src/base/basictypes.h - chromium/src - Git at Google

 // Copyright (c) 2006-2008 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.

 #ifndef BASE_BASICTYPES_H_
 #define BASE_BASICTYPES_H_

 #include <assert.h>         // for use with down_cast<>
 #include <limits.h>         // So we can set the bounds of our types
 #include <stddef.h>         // For size_t
 #include <string.h>         // for memcpy

 #include "base/port.h"    // Types that only need exist on certain systems

 #ifndef COMPILER_MSVC
 // stdint.h is part of C99 but MSVC doesn't have it.
 #include <stdint.h>         // For intptr_t.
 #endif

 typedef signed char         schar;
 typedef signed char         int8;
 typedef short               int16;
 // TODO(mbelshe) Remove these type guards.  These are
 //               temporary to avoid conflicts with npapi.h.
 #ifndef _INT32
 #define _INT32
 typedef int                 int32;
 #endif
 typedef long long           int64;

 // NOTE: unsigned types are DANGEROUS in loops and other arithmetical
 // places.  Use the signed types unless your variable represents a bit
 // pattern (eg a hash value) or you really need the extra bit.  Do NOT
 // use 'unsigned' to express "this value should always be positive";
 // use assertions for this.

 typedef unsigned char      uint8;
 typedef unsigned short     uint16;
 // TODO(mbelshe) Remove these type guards.  These are
 //               temporary to avoid conflicts with npapi.h.
 #ifndef _UINT32
 #define _UINT32
 typedef unsigned int       uint32;
 #endif
 typedef unsigned long long uint64;

 // A type to represent a Unicode code-point value. As of Unicode 4.0,
 // such values require up to 21 bits.
 // (For type-checking on pointers, make this explicitly signed,
 // and it should always be the signed version of whatever int32 is.)
 typedef signed int         char32;

 const uint8  kuint8max  = (( uint8) 0xFF);
 const uint16 kuint16max = ((uint16) 0xFFFF);
 const uint32 kuint32max = ((uint32) 0xFFFFFFFF);
 const uint64 kuint64max = ((uint64) GG_LONGLONG(0xFFFFFFFFFFFFFFFF));
 const  int8  kint8min   = ((  int8) 0x80);
 const  int8  kint8max   = ((  int8) 0x7F);
 const  int16 kint16min  = (( int16) 0x8000);
 const  int16 kint16max  = (( int16) 0x7FFF);
 const  int32 kint32min  = (( int32) 0x80000000);
 const  int32 kint32max  = (( int32) 0x7FFFFFFF);
 const  int64 kint64min  = (( int64) GG_LONGLONG(0x8000000000000000));
 const  int64 kint64max  = (( int64) GG_LONGLONG(0x7FFFFFFFFFFFFFFF));

 // id for odp categories
 typedef uint32 CatId;
 const CatId kIllegalCatId = static_cast<CatId>(0);

 typedef uint32 TermId;
 const TermId kIllegalTermId = static_cast<TermId>(0);

 typedef uint32 HostId;
 const HostId kIllegalHostId = static_cast<HostId>(0);

 typedef uint32 DomainId;
 const DomainId kIllegalDomainId = static_cast<DomainId>(0);

 // A macro to disallow the copy constructor and operator= functions
 // This should be used in the private: declarations for a class
 #define DISALLOW_COPY_AND_ASSIGN(TypeName) \
   TypeName(const TypeName&);               \
   void operator=(const TypeName&)

 // An older, deprecated, politically incorrect name for the above.
 #define DISALLOW_EVIL_CONSTRUCTORS(TypeName) DISALLOW_COPY_AND_ASSIGN(TypeName)

 // A macro to disallow all the implicit constructors, namely the
 // default constructor, copy constructor and operator= functions.
 //
 // This should be used in the private: declarations for a class
 // that wants to prevent anyone from instantiating it. This is
 // especially useful for classes containing only static methods.
 #define DISALLOW_IMPLICIT_CONSTRUCTORS(TypeName) \
   TypeName();                                    \
   DISALLOW_COPY_AND_ASSIGN(TypeName)

 // The arraysize(arr) macro returns the # of elements in an array arr.
 // The expression is a compile-time constant, and therefore can be
 // used in defining new arrays, for example.  If you use arraysize on
 // a pointer by mistake, you will get a compile-time error.
 //
 // One caveat is that arraysize() doesn't accept any array of an
 // anonymous type or a type defined inside a function.  In these rare
 // cases, you have to use the unsafe ARRAYSIZE_UNSAFE() macro below.  This is
 // due to a limitation in C++'s template system.  The limitation might
 // eventually be removed, but it hasn't happened yet.

 // This template function declaration is used in defining arraysize.
 // Note that the function doesn't need an implementation, as we only
 // use its type.
 template <typename T, size_t N>
 char (&ArraySizeHelper(T (&array)[N]))[N];

 // That gcc wants both of these prototypes seems mysterious. VC, for
 // its part, can't decide which to use (another mystery). Matching of
 // template overloads: the final frontier.
 #ifndef _MSC_VER
 template <typename T, size_t N>
 char (&ArraySizeHelper(const T (&array)[N]))[N];
 #endif

 #define arraysize(array) (sizeof(ArraySizeHelper(array)))

 // ARRAYSIZE_UNSAFE performs essentially the same calculation as arraysize,
 // but can be used on anonymous types or types defined inside
 // functions.  It's less safe than arraysize as it accepts some
 // (although not all) pointers.  Therefore, you should use arraysize
 // whenever possible.
 //
 // The expression ARRAYSIZE_UNSAFE(a) is a compile-time constant of type
 // size_t.
 //
 // ARRAYSIZE_UNSAFE catches a few type errors.  If you see a compiler error
 //
 //   "warning: division by zero in ..."
 //
 // when using ARRAYSIZE_UNSAFE, you are (wrongfully) giving it a pointer.
 // You should only use ARRAYSIZE_UNSAFE on statically allocated arrays.
 //
 // The following comments are on the implementation details, and can
 // be ignored by the users.
 //
 // ARRAYSIZE_UNSAFE(arr) works by inspecting sizeof(arr) (the # of bytes in
 // the array) and sizeof(*(arr)) (the # of bytes in one array
 // element).  If the former is divisible by the latter, perhaps arr is
 // indeed an array, in which case the division result is the # of
 // elements in the array.  Otherwise, arr cannot possibly be an array,
 // and we generate a compiler error to prevent the code from
 // compiling.
 //
 // Since the size of bool is implementation-defined, we need to cast
 // !(sizeof(a) & sizeof(*(a))) to size_t in order to ensure the final
 // result has type size_t.
 //
 // This macro is not perfect as it wrongfully accepts certain
 // pointers, namely where the pointer size is divisible by the pointee
 // size.  Since all our code has to go through a 32-bit compiler,
 // where a pointer is 4 bytes, this means all pointers to a type whose
 // size is 3 or greater than 4 will be (righteously) rejected.

 #define ARRAYSIZE_UNSAFE(a) \
   ((sizeof(a) / sizeof(*(a))) / \
    static_cast<size_t>(!(sizeof(a) % sizeof(*(a)))))


 // Use implicit_cast as a safe version of static_cast or const_cast
 // for upcasting in the type hierarchy (i.e. casting a pointer to Foo
 // to a pointer to SuperclassOfFoo or casting a pointer to Foo to
 // a const pointer to Foo).
 // When you use implicit_cast, the compiler checks that the cast is safe.
 // Such explicit implicit_casts are necessary in surprisingly many
 // situations where C++ demands an exact type match instead of an
 // argument type convertable to a target type.
 //
 // The From type can be inferred, so the preferred syntax for using
 // implicit_cast is the same as for static_cast etc.:
 //
 //   implicit_cast<ToType>(expr)
 //
 // implicit_cast would have been part of the C++ standard library,
 // but the proposal was submitted too late.  It will probably make
 // its way into the language in the future.
 template<typename To, typename From>
 inline To implicit_cast(From const &f) {
   return f;
 }


 // When you upcast (that is, cast a pointer from type Foo to type
 // SuperclassOfFoo), it's fine to use implicit_cast<>, since upcasts
 // always succeed.  When you downcast (that is, cast a pointer from
 // type Foo to type SubclassOfFoo), static_cast<> isn't safe, because
 // how do you know the pointer is really of type SubclassOfFoo?  It
 // could be a bare Foo, or of type DifferentSubclassOfFoo.  Thus,
 // when you downcast, you should use this macro.  In debug mode, we
 // use dynamic_cast<> to double-check the downcast is legal (we die
 // if it's not).  In normal mode, we do the efficient static_cast<>
 // instead.  Thus, it's important to test in debug mode to make sure
 // the cast is legal!
 //    This is the only place in the code we should use dynamic_cast<>.
 // In particular, you SHOULDN'T be using dynamic_cast<> in order to
 // do RTTI (eg code like this:
 //    if (dynamic_cast<Subclass1>(foo)) HandleASubclass1Object(foo);
 //    if (dynamic_cast<Subclass2>(foo)) HandleASubclass2Object(foo);
 // You should design the code some other way not to need this.

 template<typename To, typename From>     // use like this: down_cast<T*>(foo);
 inline To down_cast(From* f) {                   // so we only accept pointers
   // Ensures that To is a sub-type of From *.  This test is here only
   // for compile-time type checking, and has no overhead in an
   // optimized build at run-time, as it will be optimized away
   // completely.
   if (false) {
     implicit_cast<From*, To>(0);
   }

   assert(f == NULL || dynamic_cast<To>(f) != NULL);  // RTTI: debug mode only!
   return static_cast<To>(f);
 }

 // The COMPILE_ASSERT macro can be used to verify that a compile time
 // expression is true. For example, you could use it to verify the
 // size of a static array:
 //
 //   COMPILE_ASSERT(ARRAYSIZE_UNSAFE(content_type_names) == CONTENT_NUM_TYPES,
 //                  content_type_names_incorrect_size);
 //
 // or to make sure a struct is smaller than a certain size:
 //
 //   COMPILE_ASSERT(sizeof(foo) < 128, foo_too_large);
 //
 // The second argument to the macro is the name of the variable. If
 // the expression is false, most compilers will issue a warning/error
 // containing the name of the variable.

 template <bool>
 struct CompileAssert {
 };

 #undef COMPILE_ASSERT
 #define COMPILE_ASSERT(expr, msg) \
   typedef CompileAssert<(bool(expr))> msg[bool(expr) ? 1 : -1]

 // Implementation details of COMPILE_ASSERT:
 //
 // - COMPILE_ASSERT works by defining an array type that has -1
 //   elements (and thus is invalid) when the expression is false.
 //
 // - The simpler definition
 //
 //     #define COMPILE_ASSERT(expr, msg) typedef char msg[(expr) ? 1 : -1]
 //
 //   does not work, as gcc supports variable-length arrays whose sizes
 //   are determined at run-time (this is gcc's extension and not part
 //   of the C++ standard).  As a result, gcc fails to reject the
 //   following code with the simple definition:
 //
 //     int foo;
 //     COMPILE_ASSERT(foo, msg); // not supposed to compile as foo is
 //                               // not a compile-time constant.
 //
 // - By using the type CompileAssert<(bool(expr))>, we ensures that
 //   expr is a compile-time constant.  (Template arguments must be
 //   determined at compile-time.)
 //
 // - The outter parentheses in CompileAssert<(bool(expr))> are necessary
 //   to work around a bug in gcc 3.4.4 and 4.0.1.  If we had written
 //
 //     CompileAssert<bool(expr)>
 //
 //   instead, these compilers will refuse to compile
 //
 //     COMPILE_ASSERT(5 > 0, some_message);
 //
 //   (They seem to think the ">" in "5 > 0" marks the end of the
 //   template argument list.)
 //
 // - The array size is (bool(expr) ? 1 : -1), instead of simply
 //
 //     ((expr) ? 1 : -1).
 //
 //   This is to avoid running into a bug in MS VC 7.1, which
 //   causes ((0.0) ? 1 : -1) to incorrectly evaluate to 1.


 // MetatagId refers to metatag-id that we assign to
 // each metatag <name, value> pair..
 typedef uint32 MetatagId;

 // Argument type used in interfaces that can optionally take ownership
 // of a passed in argument.  If TAKE_OWNERSHIP is passed, the called
 // object takes ownership of the argument.  Otherwise it does not.
 enum Ownership {
   DO_NOT_TAKE_OWNERSHIP,
   TAKE_OWNERSHIP
 };

 // Use these as the mlock_bytes parameter to MLock and MLockGeneral
 enum { MLOCK_ALL = -1, MLOCK_NONE = 0 };

 // Helper routine to avoid buggy code like the following:
 //      if (pos + N < end) ...
 // If pos is large enough, "pos + N" may overflow.  For example,
 // pos==0xfffff000 and N==1MB.
 //
 // PointerRangeSize(a,b) returns the size of the range [a,b-1]
 inline size_t PointerRangeSize(const char* start, const char* end) {
   assert(start <= end);
   return end - start;
 }

 // bit_cast<Dest,Source> is a template function that implements the
 // equivalent of "*reinterpret_cast<Dest*>(&source)".  We need this in
 // very low-level functions like the protobuf library and fast math
 // support.
 //
 //   float f = 3.14159265358979;
 //   int i = bit_cast<int32>(f);
 //   // i = 0x40490fdb
 //
 // The classical address-casting method is:
 //
 //   // WRONG
 //   float f = 3.14159265358979;            // WRONG
 //   int i = * reinterpret_cast<int*>(&f);  // WRONG
 //
 // The address-casting method actually produces undefined behavior
 // according to ISO C++ specification section 3.10 -15 -.  Roughly, this
 // section says: if an object in memory has one type, and a program
 // accesses it with a different type, then the result is undefined
 // behavior for most values of "different type".
 //
 // This is true for any cast syntax, either *(int*)&f or
 // *reinterpret_cast<int*>(&f).  And it is particularly true for
 // conversions betweeen integral lvalues and floating-point lvalues.
 //
 // The purpose of 3.10 -15- is to allow optimizing compilers to assume
 // that expressions with different types refer to different memory.  gcc
 // 4.0.1 has an optimizer that takes advantage of this.  So a
 // non-conforming program quietly produces wildly incorrect output.
 //
 // The problem is not the use of reinterpret_cast.  The problem is type
 // punning: holding an object in memory of one type and reading its bits
 // back using a different type.
 //
 // The C++ standard is more subtle and complex than this, but that
 // is the basic idea.
 //
 // Anyways ...
 //
 // bit_cast<> calls memcpy() which is blessed by the standard,
 // especially by the example in section 3.9 .  Also, of course,
 // bit_cast<> wraps up the nasty logic in one place.
 //
 // Fortunately memcpy() is very fast.  In optimized mode, with a
 // constant size, gcc 2.95.3, gcc 4.0.1, and msvc 7.1 produce inline
 // code with the minimal amount of data movement.  On a 32-bit system,
 // memcpy(d,s,4) compiles to one load and one store, and memcpy(d,s,8)
 // compiles to two loads and two stores.
 //
 // I tested this code with gcc 2.95.3, gcc 4.0.1, icc 8.1, and msvc 7.1.
 //
 // WARNING: if Dest or Source is a non-POD type, the result of the memcpy
 // is likely to surprise you.

 template <class Dest, class Source>
 inline Dest bit_cast(const Source& source) {
   // Compile time assertion: sizeof(Dest) == sizeof(Source)
   // A compile error here means your Dest and Source have different sizes.
   typedef char VerifySizesAreEqual [sizeof(Dest) == sizeof(Source) ? 1 : -1];

   Dest dest;
   memcpy(&dest, &source, sizeof(dest));
   return dest;
 }

 // The following enum should be used only as a constructor argument to indicate
 // that the variable has static storage class, and that the constructor should
 // do nothing to its state.  It indicates to the reader that it is legal to
 // declare a static instance of the class, provided the constructor is given
 // the base::LINKER_INITIALIZED argument.  Normally, it is unsafe to declare a
 // static variable that has a constructor or a destructor because invocation
 // order is undefined.  However, IF the type can be initialized by filling with
 // zeroes (which the loader does for static variables), AND the destructor also
 // does nothing to the storage, AND there are no virtual methods, then a
 // constructor declared as
 //       explicit MyClass(base::LinkerInitialized x) {}
 // and invoked as
 //       static MyClass my_variable_name(base::LINKER_INITIALIZED);
 namespace base {
 enum LinkerInitialized { LINKER_INITIALIZED };
 }  // base


 #endif  // BASE_BASICTYPES_H_
	// Copyright (c) 2006-2008 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.

	#ifndef BASE_BASICTYPES_H_
	#define BASE_BASICTYPES_H_

	#include <assert.h> // for use with down_cast<>
	#include <limits.h> // So we can set the bounds of our types
	#include <stddef.h> // For size_t
	#include <string.h> // for memcpy

	#include "base/port.h" // Types that only need exist on certain systems

	#ifndef COMPILER_MSVC
	// stdint.h is part of C99 but MSVC doesn't have it.
	#include <stdint.h> // For intptr_t.
	#endif

	typedef signed char schar;
	typedef signed char int8;
	typedef short int16;
	// TODO(mbelshe) Remove these type guards. These are
	// temporary to avoid conflicts with npapi.h.
	#ifndef _INT32
	#define _INT32
	typedef int int32;
	#endif
	typedef long long int64;

	// NOTE: unsigned types are DANGEROUS in loops and other arithmetical
	// places. Use the signed types unless your variable represents a bit
	// pattern (eg a hash value) or you really need the extra bit. Do NOT
	// use 'unsigned' to express "this value should always be positive";
	// use assertions for this.

	typedef unsigned char uint8;
	typedef unsigned short uint16;
	// TODO(mbelshe) Remove these type guards. These are
	// temporary to avoid conflicts with npapi.h.
	#ifndef _UINT32
	#define _UINT32
	typedef unsigned int uint32;
	#endif
	typedef unsigned long long uint64;

	// A type to represent a Unicode code-point value. As of Unicode 4.0,
	// such values require up to 21 bits.
	// (For type-checking on pointers, make this explicitly signed,
	// and it should always be the signed version of whatever int32 is.)
	typedef signed int char32;

	const uint8 kuint8max = (( uint8) 0xFF);
	const uint16 kuint16max = ((uint16) 0xFFFF);
	const uint32 kuint32max = ((uint32) 0xFFFFFFFF);
	const uint64 kuint64max = ((uint64) GG_LONGLONG(0xFFFFFFFFFFFFFFFF));
	const int8 kint8min = (( int8) 0x80);
	const int8 kint8max = (( int8) 0x7F);
	const int16 kint16min = (( int16) 0x8000);
	const int16 kint16max = (( int16) 0x7FFF);
	const int32 kint32min = (( int32) 0x80000000);
	const int32 kint32max = (( int32) 0x7FFFFFFF);
	const int64 kint64min = (( int64) GG_LONGLONG(0x8000000000000000));
	const int64 kint64max = (( int64) GG_LONGLONG(0x7FFFFFFFFFFFFFFF));

	// id for odp categories
	typedef uint32 CatId;
	const CatId kIllegalCatId = static_cast<CatId>(0);

	typedef uint32 TermId;
	const TermId kIllegalTermId = static_cast<TermId>(0);

	typedef uint32 HostId;
	const HostId kIllegalHostId = static_cast<HostId>(0);

	typedef uint32 DomainId;
	const DomainId kIllegalDomainId = static_cast<DomainId>(0);

	// A macro to disallow the copy constructor and operator= functions
	// This should be used in the private: declarations for a class
	#define DISALLOW_COPY_AND_ASSIGN(TypeName) \
	TypeName(const TypeName&); \
	void operator=(const TypeName&)

	// An older, deprecated, politically incorrect name for the above.
	#define DISALLOW_EVIL_CONSTRUCTORS(TypeName) DISALLOW_COPY_AND_ASSIGN(TypeName)

	// A macro to disallow all the implicit constructors, namely the
	// default constructor, copy constructor and operator= functions.
	//
	// This should be used in the private: declarations for a class
	// that wants to prevent anyone from instantiating it. This is
	// especially useful for classes containing only static methods.
	#define DISALLOW_IMPLICIT_CONSTRUCTORS(TypeName) \
	TypeName(); \
	DISALLOW_COPY_AND_ASSIGN(TypeName)

	// The arraysize(arr) macro returns the # of elements in an array arr.
	// The expression is a compile-time constant, and therefore can be
	// used in defining new arrays, for example. If you use arraysize on
	// a pointer by mistake, you will get a compile-time error.
	//
	// One caveat is that arraysize() doesn't accept any array of an
	// anonymous type or a type defined inside a function. In these rare
	// cases, you have to use the unsafe ARRAYSIZE_UNSAFE() macro below. This is
	// due to a limitation in C++'s template system. The limitation might
	// eventually be removed, but it hasn't happened yet.

	// This template function declaration is used in defining arraysize.
	// Note that the function doesn't need an implementation, as we only
	// use its type.
	template <typename T, size_t N>
	char (&ArraySizeHelper(T (&array)[N]))[N];

	// That gcc wants both of these prototypes seems mysterious. VC, for
	// its part, can't decide which to use (another mystery). Matching of
	// template overloads: the final frontier.
	#ifndef _MSC_VER
	template <typename T, size_t N>
	char (&ArraySizeHelper(const T (&array)[N]))[N];
	#endif

	#define arraysize(array) (sizeof(ArraySizeHelper(array)))

	// ARRAYSIZE_UNSAFE performs essentially the same calculation as arraysize,
	// but can be used on anonymous types or types defined inside
	// functions. It's less safe than arraysize as it accepts some
	// (although not all) pointers. Therefore, you should use arraysize
	// whenever possible.
	//
	// The expression ARRAYSIZE_UNSAFE(a) is a compile-time constant of type
	// size_t.
	//
	// ARRAYSIZE_UNSAFE catches a few type errors. If you see a compiler error
	//
	// "warning: division by zero in ..."
	//
	// when using ARRAYSIZE_UNSAFE, you are (wrongfully) giving it a pointer.
	// You should only use ARRAYSIZE_UNSAFE on statically allocated arrays.
	//
	// The following comments are on the implementation details, and can
	// be ignored by the users.
	//
	// ARRAYSIZE_UNSAFE(arr) works by inspecting sizeof(arr) (the # of bytes in
	// the array) and sizeof(*(arr)) (the # of bytes in one array
	// element). If the former is divisible by the latter, perhaps arr is
	// indeed an array, in which case the division result is the # of
	// elements in the array. Otherwise, arr cannot possibly be an array,
	// and we generate a compiler error to prevent the code from
	// compiling.
	//
	// Since the size of bool is implementation-defined, we need to cast
	// !(sizeof(a) & sizeof(*(a))) to size_t in order to ensure the final
	// result has type size_t.
	//
	// This macro is not perfect as it wrongfully accepts certain
	// pointers, namely where the pointer size is divisible by the pointee
	// size. Since all our code has to go through a 32-bit compiler,
	// where a pointer is 4 bytes, this means all pointers to a type whose
	// size is 3 or greater than 4 will be (righteously) rejected.

	#define ARRAYSIZE_UNSAFE(a) \
	((sizeof(a) / sizeof(*(a))) / \
	static_cast<size_t>(!(sizeof(a) % sizeof(*(a)))))


	// Use implicit_cast as a safe version of static_cast or const_cast
	// for upcasting in the type hierarchy (i.e. casting a pointer to Foo
	// to a pointer to SuperclassOfFoo or casting a pointer to Foo to
	// a const pointer to Foo).
	// When you use implicit_cast, the compiler checks that the cast is safe.
	// Such explicit implicit_casts are necessary in surprisingly many
	// situations where C++ demands an exact type match instead of an
	// argument type convertable to a target type.
	//
	// The From type can be inferred, so the preferred syntax for using
	// implicit_cast is the same as for static_cast etc.:
	//
	// implicit_cast<ToType>(expr)
	//
	// implicit_cast would have been part of the C++ standard library,
	// but the proposal was submitted too late. It will probably make
	// its way into the language in the future.
	template<typename To, typename From>
	inline To implicit_cast(From const &f) {
	return f;
	}


	// When you upcast (that is, cast a pointer from type Foo to type
	// SuperclassOfFoo), it's fine to use implicit_cast<>, since upcasts
	// always succeed. When you downcast (that is, cast a pointer from
	// type Foo to type SubclassOfFoo), static_cast<> isn't safe, because
	// how do you know the pointer is really of type SubclassOfFoo? It
	// could be a bare Foo, or of type DifferentSubclassOfFoo. Thus,
	// when you downcast, you should use this macro. In debug mode, we
	// use dynamic_cast<> to double-check the downcast is legal (we die
	// if it's not). In normal mode, we do the efficient static_cast<>
	// instead. Thus, it's important to test in debug mode to make sure
	// the cast is legal!
	// This is the only place in the code we should use dynamic_cast<>.
	// In particular, you SHOULDN'T be using dynamic_cast<> in order to
	// do RTTI (eg code like this:
	// if (dynamic_cast<Subclass1>(foo)) HandleASubclass1Object(foo);
	// if (dynamic_cast<Subclass2>(foo)) HandleASubclass2Object(foo);
	// You should design the code some other way not to need this.

	template<typename To, typename From> // use like this: down_cast<T*>(foo);
	inline To down_cast(From* f) { // so we only accept pointers
	// Ensures that To is a sub-type of From *. This test is here only
	// for compile-time type checking, and has no overhead in an
	// optimized build at run-time, as it will be optimized away
	// completely.
	if (false) {
	implicit_cast<From*, To>(0);
	}

	assert(f == NULL \|\| dynamic_cast<To>(f) != NULL); // RTTI: debug mode only!
	return static_cast<To>(f);
	}

	// The COMPILE_ASSERT macro can be used to verify that a compile time
	// expression is true. For example, you could use it to verify the
	// size of a static array:
	//
	// COMPILE_ASSERT(ARRAYSIZE_UNSAFE(content_type_names) == CONTENT_NUM_TYPES,
	// content_type_names_incorrect_size);
	//
	// or to make sure a struct is smaller than a certain size:
	//
	// COMPILE_ASSERT(sizeof(foo) < 128, foo_too_large);
	//
	// The second argument to the macro is the name of the variable. If
	// the expression is false, most compilers will issue a warning/error
	// containing the name of the variable.

	template <bool>
	struct CompileAssert {
	};

	#undef COMPILE_ASSERT
	#define COMPILE_ASSERT(expr, msg) \
	typedef CompileAssert<(bool(expr))> msg[bool(expr) ? 1 : -1]

	// Implementation details of COMPILE_ASSERT:
	//
	// - COMPILE_ASSERT works by defining an array type that has -1
	// elements (and thus is invalid) when the expression is false.
	//
	// - The simpler definition
	//
	// #define COMPILE_ASSERT(expr, msg) typedef char msg[(expr) ? 1 : -1]
	//
	// does not work, as gcc supports variable-length arrays whose sizes
	// are determined at run-time (this is gcc's extension and not part
	// of the C++ standard). As a result, gcc fails to reject the
	// following code with the simple definition:
	//
	// int foo;
	// COMPILE_ASSERT(foo, msg); // not supposed to compile as foo is
	// // not a compile-time constant.
	//
	// - By using the type CompileAssert<(bool(expr))>, we ensures that
	// expr is a compile-time constant. (Template arguments must be
	// determined at compile-time.)
	//
	// - The outter parentheses in CompileAssert<(bool(expr))> are necessary
	// to work around a bug in gcc 3.4.4 and 4.0.1. If we had written
	//
	// CompileAssert<bool(expr)>
	//
	// instead, these compilers will refuse to compile
	//
	// COMPILE_ASSERT(5 > 0, some_message);
	//
	// (They seem to think the ">" in "5 > 0" marks the end of the
	// template argument list.)
	//
	// - The array size is (bool(expr) ? 1 : -1), instead of simply
	//
	// ((expr) ? 1 : -1).
	//
	// This is to avoid running into a bug in MS VC 7.1, which
	// causes ((0.0) ? 1 : -1) to incorrectly evaluate to 1.


	// MetatagId refers to metatag-id that we assign to
	// each metatag <name, value> pair..
	typedef uint32 MetatagId;

	// Argument type used in interfaces that can optionally take ownership
	// of a passed in argument. If TAKE_OWNERSHIP is passed, the called
	// object takes ownership of the argument. Otherwise it does not.
	enum Ownership {
	DO_NOT_TAKE_OWNERSHIP,
	TAKE_OWNERSHIP
	};

	// Use these as the mlock_bytes parameter to MLock and MLockGeneral
	enum { MLOCK_ALL = -1, MLOCK_NONE = 0 };

	// Helper routine to avoid buggy code like the following:
	// if (pos + N < end) ...
	// If pos is large enough, "pos + N" may overflow. For example,
	// pos==0xfffff000 and N==1MB.
	//
	// PointerRangeSize(a,b) returns the size of the range [a,b-1]
	inline size_t PointerRangeSize(const char* start, const char* end) {
	assert(start <= end);
	return end - start;
	}

	// bit_cast<Dest,Source> is a template function that implements the
	// equivalent of "reinterpret_cast<Dest>(&source)". We need this in
	// very low-level functions like the protobuf library and fast math
	// support.
	//
	// float f = 3.14159265358979;
	// int i = bit_cast<int32>(f);
	// // i = 0x40490fdb
	//
	// The classical address-casting method is:
	//
	// // WRONG
	// float f = 3.14159265358979; // WRONG
	// int i = * reinterpret_cast<int*>(&f); // WRONG
	//
	// The address-casting method actually produces undefined behavior
	// according to ISO C++ specification section 3.10 -15 -. Roughly, this
	// section says: if an object in memory has one type, and a program
	// accesses it with a different type, then the result is undefined
	// behavior for most values of "different type".
	//
	// This is true for any cast syntax, either (int)&f or
	// reinterpret_cast<int>(&f). And it is particularly true for
	// conversions betweeen integral lvalues and floating-point lvalues.
	//
	// The purpose of 3.10 -15- is to allow optimizing compilers to assume
	// that expressions with different types refer to different memory. gcc
	// 4.0.1 has an optimizer that takes advantage of this. So a
	// non-conforming program quietly produces wildly incorrect output.
	//
	// The problem is not the use of reinterpret_cast. The problem is type
	// punning: holding an object in memory of one type and reading its bits
	// back using a different type.
	//
	// The C++ standard is more subtle and complex than this, but that
	// is the basic idea.
	//
	// Anyways ...
	//
	// bit_cast<> calls memcpy() which is blessed by the standard,
	// especially by the example in section 3.9 . Also, of course,
	// bit_cast<> wraps up the nasty logic in one place.
	//
	// Fortunately memcpy() is very fast. In optimized mode, with a
	// constant size, gcc 2.95.3, gcc 4.0.1, and msvc 7.1 produce inline
	// code with the minimal amount of data movement. On a 32-bit system,
	// memcpy(d,s,4) compiles to one load and one store, and memcpy(d,s,8)
	// compiles to two loads and two stores.
	//
	// I tested this code with gcc 2.95.3, gcc 4.0.1, icc 8.1, and msvc 7.1.
	//
	// WARNING: if Dest or Source is a non-POD type, the result of the memcpy
	// is likely to surprise you.

	template <class Dest, class Source>
	inline Dest bit_cast(const Source& source) {
	// Compile time assertion: sizeof(Dest) == sizeof(Source)
	// A compile error here means your Dest and Source have different sizes.
	typedef char VerifySizesAreEqual [sizeof(Dest) == sizeof(Source) ? 1 : -1];

	Dest dest;
	memcpy(&dest, &source, sizeof(dest));
	return dest;
	}

	// The following enum should be used only as a constructor argument to indicate
	// that the variable has static storage class, and that the constructor should
	// do nothing to its state. It indicates to the reader that it is legal to
	// declare a static instance of the class, provided the constructor is given
	// the base::LINKER_INITIALIZED argument. Normally, it is unsafe to declare a
	// static variable that has a constructor or a destructor because invocation
	// order is undefined. However, IF the type can be initialized by filling with
	// zeroes (which the loader does for static variables), AND the destructor also
	// does nothing to the storage, AND there are no virtual methods, then a
	// constructor declared as
	// explicit MyClass(base::LinkerInitialized x) {}
	// and invoked as
	// static MyClass my_variable_name(base::LINKER_INITIALIZED);
	namespace base {
	enum LinkerInitialized { LINKER_INITIALIZED };
	} // base


	#endif // BASE_BASICTYPES_H_