int main(int argc, char **argv) { if (argc < 4 || argc > 8) { printf("Usage: %s <list.in> <tree.in> <tree.out> [use_tfidf:1] " "[normalize:1] [start_id:0] [distance_type:1]\n", argv[0]); return 1; } double min_feature_scale = 1.4; bool use_tfidf = true; bool normalize = true; char *list_in = argv[1]; char *tree_in = argv[2]; char *tree_out = argv[3]; DistanceType distance_type = DistanceMin; int start_id = 0; if (argc >= 5) use_tfidf = atoi(argv[4]); if (argc >= 6) normalize = atoi(argv[5]); if (argc >= 7) start_id = atoi(argv[6]); if (argc >= 8) distance_type = (DistanceType) atoi(argv[7]); switch (distance_type) { case DistanceDot: printf("[VocabMatch] Using distance Dot\n"); break; case DistanceMin: printf("[VocabMatch] Using distance Min\n"); break; default: printf("[VocabMatch] Using no known distance!\n"); break; } FILE *f = fopen(list_in, "r"); if (f == NULL) { printf("Error opening file %s for reading\n", list_in); return 1; } std::vector<std::string> key_files; char buf[256]; while (fgets(buf, 256, f)) { /* Remove trailing newline */ if (buf[strlen(buf) - 1] == '\n') buf[strlen(buf) - 1] = 0; key_files.push_back(std::string(buf)); } printf("[VocabBuildDB] Reading tree %s...\n", tree_in); fflush(stdout); VocabTree tree; tree.Read(tree_in); #if 1 tree.Flatten(); #endif tree.m_distance_type = distance_type; tree.SetInteriorNodeWeight(0.0); /* Initialize leaf weights to 1.0 */ tree.SetConstantLeafWeights(); const int dim = 128; int num_db_images = (int) key_files.size(); unsigned long count = 0; tree.ClearDatabase(); for (int i = 0; i < num_db_images; i++) { int num_keys = 0; unsigned char *keys = ReadAndFilterKeys(key_files[i].c_str(), dim, min_feature_scale, 0, num_keys); printf("[VocabBuildDB] Adding vector %d (%d keys)\n", start_id + i, num_keys); tree.AddImageToDatabase(start_id + i, num_keys, keys); if (num_keys > 0) delete [] keys; } printf("[VocabBuildDB] Pushed %lu features\n", count); fflush(stdout); if (use_tfidf) tree.ComputeTFIDFWeights(num_db_images); if (normalize) tree.NormalizeDatabase(start_id, num_db_images); printf("[VocabBuildDB] Writing tree...\n"); tree.Write(tree_out); // char filename[256]; // sprintf(filename, "vectors_%03d.txt", start_id); // tree.WriteDatabaseVectors(filename, start_id, num_db_images); return 0; }
int main(int argc, char **argv) { const int dim = 128; if (argc != 6 && argc != 7 && argc != 8) { printf("Usage: %s <tree.in> <db.in> <query.in> <num_nbrs> " "<matches.out> [distance_type:1] [normalize:1]\n", argv[0]); return 1; } char *tree_in = argv[1]; char *db_in = argv[2]; char *query_in = argv[3]; int num_nbrs = atoi(argv[4]); char *matches_out = argv[5]; DistanceType distance_type = DistanceMin; bool normalize = true; #if 0 if (argc >= 7) output_html = argv[6]; #endif if (argc >= 7) distance_type = (DistanceType) atoi(argv[6]); if (argc >= 8) normalize = (atoi(argv[7]) != 0); printf("[VocabMatch] Using tree %s\n", tree_in); switch (distance_type) { case DistanceDot: printf("[VocabMatch] Using distance Dot\n"); break; case DistanceMin: printf("[VocabMatch] Using distance Min\n"); break; default: printf("[VocabMatch] Using no known distance!\n"); break; } /* Read the tree */ printf("[VocabMatch] Reading tree...\n"); fflush(stdout); clock_t start = clock(); VocabTree tree; tree.Read(tree_in); clock_t end = clock(); printf("[VocabMatch] Read tree in %0.3fs\n", (double) (end - start) / CLOCKS_PER_SEC); #if 1 tree.Flatten(); #endif tree.SetDistanceType(distance_type); tree.SetInteriorNodeWeight(0, 0.0); /* Read the database keyfiles */ FILE *f = fopen(db_in, "r"); std::vector<std::string> db_files; char buf[256]; while (fgets(buf, 256, f)) { /* Remove trailing newline */ if (buf[strlen(buf) - 1] == '\n') buf[strlen(buf) - 1] = 0; db_files.push_back(std::string(buf)); } fclose(f); /* Read the query keyfiles */ f = fopen(query_in, "r"); std::vector<std::string> query_files; while (fgets(buf, 256, f)) { /* Remove trailing newline */ if (buf[strlen(buf) - 1] == '\n') buf[strlen(buf) - 1] = 0; char keyfile[256]; sscanf(buf, "%s", keyfile); query_files.push_back(std::string(keyfile)); } fclose(f); int num_db_images = db_files.size(); int num_query_images = query_files.size(); printf("[VocabMatch] Read %d database images\n", num_db_images); /* Now score each query keyfile */ printf("[VocabMatch] Scoring %d query images...\n", num_query_images); fflush(stdout); #if 0 FILE *f_html = fopen(output_html, "w"); PrintHTMLHeader(f_html, num_nbrs); #endif float *scores = new float[num_db_images]; double *scores_d = new double[num_db_images]; int *perm = new int[num_db_images]; FILE *f_match = fopen(matches_out, "w"); if (f_match == NULL) { printf("[VocabMatch] Error opening file %s for writing\n", matches_out); return 1; } for (int i = 0; i < num_query_images; i++) { start = clock(); /* Clear scores */ for (int j = 0; j < num_db_images; j++) scores[j] = 0.0; int num_keys = 0; unsigned char *keys = ReadDescriptorFile(query_files[i].c_str(), dim, num_keys); clock_t start_score = clock(); double mag = tree.ScoreQueryKeys(num_keys, normalize, keys, scores); clock_t end_score = end = clock(); printf("[VocabMatch] Scored image %s in %0.3fs " "( %0.3fs total, num_keys = %d, mag = %0.3f )\n", query_files[i].c_str(), (double) (end_score - start_score) / CLOCKS_PER_SEC, (double) (end - start) / CLOCKS_PER_SEC, num_keys, mag); /* Find the top scores */ for (int j = 0; j < num_db_images; j++) { scores_d[j] = (double) scores[j]; } qsort_descending(); qsort_perm(num_db_images, scores_d, perm); int top = MIN(num_nbrs, num_db_images); for (int j = 0; j < top; j++) { // if (perm[j] == index_i) // continue; fprintf(f_match, "%d %d %0.4f\n", i, perm[j], scores_d[j]); //fprintf(f_match, "%d %d %0.4f\n", i, perm[j], mag - scores_d[j]); } fflush(f_match); fflush(stdout); #if 0 PrintHTMLRow(f_html, query_files[i], scores_d, perm, num_nbrs, db_files); #endif delete [] keys; } fclose(f_match); #if 0 PrintHTMLFooter(f_html); fclose(f_html); #endif delete [] scores; delete [] scores_d; delete [] perm; return 0; }
int main(int argc, char **argv) { const int dim = 128; if (argc != 6 && argc != 7 && argc != 8 && argc != 9 && argc != 10 && argc != 11) { printf("Usage: %s <tree.in> <db.in> <query.in> <num_nbrs> " "<match-script.out> [leaves_only] [distance_type] [normalize] " "[min_feature_scale] [max_keys]\n", argv[0]); return 1; } char *tree_in = argv[1]; char *db_in = argv[2]; char *query_in = argv[3]; int num_nbrs = atoi(argv[4]); char *matches_out = argv[5]; bool leaves_only = false; bool normalize = true; double min_feature_scale = 0.0; DistanceType distance_type = DistanceMin; int max_keys = 0; if (argc >= 7) { if (atoi(argv[6]) != 0) leaves_only = true; } if (argc >= 8) distance_type = (DistanceType) atoi(argv[7]); if (argc >= 9) if (atoi(argv[8]) == 0) normalize = false; if (argc >= 10) { min_feature_scale = atof(argv[9]); } if (argc >= 11) { max_keys = atoi(argv[10]); } if (leaves_only) { printf("[VocabMatch] Scoring with leaves only\n"); } else { printf("[VocabMatch] Scoring with all nodes\n"); } printf("[VocabMatch] Using tree %s\n", tree_in); printf("[VocabMatch] min_feature_scale = %0.3f\n", min_feature_scale); printf("[VocabMatch] max_keys = %d\n", max_keys); switch (distance_type) { case DistanceDot: printf("[VocabMatch] Using distance Dot\n"); break; case DistanceMin: printf("[VocabMatch] Using distance Min\n"); break; default: printf("[VocabMatch] Using no known distance!\n"); break; } /* Read the tree */ printf("[VocabMatch] Reading tree...\n"); fflush(stdout); clock_t start = clock(); VocabTree tree; tree.Read(tree_in); clock_t end = clock(); printf("[VocabMatch] Read tree in %0.3fs\n", (double) (end - start) / CLOCKS_PER_SEC); #if 1 tree.Flatten(); #endif tree.SetDistanceType(distance_type); if (leaves_only) { tree.SetInteriorNodeWeight(atoi(argv[6]) - 1, 0.0); // #define CONSTANT_WEIGHTS #ifdef CONSTANT_WEIGHTS tree.SetConstantLeafWeights(); #endif } /* Read the database keyfiles */ FILE *f = fopen(db_in, "r"); std::vector<std::string> db_files; char buf[256]; while (fgets(buf, 256, f)) { /* Remove trailing newline */ if (buf[strlen(buf) - 1] == '\n') buf[strlen(buf) - 1] = 0; db_files.push_back(std::string(buf)); } fclose(f); /* Read the query keyfiles */ f = fopen(query_in, "r"); std::vector<std::string> query_files; std::vector<int> query_indices; while (fgets(buf, 256, f)) { /* Remove trailing newline */ if (buf[strlen(buf) - 1] == '\n') buf[strlen(buf) - 1] = 0; char keyfile[256]; int index; sscanf(buf, "%d %s", &index, keyfile); query_files.push_back(std::string(keyfile)); query_indices.push_back(index); } fclose(f); /* Populate the database */ printf("[VocabMatch] Populating database...\n"); fflush(stdout); int num_db_images = db_files.size(); int num_query_images = query_files.size(); /* Now score each query keyfile */ printf("[VocabMatch] Scoring query images...\n"); fflush(stdout); float *scores = new float[num_db_images]; double *scores_d = new double[num_db_images]; int *perm = new int[num_db_images]; FILE *f_match = fopen(matches_out, "w"); if (f_match == NULL) { printf("[VocabMatch] Error opening file %s for writing\n", matches_out); return 1; } for (int i = 0; i < num_query_images; i++) { int index_i = query_indices[i]; start = clock(); /* Clear scores */ for (int j = 0; j < num_db_images; j++) scores[j] = 0.0; unsigned char *keys; int num_keys; keys = ReadAndFilterKeys(query_files[i].c_str(), dim, min_feature_scale, max_keys, num_keys); tree.ScoreQueryKeys(num_keys, /*i,*/ true, keys, scores); end = clock(); printf("[VocabMatch] Scored image %s (%d keys) in %0.3fs\n", query_files[i].c_str(), num_keys, (double) (end - start) / CLOCKS_PER_SEC); #if 0 for (int j = 0; j < num_db_images; j++) { /* Normalize scores */ if (magnitudes[j] > 0.0) scores[j] /= magnitudes[j]; else scores[j] = 0.0; } #endif /* Find the top scores */ for (int j = 0; j < num_db_images; j++) { scores_d[j] = (double) scores[j]; } qsort_descending(); qsort_perm(num_db_images, scores_d, perm); // assert(is_sorted(num_db_images, scores_d)); int top = MIN(num_nbrs+1, num_db_images); for (int j = 0; j < top; j++) { if (perm[j] == index_i) continue; fprintf(f_match, "%d %d %0.5e\n", index_i, perm[j], scores_d[j]); fflush(f_match); } fflush(stdout); delete [] keys; } fclose(f_match); delete [] scores; delete [] scores_d; delete [] perm; return 0; }
// compare images feature using db int VocabCompare(int argc, char **argv) { if (argc != 5 && argc != 6) { printf("Usage: %s <tree.in> <image1.key> <image2.key> <matches.out> [distance_type]\n", argv[0]); return 1; } char *tree_in = argv[1]; char *image1_in = argv[2]; char *image2_in = argv[3]; char *matches_out = argv[4]; DistanceType distance_type = DistanceMin; if (argc >= 6) distance_type = (DistanceType)atoi(argv[5]); switch (distance_type) { case DistanceDot: printf("[VocabMatch] Using distance Dot\n"); break; case DistanceMin: printf("[VocabMatch] Using distance Min\n"); break; default: printf("[VocabMatch] Using no known distance!\n"); break; } printf("[VocabBuildDB] Reading tree %s...\n", tree_in); fflush(stdout); VocabTree tree; tree.Read(tree_in); printf("[VocabCompare] Flattening tree...\n"); tree.Flatten(); tree.m_distance_type = distance_type; tree.SetInteriorNodeWeight(0.0); /* Initialize leaf weights to 1.0 */ tree.SetConstantLeafWeights(); const int dim = 128; tree.ClearDatabase(); int num_keys_1 = 0, num_keys_2 = 0; unsigned char *keys1 = ReadKeys(image1_in, dim, num_keys_1); unsigned char *keys2 = ReadKeys(image2_in, dim, num_keys_2); unsigned long *ids1 = new unsigned long[num_keys_1]; unsigned long *ids2 = new unsigned long[num_keys_2]; printf("[VocabCompare] Adding image 0 (%d keys)\n", num_keys_1); tree.AddImageToDatabase(0, num_keys_1, keys1, ids1); if (num_keys_1 > 0) delete[] keys1; printf("[VocabCompare] Adding image 1 (%d keys)\n", num_keys_2); tree.AddImageToDatabase(1, num_keys_2, keys2, ids2); if (num_keys_2 > 0) delete[] keys2; // tree.ComputeTFIDFWeights(); tree.NormalizeDatabase(0, 2); //Find collisions among visual word IDs std::multimap<unsigned long, unsigned int> word_map; for (unsigned int i = 0; i < (unsigned int)num_keys_1; i++) { printf("0 %d -> %lu\n", i, ids1[i]); std::pair<unsigned long, unsigned int> elem(ids1[i], i); word_map.insert(elem); } //Count number of matches int num_matches = 0; for (unsigned int i = 0; i < (unsigned int)num_keys_2; i++) { unsigned long id = ids2[i]; printf("1 %d -> %lu\n", i, ids2[i]); std::pair<std::multimap<unsigned long, unsigned int>::iterator, std::multimap<unsigned long, unsigned int>::iterator> ret; ret = word_map.equal_range(id); unsigned int size = 0; std::multimap<unsigned long, unsigned int>::iterator iter; for (iter = ret.first; iter != ret.second; iter++) size++, num_matches++; if (size > 0) printf("size[%lu] = %d\n", id, size); } printf("number of matches: %d\n", num_matches); fflush(stdout); FILE *f = fopen(matches_out, "w"); if (f == NULL) { printf("Error opening file %s for writing\n", matches_out); return 1; } fprintf(f, "%d\n", num_matches); /* Write matches */ for (unsigned int i = 0; i < (unsigned int)num_keys_2; i++) { unsigned long id = ids2[i]; std::pair<std::multimap<unsigned long, unsigned int>::iterator, std::multimap<unsigned long, unsigned int>::iterator> ret; ret = word_map.equal_range(id); std::multimap<unsigned long, unsigned int>::iterator iter; for (iter = ret.first; iter != ret.second; iter++) fprintf(f, "%d %d\n", iter->second, i); } fclose(f); // printf("[VocabBuildDB] Writing tree...\n"); // tree.Write(tree_out); return 0; }
//Read a database stored as a vocab tree and score a set of query images int VocabMatch(char *db_in, char *list_in, char *query_in, int num_nbrs, char *matches_out, DistanceType distance_type = DistanceMin, int normalize = 1) { const int dim = 128; printf("[VocabMatch] Using database %s\n", db_in); switch (distance_type) { case DistanceDot: printf("[VocabMatch] Using distance Dot\n"); break; case DistanceMin: printf("[VocabMatch] Using distance Min\n"); break; default: printf("[VocabMatch] Using no known distance!\n"); break; } // Read the tree printf("[VocabMatch] Reading database...\n"); fflush(stdout); clock_t start = clock(); VocabTree tree; tree.Read(db_in); clock_t end = clock(); printf("[VocabMatch] Read database in %0.3fs\n", (double)(end - start) / CLOCKS_PER_SEC); tree.Flatten(); tree.SetDistanceType(distance_type); tree.SetInteriorNodeWeight(0, 0.0); // Read the database keyfiles FILE *f = fopen(list_in, "r"); if (f == NULL) { printf("Could not open file: %s\n", list_in); return 1; } std::vector<std::string> db_files; char buf[256]; while (fgets(buf, 256, f)) { // Remove trailing newline if (buf[strlen(buf) - 1] == '\n') buf[strlen(buf) - 1] = 0; db_files.push_back(std::string(buf)); } fclose(f); //Read the query keyfiles f = fopen(query_in, "r"); if (f == NULL) { printf("Could not open file: %s\n", query_in); return 1; } std::vector<std::string> query_files; while (fgets(buf, 256, f)) { // Remove trailing newline if (buf[strlen(buf) - 1] == '\n') buf[strlen(buf) - 1] = 0; char keyfile[256]; sscanf(buf, "%s", keyfile); query_files.push_back(std::string(keyfile)); } fclose(f); int num_db_images = (int)db_files.size(); int num_query_images = (int)query_files.size(); printf("[VocabMatch] Read %d database images\n", num_db_images); //Now score each query keyfile printf("[VocabMatch] Scoring %d query images...\n", num_query_images); fflush(stdout); float *scores = new float[num_db_images]; double *scores_d = new double[num_db_images]; int *perm = new int[num_db_images]; FILE *f_match = fopen(matches_out, "w"); if (f_match == NULL) { printf("[VocabMatch] Error opening file %s for writing\n", matches_out); return 1; } bool bnormalize = normalize == 1 ? true : false; for (int i = 0; i < num_query_images; i++) { start = clock(); for (int j = 0; j < num_db_images; j++) scores[j] = 0.0; int num_keys; unsigned char *keys = ReadKeys(query_files[i].c_str(), dim, num_keys); clock_t start_score = clock(); double mag = tree.ScoreQueryKeys(num_keys, bnormalize, keys, scores); clock_t end_score = end = clock(); printf("[VocabMatch] Scored image %s in %0.3fs ( %0.3fs total, num_keys = %d, mag = %0.3f )\n", query_files[i].c_str(), (double)(end_score - start_score) / CLOCKS_PER_SEC, (double)(end - start) / CLOCKS_PER_SEC, num_keys, mag); //Find the top scores for (int j = 0; j < num_db_images; j++) scores_d[j] = (double)scores[j]; qsort_descending(); qsort_perm(num_db_images, scores_d, perm); int top = MIN(num_nbrs, num_db_images); for (int j = 0; j < top; j++) { // if (perm[j] == index_i) // continue; fprintf(f_match, "%d %d %0.4f\n", i, perm[j], scores_d[j]); //fprintf(f_match, "%d %d %0.4f\n", i, perm[j], mag - scores_d[j]); } fflush(f_match); fflush(stdout); delete[] keys; } fclose(f_match); delete[] scores, delete[] scores_d, delete[] perm; return 0; }
// Building a database with a vocabulary tree int VocabDB(char *list_in, char *tree_in, char *db_out, int use_tfidf = 1, int normalize = 1, int start_id = 0, DistanceType distance_type = DistanceMin) { double min_feature_scale = 1.4; switch (distance_type) { case DistanceDot: printf("[VocabMatch] Using distance Dot\n"); break; case DistanceMin: printf("[VocabMatch] Using distance Min\n"); break; default: printf("[VocabMatch] Using no known distance!\n"); break; } FILE *f = fopen(list_in, "r"); if (f == NULL) { printf("Error opening file %s for reading\n", list_in); return 1; } std::vector<std::string> key_files; char buf[256]; while (fgets(buf, 256, f)) { /* Remove trailing newline */ if (buf[strlen(buf) - 1] == '\n') buf[strlen(buf) - 1] = 0; key_files.push_back(std::string(buf)); } printf("[VocabBuildDB] Reading tree %s...\n", tree_in); fflush(stdout); VocabTree tree; tree.Read(tree_in); tree.Flatten(); tree.m_distance_type = distance_type; tree.SetInteriorNodeWeight(0.0); //Initialize leaf weights to 1.0 tree.SetConstantLeafWeights(); const int dim = 128; int num_db_images = (int)key_files.size(); unsigned long count = 0; tree.ClearDatabase(); for (int i = 0; i < num_db_images; i++) { int num_keys = 0; unsigned char *keys = ReadAndFilterKeys(key_files[i].c_str(), dim, min_feature_scale, 0, num_keys); printf("[VocabBuildDB] Adding vector %d (%d keys)\n", start_id + i, num_keys); tree.AddImageToDatabase(start_id + i, num_keys, keys); if (num_keys > 0) delete[] keys; } printf("[VocabBuildDB] Pushed %lu features\n", count); fflush(stdout); if (use_tfidf == 1) tree.ComputeTFIDFWeights(num_db_images); if (normalize == 1) tree.NormalizeDatabase(start_id, num_db_images); printf("[VocabBuildDB] Writing database ...\n"); tree.Write(db_out); // char filename[256]; // sprintf(filename, "vectors_%03d.txt", start_id); // tree.WriteDatabaseVectors(filename, start_id, num_db_images); return 0; }