// Copyright (c) 2021 by Rockchip Electronics Co., Ltd. All Rights Reserved.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#include "postprocess.h"
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#include <math.h>
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#include <stdint.h>
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <sys/time.h>
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#include <set>
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#include <vector>
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#define LABEL_NALE_TXT_PATH "./model/coco_80_labels_list.txt"
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static char* labels[OBJ_CLASS_NUM];
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const int anchor0[6] = {10, 13, 16, 30, 33, 23};
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const int anchor1[6] = {30, 61, 62, 45, 59, 119};
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const int anchor2[6] = {116, 90, 156, 198, 373, 326};
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inline static int clamp(float val, int min, int max) { return val > min ? (val < max ? val : max) : min; }
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char* readLine(FILE* fp, char* buffer, int* len)
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{
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int ch;
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int i = 0;
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size_t buff_len = 0;
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buffer = (char*)malloc(buff_len + 1);
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if (!buffer)
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return NULL; // Out of memory
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while ((ch = fgetc(fp)) != '\n' && ch != EOF) {
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buff_len++;
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void* tmp = realloc(buffer, buff_len + 1);
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if (tmp == NULL) {
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free(buffer);
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return NULL; // Out of memory
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}
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buffer = (char*)tmp;
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buffer[i] = (char)ch;
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i++;
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}
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buffer[i] = '\0';
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*len = buff_len;
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// Detect end
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if (ch == EOF && (i == 0 || ferror(fp))) {
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free(buffer);
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return NULL;
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}
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return buffer;
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}
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int readLines(const char* fileName, char* lines[], int max_line)
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{
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FILE* file = fopen(fileName, "r");
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char* s;
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int i = 0;
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int n = 0;
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if (file == NULL) {
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printf("Open %s fail!\n", fileName);
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return -1;
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}
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while ((s = readLine(file, s, &n)) != NULL) {
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lines[i++] = s;
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if (i >= max_line)
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break;
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}
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fclose(file);
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return i;
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}
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int loadLabelName(const char* locationFilename, char* label[])
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{
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printf("loadLabelName %s\n", locationFilename);
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readLines(locationFilename, label, OBJ_CLASS_NUM);
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return 0;
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}
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static float CalculateOverlap(float xmin0, float ymin0, float xmax0, float ymax0, float xmin1, float ymin1, float xmax1,
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float ymax1)
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{
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float w = fmax(0.f, fmin(xmax0, xmax1) - fmax(xmin0, xmin1) + 1.0);
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float h = fmax(0.f, fmin(ymax0, ymax1) - fmax(ymin0, ymin1) + 1.0);
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float i = w * h;
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float u = (xmax0 - xmin0 + 1.0) * (ymax0 - ymin0 + 1.0) + (xmax1 - xmin1 + 1.0) * (ymax1 - ymin1 + 1.0) - i;
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return u <= 0.f ? 0.f : (i / u);
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}
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static int nms(int validCount, std::vector<float>& outputLocations, std::vector<int> classIds, std::vector<int>& order,
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int filterId, float threshold)
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{
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for (int i = 0; i < validCount; ++i) {
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if (order[i] == -1 || classIds[i] != filterId) {
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continue;
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}
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int n = order[i];
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for (int j = i + 1; j < validCount; ++j) {
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int m = order[j];
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if (m == -1 || classIds[i] != filterId) {
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continue;
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}
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float xmin0 = outputLocations[n * 4 + 0];
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float ymin0 = outputLocations[n * 4 + 1];
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float xmax0 = outputLocations[n * 4 + 0] + outputLocations[n * 4 + 2];
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float ymax0 = outputLocations[n * 4 + 1] + outputLocations[n * 4 + 3];
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float xmin1 = outputLocations[m * 4 + 0];
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float ymin1 = outputLocations[m * 4 + 1];
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float xmax1 = outputLocations[m * 4 + 0] + outputLocations[m * 4 + 2];
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float ymax1 = outputLocations[m * 4 + 1] + outputLocations[m * 4 + 3];
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float iou = CalculateOverlap(xmin0, ymin0, xmax0, ymax0, xmin1, ymin1, xmax1, ymax1);
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if (iou > threshold) {
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order[j] = -1;
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}
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}
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}
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return 0;
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}
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static int quick_sort_indice_inverse(std::vector<float>& input, int left, int right, std::vector<int>& indices)
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{
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float key;
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int key_index;
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int low = left;
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int high = right;
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if (left < right) {
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key_index = indices[left];
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key = input[left];
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while (low < high) {
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while (low < high && input[high] <= key) {
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high--;
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}
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input[low] = input[high];
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indices[low] = indices[high];
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while (low < high && input[low] >= key) {
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low++;
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}
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input[high] = input[low];
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indices[high] = indices[low];
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}
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input[low] = key;
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indices[low] = key_index;
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quick_sort_indice_inverse(input, left, low - 1, indices);
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quick_sort_indice_inverse(input, low + 1, right, indices);
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}
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return low;
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}
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static float sigmoid(float x) { return 1.0 / (1.0 + expf(-x)); }
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static float unsigmoid(float y) { return -1.0 * logf((1.0 / y) - 1.0); }
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inline static int32_t __clip(float val, float min, float max)
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{
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float f = val <= min ? min : (val >= max ? max : val);
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return f;
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}
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static int8_t qnt_f32_to_affine(float f32, int32_t zp, float scale)
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{
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float dst_val = (f32 / scale) + zp;
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int8_t res = (int8_t)__clip(dst_val, -128, 127);
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return res;
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}
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static float deqnt_affine_to_f32(int8_t qnt, int32_t zp, float scale) { return ((float)qnt - (float)zp) * scale; }
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static int process(int8_t* input, int* anchor, int grid_h, int grid_w, int height, int width, int stride,
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std::vector<float>& boxes, std::vector<float>& objProbs, std::vector<int>& classId, float threshold,
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int32_t zp, float scale)
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{
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int validCount = 0;
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int grid_len = grid_h * grid_w;
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float thres = unsigmoid(threshold);
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int8_t thres_i8 = qnt_f32_to_affine(thres, zp, scale);
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for (int a = 0; a < 3; a++) {
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for (int i = 0; i < grid_h; i++) {
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for (int j = 0; j < grid_w; j++) {
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int8_t box_confidence = input[(PROP_BOX_SIZE * a + 4) * grid_len + i * grid_w + j];
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if (box_confidence >= thres_i8) {
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int offset = (PROP_BOX_SIZE * a) * grid_len + i * grid_w + j;
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int8_t* in_ptr = input + offset;
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float box_x = sigmoid(deqnt_affine_to_f32(*in_ptr, zp, scale)) * 2.0 - 0.5;
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float box_y = sigmoid(deqnt_affine_to_f32(in_ptr[grid_len], zp, scale)) * 2.0 - 0.5;
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float box_w = sigmoid(deqnt_affine_to_f32(in_ptr[2 * grid_len], zp, scale)) * 2.0;
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float box_h = sigmoid(deqnt_affine_to_f32(in_ptr[3 * grid_len], zp, scale)) * 2.0;
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box_x = (box_x + j) * (float)stride;
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box_y = (box_y + i) * (float)stride;
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box_w = box_w * box_w * (float)anchor[a * 2];
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box_h = box_h * box_h * (float)anchor[a * 2 + 1];
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box_x -= (box_w / 2.0);
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box_y -= (box_h / 2.0);
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int8_t maxClassProbs = in_ptr[5 * grid_len];
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int maxClassId = 0;
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for (int k = 1; k < OBJ_CLASS_NUM; ++k) {
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int8_t prob = in_ptr[(5 + k) * grid_len];
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if (prob > maxClassProbs) {
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maxClassId = k;
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maxClassProbs = prob;
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}
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}
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if (maxClassProbs>thres_i8){
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objProbs.push_back(sigmoid(deqnt_affine_to_f32(maxClassProbs, zp, scale))* sigmoid(deqnt_affine_to_f32(box_confidence, zp, scale)));
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classId.push_back(maxClassId);
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validCount++;
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boxes.push_back(box_x);
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boxes.push_back(box_y);
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boxes.push_back(box_w);
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boxes.push_back(box_h);
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}
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}
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}
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}
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}
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return validCount;
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}
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int post_process(int8_t* input0, int8_t* input1, int8_t* input2, int model_in_h, int model_in_w, float conf_threshold,
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float nms_threshold, float scale_w, float scale_h, std::vector<int32_t>& qnt_zps,
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std::vector<float>& qnt_scales, detect_result_group_t* group)
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{
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static int init = -1;
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if (init == -1) {
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int ret = 0;
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ret = loadLabelName(LABEL_NALE_TXT_PATH, labels);
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if (ret < 0) {
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return -1;
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}
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init = 0;
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}
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memset(group, 0, sizeof(detect_result_group_t));
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std::vector<float> filterBoxes;
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std::vector<float> objProbs;
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std::vector<int> classId;
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// stride 8
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int stride0 = 8;
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int grid_h0 = model_in_h / stride0;
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int grid_w0 = model_in_w / stride0;
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int validCount0 = 0;
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validCount0 = process(input0, (int*)anchor0, grid_h0, grid_w0, model_in_h, model_in_w, stride0, filterBoxes, objProbs,
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classId, conf_threshold, qnt_zps[0], qnt_scales[0]);
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// stride 16
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int stride1 = 16;
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int grid_h1 = model_in_h / stride1;
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int grid_w1 = model_in_w / stride1;
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int validCount1 = 0;
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validCount1 = process(input1, (int*)anchor1, grid_h1, grid_w1, model_in_h, model_in_w, stride1, filterBoxes, objProbs,
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classId, conf_threshold, qnt_zps[1], qnt_scales[1]);
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// stride 32
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int stride2 = 32;
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int grid_h2 = model_in_h / stride2;
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int grid_w2 = model_in_w / stride2;
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int validCount2 = 0;
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validCount2 = process(input2, (int*)anchor2, grid_h2, grid_w2, model_in_h, model_in_w, stride2, filterBoxes, objProbs,
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classId, conf_threshold, qnt_zps[2], qnt_scales[2]);
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int validCount = validCount0 + validCount1 + validCount2;
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// no object detect
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if (validCount <= 0) {
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return 0;
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}
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std::vector<int> indexArray;
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for (int i = 0; i < validCount; ++i) {
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indexArray.push_back(i);
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}
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quick_sort_indice_inverse(objProbs, 0, validCount - 1, indexArray);
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std::set<int> class_set(std::begin(classId), std::end(classId));
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for (auto c : class_set) {
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nms(validCount, filterBoxes, classId, indexArray, c, nms_threshold);
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}
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int last_count = 0;
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group->count = 0;
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/* box valid detect target */
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for (int i = 0; i < validCount; ++i) {
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if (indexArray[i] == -1 || last_count >= OBJ_NUMB_MAX_SIZE) {
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continue;
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}
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int n = indexArray[i];
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float x1 = filterBoxes[n * 4 + 0];
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float y1 = filterBoxes[n * 4 + 1];
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float x2 = x1 + filterBoxes[n * 4 + 2];
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float y2 = y1 + filterBoxes[n * 4 + 3];
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int id = classId[n];
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float obj_conf = objProbs[i];
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group->results[last_count].box.left = (int)(clamp(x1, 0, model_in_w) / scale_w);
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group->results[last_count].box.top = (int)(clamp(y1, 0, model_in_h) / scale_h);
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group->results[last_count].box.right = (int)(clamp(x2, 0, model_in_w) / scale_w);
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group->results[last_count].box.bottom = (int)(clamp(y2, 0, model_in_h) / scale_h);
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group->results[last_count].prop = obj_conf;
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char* label = labels[id];
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strncpy(group->results[last_count].name, label, OBJ_NAME_MAX_SIZE);
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// printf("result %2d: (%4d, %4d, %4d, %4d), %s\n", i, group->results[last_count].box.left,
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// group->results[last_count].box.top,
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// group->results[last_count].box.right, group->results[last_count].box.bottom, label);
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last_count++;
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}
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group->count = last_count;
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return 0;
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}
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void deinitPostProcess()
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{
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for (int i = 0; i < OBJ_CLASS_NUM; i++) {
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if (labels[i] != nullptr) {
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free(labels[i]);
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labels[i] = nullptr;
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}
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}
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}
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