Merge branch 'master' into for_paulus

[linux-drm-fsl-dcu.git] / drivers / input / touchscreen / ucb1400_ts.c

/*
 *  Philips UCB1400 touchscreen driver
 *
 *  Author:     Nicolas Pitre
 *  Created:    September 25, 2006
 *  Copyright:  MontaVista Software, Inc.
 *
 * 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 code is heavily based on ucb1x00-*.c copyrighted by Russell King
 * covering the UCB1100, UCB1200 and UCB1300..  Support for the UCB1400 has
 * been made separate from ucb1x00-core/ucb1x00-ts on Russell's request.
 */

#include <linux/module.h>
#include <linux/moduleparam.h>
#include <linux/init.h>
#include <linux/completion.h>
#include <linux/delay.h>
#include <linux/input.h>
#include <linux/device.h>
#include <linux/interrupt.h>
#include <linux/suspend.h>
#include <linux/slab.h>
#include <linux/kthread.h>
#include <linux/freezer.h>

#include <sound/driver.h>
#include <sound/core.h>
#include <sound/ac97_codec.h>


/*
 * Interesting UCB1400 AC-link registers
 */

#define UCB_IE_RIS              0x5e
#define UCB_IE_FAL              0x60
#define UCB_IE_STATUS           0x62
#define UCB_IE_CLEAR            0x62
#define UCB_IE_ADC              (1 << 11)
#define UCB_IE_TSPX             (1 << 12)

#define UCB_TS_CR               0x64
#define UCB_TS_CR_TSMX_POW      (1 << 0)
#define UCB_TS_CR_TSPX_POW      (1 << 1)
#define UCB_TS_CR_TSMY_POW      (1 << 2)
#define UCB_TS_CR_TSPY_POW      (1 << 3)
#define UCB_TS_CR_TSMX_GND      (1 << 4)
#define UCB_TS_CR_TSPX_GND      (1 << 5)
#define UCB_TS_CR_TSMY_GND      (1 << 6)
#define UCB_TS_CR_TSPY_GND      (1 << 7)
#define UCB_TS_CR_MODE_INT      (0 << 8)
#define UCB_TS_CR_MODE_PRES     (1 << 8)
#define UCB_TS_CR_MODE_POS      (2 << 8)
#define UCB_TS_CR_BIAS_ENA      (1 << 11)
#define UCB_TS_CR_TSPX_LOW      (1 << 12)
#define UCB_TS_CR_TSMX_LOW      (1 << 13)

#define UCB_ADC_CR              0x66
#define UCB_ADC_SYNC_ENA        (1 << 0)
#define UCB_ADC_VREFBYP_CON     (1 << 1)
#define UCB_ADC_INP_TSPX        (0 << 2)
#define UCB_ADC_INP_TSMX        (1 << 2)
#define UCB_ADC_INP_TSPY        (2 << 2)
#define UCB_ADC_INP_TSMY        (3 << 2)
#define UCB_ADC_INP_AD0         (4 << 2)
#define UCB_ADC_INP_AD1         (5 << 2)
#define UCB_ADC_INP_AD2         (6 << 2)
#define UCB_ADC_INP_AD3         (7 << 2)
#define UCB_ADC_EXT_REF         (1 << 5)
#define UCB_ADC_START           (1 << 7)
#define UCB_ADC_ENA             (1 << 15)

#define UCB_ADC_DATA            0x68
#define UCB_ADC_DAT_VALID       (1 << 15)
#define UCB_ADC_DAT_VALUE(x)    ((x) & 0x3ff)

#define UCB_ID                  0x7e
#define UCB_ID_1400             0x4304


struct ucb1400 {
        struct snd_ac97         *ac97;
        struct input_dev        *ts_idev;

        int                     irq;

        wait_queue_head_t       ts_wait;
        struct task_struct      *ts_task;

        unsigned int            irq_pending;    /* not bit field shared */
        unsigned int            ts_restart:1;
        unsigned int            adcsync:1;
};

static int adcsync;

static inline u16 ucb1400_reg_read(struct ucb1400 *ucb, u16 reg)
{
        return ucb->ac97->bus->ops->read(ucb->ac97, reg);
}

static inline void ucb1400_reg_write(struct ucb1400 *ucb, u16 reg, u16 val)
{
        ucb->ac97->bus->ops->write(ucb->ac97, reg, val);
}

static inline void ucb1400_adc_enable(struct ucb1400 *ucb)
{
        ucb1400_reg_write(ucb, UCB_ADC_CR, UCB_ADC_ENA);
}

static unsigned int ucb1400_adc_read(struct ucb1400 *ucb, u16 adc_channel)
{
        unsigned int val;

        if (ucb->adcsync)
                adc_channel |= UCB_ADC_SYNC_ENA;

        ucb1400_reg_write(ucb, UCB_ADC_CR, UCB_ADC_ENA | adc_channel);
        ucb1400_reg_write(ucb, UCB_ADC_CR, UCB_ADC_ENA | adc_channel | UCB_ADC_START);

        for (;;) {
                val = ucb1400_reg_read(ucb, UCB_ADC_DATA);
                if (val & UCB_ADC_DAT_VALID)
                        break;
                /* yield to other processes */
                set_current_state(TASK_INTERRUPTIBLE);
                schedule_timeout(1);
        }

        return UCB_ADC_DAT_VALUE(val);
}

static inline void ucb1400_adc_disable(struct ucb1400 *ucb)
{
        ucb1400_reg_write(ucb, UCB_ADC_CR, 0);
}

/* Switch to interrupt mode. */
static inline void ucb1400_ts_mode_int(struct ucb1400 *ucb)
{
        ucb1400_reg_write(ucb, UCB_TS_CR,
                        UCB_TS_CR_TSMX_POW | UCB_TS_CR_TSPX_POW |
                        UCB_TS_CR_TSMY_GND | UCB_TS_CR_TSPY_GND |
                        UCB_TS_CR_MODE_INT);
}

/*
 * Switch to pressure mode, and read pressure.  We don't need to wait
 * here, since both plates are being driven.
 */
static inline unsigned int ucb1400_ts_read_pressure(struct ucb1400 *ucb)
{
        ucb1400_reg_write(ucb, UCB_TS_CR,
                        UCB_TS_CR_TSMX_POW | UCB_TS_CR_TSPX_POW |
                        UCB_TS_CR_TSMY_GND | UCB_TS_CR_TSPY_GND |
                        UCB_TS_CR_MODE_PRES | UCB_TS_CR_BIAS_ENA);
        return ucb1400_adc_read(ucb, UCB_ADC_INP_TSPY);
}

/*
 * Switch to X position mode and measure Y plate.  We switch the plate
 * configuration in pressure mode, then switch to position mode.  This
 * gives a faster response time.  Even so, we need to wait about 55us
 * for things to stabilise.
 */
static inline unsigned int ucb1400_ts_read_xpos(struct ucb1400 *ucb)
{
        ucb1400_reg_write(ucb, UCB_TS_CR,
                        UCB_TS_CR_TSMX_GND | UCB_TS_CR_TSPX_POW |
                        UCB_TS_CR_MODE_PRES | UCB_TS_CR_BIAS_ENA);
        ucb1400_reg_write(ucb, UCB_TS_CR,
                        UCB_TS_CR_TSMX_GND | UCB_TS_CR_TSPX_POW |
                        UCB_TS_CR_MODE_PRES | UCB_TS_CR_BIAS_ENA);
        ucb1400_reg_write(ucb, UCB_TS_CR,
                        UCB_TS_CR_TSMX_GND | UCB_TS_CR_TSPX_POW |
                        UCB_TS_CR_MODE_POS | UCB_TS_CR_BIAS_ENA);

        udelay(55);

        return ucb1400_adc_read(ucb, UCB_ADC_INP_TSPY);
}

/*
 * Switch to Y position mode and measure X plate.  We switch the plate
 * configuration in pressure mode, then switch to position mode.  This
 * gives a faster response time.  Even so, we need to wait about 55us
 * for things to stabilise.
 */
static inline unsigned int ucb1400_ts_read_ypos(struct ucb1400 *ucb)
{
        ucb1400_reg_write(ucb, UCB_TS_CR,
                        UCB_TS_CR_TSMY_GND | UCB_TS_CR_TSPY_POW |
                        UCB_TS_CR_MODE_PRES | UCB_TS_CR_BIAS_ENA);
        ucb1400_reg_write(ucb, UCB_TS_CR,
                        UCB_TS_CR_TSMY_GND | UCB_TS_CR_TSPY_POW |
                        UCB_TS_CR_MODE_PRES | UCB_TS_CR_BIAS_ENA);
        ucb1400_reg_write(ucb, UCB_TS_CR,
                        UCB_TS_CR_TSMY_GND | UCB_TS_CR_TSPY_POW |
                        UCB_TS_CR_MODE_POS | UCB_TS_CR_BIAS_ENA);

        udelay(55);

        return ucb1400_adc_read(ucb, UCB_ADC_INP_TSPX);
}

/*
 * Switch to X plate resistance mode.  Set MX to ground, PX to
 * supply.  Measure current.
 */
static inline unsigned int ucb1400_ts_read_xres(struct ucb1400 *ucb)
{
        ucb1400_reg_write(ucb, UCB_TS_CR,
                        UCB_TS_CR_TSMX_GND | UCB_TS_CR_TSPX_POW |
                        UCB_TS_CR_MODE_PRES | UCB_TS_CR_BIAS_ENA);
        return ucb1400_adc_read(ucb, 0);
}

/*
 * Switch to Y plate resistance mode.  Set MY to ground, PY to
 * supply.  Measure current.
 */
static inline unsigned int ucb1400_ts_read_yres(struct ucb1400 *ucb)
{
        ucb1400_reg_write(ucb, UCB_TS_CR,
                        UCB_TS_CR_TSMY_GND | UCB_TS_CR_TSPY_POW |
                        UCB_TS_CR_MODE_PRES | UCB_TS_CR_BIAS_ENA);
        return ucb1400_adc_read(ucb, 0);
}

static inline int ucb1400_ts_pen_down(struct ucb1400 *ucb)
{
        unsigned short val = ucb1400_reg_read(ucb, UCB_TS_CR);
        return (val & (UCB_TS_CR_TSPX_LOW | UCB_TS_CR_TSMX_LOW));
}

static inline void ucb1400_ts_irq_enable(struct ucb1400 *ucb)
{
        ucb1400_reg_write(ucb, UCB_IE_CLEAR, UCB_IE_TSPX);
        ucb1400_reg_write(ucb, UCB_IE_CLEAR, 0);
        ucb1400_reg_write(ucb, UCB_IE_FAL, UCB_IE_TSPX);
}

static inline void ucb1400_ts_irq_disable(struct ucb1400 *ucb)
{
        ucb1400_reg_write(ucb, UCB_IE_FAL, 0);
}

static void ucb1400_ts_evt_add(struct input_dev *idev, u16 pressure, u16 x, u16 y)
{
        input_report_abs(idev, ABS_X, x);
        input_report_abs(idev, ABS_Y, y);
        input_report_abs(idev, ABS_PRESSURE, pressure);
        input_sync(idev);
}

static void ucb1400_ts_event_release(struct input_dev *idev)
{
        input_report_abs(idev, ABS_PRESSURE, 0);
        input_sync(idev);
}

static void ucb1400_handle_pending_irq(struct ucb1400 *ucb)
{
        unsigned int isr;

        isr = ucb1400_reg_read(ucb, UCB_IE_STATUS);
        ucb1400_reg_write(ucb, UCB_IE_CLEAR, isr);
        ucb1400_reg_write(ucb, UCB_IE_CLEAR, 0);

        if (isr & UCB_IE_TSPX)
                ucb1400_ts_irq_disable(ucb);
        else
                printk(KERN_ERR "ucb1400: unexpected IE_STATUS = %#x\n", isr);

        enable_irq(ucb->irq);
}

static int ucb1400_ts_thread(void *_ucb)
{
        struct ucb1400 *ucb = _ucb;
        struct task_struct *tsk = current;
        int valid = 0;

        tsk->policy = SCHED_FIFO;
        tsk->rt_priority = 1;

        while (!kthread_should_stop()) {
                unsigned int x, y, p;
                long timeout;

                ucb->ts_restart = 0;

                if (ucb->irq_pending) {
                        ucb->irq_pending = 0;
                        ucb1400_handle_pending_irq(ucb);
                }

                ucb1400_adc_enable(ucb);
                x = ucb1400_ts_read_xpos(ucb);
                y = ucb1400_ts_read_ypos(ucb);
                p = ucb1400_ts_read_pressure(ucb);
                ucb1400_adc_disable(ucb);

                /* Switch back to interrupt mode. */
                ucb1400_ts_mode_int(ucb);

                msleep(10);

                if (ucb1400_ts_pen_down(ucb)) {
                        ucb1400_ts_irq_enable(ucb);

                        /*
                         * If we spat out a valid sample set last time,
                         * spit out a "pen off" sample here.
                         */
                        if (valid) {
                                ucb1400_ts_event_release(ucb->ts_idev);
                                valid = 0;
                        }

                        timeout = MAX_SCHEDULE_TIMEOUT;
                } else {
                        valid = 1;
                        ucb1400_ts_evt_add(ucb->ts_idev, p, x, y);
                        timeout = msecs_to_jiffies(10);
                }

                wait_event_interruptible_timeout(ucb->ts_wait,
                        ucb->irq_pending || ucb->ts_restart || kthread_should_stop(),
                        timeout);
                try_to_freeze();
        }

        /* Send the "pen off" if we are stopping with the pen still active */
        if (valid)
                ucb1400_ts_event_release(ucb->ts_idev);

        ucb->ts_task = NULL;
        return 0;
}

/*
 * A restriction with interrupts exists when using the ucb1400, as
 * the codec read/write routines may sleep while waiting for codec
 * access completion and uses semaphores for access control to the
 * AC97 bus.  A complete codec read cycle could take  anywhere from
 * 60 to 100uSec so we *definitely* don't want to spin inside the
 * interrupt handler waiting for codec access.  So, we handle the
 * interrupt by scheduling a RT kernel thread to run in process
 * context instead of interrupt context.
 */
static irqreturn_t ucb1400_hard_irq(int irqnr, void *devid)
{
        struct ucb1400 *ucb = devid;

        if (irqnr == ucb->irq) {
                disable_irq(ucb->irq);
                ucb->irq_pending = 1;
                wake_up(&ucb->ts_wait);
                return IRQ_HANDLED;
        }
        return IRQ_NONE;
}

static int ucb1400_ts_open(struct input_dev *idev)
{
        struct ucb1400 *ucb = idev->private;
        int ret = 0;

        BUG_ON(ucb->ts_task);

        ucb->ts_task = kthread_run(ucb1400_ts_thread, ucb, "UCB1400_ts");
        if (IS_ERR(ucb->ts_task)) {
                ret = PTR_ERR(ucb->ts_task);
                ucb->ts_task = NULL;
        }

        return ret;
}

static void ucb1400_ts_close(struct input_dev *idev)
{
        struct ucb1400 *ucb = idev->private;

        if (ucb->ts_task)
                kthread_stop(ucb->ts_task);

        ucb1400_ts_irq_disable(ucb);
        ucb1400_reg_write(ucb, UCB_TS_CR, 0);
}

#ifdef CONFIG_PM
static int ucb1400_ts_resume(struct device *dev)
{
        struct ucb1400 *ucb = dev_get_drvdata(dev);

        if (ucb->ts_task) {
                /*
                 * Restart the TS thread to ensure the
                 * TS interrupt mode is set up again
                 * after sleep.
                 */
                ucb->ts_restart = 1;
                wake_up(&ucb->ts_wait);
        }
        return 0;
}
#else
#define ucb1400_ts_resume NULL
#endif

#ifndef NO_IRQ
#define NO_IRQ  0
#endif

/*
 * Try to probe our interrupt, rather than relying on lots of
 * hard-coded machine dependencies.
 */
static int ucb1400_detect_irq(struct ucb1400 *ucb)
{
        unsigned long mask, timeout;

        mask = probe_irq_on();
        if (!mask) {
                probe_irq_off(mask);
                return -EBUSY;
        }

        /* Enable the ADC interrupt. */
        ucb1400_reg_write(ucb, UCB_IE_RIS, UCB_IE_ADC);
        ucb1400_reg_write(ucb, UCB_IE_FAL, UCB_IE_ADC);
        ucb1400_reg_write(ucb, UCB_IE_CLEAR, 0xffff);
        ucb1400_reg_write(ucb, UCB_IE_CLEAR, 0);

        /* Cause an ADC interrupt. */
        ucb1400_reg_write(ucb, UCB_ADC_CR, UCB_ADC_ENA);
        ucb1400_reg_write(ucb, UCB_ADC_CR, UCB_ADC_ENA | UCB_ADC_START);

        /* Wait for the conversion to complete. */
        timeout = jiffies + HZ/2;
        while (!(ucb1400_reg_read(ucb, UCB_ADC_DATA) & UCB_ADC_DAT_VALID)) {
                cpu_relax();
                if (time_after(jiffies, timeout)) {
                        printk(KERN_ERR "ucb1400: timed out in IRQ probe\n");
                        probe_irq_off(mask);
                        return -ENODEV;
                }
        }
        ucb1400_reg_write(ucb, UCB_ADC_CR, 0);

        /* Disable and clear interrupt. */
        ucb1400_reg_write(ucb, UCB_IE_RIS, 0);
        ucb1400_reg_write(ucb, UCB_IE_FAL, 0);
        ucb1400_reg_write(ucb, UCB_IE_CLEAR, 0xffff);
        ucb1400_reg_write(ucb, UCB_IE_CLEAR, 0);

        /* Read triggered interrupt. */
        ucb->irq = probe_irq_off(mask);
        if (ucb->irq < 0 || ucb->irq == NO_IRQ)
                return -ENODEV;

        return 0;
}

static int ucb1400_ts_probe(struct device *dev)
{
        struct ucb1400 *ucb;
        struct input_dev *idev;
        int error, id, x_res, y_res;

        ucb = kzalloc(sizeof(struct ucb1400), GFP_KERNEL);
        idev = input_allocate_device();
        if (!ucb || !idev) {
                error = -ENOMEM;
                goto err_free_devs;
        }

        ucb->ts_idev = idev;
        ucb->adcsync = adcsync;
        ucb->ac97 = to_ac97_t(dev);
        init_waitqueue_head(&ucb->ts_wait);

        id = ucb1400_reg_read(ucb, UCB_ID);
        if (id != UCB_ID_1400) {
                error = -ENODEV;
                goto err_free_devs;
        }

        error = ucb1400_detect_irq(ucb);
        if (error) {
                printk(KERN_ERR "UCB1400: IRQ probe failed\n");
                goto err_free_devs;
        }

        error = request_irq(ucb->irq, ucb1400_hard_irq, IRQF_TRIGGER_RISING,
                                "UCB1400", ucb);
        if (error) {
                printk(KERN_ERR "ucb1400: unable to grab irq%d: %d\n",
                                ucb->irq, error);
                goto err_free_devs;
        }
        printk(KERN_DEBUG "UCB1400: found IRQ %d\n", ucb->irq);

        idev->private           = ucb;
        idev->cdev.dev          = dev;
        idev->name              = "UCB1400 touchscreen interface";
        idev->id.vendor         = ucb1400_reg_read(ucb, AC97_VENDOR_ID1);
        idev->id.product        = id;
        idev->open              = ucb1400_ts_open;
        idev->close             = ucb1400_ts_close;
        idev->evbit[0]          = BIT(EV_ABS);

        ucb1400_adc_enable(ucb);
        x_res = ucb1400_ts_read_xres(ucb);
        y_res = ucb1400_ts_read_yres(ucb);
        ucb1400_adc_disable(ucb);
        printk(KERN_DEBUG "UCB1400: x/y = %d/%d\n", x_res, y_res);

        input_set_abs_params(idev, ABS_X, 0, x_res, 0, 0);
        input_set_abs_params(idev, ABS_Y, 0, y_res, 0, 0);
        input_set_abs_params(idev, ABS_PRESSURE, 0, 0, 0, 0);

        error = input_register_device(idev);
        if (error)
                goto err_free_irq;

        dev_set_drvdata(dev, ucb);
        return 0;

 err_free_irq:
        free_irq(ucb->irq, ucb);
 err_free_devs:
        input_free_device(idev);
        kfree(ucb);
        return error;
}

static int ucb1400_ts_remove(struct device *dev)
{
        struct ucb1400 *ucb = dev_get_drvdata(dev);

        free_irq(ucb->irq, ucb);
        input_unregister_device(ucb->ts_idev);
        dev_set_drvdata(dev, NULL);
        kfree(ucb);
        return 0;
}

static struct device_driver ucb1400_ts_driver = {
        .owner          = THIS_MODULE,
        .bus            = &ac97_bus_type,
        .probe          = ucb1400_ts_probe,
        .remove         = ucb1400_ts_remove,
        .resume         = ucb1400_ts_resume,
};

static int __init ucb1400_ts_init(void)
{
        return driver_register(&ucb1400_ts_driver);
}

static void __exit ucb1400_ts_exit(void)
{
        driver_unregister(&ucb1400_ts_driver);
}

module_param(adcsync, int, 0444);

module_init(ucb1400_ts_init);
module_exit(ucb1400_ts_exit);

MODULE_DESCRIPTION("Philips UCB1400 touchscreen driver");
MODULE_LICENSE("GPL");