#include <thread>
#include "example.h"
#if LITE_BUILD_WITH_MGE
#include <cstdio>
#include "misc.h"
#define STB_IMAGE_STATIC
#define STB_IMAGE_IMPLEMENTATION
#include "stb_image.h"
#define STB_IMAGE_RESIZE_STATIC
#define STB_IMAGE_RESIZE_IMPLEMENTATION
#include "stb_image_resize.h"
#define STB_IMAGE_WRITE_STATIC
#define STB_IMAGE_WRITE_IMPLEMENTATION
#include "stb_image_write.h"
#define NMS_THRESH 0.25
#define BBOX_CONF_THRESH 0.6
constexpr int INPUT_W = 640;
constexpr int INPUT_H = 640;
using namespace lite;
using namespace example;
namespace {
void preprocess_image(
uint8_t* image, const int width, const int height, const int channel,
std::shared_ptr<Tensor> tensor) {
auto layout = tensor->get_layout();
for (size_t i = 0; i < layout.ndim; i++) {
printf("model input shape[%zu]=%zu \n", i, layout.shapes[i]);
}
float r = std::min(INPUT_W / (width * 1.0), INPUT_H / (height * 1.0));
int unpad_w = r * width;
int unpad_h = r * height;
std::shared_ptr<std::vector<uint8_t>> resize_int8 =
std::make_shared<std::vector<uint8_t>>(unpad_w * unpad_h * channel);
stbir_resize_uint8(
image, width, height, 0, resize_int8->data(), unpad_w, unpad_h, 0, channel);
std::shared_ptr<std::vector<uint8_t>> padded;
if (unpad_h != INPUT_H || unpad_w != INPUT_W) {
padded = std::make_shared<std::vector<uint8_t>>(
INPUT_H * INPUT_W * channel, 114);
for (int h = 0; h < unpad_h; h++) {
for (int w = 0; w < unpad_w; w++) {
for (int c = 0; c < channel; c++) {
(*padded)[h * INPUT_W * channel + w * channel + c] =
(*resize_int8)[h * unpad_w * channel + w * channel + c];
}
}
}
} else {
padded = resize_int8;
}
tensor->set_layout({{1, 3, 640, 640}, 4});
std::vector<float> mean = {0.485, 0.456, 0.406};
std::vector<float> std = {0.229, 0.224, 0.225};
float* in_data = static_cast<float*>(tensor->get_memory_ptr());
size_t pixels = INPUT_H * INPUT_W;
for (size_t i = 0; i < pixels; i++) {
in_data[i] = (padded->at(i * channel + 0) / 255.0f - mean[0]) / std[0];
in_data[i + 1 * pixels] =
(padded->at(i * channel + 1) / 255.0f - mean[1]) / std[1];
in_data[i + 2 * pixels] =
(padded->at(i * channel + 2) / 255.0f - mean[2]) / std[2];
}
}
struct Rect {
float x;
float y;
float height;
float width;
float area() const { return height * width; }
Rect operator&(Rect other) const {
Rect ret;
float x_start = std::max(x, other.x);
float x_end = std::min(x + width, other.width);
ret.x = x_start;
ret.width = (x_end - x_start) > 0 ? x_end - x_start : 0;
float y_start = std::max(y, other.y);
float y_end = std::min(y + height, other.height);
ret.y = y_start;
ret.height = (y_end - y_start) > 0 ? y_end - y_start : 0;
return ret;
}
};
struct Object {
Rect rect;
int label;
float prob;
};
struct GridAndStride {
int grid0;
int grid1;
int stride;
};
static void generate_grids_and_stride(
const int target_size, std::vector<int>& strides,
std::vector<GridAndStride>& grid_strides) {
for (auto stride : strides) {
int num_grid = target_size / stride;
for (int g1 = 0; g1 < num_grid; g1++) {
for (int g0 = 0; g0 < num_grid; g0++) {
grid_strides.push_back((GridAndStride){g0, g1, stride});
}
}
}
}
static void generate_yolox_proposals(
std::vector<GridAndStride> grid_strides, const float* feat_ptr,
float prob_threshold, std::vector<Object>& objects) {
const int num_class = 80;
const int num_anchors = grid_strides.size();
for (int anchor_idx = 0; anchor_idx < num_anchors; anchor_idx++) {
const int grid0 = grid_strides[anchor_idx].grid0;
const int grid1 = grid_strides[anchor_idx].grid1;
const int stride = grid_strides[anchor_idx].stride;
const int basic_pos = anchor_idx * 85;
float x_center = (feat_ptr[basic_pos + 0] + grid0) * stride;
float y_center = (feat_ptr[basic_pos + 1] + grid1) * stride;
float w = exp(feat_ptr[basic_pos + 2]) * stride;
float h = exp(feat_ptr[basic_pos + 3]) * stride;
float x0 = x_center - w * 0.5f;
float y0 = y_center - h * 0.5f;
float box_objectness = feat_ptr[basic_pos + 4];
for (int class_idx = 0; class_idx < num_class; class_idx++) {
float box_cls_score = feat_ptr[basic_pos + 5 + class_idx];
float box_prob = box_objectness * box_cls_score;
if (box_prob > prob_threshold) {
Object obj;
obj.rect.x = x0;
obj.rect.y = y0;
obj.rect.width = w;
obj.rect.height = h;
obj.label = class_idx;
obj.prob = box_prob;
objects.push_back(obj);
}
}
} }
void qsort_descent_inplace(std::vector<Object>& faceobjects, int left, int right) {
int i = left;
int j = right;
float p = faceobjects[(left + right) / 2].prob;
while (i <= j) {
while (faceobjects[i].prob > p)
i++;
while (faceobjects[j].prob < p)
j--;
if (i <= j) {
std::swap(faceobjects[i], faceobjects[j]);
i++;
j--;
}
}
if (left < j)
qsort_descent_inplace(faceobjects, left, j);
if (i < right)
qsort_descent_inplace(faceobjects, i, right);
}
void qsort_descent_inplace(std::vector<Object>& objects) {
if (objects.empty())
return;
qsort_descent_inplace(objects, 0, objects.size() - 1);
}
inline float intersection_area(const Object& a, const Object& b) {
Rect inter = a.rect & b.rect;
return inter.area();
}
void nms_sorted_bboxes(
const std::vector<Object>& faceobjects, std::vector<int>& picked,
float nms_threshold) {
picked.clear();
const int n = faceobjects.size();
std::vector<float> areas(n);
for (int i = 0; i < n; i++) {
areas[i] = faceobjects[i].rect.area();
}
for (int i = 0; i < n; i++) {
const Object& a = faceobjects[i];
int keep = 1;
for (int j = 0; j < (int)picked.size(); j++) {
const Object& b = faceobjects[picked[j]];
float inter_area = intersection_area(a, b);
float union_area = areas[i] + areas[picked[j]] - inter_area;
if (inter_area / union_area > nms_threshold)
keep = 0;
}
if (keep)
picked.push_back(i);
}
}
void decode_outputs(
const float* prob, std::vector<Object>& objects, float scale, const int img_w,
const int img_h) {
std::vector<Object> proposals;
std::vector<int> strides = {8, 16, 32};
std::vector<GridAndStride> grid_strides;
generate_grids_and_stride(INPUT_W, strides, grid_strides);
generate_yolox_proposals(grid_strides, prob, BBOX_CONF_THRESH, proposals);
qsort_descent_inplace(proposals);
std::vector<int> picked;
nms_sorted_bboxes(proposals, picked, NMS_THRESH);
int count = picked.size();
objects.resize(count);
for (int i = 0; i < count; i++) {
objects[i] = proposals[picked[i]];
float x0 = (objects[i].rect.x) / scale;
float y0 = (objects[i].rect.y) / scale;
float x1 = (objects[i].rect.x + objects[i].rect.width) / scale;
float y1 = (objects[i].rect.y + objects[i].rect.height) / scale;
x0 = std::max(std::min(x0, (float)(img_w - 1)), 0.f);
y0 = std::max(std::min(y0, (float)(img_h - 1)), 0.f);
x1 = std::max(std::min(x1, (float)(img_w - 1)), 0.f);
y1 = std::max(std::min(y1, (float)(img_h - 1)), 0.f);
objects[i].rect.x = x0;
objects[i].rect.y = y0;
objects[i].rect.width = x1 - x0;
objects[i].rect.height = y1 - y0;
}
}
void draw_objects(
uint8_t* image, int width, int height, int channel,
const std::vector<Object>& objects) {
(void)image;
(void)width;
(void)height;
(void)channel;
for (size_t i = 0; i < objects.size(); i++) {
const Object& obj = objects[i];
printf("Object: %d = %.5f at %.2f %.2f %.2f x %.2f\n", obj.label, obj.prob,
obj.rect.x, obj.rect.y, obj.rect.width, obj.rect.height);
}
}
bool detect_yolox(const Args& args) {
std::string network_path = args.model_path;
std::string input_path = args.input_path;
int width, height, channel;
uint8_t* image = stbi_load(input_path.c_str(), &width, &height, &channel, 0);
printf("Input image %s with height=%d, width=%d, channel=%d\n", input_path.c_str(),
width, height, channel);
std::shared_ptr<Network> network = std::make_shared<Network>();
network->load_model(network_path);
auto input_tensor = network->get_io_tensor("data");
preprocess_image(image, width, height, channel, input_tensor);
network->forward();
network->wait();
float* predict_ptr =
static_cast<float*>(network->get_output_tensor(0)->get_memory_ptr());
float scale = std::min(INPUT_W / (width * 1.0), INPUT_H / (height * 1.0));
std::vector<Object> objects;
decode_outputs(predict_ptr, objects, scale, width, height);
draw_objects(image, width, height, channel, objects);
stbi_image_free(image);
return 0;
}
}
REGIST_EXAMPLE("detect_yolox", detect_yolox);
#endif