drivers/gpu/drm/amd/display/include/fixed31_32.h - linux/kernel/git/bpf/bpf - Git at Google

 /*
  * Copyright 2012-15 Advanced Micro Devices, Inc.
  *
  * Permission is hereby granted, free of charge, to any person obtaining a
  * copy of this software and associated documentation files (the "Software"),
  * to deal in the Software without restriction, including without limitation
  * the rights to use, copy, modify, merge, publish, distribute, sublicense,
  * and/or sell copies of the Software, and to permit persons to whom the
  * Software is furnished to do so, subject to the following conditions:
  *
  * The above copyright notice and this permission notice shall be included in
  * all copies or substantial portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
  * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
  * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
  * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
  * OTHER DEALINGS IN THE SOFTWARE.
  *
  * Authors: AMD
  *
  */

 #ifndef __DAL_FIXED31_32_H__
 #define __DAL_FIXED31_32_H__

 #ifndef LLONG_MAX
 #define LLONG_MAX 9223372036854775807ll
 #endif
 #ifndef LLONG_MIN
 #define LLONG_MIN (-LLONG_MAX - 1ll)
 #endif

 #define FIXED31_32_BITS_PER_FRACTIONAL_PART 32
 #ifndef LLONG_MIN
 #define LLONG_MIN (1LL<<63)
 #endif
 #ifndef LLONG_MAX
 #define LLONG_MAX (-1LL>>1)
 #endif

 /*
  * @brief
  * Arithmetic operations on real numbers
  * represented as fixed-point numbers.
  * There are: 1 bit for sign,
  * 31 bit for integer part,
  * 32 bits for fractional part.
  *
  * @note
  * Currently, overflows and underflows are asserted;
  * no special result returned.
  */

 struct fixed31_32 {
 	long long value;
 };


 /*
  * @brief
  * Useful constants
  */

 static const struct fixed31_32 dc_fixpt_zero = { 0 };
 static const struct fixed31_32 dc_fixpt_epsilon = { 1LL };
 static const struct fixed31_32 dc_fixpt_half = { 0x80000000LL };
 static const struct fixed31_32 dc_fixpt_one = { 0x100000000LL };

 static const struct fixed31_32 dc_fixpt_pi = { 13493037705LL };
 static const struct fixed31_32 dc_fixpt_two_pi = { 26986075409LL };
 static const struct fixed31_32 dc_fixpt_e = { 11674931555LL };
 static const struct fixed31_32 dc_fixpt_ln2 = { 2977044471LL };
 static const struct fixed31_32 dc_fixpt_ln2_div_2 = { 1488522236LL };

 /*
  * @brief
  * Initialization routines
  */

 /*
  * @brief
  * result = numerator / denominator
  */
 struct fixed31_32 dc_fixpt_from_fraction(long long numerator, long long denominator);

 /*
  * @brief
  * result = arg
  */
 static inline struct fixed31_32 dc_fixpt_from_int(int arg)
 {
 	struct fixed31_32 res;

 	res.value = (long long) arg << FIXED31_32_BITS_PER_FRACTIONAL_PART;

 	return res;
 }

 /*
  * @brief
  * Unary operators
  */

 /*
  * @brief
  * result = -arg
  */
 static inline struct fixed31_32 dc_fixpt_neg(struct fixed31_32 arg)
 {
 	struct fixed31_32 res;

 	res.value = -arg.value;

 	return res;
 }

 /*
  * @brief
  * result = abs(arg) := (arg >= 0) ? arg : -arg
  */
 static inline struct fixed31_32 dc_fixpt_abs(struct fixed31_32 arg)
 {
 	if (arg.value < 0)
 		return dc_fixpt_neg(arg);
 	else
 		return arg;
 }

 /*
  * @brief
  * Binary relational operators
  */

 /*
  * @brief
  * result = arg1 < arg2
  */
 static inline bool dc_fixpt_lt(struct fixed31_32 arg1, struct fixed31_32 arg2)
 {
 	return arg1.value < arg2.value;
 }

 /*
  * @brief
  * result = arg1 <= arg2
  */
 static inline bool dc_fixpt_le(struct fixed31_32 arg1, struct fixed31_32 arg2)
 {
 	return arg1.value <= arg2.value;
 }

 /*
  * @brief
  * result = arg1 == arg2
  */
 static inline bool dc_fixpt_eq(struct fixed31_32 arg1, struct fixed31_32 arg2)
 {
 	return arg1.value == arg2.value;
 }

 /*
  * @brief
  * result = min(arg1, arg2) := (arg1 <= arg2) ? arg1 : arg2
  */
 static inline struct fixed31_32 dc_fixpt_min(struct fixed31_32 arg1, struct fixed31_32 arg2)
 {
 	if (arg1.value <= arg2.value)
 		return arg1;
 	else
 		return arg2;
 }

 /*
  * @brief
  * result = max(arg1, arg2) := (arg1 <= arg2) ? arg2 : arg1
  */
 static inline struct fixed31_32 dc_fixpt_max(struct fixed31_32 arg1, struct fixed31_32 arg2)
 {
 	if (arg1.value <= arg2.value)
 		return arg2;
 	else
 		return arg1;
 }

 /*
  * @brief
  *          | min_value, when arg <= min_value
  * result = | arg, when min_value < arg < max_value
  *          | max_value, when arg >= max_value
  */
 static inline struct fixed31_32 dc_fixpt_clamp(
 	struct fixed31_32 arg,
 	struct fixed31_32 min_value,
 	struct fixed31_32 max_value)
 {
 	if (dc_fixpt_le(arg, min_value))
 		return min_value;
 	else if (dc_fixpt_le(max_value, arg))
 		return max_value;
 	else
 		return arg;
 }

 /*
  * @brief
  * Binary shift operators
  */

 /*
  * @brief
  * result = arg << shift
  */
 static inline struct fixed31_32 dc_fixpt_shl(struct fixed31_32 arg, unsigned char shift)
 {
 	ASSERT(((arg.value >= 0) && (arg.value <= LLONG_MAX >> shift)) ||
 		((arg.value < 0) && (arg.value >= ~(LLONG_MAX >> shift))));

 	arg.value = arg.value << shift;

 	return arg;
 }

 /*
  * @brief
  * result = arg >> shift
  */
 static inline struct fixed31_32 dc_fixpt_shr(struct fixed31_32 arg, unsigned char shift)
 {
 	bool negative = arg.value < 0;

 	if (negative)
 		arg.value = -arg.value;
 	arg.value = arg.value >> shift;
 	if (negative)
 		arg.value = -arg.value;
 	return arg;
 }

 /*
  * @brief
  * Binary additive operators
  */

 /*
  * @brief
  * result = arg1 + arg2
  */
 static inline struct fixed31_32 dc_fixpt_add(struct fixed31_32 arg1, struct fixed31_32 arg2)
 {
 	struct fixed31_32 res;

 	ASSERT(((arg1.value >= 0) && (LLONG_MAX - arg1.value >= arg2.value)) ||
 		((arg1.value < 0) && (LLONG_MIN - arg1.value <= arg2.value)));

 	res.value = arg1.value + arg2.value;

 	return res;
 }

 /*
  * @brief
  * result = arg1 + arg2
  */
 static inline struct fixed31_32 dc_fixpt_add_int(struct fixed31_32 arg1, int arg2)
 {
 	return dc_fixpt_add(arg1, dc_fixpt_from_int(arg2));
 }

 /*
  * @brief
  * result = arg1 - arg2
  */
 static inline struct fixed31_32 dc_fixpt_sub(struct fixed31_32 arg1, struct fixed31_32 arg2)
 {
 	struct fixed31_32 res;

 	ASSERT(((arg2.value >= 0) && (LLONG_MIN + arg2.value <= arg1.value)) ||
 		((arg2.value < 0) && (LLONG_MAX + arg2.value >= arg1.value)));

 	res.value = arg1.value - arg2.value;

 	return res;
 }

 /*
  * @brief
  * result = arg1 - arg2
  */
 static inline struct fixed31_32 dc_fixpt_sub_int(struct fixed31_32 arg1, int arg2)
 {
 	return dc_fixpt_sub(arg1, dc_fixpt_from_int(arg2));
 }


 /*
  * @brief
  * Binary multiplicative operators
  */

 /*
  * @brief
  * result = arg1 * arg2
  */
 struct fixed31_32 dc_fixpt_mul(struct fixed31_32 arg1, struct fixed31_32 arg2);


 /*
  * @brief
  * result = arg1 * arg2
  */
 static inline struct fixed31_32 dc_fixpt_mul_int(struct fixed31_32 arg1, int arg2)
 {
 	return dc_fixpt_mul(arg1, dc_fixpt_from_int(arg2));
 }

 /*
  * @brief
  * result = square(arg) := arg * arg
  */
 struct fixed31_32 dc_fixpt_sqr(struct fixed31_32 arg);

 /*
  * @brief
  * result = arg1 / arg2
  */
 static inline struct fixed31_32 dc_fixpt_div_int(struct fixed31_32 arg1, long long arg2)
 {
 	return dc_fixpt_from_fraction(arg1.value, dc_fixpt_from_int(arg2).value);
 }

 /*
  * @brief
  * result = arg1 / arg2
  */
 static inline struct fixed31_32 dc_fixpt_div(struct fixed31_32 arg1, struct fixed31_32 arg2)
 {
 	return dc_fixpt_from_fraction(arg1.value, arg2.value);
 }

 /*
  * @brief
  * Reciprocal function
  */

 /*
  * @brief
  * result = reciprocal(arg) := 1 / arg
  *
  * @note
  * No special actions taken in case argument is zero.
  */
 struct fixed31_32 dc_fixpt_recip(struct fixed31_32 arg);

 /*
  * @brief
  * Trigonometric functions
  */

 /*
  * @brief
  * result = sinc(arg) := sin(arg) / arg
  *
  * @note
  * Argument specified in radians,
  * internally it's normalized to [-2pi...2pi] range.
  */
 struct fixed31_32 dc_fixpt_sinc(struct fixed31_32 arg);

 /*
  * @brief
  * result = sin(arg)
  *
  * @note
  * Argument specified in radians,
  * internally it's normalized to [-2pi...2pi] range.
  */
 struct fixed31_32 dc_fixpt_sin(struct fixed31_32 arg);

 /*
  * @brief
  * result = cos(arg)
  *
  * @note
  * Argument specified in radians
  * and should be in [-2pi...2pi] range -
  * passing arguments outside that range
  * will cause incorrect result!
  */
 struct fixed31_32 dc_fixpt_cos(struct fixed31_32 arg);

 /*
  * @brief
  * Transcendent functions
  */

 /*
  * @brief
  * result = exp(arg)
  *
  * @note
  * Currently, function is verified for abs(arg) <= 1.
  */
 struct fixed31_32 dc_fixpt_exp(struct fixed31_32 arg);

 /*
  * @brief
  * result = log(arg)
  *
  * @note
  * Currently, abs(arg) should be less than 1.
  * No normalization is done.
  * Currently, no special actions taken
  * in case of invalid argument(s). Take care!
  */
 struct fixed31_32 dc_fixpt_log(struct fixed31_32 arg);

 /*
  * @brief
  * Power function
  */

 /*
  * @brief
  * result = pow(arg1, arg2)
  *
  * @note
  * Currently, abs(arg1) should be less than 1. Take care!
  */
 static inline struct fixed31_32 dc_fixpt_pow(struct fixed31_32 arg1, struct fixed31_32 arg2)
 {
 	return dc_fixpt_exp(
 		dc_fixpt_mul(
 			dc_fixpt_log(arg1),
 			arg2));
 }

 /*
  * @brief
  * Rounding functions
  */

 /*
  * @brief
  * result = floor(arg) := greatest integer lower than or equal to arg
  */
 static inline int dc_fixpt_floor(struct fixed31_32 arg)
 {
 	unsigned long long arg_value = arg.value > 0 ? arg.value : -arg.value;

 	if (arg.value >= 0)
 		return (int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
 	else
 		return -(int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
 }

 /*
  * @brief
  * result = round(arg) := integer nearest to arg
  */
 static inline int dc_fixpt_round(struct fixed31_32 arg)
 {
 	unsigned long long arg_value = arg.value > 0 ? arg.value : -arg.value;

 	const long long summand = dc_fixpt_half.value;

 	ASSERT(LLONG_MAX - (long long)arg_value >= summand);

 	arg_value += summand;

 	if (arg.value >= 0)
 		return (int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
 	else
 		return -(int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
 }

 /*
  * @brief
  * result = ceil(arg) := lowest integer greater than or equal to arg
  */
 static inline int dc_fixpt_ceil(struct fixed31_32 arg)
 {
 	unsigned long long arg_value = arg.value > 0 ? arg.value : -arg.value;

 	const long long summand = dc_fixpt_one.value -
 		dc_fixpt_epsilon.value;

 	ASSERT(LLONG_MAX - (long long)arg_value >= summand);

 	arg_value += summand;

 	if (arg.value >= 0)
 		return (int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
 	else
 		return -(int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
 }

 /* the following two function are used in scaler hw programming to convert fixed
  * point value to format 2 bits from integer part and 19 bits from fractional
  * part. The same applies for u0d19, 0 bits from integer part and 19 bits from
  * fractional
  */

 unsigned int dc_fixpt_u4d19(struct fixed31_32 arg);

 unsigned int dc_fixpt_u3d19(struct fixed31_32 arg);

 unsigned int dc_fixpt_u2d19(struct fixed31_32 arg);

 unsigned int dc_fixpt_u0d19(struct fixed31_32 arg);

 unsigned int dc_fixpt_clamp_u0d14(struct fixed31_32 arg);

 unsigned int dc_fixpt_clamp_u0d10(struct fixed31_32 arg);

 int dc_fixpt_s4d19(struct fixed31_32 arg);

 static inline struct fixed31_32 dc_fixpt_truncate(struct fixed31_32 arg, unsigned int frac_bits)
 {
 	bool negative = arg.value < 0;

 	if (frac_bits >= FIXED31_32_BITS_PER_FRACTIONAL_PART) {
 		ASSERT(frac_bits == FIXED31_32_BITS_PER_FRACTIONAL_PART);
 		return arg;
 	}

 	if (negative)
 		arg.value = -arg.value;
 	arg.value &= (~0LL) << (FIXED31_32_BITS_PER_FRACTIONAL_PART - frac_bits);
 	if (negative)
 		arg.value = -arg.value;
 	return arg;
 }

 #endif
	/*
	* Copyright 2012-15 Advanced Micro Devices, Inc.
	*
	* Permission is hereby granted, free of charge, to any person obtaining a
	* copy of this software and associated documentation files (the "Software"),
	* to deal in the Software without restriction, including without limitation
	* the rights to use, copy, modify, merge, publish, distribute, sublicense,
	* and/or sell copies of the Software, and to permit persons to whom the
	* Software is furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included in
	* all copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
	* THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
	* OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
	* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
	* OTHER DEALINGS IN THE SOFTWARE.
	*
	* Authors: AMD
	*
	*/

	#ifndef __DAL_FIXED31_32_H__
	#define __DAL_FIXED31_32_H__

	#ifndef LLONG_MAX
	#define LLONG_MAX 9223372036854775807ll
	#endif
	#ifndef LLONG_MIN
	#define LLONG_MIN (-LLONG_MAX - 1ll)
	#endif

	#define FIXED31_32_BITS_PER_FRACTIONAL_PART 32
	#ifndef LLONG_MIN
	#define LLONG_MIN (1LL<<63)
	#endif
	#ifndef LLONG_MAX
	#define LLONG_MAX (-1LL>>1)
	#endif

	/*
	* @brief
	* Arithmetic operations on real numbers
	* represented as fixed-point numbers.
	* There are: 1 bit for sign,
	* 31 bit for integer part,
	* 32 bits for fractional part.
	*
	* @note
	* Currently, overflows and underflows are asserted;
	* no special result returned.
	*/

	struct fixed31_32 {
	long long value;
	};


	/*
	* @brief
	* Useful constants
	*/

	static const struct fixed31_32 dc_fixpt_zero = { 0 };
	static const struct fixed31_32 dc_fixpt_epsilon = { 1LL };
	static const struct fixed31_32 dc_fixpt_half = { 0x80000000LL };
	static const struct fixed31_32 dc_fixpt_one = { 0x100000000LL };

	static const struct fixed31_32 dc_fixpt_pi = { 13493037705LL };
	static const struct fixed31_32 dc_fixpt_two_pi = { 26986075409LL };
	static const struct fixed31_32 dc_fixpt_e = { 11674931555LL };
	static const struct fixed31_32 dc_fixpt_ln2 = { 2977044471LL };
	static const struct fixed31_32 dc_fixpt_ln2_div_2 = { 1488522236LL };

	/*
	* @brief
	* Initialization routines
	*/

	/*
	* @brief
	* result = numerator / denominator
	*/
	struct fixed31_32 dc_fixpt_from_fraction(long long numerator, long long denominator);

	/*
	* @brief
	* result = arg
	*/
	static inline struct fixed31_32 dc_fixpt_from_int(int arg)
	{
	struct fixed31_32 res;

	res.value = (long long) arg << FIXED31_32_BITS_PER_FRACTIONAL_PART;

	return res;
	}

	/*
	* @brief
	* Unary operators
	*/

	/*
	* @brief
	* result = -arg
	*/
	static inline struct fixed31_32 dc_fixpt_neg(struct fixed31_32 arg)
	{
	struct fixed31_32 res;

	res.value = -arg.value;

	return res;
	}

	/*
	* @brief
	* result = abs(arg) := (arg >= 0) ? arg : -arg
	*/
	static inline struct fixed31_32 dc_fixpt_abs(struct fixed31_32 arg)
	{
	if (arg.value < 0)
	return dc_fixpt_neg(arg);
	else
	return arg;
	}

	/*
	* @brief
	* Binary relational operators
	*/

	/*
	* @brief
	* result = arg1 < arg2
	*/
	static inline bool dc_fixpt_lt(struct fixed31_32 arg1, struct fixed31_32 arg2)
	{
	return arg1.value < arg2.value;
	}

	/*
	* @brief
	* result = arg1 <= arg2
	*/
	static inline bool dc_fixpt_le(struct fixed31_32 arg1, struct fixed31_32 arg2)
	{
	return arg1.value <= arg2.value;
	}

	/*
	* @brief
	* result = arg1 == arg2
	*/
	static inline bool dc_fixpt_eq(struct fixed31_32 arg1, struct fixed31_32 arg2)
	{
	return arg1.value == arg2.value;
	}

	/*
	* @brief
	* result = min(arg1, arg2) := (arg1 <= arg2) ? arg1 : arg2
	*/
	static inline struct fixed31_32 dc_fixpt_min(struct fixed31_32 arg1, struct fixed31_32 arg2)
	{
	if (arg1.value <= arg2.value)
	return arg1;
	else
	return arg2;
	}

	/*
	* @brief
	* result = max(arg1, arg2) := (arg1 <= arg2) ? arg2 : arg1
	*/
	static inline struct fixed31_32 dc_fixpt_max(struct fixed31_32 arg1, struct fixed31_32 arg2)
	{
	if (arg1.value <= arg2.value)
	return arg2;
	else
	return arg1;
	}

	/*
	* @brief
	* \| min_value, when arg <= min_value
	* result = \| arg, when min_value < arg < max_value
	* \| max_value, when arg >= max_value
	*/
	static inline struct fixed31_32 dc_fixpt_clamp(
	struct fixed31_32 arg,
	struct fixed31_32 min_value,
	struct fixed31_32 max_value)
	{
	if (dc_fixpt_le(arg, min_value))
	return min_value;
	else if (dc_fixpt_le(max_value, arg))
	return max_value;
	else
	return arg;
	}

	/*
	* @brief
	* Binary shift operators
	*/

	/*
	* @brief
	* result = arg << shift
	*/
	static inline struct fixed31_32 dc_fixpt_shl(struct fixed31_32 arg, unsigned char shift)
	{
	ASSERT(((arg.value >= 0) && (arg.value <= LLONG_MAX >> shift)) \|\|
	((arg.value < 0) && (arg.value >= ~(LLONG_MAX >> shift))));

	arg.value = arg.value << shift;

	return arg;
	}

	/*
	* @brief
	* result = arg >> shift
	*/
	static inline struct fixed31_32 dc_fixpt_shr(struct fixed31_32 arg, unsigned char shift)
	{
	bool negative = arg.value < 0;

	if (negative)
	arg.value = -arg.value;
	arg.value = arg.value >> shift;
	if (negative)
	arg.value = -arg.value;
	return arg;
	}

	/*
	* @brief
	* Binary additive operators
	*/

	/*
	* @brief
	* result = arg1 + arg2
	*/
	static inline struct fixed31_32 dc_fixpt_add(struct fixed31_32 arg1, struct fixed31_32 arg2)
	{
	struct fixed31_32 res;

	ASSERT(((arg1.value >= 0) && (LLONG_MAX - arg1.value >= arg2.value)) \|\|
	((arg1.value < 0) && (LLONG_MIN - arg1.value <= arg2.value)));

	res.value = arg1.value + arg2.value;

	return res;
	}

	/*
	* @brief
	* result = arg1 + arg2
	*/
	static inline struct fixed31_32 dc_fixpt_add_int(struct fixed31_32 arg1, int arg2)
	{
	return dc_fixpt_add(arg1, dc_fixpt_from_int(arg2));
	}

	/*
	* @brief
	* result = arg1 - arg2
	*/
	static inline struct fixed31_32 dc_fixpt_sub(struct fixed31_32 arg1, struct fixed31_32 arg2)
	{
	struct fixed31_32 res;

	ASSERT(((arg2.value >= 0) && (LLONG_MIN + arg2.value <= arg1.value)) \|\|
	((arg2.value < 0) && (LLONG_MAX + arg2.value >= arg1.value)));

	res.value = arg1.value - arg2.value;

	return res;
	}

	/*
	* @brief
	* result = arg1 - arg2
	*/
	static inline struct fixed31_32 dc_fixpt_sub_int(struct fixed31_32 arg1, int arg2)
	{
	return dc_fixpt_sub(arg1, dc_fixpt_from_int(arg2));
	}


	/*
	* @brief
	* Binary multiplicative operators
	*/

	/*
	* @brief
	* result = arg1 * arg2
	*/
	struct fixed31_32 dc_fixpt_mul(struct fixed31_32 arg1, struct fixed31_32 arg2);


	/*
	* @brief
	* result = arg1 * arg2
	*/
	static inline struct fixed31_32 dc_fixpt_mul_int(struct fixed31_32 arg1, int arg2)
	{
	return dc_fixpt_mul(arg1, dc_fixpt_from_int(arg2));
	}

	/*
	* @brief
	* result = square(arg) := arg * arg
	*/
	struct fixed31_32 dc_fixpt_sqr(struct fixed31_32 arg);

	/*
	* @brief
	* result = arg1 / arg2
	*/
	static inline struct fixed31_32 dc_fixpt_div_int(struct fixed31_32 arg1, long long arg2)
	{
	return dc_fixpt_from_fraction(arg1.value, dc_fixpt_from_int(arg2).value);
	}

	/*
	* @brief
	* result = arg1 / arg2
	*/
	static inline struct fixed31_32 dc_fixpt_div(struct fixed31_32 arg1, struct fixed31_32 arg2)
	{
	return dc_fixpt_from_fraction(arg1.value, arg2.value);
	}

	/*
	* @brief
	* Reciprocal function
	*/

	/*
	* @brief
	* result = reciprocal(arg) := 1 / arg
	*
	* @note
	* No special actions taken in case argument is zero.
	*/
	struct fixed31_32 dc_fixpt_recip(struct fixed31_32 arg);

	/*
	* @brief
	* Trigonometric functions
	*/

	/*
	* @brief
	* result = sinc(arg) := sin(arg) / arg
	*
	* @note
	* Argument specified in radians,
	* internally it's normalized to [-2pi...2pi] range.
	*/
	struct fixed31_32 dc_fixpt_sinc(struct fixed31_32 arg);

	/*
	* @brief
	* result = sin(arg)
	*
	* @note
	* Argument specified in radians,
	* internally it's normalized to [-2pi...2pi] range.
	*/
	struct fixed31_32 dc_fixpt_sin(struct fixed31_32 arg);

	/*
	* @brief
	* result = cos(arg)
	*
	* @note
	* Argument specified in radians
	* and should be in [-2pi...2pi] range -
	* passing arguments outside that range
	* will cause incorrect result!
	*/
	struct fixed31_32 dc_fixpt_cos(struct fixed31_32 arg);

	/*
	* @brief
	* Transcendent functions
	*/

	/*
	* @brief
	* result = exp(arg)
	*
	* @note
	* Currently, function is verified for abs(arg) <= 1.
	*/
	struct fixed31_32 dc_fixpt_exp(struct fixed31_32 arg);

	/*
	* @brief
	* result = log(arg)
	*
	* @note
	* Currently, abs(arg) should be less than 1.
	* No normalization is done.
	* Currently, no special actions taken
	* in case of invalid argument(s). Take care!
	*/
	struct fixed31_32 dc_fixpt_log(struct fixed31_32 arg);

	/*
	* @brief
	* Power function
	*/

	/*
	* @brief
	* result = pow(arg1, arg2)
	*
	* @note
	* Currently, abs(arg1) should be less than 1. Take care!
	*/
	static inline struct fixed31_32 dc_fixpt_pow(struct fixed31_32 arg1, struct fixed31_32 arg2)
	{
	return dc_fixpt_exp(
	dc_fixpt_mul(
	dc_fixpt_log(arg1),
	arg2));
	}

	/*
	* @brief
	* Rounding functions
	*/

	/*
	* @brief
	* result = floor(arg) := greatest integer lower than or equal to arg
	*/
	static inline int dc_fixpt_floor(struct fixed31_32 arg)
	{
	unsigned long long arg_value = arg.value > 0 ? arg.value : -arg.value;

	if (arg.value >= 0)
	return (int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
	else
	return -(int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
	}

	/*
	* @brief
	* result = round(arg) := integer nearest to arg
	*/
	static inline int dc_fixpt_round(struct fixed31_32 arg)
	{
	unsigned long long arg_value = arg.value > 0 ? arg.value : -arg.value;

	const long long summand = dc_fixpt_half.value;

	ASSERT(LLONG_MAX - (long long)arg_value >= summand);

	arg_value += summand;

	if (arg.value >= 0)
	return (int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
	else
	return -(int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
	}

	/*
	* @brief
	* result = ceil(arg) := lowest integer greater than or equal to arg
	*/
	static inline int dc_fixpt_ceil(struct fixed31_32 arg)
	{
	unsigned long long arg_value = arg.value > 0 ? arg.value : -arg.value;

	const long long summand = dc_fixpt_one.value -
	dc_fixpt_epsilon.value;

	ASSERT(LLONG_MAX - (long long)arg_value >= summand);

	arg_value += summand;

	if (arg.value >= 0)
	return (int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
	else
	return -(int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
	}

	/* the following two function are used in scaler hw programming to convert fixed
	* point value to format 2 bits from integer part and 19 bits from fractional
	* part. The same applies for u0d19, 0 bits from integer part and 19 bits from
	* fractional
	*/

	unsigned int dc_fixpt_u4d19(struct fixed31_32 arg);

	unsigned int dc_fixpt_u3d19(struct fixed31_32 arg);

	unsigned int dc_fixpt_u2d19(struct fixed31_32 arg);

	unsigned int dc_fixpt_u0d19(struct fixed31_32 arg);

	unsigned int dc_fixpt_clamp_u0d14(struct fixed31_32 arg);

	unsigned int dc_fixpt_clamp_u0d10(struct fixed31_32 arg);

	int dc_fixpt_s4d19(struct fixed31_32 arg);

	static inline struct fixed31_32 dc_fixpt_truncate(struct fixed31_32 arg, unsigned int frac_bits)
	{
	bool negative = arg.value < 0;

	if (frac_bits >= FIXED31_32_BITS_PER_FRACTIONAL_PART) {
	ASSERT(frac_bits == FIXED31_32_BITS_PER_FRACTIONAL_PART);
	return arg;
	}

	if (negative)
	arg.value = -arg.value;
	arg.value &= (~0LL) << (FIXED31_32_BITS_PER_FRACTIONAL_PART - frac_bits);
	if (negative)
	arg.value = -arg.value;
	return arg;
	}

	#endif