android_kernel_cmhtcleo/drivers/serial/msm_serial_hs.c
tytung 1b9449e9a4 Fixed Bluetooth 60mA battery drain
Based on Trilu's patch http://forum.xda-developers.com/showthread.php?t=1007774
Removed some debug and unnecessary code, and added some missing code by tytung.
Thanks to Trilu for finally fixing the BT problem.
Thanks to Charansingh for the work he has done on the BT problem.
2011-03-25 23:15:05 +08:00

1556 lines
42 KiB
C

/* drivers/serial/msm_serial_hs.c
*
* MSM 7k/8k High speed uart driver
*
* Copyright (c) 2007-2008 QUALCOMM Incorporated.
* Copyright (c) 2008 QUALCOMM USA, INC.
* Copyright (c) 2008 Google Inc.
* Modified: Nick Pelly <npelly@google.com>
*
* All source code in this file is licensed under the following license
* except where indicated.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* version 2 as published by the Free Software Foundation.
*
* 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, you can find it at http://www.fsf.org
*/
/*
* MSM 7k/8k High speed uart driver
*
* Has optional support for uart power management independent of linux
* suspend/resume:
*
* RX wakeup.
* UART wakeup can be triggered by RX activity (using a wakeup GPIO on the
* UART RX pin). This should only be used if there is not a wakeup
* GPIO on the UART CTS, and the first RX byte is known (for example, with the
* Bluetooth Texas Instruments HCILL protocol), since the first RX byte will
* always be lost. RTS will be asserted even while the UART is off in this mode
* of operation. See msm_serial_hs_platform_data.rx_wakeup_irq.
*/
#include <linux/module.h>
#include <linux/serial.h>
#include <linux/serial_core.h>
#include <linux/slab.h>
#include <linux/init.h>
#include <linux/interrupt.h>
#include <linux/irq.h>
#include <linux/io.h>
#include <linux/ioport.h>
#include <linux/kernel.h>
#include <linux/timer.h>
#include <linux/clk.h>
#include <linux/platform_device.h>
#include <linux/dma-mapping.h>
#include <linux/dmapool.h>
#include <linux/wait.h>
#include <linux/wakelock.h>
#include <linux/workqueue.h>
#include <asm/atomic.h>
#include <asm/irq.h>
#include <asm/system.h>
#include <mach/hardware.h>
#include <mach/dma.h>
#include <mach/msm_serial_hs.h>
#include "msm_serial_hs_hwreg.h"
enum flush_reason {
FLUSH_NONE,
FLUSH_DATA_READY,
FLUSH_DATA_INVALID, /* values after this indicate invalid data */
FLUSH_IGNORE = FLUSH_DATA_INVALID,
FLUSH_STOP,
FLUSH_SHUTDOWN,
};
enum msm_hs_clk_states_e {
MSM_HS_CLK_PORT_OFF, /* port not in use */
MSM_HS_CLK_OFF, /* clock disabled */
MSM_HS_CLK_REQUEST_OFF, /* disable after TX and RX flushed */
MSM_HS_CLK_ON, /* clock enabled */
};
/* Track the forced RXSTALE flush during clock off sequence.
* These states are only valid during MSM_HS_CLK_REQUEST_OFF */
enum msm_hs_clk_req_off_state_e {
CLK_REQ_OFF_START,
CLK_REQ_OFF_RXSTALE_ISSUED,
CLK_REQ_OFF_FLUSH_ISSUED,
CLK_REQ_OFF_RXSTALE_FLUSHED,
};
struct msm_hs_tx {
unsigned int tx_ready_int_en; /* ok to dma more tx */
unsigned int dma_in_flight; /* tx dma in progress */
struct msm_dmov_cmd xfer;
dmov_box *command_ptr;
u32 *command_ptr_ptr;
dma_addr_t mapped_cmd_ptr;
dma_addr_t mapped_cmd_ptr_ptr;
int tx_count;
dma_addr_t dma_base;
};
struct msm_hs_rx {
enum flush_reason flush;
struct msm_dmov_cmd xfer;
dma_addr_t cmdptr_dmaaddr;
dmov_box *command_ptr;
u32 *command_ptr_ptr;
dma_addr_t mapped_cmd_ptr;
wait_queue_head_t wait;
dma_addr_t rbuffer;
unsigned char *buffer;
struct dma_pool *pool;
struct wake_lock wake_lock;
struct work_struct tty_work;
};
/* optional RX GPIO IRQ low power wakeup */
struct msm_hs_rx_wakeup {
int irq; /* < 0 indicates low power wakeup disabled */
unsigned char ignore; /* bool */
/* bool: inject char into rx tty on wakeup */
unsigned char inject_rx;
char rx_to_inject;
};
struct msm_hs_port {
struct uart_port uport;
unsigned long imr_reg; /* shadow value of UARTDM_IMR */
struct clk *clk;
struct msm_hs_tx tx;
struct msm_hs_rx rx;
int dma_tx_channel;
int dma_rx_channel;
int dma_tx_crci;
int dma_rx_crci;
struct hrtimer clk_off_timer; /* to poll TXEMT before clock off */
ktime_t clk_off_delay;
enum msm_hs_clk_states_e clk_state;
enum msm_hs_clk_req_off_state_e clk_req_off_state;
struct msm_hs_rx_wakeup rx_wakeup;
/* optional callback to exit low power mode */
void (*exit_lpm_cb)(struct uart_port *);
struct wake_lock dma_wake_lock; /* held while any DMA active */
};
#define MSM_UARTDM_BURST_SIZE 16 /* DM burst size (in bytes) */
#define UARTDM_TX_BUF_SIZE UART_XMIT_SIZE
#define UARTDM_RX_BUF_SIZE 512
#define UARTDM_NR 2
static struct msm_hs_port q_uart_port[UARTDM_NR];
static struct platform_driver msm_serial_hs_platform_driver;
static struct uart_driver msm_hs_driver;
static struct uart_ops msm_hs_ops;
static struct workqueue_struct *msm_hs_workqueue;
#define UARTDM_TO_MSM(uart_port) \
container_of((uart_port), struct msm_hs_port, uport)
static inline unsigned int use_low_power_rx_wakeup(struct msm_hs_port *msm_uport)
{
return (msm_uport->rx_wakeup.irq >= 0);
}
static inline unsigned int msm_hs_read(struct uart_port *uport,
unsigned int offset)
{
return ioread32(uport->membase + offset);
}
static inline void msm_hs_write(struct uart_port *uport, unsigned int offset,
unsigned int value)
{
iowrite32(value, uport->membase + offset);
}
static void msm_hs_release_port(struct uart_port *port)
{
}
static int msm_hs_request_port(struct uart_port *port)
{
return 0;
}
static int __devexit msm_hs_remove(struct platform_device *pdev)
{
struct msm_hs_port *msm_uport;
struct device *dev;
if (pdev->id < 0 || pdev->id >= UARTDM_NR) {
printk(KERN_ERR "Invalid plaform device ID = %d\n", pdev->id);
return -EINVAL;
}
msm_uport = &q_uart_port[pdev->id];
dev = msm_uport->uport.dev;
dma_unmap_single(dev, msm_uport->rx.mapped_cmd_ptr, sizeof(dmov_box),
DMA_TO_DEVICE);
dma_pool_free(msm_uport->rx.pool, msm_uport->rx.buffer,
msm_uport->rx.rbuffer);
dma_pool_destroy(msm_uport->rx.pool);
dma_unmap_single(dev, msm_uport->rx.cmdptr_dmaaddr, sizeof(u32 *),
DMA_TO_DEVICE);
dma_unmap_single(dev, msm_uport->tx.mapped_cmd_ptr_ptr, sizeof(u32 *),
DMA_TO_DEVICE);
dma_unmap_single(dev, msm_uport->tx.mapped_cmd_ptr, sizeof(dmov_box),
DMA_TO_DEVICE);
wake_lock_destroy(&msm_uport->rx.wake_lock);
wake_lock_destroy(&msm_uport->dma_wake_lock);
uart_remove_one_port(&msm_hs_driver, &msm_uport->uport);
clk_put(msm_uport->clk);
/* Free the tx resources */
kfree(msm_uport->tx.command_ptr);
kfree(msm_uport->tx.command_ptr_ptr);
/* Free the rx resources */
kfree(msm_uport->rx.command_ptr);
kfree(msm_uport->rx.command_ptr_ptr);
iounmap(msm_uport->uport.membase);
return 0;
}
static int msm_hs_init_clk_locked(struct uart_port *uport)
{
int ret;
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
wake_lock(&msm_uport->dma_wake_lock);
ret = clk_enable(msm_uport->clk);
if (ret) {
printk(KERN_ERR "Error could not turn on UART clk\n");
return ret;
}
/* Set up the MREG/NREG/DREG/MNDREG */
ret = clk_set_rate(msm_uport->clk, uport->uartclk);
if (ret) {
printk(KERN_WARNING "Error setting clock rate on UART\n");
return ret;
}
msm_uport->clk_state = MSM_HS_CLK_ON;
return 0;
}
/* Enable and Disable clocks (Used for power management) */
static void msm_hs_pm(struct uart_port *uport, unsigned int state,
unsigned int oldstate)
{
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
if (use_low_power_rx_wakeup(msm_uport) || msm_uport->exit_lpm_cb)
return; /* ignore linux PM states, use msm_hs_request_clock API */
switch (state) {
case 0:
clk_enable(msm_uport->clk);
break;
case 3:
clk_disable(msm_uport->clk);
break;
default:
printk(KERN_ERR "msm_serial: Unknown PM state %d\n", state);
}
}
/*
* programs the UARTDM_CSR register with correct bit rates
*
* Interrupts should be disabled before we are called, as
* we modify Set Baud rate
* Set receive stale interrupt level, dependant on Bit Rate
* Goal is to have around 8 ms before indicate stale.
* roundup (((Bit Rate * .008) / 10) + 1
*/
static void msm_hs_set_bps_locked(struct uart_port *uport,
unsigned int bps)
{
unsigned long rxstale;
unsigned long data;
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
switch (bps) {
case 300:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0x00);
rxstale = 1;
break;
case 600:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0x11);
rxstale = 1;
break;
case 1200:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0x22);
rxstale = 1;
break;
case 2400:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0x33);
rxstale = 1;
break;
case 4800:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0x44);
rxstale = 1;
break;
case 9600:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0x55);
rxstale = 2;
break;
case 14400:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0x66);
rxstale = 3;
break;
case 19200:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0x77);
rxstale = 4;
break;
case 28800:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0x88);
rxstale = 6;
break;
case 38400:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0x99);
rxstale = 8;
break;
case 57600:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0xaa);
rxstale = 16;
break;
case 76800:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0xbb);
rxstale = 16;
break;
case 115200:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0xcc);
rxstale = 31;
break;
case 230400:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0xee);
rxstale = 31;
break;
case 460800:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0xff);
rxstale = 31;
break;
case 4000000:
case 3686400:
case 3200000:
case 3500000:
case 3000000:
case 2500000:
case 1500000:
case 1152000:
case 1000000:
case 921600:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0xff);
rxstale = 31;
break;
default:
msm_hs_write(uport, UARTDM_CSR_ADDR, 0xff);
/* default to 9600 */
bps = 9600;
rxstale = 2;
break;
}
if (bps > 460800) {
uport->uartclk = bps * 16;
} else {
uport->uartclk = 7372800;
}
if (clk_set_rate(msm_uport->clk, uport->uartclk)) {
printk(KERN_WARNING "Error setting clock rate on UART\n");
return;
}
data = rxstale & UARTDM_IPR_STALE_LSB_BMSK;
data |= UARTDM_IPR_STALE_TIMEOUT_MSB_BMSK & (rxstale << 2);
msm_hs_write(uport, UARTDM_IPR_ADDR, data);
}
/*
* termios : new ktermios
* oldtermios: old ktermios previous setting
*
* Configure the serial port
*/
static void msm_hs_set_termios(struct uart_port *uport,
struct ktermios *termios,
struct ktermios *oldtermios)
{
unsigned int bps;
unsigned long data;
unsigned long flags;
unsigned int c_cflag = termios->c_cflag;
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
spin_lock_irqsave(&uport->lock, flags);
clk_enable(msm_uport->clk);
/* 300 is the minimum baud support by the driver */
bps = uart_get_baud_rate(uport, termios, oldtermios, 200, 4000000);
/* Temporary remapping 200 BAUD to 3.2 mbps */
if (bps == 200)
bps = 3200000;
msm_hs_set_bps_locked(uport, bps);
data = msm_hs_read(uport, UARTDM_MR2_ADDR);
data &= ~UARTDM_MR2_PARITY_MODE_BMSK;
/* set parity */
if (PARENB == (c_cflag & PARENB)) {
if (PARODD == (c_cflag & PARODD)) {
data |= ODD_PARITY;
} else if (CMSPAR == (c_cflag & CMSPAR)) {
data |= SPACE_PARITY;
} else {
data |= EVEN_PARITY;
}
}
/* Set bits per char */
data &= ~UARTDM_MR2_BITS_PER_CHAR_BMSK;
switch (c_cflag & CSIZE) {
case CS5:
data |= FIVE_BPC;
break;
case CS6:
data |= SIX_BPC;
break;
case CS7:
data |= SEVEN_BPC;
break;
default:
data |= EIGHT_BPC;
break;
}
/* stop bits */
if (c_cflag & CSTOPB) {
data |= STOP_BIT_TWO;
} else {
/* otherwise 1 stop bit */
data |= STOP_BIT_ONE;
}
data |= UARTDM_MR2_ERROR_MODE_BMSK;
/* write parity/bits per char/stop bit configuration */
msm_hs_write(uport, UARTDM_MR2_ADDR, data);
/* Configure HW flow control */
data = msm_hs_read(uport, UARTDM_MR1_ADDR);
data &= ~(UARTDM_MR1_CTS_CTL_BMSK | UARTDM_MR1_RX_RDY_CTL_BMSK);
if (c_cflag & CRTSCTS) {
data |= UARTDM_MR1_CTS_CTL_BMSK;
data |= UARTDM_MR1_RX_RDY_CTL_BMSK;
}
msm_hs_write(uport, UARTDM_MR1_ADDR, data);
uport->ignore_status_mask = termios->c_iflag & INPCK;
uport->ignore_status_mask |= termios->c_iflag & IGNPAR;
uport->read_status_mask = (termios->c_cflag & CREAD);
msm_hs_write(uport, UARTDM_IMR_ADDR, 0);
/* Set Transmit software time out */
uart_update_timeout(uport, c_cflag, bps);
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_RX);
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_TX);
if (msm_uport->rx.flush == FLUSH_NONE) {
wake_lock(&msm_uport->rx.wake_lock);
msm_uport->rx.flush = FLUSH_IGNORE;
msm_dmov_flush(msm_uport->dma_rx_channel);
}
msm_hs_write(uport, UARTDM_IMR_ADDR, msm_uport->imr_reg);
clk_disable(msm_uport->clk);
spin_unlock_irqrestore(&uport->lock, flags);
}
/*
* Standard API, Transmitter
* Any character in the transmit shift register is sent
*/
static unsigned int msm_hs_tx_empty(struct uart_port *uport)
{
unsigned int data;
unsigned int ret = 0;
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
clk_enable(msm_uport->clk);
data = msm_hs_read(uport, UARTDM_SR_ADDR);
if (data & UARTDM_SR_TXEMT_BMSK)
ret = TIOCSER_TEMT;
clk_disable(msm_uport->clk);
return ret;
}
/*
* Standard API, Stop transmitter.
* Any character in the transmit shift register is sent as
* well as the current data mover transfer .
*/
static void msm_hs_stop_tx_locked(struct uart_port *uport)
{
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
msm_uport->tx.tx_ready_int_en = 0;
}
/*
* Standard API, Stop receiver as soon as possible.
*
* Function immediately terminates the operation of the
* channel receiver and any incoming characters are lost. None
* of the receiver status bits are affected by this command and
* characters that are already in the receive FIFO there.
*/
static void msm_hs_stop_rx_locked(struct uart_port *uport)
{
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
unsigned int data;
clk_enable(msm_uport->clk);
/* disable dlink */
data = msm_hs_read(uport, UARTDM_DMEN_ADDR);
data &= ~UARTDM_RX_DM_EN_BMSK;
msm_hs_write(uport, UARTDM_DMEN_ADDR, data);
/* Disable the receiver */
if (msm_uport->rx.flush == FLUSH_NONE) {
wake_lock(&msm_uport->rx.wake_lock);
msm_dmov_flush(msm_uport->dma_rx_channel);
}
if (msm_uport->rx.flush != FLUSH_SHUTDOWN)
msm_uport->rx.flush = FLUSH_STOP;
clk_disable(msm_uport->clk);
}
/* Transmit the next chunk of data */
static void msm_hs_submit_tx_locked(struct uart_port *uport)
{
int left;
int tx_count;
dma_addr_t src_addr;
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
struct msm_hs_tx *tx = &msm_uport->tx;
struct circ_buf *tx_buf = &msm_uport->uport.state->xmit;
if (uart_circ_empty(tx_buf) || uport->state->port.tty->stopped) {
msm_hs_stop_tx_locked(uport);
return;
}
tx->dma_in_flight = 1;
tx_count = uart_circ_chars_pending(tx_buf);
if (UARTDM_TX_BUF_SIZE < tx_count)
tx_count = UARTDM_TX_BUF_SIZE;
left = UART_XMIT_SIZE - tx_buf->tail;
if (tx_count > left)
tx_count = left;
src_addr = tx->dma_base + tx_buf->tail;
dma_sync_single_for_device(uport->dev, src_addr, tx_count,
DMA_TO_DEVICE);
tx->command_ptr->num_rows = (((tx_count + 15) >> 4) << 16) |
((tx_count + 15) >> 4);
tx->command_ptr->src_row_addr = src_addr;
dma_sync_single_for_device(uport->dev, tx->mapped_cmd_ptr,
sizeof(dmov_box), DMA_TO_DEVICE);
*tx->command_ptr_ptr = CMD_PTR_LP | DMOV_CMD_ADDR(tx->mapped_cmd_ptr);
dma_sync_single_for_device(uport->dev, tx->mapped_cmd_ptr_ptr,
sizeof(u32 *), DMA_TO_DEVICE);
/* Save tx_count to use in Callback */
tx->tx_count = tx_count;
msm_hs_write(uport, UARTDM_NCF_TX_ADDR, tx_count);
/* Disable the tx_ready interrupt */
msm_uport->imr_reg &= ~UARTDM_ISR_TX_READY_BMSK;
msm_hs_write(uport, UARTDM_IMR_ADDR, msm_uport->imr_reg);
msm_dmov_enqueue_cmd(msm_uport->dma_tx_channel, &tx->xfer);
}
/* Start to receive the next chunk of data */
static void msm_hs_start_rx_locked(struct uart_port *uport)
{
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_STALE_INT);
msm_hs_write(uport, UARTDM_DMRX_ADDR, UARTDM_RX_BUF_SIZE);
msm_hs_write(uport, UARTDM_CR_ADDR, STALE_EVENT_ENABLE);
msm_uport->imr_reg |= UARTDM_ISR_RXLEV_BMSK;
msm_hs_write(uport, UARTDM_IMR_ADDR, msm_uport->imr_reg);
msm_uport->rx.flush = FLUSH_NONE;
msm_dmov_enqueue_cmd(msm_uport->dma_rx_channel, &msm_uport->rx.xfer);
/* might have finished RX and be ready to clock off */
hrtimer_start(&msm_uport->clk_off_timer, msm_uport->clk_off_delay,
HRTIMER_MODE_REL);
}
/* Enable the transmitter Interrupt */
static void msm_hs_start_tx_locked(struct uart_port *uport )
{
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
clk_enable(msm_uport->clk);
if (msm_uport->exit_lpm_cb)
msm_uport->exit_lpm_cb(uport);
if (msm_uport->tx.tx_ready_int_en == 0) {
msm_uport->tx.tx_ready_int_en = 1;
msm_hs_submit_tx_locked(uport);
}
clk_disable(msm_uport->clk);
}
/*
* This routine is called when we are done with a DMA transfer
*
* This routine is registered with Data mover when we set
* up a Data Mover transfer. It is called from Data mover ISR
* when the DMA transfer is done.
*/
static void msm_hs_dmov_tx_callback(struct msm_dmov_cmd *cmd_ptr,
unsigned int result,
struct msm_dmov_errdata *err)
{
unsigned long flags;
struct msm_hs_port *msm_uport;
WARN_ON(result != 0x80000002); /* DMA did not finish properly */
msm_uport = container_of(cmd_ptr, struct msm_hs_port, tx.xfer);
spin_lock_irqsave(&msm_uport->uport.lock, flags);
clk_enable(msm_uport->clk);
msm_uport->imr_reg |= UARTDM_ISR_TX_READY_BMSK;
msm_hs_write(&msm_uport->uport, UARTDM_IMR_ADDR, msm_uport->imr_reg);
clk_disable(msm_uport->clk);
spin_unlock_irqrestore(&msm_uport->uport.lock, flags);
}
/*
* This routine is called when we are done with a DMA transfer or the
* a flush has been sent to the data mover driver.
*
* This routine is registered with Data mover when we set up a Data Mover
* transfer. It is called from Data mover ISR when the DMA transfer is done.
*/
static void msm_hs_dmov_rx_callback(struct msm_dmov_cmd *cmd_ptr,
unsigned int result,
struct msm_dmov_errdata *err)
{
int retval;
int rx_count;
unsigned long status;
unsigned int error_f = 0;
unsigned long flags;
unsigned int flush;
struct tty_struct *tty;
struct uart_port *uport;
struct msm_hs_port *msm_uport;
msm_uport = container_of(cmd_ptr, struct msm_hs_port, rx.xfer);
uport = &msm_uport->uport;
spin_lock_irqsave(&uport->lock, flags);
clk_enable(msm_uport->clk);
tty = uport->state->port.tty;
msm_hs_write(uport, UARTDM_CR_ADDR, STALE_EVENT_DISABLE);
status = msm_hs_read(uport, UARTDM_SR_ADDR);
/* overflow is not connect to data in a FIFO */
if (unlikely((status & UARTDM_SR_OVERRUN_BMSK) &&
(uport->read_status_mask & CREAD))) {
tty_insert_flip_char(tty, 0, TTY_OVERRUN);
uport->icount.buf_overrun++;
error_f = 1;
}
if (!(uport->ignore_status_mask & INPCK))
status = status & ~(UARTDM_SR_PAR_FRAME_BMSK);
if (unlikely(status & UARTDM_SR_PAR_FRAME_BMSK)) {
/* Can not tell difference between parity & frame error */
uport->icount.parity++;
error_f = 1;
if (uport->ignore_status_mask & IGNPAR)
tty_insert_flip_char(tty, 0, TTY_PARITY);
}
if (error_f)
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_ERROR_STATUS);
if (msm_uport->clk_req_off_state == CLK_REQ_OFF_FLUSH_ISSUED)
msm_uport->clk_req_off_state = CLK_REQ_OFF_RXSTALE_FLUSHED;
flush = msm_uport->rx.flush;
if (flush == FLUSH_IGNORE)
msm_hs_start_rx_locked(uport);
if (flush == FLUSH_STOP)
msm_uport->rx.flush = FLUSH_SHUTDOWN;
if (flush >= FLUSH_DATA_INVALID)
goto out;
rx_count = msm_hs_read(uport, UARTDM_RX_TOTAL_SNAP_ADDR);
if (0 != (uport->read_status_mask & CREAD)) {
retval = tty_insert_flip_string(tty, msm_uport->rx.buffer,
rx_count);
BUG_ON(retval != rx_count);
}
msm_hs_start_rx_locked(uport);
out:
clk_disable(msm_uport->clk);
/* release wakelock in 500ms, not immediately, because higher layers
* don't always take wakelocks when they should */
wake_lock_timeout(&msm_uport->rx.wake_lock, HZ / 2);
spin_unlock_irqrestore(&uport->lock, flags);
if (flush < FLUSH_DATA_INVALID)
queue_work(msm_hs_workqueue, &msm_uport->rx.tty_work);
}
static void msm_hs_tty_flip_buffer_work(struct work_struct *work)
{
struct msm_hs_port *msm_uport =
container_of(work, struct msm_hs_port, rx.tty_work);
struct tty_struct *tty = msm_uport->uport.state->port.tty;
tty_flip_buffer_push(tty);
}
/*
* Standard API, Current states of modem control inputs
*
* Since CTS can be handled entirely by HARDWARE we always
* indicate clear to send and count on the TX FIFO to block when
* it fills up.
*
* - TIOCM_DCD
* - TIOCM_CTS
* - TIOCM_DSR
* - TIOCM_RI
* (Unsupported) DCD and DSR will return them high. RI will return low.
*/
static unsigned int msm_hs_get_mctrl_locked(struct uart_port *uport)
{
return TIOCM_DSR | TIOCM_CAR | TIOCM_CTS;
}
/*
* True enables UART auto RFR, which indicates we are ready for data if the RX
* buffer is not full. False disables auto RFR, and deasserts RFR to indicate
* we are not ready for data. Must be called with UART clock on.
*/
static void set_rfr_locked(struct uart_port *uport, int auto_rfr) {
unsigned int data;
data = msm_hs_read(uport, UARTDM_MR1_ADDR);
if (auto_rfr) {
/* enable auto ready-for-receiving */
data |= UARTDM_MR1_RX_RDY_CTL_BMSK;
msm_hs_write(uport, UARTDM_MR1_ADDR, data);
} else {
/* disable auto ready-for-receiving */
data &= ~UARTDM_MR1_RX_RDY_CTL_BMSK;
msm_hs_write(uport, UARTDM_MR1_ADDR, data);
/* RFR is active low, set high */
msm_hs_write(uport, UARTDM_CR_ADDR, RFR_HIGH);
}
}
/*
* Standard API, used to set or clear RFR
*/
static void msm_hs_set_mctrl_locked(struct uart_port *uport,
unsigned int mctrl)
{
unsigned int auto_rfr;
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
clk_enable(msm_uport->clk);
auto_rfr = TIOCM_RTS & mctrl ? 1 : 0;
set_rfr_locked(uport, auto_rfr);
clk_disable(msm_uport->clk);
}
/* Standard API, Enable modem status (CTS) interrupt */
static void msm_hs_enable_ms_locked(struct uart_port *uport)
{
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
clk_enable(msm_uport->clk);
/* Enable DELTA_CTS Interrupt */
msm_uport->imr_reg |= UARTDM_ISR_DELTA_CTS_BMSK;
msm_hs_write(uport, UARTDM_IMR_ADDR, msm_uport->imr_reg);
clk_disable(msm_uport->clk);
}
/*
* Standard API, Break Signal
*
* Control the transmission of a break signal. ctl eq 0 => break
* signal terminate ctl ne 0 => start break signal
*/
static void msm_hs_break_ctl(struct uart_port *uport, int ctl)
{
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
clk_enable(msm_uport->clk);
msm_hs_write(uport, UARTDM_CR_ADDR, ctl ? START_BREAK : STOP_BREAK);
clk_disable(msm_uport->clk);
}
static void msm_hs_config_port(struct uart_port *uport, int cfg_flags)
{
unsigned long flags;
spin_lock_irqsave(&uport->lock, flags);
if (cfg_flags & UART_CONFIG_TYPE) {
uport->type = PORT_MSM;
msm_hs_request_port(uport);
}
spin_unlock_irqrestore(&uport->lock, flags);
}
/* Handle CTS changes (Called from interrupt handler) */
static void msm_hs_handle_delta_cts(struct uart_port *uport)
{
unsigned long flags;
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
spin_lock_irqsave(&uport->lock, flags);
clk_enable(msm_uport->clk);
/* clear interrupt */
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_CTS);
uport->icount.cts++;
clk_disable(msm_uport->clk);
spin_unlock_irqrestore(&uport->lock, flags);
/* clear the IOCTL TIOCMIWAIT if called */
wake_up_interruptible(&uport->state->port.delta_msr_wait);
}
/* check if the TX path is flushed, and if so clock off
* returns 0 did not clock off, need to retry (still sending final byte)
* -1 did not clock off, do not retry
* 1 if we clocked off
*/
static int msm_hs_check_clock_off_locked(struct uart_port *uport)
{
unsigned long sr_status;
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
struct circ_buf *tx_buf = &uport->state->xmit;
/* Cancel if tx tty buffer is not empty, dma is in flight,
* or tx fifo is not empty, or rx fifo is not empty */
if (msm_uport->clk_state != MSM_HS_CLK_REQUEST_OFF ||
!uart_circ_empty(tx_buf) || msm_uport->tx.dma_in_flight ||
(msm_uport->imr_reg & UARTDM_ISR_TXLEV_BMSK) ||
!(msm_uport->imr_reg & UARTDM_ISR_RXLEV_BMSK)) {
return -1;
}
/* Make sure the uart is finished with the last byte */
sr_status = msm_hs_read(uport, UARTDM_SR_ADDR);
if (!(sr_status & UARTDM_SR_TXEMT_BMSK))
return 0; /* retry */
/* Make sure forced RXSTALE flush complete */
switch (msm_uport->clk_req_off_state) {
case CLK_REQ_OFF_START:
msm_uport->clk_req_off_state = CLK_REQ_OFF_RXSTALE_ISSUED;
msm_hs_write(uport, UARTDM_CR_ADDR, FORCE_STALE_EVENT);
return 0; /* RXSTALE flush not complete - retry */
case CLK_REQ_OFF_RXSTALE_ISSUED:
case CLK_REQ_OFF_FLUSH_ISSUED:
return 0; /* RXSTALE flush not complete - retry */
case CLK_REQ_OFF_RXSTALE_FLUSHED:
break; /* continue */
}
if (msm_uport->rx.flush != FLUSH_SHUTDOWN) {
if (msm_uport->rx.flush == FLUSH_NONE)
msm_hs_stop_rx_locked(uport);
return 0; /* come back later to really clock off */
}
/* we really want to clock off */
clk_disable(msm_uport->clk);
msm_uport->clk_state = MSM_HS_CLK_OFF;
wake_unlock(&msm_uport->dma_wake_lock);
if (use_low_power_rx_wakeup(msm_uport)) {
msm_uport->rx_wakeup.ignore = 1;
enable_irq(msm_uport->rx_wakeup.irq);
}
return 1;
}
static enum hrtimer_restart msm_hs_clk_off_retry(struct hrtimer *timer) {
unsigned long flags;
int ret = HRTIMER_NORESTART;
struct msm_hs_port *msm_uport = container_of(timer, struct msm_hs_port,
clk_off_timer);
struct uart_port *uport = &msm_uport->uport;
spin_lock_irqsave(&uport->lock, flags);
if (!msm_hs_check_clock_off_locked(uport)) {
hrtimer_forward_now(timer, msm_uport->clk_off_delay);
ret = HRTIMER_RESTART;
}
spin_unlock_irqrestore(&uport->lock, flags);
return ret;
}
static irqreturn_t msm_hs_isr(int irq, void *dev)
{
unsigned long flags;
unsigned long isr_status;
struct msm_hs_port *msm_uport = (struct msm_hs_port *)dev;
struct uart_port *uport = &msm_uport->uport;
struct circ_buf *tx_buf = &uport->state->xmit;
struct msm_hs_tx *tx = &msm_uport->tx;
struct msm_hs_rx *rx = &msm_uport->rx;
spin_lock_irqsave(&uport->lock, flags);
isr_status = msm_hs_read(uport, UARTDM_MISR_ADDR);
/* Uart RX starting */
if (isr_status & UARTDM_ISR_RXLEV_BMSK) {
wake_lock(&rx->wake_lock); /* hold wakelock while rx dma */
msm_uport->imr_reg &= ~UARTDM_ISR_RXLEV_BMSK;
msm_hs_write(uport, UARTDM_IMR_ADDR, msm_uport->imr_reg);
}
/* Stale rx interrupt */
if (isr_status & UARTDM_ISR_RXSTALE_BMSK) {
msm_hs_write(uport, UARTDM_CR_ADDR, STALE_EVENT_DISABLE);
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_STALE_INT);
if (msm_uport->clk_req_off_state == CLK_REQ_OFF_RXSTALE_ISSUED)
msm_uport->clk_req_off_state =
CLK_REQ_OFF_FLUSH_ISSUED;
if (rx->flush == FLUSH_NONE) {
rx->flush = FLUSH_DATA_READY;
msm_dmov_flush(msm_uport->dma_rx_channel);
}
}
/* tx ready interrupt */
if (isr_status & UARTDM_ISR_TX_READY_BMSK) {
/* Clear TX Ready */
msm_hs_write(uport, UARTDM_CR_ADDR, CLEAR_TX_READY);
if (msm_uport->clk_state == MSM_HS_CLK_REQUEST_OFF) {
msm_uport->imr_reg |= UARTDM_ISR_TXLEV_BMSK;
msm_hs_write(uport, UARTDM_IMR_ADDR,
msm_uport->imr_reg);
}
/* Complete DMA TX transactions and submit new transactions */
tx_buf->tail = (tx_buf->tail + tx->tx_count) & ~UART_XMIT_SIZE;
tx->dma_in_flight = 0;
uport->icount.tx += tx->tx_count;
if (tx->tx_ready_int_en)
msm_hs_submit_tx_locked(uport);
if (uart_circ_chars_pending(tx_buf) < WAKEUP_CHARS)
uart_write_wakeup(uport);
}
if (isr_status & UARTDM_ISR_TXLEV_BMSK) {
/* TX FIFO is empty */
msm_uport->imr_reg &= ~UARTDM_ISR_TXLEV_BMSK;
msm_hs_write(uport, UARTDM_IMR_ADDR, msm_uport->imr_reg);
if (!msm_hs_check_clock_off_locked(uport))
hrtimer_start(&msm_uport->clk_off_timer,
msm_uport->clk_off_delay,
HRTIMER_MODE_REL);
}
/* Change in CTS interrupt */
if (isr_status & UARTDM_ISR_DELTA_CTS_BMSK)
msm_hs_handle_delta_cts(uport);
spin_unlock_irqrestore(&uport->lock, flags);
return IRQ_HANDLED;
}
void msm_hs_request_clock_off_locked(struct uart_port *uport) {
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
if (msm_uport->clk_state == MSM_HS_CLK_ON) {
msm_uport->clk_state = MSM_HS_CLK_REQUEST_OFF;
msm_uport->clk_req_off_state = CLK_REQ_OFF_START;
if (!use_low_power_rx_wakeup(msm_uport))
set_rfr_locked(uport, 0);
msm_uport->imr_reg |= UARTDM_ISR_TXLEV_BMSK;
msm_hs_write(uport, UARTDM_IMR_ADDR, msm_uport->imr_reg);
}
}
EXPORT_SYMBOL(msm_hs_request_clock_off_locked);
/* request to turn off uart clock once pending TX is flushed */
void msm_hs_request_clock_off(struct uart_port *uport) {
unsigned long flags;
spin_lock_irqsave(&uport->lock, flags);
msm_hs_request_clock_off_locked(uport);
spin_unlock_irqrestore(&uport->lock, flags);
}
EXPORT_SYMBOL(msm_hs_request_clock_off);
void msm_hs_request_clock_on_locked(struct uart_port *uport) {
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
unsigned int data;
switch (msm_uport->clk_state) {
case MSM_HS_CLK_OFF:
wake_lock(&msm_uport->dma_wake_lock);
clk_enable(msm_uport->clk);
disable_irq_nosync(msm_uport->rx_wakeup.irq);
/* fall-through */
case MSM_HS_CLK_REQUEST_OFF:
if (msm_uport->rx.flush == FLUSH_STOP ||
msm_uport->rx.flush == FLUSH_SHUTDOWN) {
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_RX);
data = msm_hs_read(uport, UARTDM_DMEN_ADDR);
data |= UARTDM_RX_DM_EN_BMSK;
msm_hs_write(uport, UARTDM_DMEN_ADDR, data);
}
hrtimer_try_to_cancel(&msm_uport->clk_off_timer);
if (msm_uport->rx.flush == FLUSH_SHUTDOWN)
msm_hs_start_rx_locked(uport);
if (!use_low_power_rx_wakeup(msm_uport))
set_rfr_locked(uport, 1);
if (msm_uport->rx.flush == FLUSH_STOP)
msm_uport->rx.flush = FLUSH_IGNORE;
msm_uport->clk_state = MSM_HS_CLK_ON;
break;
case MSM_HS_CLK_ON: break;
case MSM_HS_CLK_PORT_OFF: break;
}
}
EXPORT_SYMBOL(msm_hs_request_clock_on_locked);
void msm_hs_request_clock_on(struct uart_port *uport) {
unsigned long flags;
spin_lock_irqsave(&uport->lock, flags);
msm_hs_request_clock_on_locked(uport);
spin_unlock_irqrestore(&uport->lock, flags);
}
EXPORT_SYMBOL(msm_hs_request_clock_on);
static irqreturn_t msm_hs_rx_wakeup_isr(int irq, void *dev)
{
unsigned int wakeup = 0;
unsigned long flags;
struct msm_hs_port *msm_uport = (struct msm_hs_port *)dev;
struct uart_port *uport = &msm_uport->uport;
struct tty_struct *tty = NULL;
spin_lock_irqsave(&uport->lock, flags);
if (msm_uport->clk_state == MSM_HS_CLK_OFF) {
/* ignore the first irq - it is a pending irq that occured
* before enable_irq() */
if (msm_uport->rx_wakeup.ignore)
msm_uport->rx_wakeup.ignore = 0;
else
wakeup = 1;
}
if (wakeup) {
/* the uart was clocked off during an rx, wake up and
* optionally inject char into tty rx */
msm_hs_request_clock_on_locked(uport);
if (msm_uport->rx_wakeup.inject_rx) {
tty = uport->state->port.tty;
tty_insert_flip_char(tty,
msm_uport->rx_wakeup.rx_to_inject,
TTY_NORMAL);
queue_work(msm_hs_workqueue, &msm_uport->rx.tty_work);
}
}
spin_unlock_irqrestore(&uport->lock, flags);
return IRQ_HANDLED;
}
static const char *msm_hs_type(struct uart_port *port)
{
return ("MSM HS UART");
}
/* Called when port is opened */
static int msm_hs_startup(struct uart_port *uport)
{
int ret;
int rfr_level;
unsigned long flags;
unsigned int data;
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
struct circ_buf *tx_buf = &uport->state->xmit;
struct msm_hs_tx *tx = &msm_uport->tx;
struct msm_hs_rx *rx = &msm_uport->rx;
rfr_level = uport->fifosize;
if (rfr_level > 16)
rfr_level -= 16;
tx->dma_base = dma_map_single(uport->dev, tx_buf->buf, UART_XMIT_SIZE,
DMA_TO_DEVICE);
/* do not let tty layer execute RX in global workqueue, use a
* dedicated workqueue managed by this driver */
uport->state->port.tty->low_latency = 1;
/* turn on uart clk */
ret = msm_hs_init_clk_locked(uport);
if (unlikely(ret))
return ret;
/* Set auto RFR Level */
data = msm_hs_read(uport, UARTDM_MR1_ADDR);
data &= ~UARTDM_MR1_AUTO_RFR_LEVEL1_BMSK;
data &= ~UARTDM_MR1_AUTO_RFR_LEVEL0_BMSK;
data |= (UARTDM_MR1_AUTO_RFR_LEVEL1_BMSK & (rfr_level << 2));
data |= (UARTDM_MR1_AUTO_RFR_LEVEL0_BMSK & rfr_level);
msm_hs_write(uport, UARTDM_MR1_ADDR, data);
/* Make sure RXSTALE count is non-zero */
data = msm_hs_read(uport, UARTDM_IPR_ADDR);
if (!data) {
data |= 0x1f & UARTDM_IPR_STALE_LSB_BMSK;
msm_hs_write(uport, UARTDM_IPR_ADDR, data);
}
/* Enable Data Mover Mode */
data = UARTDM_TX_DM_EN_BMSK | UARTDM_RX_DM_EN_BMSK;
msm_hs_write(uport, UARTDM_DMEN_ADDR, data);
/* Reset TX */
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_TX);
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_RX);
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_ERROR_STATUS);
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_BREAK_INT);
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_STALE_INT);
msm_hs_write(uport, UARTDM_CR_ADDR, RESET_CTS);
msm_hs_write(uport, UARTDM_CR_ADDR, RFR_LOW);
/* Turn on Uart Receiver */
msm_hs_write(uport, UARTDM_CR_ADDR, UARTDM_CR_RX_EN_BMSK);
/* Turn on Uart Transmitter */
msm_hs_write(uport, UARTDM_CR_ADDR, UARTDM_CR_TX_EN_BMSK);
/* Initialize the tx */
tx->tx_ready_int_en = 0;
tx->dma_in_flight = 0;
tx->xfer.complete_func = msm_hs_dmov_tx_callback;
tx->xfer.execute_func = NULL;
tx->command_ptr->cmd = CMD_LC |
CMD_DST_CRCI(msm_uport->dma_tx_crci) | CMD_MODE_BOX;
tx->command_ptr->src_dst_len = (MSM_UARTDM_BURST_SIZE << 16)
| (MSM_UARTDM_BURST_SIZE);
tx->command_ptr->row_offset = (MSM_UARTDM_BURST_SIZE << 16);
tx->command_ptr->dst_row_addr =
msm_uport->uport.mapbase + UARTDM_TF_ADDR;
/* Turn on Uart Receive */
rx->xfer.complete_func = msm_hs_dmov_rx_callback;
rx->xfer.execute_func = NULL;
rx->command_ptr->cmd = CMD_LC |
CMD_SRC_CRCI(msm_uport->dma_rx_crci) | CMD_MODE_BOX;
rx->command_ptr->src_dst_len = (MSM_UARTDM_BURST_SIZE << 16)
| (MSM_UARTDM_BURST_SIZE);
rx->command_ptr->row_offset = MSM_UARTDM_BURST_SIZE;
rx->command_ptr->src_row_addr = uport->mapbase + UARTDM_RF_ADDR;
msm_uport->imr_reg |= UARTDM_ISR_RXSTALE_BMSK;
/* Enable reading the current CTS, no harm even if CTS is ignored */
msm_uport->imr_reg |= UARTDM_ISR_CURRENT_CTS_BMSK;
msm_hs_write(uport, UARTDM_TFWR_ADDR, 0); /* TXLEV on empty TX fifo */
ret = request_irq(uport->irq, msm_hs_isr, IRQF_TRIGGER_HIGH,
"msm_hs_uart", msm_uport);
if (unlikely(ret))
return ret;
if (use_low_power_rx_wakeup(msm_uport)) {
ret = request_irq(msm_uport->rx_wakeup.irq,
msm_hs_rx_wakeup_isr,
IRQF_TRIGGER_FALLING,
"msm_hs_rx_wakeup", msm_uport);
if (unlikely(ret))
return ret;
disable_irq(msm_uport->rx_wakeup.irq);
}
spin_lock_irqsave(&uport->lock, flags);
msm_hs_write(uport, UARTDM_RFWR_ADDR, 0);
msm_hs_start_rx_locked(uport);
spin_unlock_irqrestore(&uport->lock, flags);
return 0;
}
/* Initialize tx and rx data structures */
static int uartdm_init_port(struct uart_port *uport)
{
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
struct msm_hs_tx *tx = &msm_uport->tx;
struct msm_hs_rx *rx = &msm_uport->rx;
/* Allocate the command pointer. Needs to be 64 bit aligned */
tx->command_ptr = kmalloc(sizeof(dmov_box), GFP_KERNEL | __GFP_DMA);
tx->command_ptr_ptr = kmalloc(sizeof(u32 *), GFP_KERNEL | __GFP_DMA);
if (!tx->command_ptr || !tx->command_ptr_ptr)
return -ENOMEM;
tx->mapped_cmd_ptr = dma_map_single(uport->dev, tx->command_ptr,
sizeof(dmov_box), DMA_TO_DEVICE);
tx->mapped_cmd_ptr_ptr = dma_map_single(uport->dev,
tx->command_ptr_ptr,
sizeof(u32 *), DMA_TO_DEVICE);
tx->xfer.cmdptr = DMOV_CMD_ADDR(tx->mapped_cmd_ptr_ptr);
init_waitqueue_head(&rx->wait);
wake_lock_init(&rx->wake_lock, WAKE_LOCK_SUSPEND, "msm_serial_hs_rx");
wake_lock_init(&msm_uport->dma_wake_lock, WAKE_LOCK_SUSPEND,
"msm_serial_hs_dma");
rx->pool = dma_pool_create("rx_buffer_pool", uport->dev,
UARTDM_RX_BUF_SIZE, 16, 0);
rx->buffer = dma_pool_alloc(rx->pool, GFP_KERNEL, &rx->rbuffer);
/* Allocate the command pointer. Needs to be 64 bit aligned */
rx->command_ptr = kmalloc(sizeof(dmov_box), GFP_KERNEL | __GFP_DMA);
rx->command_ptr_ptr = kmalloc(sizeof(u32 *), GFP_KERNEL | __GFP_DMA);
if (!rx->command_ptr || !rx->command_ptr_ptr || !rx->pool ||
!rx->buffer)
return -ENOMEM;
rx->command_ptr->num_rows = ((UARTDM_RX_BUF_SIZE >> 4) << 16) |
(UARTDM_RX_BUF_SIZE >> 4);
rx->command_ptr->dst_row_addr = rx->rbuffer;
rx->mapped_cmd_ptr = dma_map_single(uport->dev, rx->command_ptr,
sizeof(dmov_box), DMA_TO_DEVICE);
*rx->command_ptr_ptr = CMD_PTR_LP | DMOV_CMD_ADDR(rx->mapped_cmd_ptr);
rx->cmdptr_dmaaddr = dma_map_single(uport->dev, rx->command_ptr_ptr,
sizeof(u32 *), DMA_TO_DEVICE);
rx->xfer.cmdptr = DMOV_CMD_ADDR(rx->cmdptr_dmaaddr);
INIT_WORK(&rx->tty_work, msm_hs_tty_flip_buffer_work);
return 0;
}
static int msm_hs_probe(struct platform_device *pdev)
{
int ret;
struct uart_port *uport;
struct msm_hs_port *msm_uport;
struct resource *resource;
struct msm_serial_hs_platform_data *pdata = pdev->dev.platform_data;
if (pdev->id < 0 || pdev->id >= UARTDM_NR) {
printk(KERN_ERR "Invalid plaform device ID = %d\n", pdev->id);
return -EINVAL;
}
msm_uport = &q_uart_port[pdev->id];
uport = &msm_uport->uport;
uport->dev = &pdev->dev;
resource = platform_get_resource(pdev, IORESOURCE_MEM, 0);
if (unlikely(!resource))
return -ENXIO;
uport->mapbase = resource->start; /* virtual address */
uport->membase = ioremap(uport->mapbase, PAGE_SIZE);
if (unlikely(!uport->membase))
return -ENOMEM;
uport->irq = platform_get_irq(pdev, 0);
if (unlikely(uport->irq < 0))
return -ENXIO;
if (unlikely(set_irq_wake(uport->irq, 1)))
return -ENXIO;
if (pdata == NULL || pdata->rx_wakeup_irq < 0)
msm_uport->rx_wakeup.irq = -1;
else {
msm_uport->rx_wakeup.irq = pdata->rx_wakeup_irq;
msm_uport->rx_wakeup.ignore = 1;
msm_uport->rx_wakeup.inject_rx = pdata->inject_rx_on_wakeup;
msm_uport->rx_wakeup.rx_to_inject = pdata->rx_to_inject;
if (unlikely(msm_uport->rx_wakeup.irq < 0))
return -ENXIO;
if (unlikely(set_irq_wake(msm_uport->rx_wakeup.irq, 1)))
return -ENXIO;
}
if (pdata == NULL)
msm_uport->exit_lpm_cb = NULL;
else
msm_uport->exit_lpm_cb = pdata->exit_lpm_cb;
resource = platform_get_resource_byname(pdev, IORESOURCE_DMA,
"uartdm_channels");
if (unlikely(!resource))
return -ENXIO;
msm_uport->dma_tx_channel = resource->start;
msm_uport->dma_rx_channel = resource->end;
resource = platform_get_resource_byname(pdev, IORESOURCE_DMA,
"uartdm_crci");
if (unlikely(!resource))
return -ENXIO;
msm_uport->dma_tx_crci = resource->start;
msm_uport->dma_rx_crci = resource->end;
uport->iotype = UPIO_MEM;
uport->fifosize = 64;
uport->ops = &msm_hs_ops;
uport->flags = UPF_BOOT_AUTOCONF;
uport->uartclk = 7372800;
msm_uport->imr_reg = 0x0;
msm_uport->clk = clk_get(&pdev->dev, "uartdm_clk");
if (IS_ERR(msm_uport->clk))
return PTR_ERR(msm_uport->clk);
ret = uartdm_init_port(uport);
if (unlikely(ret))
return ret;
/* configure the CR Protection to Enable */
msm_hs_write(uport, UARTDM_CR_ADDR, CR_PROTECTION_EN);
msm_uport->clk_state = MSM_HS_CLK_PORT_OFF;
hrtimer_init(&msm_uport->clk_off_timer, CLOCK_MONOTONIC,
HRTIMER_MODE_REL);
msm_uport->clk_off_timer.function = msm_hs_clk_off_retry;
msm_uport->clk_off_delay = ktime_set(0, 1000000); /* 1ms */
uport->line = pdev->id;
return uart_add_one_port(&msm_hs_driver, uport);
}
static int __init msm_serial_hs_init(void)
{
int ret;
int i;
/* Init all UARTS as non-configured */
for (i = 0; i < UARTDM_NR; i++)
q_uart_port[i].uport.type = PORT_UNKNOWN;
msm_hs_workqueue = create_singlethread_workqueue("msm_serial_hs");
ret = uart_register_driver(&msm_hs_driver);
if (unlikely(ret)) {
printk(KERN_ERR "%s failed to load\n", __FUNCTION__);
return ret;
}
ret = platform_driver_register(&msm_serial_hs_platform_driver);
if (ret) {
printk(KERN_ERR "%s failed to load\n", __FUNCTION__);
uart_unregister_driver(&msm_hs_driver);
return ret;
}
printk(KERN_INFO "msm_serial_hs module loaded\n");
return ret;
}
/*
* Called by the upper layer when port is closed.
* - Disables the port
* - Unhook the ISR
*/
static void msm_hs_shutdown(struct uart_port *uport)
{
unsigned long flags;
struct msm_hs_port *msm_uport = UARTDM_TO_MSM(uport);
BUG_ON(msm_uport->rx.flush < FLUSH_STOP);
spin_lock_irqsave(&uport->lock, flags);
clk_enable(msm_uport->clk);
/* Disable the transmitter */
msm_hs_write(uport, UARTDM_CR_ADDR, UARTDM_CR_TX_DISABLE_BMSK);
/* Disable the receiver */
msm_hs_write(uport, UARTDM_CR_ADDR, UARTDM_CR_RX_DISABLE_BMSK);
/* Free the interrupt */
free_irq(uport->irq, msm_uport);
if (use_low_power_rx_wakeup(msm_uport))
free_irq(msm_uport->rx_wakeup.irq, msm_uport);
msm_uport->imr_reg = 0;
msm_hs_write(uport, UARTDM_IMR_ADDR, msm_uport->imr_reg);
wait_event(msm_uport->rx.wait, msm_uport->rx.flush == FLUSH_SHUTDOWN);
clk_disable(msm_uport->clk); /* to balance local clk_enable() */
if (msm_uport->clk_state != MSM_HS_CLK_OFF) {
wake_unlock(&msm_uport->dma_wake_lock);
clk_disable(msm_uport->clk); /* to balance clk_state */
}
msm_uport->clk_state = MSM_HS_CLK_PORT_OFF;
dma_unmap_single(uport->dev, msm_uport->tx.dma_base,
UART_XMIT_SIZE, DMA_TO_DEVICE);
spin_unlock_irqrestore(&uport->lock, flags);
if (cancel_work_sync(&msm_uport->rx.tty_work))
msm_hs_tty_flip_buffer_work(&msm_uport->rx.tty_work);
}
static void __exit msm_serial_hs_exit(void)
{
printk(KERN_INFO "msm_serial_hs module removed\n");
platform_driver_unregister(&msm_serial_hs_platform_driver);
uart_unregister_driver(&msm_hs_driver);
destroy_workqueue(msm_hs_workqueue);
}
static struct platform_driver msm_serial_hs_platform_driver = {
.probe = msm_hs_probe,
.remove = msm_hs_remove,
.driver = {
.name = "msm_serial_hs",
},
};
static struct uart_driver msm_hs_driver = {
.owner = THIS_MODULE,
.driver_name = "msm_serial_hs",
.dev_name = "ttyHS",
.nr = UARTDM_NR,
.cons = 0,
};
static struct uart_ops msm_hs_ops = {
.tx_empty = msm_hs_tx_empty,
.set_mctrl = msm_hs_set_mctrl_locked,
.get_mctrl = msm_hs_get_mctrl_locked,
.stop_tx = msm_hs_stop_tx_locked,
.start_tx = msm_hs_start_tx_locked,
.stop_rx = msm_hs_stop_rx_locked,
.enable_ms = msm_hs_enable_ms_locked,
.break_ctl = msm_hs_break_ctl,
.startup = msm_hs_startup,
.shutdown = msm_hs_shutdown,
.set_termios = msm_hs_set_termios,
.pm = msm_hs_pm,
.type = msm_hs_type,
.config_port = msm_hs_config_port,
.release_port = msm_hs_release_port,
.request_port = msm_hs_request_port,
};
module_init(msm_serial_hs_init);
module_exit(msm_serial_hs_exit);
MODULE_DESCRIPTION("High Speed UART Driver for the MSM chipset");
MODULE_VERSION("1.2");
MODULE_LICENSE("GPL v2");