/** 
 * @file lluuidhashmap_tut.cpp
 * @author Adroit
 * @date 2007-02
 * @brief Test cases for LLUUIDHashMap
 *
 * $LicenseInfo:firstyear=2007&license=viewergpl$
 * 
 * Copyright (c) 2007-2009, Linden Research, Inc.
 * 
 * Second Life Viewer Source Code
 * The source code in this file ("Source Code") is provided by Linden Lab
 * to you under the terms of the GNU General Public License, version 2.0
 * ("GPL"), unless you have obtained a separate licensing agreement
 * ("Other License"), formally executed by you and Linden Lab.  Terms of
 * the GPL can be found in doc/GPL-license.txt in this distribution, or
 * online at http://secondlifegrid.net/programs/open_source/licensing/gplv2
 * 
 * There are special exceptions to the terms and conditions of the GPL as
 * it is applied to this Source Code. View the full text of the exception
 * in the file doc/FLOSS-exception.txt in this software distribution, or
 * online at
 * http://secondlifegrid.net/programs/open_source/licensing/flossexception
 * 
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 * 
 * ALL LINDEN LAB SOURCE CODE IS PROVIDED "AS IS." LINDEN LAB MAKES NO
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 */

#include <tut/tut.hpp>
#include "linden_common.h"
#include "lluuidhashmap.h"
#include "llsdserialize.h"

namespace tut
{
	class UUIDTableEntry
	{
	public:
		UUIDTableEntry()
		{
			mID.setNull();
			mValue = 0;
		}
		
		UUIDTableEntry(const LLUUID& id, U32 value)
		{
			mID = id;
			mValue = value;
		}

		~UUIDTableEntry(){};

		static BOOL uuidEq(const LLUUID &uuid, const UUIDTableEntry &id_pair)
		{
			if (uuid == id_pair.mID)
			{
				return TRUE;
			}
			return FALSE;
		}

		const LLUUID& getID() { return mID; }
		const U32& getValue() { return mValue; }

	protected:
		LLUUID	mID;
		U32  mValue;
	};

	struct hashmap_test
	{
	};

	typedef test_group<hashmap_test> hash_index_t;
	typedef hash_index_t::object hash_index_object_t;
	tut::hash_index_t tut_hash_index("hashmap_test");

	// stress test
	template<> template<>
	void hash_index_object_t::test<1>()
	{
		LLUUIDHashMap<UUIDTableEntry, 32>	hashTable(UUIDTableEntry::uuidEq, UUIDTableEntry());
		const int numElementsToCheck = 32*256*32;
		std::vector<LLUUID> idList(numElementsToCheck);
		int i;
		
		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID id;
			id.generate();
			UUIDTableEntry entry(id, i);
			hashTable.set(id, entry);
			idList[i] = id;
		}

		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID idToCheck = idList[i];
			UUIDTableEntry entryToCheck = hashTable.get(idToCheck);
			ensure("set/get did not work", entryToCheck.getID() == idToCheck && entryToCheck.getValue() == (size_t)i);
		}

		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID idToCheck = idList[i];
			if (i % 2 != 0)
			{
				hashTable.remove(idToCheck);
			}
		}

		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID idToCheck = idList[i];
			ensure("remove or check did not work", (i % 2 == 0 && hashTable.check(idToCheck)) || (i % 2 != 0 && !hashTable.check(idToCheck)));
		}
	}

	// test removing all but one element. 
	template<> template<>
	void hash_index_object_t::test<2>()
	{
		LLUUIDHashMap<UUIDTableEntry, 2>	hashTable(UUIDTableEntry::uuidEq, UUIDTableEntry());
		const int numElementsToCheck = 5;
		std::vector<LLUUID> idList(numElementsToCheck*10);
		int i;
		
		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID id;
			id.generate();
			UUIDTableEntry entry(id, i);
			hashTable.set(id, entry);
			idList[i] = id;
		}

		ensure("getLength failed", hashTable.getLength() == numElementsToCheck);

		// remove all but the last element
		for (i = 0; i < numElementsToCheck-1; i++)
		{
			LLUUID idToCheck = idList[i];
			hashTable.remove(idToCheck);
		}

		// there should only be one element left now.
		ensure("getLength failed", hashTable.getLength() == 1);

		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID idToCheck = idList[i];
			if (i != numElementsToCheck - 1)
			{
				ensure("remove did not work", hashTable.check(idToCheck)  == FALSE);
			}
			else
			{
				UUIDTableEntry entryToCheck = hashTable.get(idToCheck);
				ensure("remove did not work", entryToCheck.getID() == idToCheck && entryToCheck.getValue() == (size_t)i);
			}
		}
	}

	// test overriding of value already set. 
	template<> template<>
	void hash_index_object_t::test<3>()
	{
		LLUUIDHashMap<UUIDTableEntry, 5>	hashTable(UUIDTableEntry::uuidEq, UUIDTableEntry());
		const int numElementsToCheck = 10;
		std::vector<LLUUID> idList(numElementsToCheck);
		int i;
		
		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID id;
			id.generate();
			UUIDTableEntry entry(id, i);
			hashTable.set(id, entry);
			idList[i] = id;
		}

		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID id = idList[i];
			// set new entry with value = i+numElementsToCheck
			UUIDTableEntry entry(id, i+numElementsToCheck);
			hashTable.set(id, entry);
		}

		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID idToCheck = idList[i];
			UUIDTableEntry entryToCheck = hashTable.get(idToCheck);
			ensure("set/get did not work", entryToCheck.getID() == idToCheck && entryToCheck.getValue() == (size_t)(i+numElementsToCheck));
		}
	}

	// test removeAll() 
	template<> template<>
	void hash_index_object_t::test<4>()
	{
		LLUUIDHashMap<UUIDTableEntry, 5>	hashTable(UUIDTableEntry::uuidEq, UUIDTableEntry());
		const int numElementsToCheck = 10;
		std::vector<LLUUID> idList(numElementsToCheck);
		int i;
		
		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID id;
			id.generate();
			UUIDTableEntry entry(id, i);
			hashTable.set(id, entry);
			idList[i] = id;
		}

		hashTable.removeAll();
		ensure("removeAll failed", hashTable.getLength() == 0);
	}


	// test sparse map - force it by creating 256 entries that fall into 256 different nodes 
	template<> template<>
	void hash_index_object_t::test<5>()
	{
		LLUUIDHashMap<UUIDTableEntry, 2>	hashTable(UUIDTableEntry::uuidEq, UUIDTableEntry());
		const int numElementsToCheck = 256;
		std::vector<LLUUID> idList(numElementsToCheck);
		int i;
		
		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID id;
			id.generate();
			// LLUUIDHashMap uses mData[0] to pick the bucket
			// overwrite mData[0] so that it ranges from 0 to 255
			id.mData[0] = i; 
			UUIDTableEntry entry(id, i);
			hashTable.set(id, entry);
			idList[i] = id;
		}

		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID idToCheck = idList[i];
			UUIDTableEntry entryToCheck = hashTable.get(idToCheck);
			ensure("set/get did not work for sparse map", entryToCheck.getID() == idToCheck && entryToCheck.getValue() == (size_t)i);
		}

		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID idToCheck = idList[i];
			if (i % 2 != 0)
			{
				hashTable.remove(idToCheck);
			}
		}

		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID idToCheck = idList[i];
			ensure("remove or check did not work for sparse map", (i % 2 == 0 && hashTable.check(idToCheck)) || (i % 2 != 0 && !hashTable.check(idToCheck)));
		}
	}

	// iterator
	template<> template<>
	void hash_index_object_t::test<6>()
	{
		LLUUIDHashMap<UUIDTableEntry, 2>	hashTable(UUIDTableEntry::uuidEq, UUIDTableEntry());
		LLUUIDHashMapIter<UUIDTableEntry, 2> hashIter(&hashTable);
		const int numElementsToCheck = 256;
		std::vector<LLUUID> idList(numElementsToCheck);
		int i;
		
		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID id;
			id.generate();
			// LLUUIDHashMap uses mData[0] to pick the bucket
			// overwrite mData[0] so that it ranges from 0 to 255
			// to create a sparse map
			id.mData[0] = i; 
			UUIDTableEntry entry(id, i);
			hashTable.set(id, entry);
			idList[i] = id;
		}

		hashIter.first();
		int numElementsIterated = 0;
		while(!hashIter.done())
		{
			numElementsIterated++;
			UUIDTableEntry tableEntry = *hashIter;
			LLUUID id = tableEntry.getID();
			hashIter.next();
			ensure("Iteration failed for sparse map", tableEntry.getValue() < (size_t)numElementsToCheck && idList[tableEntry.getValue()] ==  tableEntry.getID());
		}

		ensure("iteration count failed", numElementsIterated == numElementsToCheck);
	}

	// remove after middle of iteration
	template<> template<>
	void hash_index_object_t::test<7>()
	{
		LLUUIDHashMap<UUIDTableEntry, 2>	hashTable(UUIDTableEntry::uuidEq, UUIDTableEntry());
		LLUUIDHashMapIter<UUIDTableEntry, 2> hashIter(&hashTable);
		const int numElementsToCheck = 256;
		std::vector<LLUUID> idList(numElementsToCheck);
		int i;
		
		LLUUID uuidtoSearch;
		for (i = 0; i < numElementsToCheck; i++)
		{
			LLUUID id;
			id.generate();
			// LLUUIDHashMap uses mData[0] to pick the bucket
			// overwrite mData[0] so that it ranges from 0 to 255
			// to create a sparse map
			id.mData[0] = i; 
			UUIDTableEntry entry(id, i);
			hashTable.set(id, entry);
			idList[i] = id;

			// pick uuid somewhere in the middle
			if (i == 5)
			{
				uuidtoSearch = id;
			}
		}

		hashIter.first();
		int numElementsIterated = 0;
		while(!hashIter.done())
		{
			numElementsIterated++;
			UUIDTableEntry tableEntry = *hashIter;
			LLUUID id = tableEntry.getID();
			if (uuidtoSearch == id)
			{
				break;
			}
			hashIter.next();
		}

		// current iterator implementation will not allow any remove operations
		// until ALL elements have been iterated over. this seems to be 
		// an unnecessary restriction. Iterator should have a method to
		// reset() its state so that further operations (inckuding remove)
		// can be performed on the HashMap without having to iterate thru 
		// all the remaining nodes. 
		
//		 hashIter.reset();
//		 hashTable.remove(uuidtoSearch);
//		 ensure("remove after iteration reset failed", hashTable.check(uuidtoSearch) == FALSE);
	}
}