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+/*
+ * Copyright (c) 2010, Andrea Mazzoleni. All rights reserved.
+ *
+ * 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 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.
+ */
+
+/** \mainpage
+ * \section Introduction
+ * Tommy is a C library of array, hashtables and tries data structures,
+ * designed for high performance and providing an easy to use interface.
+ *
+ * It's <b>faster</b> than all the similar libraries like
+ * <a href="http://www.canonware.com/rb/">rbtree</a>,
+ * <a href="http://judy.sourceforge.net/">judy</a>,
+ * <a href="http://code.google.com/p/cpp-btree/">googlebtree</a>,
+ * <a href="http://panthema.net/2007/stx-btree/">stxbtree</a>,
+ * <a href="http://attractivechaos.awardspace.com/">khash</a>,
+ * <a href="http://uthash.sourceforge.net/">uthash</a>,
+ * <a href="http://www.nedprod.com/programs/portable/nedtries/">nedtrie</a>,
+ * <a href="http://code.google.com/p/judyarray/">judyarray</a>,
+ * <a href="http://concurrencykit.org/">concurrencykit</a> and others.
+ * Only <a href="http://code.google.com/p/google-sparsehash/">googledensehash</a> is a real competitor for Tommy.
+ *
+ * The data structures provided are:
+ *
+ * - ::tommy_list - A double linked list.
+ * - ::tommy_array, ::tommy_arrayof - A linear array.
+ * It doesn't fragment the heap.
+ * - ::tommy_arrayblk, ::tommy_arrayblkof - A blocked linear array.
+ * It doesn't fragment the heap and it minimizes the space occupation.
+ * - ::tommy_hashtable - A fixed size chained hashtable.
+ * - ::tommy_hashdyn - A dynamic chained hashtable.
+ * - ::tommy_hashlin - A linear chained hashtable.
+ * It doesn't have the problem of the delay when resizing and
+ * it doesn't fragment the heap.
+ * - ::tommy_trie - A trie optimized for cache utilization.
+ * - ::tommy_trie_inplace - A trie completely inplace.
+ * - ::tommy_tree - A tree to keep elements in order.
+ *
+ * The most interesting are ::tommy_array, ::tommy_hashdyn, ::tommy_hashlin, ::tommy_trie and ::tommy_trie_inplace.
+ *
+ * The official site of TommyDS is <a href="http://www.tommyds.it/">http://www.tommyds.it/</a>,
+ *
+ * \section Use
+ *
+ * All the Tommy containers are used to store pointers to generic objects, associated to an
+ * integer value, that could be a key or a hash value.
+ *
+ * They are semantically equivalent at the C++ <a href="http://www.cplusplus.com/reference/map/multimap/">multimap\<unsigned,void*\></a>
+ * and <a href="http://www.cplusplus.com/reference/unordered_map/unordered_multimap/">unordered_multimap\<unsigned,void*\></a>.
+ *
+ * An object, to be inserted in a container, should contain a node of type ::tommy_node.
+ * Inside this node is present a pointer to the object itself in the tommy_node::data field,
+ * the key used to identify the object in the tommy_node::key field, and other fields used
+ * by the containers.
+ *
+ * This is a typical object declaration:
+ * \code
+ * struct object {
+ *     // other fields
+ *     tommy_node node;
+ * };
+ * \endcode
+ *
+ * To insert an object in a container, you have to provide the address of the embedded node,
+ * the address of the object and the value of the key.
+ * \code
+ * int key_to_insert = 1;
+ * struct object* obj = malloc(sizeof(struct object));
+ * ...
+ * tommy_trie_insert(..., &obj->node, obj, key_to_insert);
+ * \endcode
+ *
+ * To search an object you have to provide the key and call the search function.
+ * \code
+ * int key_to_find = 1;
+ * struct object* obj = tommy_trie_search(..., key_to_find);
+ * if (obj) {
+ *   // found
+ * }
+ * \endcode
+ *
+ * To access all the objects with the same keys you have to iterate over the bucket
+ * assigned at the specified key.
+ * \code
+ * int key_to_find = 1;
+ * tommy_trie_node* i = tommy_trie_bucket(..., key_to_find);
+ *
+ * while (i) {
+ *     struct object* obj = i->data; // gets the object pointer
+ *
+ *     printf("%d\n", obj->value); // process the object
+ *
+ *     i = i->next; // goes to the next element
+ * }
+ * \endcode
+ *
+ * To remove an object you have to provide the key and call the remove function.
+ * \code
+ * int key_to_remove = 1;
+ * struct object* obj = tommy_trie_remove(..., key_to_remove);
+ * if (obj) {
+ *     // found
+ *     free(obj); // frees the object allocated memory
+ * }
+ * \endcode
+ *
+ * Dealing with hashtables, instead of the key, you have to provide the hash
+ * value of the object, and a compare function able to differentiate objects with
+ * the same hash value.
+ * To compute the hash value, you can use the generic tommy_hash_u32() function,
+ * or the specialized integer hash function tommy_inthash_u32().
+ *
+ * \section Features
+ *
+ * Tommy is fast and easy to use.
+ *
+ * Tommy is portable to all platforms and operating systems.
+ *
+ * Tommy containers support multiple elements with the same key.
+ *
+ * Tommy containers keep the original insertion order of elements with equal keys.
+ *
+ * Tommy is released with the \ref license "2-clause BSD license".
+ *
+ * See the \ref design page for more details and limitations.
+ *
+ * \section Performance
+ * Here you can see some timings comparing with other notable implementations.
+ * The <i>Hit</i> graph shows the time required for searching random objects
+ * with a key.
+ * The <i>Change</i> graph shows the time required for searching, removing and
+ * reinsert random objects with a different key value.
+ *
+ * Times are expressed in nanoseconds for each element, and <b>lower is better</b>.
+ *
+ * To have some reference numbers, you can check <a href="https://gist.github.com/jboner/2841832">Latency numbers every programmer should know</a>.
+ *
+ * A complete analysis is available in the \ref benchmark page.
+ *
+ * <img src="def/img_random_hit.png"/>
+ *
+ * <img src="def/img_random_change.png"/>
+ *
+ * \page benchmark Tommy Benchmarks
+ *
+ * To evaluate Tommy performances, an extensive benchmark was done,
+ * comparing it to the best libraries of data structures available:
+ *
+ * Specifically we test:
+ *  - ::tommy_hashtable - Fixed size chained hashtable.
+ *  - ::tommy_hashdyn - Dynamic chained hashtable.
+ *  - ::tommy_hashlin - Linear chained hashtable.
+ *  - ::tommy_trie - Trie optimized for cache usage.
+ *  - ::tommy_trie_inplace - Trie completely inplace.
+ *  - <a href="http://www.canonware.com/rb/">rbtree</a> - Red-black tree by Jason Evans.
+ *  - <a href="http://www.nedprod.com/programs/portable/nedtries/">nedtrie</a> - Binary trie inplace by Niall Douglas.
+ *  - <a href="http://attractivechaos.awardspace.com/">khash</a> - Dynamic open addressing hashtable by Attractive Chaos.
+ *  - <a href="http://uthash.sourceforge.net/">uthash</a> - Dynamic chaining hashtable by Troy D. Hanson.
+ *  - <a href="http://judy.sourceforge.net/">judy</a> - Burst trie (JudyL) by Doug Baskins.
+ *  - <a href="http://code.google.com/p/judyarray/">judyarray</a> - Burst trie by Karl Malbrain.
+ *  - <a href="http://code.google.com/p/google-sparsehash/">googledensehash</a> - Dynamic open addressing hashtable by Craig Silverstein at Google.
+ *  - <a href="http://code.google.com/p/cpp-btree/">googlebtree</a> - Btree by Google.
+ *  - <a href="http://panthema.net/2007/stx-btree/">stxbtree</a> - STX Btree by Timo Bingmann.
+ *  - <a href="http://www.cplusplus.com/reference/unordered_map/unordered_map/">c++unordered_map</a> - C++ STL unordered_map<> template.
+ *  - <a href="http://www.cplusplus.com/reference/map/map/">c++map</a> - C++ STL map<> template.
+ *  - <a href="https://sites.google.com/site/binarysearchcube/">tesseract</a> - Binary Search Tesseract by Gregorius van den Hoven.
+ *  - <a href="https://code.google.com/p/sparsehash/source/browse/trunk/experimental/libchash.c">googlelibchash</a> - LibCHash by Craig Silverstein at Google.
+ *  - <a href="https://github.com/fredrikwidlund/libdynamic">libdynamic</a> - Hash set by Fredrik Widlund.
+ *  - <a href="http://concurrencykit.org/">concurrencykit</a> - Non-blocking hash set by Samy Al Bahra.
+ *
+ * Note that <em>googlelibchash</em> and <em>concurrencykit</em> are not shown in the graphs
+ * because they present a lot of spikes. See the \ref notes the end.
+ *
+ * \section thebenchmark The Benchmark
+ *
+ * The benchmark consists in storing a set of N pointers to objects and
+ * searching them using integer keys.
+ *
+ * Compared to the case of mapping integers to integers, mapping pointers to
+ * objects means that the pointers are also dereferenced, to simulate the
+ * object access, resulting in additional cache misses.
+ * This gives an advantage to implementations that store information in the
+ * objects itself, as the additional cache misses are already implicit.
+ *
+ * The test done are:
+ *  - <b>Insert</b> Insert all the objects starting with an empty container.
+ *  - <b>Change</b> Find and remove one object and reinsert it with a different key, repeated for all the objects.
+ *  - <b>Hit</b> Find with success all the objects and dereference them.
+ *  - <b>Miss</b> Find with failure all the objects.
+ *  - <b>Remove</b> Remove all the objects and dereference them.
+ *
+ * The <i>Change</i>, <i>Hit</i> and <i>Miss</i> tests operate always with N
+ * objects in the containers.
+ * The <i>Insert</i> test starts with an empty container, and the <i>Remove</i>
+ * test ends with an empty container.
+ * The objects are always dereferenced, as we are supposing to use them. This
+ * happens even in the remove case, as we are supposing to deallocate them.
+ *
+ * All the objects are preallocated in the heap, and the allocation and deallocation
+ * time is not included in the test.
+ *
+ * The objects contain an integer <i>value</i> field used for consistency checks,
+ * an unused <i>payload</i> field of 16 bytes, and any other data required by the
+ * data structure.
+ *
+ * The objects are identified and stored using integer and unique <i>keys</i>.
+ * The key domain used is <strong>dense</strong>, and it's defined by the set
+ * of N even numbers starting from 0x80000000 to 0x80000000+2*N.
+ *
+ * The use of even numbers allows to have missing keys inside the domain for
+ * the <i>Miss</i> and <i>Change</i> test.
+ * In such tests it's used the key domain defined by the set of N odd numbers
+ * starting from 0x80000000+1 to 0x80000000+2*N+1.
+ * Note that using additional keys at the corners of the domain would have given
+ * an unfair advantage to tries and trees as they implicitly keep track of the
+ * maximum and minimum key value inserted.
+ *
+ * The use of the 0x80000000 base, allow to test a key domain not necessarily
+ * starting at 0. Using a 0 base would have given an unfair advantage to some
+ * implementation handling it as a special case.
+ *
+ * For all the hashtables the keys are hashed using the tommy_inthash_u32()
+ * function that ensures an uniform distribution. This hash function is also
+ * reversible, meaning that no collision is going to be caused by hashing the
+ * keys. For tries and trees the keys are not hashed, and used directly.
+ *
+ * The tests are repeated using keys in <i>Random</i> mode and in <i>Forward</i>
+ * mode. In the forward mode the key values are used in order from the lowest
+ * to the highest.
+ * In the random mode the key values are used in a completely random order.
+ * In the <i>Change</i> test in forward mode, each object is reinserted using
+ * the previous key incremented by 1. In random mode each object is reinserted
+ * using a completely different and uncorrelated key.
+ *
+ * The forward order advantages tries and trees as they use the key directly
+ * and they have a cache advantage on using consecutive keys.
+ * The random order advantages hashtables, as the hash function already
+ * randomizes the key. Usually real uses case are in between, and the random
+ * one is the worst case.
+ *
+ * \section result Results
+ *
+ * The most significant tests depend on your data usage model, but if in doubt,
+ * you can look at <i>Random Hit</i> and <i>Random Change</i>.
+ * They represent the real world worst condition.
+ *
+ * <img src="def/img_random_hit.png"/>
+ *
+ * In the <i>Random Hit</i> graph you can see a vertical split at the 100.000
+ * elements limit. Before this limit the cache of modern processor is able to
+ * contains most of the data, and it allows a very fast access with almost all
+ * data structures.
+ * After this limit, the number of cache misses is the dominant factor, and
+ * the curve depends mainly on the number of cache-miss required.
+ *
+ * rbtree and nedtrie grow as log2(N) as they have two branches on each node,
+ * ::tommy_trie_inplace grows as log4(N), ::tommy_trie as log8(N) and hashtables
+ * are almost constant and don't grow.
+ * For ::tommy_trie_inplace and ::tommy_trie you can change the grow curve
+ * configuring a different number of branches for node.
+ *
+ * <img src="def/img_random_change.png"/>
+ *
+ * The <i>Random Change</i> graph confirms the vertical split at the 100.000
+ * elements limit. It also show that hashtables are almost unbeatable with a
+ * random access.
+ *
+ * \section random Random order
+ * Here you can see the whole <i>Random</i> test results in different platforms.
+ *
+ * In the <i>Random</i> test, hashtables are almost always winning, seconds are
+ * tries, and as last trees.
+ *
+ * The best choices are ::tommy_hashdyn, ::tommy_hashlin, and googledensehash,
+ * with ::tommy_hashlin having the advantage to be real-time friendly and not
+ * increasing the heap fragmentation.
+ * <table border="0">
+ * <tr><td>
+ * <img src="core_i5_650_3G2_linux/img_random_insert.png"/>
+ * </td></tr><tr><td>
+ * <img src="core_i5_650_3G2_linux/img_random_hit.png"/>
+ * </td></tr><tr><td>
+ * <img src="core_i5_650_3G2_linux/img_random_miss.png"/>
+ * </td></tr><tr><td>
+ * <img src="core_i5_650_3G2_linux/img_random_change.png"/>
+ * </td></tr><tr><td>
+ * <img src="core_i5_650_3G2_linux/img_random_remove.png"/>
+ * </td></tr>
+ * </table>
+ *
+ * \section forward Forward order
+ * Here you can see the whole <i>Forward</i> test results in different platforms.
+ *
+ * In the <i>Forward</i> test, tries are the winners. Hashtables are competitive
+ * until the cache limit, then they lose against tries. Trees are the slowest.
+ *
+ * The best choices are ::tommy_trie and ::tommy_trie_inplace, where ::tommy_trie is
+ * a bit faster, and ::tommy_trie_inplace doesn't require a custom allocator.
+ *
+ * Note that also hashtables are faster in forward order than random. This may
+ * seem a bit surprising as the hash function randomizes the access even with
+ * consecutive keys. This happens because the objects are allocated in consecutive
+ * memory, and accessing them in order, improves the cache utilization, even if
+ * the hashed key is random.
+ *
+ * Note that you can make hashtables to reach tries performance tweaking the hash
+ * function to put near keys allocated nearby.
+ * This is possible if you know in advance the distribution of keys.
+ * For example, in the benchmark you could use something like:
+ * \code
+ * #define hash(v) tommy_inthash_u32(v & ~0xF) + (v & 0xF)
+ * \endcode
+ * and make keys that differ only by the lowest bits to have hashes with the same
+ * property, resulting in objects stored nearby, and improving cache utilization.
+ *
+ * <table border="0">
+ * <tr><td>
+ * <img src="core_i5_650_3G2_linux/img_forward_insert.png"/>
+ * </td></tr><tr><td>
+ * <img src="core_i5_650_3G2_linux/img_forward_hit.png"/>
+ * </td></tr><tr><td>
+ * <img src="core_i5_650_3G2_linux/img_forward_miss.png"/>
+ * </td></tr><tr><td>
+ * <img src="core_i5_650_3G2_linux/img_forward_change.png"/>
+ * </td></tr><tr><td>
+ * <img src="core_i5_650_3G2_linux/img_forward_remove.png"/>
+ * </td></tr>
+ * </table>
+ *
+ * \section size Size
+ * Here you can see the memory usage of the different data structures.
+ * <table border="0">
+ * <tr><td>
+ * <img src="core_i5_650_3G2_linux/img_random_size.png"/>
+ * </td></tr>
+ * </table>
+ *
+ * \section code Code
+ *
+ * The compilers used in the benchmark are:
+ *  - <b>gcc 4.9.2</b> in Linux with options: -O3 -march=nehalem
+ *  - <b>Visual C 2012</b> in Windows with options: /Ox /Oy- /GL /GS- /arch:SSE2
+ *
+ * The following is pseudo code of the benchmark used. In this case it's written
+ * for the C++ unordered_map.
+ *
+ * \code
+ * #define N 10000000 // Number of elements
+ * #define PAYLOAD 16 // Size of the object
+ *
+ * // Basic object inserted in the colletion
+ * struct obj {
+ *     unsigned value; // Key used for searching
+ *     char payload[PAYLOAD];
+ * };
+ *
+ * // Custom hash function to avoid to use the STL one
+ * class custom_hash {
+ * public:
+ *     unsigned operator()(unsigned key) const { return tommy_inthash_u32(key); }
+ * };
+ *
+ * // Map collection from "unsigned" to "pointer to object"
+ * typedef std::unordered_map<unsigned, obj*, custom_hash> bag_t;
+ * bag_t bag;
+ *
+ * // Preallocate objects
+ * obj* OBJ = new obj[N];
+ *
+ * // Keys used for inserting and searching elements
+ * unsigned INSERT[N];
+ * unsigned SEARCH[N];
+ *
+ * // Initialize the keys
+ * for(i=0;i<N;++i) {
+ *     INSERT[i] = 0x80000000 + i * 2;
+ *     SEARCH[i] = 0x80000000 + i * 2;
+ * }
+ *
+ * // If random order is required, shuffle the keys with Fisher-Yates
+ * // The two key orders are not correlated
+ * if (test_random) {
+ *     std::random_shuffle(INSERT, INSERT + N);
+ *     std::random_shuffle(SEARCH, SEARCH + N);
+ * }
+ * \endcode
+ *
+ * \subsection insertion Insert benchmark
+ * \code
+ * for(i=0;i<N;++i) {
+ *     // Setup the element to insert
+ *     unsigned key = INSERT[i];
+ *     obj* element = &OBJ[i];
+ *     element->value = key;
+ *
+ *     // Insert it
+ *     bag[key] = element;
+ * }
+ * \endcode
+ *
+ * \subsection change Change benchmark
+ * \code
+ * for(i=0;i<N;++i) {
+ *     // Search the element
+ *     unsigned key = SEARCH[i];
+ *     bag_t::iterator j = bag.find(key);
+ *     if (j == bag.end())
+ *         abort();
+ *
+ *     // Remove it
+ *     obj* element = j->second;
+ *     bag.erase(j);
+ *
+ *     // Reinsert the element with a new key
+ *     // Use +1 in the key to ensure that the new key is unique
+ *     key = INSERT[i] + 1;
+ *     element->value = key;
+ *     bag[key] = element;
+ * }
+ * \endcode
+ *
+ * \subsection hit Hit benchmark
+ * \code
+ * for(i=0;i<N;++i) {
+ *     // Search the element
+ *     // Use a different key order than insertion
+ *     // Use +1 in the key because we run after the "Change" test
+ *     unsigned key = SEARCH[i] + 1;
+ *     bag_t::const_iterator j = bag.find(key);
+ *     if (j == bag.end())
+ *         abort();
+ *
+ *     // Ensure that it's the correct element.
+ *     // This operation is like using the object after finding it,
+ *     // and likely involves a cache-miss operation.
+ *     obj* element = j->second;
+ *     if (element->value != key)
+ *         abort();
+ * }
+ * \endcode
+ *
+ * \subsection miss Miss benchmark
+ * \code
+ * for(i=0;i<N;++i) {
+ *     // Search the element
+ *     // All the keys are now shifted by +1 by the "Change" test, and we'll find nothing
+ *     unsigned key = SEARCH[i];
+ *     bag_t::const_iterator j = bag.find(key);
+ *     if (j != bag.end())
+ *         abort();
+ * }
+ * \endcode
+ *
+ * \subsection remove Remove benchmark
+ * \code
+ * for(i=0;i<N;++i) {
+ *     // Search the element
+ *     // Use +1 in the key because we run after the "Change" test
+ *     unsigned key = SEARCH[i] + 1;
+ *     bag_t::iterator j = bag.find(key);
+ *     if (j == bag.end())
+ *         abort();
+ *
+ *     // Remove it
+ *     bag.erase(j);
+ *
+ *     // Ensure that it's the correct element.
+ *     obj* element = j->second;
+ *     if (element->value != key)
+ *         abort();
+ * }
+ * \endcode
+ *
+ * \section others Other benchmarks
+ * Here some links to other performance comparison:
+ *
+ * <a href="http://attractivechaos.wordpress.com/2008/08/28/comparison-of-hash-table-libraries/">Comparison of Hash Table Libraries</a>
+ *
+ * <a href="http://incise.org/hash-table-benchmarks.html">Hash Table Benchmarks</a>
+ *
+ * \section notes Notes
+ *
+ * Here some notes about the data structure tested not part of Tommy.
+ *
+ * \subsection googlelibchash Google C libchash
+ * It's the C implementation located in the <i>experimental/</i> directory of the googlesparsehash archive.
+ * It has very bad performances in the <i>Change</i> test for some N values.
+ * See this <a href="other/googlelibchash_problem.png">graph</a> with a lot of spikes.
+ * The C++ version doesn't suffer of this problem.
+ *
+ * \subsection googledensehash Google C++ densehash
+ * It doesn't release memory on deletion.
+ * To avoid an unfair advantage in the <i>Remove</i> test, we force a periodic
+ * resize calling resize(0) after any deallocation.
+ * The resize is executed when the load factor is lower than 20%.
+ *
+ * \subsection khash khash
+ * It doesn't release memory on deletion. This gives an unfair advantage on the <i>Remove</i> test.
+ *
+ * \subsection nedtrie nedtrie
+ * I've found a crash bug when inserting keys with the 0 value.
+ * The <a href="https://github.com/ned14/nedtries/commit/21039696f27db4ffac70a82f89dc5d00ae74b332">fix</a> of this issue is now in the nedtries github.
+ * We do not use the C++ implementation as it doesn't compile with gcc 4.4.3.
+ *
+ * \subsection judy Judy
+ * Sometimes it has bad performances in some specific platform
+ * and for some specific input data size.
+ * This makes difficult to predict the performance, as it is usually good until
+ * you get one of these cases.
+ * See for example this <a href="other/judy_problem.png">graph</a> with a big replicable spike at 50.000 elements.
+ *
+ * \subsection ck Concurrency Kit
+ * It has very bad performances in the <i>Change</i> test for some N values.
+ * See this <a href="other/ck_problem.png">graph</a> with a lot of spikes.
+ *
+ * \page multiindex Tommy Multi Indexing
+ *
+ * Tommy provides only partial iterator support with the "foreach" functions.
+ * If you need real iterators you have to insert all the objects also in a ::tommy_list,
+ * and use the list as iterator.
+ *
+ * This technique allows to keep track of the insertion order with the list,
+ * and provides more search possibilities using different data structures for
+ * different search keys.
+ *
+ * See the next example, for a objects inserted in a ::tommy_list, and in
+ * two ::tommy_hashdyn using different keys.
+ *
+ * \code
+ * struct object {
+ *     // data fields
+ *     int value_0;
+ *     int value_1;
+ *
+ *     // for containers
+ *     tommy_node list_node; // node for the list
+ *     tommy_node hash_node_0; // node for the first hash
+ *     tommy_node hash_node_1; // node for the second hash
+ * };
+ *
+ * // search function for value_1
+ * int search_1(const void* arg, const void* obj)
+ * {
+ *     return *(const int*)arg != ((const struct object*)obj)->value_1;
+ * }
+ *
+ * tommy_hashdyn hash_0;
+ * tommy_hashdyn hash_1;
+ * tommy_list list;
+ *
+ * // initializes the hash tables and the list
+ * tommy_hashdyn_init(&hash_0);
+ * tommy_hashdyn_init(&hash_1);
+ * tommy_list_init(&list);
+ *
+ * ...
+ *
+ * // creates an object and inserts it
+ * struct object* obj = malloc(sizeof(struct object));
+ * obj->value_0 = ...;
+ * obj->value_1 = ...;
+ * // inserts in the first hash table
+ * tommy_hashdyn_insert(&hash_0, &obj->hash_node_0, obj, tommy_inthash_u32(obj->value_0));
+ * // inserts in the second hash table
+ * tommy_hashdyn_insert(&hash_1, &obj->hash_node_1, obj, tommy_inthash_u32(obj->value_1));
+ * // inserts in the list
+ * tommy_list_insert_tail(&list, &obj->list_node, obj);
+ *
+ * ...
+ *
+ * // searches an object by value_1 and deletes it
+ * int value_to_find = ...;
+ * struct object* obj = tommy_hashdyn_search(&hash_1, search_1, &value_to_find, tommy_inthash_u32(value_to_find));
+ * if (obj) {
+ *     // if found removes all the references
+ *     tommy_hashdyn_remove_existing(&hash_0, &obj->hash_node_0);
+ *     tommy_hashdyn_remove_existing(&hash_1, &obj->hash_node_1);
+ *     tommy_list_remove_existing(&list, &obj->list_node);
+ * }
+ *
+ * ...
+ *
+ * // complex iterator logic
+ * tommy_node* i = tommy_list_head(&list);
+ * while (i != 0) {
+ *    // get the object
+ *    struct object* obj = i->data;
+ *    ...
+ *    // go to the next element
+ *    i = i->next;
+ *    ...
+ *    // go to the prev element
+ *    i = i->prev;
+ *    ...
+ * }
+ *
+ * ...
+ *
+ * // deallocates the objects iterating the list
+ * tommy_list_foreach(&list, free);
+ *
+ * // deallocates the hash tables
+ * tommy_hashdyn_done(&hash_0);
+ * tommy_hashdyn_done(&hash_1);
+ * \endcode
+ *
+ * \page design Tommy Design
+ *
+ * Tommy is designed to fulfill the need of generic data structures for the
+ * C language, providing at the same time high performance and a clean
+ * and easy to use interface.
+ *
+ * \section testing Testing
+ *
+ * Extensive and automated tests with the runtime checker <a href="http://valgrind.org/">valgrind</a>
+ * and the static analyzer <a href="http://clang-analyzer.llvm.org/">clang</a>
+ * are done to ensure the correctness of the library.
+ *
+ * The test has a <a href="http://www.tommyds.it/cov/tommyds/tommyds">code coverage of 100%</a>,
+ * measured with <a href="http://ltp.sourceforge.net/coverage/lcov.php">lcov</a>.
+ *
+ * \section Limitations
+ *
+ * Tommy is not thread safe. You have always to provide thread safety using
+ * locks before calling any Tommy functions.
+ *
+ * Tommy doesn't provide iterators over the implicit order defined by the data
+ * structures. To iterate on elements you must insert them also into a ::tommy_list,
+ * and use the list as iterator. See the \ref multiindex example for more details.
+ * Note that this is a real limitation only for ::tommy_trie, as it's the only
+ * data structure defining an useable order.
+ *
+ * Tommy doesn't provide an error reporting mechanism for a malloc() failure.
+ * You have to provide it redefining malloc() if you expect it to fail.
+ *
+ * Tommy assumes to never have more than 2^32-1 elements in a container.
+ *
+ * \section compromise Compromises
+ *
+ * Finding the right balance between efficency and easy to use required some
+ * comprimises. Most of them are on memory efficency, and were done to avoid to
+ * cripple the interface.
+ *
+ * The following is a list of such decisions.
+ *
+ * \subsection multi_key Multi key
+ * All the Tommy containers support the insertion of multiple elements with
+ * the same key, adding in each node a list of equal elements.
+ *
+ * They are the equivalent at the C++ associative containers <a href="http://www.cplusplus.com/reference/map/multimap/">multimap\<unsigned,void*\></a>
+ * and <a href="http://www.cplusplus.com/reference/unordered_map/unordered_multimap/">unordered_multimap\<unsigned,void*\></a>
+ * that allow duplicates of the same key.
+ *
+ * A more memory conservative approach is to not allow duplicated elements,
+ * removing the need of this list.
+ *
+ * \subsection data_pointer Data pointer
+ * The tommy_node::data field is present to allow search and remove functions to return
+ * directly a pointer to the element stored in the container.
+ *
+ * A more memory conservative approach is to require the user to compute
+ * the element pointer from the embedded node with a fixed displacement.
+ * For an example, see the Linux Kernel declaration of
+ * <a href="http://lxr.free-electrons.com/ident?i=container_of">container_of()</a>.
+ *
+ * \subsection insertion_order Insertion order
+ * The list used for collisions is double linked to allow
+ * insertion of elements at the end of the list to keep the
+ * insertion order of equal elements.
+ *
+ * A more memory conservative approach is to use a single linked list,
+ * inserting elements only at the start of the list, losing the
+ * original insertion order.
+ *
+ * \subsection zero_list Zero terminated list
+ * The 0 terminated format of tommy_node::next is present to provide a forward
+ * iterator terminating in 0. This allows the user to write a simple iteration
+ * loop over the list of elements in the same bucket.
+ *
+ * A more efficient approach is to use a circular list, because operating on nodes
+ * in a circular list doesn't requires to manage the special terminating case when
+ * adding or removing elements.
+ *
+ * \page license Tommy License
+ * Tommy is released with a <i>2-clause BSD license</i>.
+ *
+ * \code
+ * Copyright (c) 2010, Andrea Mazzoleni. All rights reserved.
+ *
+ * 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 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.
+ * \endcode
+ */
+
+/** \file
+ * All in one include for Tommy.
+ */
+
+#ifdef __cplusplus
+extern "C" {
+#endif
+
+#include "tommytypes.h"
+#include "tommyhash.h"
+#include "tommyalloc.h"
+#include "tommyarray.h"
+#include "tommyarrayof.h"
+#include "tommyarrayblk.h"
+#include "tommyarrayblkof.h"
+#include "tommylist.h"
+#include "tommytree.h"
+#include "tommytrie.h"
+#include "tommytrieinp.h"
+#include "tommyhashtbl.h"
+#include "tommyhashdyn.h"
+#include "tommyhashlin.h"
+
+#ifdef __cplusplus
+}
+#endif
+