// Copyright (c) 2005, Google Inc. // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * 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. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "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 COPYRIGHT // OWNER OR CONTRIBUTORS 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. // --- // // A sparse hashtable is a particular implementation of // a hashtable: one that is meant to minimize memory use. // It does this by using a *sparse table* (cf sparsetable.h), // which uses between 1 and 2 bits to store empty buckets // (we may need another bit for hashtables that support deletion). // // When empty buckets are so cheap, an appealing hashtable // implementation is internal probing, in which the hashtable // is a single table, and collisions are resolved by trying // to insert again in another bucket. The most cache-efficient // internal probing schemes are linear probing (which suffers, // alas, from clumping) and quadratic probing, which is what // we implement by default. // // Deleted buckets are a bit of a pain. We have to somehow mark // deleted buckets (the probing must distinguish them from empty // buckets). The most principled way is to have another bitmap, // but that's annoying and takes up space. Instead we let the // user specify an "impossible" key. We set deleted buckets // to have the impossible key. // // Note it is possible to change the value of the delete key // on the fly; you can even remove it, though after that point // the hashtable is insert_only until you set it again. // // You probably shouldn't use this code directly. Use // sparse_hash_map<> or sparse_hash_set<> instead. // // You can modify the following, below: // HT_OCCUPANCY_PCT -- how full before we double size // HT_EMPTY_PCT -- how empty before we halve size // HT_MIN_BUCKETS -- smallest bucket size // HT_DEFAULT_STARTING_BUCKETS -- default bucket size at construct-time // // You can also change enlarge_factor (which defaults to // HT_OCCUPANCY_PCT), and shrink_factor (which defaults to // HT_EMPTY_PCT) with set_resizing_parameters(). // // How to decide what values to use? // shrink_factor's default of .4 * OCCUPANCY_PCT, is probably good. // HT_MIN_BUCKETS is probably unnecessary since you can specify // (indirectly) the starting number of buckets at construct-time. // For enlarge_factor, you can use this chart to try to trade-off // expected lookup time to the space taken up. By default, this // code uses quadratic probing, though you can change it to linear // via _JUMP below if you really want to. // // From http://www.augustana.ca/~mohrj/courses/1999.fall/csc210/lecture_notes/hashing.html // NUMBER OF PROBES / LOOKUP Successful Unsuccessful // Quadratic collision resolution 1 - ln(1-L) - L/2 1/(1-L) - L - ln(1-L) // Linear collision resolution [1+1/(1-L)]/2 [1+1/(1-L)2]/2 // // -- enlarge_factor -- 0.10 0.50 0.60 0.75 0.80 0.90 0.99 // QUADRATIC COLLISION RES. // probes/successful lookup 1.05 1.44 1.62 2.01 2.21 2.85 5.11 // probes/unsuccessful lookup 1.11 2.19 2.82 4.64 5.81 11.4 103.6 // LINEAR COLLISION RES. // probes/successful lookup 1.06 1.5 1.75 2.5 3.0 5.5 50.5 // probes/unsuccessful lookup 1.12 2.5 3.6 8.5 13.0 50.0 5000.0 // // The value type is required to be copy constructible and default // constructible, but it need not be (and commonly isn't) assignable. #ifndef _SPARSEHASHTABLE_H_ #define _SPARSEHASHTABLE_H_ #include #include #include // For swap(), eg #include // for iterator tags #include // for numeric_limits #include // for pair #include // for remove_const #include #include // IWYU pragma: export #include // For length_error _START_GOOGLE_NAMESPACE_ namespace base { // just to make google->opensource transition easier using GOOGLE_NAMESPACE::remove_const; } #ifndef SPARSEHASH_STAT_UPDATE #define SPARSEHASH_STAT_UPDATE(x) ((void) 0) #endif // The probing method // Linear probing // #define JUMP_(key, num_probes) ( 1 ) // Quadratic probing #define JUMP_(key, num_probes) ( num_probes ) // The smaller this is, the faster lookup is (because the group bitmap is // smaller) and the faster insert is, because there's less to move. // On the other hand, there are more groups. Since group::size_type is // a short, this number should be of the form 32*x + 16 to avoid waste. static const u_int16_t DEFAULT_GROUP_SIZE = 48; // fits in 1.5 words // Hashtable class, used to implement the hashed associative containers // hash_set and hash_map. // // Value: what is stored in the table (each bucket is a Value). // Key: something in a 1-to-1 correspondence to a Value, that can be used // to search for a Value in the table (find() takes a Key). // HashFcn: Takes a Key and returns an integer, the more unique the better. // ExtractKey: given a Value, returns the unique Key associated with it. // Must inherit from unary_function, or at least have a // result_type enum indicating the return type of operator(). // SetKey: given a Value* and a Key, modifies the value such that // ExtractKey(value) == key. We guarantee this is only called // with key == deleted_key. // EqualKey: Given two Keys, says whether they are the same (that is, // if they are both associated with the same Value). // Alloc: STL allocator to use to allocate memory. template class sparse_hashtable; template struct sparse_hashtable_iterator; template struct sparse_hashtable_const_iterator; // As far as iterating, we're basically just a sparsetable // that skips over deleted elements. template struct sparse_hashtable_iterator { private: typedef typename A::template rebind::other value_alloc_type; public: typedef sparse_hashtable_iterator iterator; typedef sparse_hashtable_const_iterator const_iterator; typedef typename sparsetable::nonempty_iterator st_iterator; typedef std::forward_iterator_tag iterator_category; // very little defined! typedef V value_type; typedef typename value_alloc_type::difference_type difference_type; typedef typename value_alloc_type::size_type size_type; typedef typename value_alloc_type::reference reference; typedef typename value_alloc_type::pointer pointer; // "Real" constructor and default constructor sparse_hashtable_iterator(const sparse_hashtable *h, st_iterator it, st_iterator it_end) : ht(h), pos(it), end(it_end) { advance_past_deleted(); } sparse_hashtable_iterator() { } // not ever used internally // The default destructor is fine; we don't define one // The default operator= is fine; we don't define one // Happy dereferencer reference operator*() const { return *pos; } pointer operator->() const { return &(operator*()); } // Arithmetic. The only hard part is making sure that // we're not on a marked-deleted array element void advance_past_deleted() { while ( pos != end && ht->test_deleted(*this) ) ++pos; } iterator& operator++() { assert(pos != end); ++pos; advance_past_deleted(); return *this; } iterator operator++(int) { iterator tmp(*this); ++*this; return tmp; } // Comparison. bool operator==(const iterator& it) const { return pos == it.pos; } bool operator!=(const iterator& it) const { return pos != it.pos; } // The actual data const sparse_hashtable *ht; st_iterator pos, end; }; // Now do it all again, but with const-ness! template struct sparse_hashtable_const_iterator { private: typedef typename A::template rebind::other value_alloc_type; public: typedef sparse_hashtable_iterator iterator; typedef sparse_hashtable_const_iterator const_iterator; typedef typename sparsetable::const_nonempty_iterator st_iterator; typedef std::forward_iterator_tag iterator_category; // very little defined! typedef V value_type; typedef typename value_alloc_type::difference_type difference_type; typedef typename value_alloc_type::size_type size_type; typedef typename value_alloc_type::const_reference reference; typedef typename value_alloc_type::const_pointer pointer; // "Real" constructor and default constructor sparse_hashtable_const_iterator(const sparse_hashtable *h, st_iterator it, st_iterator it_end) : ht(h), pos(it), end(it_end) { advance_past_deleted(); } // This lets us convert regular iterators to const iterators sparse_hashtable_const_iterator() { } // never used internally sparse_hashtable_const_iterator(const iterator &it) : ht(it.ht), pos(it.pos), end(it.end) { } // The default destructor is fine; we don't define one // The default operator= is fine; we don't define one // Happy dereferencer reference operator*() const { return *pos; } pointer operator->() const { return &(operator*()); } // Arithmetic. The only hard part is making sure that // we're not on a marked-deleted array element void advance_past_deleted() { while ( pos != end && ht->test_deleted(*this) ) ++pos; } const_iterator& operator++() { assert(pos != end); ++pos; advance_past_deleted(); return *this; } const_iterator operator++(int) { const_iterator tmp(*this); ++*this; return tmp; } // Comparison. bool operator==(const const_iterator& it) const { return pos == it.pos; } bool operator!=(const const_iterator& it) const { return pos != it.pos; } // The actual data const sparse_hashtable *ht; st_iterator pos, end; }; // And once again, but this time freeing up memory as we iterate template struct sparse_hashtable_destructive_iterator { private: typedef typename A::template rebind::other value_alloc_type; public: typedef sparse_hashtable_destructive_iterator iterator; typedef typename sparsetable::destructive_iterator st_iterator; typedef std::forward_iterator_tag iterator_category; // very little defined! typedef V value_type; typedef typename value_alloc_type::difference_type difference_type; typedef typename value_alloc_type::size_type size_type; typedef typename value_alloc_type::reference reference; typedef typename value_alloc_type::pointer pointer; // "Real" constructor and default constructor sparse_hashtable_destructive_iterator(const sparse_hashtable *h, st_iterator it, st_iterator it_end) : ht(h), pos(it), end(it_end) { advance_past_deleted(); } sparse_hashtable_destructive_iterator() { } // never used internally // The default destructor is fine; we don't define one // The default operator= is fine; we don't define one // Happy dereferencer reference operator*() const { return *pos; } pointer operator->() const { return &(operator*()); } // Arithmetic. The only hard part is making sure that // we're not on a marked-deleted array element void advance_past_deleted() { while ( pos != end && ht->test_deleted(*this) ) ++pos; } iterator& operator++() { assert(pos != end); ++pos; advance_past_deleted(); return *this; } iterator operator++(int) { iterator tmp(*this); ++*this; return tmp; } // Comparison. bool operator==(const iterator& it) const { return pos == it.pos; } bool operator!=(const iterator& it) const { return pos != it.pos; } // The actual data const sparse_hashtable *ht; st_iterator pos, end; }; template class sparse_hashtable { private: typedef typename Alloc::template rebind::other value_alloc_type; public: typedef Key key_type; typedef Value value_type; typedef HashFcn hasher; typedef EqualKey key_equal; typedef Alloc allocator_type; typedef typename value_alloc_type::size_type size_type; typedef typename value_alloc_type::difference_type difference_type; typedef typename value_alloc_type::reference reference; typedef typename value_alloc_type::const_reference const_reference; typedef typename value_alloc_type::pointer pointer; typedef typename value_alloc_type::const_pointer const_pointer; typedef sparse_hashtable_iterator iterator; typedef sparse_hashtable_const_iterator const_iterator; typedef sparse_hashtable_destructive_iterator destructive_iterator; // These come from tr1. For us they're the same as regular iterators. typedef iterator local_iterator; typedef const_iterator const_local_iterator; // How full we let the table get before we resize, by default. // Knuth says .8 is good -- higher causes us to probe too much, // though it saves memory. static const int HT_OCCUPANCY_PCT; // = 80 (out of 100); // How empty we let the table get before we resize lower, by default. // (0.0 means never resize lower.) // It should be less than OCCUPANCY_PCT / 2 or we thrash resizing static const int HT_EMPTY_PCT; // = 0.4 * HT_OCCUPANCY_PCT; // Minimum size we're willing to let hashtables be. // Must be a power of two, and at least 4. // Note, however, that for a given hashtable, the initial size is a // function of the first constructor arg, and may be >HT_MIN_BUCKETS. static const size_type HT_MIN_BUCKETS = 4; // By default, if you don't specify a hashtable size at // construction-time, we use this size. Must be a power of two, and // at least HT_MIN_BUCKETS. static const size_type HT_DEFAULT_STARTING_BUCKETS = 32; // ITERATOR FUNCTIONS iterator begin() { return iterator(this, table.nonempty_begin(), table.nonempty_end()); } iterator end() { return iterator(this, table.nonempty_end(), table.nonempty_end()); } const_iterator begin() const { return const_iterator(this, table.nonempty_begin(), table.nonempty_end()); } const_iterator end() const { return const_iterator(this, table.nonempty_end(), table.nonempty_end()); } // These come from tr1 unordered_map. They iterate over 'bucket' n. // For sparsehashtable, we could consider each 'group' to be a bucket, // I guess, but I don't really see the point. We'll just consider // bucket n to be the n-th element of the sparsetable, if it's occupied, // or some empty element, otherwise. local_iterator begin(size_type i) { if (table.test(i)) return local_iterator(this, table.get_iter(i), table.nonempty_end()); else return local_iterator(this, table.nonempty_end(), table.nonempty_end()); } local_iterator end(size_type i) { local_iterator it = begin(i); if (table.test(i) && !test_deleted(i)) ++it; return it; } const_local_iterator begin(size_type i) const { if (table.test(i)) return const_local_iterator(this, table.get_iter(i), table.nonempty_end()); else return const_local_iterator(this, table.nonempty_end(), table.nonempty_end()); } const_local_iterator end(size_type i) const { const_local_iterator it = begin(i); if (table.test(i) && !test_deleted(i)) ++it; return it; } // This is used when resizing destructive_iterator destructive_begin() { return destructive_iterator(this, table.destructive_begin(), table.destructive_end()); } destructive_iterator destructive_end() { return destructive_iterator(this, table.destructive_end(), table.destructive_end()); } // ACCESSOR FUNCTIONS for the things we templatize on, basically hasher hash_funct() const { return settings; } key_equal key_eq() const { return key_info; } allocator_type get_allocator() const { return table.get_allocator(); } // Accessor function for statistics gathering. int num_table_copies() const { return settings.num_ht_copies(); } private: // We need to copy values when we set the special marker for deleted // elements, but, annoyingly, we can't just use the copy assignment // operator because value_type might not be assignable (it's often // pair). We use explicit destructor invocation and // placement new to get around this. Arg. void set_value(pointer dst, const_reference src) { dst->~value_type(); // delete the old value, if any new(dst) value_type(src); } // This is used as a tag for the copy constructor, saying to destroy its // arg We have two ways of destructively copying: with potentially growing // the hashtable as we copy, and without. To make sure the outside world // can't do a destructive copy, we make the typename private. enum MoveDontCopyT {MoveDontCopy, MoveDontGrow}; // DELETE HELPER FUNCTIONS // This lets the user describe a key that will indicate deleted // table entries. This key should be an "impossible" entry -- // if you try to insert it for real, you won't be able to retrieve it! // (NB: while you pass in an entire value, only the key part is looked // at. This is just because I don't know how to assign just a key.) private: void squash_deleted() { // gets rid of any deleted entries we have if ( num_deleted ) { // get rid of deleted before writing sparse_hashtable tmp(MoveDontGrow, *this); swap(tmp); // now we are tmp } assert(num_deleted == 0); } // Test if the given key is the deleted indicator. Requires // num_deleted > 0, for correctness of read(), and because that // guarantees that key_info.delkey is valid. bool test_deleted_key(const key_type& key) const { assert(num_deleted > 0); return equals(key_info.delkey, key); } public: void set_deleted_key(const key_type &key) { // It's only safe to change what "deleted" means if we purge deleted guys squash_deleted(); settings.set_use_deleted(true); key_info.delkey = key; } void clear_deleted_key() { squash_deleted(); settings.set_use_deleted(false); } key_type deleted_key() const { assert(settings.use_deleted() && "Must set deleted key before calling deleted_key"); return key_info.delkey; } // These are public so the iterators can use them // True if the item at position bucknum is "deleted" marker bool test_deleted(size_type bucknum) const { // Invariant: !use_deleted() implies num_deleted is 0. assert(settings.use_deleted() || num_deleted == 0); return num_deleted > 0 && table.test(bucknum) && test_deleted_key(get_key(table.unsafe_get(bucknum))); } bool test_deleted(const iterator &it) const { // Invariant: !use_deleted() implies num_deleted is 0. assert(settings.use_deleted() || num_deleted == 0); return num_deleted > 0 && test_deleted_key(get_key(*it)); } bool test_deleted(const const_iterator &it) const { // Invariant: !use_deleted() implies num_deleted is 0. assert(settings.use_deleted() || num_deleted == 0); return num_deleted > 0 && test_deleted_key(get_key(*it)); } bool test_deleted(const destructive_iterator &it) const { // Invariant: !use_deleted() implies num_deleted is 0. assert(settings.use_deleted() || num_deleted == 0); return num_deleted > 0 && test_deleted_key(get_key(*it)); } private: void check_use_deleted(const char* caller) { (void)caller; // could log it if the assert failed assert(settings.use_deleted()); } // Set it so test_deleted is true. true if object didn't used to be deleted. // TODO(csilvers): make these private (also in densehashtable.h) bool set_deleted(iterator &it) { check_use_deleted("set_deleted()"); bool retval = !test_deleted(it); // &* converts from iterator to value-type. set_key(&(*it), key_info.delkey); return retval; } // Set it so test_deleted is false. true if object used to be deleted. bool clear_deleted(iterator &it) { check_use_deleted("clear_deleted()"); // Happens automatically when we assign something else in its place. return test_deleted(it); } // We also allow to set/clear the deleted bit on a const iterator. // We allow a const_iterator for the same reason you can delete a // const pointer: it's convenient, and semantically you can't use // 'it' after it's been deleted anyway, so its const-ness doesn't // really matter. bool set_deleted(const_iterator &it) { check_use_deleted("set_deleted()"); bool retval = !test_deleted(it); set_key(const_cast(&(*it)), key_info.delkey); return retval; } // Set it so test_deleted is false. true if object used to be deleted. bool clear_deleted(const_iterator &it) { check_use_deleted("clear_deleted()"); return test_deleted(it); } // FUNCTIONS CONCERNING SIZE public: size_type size() const { return table.num_nonempty() - num_deleted; } size_type max_size() const { return table.max_size(); } bool empty() const { return size() == 0; } size_type bucket_count() const { return table.size(); } size_type max_bucket_count() const { return max_size(); } // These are tr1 methods. Their idea of 'bucket' doesn't map well to // what we do. We just say every bucket has 0 or 1 items in it. size_type bucket_size(size_type i) const { return begin(i) == end(i) ? 0 : 1; } private: // Because of the above, size_type(-1) is never legal; use it for errors static const size_type ILLEGAL_BUCKET = size_type(-1); // Used after a string of deletes. Returns true if we actually shrunk. // TODO(csilvers): take a delta so we can take into account inserts // done after shrinking. Maybe make part of the Settings class? bool maybe_shrink() { assert(table.num_nonempty() >= num_deleted); assert((bucket_count() & (bucket_count()-1)) == 0); // is a power of two assert(bucket_count() >= HT_MIN_BUCKETS); bool retval = false; // If you construct a hashtable with < HT_DEFAULT_STARTING_BUCKETS, // we'll never shrink until you get relatively big, and we'll never // shrink below HT_DEFAULT_STARTING_BUCKETS. Otherwise, something // like "dense_hash_set x; x.insert(4); x.erase(4);" will // shrink us down to HT_MIN_BUCKETS buckets, which is too small. const size_type num_remain = table.num_nonempty() - num_deleted; const size_type shrink_threshold = settings.shrink_threshold(); if (shrink_threshold > 0 && num_remain < shrink_threshold && bucket_count() > HT_DEFAULT_STARTING_BUCKETS) { const float shrink_factor = settings.shrink_factor(); size_type sz = bucket_count() / 2; // find how much we should shrink while (sz > HT_DEFAULT_STARTING_BUCKETS && num_remain < static_cast(sz * shrink_factor)) { sz /= 2; // stay a power of 2 } sparse_hashtable tmp(MoveDontCopy, *this, sz); swap(tmp); // now we are tmp retval = true; } settings.set_consider_shrink(false); // because we just considered it return retval; } // We'll let you resize a hashtable -- though this makes us copy all! // When you resize, you say, "make it big enough for this many more elements" // Returns true if we actually resized, false if size was already ok. bool resize_delta(size_type delta) { bool did_resize = false; if ( settings.consider_shrink() ) { // see if lots of deletes happened if ( maybe_shrink() ) did_resize = true; } if (table.num_nonempty() >= (std::numeric_limits::max)() - delta) { throw std::length_error("resize overflow"); } if ( bucket_count() >= HT_MIN_BUCKETS && (table.num_nonempty() + delta) <= settings.enlarge_threshold() ) return did_resize; // we're ok as we are // Sometimes, we need to resize just to get rid of all the // "deleted" buckets that are clogging up the hashtable. So when // deciding whether to resize, count the deleted buckets (which // are currently taking up room). But later, when we decide what // size to resize to, *don't* count deleted buckets, since they // get discarded during the resize. const size_type needed_size = settings.min_buckets(table.num_nonempty() + delta, 0); if ( needed_size <= bucket_count() ) // we have enough buckets return did_resize; size_type resize_to = settings.min_buckets(table.num_nonempty() - num_deleted + delta, bucket_count()); if (resize_to < needed_size && // may double resize_to resize_to < (std::numeric_limits::max)() / 2) { // This situation means that we have enough deleted elements, // that once we purge them, we won't actually have needed to // grow. But we may want to grow anyway: if we just purge one // element, say, we'll have to grow anyway next time we // insert. Might as well grow now, since we're already going // through the trouble of copying (in order to purge the // deleted elements). const size_type target = static_cast(settings.shrink_size(resize_to*2)); if (table.num_nonempty() - num_deleted + delta >= target) { // Good, we won't be below the shrink threshhold even if we double. resize_to *= 2; } } sparse_hashtable tmp(MoveDontCopy, *this, resize_to); swap(tmp); // now we are tmp return true; } // Used to actually do the rehashing when we grow/shrink a hashtable void copy_from(const sparse_hashtable &ht, size_type min_buckets_wanted) { clear(); // clear table, set num_deleted to 0 // If we need to change the size of our table, do it now const size_type resize_to = settings.min_buckets(ht.size(), min_buckets_wanted); if ( resize_to > bucket_count() ) { // we don't have enough buckets table.resize(resize_to); // sets the number of buckets settings.reset_thresholds(bucket_count()); } // We use a normal iterator to get non-deleted bcks from ht // We could use insert() here, but since we know there are // no duplicates and no deleted items, we can be more efficient assert((bucket_count() & (bucket_count()-1)) == 0); // a power of two for ( const_iterator it = ht.begin(); it != ht.end(); ++it ) { size_type num_probes = 0; // how many times we've probed size_type bucknum; const size_type bucket_count_minus_one = bucket_count() - 1; for (bucknum = hash(get_key(*it)) & bucket_count_minus_one; table.test(bucknum); // not empty bucknum = (bucknum + JUMP_(key, num_probes)) & bucket_count_minus_one) { ++num_probes; assert(num_probes < bucket_count() && "Hashtable is full: an error in key_equal<> or hash<>"); } table.set(bucknum, *it); // copies the value to here } settings.inc_num_ht_copies(); } // Implementation is like copy_from, but it destroys the table of the // "from" guy by freeing sparsetable memory as we iterate. This is // useful in resizing, since we're throwing away the "from" guy anyway. void move_from(MoveDontCopyT mover, sparse_hashtable &ht, size_type min_buckets_wanted) { clear(); // clear table, set num_deleted to 0 // If we need to change the size of our table, do it now size_type resize_to; if ( mover == MoveDontGrow ) resize_to = ht.bucket_count(); // keep same size as old ht else // MoveDontCopy resize_to = settings.min_buckets(ht.size(), min_buckets_wanted); if ( resize_to > bucket_count() ) { // we don't have enough buckets table.resize(resize_to); // sets the number of buckets settings.reset_thresholds(bucket_count()); } // We use a normal iterator to get non-deleted bcks from ht // We could use insert() here, but since we know there are // no duplicates and no deleted items, we can be more efficient assert( (bucket_count() & (bucket_count()-1)) == 0); // a power of two // THIS IS THE MAJOR LINE THAT DIFFERS FROM COPY_FROM(): for ( destructive_iterator it = ht.destructive_begin(); it != ht.destructive_end(); ++it ) { size_type num_probes = 0; // how many times we've probed size_type bucknum; for ( bucknum = hash(get_key(*it)) & (bucket_count()-1); // h % buck_cnt table.test(bucknum); // not empty bucknum = (bucknum + JUMP_(key, num_probes)) & (bucket_count()-1) ) { ++num_probes; assert(num_probes < bucket_count() && "Hashtable is full: an error in key_equal<> or hash<>"); } table.set(bucknum, *it); // copies the value to here } settings.inc_num_ht_copies(); } // Required by the spec for hashed associative container public: // Though the docs say this should be num_buckets, I think it's much // more useful as num_elements. As a special feature, calling with // req_elements==0 will cause us to shrink if we can, saving space. void resize(size_type req_elements) { // resize to this or larger if ( settings.consider_shrink() || req_elements == 0 ) maybe_shrink(); if ( req_elements > table.num_nonempty() ) // we only grow resize_delta(req_elements - table.num_nonempty()); } // Get and change the value of shrink_factor and enlarge_factor. The // description at the beginning of this file explains how to choose // the values. Setting the shrink parameter to 0.0 ensures that the // table never shrinks. void get_resizing_parameters(float* shrink, float* grow) const { *shrink = settings.shrink_factor(); *grow = settings.enlarge_factor(); } void set_resizing_parameters(float shrink, float grow) { settings.set_resizing_parameters(shrink, grow); settings.reset_thresholds(bucket_count()); } // CONSTRUCTORS -- as required by the specs, we take a size, // but also let you specify a hashfunction, key comparator, // and key extractor. We also define a copy constructor and =. // DESTRUCTOR -- the default is fine, surprisingly. explicit sparse_hashtable(size_type expected_max_items_in_table = 0, const HashFcn& hf = HashFcn(), const EqualKey& eql = EqualKey(), const ExtractKey& ext = ExtractKey(), const SetKey& set = SetKey(), const Alloc& alloc = Alloc()) : settings(hf), key_info(ext, set, eql), num_deleted(0), table((expected_max_items_in_table == 0 ? HT_DEFAULT_STARTING_BUCKETS : settings.min_buckets(expected_max_items_in_table, 0)), alloc) { settings.reset_thresholds(bucket_count()); } // As a convenience for resize(), we allow an optional second argument // which lets you make this new hashtable a different size than ht. // We also provide a mechanism of saying you want to "move" the ht argument // into us instead of copying. sparse_hashtable(const sparse_hashtable& ht, size_type min_buckets_wanted = HT_DEFAULT_STARTING_BUCKETS) : settings(ht.settings), key_info(ht.key_info), num_deleted(0), table(0, ht.get_allocator()) { settings.reset_thresholds(bucket_count()); copy_from(ht, min_buckets_wanted); // copy_from() ignores deleted entries } sparse_hashtable(MoveDontCopyT mover, sparse_hashtable& ht, size_type min_buckets_wanted = HT_DEFAULT_STARTING_BUCKETS) : settings(ht.settings), key_info(ht.key_info), num_deleted(0), table(0, ht.get_allocator()) { settings.reset_thresholds(bucket_count()); move_from(mover, ht, min_buckets_wanted); // ignores deleted entries } sparse_hashtable& operator= (const sparse_hashtable& ht) { if (&ht == this) return *this; // don't copy onto ourselves settings = ht.settings; key_info = ht.key_info; num_deleted = ht.num_deleted; // copy_from() calls clear and sets num_deleted to 0 too copy_from(ht, HT_MIN_BUCKETS); // we purposefully don't copy the allocator, which may not be copyable return *this; } // Many STL algorithms use swap instead of copy constructors void swap(sparse_hashtable& ht) { std::swap(settings, ht.settings); std::swap(key_info, ht.key_info); std::swap(num_deleted, ht.num_deleted); table.swap(ht.table); settings.reset_thresholds(bucket_count()); // also resets consider_shrink ht.settings.reset_thresholds(ht.bucket_count()); // we purposefully don't swap the allocator, which may not be swap-able } // It's always nice to be able to clear a table without deallocating it void clear() { if (!empty() || (num_deleted != 0)) { table.clear(); } settings.reset_thresholds(bucket_count()); num_deleted = 0; } // LOOKUP ROUTINES private: // Returns a pair of positions: 1st where the object is, 2nd where // it would go if you wanted to insert it. 1st is ILLEGAL_BUCKET // if object is not found; 2nd is ILLEGAL_BUCKET if it is. // Note: because of deletions where-to-insert is not trivial: it's the // first deleted bucket we see, as long as we don't find the key later std::pair find_position(const key_type &key) const { size_type num_probes = 0; // how many times we've probed const size_type bucket_count_minus_one = bucket_count() - 1; size_type bucknum = hash(key) & bucket_count_minus_one; size_type insert_pos = ILLEGAL_BUCKET; // where we would insert SPARSEHASH_STAT_UPDATE(total_lookups += 1); while ( 1 ) { // probe until something happens if ( !table.test(bucknum) ) { // bucket is empty SPARSEHASH_STAT_UPDATE(total_probes += num_probes); if ( insert_pos == ILLEGAL_BUCKET ) // found no prior place to insert return std::pair(ILLEGAL_BUCKET, bucknum); else return std::pair(ILLEGAL_BUCKET, insert_pos); } else if ( test_deleted(bucknum) ) {// keep searching, but mark to insert if ( insert_pos == ILLEGAL_BUCKET ) insert_pos = bucknum; } else if ( equals(key, get_key(table.unsafe_get(bucknum))) ) { SPARSEHASH_STAT_UPDATE(total_probes += num_probes); return std::pair(bucknum, ILLEGAL_BUCKET); } ++num_probes; // we're doing another probe bucknum = (bucknum + JUMP_(key, num_probes)) & bucket_count_minus_one; assert(num_probes < bucket_count() && "Hashtable is full: an error in key_equal<> or hash<>"); } } public: iterator find(const key_type& key) { if ( size() == 0 ) return end(); std::pair pos = find_position(key); if ( pos.first == ILLEGAL_BUCKET ) // alas, not there return end(); else return iterator(this, table.get_iter(pos.first), table.nonempty_end()); } const_iterator find(const key_type& key) const { if ( size() == 0 ) return end(); std::pair pos = find_position(key); if ( pos.first == ILLEGAL_BUCKET ) // alas, not there return end(); else return const_iterator(this, table.get_iter(pos.first), table.nonempty_end()); } // This is a tr1 method: the bucket a given key is in, or what bucket // it would be put in, if it were to be inserted. Shrug. size_type bucket(const key_type& key) const { std::pair pos = find_position(key); return pos.first == ILLEGAL_BUCKET ? pos.second : pos.first; } // Counts how many elements have key key. For maps, it's either 0 or 1. size_type count(const key_type &key) const { std::pair pos = find_position(key); return pos.first == ILLEGAL_BUCKET ? 0 : 1; } // Likewise, equal_range doesn't really make sense for us. Oh well. std::pair equal_range(const key_type& key) { iterator pos = find(key); // either an iterator or end if (pos == end()) { return std::pair(pos, pos); } else { const iterator startpos = pos++; return std::pair(startpos, pos); } } std::pair equal_range(const key_type& key) const { const_iterator pos = find(key); // either an iterator or end if (pos == end()) { return std::pair(pos, pos); } else { const const_iterator startpos = pos++; return std::pair(startpos, pos); } } // INSERTION ROUTINES private: // Private method used by insert_noresize and find_or_insert. iterator insert_at(const_reference obj, size_type pos) { if (size() >= max_size()) { throw std::length_error("insert overflow"); } if ( test_deleted(pos) ) { // just replace if it's been deleted // The set() below will undelete this object. We just worry about stats assert(num_deleted > 0); --num_deleted; // used to be, now it isn't } table.set(pos, obj); return iterator(this, table.get_iter(pos), table.nonempty_end()); } // If you know *this is big enough to hold obj, use this routine std::pair insert_noresize(const_reference obj) { // First, double-check we're not inserting delkey assert((!settings.use_deleted() || !equals(get_key(obj), key_info.delkey)) && "Inserting the deleted key"); const std::pair pos = find_position(get_key(obj)); if ( pos.first != ILLEGAL_BUCKET) { // object was already there return std::pair(iterator(this, table.get_iter(pos.first), table.nonempty_end()), false); // false: we didn't insert } else { // pos.second says where to put it return std::pair(insert_at(obj, pos.second), true); } } // Specializations of insert(it, it) depending on the power of the iterator: // (1) Iterator supports operator-, resize before inserting template void insert(ForwardIterator f, ForwardIterator l, std::forward_iterator_tag) { size_t dist = std::distance(f, l); if (dist >= (std::numeric_limits::max)()) { throw std::length_error("insert-range overflow"); } resize_delta(static_cast(dist)); for ( ; dist > 0; --dist, ++f) { insert_noresize(*f); } } // (2) Arbitrary iterator, can't tell how much to resize template void insert(InputIterator f, InputIterator l, std::input_iterator_tag) { for ( ; f != l; ++f) insert(*f); } public: // This is the normal insert routine, used by the outside world std::pair insert(const_reference obj) { resize_delta(1); // adding an object, grow if need be return insert_noresize(obj); } // When inserting a lot at a time, we specialize on the type of iterator template void insert(InputIterator f, InputIterator l) { // specializes on iterator type insert(f, l, typename std::iterator_traits::iterator_category()); } // DefaultValue is a functor that takes a key and returns a value_type // representing the default value to be inserted if none is found. template value_type& find_or_insert(const key_type& key) { // First, double-check we're not inserting delkey assert((!settings.use_deleted() || !equals(key, key_info.delkey)) && "Inserting the deleted key"); const std::pair pos = find_position(key); DefaultValue default_value; if ( pos.first != ILLEGAL_BUCKET) { // object was already there return *table.get_iter(pos.first); } else if (resize_delta(1)) { // needed to rehash to make room // Since we resized, we can't use pos, so recalculate where to insert. return *insert_noresize(default_value(key)).first; } else { // no need to rehash, insert right here return *insert_at(default_value(key), pos.second); } } // DELETION ROUTINES size_type erase(const key_type& key) { // First, double-check we're not erasing delkey. assert((!settings.use_deleted() || !equals(key, key_info.delkey)) && "Erasing the deleted key"); assert(!settings.use_deleted() || !equals(key, key_info.delkey)); const_iterator pos = find(key); // shrug: shouldn't need to be const if ( pos != end() ) { assert(!test_deleted(pos)); // or find() shouldn't have returned it set_deleted(pos); ++num_deleted; // will think about shrink after next insert settings.set_consider_shrink(true); return 1; // because we deleted one thing } else { return 0; // because we deleted nothing } } // We return the iterator past the deleted item. void erase(iterator pos) { if ( pos == end() ) return; // sanity check if ( set_deleted(pos) ) { // true if object has been newly deleted ++num_deleted; // will think about shrink after next insert settings.set_consider_shrink(true); } } void erase(iterator f, iterator l) { for ( ; f != l; ++f) { if ( set_deleted(f) ) // should always be true ++num_deleted; } // will think about shrink after next insert settings.set_consider_shrink(true); } // We allow you to erase a const_iterator just like we allow you to // erase an iterator. This is in parallel to 'delete': you can delete // a const pointer just like a non-const pointer. The logic is that // you can't use the object after it's erased anyway, so it doesn't matter // if it's const or not. void erase(const_iterator pos) { if ( pos == end() ) return; // sanity check if ( set_deleted(pos) ) { // true if object has been newly deleted ++num_deleted; // will think about shrink after next insert settings.set_consider_shrink(true); } } void erase(const_iterator f, const_iterator l) { for ( ; f != l; ++f) { if ( set_deleted(f) ) // should always be true ++num_deleted; } // will think about shrink after next insert settings.set_consider_shrink(true); } // COMPARISON bool operator==(const sparse_hashtable& ht) const { if (size() != ht.size()) { return false; } else if (this == &ht) { return true; } else { // Iterate through the elements in "this" and see if the // corresponding element is in ht for ( const_iterator it = begin(); it != end(); ++it ) { const_iterator it2 = ht.find(get_key(*it)); if ((it2 == ht.end()) || (*it != *it2)) { return false; } } return true; } } bool operator!=(const sparse_hashtable& ht) const { return !(*this == ht); } // I/O // We support reading and writing hashtables to disk. NOTE that // this only stores the hashtable metadata, not the stuff you've // actually put in the hashtable! Alas, since I don't know how to // write a hasher or key_equal, you have to make sure everything // but the table is the same. We compact before writing. // // The OUTPUT type needs to support a Write() operation. File and // OutputBuffer are appropriate types to pass in. // // The INPUT type needs to support a Read() operation. File and // InputBuffer are appropriate types to pass in. template bool write_metadata(OUTPUT *fp) { squash_deleted(); // so we don't have to worry about delkey return table.write_metadata(fp); } template bool read_metadata(INPUT *fp) { num_deleted = 0; // since we got rid before writing const bool result = table.read_metadata(fp); settings.reset_thresholds(bucket_count()); return result; } // Only meaningful if value_type is a POD. template bool write_nopointer_data(OUTPUT *fp) { return table.write_nopointer_data(fp); } // Only meaningful if value_type is a POD. template bool read_nopointer_data(INPUT *fp) { return table.read_nopointer_data(fp); } // INPUT and OUTPUT must be either a FILE, *or* a C++ stream // (istream, ostream, etc) *or* a class providing // Read(void*, size_t) and Write(const void*, size_t) // (respectively), which writes a buffer into a stream // (which the INPUT/OUTPUT instance presumably owns). typedef sparsehash_internal::pod_serializer NopointerSerializer; // ValueSerializer: a functor. operator()(OUTPUT*, const value_type&) template bool serialize(ValueSerializer serializer, OUTPUT *fp) { squash_deleted(); // so we don't have to worry about delkey return table.serialize(serializer, fp); } // ValueSerializer: a functor. operator()(INPUT*, value_type*) template bool unserialize(ValueSerializer serializer, INPUT *fp) { num_deleted = 0; // since we got rid before writing const bool result = table.unserialize(serializer, fp); settings.reset_thresholds(bucket_count()); return result; } private: // Table is the main storage class. typedef sparsetable Table; // Package templated functors with the other types to eliminate memory // needed for storing these zero-size operators. Since ExtractKey and // hasher's operator() might have the same function signature, they // must be packaged in different classes. struct Settings : sparsehash_internal::sh_hashtable_settings { explicit Settings(const hasher& hf) : sparsehash_internal::sh_hashtable_settings( hf, HT_OCCUPANCY_PCT / 100.0f, HT_EMPTY_PCT / 100.0f) {} }; // KeyInfo stores delete key and packages zero-size functors: // ExtractKey and SetKey. class KeyInfo : public ExtractKey, public SetKey, public EqualKey { public: KeyInfo(const ExtractKey& ek, const SetKey& sk, const EqualKey& eq) : ExtractKey(ek), SetKey(sk), EqualKey(eq) { } // We want to return the exact same type as ExtractKey: Key or const Key& typename ExtractKey::result_type get_key(const_reference v) const { return ExtractKey::operator()(v); } void set_key(pointer v, const key_type& k) const { SetKey::operator()(v, k); } bool equals(const key_type& a, const key_type& b) const { return EqualKey::operator()(a, b); } // Which key marks deleted entries. // TODO(csilvers): make a pointer, and get rid of use_deleted (benchmark!) typename base::remove_const::type delkey; }; // Utility functions to access the templated operators size_type hash(const key_type& v) const { return settings.hash(v); } bool equals(const key_type& a, const key_type& b) const { return key_info.equals(a, b); } typename ExtractKey::result_type get_key(const_reference v) const { return key_info.get_key(v); } void set_key(pointer v, const key_type& k) const { key_info.set_key(v, k); } private: // Actual data Settings settings; KeyInfo key_info; size_type num_deleted; // how many occupied buckets are marked deleted Table table; // holds num_buckets and num_elements too }; // We need a global swap as well template inline void swap(sparse_hashtable &x, sparse_hashtable &y) { x.swap(y); } #undef JUMP_ template const typename sparse_hashtable::size_type sparse_hashtable::ILLEGAL_BUCKET; // How full we let the table get before we resize. Knuth says .8 is // good -- higher causes us to probe too much, though saves memory template const int sparse_hashtable::HT_OCCUPANCY_PCT = 80; // How empty we let the table get before we resize lower. // It should be less than OCCUPANCY_PCT / 2 or we thrash resizing template const int sparse_hashtable::HT_EMPTY_PCT = static_cast(0.4 * sparse_hashtable::HT_OCCUPANCY_PCT); _END_GOOGLE_NAMESPACE_ #endif /* _SPARSEHASHTABLE_H_ */