Mercurial > hg > audiodb
view query.cpp @ 466:11fccb6a3bd5 api-inversion
Almost there!
audioDB::index_query_loop is now set, except for the lsh_in_core and
lsh_exact flags. I think the plan is to zap lsh_in_core entirely, and
add some flags to the qid structure for indexed behaviour.
| author | mas01cr |
|---|---|
| date | Wed, 31 Dec 2008 12:25:22 +0000 |
| parents | 1030664df98c |
| children | 4dbd7917bf9e |
line wrap: on
line source
#include "audioDB.h" #include "reporter.h" #include "audioDB-internals.h" #include "accumulators.h" bool audiodb_powers_acceptable(adb_query_refine_t *r, double p1, double p2) { if (r->flags & ADB_REFINE_ABSOLUTE_THRESHOLD) { if ((p1 < r->absolute_threshold) || (p2 < r->absolute_threshold)) { return false; } } if (r->flags & ADB_REFINE_RELATIVE_THRESHOLD) { if (fabs(p1-p2) > fabs(r->relative_threshold)) { return false; } } return true; } void audioDB::query(const char* dbName, const char* inFile, adb__queryResponse *adbQueryResponse) { // init database tables and dbH first if(query_from_key) initTables(dbName); else initTables(dbName, inFile); adb_query_spec_t qspec; adb_datum_t datum = {0}; qspec.refine.flags = 0; if(trackFile) { qspec.refine.flags |= ADB_REFINE_INCLUDE_KEYLIST; std::vector<const char *> v; char *k = new char[MAXSTR]; trackFile->getline(k, MAXSTR); while(!trackFile->eof()) { v.push_back(k); k = new char[MAXSTR]; trackFile->getline(k, MAXSTR); } delete [] k; qspec.refine.include.nkeys = v.size(); qspec.refine.include.keys = new const char *[qspec.refine.include.nkeys]; for(unsigned int k = 0; k < qspec.refine.include.nkeys; k++) { qspec.refine.include.keys[k] = v[k]; } } if(query_from_key) { qspec.refine.flags |= ADB_REFINE_EXCLUDE_KEYLIST; qspec.refine.exclude.nkeys = 1; qspec.refine.exclude.keys = &key; } if(radius) { qspec.refine.flags |= ADB_REFINE_RADIUS; qspec.refine.radius = radius; } if(use_absolute_threshold) { qspec.refine.flags |= ADB_REFINE_ABSOLUTE_THRESHOLD; qspec.refine.absolute_threshold = absolute_threshold; } if(use_relative_threshold) { qspec.refine.flags |= ADB_REFINE_RELATIVE_THRESHOLD; qspec.refine.relative_threshold = relative_threshold; } if(usingTimes) { qspec.refine.flags |= ADB_REFINE_DURATION_RATIO; qspec.refine.duration_ratio = timesTol; } /* FIXME: not sure about this any more; maybe it belongs in query_id? Or maybe we just don't need a flag for it? */ qspec.refine.hopsize = sequenceHop; if(sequenceHop != 1) { qspec.refine.flags |= ADB_REFINE_HOP_SIZE; } if(query_from_key) { datum.key = key; } else { int fd; struct stat st; /* FIXME: around here there are all sorts of hideous leaks. */ fd = open(inFile, O_RDONLY); if(fd < 0) { error("failed to open feature file", inFile); } fstat(fd, &st); read(fd, &datum.dim, sizeof(uint32_t)); datum.nvectors = (st.st_size - sizeof(uint32_t)) / (datum.dim * sizeof(double)); datum.data = (double *) malloc(st.st_size - sizeof(uint32_t)); read(fd, datum.data, st.st_size - sizeof(uint32_t)); close(fd); if(usingPower) { uint32_t one; fd = open(powerFileName, O_RDONLY); if(fd < 0) { error("failed to open power file", powerFileName); } read(fd, &one, sizeof(uint32_t)); if(one != 1) { error("malformed power file dimensionality", powerFileName); } datum.power = (double *) malloc(datum.nvectors * sizeof(double)); if(read(fd, datum.power, datum.nvectors * sizeof(double)) != (ssize_t) (datum.nvectors * sizeof(double))) { error("malformed power file", powerFileName); } close(fd); } if(usingTimes) { datum.times = (double *) malloc(2 * datum.nvectors * sizeof(double)); insertTimeStamps(datum.nvectors, timesFile, datum.times); } } qspec.qid.datum = &datum; qspec.qid.sequence_length = sequenceLength; qspec.qid.flags = usingQueryPoint ? 0 : ADB_QUERY_ID_FLAG_EXHAUSTIVE; qspec.qid.sequence_start = queryPoint; switch(queryType) { case O2_POINT_QUERY: qspec.qid.sequence_length = 1; qspec.params.accumulation = ADB_ACCUMULATION_DB; qspec.params.distance = ADB_DISTANCE_DOT_PRODUCT; qspec.params.npoints = pointNN; qspec.params.ntracks = 0; reporter = new pointQueryReporter< std::greater < NNresult > >(pointNN); break; case O2_TRACK_QUERY: qspec.qid.sequence_length = 1; qspec.params.accumulation = ADB_ACCUMULATION_PER_TRACK; qspec.params.distance = ADB_DISTANCE_DOT_PRODUCT; qspec.params.npoints = pointNN; qspec.params.ntracks = trackNN; reporter = new trackAveragingReporter< std::greater< NNresult > >(pointNN, trackNN, dbH->numFiles); break; case O2_SEQUENCE_QUERY: case O2_N_SEQUENCE_QUERY: qspec.params.accumulation = ADB_ACCUMULATION_PER_TRACK; qspec.params.distance = no_unit_norming ? ADB_DISTANCE_EUCLIDEAN : ADB_DISTANCE_EUCLIDEAN_NORMED; qspec.params.npoints = pointNN; qspec.params.ntracks = trackNN; switch(queryType) { case O2_SEQUENCE_QUERY: if(!(qspec.refine.flags & ADB_REFINE_RADIUS)) { reporter = new trackAveragingReporter< std::less< NNresult > >(pointNN, trackNN, dbH->numFiles); } else { reporter = new trackSequenceQueryRadReporter(trackNN, dbH->numFiles); } break; case O2_N_SEQUENCE_QUERY: if(!(qspec.refine.flags & ADB_REFINE_RADIUS)) { reporter = new trackSequenceQueryNNReporter< std::less < NNresult > >(pointNN, trackNN, dbH->numFiles); } else { reporter = new trackSequenceQueryRadNNReporter(pointNN, trackNN, dbH->numFiles); } break; } break; case O2_ONE_TO_ONE_N_SEQUENCE_QUERY: qspec.params.accumulation = ADB_ACCUMULATION_ONE_TO_ONE; qspec.params.distance = ADB_DISTANCE_EUCLIDEAN_NORMED; qspec.params.npoints = 0; qspec.params.ntracks = 0; break; default: error("unrecognized queryType"); } /* Somewhere around here is where the implementation of * audiodb_query_spec() starts. */ adb_qstate_internal_t qstate; qstate.allowed_keys = new std::set<std::string>; if(qspec.refine.flags & ADB_REFINE_INCLUDE_KEYLIST) { for(unsigned int k = 0; k < qspec.refine.include.nkeys; k++) { qstate.allowed_keys->insert(qspec.refine.include.keys[k]); } } else { for(unsigned int k = 0; k < adb->header->numFiles; k++) { qstate.allowed_keys->insert((*adb->keys)[k]); } } if(qspec.refine.flags & ADB_REFINE_EXCLUDE_KEYLIST) { for(unsigned int k = 0; k < qspec.refine.exclude.nkeys; k++) { qstate.allowed_keys->erase(qspec.refine.exclude.keys[k]); } } switch(qspec.params.distance) { case ADB_DISTANCE_DOT_PRODUCT: switch(qspec.params.accumulation) { case ADB_ACCUMULATION_DB: qstate.accumulator = new DBAccumulator<adb_result_dist_gt>(qspec.params.npoints); break; case ADB_ACCUMULATION_PER_TRACK: qstate.accumulator = new PerTrackAccumulator<adb_result_dist_gt>(qspec.params.npoints, qspec.params.ntracks); break; case ADB_ACCUMULATION_ONE_TO_ONE: qstate.accumulator = new NearestAccumulator<adb_result_dist_gt>(); break; default: error("unknown accumulation"); } break; case ADB_DISTANCE_EUCLIDEAN_NORMED: case ADB_DISTANCE_EUCLIDEAN: switch(qspec.params.accumulation) { case ADB_ACCUMULATION_DB: qstate.accumulator = new DBAccumulator<adb_result_dist_lt>(qspec.params.npoints); break; case ADB_ACCUMULATION_PER_TRACK: qstate.accumulator = new PerTrackAccumulator<adb_result_dist_lt>(qspec.params.npoints, qspec.params.ntracks); break; case ADB_ACCUMULATION_ONE_TO_ONE: qstate.accumulator = new NearestAccumulator<adb_result_dist_lt>(); break; default: error("unknown accumulation"); } break; default: error("unknown distance function"); } // Test for index (again) here if((qspec.refine.flags & ADB_REFINE_RADIUS) && audiodb_index_exists(adb->path, qspec.refine.radius, qspec.qid.sequence_length)){ VERB_LOG(1, "Calling indexed query on database %s, radius=%f, sequence_length=%d\n", adb->path, qspec.refine.radius, qspec.qid.sequence_length); if(index_query_loop(adb, &qspec, &qstate) < 0) { error("index_query_loop failed"); } } else { VERB_LOG(1, "Calling brute-force query on database %s\n", dbName); if(audiodb_query_loop(adb, &qspec, &qstate)) { error("audiodb_query_loop failed"); } } adb_query_results_t *rs = qstate.accumulator->get_points(); delete qstate.accumulator; delete qstate.allowed_keys; /* End of audiodb_query_spec() function */ for(unsigned int k = 0; k < rs->nresults; k++) { adb_result_t r = rs->results[k]; reporter->add_point(audiodb_key_index(adb, r.key), r.qpos, r.ipos, r.dist); } audiodb_query_free_results(adb, &qspec, rs); reporter->report(fileTable, adbQueryResponse); } int audiodb_query_free_results(adb_t *adb, adb_query_spec_t *spec, adb_query_results_t *rs) { free(rs->results); free(rs); return 0; } static void audiodb_initialize_arrays(adb_t *adb, adb_query_spec_t *spec, int track, unsigned int numVectors, double *query, double *data_buffer, double **D, double **DD) { unsigned int j, k, l, w; double *dp, *qp, *sp; const unsigned HOP_SIZE = spec->refine.hopsize; const unsigned wL = spec->qid.sequence_length; for(j = 0; j < numVectors; j++) { // Sum products matrix D[j] = new double[(*adb->track_lengths)[track]]; assert(D[j]); // Matched filter matrix DD[j]=new double[(*adb->track_lengths)[track]]; assert(DD[j]); } // Dot product for(j = 0; j < numVectors; j++) for(k = 0; k < (*adb->track_lengths)[track]; k++){ qp = query + j * adb->header->dim; sp = data_buffer + k * adb->header->dim; DD[j][k] = 0.0; // Initialize matched filter array dp = &D[j][k]; // point to correlation cell j,k *dp = 0.0; // initialize correlation cell l = adb->header->dim; // size of vectors while(l--) *dp += *qp++ * *sp++; } // Matched Filter // HOP SIZE == 1 double* spd; if(HOP_SIZE == 1) { // HOP_SIZE = shingleHop for(w = 0; w < wL; w++) { for(j = 0; j < numVectors - w; j++) { sp = DD[j]; spd = D[j+w] + w; k = (*adb->track_lengths)[track] - w; while(k--) *sp++ += *spd++; } } } else { // HOP_SIZE != 1 for(w = 0; w < wL; w++) { for(j = 0; j < numVectors - w; j += HOP_SIZE) { sp = DD[j]; spd = D[j+w]+w; for(k = 0; k < (*adb->track_lengths)[track] - w; k += HOP_SIZE) { *sp += *spd; sp += HOP_SIZE; spd += HOP_SIZE; } } } } } static void audiodb_delete_arrays(int track, unsigned int numVectors, double **D, double **DD) { if(D != NULL) { for(unsigned int j = 0; j < numVectors; j++) { delete[] D[j]; } } if(DD != NULL) { for(unsigned int j = 0; j < numVectors; j++) { delete[] DD[j]; } } } int audiodb_read_data(adb_t *adb, int trkfid, int track, double **data_buffer_p, size_t *data_buffer_size_p) { uint32_t track_length = (*adb->track_lengths)[track]; size_t track_size = track_length * sizeof(double) * adb->header->dim; if (track_size > *data_buffer_size_p) { if(*data_buffer_p) { free(*data_buffer_p); } { *data_buffer_size_p = track_size; void *tmp = malloc(track_size); if (tmp == NULL) { goto error; } *data_buffer_p = (double *) tmp; } } read_or_goto_error(trkfid, *data_buffer_p, track_size); return 0; error: return 1; } void audioDB::insertTimeStamps(unsigned numVectors, std::ifstream *timesFile, double *timesdata) { assert(usingTimes); unsigned numtimes = 0; if(!timesFile->is_open()) { error("problem opening times file on timestamped database", timesFileName); } double timepoint, next; *timesFile >> timepoint; if (timesFile->eof()) { error("no entries in times file", timesFileName); } numtimes++; do { *timesFile >> next; if (timesFile->eof()) { break; } numtimes++; timesdata[0] = timepoint; timepoint = (timesdata[1] = next); timesdata += 2; } while (numtimes < numVectors + 1); if (numtimes < numVectors + 1) { error("too few timepoints in times file", timesFileName); } *timesFile >> next; if (!timesFile->eof()) { error("too many timepoints in times file", timesFileName); } } int audiodb_track_id_datum(adb_t *adb, uint32_t track_id, adb_datum_t *d) { off_t track_offset = (*adb->track_offsets)[track_id]; if(adb->header->flags & O2_FLAG_LARGE_ADB) { /* create a reference/insert, then use adb_insert_create_datum() */ adb_reference_t reference = {0}; char features[MAXSTR], power[MAXSTR], times[MAXSTR]; lseek(adb->fd, adb->header->dataOffset + track_id * O2_FILETABLE_ENTRY_SIZE, SEEK_SET); /* FIXME: learn not to worry and love the bomb^Wbuffer overflow */ read(adb->fd, features, MAXSTR); reference.features = features; if(adb->header->flags & O2_FLAG_POWER) { lseek(adb->fd, adb->header->powerTableOffset + track_id * O2_FILETABLE_ENTRY_SIZE, SEEK_SET); read(adb->fd, power, MAXSTR); reference.power = power; } if(adb->header->flags & O2_FLAG_TIMES) { lseek(adb->fd, adb->header->timesTableOffset + track_id * O2_FILETABLE_ENTRY_SIZE, SEEK_SET); read(adb->fd, times, MAXSTR); reference.times = times; } audiodb_insert_create_datum(&reference, d); } else { /* initialize from sources of data that we already have */ d->nvectors = (*adb->track_lengths)[track_id]; d->dim = adb->header->dim; d->key = (*adb->keys)[track_id].c_str(); /* read out stuff from the database tables */ d->data = (double *) malloc(d->nvectors * d->dim * sizeof(double)); lseek(adb->fd, adb->header->dataOffset + track_offset, SEEK_SET); read(adb->fd, d->data, d->nvectors * d->dim * sizeof(double)); if(adb->header->flags & O2_FLAG_POWER) { d->power = (double *) malloc(d->nvectors * sizeof(double)); lseek(adb->fd, adb->header->powerTableOffset + track_offset / d->dim, SEEK_SET); read(adb->fd, d->power, d->nvectors * sizeof(double)); } if(adb->header->flags & O2_FLAG_TIMES) { d->times = (double *) malloc(2 * d->nvectors * sizeof(double)); lseek(adb->fd, adb->header->timesTableOffset + track_offset / d->dim, SEEK_SET); read(adb->fd, d->times, 2 * d->nvectors * sizeof(double)); } } return 0; } int audiodb_datum_qpointers(adb_datum_t *d, uint32_t sequence_length, double **vector_data, double **vector, adb_qpointers_internal_t *qpointers) { uint32_t nvectors = d->nvectors; qpointers->nvectors = nvectors; size_t vector_size = nvectors * sizeof(double) * d->dim; *vector_data = new double[vector_size]; memcpy(*vector_data, d->data, vector_size); qpointers->l2norm_data = new double[vector_size / d->dim]; audiodb_l2norm_buffer(*vector_data, d->dim, nvectors, qpointers->l2norm_data); audiodb_sequence_sum(qpointers->l2norm_data, nvectors, sequence_length); audiodb_sequence_sqrt(qpointers->l2norm_data, nvectors, sequence_length); if(d->power) { qpointers->power_data = new double[vector_size / d->dim]; memcpy(qpointers->power_data, d->power, vector_size / d->dim); audiodb_sequence_sum(qpointers->power_data, nvectors, sequence_length); audiodb_sequence_average(qpointers->power_data, nvectors, sequence_length); } if(d->times) { qpointers->mean_duration = new double[1]; *qpointers->mean_duration = 0; for(unsigned int k = 0; k < nvectors; k++) { *qpointers->mean_duration += d->times[2*k+1] - d->times[2*k]; } *qpointers->mean_duration /= nvectors; } *vector = *vector_data; qpointers->l2norm = qpointers->l2norm_data; qpointers->power = qpointers->power_data; return 0; } int audiodb_query_spec_qpointers(adb_t *adb, adb_query_spec_t *spec, double **vector_data, double **vector, adb_qpointers_internal_t *qpointers) { adb_datum_t *datum; adb_datum_t d = {0}; uint32_t sequence_length; uint32_t sequence_start; datum = spec->qid.datum; sequence_length = spec->qid.sequence_length; sequence_start = spec->qid.sequence_start; if(datum->data) { if(datum->dim != adb->header->dim) { return 1; } /* initialize d, and mark that nothing needs freeing later. */ d = *datum; datum = &d; } else if (datum->key) { uint32_t track_id; if((track_id = audiodb_key_index(adb, datum->key)) == (uint32_t) -1) { return 1; } audiodb_track_id_datum(adb, track_id, &d); } else { return 1; } /* FIXME: check the overflow logic here */ if(sequence_start + sequence_length > d.nvectors) { if(datum != &d) { audiodb_free_datum(&d); } return 1; } audiodb_datum_qpointers(&d, sequence_length, vector_data, vector, qpointers); /* Finally, if applicable, set up the moving qpointers. */ if(spec->qid.flags & ADB_QUERY_ID_FLAG_EXHAUSTIVE) { /* the qpointers are already at the start, and so correct. */ } else { /* adjust the qpointers to point to the correct place in the sequence */ *vector = *vector_data + spec->qid.sequence_start * d.dim; qpointers->l2norm = qpointers->l2norm_data + spec->qid.sequence_start; if(d.power) { qpointers->power = qpointers->power_data + spec->qid.sequence_start; } qpointers->nvectors = sequence_length; } /* Clean up: free any bits of datum that we have ourselves * allocated. */ if(datum != &d) { audiodb_free_datum(&d); } return 0; } static int audiodb_set_up_dbpointers(adb_t *adb, adb_query_spec_t *spec, adb_qpointers_internal_t *dbpointers) { uint32_t nvectors = adb->header->length / (adb->header->dim * sizeof(double)); uint32_t sequence_length = spec->qid.sequence_length; bool using_power = spec->refine.flags & (ADB_REFINE_ABSOLUTE_THRESHOLD|ADB_REFINE_RELATIVE_THRESHOLD); bool using_times = spec->refine.flags & ADB_REFINE_DURATION_RATIO; double *times_table = NULL; dbpointers->nvectors = nvectors; dbpointers->l2norm_data = new double[nvectors]; double *snpp = dbpointers->l2norm_data, *sppp = 0; lseek(adb->fd, adb->header->l2normTableOffset, SEEK_SET); read_or_goto_error(adb->fd, dbpointers->l2norm_data, nvectors * sizeof(double)); if (using_power) { if (!(adb->header->flags & O2_FLAG_POWER)) { goto error; } dbpointers->power_data = new double[nvectors]; sppp = dbpointers->power_data; lseek(adb->fd, adb->header->powerTableOffset, SEEK_SET); read_or_goto_error(adb->fd, dbpointers->power_data, nvectors * sizeof(double)); } for(unsigned int i = 0; i < adb->header->numFiles; i++){ size_t track_length = (*adb->track_lengths)[i]; if(track_length >= sequence_length) { audiodb_sequence_sum(snpp, track_length, sequence_length); audiodb_sequence_sqrt(snpp, track_length, sequence_length); if (using_power) { audiodb_sequence_sum(sppp, track_length, sequence_length); audiodb_sequence_average(sppp, track_length, sequence_length); } } snpp += track_length; if (using_power) { sppp += track_length; } } if (using_times) { if(!(adb->header->flags & O2_FLAG_TIMES)) { goto error; } dbpointers->mean_duration = new double[adb->header->numFiles]; times_table = (double *) malloc(2 * nvectors * sizeof(double)); if(!times_table) { goto error; } lseek(adb->fd, adb->header->timesTableOffset, SEEK_SET); read_or_goto_error(adb->fd, times_table, 2 * nvectors * sizeof(double)); for(unsigned int k = 0; k < adb->header->numFiles; k++) { size_t track_length = (*adb->track_lengths)[k]; unsigned int j; dbpointers->mean_duration[k] = 0.0; for(j = 0; j < track_length; j++) { dbpointers->mean_duration[k] += times_table[2*j+1] - times_table[2*j]; } dbpointers->mean_duration[k] /= j; } free(times_table); times_table = NULL; } dbpointers->l2norm = dbpointers->l2norm_data; dbpointers->power = dbpointers->power_data; return 0; error: if(dbpointers->l2norm_data) { delete [] dbpointers->l2norm_data; } if(dbpointers->power_data) { delete [] dbpointers->power_data; } if(dbpointers->mean_duration) { delete [] dbpointers->mean_duration; } if(times_table) { free(times_table); } return 1; } int audiodb_query_queue_loop(adb_t *adb, adb_query_spec_t *spec, adb_qstate_internal_t *qstate, double *query, adb_qpointers_internal_t *qpointers) { adb_qpointers_internal_t dbpointers = {0}; uint32_t sequence_length = spec->qid.sequence_length; bool power_refine = spec->refine.flags & (ADB_REFINE_ABSOLUTE_THRESHOLD|ADB_REFINE_RELATIVE_THRESHOLD); if(qstate->exact_evaluation_queue->size() == 0) { return 0; } /* We are guaranteed that the order of points is sorted by: * {trackID, spos, qpos} so we can be relatively efficient in * initialization of track data. We assume that points usually * don't overlap, so we will use exhaustive dot product evaluation * (instead of memoization of partial sums, as in query_loop()). */ double dist; double *dbdata = 0, *dbdata_pointer; Uns32T currentTrack = 0x80000000; // KLUDGE: Initialize with a value outside of track index range Uns32T npairs = qstate->exact_evaluation_queue->size(); while(npairs--) { PointPair pp = qstate->exact_evaluation_queue->top(); if(currentTrack != pp.trackID) { SAFE_DELETE_ARRAY(dbdata); SAFE_DELETE_ARRAY(dbpointers.l2norm_data); SAFE_DELETE_ARRAY(dbpointers.power_data); SAFE_DELETE_ARRAY(dbpointers.mean_duration); currentTrack = pp.trackID; adb_datum_t d = {0}; if(audiodb_track_id_datum(adb, pp.trackID, &d)) { delete qstate->exact_evaluation_queue; return 1; } if(audiodb_datum_qpointers(&d, sequence_length, &dbdata, &dbdata_pointer, &dbpointers)) { delete qstate->exact_evaluation_queue; audiodb_free_datum(&d); return 1; } audiodb_free_datum(&d); } Uns32T qPos = (spec->qid.flags & ADB_QUERY_ID_FLAG_EXHAUSTIVE) ? pp.qpos : 0; Uns32T sPos = pp.spos; // index into l2norm table // Test power thresholds before computing distance if( ( (!power_refine) || audiodb_powers_acceptable(&spec->refine, qpointers->power[qPos], dbpointers.power[sPos])) && ( qPos<qpointers->nvectors-sequence_length+1 && sPos<(*adb->track_lengths)[pp.trackID]-sequence_length+1 ) ){ // Compute distance dist = audiodb_dot_product(query + qPos*adb->header->dim, dbdata + sPos*adb->header->dim, adb->header->dim*sequence_length); double qn = qpointers->l2norm[qPos]; double sn = dbpointers.l2norm[sPos]; switch(spec->params.distance) { case ADB_DISTANCE_EUCLIDEAN_NORMED: dist = 2 - (2/(qn*sn))*dist; break; case ADB_DISTANCE_EUCLIDEAN: dist = qn*qn + sn*sn - 2*dist; break; } if((!(spec->refine.flags & ADB_REFINE_RADIUS)) || dist <= (spec->refine.radius+O2_DISTANCE_TOLERANCE)) { adb_result_t r; r.key = (*adb->keys)[pp.trackID].c_str(); r.dist = dist; r.qpos = pp.qpos; r.ipos = pp.spos; qstate->accumulator->add_point(&r); } } qstate->exact_evaluation_queue->pop(); } // Cleanup SAFE_DELETE_ARRAY(dbdata); SAFE_DELETE_ARRAY(dbpointers.l2norm_data); SAFE_DELETE_ARRAY(dbpointers.power_data); SAFE_DELETE_ARRAY(dbpointers.mean_duration); delete qstate->exact_evaluation_queue; return 0; } int audiodb_query_loop(adb_t *adb, adb_query_spec_t *spec, adb_qstate_internal_t *qstate) { double *query, *query_data; adb_qpointers_internal_t qpointers = {0}, dbpointers = {0}; bool power_refine = spec->refine.flags & (ADB_REFINE_ABSOLUTE_THRESHOLD|ADB_REFINE_RELATIVE_THRESHOLD); if(adb->header->flags & O2_FLAG_LARGE_ADB) { /* FIXME: actually it would be nice to support this mode of * operation, but for now... */ return 1; } if(audiodb_query_spec_qpointers(adb, spec, &query_data, &query, &qpointers)) { return 1; } if(audiodb_set_up_dbpointers(adb, spec, &dbpointers)) { return 1; } unsigned j,k,track,trackOffset=0, HOP_SIZE = spec->refine.hopsize; unsigned wL = spec->qid.sequence_length; double **D = 0; // Differences query and target double **DD = 0; // Matched filter distance D = new double*[qpointers.nvectors]; // pre-allocate DD = new double*[qpointers.nvectors]; off_t trackIndexOffset; // Track loop size_t data_buffer_size = 0; double *data_buffer = 0; lseek(adb->fd, adb->header->dataOffset, SEEK_SET); std::set<std::string>::iterator keys_end = qstate->allowed_keys->end(); for(track = 0; track < adb->header->numFiles; track++) { unsigned t = track; while (qstate->allowed_keys->find((*adb->keys)[track]) == keys_end) { track++; if(track == adb->header->numFiles) { goto loop_finish; } } trackOffset = (*adb->track_offsets)[track]; if(track != t) { lseek(adb->fd, adb->header->dataOffset + trackOffset, SEEK_SET); } trackIndexOffset = trackOffset / (adb->header->dim * sizeof(double)); // dbpointers.nvectors offset if(audiodb_read_data(adb, adb->fd, track, &data_buffer, &data_buffer_size)) { return 1; } if(wL <= (*adb->track_lengths)[track]) { // test for short sequences audiodb_initialize_arrays(adb, spec, track, qpointers.nvectors, query, data_buffer, D, DD); if((!(spec->refine.flags & ADB_REFINE_DURATION_RATIO)) || fabs(dbpointers.mean_duration[track]-qpointers.mean_duration[0]) < qpointers.mean_duration[0]*spec->refine.duration_ratio) { // Search for minimum distance by shingles (concatenated vectors) for(j = 0; j <= qpointers.nvectors - wL; j += HOP_SIZE) { for(k = 0; k <= (*adb->track_lengths)[track] - wL; k += HOP_SIZE) { double thisDist = 0; double qn = qpointers.l2norm[j]; double sn = dbpointers.l2norm[trackIndexOffset + k]; switch(spec->params.distance) { case ADB_DISTANCE_EUCLIDEAN_NORMED: thisDist = 2-(2/(qn*sn))*DD[j][k]; break; case ADB_DISTANCE_EUCLIDEAN: thisDist = qn*qn + sn*sn - 2*DD[j][k]; break; case ADB_DISTANCE_DOT_PRODUCT: thisDist = DD[j][k]; break; } // Power test if ((!power_refine) || audiodb_powers_acceptable(&spec->refine, qpointers.power[j], dbpointers.power[trackIndexOffset + k])) { // radius test if((!(spec->refine.flags & ADB_REFINE_RADIUS)) || thisDist <= (spec->refine.radius+O2_DISTANCE_TOLERANCE)) { adb_result_t r; r.key = (*adb->keys)[track].c_str(); r.dist = thisDist; if(spec->qid.flags & ADB_QUERY_ID_FLAG_EXHAUSTIVE) { r.qpos = j; } else { r.qpos = spec->qid.sequence_start; } r.ipos = k; qstate->accumulator->add_point(&r); } } } } } // Duration match audiodb_delete_arrays(track, qpointers.nvectors, D, DD); } } loop_finish: free(data_buffer); // Clean up if(query_data) delete[] query_data; if(qpointers.l2norm_data) delete[] qpointers.l2norm_data; if(qpointers.power_data) delete[] qpointers.power_data; if(qpointers.mean_duration) delete[] qpointers.mean_duration; if(dbpointers.power_data) delete[] dbpointers.power_data; if(dbpointers.l2norm_data) delete[] dbpointers.l2norm_data; if(D) delete[] D; if(DD) delete[] DD; if(dbpointers.mean_duration) delete[] dbpointers.mean_duration; return 0; }