bool addKeywordsImg(const int dbId, const int id, int_vector hashes){ if (!validate_imgid(dbId, id)) { cerr << "ERROR: image id (" << id << ") not found on given dbid (" << dbId << ") or dbid not existant" << endl ; return false;}; // populate keyword postings for (intVectorIterator it = hashes.begin(); it != hashes.end(); it++) { getKwdPostings(*it)->imgIdsFilter->insert(id); } // populate image kwds int_hashset& imgKwds = dbSpace[dbId]->sigs[id]->keywords; imgKwds.insert(hashes.begin(),hashes.end()); return true; }
// query by keywords std::vector<double> queryImgIDKeywords(const int dbId, long int id, int numres, int kwJoinType, int_vector keywords, bool colorOnly){ if (!validate_dbid(dbId)) { cerr << "ERROR: database space not found (" << dbId << ")" << endl; return std::vector<double>();} if ((id != 0) && !validate_imgid(dbId, id)) { // not search random and image doesnt exist cerr << "ERROR: image id (" << id << ") not found on given dbid (" << dbId << ") or dbid not existant" << endl ; return std::vector<double>(); } if (keywords.size() < 1) { cerr << "ERROR: At least one keyword must be supplied" << endl ; return std::vector<double>(); } // populate filter intVectorIterator it = keywords.begin(); bloom_filter* bf = 0; // OR or AND each kwd postings filter to get final filter // start with the first one bf = new bloom_filter(*(getKwdPostings(*it)->imgIdsFilter)); it++; for (; it != keywords.end(); it++) { // iterate the rest if (kwJoinType) { // and'd (*bf) &= *(getKwdPostings(*it)->imgIdsFilter); } else { // or'd (*bf) |= *(getKwdPostings(*it)->imgIdsFilter); } } if (id == 0) { // random images with these kwds vector<double> V; // select all images with the desired keywords for (sigIterator sit = dbSpace[dbId]->sigs.begin(); sit != dbSpace[dbId]->sigs.end(); sit++) { if (V.size() > 20*numres) break; if ((bf == 0) || (bf->contains((*sit).first))) { // image has desired keyword or we're querying random V.insert(V.end(), (*sit).first); V.insert(V.end(), 0); } } vector<double> Vres; for (int var = 0; var < min(V.size()/2, numres); ) { // var goes from 0 to numres int rint = rand()%(V.size()/2); if (V[rint*2] > 0) { // havent added this random result yet Vres.insert(Vres.end(), V[rint*2] ); Vres.insert(Vres.end(), 0 ); V[rint*2] = 0; ++var; } ++var; } return Vres; } return queryImgIDFiltered(dbId, id, numres, bf, colorOnly); }
/*! \param i Index of the value. \f$ i \in [0..size()-1]\f$. * Time complexity: O(1) for small and O(log n) for large values */ inline value_type operator[](size_type i)const { if (m_small_lcp[i]!=255) { return m_small_lcp[i]; } else { size_type idx = lower_bound(m_big_lcp_idx.begin(), m_big_lcp_idx.end(),i) - m_big_lcp_idx.begin(); return m_big_lcp[idx]; } }
bool ternary::encode(const int_vector &v, int_vector &z){ z.setIntWidth( v.getIntWidth() ); size_t z_bit_size = 0; for(typename int_vector::const_iterator it = v.begin(), end = v.end(); it != end; ++it){ z_bit_size += encoding_length(*it); } z.bit_resize( z_bit_size ); // Initial size of z if( z_bit_size & 0x3F ){ // if z_bit_size % 64 != 0 *(z.m_data + (z_bit_size>>6)) = 0; // initialize last word }
std::vector<int> const build_vector() { typedef std::vector<int> int_vector; static int_vector data = init_vector(); int_vector::size_type const size = data.size(); int_vector::iterator it = data.begin(); int_vector::iterator const end = data.end(); for (; it != end; ++it) *it += size; return data; }
std::unordered_set<int> const build_unordered_set() { typedef std::unordered_set<int> int_set; typedef std::vector<int> int_vector; int_set result; int_vector const data = build_vector(); int_vector::const_iterator it = data.begin(); int_vector::const_iterator const end = data.end(); result.insert(it, end); return result; }
std::map<int, int> const build_map() { typedef std::map<int, int> int_map; typedef std::vector<int> int_vector; int_map result; int_vector const data = build_vector(); int_vector::const_iterator it = data.begin(); int_vector::const_iterator const end = data.end(); for (; it != end; ++it) { int const value = *it; result[value] = 100 * value; } return result; }
bool elias_delta::encode(const int_vector& v, int_vector& z) { typedef typename int_vector::size_type size_type; z.width(v.width()); size_type z_bit_size = 0; uint64_t w; const uint64_t zero_val = v.width() < 64 ? (1ULL)<<v.width() : 0; for (typename int_vector::const_iterator it = v.begin(), end = v.end(); it != end; ++it) { if ((w=*it) == 0) { w = zero_val; } z_bit_size += encoding_length(w); } z.bit_resize(z_bit_size); // Initial size of z if (z_bit_size & 0x3F) { // if z_bit_size % 64 != 0 *(z.m_data + (z_bit_size>>6)) = 0; // initialize last word }
/*! * Constructor for building the Index * \param[in] str C-string of the text */ index_sa_text_occ(const unsigned char* str) : index() { size_t n = strlen((const char*)str); sa = int_vector<>(n+1, 0, bit_magic::l1BP(n+1)+1); algorithm::calculate_sa(str, n+1, sa); // calculate the suffix array sa of str setText(str, n+1); text = int_vector<>(sa.size(), 0, bit_magic::l1BP(sigma)+1); for (size_t i=0; i<sa.size(); i++) text[i] = char2comp[str[i]]; unsigned char *bwt = new unsigned char[n+1]; { /* Calculate Burrows-Wheeler-Transform */ size_t i = 0; for(int_vector<>::const_iterator it = sa.begin(), end = sa.end(); it != end; ++it, ++i){ bwt[i] = m_char2comp[str[(*it+n)%(n+1)]]; } } occ = Occ(bwt, n+1, m_sigma); delete[] bwt; }
) ) == 0u ); CHECK( fcppt::range::size( fcppt::iterator::make_range( vec1.begin(), std::next( vec1.begin() ) ) ) == 1u ); CHECK( fcppt::range::size( fcppt::iterator::make_range( vec1.begin(), vec1.end() ) ) == 2u ); }