[firefly-linux-kernel-4.4.55.git] / drivers / input / sensors / angle / angle_kxtik.c

/* drivers/input/sensors/access/angle_kxtik.c
 *
 * Copyright (C) 2012-2015 ROCKCHIP.
 * Author: luowei <lw@rock-chips.com>
 *
 * This software is licensed under the terms of the GNU General Public
 * License version 2, as published by the Free Software Foundation, and
 * may be copied, distributed, and modified under those terms.
 *
 * 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.
 *
 */
#include <linux/interrupt.h>
#include <linux/i2c.h>
#include <linux/slab.h>
#include <linux/irq.h>
#include <linux/miscdevice.h>
#include <linux/gpio.h>
#include <asm/uaccess.h>
#include <asm/atomic.h>
#include <linux/delay.h>
#include <linux/input.h>
#include <linux/workqueue.h>
#include <linux/freezer.h>
#include <mach/gpio.h>
#include <mach/board.h> 
#ifdef CONFIG_HAS_EARLYSUSPEND
#include <linux/earlysuspend.h>
#endif
#include <linux/sensor-dev.h>

#define KXTIK_DEVID_1004                0x05     //chip id
#define KXTIK_DEVID_J9_1005             0x07     //chip id
#define KXTIK_DEVID_J2_1009             0x09     //chip id
#define KXTIK_DEVID_1013                0x11     //chip id
#define KXTIK_RANGE                     2000000

#define KXTIK_XOUT_HPF_L                (0x00)  /* 0000 0000 */
#define KXTIK_XOUT_HPF_H                (0x01)  /* 0000 0001 */
#define KXTIK_YOUT_HPF_L                (0x02)  /* 0000 0010 */
#define KXTIK_YOUT_HPF_H                (0x03)  /* 0000 0011 */
#define KXTIK_ZOUT_HPF_L                (0x04)  /* 0001 0100 */
#define KXTIK_ZOUT_HPF_H                (0x05)  /* 0001 0101 */
#define KXTIK_XOUT_L                    (0x06)  /* 0000 0110 */
#define KXTIK_XOUT_H                    (0x07)  /* 0000 0111 */
#define KXTIK_YOUT_L                    (0x08)  /* 0000 1000 */
#define KXTIK_YOUT_H                    (0x09)  /* 0000 1001 */
#define KXTIK_ZOUT_L                    (0x0A)  /* 0001 1010 */
#define KXTIK_ZOUT_H                    (0x0B)  /* 0001 1011 */
#define KXTIK_ST_RESP                   (0x0C)  /* 0000 1100 */
#define KXTIK_WHO_AM_I                  (0x0F)  /* 0000 1111 */
#define KXTIK_TILT_POS_CUR              (0x10)  /* 0001 0000 */
#define KXTIK_TILT_POS_PRE              (0x11)  /* 0001 0001 */
#define KXTIK_INT_SRC_REG1              (0x15)  /* 0001 0101 */
#define KXTIK_INT_SRC_REG2              (0x16)  /* 0001 0110 */
#define KXTIK_STATUS_REG                (0x18)  /* 0001 1000 */
#define KXTIK_INT_REL                   (0x1A)  /* 0001 1010 */
#define KXTIK_CTRL_REG1                 (0x1B)  /* 0001 1011 */
#define KXTIK_CTRL_REG2                 (0x1C)  /* 0001 1100 */
#define KXTIK_CTRL_REG3                 (0x1D)  /* 0001 1101 */
#define KXTIK_INT_CTRL_REG1             (0x1E)  /* 0001 1110 */
#define KXTIK_INT_CTRL_REG2             (0x1F)  /* 0001 1111 */
#define KXTIK_INT_CTRL_REG3             (0x20)  /* 0010 0000 */
#define KXTIK_DATA_CTRL_REG             (0x21)  /* 0010 0001 */
#define KXTIK_TILT_TIMER                (0x28)  /* 0010 1000 */
#define KXTIK_WUF_TIMER                 (0x29)  /* 0010 1001 */
#define KXTIK_TDT_TIMER                 (0x2B)  /* 0010 1011 */
#define KXTIK_TDT_H_THRESH              (0x2C)  /* 0010 1100 */
#define KXTIK_TDT_L_THRESH              (0x2D)  /* 0010 1101 */
#define KXTIK_TDT_TAP_TIMER             (0x2E)  /* 0010 1110 */
#define KXTIK_TDT_TOTAL_TIMER           (0x2F)  /* 0010 1111 */
#define KXTIK_TDT_LATENCY_TIMER         (0x30)  /* 0011 0000 */
#define KXTIK_TDT_WINDOW_TIMER          (0x31)  /* 0011 0001 */
#define KXTIK_WUF_THRESH                (0x5A)  /* 0101 1010 */
#define KXTIK_TILT_ANGLE                (0x5C)  /* 0101 1100 */
#define KXTIK_HYST_SET                  (0x5F)  /* 0101 1111 */

/* CONTROL REGISTER 1 BITS */
#define KXTIK_DISABLE                   0x7F
#define KXTIK_ENABLE                    (1 << 7)
#define KXTIK_DRDYE                             (1 << 5)
/* INPUT_ABS CONSTANTS */
#define FUZZ                    3
#define FLAT                    3
/* RESUME STATE INDICES */
#define RES_DATA_CTRL           0
#define RES_CTRL_REG1           1
#define RES_INT_CTRL1           2
#define RESUME_ENTRIES          3

/* CTRL_REG1: set resolution, g-range, data ready enable */
/* Output resolution: 8-bit valid or 12-bit valid */
#define KXTIK_RES_8BIT          0
#define KXTIK_RES_12BIT         (1 << 6)
/* Output g-range: +/-2g, 4g, or 8g */
#define KXTIK_G_2G              0
#define KXTIK_G_4G              (1 << 3)
#define KXTIK_G_8G              (1 << 4)

/* DATA_CTRL_REG: controls the output data rate of the part */
#define KXTIK_ODR12_5F          0
#define KXTIK_ODR25F                    1
#define KXTIK_ODR50F                    2
#define KXTIK_ODR100F                   3
#define KXTIK_ODR200F                   4
#define KXTIK_ODR400F                   5
#define KXTIK_ODR800F                   6

/* kxtik */
#define KXTIK_PRECISION       12
#define KXTIK_BOUNDARY        (0x1 << (KXTIK_PRECISION - 1))
#define KXTIK_GRAVITY_STEP    KXTIK_RANGE / KXTIK_BOUNDARY


/****************operate according to sensor chip:start************/

static int sensor_active(struct i2c_client *client, int enable, int rate)
{
        struct sensor_private_data *sensor =
            (struct sensor_private_data *) i2c_get_clientdata(client);  
        int result = 0;
        int status = 0;
                
        sensor->ops->ctrl_data = sensor_read_reg(client, sensor->ops->ctrl_reg);
        
        //register setting according to chip datasheet          
        if(enable)
        {       
                status = KXTIK_ENABLE;  //kxtik 
                sensor->ops->ctrl_data |= status;       
        }
        else
        {
                status = ~KXTIK_ENABLE; //kxtik
                sensor->ops->ctrl_data &= status;
        }

        DBG("%s:reg=0x%x,reg_ctrl=0x%x,enable=%d\n",__func__,sensor->ops->ctrl_reg, sensor->ops->ctrl_data, enable);
        result = sensor_write_reg(client, sensor->ops->ctrl_reg, sensor->ops->ctrl_data);
        if(result)
                printk("%s:fail to active sensor\n",__func__);
        
        return result;

} 

static int sensor_init(struct i2c_client *client)
{       
        struct sensor_private_data *sensor =
            (struct sensor_private_data *) i2c_get_clientdata(client);  
        int result = 0; 
        int i = 0;      
        unsigned char id_reg = KXTIK_WHO_AM_I;
        unsigned char id_data = 0;
        unsigned char ctrl_data_save = 0;
        
        result = sensor->ops->active(client,0,0);
        if(result)
        {
                printk("%s:line=%d,error\n",__func__,__LINE__);
                return result;
        }
        
        sensor->status_cur = SENSOR_OFF;

        for(i=0; i<3; i++)
        {
                result = sensor_rx_data(client, &id_reg, 1);
                id_data = id_reg;
                if(!result)
                break;
        }

        if(result)
        {
                printk("%s:fail to read id,result=%d\n",__func__, result);
                return result;
        }

        sensor->devid = id_data;
        
        result = sensor_write_reg(client, KXTIK_DATA_CTRL_REG, KXTIK_ODR400F);
        if(result)
        {
                printk("%s:line=%d,error\n",__func__,__LINE__);
                return result;
        }

        if(sensor->pdata->irq_enable)   //open interrupt
        {

/*
BIT 4 IEA sets the polarity of the physical interrupt pin (7)
IEA = 0 ¿ polarity of the physical interrupt pin (7) is active low
IEA = 1 ¿ polarity of the physical interrupt pin (7) is active high
BIT 3 IEL sets the response of the physical interrupt pin (7)
IEL = 0 ¿ the physical interrupt pin (7) latches until it is cleared by reading INT_REL
IEL = 1 ¿ the physical interrupt pin (7) will transmit one pulse with a period of 0.03 - 0.05ms
*/
                if (id_data == KXTIK_DEVID_1004)
                result = sensor_write_reg(client, KXTIK_INT_CTRL_REG1, 0x34);//enable int,active high,need read INT_REL
                else
                result = sensor_write_reg(client, KXTIK_INT_CTRL_REG1, 0x28);//enable int,active high,need read INT_REL
                
                if(result)
                {
                        printk("%s:line=%d,error\n",__func__,__LINE__);
                        return result;
                }
        }
        
        ctrl_data_save = sensor_read_reg(client, sensor->ops->ctrl_reg);
        DBG("%s: ctrl_data_save = 0x%x\n", __func__, ctrl_data_save);
        sensor->ops->ctrl_data = (KXTIK_RES_12BIT | KXTIK_G_2G);
        if(sensor->pdata->irq_enable)
        {
                sensor->ops->ctrl_data &= ~KXTIK_ENABLE;
                sensor->ops->ctrl_data |= KXTIK_DRDYE;
        }
        DBG("%s: first write sensor->ops->ctrl_data = 0x%x\n", __func__, sensor->ops->ctrl_data);
        result = sensor_write_reg(client, sensor->ops->ctrl_reg, sensor->ops->ctrl_data);
        if(result)
        {
                printk("%s:line=%d,error\n",__func__,__LINE__);
                return result;
        }
        if(ctrl_data_save & 0x80)
                sensor->ops->ctrl_data |= KXTIK_ENABLE;
        else
                sensor->ops->ctrl_data &= ~KXTIK_ENABLE;
        DBG("%s: second write sensor->ops->ctrl_data = 0x%x\n", __func__, sensor->ops->ctrl_data);
        result = sensor_write_reg(client, sensor->ops->ctrl_reg, sensor->ops->ctrl_data);
        if(result)
        {
                printk("%s:line=%d,error\n",__func__,__LINE__);
                return result;
        }

        DBG("%s:%s id=0x%x\n",__func__,sensor->ops->name, id_data);
        return result;
}

static int sensor_convert_data(struct i2c_client *client, char high_byte, char low_byte)
{
    s64 result;
        struct sensor_private_data *sensor =
            (struct sensor_private_data *) i2c_get_clientdata(client);  
        //int precision = sensor->ops->precision;
        switch (sensor->devid) {        
                case KXTIK_DEVID_1004:  
                case KXTIK_DEVID_1013:
                case KXTIK_DEVID_J9_1005:
                case KXTIK_DEVID_J2_1009:
                        result = (((int)high_byte << 8) | ((int)low_byte ))>>4;
                        if (result < KXTIK_BOUNDARY)
                        result = result* KXTIK_GRAVITY_STEP;
                else
                        result = ~( ((~result & (0x7fff>>(16-KXTIK_PRECISION)) ) + 1) 
                                                * KXTIK_GRAVITY_STEP) + 1;
                        break;

                default:
                        printk(KERN_ERR "%s: devid wasn't set correctly\n",__func__);
                        return -EFAULT;
    }
    return (int)result;
}

static int angle_report_value(struct i2c_client *client, struct sensor_axis *axis)
{
        struct sensor_private_data *sensor =
                (struct sensor_private_data *) i2c_get_clientdata(client);      

        /* Report acceleration sensor information */
        input_report_abs(sensor->input_dev, ABS_X, axis->x);
        input_report_abs(sensor->input_dev, ABS_Y, axis->y);
        input_report_abs(sensor->input_dev, ABS_Z, axis->z);
        input_sync(sensor->input_dev);
        DBG("Gsensor x==%d  y==%d z==%d\n",axis->x,axis->y,axis->z);

        return 0;
}

#define GSENSOR_MIN  10
static int sensor_report_value(struct i2c_client *client)
{
        struct sensor_private_data *sensor =
                        (struct sensor_private_data *) i2c_get_clientdata(client);      
        struct sensor_platform_data *pdata = sensor->pdata;
        int ret = 0;
        int x,y,z;
        struct sensor_axis axis;        
        char buffer[6] = {0};   
        char value = 0;
        
        if(sensor->ops->read_len < 6)   //sensor->ops->read_len = 6
        {
                printk("%s:lenth is error,len=%d\n",__func__,sensor->ops->read_len);
                return -1;
        }
        
        memset(buffer, 0, 6);
        
        /* Data bytes from hardware xL, xH, yL, yH, zL, zH */   
        do {
                *buffer = sensor->ops->read_reg;
                ret = sensor_rx_data(client, buffer, sensor->ops->read_len);
                if (ret < 0)
                return ret;
        } while (0);

        //this angle need 6 bytes buffer
        x = sensor_convert_data(sensor->client, buffer[1], buffer[0]);  //buffer[1]:high bit 
        y = sensor_convert_data(sensor->client, buffer[3], buffer[2]);
        z = sensor_convert_data(sensor->client, buffer[5], buffer[4]);          

        axis.x = (pdata->orientation[0])*x + (pdata->orientation[1])*y + (pdata->orientation[2])*z;
        axis.y = (pdata->orientation[3])*x + (pdata->orientation[4])*y + (pdata->orientation[5])*z;     
        axis.z = (pdata->orientation[6])*x + (pdata->orientation[7])*y + (pdata->orientation[8])*z;

        DBG( "%s: axis = %d  %d  %d \n", __func__, axis.x, axis.y, axis.z);

        //Report event  only while value is changed to save some power
        if((abs(sensor->axis.x - axis.x) > GSENSOR_MIN) || (abs(sensor->axis.y - axis.y) > GSENSOR_MIN) || (abs(sensor->axis.z - axis.z) > GSENSOR_MIN))
        {
                angle_report_value(client, &axis);

                /* »¥³âµØ»º´æÊý¾Ý. */
                mutex_lock(&(sensor->data_mutex) );
                sensor->axis = axis;
                mutex_unlock(&(sensor->data_mutex) );
        }

        if((sensor->pdata->irq_enable)&& (sensor->ops->int_status_reg >= 0))    //read sensor intterupt status register
        {
                
                value = sensor_read_reg(client, sensor->ops->int_status_reg);
                DBG("%s:sensor int status :0x%x\n",__func__,value);
        }
        
        return ret;
}

struct sensor_operate angle_kxtik_ops = {
        .name                           = "angle_kxtik",
        .type                           = SENSOR_TYPE_ANGLE,            //sensor type and it should be correct
        .id_i2c                         = ANGLE_ID_KXTIK,               //i2c id number
        .read_reg                       = KXTIK_XOUT_L,                 //read data
        .read_len                       = 6,                            //data length
        .id_reg                         = SENSOR_UNKNOW_DATA,           //read device id from this register
        .id_data                        = SENSOR_UNKNOW_DATA,
        .precision                      = KXTIK_PRECISION,              //12 bits
        .ctrl_reg                       = KXTIK_CTRL_REG1,              //enable or disable 
        .int_status_reg                 = KXTIK_INT_REL,                //intterupt status register
        .range                          = {-KXTIK_RANGE,KXTIK_RANGE},   //range
        .trig                           = IRQF_TRIGGER_LOW|IRQF_ONESHOT,                
        .active                         = sensor_active,        
        .init                           = sensor_init,
        .report                         = sensor_report_value,
};

/****************operate according to sensor chip:end************/

//function name should not be changed
static struct sensor_operate *angle_get_ops(void)
{
        return &angle_kxtik_ops;
}


static int __init angle_kxtik_init(void)
{
        struct sensor_operate *ops = angle_get_ops();
        int result = 0;
        int type = ops->type;
        result = sensor_register_slave(type, NULL, NULL, angle_get_ops);
        printk("%s\n",__func__);
        return result;
}

static void __exit angle_kxtik_exit(void)
{
        struct sensor_operate *ops = angle_get_ops();
        int type = ops->type;
        sensor_unregister_slave(type, NULL, NULL, angle_get_ops);
}


module_init(angle_kxtik_init);
module_exit(angle_kxtik_exit);