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AI-on-the-edge-device/code/components/jomjol_controlcamera/ClassControllCamera.cpp
CaCO3 58185a0569 Show PSRAM usage (#2206) 
* centralize PSRAM usage (application code only)

* update logging

* update logging

* fix use after free

* initialize buffer

* free rgb_image before ussing it for new allocation

* use wrapper function

* switch log level to debug

* .

* undo adding free() calls

* .

* add names to all CImage instances

* .

* .

* .

* revert changes of stbi_image_free() with free_psram_heap() on the places where is is not in PSRAM

* .

* typos

* typo

* Added MQTT Outbox explanation/warning

* added CONFIG_SPIRAM_USE_MEMMAP explanation

---------

Co-authored-by: CaCO3 <caco@ruinelli.ch>
2023-03-19 23:28:06 +01:00

771 lines
22 KiB
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#include "ClassControllCamera.h"
#include "ClassLogFile.h"
#include <stdio.h>
#include "driver/gpio.h"
#include "esp_timer.h"
#include "esp_log.h"
#include "Helper.h"
#include "statusled.h"
#include "CImageBasis.h"
#include "server_ota.h"
#include "server_GPIO.h"
#include "../../include/defines.h"
#include <esp_event.h>
#include <esp_log.h>
#include <esp_system.h>
#include <nvs_flash.h>
#include <sys/param.h>
#include <string.h>
#include "freertos/FreeRTOS.h"
#include "freertos/task.h"
#include "esp_camera.h"
#include "driver/ledc.h"
#include "server_tflite.h"
static const char *TAG = "CAM";
static camera_config_t camera_config = {
.pin_pwdn = CAM_PIN_PWDN,
.pin_reset = CAM_PIN_RESET,
.pin_xclk = CAM_PIN_XCLK,
.pin_sscb_sda = CAM_PIN_SIOD,
.pin_sscb_scl = CAM_PIN_SIOC,
.pin_d7 = CAM_PIN_D7,
.pin_d6 = CAM_PIN_D6,
.pin_d5 = CAM_PIN_D5,
.pin_d4 = CAM_PIN_D4,
.pin_d3 = CAM_PIN_D3,
.pin_d2 = CAM_PIN_D2,
.pin_d1 = CAM_PIN_D1,
.pin_d0 = CAM_PIN_D0,
.pin_vsync = CAM_PIN_VSYNC,
.pin_href = CAM_PIN_HREF,
.pin_pclk = CAM_PIN_PCLK,
//XCLK 20MHz or 10MHz for OV2640 double FPS (Experimental)
.xclk_freq_hz = 20000000, // Orginal value
// .xclk_freq_hz = 5000000, // Test to get rid of the image errors !!!! Hangs in version 9.2 !!!!
.ledc_timer = LEDC_TIMER_0,
.ledc_channel = LEDC_CHANNEL_0,
.pixel_format = PIXFORMAT_JPEG, //YUV422,GRAYSCALE,RGB565,JPEG
.frame_size = FRAMESIZE_VGA, //QQVGA-UXGA Do not use sizes above QVGA when not JPEG
// .frame_size = FRAMESIZE_UXGA, //QQVGA-UXGA Do not use sizes above QVGA when not JPEG
.jpeg_quality = 12, //0-63 lower number means higher quality
.fb_count = 1, //if more than one, i2s runs in continuous mode. Use only with JPEG
.fb_location = CAMERA_FB_IN_PSRAM, /*!< The location where the frame buffer will be allocated */
.grab_mode = CAMERA_GRAB_LATEST, // only from new esp32cam version
};
CCamera Camera;
uint8_t *demoImage = NULL; // Buffer holding the demo image in bytes
#define DEMO_IMAGE_SIZE 30000 // Max size of demo image in bytes
typedef struct {
httpd_req_t *req;
size_t len;
} jpg_chunking_t;
bool CCamera::testCamera(void) {
bool success;
camera_fb_t *fb = esp_camera_fb_get();
if (fb) {
success = true;
}
else {
success = false;
}
esp_camera_fb_return(fb);
return success;
}
void CCamera::ledc_init(void)
{
#ifdef USE_PWM_LEDFLASH
// Prepare and then apply the LEDC PWM timer configuration
ledc_timer_config_t ledc_timer = { };
ledc_timer.speed_mode = LEDC_MODE;
ledc_timer.timer_num = LEDC_TIMER;
ledc_timer.duty_resolution = LEDC_DUTY_RES;
ledc_timer.freq_hz = LEDC_FREQUENCY; // Set output frequency at 5 kHz
ledc_timer.clk_cfg = LEDC_AUTO_CLK;
ESP_ERROR_CHECK(ledc_timer_config(&ledc_timer));
// Prepare and then apply the LEDC PWM channel configuration
ledc_channel_config_t ledc_channel = { };
ledc_channel.speed_mode = LEDC_MODE;
ledc_channel.channel = LEDC_CHANNEL;
ledc_channel.timer_sel = LEDC_TIMER;
ledc_channel.intr_type = LEDC_INTR_DISABLE;
ledc_channel.gpio_num = LEDC_OUTPUT_IO;
ledc_channel.duty = 0; // Set duty to 0%
ledc_channel.hpoint = 0;
ESP_ERROR_CHECK(ledc_channel_config(&ledc_channel));
#endif
}
static size_t jpg_encode_stream(void * arg, size_t index, const void* data, size_t len)
{
jpg_chunking_t *j = (jpg_chunking_t *)arg;
if(!index) {
j->len = 0;
}
if(httpd_resp_send_chunk(j->req, (const char *)data, len) != ESP_OK) {
return 0;
}
j->len += len;
return len;
}
bool CCamera::SetBrightnessContrastSaturation(int _brightness, int _contrast, int _saturation)
{
_brightness = min(2, max(-2, _brightness));
_contrast = min(2, max(-2, _contrast));
_saturation = min(2, max(-2, _saturation));
sensor_t * s = esp_camera_sensor_get();
if (s) {
s->set_saturation(s, _saturation);
s->set_contrast(s, _contrast);
s->set_brightness(s, _brightness);
/* Workaround - bug in cam library - enable bits are set without using bitwise OR logic -> only latest enable setting is used */
/* Library version: https://github.com/espressif/esp32-camera/commit/5c8349f4cf169c8a61283e0da9b8cff10994d3f3 */
/* Reference: https://esp32.com/viewtopic.php?f=19&t=14376#p93178 */
/* The memory structure is as follows for
byte_0 = enable_bits
byte_0->bit0 = enable saturation and hue --> OK
byte_0->bit1 = enable saturation --> OK
byte_0->bit2 = enable brightness and contrast --> OK
byte_0->bit3 = enable green -> blue spitial effect (Antique and blunish and greenish and readdish and b&w) enable
byte_0->bit4 = anable gray -> read spitial effect (Antique and blunish and greenish and readdish and b&w) enable
byte_0->bit5 = remove (UV) in YUV color system
byte_0->bit6 = enable negative
byte_0->bit7 = remove (Y) in YUV color system
byte_1 = saturation1 0-255 --> ?
byte_2 = hue 0-255 --> OK
byte_3 = saturation2 0-255 --> OK
byte_4 = reenter saturation2 in documents --> ?
byte_5 = spital effect green -> blue 0-255 --> ?
byte_6 = spital effect gray -> read 0-255 --> ?
byte_7 = contrast lower byte 0-255 --> OK
byte_8 = contrast higher byte 0-255 --> OK
byte_9 = brightness 0-255 --> OK
byte_10= if byte_10==4 contrast effective --> ?
*/
//s->set_reg(s, 0x7C, 0xFF, 2); // Optional feature - hue setting: Select byte 2 in register 0x7C to set hue value
//s->set_reg(s, 0x7D, 0xFF, 0); // Optional feature - hue setting: Hue value 0 - 255
s->set_reg(s, 0xFF, 0x01, 0); // Select DSP bank
s->set_reg(s, 0x7C, 0xFF, 0); // Select byte 0 in register 0x7C
s->set_reg(s, 0x7D, 7, 7); // Set bit 0, 1, 2 in register 0x7D to enable saturation, contrast, brightness and hue control
}
else {
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "SetBrightnessContrastSaturation: Failed to get control structure");
}
if (((_brightness != brightness) || (_contrast != contrast) || (_saturation != saturation)) && isFixedExposure)
EnableAutoExposure(waitbeforepicture_org);
brightness = _brightness;
contrast = _contrast;
saturation = _saturation;
ESP_LOGD(TAG, "brightness %d, contrast: %d, saturation %d", brightness, contrast, saturation);
return true;
}
void CCamera::SetQualitySize(int qual, framesize_t resol)
{
qual = min(63, max(8, qual)); // Limit quality from 8..63 (values lower than 8 tent to be unstable)
sensor_t * s = esp_camera_sensor_get();
if (s) {
s->set_quality(s, qual);
s->set_framesize(s, resol);
}
else {
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "SetQualitySize: Failed to get control structure");
}
ActualResolution = resol;
ActualQuality = qual;
if (resol == FRAMESIZE_QVGA)
{
image_height = 240;
image_width = 320;
}
else if (resol == FRAMESIZE_VGA)
{
image_height = 480;
image_width = 640;
}
}
void CCamera::EnableAutoExposure(int flash_duration)
{
ESP_LOGD(TAG, "EnableAutoExposure");
LEDOnOff(true);
if (flash_duration > 0) {
LightOnOff(true);
const TickType_t xDelay = flash_duration / portTICK_PERIOD_MS;
vTaskDelay( xDelay );
}
camera_fb_t * fb = esp_camera_fb_get();
esp_camera_fb_return(fb);
fb = esp_camera_fb_get();
if (!fb) {
LEDOnOff(false);
LightOnOff(false);
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "EnableAutoExposure: Capture Failed. "
"Check camera module and/or proper electrical connection");
//doReboot();
}
esp_camera_fb_return(fb);
sensor_t * s = esp_camera_sensor_get();
if (s) {
s->set_gain_ctrl(s, 0);
s->set_exposure_ctrl(s, 0);
}
else {
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "EnableAutoExposure: Failed to get control structure to set gain+exposure");
}
LEDOnOff(false);
LightOnOff(false);
isFixedExposure = true;
waitbeforepicture_org = flash_duration;
}
esp_err_t CCamera::CaptureToBasisImage(CImageBasis *_Image, int delay)
{
#ifdef DEBUG_DETAIL_ON
LogFile.WriteHeapInfo("CaptureToBasisImage - Start");
#endif
_Image->EmptyImage(); //Delete previous stored raw image -> black image
LEDOnOff(true);
if (delay > 0) {
LightOnOff(true);
const TickType_t xDelay = delay / portTICK_PERIOD_MS;
vTaskDelay( xDelay );
}
#ifdef DEBUG_DETAIL_ON
LogFile.WriteHeapInfo("CaptureToBasisImage - After LightOn");
#endif
camera_fb_t * fb = esp_camera_fb_get();
esp_camera_fb_return(fb);
fb = esp_camera_fb_get();
if (!fb) {
LEDOnOff(false);
LightOnOff(false);
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "is not working anymore (CaptureToBasisImage) - most probably caused "
"by a hardware problem (instablility, ...). System will reboot.");
doReboot();
return ESP_FAIL;
}
if (demoMode) { // Use images stored on SD-Card instead of camera image
/* Replace Framebuffer with image from SD-Card */
loadNextDemoImage(fb);
}
CImageBasis* _zwImage = new CImageBasis("zwImage");
if (_zwImage) {
_zwImage->LoadFromMemory(fb->buf, fb->len);
}
else {
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "CaptureToBasisImage: Can't allocate _zwImage");
}
esp_camera_fb_return(fb);
#ifdef DEBUG_DETAIL_ON
LogFile.WriteHeapInfo("CaptureToBasisImage - After fb_get");
#endif
LEDOnOff(false);
if (delay > 0)
LightOnOff(false);
// TickType_t xDelay = 1000 / portTICK_PERIOD_MS;
// vTaskDelay( xDelay ); // wait for power to recover
#ifdef DEBUG_DETAIL_ON
LogFile.WriteHeapInfo("CaptureToBasisImage - After LoadFromMemory");
#endif
stbi_uc* p_target;
stbi_uc* p_source;
int channels = 3;
int width = image_width;
int height = image_height;
#ifdef DEBUG_DETAIL_ON
std::string _zw = "Targetimage: " + std::to_string((int) _Image->rgb_image) + " Size: " + std::to_string(_Image->width) + ", " + std::to_string(_Image->height);
_zw = _zw + " _zwImage: " + std::to_string((int) _zwImage->rgb_image) + " Size: " + std::to_string(_zwImage->width) + ", " + std::to_string(_zwImage->height);
LogFile.WriteToFile(ESP_LOG_DEBUG, TAG, _zw);
#endif
for (int x = 0; x < width; ++x)
for (int y = 0; y < height; ++y)
{
p_target = _Image->rgb_image + (channels * (y * width + x));
p_source = _zwImage->rgb_image + (channels * (y * width + x));
p_target[0] = p_source[0];
p_target[1] = p_source[1];
p_target[2] = p_source[2];
}
delete _zwImage;
#ifdef DEBUG_DETAIL_ON
LogFile.WriteHeapInfo("CaptureToBasisImage - Done");
#endif
return ESP_OK;
}
esp_err_t CCamera::CaptureToFile(std::string nm, int delay)
{
string ftype;
LEDOnOff(true); // Switched off to save power !
if (delay > 0) {
LightOnOff(true);
const TickType_t xDelay = delay / portTICK_PERIOD_MS;
vTaskDelay( xDelay );
}
camera_fb_t * fb = esp_camera_fb_get();
esp_camera_fb_return(fb);
fb = esp_camera_fb_get();
if (!fb) {
LEDOnOff(false);
LightOnOff(false);
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "CaptureToFile: Capture Failed. "
"Check camera module and/or proper electrical connection");
//doReboot();
return ESP_FAIL;
}
LEDOnOff(false);
#ifdef DEBUG_DETAIL_ON
ESP_LOGD(TAG, "w %d, h %d, size %d", fb->width, fb->height, fb->len);
#endif
nm = FormatFileName(nm);
#ifdef DEBUG_DETAIL_ON
ESP_LOGD(TAG, "Save Camera to: %s", nm.c_str());
#endif
ftype = toUpper(getFileType(nm));
#ifdef DEBUG_DETAIL_ON
ESP_LOGD(TAG, "Filetype: %s", ftype.c_str());
#endif
uint8_t * buf = NULL;
size_t buf_len = 0;
bool converted = false;
if (ftype.compare("BMP") == 0)
{
frame2bmp(fb, &buf, &buf_len);
converted = true;
}
if (ftype.compare("JPG") == 0)
{
if(fb->format != PIXFORMAT_JPEG){
bool jpeg_converted = frame2jpg(fb, ActualQuality, &buf, &buf_len);
converted = true;
if(!jpeg_converted){
ESP_LOGE(TAG, "JPEG compression failed");
}
} else {
buf_len = fb->len;
buf = fb->buf;
}
}
FILE * fp = fopen(nm.c_str(), "wb");
if (fp == NULL) { // If an error occurs during the file creation
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "CaptureToFile: Failed to open file " + nm);
}
else {
fwrite(buf, sizeof(uint8_t), buf_len, fp);
fclose(fp);
}
if (converted)
free(buf);
esp_camera_fb_return(fb);
if (delay > 0)
LightOnOff(false);
return ESP_OK;
}
esp_err_t CCamera::CaptureToHTTP(httpd_req_t *req, int delay)
{
esp_err_t res = ESP_OK;
size_t fb_len = 0;
int64_t fr_start = esp_timer_get_time();
LEDOnOff(true);
if (delay > 0) {
LightOnOff(true);
const TickType_t xDelay = delay / portTICK_PERIOD_MS;
vTaskDelay( xDelay );
}
camera_fb_t *fb = esp_camera_fb_get();
esp_camera_fb_return(fb);
fb = esp_camera_fb_get();
if (!fb) {
LEDOnOff(false);
LightOnOff(false);
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "CaptureToFile: Capture Failed. "
"Check camera module and/or proper electrical connection");
httpd_resp_send_500(req);
// doReboot();
return ESP_FAIL;
}
LEDOnOff(false);
res = httpd_resp_set_type(req, "image/jpeg");
if(res == ESP_OK){
res = httpd_resp_set_hdr(req, "Content-Disposition", "inline; filename=raw.jpg");
}
if(res == ESP_OK){
if (demoMode) { // Use images stored on SD-Card instead of camera image
LogFile.WriteToFile(ESP_LOG_DEBUG, TAG, "Using Demo image!");
/* Replace Framebuffer with image from SD-Card */
loadNextDemoImage(fb);
res = httpd_resp_send(req, (const char *)fb->buf, fb->len);
}
else {
if(fb->format == PIXFORMAT_JPEG){
fb_len = fb->len;
res = httpd_resp_send(req, (const char *)fb->buf, fb->len);
} else {
jpg_chunking_t jchunk = {req, 0};
res = frame2jpg_cb(fb, 80, jpg_encode_stream, &jchunk)?ESP_OK:ESP_FAIL;
httpd_resp_send_chunk(req, NULL, 0);
fb_len = jchunk.len;
}
}
}
esp_camera_fb_return(fb);
int64_t fr_end = esp_timer_get_time();
ESP_LOGI(TAG, "JPG: %uKB %ums", (uint32_t)(fb_len/1024), (uint32_t)((fr_end - fr_start)/1000));
if (delay > 0)
LightOnOff(false);
return res;
}
void CCamera::LightOnOff(bool status)
{
GpioHandler* gpioHandler = gpio_handler_get();
if ((gpioHandler != NULL) && (gpioHandler->isEnabled())) {
ESP_LOGD(TAG, "Use gpioHandler to trigger flashlight");
gpioHandler->flashLightEnable(status);
}
else {
#ifdef USE_PWM_LEDFLASH
if (status) {
ESP_LOGD(TAG, "Internal Flash-LED turn on with PWM %d", led_intensity);
ESP_ERROR_CHECK(ledc_set_duty(LEDC_MODE, LEDC_CHANNEL, led_intensity));
// Update duty to apply the new value
ESP_ERROR_CHECK(ledc_update_duty(LEDC_MODE, LEDC_CHANNEL));
}
else {
ESP_LOGD(TAG, "Internal Flash-LED turn off PWM");
ESP_ERROR_CHECK(ledc_set_duty(LEDC_MODE, LEDC_CHANNEL, 0));
ESP_ERROR_CHECK(ledc_update_duty(LEDC_MODE, LEDC_CHANNEL));
}
#else
// Init the GPIO
gpio_pad_select_gpio(FLASH_GPIO);
// Set the GPIO as a push/pull output
gpio_set_direction(FLASH_GPIO, GPIO_MODE_OUTPUT);
if (status)
gpio_set_level(FLASH_GPIO, 1);
else
gpio_set_level(FLASH_GPIO, 0);
#endif
}
}
void CCamera::LEDOnOff(bool status)
{
if (xHandle_task_StatusLED == NULL) {
// Init the GPIO
gpio_pad_select_gpio(BLINK_GPIO);
/* Set the GPIO as a push/pull output */
gpio_set_direction(BLINK_GPIO, GPIO_MODE_OUTPUT);
if (!status)
gpio_set_level(BLINK_GPIO, 1);
else
gpio_set_level(BLINK_GPIO, 0);
}
}
void CCamera::GetCameraParameter(httpd_req_t *req, int &qual, framesize_t &resol)
{
char _query[100];
char _qual[10];
char _size[10];
resol = ActualResolution;
qual = ActualQuality;
if (httpd_req_get_url_query_str(req, _query, 100) == ESP_OK)
{
ESP_LOGD(TAG, "Query: %s", _query);
if (httpd_query_key_value(_query, "size", _size, 10) == ESP_OK)
{
#ifdef DEBUG_DETAIL_ON
ESP_LOGD(TAG, "Size: %s", _size);
#endif
if (strcmp(_size, "QVGA") == 0)
resol = FRAMESIZE_QVGA; // 320x240
else if (strcmp(_size, "VGA") == 0)
resol = FRAMESIZE_VGA; // 640x480
else if (strcmp(_size, "SVGA") == 0)
resol = FRAMESIZE_SVGA; // 800x600
else if (strcmp(_size, "XGA") == 0)
resol = FRAMESIZE_XGA; // 1024x768
else if (strcmp(_size, "SXGA") == 0)
resol = FRAMESIZE_SXGA; // 1280x1024
else if (strcmp(_size, "UXGA") == 0)
resol = FRAMESIZE_UXGA; // 1600x1200
}
if (httpd_query_key_value(_query, "quality", _qual, 10) == ESP_OK)
{
#ifdef DEBUG_DETAIL_ON
ESP_LOGD(TAG, "Quality: %s", _qual);
#endif
qual = atoi(_qual);
if (qual > 63) // Limit to max. 63
qual = 63;
else if (qual < 8) // Limit to min. 8
qual = 8;
}
}
}
framesize_t CCamera::TextToFramesize(const char * _size)
{
if (strcmp(_size, "QVGA") == 0)
return FRAMESIZE_QVGA; // 320x240
else if (strcmp(_size, "VGA") == 0)
return FRAMESIZE_VGA; // 640x480
else if (strcmp(_size, "SVGA") == 0)
return FRAMESIZE_SVGA; // 800x600
else if (strcmp(_size, "XGA") == 0)
return FRAMESIZE_XGA; // 1024x768
else if (strcmp(_size, "SXGA") == 0)
return FRAMESIZE_SXGA; // 1280x1024
else if (strcmp(_size, "UXGA") == 0)
return FRAMESIZE_UXGA; // 1600x1200
return ActualResolution;
}
CCamera::CCamera()
{
#ifdef DEBUG_DETAIL_ON
ESP_LOGD(TAG, "CreateClassCamera");
#endif
brightness = 0;
contrast = 0;
saturation = 0;
isFixedExposure = false;
ledc_init();
}
esp_err_t CCamera::InitCam()
{
ESP_LOGD(TAG, "Init Camera");
ActualQuality = camera_config.jpeg_quality;
ActualResolution = camera_config.frame_size;
//initialize the camera
esp_camera_deinit(); // De-init in case it was already initialized
esp_err_t err = esp_camera_init(&camera_config);
if (err != ESP_OK) {
ESP_LOGE(TAG, "Camera Init Failed");
return err;
}
CameraInitSuccessful = true;
return ESP_OK;
}
void CCamera::SetLEDIntensity(float _intrel)
{
_intrel = min(_intrel, (float) 100);
_intrel = max(_intrel, (float) 0);
_intrel = _intrel / 100;
led_intensity = (int) (_intrel * 8191);
ESP_LOGD(TAG, "Set led_intensity to %d of 8191", led_intensity);
}
bool CCamera::getCameraInitSuccessful()
{
return CameraInitSuccessful;
}
std::vector<std::string> demoFiles;
void CCamera::useDemoMode()
{
char line[50];
FILE *fd = fopen("/sdcard/demo/files.txt", "r");
if (!fd) {
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "Can not start Demo mode, the folder '/sdcard/demo/' does not contain the needed files!");
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "See Details on https://jomjol.github.io/AI-on-the-edge-device-docs/Demo-Mode!");
return;
}
demoImage = (uint8_t*)malloc(DEMO_IMAGE_SIZE);
if (demoImage == NULL) {
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "Unable to acquire required memory for demo image!");
return;
}
while (fgets(line, sizeof(line), fd) != NULL) {
line[strlen(line) - 1] = '\0';
demoFiles.push_back(line);
}
fclose(fd);
LogFile.WriteToFile(ESP_LOG_INFO, TAG, "Using Demo mode (" + std::to_string(demoFiles.size()) +
" files) instead of real camera image!");
for (auto file : demoFiles) {
LogFile.WriteToFile(ESP_LOG_DEBUG, TAG, file);
}
demoMode = true;
}
bool CCamera::loadNextDemoImage(camera_fb_t *fb) {
char filename[50];
int readBytes;
long fileSize;
snprintf(filename, sizeof(filename), "/sdcard/demo/%s", demoFiles[getCountFlowRounds() % demoFiles.size()].c_str());
LogFile.WriteToFile(ESP_LOG_DEBUG, TAG, "Using " + std::string(filename) + " as demo image");
/* Inject saved image */
FILE * fp = fopen(filename, "rb");
if (!fp) {
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, "Failed to read file: " + std::string(filename) +"!");
return false;
}
fileSize = GetFileSize(filename);
if (fileSize > DEMO_IMAGE_SIZE) {
char buf[100];
snprintf(buf, sizeof(buf), "Demo Image (%d bytes) is larger than provided buffer (%d bytes)!",
(int)fileSize, DEMO_IMAGE_SIZE);
LogFile.WriteToFile(ESP_LOG_ERROR, TAG, std::string(buf));
return false;
}
readBytes = fread(demoImage, 1, DEMO_IMAGE_SIZE, fp);
LogFile.WriteToFile(ESP_LOG_DEBUG, TAG, "read " + std::to_string(readBytes) + " bytes");
fclose(fp);
fb->buf = demoImage; // Update pointer
fb->len = readBytes;
// ToDo do we also need to set height, width, format and timestamp?
return true;
}
long CCamera::GetFileSize(std::string filename)
{
struct stat stat_buf;
long rc = stat(filename.c_str(), &stat_buf);
return rc == 0 ? stat_buf.st_size : -1;
}
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