4. transmitting one char > 5. Cannot transmit more chars, although CTS line is 0 > > Second case: > 1. closing the port while CTS line = 0 (TX allowed) > 2. setting CTS line = 1 (TX not allowed) > 3. opening the port > 4. receiving some chars > 5. Now we can transmit, although CTS line is 1 > > This reason for this is that the tasklet is scheduled as a result of > TX or RX interrupts (not a status change!), in steps 4 above. Inside > the tasklet, the atmel_port->irq_status (which holds the value from > the previous session) is compared to atmel_port->irq_status_prev. > Hence, a status-change of the CTS line is faultily detected. > > Both cases were verified on 9260 hardware. [haavard.skinnemoen@atmel.com: folded with patch from Itai Levi] Signed-off-by: Atsushi Nemoto <anemo@mba.ocn.ne.jp> Signed-off-by: Haavard Skinnemoen <haavard.skinnemoen@atmel.com> Cc: Remy Bohmer <linux@bohmer.net> Cc: Marc Pignat <marc.pignat@hevs.ch> Cc: Itai Levi <itai.levi.devel@gmail.com> Cc: Alan Cox <alan@lxorguk.ukuu.org.uk> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2009-02-19 01:48:28 +03:00
atmel_port->irq_status = atmel_port->irq_status_prev;
/*
* Finally, enable the serial port
*/
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_RSTSTA | ATMEL_US_RSTRX);
/* enable xmit & rcvr */
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_TXEN | ATMEL_US_RXEN);
setup_timer(&atmel_port->uart_timer,
atmel_uart_timer_callback,
(unsigned long)port);
if (atmel_use_pdc_rx(port)) {
/* set UART timeout */
if (!atmel_port->is_usart) {
mod_timer(&atmel_port->uart_timer,
jiffies + uart_poll_timeout(port));
/* set USART timeout */
} else {
atmel_uart_writel(port, ATMEL_US_RTOR, PDC_RX_TIMEOUT);
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_STTTO);
atmel_uart_writel(port, ATMEL_US_IER,
ATMEL_US_ENDRX | ATMEL_US_TIMEOUT);
}
/* enable PDC controller */
atmel_uart_writel(port, ATMEL_PDC_PTCR, ATMEL_PDC_RXTEN);
} else if (atmel_use_dma_rx(port)) {
/* set UART timeout */
if (!atmel_port->is_usart) {
mod_timer(&atmel_port->uart_timer,
jiffies + uart_poll_timeout(port));
/* set USART timeout */
} else {
atmel_uart_writel(port, ATMEL_US_RTOR, PDC_RX_TIMEOUT);
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_STTTO);
atmel_uart_writel(port, ATMEL_US_IER,
ATMEL_US_TIMEOUT);
}
} else {
/* enable receive only */
atmel_uart_writel(port, ATMEL_US_IER, ATMEL_US_RXRDY);
}
return 0;
free_irq:
free_irq(port->irq, port);
return retval;
}
/*
* Flush any TX data submitted for DMA. Called when the TX circular
* buffer is reset.
*/
static void atmel_flush_buffer(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
if (atmel_use_pdc_tx(port)) {
atmel_uart_writel(port, ATMEL_PDC_TCR, 0);
atmel_port->pdc_tx.ofs = 0;
}
}
/*
* Disable the port
*/
static void atmel_shutdown(struct uart_port *port)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
/*
* Prevent any tasklets being scheduled during
* cleanup
*/
del_timer_sync(&atmel_port->uart_timer);
/*
* Clear out any scheduled tasklets before
* we destroy the buffers
*/
tasklet_disable(&atmel_port->tasklet);
tasklet_kill(&atmel_port->tasklet);
/*
* Ensure everything is stopped and
* disable all interrupts, port and break condition.
*/
atmel_stop_rx(port);
atmel_stop_tx(port);
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_RSTSTA);
atmel_uart_writel(port, ATMEL_US_IDR, -1);
/*
* Shut-down the DMA.
*/
if (atmel_port->release_rx)
atmel_port->release_rx(port);
if (atmel_port->release_tx)
atmel_port->release_tx(port);
/*
* Reset ring buffer pointers
*/
atmel_port->rx_ring.head = 0;
atmel_port->rx_ring.tail = 0;
/*
* Free the interrupts
*/
free_irq(port->irq, port);
atmel_free_gpio_irq(port);
atmel_port->ms_irq_enabled = false;
atmel_flush_buffer(port);
}
/*
* Power / Clock management.
*/
static void atmel_serial_pm(struct uart_port *port, unsigned int state,
unsigned int oldstate)
{
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
switch (state) {
case 0:
/*
* Enable the peripheral clock for this serial port.
* This is called on uart_open() or a resume event.
*/
clk_prepare_enable(atmel_port->clk);
/* re-enable interrupts if we disabled some on suspend */
atmel_uart_writel(port, ATMEL_US_IER, atmel_port->backup_imr);
break;
case 3:
/* Back up the interrupt mask and disable all interrupts */
atmel_port->backup_imr = atmel_uart_readl(port, ATMEL_US_IMR);
atmel_uart_writel(port, ATMEL_US_IDR, -1);
/*
* Disable the peripheral clock for this serial port.
* This is called on uart_close() or a suspend event.
*/
clk_disable_unprepare(atmel_port->clk);
break;
default:
dev_err(port->dev, "atmel_serial: unknown pm %d\n", state);
}
}
/*
* Change the port parameters
*/
static void atmel_set_termios(struct uart_port *port, struct ktermios *termios,
struct ktermios *old)
{
unsigned long flags;
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
unsigned int old_mode, mode, imr, quot, baud;
/* save the current mode register */
mode = old_mode = atmel_uart_readl(port, ATMEL_US_MR);
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
/* reset the mode, clock divisor, parity, stop bits and data size */
mode &= ~(ATMEL_US_USCLKS | ATMEL_US_CHRL | ATMEL_US_NBSTOP |
ATMEL_US_PAR | ATMEL_US_USMODE);
baud = uart_get_baud_rate(port, termios, old, 0, port->uartclk / 16);
quot = uart_get_divisor(port, baud);
if (quot > 65535) { /* BRGR is 16-bit, so switch to slower clock */
quot /= 8;
mode |= ATMEL_US_USCLKS_MCK_DIV8;
}
/* byte size */
switch (termios->c_cflag & CSIZE) {
case CS5:
mode |= ATMEL_US_CHRL_5;
break;
case CS6:
mode |= ATMEL_US_CHRL_6;
break;
case CS7:
mode |= ATMEL_US_CHRL_7;
break;
default:
mode |= ATMEL_US_CHRL_8;
break;
}
/* stop bits */
if (termios->c_cflag & CSTOPB)
mode |= ATMEL_US_NBSTOP_2;
/* parity */
if (termios->c_cflag & PARENB) {
/* Mark or Space parity */
if (termios->c_cflag & CMSPAR) {
if (termios->c_cflag & PARODD)
mode |= ATMEL_US_PAR_MARK;
else
mode |= ATMEL_US_PAR_SPACE;
} else if (termios->c_cflag & PARODD)
mode |= ATMEL_US_PAR_ODD;
else
mode |= ATMEL_US_PAR_EVEN;
} else
mode |= ATMEL_US_PAR_NONE;
spin_lock_irqsave(&port->lock, flags);
port->read_status_mask = ATMEL_US_OVRE;
if (termios->c_iflag & INPCK)
port->read_status_mask |= (ATMEL_US_FRAME | ATMEL_US_PARE);
serial: Fix IGNBRK handling If IGNBRK is set without either BRKINT or PARMRK set, some uart drivers send a 0x00 byte for BREAK without the TTYBREAK flag to the line discipline, when it should send either nothing or the TTYBREAK flag set. This happens because the read_status_mask masks out the BI condition, which uart_insert_char() then interprets as a normal 0x00 byte. SUS v3 is clear regarding the meaning of IGNBRK; Section 11.2.2, General Terminal Interface - Input Modes, states: "If IGNBRK is set, a break condition detected on input shall be ignored; that is, not put on the input queue and therefore not read by any process." Fix read_status_mask to include the BI bit if IGNBRK is set; the lsr status retains the BI bit if a BREAK is recv'd, which is subsequently ignored in uart_insert_char() when masked with the ignore_status_mask. Affected drivers: 8250 - all serial_txx9 mfd amba-pl010 amba-pl011 atmel_serial bfin_uart dz ip22zilog max310x mxs-auart netx-serial pnx8xxx_uart pxa sb1250-duart sccnxp serial_ks8695 sirfsoc_uart st-asc vr41xx_siu zs sunzilog fsl_lpuart sunsab ucc_uart bcm63xx_uart sunsu efm32-uart pmac_zilog mpsc msm_serial m32r_sio Unaffected drivers: omap-serial rp2 sa1100 imx icom Annotated for fixes: altera_uart mcf Drivers without break detection: 21285 xilinx-uartps altera_jtaguart apbuart arc-uart clps711x max3100 uartlite msm_serial_hs nwpserial lantiq vt8500_serial Unknown: samsung mpc52xx_uart bfin_sport_uart cpm_uart/core Fixes: Bugzilla #71651, '8250_core.c incorrectly handles IGNBRK flag' Reported-by: Ivan <athlon_@mail.ru> Signed-off-by: Peter Hurley <peter@hurleysoftware.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-06-16 16:10:41 +04:00
if (termios->c_iflag & (IGNBRK | BRKINT | PARMRK))
port->read_status_mask |= ATMEL_US_RXBRK;
if (atmel_use_pdc_rx(port))
/* need to enable error interrupts */
atmel_uart_writel(port, ATMEL_US_IER, port->read_status_mask);
/*
* Characters to ignore
*/
port->ignore_status_mask = 0;
if (termios->c_iflag & IGNPAR)
port->ignore_status_mask |= (ATMEL_US_FRAME | ATMEL_US_PARE);
if (termios->c_iflag & IGNBRK) {
port->ignore_status_mask |= ATMEL_US_RXBRK;
/*
* If we're ignoring parity and break indicators,
* ignore overruns too (for real raw support).
*/
if (termios->c_iflag & IGNPAR)
port->ignore_status_mask |= ATMEL_US_OVRE;
}
/* TODO: Ignore all characters if CREAD is set.*/
/* update the per-port timeout */
uart_update_timeout(port, termios->c_cflag, baud);
/*
* save/disable interrupts. The tty layer will ensure that the
* transmitter is empty if requested by the caller, so there's
* no need to wait for it here.
*/
imr = atmel_uart_readl(port, ATMEL_US_IMR);
atmel_uart_writel(port, ATMEL_US_IDR, -1);
/* disable receiver and transmitter */
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_TXDIS | ATMEL_US_RXDIS);
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
/* mode */
if (port->rs485.flags & SER_RS485_ENABLED) {
atmel_uart_writel(port, ATMEL_US_TTGR,
port->rs485.delay_rts_after_send);
mode |= ATMEL_US_USMODE_RS485;
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
} else if (termios->c_cflag & CRTSCTS) {
/* RS232 with hardware handshake (RTS/CTS) */
mode |= ATMEL_US_USMODE_HWHS;
} else {
/* RS232 without hadware handshake */
mode |= ATMEL_US_USMODE_NORMAL;
}
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
/* set the mode, clock divisor, parity, stop bits and data size */
atmel_uart_writel(port, ATMEL_US_MR, mode);
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
/*
* when switching the mode, set the RTS line state according to the
* new mode, otherwise keep the former state
*/
if ((old_mode & ATMEL_US_USMODE) != (mode & ATMEL_US_USMODE)) {
unsigned int rts_state;
if ((mode & ATMEL_US_USMODE) == ATMEL_US_USMODE_HWHS) {
/* let the hardware control the RTS line */
rts_state = ATMEL_US_RTSDIS;
} else {
/* force RTS line to low level */
rts_state = ATMEL_US_RTSEN;
}
atmel_uart_writel(port, ATMEL_US_CR, rts_state);
tty/serial: at91: fix RTS line management when hardware handshake is enabled This patch fixes many bugs in the code dealing with the hardware handshake. As an example, in atmel_set_termios(), we used to test whether the CRTSCTS c_cflag was set. If so, we selected the "Hardware Handshake" mode through the Mode Register. However, few lines below the mode was reset to "Normal" (0). So there was no way to select the "Hardware Handshake" mode. To fix this issue, we moved the CRTSCRTS c_cflag test AFTER the mode has been reset to "Normal". Also setting the RTSEN and RTSDIS bits in the Control Register has different results whether the USART is set in "Normal" or "Hardware Handshake" mode: 1) "Normal" mode - the RTSEN bit forces the RTS line to low level, which tells the remote peer that we are ready to received new data. - the RTSDIS bit forces the RTS line to high level, which tells the remote peer to stop sending new data. 2) "Hardware Handshake" mode - the RTSEN bit forces the RTS line to high level. - the RTSDIS bit lets the hardware control the RTS line. WARNING: when FIFOs are not available or not enabled, the RTS line is controlled by the PDC. This is why using the Hardware Handshake mode requires using the PDC channel for reception. However the Hardware Handshake mode DOES NOT work with DMA controller since it cannot control the RTS line. Future designs with FIFOs will introduce a new feature: the RTS line will be controlled by the RX FIFO using thresholds. This patch was tested with this new design. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Acked-by: Nicolas Ferre <nicolas.ferre@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2014-12-09 16:31:35 +03:00
}
/* set the baud rate */
atmel_uart_writel(port, ATMEL_US_BRGR, quot);
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_RSTSTA | ATMEL_US_RSTRX);
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_TXEN | ATMEL_US_RXEN);
/* restore interrupts */
atmel_uart_writel(port, ATMEL_US_IER, imr);
/* CTS flow-control and modem-status interrupts */
if (UART_ENABLE_MS(port, termios->c_cflag))
atmel_enable_ms(port);
else
atmel_disable_ms(port);
spin_unlock_irqrestore(&port->lock, flags);
}
static void atmel_set_ldisc(struct uart_port *port, struct ktermios *termios)
{
if (termios->c_line == N_PPS) {
port->flags |= UPF_HARDPPS_CD;
spin_lock_irq(&port->lock);
atmel_enable_ms(port);
spin_unlock_irq(&port->lock);
} else {
port->flags &= ~UPF_HARDPPS_CD;
if (!UART_ENABLE_MS(port, termios->c_cflag)) {
spin_lock_irq(&port->lock);
atmel_disable_ms(port);
spin_unlock_irq(&port->lock);
}
}
}
/*
* Return string describing the specified port
*/
static const char *atmel_type(struct uart_port *port)
{
return (port->type == PORT_ATMEL) ? "ATMEL_SERIAL" : NULL;
}
/*
* Release the memory region(s) being used by 'port'.
*/
static void atmel_release_port(struct uart_port *port)
{
struct platform_device *pdev = to_platform_device(port->dev);
int size = pdev->resource[0].end - pdev->resource[0].start + 1;
release_mem_region(port->mapbase, size);
if (port->flags & UPF_IOREMAP) {
iounmap(port->membase);
port->membase = NULL;
}
}
/*
* Request the memory region(s) being used by 'port'.
*/
static int atmel_request_port(struct uart_port *port)
{
struct platform_device *pdev = to_platform_device(port->dev);
int size = pdev->resource[0].end - pdev->resource[0].start + 1;
if (!request_mem_region(port->mapbase, size, "atmel_serial"))
return -EBUSY;
if (port->flags & UPF_IOREMAP) {
port->membase = ioremap(port->mapbase, size);
if (port->membase == NULL) {
release_mem_region(port->mapbase, size);
return -ENOMEM;
}
}
return 0;
}
/*
* Configure/autoconfigure the port.
*/
static void atmel_config_port(struct uart_port *port, int flags)
{
if (flags & UART_CONFIG_TYPE) {
port->type = PORT_ATMEL;
atmel_request_port(port);
}
}
/*
* Verify the new serial_struct (for TIOCSSERIAL).
*/
static int atmel_verify_port(struct uart_port *port, struct serial_struct *ser)
{
int ret = 0;
if (ser->type != PORT_UNKNOWN && ser->type != PORT_ATMEL)
ret = -EINVAL;
if (port->irq != ser->irq)
ret = -EINVAL;
if (ser->io_type != SERIAL_IO_MEM)
ret = -EINVAL;
if (port->uartclk / 16 != ser->baud_base)
ret = -EINVAL;
if (port->mapbase != (unsigned long)ser->iomem_base)
ret = -EINVAL;
if (port->iobase != ser->port)
ret = -EINVAL;
if (ser->hub6 != 0)
ret = -EINVAL;
return ret;
}
#ifdef CONFIG_CONSOLE_POLL
static int atmel_poll_get_char(struct uart_port *port)
{
while (!(atmel_uart_readl(port, ATMEL_US_CSR) & ATMEL_US_RXRDY))
cpu_relax();
return atmel_uart_read_char(port);
}
static void atmel_poll_put_char(struct uart_port *port, unsigned char ch)
{
while (!(atmel_uart_readl(port, ATMEL_US_CSR) & ATMEL_US_TXRDY))
cpu_relax();
atmel_uart_write_char(port, ch);
}
#endif
static struct uart_ops atmel_pops = {
.tx_empty = atmel_tx_empty,
.set_mctrl = atmel_set_mctrl,
.get_mctrl = atmel_get_mctrl,
.stop_tx = atmel_stop_tx,
.start_tx = atmel_start_tx,
.stop_rx = atmel_stop_rx,
.enable_ms = atmel_enable_ms,
.break_ctl = atmel_break_ctl,
.startup = atmel_startup,
.shutdown = atmel_shutdown,
.flush_buffer = atmel_flush_buffer,
.set_termios = atmel_set_termios,
.set_ldisc = atmel_set_ldisc,
.type = atmel_type,
.release_port = atmel_release_port,
.request_port = atmel_request_port,
.config_port = atmel_config_port,
.verify_port = atmel_verify_port,
.pm = atmel_serial_pm,
#ifdef CONFIG_CONSOLE_POLL
.poll_get_char = atmel_poll_get_char,
.poll_put_char = atmel_poll_put_char,
#endif
};
/*
* Configure the port from the platform device resource info.
*/
static int atmel_init_port(struct atmel_uart_port *atmel_port,
struct platform_device *pdev)
{
int ret;
struct uart_port *port = &atmel_port->uart;
struct atmel_uart_data *pdata = dev_get_platdata(&pdev->dev);
atmel_init_property(atmel_port, pdev);
atmel_set_ops(port);
atmel_init_rs485(port, pdev);
port->iotype = UPIO_MEM;
port->flags = UPF_BOOT_AUTOCONF;
port->ops = &atmel_pops;
port->fifosize = 1;
port->dev = &pdev->dev;
port->mapbase = pdev->resource[0].start;
port->irq = pdev->resource[1].start;
port->rs485_config = atmel_config_rs485;
tasklet_init(&atmel_port->tasklet, atmel_tasklet_func,
(unsigned long)port);
tasklet_disable(&atmel_port->tasklet);
memset(&atmel_port->rx_ring, 0, sizeof(atmel_port->rx_ring));
if (pdata && pdata->regs) {
/* Already mapped by setup code */
port->membase = pdata->regs;
} else {
port->flags |= UPF_IOREMAP;
port->membase = NULL;
}
/* for console, the clock could already be configured */
if (!atmel_port->clk) {
atmel_port->clk = clk_get(&pdev->dev, "usart");
if (IS_ERR(atmel_port->clk)) {
ret = PTR_ERR(atmel_port->clk);
atmel_port->clk = NULL;
return ret;
}
ret = clk_prepare_enable(atmel_port->clk);
if (ret) {
clk_put(atmel_port->clk);
atmel_port->clk = NULL;
return ret;
}
port->uartclk = clk_get_rate(atmel_port->clk);
clk_disable_unprepare(atmel_port->clk);
/* only enable clock when USART is in use */
}
/* Use TXEMPTY for interrupt when rs485 else TXRDY or ENDTX|TXBUFE */
if (port->rs485.flags & SER_RS485_ENABLED)
atmel_port->tx_done_mask = ATMEL_US_TXEMPTY;
else if (atmel_use_pdc_tx(port)) {
port->fifosize = PDC_BUFFER_SIZE;
atmel_port->tx_done_mask = ATMEL_US_ENDTX | ATMEL_US_TXBUFE;
} else {
atmel_port->tx_done_mask = ATMEL_US_TXRDY;
}
return 0;
}
struct platform_device *atmel_default_console_device; /* the serial console device */
#ifdef CONFIG_SERIAL_ATMEL_CONSOLE
static void atmel_console_putchar(struct uart_port *port, int ch)
{
while (!(atmel_uart_readl(port, ATMEL_US_CSR) & ATMEL_US_TXRDY))
cpu_relax();
atmel_uart_write_char(port, ch);
}
/*
* Interrupts are disabled on entering
*/
static void atmel_console_write(struct console *co, const char *s, u_int count)
{
struct uart_port *port = &atmel_ports[co->index].uart;
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
unsigned int status, imr;
unsigned int pdc_tx;
/*
* First, save IMR and then disable interrupts
*/
imr = atmel_uart_readl(port, ATMEL_US_IMR);
atmel_uart_writel(port, ATMEL_US_IDR,
ATMEL_US_RXRDY | atmel_port->tx_done_mask);
/* Store PDC transmit status and disable it */
pdc_tx = atmel_uart_readl(port, ATMEL_PDC_PTSR) & ATMEL_PDC_TXTEN;
atmel_uart_writel(port, ATMEL_PDC_PTCR, ATMEL_PDC_TXTDIS);
uart_console_write(port, s, count, atmel_console_putchar);
/*
* Finally, wait for transmitter to become empty
* and restore IMR
*/
do {
status = atmel_uart_readl(port, ATMEL_US_CSR);
} while (!(status & ATMEL_US_TXRDY));
/* Restore PDC transmit status */
if (pdc_tx)
atmel_uart_writel(port, ATMEL_PDC_PTCR, ATMEL_PDC_TXTEN);
/* set interrupts back the way they were */
atmel_uart_writel(port, ATMEL_US_IER, imr);
}
/*
* If the port was already initialised (eg, by a boot loader),
* try to determine the current setup.
*/
static void __init atmel_console_get_options(struct uart_port *port, int *baud,
int *parity, int *bits)
{
unsigned int mr, quot;
/*
* If the baud rate generator isn't running, the port wasn't
* initialized by the boot loader.
*/
quot = atmel_uart_readl(port, ATMEL_US_BRGR) & ATMEL_US_CD;
if (!quot)
return;
mr = atmel_uart_readl(port, ATMEL_US_MR) & ATMEL_US_CHRL;
if (mr == ATMEL_US_CHRL_8)
*bits = 8;
else
*bits = 7;
mr = atmel_uart_readl(port, ATMEL_US_MR) & ATMEL_US_PAR;
if (mr == ATMEL_US_PAR_EVEN)
*parity = 'e';
else if (mr == ATMEL_US_PAR_ODD)
*parity = 'o';
/*
* The serial core only rounds down when matching this to a
* supported baud rate. Make sure we don't end up slightly
* lower than one of those, as it would make us fall through
* to a much lower baud rate than we really want.
*/
*baud = port->uartclk / (16 * (quot - 1));
}
static int __init atmel_console_setup(struct console *co, char *options)
{
int ret;
struct uart_port *port = &atmel_ports[co->index].uart;
int baud = 115200;
int bits = 8;
int parity = 'n';
int flow = 'n';
if (port->membase == NULL) {
/* Port not initialized yet - delay setup */
return -ENODEV;
}
ret = clk_prepare_enable(atmel_ports[co->index].clk);
if (ret)
return ret;
atmel_uart_writel(port, ATMEL_US_IDR, -1);
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_RSTSTA | ATMEL_US_RSTRX);
atmel_uart_writel(port, ATMEL_US_CR, ATMEL_US_TXEN | ATMEL_US_RXEN);
if (options)
uart_parse_options(options, &baud, &parity, &bits, &flow);
else
atmel_console_get_options(port, &baud, &parity, &bits);
return uart_set_options(port, co, baud, parity, bits, flow);
}
static struct uart_driver atmel_uart;
static struct console atmel_console = {
.name = ATMEL_DEVICENAME,
.write = atmel_console_write,
.device = uart_console_device,
.setup = atmel_console_setup,
.flags = CON_PRINTBUFFER,
.index = -1,
.data = &atmel_uart,
};
#define ATMEL_CONSOLE_DEVICE (&atmel_console)
/*
* Early console initialization (before VM subsystem initialized).
*/
static int __init atmel_console_init(void)
{
int ret;
if (atmel_default_console_device) {
struct atmel_uart_data *pdata =
dev_get_platdata(&atmel_default_console_device->dev);
2011-10-26 17:11:09 +04:00
int id = pdata->num;
struct atmel_uart_port *port = &atmel_ports[id];
port->backup_imr = 0;
port->uart.line = id;
add_preferred_console(ATMEL_DEVICENAME, id, NULL);
ret = atmel_init_port(port, atmel_default_console_device);
if (ret)
return ret;
register_console(&atmel_console);
}
return 0;
}
console_initcall(atmel_console_init);
/*
* Late console initialization.
*/
static int __init atmel_late_console_init(void)
{
if (atmel_default_console_device
&& !(atmel_console.flags & CON_ENABLED))
register_console(&atmel_console);
return 0;
}
core_initcall(atmel_late_console_init);
static inline bool atmel_is_console_port(struct uart_port *port)
{
return port->cons && port->cons->index == port->line;
}
#else
#define ATMEL_CONSOLE_DEVICE NULL
static inline bool atmel_is_console_port(struct uart_port *port)
{
return false;
}
#endif
static struct uart_driver atmel_uart = {
.owner = THIS_MODULE,
.driver_name = "atmel_serial",
.dev_name = ATMEL_DEVICENAME,
.major = SERIAL_ATMEL_MAJOR,
.minor = MINOR_START,
.nr = ATMEL_MAX_UART,
.cons = ATMEL_CONSOLE_DEVICE,
};
#ifdef CONFIG_PM
static bool atmel_serial_clk_will_stop(void)
{
#ifdef CONFIG_ARCH_AT91
return at91_suspend_entering_slow_clock();
#else
return false;
#endif
}
static int atmel_serial_suspend(struct platform_device *pdev,
pm_message_t state)
{
struct uart_port *port = platform_get_drvdata(pdev);
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
if (atmel_is_console_port(port) && console_suspend_enabled) {
/* Drain the TX shifter */
while (!(atmel_uart_readl(port, ATMEL_US_CSR) &
ATMEL_US_TXEMPTY))
cpu_relax();
}
/* we can not wake up if we're running on slow clock */
atmel_port->may_wakeup = device_may_wakeup(&pdev->dev);
if (atmel_serial_clk_will_stop()) {
unsigned long flags;
spin_lock_irqsave(&atmel_port->lock_suspended, flags);
atmel_port->suspended = true;
spin_unlock_irqrestore(&atmel_port->lock_suspended, flags);
device_set_wakeup_enable(&pdev->dev, 0);
}
uart_suspend_port(&atmel_uart, port);
return 0;
}
static int atmel_serial_resume(struct platform_device *pdev)
{
struct uart_port *port = platform_get_drvdata(pdev);
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
unsigned long flags;
spin_lock_irqsave(&atmel_port->lock_suspended, flags);
if (atmel_port->pending) {
atmel_handle_receive(port, atmel_port->pending);
atmel_handle_status(port, atmel_port->pending,
atmel_port->pending_status);
atmel_handle_transmit(port, atmel_port->pending);
atmel_port->pending = 0;
}
atmel_port->suspended = false;
spin_unlock_irqrestore(&atmel_port->lock_suspended, flags);
uart_resume_port(&atmel_uart, port);
device_set_wakeup_enable(&pdev->dev, atmel_port->may_wakeup);
return 0;
}
#else
#define atmel_serial_suspend NULL
#define atmel_serial_resume NULL
#endif
static int atmel_init_gpios(struct atmel_uart_port *p, struct device *dev)
{
enum mctrl_gpio_idx i;
struct gpio_desc *gpiod;
p->gpios = mctrl_gpio_init_noauto(dev, 0);
if (IS_ERR(p->gpios))
return PTR_ERR(p->gpios);
for (i = 0; i < UART_GPIO_MAX; i++) {
gpiod = mctrl_gpio_to_gpiod(p->gpios, i);
if (gpiod && (gpiod_get_direction(gpiod) == GPIOF_DIR_IN))
p->gpio_irq[i] = gpiod_to_irq(gpiod);
else
p->gpio_irq[i] = -EINVAL;
}
return 0;
}
tty/serial: at91: add support to FIFOs Depending on the hardware, TX and RX FIFOs may be available. The RX FIFO can avoid receive overruns, especially when DMA transfers are not used to read data from the Receive Holding Register. For heavy system load, The CPU is likely not be able to fetch data fast enough from the RHR. In addition, the RX FIFO can supersede the DMA/PDC to control the RTS line when the Hardware Handshaking mode is enabled. Two thresholds are to be set for that purpose: - When the number of data in the RX FIFO crosses and becomes lower than or equal to the low threshold, the RTS line is set to low level: the remote peer is requested to send data. - When the number of data in the RX FIFO crosses and becomes greater than or equal to the high threshold, the RTS line is set to high level: the remote peer should stop sending new data. - low threshold <= high threshold Once these two thresholds are set properly, this new feature is enabled by setting the FIFO RTS Control bit of the FIFO Mode Register. FIFOs also introduce a new multiple data mode: the USART works either in multiple data mode or in single data (legacy) mode. If MODE9 bit is set into the Mode Register or if USMODE is set to either LIN_MASTER, LIN_SLAVE or LON_MODE, FIFOs operate in single data mode. Otherwise, they operate in multiple data mode. In this new multiple data mode, accesses to the Receive Holding Register or Transmit Holding Register slightly change. Since this driver implements neither the 9bit data feature (MODE9 bit set into the Mode Register) nor LIN modes, the USART works in multiple data mode whenever FIFOs are available and enabled. We also assume that data are 8bit wide. In single data mode, 32bit access CAN be used to read a single data from RHR or write a single data into THR. However in multiple data mode, a 32bit access to RHR now allows us to read four consecutive data from RX FIFO. Also a 32bit access to THR now allows to write four consecutive data into TX FIFO. So we MUST use 8bit access whenever only one data have to be read/written at a time. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:12 +03:00
static void atmel_serial_probe_fifos(struct atmel_uart_port *port,
struct platform_device *pdev)
{
port->fifo_size = 0;
port->rts_low = 0;
port->rts_high = 0;
if (of_property_read_u32(pdev->dev.of_node,
"atmel,fifo-size",
&port->fifo_size))
return;
if (!port->fifo_size)
return;
if (port->fifo_size < ATMEL_MIN_FIFO_SIZE) {
port->fifo_size = 0;
dev_err(&pdev->dev, "Invalid FIFO size\n");
return;
}
/*
* 0 <= rts_low <= rts_high <= fifo_size
* Once their CTS line asserted by the remote peer, some x86 UARTs tend
* to flush their internal TX FIFO, commonly up to 16 data, before
* actually stopping to send new data. So we try to set the RTS High
* Threshold to a reasonably high value respecting this 16 data
* empirical rule when possible.
*/
port->rts_high = max_t(int, port->fifo_size >> 1,
port->fifo_size - ATMEL_RTS_HIGH_OFFSET);
port->rts_low = max_t(int, port->fifo_size >> 2,
port->fifo_size - ATMEL_RTS_LOW_OFFSET);
dev_info(&pdev->dev, "Using FIFO (%u data)\n",
port->fifo_size);
dev_dbg(&pdev->dev, "RTS High Threshold : %2u data\n",
port->rts_high);
dev_dbg(&pdev->dev, "RTS Low Threshold : %2u data\n",
port->rts_low);
}
static int atmel_serial_probe(struct platform_device *pdev)
{
struct atmel_uart_port *port;
struct device_node *np = pdev->dev.of_node;
struct atmel_uart_data *pdata = dev_get_platdata(&pdev->dev);
void *data;
int ret = -ENODEV;
bool rs485_enabled;
BUILD_BUG_ON(ATMEL_SERIAL_RINGSIZE & (ATMEL_SERIAL_RINGSIZE - 1));
if (np)
ret = of_alias_get_id(np, "serial");
else
if (pdata)
ret = pdata->num;
if (ret < 0)
/* port id not found in platform data nor device-tree aliases:
* auto-enumerate it */
ret = find_first_zero_bit(atmel_ports_in_use, ATMEL_MAX_UART);
if (ret >= ATMEL_MAX_UART) {
ret = -ENODEV;
goto err;
}
if (test_and_set_bit(ret, atmel_ports_in_use)) {
/* port already in use */
ret = -EBUSY;
goto err;
}
port = &atmel_ports[ret];
port->backup_imr = 0;
port->uart.line = ret;
tty/serial: at91: add support to FIFOs Depending on the hardware, TX and RX FIFOs may be available. The RX FIFO can avoid receive overruns, especially when DMA transfers are not used to read data from the Receive Holding Register. For heavy system load, The CPU is likely not be able to fetch data fast enough from the RHR. In addition, the RX FIFO can supersede the DMA/PDC to control the RTS line when the Hardware Handshaking mode is enabled. Two thresholds are to be set for that purpose: - When the number of data in the RX FIFO crosses and becomes lower than or equal to the low threshold, the RTS line is set to low level: the remote peer is requested to send data. - When the number of data in the RX FIFO crosses and becomes greater than or equal to the high threshold, the RTS line is set to high level: the remote peer should stop sending new data. - low threshold <= high threshold Once these two thresholds are set properly, this new feature is enabled by setting the FIFO RTS Control bit of the FIFO Mode Register. FIFOs also introduce a new multiple data mode: the USART works either in multiple data mode or in single data (legacy) mode. If MODE9 bit is set into the Mode Register or if USMODE is set to either LIN_MASTER, LIN_SLAVE or LON_MODE, FIFOs operate in single data mode. Otherwise, they operate in multiple data mode. In this new multiple data mode, accesses to the Receive Holding Register or Transmit Holding Register slightly change. Since this driver implements neither the 9bit data feature (MODE9 bit set into the Mode Register) nor LIN modes, the USART works in multiple data mode whenever FIFOs are available and enabled. We also assume that data are 8bit wide. In single data mode, 32bit access CAN be used to read a single data from RHR or write a single data into THR. However in multiple data mode, a 32bit access to RHR now allows us to read four consecutive data from RX FIFO. Also a 32bit access to THR now allows to write four consecutive data into TX FIFO. So we MUST use 8bit access whenever only one data have to be read/written at a time. Signed-off-by: Cyrille Pitchen <cyrille.pitchen@atmel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-07-02 16:18:12 +03:00
atmel_serial_probe_fifos(port, pdev);
spin_lock_init(&port->lock_suspended);
ret = atmel_init_gpios(port, &pdev->dev);
if (ret < 0) {
dev_err(&pdev->dev, "Failed to initialize GPIOs.");
goto err_clear_bit;
}
ret = atmel_init_port(port, pdev);
if (ret)
goto err_clear_bit;
if (!atmel_use_pdc_rx(&port->uart)) {
ret = -ENOMEM;
data = kmalloc(sizeof(struct atmel_uart_char)
* ATMEL_SERIAL_RINGSIZE, GFP_KERNEL);
if (!data)
goto err_alloc_ring;
port->rx_ring.buf = data;
}
rs485_enabled = port->uart.rs485.flags & SER_RS485_ENABLED;
ret = uart_add_one_port(&atmel_uart, &port->uart);
if (ret)
goto err_add_port;
#ifdef CONFIG_SERIAL_ATMEL_CONSOLE
if (atmel_is_console_port(&port->uart)
&& ATMEL_CONSOLE_DEVICE->flags & CON_ENABLED) {
/*
* The serial core enabled the clock for us, so undo
* the clk_prepare_enable() in atmel_console_setup()
*/
clk_disable_unprepare(port->clk);
}
#endif
device_init_wakeup(&pdev->dev, 1);
platform_set_drvdata(pdev, port);
/*
* The peripheral clock has been disabled by atmel_init_port():
* enable it before accessing I/O registers
*/
clk_prepare_enable(port->clk);
if (rs485_enabled) {
atmel_uart_writel(&port->uart, ATMEL_US_MR,
ATMEL_US_USMODE_NORMAL);
atmel_uart_writel(&port->uart, ATMEL_US_CR, ATMEL_US_RTSEN);
}
/*
* Get port name of usart or uart
*/
atmel_get_ip_name(&port->uart);
/*
* The peripheral clock can now safely be disabled till the port
* is used
*/
clk_disable_unprepare(port->clk);
return 0;
err_add_port:
kfree(port->rx_ring.buf);
port->rx_ring.buf = NULL;
err_alloc_ring:
if (!atmel_is_console_port(&port->uart)) {
clk_put(port->clk);
port->clk = NULL;
}
err_clear_bit:
clear_bit(port->uart.line, atmel_ports_in_use);
err:
return ret;
}
static int atmel_serial_remove(struct platform_device *pdev)
{
struct uart_port *port = platform_get_drvdata(pdev);
struct atmel_uart_port *atmel_port = to_atmel_uart_port(port);
int ret = 0;
tasklet_kill(&atmel_port->tasklet);
device_init_wakeup(&pdev->dev, 0);
ret = uart_remove_one_port(&atmel_uart, port);
kfree(atmel_port->rx_ring.buf);
/* "port" is allocated statically, so we shouldn't free it */
clear_bit(port->line, atmel_ports_in_use);
clk_put(atmel_port->clk);
return ret;
}
static struct platform_driver atmel_serial_driver = {
.probe = atmel_serial_probe,
.remove = atmel_serial_remove,
.suspend = atmel_serial_suspend,
.resume = atmel_serial_resume,
.driver = {
.name = "atmel_usart",
.of_match_table = of_match_ptr(atmel_serial_dt_ids),
},
};
static int __init atmel_serial_init(void)
{
int ret;
ret = uart_register_driver(&atmel_uart);
if (ret)
return ret;
ret = platform_driver_register(&atmel_serial_driver);
if (ret)
uart_unregister_driver(&atmel_uart);
return ret;
}
static void __exit atmel_serial_exit(void)
{
platform_driver_unregister(&atmel_serial_driver);
uart_unregister_driver(&atmel_uart);
}
module_init(atmel_serial_init);
module_exit(atmel_serial_exit);
MODULE_AUTHOR("Rick Bronson");
MODULE_DESCRIPTION("Atmel AT91 / AT32 serial port driver");
MODULE_LICENSE("GPL");
MODULE_ALIAS("platform:atmel_usart");