Mercurial > hg > audiodb
view query.cpp @ 248:5682c7d7444b
Added new query type: nsequence : this reports the n-nearest neighbours for each track in a sequence averaging query.
Next up is the same for the radius search (still accessed via nsequence but with -R set non zero)
| author | mas01mc |
|---|---|
| date | Sun, 17 Feb 2008 14:56:02 +0000 |
| parents | 4eb4608e28e1 |
| children | a6ee49f10296 |
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#include "audioDB.h" #include "reporter.h" bool audioDB::powers_acceptable(double p1, double p2) { if (use_absolute_threshold) { if ((p1 < absolute_threshold) || (p2 < absolute_threshold)) { return false; } } if (use_relative_threshold) { if (fabs(p1-p2) > fabs(relative_threshold)) { return false; } } return true; } void audioDB::query(const char* dbName, const char* inFile, adb__queryResponse *adbQueryResponse) { initTables(dbName, inFile); Reporter *r = 0; switch (queryType) { case O2_POINT_QUERY: sequenceLength = 1; normalizedDistance = false; r = new pointQueryReporter<std::greater < NNresult > >(pointNN); break; case O2_TRACK_QUERY: sequenceLength = 1; normalizedDistance = false; r = new trackAveragingReporter<std::greater < NNresult > >(pointNN, trackNN, dbH->numFiles); break; case O2_SEQUENCE_QUERY: if(radius == 0) { r = new trackAveragingReporter<std::less < NNresult > >(pointNN, trackNN, dbH->numFiles); } else { r = new trackSequenceQueryRadReporter(trackNN, dbH->numFiles); } break; case O2_N_SEQUENCE_QUERY : if(radius == 0) { r = new trackSequenceQueryNNReporter<std::less < NNresult > >(pointNN, trackNN, dbH->numFiles); } else { r = new trackSequenceQueryRadReporter(trackNN, dbH->numFiles); } break; default: error("unrecognized queryType in query()"); } query_loop(dbName, inFile, r); r->report(fileTable, adbQueryResponse); delete r; } // return ordinal position of key in keyTable unsigned audioDB::getKeyPos(char* key){ for(unsigned k=0; k<dbH->numFiles; k++) if(strncmp(fileTable + k*O2_FILETABLESIZE, key, strlen(key))==0) return k; error("Key not found",key); return O2_ERR_KEYNOTFOUND; } // This is a common pattern in sequence queries: what we are doing is // taking a window of length seqlen over a buffer of length length, // and placing the sum of the elements in that window in the first // element of the window: thus replacing all but the last seqlen // elements in the buffer with the corresponding windowed sum. void audioDB::sequence_sum(double *buffer, int length, int seqlen) { double tmp1, tmp2, *ps; int j, w; tmp1 = *buffer; j = 1; w = seqlen - 1; while(w--) { *buffer += buffer[j++]; } ps = buffer + 1; w = length - seqlen; // +1 - 1 while(w--) { tmp2 = *ps; if(isfinite(tmp1)) { *ps = *(ps - 1) - tmp1 + *(ps + seqlen - 1); } else { for(int i = 1; i < seqlen; i++) { *ps += *(ps + i); } } tmp1 = tmp2; ps++; } } // In contrast to sequence_sum() above, sequence_sqrt() and // sequence_average() below are simple mappers across the sequence. void audioDB::sequence_sqrt(double *buffer, int length, int seqlen) { int w = length - seqlen + 1; while(w--) { *buffer = sqrt(*buffer); buffer++; } } void audioDB::sequence_average(double *buffer, int length, int seqlen) { int w = length - seqlen + 1; while(w--) { *buffer /= seqlen; buffer++; } } void audioDB::initialize_arrays(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 = sequenceHop; const unsigned wL = sequenceLength; for(j = 0; j < numVectors; j++) { // Sum products matrix D[j] = new double[trackTable[track]]; assert(D[j]); // Matched filter matrix DD[j]=new double[trackTable[track]]; assert(DD[j]); } // Dot product for(j = 0; j < numVectors; j++) for(k = 0; k < trackTable[track]; k++){ qp = query + j * dbH->dim; sp = data_buffer + k * dbH->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 = dbH->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 = trackTable[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 < trackTable[track] - w; k += HOP_SIZE) { *sp += *spd; sp += HOP_SIZE; spd += HOP_SIZE; } } } } } 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]; } } } void audioDB::read_data(int track, double **data_buffer_p, size_t *data_buffer_size_p) { if (trackTable[track] * sizeof(double) * dbH->dim > *data_buffer_size_p) { if(*data_buffer_p) { free(*data_buffer_p); } { *data_buffer_size_p = trackTable[track] * sizeof(double) * dbH->dim; void *tmp = malloc(*data_buffer_size_p); if (tmp == NULL) { error("error allocating data buffer"); } *data_buffer_p = (double *) tmp; } } read(dbfid, *data_buffer_p, trackTable[track] * sizeof(double) * dbH->dim); } // These names deserve some unpicking. The names starting with a "q" // are pointers to the query, norm and power vectors; the names // starting with "v" are things that will end up pointing to the // actual query point's information. -- CSR, 2007-12-05 void audioDB::set_up_query(double **qp, double **vqp, double **qnp, double **vqnp, double **qpp, double **vqpp, double *mqdp, unsigned *nvp) { *nvp = (statbuf.st_size - sizeof(int)) / (dbH->dim * sizeof(double)); if(!(dbH->flags & O2_FLAG_L2NORM)) { error("Database must be L2 normed for sequence query","use -L2NORM"); } if(*nvp < sequenceLength) { error("Query shorter than requested sequence length", "maybe use -l"); } VERB_LOG(1, "performing norms... "); *qp = new double[*nvp * dbH->dim]; memcpy(*qp, indata+sizeof(int), *nvp * dbH->dim * sizeof(double)); *qnp = new double[*nvp]; unitNorm(*qp, dbH->dim, *nvp, *qnp); sequence_sum(*qnp, *nvp, sequenceLength); sequence_sqrt(*qnp, *nvp, sequenceLength); if (usingPower) { *qpp = new double[*nvp]; if (lseek(powerfd, sizeof(int), SEEK_SET) == (off_t) -1) { error("error seeking to data", powerFileName, "lseek"); } int count = read(powerfd, *qpp, *nvp * sizeof(double)); if (count == -1) { error("error reading data", powerFileName, "read"); } if ((unsigned) count != *nvp * sizeof(double)) { error("short read", powerFileName); } sequence_sum(*qpp, *nvp, sequenceLength); sequence_average(*qpp, *nvp, sequenceLength); } if (usingTimes) { unsigned int k; *mqdp = 0.0; double *querydurs = new double[*nvp]; double *timesdata = new double[*nvp*2]; insertTimeStamps(*nvp, timesFile, timesdata); for(k = 0; k < *nvp; k++) { querydurs[k] = timesdata[2*k+1] - timesdata[2*k]; *mqdp += querydurs[k]; } *mqdp /= k; VERB_LOG(1, "mean query file duration: %f\n", *mqdp); delete [] querydurs; delete [] timesdata; } // Defaults, for exhaustive search (!usingQueryPoint) *vqp = *qp; *vqnp = *qnp; *vqpp = *qpp; if(usingQueryPoint) { if(queryPoint > *nvp || queryPoint > *nvp - sequenceLength + 1) { error("queryPoint > numVectors-wL+1 in query"); } else { VERB_LOG(1, "query point: %u\n", queryPoint); *vqp = *qp + queryPoint * dbH->dim; *vqnp = *qnp + queryPoint; if (usingPower) { *vqpp = *qpp + queryPoint; } *nvp = sequenceLength; } } } // FIXME: this is not the right name; we're not actually setting up // the database, but copying various bits of it out of mmap()ed tables // in order to reduce seeks. void audioDB::set_up_db(double **snp, double **vsnp, double **spp, double **vspp, double **mddp, unsigned int *dvp) { *dvp = dbH->length / (dbH->dim * sizeof(double)); *snp = new double[*dvp]; double *snpp = *snp, *sppp = 0; memcpy(*snp, l2normTable, *dvp * sizeof(double)); if (usingPower) { if (!(dbH->flags & O2_FLAG_POWER)) { error("database not power-enabled", dbName); } *spp = new double[*dvp]; sppp = *spp; memcpy(*spp, powerTable, *dvp * sizeof(double)); } for(unsigned int i = 0; i < dbH->numFiles; i++){ if(trackTable[i] >= sequenceLength) { sequence_sum(snpp, trackTable[i], sequenceLength); sequence_sqrt(snpp, trackTable[i], sequenceLength); if (usingPower) { sequence_sum(sppp, trackTable[i], sequenceLength); sequence_average(sppp, trackTable[i], sequenceLength); } } snpp += trackTable[i]; if (usingPower) { sppp += trackTable[i]; } } if (usingTimes) { if(!(dbH->flags & O2_FLAG_TIMES)) { error("query timestamps provided for non-timed database", dbName); } *mddp = new double[dbH->numFiles]; for(unsigned int k = 0; k < dbH->numFiles; k++) { unsigned int j; (*mddp)[k] = 0.0; for(j = 0; j < trackTable[k]; j++) { (*mddp)[k] += timesTable[2*j+1] - timesTable[2*j]; } (*mddp)[k] /= j; } } *vsnp = *snp; *vspp = *spp; } void audioDB::query_loop(const char* dbName, const char* inFile, Reporter *reporter) { unsigned int numVectors; double *query, *query_data; double *qNorm, *qnPtr, *qPower = 0, *qpPtr = 0; double meanQdur; set_up_query(&query_data, &query, &qNorm, &qnPtr, &qPower, &qpPtr, &meanQdur, &numVectors); unsigned int dbVectors; double *sNorm, *snPtr, *sPower = 0, *spPtr = 0; double *meanDBdur = 0; set_up_db(&sNorm, &snPtr, &sPower, &spPtr, &meanDBdur, &dbVectors); VERB_LOG(1, "matching tracks..."); assert(pointNN>0 && pointNN<=O2_MAXNN); assert(trackNN>0 && trackNN<=O2_MAXNN); unsigned j,k,track,trackOffset=0, HOP_SIZE=sequenceHop, wL=sequenceLength; double **D = 0; // Differences query and target double **DD = 0; // Matched filter distance D = new double*[numVectors]; DD = new double*[numVectors]; gettimeofday(&tv1, NULL); unsigned processedTracks = 0; // build track offset table off_t *trackOffsetTable = new off_t[dbH->numFiles]; unsigned cumTrack=0; off_t trackIndexOffset; for(k = 0; k < dbH->numFiles; k++){ trackOffsetTable[k] = cumTrack; cumTrack += trackTable[k] * dbH->dim; } char nextKey[MAXSTR]; // Track loop size_t data_buffer_size = 0; double *data_buffer = 0; lseek(dbfid, dbH->dataOffset, SEEK_SET); for(processedTracks=0, track=0 ; processedTracks < dbH->numFiles ; track++, processedTracks++) { trackOffset = trackOffsetTable[track]; // numDoubles offset // get trackID from file if using a control file if(trackFile) { trackFile->getline(nextKey,MAXSTR); if(!trackFile->eof()) { track = getKeyPos(nextKey); trackOffset = trackOffsetTable[track]; lseek(dbfid, dbH->dataOffset + trackOffset * sizeof(double), SEEK_SET); } else { break; } } trackIndexOffset=trackOffset/dbH->dim; // numVectors offset read_data(track, &data_buffer, &data_buffer_size); if(sequenceLength <= trackTable[track]) { // test for short sequences VERB_LOG(7,"%u.%jd.%u | ", track, (intmax_t) trackIndexOffset, trackTable[track]); initialize_arrays(track, numVectors, query, data_buffer, D, DD); if(usingTimes) { VERB_LOG(3,"meanQdur=%f meanDBdur=%f\n", meanQdur, meanDBdur[track]); } if((!usingTimes) || fabs(meanDBdur[track]-meanQdur) < meanQdur*timesTol) { if(usingTimes) { VERB_LOG(3,"within duration tolerance.\n"); } // Search for minimum distance by shingles (concatenated vectors) for(j = 0; j <= numVectors - wL; j += HOP_SIZE) { for(k = 0; k <= trackTable[track] - wL; k += HOP_SIZE) { double thisDist; if(normalizedDistance) { thisDist = 2-(2/(qnPtr[j]*sNorm[trackIndexOffset+k]))*DD[j][k]; } else { thisDist = DD[j][k]; } // Power test if ((!usingPower) || powers_acceptable(qpPtr[j], sPower[trackIndexOffset + k])) { // radius test if((!radius) || thisDist < radius) { reporter->add_point(track, usingQueryPoint ? queryPoint : j, k, thisDist); } } } } } // Duration match delete_arrays(track, numVectors, D, DD); } } free(data_buffer); gettimeofday(&tv2,NULL); VERB_LOG(1,"elapsed time: %ld msec\n", (tv2.tv_sec*1000 + tv2.tv_usec/1000) - (tv1.tv_sec*1000 + tv1.tv_usec/1000)) // Clean up if(trackOffsetTable) delete[] trackOffsetTable; if(query_data) delete[] query_data; if(qNorm) delete[] qNorm; if(sNorm) delete[] sNorm; if(qPower) delete[] qPower; if(sPower) delete[] sPower; if(D) delete[] D; if(DD) delete[] DD; if(meanDBdur) delete[] meanDBdur; } // Unit norm block of features void audioDB::unitNorm(double* X, unsigned dim, unsigned n, double* qNorm){ unsigned d; double L2, *p; VERB_LOG(2, "norming %u vectors...", n); while(n--) { p = X; L2 = 0.0; d = dim; while(d--) { L2 += *p * *p; p++; } if(qNorm) { *qNorm++=L2; } X += dim; } VERB_LOG(2, "done.\n"); }