arm_compute/core/FixedPoint.inl - platform/external/ComputeLibrary - Git at Google

 /*
  * Copyright (c) 2017 ARM Limited.
  *
  * SPDX-License-Identifier: MIT
  *
  * 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
  * AUTHORS OR COPYRIGHT HOLDERS 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.
  */
 #include "arm_compute/core/Error.h"

 #include <cmath>
 #include <limits>

 namespace
 {
 template <typename TpIn, typename TpSat>
 inline TpSat saturate_convert(TpIn a)
 {
     if(a > std::numeric_limits<TpSat>::max())
     {
         a = std::numeric_limits<TpSat>::max();
     }
     if(a < std::numeric_limits<TpSat>::min())
     {
         a = std::numeric_limits<TpSat>::min();
     }
     return static_cast<TpSat>(a);
 }
 } // namespace

 namespace arm_compute
 {
 inline qint8_t sqshl_qs8(qint8_t a, int shift)
 {
     qint16_t tmp = static_cast<qint16_t>(a) << shift;

     // Saturate the result in case of overflow and cast to qint8_t
     return saturate_convert<qint16_t, qint8_t>(tmp);
 }

 inline qint16_t sqshl_qs16(qint16_t a, int shift)
 {
     qint32_t tmp = static_cast<qint32_t>(a) << shift;

     // Saturate the result in case of overflow and cast to qint16_t
     return saturate_convert<qint32_t, qint16_t>(tmp);
 }

 inline qint8_t sshr_qs8(qint8_t a, int shift)
 {
     ARM_COMPUTE_ERROR_ON_MSG(shift == 0, "Shift should not be zero");
     const qint8_t round_val = 1 << (shift - 1);
     return sqadd_qs8(a, round_val) >> shift;
 }

 inline qint16_t sshr_qs16(qint16_t a, int shift)
 {
     ARM_COMPUTE_ERROR_ON_MSG(shift == 0, "Shift should not be zero");
     const qint16_t round_val = 1 << (shift - 1);
     return sqadd_qs16(a, round_val) >> shift;
 }

 inline qint8_t sabs_qs8(qint8_t a)
 {
     return (a < 0) ? (a == std::numeric_limits<int8_t>::min()) ? std::numeric_limits<int8_t>::max() : -a : a;
 }

 inline qint16_t sabs_qs16(qint16_t a)
 {
     return (a < 0) ? (a == std::numeric_limits<int16_t>::min()) ? std::numeric_limits<int16_t>::max() : -a : a;
 }

 inline qint8_t sadd_qs8(qint8_t a, qint8_t b)
 {
     return a + b;
 }

 inline qint16_t sadd_qs16(qint16_t a, qint16_t b)
 {
     return a + b;
 }

 inline qint8_t sqadd_qs8(qint8_t a, qint8_t b)
 {
     // We need to store the temporary result in qint16_t otherwise we cannot evaluate the overflow
     qint16_t tmp = (static_cast<qint16_t>(a) + static_cast<qint16_t>(b));

     // Saturate the result in case of overflow and cast to qint8_t
     return saturate_convert<qint16_t, qint8_t>(tmp);
 }

 inline qint16_t sqadd_qs16(qint16_t a, qint16_t b)
 {
     // We need to store the temporary result in qint32_t otherwise we cannot evaluate the overflow
     qint32_t tmp = (static_cast<qint32_t>(a) + static_cast<qint32_t>(b));

     // Saturate the result in case of overflow and cast to qint16_t
     return saturate_convert<qint32_t, qint16_t>(tmp);
 }

 inline qint32_t sqadd_qs32(qint32_t a, qint32_t b)
 {
     // We need to store the temporary result in qint64_t otherwise we cannot evaluate the overflow
     qint64_t tmp = (static_cast<qint64_t>(a) + static_cast<qint64_t>(b));

     // Saturate the result in case of overflow and cast to qint32_t
     return saturate_convert<qint64_t, qint32_t>(tmp);
 }

 inline qint8_t ssub_qs8(qint8_t a, qint8_t b)
 {
     return a - b;
 }

 inline qint16_t ssub_qs16(qint16_t a, qint16_t b)
 {
     return a - b;
 }

 inline qint8_t sqsub_qs8(qint8_t a, qint8_t b)
 {
     // We need to store the temporary result in uint16_t otherwise we cannot evaluate the overflow
     qint16_t tmp = static_cast<qint16_t>(a) - static_cast<qint16_t>(b);

     // Saturate the result in case of overflow and cast to qint8_t
     return saturate_convert<qint16_t, qint8_t>(tmp);
 }

 inline qint16_t sqsub_qs16(qint16_t a, qint16_t b)
 {
     // We need to store the temporary result in qint32_t otherwise we cannot evaluate the overflow
     qint32_t tmp = static_cast<qint32_t>(a) - static_cast<qint32_t>(b);

     // Saturate the result in case of overflow and cast to qint16_t
     return saturate_convert<qint32_t, qint16_t>(tmp);
 }

 inline qint8_t smul_qs8(qint8_t a, qint8_t b, int fixed_point_position)
 {
     const qint16_t round_up_const = (1 << (fixed_point_position - 1));

     qint16_t tmp = static_cast<qint16_t>(a) * static_cast<qint16_t>(b);

     // Rounding up
     tmp += round_up_const;

     return static_cast<qint8_t>(tmp >> fixed_point_position);
 }

 inline qint16_t smul_qs16(qint16_t a, qint16_t b, int fixed_point_position)
 {
     const qint32_t round_up_const = (1 << (fixed_point_position - 1));

     qint32_t tmp = static_cast<qint32_t>(a) * static_cast<qint32_t>(b);

     // Rounding up
     tmp += round_up_const;

     return static_cast<qint16_t>(tmp >> fixed_point_position);
 }

 inline qint8_t sqmul_qs8(qint8_t a, qint8_t b, int fixed_point_position)
 {
     const qint16_t round_up_const = (1 << (fixed_point_position - 1));

     qint16_t tmp = static_cast<qint16_t>(a) * static_cast<qint16_t>(b);

     // Rounding up
     tmp += round_up_const;

     return saturate_convert<qint16_t, qint8_t>(tmp >> fixed_point_position);
 }

 inline qint16_t sqmul_qs16(qint16_t a, qint16_t b, int fixed_point_position)
 {
     const qint32_t round_up_const = (1 << (fixed_point_position - 1));

     qint32_t tmp = static_cast<qint32_t>(a) * static_cast<qint32_t>(b);

     // Rounding up
     tmp += round_up_const;

     return saturate_convert<qint32_t, qint16_t>(tmp >> fixed_point_position);
 }

 inline qint16_t sqmull_qs8(qint8_t a, qint8_t b, int fixed_point_position)
 {
     const qint16_t round_up_const = (1 << (fixed_point_position - 1));

     qint16_t tmp = static_cast<qint16_t>(a) * static_cast<qint16_t>(b);

     // Rounding up
     tmp += round_up_const;

     return tmp >> fixed_point_position;
 }

 inline qint32_t sqmull_qs16(qint16_t a, qint16_t b, int fixed_point_position)
 {
     const qint32_t round_up_const = (1 << (fixed_point_position - 1));

     qint32_t tmp = static_cast<qint32_t>(a) * static_cast<qint32_t>(b);

     // Rounding up
     tmp += round_up_const;

     return tmp >> fixed_point_position;
 }

 inline qint8_t sinvsqrt_qs8(qint8_t a, int fixed_point_position)
 {
     const qint8_t shift = 8 - (fixed_point_position + (__builtin_clz(a) - 24));

     const qint8_t const_three = (3 << fixed_point_position);
     qint8_t       temp        = shift < 0 ? (a << -shift) : (a >> shift);
     qint8_t       x2          = temp;

     // We need three iterations to find the result
     for(int i = 0; i < 3; ++i)
     {
         qint8_t three_minus_dx = ssub_qs8(const_three, smul_qs8(temp, smul_qs8(x2, x2, fixed_point_position), fixed_point_position));
         x2                     = (smul_qs8(x2, three_minus_dx, fixed_point_position) >> 1);
     }

     temp = shift < 0 ? (x2 << (-shift >> 1)) : (x2 >> (shift >> 1));

     return temp;
 }

 inline qint16_t sinvsqrt_qs16(qint16_t a, int fixed_point_position)
 {
     const qint16_t shift = 16 - (fixed_point_position + (__builtin_clz(a) - 16));

     const qint16_t const_three = (3 << fixed_point_position);
     qint16_t       temp        = shift < 0 ? (a << -shift) : (a >> shift);
     qint16_t       x2          = temp;

     // We need three iterations to find the result
     for(int i = 0; i < 3; ++i)
     {
         qint16_t three_minus_dx = ssub_qs16(const_three, smul_qs16(temp, smul_qs16(x2, x2, fixed_point_position), fixed_point_position));
         x2                      = smul_qs16(x2, three_minus_dx, fixed_point_position) >> 1;
     }

     temp = shift < 0 ? (x2 << ((-shift) >> 1)) : (x2 >> (shift >> 1));

     return temp;
 }

 inline qint8_t sdiv_qs8(qint8_t a, qint8_t b, int fixed_point_position)
 {
     const qint16_t temp = a << fixed_point_position;
     return static_cast<qint8_t>(temp / b);
 }

 inline qint16_t sdiv_qs16(qint16_t a, qint16_t b, int fixed_point_position)
 {
     const qint32_t temp = a << fixed_point_position;
     return static_cast<qint16_t>(temp / b);
 }

 inline qint8_t sqexp_qs8(qint8_t a, int fixed_point_position)
 {
     // Constants
     const qint8_t const_one = (1 << fixed_point_position);
     const qint8_t ln2       = ((0x58 >> (6 - fixed_point_position)) + 1) >> 1;
     const qint8_t inv_ln2   = (((0x38 >> (6 - fixed_point_position)) + 1) >> 1) | const_one;
     const qint8_t A         = ((0x7F >> (6 - fixed_point_position)) + 1) >> 1;
     const qint8_t B         = ((0x3F >> (6 - fixed_point_position)) + 1) >> 1;
     const qint8_t C         = ((0x16 >> (6 - fixed_point_position)) + 1) >> 1;
     const qint8_t D         = ((0x05 >> (6 - fixed_point_position)) + 1) >> 1;

     // Polynomial expansion
     const int     dec_a = (sqmul_qs8(a, inv_ln2, fixed_point_position) >> fixed_point_position);
     const qint8_t alpha = sabs_qs8(sqsub_qs8(a, sqmul_qs8(ln2, sqshl_qs8(dec_a, fixed_point_position), fixed_point_position)));
     qint8_t       sum   = sqadd_qs8(sqmul_qs8(alpha, D, fixed_point_position), C);
     sum                 = sqadd_qs8(sqmul_qs8(alpha, sum, fixed_point_position), B);
     sum                 = sqadd_qs8(sqmul_qs8(alpha, sum, fixed_point_position), A);
     sum                 = sqmul_qs8(alpha, sum, fixed_point_position);
     sum                 = sqadd_qs8(sum, const_one);

     return (dec_a < 0) ? (sum >> -dec_a) : sqshl_qs8(sum, dec_a);
 }

 inline qint16_t sqexp_qs16(qint16_t a, int fixed_point_position)
 {
     // Constants
     const qint16_t const_one = (1 << fixed_point_position);
     const qint16_t ln2       = ((0x58B9 >> (14 - fixed_point_position)) + 1) >> 1;
     const qint16_t inv_ln2   = (((0x38AA >> (14 - fixed_point_position)) + 1) >> 1) | const_one;
     const qint16_t A         = ((0x7FBA >> (14 - fixed_point_position)) + 1) >> 1;
     const qint16_t B         = ((0x3FE9 >> (14 - fixed_point_position)) + 1) >> 1;
     const qint16_t C         = ((0x1693 >> (14 - fixed_point_position)) + 1) >> 1;
     const qint16_t D         = ((0x0592 >> (14 - fixed_point_position)) + 1) >> 1;

     // Polynomial expansion
     const int      dec_a = (sqmul_qs16(a, inv_ln2, fixed_point_position) >> fixed_point_position);
     const qint16_t alpha = sabs_qs16(sqsub_qs16(a, sqmul_qs16(ln2, sqshl_qs16(dec_a, fixed_point_position), fixed_point_position)));
     qint16_t       sum   = sqadd_qs16(sqmul_qs16(alpha, D, fixed_point_position), C);
     sum                  = sqadd_qs16(sqmul_qs16(alpha, sum, fixed_point_position), B);
     sum                  = sqadd_qs16(sqmul_qs16(alpha, sum, fixed_point_position), A);
     sum                  = sqmul_qs16(alpha, sum, fixed_point_position);
     sum                  = sqadd_qs16(sum, const_one);

     return (dec_a < 0) ? (sum >> -dec_a) : sqshl_qs16(sum, dec_a);
 }

 inline qint8_t slog_qs8(qint8_t a, int fixed_point_position)
 {
     // Constants
     qint8_t const_one = (1 << fixed_point_position);
     qint8_t ln2       = (0x58 >> (7 - fixed_point_position));
     qint8_t A         = (0x5C >> (7 - fixed_point_position - 1));
     qint8_t B         = -(0x56 >> (7 - fixed_point_position));
     qint8_t C         = (0x29 >> (7 - fixed_point_position));
     qint8_t D         = -(0x0A >> (7 - fixed_point_position));

     if((const_one == a) || (a < 0))
     {
         return 0;
     }
     else if(a < const_one)
     {
         return -slog_qs8(sdiv_qs8(const_one, a, fixed_point_position), fixed_point_position);
     }

     // Remove even powers of 2
     qint8_t shift_val = 31 - __builtin_clz(a >> fixed_point_position);
     a >>= shift_val;
     a = ssub_qs8(a, const_one);

     // Polynomial expansion
     qint8_t sum = sqadd_qs8(sqmul_qs8(a, D, fixed_point_position), C);
     sum         = sqadd_qs8(sqmul_qs8(a, sum, fixed_point_position), B);
     sum         = sqadd_qs8(sqmul_qs8(a, sum, fixed_point_position), A);
     sum         = sqmul_qs8(a, sum, fixed_point_position);

     return smul_qs8(sadd_qs8(sum, shift_val << fixed_point_position), ln2, fixed_point_position);
 }

 inline qint16_t slog_qs16(qint16_t a, int fixed_point_position)
 {
     // Constants
     qint16_t const_one = (1 << fixed_point_position);
     qint16_t ln2       = (0x58B9 >> (7 - fixed_point_position));
     qint16_t A         = (0x5C0F >> (7 - fixed_point_position - 1));
     qint16_t B         = -(0x56AE >> (7 - fixed_point_position));
     qint16_t C         = (0x2933 >> (7 - fixed_point_position));
     qint16_t D         = -(0x0AA7 >> (7 - fixed_point_position));

     if((const_one == a) || (a < 0))
     {
         return 0;
     }
     else if(a < const_one)
     {
         return -slog_qs16(sdiv_qs16(const_one, a, fixed_point_position), fixed_point_position);
     }

     // Remove even powers of 2
     qint16_t shift_val = 31 - __builtin_clz(a >> fixed_point_position);
     a >>= shift_val;
     a = ssub_qs16(a, const_one);

     // Polynomial expansion
     qint16_t sum = sqadd_qs16(sqmul_qs16(a, D, fixed_point_position), C);
     sum          = sqadd_qs16(sqmul_qs16(a, sum, fixed_point_position), B);
     sum          = sqadd_qs16(sqmul_qs16(a, sum, fixed_point_position), A);
     sum          = sqmul_qs16(a, sum, fixed_point_position);

     return smul_qs16(sadd_qs16(sum, shift_val << fixed_point_position), ln2, fixed_point_position);
 }

 inline float scvt_f32_qs8(qint8_t a, int fixed_point_position)
 {
     return static_cast<float>(a) / (1 << fixed_point_position);
 }

 inline qint8_t sqcvt_qs8_f32(float a, int fixed_point_position)
 {
     // round_nearest_integer(a * 2^(fixed_point_position))
     return saturate_convert<float, qint8_t>(a * (1 << fixed_point_position) + ((a >= 0) ? 0.5 : -0.5));
 }

 inline float scvt_f32_qs16(qint16_t a, int fixed_point_position)
 {
     return static_cast<float>(a) / (1 << fixed_point_position);
 }

 inline qint16_t sqcvt_qs16_f32(float a, int fixed_point_position)
 {
     // round_nearest_integer(a * 2^(fixed_point_position))
     return saturate_convert<float, qint16_t>(a * (1 << fixed_point_position) + ((a >= 0) ? 0.5 : -0.5));
 }

 inline qint8_t sqmovn_qs16(qint16_t a)
 {
     // Saturate the result in case of overflow and cast to qint8_t
     return saturate_convert<qint16_t, qint8_t>(a);
 }

 inline qint16_t sqmovn_qs32(qint32_t a)
 {
     // Saturate the result in case of overflow and cast to qint16_t
     return saturate_convert<qint32_t, qint16_t>(a);
 }
 }
	/*
	* Copyright (c) 2017 ARM Limited.
	*
	* SPDX-License-Identifier: MIT
	*
	* 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
	* AUTHORS OR COPYRIGHT HOLDERS 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.
	*/
	#include "arm_compute/core/Error.h"

	#include <cmath>
	#include <limits>

	namespace
	{
	template <typename TpIn, typename TpSat>
	inline TpSat saturate_convert(TpIn a)
	{
	if(a > std::numeric_limits<TpSat>::max())
	{
	a = std::numeric_limits<TpSat>::max();
	}
	if(a < std::numeric_limits<TpSat>::min())
	{
	a = std::numeric_limits<TpSat>::min();
	}
	return static_cast<TpSat>(a);
	}
	} // namespace

	namespace arm_compute
	{
	inline qint8_t sqshl_qs8(qint8_t a, int shift)
	{
	qint16_t tmp = static_cast<qint16_t>(a) << shift;

	// Saturate the result in case of overflow and cast to qint8_t
	return saturate_convert<qint16_t, qint8_t>(tmp);
	}

	inline qint16_t sqshl_qs16(qint16_t a, int shift)
	{
	qint32_t tmp = static_cast<qint32_t>(a) << shift;

	// Saturate the result in case of overflow and cast to qint16_t
	return saturate_convert<qint32_t, qint16_t>(tmp);
	}

	inline qint8_t sshr_qs8(qint8_t a, int shift)
	{
	ARM_COMPUTE_ERROR_ON_MSG(shift == 0, "Shift should not be zero");
	const qint8_t round_val = 1 << (shift - 1);
	return sqadd_qs8(a, round_val) >> shift;
	}

	inline qint16_t sshr_qs16(qint16_t a, int shift)
	{
	ARM_COMPUTE_ERROR_ON_MSG(shift == 0, "Shift should not be zero");
	const qint16_t round_val = 1 << (shift - 1);
	return sqadd_qs16(a, round_val) >> shift;
	}

	inline qint8_t sabs_qs8(qint8_t a)
	{
	return (a < 0) ? (a == std::numeric_limits<int8_t>::min()) ? std::numeric_limits<int8_t>::max() : -a : a;
	}

	inline qint16_t sabs_qs16(qint16_t a)
	{
	return (a < 0) ? (a == std::numeric_limits<int16_t>::min()) ? std::numeric_limits<int16_t>::max() : -a : a;
	}

	inline qint8_t sadd_qs8(qint8_t a, qint8_t b)
	{
	return a + b;
	}

	inline qint16_t sadd_qs16(qint16_t a, qint16_t b)
	{
	return a + b;
	}

	inline qint8_t sqadd_qs8(qint8_t a, qint8_t b)
	{
	// We need to store the temporary result in qint16_t otherwise we cannot evaluate the overflow
	qint16_t tmp = (static_cast<qint16_t>(a) + static_cast<qint16_t>(b));

	// Saturate the result in case of overflow and cast to qint8_t
	return saturate_convert<qint16_t, qint8_t>(tmp);
	}

	inline qint16_t sqadd_qs16(qint16_t a, qint16_t b)
	{
	// We need to store the temporary result in qint32_t otherwise we cannot evaluate the overflow
	qint32_t tmp = (static_cast<qint32_t>(a) + static_cast<qint32_t>(b));

	// Saturate the result in case of overflow and cast to qint16_t
	return saturate_convert<qint32_t, qint16_t>(tmp);
	}

	inline qint32_t sqadd_qs32(qint32_t a, qint32_t b)
	{
	// We need to store the temporary result in qint64_t otherwise we cannot evaluate the overflow
	qint64_t tmp = (static_cast<qint64_t>(a) + static_cast<qint64_t>(b));

	// Saturate the result in case of overflow and cast to qint32_t
	return saturate_convert<qint64_t, qint32_t>(tmp);
	}

	inline qint8_t ssub_qs8(qint8_t a, qint8_t b)
	{
	return a - b;
	}

	inline qint16_t ssub_qs16(qint16_t a, qint16_t b)
	{
	return a - b;
	}

	inline qint8_t sqsub_qs8(qint8_t a, qint8_t b)
	{
	// We need to store the temporary result in uint16_t otherwise we cannot evaluate the overflow
	qint16_t tmp = static_cast<qint16_t>(a) - static_cast<qint16_t>(b);

	// Saturate the result in case of overflow and cast to qint8_t
	return saturate_convert<qint16_t, qint8_t>(tmp);
	}

	inline qint16_t sqsub_qs16(qint16_t a, qint16_t b)
	{
	// We need to store the temporary result in qint32_t otherwise we cannot evaluate the overflow
	qint32_t tmp = static_cast<qint32_t>(a) - static_cast<qint32_t>(b);

	// Saturate the result in case of overflow and cast to qint16_t
	return saturate_convert<qint32_t, qint16_t>(tmp);
	}

	inline qint8_t smul_qs8(qint8_t a, qint8_t b, int fixed_point_position)
	{
	const qint16_t round_up_const = (1 << (fixed_point_position - 1));

	qint16_t tmp = static_cast<qint16_t>(a) * static_cast<qint16_t>(b);

	// Rounding up
	tmp += round_up_const;

	return static_cast<qint8_t>(tmp >> fixed_point_position);
	}

	inline qint16_t smul_qs16(qint16_t a, qint16_t b, int fixed_point_position)
	{
	const qint32_t round_up_const = (1 << (fixed_point_position - 1));

	qint32_t tmp = static_cast<qint32_t>(a) * static_cast<qint32_t>(b);

	// Rounding up
	tmp += round_up_const;

	return static_cast<qint16_t>(tmp >> fixed_point_position);
	}

	inline qint8_t sqmul_qs8(qint8_t a, qint8_t b, int fixed_point_position)
	{
	const qint16_t round_up_const = (1 << (fixed_point_position - 1));

	qint16_t tmp = static_cast<qint16_t>(a) * static_cast<qint16_t>(b);

	// Rounding up
	tmp += round_up_const;

	return saturate_convert<qint16_t, qint8_t>(tmp >> fixed_point_position);
	}

	inline qint16_t sqmul_qs16(qint16_t a, qint16_t b, int fixed_point_position)
	{
	const qint32_t round_up_const = (1 << (fixed_point_position - 1));

	qint32_t tmp = static_cast<qint32_t>(a) * static_cast<qint32_t>(b);

	// Rounding up
	tmp += round_up_const;

	return saturate_convert<qint32_t, qint16_t>(tmp >> fixed_point_position);
	}

	inline qint16_t sqmull_qs8(qint8_t a, qint8_t b, int fixed_point_position)
	{
	const qint16_t round_up_const = (1 << (fixed_point_position - 1));

	qint16_t tmp = static_cast<qint16_t>(a) * static_cast<qint16_t>(b);

	// Rounding up
	tmp += round_up_const;

	return tmp >> fixed_point_position;
	}

	inline qint32_t sqmull_qs16(qint16_t a, qint16_t b, int fixed_point_position)
	{
	const qint32_t round_up_const = (1 << (fixed_point_position - 1));

	qint32_t tmp = static_cast<qint32_t>(a) * static_cast<qint32_t>(b);

	// Rounding up
	tmp += round_up_const;

	return tmp >> fixed_point_position;
	}

	inline qint8_t sinvsqrt_qs8(qint8_t a, int fixed_point_position)
	{
	const qint8_t shift = 8 - (fixed_point_position + (__builtin_clz(a) - 24));

	const qint8_t const_three = (3 << fixed_point_position);
	qint8_t temp = shift < 0 ? (a << -shift) : (a >> shift);
	qint8_t x2 = temp;

	// We need three iterations to find the result
	for(int i = 0; i < 3; ++i)
	{
	qint8_t three_minus_dx = ssub_qs8(const_three, smul_qs8(temp, smul_qs8(x2, x2, fixed_point_position), fixed_point_position));
	x2 = (smul_qs8(x2, three_minus_dx, fixed_point_position) >> 1);
	}

	temp = shift < 0 ? (x2 << (-shift >> 1)) : (x2 >> (shift >> 1));

	return temp;
	}

	inline qint16_t sinvsqrt_qs16(qint16_t a, int fixed_point_position)
	{
	const qint16_t shift = 16 - (fixed_point_position + (__builtin_clz(a) - 16));

	const qint16_t const_three = (3 << fixed_point_position);
	qint16_t temp = shift < 0 ? (a << -shift) : (a >> shift);
	qint16_t x2 = temp;

	// We need three iterations to find the result
	for(int i = 0; i < 3; ++i)
	{
	qint16_t three_minus_dx = ssub_qs16(const_three, smul_qs16(temp, smul_qs16(x2, x2, fixed_point_position), fixed_point_position));
	x2 = smul_qs16(x2, three_minus_dx, fixed_point_position) >> 1;
	}

	temp = shift < 0 ? (x2 << ((-shift) >> 1)) : (x2 >> (shift >> 1));

	return temp;
	}

	inline qint8_t sdiv_qs8(qint8_t a, qint8_t b, int fixed_point_position)
	{
	const qint16_t temp = a << fixed_point_position;
	return static_cast<qint8_t>(temp / b);
	}

	inline qint16_t sdiv_qs16(qint16_t a, qint16_t b, int fixed_point_position)
	{
	const qint32_t temp = a << fixed_point_position;
	return static_cast<qint16_t>(temp / b);
	}

	inline qint8_t sqexp_qs8(qint8_t a, int fixed_point_position)
	{
	// Constants
	const qint8_t const_one = (1 << fixed_point_position);
	const qint8_t ln2 = ((0x58 >> (6 - fixed_point_position)) + 1) >> 1;
	const qint8_t inv_ln2 = (((0x38 >> (6 - fixed_point_position)) + 1) >> 1) \| const_one;
	const qint8_t A = ((0x7F >> (6 - fixed_point_position)) + 1) >> 1;
	const qint8_t B = ((0x3F >> (6 - fixed_point_position)) + 1) >> 1;
	const qint8_t C = ((0x16 >> (6 - fixed_point_position)) + 1) >> 1;
	const qint8_t D = ((0x05 >> (6 - fixed_point_position)) + 1) >> 1;

	// Polynomial expansion
	const int dec_a = (sqmul_qs8(a, inv_ln2, fixed_point_position) >> fixed_point_position);
	const qint8_t alpha = sabs_qs8(sqsub_qs8(a, sqmul_qs8(ln2, sqshl_qs8(dec_a, fixed_point_position), fixed_point_position)));
	qint8_t sum = sqadd_qs8(sqmul_qs8(alpha, D, fixed_point_position), C);
	sum = sqadd_qs8(sqmul_qs8(alpha, sum, fixed_point_position), B);
	sum = sqadd_qs8(sqmul_qs8(alpha, sum, fixed_point_position), A);
	sum = sqmul_qs8(alpha, sum, fixed_point_position);
	sum = sqadd_qs8(sum, const_one);

	return (dec_a < 0) ? (sum >> -dec_a) : sqshl_qs8(sum, dec_a);
	}

	inline qint16_t sqexp_qs16(qint16_t a, int fixed_point_position)
	{
	// Constants
	const qint16_t const_one = (1 << fixed_point_position);
	const qint16_t ln2 = ((0x58B9 >> (14 - fixed_point_position)) + 1) >> 1;
	const qint16_t inv_ln2 = (((0x38AA >> (14 - fixed_point_position)) + 1) >> 1) \| const_one;
	const qint16_t A = ((0x7FBA >> (14 - fixed_point_position)) + 1) >> 1;
	const qint16_t B = ((0x3FE9 >> (14 - fixed_point_position)) + 1) >> 1;
	const qint16_t C = ((0x1693 >> (14 - fixed_point_position)) + 1) >> 1;
	const qint16_t D = ((0x0592 >> (14 - fixed_point_position)) + 1) >> 1;

	// Polynomial expansion
	const int dec_a = (sqmul_qs16(a, inv_ln2, fixed_point_position) >> fixed_point_position);
	const qint16_t alpha = sabs_qs16(sqsub_qs16(a, sqmul_qs16(ln2, sqshl_qs16(dec_a, fixed_point_position), fixed_point_position)));
	qint16_t sum = sqadd_qs16(sqmul_qs16(alpha, D, fixed_point_position), C);
	sum = sqadd_qs16(sqmul_qs16(alpha, sum, fixed_point_position), B);
	sum = sqadd_qs16(sqmul_qs16(alpha, sum, fixed_point_position), A);
	sum = sqmul_qs16(alpha, sum, fixed_point_position);
	sum = sqadd_qs16(sum, const_one);

	return (dec_a < 0) ? (sum >> -dec_a) : sqshl_qs16(sum, dec_a);
	}

	inline qint8_t slog_qs8(qint8_t a, int fixed_point_position)
	{
	// Constants
	qint8_t const_one = (1 << fixed_point_position);
	qint8_t ln2 = (0x58 >> (7 - fixed_point_position));
	qint8_t A = (0x5C >> (7 - fixed_point_position - 1));
	qint8_t B = -(0x56 >> (7 - fixed_point_position));
	qint8_t C = (0x29 >> (7 - fixed_point_position));
	qint8_t D = -(0x0A >> (7 - fixed_point_position));

	if((const_one == a) \|\| (a < 0))
	{
	return 0;
	}
	else if(a < const_one)
	{
	return -slog_qs8(sdiv_qs8(const_one, a, fixed_point_position), fixed_point_position);
	}

	// Remove even powers of 2
	qint8_t shift_val = 31 - __builtin_clz(a >> fixed_point_position);
	a >>= shift_val;
	a = ssub_qs8(a, const_one);

	// Polynomial expansion
	qint8_t sum = sqadd_qs8(sqmul_qs8(a, D, fixed_point_position), C);
	sum = sqadd_qs8(sqmul_qs8(a, sum, fixed_point_position), B);
	sum = sqadd_qs8(sqmul_qs8(a, sum, fixed_point_position), A);
	sum = sqmul_qs8(a, sum, fixed_point_position);

	return smul_qs8(sadd_qs8(sum, shift_val << fixed_point_position), ln2, fixed_point_position);
	}

	inline qint16_t slog_qs16(qint16_t a, int fixed_point_position)
	{
	// Constants
	qint16_t const_one = (1 << fixed_point_position);
	qint16_t ln2 = (0x58B9 >> (7 - fixed_point_position));
	qint16_t A = (0x5C0F >> (7 - fixed_point_position - 1));
	qint16_t B = -(0x56AE >> (7 - fixed_point_position));
	qint16_t C = (0x2933 >> (7 - fixed_point_position));
	qint16_t D = -(0x0AA7 >> (7 - fixed_point_position));

	if((const_one == a) \|\| (a < 0))
	{
	return 0;
	}
	else if(a < const_one)
	{
	return -slog_qs16(sdiv_qs16(const_one, a, fixed_point_position), fixed_point_position);
	}

	// Remove even powers of 2
	qint16_t shift_val = 31 - __builtin_clz(a >> fixed_point_position);
	a >>= shift_val;
	a = ssub_qs16(a, const_one);

	// Polynomial expansion
	qint16_t sum = sqadd_qs16(sqmul_qs16(a, D, fixed_point_position), C);
	sum = sqadd_qs16(sqmul_qs16(a, sum, fixed_point_position), B);
	sum = sqadd_qs16(sqmul_qs16(a, sum, fixed_point_position), A);
	sum = sqmul_qs16(a, sum, fixed_point_position);

	return smul_qs16(sadd_qs16(sum, shift_val << fixed_point_position), ln2, fixed_point_position);
	}

	inline float scvt_f32_qs8(qint8_t a, int fixed_point_position)
	{
	return static_cast<float>(a) / (1 << fixed_point_position);
	}

	inline qint8_t sqcvt_qs8_f32(float a, int fixed_point_position)
	{
	// round_nearest_integer(a * 2^(fixed_point_position))
	return saturate_convert<float, qint8_t>(a * (1 << fixed_point_position) + ((a >= 0) ? 0.5 : -0.5));
	}

	inline float scvt_f32_qs16(qint16_t a, int fixed_point_position)
	{
	return static_cast<float>(a) / (1 << fixed_point_position);
	}

	inline qint16_t sqcvt_qs16_f32(float a, int fixed_point_position)
	{
	// round_nearest_integer(a * 2^(fixed_point_position))
	return saturate_convert<float, qint16_t>(a * (1 << fixed_point_position) + ((a >= 0) ? 0.5 : -0.5));
	}

	inline qint8_t sqmovn_qs16(qint16_t a)
	{
	// Saturate the result in case of overflow and cast to qint8_t
	return saturate_convert<qint16_t, qint8_t>(a);
	}

	inline qint16_t sqmovn_qs32(qint32_t a)
	{
	// Saturate the result in case of overflow and cast to qint16_t
	return saturate_convert<qint32_t, qint16_t>(a);
	}
	}