/* KXTIK1004 motion sensor driver * * * * 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 #include #include #include #include #include #include #include #include #include #include #include #include //#include #include #include #include #define POWER_NONE_MACRO MT65XX_POWER_NONE #include #include #include #include #include "kxtik1004.h" #include /*----------------------------------------------------------------------------*/ #define I2C_DRIVERID_KXTIK1004 150 /*----------------------------------------------------------------------------*/ //#define DEBUG 1 /*----------------------------------------------------------------------------*/ //#define CONFIG_KXTIK1004_LOWPASS /*apply low pass filter on output*/ #define SW_CALIBRATION /*----------------------------------------------------------------------------*/ #define KXTIK1004_AXIS_X 0 #define KXTIK1004_AXIS_Y 1 #define KXTIK1004_AXIS_Z 2 #define KXTIK1004_AXES_NUM 3 #define KXTIK1004_DATA_LEN 6 #define KXTIK1004_DEV_NAME "KXTIK1004" /*----------------------------------------------------------------------------*/ /*----------------------------------------------------------------------------*/ static const struct i2c_device_id kxtik1004_i2c_id[] = {{KXTIK1004_DEV_NAME,0},{}}; static struct i2c_board_info __initdata i2c_kxtik1004={ I2C_BOARD_INFO(KXTIK1004_DEV_NAME, (KXTIK1004_I2C_SLAVE_ADDR>>1))}; /*the adapter id will be available in customization*/ //static unsigned short kxtik1004_force[] = {0x00, KXTIK1004_I2C_SLAVE_ADDR, I2C_CLIENT_END, I2C_CLIENT_END}; //static const unsigned short *const kxtik1004_forces[] = { kxtik1004_force, NULL }; //static struct i2c_client_address_data kxtik1004_addr_data = { .forces = kxtik1004_forces,}; /*----------------------------------------------------------------------------*/ static int kxtik1004_i2c_probe(struct i2c_client *client, const struct i2c_device_id *id); static int kxtik1004_i2c_remove(struct i2c_client *client); static int kxtik1004_i2c_detect(struct i2c_client *client, struct i2c_board_info *info); #ifndef USE_EARLY_SUSPEND static int kxtik1004_suspend(struct i2c_client *client, pm_message_t msg); static int kxtik1004_resume(struct i2c_client *client); #endif /*----------------------------------------------------------------------------*/ typedef enum { ADX_TRC_FILTER = 0x01, ADX_TRC_RAWDATA = 0x02, ADX_TRC_IOCTL = 0x04, ADX_TRC_CALI = 0X08, ADX_TRC_INFO = 0X10, } ADX_TRC; /*----------------------------------------------------------------------------*/ struct scale_factor{ u8 whole; u8 fraction; }; /*----------------------------------------------------------------------------*/ struct data_resolution { struct scale_factor scalefactor; int sensitivity; }; /*----------------------------------------------------------------------------*/ #define C_MAX_FIR_LENGTH (32) /*----------------------------------------------------------------------------*/ struct data_filter { s16 raw[C_MAX_FIR_LENGTH][KXTIK1004_AXES_NUM]; int sum[KXTIK1004_AXES_NUM]; int num; int idx; }; /*----------------------------------------------------------------------------*/ struct kxtik1004_i2c_data { struct i2c_client *client; struct acc_hw *hw; struct hwmsen_convert cvt; /*misc*/ struct data_resolution *reso; atomic_t trace; atomic_t suspend; atomic_t selftest; atomic_t filter; s16 cali_sw[KXTIK1004_AXES_NUM+1]; /*data*/ s8 offset[KXTIK1004_AXES_NUM+1]; /*+1: for 4-byte alignment*/ s16 data[KXTIK1004_AXES_NUM+1]; #if defined(CONFIG_KXTIK1004_LOWPASS) atomic_t firlen; atomic_t fir_en; struct data_filter fir; #endif /*early suspend*/ #ifdef USE_EARLY_SUSPEND struct early_suspend early_drv; #endif }; /*----------------------------------------------------------------------------*/ static struct i2c_driver kxtik1004_i2c_driver = { .driver = { // .owner = THIS_MODULE, .name = KXTIK1004_DEV_NAME, }, .probe = kxtik1004_i2c_probe, .remove = kxtik1004_i2c_remove, .detect = kxtik1004_i2c_detect, #if !defined(USE_EARLY_SUSPEND) .suspend = kxtik1004_suspend, .resume = kxtik1004_resume, #endif .id_table = kxtik1004_i2c_id, // .address_data = &kxtik1004_addr_data, }; /*----------------------------------------------------------------------------*/ static struct i2c_client *kxtik1004_i2c_client = NULL; static struct platform_driver kxtik1004_gsensor_driver; static struct kxtik1004_i2c_data *obj_i2c_data = NULL; static bool sensor_power = true; static int sensor_suspend = 0; static GSENSOR_VECTOR3D gsensor_gain; static char selftestRes[8]= {0}; static DEFINE_MUTEX(kxtik1004_i2c_mutex); static DEFINE_MUTEX(kxtik1004_op_mutex); static bool enable_status = false; /*----------------------------------------------------------------------------*/ #define GSE_TAG "[Gsensor] " #define GSE_FUN(f) printk(KERN_INFO GSE_TAG"%s\n", __func__) #define GSE_ERR(fmt, args...) printk(KERN_ERR GSE_TAG"%s %d : "fmt, __func__, __LINE__, ##args) #define GSE_LOG(fmt, args...) printk(KERN_INFO GSE_TAG fmt, ##args) /*----------------------------------------------------------------------------*/ static struct data_resolution kxtik1004_data_resolution[1] = { /* combination by {FULL_RES,RANGE}*/ {{ 0, 9}, 1024}, // dataformat +/-2g in 12-bit resolution; { 3, 9} = 3.9 = (2*2*1000)/(2^12); 256 = (2^12)/(2*2) }; /*----------------------------------------------------------------------------*/ static struct data_resolution kxtik1004_offset_resolution = {{15, 6}, 64}; /*----------------------------------------------------------------------------*/ static int kxt_i2c_read_block(struct i2c_client *client, u8 addr, u8 *data, u8 len) { u8 beg = addr; int err; struct i2c_msg msgs[2]={{0},{0}}; mutex_lock(&kxtik1004_i2c_mutex); msgs[0].addr = client->addr; msgs[0].flags = 0; msgs[0].len =1; msgs[0].buf = &beg; msgs[1].addr = client->addr; msgs[1].flags = I2C_M_RD; msgs[1].len =len; msgs[1].buf = data; if (!client) { mutex_unlock(&kxtik1004_i2c_mutex); return -EINVAL; } else if (len > C_I2C_FIFO_SIZE) { GSE_ERR(" length %d exceeds %d\n", len, C_I2C_FIFO_SIZE); mutex_unlock(&kxtik1004_i2c_mutex); return -EINVAL; } err = i2c_transfer(client->adapter, msgs, sizeof(msgs)/sizeof(msgs[0])); if (err != 2) { GSE_ERR("i2c_transfer error: (%d %p %d) %d\n",addr, data, len, err); err = -EIO; } else { err = 0; } mutex_unlock(&kxtik1004_i2c_mutex); return err; } static int kxt_i2c_write_block(struct i2c_client *client, u8 addr, u8 *data, u8 len) { /*because address also occupies one byte, the maximum length for write is 7 bytes*/ int err, idx, num; char buf[C_I2C_FIFO_SIZE]; err =0; mutex_lock(&kxtik1004_i2c_mutex); if (!client) { mutex_unlock(&kxtik1004_i2c_mutex); return -EINVAL; } else if (len >= C_I2C_FIFO_SIZE) { GSE_ERR(" length %d exceeds %d\n", len, C_I2C_FIFO_SIZE); mutex_unlock(&kxtik1004_i2c_mutex); return -EINVAL; } num = 0; buf[num++] = addr; for (idx = 0; idx < len; idx++) { buf[num++] = data[idx]; } err = i2c_master_send(client, buf, num); if (err < 0) { GSE_ERR("send command error!!\n"); mutex_unlock(&kxtik1004_i2c_mutex); return -EFAULT; } mutex_unlock(&kxtik1004_i2c_mutex); return err; } /*----------------------------------------------------------------------------*/ /*----------------------------------------------------------------------------*/ static int KXTIK1004_SetPowerMode(struct i2c_client *client, bool enable); /*--------------------KXTIK1004 power control function----------------------------------*/ static void KXTIK1004_power(struct acc_hw *hw, unsigned int on) { static unsigned int power_on = 0; if(hw->power_id != POWER_NONE_MACRO) // have externel LDO { GSE_LOG("power %s\n", on ? "on" : "off"); if(power_on == on) // power status not change { GSE_LOG("ignore power control: %d\n", on); } else if(on) // power on { if(!hwPowerOn(hw->power_id, hw->power_vol, "KXTIK1004")) { GSE_ERR("power on fails!!\n"); } } else // power off { if (!hwPowerDown(hw->power_id, "KXTIK1004")) { GSE_ERR("power off fail!!\n"); } } } power_on = on; } /*----------------------------------------------------------------------------*/ /*----------------------------------------------------------------------------*/ static int KXTIK1004_SetDataResolution(struct kxtik1004_i2c_data *obj) { int err; u8 databuf[2]; KXTIK1004_SetPowerMode(obj->client, false); if(kxt_i2c_read_block(obj->client, KXTIK1004_REG_DATA_RESOLUTION, databuf, 0x01)) { printk("kxtik1004 read Dataformat failt \n"); return KXTIK1004_ERR_I2C; } databuf[0] &= ~KXTIK1004_RANGE_DATA_RESOLUTION_MASK; databuf[0] |= KXTIK1004_RANGE_DATA_RESOLUTION_MASK;//12bit err = kxt_i2c_write_block(obj->client, KXTIK1004_REG_DATA_RESOLUTION, databuf, 0x1); if(err < 0) { return KXTIK1004_ERR_I2C; } KXTIK1004_SetPowerMode(obj->client, true); //kxtik1004_data_resolution[0] has been set when initialize: +/-2g in 8-bit resolution: 15.6 mg/LSB*/ obj->reso = &kxtik1004_data_resolution[0]; return 0; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_ReadData(struct i2c_client *client, s16 data[KXTIK1004_AXES_NUM]) { struct kxtik1004_i2c_data *priv = i2c_get_clientdata(client); u8 addr = KXTIK1004_REG_DATAX0; u8 buf[KXTIK1004_DATA_LEN] = {0}; int err = 0; int i; if(NULL == client) { err = -EINVAL; } else if((err = kxt_i2c_read_block(client, addr, buf, 0x06))) { GSE_ERR("error: %d\n", err); } else { data[KXTIK1004_AXIS_X] = (s16)((buf[KXTIK1004_AXIS_X*2] >> 4) | (buf[KXTIK1004_AXIS_X*2+1] << 4)); data[KXTIK1004_AXIS_Y] = (s16)((buf[KXTIK1004_AXIS_Y*2] >> 4) | (buf[KXTIK1004_AXIS_Y*2+1] << 4)); data[KXTIK1004_AXIS_Z] = (s16)((buf[KXTIK1004_AXIS_Z*2] >> 4) | (buf[KXTIK1004_AXIS_Z*2+1] << 4)); for(i=0;i<3;i++) { //because the data is store in binary complement number formation in computer system if ( data[i] == 0x0800 ) //so we want to calculate actual number here data[i]= -2048; //10bit resolution, 512= 2^(12-1) else if ( data[i] & 0x0800 )//transfor format { //printk("data 0 step %x \n",data[i]); data[i] -= 0x1; //printk("data 1 step %x \n",data[i]); data[i] = ~data[i]; //printk("data 2 step %x \n",data[i]); data[i] &= 0x07ff; //printk("data 3 step %x \n\n",data[i]); data[i] = -data[i]; } } if(atomic_read(&priv->trace) & ADX_TRC_RAWDATA) { GSE_LOG("[%08X %08X %08X] => [%5d %5d %5d]\n", data[KXTIK1004_AXIS_X], data[KXTIK1004_AXIS_Y], data[KXTIK1004_AXIS_Z], data[KXTIK1004_AXIS_X], data[KXTIK1004_AXIS_Y], data[KXTIK1004_AXIS_Z]); } #ifdef CONFIG_KXTIK1004_LOWPASS if(atomic_read(&priv->filter)) { if(atomic_read(&priv->fir_en) && !atomic_read(&priv->suspend)) { int idx, firlen = atomic_read(&priv->firlen); if(priv->fir.num < firlen) { priv->fir.raw[priv->fir.num][KXTIK1004_AXIS_X] = data[KXTIK1004_AXIS_X]; priv->fir.raw[priv->fir.num][KXTIK1004_AXIS_Y] = data[KXTIK1004_AXIS_Y]; priv->fir.raw[priv->fir.num][KXTIK1004_AXIS_Z] = data[KXTIK1004_AXIS_Z]; priv->fir.sum[KXTIK1004_AXIS_X] += data[KXTIK1004_AXIS_X]; priv->fir.sum[KXTIK1004_AXIS_Y] += data[KXTIK1004IK_AXIS_Y]; priv->fir.sum[KXTIK1004_AXIS_Z] += data[KXTIK1004_AXIS_Z]; if(atomic_read(&priv->trace) & ADX_TRC_FILTER) { GSE_LOG("add [%2d] [%5d %5d %5d] => [%5d %5d %5d]\n", priv->fir.num, priv->fir.raw[priv->fir.num][KXTIK1004_AXIS_X], priv->fir.raw[priv->fir.num][KXTIK1004_AXIS_Y], priv->fir.raw[priv->fir.num][KXTIK1004_AXIS_Z], priv->fir.sum[KXTIK1004_AXIS_X], priv->fir.sum[KXTIK1004_AXIS_Y], priv->fir.sum[KXTIK1004_AXIS_Z]); } priv->fir.num++; priv->fir.idx++; } else { idx = priv->fir.idx % firlen; priv->fir.sum[KXTIK1004_AXIS_X] -= priv->fir.raw[idx][KXTIK1004_AXIS_X]; priv->fir.sum[KXTIK1004_AXIS_Y] -= priv->fir.raw[idx][KXTIK1004_AXIS_Y]; priv->fir.sum[KXTIK1004_AXIS_Z] -= priv->fir.raw[idx][KXTIK1004_AXIS_Z]; priv->fir.raw[idx][KXTIK1004_AXIS_X] = data[KXTIK1004_AXIS_X]; priv->fir.raw[idx][KXTIK1004_AXIS_Y] = data[KXTIK1004_AXIS_Y]; priv->fir.raw[idx][KXTIK1004_AXIS_Z] = data[KXTIK1004_AXIS_Z]; priv->fir.sum[KXTIK1004_AXIS_X] += data[KXTIK1004_AXIS_X]; priv->fir.sum[KXTIK1004_AXIS_Y] += data[KXTIK1004_AXIS_Y]; priv->fir.sum[KXTIK1004_AXIS_Z] += data[KXTIK1004_AXIS_Z]; priv->fir.idx++; data[KXTIK1004_AXIS_X] = priv->fir.sum[KXTIK1004_AXIS_X]/firlen; data[KXTIK1004_AXIS_Y] = priv->fir.sum[KXTIK1004_AXIS_Y]/firlen; data[KXTIK1004_AXIS_Z] = priv->fir.sum[KXTIK1004_AXIS_Z]/firlen; if(atomic_read(&priv->trace) & ADX_TRC_FILTER) { GSE_LOG("add [%2d] [%5d %5d %5d] => [%5d %5d %5d] : [%5d %5d %5d]\n", idx, priv->fir.raw[idx][KXTIK1004_AXIS_X], priv->fir.raw[idx][KXTIK1004_AXIS_Y], priv->fir.raw[idx][KXTIK1004_AXIS_Z], priv->fir.sum[KXTIK1004_AXIS_X], priv->fir.sum[KXTIK1004_AXIS_Y], priv->fir.sum[KXTIK1004_AXIS_Z], data[KXTIK1004_AXIS_X], data[KXTIK1004_AXIS_Y], data[KXTIK1004_AXIS_Z]); } } } } #endif } return err; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_ReadOffset(struct i2c_client *client, s8 ofs[KXTIK1004_AXES_NUM]) { int err = 0; ofs[1]=ofs[2]=ofs[0]=0x00; printk("offesx=%x, y=%x, z=%x",ofs[0],ofs[1],ofs[2]); return err; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_ResetCalibration(struct i2c_client *client) { struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); //u8 ofs[4]={0,0,0,0}; int err = 0; memset(obj->cali_sw, 0x00, sizeof(obj->cali_sw)); memset(obj->offset, 0x00, sizeof(obj->offset)); return err; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_ReadCalibration(struct i2c_client *client, int dat[KXTIK1004_AXES_NUM]) { struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); int err = 0; int mul; #ifdef SW_CALIBRATION mul = 0;//only SW Calibration, disable HW Calibration #else if ((err = KXTIK1004_ReadOffset(client, obj->offset))) { GSE_ERR("read offset fail, %d\n", err); return err; } mul = obj->reso->sensitivity/kxtik1004_offset_resolution.sensitivity; #endif dat[obj->cvt.map[KXTIK1004_AXIS_X]] = obj->cvt.sign[KXTIK1004_AXIS_X]*(obj->offset[KXTIK1004_AXIS_X]*mul * GRAVITY_EARTH_1000 / obj->reso->sensitivity + obj->cali_sw[KXTIK1004_AXIS_X]); dat[obj->cvt.map[KXTIK1004_AXIS_Y]] = obj->cvt.sign[KXTIK1004_AXIS_Y]*(obj->offset[KXTIK1004_AXIS_Y]*mul * GRAVITY_EARTH_1000 / obj->reso->sensitivity + obj->cali_sw[KXTIK1004_AXIS_Y]); dat[obj->cvt.map[KXTIK1004_AXIS_Z]] = obj->cvt.sign[KXTIK1004_AXIS_Z]*(obj->offset[KXTIK1004_AXIS_Z]*mul * GRAVITY_EARTH_1000 / obj->reso->sensitivity + obj->cali_sw[KXTIK1004_AXIS_Z]); return err; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_ReadCalibrationEx(struct i2c_client *client, int act[KXTIK1004_AXES_NUM], int raw[KXTIK1004_AXES_NUM]) { /*raw: the raw calibration data; act: the actual calibration data*/ struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); int err; int mul; err = 0; #ifdef SW_CALIBRATION mul = 0;//only SW Calibration, disable HW Calibration #else if((err = KXTIK1004_ReadOffset(client, obj->offset))) { GSE_ERR("read offset fail, %d\n", err); return err; } mul = obj->reso->sensitivity/kxtik1004_offset_resolution.sensitivity; #endif raw[KXTIK1004_AXIS_X] = obj->offset[KXTIK1004_AXIS_X]*mul * GRAVITY_EARTH_1000 / obj->reso->sensitivity + obj->cali_sw[KXTIK1004_AXIS_X]; raw[KXTIK1004_AXIS_Y] = obj->offset[KXTIK1004_AXIS_Y]*mul * GRAVITY_EARTH_1000 / obj->reso->sensitivity + obj->cali_sw[KXTIK1004_AXIS_Y]; raw[KXTIK1004_AXIS_Z] = obj->offset[KXTIK1004_AXIS_Z]*mul * GRAVITY_EARTH_1000 / obj->reso->sensitivity + obj->cali_sw[KXTIK1004_AXIS_Z]; act[obj->cvt.map[KXTIK1004_AXIS_X]] = obj->cvt.sign[KXTIK1004_AXIS_X]*raw[KXTIK1004_AXIS_X]; act[obj->cvt.map[KXTIK1004_AXIS_Y]] = obj->cvt.sign[KXTIK1004_AXIS_Y]*raw[KXTIK1004_AXIS_Y]; act[obj->cvt.map[KXTIK1004_AXIS_Z]] = obj->cvt.sign[KXTIK1004_AXIS_Z]*raw[KXTIK1004_AXIS_Z]; return 0; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_WriteCalibration(struct i2c_client *client, int dat[KXTIK1004_AXES_NUM]) { struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); int err = 0; int cali[KXTIK1004_AXES_NUM], raw[KXTIK1004_AXES_NUM]; //int lsb = kxtik1004_offset_resolution.sensitivity; //int divisor = obj->reso->sensitivity/lsb; if((err = KXTIK1004_ReadCalibrationEx(client, cali, raw))) /*offset will be updated in obj->offset*/ { GSE_ERR("read offset fail, %d\n", err); return err; } GSE_LOG("OLDOFF: (%+3d %+3d %+3d): (%+3d %+3d %+3d) / (%+3d %+3d %+3d)\n", raw[KXTIK1004_AXIS_X], raw[KXTIK1004_AXIS_Y], raw[KXTIK1004_AXIS_Z], obj->offset[KXTIK1004_AXIS_X], obj->offset[KXTIK1004_AXIS_Y], obj->offset[KXTIK1004_AXIS_Z], obj->cali_sw[KXTIK1004_AXIS_X], obj->cali_sw[KXTIK1004_AXIS_Y], obj->cali_sw[KXTIK1004_AXIS_Z]); /*calculate the real offset expected by caller*/ cali[KXTIK1004_AXIS_X] += dat[KXTIK1004_AXIS_X]; cali[KXTIK1004_AXIS_Y] += dat[KXTIK1004_AXIS_Y]; cali[KXTIK1004_AXIS_Z] += dat[KXTIK1004_AXIS_Z]; GSE_LOG("UPDATE: (%+3d %+3d %+3d)\n", dat[KXTIK1004_AXIS_X], dat[KXTIK1004_AXIS_Y], dat[KXTIK1004_AXIS_Z]); #ifdef SW_CALIBRATION obj->cali_sw[KXTIK1004_AXIS_X] = obj->cvt.sign[KXTIK1004_AXIS_X]*(cali[obj->cvt.map[KXTIK1004_AXIS_X]]); obj->cali_sw[KXTIK1004_AXIS_Y] = obj->cvt.sign[KXTIK1004_AXIS_Y]*(cali[obj->cvt.map[KXTIK1004_AXIS_Y]]); obj->cali_sw[KXTIK1004_AXIS_Z] = obj->cvt.sign[KXTIK1004_AXIS_Z]*(cali[obj->cvt.map[KXTIK1004_AXIS_Z]]); #else obj->offset[KXTIK1004_AXIS_X] = (s8)(obj->cvt.sign[KXTIK1004_AXIS_X]*(cali[obj->cvt.map[KXTIK1004_AXIS_X]]) * obj->reso->sensitivity / GRAVITY_EARTH_1000/(divisor)); obj->offset[KXTIK1004_AXIS_Y] = (s8)(obj->cvt.sign[KXTIK1004_AXIS_Y]*(cali[obj->cvt.map[KXTIK1004_AXIS_Y]]) * obj->reso->sensitivity / GRAVITY_EARTH_1000/(divisor)); obj->offset[KXTIK1004_AXIS_Z] = (s8)(obj->cvt.sign[KXTIK1004_AXIS_Z]*(cali[obj->cvt.map[KXTIK1004_AXIS_Z]]) * obj->reso->sensitivity / GRAVITY_EARTH_1000/(divisor)); /*convert software calibration using standard calibration*/ obj->cali_sw[KXTIK1004_AXIS_X] = obj->cvt.sign[KXTIK1004_AXIS_X]*(cali[obj->cvt.map[KXTIK1004_AXIS_X]])%(divisor); obj->cali_sw[KXTIK1004_AXIS_Y] = obj->cvt.sign[KXTIK1004_AXIS_Y]*(cali[obj->cvt.map[KXTIK1004_AXIS_Y]])%(divisor); obj->cali_sw[KXTIK1004_AXIS_Z] = obj->cvt.sign[KXTIK1004_AXIS_Z]*(cali[obj->cvt.map[KXTIK1004_AXIS_Z]])%(divisor); GSE_LOG("NEWOFF: (%+3d %+3d %+3d): (%+3d %+3d %+3d) / (%+3d %+3d %+3d)\n", obj->offset[KXTIK1004_AXIS_X]*divisor + obj->cali_sw[KXTIK1004_AXIS_X], obj->offset[KXTIK1004_AXIS_Y]*divisor + obj->cali_sw[KXTIK1004_AXIS_Y], obj->offset[KXTIK1004_AXIS_Z]*divisor + obj->cali_sw[KXTIK1004_AXIS_Z], obj->offset[KXTIK1004_AXIS_X], obj->offset[KXTIK1004_AXIS_Y], obj->offset[KXTIK1004_AXIS_Z], obj->cali_sw[KXTIK1004_AXIS_X], obj->cali_sw[KXTIK1004_AXIS_Y], obj->cali_sw[KXTIK1004_AXIS_Z]); if((err = kxt_i2c_write_block(obj->client, KXTIK1004_REG_OFSX, obj->offset, KXTIK1004_AXES_NUM))<0) { GSE_ERR("write offset fail: %d\n", err); return err; } #endif return err; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_CheckDeviceID(struct i2c_client *client) { u8 databuf[10]; int res = 0; memset(databuf, 0, sizeof(u8)*10); res = kxt_i2c_read_block(client, KXTIK1004_REG_DEVID, databuf, 0x1); if(res < 0) { goto exit_KXTIK1004_CheckDeviceID; } if(databuf[0] == KXTIK1004_DEVICE_ID) { GSE_LOG("KXTIK1004_CheckDeviceID 0x%x pass!\n ", databuf[0]); } else if(databuf[0] == KXCJK1013_DEVICE_ID) { GSE_LOG("KXCJK1013_CheckDeviceID 0x%x pass!\n ", databuf[0]);/*because KXCJK-1013 use same driver with KXTIK1004*/ } else { GSE_LOG("KXTIK1004_CheckDeviceID 0x%x failt!\n ", databuf[0]); return KXTIK1004_ERR_IDENTIFICATION; } exit_KXTIK1004_CheckDeviceID: if (res < 0) { return KXTIK1004_ERR_I2C; } return KXTIK1004_SUCCESS; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_SetPowerMode(struct i2c_client *client, bool enable) { u8 databuf[2]; int res = 0; u8 addr = KXTIK1004_REG_POWER_CTL; //struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); if(enable == sensor_power) { GSE_LOG("Sensor power status is newest!\n"); return KXTIK1004_SUCCESS; } if(kxt_i2c_read_block(client, addr, databuf, 0x01)) { GSE_ERR("read power ctl register err!\n"); return KXTIK1004_ERR_I2C; } if(enable == TRUE) { databuf[0] |= KXTIK1004_MEASURE_MODE; } else { databuf[0] &= ~KXTIK1004_MEASURE_MODE; } res = kxt_i2c_write_block(client, KXTIK1004_REG_POWER_CTL, databuf, 0x1); if(res < 0) { return KXTIK1004_ERR_I2C; } GSE_LOG("KXTIK1004_SetPowerMode %d!\n ",enable); sensor_power = enable; mdelay(50); return KXTIK1004_SUCCESS; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_SetDataFormat(struct i2c_client *client, u8 dataformat) { struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); u8 databuf[10]; int res = 0; memset(databuf, 0, sizeof(u8)*10); KXTIK1004_SetPowerMode(client, false); if(kxt_i2c_read_block(client, KXTIK1004_REG_DATA_FORMAT, databuf, 0x01)) { GSE_LOG("kxtik1004 read Dataformat failt \n"); return KXTIK1004_ERR_I2C; } databuf[0] &= ~KXTIK1004_RANGE_MASK; databuf[0] |= dataformat; res = kxt_i2c_write_block(client, KXTIK1004_REG_DATA_FORMAT, databuf, 0x1); if(res < 0) { return KXTIK1004_ERR_I2C; } KXTIK1004_SetPowerMode(client, true); GSE_LOG("KXTIK1004_SetDataFormat OK! \n"); return KXTIK1004_SetDataResolution(obj); } /*----------------------------------------------------------------------------*/ static int KXTIK1004_SetBWRate(struct i2c_client *client, u8 bwrate) { u8 databuf[10]={0}; int res = 0; memset(databuf, 0, sizeof(u8)*10); if(kxt_i2c_read_block(client, KXTIK1004_REG_BW_RATE, databuf, 0x01)) { GSE_LOG("kxtik1004 read rate failt \n"); return KXTIK1004_ERR_I2C; } databuf[0] &= 0xf8; databuf[0] |= bwrate; res = kxt_i2c_write_block(client, KXTIK1004_REG_BW_RATE, databuf, 0x1); if(res < 0) { return KXTIK1004_ERR_I2C; } GSE_LOG("KXTIK1004_SetBWRate OK! \n"); return KXTIK1004_SUCCESS; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_SetIntEnable(struct i2c_client *client, u8 intenable) { u8 databuf[10]; int res = 0; memset(databuf, 0, sizeof(u8)*10); databuf[0] = 0x00; res = kxt_i2c_write_block(client, KXTIK1004_REG_INT_ENABLE, databuf, 0x1); if(res < 0) { return KXTIK1004_ERR_I2C; } return KXTIK1004_SUCCESS; } /*----------------------------------------------------------------------------*/ static int kxtik1004_init_client(struct i2c_client *client, int reset_cali) { struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); int res = 0; res = KXTIK1004_CheckDeviceID(client); if(res != KXTIK1004_SUCCESS) { return res; } res = KXTIK1004_SetPowerMode(client, enable_status); if(res != KXTIK1004_SUCCESS) { return res; } res = KXTIK1004_SetBWRate(client, KXTIK1004_BW_100HZ); if(res != KXTIK1004_SUCCESS ) //0x2C->BW=100Hz { return res; } res = KXTIK1004_SetDataFormat(client, KXTIK1004_RANGE_2G); if(res != KXTIK1004_SUCCESS) //0x2C->BW=100Hz { return res; } gsensor_gain.x = gsensor_gain.y = gsensor_gain.z = obj->reso->sensitivity; res = KXTIK1004_SetIntEnable(client, 0x00); if(res != KXTIK1004_SUCCESS)//0x2E->0x80 { return res; } if(0 != reset_cali) { /*reset calibration only in power on*/ res = KXTIK1004_ResetCalibration(client); if(res != KXTIK1004_SUCCESS) { return res; } } GSE_LOG("kxtik1004_init_client OK!\n"); #ifdef CONFIG_KXTIK1004_LOWPASS memset(&obj->fir, 0x00, sizeof(obj->fir)); #endif return KXTIK1004_SUCCESS; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_ReadChipInfo(struct i2c_client *client, char *buf, int bufsize) { u8 databuf[10]; memset(databuf, 0, sizeof(u8)*10); if((NULL == buf)||(bufsize<=30)) { return -1; } if(NULL == client) { *buf = 0; return -2; } sprintf(buf, "KXTIK1004 Chip"); return 0; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_ReadSensorData(struct i2c_client *client, char *buf, int bufsize) { struct kxtik1004_i2c_data *obj = (struct kxtik1004_i2c_data*)i2c_get_clientdata(client); u8 databuf[20]; int acc[KXTIK1004_AXES_NUM]; int res = 0; memset(databuf, 0, sizeof(u8)*10); if(NULL == buf) { return -1; } if(NULL == client) { *buf = 0; return -2; } if(sensor_suspend == 1) { //GSE_LOG("sensor in suspend read not data!\n"); return 0; } if((res = KXTIK1004_ReadData(client, obj->data))) { GSE_ERR("I2C error: ret value=%d", res); return -3; } else { #if 1 obj->data[KXTIK1004_AXIS_X] = obj->data[KXTIK1004_AXIS_X] * GRAVITY_EARTH_1000 / obj->reso->sensitivity; obj->data[KXTIK1004_AXIS_Y] = obj->data[KXTIK1004_AXIS_Y] * GRAVITY_EARTH_1000 / obj->reso->sensitivity; obj->data[KXTIK1004_AXIS_Z] = obj->data[KXTIK1004_AXIS_Z] * GRAVITY_EARTH_1000 / obj->reso->sensitivity; #endif //printk("raw data x=%d, y=%d, z=%d \n",obj->data[KXTIK1004_AXIS_X],obj->data[KXTIK1004_AXIS_Y],obj->data[KXTIK1004_AXIS_Z]); obj->data[KXTIK1004_AXIS_X] += obj->cali_sw[KXTIK1004_AXIS_X]; obj->data[KXTIK1004_AXIS_Y] += obj->cali_sw[KXTIK1004_AXIS_Y]; obj->data[KXTIK1004_AXIS_Z] += obj->cali_sw[KXTIK1004_AXIS_Z]; //printk("cali_sw x=%d, y=%d, z=%d \n",obj->cali_sw[KXTIK1004_AXIS_X],obj->cali_sw[KXTIK1004_AXIS_Y],obj->cali_sw[KXTIK1004_AXIS_Z]); /*remap coordinate*/ acc[obj->cvt.map[KXTIK1004_AXIS_X]] = obj->cvt.sign[KXTIK1004_AXIS_X]*obj->data[KXTIK1004_AXIS_X]; acc[obj->cvt.map[KXTIK1004_AXIS_Y]] = obj->cvt.sign[KXTIK1004_AXIS_Y]*obj->data[KXTIK1004_AXIS_Y]; acc[obj->cvt.map[KXTIK1004_AXIS_Z]] = obj->cvt.sign[KXTIK1004_AXIS_Z]*obj->data[KXTIK1004_AXIS_Z]; //printk("cvt x=%d, y=%d, z=%d \n",obj->cvt.sign[KXTIK1004_AXIS_X],obj->cvt.sign[KXTIK1004_AXIS_Y],obj->cvt.sign[KXTIK1004_AXIS_Z]); //GSE_LOG("Mapped gsensor data: %d, %d, %d!\n", acc[KXTIK1004_AXIS_X], acc[KXTIK1004_AXIS_Y], acc[KXTIK1004_AXIS_Z]); //Out put the mg //printk("mg acc=%d, GRAVITY=%d, sensityvity=%d \n",acc[KXTIK1004_AXIS_X],GRAVITY_EARTH_1000,obj->reso->sensitivity); #if 0 acc[KXTIK1004_AXIS_X] = acc[KXTIK1004_AXIS_X] * GRAVITY_EARTH_1000 / obj->reso->sensitivity; acc[KXTIK1004_AXIS_Y] = acc[KXTIK1004_AXIS_Y] * GRAVITY_EARTH_1000 / obj->reso->sensitivity; acc[KXTIK1004_AXIS_Z] = acc[KXTIK1004_AXIS_Z] * GRAVITY_EARTH_1000 / obj->reso->sensitivity; #endif sprintf(buf, "%04x %04x %04x", acc[KXTIK1004_AXIS_X], acc[KXTIK1004_AXIS_Y], acc[KXTIK1004_AXIS_Z]); if(atomic_read(&obj->trace) & ADX_TRC_IOCTL) { GSE_LOG("gsensor data: %s!\n", buf); } } return 0; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_ReadRawData(struct i2c_client *client, char *buf) { struct kxtik1004_i2c_data *obj = (struct kxtik1004_i2c_data*)i2c_get_clientdata(client); int res = 0; if (!buf || !client) { return EINVAL; } if((res = KXTIK1004_ReadData(client, obj->data))) { GSE_ERR("I2C error: ret value=%d", res); return EIO; } else { sprintf(buf, "KXTIK1004_ReadRawData %04x %04x %04x", obj->data[KXTIK1004_AXIS_X], obj->data[KXTIK1004_AXIS_Y], obj->data[KXTIK1004_AXIS_Z]); } return 0; } /*----------------------------------------------------------------------------*/ static int KXTIK1004_InitSelfTest(struct i2c_client *client) { int res = 0; u8 data,result; res = kxt_i2c_read_block(client, KXTIK1004_REG_CTL_REG3, &data, 0x1); if(res < 0) { return res; } //enable selftest bit data |= KXTIK1004_SELF_TEST; res = kxt_i2c_write_block(client, KXTIK1004_REG_CTL_REG3, &data, 0x1); if(res < 0) //0x2C->BW=100Hz { return res; } //step 1 res = kxt_i2c_read_block(client, KXTIK1004_DCST_RESP, &result, 0x1); if(res < 0) { return res; } GSE_LOG("step1: result = %x",result); if(result != 0xaa) return -EINVAL; //step 2 data |= KXTIK1004_SELF_TEST; res = kxt_i2c_write_block(client, KXTIK1004_REG_CTL_REG3, &data, 0x1); if(res < 0) //0x2C->BW=100Hz { return res; } //step 3 res = kxt_i2c_read_block(client, KXTIK1004_DCST_RESP, &result, 0x1); if(res < 0) { return res; } GSE_LOG("step3: result = %x",result); if(result != 0xAA) return -EINVAL; //step 4 res = kxt_i2c_read_block(client, KXTIK1004_DCST_RESP, &result, 0x1); if(res < 0) { return res; } GSE_LOG("step4: result = %x",result); if(result != 0x55) return -EINVAL; else return KXTIK1004_SUCCESS; } /*----------------------------------------------------------------------------*/ /*----------------------------------------------------------------------------*/ static ssize_t show_chipinfo_value(struct device_driver *ddri, char *buf) { struct i2c_client *client = kxtik1004_i2c_client; char strbuf[KXTIK1004_BUFSIZE]; if(NULL == client) { GSE_ERR("i2c client is null!!\n"); return 0; } KXTIK1004_ReadChipInfo(client, strbuf, KXTIK1004_BUFSIZE); return snprintf(buf, PAGE_SIZE, "%s\n", strbuf); } /*----------------------------------------------------------------------------*/ static ssize_t show_sensordata_value(struct device_driver *ddri, char *buf) { struct i2c_client *client = kxtik1004_i2c_client; char strbuf[KXTIK1004_BUFSIZE]; if(NULL == client) { GSE_ERR("i2c client is null!!\n"); return 0; } KXTIK1004_ReadSensorData(client, strbuf, KXTIK1004_BUFSIZE); return snprintf(buf, PAGE_SIZE, "%s\n", strbuf); } /*----------------------------------------------------------------------------*/ static ssize_t show_cali_value(struct device_driver *ddri, char *buf) { struct i2c_client *client = kxtik1004_i2c_client; struct kxtik1004_i2c_data *obj; int err, len = 0, mul; int tmp[KXTIK1004_AXES_NUM]; if(NULL == client) { GSE_ERR("i2c client is null!!\n"); return 0; } obj = i2c_get_clientdata(client); if((err = KXTIK1004_ReadOffset(client, obj->offset))) { return -EINVAL; } else if((err = KXTIK1004_ReadCalibration(client, tmp))) { return -EINVAL; } else { mul = obj->reso->sensitivity/kxtik1004_offset_resolution.sensitivity; len += snprintf(buf+len, PAGE_SIZE-len, "[HW ][%d] (%+3d, %+3d, %+3d) : (0x%02X, 0x%02X, 0x%02X)\n", mul, obj->offset[KXTIK1004_AXIS_X], obj->offset[KXTIK1004_AXIS_Y], obj->offset[KXTIK1004_AXIS_Z], obj->offset[KXTIK1004_AXIS_X], obj->offset[KXTIK1004_AXIS_Y], obj->offset[KXTIK1004_AXIS_Z]); len += snprintf(buf+len, PAGE_SIZE-len, "[SW ][%d] (%+3d, %+3d, %+3d)\n", 1, obj->cali_sw[KXTIK1004_AXIS_X], obj->cali_sw[KXTIK1004_AXIS_Y], obj->cali_sw[KXTIK1004_AXIS_Z]); len += snprintf(buf+len, PAGE_SIZE-len, "[ALL] (%+3d, %+3d, %+3d) : (%+3d, %+3d, %+3d)\n", obj->offset[KXTIK1004_AXIS_X]*mul + obj->cali_sw[KXTIK1004_AXIS_X], obj->offset[KXTIK1004_AXIS_Y]*mul + obj->cali_sw[KXTIK1004_AXIS_Y], obj->offset[KXTIK1004_AXIS_Z]*mul + obj->cali_sw[KXTIK1004_AXIS_Z], tmp[KXTIK1004_AXIS_X], tmp[KXTIK1004_AXIS_Y], tmp[KXTIK1004_AXIS_Z]); return len; } } /*----------------------------------------------------------------------------*/ static ssize_t store_cali_value(struct device_driver *ddri, const char *buf, size_t count) { struct i2c_client *client = kxtik1004_i2c_client; int err, x, y, z; int dat[KXTIK1004_AXES_NUM]; if(!strncmp(buf, "rst", 3)) { if((err = KXTIK1004_ResetCalibration(client))) { GSE_ERR("reset offset err = %d\n", err); } } else if(3 == sscanf(buf, "0x%02X 0x%02X 0x%02X", &x, &y, &z)) { dat[KXTIK1004_AXIS_X] = x; dat[KXTIK1004_AXIS_Y] = y; dat[KXTIK1004_AXIS_Z] = z; if((err = KXTIK1004_WriteCalibration(client, dat))) { GSE_ERR("write calibration err = %d\n", err); } } else { GSE_ERR("invalid format\n"); } return count; } /*----------------------------------------------------------------------------*/ static ssize_t show_self_value(struct device_driver *ddri, char *buf) { struct i2c_client *client = kxtik1004_i2c_client; if(NULL == client) { GSE_ERR("i2c client is null!!\n"); return 0; } return snprintf(buf, 8, "%s\n", selftestRes); } /*----------------------------------------------------------------------------*/ static ssize_t store_self_value(struct device_driver *ddri, const char *buf, size_t count) { /*write anything to this register will trigger the process*/ struct item{ s16 raw[KXTIK1004_AXES_NUM]; }; struct i2c_client *client = kxtik1004_i2c_client; int res, num; struct item *prv = NULL, *nxt = NULL; //s32 avg_prv[KXTIK1004_AXES_NUM] = {0, 0, 0}; //s32 avg_nxt[KXTIK1004_AXES_NUM] = {0, 0, 0}; u8 data; if(1 != sscanf(buf, "%d", &num)) { GSE_ERR("parse number fail\n"); return count; } else if(num == 0) { GSE_ERR("invalid data count\n"); return count; } prv = kzalloc(sizeof(*prv) * num, GFP_KERNEL); nxt = kzalloc(sizeof(*nxt) * num, GFP_KERNEL); if (!prv || !nxt) { goto exit; } GSE_LOG("NORMAL:\n"); KXTIK1004_SetPowerMode(client,true); /*initial setting for self test*/ if(!KXTIK1004_InitSelfTest(client)) { GSE_LOG("SELFTEST : PASS\n"); strcpy(selftestRes,"y"); } else { GSE_LOG("SELFTEST : FAIL\n"); strcpy(selftestRes,"n"); } res = kxt_i2c_read_block(client, KXTIK1004_REG_CTL_REG3, &data, 0x1); if(res < 0) { return res; } data &= ~KXTIK1004_SELF_TEST; res = kxt_i2c_write_block(client, KXTIK1004_REG_CTL_REG3, &data, 0x1); if(res < 0) //0x2C->BW=100Hz { return res; } exit: /*restore the setting*/ kxtik1004_init_client(client, 0); kfree(prv); kfree(nxt); return count; } /*----------------------------------------------------------------------------*/ static ssize_t show_selftest_value(struct device_driver *ddri, char *buf) { struct i2c_client *client = kxtik1004_i2c_client; struct kxtik1004_i2c_data *obj; if(NULL == client) { GSE_ERR("i2c client is null!!\n"); return 0; } obj = i2c_get_clientdata(client); return snprintf(buf, PAGE_SIZE, "%d\n", atomic_read(&obj->selftest)); } /*----------------------------------------------------------------------------*/ static ssize_t store_selftest_value(struct device_driver *ddri, const char *buf, size_t count) { struct kxtik1004_i2c_data *obj = obj_i2c_data; int tmp; if(NULL == obj) { GSE_ERR("i2c data obj is null!!\n"); return 0; } if(1 == sscanf(buf, "%d", &tmp)) { if(atomic_read(&obj->selftest) && !tmp) { /*enable -> disable*/ kxtik1004_init_client(obj->client, 0); } else if(!atomic_read(&obj->selftest) && tmp) { /*disable -> enable*/ KXTIK1004_InitSelfTest(obj->client); } GSE_LOG("selftest: %d => %d\n", atomic_read(&obj->selftest), tmp); atomic_set(&obj->selftest, tmp); } else { GSE_ERR("invalid content: '%s', length = %d\n", buf, count); } return count; } /*----------------------------------------------------------------------------*/ static ssize_t show_firlen_value(struct device_driver *ddri, char *buf) { #ifdef CONFIG_KXTIK1004_LOWPASS struct i2c_client *client = kxtik1004_i2c_client; struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); if(atomic_read(&obj->firlen)) { int idx, len = atomic_read(&obj->firlen); GSE_LOG("len = %2d, idx = %2d\n", obj->fir.num, obj->fir.idx); for(idx = 0; idx < len; idx++) { GSE_LOG("[%5d %5d %5d]\n", obj->fir.raw[idx][KXTIK1004_AXIS_X], obj->fir.raw[idx][KXTIK1004_AXIS_Y], obj->fir.raw[idx][KXTIK1004_AXIS_Z]); } GSE_LOG("sum = [%5d %5d %5d]\n", obj->fir.sum[KXTIK1004_AXIS_X], obj->fir.sum[KXTIK1004_AXIS_Y], obj->fir.sum[KXTIK1004_AXIS_Z]); GSE_LOG("avg = [%5d %5d %5d]\n", obj->fir.sum[KXTIK1004_AXIS_X]/len, obj->fir.sum[KXTIK1004_AXIS_Y]/len, obj->fir.sum[KXTIK1004_AXIS_Z]/len); } return snprintf(buf, PAGE_SIZE, "%d\n", atomic_read(&obj->firlen)); #else return snprintf(buf, PAGE_SIZE, "not support\n"); #endif } /*----------------------------------------------------------------------------*/ static ssize_t store_firlen_value(struct device_driver *ddri, const char *buf, size_t count) { #ifdef CONFIG_KXTIK1004_LOWPASS struct i2c_client *client = kxtik1004_i2c_client; struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); int firlen; if(1 != sscanf(buf, "%d", &firlen)) { GSE_ERR("invallid format\n"); } else if(firlen > C_MAX_FIR_LENGTH) { GSE_ERR("exceeds maximum filter length\n"); } else { atomic_set(&obj->firlen, firlen); if(0 == firlen) { atomic_set(&obj->fir_en, 0); } else { memset(&obj->fir, 0x00, sizeof(obj->fir)); atomic_set(&obj->fir_en, 1); } } #endif return count; } /*----------------------------------------------------------------------------*/ static ssize_t show_trace_value(struct device_driver *ddri, char *buf) { ssize_t res; struct kxtik1004_i2c_data *obj = obj_i2c_data; if (obj == NULL) { GSE_ERR("i2c_data obj is null!!\n"); return 0; } res = snprintf(buf, PAGE_SIZE, "0x%04X\n", atomic_read(&obj->trace)); return res; } /*----------------------------------------------------------------------------*/ static ssize_t store_trace_value(struct device_driver *ddri, const char *buf, size_t count) { struct kxtik1004_i2c_data *obj = obj_i2c_data; int trace; if (obj == NULL) { GSE_ERR("i2c_data obj is null!!\n"); return 0; } if(1 == sscanf(buf, "0x%x", &trace)) { atomic_set(&obj->trace, trace); } else { GSE_ERR("invalid content: '%s', length = %d\n", buf, count); } return count; } /*----------------------------------------------------------------------------*/ static ssize_t show_status_value(struct device_driver *ddri, char *buf) { ssize_t len = 0; struct kxtik1004_i2c_data *obj = obj_i2c_data; if (obj == NULL) { GSE_ERR("i2c_data obj is null!!\n"); return 0; } if(obj->hw) { len += snprintf(buf+len, PAGE_SIZE-len, "CUST: %d %d (%d %d)\n", obj->hw->i2c_num, obj->hw->direction, obj->hw->power_id, obj->hw->power_vol); } else { len += snprintf(buf+len, PAGE_SIZE-len, "CUST: NULL\n"); } return len; } /*----------------------------------------------------------------------------*/ static ssize_t show_power_status_value(struct device_driver *ddri, char *buf) { if(sensor_power) GSE_LOG("G sensor is in work mode, sensor_power = %d\n", sensor_power); else GSE_LOG("G sensor is in standby mode, sensor_power = %d\n", sensor_power); return 0; } /*----------------------------------------------------------------------------*/ static DRIVER_ATTR(chipinfo, S_IWUSR | S_IRUGO, show_chipinfo_value, NULL); static DRIVER_ATTR(sensordata, S_IWUSR | S_IRUGO, show_sensordata_value, NULL); static DRIVER_ATTR(cali, S_IWUSR | S_IRUGO, show_cali_value, store_cali_value); static DRIVER_ATTR(selftest, S_IWUSR | S_IRUGO, show_self_value, store_self_value); static DRIVER_ATTR(self, S_IWUSR | S_IRUGO, show_selftest_value, store_selftest_value); static DRIVER_ATTR(firlen, S_IWUSR | S_IRUGO, show_firlen_value, store_firlen_value); static DRIVER_ATTR(trace, S_IWUSR | S_IRUGO, show_trace_value, store_trace_value); static DRIVER_ATTR(status, S_IRUGO, show_status_value, NULL); static DRIVER_ATTR(powerstatus, S_IRUGO, show_power_status_value, NULL); /*----------------------------------------------------------------------------*/ static u8 i2c_dev_reg =0 ; static ssize_t show_register(struct device_driver *pdri, char *buf) { //int input_value; GSE_LOG("i2c_dev_reg is 0x%2x \n", i2c_dev_reg); return 0; } static ssize_t store_register(struct device_driver *ddri, const char *buf, size_t count) { //unsigned long input_value; i2c_dev_reg = simple_strtoul(buf, NULL, 16); GSE_LOG("set i2c_dev_reg = 0x%2x \n", i2c_dev_reg); return 0; } static ssize_t store_register_value(struct device_driver *ddri, const char *buf, size_t count) { struct kxtik1004_i2c_data *obj = obj_i2c_data; u8 databuf[2]; unsigned long input_value; int res; memset(databuf, 0, sizeof(u8)*2); input_value = simple_strtoul(buf, NULL, 16); GSE_LOG("input_value = 0x%2lx \n", input_value); if(NULL == obj) { GSE_ERR("i2c data obj is null!!\n"); return 0; } databuf[0] = input_value; GSE_LOG("databuf[0]=0x%2x databuf[1]=0x%2x \n", databuf[0],databuf[1]); res = kxt_i2c_write_block(obj->client, i2c_dev_reg, databuf, 0x1); if(res < 0) { return KXTIK1004_ERR_I2C; } return 0; } static ssize_t show_register_value(struct device_driver *ddri, char *buf) { struct kxtik1004_i2c_data *obj = obj_i2c_data; u8 databuf[1]; memset(databuf, 0, sizeof(u8)*1); if(NULL == obj) { GSE_ERR("i2c data obj is null!!\n"); return 0; } if(kxt_i2c_read_block(obj->client, i2c_dev_reg, databuf, 0x01)) { GSE_ERR("read power ctl register err!\n"); return KXTIK1004_ERR_I2C; } GSE_LOG("i2c_dev_reg=0x%2x data=0x%2x \n", i2c_dev_reg,databuf[0]); return 0; } static DRIVER_ATTR(i2c, S_IWUSR | S_IRUGO, show_register_value, store_register_value); static DRIVER_ATTR(register, S_IWUSR | S_IRUGO, show_register, store_register); /*----------------------------------------------------------------------------*/ static struct driver_attribute *kxtik1004_attr_list[] = { &driver_attr_chipinfo, /*chip information*/ &driver_attr_sensordata, /*dump sensor data*/ &driver_attr_cali, /*show calibration data*/ &driver_attr_self, /*self test demo*/ &driver_attr_selftest, /*self control: 0: disable, 1: enable*/ &driver_attr_firlen, /*filter length: 0: disable, others: enable*/ &driver_attr_trace, /*trace log*/ &driver_attr_status, &driver_attr_powerstatus, &driver_attr_register, &driver_attr_i2c, }; /*----------------------------------------------------------------------------*/ static int kxtik1004_create_attr(struct device_driver *driver) { int idx, err = 0; int num = (int)(sizeof(kxtik1004_attr_list)/sizeof(kxtik1004_attr_list[0])); if (driver == NULL) { return -EINVAL; } for(idx = 0; idx < num; idx++) { if((err = driver_create_file(driver, kxtik1004_attr_list[idx]))) { GSE_ERR("driver_create_file (%s) = %d\n", kxtik1004_attr_list[idx]->attr.name, err); break; } } return err; } /*----------------------------------------------------------------------------*/ static int kxtik1004_delete_attr(struct device_driver *driver) { int idx ,err = 0; int num = (int)(sizeof(kxtik1004_attr_list)/sizeof(kxtik1004_attr_list[0])); if(driver == NULL) { return -EINVAL; } for(idx = 0; idx < num; idx++) { driver_remove_file(driver, kxtik1004_attr_list[idx]); } return err; } /*----------------------------------------------------------------------------*/ int gsensor_operate(void* self, uint32_t command, void* buff_in, int size_in, void* buff_out, int size_out, int* actualout) { int err = 0; int value, sample_delay; struct kxtik1004_i2c_data *priv = (struct kxtik1004_i2c_data*)self; hwm_sensor_data* gsensor_data; char buff[KXTIK1004_BUFSIZE]; //GSE_FUN(f); switch (command) { case SENSOR_DELAY: if((buff_in == NULL) || (size_in < sizeof(int))) { GSE_ERR("Set delay parameter error!\n"); err = -EINVAL; } else { value = *(int *)buff_in; if(value <= 5) { sample_delay = KXTIK1004_BW_200HZ; } else if(value <= 10) { sample_delay = KXTIK1004_BW_100HZ; } else { sample_delay = KXTIK1004_BW_50HZ; } mutex_lock(&kxtik1004_op_mutex); err = KXTIK1004_SetBWRate(priv->client, sample_delay); if(err != KXTIK1004_SUCCESS ) //0x2C->BW=100Hz { GSE_ERR("Set delay parameter error!\n"); } mutex_unlock(&kxtik1004_op_mutex); if(value >= 50) { atomic_set(&priv->filter, 0); } else { #if defined(CONFIG_KXTIK1004_LOWPASS) priv->fir.num = 0; priv->fir.idx = 0; priv->fir.sum[KXTIK1004_AXIS_X] = 0; priv->fir.sum[KXTIK1004_AXIS_Y] = 0; priv->fir.sum[KXTIK1004_AXIS_Z] = 0; atomic_set(&priv->filter, 1); #endif } } break; case SENSOR_ENABLE: if((buff_in == NULL) || (size_in < sizeof(int))) { GSE_ERR("Enable sensor parameter error!\n"); err = -EINVAL; } else { value = *(int *)buff_in; mutex_lock(&kxtik1004_op_mutex); GSE_LOG("Gsensor device enable function enable = %d, sensor_power = %d!\n",value,sensor_power); if(((value == 0) && (sensor_power == false)) ||((value == 1) && (sensor_power == true))) { enable_status = sensor_power; GSE_LOG("Gsensor device have updated!\n"); } else { enable_status = !sensor_power; err = KXTIK1004_SetPowerMode( priv->client, !sensor_power); GSE_LOG("Gsensor not in suspend BMA222_SetPowerMode!, enable_status = %d\n",enable_status); } mutex_unlock(&kxtik1004_op_mutex); } break; case SENSOR_GET_DATA: if((buff_out == NULL) || (size_out< sizeof(hwm_sensor_data))) { GSE_ERR("get sensor data parameter error!\n"); err = -EINVAL; } else { mutex_lock(&kxtik1004_op_mutex); gsensor_data = (hwm_sensor_data *)buff_out; KXTIK1004_ReadSensorData(priv->client, buff, KXTIK1004_BUFSIZE); sscanf(buff, "%x %x %x", &gsensor_data->values[0], &gsensor_data->values[1], &gsensor_data->values[2]); gsensor_data->status = SENSOR_STATUS_ACCURACY_MEDIUM; gsensor_data->value_divide = 1000; mutex_unlock(&kxtik1004_op_mutex); } break; default: GSE_ERR("gsensor operate function no this parameter %d!\n", command); err = -1; break; } return err; } /****************************************************************************** * Function Configuration ******************************************************************************/ static int kxtik1004_open(struct inode *inode, struct file *file) { file->private_data = kxtik1004_i2c_client; if(file->private_data == NULL) { GSE_ERR("null pointer!!\n"); return -EINVAL; } return nonseekable_open(inode, file); } /*----------------------------------------------------------------------------*/ static int kxtik1004_release(struct inode *inode, struct file *file) { file->private_data = NULL; return 0; } /*----------------------------------------------------------------------------*/ static long kxtik1004_unlocked_ioctl(struct file *file, unsigned int cmd,unsigned long arg) { struct i2c_client *client = (struct i2c_client*)file->private_data; struct kxtik1004_i2c_data *obj = (struct kxtik1004_i2c_data*)i2c_get_clientdata(client); char strbuf[KXTIK1004_BUFSIZE]; void __user *data; SENSOR_DATA sensor_data; long err = 0; int cali[3]; //GSE_FUN(f); if(_IOC_DIR(cmd) & _IOC_READ) { err = !access_ok(VERIFY_WRITE, (void __user *)arg, _IOC_SIZE(cmd)); } else if(_IOC_DIR(cmd) & _IOC_WRITE) { err = !access_ok(VERIFY_READ, (void __user *)arg, _IOC_SIZE(cmd)); } if(err) { GSE_ERR("access error: %08X, (%2d, %2d)\n", cmd, _IOC_DIR(cmd), _IOC_SIZE(cmd)); return -EFAULT; } switch(cmd) { case GSENSOR_IOCTL_INIT: kxtik1004_init_client(client, 0); break; case GSENSOR_IOCTL_READ_CHIPINFO: data = (void __user *) arg; if(data == NULL) { err = -EINVAL; break; } KXTIK1004_ReadChipInfo(client, strbuf, KXTIK1004_BUFSIZE); if(copy_to_user(data, strbuf, strlen(strbuf)+1)) { err = -EFAULT; break; } break; case GSENSOR_IOCTL_READ_SENSORDATA: data = (void __user *) arg; if(data == NULL) { err = -EINVAL; break; } KXTIK1004_SetPowerMode(client,true); KXTIK1004_ReadSensorData(client, strbuf, KXTIK1004_BUFSIZE); if(copy_to_user(data, strbuf, strlen(strbuf)+1)) { err = -EFAULT; break; } break; case GSENSOR_IOCTL_READ_GAIN: data = (void __user *) arg; if(data == NULL) { err = -EINVAL; break; } if(copy_to_user(data, &gsensor_gain, sizeof(GSENSOR_VECTOR3D))) { err = -EFAULT; break; } break; case GSENSOR_IOCTL_READ_RAW_DATA: data = (void __user *) arg; if(data == NULL) { err = -EINVAL; break; } KXTIK1004_ReadRawData(client, strbuf); if(copy_to_user(data, &strbuf, strlen(strbuf)+1)) { err = -EFAULT; break; } break; case GSENSOR_IOCTL_SET_CALI: data = (void __user*)arg; if(data == NULL) { err = -EINVAL; break; } if(copy_from_user(&sensor_data, data, sizeof(sensor_data))) { err = -EFAULT; break; } if(atomic_read(&obj->suspend)) { GSE_ERR("Perform calibration in suspend state!!\n"); err = -EINVAL; } else { #if 0 cali[KXTIK1004_AXIS_X] = sensor_data.x * obj->reso->sensitivity / GRAVITY_EARTH_1000; cali[KXTIK1004_AXIS_Y] = sensor_data.y * obj->reso->sensitivity / GRAVITY_EARTH_1000; cali[KXTIK1004_AXIS_Z] = sensor_data.z * obj->reso->sensitivity / GRAVITY_EARTH_1000; #else cali[KXTIK1004_AXIS_X] = sensor_data.x; cali[KXTIK1004_AXIS_Y] = sensor_data.y; cali[KXTIK1004_AXIS_Z] = sensor_data.z; #endif err = KXTIK1004_WriteCalibration(client, cali); } break; case GSENSOR_IOCTL_CLR_CALI: err = KXTIK1004_ResetCalibration(client); break; case GSENSOR_IOCTL_GET_CALI: data = (void __user*)arg; if(data == NULL) { err = -EINVAL; break; } if((err = KXTIK1004_ReadCalibration(client, cali))) { break; } #if 0 sensor_data.x = cali[KXTIK1004_AXIS_X] * GRAVITY_EARTH_1000 / obj->reso->sensitivity; sensor_data.y = cali[KXTIK1004_AXIS_Y] * GRAVITY_EARTH_1000 / obj->reso->sensitivity; sensor_data.z = cali[KXTIK1004_AXIS_Z] * GRAVITY_EARTH_1000 / obj->reso->sensitivity; #else sensor_data.x = cali[KXTIK1004_AXIS_X]; sensor_data.y = cali[KXTIK1004_AXIS_Y]; sensor_data.z = cali[KXTIK1004_AXIS_Z]; #endif if(copy_to_user(data, &sensor_data, sizeof(sensor_data))) { err = -EFAULT; break; } break; default: GSE_ERR("unknown IOCTL: 0x%08x\n", cmd); err = -ENOIOCTLCMD; break; } return err; } /*----------------------------------------------------------------------------*/ static struct file_operations kxtik1004_fops = { .owner = THIS_MODULE, .open = kxtik1004_open, .release = kxtik1004_release, .unlocked_ioctl = kxtik1004_unlocked_ioctl, }; /*----------------------------------------------------------------------------*/ static struct miscdevice kxtik1004_device = { .minor = MISC_DYNAMIC_MINOR, .name = "gsensor", .fops = &kxtik1004_fops, }; /*----------------------------------------------------------------------------*/ #ifndef USE_EARLY_SUSPEND /*----------------------------------------------------------------------------*/ static int kxtik1004_suspend(struct i2c_client *client, pm_message_t msg) { struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); int err = 0; GSE_FUN(); mutex_lock(&kxtik1004_op_mutex); if(msg.event == PM_EVENT_SUSPEND) { if(obj == NULL) { GSE_ERR("null pointer!!\n"); mutex_unlock(&kxtik1004_op_mutex); return -EINVAL; } atomic_set(&obj->suspend, 1); if((err = KXTIK1004_SetPowerMode(obj->client, false))) { GSE_ERR("write power control fail!!\n"); mutex_unlock(&kxtik1004_op_mutex); return err; } KXTIK1004_power(obj->hw, 0); } sensor_suspend = 1; mutex_unlock(&kxtik1004_op_mutex); return err; } /*----------------------------------------------------------------------------*/ static int kxtik1004_resume(struct i2c_client *client) { struct kxtik1004_i2c_data *obj = i2c_get_clientdata(client); int err; GSE_FUN(); if(obj == NULL) { GSE_ERR("null pointer!!\n"); return -EINVAL; } mutex_lock(&kxtik1004_op_mutex); KXTIK1004_power(obj->hw, 1); if((err = kxtik1004_init_client(client, 0))) { GSE_ERR("initialize client fail!!\n"); mutex_unlock(&kxtik1004_op_mutex); return err; } sensor_suspend = 0; atomic_set(&obj->suspend, 0); mutex_unlock(&kxtik1004_op_mutex); return 0; } /*----------------------------------------------------------------------------*/ #else /*CONFIG_HAS_EARLY_SUSPEND is defined*/ /*----------------------------------------------------------------------------*/ static void kxtik1004_early_suspend(struct early_suspend *h) { struct kxtik1004_i2c_data *obj = container_of(h, struct kxtik1004_i2c_data, early_drv); int err; GSE_FUN(); if(obj == NULL) { GSE_ERR("null pointer!!\n"); return; } atomic_set(&obj->suspend, 1); mutex_lock(&kxtik1004_op_mutex); if((err = KXTIK1004_SetPowerMode(obj->client, false))) { GSE_ERR("write power control fail!!\n"); mutex_unlock(&kxtik1004_op_mutex); return; } sensor_suspend = 1; mutex_unlock(&kxtik1004_op_mutex); KXTIK1004_power(obj->hw, 0); } /*----------------------------------------------------------------------------*/ static void kxtik1004_late_resume(struct early_suspend *h) { struct kxtik1004_i2c_data *obj = container_of(h, struct kxtik1004_i2c_data, early_drv); int err; GSE_FUN(); if(obj == NULL) { GSE_ERR("null pointer!!\n"); return; } KXTIK1004_power(obj->hw, 1); mutex_lock(&kxtik1004_op_mutex); if((err = kxtik1004_init_client(obj->client, 0))) { GSE_ERR("initialize client fail!!\n"); mutex_unlock(&kxtik1004_op_mutex); return; } sensor_suspend = 0; mutex_unlock(&kxtik1004_op_mutex); atomic_set(&obj->suspend, 0); } /*----------------------------------------------------------------------------*/ #endif /*CONFIG_HAS_EARLYSUSPEND*/ /*----------------------------------------------------------------------------*/ static int kxtik1004_i2c_detect(struct i2c_client *client, struct i2c_board_info *info) { strcpy(info->type, KXTIK1004_DEV_NAME); return 0; } /*----------------------------------------------------------------------------*/ static int kxtik1004_i2c_probe(struct i2c_client *client, const struct i2c_device_id *id) { struct i2c_client *new_client; struct kxtik1004_i2c_data *obj; struct hwmsen_object sobj; int err = 0; int retry = 0; GSE_FUN(); if(!(obj = kzalloc(sizeof(*obj), GFP_KERNEL))) { err = -ENOMEM; goto exit; } memset(obj, 0, sizeof(struct kxtik1004_i2c_data)); obj->hw = get_cust_acc_hw(); if((err = hwmsen_get_convert(obj->hw->direction, &obj->cvt))) { GSE_ERR("invalid direction: %d\n", obj->hw->direction); goto exit; } obj_i2c_data = obj; obj->client = client; new_client = obj->client; i2c_set_clientdata(new_client,obj); atomic_set(&obj->trace, 0); atomic_set(&obj->suspend, 0); #ifdef CONFIG_KXTIK1004_LOWPASS if(obj->hw->firlen > C_MAX_FIR_LENGTH) { atomic_set(&obj->firlen, C_MAX_FIR_LENGTH); } else { atomic_set(&obj->firlen, obj->hw->firlen); } if(atomic_read(&obj->firlen) > 0) { atomic_set(&obj->fir_en, 1); } #endif kxtik1004_i2c_client = new_client; for(retry = 0; retry < 3; retry++){ if((err = kxtik1004_init_client(new_client, 1))) { GSE_ERR("kxtik1004_device init cilent fail time: %d\n", retry); continue; } } if(err != 0) goto exit_init_failed; if((err = misc_register(&kxtik1004_device))) { GSE_ERR("kxtik1004_device register failed\n"); goto exit_misc_device_register_failed; } if((err = kxtik1004_create_attr(&kxtik1004_gsensor_driver.driver))) { GSE_ERR("create attribute err = %d\n", err); goto exit_create_attr_failed; } sobj.self = obj; sobj.polling = 1; sobj.sensor_operate = gsensor_operate; if((err = hwmsen_attach(ID_ACCELEROMETER, &sobj))) { GSE_ERR("attach fail = %d\n", err); goto exit_kfree; } #ifdef USE_EARLY_SUSPEND obj->early_drv.level = EARLY_SUSPEND_LEVEL_STOP_DRAWING - 2, obj->early_drv.suspend = kxtik1004_early_suspend, obj->early_drv.resume = kxtik1004_late_resume, register_early_suspend(&obj->early_drv); #endif GSE_LOG("%s: OK\n", __func__); return 0; exit_create_attr_failed: misc_deregister(&kxtik1004_device); exit_misc_device_register_failed: exit_init_failed: //i2c_detach_client(new_client); exit_kfree: kfree(obj); exit: GSE_ERR("%s: err = %d\n", __func__, err); return err; } /*----------------------------------------------------------------------------*/ static int kxtik1004_i2c_remove(struct i2c_client *client) { int err = 0; if((err = kxtik1004_delete_attr(&kxtik1004_gsensor_driver.driver))) { GSE_ERR("kxtik1004_delete_attr fail: %d\n", err); } if((err = misc_deregister(&kxtik1004_device))) { GSE_ERR("misc_deregister fail: %d\n", err); } if((err = hwmsen_detach(ID_ACCELEROMETER))) kxtik1004_i2c_client = NULL; i2c_unregister_device(client); kfree(i2c_get_clientdata(client)); return 0; } /*----------------------------------------------------------------------------*/ static int kxtik1004_probe(struct platform_device *pdev) { struct acc_hw *hw = get_cust_acc_hw(); GSE_FUN(); KXTIK1004_power(hw, 1); if(i2c_add_driver(&kxtik1004_i2c_driver)) { GSE_ERR("add driver error\n"); return -1; } return 0; } /*----------------------------------------------------------------------------*/ static int kxtik1004_remove(struct platform_device *pdev) { struct acc_hw *hw = get_cust_acc_hw(); GSE_FUN(); KXTIK1004_power(hw, 0); i2c_del_driver(&kxtik1004_i2c_driver); return 0; } /*----------------------------------------------------------------------------*/ #if 1 #ifdef CONFIG_OF static const struct of_device_id gsensor_of_match[] = { { .compatible = "mediatek,gsensor", }, {}, }; #endif static struct platform_driver kxtik1004_gsensor_driver = { .probe = kxtik1004_probe, .remove = kxtik1004_remove, .driver = { .name = "gsensor", .owner = THIS_MODULE, #ifdef CONFIG_OF .of_match_table = gsensor_of_match, #endif } }; #else static struct platform_driver kxtik1004_gsensor_driver = { .probe = kxtik1004_probe, .remove = kxtik1004_remove, .driver = { .name = "gsensor", .owner = THIS_MODULE, } }; #endif /*----------------------------------------------------------------------------*/ static int __init kxtik1004_init(void) { struct acc_hw *hw = get_cust_acc_hw(); GSE_FUN(); GSE_LOG("%s: i2c_number=%d\n", __func__,hw->i2c_num); if (hw->i2c_addr[0]) { GSE_LOG("%s: i2c_slave_addr=%d\n", __func__,hw->i2c_addr[0]); i2c_kxtik1004.addr = hw->i2c_addr[0]>>1; } i2c_register_board_info(hw->i2c_num, &i2c_kxtik1004, 1); if(platform_driver_register(&kxtik1004_gsensor_driver)) { GSE_ERR("failed to register driver"); return -ENODEV; } return 0; } /*----------------------------------------------------------------------------*/ static void __exit kxtik1004_exit(void) { GSE_FUN(); platform_driver_unregister(&kxtik1004_gsensor_driver); } /*----------------------------------------------------------------------------*/ module_init(kxtik1004_init); module_exit(kxtik1004_exit); /*----------------------------------------------------------------------------*/ MODULE_LICENSE("GPL"); MODULE_DESCRIPTION("KXTIK1004 I2C driver"); MODULE_AUTHOR("Dexiang.Liu@mediatek.com");