Source/WebCore/html/canvas/CheckedInt.h - platform/external/webkit - Git at Google

 /* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
 /* vim:set ts=2 sw=2 sts=2 et cindent: */
 /* ***** BEGIN LICENSE BLOCK *****
  * Version: MPL 1.1/GPL 2.0/LGPL 2.1
  *
  * The contents of this file are subject to the Mozilla Public License Version
  * 1.1 (the "License"); you may not use this file except in compliance with
  * the License. You may obtain a copy of the License at
  * http://www.mozilla.org/MPL/
  *
  * Software distributed under the License is distributed on an "AS IS" basis,
  * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
  * for the specific language governing rights and limitations under the
  * License.
  *
  * The Original Code is Mozilla code.
  *
  * The Initial Developer of the Original Code is the Mozilla Corporation.
  * Portions created by the Initial Developer are Copyright (C) 2009
  * the Initial Developer. All Rights Reserved.
  *
  * Contributor(s):
  *  Benoit Jacob <bjacob@mozilla.com>
  *  Jeff Muizelaar <jmuizelaar@mozilla.com>
  *
  * Alternatively, the contents of this file may be used under the terms of
  * either the GNU General Public License Version 2 or later (the "GPL"), or
  * the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
  * in which case the provisions of the GPL or the LGPL are applicable instead
  * of those above. If you wish to allow use of your version of this file only
  * under the terms of either the GPL or the LGPL, and not to allow others to
  * use your version of this file under the terms of the MPL, indicate your
  * decision by deleting the provisions above and replace them with the notice
  * and other provisions required by the GPL or the LGPL. If you do not delete
  * the provisions above, a recipient may use your version of this file under
  * the terms of any one of the MPL, the GPL or the LGPL.
  *
  * ***** END LICENSE BLOCK ***** */

 // Necessary modifications are made to the original CheckedInt.h file to remove
 // dependencies on prtypes.
 // Also, change define Mozilla_CheckedInt_h to CheckedInt_h, change namespace
 // from mozilla to WebCore for easier usage.

 #ifndef CheckedInt_h
 #define CheckedInt_h

 #include <climits>

 namespace WebCore {

 namespace CheckedInt_internal {

 /* we don't want to use std::numeric_limits here because int... types may not support it,
  * depending on the platform, e.g. on certain platform they use nonstandard built-in types
  */

 /*** Step 1: manually record information for all the types that we want to support
  ***/

 struct unsupported_type {};

 template<typename T> struct integer_type_manually_recorded_info;


 #define CHECKEDINT_REGISTER_SUPPORTED_TYPE(T,_twice_bigger_type,_unsigned_type) \
 template<> struct integer_type_manually_recorded_info<T>       \
 {                                                              \
     enum { is_supported = 1 };                                 \
     typedef _twice_bigger_type twice_bigger_type;              \
     typedef _unsigned_type unsigned_type;                      \
 };

 //                                 Type      Twice Bigger Type   Unsigned Type
 CHECKEDINT_REGISTER_SUPPORTED_TYPE(int8_t,   int16_t,             uint8_t)
 CHECKEDINT_REGISTER_SUPPORTED_TYPE(uint8_t,  uint16_t,            uint8_t)
 CHECKEDINT_REGISTER_SUPPORTED_TYPE(int16_t,  int32_t,             uint16_t)
 CHECKEDINT_REGISTER_SUPPORTED_TYPE(uint16_t, uint32_t,            uint16_t)
 CHECKEDINT_REGISTER_SUPPORTED_TYPE(int32_t,  int64_t,             uint32_t)
 CHECKEDINT_REGISTER_SUPPORTED_TYPE(uint32_t, uint64_t,            uint32_t)
 CHECKEDINT_REGISTER_SUPPORTED_TYPE(int64_t,  unsupported_type,    uint64_t)
 CHECKEDINT_REGISTER_SUPPORTED_TYPE(uint64_t, unsupported_type,    uint64_t)

 // now implement the fallback for standard types like int, long, ...
 // the difficulty is that they may or may not be equal to one of the above types, and/or
 // to each other. This is why any attempt to handle at once PRInt8... types and standard types
 // is bound to fail.
 template<typename T>
 struct is_standard_integer_type { enum { value = 0 }; };

 template<>
 struct is_standard_integer_type<char> { enum { value = 1 }; };
 template<>
 struct is_standard_integer_type<unsigned char> { enum { value = 1 }; };
 template<>
 struct is_standard_integer_type<short> { enum { value = 1 }; };
 template<>
 struct is_standard_integer_type<unsigned short> { enum { value = 1 }; };
 template<>
 struct is_standard_integer_type<int> { enum { value = 1 }; };
 template<>
 struct is_standard_integer_type<unsigned int> { enum { value = 1 }; };
 template<>
 struct is_standard_integer_type<long> { enum { value = 1 }; };
 template<>
 struct is_standard_integer_type<unsigned long> { enum { value = 1 }; };
 template<>
 struct is_standard_integer_type<long long> { enum { value = 1 }; };
 template<>
 struct is_standard_integer_type<unsigned long long> { enum { value = 1 }; };

 template<int size, bool is_signed>
 struct explicitly_sized_integer_type {};

 template<>
 struct explicitly_sized_integer_type<1, true> { typedef int8_t type; };
 template<>
 struct explicitly_sized_integer_type<1, false> { typedef uint8_t type; };
 template<>
 struct explicitly_sized_integer_type<2, true> { typedef int16_t type; };
 template<>
 struct explicitly_sized_integer_type<2, false> { typedef uint16_t type; };
 template<>
 struct explicitly_sized_integer_type<4, true> { typedef int32_t type; };
 template<>
 struct explicitly_sized_integer_type<4, false> { typedef uint32_t type; };
 template<>
 struct explicitly_sized_integer_type<8, true> { typedef int64_t type; };
 template<>
 struct explicitly_sized_integer_type<8, false> { typedef uint64_t type; };

 template<typename T> struct integer_type_manually_recorded_info
 {
     enum {
       is_supported = is_standard_integer_type<T>::value,
       size = sizeof(T),
       is_signed = (T(-1) > T(0)) ? 0 : 1
     };
     typedef typename explicitly_sized_integer_type<size, is_signed>::type explicit_sized_type;
     typedef integer_type_manually_recorded_info<explicit_sized_type> base;
     typedef typename base::twice_bigger_type twice_bigger_type;
     typedef typename base::unsigned_type unsigned_type;
 };

 template<typename T, bool is_supported = integer_type_manually_recorded_info<T>::is_supported>
 struct TYPE_NOT_SUPPORTED_BY_CheckedInt {};

 template<typename T>
 struct TYPE_NOT_SUPPORTED_BY_CheckedInt<T, true> { static void run() {} };


 /*** Step 2: record some info about a given integer type,
  ***         including whether it is supported, whether a twice bigger integer type
  ***         is supported, what that twice bigger type is, and some stuff as found
  ***         in std::numeric_limits (which we don't use because int.. types may
  ***         not support it, if they are defined directly from compiler built-in types).
  ***/

 template<typename T> struct is_unsupported_type { enum { answer = 0 }; };
 template<> struct is_unsupported_type<unsupported_type> { enum { answer = 1 }; };

 template<typename T> struct integer_traits
 {
     typedef typename integer_type_manually_recorded_info<T>::twice_bigger_type twice_bigger_type;

     enum {
         is_supported = integer_type_manually_recorded_info<T>::is_supported,
         twice_bigger_type_is_supported
             = is_unsupported_type<
                   typename integer_type_manually_recorded_info<T>::twice_bigger_type
               >::answer ? 0 : 1,
         size = sizeof(T),
         position_of_sign_bit = CHAR_BIT * size - 1,
         is_signed = (T(-1) > T(0)) ? 0 : 1
     };

     static T min()
     {
         // bitwise ops may return a larger type, that's why we cast explicitly to T
         return is_signed ? T(T(1) << position_of_sign_bit) : T(0);
     }

     static T max()
     {
         return ~min();
     }
 };

 /*** Step 3: Implement the actual validity checks --- ideas taken from IntegerLib, code different.
  ***/

 // bitwise ops may return a larger type, so it's good to use these inline helpers guaranteeing that
 // the result is really of type T

 template<typename T> inline T has_sign_bit(T x)
 {
     return x >> integer_traits<T>::position_of_sign_bit;
 }

 template<typename T> inline T binary_complement(T x)
 {
     return ~x;
 }

 template<typename T, typename U,
          bool is_T_signed = integer_traits<T>::is_signed,
          bool is_U_signed = integer_traits<U>::is_signed>
 struct is_in_range_impl {};

 template<typename T, typename U>
 struct is_in_range_impl<T, U, true, true>
 {
     static T run(U x)
     {
         return (x <= integer_traits<T>::max()) &
                (x >= integer_traits<T>::min());
     }
 };

 template<typename T, typename U>
 struct is_in_range_impl<T, U, false, false>
 {
     static T run(U x)
     {
         return x <= integer_traits<T>::max();
     }
 };

 template<typename T, typename U>
 struct is_in_range_impl<T, U, true, false>
 {
     static T run(U x)
     {
         if (sizeof(T) > sizeof(U))
             return 1;
         else
             return x <= U(integer_traits<T>::max());
     }
 };

 template<typename T, typename U>
 struct is_in_range_impl<T, U, false, true>
 {
     static T run(U x)
     {
         if (sizeof(T) >= sizeof(U))
             return x >= 0;
         else
             return x >= 0 && x <= U(integer_traits<T>::max());
     }
 };

 template<typename T, typename U> inline T is_in_range(U x)
 {
     return is_in_range_impl<T, U>::run(x);
 }

 template<typename T> inline T is_add_valid(T x, T y, T result)
 {
     return integer_traits<T>::is_signed ?
                         // addition is valid if the sign of x+y is equal to either that of x or that of y.
                         // Beware! These bitwise operations can return a larger integer type, if T was a
                         // small type like int8, so we explicitly cast to T.
                         has_sign_bit(binary_complement(T((result^x) & (result^y))))
                     :
                         binary_complement(x) >= y;
 }

 template<typename T> inline T is_sub_valid(T x, T y, T result)
 {
     return integer_traits<T>::is_signed ?
                         // substraction is valid if either x and y have same sign, or x-y and x have same sign
                         has_sign_bit(binary_complement(T((result^x) & (x^y))))
                     :
                         x >= y;
 }

 template<typename T,
          bool is_signed =  integer_traits<T>::is_signed,
          bool twice_bigger_type_is_supported = integer_traits<T>::twice_bigger_type_is_supported>
 struct is_mul_valid_impl {};

 template<typename T>
 struct is_mul_valid_impl<T, true, true>
 {
     static T run(T x, T y)
     {
         typedef typename integer_traits<T>::twice_bigger_type twice_bigger_type;
         twice_bigger_type product = twice_bigger_type(x) * twice_bigger_type(y);
         return is_in_range<T>(product);
     }
 };

 template<typename T>
 struct is_mul_valid_impl<T, false, true>
 {
     static T run(T x, T y)
     {
         typedef typename integer_traits<T>::twice_bigger_type twice_bigger_type;
         twice_bigger_type product = twice_bigger_type(x) * twice_bigger_type(y);
         return is_in_range<T>(product);
     }
 };

 template<typename T>
 struct is_mul_valid_impl<T, true, false>
 {
     static T run(T x, T y)
     {
         const T max_value = integer_traits<T>::max();
         const T min_value = integer_traits<T>::min();

         if (x == 0 || y == 0) return true;

         if (x > 0) {
             if (y > 0)
                 return x <= max_value / y;
             else
                 return y >= min_value / x;
         } else {
             if (y > 0)
                 return x >= min_value / y;
             else
                 return y >= max_value / x;
         }
     }
 };

 template<typename T>
 struct is_mul_valid_impl<T, false, false>
 {
     static T run(T x, T y)
     {
         const T max_value = integer_traits<T>::max();
         if (x == 0 || y == 0) return true;
         return x <= max_value / y;
     }
 };

 template<typename T> inline T is_mul_valid(T x, T y, T /*result not used*/)
 {
     return is_mul_valid_impl<T>::run(x, y);
 }

 template<typename T> inline T is_div_valid(T x, T y)
 {
     return integer_traits<T>::is_signed ?
                         // keep in mind that min/-1 is invalid because abs(min)>max
                         y != 0 && (x != integer_traits<T>::min() || y != T(-1))
                     :
                         y != 0;
 }

 } // end namespace CheckedInt_internal


 /*** Step 4: Now define the CheckedInt class.
  ***/

 /** \class CheckedInt
   * \brief Integer wrapper class checking for integer overflow and other errors
   * \param T the integer type to wrap. Can be any of int8_t, uint8_t, int16_t, uint16_t,
   *          int32_t, uint32_t, int64_t, uint64_t.
   *
   * This class implements guarded integer arithmetic. Do a computation, then check that
   * valid() returns true, you then have a guarantee that no problem, such as integer overflow,
   * happened during this computation.
   *
   * The arithmetic operators in this class are guaranteed not to crash your app
   * in case of a division by zero.
   *
   * For example, suppose that you want to implement a function that computes (x+y)/z,
   * that doesn't crash if z==0, and that reports on error (divide by zero or integer overflow).
   * You could code it as follows:
     \code
     bool compute_x_plus_y_over_z(int32_t x, int32_t y, int32_t z, int32_t *result)
     {
         CheckedInt<int32_t> checked_result = (CheckedInt<int32_t>(x) + y) / z;
         *result = checked_result.value();
         return checked_result.valid();
     }
     \endcode
   *
   * Implicit conversion from plain integers to checked integers is allowed. The plain integer
   * is checked to be in range before being casted to the destination type. This means that the following
   * lines all compile, and the resulting CheckedInts are correctly detected as valid or invalid:
   * \code
     CheckedInt<uint8_t> x(1);   // 1 is of type int, is found to be in range for uint8_t, x is valid
     CheckedInt<uint8_t> x(-1);  // -1 is of type int, is found not to be in range for uint8_t, x is invalid
     CheckedInt<int8_t> x(-1);   // -1 is of type int, is found to be in range for int8_t, x is valid
     CheckedInt<int8_t> x(int16_t(1000)); // 1000 is of type int16_t, is found not to be in range for int8_t, x is invalid
     CheckedInt<int32_t> x(uint32_t(123456789)); // 3123456789 is of type uint32_t, is found not to be in range
                                              // for int32_t, x is invalid
   * \endcode
   * Implicit conversion from
   * checked integers to plain integers is not allowed. As shown in the
   * above example, to get the value of a checked integer as a normal integer, call value().
   *
   * Arithmetic operations between checked and plain integers is allowed; the result type
   * is the type of the checked integer.
   *
   * Safe integers of different types cannot be used in the same arithmetic expression.
   */
 template<typename T>
 class CheckedInt
 {
 protected:
     T mValue;
     T mIsValid; // stored as a T to limit the number of integer conversions when
                 // evaluating nested arithmetic expressions.

     template<typename U>
     CheckedInt(const U& value, bool isValid) : mValue(value), mIsValid(isValid)
     {
         CheckedInt_internal::TYPE_NOT_SUPPORTED_BY_CheckedInt<T>::run();
     }

 public:
     /** Constructs a checked integer with given \a value. The checked integer is initialized as valid or invalid
       * depending on whether the \a value is in range.
       *
       * This constructor is not explicit. Instead, the type of its argument is a separate template parameter,
       * ensuring that no conversion is performed before this constructor is actually called.
       * As explained in the above documentation for class CheckedInt, this constructor checks that its argument is
       * valid.
       */
     template<typename U>
     CheckedInt(const U& value)
         : mValue(value),
           mIsValid(CheckedInt_internal::is_in_range<T>(value))
     {
         CheckedInt_internal::TYPE_NOT_SUPPORTED_BY_CheckedInt<T>::run();
     }

     /** Constructs a valid checked integer with uninitialized value */
     CheckedInt() : mIsValid(1)
     {
         CheckedInt_internal::TYPE_NOT_SUPPORTED_BY_CheckedInt<T>::run();
     }

     /** \returns the actual value */
     T value() const { return mValue; }

     /** \returns true if the checked integer is valid, i.e. is not the result
       * of an invalid operation or of an operation involving an invalid checked integer
       */
     bool valid() const { return mIsValid; }

     /** \returns the sum. Checks for overflow. */
     template<typename U> friend CheckedInt<U> operator +(const CheckedInt<U>& lhs, const CheckedInt<U>& rhs);
     /** Adds. Checks for overflow. \returns self reference */
     template<typename U> CheckedInt& operator +=(const U &rhs);
     /** \returns the difference. Checks for overflow. */
     template<typename U> friend CheckedInt<U> operator -(const CheckedInt<U>& lhs, const CheckedInt<U> &rhs);
     /** Substracts. Checks for overflow. \returns self reference */
     template<typename U> CheckedInt& operator -=(const U &rhs);
     /** \returns the product. Checks for overflow. */
     template<typename U> friend CheckedInt<U> operator *(const CheckedInt<U>& lhs, const CheckedInt<U> &rhs);
     /** Multiplies. Checks for overflow. \returns self reference */
     template<typename U> CheckedInt& operator *=(const U &rhs);
     /** \returns the quotient. Checks for overflow and for divide-by-zero. */
     template<typename U> friend CheckedInt<U> operator /(const CheckedInt<U>& lhs, const CheckedInt<U> &rhs);
     /** Divides. Checks for overflow and for divide-by-zero. \returns self reference */
     template<typename U> CheckedInt& operator /=(const U &rhs);

     /** \returns the opposite value. Checks for overflow. */
     CheckedInt operator -() const
     {
         T result = -value();
         /* give the compiler a good chance to perform RVO */
         return CheckedInt(result,
                        mIsValid & CheckedInt_internal::is_sub_valid(T(0), value(), result));
     }

     /** \returns true if the left and right hand sides are valid and have the same value. */
     bool operator ==(const CheckedInt& other) const
     {
         return bool(mIsValid & other.mIsValid & T(value() == other.value()));
     }

 private:
     /** operator!= is disabled. Indeed: (a!=b) should be the same as !(a==b) but that
       * would mean that if a or b is invalid, (a!=b) is always true, which is very tricky.
       */
     template<typename U>
     bool operator !=(const U& other) const { return !(*this == other); }
 };

 #define CHECKEDINT_BASIC_BINARY_OPERATOR(NAME, OP)               \
 template<typename T>                                          \
 inline CheckedInt<T> operator OP(const CheckedInt<T> &lhs, const CheckedInt<T> &rhs) \
 {                                                             \
     T x = lhs.value();                                        \
     T y = rhs.value();                                        \
     T result = x OP y;                                        \
     T is_op_valid                                             \
         = CheckedInt_internal::is_##NAME##_valid(x, y, result);  \
     /* give the compiler a good chance to perform RVO */      \
     return CheckedInt<T>(result,                                 \
                       lhs.mIsValid &                          \
                       rhs.mIsValid &                          \
                       is_op_valid);                           \
 }

 CHECKEDINT_BASIC_BINARY_OPERATOR(add, +)
 CHECKEDINT_BASIC_BINARY_OPERATOR(sub, -)
 CHECKEDINT_BASIC_BINARY_OPERATOR(mul, *)

 // division can't be implemented by CHECKEDINT_BASIC_BINARY_OPERATOR
 // because if rhs == 0, we are not allowed to even try to compute the quotient.
 template<typename T>
 inline CheckedInt<T> operator /(const CheckedInt<T> &lhs, const CheckedInt<T> &rhs)
 {
     T x = lhs.value();
     T y = rhs.value();
     T is_op_valid = CheckedInt_internal::is_div_valid(x, y);
     T result = is_op_valid ? (x / y) : 0;
     /* give the compiler a good chance to perform RVO */
     return CheckedInt<T>(result,
                       lhs.mIsValid &
                       rhs.mIsValid &
                       is_op_valid);
 }

 // implement cast_to_CheckedInt<T>(x), making sure that
 //  - it allows x to be either a CheckedInt<T> or any integer type that can be casted to T
 //  - if x is already a CheckedInt<T>, we just return a reference to it, instead of copying it (optimization)

 template<typename T, typename U>
 struct cast_to_CheckedInt_impl
 {
     typedef CheckedInt<T> return_type;
     static CheckedInt<T> run(const U& u) { return u; }
 };

 template<typename T>
 struct cast_to_CheckedInt_impl<T, CheckedInt<T> >
 {
     typedef const CheckedInt<T>& return_type;
     static const CheckedInt<T>& run(const CheckedInt<T>& u) { return u; }
 };

 template<typename T, typename U>
 inline typename cast_to_CheckedInt_impl<T, U>::return_type
 cast_to_CheckedInt(const U& u)
 {
     return cast_to_CheckedInt_impl<T, U>::run(u);
 }

 #define CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(OP, COMPOUND_OP) \
 template<typename T>                                          \
 template<typename U>                                          \
 CheckedInt<T>& CheckedInt<T>::operator COMPOUND_OP(const U &rhs)    \
 {                                                             \
     *this = *this OP cast_to_CheckedInt<T>(rhs);                 \
     return *this;                                             \
 }                                                             \
 template<typename T, typename U>                              \
 inline CheckedInt<T> operator OP(const CheckedInt<T> &lhs, const U &rhs) \
 {                                                             \
     return lhs OP cast_to_CheckedInt<T>(rhs);                    \
 }                                                             \
 template<typename T, typename U>                              \
 inline CheckedInt<T> operator OP(const U & lhs, const CheckedInt<T> &rhs) \
 {                                                             \
     return cast_to_CheckedInt<T>(lhs) OP rhs;                    \
 }

 CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(+, +=)
 CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(*, *=)
 CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(-, -=)
 CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(/, /=)

 template<typename T, typename U>
 inline bool operator ==(const CheckedInt<T> &lhs, const U &rhs)
 {
     return lhs == cast_to_CheckedInt<T>(rhs);
 }

 template<typename T, typename U>
 inline bool operator ==(const U & lhs, const CheckedInt<T> &rhs)
 {
     return cast_to_CheckedInt<T>(lhs) == rhs;
 }

 } // end namespace WebCore

 #endif /* CheckedInt_h */
	/* -- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -- */
	/* vim:set ts=2 sw=2 sts=2 et cindent: */
	/* *** BEGIN LICENSE BLOCK ***
	* Version: MPL 1.1/GPL 2.0/LGPL 2.1
	*
	* The contents of this file are subject to the Mozilla Public License Version
	* 1.1 (the "License"); you may not use this file except in compliance with
	* the License. You may obtain a copy of the License at
	* http://www.mozilla.org/MPL/
	*
	* Software distributed under the License is distributed on an "AS IS" basis,
	* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
	* for the specific language governing rights and limitations under the
	* License.
	*
	* The Original Code is Mozilla code.
	*
	* The Initial Developer of the Original Code is the Mozilla Corporation.
	* Portions created by the Initial Developer are Copyright (C) 2009
	* the Initial Developer. All Rights Reserved.
	*
	* Contributor(s):
	* Benoit Jacob <bjacob@mozilla.com>
	* Jeff Muizelaar <jmuizelaar@mozilla.com>
	*
	* Alternatively, the contents of this file may be used under the terms of
	* either the GNU General Public License Version 2 or later (the "GPL"), or
	* the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
	* in which case the provisions of the GPL or the LGPL are applicable instead
	* of those above. If you wish to allow use of your version of this file only
	* under the terms of either the GPL or the LGPL, and not to allow others to
	* use your version of this file under the terms of the MPL, indicate your
	* decision by deleting the provisions above and replace them with the notice
	* and other provisions required by the GPL or the LGPL. If you do not delete
	* the provisions above, a recipient may use your version of this file under
	* the terms of any one of the MPL, the GPL or the LGPL.
	*
	* *** END LICENSE BLOCK *** */

	// Necessary modifications are made to the original CheckedInt.h file to remove
	// dependencies on prtypes.
	// Also, change define Mozilla_CheckedInt_h to CheckedInt_h, change namespace
	// from mozilla to WebCore for easier usage.

	#ifndef CheckedInt_h
	#define CheckedInt_h

	#include <climits>

	namespace WebCore {

	namespace CheckedInt_internal {

	/* we don't want to use std::numeric_limits here because int... types may not support it,
	* depending on the platform, e.g. on certain platform they use nonstandard built-in types
	*/

	/*** Step 1: manually record information for all the types that we want to support
	***/

	struct unsupported_type {};

	template<typename T> struct integer_type_manually_recorded_info;


	#define CHECKEDINT_REGISTER_SUPPORTED_TYPE(T,_twice_bigger_type,_unsigned_type) \
	template<> struct integer_type_manually_recorded_info<T> \
	{ \
	enum { is_supported = 1 }; \
	typedef _twice_bigger_type twice_bigger_type; \
	typedef _unsigned_type unsigned_type; \
	};

	// Type Twice Bigger Type Unsigned Type
	CHECKEDINT_REGISTER_SUPPORTED_TYPE(int8_t, int16_t, uint8_t)
	CHECKEDINT_REGISTER_SUPPORTED_TYPE(uint8_t, uint16_t, uint8_t)
	CHECKEDINT_REGISTER_SUPPORTED_TYPE(int16_t, int32_t, uint16_t)
	CHECKEDINT_REGISTER_SUPPORTED_TYPE(uint16_t, uint32_t, uint16_t)
	CHECKEDINT_REGISTER_SUPPORTED_TYPE(int32_t, int64_t, uint32_t)
	CHECKEDINT_REGISTER_SUPPORTED_TYPE(uint32_t, uint64_t, uint32_t)
	CHECKEDINT_REGISTER_SUPPORTED_TYPE(int64_t, unsupported_type, uint64_t)
	CHECKEDINT_REGISTER_SUPPORTED_TYPE(uint64_t, unsupported_type, uint64_t)

	// now implement the fallback for standard types like int, long, ...
	// the difficulty is that they may or may not be equal to one of the above types, and/or
	// to each other. This is why any attempt to handle at once PRInt8... types and standard types
	// is bound to fail.
	template<typename T>
	struct is_standard_integer_type { enum { value = 0 }; };

	template<>
	struct is_standard_integer_type<char> { enum { value = 1 }; };
	template<>
	struct is_standard_integer_type<unsigned char> { enum { value = 1 }; };
	template<>
	struct is_standard_integer_type<short> { enum { value = 1 }; };
	template<>
	struct is_standard_integer_type<unsigned short> { enum { value = 1 }; };
	template<>
	struct is_standard_integer_type<int> { enum { value = 1 }; };
	template<>
	struct is_standard_integer_type<unsigned int> { enum { value = 1 }; };
	template<>
	struct is_standard_integer_type<long> { enum { value = 1 }; };
	template<>
	struct is_standard_integer_type<unsigned long> { enum { value = 1 }; };
	template<>
	struct is_standard_integer_type<long long> { enum { value = 1 }; };
	template<>
	struct is_standard_integer_type<unsigned long long> { enum { value = 1 }; };

	template<int size, bool is_signed>
	struct explicitly_sized_integer_type {};

	template<>
	struct explicitly_sized_integer_type<1, true> { typedef int8_t type; };
	template<>
	struct explicitly_sized_integer_type<1, false> { typedef uint8_t type; };
	template<>
	struct explicitly_sized_integer_type<2, true> { typedef int16_t type; };
	template<>
	struct explicitly_sized_integer_type<2, false> { typedef uint16_t type; };
	template<>
	struct explicitly_sized_integer_type<4, true> { typedef int32_t type; };
	template<>
	struct explicitly_sized_integer_type<4, false> { typedef uint32_t type; };
	template<>
	struct explicitly_sized_integer_type<8, true> { typedef int64_t type; };
	template<>
	struct explicitly_sized_integer_type<8, false> { typedef uint64_t type; };

	template<typename T> struct integer_type_manually_recorded_info
	{
	enum {
	is_supported = is_standard_integer_type<T>::value,
	size = sizeof(T),
	is_signed = (T(-1) > T(0)) ? 0 : 1
	};
	typedef typename explicitly_sized_integer_type<size, is_signed>::type explicit_sized_type;
	typedef integer_type_manually_recorded_info<explicit_sized_type> base;
	typedef typename base::twice_bigger_type twice_bigger_type;
	typedef typename base::unsigned_type unsigned_type;
	};

	template<typename T, bool is_supported = integer_type_manually_recorded_info<T>::is_supported>
	struct TYPE_NOT_SUPPORTED_BY_CheckedInt {};

	template<typename T>
	struct TYPE_NOT_SUPPORTED_BY_CheckedInt<T, true> { static void run() {} };


	/*** Step 2: record some info about a given integer type,
	*** including whether it is supported, whether a twice bigger integer type
	*** is supported, what that twice bigger type is, and some stuff as found
	*** in std::numeric_limits (which we don't use because int.. types may
	*** not support it, if they are defined directly from compiler built-in types).
	***/

	template<typename T> struct is_unsupported_type { enum { answer = 0 }; };
	template<> struct is_unsupported_type<unsupported_type> { enum { answer = 1 }; };

	template<typename T> struct integer_traits
	{
	typedef typename integer_type_manually_recorded_info<T>::twice_bigger_type twice_bigger_type;

	enum {
	is_supported = integer_type_manually_recorded_info<T>::is_supported,
	twice_bigger_type_is_supported
	= is_unsupported_type<
	typename integer_type_manually_recorded_info<T>::twice_bigger_type
	>::answer ? 0 : 1,
	size = sizeof(T),
	position_of_sign_bit = CHAR_BIT * size - 1,
	is_signed = (T(-1) > T(0)) ? 0 : 1
	};

	static T min()
	{
	// bitwise ops may return a larger type, that's why we cast explicitly to T
	return is_signed ? T(T(1) << position_of_sign_bit) : T(0);
	}

	static T max()
	{
	return ~min();
	}
	};

	/*** Step 3: Implement the actual validity checks --- ideas taken from IntegerLib, code different.
	***/

	// bitwise ops may return a larger type, so it's good to use these inline helpers guaranteeing that
	// the result is really of type T

	template<typename T> inline T has_sign_bit(T x)
	{
	return x >> integer_traits<T>::position_of_sign_bit;
	}

	template<typename T> inline T binary_complement(T x)
	{
	return ~x;
	}

	template<typename T, typename U,
	bool is_T_signed = integer_traits<T>::is_signed,
	bool is_U_signed = integer_traits<U>::is_signed>
	struct is_in_range_impl {};

	template<typename T, typename U>
	struct is_in_range_impl<T, U, true, true>
	{
	static T run(U x)
	{
	return (x <= integer_traits<T>::max()) &
	(x >= integer_traits<T>::min());
	}
	};

	template<typename T, typename U>
	struct is_in_range_impl<T, U, false, false>
	{
	static T run(U x)
	{
	return x <= integer_traits<T>::max();
	}
	};

	template<typename T, typename U>
	struct is_in_range_impl<T, U, true, false>
	{
	static T run(U x)
	{
	if (sizeof(T) > sizeof(U))
	return 1;
	else
	return x <= U(integer_traits<T>::max());
	}
	};

	template<typename T, typename U>
	struct is_in_range_impl<T, U, false, true>
	{
	static T run(U x)
	{
	if (sizeof(T) >= sizeof(U))
	return x >= 0;
	else
	return x >= 0 && x <= U(integer_traits<T>::max());
	}
	};

	template<typename T, typename U> inline T is_in_range(U x)
	{
	return is_in_range_impl<T, U>::run(x);
	}

	template<typename T> inline T is_add_valid(T x, T y, T result)
	{
	return integer_traits<T>::is_signed ?
	// addition is valid if the sign of x+y is equal to either that of x or that of y.
	// Beware! These bitwise operations can return a larger integer type, if T was a
	// small type like int8, so we explicitly cast to T.
	has_sign_bit(binary_complement(T((result^x) & (result^y))))
	:
	binary_complement(x) >= y;
	}

	template<typename T> inline T is_sub_valid(T x, T y, T result)
	{
	return integer_traits<T>::is_signed ?
	// substraction is valid if either x and y have same sign, or x-y and x have same sign
	has_sign_bit(binary_complement(T((result^x) & (x^y))))
	:
	x >= y;
	}

	template<typename T,
	bool is_signed = integer_traits<T>::is_signed,
	bool twice_bigger_type_is_supported = integer_traits<T>::twice_bigger_type_is_supported>
	struct is_mul_valid_impl {};

	template<typename T>
	struct is_mul_valid_impl<T, true, true>
	{
	static T run(T x, T y)
	{
	typedef typename integer_traits<T>::twice_bigger_type twice_bigger_type;
	twice_bigger_type product = twice_bigger_type(x) * twice_bigger_type(y);
	return is_in_range<T>(product);
	}
	};

	template<typename T>
	struct is_mul_valid_impl<T, false, true>
	{
	static T run(T x, T y)
	{
	typedef typename integer_traits<T>::twice_bigger_type twice_bigger_type;
	twice_bigger_type product = twice_bigger_type(x) * twice_bigger_type(y);
	return is_in_range<T>(product);
	}
	};

	template<typename T>
	struct is_mul_valid_impl<T, true, false>
	{
	static T run(T x, T y)
	{
	const T max_value = integer_traits<T>::max();
	const T min_value = integer_traits<T>::min();

	if (x == 0 \|\| y == 0) return true;

	if (x > 0) {
	if (y > 0)
	return x <= max_value / y;
	else
	return y >= min_value / x;
	} else {
	if (y > 0)
	return x >= min_value / y;
	else
	return y >= max_value / x;
	}
	}
	};

	template<typename T>
	struct is_mul_valid_impl<T, false, false>
	{
	static T run(T x, T y)
	{
	const T max_value = integer_traits<T>::max();
	if (x == 0 \|\| y == 0) return true;
	return x <= max_value / y;
	}
	};

	template<typename T> inline T is_mul_valid(T x, T y, T /result not used/)
	{
	return is_mul_valid_impl<T>::run(x, y);
	}

	template<typename T> inline T is_div_valid(T x, T y)
	{
	return integer_traits<T>::is_signed ?
	// keep in mind that min/-1 is invalid because abs(min)>max
	y != 0 && (x != integer_traits<T>::min() \|\| y != T(-1))
	:
	y != 0;
	}

	} // end namespace CheckedInt_internal


	/*** Step 4: Now define the CheckedInt class.
	***/

	/** \class CheckedInt
	* \brief Integer wrapper class checking for integer overflow and other errors
	* \param T the integer type to wrap. Can be any of int8_t, uint8_t, int16_t, uint16_t,
	* int32_t, uint32_t, int64_t, uint64_t.
	*
	* This class implements guarded integer arithmetic. Do a computation, then check that
	* valid() returns true, you then have a guarantee that no problem, such as integer overflow,
	* happened during this computation.
	*
	* The arithmetic operators in this class are guaranteed not to crash your app
	* in case of a division by zero.
	*
	* For example, suppose that you want to implement a function that computes (x+y)/z,
	* that doesn't crash if z==0, and that reports on error (divide by zero or integer overflow).
	* You could code it as follows:
	\code
	bool compute_x_plus_y_over_z(int32_t x, int32_t y, int32_t z, int32_t *result)
	{
	CheckedInt<int32_t> checked_result = (CheckedInt<int32_t>(x) + y) / z;
	*result = checked_result.value();
	return checked_result.valid();
	}
	\endcode
	*
	* Implicit conversion from plain integers to checked integers is allowed. The plain integer
	* is checked to be in range before being casted to the destination type. This means that the following
	* lines all compile, and the resulting CheckedInts are correctly detected as valid or invalid:
	* \code
	CheckedInt<uint8_t> x(1); // 1 is of type int, is found to be in range for uint8_t, x is valid
	CheckedInt<uint8_t> x(-1); // -1 is of type int, is found not to be in range for uint8_t, x is invalid
	CheckedInt<int8_t> x(-1); // -1 is of type int, is found to be in range for int8_t, x is valid
	CheckedInt<int8_t> x(int16_t(1000)); // 1000 is of type int16_t, is found not to be in range for int8_t, x is invalid
	CheckedInt<int32_t> x(uint32_t(123456789)); // 3123456789 is of type uint32_t, is found not to be in range
	// for int32_t, x is invalid
	* \endcode
	* Implicit conversion from
	* checked integers to plain integers is not allowed. As shown in the
	* above example, to get the value of a checked integer as a normal integer, call value().
	*
	* Arithmetic operations between checked and plain integers is allowed; the result type
	* is the type of the checked integer.
	*
	* Safe integers of different types cannot be used in the same arithmetic expression.
	*/
	template<typename T>
	class CheckedInt
	{
	protected:
	T mValue;
	T mIsValid; // stored as a T to limit the number of integer conversions when
	// evaluating nested arithmetic expressions.

	template<typename U>
	CheckedInt(const U& value, bool isValid) : mValue(value), mIsValid(isValid)
	{
	CheckedInt_internal::TYPE_NOT_SUPPORTED_BY_CheckedInt<T>::run();
	}

	public:
	/** Constructs a checked integer with given \a value. The checked integer is initialized as valid or invalid
	* depending on whether the \a value is in range.
	*
	* This constructor is not explicit. Instead, the type of its argument is a separate template parameter,
	* ensuring that no conversion is performed before this constructor is actually called.
	* As explained in the above documentation for class CheckedInt, this constructor checks that its argument is
	* valid.
	*/
	template<typename U>
	CheckedInt(const U& value)
	: mValue(value),
	mIsValid(CheckedInt_internal::is_in_range<T>(value))
	{
	CheckedInt_internal::TYPE_NOT_SUPPORTED_BY_CheckedInt<T>::run();
	}

	/** Constructs a valid checked integer with uninitialized value */
	CheckedInt() : mIsValid(1)
	{
	CheckedInt_internal::TYPE_NOT_SUPPORTED_BY_CheckedInt<T>::run();
	}

	/** \returns the actual value */
	T value() const { return mValue; }

	/** \returns true if the checked integer is valid, i.e. is not the result
	* of an invalid operation or of an operation involving an invalid checked integer
	*/
	bool valid() const { return mIsValid; }

	/** \returns the sum. Checks for overflow. */
	template<typename U> friend CheckedInt<U> operator +(const CheckedInt<U>& lhs, const CheckedInt<U>& rhs);
	/** Adds. Checks for overflow. \returns self reference */
	template<typename U> CheckedInt& operator +=(const U &rhs);
	/** \returns the difference. Checks for overflow. */
	template<typename U> friend CheckedInt<U> operator -(const CheckedInt<U>& lhs, const CheckedInt<U> &rhs);
	/** Substracts. Checks for overflow. \returns self reference */
	template<typename U> CheckedInt& operator -=(const U &rhs);
	/** \returns the product. Checks for overflow. */
	template<typename U> friend CheckedInt<U> operator *(const CheckedInt<U>& lhs, const CheckedInt<U> &rhs);
	/** Multiplies. Checks for overflow. \returns self reference */
	template<typename U> CheckedInt& operator *=(const U &rhs);
	/** \returns the quotient. Checks for overflow and for divide-by-zero. */
	template<typename U> friend CheckedInt<U> operator /(const CheckedInt<U>& lhs, const CheckedInt<U> &rhs);
	/** Divides. Checks for overflow and for divide-by-zero. \returns self reference */
	template<typename U> CheckedInt& operator /=(const U &rhs);

	/** \returns the opposite value. Checks for overflow. */
	CheckedInt operator -() const
	{
	T result = -value();
	/* give the compiler a good chance to perform RVO */
	return CheckedInt(result,
	mIsValid & CheckedInt_internal::is_sub_valid(T(0), value(), result));
	}

	/** \returns true if the left and right hand sides are valid and have the same value. */
	bool operator ==(const CheckedInt& other) const
	{
	return bool(mIsValid & other.mIsValid & T(value() == other.value()));
	}

	private:
	/** operator!= is disabled. Indeed: (a!=b) should be the same as !(a==b) but that
	* would mean that if a or b is invalid, (a!=b) is always true, which is very tricky.
	*/
	template<typename U>
	bool operator !=(const U& other) const { return !(*this == other); }
	};

	#define CHECKEDINT_BASIC_BINARY_OPERATOR(NAME, OP) \
	template<typename T> \
	inline CheckedInt<T> operator OP(const CheckedInt<T> &lhs, const CheckedInt<T> &rhs) \
	{ \
	T x = lhs.value(); \
	T y = rhs.value(); \
	T result = x OP y; \
	T is_op_valid \
	= CheckedInt_internal::is_##NAME##_valid(x, y, result); \
	/* give the compiler a good chance to perform RVO */ \
	return CheckedInt<T>(result, \
	lhs.mIsValid & \
	rhs.mIsValid & \
	is_op_valid); \
	}

	CHECKEDINT_BASIC_BINARY_OPERATOR(add, +)
	CHECKEDINT_BASIC_BINARY_OPERATOR(sub, -)
	CHECKEDINT_BASIC_BINARY_OPERATOR(mul, *)

	// division can't be implemented by CHECKEDINT_BASIC_BINARY_OPERATOR
	// because if rhs == 0, we are not allowed to even try to compute the quotient.
	template<typename T>
	inline CheckedInt<T> operator /(const CheckedInt<T> &lhs, const CheckedInt<T> &rhs)
	{
	T x = lhs.value();
	T y = rhs.value();
	T is_op_valid = CheckedInt_internal::is_div_valid(x, y);
	T result = is_op_valid ? (x / y) : 0;
	/* give the compiler a good chance to perform RVO */
	return CheckedInt<T>(result,
	lhs.mIsValid &
	rhs.mIsValid &
	is_op_valid);
	}

	// implement cast_to_CheckedInt<T>(x), making sure that
	// - it allows x to be either a CheckedInt<T> or any integer type that can be casted to T
	// - if x is already a CheckedInt<T>, we just return a reference to it, instead of copying it (optimization)

	template<typename T, typename U>
	struct cast_to_CheckedInt_impl
	{
	typedef CheckedInt<T> return_type;
	static CheckedInt<T> run(const U& u) { return u; }
	};

	template<typename T>
	struct cast_to_CheckedInt_impl<T, CheckedInt<T> >
	{
	typedef const CheckedInt<T>& return_type;
	static const CheckedInt<T>& run(const CheckedInt<T>& u) { return u; }
	};

	template<typename T, typename U>
	inline typename cast_to_CheckedInt_impl<T, U>::return_type
	cast_to_CheckedInt(const U& u)
	{
	return cast_to_CheckedInt_impl<T, U>::run(u);
	}

	#define CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(OP, COMPOUND_OP) \
	template<typename T> \
	template<typename U> \
	CheckedInt<T>& CheckedInt<T>::operator COMPOUND_OP(const U &rhs) \
	{ \
	this = this OP cast_to_CheckedInt<T>(rhs); \
	return *this; \
	} \
	template<typename T, typename U> \
	inline CheckedInt<T> operator OP(const CheckedInt<T> &lhs, const U &rhs) \
	{ \
	return lhs OP cast_to_CheckedInt<T>(rhs); \
	} \
	template<typename T, typename U> \
	inline CheckedInt<T> operator OP(const U & lhs, const CheckedInt<T> &rhs) \
	{ \
	return cast_to_CheckedInt<T>(lhs) OP rhs; \
	}

	CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(+, +=)
	CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(, =)
	CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(-, -=)
	CHECKEDINT_CONVENIENCE_BINARY_OPERATORS(/, /=)

	template<typename T, typename U>
	inline bool operator ==(const CheckedInt<T> &lhs, const U &rhs)
	{
	return lhs == cast_to_CheckedInt<T>(rhs);
	}

	template<typename T, typename U>
	inline bool operator ==(const U & lhs, const CheckedInt<T> &rhs)
	{
	return cast_to_CheckedInt<T>(lhs) == rhs;
	}

	} // end namespace WebCore

	#endif /* CheckedInt_h */