/* This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #include #include "GPIO.h" #if CONFIG_HAL_BOARD_SUBTYPE == HAL_BOARD_SUBTYPE_LINUX_BEBOP #include "CameraSensor_Mt9v117.h" /* Cam sensor register definitions */ #define CHIP_ID 0x0 #define MT9V117_CHIP_ID 0x2282 #define COMMAND_REGISTER 0x0040 #define HOST_COMMAND_OK (1 << 15) #define HOST_COMMAND_2 (1 << 2) #define HOST_COMMAND_1 (1 << 1) #define HOST_COMMAND_0 (1 << 0) #define PAD_SLEW 0x0030 #define RESET_AND_MISC_CONTROL 0x001a #define RESET_SOC_I2C (1 << 0) #define ACCESS_CTL_STAT 0x0982 #define PHYSICAL_ADDRESS_ACCESS 0x098a #define LOGICAL_ADDRESS_ACCESS 0x098e #define AE_TRACK_JUMP_DIVISOR 0xa812 #define CAM_AET_SKIP_FRAMES 0xc868 #define AE_RULE_VAR 9 #define AE_RULE_ALGO_OFFSET 4 #define AE_RULE_ALGO_AVERAGE 0 #define AE_RULE_ALGO_WEIGHTED 1 #define AE_TRACK_VAR 10 #define AWB_VAR 11 #define AWB_PIXEL_THRESHOLD_COUNT_OFFSET 64 #define LOW_LIGHT_VAR 15 #define CAM_CTRL_VAR 18 #define CAM_SENSOR_CFG_Y_ADDR_START_OFFSET 0 #define CAM_SENSOR_CFG_X_ADDR_START_OFFSET 2 #define CAM_SENSOR_CFG_Y_ADDR_END_OFFSET 4 #define CAM_SENSOR_CFG_X_ADDR_END_OFFSET 6 #define CAM_SENSOR_CFG_FRAME_LENGTH_LINES_OFFSET 14 #define CAM_SENSOR_CFG_CPIPE_LAST_ROW_OFFSET 20 #define CAM_SENSOR_CFG_FDPERIOD_60HZ 22 #define CAM_SENSOR_CFG_FDPERIOD_50HZ 24 #define CAM_SENSOR_CFG_MAX_FDZONE_60_OFFSET 26 #define CAM_SENSOR_CFG_MAX_FDZONE_50_OFFSET 28 #define CAM_SENSOR_CFG_TARGET_FDZONE_60_OFFSET 30 #define CAM_SENSOR_CFG_TARGET_FDZONE_50_OFFSET 32 #define CAM_SENSOR_CONTROL_READ_MODE_OFFSET 40 #define CAM_SENSOR_CONTROL_Y_SKIP_EN (1 << 2) #define CAM_SENSOR_CONTROL_VERT_FLIP_EN (1 << 1) #define CAM_SENSOR_CONTROL_HORZ_MIRROR_EN (1 << 0) #define CAM_FLICKER_PERIOD_OFFSET 62 #define CAM_FLICKER_PERIOD_60HZ 0 #define CAM_FLICKER_PERIOD_50HZ 1 #define CAM_CROP_WINDOW_XOFFSET_OFFSET 72 #define CAM_CROP_WINDOW_YOFFSET_OFFSET 74 #define CAM_CROP_WINDOW_WIDTH_OFFSET 76 #define CAM_CROP_WINDOW_HEIGHT_OFFSET 78 #define CAM_CROP_MODE_OFFSET 80 #define CAM_OUTPUT_WIDTH_OFFSET 84 #define CAM_OUTPUT_HEIGHT_OFFSET 86 #define CAM_OUTPUT_FORMAT_OFFSET 88 #define CAM_OUTPUT_FORMAT_RGB_565 (0 << 12) #define CAM_OUTPUT_FORMAT_RGB_555 (1 << 12) #define CAM_OUTPUT_FORMAT_RGB_444X (2 << 12) #define CAM_OUTPUT_FORMAT_RGB_X444 (3 << 12) #define CAM_OUTPUT_FORMAT_BAYER_10 (0 << 10) #define CAM_OUTPUT_FORMAT_YUV (0 << 8) #define CAM_OUTPUT_FORMAT_RGB (1 << 8) #define CAM_OUTPUT_FORMAT_BAYER (2 << 8) #define CAM_OUTPUT_FORMAT_BT656_ENABLE (1 << 3) #define CAM_OUTPUT_FORMAT_MONO_ENABLE (1 << 2) #define CAM_OUTPUT_FORMAT_SWAP_BYTES (1 << 1) #define CAM_OUTPUT_FORMAT_SWAP_RED_BLUE (1 << 0) #define CAM_STAT_AWB_HG_WINDOW_XSTART_OFFSET 236 #define CAM_STAT_AWB_HG_WINDOW_YSTART_OFFSET 238 #define CAM_STAT_AWB_HG_WINDOW_XEND_OFFSET 240 #define CAM_STAT_AWB_HG_WINDOW_YEND_OFFSET 242 #define CAM_STAT_AE_INITIAL_WINDOW_XSTART_OFFSET 244 #define CAM_STAT_AE_INITIAL_WINDOW_YSTART_OFFSET 246 #define CAM_STAT_AE_INITIAL_WINDOW_XEND_OFFSET 248 #define CAM_STAT_AE_INITIAL_WINDOW_YEND_OFFSET 250 #define CAM_LL_START_GAIN_METRIC_OFFSET 278 #define CAM_LL_STOP_GAIN_METRIC_OFFSET 280 #define SYSMGR_VAR 23 #define SYSMGR_NEXT_STATE_OFFSET 0 #define PATCHLDR_VAR 24 #define PATCHLDR_LOADER_ADDRESS_OFFSET 0 #define PATCHLDR_PATCH_ID_OFFSET 2 #define PATCHLDR_FIRMWARE_ID_OFFSET 4 extern const AP_HAL::HAL& hal; using namespace Linux; CameraSensor_Mt9v117::CameraSensor_Mt9v117(const char *device_path, AP_HAL::I2CDriver *i2c, uint8_t addr, enum mt9v117_res res, uint16_t nrst_gpio, uint32_t clock_freq) : CameraSensor(device_path) , _i2c(i2c) , _addr(addr) , _nrst_gpio(nrst_gpio) , _clock_freq(clock_freq) { switch (res) { case MT9V117_QVGA: _init_sensor(); _configure_sensor_qvga(); break; default: AP_HAL::panic("mt9v117: unsupported resolution\n"); break; } _itu656_enable(); _config_change(); } uint8_t CameraSensor_Mt9v117::_read_reg8(uint16_t reg) { uint8_t buf[2]; buf[0] = (uint8_t) (reg >> 8); buf[1] = (uint8_t) (reg & 0xFF); if (!_i2c->do_transfer(_addr, buf, 2, buf, 1)) { hal.console->printf("mt9v117: error reading 0x%2x\n", reg); return 0; } return buf[0]; } void CameraSensor_Mt9v117::_write_reg8(uint16_t reg, uint8_t val) { uint8_t buf[3]; buf[0] = (uint8_t) (reg >> 8); buf[1] = (uint8_t) (reg & 0xFF); buf[2] = val; if (!_i2c->do_transfer(_addr, buf, 3, NULL, 0)) { hal.console->printf("mt9v117: error writing 0x%2x\n", reg); } } uint16_t CameraSensor_Mt9v117::_read_reg16(uint16_t reg) { uint8_t buf[2]; buf[0] = (uint8_t) (reg >> 8); buf[1] = (uint8_t) (reg & 0xFF); if (!_i2c->do_transfer(_addr, buf, 2, buf, 2)) { hal.console->printf("mt9v117: error reading 0x%4x\n", reg); return 0; } return (buf[0] << 8 | buf[1]); } void CameraSensor_Mt9v117::_write_reg16(uint16_t reg, uint16_t val) { uint8_t buf[4]; buf[0] = (uint8_t) (reg >> 8); buf[1] = (uint8_t) (reg & 0xFF); buf[2] = (uint8_t) (val >> 8); buf[3] = (uint8_t) (val & 0xFF); if (!_i2c->do_transfer(_addr, buf, 4, NULL, 0)) { hal.console->printf("mt9v117: error writing 0x%4x\n", reg); } } void CameraSensor_Mt9v117::_write_reg32(uint16_t reg, uint32_t val) { uint8_t buf[6]; buf[0] = (uint8_t) (reg >> 8); buf[1] = (uint8_t) (reg & 0xFF); buf[2] = (uint8_t) (val >> 24); buf[3] = (uint8_t) ((val >> 16) & 0xFF); buf[4] = (uint8_t) ((val >> 8) & 0xFF); buf[5] = (uint8_t) (val & 0xFF); if (!_i2c->do_transfer(_addr, buf, 6, NULL, 0)) { hal.console->printf("mt9v117: error writing 0x%8x\n", reg); } } inline uint16_t CameraSensor_Mt9v117::_var2reg(uint16_t var, uint16_t offset) { return (0x8000 | (var << 10) | offset); } uint16_t CameraSensor_Mt9v117::_read_var16(uint16_t var, uint16_t offset) { uint16_t reg = _var2reg(var, offset); return _read_reg16(reg); } void CameraSensor_Mt9v117::_write_var16(uint16_t var, uint16_t offset, uint16_t value) { uint16_t reg = _var2reg(var, offset); _write_reg16(reg, value); } uint8_t CameraSensor_Mt9v117::_read_var8(uint16_t var, uint16_t offset) { uint16_t reg = _var2reg(var, offset); return _read_reg8(reg); } void CameraSensor_Mt9v117::_write_var8(uint16_t var, uint16_t offset, uint8_t value) { uint16_t reg = _var2reg(var, offset); return _write_reg8(reg, value); } void CameraSensor_Mt9v117::_write_var32(uint16_t var, uint16_t offset, uint32_t value) { uint16_t reg = _var2reg(var, offset); return _write_reg32(reg, value); } void CameraSensor_Mt9v117::_config_change() { uint16_t cmd_status; /* timeout 100ms delay 10ms */ int timeout = 10; _write_var8(SYSMGR_VAR, SYSMGR_NEXT_STATE_OFFSET, 0x28); _write_reg16(COMMAND_REGISTER, HOST_COMMAND_OK | HOST_COMMAND_1); do { hal.scheduler->delay(10); cmd_status = _read_reg16(COMMAND_REGISTER); timeout--; } while (((cmd_status & HOST_COMMAND_1) != 0) && (timeout > 0)); if (timeout == 0) { hal.console->printf("mt9v117:" "timeout waiting or command to complete\n"); } if ((cmd_status & HOST_COMMAND_OK) == 0) { hal.console->printf("mt9v117:config change failed\n"); } } void CameraSensor_Mt9v117::_itu656_enable() { _write_var16(CAM_CTRL_VAR, CAM_OUTPUT_FORMAT_OFFSET, _read_var16(CAM_CTRL_VAR, CAM_OUTPUT_FORMAT_OFFSET) | CAM_OUTPUT_FORMAT_BT656_ENABLE); } void CameraSensor_Mt9v117::_soft_reset() { _write_reg16(RESET_AND_MISC_CONTROL, RESET_SOC_I2C); _write_reg16(RESET_AND_MISC_CONTROL, 0); /* sleep 50ms after soft reset */ hal.scheduler->delay(50); } void CameraSensor_Mt9v117::_apply_patch() { uint16_t cmd_status; /* timeout 100ms delay 10ms */ int timeout = 10; /* Errata item 2 */ _write_reg16(0x301a, 0x10d0); _write_reg16(0x31c0, 0x1404); _write_reg16(0x3ed8, 0x879c); _write_reg16(0x3042, 0x20e1); _write_reg16(0x30d4, 0x8020); _write_reg16(0x30c0, 0x0026); _write_reg16(0x301a, 0x10d4); /* Errata item 6 */ _write_var16(AE_TRACK_VAR, 0x0002, 0x00d3); _write_var16(CAM_CTRL_VAR, 0x0078, 0x00a0); _write_var16(CAM_CTRL_VAR, 0x0076, 0x0140); /* Errata item 8 */ _write_var16(LOW_LIGHT_VAR, 0x0004, 0x00fc); _write_var16(LOW_LIGHT_VAR, 0x0038, 0x007f); _write_var16(LOW_LIGHT_VAR, 0x003a, 0x007f); _write_var16(LOW_LIGHT_VAR, 0x003c, 0x007f); _write_var16(LOW_LIGHT_VAR, 0x0004, 0x00f4); /* Patch 0403; Critical; Sensor optimization */ _write_reg16(ACCESS_CTL_STAT, 0x0001); _write_reg16(PHYSICAL_ADDRESS_ACCESS, 0x7000); /* write patch */ for (unsigned int i = 0; i < MT9V117_PATCH_LINE_NUM; i++) { _i2c->do_transfer(_addr, _patch_lines[i].data, _patch_lines[i].size, NULL, 0); } _write_reg16(LOGICAL_ADDRESS_ACCESS, 0x0000); _write_var16(PATCHLDR_VAR, PATCHLDR_LOADER_ADDRESS_OFFSET, 0x05d8); _write_var16(PATCHLDR_VAR, PATCHLDR_PATCH_ID_OFFSET, 0x0403); _write_var32(PATCHLDR_VAR, PATCHLDR_FIRMWARE_ID_OFFSET, 0x00430104); _write_reg16(COMMAND_REGISTER, HOST_COMMAND_OK | HOST_COMMAND_0); do { hal.scheduler->delay(10); cmd_status = _read_reg16(COMMAND_REGISTER); timeout--; } while (((cmd_status & HOST_COMMAND_0) != 0) && (timeout > 0)); if ((cmd_status & HOST_COMMAND_OK) == 0) { hal.console->printf("mt9v117:patch apply failed\n"); } } void CameraSensor_Mt9v117::_set_basic_settings() { _write_var32(AWB_VAR, AWB_PIXEL_THRESHOLD_COUNT_OFFSET, 50000); _write_var16(AE_RULE_VAR, AE_RULE_ALGO_OFFSET, AE_RULE_ALGO_AVERAGE); /* Set pixclk pad slew to 6 and data out pad slew to 1 */ _write_reg16(PAD_SLEW, _read_reg16(PAD_SLEW) | 0x0600 | 0x0001); } void CameraSensor_Mt9v117::_configure_sensor_qvga() { _write_var16(CAM_CTRL_VAR, CAM_SENSOR_CFG_X_ADDR_START_OFFSET, 16); _write_var16(CAM_CTRL_VAR, CAM_SENSOR_CFG_X_ADDR_END_OFFSET, 663); _write_var16(CAM_CTRL_VAR, CAM_SENSOR_CFG_Y_ADDR_START_OFFSET, 8); _write_var16(CAM_CTRL_VAR, CAM_SENSOR_CFG_Y_ADDR_END_OFFSET, 501); _write_var16(CAM_CTRL_VAR, CAM_SENSOR_CFG_CPIPE_LAST_ROW_OFFSET, 243); _write_var16(CAM_CTRL_VAR, CAM_SENSOR_CFG_FRAME_LENGTH_LINES_OFFSET, 283); _write_var16(CAM_CTRL_VAR, CAM_SENSOR_CONTROL_READ_MODE_OFFSET, CAM_SENSOR_CONTROL_Y_SKIP_EN); _write_var16(CAM_CTRL_VAR, CAM_SENSOR_CFG_MAX_FDZONE_60_OFFSET, 1); _write_var16(CAM_CTRL_VAR, CAM_SENSOR_CFG_TARGET_FDZONE_60_OFFSET, 1); _write_reg8(AE_TRACK_JUMP_DIVISOR, 0x03); _write_reg8(CAM_AET_SKIP_FRAMES, 0x02); _write_var16(CAM_CTRL_VAR, CAM_OUTPUT_WIDTH_OFFSET, 320); _write_var16(CAM_CTRL_VAR, CAM_OUTPUT_HEIGHT_OFFSET, 240); /* Set gain metric for 111.2 fps * The final fps depends on the input clock * (89.2fps on bebop) so a modification may be needed here */ _write_var16(CAM_CTRL_VAR, CAM_LL_START_GAIN_METRIC_OFFSET, 0x03e8); _write_var16(CAM_CTRL_VAR, CAM_LL_STOP_GAIN_METRIC_OFFSET, 0x1770); /* set crop window */ _write_var16(CAM_CTRL_VAR, CAM_CROP_WINDOW_XOFFSET_OFFSET, 0); _write_var16(CAM_CTRL_VAR, CAM_CROP_WINDOW_YOFFSET_OFFSET, 0); _write_var16(CAM_CTRL_VAR, CAM_CROP_WINDOW_WIDTH_OFFSET, 640); _write_var16(CAM_CTRL_VAR, CAM_CROP_WINDOW_HEIGHT_OFFSET, 240); /* Enable auto-stats mode */ _write_var8(CAM_CTRL_VAR, CAM_CROP_MODE_OFFSET, 3); _write_var16(CAM_CTRL_VAR, CAM_STAT_AWB_HG_WINDOW_XEND_OFFSET, 319); _write_var16(CAM_CTRL_VAR, CAM_STAT_AWB_HG_WINDOW_YEND_OFFSET, 239); _write_var16(CAM_CTRL_VAR, CAM_STAT_AE_INITIAL_WINDOW_XSTART_OFFSET, 2); _write_var16(CAM_CTRL_VAR, CAM_STAT_AE_INITIAL_WINDOW_YSTART_OFFSET, 2); _write_var16(CAM_CTRL_VAR, CAM_STAT_AE_INITIAL_WINDOW_XEND_OFFSET, 65); _write_var16(CAM_CTRL_VAR, CAM_STAT_AE_INITIAL_WINDOW_YEND_OFFSET, 49); } void CameraSensor_Mt9v117::_init_sensor() { AP_HAL::DigitalSource *gpio_source; uint16_t id; if (_nrst_gpio != 0xFFFF) { gpio_source = hal.gpio->channel(_nrst_gpio); gpio_source->mode(HAL_GPIO_OUTPUT); gpio_source->write(1); uint32_t delay = 3.5f + (35.0f - 3.5f) * (54000000.0f - (float)_clock_freq) / (54000000.0f - 6000000.0f); hal.scheduler->delay(delay); } id = _read_reg16(CHIP_ID); if (id != MT9V117_CHIP_ID) { AP_HAL::panic("Mt9v117: bad chip id\n"); } _soft_reset(); _apply_patch(); _set_basic_settings(); } #endif