/*********************************************************************** * Software License Agreement (BSD License) * * Copyright 2008-2009 Marius Muja (mariusm@cs.ubc.ca). All rights reserved. * Copyright 2008-2009 David G. Lowe (lowe@cs.ubc.ca). All rights reserved. * Copyright 2011-2016 Jose Luis Blanco (joseluisblancoc@gmail.com). * All rights reserved. * * THE BSD LICENSE * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. *************************************************************************/ /** \mainpage nanoflann C++ API documentation * nanoflann is a C++ header-only library for building KD-Trees, mostly * optimized for 2D or 3D point clouds. * * nanoflann does not require compiling or installing, just an * #include in your code. * * See: * - C++ API organized by modules * - Online README * - Doxygen * documentation */ #ifndef NANOFLANN_HPP_ #define NANOFLANN_HPP_ #include #include #include #include // for abs() #include // for fwrite() #include // for abs() #include #include // std::reference_wrapper #include #include /** Library version: 0xMmP (M=Major,m=minor,P=patch) */ #define NANOFLANN_VERSION 0x132 // Avoid conflicting declaration of min/max macros in windows headers #if !defined(NOMINMAX) && \ (defined(_WIN32) || defined(_WIN32_) || defined(WIN32) || defined(_WIN64)) #define NOMINMAX #ifdef max #undef max #undef min #endif #endif namespace nanoflann { /** @addtogroup nanoflann_grp nanoflann C++ library for ANN * @{ */ /** the PI constant (required to avoid MSVC missing symbols) */ template T pi_const() { return static_cast(3.14159265358979323846); } /** * Traits if object is resizable and assignable (typically has a resize | assign * method) */ template struct has_resize : std::false_type {}; template struct has_resize().resize(1), 0)> : std::true_type {}; template struct has_assign : std::false_type {}; template struct has_assign().assign(1, 0), 0)> : std::true_type {}; /** * Free function to resize a resizable object */ template inline typename std::enable_if::value, void>::type resize(Container &c, const size_t nElements) { c.resize(nElements); } /** * Free function that has no effects on non resizable containers (e.g. * std::array) It raises an exception if the expected size does not match */ template inline typename std::enable_if::value, void>::type resize(Container &c, const size_t nElements) { if (nElements != c.size()) throw std::logic_error("Try to change the size of a std::array."); } /** * Free function to assign to a container */ template inline typename std::enable_if::value, void>::type assign(Container &c, const size_t nElements, const T &value) { c.assign(nElements, value); } /** * Free function to assign to a std::array */ template inline typename std::enable_if::value, void>::type assign(Container &c, const size_t nElements, const T &value) { for (size_t i = 0; i < nElements; i++) c[i] = value; } /** @addtogroup result_sets_grp Result set classes * @{ */ template class KNNResultSet { public: typedef _DistanceType DistanceType; typedef _IndexType IndexType; typedef _CountType CountType; private: IndexType *indices; DistanceType *dists; CountType capacity; CountType count; public: inline KNNResultSet(CountType capacity_) : indices(0), dists(0), capacity(capacity_), count(0) {} inline void init(IndexType *indices_, DistanceType *dists_) { indices = indices_; dists = dists_; count = 0; if (capacity) dists[capacity - 1] = (std::numeric_limits::max)(); } inline CountType size() const { return count; } inline bool full() const { return count == capacity; } /** * Called during search to add an element matching the criteria. * @return true if the search should be continued, false if the results are * sufficient */ inline bool addPoint(DistanceType dist, IndexType index) { CountType i; for (i = count; i > 0; --i) { #ifdef NANOFLANN_FIRST_MATCH // If defined and two points have the same // distance, the one with the lowest-index will be // returned first. if ((dists[i - 1] > dist) || ((dist == dists[i - 1]) && (indices[i - 1] > index))) { #else if (dists[i - 1] > dist) { #endif if (i < capacity) { dists[i] = dists[i - 1]; indices[i] = indices[i - 1]; } } else break; } if (i < capacity) { dists[i] = dist; indices[i] = index; } if (count < capacity) count++; // tell caller that the search shall continue return true; } inline DistanceType worstDist() const { return dists[capacity - 1]; } }; /** operator "<" for std::sort() */ struct IndexDist_Sorter { /** PairType will be typically: std::pair */ template inline bool operator()(const PairType &p1, const PairType &p2) const { return p1.second < p2.second; } }; /** * A result-set class used when performing a radius based search. */ template class RadiusResultSet { public: typedef _DistanceType DistanceType; typedef _IndexType IndexType; public: const DistanceType radius; std::vector> &m_indices_dists; inline RadiusResultSet( DistanceType radius_, std::vector> &indices_dists) : radius(radius_), m_indices_dists(indices_dists) { init(); } inline void init() { clear(); } inline void clear() { m_indices_dists.clear(); } inline size_t size() const { return m_indices_dists.size(); } inline bool full() const { return true; } /** * Called during search to add an element matching the criteria. * @return true if the search should be continued, false if the results are * sufficient */ inline bool addPoint(DistanceType dist, IndexType index) { if (dist < radius) m_indices_dists.push_back(std::make_pair(index, dist)); return true; } inline DistanceType worstDist() const { return radius; } /** * Find the worst result (furtherest neighbor) without copying or sorting * Pre-conditions: size() > 0 */ std::pair worst_item() const { if (m_indices_dists.empty()) throw std::runtime_error("Cannot invoke RadiusResultSet::worst_item() on " "an empty list of results."); typedef typename std::vector>::const_iterator DistIt; DistIt it = std::max_element(m_indices_dists.begin(), m_indices_dists.end(), IndexDist_Sorter()); return *it; } }; /** @} */ /** @addtogroup loadsave_grp Load/save auxiliary functions * @{ */ template void save_value(FILE *stream, const T &value, size_t count = 1) { fwrite(&value, sizeof(value), count, stream); } template void save_value(FILE *stream, const std::vector &value) { size_t size = value.size(); fwrite(&size, sizeof(size_t), 1, stream); fwrite(&value[0], sizeof(T), size, stream); } template void load_value(FILE *stream, T &value, size_t count = 1) { size_t read_cnt = fread(&value, sizeof(value), count, stream); if (read_cnt != count) { throw std::runtime_error("Cannot read from file"); } } template void load_value(FILE *stream, std::vector &value) { size_t size; size_t read_cnt = fread(&size, sizeof(size_t), 1, stream); if (read_cnt != 1) { throw std::runtime_error("Cannot read from file"); } value.resize(size); read_cnt = fread(&value[0], sizeof(T), size, stream); if (read_cnt != size) { throw std::runtime_error("Cannot read from file"); } } /** @} */ /** @addtogroup metric_grp Metric (distance) classes * @{ */ struct Metric {}; /** Manhattan distance functor (generic version, optimized for * high-dimensionality data sets). Corresponding distance traits: * nanoflann::metric_L1 \tparam T Type of the elements (e.g. double, float, * uint8_t) \tparam _DistanceType Type of distance variables (must be signed) * (e.g. float, double, int64_t) */ template struct L1_Adaptor { typedef T ElementType; typedef _DistanceType DistanceType; const DataSource &data_source; L1_Adaptor(const DataSource &_data_source) : data_source(_data_source) {} inline DistanceType evalMetric(const T *a, const size_t b_idx, size_t size, DistanceType worst_dist = -1) const { DistanceType result = DistanceType(); const T *last = a + size; const T *lastgroup = last - 3; size_t d = 0; /* Process 4 items with each loop for efficiency. */ while (a < lastgroup) { const DistanceType diff0 = std::abs(a[0] - data_source.kdtree_get_pt(b_idx, d++)); const DistanceType diff1 = std::abs(a[1] - data_source.kdtree_get_pt(b_idx, d++)); const DistanceType diff2 = std::abs(a[2] - data_source.kdtree_get_pt(b_idx, d++)); const DistanceType diff3 = std::abs(a[3] - data_source.kdtree_get_pt(b_idx, d++)); result += diff0 + diff1 + diff2 + diff3; a += 4; if ((worst_dist > 0) && (result > worst_dist)) { return result; } } /* Process last 0-3 components. Not needed for standard vector lengths. */ while (a < last) { result += std::abs(*a++ - data_source.kdtree_get_pt(b_idx, d++)); } return result; } template inline DistanceType accum_dist(const U a, const V b, const size_t) const { return std::abs(a - b); } }; /** Squared Euclidean distance functor (generic version, optimized for * high-dimensionality data sets). Corresponding distance traits: * nanoflann::metric_L2 \tparam T Type of the elements (e.g. double, float, * uint8_t) \tparam _DistanceType Type of distance variables (must be signed) * (e.g. float, double, int64_t) */ template struct L2_Adaptor { typedef T ElementType; typedef _DistanceType DistanceType; const DataSource &data_source; L2_Adaptor(const DataSource &_data_source) : data_source(_data_source) {} inline DistanceType evalMetric(const T *a, const size_t b_idx, size_t size, DistanceType worst_dist = -1) const { DistanceType result = DistanceType(); const T *last = a + size; const T *lastgroup = last - 3; size_t d = 0; /* Process 4 items with each loop for efficiency. */ while (a < lastgroup) { const DistanceType diff0 = a[0] - data_source.kdtree_get_pt(b_idx, d++); const DistanceType diff1 = a[1] - data_source.kdtree_get_pt(b_idx, d++); const DistanceType diff2 = a[2] - data_source.kdtree_get_pt(b_idx, d++); const DistanceType diff3 = a[3] - data_source.kdtree_get_pt(b_idx, d++); result += diff0 * diff0 + diff1 * diff1 + diff2 * diff2 + diff3 * diff3; a += 4; if ((worst_dist > 0) && (result > worst_dist)) { return result; } } /* Process last 0-3 components. Not needed for standard vector lengths. */ while (a < last) { const DistanceType diff0 = *a++ - data_source.kdtree_get_pt(b_idx, d++); result += diff0 * diff0; } return result; } template inline DistanceType accum_dist(const U a, const V b, const size_t) const { return (a - b) * (a - b); } }; /** Squared Euclidean (L2) distance functor (suitable for low-dimensionality * datasets, like 2D or 3D point clouds) Corresponding distance traits: * nanoflann::metric_L2_Simple \tparam T Type of the elements (e.g. double, * float, uint8_t) \tparam _DistanceType Type of distance variables (must be * signed) (e.g. float, double, int64_t) */ template struct L2_Simple_Adaptor { typedef T ElementType; typedef _DistanceType DistanceType; const DataSource &data_source; L2_Simple_Adaptor(const DataSource &_data_source) : data_source(_data_source) {} inline DistanceType evalMetric(const T *a, const size_t b_idx, size_t size) const { DistanceType result = DistanceType(); for (size_t i = 0; i < size; ++i) { const DistanceType diff = a[i] - data_source.kdtree_get_pt(b_idx, i); result += diff * diff; } return result; } template inline DistanceType accum_dist(const U a, const V b, const size_t) const { return (a - b) * (a - b); } }; /** SO2 distance functor * Corresponding distance traits: nanoflann::metric_SO2 * \tparam T Type of the elements (e.g. double, float) * \tparam _DistanceType Type of distance variables (must be signed) (e.g. * float, double) orientation is constrained to be in [-pi, pi] */ template struct SO2_Adaptor { typedef T ElementType; typedef _DistanceType DistanceType; const DataSource &data_source; SO2_Adaptor(const DataSource &_data_source) : data_source(_data_source) {} inline DistanceType evalMetric(const T *a, const size_t b_idx, size_t size) const { return accum_dist(a[size - 1], data_source.kdtree_get_pt(b_idx, size - 1), size - 1); } /** Note: this assumes that input angles are already in the range [-pi,pi] */ template inline DistanceType accum_dist(const U a, const V b, const size_t) const { DistanceType result = DistanceType(); DistanceType PI = pi_const(); result = b - a; if (result > PI) result -= 2 * PI; else if (result < -PI) result += 2 * PI; return result; } }; /** SO3 distance functor (Uses L2_Simple) * Corresponding distance traits: nanoflann::metric_SO3 * \tparam T Type of the elements (e.g. double, float) * \tparam _DistanceType Type of distance variables (must be signed) (e.g. * float, double) */ template struct SO3_Adaptor { typedef T ElementType; typedef _DistanceType DistanceType; L2_Simple_Adaptor distance_L2_Simple; SO3_Adaptor(const DataSource &_data_source) : distance_L2_Simple(_data_source) {} inline DistanceType evalMetric(const T *a, const size_t b_idx, size_t size) const { return distance_L2_Simple.evalMetric(a, b_idx, size); } template inline DistanceType accum_dist(const U a, const V b, const size_t idx) const { return distance_L2_Simple.accum_dist(a, b, idx); } }; /** Metaprogramming helper traits class for the L1 (Manhattan) metric */ struct metric_L1 : public Metric { template struct traits { typedef L1_Adaptor distance_t; }; }; /** Metaprogramming helper traits class for the L2 (Euclidean) metric */ struct metric_L2 : public Metric { template struct traits { typedef L2_Adaptor distance_t; }; }; /** Metaprogramming helper traits class for the L2_simple (Euclidean) metric */ struct metric_L2_Simple : public Metric { template struct traits { typedef L2_Simple_Adaptor distance_t; }; }; /** Metaprogramming helper traits class for the SO3_InnerProdQuat metric */ struct metric_SO2 : public Metric { template struct traits { typedef SO2_Adaptor distance_t; }; }; /** Metaprogramming helper traits class for the SO3_InnerProdQuat metric */ struct metric_SO3 : public Metric { template struct traits { typedef SO3_Adaptor distance_t; }; }; /** @} */ /** @addtogroup param_grp Parameter structs * @{ */ /** Parameters (see README.md) */ struct KDTreeSingleIndexAdaptorParams { KDTreeSingleIndexAdaptorParams(size_t _leaf_max_size = 10) : leaf_max_size(_leaf_max_size) {} size_t leaf_max_size; }; /** Search options for KDTreeSingleIndexAdaptor::findNeighbors() */ struct SearchParams { /** Note: The first argument (checks_IGNORED_) is ignored, but kept for * compatibility with the FLANN interface */ SearchParams(int checks_IGNORED_ = 32, float eps_ = 0, bool sorted_ = true) : checks(checks_IGNORED_), eps(eps_), sorted(sorted_) {} int checks; //!< Ignored parameter (Kept for compatibility with the FLANN //!< interface). float eps; //!< search for eps-approximate neighbours (default: 0) bool sorted; //!< only for radius search, require neighbours sorted by //!< distance (default: true) }; /** @} */ /** @addtogroup memalloc_grp Memory allocation * @{ */ /** * Allocates (using C's malloc) a generic type T. * * Params: * count = number of instances to allocate. * Returns: pointer (of type T*) to memory buffer */ template inline T *allocate(size_t count = 1) { T *mem = static_cast(::malloc(sizeof(T) * count)); return mem; } /** * Pooled storage allocator * * The following routines allow for the efficient allocation of storage in * small chunks from a specified pool. Rather than allowing each structure * to be freed individually, an entire pool of storage is freed at once. * This method has two advantages over just using malloc() and free(). First, * it is far more efficient for allocating small objects, as there is * no overhead for remembering all the information needed to free each * object or consolidating fragmented memory. Second, the decision about * how long to keep an object is made at the time of allocation, and there * is no need to track down all the objects to free them. * */ const size_t WORDSIZE = 16; const size_t BLOCKSIZE = 8192; class PooledAllocator { /* We maintain memory alignment to word boundaries by requiring that all allocations be in multiples of the machine wordsize. */ /* Size of machine word in bytes. Must be power of 2. */ /* Minimum number of bytes requested at a time from the system. Must be * multiple of WORDSIZE. */ size_t remaining; /* Number of bytes left in current block of storage. */ void *base; /* Pointer to base of current block of storage. */ void *loc; /* Current location in block to next allocate memory. */ void internal_init() { remaining = 0; base = NULL; usedMemory = 0; wastedMemory = 0; } public: size_t usedMemory; size_t wastedMemory; /** Default constructor. Initializes a new pool. */ PooledAllocator() { internal_init(); } /** * Destructor. Frees all the memory allocated in this pool. */ ~PooledAllocator() { free_all(); } /** Frees all allocated memory chunks */ void free_all() { while (base != NULL) { void *prev = *(static_cast(base)); /* Get pointer to prev block. */ ::free(base); base = prev; } internal_init(); } /** * Returns a pointer to a piece of new memory of the given size in bytes * allocated from the pool. */ void *malloc(const size_t req_size) { /* Round size up to a multiple of wordsize. The following expression only works for WORDSIZE that is a power of 2, by masking last bits of incremented size to zero. */ const size_t size = (req_size + (WORDSIZE - 1)) & ~(WORDSIZE - 1); /* Check whether a new block must be allocated. Note that the first word of a block is reserved for a pointer to the previous block. */ if (size > remaining) { wastedMemory += remaining; /* Allocate new storage. */ const size_t blocksize = (size + sizeof(void *) + (WORDSIZE - 1) > BLOCKSIZE) ? size + sizeof(void *) + (WORDSIZE - 1) : BLOCKSIZE; // use the standard C malloc to allocate memory void *m = ::malloc(blocksize); if (!m) { fprintf(stderr, "Failed to allocate memory.\n"); return NULL; } /* Fill first word of new block with pointer to previous block. */ static_cast(m)[0] = base; base = m; size_t shift = 0; // int size_t = (WORDSIZE - ( (((size_t)m) + sizeof(void*)) & // (WORDSIZE-1))) & (WORDSIZE-1); remaining = blocksize - sizeof(void *) - shift; loc = (static_cast(m) + sizeof(void *) + shift); } void *rloc = loc; loc = static_cast(loc) + size; remaining -= size; usedMemory += size; return rloc; } /** * Allocates (using this pool) a generic type T. * * Params: * count = number of instances to allocate. * Returns: pointer (of type T*) to memory buffer */ template T *allocate(const size_t count = 1) { T *mem = static_cast(this->malloc(sizeof(T) * count)); return mem; } }; /** @} */ /** @addtogroup nanoflann_metaprog_grp Auxiliary metaprogramming stuff * @{ */ /** Used to declare fixed-size arrays when DIM>0, dynamically-allocated vectors * when DIM=-1. Fixed size version for a generic DIM: */ template struct array_or_vector_selector { typedef std::array container_t; }; /** Dynamic size version */ template struct array_or_vector_selector<-1, T> { typedef std::vector container_t; }; /** @} */ /** kd-tree base-class * * Contains the member functions common to the classes KDTreeSingleIndexAdaptor * and KDTreeSingleIndexDynamicAdaptor_. * * \tparam Derived The name of the class which inherits this class. * \tparam DatasetAdaptor The user-provided adaptor (see comments above). * \tparam Distance The distance metric to use, these are all classes derived * from nanoflann::Metric \tparam DIM Dimensionality of data points (e.g. 3 for * 3D points) \tparam IndexType Will be typically size_t or int */ template class KDTreeBaseClass { public: /** Frees the previously-built index. Automatically called within * buildIndex(). */ void freeIndex(Derived &obj) { obj.pool.free_all(); obj.root_node = NULL; obj.m_size_at_index_build = 0; } typedef typename Distance::ElementType ElementType; typedef typename Distance::DistanceType DistanceType; /*--------------------- Internal Data Structures --------------------------*/ struct Node { /** Union used because a node can be either a LEAF node or a non-leaf node, * so both data fields are never used simultaneously */ union { struct leaf { IndexType left, right; //!< Indices of points in leaf node } lr; struct nonleaf { int divfeat; //!< Dimension used for subdivision. DistanceType divlow, divhigh; //!< The values used for subdivision. } sub; } node_type; Node *child1, *child2; //!< Child nodes (both=NULL mean its a leaf node) }; typedef Node *NodePtr; struct Interval { ElementType low, high; }; /** * Array of indices to vectors in the dataset. */ std::vector vind; NodePtr root_node; size_t m_leaf_max_size; size_t m_size; //!< Number of current points in the dataset size_t m_size_at_index_build; //!< Number of points in the dataset when the //!< index was built int dim; //!< Dimensionality of each data point /** Define "BoundingBox" as a fixed-size or variable-size container depending * on "DIM" */ typedef typename array_or_vector_selector::container_t BoundingBox; /** Define "distance_vector_t" as a fixed-size or variable-size container * depending on "DIM" */ typedef typename array_or_vector_selector::container_t distance_vector_t; /** The KD-tree used to find neighbours */ BoundingBox root_bbox; /** * Pooled memory allocator. * * Using a pooled memory allocator is more efficient * than allocating memory directly when there is a large * number small of memory allocations. */ PooledAllocator pool; /** Returns number of points in dataset */ size_t size(const Derived &obj) const { return obj.m_size; } /** Returns the length of each point in the dataset */ size_t veclen(const Derived &obj) { return static_cast(DIM > 0 ? DIM : obj.dim); } /// Helper accessor to the dataset points: inline ElementType dataset_get(const Derived &obj, size_t idx, int component) const { return obj.dataset.kdtree_get_pt(idx, component); } /** * Computes the inde memory usage * Returns: memory used by the index */ size_t usedMemory(Derived &obj) { return obj.pool.usedMemory + obj.pool.wastedMemory + obj.dataset.kdtree_get_point_count() * sizeof(IndexType); // pool memory and vind array memory } void computeMinMax(const Derived &obj, IndexType *ind, IndexType count, int element, ElementType &min_elem, ElementType &max_elem) { min_elem = dataset_get(obj, ind[0], element); max_elem = dataset_get(obj, ind[0], element); for (IndexType i = 1; i < count; ++i) { ElementType val = dataset_get(obj, ind[i], element); if (val < min_elem) min_elem = val; if (val > max_elem) max_elem = val; } } /** * Create a tree node that subdivides the list of vecs from vind[first] * to vind[last]. The routine is called recursively on each sublist. * * @param left index of the first vector * @param right index of the last vector */ NodePtr divideTree(Derived &obj, const IndexType left, const IndexType right, BoundingBox &bbox) { NodePtr node = obj.pool.template allocate(); // allocate memory /* If too few exemplars remain, then make this a leaf node. */ if ((right - left) <= static_cast(obj.m_leaf_max_size)) { node->child1 = node->child2 = NULL; /* Mark as leaf node. */ node->node_type.lr.left = left; node->node_type.lr.right = right; // compute bounding-box of leaf points for (int i = 0; i < (DIM > 0 ? DIM : obj.dim); ++i) { bbox[i].low = dataset_get(obj, obj.vind[left], i); bbox[i].high = dataset_get(obj, obj.vind[left], i); } for (IndexType k = left + 1; k < right; ++k) { for (int i = 0; i < (DIM > 0 ? DIM : obj.dim); ++i) { if (bbox[i].low > dataset_get(obj, obj.vind[k], i)) bbox[i].low = dataset_get(obj, obj.vind[k], i); if (bbox[i].high < dataset_get(obj, obj.vind[k], i)) bbox[i].high = dataset_get(obj, obj.vind[k], i); } } } else { IndexType idx; int cutfeat; DistanceType cutval; middleSplit_(obj, &obj.vind[0] + left, right - left, idx, cutfeat, cutval, bbox); node->node_type.sub.divfeat = cutfeat; BoundingBox left_bbox(bbox); left_bbox[cutfeat].high = cutval; node->child1 = divideTree(obj, left, left + idx, left_bbox); BoundingBox right_bbox(bbox); right_bbox[cutfeat].low = cutval; node->child2 = divideTree(obj, left + idx, right, right_bbox); node->node_type.sub.divlow = left_bbox[cutfeat].high; node->node_type.sub.divhigh = right_bbox[cutfeat].low; for (int i = 0; i < (DIM > 0 ? DIM : obj.dim); ++i) { bbox[i].low = std::min(left_bbox[i].low, right_bbox[i].low); bbox[i].high = std::max(left_bbox[i].high, right_bbox[i].high); } } return node; } void middleSplit_(Derived &obj, IndexType *ind, IndexType count, IndexType &index, int &cutfeat, DistanceType &cutval, const BoundingBox &bbox) { const DistanceType EPS = static_cast(0.00001); ElementType max_span = bbox[0].high - bbox[0].low; for (int i = 1; i < (DIM > 0 ? DIM : obj.dim); ++i) { ElementType span = bbox[i].high - bbox[i].low; if (span > max_span) { max_span = span; } } ElementType max_spread = -1; cutfeat = 0; for (int i = 0; i < (DIM > 0 ? DIM : obj.dim); ++i) { ElementType span = bbox[i].high - bbox[i].low; if (span > (1 - EPS) * max_span) { ElementType min_elem, max_elem; computeMinMax(obj, ind, count, i, min_elem, max_elem); ElementType spread = max_elem - min_elem; ; if (spread > max_spread) { cutfeat = i; max_spread = spread; } } } // split in the middle DistanceType split_val = (bbox[cutfeat].low + bbox[cutfeat].high) / 2; ElementType min_elem, max_elem; computeMinMax(obj, ind, count, cutfeat, min_elem, max_elem); if (split_val < min_elem) cutval = min_elem; else if (split_val > max_elem) cutval = max_elem; else cutval = split_val; IndexType lim1, lim2; planeSplit(obj, ind, count, cutfeat, cutval, lim1, lim2); if (lim1 > count / 2) index = lim1; else if (lim2 < count / 2) index = lim2; else index = count / 2; } /** * Subdivide the list of points by a plane perpendicular on axe corresponding * to the 'cutfeat' dimension at 'cutval' position. * * On return: * dataset[ind[0..lim1-1]][cutfeat]cutval */ void planeSplit(Derived &obj, IndexType *ind, const IndexType count, int cutfeat, DistanceType &cutval, IndexType &lim1, IndexType &lim2) { /* Move vector indices for left subtree to front of list. */ IndexType left = 0; IndexType right = count - 1; for (;;) { while (left <= right && dataset_get(obj, ind[left], cutfeat) < cutval) ++left; while (right && left <= right && dataset_get(obj, ind[right], cutfeat) >= cutval) --right; if (left > right || !right) break; // "!right" was added to support unsigned Index types std::swap(ind[left], ind[right]); ++left; --right; } /* If either list is empty, it means that all remaining features * are identical. Split in the middle to maintain a balanced tree. */ lim1 = left; right = count - 1; for (;;) { while (left <= right && dataset_get(obj, ind[left], cutfeat) <= cutval) ++left; while (right && left <= right && dataset_get(obj, ind[right], cutfeat) > cutval) --right; if (left > right || !right) break; // "!right" was added to support unsigned Index types std::swap(ind[left], ind[right]); ++left; --right; } lim2 = left; } DistanceType computeInitialDistances(const Derived &obj, const ElementType *vec, distance_vector_t &dists) const { assert(vec); DistanceType distsq = DistanceType(); for (int i = 0; i < (DIM > 0 ? DIM : obj.dim); ++i) { if (vec[i] < obj.root_bbox[i].low) { dists[i] = obj.distance.accum_dist(vec[i], obj.root_bbox[i].low, i); distsq += dists[i]; } if (vec[i] > obj.root_bbox[i].high) { dists[i] = obj.distance.accum_dist(vec[i], obj.root_bbox[i].high, i); distsq += dists[i]; } } return distsq; } void save_tree(Derived &obj, FILE *stream, NodePtr tree) { save_value(stream, *tree); if (tree->child1 != NULL) { save_tree(obj, stream, tree->child1); } if (tree->child2 != NULL) { save_tree(obj, stream, tree->child2); } } void load_tree(Derived &obj, FILE *stream, NodePtr &tree) { tree = obj.pool.template allocate(); load_value(stream, *tree); if (tree->child1 != NULL) { load_tree(obj, stream, tree->child1); } if (tree->child2 != NULL) { load_tree(obj, stream, tree->child2); } } /** Stores the index in a binary file. * IMPORTANT NOTE: The set of data points is NOT stored in the file, so when * loading the index object it must be constructed associated to the same * source of data points used while building it. See the example: * examples/saveload_example.cpp \sa loadIndex */ void saveIndex_(Derived &obj, FILE *stream) { save_value(stream, obj.m_size); save_value(stream, obj.dim); save_value(stream, obj.root_bbox); save_value(stream, obj.m_leaf_max_size); save_value(stream, obj.vind); save_tree(obj, stream, obj.root_node); } /** Loads a previous index from a binary file. * IMPORTANT NOTE: The set of data points is NOT stored in the file, so the * index object must be constructed associated to the same source of data * points used while building the index. See the example: * examples/saveload_example.cpp \sa loadIndex */ void loadIndex_(Derived &obj, FILE *stream) { load_value(stream, obj.m_size); load_value(stream, obj.dim); load_value(stream, obj.root_bbox); load_value(stream, obj.m_leaf_max_size); load_value(stream, obj.vind); load_tree(obj, stream, obj.root_node); } }; /** @addtogroup kdtrees_grp KD-tree classes and adaptors * @{ */ /** kd-tree static index * * Contains the k-d trees and other information for indexing a set of points * for nearest-neighbor matching. * * The class "DatasetAdaptor" must provide the following interface (can be * non-virtual, inlined methods): * * \code * // Must return the number of data poins * inline size_t kdtree_get_point_count() const { ... } * * * // Must return the dim'th component of the idx'th point in the class: * inline T kdtree_get_pt(const size_t idx, const size_t dim) const { ... } * * // Optional bounding-box computation: return false to default to a standard * bbox computation loop. * // Return true if the BBOX was already computed by the class and returned * in "bb" so it can be avoided to redo it again. * // Look at bb.size() to find out the expected dimensionality (e.g. 2 or 3 * for point clouds) template bool kdtree_get_bbox(BBOX &bb) const * { * bb[0].low = ...; bb[0].high = ...; // 0th dimension limits * bb[1].low = ...; bb[1].high = ...; // 1st dimension limits * ... * return true; * } * * \endcode * * \tparam DatasetAdaptor The user-provided adaptor (see comments above). * \tparam Distance The distance metric to use: nanoflann::metric_L1, * nanoflann::metric_L2, nanoflann::metric_L2_Simple, etc. \tparam DIM * Dimensionality of data points (e.g. 3 for 3D points) \tparam IndexType Will * be typically size_t or int */ template class KDTreeSingleIndexAdaptor : public KDTreeBaseClass< KDTreeSingleIndexAdaptor, Distance, DatasetAdaptor, DIM, IndexType> { public: /** Deleted copy constructor*/ KDTreeSingleIndexAdaptor( const KDTreeSingleIndexAdaptor &) = delete; /** * The dataset used by this index */ const DatasetAdaptor &dataset; //!< The source of our data const KDTreeSingleIndexAdaptorParams index_params; Distance distance; typedef typename nanoflann::KDTreeBaseClass< nanoflann::KDTreeSingleIndexAdaptor, Distance, DatasetAdaptor, DIM, IndexType> BaseClassRef; typedef typename BaseClassRef::ElementType ElementType; typedef typename BaseClassRef::DistanceType DistanceType; typedef typename BaseClassRef::Node Node; typedef Node *NodePtr; typedef typename BaseClassRef::Interval Interval; /** Define "BoundingBox" as a fixed-size or variable-size container depending * on "DIM" */ typedef typename BaseClassRef::BoundingBox BoundingBox; /** Define "distance_vector_t" as a fixed-size or variable-size container * depending on "DIM" */ typedef typename BaseClassRef::distance_vector_t distance_vector_t; /** * KDTree constructor * * Refer to docs in README.md or online in * https://github.com/jlblancoc/nanoflann * * The KD-Tree point dimension (the length of each point in the datase, e.g. 3 * for 3D points) is determined by means of: * - The \a DIM template parameter if >0 (highest priority) * - Otherwise, the \a dimensionality parameter of this constructor. * * @param inputData Dataset with the input features * @param params Basically, the maximum leaf node size */ KDTreeSingleIndexAdaptor(const int dimensionality, const DatasetAdaptor &inputData, const KDTreeSingleIndexAdaptorParams ¶ms = KDTreeSingleIndexAdaptorParams()) : dataset(inputData), index_params(params), distance(inputData) { BaseClassRef::root_node = NULL; BaseClassRef::m_size = dataset.kdtree_get_point_count(); BaseClassRef::m_size_at_index_build = BaseClassRef::m_size; BaseClassRef::dim = dimensionality; if (DIM > 0) BaseClassRef::dim = DIM; BaseClassRef::m_leaf_max_size = params.leaf_max_size; // Create a permutable array of indices to the input vectors. init_vind(); } /** * Builds the index */ void buildIndex() { BaseClassRef::m_size = dataset.kdtree_get_point_count(); BaseClassRef::m_size_at_index_build = BaseClassRef::m_size; init_vind(); this->freeIndex(*this); BaseClassRef::m_size_at_index_build = BaseClassRef::m_size; if (BaseClassRef::m_size == 0) return; computeBoundingBox(BaseClassRef::root_bbox); BaseClassRef::root_node = this->divideTree(*this, 0, BaseClassRef::m_size, BaseClassRef::root_bbox); // construct the tree } /** \name Query methods * @{ */ /** * Find set of nearest neighbors to vec[0:dim-1]. Their indices are stored * inside the result object. * * Params: * result = the result object in which the indices of the * nearest-neighbors are stored vec = the vector for which to search the * nearest neighbors * * \tparam RESULTSET Should be any ResultSet * \return True if the requested neighbors could be found. * \sa knnSearch, radiusSearch */ template bool findNeighbors(RESULTSET &result, const ElementType *vec, const SearchParams &searchParams) const { assert(vec); if (this->size(*this) == 0) return false; if (!BaseClassRef::root_node) throw std::runtime_error( "[nanoflann] findNeighbors() called before building the index."); float epsError = 1 + searchParams.eps; distance_vector_t dists; // fixed or variable-sized container (depending on DIM) auto zero = static_cast(0); assign(dists, (DIM > 0 ? DIM : BaseClassRef::dim), zero); // Fill it with zeros. DistanceType distsq = this->computeInitialDistances(*this, vec, dists); searchLevel(result, vec, BaseClassRef::root_node, distsq, dists, epsError); // "count_leaf" parameter removed since was neither // used nor returned to the user. return result.full(); } /** * Find the "num_closest" nearest neighbors to the \a query_point[0:dim-1]. * Their indices are stored inside the result object. \sa radiusSearch, * findNeighbors \note nChecks_IGNORED is ignored but kept for compatibility * with the original FLANN interface. \return Number `N` of valid points in * the result set. Only the first `N` entries in `out_indices` and * `out_distances_sq` will be valid. Return may be less than `num_closest` * only if the number of elements in the tree is less than `num_closest`. */ size_t knnSearch(const ElementType *query_point, const size_t num_closest, IndexType *out_indices, DistanceType *out_distances_sq, const int /* nChecks_IGNORED */ = 10) const { nanoflann::KNNResultSet resultSet(num_closest); resultSet.init(out_indices, out_distances_sq); this->findNeighbors(resultSet, query_point, nanoflann::SearchParams()); return resultSet.size(); } /** * Find all the neighbors to \a query_point[0:dim-1] within a maximum radius. * The output is given as a vector of pairs, of which the first element is a * point index and the second the corresponding distance. Previous contents of * \a IndicesDists are cleared. * * If searchParams.sorted==true, the output list is sorted by ascending * distances. * * For a better performance, it is advisable to do a .reserve() on the vector * if you have any wild guess about the number of expected matches. * * \sa knnSearch, findNeighbors, radiusSearchCustomCallback * \return The number of points within the given radius (i.e. indices.size() * or dists.size() ) */ size_t radiusSearch(const ElementType *query_point, const DistanceType &radius, std::vector> &IndicesDists, const SearchParams &searchParams) const { RadiusResultSet resultSet(radius, IndicesDists); const size_t nFound = radiusSearchCustomCallback(query_point, resultSet, searchParams); if (searchParams.sorted) std::sort(IndicesDists.begin(), IndicesDists.end(), IndexDist_Sorter()); return nFound; } /** * Just like radiusSearch() but with a custom callback class for each point * found in the radius of the query. See the source of RadiusResultSet<> as a * start point for your own classes. \sa radiusSearch */ template size_t radiusSearchCustomCallback( const ElementType *query_point, SEARCH_CALLBACK &resultSet, const SearchParams &searchParams = SearchParams()) const { this->findNeighbors(resultSet, query_point, searchParams); return resultSet.size(); } /** @} */ public: /** Make sure the auxiliary list \a vind has the same size than the current * dataset, and re-generate if size has changed. */ void init_vind() { // Create a permutable array of indices to the input vectors. BaseClassRef::m_size = dataset.kdtree_get_point_count(); if (BaseClassRef::vind.size() != BaseClassRef::m_size) BaseClassRef::vind.resize(BaseClassRef::m_size); for (size_t i = 0; i < BaseClassRef::m_size; i++) BaseClassRef::vind[i] = i; } void computeBoundingBox(BoundingBox &bbox) { resize(bbox, (DIM > 0 ? DIM : BaseClassRef::dim)); if (dataset.kdtree_get_bbox(bbox)) { // Done! It was implemented in derived class } else { const size_t N = dataset.kdtree_get_point_count(); if (!N) throw std::runtime_error("[nanoflann] computeBoundingBox() called but " "no data points found."); for (int i = 0; i < (DIM > 0 ? DIM : BaseClassRef::dim); ++i) { bbox[i].low = bbox[i].high = this->dataset_get(*this, 0, i); } for (size_t k = 1; k < N; ++k) { for (int i = 0; i < (DIM > 0 ? DIM : BaseClassRef::dim); ++i) { if (this->dataset_get(*this, k, i) < bbox[i].low) bbox[i].low = this->dataset_get(*this, k, i); if (this->dataset_get(*this, k, i) > bbox[i].high) bbox[i].high = this->dataset_get(*this, k, i); } } } } /** * Performs an exact search in the tree starting from a node. * \tparam RESULTSET Should be any ResultSet * \return true if the search should be continued, false if the results are * sufficient */ template bool searchLevel(RESULTSET &result_set, const ElementType *vec, const NodePtr node, DistanceType mindistsq, distance_vector_t &dists, const float epsError) const { /* If this is a leaf node, then do check and return. */ if ((node->child1 == NULL) && (node->child2 == NULL)) { // count_leaf += (node->lr.right-node->lr.left); // Removed since was // neither used nor returned to the user. DistanceType worst_dist = result_set.worstDist(); for (IndexType i = node->node_type.lr.left; i < node->node_type.lr.right; ++i) { const IndexType index = BaseClassRef::vind[i]; // reorder... : i; DistanceType dist = distance.evalMetric( vec, index, (DIM > 0 ? DIM : BaseClassRef::dim)); if (dist < worst_dist) { if (!result_set.addPoint(dist, BaseClassRef::vind[i])) { // the resultset doesn't want to receive any more points, we're done // searching! return false; } } } return true; } /* Which child branch should be taken first? */ int idx = node->node_type.sub.divfeat; ElementType val = vec[idx]; DistanceType diff1 = val - node->node_type.sub.divlow; DistanceType diff2 = val - node->node_type.sub.divhigh; NodePtr bestChild; NodePtr otherChild; DistanceType cut_dist; if ((diff1 + diff2) < 0) { bestChild = node->child1; otherChild = node->child2; cut_dist = distance.accum_dist(val, node->node_type.sub.divhigh, idx); } else { bestChild = node->child2; otherChild = node->child1; cut_dist = distance.accum_dist(val, node->node_type.sub.divlow, idx); } /* Call recursively to search next level down. */ if (!searchLevel(result_set, vec, bestChild, mindistsq, dists, epsError)) { // the resultset doesn't want to receive any more points, we're done // searching! return false; } DistanceType dst = dists[idx]; mindistsq = mindistsq + cut_dist - dst; dists[idx] = cut_dist; if (mindistsq * epsError <= result_set.worstDist()) { if (!searchLevel(result_set, vec, otherChild, mindistsq, dists, epsError)) { // the resultset doesn't want to receive any more points, we're done // searching! return false; } } dists[idx] = dst; return true; } public: /** Stores the index in a binary file. * IMPORTANT NOTE: The set of data points is NOT stored in the file, so when * loading the index object it must be constructed associated to the same * source of data points used while building it. See the example: * examples/saveload_example.cpp \sa loadIndex */ void saveIndex(FILE *stream) { this->saveIndex_(*this, stream); } /** Loads a previous index from a binary file. * IMPORTANT NOTE: The set of data points is NOT stored in the file, so the * index object must be constructed associated to the same source of data * points used while building the index. See the example: * examples/saveload_example.cpp \sa loadIndex */ void loadIndex(FILE *stream) { this->loadIndex_(*this, stream); } }; // class KDTree /** kd-tree dynamic index * * Contains the k-d trees and other information for indexing a set of points * for nearest-neighbor matching. * * The class "DatasetAdaptor" must provide the following interface (can be * non-virtual, inlined methods): * * \code * // Must return the number of data poins * inline size_t kdtree_get_point_count() const { ... } * * // Must return the dim'th component of the idx'th point in the class: * inline T kdtree_get_pt(const size_t idx, const size_t dim) const { ... } * * // Optional bounding-box computation: return false to default to a standard * bbox computation loop. * // Return true if the BBOX was already computed by the class and returned * in "bb" so it can be avoided to redo it again. * // Look at bb.size() to find out the expected dimensionality (e.g. 2 or 3 * for point clouds) template bool kdtree_get_bbox(BBOX &bb) const * { * bb[0].low = ...; bb[0].high = ...; // 0th dimension limits * bb[1].low = ...; bb[1].high = ...; // 1st dimension limits * ... * return true; * } * * \endcode * * \tparam DatasetAdaptor The user-provided adaptor (see comments above). * \tparam Distance The distance metric to use: nanoflann::metric_L1, * nanoflann::metric_L2, nanoflann::metric_L2_Simple, etc. \tparam DIM * Dimensionality of data points (e.g. 3 for 3D points) \tparam IndexType Will * be typically size_t or int */ template class KDTreeSingleIndexDynamicAdaptor_ : public KDTreeBaseClass, Distance, DatasetAdaptor, DIM, IndexType> { public: /** * The dataset used by this index */ const DatasetAdaptor &dataset; //!< The source of our data KDTreeSingleIndexAdaptorParams index_params; std::vector &treeIndex; Distance distance; typedef typename nanoflann::KDTreeBaseClass< nanoflann::KDTreeSingleIndexDynamicAdaptor_, Distance, DatasetAdaptor, DIM, IndexType> BaseClassRef; typedef typename BaseClassRef::ElementType ElementType; typedef typename BaseClassRef::DistanceType DistanceType; typedef typename BaseClassRef::Node Node; typedef Node *NodePtr; typedef typename BaseClassRef::Interval Interval; /** Define "BoundingBox" as a fixed-size or variable-size container depending * on "DIM" */ typedef typename BaseClassRef::BoundingBox BoundingBox; /** Define "distance_vector_t" as a fixed-size or variable-size container * depending on "DIM" */ typedef typename BaseClassRef::distance_vector_t distance_vector_t; /** * KDTree constructor * * Refer to docs in README.md or online in * https://github.com/jlblancoc/nanoflann * * The KD-Tree point dimension (the length of each point in the datase, e.g. 3 * for 3D points) is determined by means of: * - The \a DIM template parameter if >0 (highest priority) * - Otherwise, the \a dimensionality parameter of this constructor. * * @param inputData Dataset with the input features * @param params Basically, the maximum leaf node size */ KDTreeSingleIndexDynamicAdaptor_( const int dimensionality, const DatasetAdaptor &inputData, std::vector &treeIndex_, const KDTreeSingleIndexAdaptorParams ¶ms = KDTreeSingleIndexAdaptorParams()) : dataset(inputData), index_params(params), treeIndex(treeIndex_), distance(inputData) { BaseClassRef::root_node = NULL; BaseClassRef::m_size = 0; BaseClassRef::m_size_at_index_build = 0; BaseClassRef::dim = dimensionality; if (DIM > 0) BaseClassRef::dim = DIM; BaseClassRef::m_leaf_max_size = params.leaf_max_size; } /** Assignment operator definiton */ KDTreeSingleIndexDynamicAdaptor_ operator=(const KDTreeSingleIndexDynamicAdaptor_ &rhs) { KDTreeSingleIndexDynamicAdaptor_ tmp(rhs); std::swap(BaseClassRef::vind, tmp.BaseClassRef::vind); std::swap(BaseClassRef::m_leaf_max_size, tmp.BaseClassRef::m_leaf_max_size); std::swap(index_params, tmp.index_params); std::swap(treeIndex, tmp.treeIndex); std::swap(BaseClassRef::m_size, tmp.BaseClassRef::m_size); std::swap(BaseClassRef::m_size_at_index_build, tmp.BaseClassRef::m_size_at_index_build); std::swap(BaseClassRef::root_node, tmp.BaseClassRef::root_node); std::swap(BaseClassRef::root_bbox, tmp.BaseClassRef::root_bbox); std::swap(BaseClassRef::pool, tmp.BaseClassRef::pool); return *this; } /** * Builds the index */ void buildIndex() { BaseClassRef::m_size = BaseClassRef::vind.size(); this->freeIndex(*this); BaseClassRef::m_size_at_index_build = BaseClassRef::m_size; if (BaseClassRef::m_size == 0) return; computeBoundingBox(BaseClassRef::root_bbox); BaseClassRef::root_node = this->divideTree(*this, 0, BaseClassRef::m_size, BaseClassRef::root_bbox); // construct the tree } /** \name Query methods * @{ */ /** * Find set of nearest neighbors to vec[0:dim-1]. Their indices are stored * inside the result object. * * Params: * result = the result object in which the indices of the * nearest-neighbors are stored vec = the vector for which to search the * nearest neighbors * * \tparam RESULTSET Should be any ResultSet * \return True if the requested neighbors could be found. * \sa knnSearch, radiusSearch */ template bool findNeighbors(RESULTSET &result, const ElementType *vec, const SearchParams &searchParams) const { assert(vec); if (this->size(*this) == 0) return false; if (!BaseClassRef::root_node) return false; float epsError = 1 + searchParams.eps; // fixed or variable-sized container (depending on DIM) distance_vector_t dists; // Fill it with zeros. assign(dists, (DIM > 0 ? DIM : BaseClassRef::dim), static_cast(0)); DistanceType distsq = this->computeInitialDistances(*this, vec, dists); searchLevel(result, vec, BaseClassRef::root_node, distsq, dists, epsError); // "count_leaf" parameter removed since was neither // used nor returned to the user. return result.full(); } /** * Find the "num_closest" nearest neighbors to the \a query_point[0:dim-1]. * Their indices are stored inside the result object. \sa radiusSearch, * findNeighbors \note nChecks_IGNORED is ignored but kept for compatibility * with the original FLANN interface. \return Number `N` of valid points in * the result set. Only the first `N` entries in `out_indices` and * `out_distances_sq` will be valid. Return may be less than `num_closest` * only if the number of elements in the tree is less than `num_closest`. */ size_t knnSearch(const ElementType *query_point, const size_t num_closest, IndexType *out_indices, DistanceType *out_distances_sq, const int /* nChecks_IGNORED */ = 10) const { nanoflann::KNNResultSet resultSet(num_closest); resultSet.init(out_indices, out_distances_sq); this->findNeighbors(resultSet, query_point, nanoflann::SearchParams()); return resultSet.size(); } /** * Find all the neighbors to \a query_point[0:dim-1] within a maximum radius. * The output is given as a vector of pairs, of which the first element is a * point index and the second the corresponding distance. Previous contents of * \a IndicesDists are cleared. * * If searchParams.sorted==true, the output list is sorted by ascending * distances. * * For a better performance, it is advisable to do a .reserve() on the vector * if you have any wild guess about the number of expected matches. * * \sa knnSearch, findNeighbors, radiusSearchCustomCallback * \return The number of points within the given radius (i.e. indices.size() * or dists.size() ) */ size_t radiusSearch(const ElementType *query_point, const DistanceType &radius, std::vector> &IndicesDists, const SearchParams &searchParams) const { RadiusResultSet resultSet(radius, IndicesDists); const size_t nFound = radiusSearchCustomCallback(query_point, resultSet, searchParams); if (searchParams.sorted) std::sort(IndicesDists.begin(), IndicesDists.end(), IndexDist_Sorter()); return nFound; } /** * Just like radiusSearch() but with a custom callback class for each point * found in the radius of the query. See the source of RadiusResultSet<> as a * start point for your own classes. \sa radiusSearch */ template size_t radiusSearchCustomCallback( const ElementType *query_point, SEARCH_CALLBACK &resultSet, const SearchParams &searchParams = SearchParams()) const { this->findNeighbors(resultSet, query_point, searchParams); return resultSet.size(); } /** @} */ public: void computeBoundingBox(BoundingBox &bbox) { resize(bbox, (DIM > 0 ? DIM : BaseClassRef::dim)); if (dataset.kdtree_get_bbox(bbox)) { // Done! It was implemented in derived class } else { const size_t N = BaseClassRef::m_size; if (!N) throw std::runtime_error("[nanoflann] computeBoundingBox() called but " "no data points found."); for (int i = 0; i < (DIM > 0 ? DIM : BaseClassRef::dim); ++i) { bbox[i].low = bbox[i].high = this->dataset_get(*this, BaseClassRef::vind[0], i); } for (size_t k = 1; k < N; ++k) { for (int i = 0; i < (DIM > 0 ? DIM : BaseClassRef::dim); ++i) { if (this->dataset_get(*this, BaseClassRef::vind[k], i) < bbox[i].low) bbox[i].low = this->dataset_get(*this, BaseClassRef::vind[k], i); if (this->dataset_get(*this, BaseClassRef::vind[k], i) > bbox[i].high) bbox[i].high = this->dataset_get(*this, BaseClassRef::vind[k], i); } } } } /** * Performs an exact search in the tree starting from a node. * \tparam RESULTSET Should be any ResultSet */ template void searchLevel(RESULTSET &result_set, const ElementType *vec, const NodePtr node, DistanceType mindistsq, distance_vector_t &dists, const float epsError) const { /* If this is a leaf node, then do check and return. */ if ((node->child1 == NULL) && (node->child2 == NULL)) { // count_leaf += (node->lr.right-node->lr.left); // Removed since was // neither used nor returned to the user. DistanceType worst_dist = result_set.worstDist(); for (IndexType i = node->node_type.lr.left; i < node->node_type.lr.right; ++i) { const IndexType index = BaseClassRef::vind[i]; // reorder... : i; if (treeIndex[index] == -1) continue; DistanceType dist = distance.evalMetric( vec, index, (DIM > 0 ? DIM : BaseClassRef::dim)); if (dist < worst_dist) { if (!result_set.addPoint( static_cast(dist), static_cast( BaseClassRef::vind[i]))) { // the resultset doesn't want to receive any more points, we're done // searching! return; // false; } } } return; } /* Which child branch should be taken first? */ int idx = node->node_type.sub.divfeat; ElementType val = vec[idx]; DistanceType diff1 = val - node->node_type.sub.divlow; DistanceType diff2 = val - node->node_type.sub.divhigh; NodePtr bestChild; NodePtr otherChild; DistanceType cut_dist; if ((diff1 + diff2) < 0) { bestChild = node->child1; otherChild = node->child2; cut_dist = distance.accum_dist(val, node->node_type.sub.divhigh, idx); } else { bestChild = node->child2; otherChild = node->child1; cut_dist = distance.accum_dist(val, node->node_type.sub.divlow, idx); } /* Call recursively to search next level down. */ searchLevel(result_set, vec, bestChild, mindistsq, dists, epsError); DistanceType dst = dists[idx]; mindistsq = mindistsq + cut_dist - dst; dists[idx] = cut_dist; if (mindistsq * epsError <= result_set.worstDist()) { searchLevel(result_set, vec, otherChild, mindistsq, dists, epsError); } dists[idx] = dst; } public: /** Stores the index in a binary file. * IMPORTANT NOTE: The set of data points is NOT stored in the file, so when * loading the index object it must be constructed associated to the same * source of data points used while building it. See the example: * examples/saveload_example.cpp \sa loadIndex */ void saveIndex(FILE *stream) { this->saveIndex_(*this, stream); } /** Loads a previous index from a binary file. * IMPORTANT NOTE: The set of data points is NOT stored in the file, so the * index object must be constructed associated to the same source of data * points used while building the index. See the example: * examples/saveload_example.cpp \sa loadIndex */ void loadIndex(FILE *stream) { this->loadIndex_(*this, stream); } }; /** kd-tree dynaimic index * * class to create multiple static index and merge their results to behave as * single dynamic index as proposed in Logarithmic Approach. * * Example of usage: * examples/dynamic_pointcloud_example.cpp * * \tparam DatasetAdaptor The user-provided adaptor (see comments above). * \tparam Distance The distance metric to use: nanoflann::metric_L1, * nanoflann::metric_L2, nanoflann::metric_L2_Simple, etc. \tparam DIM * Dimensionality of data points (e.g. 3 for 3D points) \tparam IndexType Will * be typically size_t or int */ template class KDTreeSingleIndexDynamicAdaptor { public: typedef typename Distance::ElementType ElementType; typedef typename Distance::DistanceType DistanceType; protected: size_t m_leaf_max_size; size_t treeCount; size_t pointCount; /** * The dataset used by this index */ const DatasetAdaptor &dataset; //!< The source of our data std::vector treeIndex; //!< treeIndex[idx] is the index of tree in which //!< point at idx is stored. treeIndex[idx]=-1 //!< means that point has been removed. KDTreeSingleIndexAdaptorParams index_params; int dim; //!< Dimensionality of each data point typedef KDTreeSingleIndexDynamicAdaptor_ index_container_t; std::vector index; public: /** Get a const ref to the internal list of indices; the number of indices is * adapted dynamically as the dataset grows in size. */ const std::vector &getAllIndices() const { return index; } private: /** finds position of least significant unset bit */ int First0Bit(IndexType num) { int pos = 0; while (num & 1) { num = num >> 1; pos++; } return pos; } /** Creates multiple empty trees to handle dynamic support */ void init() { typedef KDTreeSingleIndexDynamicAdaptor_ my_kd_tree_t; std::vector index_( treeCount, my_kd_tree_t(dim /*dim*/, dataset, treeIndex, index_params)); index = index_; } public: Distance distance; /** * KDTree constructor * * Refer to docs in README.md or online in * https://github.com/jlblancoc/nanoflann * * The KD-Tree point dimension (the length of each point in the datase, e.g. 3 * for 3D points) is determined by means of: * - The \a DIM template parameter if >0 (highest priority) * - Otherwise, the \a dimensionality parameter of this constructor. * * @param inputData Dataset with the input features * @param params Basically, the maximum leaf node size */ KDTreeSingleIndexDynamicAdaptor(const int dimensionality, const DatasetAdaptor &inputData, const KDTreeSingleIndexAdaptorParams ¶ms = KDTreeSingleIndexAdaptorParams(), const size_t maximumPointCount = 1000000000U) : dataset(inputData), index_params(params), distance(inputData) { treeCount = static_cast(std::log2(maximumPointCount)); pointCount = 0U; dim = dimensionality; treeIndex.clear(); if (DIM > 0) dim = DIM; m_leaf_max_size = params.leaf_max_size; init(); const size_t num_initial_points = dataset.kdtree_get_point_count(); if (num_initial_points > 0) { addPoints(0, num_initial_points - 1); } } /** Deleted copy constructor*/ KDTreeSingleIndexDynamicAdaptor( const KDTreeSingleIndexDynamicAdaptor &) = delete; /** Add points to the set, Inserts all points from [start, end] */ void addPoints(IndexType start, IndexType end) { size_t count = end - start + 1; treeIndex.resize(treeIndex.size() + count); for (IndexType idx = start; idx <= end; idx++) { int pos = First0Bit(pointCount); index[pos].vind.clear(); treeIndex[pointCount] = pos; for (int i = 0; i < pos; i++) { for (int j = 0; j < static_cast(index[i].vind.size()); j++) { index[pos].vind.push_back(index[i].vind[j]); if (treeIndex[index[i].vind[j]] != -1) treeIndex[index[i].vind[j]] = pos; } index[i].vind.clear(); index[i].freeIndex(index[i]); } index[pos].vind.push_back(idx); index[pos].buildIndex(); pointCount++; } } /** Remove a point from the set (Lazy Deletion) */ void removePoint(size_t idx) { if (idx >= pointCount) return; treeIndex[idx] = -1; } /** * Find set of nearest neighbors to vec[0:dim-1]. Their indices are stored * inside the result object. * * Params: * result = the result object in which the indices of the * nearest-neighbors are stored vec = the vector for which to search the * nearest neighbors * * \tparam RESULTSET Should be any ResultSet * \return True if the requested neighbors could be found. * \sa knnSearch, radiusSearch */ template bool findNeighbors(RESULTSET &result, const ElementType *vec, const SearchParams &searchParams) const { for (size_t i = 0; i < treeCount; i++) { index[i].findNeighbors(result, &vec[0], searchParams); } return result.full(); } }; /** An L2-metric KD-tree adaptor for working with data directly stored in an * Eigen Matrix, without duplicating the data storage. Each row in the matrix * represents a point in the state space. * * Example of usage: * \code * Eigen::Matrix mat; * // Fill out "mat"... * * typedef KDTreeEigenMatrixAdaptor< Eigen::Matrix > * my_kd_tree_t; const int max_leaf = 10; my_kd_tree_t mat_index(mat, max_leaf * ); mat_index.index->buildIndex(); mat_index.index->... \endcode * * \tparam DIM If set to >0, it specifies a compile-time fixed dimensionality * for the points in the data set, allowing more compiler optimizations. \tparam * Distance The distance metric to use: nanoflann::metric_L1, * nanoflann::metric_L2, nanoflann::metric_L2_Simple, etc. */ template struct KDTreeEigenMatrixAdaptor { typedef KDTreeEigenMatrixAdaptor self_t; typedef typename MatrixType::Scalar num_t; typedef typename MatrixType::Index IndexType; typedef typename Distance::template traits::distance_t metric_t; typedef KDTreeSingleIndexAdaptor index_t; index_t *index; //! The kd-tree index for the user to call its methods as //! usual with any other FLANN index. /// Constructor: takes a const ref to the matrix object with the data points KDTreeEigenMatrixAdaptor(const size_t dimensionality, const std::reference_wrapper &mat, const int leaf_max_size = 10) : m_data_matrix(mat) { const auto dims = mat.get().cols(); if (size_t(dims) != dimensionality) throw std::runtime_error( "Error: 'dimensionality' must match column count in data matrix"); if (DIM > 0 && int(dims) != DIM) throw std::runtime_error( "Data set dimensionality does not match the 'DIM' template argument"); index = new index_t(static_cast(dims), *this /* adaptor */, nanoflann::KDTreeSingleIndexAdaptorParams(leaf_max_size)); index->buildIndex(); } public: /** Deleted copy constructor */ KDTreeEigenMatrixAdaptor(const self_t &) = delete; ~KDTreeEigenMatrixAdaptor() { delete index; } const std::reference_wrapper m_data_matrix; /** Query for the \a num_closest closest points to a given point (entered as * query_point[0:dim-1]). Note that this is a short-cut method for * index->findNeighbors(). The user can also call index->... methods as * desired. \note nChecks_IGNORED is ignored but kept for compatibility with * the original FLANN interface. */ inline void query(const num_t *query_point, const size_t num_closest, IndexType *out_indices, num_t *out_distances_sq, const int /* nChecks_IGNORED */ = 10) const { nanoflann::KNNResultSet resultSet(num_closest); resultSet.init(out_indices, out_distances_sq); index->findNeighbors(resultSet, query_point, nanoflann::SearchParams()); } /** @name Interface expected by KDTreeSingleIndexAdaptor * @{ */ const self_t &derived() const { return *this; } self_t &derived() { return *this; } // Must return the number of data points inline size_t kdtree_get_point_count() const { return m_data_matrix.get().rows(); } // Returns the dim'th component of the idx'th point in the class: inline num_t kdtree_get_pt(const IndexType idx, size_t dim) const { return m_data_matrix.get().coeff(idx, IndexType(dim)); } // Optional bounding-box computation: return false to default to a standard // bbox computation loop. // Return true if the BBOX was already computed by the class and returned in // "bb" so it can be avoided to redo it again. Look at bb.size() to find out // the expected dimensionality (e.g. 2 or 3 for point clouds) template bool kdtree_get_bbox(BBOX & /*bb*/) const { return false; } /** @} */ }; // end of KDTreeEigenMatrixAdaptor /** @} */ /** @} */ // end of grouping } // namespace nanoflann #endif /* NANOFLANN_HPP_ */