/* This function called by vpif driver to initialize the decoder with default
* values
*/
static int mt9t001_initialize(void *dec, int flag)
{
int err = 0;
int ch_id;
v4l2_std_id std;
int index;
struct i2c_client *ch_client;
if (NULL == dec) {
printk(KERN_ERR "dec:NULL pointer");
return -EINVAL;
}
ch_id = ((struct decoder_device *)dec)->channel_id;
ch_client = &mt9t001_channel_info[ch_id].i2c_dev.client;
if (mt9t001_channel_info[ch_id].i2c_dev.i2c_registration & 0x01) {
printk(KERN_ERR "MT9T001 driver is already initialized..\n");
err = -EINVAL;
return err;
}
/* Register MT9T001 I2C client */
err |= i2c_add_driver(&mt9t001_channel_info[ch_id].i2c_dev.driver);
if (err) {
printk(KERN_ERR "Failed to register MT9T001 I2C client.\n");
return -EINVAL;
}
mt9t001_channel_info[ch_id].i2c_dev.i2c_registration |= 0x1;
mt9t001_channel_info[ch_id].dec_device = (struct decoder_device *)dec;
dev_dbg(mt9t001_i2c_dev[ch_id], "Mt9t001 driver registered\n");
if (DECODER_I2C_BIND_FLAG == flag) {
/* check that decoder is set with default values once or not,
* if yes return, if not continue */
if (mt9t001_channel_info[ch_id].i2c_dev.i2c_registration & 0x02)
return err;
}
dev_dbg(mt9t001_i2c_dev[ch_id], "Starting mt9t001_init....\n");
if (mt9xxx_set_input_mux(0) < 0)
dev_dbg(mt9t001_i2c_dev[ch_id], "Video Mux setting failed\n");
msleep(100);
/*Configure the MT9T001 in normalpower up mode */
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_ROW_START,
MT9T001_ROW_START_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_COL_START,
MT9T001_COLUMN_START_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_WIDTH,
MT9T001_ROW_SIZE_DEFAULT, MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_HEIGHT,
MT9T001_COLUMN_SIZE_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_HBLANK,
MT9T001_HOR_BLANK_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_VBLANK,
MT9T001_VER_BLANK_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_OUTPUT_CTRL,
MT9T001_OUTPUT_CTRL_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_SHUTTER_WIDTH_UPPER,
MT9T001_SHUTTER_WIDTH_UPPER_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_SHUTTER_WIDTH,
MT9T001_SHUTTER_WIDTH_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_PIXEL_CLK_CTRL,
MT9T001_PIXEL_CLK_CTRL_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_RESTART,
MT9T001_FRAME_RESTART_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_SHUTTER_DELAY,
MT9T001_SHUTTER_DELAY_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_READ_MODE1,
MT9T001_READ_MODE1_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_READ_MODE2,
MT9T001_READ_MODE2_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_READ_MODE3,
MT9T001_READ_MODE3_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_ROW_ADDR_MODE,
MT9T001_ROW_ADDR_MODE_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_COL_ADDR_MODE,
MT9T001_COL_ADDR_MODE_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_GREEN1_GAIN,
MT9T001_GREEN1_GAIN_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_BLUE_GAIN,
MT9T001_BLUE_GAIN_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_RED_GAIN,
MT9T001_RED_GAIN_DEFAULT, MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_GREEN2_GAIN,
MT9T001_GREEN2_GAIN_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_GLOBAL_GAIN,
MT9T001_GLOBAL_GAIN_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_BLACK_LEVEL,
MT9T001_BLACK_LEVEL_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_CAL_COARSE,
MT9T001_CAL_COARSE_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_CAL_TARGET,
MT9T001_CAL_TARGET_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_GREEN1_OFFSET,
MT9T001_GREEN1_OFFSET_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_GREEN2_OFFSET,
MT9T001_GREEN2_OFFSET_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_RED_OFFSET,
MT9T001_RED_OFFSET_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_BLUE_OFFSET,
MT9T001_BLUE_OFFSET_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_BLK_LVL_CALIB,
MT9T001_BLK_LVL_CALIB_DEFAULT,
MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_CHIP_ENABLE_SYNC,
MT9T001_CHIP_ENABLE_SYNC_DEFAULT,
MT9T001_I2C_CONFIG);
/* Reset the sensor to be in default power up state */
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_RESET,
MT9T001_RESET_ENABLE, MT9T001_I2C_CONFIG);
/* Clear the bit to resume normal operation */
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_RESET,
MT9T001_RESET_DISABLE, MT9T001_I2C_CONFIG);
/* delay applying changes */
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_OUTPUT_CTRL,
MT9T001_N0_CHANGE_MODE, MT9T001_I2C_CONFIG);
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_PIXEL_CLK_CTRL,
MT9T001_PIX_CLK_RISING, MT9T001_I2C_CONFIG);
/*Configure the MT9T001 in normalpower up mode */
err |=
mt9t001_i2c_write_reg(ch_client, MT9T001_OUTPUT_CTRL,
MT9T001_NORMAL_OPERATION_MODE,
MT9T001_I2C_CONFIG);
/* call set standard */
std = mt9t001_channel_info[ch_id].params.std;
err |= mt9t001_setstd(&std, dec);
/* call query standard */
err |= mt9t001_querystd(&std, dec);
/* call get input */
err |= mt9t001_getinput(&index, dec);
/* Configure for default video standard */
if (err < 0) {
err = -EINVAL;
mt9t001_deinitialize(dec);
return err;
}
mt9t001_channel_info[ch_id].i2c_dev.i2c_registration |= 0x2;
dev_dbg(mt9t001_i2c_dev[ch_id], "End of mt9t001_init.\n");
return err;
}
/* This function will configure MT9T001 for bayer pattern capture */
static int mt9t001_setparams(void *params, void *dec)
{
int err = 0;
unsigned short val;
int ch_id;
struct mt9t001_params *mt9t_params = (struct mt9t001_params *) params;
if (NULL == dec) {
printk(KERN_ERR "NULL Pointer\n");
return -EINVAL;
}
ch_id = ((struct decoder_device *)dec)->channel_id;
dev_dbg(mt9t001_i2c_dev[ch_id],
"Start of mt9t001 set params function.\n");
/* check for null pointer */
if (mt9t_params == NULL) {
dev_err(mt9t001_i2c_dev[ch_id], "Null pointer.\n");
return -EINVAL;
}
err |= mt9t001_setinput(&(mt9t_params->inputidx), dec);
if (err < 0) {
dev_dbg(mt9t001_i2c_dev[ch_id],
"Set format parameters failed.\n");
return err;
}
err |= mt9t001_setstd(&(mt9t_params->std), dec);
if (err < 0) {
dev_dbg(mt9t001_i2c_dev[ch_id],
"Set format parameters failed.\n");
return err;
}
/* set video format related parameters */
err = mt9t001_set_format_params(&mt9t_params->format, dec);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id],
"Set format parameters failed.\n");
return err;
}
/*Write the gain information */
val = (unsigned short)(mt9t_params->rgb_gain.
green1_analog_gain & MT9T001_ANALOG_GAIN_MASK);
val |= ((mt9t_params->rgb_gain.
green1_digital_gain << MT9T001_DIGITAL_GAIN_SHIFT) &
MT9T001_DIGITAL_GAIN_MASK);
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_GREEN1_GAIN, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails....\n");
return err;
}
val = (unsigned short)(mt9t_params->rgb_gain.red_analog_gain)
& MT9T001_ANALOG_GAIN_MASK;
val |= (((mt9t_params->rgb_gain.red_digital_gain)
<< MT9T001_DIGITAL_GAIN_SHIFT)
& MT9T001_DIGITAL_GAIN_MASK);
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_RED_GAIN, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails...\n");
return err;
}
val = (unsigned short)(mt9t_params->rgb_gain.blue_analog_gain)
& MT9T001_ANALOG_GAIN_MASK;
val |= (((mt9t_params->rgb_gain.blue_digital_gain)
<< MT9T001_DIGITAL_GAIN_SHIFT)
& MT9T001_DIGITAL_GAIN_MASK);
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_BLUE_GAIN, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails...\n");
return err;
}
val = (unsigned short)((mt9t_params->rgb_gain.green2_analog_gain)
<< MT9T001_ANALOG_GAIN_SHIFT) &
MT9T001_ANALOG_GAIN_MASK;
val |= (((mt9t_params->rgb_gain.
green2_digital_gain) << MT9T001_DIGITAL_GAIN_SHIFT) &
MT9T001_DIGITAL_GAIN_MASK);
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_GREEN2_GAIN, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails...\n");
return err;
}
/*Write the offset value in register */
val = mt9t_params->black_calib.green1_offset
& MT9T001_GREEN1_OFFSET_MASK;
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_GREEN1_OFFSET, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails...\n");
return err;
}
val = mt9t_params->black_calib.green2_offset
& MT9T001_GREEN2_OFFSET_MASK;
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_GREEN2_OFFSET, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails...\n");
return err;
}
val = mt9t_params->black_calib.red_offset & MT9T001_RED_OFFSET_MASK;
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_RED_OFFSET, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails...\n");
return err;
}
val = mt9t_params->black_calib.blue_offset & MT9T001_BLUE_OFFSET_MASK;
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_BLUE_OFFSET, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails...\n");
return err;
}
/*Write other black caliberation information */
val = (unsigned short)(mt9t_params->black_calib.manual_override)
& MT9T001_MANUAL_OVERRIDE_MASK;
val |= ((mt9t_params->black_calib.
disable_calibration) << MT9T001_DISABLE_CALLIBERATION_SHIFT)
& MT9T001_DISABLE_CALLIBERATION_MASK;
val |= ((mt9t_params->black_calib.
recalculate_black_level) << MT9T001_RECAL_BLACK_LEVEL_SHIFT)
& MT9T001_RECAL_BLACK_LEVEL_MASK;
val |= ((mt9t_params->black_calib.lock_red_blue_calibration)
<< MT9T001_LOCK_RB_CALIBRATION_SHIFT)
& MT9T001_LOCK_RB_CALLIBERATION_MASK;
val |= ((mt9t_params->black_calib.lock_green_calibration)
<< MT9T001_LOCK_GREEN_CALIBRATION_SHIFT)
& MT9T001_LOCK_GREEN_CALLIBERATION_MASK;
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_BLK_LVL_CALIB, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails...\n");
return err;
}
/*Write Thresholds Value */
val = (unsigned short)mt9t_params->black_calib.
low_coarse_thrld & MT9T001_LOW_COARSE_THELD_MASK;
val |= (mt9t_params->black_calib.
high_coarse_thrld << MT9T001_HIGH_COARSE_THELD_SHIFT) &
MT9T001_HIGH_COARSE_THELD_MASK;
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_CAL_COARSE, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails...\n");
return err;
}
val = (unsigned short)mt9t_params->black_calib.low_target_thrld
& MT9T001_LOW_TARGET_THELD_MASK;
val |= (mt9t_params->black_calib.high_target_thrld
<< MT9T001_HIGH_TARGET_THELD_SHIFT)
& MT9T001_HIGH_TARGET_THELD_MASK;
err = mt9t001_i2c_write_reg(&mt9t001_channel_info[ch_id].i2c_dev.
client, MT9T001_CAL_TARGET, val,
MT9T001_I2C_CONFIG);
if (err < 0) {
dev_err(mt9t001_i2c_dev[ch_id], "I2C write fails...\n");
return err;
}
mt9t001_channel_info[ch_id].params = *mt9t_params;
dev_dbg(mt9t001_i2c_dev[ch_id], "End of mt9t001 set params...\n");
return err;
}
/*This function will provide different control commands for MT9T001
configuration.*/
int mt9t001_ctrl(unsigned int cmd, void *arg, void *params)
{
int err = 0;
printk("WARNING ... Here is in MT9T001 CTRL Func...\n");
switch (cmd) {
case MT9T001_SET_PARAMS:
{
struct mt9t001_params *vpfe_mt9t001params =
(struct mt9t001_params *)params;
struct mt9t001_params *user_mt9t001params =
(struct mt9t001_params *)arg;
/* Update the global parameter of vpfe_obj */
if ((arg == NULL) || (params == NULL)) {
dev_err(mt9t001_i2c_dev, "Invalid argument for \
MT9T001_SET_PARAMS ");
return -1;
}
memcpy(vpfe_mt9t001params, user_mt9t001params,
sizeof(struct mt9t001_params));
err = mt9t001_setparams(arg);
if (err < 0) {
dev_err(mt9t001_i2c_dev,
"\nMT9T001 set parameters fails...");
return err;
}
break;
}
case MT9T001_SET_STD:
{
err = mt9t001_setstd(arg, params);
if (err < 0) {
dev_err(mt9t001_i2c_dev,
"\nMT9T001 set standard fails...");
return err;
} else {
//mt9t001_readregs();
}
break;
}
case MT9T001_GET_PARAMS:
{
struct mt9t001_params *vpfe_mt9t001params =
(struct mt9t001_params *)params;
struct mt9t001_params *user_mt9t001params =
(struct mt9t001_params *)arg;
err = mt9t001_getparams(arg);
if (err < 0) {
dev_err(mt9t001_i2c_dev,
"\nMT9T001 get parameters fails...");
return err;
}
/* Update the global parameter of vpfe_obj */
memcpy(vpfe_mt9t001params, user_mt9t001params,
sizeof(struct mt9t001_params));
break;
}
case MT9T001_ENABLE_I2C_SWITCH:
/* enable the i2c switch on the MT9T031 head board */
CONFIG_PCA9543A = 1;
break;
case MT9T001_INIT:
{
err = mt9t001_init(arg, params);
if (err < 0) {
printk(KERN_ERR
"\n Unable to initialize MT9T001...");
return err;
}
break;
}
case MT9T001_CLEANUP:
{
mt9t001_cleanup(params);
break;
}
case VIDIOC_S_CTRL:
{
struct v4l2_control *ctrl = arg;
if (ctrl->id == V4L2_CID_GAIN) {
err = mt9t001_setgain((int)ctrl->value);
if (err < 0) {
dev_err(mt9t001_i2c_dev,
"\n MT9T001 set gain fails...");
return err;
}
} else {
err = -EINVAL;
}
break;
}
case VIDIOC_G_CTRL:
{
struct v4l2_control *ctrl = arg;
if (ctrl->id == V4L2_CID_GAIN) {
err = mt9t001_getgain((int *)
&(ctrl->value));
if (err < 0) {
dev_err(mt9t001_i2c_dev,
"\n MT9T001 get gain fails...");
return err;
}
} else {
err = -EINVAL;
}
break;
}
case VIDIOC_QUERYCTRL:
{
err = mt9t001_queryctrl(arg);
break;
}
default:
{
dev_err(mt9t001_i2c_dev, "\n Undefined command");
return -1;
}
}
