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nopenpilot/selfdrive/camerad/cameras/camera_qcom.cc

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#include <stdio.h>
#include <stdbool.h>
#include <assert.h>
#include <unistd.h>
#include <fcntl.h>
#include <math.h>
#include <poll.h>
#include <sys/ioctl.h>
#include <atomic>
#include <algorithm>
#include <linux/media.h>
#include <cutils/properties.h>
#include <pthread.h>
#include <capnp/serialize.h>
#include "msmb_isp.h"
#include "msmb_ispif.h"
#include "msmb_camera.h"
#include "msm_cam_sensor.h"
#include "common/util.h"
#include "common/utilpp.h"
#include "common/timing.h"
#include "common/swaglog.h"
#include "common/params.h"
#include "clutil.h"
#include "cereal/gen/cpp/log.capnp.h"
#include "sensor_i2c.h"
#include "camera_qcom.h"
extern volatile sig_atomic_t do_exit;
// global var for AE/AF ops
std::atomic<CameraExpInfo> rear_exp{{0}};
std::atomic<CameraExpInfo> front_exp{{0}};
CameraInfo cameras_supported[CAMERA_ID_MAX] = {
[CAMERA_ID_IMX298] = {
.frame_width = 2328,
.frame_height = 1748,
.frame_stride = 2912,
.bayer = true,
.bayer_flip = 0,
.hdr = true
},
[CAMERA_ID_IMX179] = {
.frame_width = 3280,
.frame_height = 2464,
.frame_stride = 4104,
.bayer = true,
.bayer_flip = 0,
.hdr = false
},
[CAMERA_ID_S5K3P8SP] = {
.frame_width = 2304,
.frame_height = 1728,
.frame_stride = 2880,
.bayer = true,
.bayer_flip = 1,
.hdr = false
},
[CAMERA_ID_OV8865] = {
.frame_width = 1632,
.frame_height = 1224,
.frame_stride = 2040, // seems right
.bayer = true,
.bayer_flip = 3,
.hdr = false
},
// this exists to get the kernel to build for the LeEco in release
[CAMERA_ID_IMX298_FLIPPED] = {
.frame_width = 2328,
.frame_height = 1748,
.frame_stride = 2912,
.bayer = true,
.bayer_flip = 3,
.hdr = true
},
[CAMERA_ID_OV10640] = {
.frame_width = 1280,
.frame_height = 1080,
.frame_stride = 2040,
.bayer = true,
.bayer_flip = 0,
.hdr = true
},
};
static void camera_release_buffer(void* cookie, int buf_idx) {
CameraState *s = (CameraState *)cookie;
// printf("camera_release_buffer %d\n", buf_idx);
s->ss[0].qbuf_info[buf_idx].dirty_buf = 1;
ioctl(s->isp_fd, VIDIOC_MSM_ISP_ENQUEUE_BUF, &s->ss[0].qbuf_info[buf_idx]);
}
static void camera_init(CameraState *s, int camera_id, int camera_num,
uint32_t pixel_clock, uint32_t line_length_pclk,
unsigned int max_gain, unsigned int fps, cl_device_id device_id, cl_context ctx) {
s->camera_num = camera_num;
s->camera_id = camera_id;
assert(camera_id < ARRAYSIZE(cameras_supported));
s->ci = cameras_supported[camera_id];
assert(s->ci.frame_width != 0);
s->pixel_clock = pixel_clock;
s->line_length_pclk = line_length_pclk;
s->max_gain = max_gain;
s->fps = fps;
s->self_recover = 0;
s->buf.init(device_id, ctx, s, FRAME_BUF_COUNT, "frame", camera_release_buffer);
pthread_mutex_init(&s->frame_info_lock, NULL);
}
int sensor_write_regs(CameraState *s, struct msm_camera_i2c_reg_array* arr, size_t size, msm_camera_i2c_data_type data_type) {
struct msm_camera_i2c_reg_setting out_settings = {
.reg_setting = arr,
.size = (uint16_t)size,
.addr_type = MSM_CAMERA_I2C_WORD_ADDR,
.data_type = data_type,
.delay = 0,
};
struct sensorb_cfg_data cfg_data = {0};
cfg_data.cfgtype = CFG_WRITE_I2C_ARRAY;
cfg_data.cfg.setting = &out_settings;
return ioctl(s->sensor_fd, VIDIOC_MSM_SENSOR_CFG, &cfg_data);
}
static int imx298_apply_exposure(CameraState *s, int gain, int integ_lines, int frame_length) {
int err;
int analog_gain = std::min(gain, 448);
if (gain > 448) {
s->digital_gain = (512.0/(512-(gain))) / 8.0;
} else {
s->digital_gain = 1.0;
}
//printf("%5d/%5d %5d %f\n", s->cur_integ_lines, s->cur_frame_length, analog_gain, s->digital_gain);
struct msm_camera_i2c_reg_array reg_array[] = {
// REG_HOLD
{0x104,0x1,0},
{0x3002,0x0,0}, // long autoexposure off
// FRM_LENGTH
{0x340, (uint16_t)(frame_length >> 8), 0}, {0x341, (uint16_t)(frame_length & 0xff), 0},
// INTEG_TIME aka coarse_int_time_addr aka shutter speed
{0x202, (uint16_t)(integ_lines >> 8), 0}, {0x203, (uint16_t)(integ_lines & 0xff),0},
// global_gain_addr
// if you assume 1x gain is 32, 448 is 14x gain, aka 2^14=16384
{0x204, (uint16_t)(analog_gain >> 8), 0}, {0x205, (uint16_t)(analog_gain & 0xff),0},
// digital gain for colors: gain_greenR, gain_red, gain_blue, gain_greenB
/*{0x20e, digital_gain_gr >> 8, 0}, {0x20f,digital_gain_gr & 0xFF,0},
{0x210, digital_gain_r >> 8, 0}, {0x211,digital_gain_r & 0xFF,0},
{0x212, digital_gain_b >> 8, 0}, {0x213,digital_gain_b & 0xFF,0},
{0x214, digital_gain_gb >> 8, 0}, {0x215,digital_gain_gb & 0xFF,0},*/
// REG_HOLD
{0x104,0x0,0},
};
err = sensor_write_regs(s, reg_array, ARRAYSIZE(reg_array), MSM_CAMERA_I2C_BYTE_DATA);
if (err != 0) {
LOGE("apply_exposure err %d", err);
}
return err;
}
static int ov8865_apply_exposure(CameraState *s, int gain, int integ_lines, int frame_length) {
//printf("front camera: %d %d %d\n", gain, integ_lines, frame_length);
int err, coarse_gain_bitmap, fine_gain_bitmap;
// get bitmaps from iso
static const int gains[] = {0, 100, 200, 400, 800};
int i;
for (i = 1; i < ARRAYSIZE(gains); i++) {
if (gain >= gains[i - 1] && gain < gains[i])
break;
}
int coarse_gain = i - 1;
float fine_gain = (gain - gains[coarse_gain])/(float)(gains[coarse_gain+1]-gains[coarse_gain]);
coarse_gain_bitmap = (1 << coarse_gain) - 1;
fine_gain_bitmap = ((int)(16*fine_gain) << 3) + 128; // 7th is always 1, 0-2nd are always 0
integ_lines *= 16; // The exposure value in reg is in 16ths of a line
struct msm_camera_i2c_reg_array reg_array[] = {
//{0x104,0x1,0},
// FRM_LENGTH
{0x380e, (uint16_t)(frame_length >> 8), 0}, {0x380f, (uint16_t)(frame_length & 0xff), 0},
// AEC EXPO
{0x3500, (uint16_t)(integ_lines >> 16), 0}, {0x3501, (uint16_t)(integ_lines >> 8), 0}, {0x3502, (uint16_t)(integ_lines & 0xff),0},
// AEC MANUAL
{0x3503, 0x4, 0},
// AEC GAIN
{0x3508, (uint16_t)(coarse_gain_bitmap), 0}, {0x3509, (uint16_t)(fine_gain_bitmap), 0},
//{0x104,0x0,0},
};
err = sensor_write_regs(s, reg_array, ARRAYSIZE(reg_array), MSM_CAMERA_I2C_BYTE_DATA);
if (err != 0) {
LOGE("apply_exposure err %d", err);
}
return err;
}
static int imx179_s5k3p8sp_apply_exposure(CameraState *s, int gain, int integ_lines, int frame_length) {
//printf("front camera: %d %d %d\n", gain, integ_lines, frame_length);
int err;
struct msm_camera_i2c_reg_array reg_array[] = {
{0x104,0x1,0},
// FRM_LENGTH
{0x340, (uint16_t)(frame_length >> 8), 0}, {0x341, (uint16_t)(frame_length & 0xff), 0},
// coarse_int_time
{0x202, (uint16_t)(integ_lines >> 8), 0}, {0x203, (uint16_t)(integ_lines & 0xff),0},
// global_gain
{0x204, (uint16_t)(gain >> 8), 0}, {0x205, (uint16_t)(gain & 0xff),0},
{0x104,0x0,0},
};
err = sensor_write_regs(s, reg_array, ARRAYSIZE(reg_array), MSM_CAMERA_I2C_BYTE_DATA);
if (err != 0) {
LOGE("apply_exposure err %d", err);
}
return err;
}
cl_program build_conv_program(cl_device_id device_id, cl_context context, int image_w, int image_h, int filter_size) {
char args[4096];
snprintf(args, sizeof(args),
"-cl-fast-relaxed-math -cl-denorms-are-zero "
"-DIMAGE_W=%d -DIMAGE_H=%d -DFLIP_RB=%d "
"-DFILTER_SIZE=%d -DHALF_FILTER_SIZE=%d -DTWICE_HALF_FILTER_SIZE=%d -DHALF_FILTER_SIZE_IMAGE_W=%d",
image_w, image_h, 1,
filter_size, filter_size/2, (filter_size/2)*2, (filter_size/2)*image_w);
return cl_program_from_file(context, device_id, "imgproc/conv.cl", args);
}
void cameras_init(MultiCameraState *s, cl_device_id device_id, cl_context ctx) {
char project_name[1024] = {0};
property_get("ro.boot.project_name", project_name, "");
char product_name[1024] = {0};
property_get("ro.product.name", product_name, "");
if (strlen(project_name) == 0) {
LOGD("LePro 3 op system detected");
s->device = DEVICE_LP3;
// sensor is flipped in LP3
// IMAGE_ORIENT = 3
init_array_imx298[0].reg_data = 3;
cameras_supported[CAMERA_ID_IMX298].bayer_flip = 3;
} else if (strcmp(product_name, "OnePlus3") == 0 && strcmp(project_name, "15811") != 0) {
// no more OP3 support
s->device = DEVICE_OP3;
assert(false);
} else if (strcmp(product_name, "OnePlus3") == 0 && strcmp(project_name, "15811") == 0) {
// only OP3T support
s->device = DEVICE_OP3T;
} else {
assert(false);
}
// 0 = ISO 100
// 256 = ISO 200
// 384 = ISO 400
// 448 = ISO 800
// 480 = ISO 1600
// 496 = ISO 3200
// 504 = ISO 6400, 8x digital gain
// 508 = ISO 12800, 16x digital gain
// 510 = ISO 25600, 32x digital gain
camera_init(&s->rear, CAMERA_ID_IMX298, 0,
/*pixel_clock=*/600000000, /*line_length_pclk=*/5536,
/*max_gain=*/510, //0 (ISO 100)- 448 (ISO 800, max analog gain) - 511 (super noisy)
#ifdef HIGH_FPS
/*fps*/ 60,
#else
/*fps*/ 20,
#endif
device_id, ctx);
s->rear.apply_exposure = imx298_apply_exposure;
if (s->device == DEVICE_OP3T) {
camera_init(&s->front, CAMERA_ID_S5K3P8SP, 1,
/*pixel_clock=*/560000000, /*line_length_pclk=*/5120,
/*max_gain=*/510, 10, device_id, ctx);
s->front.apply_exposure = imx179_s5k3p8sp_apply_exposure;
} else if (s->device == DEVICE_LP3) {
camera_init(&s->front, CAMERA_ID_OV8865, 1,
/*pixel_clock=*/72000000, /*line_length_pclk=*/1602,
/*max_gain=*/510, 10, device_id, ctx);
s->front.apply_exposure = ov8865_apply_exposure;
} else {
camera_init(&s->front, CAMERA_ID_IMX179, 1,
/*pixel_clock=*/251200000, /*line_length_pclk=*/3440,
/*max_gain=*/224, 20, device_id, ctx);
s->front.apply_exposure = imx179_s5k3p8sp_apply_exposure;
}
s->rear.device = s->device;
s->front.device = s->device;
s->sm_front = new SubMaster({"driverState"});
s->pm = new PubMaster({"frame", "frontFrame", "thumbnail"});
for (int i = 0; i < FRAME_BUF_COUNT; i++) {
// TODO: make lengths correct
s->focus_bufs[i] = visionbuf_allocate(0xb80);
s->stats_bufs[i] = visionbuf_allocate(0xb80);
}
const int width = s->rear.buf.rgb_width/NUM_SEGMENTS_X;
const int height = s->rear.buf.rgb_height/NUM_SEGMENTS_Y;
s->prg_rgb_laplacian = build_conv_program(device_id, ctx, width, height, 3);
s->krnl_rgb_laplacian = CL_CHECK_ERR(clCreateKernel(s->prg_rgb_laplacian, "rgb2gray_conv2d", &err));
// TODO: Removed CL_MEM_SVM_FINE_GRAIN_BUFFER, confirm it doesn't matter
s->rgb_conv_roi_cl = CL_CHECK_ERR(clCreateBuffer(ctx, CL_MEM_READ_WRITE,
width * height * 3 * sizeof(uint8_t), NULL, &err));
s->rgb_conv_result_cl = CL_CHECK_ERR(clCreateBuffer(ctx, CL_MEM_READ_WRITE,
width * height * sizeof(int16_t), NULL, &err));
s->rgb_conv_filter_cl = CL_CHECK_ERR(clCreateBuffer(ctx, CL_MEM_READ_ONLY | CL_MEM_COPY_HOST_PTR,
9 * sizeof(int16_t), (void*)&lapl_conv_krnl, &err));
std::fill_n(s->lapres, std::size(s->lapres), 16160);
}
static void set_exposure(CameraState *s, float exposure_frac, float gain_frac) {
int err = 0;
unsigned int frame_length = s->pixel_clock / s->line_length_pclk / s->fps;
unsigned int gain = s->cur_gain;
unsigned int integ_lines = s->cur_integ_lines;
if (exposure_frac >= 0) {
exposure_frac = std::clamp(exposure_frac, 2.0f / frame_length, 1.0f);
integ_lines = frame_length * exposure_frac;
// See page 79 of the datasheet, this is the max allowed (-1 for phase adjust)
integ_lines = std::min(integ_lines, frame_length-11);
}
if (gain_frac >= 0) {
// ISO200 is minimum gain
gain_frac = std::clamp(gain_frac, 1.0f/64, 1.0f);
// linearize gain response
// TODO: will be wrong for front camera
// 0.125 -> 448
// 0.25 -> 480
// 0.5 -> 496
// 1.0 -> 504
// 512 - 512/(128*gain_frac)
gain = (s->max_gain/510) * (512 - 512/(256*gain_frac));
}
if (gain != s->cur_gain
|| integ_lines != s->cur_integ_lines
|| frame_length != s->cur_frame_length) {
if (s->apply_exposure == ov8865_apply_exposure) {
gain = 800 * gain_frac; // ISO
err = s->apply_exposure(s, gain, integ_lines, frame_length);
} else if (s->apply_exposure) {
err = s->apply_exposure(s, gain, integ_lines, frame_length);
}
if (err == 0) {
pthread_mutex_lock(&s->frame_info_lock);
s->cur_gain = gain;
s->cur_integ_lines = integ_lines;
s->cur_frame_length = frame_length;
pthread_mutex_unlock(&s->frame_info_lock);
}
}
if (err == 0) {
s->cur_exposure_frac = exposure_frac;
pthread_mutex_lock(&s->frame_info_lock);
s->cur_gain_frac = gain_frac;
pthread_mutex_unlock(&s->frame_info_lock);
}
//LOGD("set exposure: %f %f - %d", exposure_frac, gain_frac, err);
}
static void do_autoexposure(CameraState *s, float grey_frac) {
const float target_grey = 0.3;
if (s->apply_exposure == ov8865_apply_exposure) {
// gain limits downstream
const float gain_frac_min = 0.015625;
const float gain_frac_max = 1.0;
// exposure time limits
unsigned int frame_length = s->pixel_clock / s->line_length_pclk / s->fps;
const unsigned int exposure_time_min = 16;
const unsigned int exposure_time_max = frame_length - 11; // copied from set_exposure()
float cur_gain_frac = s->cur_gain_frac;
float exposure_factor = pow(1.05, (target_grey - grey_frac) / 0.05);
if (cur_gain_frac > 0.125 && exposure_factor < 1) {
cur_gain_frac *= exposure_factor;
} else if (s->cur_integ_lines * exposure_factor <= exposure_time_max && s->cur_integ_lines * exposure_factor >= exposure_time_min) { // adjust exposure time first
s->cur_exposure_frac *= exposure_factor;
} else if (cur_gain_frac * exposure_factor <= gain_frac_max && cur_gain_frac * exposure_factor >= gain_frac_min) {
cur_gain_frac *= exposure_factor;
}
pthread_mutex_lock(&s->frame_info_lock);
s->cur_gain_frac = cur_gain_frac;
pthread_mutex_unlock(&s->frame_info_lock);
set_exposure(s, s->cur_exposure_frac, cur_gain_frac);
} else { // keep the old for others
float new_exposure = s->cur_exposure_frac;
new_exposure *= pow(1.05, (target_grey - grey_frac) / 0.05 );
//LOGD("diff %f: %f to %f", target_grey - grey_frac, s->cur_exposure_frac, new_exposure);
float new_gain = s->cur_gain_frac;
if (new_exposure < 0.10) {
new_gain *= 0.95;
} else if (new_exposure > 0.40) {
new_gain *= 1.05;
}
set_exposure(s, new_exposure, new_gain);
}
}
static uint8_t* get_eeprom(int eeprom_fd, size_t *out_len) {
int err;
struct msm_eeprom_cfg_data cfg = {};
cfg.cfgtype = CFG_EEPROM_GET_CAL_DATA;
err = ioctl(eeprom_fd, VIDIOC_MSM_EEPROM_CFG, &cfg);
assert(err >= 0);
uint32_t num_bytes = cfg.cfg.get_data.num_bytes;
assert(num_bytes > 100);
uint8_t* buffer = (uint8_t*)malloc(num_bytes);
assert(buffer);
memset(buffer, 0, num_bytes);
cfg.cfgtype = CFG_EEPROM_READ_CAL_DATA;
cfg.cfg.read_data.num_bytes = num_bytes;
cfg.cfg.read_data.dbuffer = buffer;
err = ioctl(eeprom_fd, VIDIOC_MSM_EEPROM_CFG, &cfg);
assert(err >= 0);
*out_len = num_bytes;
return buffer;
}
static void imx298_ois_calibration(int ois_fd, uint8_t* eeprom) {
int err;
const int ois_registers[][2] = {
// == SET_FADJ_PARAM() == (factory adjustment)
// Set Hall Current DAC
{0x8230, *(uint16_t*)(eeprom+0x102)}, //_P_30_ADC_CH0 (CURDAT)
// Set Hall PreAmp Offset
{0x8231, *(uint16_t*)(eeprom+0x104)}, //_P_31_ADC_CH1 (HALOFS_X)
{0x8232, *(uint16_t*)(eeprom+0x106)}, //_P_32_ADC_CH2 (HALOFS_Y)
// Set Hall-X/Y PostAmp Offset
{0x841e, *(uint16_t*)(eeprom+0x108)}, //_M_X_H_ofs
{0x849e, *(uint16_t*)(eeprom+0x10a)}, //_M_Y_H_ofs
// Set Residual Offset
{0x8239, *(uint16_t*)(eeprom+0x10c)}, //_P_39_Ch3_VAL_1 (PSTXOF)
{0x823b, *(uint16_t*)(eeprom+0x10e)}, //_P_3B_Ch3_VAL_3 (PSTYOF)
// DIGITAL GYRO OFFSET
{0x8406, *(uint16_t*)(eeprom+0x110)}, //_M_Kgx00
{0x8486, *(uint16_t*)(eeprom+0x112)}, //_M_Kgy00
{0x846a, *(uint16_t*)(eeprom+0x120)}, //_M_TMP_X_
{0x846b, *(uint16_t*)(eeprom+0x122)}, //_M_TMP_Y_
// HALLSENSE
// Set Hall Gain
{0x8446, *(uint16_t*)(eeprom+0x114)}, //_M_KgxHG
{0x84c6, *(uint16_t*)(eeprom+0x116)}, //_M_KgyHG
// Set Cross Talk Canceller
{0x8470, *(uint16_t*)(eeprom+0x124)}, //_M_KgxH0
{0x8472, *(uint16_t*)(eeprom+0x126)}, //_M_KgyH0
// LOOPGAIN
{0x840f, *(uint16_t*)(eeprom+0x118)}, //_M_KgxG
{0x848f, *(uint16_t*)(eeprom+0x11a)}, //_M_KgyG
// Position Servo ON ( OIS OFF )
{0x847f, 0x0c0c}, //_M_EQCTL
};
struct msm_ois_cfg_data cfg = {0};
struct msm_camera_i2c_seq_reg_array ois_reg_settings[ARRAYSIZE(ois_registers)] = {{0}};
for (int i=0; i<ARRAYSIZE(ois_registers); i++) {
ois_reg_settings[i].reg_addr = ois_registers[i][0];
ois_reg_settings[i].reg_data[0] = ois_registers[i][1] & 0xff;
ois_reg_settings[i].reg_data[1] = (ois_registers[i][1] >> 8) & 0xff;
ois_reg_settings[i].reg_data_size = 2;
}
struct msm_camera_i2c_seq_reg_setting ois_reg_setting = {
.reg_setting = &ois_reg_settings[0],
.size = ARRAYSIZE(ois_reg_settings),
.addr_type = MSM_CAMERA_I2C_WORD_ADDR,
.delay = 0,
};
cfg.cfgtype = CFG_OIS_I2C_WRITE_SEQ_TABLE;
cfg.cfg.settings = &ois_reg_setting;
err = ioctl(ois_fd, VIDIOC_MSM_OIS_CFG, &cfg);
LOG("ois reg calibration: %d", err);
}
static void sensors_init(MultiCameraState *s) {
int err;
unique_fd sensorinit_fd;
if (s->device == DEVICE_LP3) {
sensorinit_fd = open("/dev/v4l-subdev11", O_RDWR | O_NONBLOCK);
} else {
sensorinit_fd = open("/dev/v4l-subdev12", O_RDWR | O_NONBLOCK);
}
assert(sensorinit_fd >= 0);
struct sensor_init_cfg_data sensor_init_cfg = {};
// init rear sensor
struct msm_camera_sensor_slave_info slave_info = {0};
if (s->device == DEVICE_LP3) {
slave_info = (struct msm_camera_sensor_slave_info){
.sensor_name = "imx298",
.eeprom_name = "sony_imx298",
.actuator_name = "dw9800w",
.ois_name = "",
.flash_name = "pmic",
.camera_id = CAMERA_0,
.slave_addr = 32,
.i2c_freq_mode = I2C_FAST_MODE,
.addr_type = MSM_CAMERA_I2C_WORD_ADDR,
.sensor_id_info = {
.sensor_id_reg_addr = 22,
.sensor_id = 664,
.sensor_id_mask = 0,
.module_id = 9,
.vcm_id = 6,
},
.power_setting_array = {
.power_setting_a = {
{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 2,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 5,
.config_val = 2,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 1,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 3,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_CLK,
.seq_val = 0,
.config_val = 24000000,
.delay = 1,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 2,
.delay = 10,
},
},
.size = 7,
.power_down_setting_a = {
{
.seq_type = SENSOR_CLK,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 1,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 5,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 2,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 3,
.config_val = 0,
.delay = 1,
},
},
.size_down = 6,
},
.is_init_params_valid = 0,
.sensor_init_params = {
.modes_supported = 1,
.position = BACK_CAMERA_B,
.sensor_mount_angle = 90,
},
.output_format = MSM_SENSOR_BAYER,
};
} else {
slave_info = (struct msm_camera_sensor_slave_info){
.sensor_name = "imx298",
.eeprom_name = "sony_imx298",
.actuator_name = "rohm_bu63165gwl",
.ois_name = "rohm_bu63165gwl",
.camera_id = CAMERA_0,
.slave_addr = 52,
.i2c_freq_mode = I2C_CUSTOM_MODE,
.addr_type = MSM_CAMERA_I2C_WORD_ADDR,
.sensor_id_info = {
.sensor_id_reg_addr = 22,
.sensor_id = 664,
.sensor_id_mask = 0,
},
.power_setting_array = {
.power_setting_a = {
{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 0,
.delay = 2,
},{
.seq_type = SENSOR_VREG,
.seq_val = 2,
.config_val = 0,
.delay = 2,
},{
.seq_type = SENSOR_VREG,
.seq_val = 0,
.config_val = 0,
.delay = 2,
},{
.seq_type = SENSOR_VREG,
.seq_val = 1,
.config_val = 0,
.delay = 2,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 6,
.config_val = 2,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 3,
.config_val = 0,
.delay = 5,
},{
.seq_type = SENSOR_VREG,
.seq_val = 4,
.config_val = 0,
.delay = 5,
},{
.seq_type = SENSOR_CLK,
.seq_val = 0,
.config_val = 24000000,
.delay = 2,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 2,
.delay = 2,
},
},
.size = 9,
.power_down_setting_a = {
{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 0,
.delay = 10,
},{
.seq_type = SENSOR_CLK,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 4,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 3,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 6,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 1,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 0,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 2,
.config_val = 0,
.delay = 0,
},
},
.size_down = 8,
},
.is_init_params_valid = 0,
.sensor_init_params = {
.modes_supported = 1,
.position = BACK_CAMERA_B,
.sensor_mount_angle = 360,
},
.output_format = MSM_SENSOR_BAYER,
};
}
slave_info.power_setting_array.power_setting =
(struct msm_sensor_power_setting *)&slave_info.power_setting_array.power_setting_a[0];
slave_info.power_setting_array.power_down_setting =
(struct msm_sensor_power_setting *)&slave_info.power_setting_array.power_down_setting_a[0];
sensor_init_cfg.cfgtype = CFG_SINIT_PROBE;
sensor_init_cfg.cfg.setting = &slave_info;
err = ioctl(sensorinit_fd, VIDIOC_MSM_SENSOR_INIT_CFG, &sensor_init_cfg);
LOG("sensor init cfg (rear): %d", err);
assert(err >= 0);
struct msm_camera_sensor_slave_info slave_info2 = {0};
if (s->device == DEVICE_LP3) {
slave_info2 = (struct msm_camera_sensor_slave_info){
.sensor_name = "ov8865_sunny",
.eeprom_name = "ov8865_plus",
.actuator_name = "",
.ois_name = "",
.flash_name = "",
.camera_id = CAMERA_2,
.slave_addr = 108,
.i2c_freq_mode = I2C_FAST_MODE,
.addr_type = MSM_CAMERA_I2C_WORD_ADDR,
.sensor_id_info = {
.sensor_id_reg_addr = 12299,
.sensor_id = 34917,
.sensor_id_mask = 0,
.module_id = 2,
.vcm_id = 0,
},
.power_setting_array = {
.power_setting_a = {
{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 0,
.delay = 5,
},{
.seq_type = SENSOR_VREG,
.seq_val = 1,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 2,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 0,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_CLK,
.seq_val = 0,
.config_val = 24000000,
.delay = 1,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 2,
.delay = 1,
},
},
.size = 6,
.power_down_setting_a = {
{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 0,
.delay = 5,
},{
.seq_type = SENSOR_CLK,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 0,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 1,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 2,
.config_val = 0,
.delay = 1,
},
},
.size_down = 5,
},
.is_init_params_valid = 0,
.sensor_init_params = {
.modes_supported = 1,
.position = FRONT_CAMERA_B,
.sensor_mount_angle = 270,
},
.output_format = MSM_SENSOR_BAYER,
};
} else if (s->front.camera_id == CAMERA_ID_S5K3P8SP) {
// init front camera
slave_info2 = (struct msm_camera_sensor_slave_info){
.sensor_name = "s5k3p8sp",
.eeprom_name = "s5k3p8sp_m24c64s",
.actuator_name = "",
.ois_name = "",
.camera_id = CAMERA_1,
.slave_addr = 32,
.i2c_freq_mode = I2C_FAST_MODE,
.addr_type = MSM_CAMERA_I2C_WORD_ADDR,
.sensor_id_info = {
.sensor_id_reg_addr = 0,
.sensor_id = 12552,
.sensor_id_mask = 0,
},
.power_setting_array = {
.power_setting_a = {
{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 2,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 1,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_CLK,
.seq_val = 0,
.config_val = 24000000,
.delay = 1,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 2,
.delay = 1,
},
},
.size = 6,
.power_down_setting_a = {
{
.seq_type = SENSOR_CLK,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 1,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 2,
.config_val = 0,
.delay = 1,
},
},
.size_down = 5,
},
.is_init_params_valid = 0,
.sensor_init_params = {
.modes_supported = 1,
.position = FRONT_CAMERA_B,
.sensor_mount_angle = 270,
},
.output_format = MSM_SENSOR_BAYER,
};
} else {
// init front camera
slave_info2 = (struct msm_camera_sensor_slave_info){
.sensor_name = "imx179",
.eeprom_name = "sony_imx179",
.actuator_name = "",
.ois_name = "",
.camera_id = CAMERA_1,
.slave_addr = 32,
.i2c_freq_mode = I2C_FAST_MODE,
.addr_type = MSM_CAMERA_I2C_WORD_ADDR,
.sensor_id_info = {
.sensor_id_reg_addr = 2,
.sensor_id = 377,
.sensor_id_mask = 4095,
},
.power_setting_array = {
.power_setting_a = {
{
.seq_type = SENSOR_VREG,
.seq_val = 2,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 1,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 0,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 2,
.delay = 0,
},{
.seq_type = SENSOR_CLK,
.seq_val = 0,
.config_val = 24000000,
.delay = 0,
},
},
.size = 5,
.power_down_setting_a = {
{
.seq_type = SENSOR_CLK,
.seq_val = 0,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_GPIO,
.seq_val = 0,
.config_val = 0,
.delay = 1,
},{
.seq_type = SENSOR_VREG,
.seq_val = 0,
.config_val = 0,
.delay = 2,
},{
.seq_type = SENSOR_VREG,
.seq_val = 1,
.config_val = 0,
.delay = 0,
},{
.seq_type = SENSOR_VREG,
.seq_val = 2,
.config_val = 0,
.delay = 0,
},
},
.size_down = 5,
},
.is_init_params_valid = 0,
.sensor_init_params = {
.modes_supported = 1,
.position = FRONT_CAMERA_B,
.sensor_mount_angle = 270,
},
.output_format = MSM_SENSOR_BAYER,
};
}
slave_info2.power_setting_array.power_setting =
(struct msm_sensor_power_setting *)&slave_info2.power_setting_array.power_setting_a[0];
slave_info2.power_setting_array.power_down_setting =
(struct msm_sensor_power_setting *)&slave_info2.power_setting_array.power_down_setting_a[0];
sensor_init_cfg.cfgtype = CFG_SINIT_PROBE;
sensor_init_cfg.cfg.setting = &slave_info2;
err = ioctl(sensorinit_fd, VIDIOC_MSM_SENSOR_INIT_CFG, &sensor_init_cfg);
LOG("sensor init cfg (front): %d", err);
assert(err >= 0);
}
static void camera_open(CameraState *s, bool rear) {
int err;
struct sensorb_cfg_data sensorb_cfg_data = {};
struct csid_cfg_data csid_cfg_data = {};
struct csiphy_cfg_data csiphy_cfg_data = {};
struct msm_camera_csiphy_params csiphy_params = {};
struct msm_camera_csid_params csid_params = {};
struct msm_vfe_input_cfg input_cfg = {};
struct msm_vfe_axi_stream_update_cmd update_cmd = {};
struct v4l2_event_subscription sub = {};
struct msm_actuator_cfg_data actuator_cfg_data = {};
struct msm_ois_cfg_data ois_cfg_data = {};
// open devices
const char *sensor_dev;
if (rear) {
s->csid_fd = open("/dev/v4l-subdev3", O_RDWR | O_NONBLOCK);
assert(s->csid_fd >= 0);
s->csiphy_fd = open("/dev/v4l-subdev0", O_RDWR | O_NONBLOCK);
assert(s->csiphy_fd >= 0);
if (s->device == DEVICE_LP3) {
sensor_dev = "/dev/v4l-subdev17";
} else {
sensor_dev = "/dev/v4l-subdev18";
}
if (s->device == DEVICE_LP3) {
s->isp_fd = open("/dev/v4l-subdev13", O_RDWR | O_NONBLOCK);
} else {
s->isp_fd = open("/dev/v4l-subdev14", O_RDWR | O_NONBLOCK);
}
assert(s->isp_fd >= 0);
s->eeprom_fd = open("/dev/v4l-subdev8", O_RDWR | O_NONBLOCK);
assert(s->eeprom_fd >= 0);
s->actuator_fd = open("/dev/v4l-subdev7", O_RDWR | O_NONBLOCK);
assert(s->actuator_fd >= 0);
if (s->device != DEVICE_LP3) {
s->ois_fd = open("/dev/v4l-subdev10", O_RDWR | O_NONBLOCK);
assert(s->ois_fd >= 0);
}
} else {
s->csid_fd = open("/dev/v4l-subdev5", O_RDWR | O_NONBLOCK);
assert(s->csid_fd >= 0);
s->csiphy_fd = open("/dev/v4l-subdev2", O_RDWR | O_NONBLOCK);
assert(s->csiphy_fd >= 0);
if (s->device == DEVICE_LP3) {
sensor_dev = "/dev/v4l-subdev18";
} else {
sensor_dev = "/dev/v4l-subdev19";
}
if (s->device == DEVICE_LP3) {
s->isp_fd = open("/dev/v4l-subdev14", O_RDWR | O_NONBLOCK);
} else {
s->isp_fd = open("/dev/v4l-subdev15", O_RDWR | O_NONBLOCK);
}
assert(s->isp_fd >= 0);
s->eeprom_fd = open("/dev/v4l-subdev9", O_RDWR | O_NONBLOCK);
assert(s->eeprom_fd >= 0);
}
// wait for sensor device
// on first startup, these devices aren't present yet
for (int i = 0; i < 10; i++) {
s->sensor_fd = open(sensor_dev, O_RDWR | O_NONBLOCK);
if (s->sensor_fd >= 0) break;
LOGW("waiting for sensors...");
sleep(1);
}
assert(s->sensor_fd >= 0);
// *** SHUTDOWN ALL ***
// CSIPHY: release csiphy
struct msm_camera_csi_lane_params csi_lane_params = {0};
csi_lane_params.csi_lane_mask = 0x1f;
csiphy_cfg_data.cfg.csi_lane_params = &csi_lane_params;
csiphy_cfg_data.cfgtype = CSIPHY_RELEASE;
err = ioctl(s->csiphy_fd, VIDIOC_MSM_CSIPHY_IO_CFG, &csiphy_cfg_data);
LOG("release csiphy: %d", err);
// CSID: release csid
csid_cfg_data.cfgtype = CSID_RELEASE;
err = ioctl(s->csid_fd, VIDIOC_MSM_CSID_IO_CFG, &csid_cfg_data);
LOG("release csid: %d", err);
// SENSOR: send power down
memset(&sensorb_cfg_data, 0, sizeof(sensorb_cfg_data));
sensorb_cfg_data.cfgtype = CFG_POWER_DOWN;
err = ioctl(s->sensor_fd, VIDIOC_MSM_SENSOR_CFG, &sensorb_cfg_data);
LOG("sensor power down: %d", err);
if (rear && s->device != DEVICE_LP3) {
// ois powerdown
ois_cfg_data.cfgtype = CFG_OIS_POWERDOWN;
err = ioctl(s->ois_fd, VIDIOC_MSM_OIS_CFG, &ois_cfg_data);
LOG("ois powerdown: %d", err);
}
// actuator powerdown
actuator_cfg_data.cfgtype = CFG_ACTUATOR_POWERDOWN;
err = ioctl(s->actuator_fd, VIDIOC_MSM_ACTUATOR_CFG, &actuator_cfg_data);
LOG("actuator powerdown: %d", err);
// reset isp
// struct msm_vfe_axi_halt_cmd halt_cmd = {
// .stop_camif = 1,
// .overflow_detected = 1,
// .blocking_halt = 1,
// };
// err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_AXI_HALT, &halt_cmd);
// printf("axi halt: %d\n", err);
// struct msm_vfe_axi_reset_cmd reset_cmd = {
// .blocking = 1,
// .frame_id = 1,
// };
// err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_AXI_RESET, &reset_cmd);
// printf("axi reset: %d\n", err);
// struct msm_vfe_axi_restart_cmd restart_cmd = {
// .enable_camif = 1,
// };
// err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_AXI_RESTART, &restart_cmd);
// printf("axi restart: %d\n", err);
// **** GO GO GO ****
LOG("******************** GO GO GO ************************");
s->eeprom = get_eeprom(s->eeprom_fd, &s->eeprom_size);
// printf("eeprom:\n");
// for (int i=0; i<s->eeprom_size; i++) {
// printf("%02x", s->eeprom[i]);
// }
// printf("\n");
// CSID: init csid
csid_cfg_data.cfgtype = CSID_INIT;
err = ioctl(s->csid_fd, VIDIOC_MSM_CSID_IO_CFG, &csid_cfg_data);
LOG("init csid: %d", err);
// CSIPHY: init csiphy
memset(&csiphy_cfg_data, 0, sizeof(csiphy_cfg_data));
csiphy_cfg_data.cfgtype = CSIPHY_INIT;
err = ioctl(s->csiphy_fd, VIDIOC_MSM_CSIPHY_IO_CFG, &csiphy_cfg_data);
LOG("init csiphy: %d", err);
// SENSOR: stop stream
struct msm_camera_i2c_reg_setting stop_settings = {
.reg_setting = stop_reg_array,
.size = ARRAYSIZE(stop_reg_array),
.addr_type = MSM_CAMERA_I2C_WORD_ADDR,
.data_type = MSM_CAMERA_I2C_BYTE_DATA,
.delay = 0
};
sensorb_cfg_data.cfgtype = CFG_SET_STOP_STREAM_SETTING;
sensorb_cfg_data.cfg.setting = &stop_settings;
err = ioctl(s->sensor_fd, VIDIOC_MSM_SENSOR_CFG, &sensorb_cfg_data);
LOG("stop stream: %d", err);
// SENSOR: send power up
memset(&sensorb_cfg_data, 0, sizeof(sensorb_cfg_data));
sensorb_cfg_data.cfgtype = CFG_POWER_UP;
err = ioctl(s->sensor_fd, VIDIOC_MSM_SENSOR_CFG, &sensorb_cfg_data);
LOG("sensor power up: %d", err);
// **** configure the sensor ****
// SENSOR: send i2c configuration
if (s->camera_id == CAMERA_ID_IMX298) {
err = sensor_write_regs(s, init_array_imx298, ARRAYSIZE(init_array_imx298), MSM_CAMERA_I2C_BYTE_DATA);
} else if (s->camera_id == CAMERA_ID_S5K3P8SP) {
err = sensor_write_regs(s, init_array_s5k3p8sp, ARRAYSIZE(init_array_s5k3p8sp), MSM_CAMERA_I2C_WORD_DATA);
} else if (s->camera_id == CAMERA_ID_IMX179) {
err = sensor_write_regs(s, init_array_imx179, ARRAYSIZE(init_array_imx179), MSM_CAMERA_I2C_BYTE_DATA);
} else if (s->camera_id == CAMERA_ID_OV8865) {
err = sensor_write_regs(s, init_array_ov8865, ARRAYSIZE(init_array_ov8865), MSM_CAMERA_I2C_BYTE_DATA);
} else {
assert(false);
}
LOG("sensor init i2c: %d", err);
if (rear) {
// init the actuator
actuator_cfg_data.cfgtype = CFG_ACTUATOR_POWERUP;
err = ioctl(s->actuator_fd, VIDIOC_MSM_ACTUATOR_CFG, &actuator_cfg_data);
LOG("actuator powerup: %d", err);
actuator_cfg_data.cfgtype = CFG_ACTUATOR_INIT;
err = ioctl(s->actuator_fd, VIDIOC_MSM_ACTUATOR_CFG, &actuator_cfg_data);
LOG("actuator init: %d", err);
// no OIS in LP3
if (s->device != DEVICE_LP3) {
// see sony_imx298_eeprom_format_afdata in libmmcamera_sony_imx298_eeprom.so
const float far_margin = -0.28;
uint16_t macro_dac = *(uint16_t*)(s->eeprom + 0x24);
s->infinity_dac = *(uint16_t*)(s->eeprom + 0x26);
LOG("macro_dac: %d infinity_dac: %d", macro_dac, s->infinity_dac);
int dac_range = macro_dac - s->infinity_dac;
s->infinity_dac += far_margin * dac_range;
LOG(" -> macro_dac: %d infinity_dac: %d", macro_dac, s->infinity_dac);
struct msm_actuator_reg_params_t actuator_reg_params[] = {
{
.reg_write_type = MSM_ACTUATOR_WRITE_DAC,
.hw_mask = 0,
.reg_addr = 240,
.hw_shift = 0,
.data_type = 10,
.addr_type = 4,
.reg_data = 0,
.delay = 0,
}, {
.reg_write_type = MSM_ACTUATOR_WRITE_DAC,
.hw_mask = 0,
.reg_addr = 241,
.hw_shift = 0,
.data_type = 10,
.addr_type = 4,
.reg_data = 0,
.delay = 0,
}, {
.reg_write_type = MSM_ACTUATOR_WRITE_DAC,
.hw_mask = 0,
.reg_addr = 242,
.hw_shift = 0,
.data_type = 10,
.addr_type = 4,
.reg_data = 0,
.delay = 0,
}, {
.reg_write_type = MSM_ACTUATOR_WRITE_DAC,
.hw_mask = 0,
.reg_addr = 243,
.hw_shift = 0,
.data_type = 10,
.addr_type = 4,
.reg_data = 0,
.delay = 0,
},
};
//...
struct reg_settings_t actuator_init_settings[1] = {0};
struct region_params_t region_params[] = {
{
.step_bound = {512, 0,},
.code_per_step = 118,
.qvalue = 128,
},
};
actuator_cfg_data.cfgtype = CFG_SET_ACTUATOR_INFO;
actuator_cfg_data.cfg.set_info = (struct msm_actuator_set_info_t){
.actuator_params = {
.act_type = ACTUATOR_VCM,
.reg_tbl_size = 4,
.data_size = 10,
.init_setting_size = 0,
.i2c_freq_mode = I2C_CUSTOM_MODE,
.i2c_addr = 28,
.i2c_addr_type = MSM_ACTUATOR_BYTE_ADDR,
.i2c_data_type = MSM_ACTUATOR_BYTE_DATA,
.reg_tbl_params = &actuator_reg_params[0],
.init_settings = &actuator_init_settings[0],
.park_lens = {
.damping_step = 1023,
.damping_delay = 15000,
.hw_params = 58404,
.max_step = 20,
}
},
.af_tuning_params = {
.initial_code = (int16_t)s->infinity_dac,
.pwd_step = 0,
.region_size = 1,
.total_steps = 512,
.region_params = &region_params[0],
},
};
err = ioctl(s->actuator_fd, VIDIOC_MSM_ACTUATOR_CFG, &actuator_cfg_data);
LOG("actuator set info: %d", err);
// power up ois
ois_cfg_data.cfgtype = CFG_OIS_POWERUP;
err = ioctl(s->ois_fd, VIDIOC_MSM_OIS_CFG, &ois_cfg_data);
LOG("ois powerup: %d", err);
ois_cfg_data.cfgtype = CFG_OIS_INIT;
err = ioctl(s->ois_fd, VIDIOC_MSM_OIS_CFG, &ois_cfg_data);
LOG("ois init: %d", err);
ois_cfg_data.cfgtype = CFG_OIS_CONTROL;
ois_cfg_data.cfg.set_info.ois_params = (struct msm_ois_params_t){
// .data_size = 26312,
.setting_size = 120,
.i2c_addr = 28,
.i2c_freq_mode = I2C_CUSTOM_MODE,
// .i2c_addr_type = wtf
// .i2c_data_type = wtf
.settings = &ois_init_settings[0],
};
err = ioctl(s->ois_fd, VIDIOC_MSM_OIS_CFG, &ois_cfg_data);
LOG("ois init settings: %d", err);
} else {
// leeco actuator (DW9800W H-Bridge Driver IC)
// from sniff
s->infinity_dac = 364;
struct msm_actuator_reg_params_t actuator_reg_params[] = {
{
.reg_write_type = MSM_ACTUATOR_WRITE_DAC,
.hw_mask = 0,
// MSB here at address 3
.reg_addr = 3,
.hw_shift = 0,
.data_type = 9,
.addr_type = 4,
.reg_data = 0,
.delay = 0,
},
};
struct reg_settings_t actuator_init_settings[] = {
{ .reg_addr=2, .addr_type=MSM_ACTUATOR_BYTE_ADDR, .reg_data=1, .data_type = MSM_ACTUATOR_BYTE_DATA, .i2c_operation = MSM_ACT_WRITE, .delay = 0 }, // PD = power down
{ .reg_addr=2, .addr_type=MSM_ACTUATOR_BYTE_ADDR, .reg_data=0, .data_type = MSM_ACTUATOR_BYTE_DATA, .i2c_operation = MSM_ACT_WRITE, .delay = 2 }, // 0 = power up
{ .reg_addr=2, .addr_type=MSM_ACTUATOR_BYTE_ADDR, .reg_data=2, .data_type = MSM_ACTUATOR_BYTE_DATA, .i2c_operation = MSM_ACT_WRITE, .delay = 2 }, // RING = SAC mode
{ .reg_addr=6, .addr_type=MSM_ACTUATOR_BYTE_ADDR, .reg_data=64, .data_type = MSM_ACTUATOR_BYTE_DATA, .i2c_operation = MSM_ACT_WRITE, .delay = 0 }, // 0x40 = SAC3 mode
{ .reg_addr=7, .addr_type=MSM_ACTUATOR_BYTE_ADDR, .reg_data=113, .data_type = MSM_ACTUATOR_BYTE_DATA, .i2c_operation = MSM_ACT_WRITE, .delay = 0 },
// 0x71 = DIV1 | DIV0 | SACT0 -- Tvib x 1/4 (quarter)
// SAC Tvib = 6.3 ms + 0.1 ms = 6.4 ms / 4 = 1.6 ms
// LSC 1-step = 252 + 1*4 = 256 ms / 4 = 64 ms
};
struct region_params_t region_params[] = {
{
.step_bound = {238, 0,},
.code_per_step = 235,
.qvalue = 128,
},
};
actuator_cfg_data.cfgtype = CFG_SET_ACTUATOR_INFO;
actuator_cfg_data.cfg.set_info = (struct msm_actuator_set_info_t){
.actuator_params = {
.act_type = ACTUATOR_BIVCM,
.reg_tbl_size = 1,
.data_size = 10,
.init_setting_size = 5,
.i2c_freq_mode = I2C_STANDARD_MODE,
.i2c_addr = 24,
.i2c_addr_type = MSM_ACTUATOR_BYTE_ADDR,
.i2c_data_type = MSM_ACTUATOR_WORD_DATA,
.reg_tbl_params = &actuator_reg_params[0],
.init_settings = &actuator_init_settings[0],
.park_lens = {
.damping_step = 1023,
.damping_delay = 14000,
.hw_params = 11,
.max_step = 20,
}
},
.af_tuning_params = {
.initial_code = (int16_t)s->infinity_dac,
.pwd_step = 0,
.region_size = 1,
.total_steps = 238,
.region_params = &region_params[0],
},
};
err = ioctl(s->actuator_fd, VIDIOC_MSM_ACTUATOR_CFG, &actuator_cfg_data);
LOG("actuator set info: %d", err);
}
}
if (s->camera_id == CAMERA_ID_IMX298) {
err = sensor_write_regs(s, mode_setting_array_imx298, ARRAYSIZE(mode_setting_array_imx298), MSM_CAMERA_I2C_BYTE_DATA);
LOG("sensor setup: %d", err);
}
// CSIPHY: configure csiphy
if (s->camera_id == CAMERA_ID_IMX298) {
csiphy_params.lane_cnt = 4;
csiphy_params.settle_cnt = 14;
csiphy_params.lane_mask = 0x1f;
csiphy_params.csid_core = 0;
} else if (s->camera_id == CAMERA_ID_S5K3P8SP) {
csiphy_params.lane_cnt = 4;
csiphy_params.settle_cnt = 24;
csiphy_params.lane_mask = 0x1f;
csiphy_params.csid_core = 0;
} else if (s->camera_id == CAMERA_ID_IMX179) {
csiphy_params.lane_cnt = 4;
csiphy_params.settle_cnt = 11;
csiphy_params.lane_mask = 0x1f;
csiphy_params.csid_core = 2;
} else if (s->camera_id == CAMERA_ID_OV8865) {
// guess!
csiphy_params.lane_cnt = 4;
csiphy_params.settle_cnt = 24;
csiphy_params.lane_mask = 0x1f;
csiphy_params.csid_core = 2;
}
csiphy_cfg_data.cfgtype = CSIPHY_CFG;
csiphy_cfg_data.cfg.csiphy_params = &csiphy_params;
err = ioctl(s->csiphy_fd, VIDIOC_MSM_CSIPHY_IO_CFG, &csiphy_cfg_data);
LOG("csiphy configure: %d", err);
// CSID: configure csid
csid_params.lane_cnt = 4;
csid_params.lane_assign = 0x4320;
if (rear) {
csid_params.phy_sel = 0;
} else {
csid_params.phy_sel = 2;
}
csid_params.lut_params.num_cid = rear ? 3 : 1;
#define CSI_STATS 0x35
#define CSI_PD 0x36
csid_params.lut_params.vc_cfg_a[0].cid = 0;
csid_params.lut_params.vc_cfg_a[0].dt = CSI_RAW10;
csid_params.lut_params.vc_cfg_a[0].decode_format = CSI_DECODE_10BIT;
csid_params.lut_params.vc_cfg_a[1].cid = 1;
csid_params.lut_params.vc_cfg_a[1].dt = CSI_PD;
csid_params.lut_params.vc_cfg_a[1].decode_format = CSI_DECODE_10BIT;
csid_params.lut_params.vc_cfg_a[2].cid = 2;
csid_params.lut_params.vc_cfg_a[2].dt = CSI_STATS;
csid_params.lut_params.vc_cfg_a[2].decode_format = CSI_DECODE_10BIT;
csid_params.lut_params.vc_cfg[0] = &csid_params.lut_params.vc_cfg_a[0];
csid_params.lut_params.vc_cfg[1] = &csid_params.lut_params.vc_cfg_a[1];
csid_params.lut_params.vc_cfg[2] = &csid_params.lut_params.vc_cfg_a[2];
csid_cfg_data.cfgtype = CSID_CFG;
csid_cfg_data.cfg.csid_params = &csid_params;
err = ioctl(s->csid_fd, VIDIOC_MSM_CSID_IO_CFG, &csid_cfg_data);
LOG("csid configure: %d", err);
// ISP: SMMU_ATTACH
struct msm_vfe_smmu_attach_cmd smmu_attach_cmd = {
.security_mode = 0,
.iommu_attach_mode = IOMMU_ATTACH
};
err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_SMMU_ATTACH, &smmu_attach_cmd);
LOG("isp smmu attach: %d", err);
// ******************* STREAM RAW *****************************
// configure QMET input
for (int i = 0; i < (rear ? 3 : 1); i++) {
StreamState *ss = &s->ss[i];
memset(&input_cfg, 0, sizeof(struct msm_vfe_input_cfg));
input_cfg.input_src = (msm_vfe_input_src)(VFE_RAW_0+i);
input_cfg.input_pix_clk = s->pixel_clock;
input_cfg.d.rdi_cfg.cid = i;
input_cfg.d.rdi_cfg.frame_based = 1;
err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_INPUT_CFG, &input_cfg);
LOG("configure input(%d): %d", i, err);
// ISP: REQUEST_STREAM
ss->stream_req.axi_stream_handle = 0;
if (rear) {
ss->stream_req.session_id = 2;
ss->stream_req.stream_id = /*ISP_META_CHANNEL_BIT | */ISP_NATIVE_BUF_BIT | (1+i);
} else {
ss->stream_req.session_id = 3;
ss->stream_req.stream_id = ISP_NATIVE_BUF_BIT | 1;
}
if (i == 0) {
ss->stream_req.output_format = v4l2_fourcc('R', 'G', '1', '0');
} else {
ss->stream_req.output_format = v4l2_fourcc('Q', 'M', 'E', 'T');
}
ss->stream_req.stream_src = (msm_vfe_axi_stream_src)(RDI_INTF_0+i);
#ifdef HIGH_FPS
if (rear) {
ss->stream_req.frame_skip_pattern = EVERY_3FRAME;
}
#endif
ss->stream_req.frame_base = 1;
ss->stream_req.buf_divert = 1; //i == 0;
// setup stream plane. doesn't even matter?
/*s->stream_req.plane_cfg[0].output_plane_format = Y_PLANE;
s->stream_req.plane_cfg[0].output_width = s->ci.frame_width;
s->stream_req.plane_cfg[0].output_height = s->ci.frame_height;
s->stream_req.plane_cfg[0].output_stride = s->ci.frame_width;
s->stream_req.plane_cfg[0].output_scan_lines = s->ci.frame_height;
s->stream_req.plane_cfg[0].rdi_cid = 0;*/
err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_REQUEST_STREAM, &ss->stream_req);
LOG("isp request stream: %d -> 0x%x", err, ss->stream_req.axi_stream_handle);
// ISP: REQUEST_BUF
ss->buf_request.session_id = ss->stream_req.session_id;
ss->buf_request.stream_id = ss->stream_req.stream_id;
ss->buf_request.num_buf = FRAME_BUF_COUNT;
ss->buf_request.buf_type = ISP_PRIVATE_BUF;
ss->buf_request.handle = 0;
err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_REQUEST_BUF, &ss->buf_request);
LOG("isp request buf: %d", err);
LOG("got buf handle: 0x%x", ss->buf_request.handle);
// ENQUEUE all buffers
for (int j = 0; j < ss->buf_request.num_buf; j++) {
ss->qbuf_info[j].handle = ss->buf_request.handle;
ss->qbuf_info[j].buf_idx = j;
ss->qbuf_info[j].buffer.num_planes = 1;
ss->qbuf_info[j].buffer.planes[0].addr = ss->bufs[j].fd;
ss->qbuf_info[j].buffer.planes[0].length = ss->bufs[j].len;
err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_ENQUEUE_BUF, &ss->qbuf_info[j]);
}
// ISP: UPDATE_STREAM
update_cmd.num_streams = 1;
update_cmd.update_info[0].user_stream_id = ss->stream_req.stream_id;
update_cmd.update_info[0].stream_handle = ss->stream_req.axi_stream_handle;
update_cmd.update_type = UPDATE_STREAM_ADD_BUFQ;
err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_UPDATE_STREAM, &update_cmd);
LOG("isp update stream: %d", err);
}
LOG("******** START STREAMS ********");
sub.id = 0;
sub.type = 0x1ff;
err = ioctl(s->isp_fd, VIDIOC_SUBSCRIBE_EVENT, &sub);
LOG("isp subscribe: %d", err);
// ISP: START_STREAM
s->stream_cfg.cmd = START_STREAM;
s->stream_cfg.num_streams = rear ? 3 : 1;
for (int i = 0; i < s->stream_cfg.num_streams; i++) {
s->stream_cfg.stream_handle[i] = s->ss[i].stream_req.axi_stream_handle;
}
err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_CFG_STREAM, &s->stream_cfg);
LOG("isp start stream: %d", err);
}
static struct damping_params_t actuator_ringing_params = {
.damping_step = 1023,
.damping_delay = 15000,
.hw_params = 0x0000e422,
};
static void rear_start(CameraState *s) {
int err;
struct msm_actuator_cfg_data actuator_cfg_data = {0};
set_exposure(s, 1.0, 1.0);
err = sensor_write_regs(s, start_reg_array, ARRAYSIZE(start_reg_array), MSM_CAMERA_I2C_BYTE_DATA);
LOG("sensor start regs: %d", err);
// focus on infinity assuming phone is perpendicular
int inf_step;
if (s->device != DEVICE_LP3) {
imx298_ois_calibration(s->ois_fd, s->eeprom);
inf_step = 332 - s->infinity_dac;
// initial guess
s->lens_true_pos = 300;
} else {
// default is OP3, this is for LeEco
actuator_ringing_params.damping_step = 1023;
actuator_ringing_params.damping_delay = 20000;
actuator_ringing_params.hw_params = 13;
inf_step = 512 - s->infinity_dac;
// initial guess
s->lens_true_pos = 400;
}
// reset lens position
memset(&actuator_cfg_data, 0, sizeof(actuator_cfg_data));
actuator_cfg_data.cfgtype = CFG_SET_POSITION;
actuator_cfg_data.cfg.setpos = (struct msm_actuator_set_position_t){
.number_of_steps = 1,
.hw_params = (uint32_t)((s->device != DEVICE_LP3) ? 0x0000e424 : 7),
.pos = {s->infinity_dac, 0},
.delay = {0,}
};
err = ioctl(s->actuator_fd, VIDIOC_MSM_ACTUATOR_CFG, &actuator_cfg_data);
LOG("actuator set pos: %d", err);
// TODO: confirm this isn't needed
/*memset(&actuator_cfg_data, 0, sizeof(actuator_cfg_data));
actuator_cfg_data.cfgtype = CFG_MOVE_FOCUS;
actuator_cfg_data.cfg.move = (struct msm_actuator_move_params_t){
.dir = 0,
.sign_dir = 1,
.dest_step_pos = inf_step,
.num_steps = inf_step,
.curr_lens_pos = 0,
.ringing_params = &actuator_ringing_params,
};
err = ioctl(s->actuator_fd, VIDIOC_MSM_ACTUATOR_CFG, &actuator_cfg_data); // should be ~332 at startup ?
LOG("init actuator move focus: %d", err);*/
//actuator_cfg_data.cfg.move.curr_lens_pos;
s->cur_lens_pos = 0;
s->cur_step_pos = inf_step;
actuator_move(s, s->cur_lens_pos);
LOG("init lens pos: %d", s->cur_lens_pos);
}
void actuator_move(CameraState *s, uint16_t target) {
int err;
int step = target - s->cur_lens_pos;
// LP3 moves only on even positions. TODO: use proper sensor params
if (s->device == DEVICE_LP3) {
step /= 2;
}
int dest_step_pos = s->cur_step_pos + step;
dest_step_pos = std::clamp(dest_step_pos, 0, 255);
struct msm_actuator_cfg_data actuator_cfg_data = {0};
actuator_cfg_data.cfgtype = CFG_MOVE_FOCUS;
actuator_cfg_data.cfg.move = (struct msm_actuator_move_params_t){
.dir = (int8_t)((step > 0) ? 0 : 1),
.sign_dir = (int8_t)((step > 0) ? 1 : -1),
.dest_step_pos = (int16_t)dest_step_pos,
.num_steps = abs(step),
.curr_lens_pos = s->cur_lens_pos,
.ringing_params = &actuator_ringing_params,
};
err = ioctl(s->actuator_fd, VIDIOC_MSM_ACTUATOR_CFG, &actuator_cfg_data);
//LOGD("actuator move focus: %d", err);
s->cur_step_pos = dest_step_pos;
s->cur_lens_pos = actuator_cfg_data.cfg.move.curr_lens_pos;
//LOGD("step %d target: %d lens pos: %d", dest_step_pos, target, s->cur_lens_pos);
}
static void parse_autofocus(CameraState *s, uint8_t *d) {
int good_count = 0;
int16_t max_focus = -32767;
int avg_focus = 0;
/*printf("FOCUS: ");
for (int i = 0; i < 0x10; i++) {
printf("%2.2X ", d[i]);
}*/
for (int i = 0; i < NUM_FOCUS; i++) {
int doff = i*5+5;
s->confidence[i] = d[doff];
// this should just be a 10-bit signed int instead of 11
// TODO: write it in a nicer way
int16_t focus_t = (d[doff+1] << 3) | (d[doff+2] >> 5);
if (focus_t >= 1024) focus_t = -(2048-focus_t);
s->focus[i] = focus_t;
//printf("%x->%d ", d[doff], focus_t);
if (s->confidence[i] > 0x20) {
good_count++;
max_focus = std::max(max_focus, s->focus[i]);
avg_focus += s->focus[i];
}
}
// self recover override
if (s->self_recover > 1) {
s->focus_err = 200 * ((s->self_recover % 2 == 0) ? 1:-1); // far for even numbers, close for odd
s->self_recover -= 2;
return;
}
if (good_count < 4) {
s->focus_err = nan("");
return;
}
avg_focus /= good_count;
// outlier rejection
if (abs(avg_focus - max_focus) > 200) {
s->focus_err = nan("");
return;
}
s->focus_err = max_focus*1.0;
}
static std::optional<float> get_accel_z(SubMaster *sm) {
if (sm->update(0) > 0) {
for (auto event : (*sm)["sensorEvents"].getSensorEvents()) {
if (event.which() == cereal::SensorEventData::ACCELERATION) {
if (auto v = event.getAcceleration().getV(); v.size() >= 3)
return -v[2];
break;
}
}
}
return std::nullopt;
}
static void do_autofocus(CameraState *s, SubMaster *sm) {
// params for focus PI controller
const int dac_up = s->device == DEVICE_LP3? LP3_AF_DAC_UP:OP3T_AF_DAC_UP;
const int dac_down = s->device == DEVICE_LP3? LP3_AF_DAC_DOWN:OP3T_AF_DAC_DOWN;
float lens_true_pos = s->lens_true_pos.load();
if (!isnan(s->focus_err)) {
// learn lens_true_pos
const float focus_kp = 0.005;
lens_true_pos -= s->focus_err*focus_kp;
}
if (auto accel_z = get_accel_z(sm)) {
s->last_sag_acc_z = *accel_z;
}
const float sag = (s->last_sag_acc_z / 9.8) * 128;
// stay off the walls
lens_true_pos = std::clamp(lens_true_pos, float(dac_down), float(dac_up));
int target = std::clamp(lens_true_pos - sag, float(dac_down), float(dac_up));
s->lens_true_pos.store(lens_true_pos);
/*char debug[4096];
char *pdebug = debug;
pdebug += sprintf(pdebug, "focus ");
for (int i = 0; i < NUM_FOCUS; i++) pdebug += sprintf(pdebug, "%2x(%4d) ", s->confidence[i], s->focus[i]);
pdebug += sprintf(pdebug, " err: %7.2f offset: %6.2f sag: %6.2f lens_true_pos: %6.2f cur_lens_pos: %4d->%4d", err * focus_kp, offset, sag, s->lens_true_pos, s->cur_lens_pos, target);
LOGD(debug);*/
actuator_move(s, target);
}
void camera_autoexposure(CameraState *s, float grey_frac) {
if (s->camera_num == 0) {
CameraExpInfo tmp = rear_exp.load();
tmp.op_id++;
tmp.grey_frac = grey_frac;
rear_exp.store(tmp);
} else {
CameraExpInfo tmp = front_exp.load();
tmp.op_id++;
tmp.grey_frac = grey_frac;
front_exp.store(tmp);
}
}
static void front_start(CameraState *s) {
int err;
set_exposure(s, 1.0, 1.0);
err = sensor_write_regs(s, start_reg_array, ARRAYSIZE(start_reg_array), MSM_CAMERA_I2C_BYTE_DATA);
LOG("sensor start regs: %d", err);
}
void cameras_open(MultiCameraState *s) {
int err;
struct ispif_cfg_data ispif_cfg_data = {};
struct msm_ispif_param_data ispif_params = {};
ispif_params.num = 4;
// rear camera
ispif_params.entries[0].vfe_intf = VFE0;
ispif_params.entries[0].intftype = RDI0;
ispif_params.entries[0].num_cids = 1;
ispif_params.entries[0].cids[0] = CID0;
ispif_params.entries[0].csid = CSID0;
// front camera
ispif_params.entries[1].vfe_intf = VFE1;
ispif_params.entries[1].intftype = RDI0;
ispif_params.entries[1].num_cids = 1;
ispif_params.entries[1].cids[0] = CID0;
ispif_params.entries[1].csid = CSID2;
// rear camera (focus)
ispif_params.entries[2].vfe_intf = VFE0;
ispif_params.entries[2].intftype = RDI1;
ispif_params.entries[2].num_cids = CID1;
ispif_params.entries[2].cids[0] = CID1;
ispif_params.entries[2].csid = CSID0;
// rear camera (stats, for AE)
ispif_params.entries[3].vfe_intf = VFE0;
ispif_params.entries[3].intftype = RDI2;
ispif_params.entries[3].num_cids = 1;
ispif_params.entries[3].cids[0] = CID2;
ispif_params.entries[3].csid = CSID0;
s->msmcfg_fd = open("/dev/media0", O_RDWR | O_NONBLOCK);
assert(s->msmcfg_fd >= 0);
sensors_init(s);
s->v4l_fd = open("/dev/video0", O_RDWR | O_NONBLOCK);
assert(s->v4l_fd >= 0);
if (s->device == DEVICE_LP3) {
s->ispif_fd = open("/dev/v4l-subdev15", O_RDWR | O_NONBLOCK);
} else {
s->ispif_fd = open("/dev/v4l-subdev16", O_RDWR | O_NONBLOCK);
}
assert(s->ispif_fd >= 0);
// ISPIF: stop
// memset(&ispif_cfg_data, 0, sizeof(ispif_cfg_data));
// ispif_cfg_data.cfg_type = ISPIF_STOP_FRAME_BOUNDARY;
// ispif_cfg_data.params = ispif_params;
// err = ioctl(s->ispif_fd, VIDIOC_MSM_ISPIF_CFG, &ispif_cfg_data);
// LOG("ispif stop: %d", err);
LOG("*** open front ***");
s->front.ss[0].bufs = s->front.buf.camera_bufs.get();
camera_open(&s->front, false);
LOG("*** open rear ***");
s->rear.ss[0].bufs = s->rear.buf.camera_bufs.get();
s->rear.ss[1].bufs = s->focus_bufs;
s->rear.ss[2].bufs = s->stats_bufs;
camera_open(&s->rear, true);
if (getenv("CAMERA_TEST")) {
cameras_close(s);
exit(0);
}
// ISPIF: set vfe info
memset(&ispif_cfg_data, 0, sizeof(ispif_cfg_data));
ispif_cfg_data.cfg_type = ISPIF_SET_VFE_INFO;
ispif_cfg_data.vfe_info.num_vfe = 2;
err = ioctl(s->ispif_fd, VIDIOC_MSM_ISPIF_CFG, &ispif_cfg_data);
LOG("ispif set vfe info: %d", err);
// ISPIF: setup
memset(&ispif_cfg_data, 0, sizeof(ispif_cfg_data));
ispif_cfg_data.cfg_type = ISPIF_INIT;
ispif_cfg_data.csid_version = 0x30050000; //CSID_VERSION_V35
err = ioctl(s->ispif_fd, VIDIOC_MSM_ISPIF_CFG, &ispif_cfg_data);
LOG("ispif setup: %d", err);
memset(&ispif_cfg_data, 0, sizeof(ispif_cfg_data));
ispif_cfg_data.cfg_type = ISPIF_CFG;
ispif_cfg_data.params = ispif_params;
err = ioctl(s->ispif_fd, VIDIOC_MSM_ISPIF_CFG, &ispif_cfg_data);
LOG("ispif cfg: %d", err);
ispif_cfg_data.cfg_type = ISPIF_START_FRAME_BOUNDARY;
err = ioctl(s->ispif_fd, VIDIOC_MSM_ISPIF_CFG, &ispif_cfg_data);
LOG("ispif start_frame_boundary: %d", err);
front_start(&s->front);
rear_start(&s->rear);
}
static void camera_close(CameraState *s) {
int err;
s->buf.stop();
// ISP: STOP_STREAM
s->stream_cfg.cmd = STOP_STREAM;
err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_CFG_STREAM, &s->stream_cfg);
LOG("isp stop stream: %d", err);
for (int i = 0; i < 3; i++) {
StreamState *ss = &s->ss[i];
if (ss->stream_req.axi_stream_handle != 0) {
err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_RELEASE_BUF, &ss->buf_request);
LOG("isp release buf: %d", err);
struct msm_vfe_axi_stream_release_cmd stream_release = {
.stream_handle = ss->stream_req.axi_stream_handle,
};
err = ioctl(s->isp_fd, VIDIOC_MSM_ISP_RELEASE_STREAM, &stream_release);
LOG("isp release stream: %d", err);
}
}
free(s->eeprom);
}
const char* get_isp_event_name(unsigned int type) {
switch (type) {
case ISP_EVENT_REG_UPDATE: return "ISP_EVENT_REG_UPDATE";
case ISP_EVENT_EPOCH_0: return "ISP_EVENT_EPOCH_0";
case ISP_EVENT_EPOCH_1: return "ISP_EVENT_EPOCH_1";
case ISP_EVENT_START_ACK: return "ISP_EVENT_START_ACK";
case ISP_EVENT_STOP_ACK: return "ISP_EVENT_STOP_ACK";
case ISP_EVENT_IRQ_VIOLATION: return "ISP_EVENT_IRQ_VIOLATION";
case ISP_EVENT_STATS_OVERFLOW: return "ISP_EVENT_STATS_OVERFLOW";
case ISP_EVENT_ERROR: return "ISP_EVENT_ERROR";
case ISP_EVENT_SOF: return "ISP_EVENT_SOF";
case ISP_EVENT_EOF: return "ISP_EVENT_EOF";
case ISP_EVENT_BUF_DONE: return "ISP_EVENT_BUF_DONE";
case ISP_EVENT_BUF_DIVERT: return "ISP_EVENT_BUF_DIVERT";
case ISP_EVENT_STATS_NOTIFY: return "ISP_EVENT_STATS_NOTIFY";
case ISP_EVENT_COMP_STATS_NOTIFY: return "ISP_EVENT_COMP_STATS_NOTIFY";
case ISP_EVENT_FE_READ_DONE: return "ISP_EVENT_FE_READ_DONE";
case ISP_EVENT_IOMMU_P_FAULT: return "ISP_EVENT_IOMMU_P_FAULT";
case ISP_EVENT_HW_FATAL_ERROR: return "ISP_EVENT_HW_FATAL_ERROR";
case ISP_EVENT_PING_PONG_MISMATCH: return "ISP_EVENT_PING_PONG_MISMATCH";
case ISP_EVENT_REG_UPDATE_MISSING: return "ISP_EVENT_REG_UPDATE_MISSING";
case ISP_EVENT_BUF_FATAL_ERROR: return "ISP_EVENT_BUF_FATAL_ERROR";
case ISP_EVENT_STREAM_UPDATE_DONE: return "ISP_EVENT_STREAM_UPDATE_DONE";
default: return "unknown";
}
}
static FrameMetadata get_frame_metadata(CameraState *s, uint32_t frame_id) {
pthread_mutex_lock(&s->frame_info_lock);
for (auto &i : s->frame_metadata) {
if (i.frame_id == frame_id) {
pthread_mutex_unlock(&s->frame_info_lock);
return i;
}
}
pthread_mutex_unlock(&s->frame_info_lock);
// should never happen
return (FrameMetadata){
.frame_id = (uint32_t)-1,
};
}
static void* ops_thread(void* arg) {
MultiCameraState *s = (MultiCameraState*)arg;
int rear_op_id_last = 0;
int front_op_id_last = 0;
CameraExpInfo rear_op;
CameraExpInfo front_op;
set_thread_name("camera_settings");
SubMaster sm({"sensorEvents"});
while(!do_exit) {
rear_op = rear_exp.load();
if (rear_op.op_id != rear_op_id_last) {
do_autoexposure(&s->rear, rear_op.grey_frac);
do_autofocus(&s->rear, &sm);
rear_op_id_last = rear_op.op_id;
}
front_op = front_exp.load();
if (front_op.op_id != front_op_id_last) {
do_autoexposure(&s->front, front_op.grey_frac);
front_op_id_last = front_op.op_id;
}
util::sleep_for(50);
}
return NULL;
}
static void update_lapmap(MultiCameraState *s, const CameraBuf *b, const int cnt) {
const size_t width = b->rgb_width / NUM_SEGMENTS_X;
const size_t height = b->rgb_height / NUM_SEGMENTS_Y;
static std::unique_ptr<uint8_t[]> rgb_roi_buf = std::make_unique<uint8_t[]>(width * height * 3);
static std::unique_ptr<int16_t[]> conv_result = std::make_unique<int16_t[]>(width * height);
// sharpness scores
const int roi_id = cnt % std::size(s->lapres); // rolling roi
const int x_offset = ROI_X_MIN + roi_id % (ROI_X_MAX - ROI_X_MIN + 1);
const int y_offset = ROI_Y_MIN + roi_id / (ROI_X_MAX - ROI_X_MIN + 1);
const uint8_t *rgb_addr_offset = (uint8_t *)b->cur_rgb_buf->addr + y_offset * height * FULL_STRIDE_X * 3 + x_offset * width * 3;
for (int i = 0; i < height; ++i) {
memcpy(rgb_roi_buf.get() + i * width * 3, rgb_addr_offset + i * FULL_STRIDE_X * 3, width * 3);
}
constexpr int conv_cl_localMemSize = (CONV_LOCAL_WORKSIZE + 2 * (3 / 2)) * (CONV_LOCAL_WORKSIZE + 2 * (3 / 2)) * (3 * sizeof(uint8_t));
CL_CHECK(clEnqueueWriteBuffer(b->q, s->rgb_conv_roi_cl, true, 0, width * height * 3 * sizeof(uint8_t), rgb_roi_buf.get(), 0, 0, 0));
CL_CHECK(clSetKernelArg(s->krnl_rgb_laplacian, 0, sizeof(cl_mem), (void *)&s->rgb_conv_roi_cl));
CL_CHECK(clSetKernelArg(s->krnl_rgb_laplacian, 1, sizeof(cl_mem), (void *)&s->rgb_conv_result_cl));
CL_CHECK(clSetKernelArg(s->krnl_rgb_laplacian, 2, sizeof(cl_mem), (void *)&s->rgb_conv_filter_cl));
CL_CHECK(clSetKernelArg(s->krnl_rgb_laplacian, 3, conv_cl_localMemSize, 0));
cl_event conv_event;
CL_CHECK(clEnqueueNDRangeKernel(b->q, s->krnl_rgb_laplacian, 2, NULL,
(size_t[]){width, height}, (size_t[]){CONV_LOCAL_WORKSIZE, CONV_LOCAL_WORKSIZE}, 0, 0, &conv_event));
clWaitForEvents(1, &conv_event);
CL_CHECK(clReleaseEvent(conv_event));
CL_CHECK(clEnqueueReadBuffer(b->q, s->rgb_conv_result_cl, true, 0,
width * height * sizeof(int16_t), conv_result.get(), 0, 0, 0));
s->lapres[roi_id] = get_lapmap_one(conv_result.get(), width, height);
}
static void setup_self_recover(CameraState *c, const uint16_t *lapres, size_t lapres_size) {
const int dac_down = c->device == DEVICE_LP3 ? LP3_AF_DAC_DOWN : OP3T_AF_DAC_DOWN;
const int dac_up = c->device == DEVICE_LP3 ? LP3_AF_DAC_UP : OP3T_AF_DAC_UP;
const int dac_m = c->device == DEVICE_LP3 ? LP3_AF_DAC_M : OP3T_AF_DAC_M;
const int dac_3sig = c->device == DEVICE_LP3 ? LP3_AF_DAC_3SIG : OP3T_AF_DAC_3SIG;
const float lens_true_pos = c->lens_true_pos.load();
int self_recover = c->self_recover.load();
if (self_recover < 2 && (lens_true_pos < (dac_down + 1) || lens_true_pos > (dac_up - 1)) && is_blur(lapres, lapres_size)) {
// truly stuck, needs help
if (--self_recover < -FOCUS_RECOVER_PATIENCE) {
LOGD("rear camera bad state detected. attempting recovery from %.1f, recover state is %d", lens_true_pos, self_recover);
// parity determined by which end is stuck at
self_recover = FOCUS_RECOVER_STEPS + (lens_true_pos < dac_m ? 1 : 0);
}
} else if (self_recover < 2 && (lens_true_pos < (dac_m - dac_3sig) || lens_true_pos > (dac_m + dac_3sig))) {
// in suboptimal position with high prob, but may still recover by itself
if (--self_recover < -(FOCUS_RECOVER_PATIENCE * 3)) {
self_recover = FOCUS_RECOVER_STEPS / 2 + (lens_true_pos < dac_m ? 1 : 0);
}
} else if (self_recover < 0) {
self_recover += 1; // reset if fine
}
c->self_recover.store(self_recover);
}
void camera_process_front(MultiCameraState *s, CameraState *c, int cnt) {
common_camera_process_front(s->sm_front, s->pm, c, cnt);
}
// called by processing_thread
void camera_process_frame(MultiCameraState *s, CameraState *c, int cnt) {
const CameraBuf *b = &c->buf;
update_lapmap(s, b, cnt);
setup_self_recover(c, &s->lapres[0], std::size(s->lapres));
MessageBuilder msg;
auto framed = msg.initEvent().initFrame();
fill_frame_data(framed, b->cur_frame_data, cnt);
if (env_send_rear) {
fill_frame_image(framed, (uint8_t *)b->cur_rgb_buf->addr, b->rgb_width, b->rgb_height, b->rgb_stride);
}
framed.setFocusVal(s->rear.focus);
framed.setFocusConf(s->rear.confidence);
framed.setRecoverState(s->rear.self_recover);
framed.setSharpnessScore(s->lapres);
framed.setTransform(b->yuv_transform.v);
s->pm->send("frame", msg);
if (cnt % 100 == 3) {
create_thumbnail(s, c, (uint8_t *)b->cur_rgb_buf->addr);
}
if (cnt % 3 == 0) {
const int x = 290, y = 322, width = 560, height = 314;
const int skip = 1;
set_exposure_target(c, (const uint8_t *)b->yuv_bufs[b->cur_yuv_idx].y, x, x + width, skip, y, y + height, skip);
}
}
void cameras_run(MultiCameraState *s) {
int err;
pthread_t ops_thread_handle;
err = pthread_create(&ops_thread_handle, NULL,
ops_thread, s);
assert(err == 0);
std::vector<std::thread> threads;
threads.push_back(start_process_thread(s, "processing", &s->rear, camera_process_frame));
threads.push_back(start_process_thread(s, "frontview", &s->front, camera_process_front));
CameraState* cameras[2] = {&s->rear, &s->front};
while (!do_exit) {
struct pollfd fds[2] = {{0}};
fds[0].fd = cameras[0]->isp_fd;
fds[0].events = POLLPRI;
fds[1].fd = cameras[1]->isp_fd;
fds[1].events = POLLPRI;
int ret = poll(fds, ARRAYSIZE(fds), 1000);
if (ret < 0) {
if (errno == EINTR || errno == EAGAIN) continue;
LOGE("poll failed (%d - %d)", ret, errno);
break;
}
// process cameras
for (int i=0; i<2; i++) {
if (!fds[i].revents) continue;
CameraState *c = cameras[i];
struct v4l2_event ev;
ret = ioctl(c->isp_fd, VIDIOC_DQEVENT, &ev);
struct msm_isp_event_data *isp_event_data = (struct msm_isp_event_data *)ev.u.data;
unsigned int event_type = ev.type;
uint64_t timestamp = (isp_event_data->mono_timestamp.tv_sec*1000000000ULL
+ isp_event_data->mono_timestamp.tv_usec*1000);
int buf_idx = isp_event_data->u.buf_done.buf_idx;
int stream_id = isp_event_data->u.buf_done.stream_id;
int buffer = (stream_id&0xFFFF) - 1;
uint64_t t = nanos_since_boot();
/*if (i == 1) {
printf("%10.2f: VIDIOC_DQEVENT: %d type:%X (%s)\n", t*1.0/1e6, ret, event_type, get_isp_event_name(event_type));
}*/
// printf("%d: %s\n", i, get_isp_event_name(event_type));
switch (event_type) {
case ISP_EVENT_BUF_DIVERT:
/*if (c->is_samsung) {
printf("write %d\n", c->frame_size);
FILE *f = fopen("/tmp/test", "wb");
fwrite((void*)c->camera_bufs[i].addr, 1, c->frame_size, f);
fclose(f);
}*/
//printf("divert: %d %d %d\n", i, buffer, buf_idx);
if (buffer == 0) {
c->buf.camera_bufs_metadata[buf_idx] = get_frame_metadata(c, isp_event_data->frame_id);
tbuffer_dispatch(&c->buf.camera_tb, buf_idx);
} else {
uint8_t *d = (uint8_t*)(c->ss[buffer].bufs[buf_idx].addr);
if (buffer == 1) {
parse_autofocus(c, d);
}
c->ss[buffer].qbuf_info[buf_idx].dirty_buf = 1;
ioctl(c->isp_fd, VIDIOC_MSM_ISP_ENQUEUE_BUF, &c->ss[buffer].qbuf_info[buf_idx]);
}
break;
case ISP_EVENT_EOF:
// printf("ISP_EVENT_EOF delta %f\n", (t-last_t)/1e6);
c->last_t = t;
pthread_mutex_lock(&c->frame_info_lock);
c->frame_metadata[c->frame_metadata_idx] = (FrameMetadata){
.frame_id = isp_event_data->frame_id,
.timestamp_eof = timestamp,
.frame_length = (unsigned int)c->cur_frame_length,
.integ_lines = (unsigned int)c->cur_integ_lines,
.global_gain = (unsigned int)c->cur_gain,
.lens_pos = c->cur_lens_pos,
.lens_sag = c->last_sag_acc_z,
.lens_err = c->focus_err,
.lens_true_pos = c->lens_true_pos,
.gain_frac = c->cur_gain_frac,
};
c->frame_metadata_idx = (c->frame_metadata_idx+1)%METADATA_BUF_COUNT;
pthread_mutex_unlock(&c->frame_info_lock);
break;
case ISP_EVENT_ERROR:
LOGE("ISP_EVENT_ERROR! err type: 0x%08x", isp_event_data->u.error_info.err_type);
break;
}
}
}
LOG(" ************** STOPPING **************");
err = pthread_join(ops_thread_handle, NULL);
assert(err == 0);
cameras_close(s);
for (auto &t : threads) t.join();
}
void cameras_close(MultiCameraState *s) {
camera_close(&s->rear);
camera_close(&s->front);
for (int i = 0; i < FRAME_BUF_COUNT; i++) {
visionbuf_free(&s->focus_bufs[i]);
visionbuf_free(&s->stats_bufs[i]);
}
CL_CHECK(clReleaseMemObject(s->rgb_conv_roi_cl));
CL_CHECK(clReleaseMemObject(s->rgb_conv_result_cl));
CL_CHECK(clReleaseMemObject(s->rgb_conv_filter_cl));
CL_CHECK(clReleaseKernel(s->krnl_rgb_laplacian));
CL_CHECK(clReleaseProgram(s->prg_rgb_laplacian));
delete s->sm_front;
delete s->pm;
}
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