src/third_party/glm/glm/detail/type_half.inl - cobalt - Git at Google

 /// @ref core
 /// @file glm/detail/type_half.inl

 namespace glm{
 namespace detail
 {
 	GLM_FUNC_QUALIFIER float overflow()
 	{
 		volatile float f = 1e10;

 		for(int i = 0; i < 10; ++i)
 			f *= f; // this will overflow before the for loop terminates
 		return f;
 	}

 	union uif32
 	{
 		GLM_FUNC_QUALIFIER uif32() :
 			i(0)
 		{}

 		GLM_FUNC_QUALIFIER uif32(float f_) :
 			f(f_)
 		{}

 		GLM_FUNC_QUALIFIER uif32(uint32 i_) :
 			i(i_)
 		{}

 		float f;
 		uint32 i;
 	};

 	GLM_FUNC_QUALIFIER float toFloat32(hdata value)
 	{
 		int s = (value >> 15) & 0x00000001;
 		int e = (value >> 10) & 0x0000001f;
 		int m =  value        & 0x000003ff;

 		if(e == 0)
 		{
 			if(m == 0)
 			{
 				//
 				// Plus or minus zero
 				//

 				detail::uif32 result;
 				result.i = (unsigned int)(s << 31);
 				return result.f;
 			}
 			else
 			{
 				//
 				// Denormalized number -- renormalize it
 				//

 				while(!(m & 0x00000400))
 				{
 					m <<= 1;
 					e -=  1;
 				}

 				e += 1;
 				m &= ~0x00000400;
 			}
 		}
 		else if(e == 31)
 		{
 			if(m == 0)
 			{
 				//
 				// Positive or negative infinity
 				//

 				uif32 result;
 				result.i = (unsigned int)((s << 31) | 0x7f800000);
 				return result.f;
 			}
 			else
 			{
 				//
 				// Nan -- preserve sign and significand bits
 				//

 				uif32 result;
 				result.i = (unsigned int)((s << 31) | 0x7f800000 | (m << 13));
 				return result.f;
 			}
 		}

 		//
 		// Normalized number
 		//

 		e = e + (127 - 15);
 		m = m << 13;

 		//
 		// Assemble s, e and m.
 		//

 		uif32 Result;
 		Result.i = (unsigned int)((s << 31) | (e << 23) | m);
 		return Result.f;
 	}

 	GLM_FUNC_QUALIFIER hdata toFloat16(float const & f)
 	{
 		uif32 Entry;
 		Entry.f = f;
 		int i = (int)Entry.i;

 		//
 		// Our floating point number, f, is represented by the bit
 		// pattern in integer i.  Disassemble that bit pattern into
 		// the sign, s, the exponent, e, and the significand, m.
 		// Shift s into the position where it will go in in the
 		// resulting half number.
 		// Adjust e, accounting for the different exponent bias
 		// of float and half (127 versus 15).
 		//

 		int s =  (i >> 16) & 0x00008000;
 		int e = ((i >> 23) & 0x000000ff) - (127 - 15);
 		int m =   i        & 0x007fffff;

 		//
 		// Now reassemble s, e and m into a half:
 		//

 		if(e <= 0)
 		{
 			if(e < -10)
 			{
 				//
 				// E is less than -10.  The absolute value of f is
 				// less than half_MIN (f may be a small normalized
 				// float, a denormalized float or a zero).
 				//
 				// We convert f to a half zero.
 				//

 				return hdata(s);
 			}

 			//
 			// E is between -10 and 0.  F is a normalized float,
 			// whose magnitude is less than __half_NRM_MIN.
 			//
 			// We convert f to a denormalized half.
 			//

 			m = (m | 0x00800000) >> (1 - e);

 			//
 			// Round to nearest, round "0.5" up.
 			//
 			// Rounding may cause the significand to overflow and make
 			// our number normalized.  Because of the way a half's bits
 			// are laid out, we don't have to treat this case separately;
 			// the code below will handle it correctly.
 			//

 			if(m & 0x00001000)
 				m += 0x00002000;

 			//
 			// Assemble the half from s, e (zero) and m.
 			//

 			return hdata(s | (m >> 13));
 		}
 		else if(e == 0xff - (127 - 15))
 		{
 			if(m == 0)
 			{
 				//
 				// F is an infinity; convert f to a half
 				// infinity with the same sign as f.
 				//

 				return hdata(s | 0x7c00);
 			}
 			else
 			{
 				//
 				// F is a NAN; we produce a half NAN that preserves
 				// the sign bit and the 10 leftmost bits of the
 				// significand of f, with one exception: If the 10
 				// leftmost bits are all zero, the NAN would turn
 				// into an infinity, so we have to set at least one
 				// bit in the significand.
 				//

 				m >>= 13;

 				return hdata(s | 0x7c00 | m | (m == 0));
 			}
 		}
 		else
 		{
 			//
 			// E is greater than zero.  F is a normalized float.
 			// We try to convert f to a normalized half.
 			//

 			//
 			// Round to nearest, round "0.5" up
 			//

 			if(m &  0x00001000)
 			{
 				m += 0x00002000;

 				if(m & 0x00800000)
 				{
 					m =  0;     // overflow in significand,
 					e += 1;     // adjust exponent
 				}
 			}

 			//
 			// Handle exponent overflow
 			//

 			if (e > 30)
 			{
 				overflow();        // Cause a hardware floating point overflow;

 				return hdata(s | 0x7c00);
 				// if this returns, the half becomes an
 			}   // infinity with the same sign as f.

 			//
 			// Assemble the half from s, e and m.
 			//

 			return hdata(s | (e << 10) | (m >> 13));
 		}
 	}

 }//namespace detail
 }//namespace glm
	/// @ref core
	/// @file glm/detail/type_half.inl

	namespace glm{
	namespace detail
	{
	GLM_FUNC_QUALIFIER float overflow()
	{
	volatile float f = 1e10;

	for(int i = 0; i < 10; ++i)
	f *= f; // this will overflow before the for loop terminates
	return f;
	}

	union uif32
	{
	GLM_FUNC_QUALIFIER uif32() :
	i(0)
	{}

	GLM_FUNC_QUALIFIER uif32(float f_) :
	f(f_)
	{}

	GLM_FUNC_QUALIFIER uif32(uint32 i_) :
	i(i_)
	{}

	float f;
	uint32 i;
	};

	GLM_FUNC_QUALIFIER float toFloat32(hdata value)
	{
	int s = (value >> 15) & 0x00000001;
	int e = (value >> 10) & 0x0000001f;
	int m = value & 0x000003ff;

	if(e == 0)
	{
	if(m == 0)
	{
	//
	// Plus or minus zero
	//

	detail::uif32 result;
	result.i = (unsigned int)(s << 31);
	return result.f;
	}
	else
	{
	//
	// Denormalized number -- renormalize it
	//

	while(!(m & 0x00000400))
	{
	m <<= 1;
	e -= 1;
	}

	e += 1;
	m &= ~0x00000400;
	}
	}
	else if(e == 31)
	{
	if(m == 0)
	{
	//
	// Positive or negative infinity
	//

	uif32 result;
	result.i = (unsigned int)((s << 31) \| 0x7f800000);
	return result.f;
	}
	else
	{
	//
	// Nan -- preserve sign and significand bits
	//

	uif32 result;
	result.i = (unsigned int)((s << 31) \| 0x7f800000 \| (m << 13));
	return result.f;
	}
	}

	//
	// Normalized number
	//

	e = e + (127 - 15);
	m = m << 13;

	//
	// Assemble s, e and m.
	//

	uif32 Result;
	Result.i = (unsigned int)((s << 31) \| (e << 23) \| m);
	return Result.f;
	}

	GLM_FUNC_QUALIFIER hdata toFloat16(float const & f)
	{
	uif32 Entry;
	Entry.f = f;
	int i = (int)Entry.i;

	//
	// Our floating point number, f, is represented by the bit
	// pattern in integer i. Disassemble that bit pattern into
	// the sign, s, the exponent, e, and the significand, m.
	// Shift s into the position where it will go in in the
	// resulting half number.
	// Adjust e, accounting for the different exponent bias
	// of float and half (127 versus 15).
	//

	int s = (i >> 16) & 0x00008000;
	int e = ((i >> 23) & 0x000000ff) - (127 - 15);
	int m = i & 0x007fffff;

	//
	// Now reassemble s, e and m into a half:
	//

	if(e <= 0)
	{
	if(e < -10)
	{
	//
	// E is less than -10. The absolute value of f is
	// less than half_MIN (f may be a small normalized
	// float, a denormalized float or a zero).
	//
	// We convert f to a half zero.
	//

	return hdata(s);
	}

	//
	// E is between -10 and 0. F is a normalized float,
	// whose magnitude is less than __half_NRM_MIN.
	//
	// We convert f to a denormalized half.
	//

	m = (m \| 0x00800000) >> (1 - e);

	//
	// Round to nearest, round "0.5" up.
	//
	// Rounding may cause the significand to overflow and make
	// our number normalized. Because of the way a half's bits
	// are laid out, we don't have to treat this case separately;
	// the code below will handle it correctly.
	//

	if(m & 0x00001000)
	m += 0x00002000;

	//
	// Assemble the half from s, e (zero) and m.
	//

	return hdata(s \| (m >> 13));
	}
	else if(e == 0xff - (127 - 15))
	{
	if(m == 0)
	{
	//
	// F is an infinity; convert f to a half
	// infinity with the same sign as f.
	//

	return hdata(s \| 0x7c00);
	}
	else
	{
	//
	// F is a NAN; we produce a half NAN that preserves
	// the sign bit and the 10 leftmost bits of the
	// significand of f, with one exception: If the 10
	// leftmost bits are all zero, the NAN would turn
	// into an infinity, so we have to set at least one
	// bit in the significand.
	//

	m >>= 13;

	return hdata(s \| 0x7c00 \| m \| (m == 0));
	}
	}
	else
	{
	//
	// E is greater than zero. F is a normalized float.
	// We try to convert f to a normalized half.
	//

	//
	// Round to nearest, round "0.5" up
	//

	if(m & 0x00001000)
	{
	m += 0x00002000;

	if(m & 0x00800000)
	{
	m = 0; // overflow in significand,
	e += 1; // adjust exponent
	}
	}

	//
	// Handle exponent overflow
	//

	if (e > 30)
	{
	overflow(); // Cause a hardware floating point overflow;

	return hdata(s \| 0x7c00);
	// if this returns, the half becomes an
	} // infinity with the same sign as f.

	//
	// Assemble the half from s, e and m.
	//

	return hdata(s \| (e << 10) \| (m >> 13));
	}
	}

	}//namespace detail
	}//namespace glm