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Tino Hager
2018-06-27 23:57:54 +02:00
parent 8a504c737d
commit 170cebf8af
1 changed files with 202 additions and 202 deletions
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src/yolo_v2_class.cpp
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@ -56,306 +56,306 @@ int detect_mat(const uint8_t* data, const size_t data_length, bbox_t_container &
} }
int dispose() { int dispose() {
//if (detector != NULL) delete detector; //if (detector != NULL) delete detector;
//detector = NULL; //detector = NULL;
detector.reset(); detector.reset();
return 1; return 1;
} }
#ifdef GPU #ifdef GPU
void check_cuda(cudaError_t status) { void check_cuda(cudaError_t status) {
if (status != cudaSuccess) { if (status != cudaSuccess) {
const char *s = cudaGetErrorString(status); const char *s = cudaGetErrorString(status);
printf("CUDA Error Prev: %s\n", s); printf("CUDA Error Prev: %s\n", s);
} }
} }
#endif #endif
struct detector_gpu_t { struct detector_gpu_t {
network net; network net;
image images[FRAMES]; image images[FRAMES];
float *avg; float *avg;
float *predictions[FRAMES]; float *predictions[FRAMES];
int demo_index; int demo_index;
unsigned int *track_id; unsigned int *track_id;
}; };
YOLODLL_API Detector::Detector(std::string cfg_filename, std::string weight_filename, int gpu_id) : cur_gpu_id(gpu_id) YOLODLL_API Detector::Detector(std::string cfg_filename, std::string weight_filename, int gpu_id) : cur_gpu_id(gpu_id)
{ {
wait_stream = 0; wait_stream = 0;
int old_gpu_index; int old_gpu_index;
#ifdef GPU #ifdef GPU
check_cuda(cudaGetDevice(&old_gpu_index)); check_cuda( cudaGetDevice(&old_gpu_index) );
#endif #endif
detector_gpu_ptr = std::make_shared<detector_gpu_t>(); detector_gpu_ptr = std::make_shared<detector_gpu_t>();
detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get()); detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get());
#ifdef GPU #ifdef GPU
//check_cuda( cudaSetDevice(cur_gpu_id) ); //check_cuda( cudaSetDevice(cur_gpu_id) );
cuda_set_device(cur_gpu_id); cuda_set_device(cur_gpu_id);
printf(" Used GPU %d \n", cur_gpu_id); printf(" Used GPU %d \n", cur_gpu_id);
#endif #endif
network &net = detector_gpu.net; network &net = detector_gpu.net;
net.gpu_index = cur_gpu_id; net.gpu_index = cur_gpu_id;
//gpu_index = i; //gpu_index = i;
char *cfgfile = const_cast<char *>(cfg_filename.data()); char *cfgfile = const_cast<char *>(cfg_filename.data());
char *weightfile = const_cast<char *>(weight_filename.data()); char *weightfile = const_cast<char *>(weight_filename.data());
net = parse_network_cfg_custom(cfgfile, 1); net = parse_network_cfg_custom(cfgfile, 1);
if (weightfile) { if (weightfile) {
load_weights(&net, weightfile); load_weights(&net, weightfile);
} }
set_batch_network(&net, 1); set_batch_network(&net, 1);
net.gpu_index = cur_gpu_id; net.gpu_index = cur_gpu_id;
fuse_conv_batchnorm(net); fuse_conv_batchnorm(net);
layer l = net.layers[net.n - 1]; layer l = net.layers[net.n - 1];
int j; int j;
detector_gpu.avg = (float *)calloc(l.outputs, sizeof(float)); detector_gpu.avg = (float *)calloc(l.outputs, sizeof(float));
for (j = 0; j < FRAMES; ++j) detector_gpu.predictions[j] = (float *)calloc(l.outputs, sizeof(float)); for (j = 0; j < FRAMES; ++j) detector_gpu.predictions[j] = (float *)calloc(l.outputs, sizeof(float));
for (j = 0; j < FRAMES; ++j) detector_gpu.images[j] = make_image(1, 1, 3); for (j = 0; j < FRAMES; ++j) detector_gpu.images[j] = make_image(1, 1, 3);
detector_gpu.track_id = (unsigned int *)calloc(l.classes, sizeof(unsigned int)); detector_gpu.track_id = (unsigned int *)calloc(l.classes, sizeof(unsigned int));
for (j = 0; j < l.classes; ++j) detector_gpu.track_id[j] = 1; for (j = 0; j < l.classes; ++j) detector_gpu.track_id[j] = 1;
#ifdef GPU #ifdef GPU
check_cuda(cudaSetDevice(old_gpu_index)); check_cuda( cudaSetDevice(old_gpu_index) );
#endif #endif
} }
YOLODLL_API Detector::~Detector() YOLODLL_API Detector::~Detector()
{ {
detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get()); detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get());
layer l = detector_gpu.net.layers[detector_gpu.net.n - 1]; layer l = detector_gpu.net.layers[detector_gpu.net.n - 1];
free(detector_gpu.track_id); free(detector_gpu.track_id);
free(detector_gpu.avg); free(detector_gpu.avg);
for (int j = 0; j < FRAMES; ++j) free(detector_gpu.predictions[j]); for (int j = 0; j < FRAMES; ++j) free(detector_gpu.predictions[j]);
for (int j = 0; j < FRAMES; ++j) if (detector_gpu.images[j].data) free(detector_gpu.images[j].data); for (int j = 0; j < FRAMES; ++j) if(detector_gpu.images[j].data) free(detector_gpu.images[j].data);
int old_gpu_index; int old_gpu_index;
#ifdef GPU #ifdef GPU
cudaGetDevice(&old_gpu_index); cudaGetDevice(&old_gpu_index);
cuda_set_device(detector_gpu.net.gpu_index); cuda_set_device(detector_gpu.net.gpu_index);
#endif #endif
free_network(detector_gpu.net); free_network(detector_gpu.net);
#ifdef GPU #ifdef GPU
cudaSetDevice(old_gpu_index); cudaSetDevice(old_gpu_index);
#endif #endif
} }
YOLODLL_API int Detector::get_net_width() const { YOLODLL_API int Detector::get_net_width() const {
detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get()); detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get());
return detector_gpu.net.w; return detector_gpu.net.w;
} }
YOLODLL_API int Detector::get_net_height() const { YOLODLL_API int Detector::get_net_height() const {
detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get()); detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get());
return detector_gpu.net.h; return detector_gpu.net.h;
} }
YOLODLL_API int Detector::get_net_color_depth() const { YOLODLL_API int Detector::get_net_color_depth() const {
detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get()); detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get());
return detector_gpu.net.c; return detector_gpu.net.c;
} }
YOLODLL_API std::vector<bbox_t> Detector::detect(std::string image_filename, float thresh, bool use_mean) YOLODLL_API std::vector<bbox_t> Detector::detect(std::string image_filename, float thresh, bool use_mean)
{ {
std::shared_ptr<image_t> image_ptr(new image_t, [](image_t *img) { if (img->data) free(img->data); delete img; }); std::shared_ptr<image_t> image_ptr(new image_t, [](image_t *img) { if (img->data) free(img->data); delete img; });
*image_ptr = load_image(image_filename); *image_ptr = load_image(image_filename);
return detect(*image_ptr, thresh, use_mean); return detect(*image_ptr, thresh, use_mean);
} }
static image load_image_stb(char *filename, int channels) static image load_image_stb(char *filename, int channels)
{ {
int w, h, c; int w, h, c;
unsigned char *data = stbi_load(filename, &w, &h, &c, channels); unsigned char *data = stbi_load(filename, &w, &h, &c, channels);
if (!data) if (!data)
throw std::runtime_error("file not found"); throw std::runtime_error("file not found");
if (channels) c = channels; if (channels) c = channels;
int i, j, k; int i, j, k;
image im = make_image(w, h, c); image im = make_image(w, h, c);
for (k = 0; k < c; ++k) { for (k = 0; k < c; ++k) {
for (j = 0; j < h; ++j) { for (j = 0; j < h; ++j) {
for (i = 0; i < w; ++i) { for (i = 0; i < w; ++i) {
int dst_index = i + w * j + w * h*k; int dst_index = i + w*j + w*h*k;
int src_index = k + c * i + c * w*j; int src_index = k + c*i + c*w*j;
im.data[dst_index] = (float)data[src_index] / 255.; im.data[dst_index] = (float)data[src_index] / 255.;
} }
} }
} }
free(data); free(data);
return im; return im;
} }
YOLODLL_API image_t Detector::load_image(std::string image_filename) YOLODLL_API image_t Detector::load_image(std::string image_filename)
{ {
char *input = const_cast<char *>(image_filename.data()); char *input = const_cast<char *>(image_filename.data());
image im = load_image_stb(input, 3); image im = load_image_stb(input, 3);
image_t img; image_t img;
img.c = im.c; img.c = im.c;
img.data = im.data; img.data = im.data;
img.h = im.h; img.h = im.h;
img.w = im.w; img.w = im.w;
return img; return img;
} }
YOLODLL_API void Detector::free_image(image_t m) YOLODLL_API void Detector::free_image(image_t m)
{ {
if (m.data) { if (m.data) {
free(m.data); free(m.data);
} }
} }
YOLODLL_API std::vector<bbox_t> Detector::detect(image_t img, float thresh, bool use_mean) YOLODLL_API std::vector<bbox_t> Detector::detect(image_t img, float thresh, bool use_mean)
{ {
detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get()); detector_gpu_t &detector_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get());
network &net = detector_gpu.net; network &net = detector_gpu.net;
int old_gpu_index; int old_gpu_index;
#ifdef GPU #ifdef GPU
cudaGetDevice(&old_gpu_index); cudaGetDevice(&old_gpu_index);
if (cur_gpu_id != old_gpu_index) if(cur_gpu_id != old_gpu_index)
cudaSetDevice(net.gpu_index); cudaSetDevice(net.gpu_index);
net.wait_stream = wait_stream; // 1 - wait CUDA-stream, 0 - not to wait net.wait_stream = wait_stream; // 1 - wait CUDA-stream, 0 - not to wait
#endif #endif
//std::cout << "net.gpu_index = " << net.gpu_index << std::endl; //std::cout << "net.gpu_index = " << net.gpu_index << std::endl;
//float nms = .4; //float nms = .4;
image im; image im;
im.c = img.c; im.c = img.c;
im.data = img.data; im.data = img.data;
im.h = img.h; im.h = img.h;
im.w = img.w; im.w = img.w;
image sized; image sized;
if (net.w == im.w && net.h == im.h) { if (net.w == im.w && net.h == im.h) {
sized = make_image(im.w, im.h, im.c); sized = make_image(im.w, im.h, im.c);
memcpy(sized.data, im.data, im.w*im.h*im.c * sizeof(float)); memcpy(sized.data, im.data, im.w*im.h*im.c * sizeof(float));
} }
else else
sized = resize_image(im, net.w, net.h); sized = resize_image(im, net.w, net.h);
layer l = net.layers[net.n - 1]; layer l = net.layers[net.n - 1];
float *X = sized.data; float *X = sized.data;
float *prediction = network_predict(net, X); float *prediction = network_predict(net, X);
if (use_mean) { if (use_mean) {
memcpy(detector_gpu.predictions[detector_gpu.demo_index], prediction, l.outputs * sizeof(float)); memcpy(detector_gpu.predictions[detector_gpu.demo_index], prediction, l.outputs * sizeof(float));
mean_arrays(detector_gpu.predictions, FRAMES, l.outputs, detector_gpu.avg); mean_arrays(detector_gpu.predictions, FRAMES, l.outputs, detector_gpu.avg);
l.output = detector_gpu.avg; l.output = detector_gpu.avg;
detector_gpu.demo_index = (detector_gpu.demo_index + 1) % FRAMES; detector_gpu.demo_index = (detector_gpu.demo_index + 1) % FRAMES;
} }
//get_region_boxes(l, 1, 1, thresh, detector_gpu.probs, detector_gpu.boxes, 0, 0); //get_region_boxes(l, 1, 1, thresh, detector_gpu.probs, detector_gpu.boxes, 0, 0);
//if (nms) do_nms_sort(detector_gpu.boxes, detector_gpu.probs, l.w*l.h*l.n, l.classes, nms); //if (nms) do_nms_sort(detector_gpu.boxes, detector_gpu.probs, l.w*l.h*l.n, l.classes, nms);
int nboxes = 0; int nboxes = 0;
int letterbox = 0; int letterbox = 0;
float hier_thresh = 0.5; float hier_thresh = 0.5;
detection *dets = get_network_boxes(&net, im.w, im.h, thresh, hier_thresh, 0, 1, &nboxes, letterbox); detection *dets = get_network_boxes(&net, im.w, im.h, thresh, hier_thresh, 0, 1, &nboxes, letterbox);
if (nms) do_nms_sort(dets, nboxes, l.classes, nms); if (nms) do_nms_sort(dets, nboxes, l.classes, nms);
std::vector<bbox_t> bbox_vec; std::vector<bbox_t> bbox_vec;
for (size_t i = 0; i < nboxes; ++i) { for (size_t i = 0; i < nboxes; ++i) {
box b = dets[i].bbox; box b = dets[i].bbox;
int const obj_id = max_index(dets[i].prob, l.classes); int const obj_id = max_index(dets[i].prob, l.classes);
float const prob = dets[i].prob[obj_id]; float const prob = dets[i].prob[obj_id];
if (prob > thresh) if (prob > thresh)
{ {
bbox_t bbox; bbox_t bbox;
bbox.x = std::max((double)0, (b.x - b.w / 2.)*im.w); bbox.x = std::max((double)0, (b.x - b.w / 2.)*im.w);
bbox.y = std::max((double)0, (b.y - b.h / 2.)*im.h); bbox.y = std::max((double)0, (b.y - b.h / 2.)*im.h);
bbox.w = b.w*im.w; bbox.w = b.w*im.w;
bbox.h = b.h*im.h; bbox.h = b.h*im.h;
bbox.obj_id = obj_id; bbox.obj_id = obj_id;
bbox.prob = prob; bbox.prob = prob;
bbox.track_id = 0; bbox.track_id = 0;
bbox_vec.push_back(bbox); bbox_vec.push_back(bbox);
} }
} }
free_detections(dets, nboxes); free_detections(dets, nboxes);
if (sized.data) if(sized.data)
free(sized.data); free(sized.data);
#ifdef GPU #ifdef GPU
if (cur_gpu_id != old_gpu_index) if (cur_gpu_id != old_gpu_index)
cudaSetDevice(old_gpu_index); cudaSetDevice(old_gpu_index);
#endif #endif
return bbox_vec; return bbox_vec;
} }
YOLODLL_API std::vector<bbox_t> Detector::tracking_id(std::vector<bbox_t> cur_bbox_vec, bool const change_history, YOLODLL_API std::vector<bbox_t> Detector::tracking_id(std::vector<bbox_t> cur_bbox_vec, bool const change_history,
int const frames_story, int const max_dist) int const frames_story, int const max_dist)
{ {
detector_gpu_t &det_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get()); detector_gpu_t &det_gpu = *static_cast<detector_gpu_t *>(detector_gpu_ptr.get());
bool prev_track_id_present = false; bool prev_track_id_present = false;
for (auto &i : prev_bbox_vec_deque) for (auto &i : prev_bbox_vec_deque)
if (i.size() > 0) prev_track_id_present = true; if (i.size() > 0) prev_track_id_present = true;
if (!prev_track_id_present) { if (!prev_track_id_present) {
for (size_t i = 0; i < cur_bbox_vec.size(); ++i) for (size_t i = 0; i < cur_bbox_vec.size(); ++i)
cur_bbox_vec[i].track_id = det_gpu.track_id[cur_bbox_vec[i].obj_id]++; cur_bbox_vec[i].track_id = det_gpu.track_id[cur_bbox_vec[i].obj_id]++;
prev_bbox_vec_deque.push_front(cur_bbox_vec); prev_bbox_vec_deque.push_front(cur_bbox_vec);
if (prev_bbox_vec_deque.size() > frames_story) prev_bbox_vec_deque.pop_back(); if (prev_bbox_vec_deque.size() > frames_story) prev_bbox_vec_deque.pop_back();
return cur_bbox_vec; return cur_bbox_vec;
} }
std::vector<unsigned int> dist_vec(cur_bbox_vec.size(), std::numeric_limits<unsigned int>::max()); std::vector<unsigned int> dist_vec(cur_bbox_vec.size(), std::numeric_limits<unsigned int>::max());
for (auto &prev_bbox_vec : prev_bbox_vec_deque) { for (auto &prev_bbox_vec : prev_bbox_vec_deque) {
for (auto &i : prev_bbox_vec) { for (auto &i : prev_bbox_vec) {
int cur_index = -1; int cur_index = -1;
for (size_t m = 0; m < cur_bbox_vec.size(); ++m) { for (size_t m = 0; m < cur_bbox_vec.size(); ++m) {
bbox_t const& k = cur_bbox_vec[m]; bbox_t const& k = cur_bbox_vec[m];
if (i.obj_id == k.obj_id) { if (i.obj_id == k.obj_id) {
float center_x_diff = (float)(i.x + i.w / 2) - (float)(k.x + k.w / 2); float center_x_diff = (float)(i.x + i.w/2) - (float)(k.x + k.w/2);
float center_y_diff = (float)(i.y + i.h / 2) - (float)(k.y + k.h / 2); float center_y_diff = (float)(i.y + i.h/2) - (float)(k.y + k.h/2);
unsigned int cur_dist = sqrt(center_x_diff*center_x_diff + center_y_diff * center_y_diff); unsigned int cur_dist = sqrt(center_x_diff*center_x_diff + center_y_diff*center_y_diff);
if (cur_dist < max_dist && (k.track_id == 0 || dist_vec[m] > cur_dist)) { if (cur_dist < max_dist && (k.track_id == 0 || dist_vec[m] > cur_dist)) {
dist_vec[m] = cur_dist; dist_vec[m] = cur_dist;
cur_index = m; cur_index = m;
} }
} }
} }
bool track_id_absent = !std::any_of(cur_bbox_vec.begin(), cur_bbox_vec.end(), bool track_id_absent = !std::any_of(cur_bbox_vec.begin(), cur_bbox_vec.end(),
[&i](bbox_t const& b) { return b.track_id == i.track_id && b.obj_id == i.obj_id; }); [&i](bbox_t const& b) { return b.track_id == i.track_id && b.obj_id == i.obj_id; });
if (cur_index >= 0 && track_id_absent) { if (cur_index >= 0 && track_id_absent){
cur_bbox_vec[cur_index].track_id = i.track_id; cur_bbox_vec[cur_index].track_id = i.track_id;
cur_bbox_vec[cur_index].w = (cur_bbox_vec[cur_index].w + i.w) / 2; cur_bbox_vec[cur_index].w = (cur_bbox_vec[cur_index].w + i.w) / 2;
cur_bbox_vec[cur_index].h = (cur_bbox_vec[cur_index].h + i.h) / 2; cur_bbox_vec[cur_index].h = (cur_bbox_vec[cur_index].h + i.h) / 2;
} }
} }
} }
for (size_t i = 0; i < cur_bbox_vec.size(); ++i) for (size_t i = 0; i < cur_bbox_vec.size(); ++i)
if (cur_bbox_vec[i].track_id == 0) if (cur_bbox_vec[i].track_id == 0)
cur_bbox_vec[i].track_id = det_gpu.track_id[cur_bbox_vec[i].obj_id]++; cur_bbox_vec[i].track_id = det_gpu.track_id[cur_bbox_vec[i].obj_id]++;
if (change_history) { if (change_history) {
prev_bbox_vec_deque.push_front(cur_bbox_vec); prev_bbox_vec_deque.push_front(cur_bbox_vec);
if (prev_bbox_vec_deque.size() > frames_story) prev_bbox_vec_deque.pop_back(); if (prev_bbox_vec_deque.size() > frames_story) prev_bbox_vec_deque.pop_back();
} }
return cur_bbox_vec; return cur_bbox_vec;
} }