base/containers/hash_tables.h - platform/external/chromium_org - Git at Google

 // Copyright (c) 2011 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.
 //

 //
 // Deal with the differences between Microsoft and GNU implemenations
 // of hash_map. Allows all platforms to use |base::hash_map| and
 // |base::hash_set|.
 //  eg:
 //   base::hash_map<int> my_map;
 //   base::hash_set<int> my_set;
 //
 // NOTE: It is an explicit non-goal of this class to provide a generic hash
 // function for pointers.  If you want to hash a pointers to a particular class,
 // please define the template specialization elsewhere (for example, in its
 // header file) and keep it specific to just pointers to that class.  This is
 // because identity hashes are not desirable for all types that might show up
 // in containers as pointers.

 #ifndef BASE_CONTAINERS_HASH_TABLES_H_
 #define BASE_CONTAINERS_HASH_TABLES_H_

 #include <utility>

 #include "base/basictypes.h"
 #include "base/strings/string16.h"
 #include "build/build_config.h"

 #if defined(COMPILER_MSVC)
 #include <hash_map>
 #include <hash_set>

 #define BASE_HASH_NAMESPACE stdext

 #elif defined(COMPILER_GCC)
 #if defined(OS_ANDROID)
 #define BASE_HASH_NAMESPACE std
 #else
 #define BASE_HASH_NAMESPACE __gnu_cxx
 #endif

 // This is a hack to disable the gcc 4.4 warning about hash_map and hash_set
 // being deprecated.  We can get rid of this when we upgrade to VS2008 and we
 // can use <tr1/unordered_map> and <tr1/unordered_set>.
 #ifdef __DEPRECATED
 #define CHROME_OLD__DEPRECATED __DEPRECATED
 #undef __DEPRECATED
 #endif

 #if defined(OS_ANDROID)
 #include <hash_map>
 #include <hash_set>
 #else
 #include <ext/hash_map>
 #include <ext/hash_set>
 #endif

 #include <string>

 #ifdef CHROME_OLD__DEPRECATED
 #define __DEPRECATED CHROME_OLD__DEPRECATED
 #undef CHROME_OLD__DEPRECATED
 #endif

 namespace BASE_HASH_NAMESPACE {

 #if !defined(OS_ANDROID)
 // The GNU C++ library provides identity hash functions for many integral types,
 // but not for |long long|.  This hash function will truncate if |size_t| is
 // narrower than |long long|.  This is probably good enough for what we will
 // use it for.

 #define DEFINE_TRIVIAL_HASH(integral_type) \
     template<> \
     struct hash<integral_type> { \
       std::size_t operator()(integral_type value) const { \
         return static_cast<std::size_t>(value); \
       } \
     }

 DEFINE_TRIVIAL_HASH(long long);
 DEFINE_TRIVIAL_HASH(unsigned long long);

 #undef DEFINE_TRIVIAL_HASH
 #endif  // !defined(OS_ANDROID)

 // Implement string hash functions so that strings of various flavors can
 // be used as keys in STL maps and sets.  The hash algorithm comes from the
 // GNU C++ library, in <tr1/functional>.  It is duplicated here because GCC
 // versions prior to 4.3.2 are unable to compile <tr1/functional> when RTTI
 // is disabled, as it is in our build.

 #define DEFINE_STRING_HASH(string_type) \
     template<> \
     struct hash<string_type> { \
       std::size_t operator()(const string_type& s) const { \
         std::size_t result = 0; \
         for (string_type::const_iterator i = s.begin(); i != s.end(); ++i) \
           result = (result * 131) + *i; \
         return result; \
       } \
     }

 DEFINE_STRING_HASH(std::string);
 DEFINE_STRING_HASH(base::string16);

 #undef DEFINE_STRING_HASH

 }  // namespace BASE_HASH_NAMESPACE

 #else  // COMPILER
 #error define BASE_HASH_NAMESPACE for your compiler
 #endif  // COMPILER

 namespace base {
 using BASE_HASH_NAMESPACE::hash_map;
 using BASE_HASH_NAMESPACE::hash_multimap;
 using BASE_HASH_NAMESPACE::hash_multiset;
 using BASE_HASH_NAMESPACE::hash_set;

 // Implement hashing for pairs of at-most 32 bit integer values.
 // When size_t is 32 bits, we turn the 64-bit hash code into 32 bits by using
 // multiply-add hashing. This algorithm, as described in
 // Theorem 4.3.3 of the thesis "Über die Komplexität der Multiplikation in
 // eingeschränkten Branchingprogrammmodellen" by Woelfel, is:
 //
 //   h32(x32, y32) = (h64(x32, y32) * rand_odd64 + rand16 * 2^16) % 2^64 / 2^32
 //
 // Contact danakj@chromium.org for any questions.
 inline std::size_t HashInts32(uint32 value1, uint32 value2) {
   uint64 value1_64 = value1;
   uint64 hash64 = (value1_64 << 32) | value2;

   if (sizeof(std::size_t) >= sizeof(uint64))
     return static_cast<std::size_t>(hash64);

   uint64 odd_random = 481046412LL << 32 | 1025306955LL;
   uint32 shift_random = 10121U << 16;

   hash64 = hash64 * odd_random + shift_random;
   std::size_t high_bits = static_cast<std::size_t>(
       hash64 >> (8 * (sizeof(uint64) - sizeof(std::size_t))));
   return high_bits;
 }

 // Implement hashing for pairs of up-to 64-bit integer values.
 // We use the compound integer hash method to produce a 64-bit hash code, by
 // breaking the two 64-bit inputs into 4 32-bit values:
 // http://opendatastructures.org/versions/edition-0.1d/ods-java/node33.html#SECTION00832000000000000000
 // Then we reduce our result to 32 bits if required, similar to above.
 inline std::size_t HashInts64(uint64 value1, uint64 value2) {
   uint32 short_random1 = 842304669U;
   uint32 short_random2 = 619063811U;
   uint32 short_random3 = 937041849U;
   uint32 short_random4 = 3309708029U;

   uint32 value1a = static_cast<uint32>(value1 & 0xffffffff);
   uint32 value1b = static_cast<uint32>((value1 >> 32) & 0xffffffff);
   uint32 value2a = static_cast<uint32>(value2 & 0xffffffff);
   uint32 value2b = static_cast<uint32>((value2 >> 32) & 0xffffffff);

   uint64 product1 = static_cast<uint64>(value1a) * short_random1;
   uint64 product2 = static_cast<uint64>(value1b) * short_random2;
   uint64 product3 = static_cast<uint64>(value2a) * short_random3;
   uint64 product4 = static_cast<uint64>(value2b) * short_random4;

   uint64 hash64 = product1 + product2 + product3 + product4;

   if (sizeof(std::size_t) >= sizeof(uint64))
     return static_cast<std::size_t>(hash64);

   uint64 odd_random = 1578233944LL << 32 | 194370989LL;
   uint32 shift_random = 20591U << 16;

   hash64 = hash64 * odd_random + shift_random;
   std::size_t high_bits = static_cast<std::size_t>(
       hash64 >> (8 * (sizeof(uint64) - sizeof(std::size_t))));
   return high_bits;
 }

 #define DEFINE_32BIT_PAIR_HASH(Type1, Type2) \
 inline std::size_t HashPair(Type1 value1, Type2 value2) { \
   return HashInts32(value1, value2); \
 }

 DEFINE_32BIT_PAIR_HASH(int16, int16);
 DEFINE_32BIT_PAIR_HASH(int16, uint16);
 DEFINE_32BIT_PAIR_HASH(int16, int32);
 DEFINE_32BIT_PAIR_HASH(int16, uint32);
 DEFINE_32BIT_PAIR_HASH(uint16, int16);
 DEFINE_32BIT_PAIR_HASH(uint16, uint16);
 DEFINE_32BIT_PAIR_HASH(uint16, int32);
 DEFINE_32BIT_PAIR_HASH(uint16, uint32);
 DEFINE_32BIT_PAIR_HASH(int32, int16);
 DEFINE_32BIT_PAIR_HASH(int32, uint16);
 DEFINE_32BIT_PAIR_HASH(int32, int32);
 DEFINE_32BIT_PAIR_HASH(int32, uint32);
 DEFINE_32BIT_PAIR_HASH(uint32, int16);
 DEFINE_32BIT_PAIR_HASH(uint32, uint16);
 DEFINE_32BIT_PAIR_HASH(uint32, int32);
 DEFINE_32BIT_PAIR_HASH(uint32, uint32);

 #undef DEFINE_32BIT_PAIR_HASH

 #define DEFINE_64BIT_PAIR_HASH(Type1, Type2) \
 inline std::size_t HashPair(Type1 value1, Type2 value2) { \
   return HashInts64(value1, value2); \
 }

 DEFINE_64BIT_PAIR_HASH(int16, int64);
 DEFINE_64BIT_PAIR_HASH(int16, uint64);
 DEFINE_64BIT_PAIR_HASH(uint16, int64);
 DEFINE_64BIT_PAIR_HASH(uint16, uint64);
 DEFINE_64BIT_PAIR_HASH(int32, int64);
 DEFINE_64BIT_PAIR_HASH(int32, uint64);
 DEFINE_64BIT_PAIR_HASH(uint32, int64);
 DEFINE_64BIT_PAIR_HASH(uint32, uint64);
 DEFINE_64BIT_PAIR_HASH(int64, int16);
 DEFINE_64BIT_PAIR_HASH(int64, uint16);
 DEFINE_64BIT_PAIR_HASH(int64, int32);
 DEFINE_64BIT_PAIR_HASH(int64, uint32);
 DEFINE_64BIT_PAIR_HASH(int64, int64);
 DEFINE_64BIT_PAIR_HASH(int64, uint64);
 DEFINE_64BIT_PAIR_HASH(uint64, int16);
 DEFINE_64BIT_PAIR_HASH(uint64, uint16);
 DEFINE_64BIT_PAIR_HASH(uint64, int32);
 DEFINE_64BIT_PAIR_HASH(uint64, uint32);
 DEFINE_64BIT_PAIR_HASH(uint64, int64);
 DEFINE_64BIT_PAIR_HASH(uint64, uint64);

 #undef DEFINE_64BIT_PAIR_HASH
 }  // namespace base

 namespace BASE_HASH_NAMESPACE {

 // Implement methods for hashing a pair of integers, so they can be used as
 // keys in STL containers.

 #if defined(COMPILER_MSVC)

 template<typename Type1, typename Type2>
 inline std::size_t hash_value(const std::pair<Type1, Type2>& value) {
   return base::HashPair(value.first, value.second);
 }

 #elif defined(COMPILER_GCC)
 template<typename Type1, typename Type2>
 struct hash<std::pair<Type1, Type2> > {
   std::size_t operator()(std::pair<Type1, Type2> value) const {
     return base::HashPair(value.first, value.second);
   }
 };

 #else
 #error define hash<std::pair<Type1, Type2> > for your compiler
 #endif  // COMPILER

 }

 #undef DEFINE_PAIR_HASH_FUNCTION_START
 #undef DEFINE_PAIR_HASH_FUNCTION_END

 #endif  // BASE_CONTAINERS_HASH_TABLES_H_
	// Copyright (c) 2011 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.
	//

	//
	// Deal with the differences between Microsoft and GNU implemenations
	// of hash_map. Allows all platforms to use \|base::hash_map\| and
	// \|base::hash_set\|.
	// eg:
	// base::hash_map<int> my_map;
	// base::hash_set<int> my_set;
	//
	// NOTE: It is an explicit non-goal of this class to provide a generic hash
	// function for pointers. If you want to hash a pointers to a particular class,
	// please define the template specialization elsewhere (for example, in its
	// header file) and keep it specific to just pointers to that class. This is
	// because identity hashes are not desirable for all types that might show up
	// in containers as pointers.

	#ifndef BASE_CONTAINERS_HASH_TABLES_H_
	#define BASE_CONTAINERS_HASH_TABLES_H_

	#include <utility>

	#include "base/basictypes.h"
	#include "base/strings/string16.h"
	#include "build/build_config.h"

	#if defined(COMPILER_MSVC)
	#include <hash_map>
	#include <hash_set>

	#define BASE_HASH_NAMESPACE stdext

	#elif defined(COMPILER_GCC)
	#if defined(OS_ANDROID)
	#define BASE_HASH_NAMESPACE std
	#else
	#define BASE_HASH_NAMESPACE __gnu_cxx
	#endif

	// This is a hack to disable the gcc 4.4 warning about hash_map and hash_set
	// being deprecated. We can get rid of this when we upgrade to VS2008 and we
	// can use <tr1/unordered_map> and <tr1/unordered_set>.
	#ifdef __DEPRECATED
	#define CHROME_OLD__DEPRECATED __DEPRECATED
	#undef __DEPRECATED
	#endif

	#if defined(OS_ANDROID)
	#include <hash_map>
	#include <hash_set>
	#else
	#include <ext/hash_map>
	#include <ext/hash_set>
	#endif

	#include <string>

	#ifdef CHROME_OLD__DEPRECATED
	#define __DEPRECATED CHROME_OLD__DEPRECATED
	#undef CHROME_OLD__DEPRECATED
	#endif

	namespace BASE_HASH_NAMESPACE {

	#if !defined(OS_ANDROID)
	// The GNU C++ library provides identity hash functions for many integral types,
	// but not for \|long long\|. This hash function will truncate if \|size_t\| is
	// narrower than \|long long\|. This is probably good enough for what we will
	// use it for.

	#define DEFINE_TRIVIAL_HASH(integral_type) \
	template<> \
	struct hash<integral_type> { \
	std::size_t operator()(integral_type value) const { \
	return static_cast<std::size_t>(value); \
	} \
	}

	DEFINE_TRIVIAL_HASH(long long);
	DEFINE_TRIVIAL_HASH(unsigned long long);

	#undef DEFINE_TRIVIAL_HASH
	#endif // !defined(OS_ANDROID)

	// Implement string hash functions so that strings of various flavors can
	// be used as keys in STL maps and sets. The hash algorithm comes from the
	// GNU C++ library, in <tr1/functional>. It is duplicated here because GCC
	// versions prior to 4.3.2 are unable to compile <tr1/functional> when RTTI
	// is disabled, as it is in our build.

	#define DEFINE_STRING_HASH(string_type) \
	template<> \
	struct hash<string_type> { \
	std::size_t operator()(const string_type& s) const { \
	std::size_t result = 0; \
	for (string_type::const_iterator i = s.begin(); i != s.end(); ++i) \
	result = (result * 131) + *i; \
	return result; \
	} \
	}

	DEFINE_STRING_HASH(std::string);
	DEFINE_STRING_HASH(base::string16);

	#undef DEFINE_STRING_HASH

	} // namespace BASE_HASH_NAMESPACE

	#else // COMPILER
	#error define BASE_HASH_NAMESPACE for your compiler
	#endif // COMPILER

	namespace base {
	using BASE_HASH_NAMESPACE::hash_map;
	using BASE_HASH_NAMESPACE::hash_multimap;
	using BASE_HASH_NAMESPACE::hash_multiset;
	using BASE_HASH_NAMESPACE::hash_set;

	// Implement hashing for pairs of at-most 32 bit integer values.
	// When size_t is 32 bits, we turn the 64-bit hash code into 32 bits by using
	// multiply-add hashing. This algorithm, as described in
	// Theorem 4.3.3 of the thesis "Über die Komplexität der Multiplikation in
	// eingeschränkten Branchingprogrammmodellen" by Woelfel, is:
	//
	// h32(x32, y32) = (h64(x32, y32) * rand_odd64 + rand16 * 2^16) % 2^64 / 2^32
	//
	// Contact danakj@chromium.org for any questions.
	inline std::size_t HashInts32(uint32 value1, uint32 value2) {
	uint64 value1_64 = value1;
	uint64 hash64 = (value1_64 << 32) \| value2;

	if (sizeof(std::size_t) >= sizeof(uint64))
	return static_cast<std::size_t>(hash64);

	uint64 odd_random = 481046412LL << 32 \| 1025306955LL;
	uint32 shift_random = 10121U << 16;

	hash64 = hash64 * odd_random + shift_random;
	std::size_t high_bits = static_cast<std::size_t>(
	hash64 >> (8 * (sizeof(uint64) - sizeof(std::size_t))));
	return high_bits;
	}

	// Implement hashing for pairs of up-to 64-bit integer values.
	// We use the compound integer hash method to produce a 64-bit hash code, by
	// breaking the two 64-bit inputs into 4 32-bit values:
	// http://opendatastructures.org/versions/edition-0.1d/ods-java/node33.html#SECTION00832000000000000000
	// Then we reduce our result to 32 bits if required, similar to above.
	inline std::size_t HashInts64(uint64 value1, uint64 value2) {
	uint32 short_random1 = 842304669U;
	uint32 short_random2 = 619063811U;
	uint32 short_random3 = 937041849U;
	uint32 short_random4 = 3309708029U;

	uint32 value1a = static_cast<uint32>(value1 & 0xffffffff);
	uint32 value1b = static_cast<uint32>((value1 >> 32) & 0xffffffff);
	uint32 value2a = static_cast<uint32>(value2 & 0xffffffff);
	uint32 value2b = static_cast<uint32>((value2 >> 32) & 0xffffffff);

	uint64 product1 = static_cast<uint64>(value1a) * short_random1;
	uint64 product2 = static_cast<uint64>(value1b) * short_random2;
	uint64 product3 = static_cast<uint64>(value2a) * short_random3;
	uint64 product4 = static_cast<uint64>(value2b) * short_random4;

	uint64 hash64 = product1 + product2 + product3 + product4;

	if (sizeof(std::size_t) >= sizeof(uint64))
	return static_cast<std::size_t>(hash64);

	uint64 odd_random = 1578233944LL << 32 \| 194370989LL;
	uint32 shift_random = 20591U << 16;

	hash64 = hash64 * odd_random + shift_random;
	std::size_t high_bits = static_cast<std::size_t>(
	hash64 >> (8 * (sizeof(uint64) - sizeof(std::size_t))));
	return high_bits;
	}

	#define DEFINE_32BIT_PAIR_HASH(Type1, Type2) \
	inline std::size_t HashPair(Type1 value1, Type2 value2) { \
	return HashInts32(value1, value2); \
	}

	DEFINE_32BIT_PAIR_HASH(int16, int16);
	DEFINE_32BIT_PAIR_HASH(int16, uint16);
	DEFINE_32BIT_PAIR_HASH(int16, int32);
	DEFINE_32BIT_PAIR_HASH(int16, uint32);
	DEFINE_32BIT_PAIR_HASH(uint16, int16);
	DEFINE_32BIT_PAIR_HASH(uint16, uint16);
	DEFINE_32BIT_PAIR_HASH(uint16, int32);
	DEFINE_32BIT_PAIR_HASH(uint16, uint32);
	DEFINE_32BIT_PAIR_HASH(int32, int16);
	DEFINE_32BIT_PAIR_HASH(int32, uint16);
	DEFINE_32BIT_PAIR_HASH(int32, int32);
	DEFINE_32BIT_PAIR_HASH(int32, uint32);
	DEFINE_32BIT_PAIR_HASH(uint32, int16);
	DEFINE_32BIT_PAIR_HASH(uint32, uint16);
	DEFINE_32BIT_PAIR_HASH(uint32, int32);
	DEFINE_32BIT_PAIR_HASH(uint32, uint32);

	#undef DEFINE_32BIT_PAIR_HASH

	#define DEFINE_64BIT_PAIR_HASH(Type1, Type2) \
	inline std::size_t HashPair(Type1 value1, Type2 value2) { \
	return HashInts64(value1, value2); \
	}

	DEFINE_64BIT_PAIR_HASH(int16, int64);
	DEFINE_64BIT_PAIR_HASH(int16, uint64);
	DEFINE_64BIT_PAIR_HASH(uint16, int64);
	DEFINE_64BIT_PAIR_HASH(uint16, uint64);
	DEFINE_64BIT_PAIR_HASH(int32, int64);
	DEFINE_64BIT_PAIR_HASH(int32, uint64);
	DEFINE_64BIT_PAIR_HASH(uint32, int64);
	DEFINE_64BIT_PAIR_HASH(uint32, uint64);
	DEFINE_64BIT_PAIR_HASH(int64, int16);
	DEFINE_64BIT_PAIR_HASH(int64, uint16);
	DEFINE_64BIT_PAIR_HASH(int64, int32);
	DEFINE_64BIT_PAIR_HASH(int64, uint32);
	DEFINE_64BIT_PAIR_HASH(int64, int64);
	DEFINE_64BIT_PAIR_HASH(int64, uint64);
	DEFINE_64BIT_PAIR_HASH(uint64, int16);
	DEFINE_64BIT_PAIR_HASH(uint64, uint16);
	DEFINE_64BIT_PAIR_HASH(uint64, int32);
	DEFINE_64BIT_PAIR_HASH(uint64, uint32);
	DEFINE_64BIT_PAIR_HASH(uint64, int64);
	DEFINE_64BIT_PAIR_HASH(uint64, uint64);

	#undef DEFINE_64BIT_PAIR_HASH
	} // namespace base

	namespace BASE_HASH_NAMESPACE {

	// Implement methods for hashing a pair of integers, so they can be used as
	// keys in STL containers.

	#if defined(COMPILER_MSVC)

	template<typename Type1, typename Type2>
	inline std::size_t hash_value(const std::pair<Type1, Type2>& value) {
	return base::HashPair(value.first, value.second);
	}

	#elif defined(COMPILER_GCC)
	template<typename Type1, typename Type2>
	struct hash<std::pair<Type1, Type2> > {
	std::size_t operator()(std::pair<Type1, Type2> value) const {
	return base::HashPair(value.first, value.second);
	}
	};

	#else
	#error define hash<std::pair<Type1, Type2> > for your compiler
	#endif // COMPILER

	}

	#undef DEFINE_PAIR_HASH_FUNCTION_START
	#undef DEFINE_PAIR_HASH_FUNCTION_END

	#endif // BASE_CONTAINERS_HASH_TABLES_H_