include/CL/cl_half.h - chromiumos/third_party/khronos - Git at Google

 /*******************************************************************************
  * Copyright (c) 2019-2020 The Khronos Group Inc.
  *
  * Licensed under the Apache License, Version 2.0 (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.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  ******************************************************************************/

 /**
  * This is a header-only utility library that provides OpenCL host code with
  * routines for converting to/from cl_half values.
  *
  * Example usage:
  *
  *    #include <CL/cl_half.h>
  *    ...
  *    cl_half h = cl_half_from_float(0.5f, CL_HALF_RTE);
  *    cl_float f = cl_half_to_float(h);
  */

 #ifndef OPENCL_CL_HALF_H
 #define OPENCL_CL_HALF_H

 #include <CL/cl_platform.h>

 #include <stdint.h>

 #ifdef __cplusplus
 extern "C" {
 #endif


 /**
  * Rounding mode used when converting to cl_half.
  */
 typedef enum
 {
   CL_HALF_RTE, // round to nearest even
   CL_HALF_RTZ, // round towards zero
   CL_HALF_RTP, // round towards positive infinity
   CL_HALF_RTN, // round towards negative infinity
 } cl_half_rounding_mode;


 /* Private utility macros. */
 #define CL_HALF_EXP_MASK 0x7C00
 #define CL_HALF_MAX_FINITE_MAG 0x7BFF


 /*
  * Utility to deal with values that overflow when converting to half precision.
  */
 static inline cl_half cl_half_handle_overflow(cl_half_rounding_mode rounding_mode,
                                               uint16_t sign)
 {
   if (rounding_mode == CL_HALF_RTZ)
   {
     // Round overflow towards zero -> largest finite number (preserving sign)
     return (sign << 15) | CL_HALF_MAX_FINITE_MAG;
   }
   else if (rounding_mode == CL_HALF_RTP && sign)
   {
     // Round negative overflow towards positive infinity -> most negative finite number
     return (1 << 15) | CL_HALF_MAX_FINITE_MAG;
   }
   else if (rounding_mode == CL_HALF_RTN && !sign)
   {
     // Round positive overflow towards negative infinity -> largest finite number
     return CL_HALF_MAX_FINITE_MAG;
   }

   // Overflow to infinity
   return (sign << 15) | CL_HALF_EXP_MASK;
 }

 /*
  * Utility to deal with values that underflow when converting to half precision.
  */
 static inline cl_half cl_half_handle_underflow(cl_half_rounding_mode rounding_mode,
                                                uint16_t sign)
 {
   if (rounding_mode == CL_HALF_RTP && !sign)
   {
     // Round underflow towards positive infinity -> smallest positive value
     return (sign << 15) | 1;
   }
   else if (rounding_mode == CL_HALF_RTN && sign)
   {
     // Round underflow towards negative infinity -> largest negative value
     return (sign << 15) | 1;
   }

   // Flush to zero
   return (sign << 15);
 }


 /**
  * Convert a cl_float to a cl_half.
  */
 static inline cl_half cl_half_from_float(cl_float f, cl_half_rounding_mode rounding_mode)
 {
   // Type-punning to get direct access to underlying bits
   union
   {
     cl_float f;
     uint32_t i;
   } f32;
   f32.f = f;

   // Extract sign bit
   uint16_t sign = f32.i >> 31;

   // Extract FP32 exponent and mantissa
   uint32_t f_exp = (f32.i >> (CL_FLT_MANT_DIG - 1)) & 0xFF;
   uint32_t f_mant = f32.i & ((1 << (CL_FLT_MANT_DIG - 1)) - 1);

   // Remove FP32 exponent bias
   int32_t exp = f_exp - CL_FLT_MAX_EXP + 1;

   // Add FP16 exponent bias
   uint16_t h_exp = (uint16_t)(exp + CL_HALF_MAX_EXP - 1);

   // Position of the bit that will become the FP16 mantissa LSB
   uint32_t lsb_pos = CL_FLT_MANT_DIG - CL_HALF_MANT_DIG;

   // Check for NaN / infinity
   if (f_exp == 0xFF)
   {
     if (f_mant)
     {
       // NaN -> propagate mantissa and silence it
       uint16_t h_mant = (uint16_t)(f_mant >> lsb_pos);
       h_mant |= 0x200;
       return (sign << 15) | CL_HALF_EXP_MASK | h_mant;
     }
     else
     {
       // Infinity -> zero mantissa
       return (sign << 15) | CL_HALF_EXP_MASK;
     }
   }

   // Check for zero
   if (!f_exp && !f_mant)
   {
     return (sign << 15);
   }

   // Check for overflow
   if (exp >= CL_HALF_MAX_EXP)
   {
     return cl_half_handle_overflow(rounding_mode, sign);
   }

   // Check for underflow
   if (exp < (CL_HALF_MIN_EXP - CL_HALF_MANT_DIG - 1))
   {
     return cl_half_handle_underflow(rounding_mode, sign);
   }

   // Check for value that will become denormal
   if (exp < -14)
   {
     // Denormal -> include the implicit 1 from the FP32 mantissa
     h_exp = 0;
     f_mant |= 1 << (CL_FLT_MANT_DIG - 1);

     // Mantissa shift amount depends on exponent
     lsb_pos = -exp + (CL_FLT_MANT_DIG - 25);
   }

   // Generate FP16 mantissa by shifting FP32 mantissa
   uint16_t h_mant = (uint16_t)(f_mant >> lsb_pos);

   // Check whether we need to round
   uint32_t halfway = 1 << (lsb_pos - 1);
   uint32_t mask = (halfway << 1) - 1;
   switch (rounding_mode)
   {
     case CL_HALF_RTE:
       if ((f_mant & mask) > halfway)
       {
         // More than halfway -> round up
         h_mant += 1;
       }
       else if ((f_mant & mask) == halfway)
       {
         // Exactly halfway -> round to nearest even
         if (h_mant & 0x1)
           h_mant += 1;
       }
       break;
     case CL_HALF_RTZ:
       // Mantissa has already been truncated -> do nothing
       break;
     case CL_HALF_RTP:
       if ((f_mant & mask) && !sign)
       {
         // Round positive numbers up
         h_mant += 1;
       }
       break;
     case CL_HALF_RTN:
       if ((f_mant & mask) && sign)
       {
         // Round negative numbers down
         h_mant += 1;
       }
       break;
   }

   // Check for mantissa overflow
   if (h_mant & 0x400)
   {
     h_exp += 1;
     h_mant = 0;
   }

   return (sign << 15) | (h_exp << 10) | h_mant;
 }


 /**
  * Convert a cl_double to a cl_half.
  */
 static inline cl_half cl_half_from_double(cl_double d, cl_half_rounding_mode rounding_mode)
 {
   // Type-punning to get direct access to underlying bits
   union
   {
     cl_double d;
     uint64_t i;
   } f64;
   f64.d = d;

   // Extract sign bit
   uint16_t sign = f64.i >> 63;

   // Extract FP64 exponent and mantissa
   uint64_t d_exp = (f64.i >> (CL_DBL_MANT_DIG - 1)) & 0x7FF;
   uint64_t d_mant = f64.i & (((uint64_t)1 << (CL_DBL_MANT_DIG - 1)) - 1);

   // Remove FP64 exponent bias
   int64_t exp = d_exp - CL_DBL_MAX_EXP + 1;

   // Add FP16 exponent bias
   uint16_t h_exp = (uint16_t)(exp + CL_HALF_MAX_EXP - 1);

   // Position of the bit that will become the FP16 mantissa LSB
   uint32_t lsb_pos = CL_DBL_MANT_DIG - CL_HALF_MANT_DIG;

   // Check for NaN / infinity
   if (d_exp == 0x7FF)
   {
     if (d_mant)
     {
       // NaN -> propagate mantissa and silence it
       uint16_t h_mant = (uint16_t)(d_mant >> lsb_pos);
       h_mant |= 0x200;
       return (sign << 15) | CL_HALF_EXP_MASK | h_mant;
     }
     else
     {
       // Infinity -> zero mantissa
       return (sign << 15) | CL_HALF_EXP_MASK;
     }
   }

   // Check for zero
   if (!d_exp && !d_mant)
   {
     return (sign << 15);
   }

   // Check for overflow
   if (exp >= CL_HALF_MAX_EXP)
   {
     return cl_half_handle_overflow(rounding_mode, sign);
   }

   // Check for underflow
   if (exp < (CL_HALF_MIN_EXP - CL_HALF_MANT_DIG - 1))
   {
     return cl_half_handle_underflow(rounding_mode, sign);
   }

   // Check for value that will become denormal
   if (exp < -14)
   {
     // Include the implicit 1 from the FP64 mantissa
     h_exp = 0;
     d_mant |= (uint64_t)1 << (CL_DBL_MANT_DIG - 1);

     // Mantissa shift amount depends on exponent
     lsb_pos = (uint32_t)(-exp + (CL_DBL_MANT_DIG - 25));
   }

   // Generate FP16 mantissa by shifting FP64 mantissa
   uint16_t h_mant = (uint16_t)(d_mant >> lsb_pos);

   // Check whether we need to round
   uint64_t halfway = (uint64_t)1 << (lsb_pos - 1);
   uint64_t mask = (halfway << 1) - 1;
   switch (rounding_mode)
   {
     case CL_HALF_RTE:
       if ((d_mant & mask) > halfway)
       {
         // More than halfway -> round up
         h_mant += 1;
       }
       else if ((d_mant & mask) == halfway)
       {
         // Exactly halfway -> round to nearest even
         if (h_mant & 0x1)
           h_mant += 1;
       }
       break;
     case CL_HALF_RTZ:
       // Mantissa has already been truncated -> do nothing
       break;
     case CL_HALF_RTP:
       if ((d_mant & mask) && !sign)
       {
         // Round positive numbers up
         h_mant += 1;
       }
       break;
     case CL_HALF_RTN:
       if ((d_mant & mask) && sign)
       {
         // Round negative numbers down
         h_mant += 1;
       }
       break;
   }

   // Check for mantissa overflow
   if (h_mant & 0x400)
   {
     h_exp += 1;
     h_mant = 0;
   }

   return (sign << 15) | (h_exp << 10) | h_mant;
 }


 /**
  * Convert a cl_half to a cl_float.
  */
 static inline cl_float cl_half_to_float(cl_half h)
 {
   // Type-punning to get direct access to underlying bits
   union
   {
     cl_float f;
     uint32_t i;
   } f32;

   // Extract sign bit
   uint16_t sign = h >> 15;

   // Extract FP16 exponent and mantissa
   uint16_t h_exp = (h >> (CL_HALF_MANT_DIG - 1)) & 0x1F;
   uint16_t h_mant = h & 0x3FF;

   // Remove FP16 exponent bias
   int32_t exp = h_exp - CL_HALF_MAX_EXP + 1;

   // Add FP32 exponent bias
   uint32_t f_exp = exp + CL_FLT_MAX_EXP - 1;

   // Check for NaN / infinity
   if (h_exp == 0x1F)
   {
     if (h_mant)
     {
       // NaN -> propagate mantissa and silence it
       uint32_t f_mant = h_mant << (CL_FLT_MANT_DIG - CL_HALF_MANT_DIG);
       f_mant |= 0x400000;
       f32.i = (sign << 31) | 0x7F800000 | f_mant;
       return f32.f;
     }
     else
     {
       // Infinity -> zero mantissa
       f32.i = (sign << 31) | 0x7F800000;
       return f32.f;
     }
   }

   // Check for zero / denormal
   if (h_exp == 0)
   {
     if (h_mant == 0)
     {
       // Zero -> zero exponent
       f_exp = 0;
     }
     else
     {
       // Denormal -> normalize it
       // - Shift mantissa to make most-significant 1 implicit
       // - Adjust exponent accordingly
       uint32_t shift = 0;
       while ((h_mant & 0x400) == 0)
       {
         h_mant <<= 1;
         shift++;
       }
       h_mant &= 0x3FF;
       f_exp -= shift - 1;
     }
   }

   f32.i = (sign << 31) | (f_exp << 23) | (h_mant << 13);
   return f32.f;
 }


 #undef CL_HALF_EXP_MASK
 #undef CL_HALF_MAX_FINITE_MAG


 #ifdef __cplusplus
 }
 #endif


 #endif  /* OPENCL_CL_HALF_H */
	/*******************************************************************************
	* Copyright (c) 2019-2020 The Khronos Group Inc.
	*
	* Licensed under the Apache License, Version 2.0 (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.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	******************************************************************************/

	/**
	* This is a header-only utility library that provides OpenCL host code with
	* routines for converting to/from cl_half values.
	*
	* Example usage:
	*
	* #include <CL/cl_half.h>
	* ...
	* cl_half h = cl_half_from_float(0.5f, CL_HALF_RTE);
	* cl_float f = cl_half_to_float(h);
	*/

	#ifndef OPENCL_CL_HALF_H
	#define OPENCL_CL_HALF_H

	#include <CL/cl_platform.h>

	#include <stdint.h>

	#ifdef __cplusplus
	extern "C" {
	#endif


	/**
	* Rounding mode used when converting to cl_half.
	*/
	typedef enum
	{
	CL_HALF_RTE, // round to nearest even
	CL_HALF_RTZ, // round towards zero
	CL_HALF_RTP, // round towards positive infinity
	CL_HALF_RTN, // round towards negative infinity
	} cl_half_rounding_mode;


	/* Private utility macros. */
	#define CL_HALF_EXP_MASK 0x7C00
	#define CL_HALF_MAX_FINITE_MAG 0x7BFF


	/*
	* Utility to deal with values that overflow when converting to half precision.
	*/
	static inline cl_half cl_half_handle_overflow(cl_half_rounding_mode rounding_mode,
	uint16_t sign)
	{
	if (rounding_mode == CL_HALF_RTZ)
	{
	// Round overflow towards zero -> largest finite number (preserving sign)
	return (sign << 15) \| CL_HALF_MAX_FINITE_MAG;
	}
	else if (rounding_mode == CL_HALF_RTP && sign)
	{
	// Round negative overflow towards positive infinity -> most negative finite number
	return (1 << 15) \| CL_HALF_MAX_FINITE_MAG;
	}
	else if (rounding_mode == CL_HALF_RTN && !sign)
	{
	// Round positive overflow towards negative infinity -> largest finite number
	return CL_HALF_MAX_FINITE_MAG;
	}

	// Overflow to infinity
	return (sign << 15) \| CL_HALF_EXP_MASK;
	}

	/*
	* Utility to deal with values that underflow when converting to half precision.
	*/
	static inline cl_half cl_half_handle_underflow(cl_half_rounding_mode rounding_mode,
	uint16_t sign)
	{
	if (rounding_mode == CL_HALF_RTP && !sign)
	{
	// Round underflow towards positive infinity -> smallest positive value
	return (sign << 15) \| 1;
	}
	else if (rounding_mode == CL_HALF_RTN && sign)
	{
	// Round underflow towards negative infinity -> largest negative value
	return (sign << 15) \| 1;
	}

	// Flush to zero
	return (sign << 15);
	}


	/**
	* Convert a cl_float to a cl_half.
	*/
	static inline cl_half cl_half_from_float(cl_float f, cl_half_rounding_mode rounding_mode)
	{
	// Type-punning to get direct access to underlying bits
	union
	{
	cl_float f;
	uint32_t i;
	} f32;
	f32.f = f;

	// Extract sign bit
	uint16_t sign = f32.i >> 31;

	// Extract FP32 exponent and mantissa
	uint32_t f_exp = (f32.i >> (CL_FLT_MANT_DIG - 1)) & 0xFF;
	uint32_t f_mant = f32.i & ((1 << (CL_FLT_MANT_DIG - 1)) - 1);

	// Remove FP32 exponent bias
	int32_t exp = f_exp - CL_FLT_MAX_EXP + 1;

	// Add FP16 exponent bias
	uint16_t h_exp = (uint16_t)(exp + CL_HALF_MAX_EXP - 1);

	// Position of the bit that will become the FP16 mantissa LSB
	uint32_t lsb_pos = CL_FLT_MANT_DIG - CL_HALF_MANT_DIG;

	// Check for NaN / infinity
	if (f_exp == 0xFF)
	{
	if (f_mant)
	{
	// NaN -> propagate mantissa and silence it
	uint16_t h_mant = (uint16_t)(f_mant >> lsb_pos);
	h_mant \|= 0x200;
	return (sign << 15) \| CL_HALF_EXP_MASK \| h_mant;
	}
	else
	{
	// Infinity -> zero mantissa
	return (sign << 15) \| CL_HALF_EXP_MASK;
	}
	}

	// Check for zero
	if (!f_exp && !f_mant)
	{
	return (sign << 15);
	}

	// Check for overflow
	if (exp >= CL_HALF_MAX_EXP)
	{
	return cl_half_handle_overflow(rounding_mode, sign);
	}

	// Check for underflow
	if (exp < (CL_HALF_MIN_EXP - CL_HALF_MANT_DIG - 1))
	{
	return cl_half_handle_underflow(rounding_mode, sign);
	}

	// Check for value that will become denormal
	if (exp < -14)
	{
	// Denormal -> include the implicit 1 from the FP32 mantissa
	h_exp = 0;
	f_mant \|= 1 << (CL_FLT_MANT_DIG - 1);

	// Mantissa shift amount depends on exponent
	lsb_pos = -exp + (CL_FLT_MANT_DIG - 25);
	}

	// Generate FP16 mantissa by shifting FP32 mantissa
	uint16_t h_mant = (uint16_t)(f_mant >> lsb_pos);

	// Check whether we need to round
	uint32_t halfway = 1 << (lsb_pos - 1);
	uint32_t mask = (halfway << 1) - 1;
	switch (rounding_mode)
	{
	case CL_HALF_RTE:
	if ((f_mant & mask) > halfway)
	{
	// More than halfway -> round up
	h_mant += 1;
	}
	else if ((f_mant & mask) == halfway)
	{
	// Exactly halfway -> round to nearest even
	if (h_mant & 0x1)
	h_mant += 1;
	}
	break;
	case CL_HALF_RTZ:
	// Mantissa has already been truncated -> do nothing
	break;
	case CL_HALF_RTP:
	if ((f_mant & mask) && !sign)
	{
	// Round positive numbers up
	h_mant += 1;
	}
	break;
	case CL_HALF_RTN:
	if ((f_mant & mask) && sign)
	{
	// Round negative numbers down
	h_mant += 1;
	}
	break;
	}

	// Check for mantissa overflow
	if (h_mant & 0x400)
	{
	h_exp += 1;
	h_mant = 0;
	}

	return (sign << 15) \| (h_exp << 10) \| h_mant;
	}


	/**
	* Convert a cl_double to a cl_half.
	*/
	static inline cl_half cl_half_from_double(cl_double d, cl_half_rounding_mode rounding_mode)
	{
	// Type-punning to get direct access to underlying bits
	union
	{
	cl_double d;
	uint64_t i;
	} f64;
	f64.d = d;

	// Extract sign bit
	uint16_t sign = f64.i >> 63;

	// Extract FP64 exponent and mantissa
	uint64_t d_exp = (f64.i >> (CL_DBL_MANT_DIG - 1)) & 0x7FF;
	uint64_t d_mant = f64.i & (((uint64_t)1 << (CL_DBL_MANT_DIG - 1)) - 1);

	// Remove FP64 exponent bias
	int64_t exp = d_exp - CL_DBL_MAX_EXP + 1;

	// Add FP16 exponent bias
	uint16_t h_exp = (uint16_t)(exp + CL_HALF_MAX_EXP - 1);

	// Position of the bit that will become the FP16 mantissa LSB
	uint32_t lsb_pos = CL_DBL_MANT_DIG - CL_HALF_MANT_DIG;

	// Check for NaN / infinity
	if (d_exp == 0x7FF)
	{
	if (d_mant)
	{
	// NaN -> propagate mantissa and silence it
	uint16_t h_mant = (uint16_t)(d_mant >> lsb_pos);
	h_mant \|= 0x200;
	return (sign << 15) \| CL_HALF_EXP_MASK \| h_mant;
	}
	else
	{
	// Infinity -> zero mantissa
	return (sign << 15) \| CL_HALF_EXP_MASK;
	}
	}

	// Check for zero
	if (!d_exp && !d_mant)
	{
	return (sign << 15);
	}

	// Check for overflow
	if (exp >= CL_HALF_MAX_EXP)
	{
	return cl_half_handle_overflow(rounding_mode, sign);
	}

	// Check for underflow
	if (exp < (CL_HALF_MIN_EXP - CL_HALF_MANT_DIG - 1))
	{
	return cl_half_handle_underflow(rounding_mode, sign);
	}

	// Check for value that will become denormal
	if (exp < -14)
	{
	// Include the implicit 1 from the FP64 mantissa
	h_exp = 0;
	d_mant \|= (uint64_t)1 << (CL_DBL_MANT_DIG - 1);

	// Mantissa shift amount depends on exponent
	lsb_pos = (uint32_t)(-exp + (CL_DBL_MANT_DIG - 25));
	}

	// Generate FP16 mantissa by shifting FP64 mantissa
	uint16_t h_mant = (uint16_t)(d_mant >> lsb_pos);

	// Check whether we need to round
	uint64_t halfway = (uint64_t)1 << (lsb_pos - 1);
	uint64_t mask = (halfway << 1) - 1;
	switch (rounding_mode)
	{
	case CL_HALF_RTE:
	if ((d_mant & mask) > halfway)
	{
	// More than halfway -> round up
	h_mant += 1;
	}
	else if ((d_mant & mask) == halfway)
	{
	// Exactly halfway -> round to nearest even
	if (h_mant & 0x1)
	h_mant += 1;
	}
	break;
	case CL_HALF_RTZ:
	// Mantissa has already been truncated -> do nothing
	break;
	case CL_HALF_RTP:
	if ((d_mant & mask) && !sign)
	{
	// Round positive numbers up
	h_mant += 1;
	}
	break;
	case CL_HALF_RTN:
	if ((d_mant & mask) && sign)
	{
	// Round negative numbers down
	h_mant += 1;
	}
	break;
	}

	// Check for mantissa overflow
	if (h_mant & 0x400)
	{
	h_exp += 1;
	h_mant = 0;
	}

	return (sign << 15) \| (h_exp << 10) \| h_mant;
	}


	/**
	* Convert a cl_half to a cl_float.
	*/
	static inline cl_float cl_half_to_float(cl_half h)
	{
	// Type-punning to get direct access to underlying bits
	union
	{
	cl_float f;
	uint32_t i;
	} f32;

	// Extract sign bit
	uint16_t sign = h >> 15;

	// Extract FP16 exponent and mantissa
	uint16_t h_exp = (h >> (CL_HALF_MANT_DIG - 1)) & 0x1F;
	uint16_t h_mant = h & 0x3FF;

	// Remove FP16 exponent bias
	int32_t exp = h_exp - CL_HALF_MAX_EXP + 1;

	// Add FP32 exponent bias
	uint32_t f_exp = exp + CL_FLT_MAX_EXP - 1;

	// Check for NaN / infinity
	if (h_exp == 0x1F)
	{
	if (h_mant)
	{
	// NaN -> propagate mantissa and silence it
	uint32_t f_mant = h_mant << (CL_FLT_MANT_DIG - CL_HALF_MANT_DIG);
	f_mant \|= 0x400000;
	f32.i = (sign << 31) \| 0x7F800000 \| f_mant;
	return f32.f;
	}
	else
	{
	// Infinity -> zero mantissa
	f32.i = (sign << 31) \| 0x7F800000;
	return f32.f;
	}
	}

	// Check for zero / denormal
	if (h_exp == 0)
	{
	if (h_mant == 0)
	{
	// Zero -> zero exponent
	f_exp = 0;
	}
	else
	{
	// Denormal -> normalize it
	// - Shift mantissa to make most-significant 1 implicit
	// - Adjust exponent accordingly
	uint32_t shift = 0;
	while ((h_mant & 0x400) == 0)
	{
	h_mant <<= 1;
	shift++;
	}
	h_mant &= 0x3FF;
	f_exp -= shift - 1;
	}
	}

	f32.i = (sign << 31) \| (f_exp << 23) \| (h_mant << 13);
	return f32.f;
	}


	#undef CL_HALF_EXP_MASK
	#undef CL_HALF_MAX_FINITE_MAG


	#ifdef __cplusplus
	}
	#endif


	#endif /* OPENCL_CL_HALF_H */