493 lines
11 KiB
C
493 lines
11 KiB
C
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/*
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* Copyright 2012-15 Advanced Micro Devices, Inc.
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*
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* Permission is hereby granted, free of charge, to any person obtaining a
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* copy of this software and associated documentation files (the "Software"),
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* to deal in the Software without restriction, including without limitation
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* the rights to use, copy, modify, merge, publish, distribute, sublicense,
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* and/or sell copies of the Software, and to permit persons to whom the
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* Software is furnished to do so, subject to the following conditions:
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*
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* The above copyright notice and this permission notice shall be included in
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* all copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
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* THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
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* OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
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* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
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* OTHER DEALINGS IN THE SOFTWARE.
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*
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* Authors: AMD
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*
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*/
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#include "dm_services.h"
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#include "include/fixed31_32.h"
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static const struct fixed31_32 dc_fixpt_two_pi = { 26986075409LL };
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static const struct fixed31_32 dc_fixpt_ln2 = { 2977044471LL };
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static const struct fixed31_32 dc_fixpt_ln2_div_2 = { 1488522236LL };
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static inline unsigned long long abs_i64(
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long long arg)
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{
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if (arg > 0)
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return (unsigned long long)arg;
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else
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return (unsigned long long)(-arg);
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}
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/*
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* @brief
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* result = dividend / divisor
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* *remainder = dividend % divisor
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*/
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static inline unsigned long long complete_integer_division_u64(
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unsigned long long dividend,
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unsigned long long divisor,
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unsigned long long *remainder)
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{
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unsigned long long result;
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ASSERT(divisor);
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result = div64_u64_rem(dividend, divisor, remainder);
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return result;
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}
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#define FRACTIONAL_PART_MASK \
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((1ULL << FIXED31_32_BITS_PER_FRACTIONAL_PART) - 1)
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#define GET_INTEGER_PART(x) \
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((x) >> FIXED31_32_BITS_PER_FRACTIONAL_PART)
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#define GET_FRACTIONAL_PART(x) \
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(FRACTIONAL_PART_MASK & (x))
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struct fixed31_32 dc_fixpt_from_fraction(long long numerator, long long denominator)
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{
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struct fixed31_32 res;
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bool arg1_negative = numerator < 0;
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bool arg2_negative = denominator < 0;
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unsigned long long arg1_value = arg1_negative ? -numerator : numerator;
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unsigned long long arg2_value = arg2_negative ? -denominator : denominator;
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unsigned long long remainder;
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/* determine integer part */
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unsigned long long res_value = complete_integer_division_u64(
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arg1_value, arg2_value, &remainder);
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ASSERT(res_value <= LONG_MAX);
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/* determine fractional part */
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{
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unsigned int i = FIXED31_32_BITS_PER_FRACTIONAL_PART;
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do {
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remainder <<= 1;
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res_value <<= 1;
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if (remainder >= arg2_value) {
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res_value |= 1;
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remainder -= arg2_value;
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}
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} while (--i != 0);
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}
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/* round up LSB */
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{
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unsigned long long summand = (remainder << 1) >= arg2_value;
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ASSERT(res_value <= LLONG_MAX - summand);
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res_value += summand;
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}
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res.value = (long long)res_value;
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if (arg1_negative ^ arg2_negative)
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res.value = -res.value;
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return res;
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}
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struct fixed31_32 dc_fixpt_mul(struct fixed31_32 arg1, struct fixed31_32 arg2)
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{
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struct fixed31_32 res;
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bool arg1_negative = arg1.value < 0;
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bool arg2_negative = arg2.value < 0;
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unsigned long long arg1_value = arg1_negative ? -arg1.value : arg1.value;
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unsigned long long arg2_value = arg2_negative ? -arg2.value : arg2.value;
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unsigned long long arg1_int = GET_INTEGER_PART(arg1_value);
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unsigned long long arg2_int = GET_INTEGER_PART(arg2_value);
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unsigned long long arg1_fra = GET_FRACTIONAL_PART(arg1_value);
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unsigned long long arg2_fra = GET_FRACTIONAL_PART(arg2_value);
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unsigned long long tmp;
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res.value = arg1_int * arg2_int;
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ASSERT(res.value <= LONG_MAX);
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res.value <<= FIXED31_32_BITS_PER_FRACTIONAL_PART;
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tmp = arg1_int * arg2_fra;
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ASSERT(tmp <= (unsigned long long)(LLONG_MAX - res.value));
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res.value += tmp;
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tmp = arg2_int * arg1_fra;
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ASSERT(tmp <= (unsigned long long)(LLONG_MAX - res.value));
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res.value += tmp;
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tmp = arg1_fra * arg2_fra;
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tmp = (tmp >> FIXED31_32_BITS_PER_FRACTIONAL_PART) +
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(tmp >= (unsigned long long)dc_fixpt_half.value);
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ASSERT(tmp <= (unsigned long long)(LLONG_MAX - res.value));
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res.value += tmp;
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if (arg1_negative ^ arg2_negative)
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res.value = -res.value;
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return res;
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}
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struct fixed31_32 dc_fixpt_sqr(struct fixed31_32 arg)
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{
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struct fixed31_32 res;
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unsigned long long arg_value = abs_i64(arg.value);
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unsigned long long arg_int = GET_INTEGER_PART(arg_value);
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unsigned long long arg_fra = GET_FRACTIONAL_PART(arg_value);
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unsigned long long tmp;
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res.value = arg_int * arg_int;
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ASSERT(res.value <= LONG_MAX);
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res.value <<= FIXED31_32_BITS_PER_FRACTIONAL_PART;
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tmp = arg_int * arg_fra;
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ASSERT(tmp <= (unsigned long long)(LLONG_MAX - res.value));
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res.value += tmp;
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ASSERT(tmp <= (unsigned long long)(LLONG_MAX - res.value));
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res.value += tmp;
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tmp = arg_fra * arg_fra;
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tmp = (tmp >> FIXED31_32_BITS_PER_FRACTIONAL_PART) +
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(tmp >= (unsigned long long)dc_fixpt_half.value);
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ASSERT(tmp <= (unsigned long long)(LLONG_MAX - res.value));
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res.value += tmp;
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return res;
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}
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struct fixed31_32 dc_fixpt_recip(struct fixed31_32 arg)
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{
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/*
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* @note
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* Good idea to use Newton's method
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*/
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ASSERT(arg.value);
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return dc_fixpt_from_fraction(
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dc_fixpt_one.value,
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arg.value);
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}
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struct fixed31_32 dc_fixpt_sinc(struct fixed31_32 arg)
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{
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struct fixed31_32 square;
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struct fixed31_32 res = dc_fixpt_one;
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int n = 27;
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struct fixed31_32 arg_norm = arg;
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if (dc_fixpt_le(
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dc_fixpt_two_pi,
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dc_fixpt_abs(arg))) {
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arg_norm = dc_fixpt_sub(
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arg_norm,
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dc_fixpt_mul_int(
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dc_fixpt_two_pi,
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(int)div64_s64(
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arg_norm.value,
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dc_fixpt_two_pi.value)));
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}
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square = dc_fixpt_sqr(arg_norm);
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do {
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res = dc_fixpt_sub(
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dc_fixpt_one,
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dc_fixpt_div_int(
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dc_fixpt_mul(
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square,
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res),
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n * (n - 1)));
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n -= 2;
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} while (n > 2);
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if (arg.value != arg_norm.value)
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res = dc_fixpt_div(
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dc_fixpt_mul(res, arg_norm),
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arg);
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return res;
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}
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struct fixed31_32 dc_fixpt_sin(struct fixed31_32 arg)
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{
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return dc_fixpt_mul(
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arg,
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dc_fixpt_sinc(arg));
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}
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struct fixed31_32 dc_fixpt_cos(struct fixed31_32 arg)
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{
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/* TODO implement argument normalization */
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const struct fixed31_32 square = dc_fixpt_sqr(arg);
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struct fixed31_32 res = dc_fixpt_one;
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int n = 26;
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do {
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res = dc_fixpt_sub(
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dc_fixpt_one,
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dc_fixpt_div_int(
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dc_fixpt_mul(
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square,
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res),
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n * (n - 1)));
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n -= 2;
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} while (n != 0);
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return res;
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}
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/*
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* @brief
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* result = exp(arg),
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* where abs(arg) < 1
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*
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* Calculated as Taylor series.
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*/
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static struct fixed31_32 fixed31_32_exp_from_taylor_series(struct fixed31_32 arg)
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{
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unsigned int n = 9;
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struct fixed31_32 res = dc_fixpt_from_fraction(
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n + 2,
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n + 1);
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/* TODO find correct res */
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ASSERT(dc_fixpt_lt(arg, dc_fixpt_one));
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do
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res = dc_fixpt_add(
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dc_fixpt_one,
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dc_fixpt_div_int(
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dc_fixpt_mul(
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arg,
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res),
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n));
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while (--n != 1);
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return dc_fixpt_add(
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dc_fixpt_one,
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dc_fixpt_mul(
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arg,
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res));
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}
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struct fixed31_32 dc_fixpt_exp(struct fixed31_32 arg)
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{
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/*
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* @brief
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* Main equation is:
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* exp(x) = exp(r + m * ln(2)) = (1 << m) * exp(r),
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* where m = round(x / ln(2)), r = x - m * ln(2)
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*/
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if (dc_fixpt_le(
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dc_fixpt_ln2_div_2,
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dc_fixpt_abs(arg))) {
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int m = dc_fixpt_round(
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dc_fixpt_div(
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arg,
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dc_fixpt_ln2));
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struct fixed31_32 r = dc_fixpt_sub(
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arg,
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dc_fixpt_mul_int(
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dc_fixpt_ln2,
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m));
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ASSERT(m != 0);
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ASSERT(dc_fixpt_lt(
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dc_fixpt_abs(r),
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dc_fixpt_one));
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if (m > 0)
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return dc_fixpt_shl(
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fixed31_32_exp_from_taylor_series(r),
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(unsigned char)m);
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else
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return dc_fixpt_div_int(
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fixed31_32_exp_from_taylor_series(r),
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1LL << -m);
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} else if (arg.value != 0)
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return fixed31_32_exp_from_taylor_series(arg);
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else
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return dc_fixpt_one;
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}
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struct fixed31_32 dc_fixpt_log(struct fixed31_32 arg)
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{
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struct fixed31_32 res = dc_fixpt_neg(dc_fixpt_one);
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/* TODO improve 1st estimation */
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struct fixed31_32 error;
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ASSERT(arg.value > 0);
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/* TODO if arg is negative, return NaN */
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/* TODO if arg is zero, return -INF */
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do {
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struct fixed31_32 res1 = dc_fixpt_add(
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dc_fixpt_sub(
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res,
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dc_fixpt_one),
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dc_fixpt_div(
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arg,
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dc_fixpt_exp(res)));
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error = dc_fixpt_sub(
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res,
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res1);
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res = res1;
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/* TODO determine max_allowed_error based on quality of exp() */
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} while (abs_i64(error.value) > 100ULL);
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return res;
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}
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/* this function is a generic helper to translate fixed point value to
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* specified integer format that will consist of integer_bits integer part and
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* fractional_bits fractional part. For example it is used in
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* dc_fixpt_u2d19 to receive 2 bits integer part and 19 bits fractional
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* part in 32 bits. It is used in hw programming (scaler)
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*/
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static inline unsigned int ux_dy(
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long long value,
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unsigned int integer_bits,
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unsigned int fractional_bits)
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{
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/* 1. create mask of integer part */
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unsigned int result = (1 << integer_bits) - 1;
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/* 2. mask out fractional part */
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unsigned int fractional_part = FRACTIONAL_PART_MASK & value;
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/* 3. shrink fixed point integer part to be of integer_bits width*/
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result &= GET_INTEGER_PART(value);
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/* 4. make space for fractional part to be filled in after integer */
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result <<= fractional_bits;
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/* 5. shrink fixed point fractional part to of fractional_bits width*/
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fractional_part >>= FIXED31_32_BITS_PER_FRACTIONAL_PART - fractional_bits;
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/* 6. merge the result */
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return result | fractional_part;
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}
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static inline unsigned int clamp_ux_dy(
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long long value,
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unsigned int integer_bits,
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unsigned int fractional_bits,
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unsigned int min_clamp)
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{
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unsigned int truncated_val = ux_dy(value, integer_bits, fractional_bits);
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if (value >= (1LL << (integer_bits + FIXED31_32_BITS_PER_FRACTIONAL_PART)))
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return (1 << (integer_bits + fractional_bits)) - 1;
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else if (truncated_val > min_clamp)
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return truncated_val;
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else
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return min_clamp;
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}
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unsigned int dc_fixpt_u4d19(struct fixed31_32 arg)
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{
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return ux_dy(arg.value, 4, 19);
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}
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unsigned int dc_fixpt_u3d19(struct fixed31_32 arg)
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{
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return ux_dy(arg.value, 3, 19);
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}
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unsigned int dc_fixpt_u2d19(struct fixed31_32 arg)
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{
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return ux_dy(arg.value, 2, 19);
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}
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unsigned int dc_fixpt_u0d19(struct fixed31_32 arg)
|
||
|
{
|
||
|
return ux_dy(arg.value, 0, 19);
|
||
|
}
|
||
|
|
||
|
unsigned int dc_fixpt_clamp_u0d14(struct fixed31_32 arg)
|
||
|
{
|
||
|
return clamp_ux_dy(arg.value, 0, 14, 1);
|
||
|
}
|
||
|
|
||
|
unsigned int dc_fixpt_clamp_u0d10(struct fixed31_32 arg)
|
||
|
{
|
||
|
return clamp_ux_dy(arg.value, 0, 10, 1);
|
||
|
}
|
||
|
|
||
|
int dc_fixpt_s4d19(struct fixed31_32 arg)
|
||
|
{
|
||
|
if (arg.value < 0)
|
||
|
return -(int)ux_dy(dc_fixpt_abs(arg).value, 4, 19);
|
||
|
else
|
||
|
return ux_dy(arg.value, 4, 19);
|
||
|
}
|