| /* |
| * 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. |
| */ |
| #ifndef ARM_COMPUTE_FIXED_POINT_H |
| #define ARM_COMPUTE_FIXED_POINT_H |
| |
| #define TYPE_ALIAS(type, alias) \ |
| typedef type alias; \ |
| typedef type alias##x##1; \ |
| typedef type##2 alias##x##2; \ |
| typedef type##3 alias##x##3; \ |
| typedef type##4 alias##x##4; \ |
| typedef type##8 alias##x##8; \ |
| typedef type##16 alias##x##16; |
| |
| TYPE_ALIAS(char, qs8) |
| TYPE_ALIAS(short, qs16) |
| TYPE_ALIAS(int, qs32) |
| |
| #define qs8_MIN ((char)CHAR_MIN) |
| #define qs8_MAX ((char)CHAR_MAX) |
| #define qs16_MIN ((short)SHRT_MIN) |
| #define qs16_MAX ((short)SHRT_MAX) |
| #define qs32_MIN ((int)INT_MIN) |
| #define qs32_MAX ((int)INT_MAX) |
| |
| #define qu8_MIN ((uchar)0) |
| #define qu8_MAX ((uchar)UCHAR_MAX) |
| #define qu16_MIN ((ushort)0) |
| #define qu16_MAX ((ushort)USHRT_MAX) |
| #define qu32_MIN ((uint)0) |
| #define qu32_MAX ((uint)UINT_MAX) |
| |
| #define qs8_TYPE char |
| #define qs8x1_TYPE char |
| #define qs8x2_TYPE char2 |
| #define qs8x3_TYPE char3 |
| #define qs8x4_TYPE char4 |
| #define qs8x8_TYPE char8 |
| #define qs8x16_TYPE char16 |
| |
| #define qs16_TYPE short |
| #define qs16x1_TYPE short |
| #define qs16x2_TYPE short2 |
| #define qs16x3_TYPE short3 |
| #define qs16x4_TYPE short4 |
| #define qs16x8_TYPE short8 |
| #define qs16x16_TYPE short16 |
| |
| #define qs32_TYPE int |
| #define qs32x1_TYPE int |
| #define qs32x2_TYPE int2 |
| #define qs32x3_TYPE int3 |
| #define qs32x4_TYPE int4 |
| #define qs32x8_TYPE int8 |
| #define qs32x16_TYPE int16 |
| |
| /* All internal constants are represented in the maximum supported fixed point format (QS16), |
| * thus we define an additional shift parameter required to convert the constant |
| * from the maximum supported format to the require one. |
| */ |
| #define qs8_SHIFT 8 |
| #define qs16_SHIFT 0 |
| |
| #undef VEC_DATA_TYPE_STR |
| #undef VEC_DATA_TYPE |
| #undef CONVERT_STR |
| #undef CONVERT |
| #undef CONVERT_SAT_STR |
| #undef CONVERT_SAT |
| |
| #define VEC_DATA_TYPE_STR(type, size) type##x##size |
| #define VEC_DATA_TYPE(type, size) VEC_DATA_TYPE_STR(type, size) |
| |
| #define CONVERT_STR3(x, type, rtype) (convert_##rtype((x))) |
| #define CONVERT_STR2(x, type, rtype) CONVERT_STR3(x, type, rtype) |
| #define CONVERT_STR(x, type) CONVERT_STR2(x, type, type##_TYPE) |
| #define CONVERT(x, type) CONVERT_STR(x, type) |
| |
| #define CONVERT_SAT_STR3(x, type, rtype) (convert_##rtype##_sat((x))) |
| #define CONVERT_SAT_STR2(x, type, rtype) CONVERT_SAT_STR3(x, type, rtype) |
| #define CONVERT_SAT_STR(x, type) CONVERT_SAT_STR2(x, type, type##_TYPE) |
| #define CONVERT_SAT(x, type) CONVERT_SAT_STR(x, type) |
| |
| /** Computes saturating absolute value of fixed point vector. |
| * |
| * @param[in] type the actual data type. |
| * |
| * @return The result of the fixed point absolute value. |
| */ |
| #define ABSQ_SAT_IMPL(type) \ |
| inline type abs_##type##_sat(type VopA) \ |
| { \ |
| return CONVERT_SAT(abs(VopA), type); \ |
| } |
| |
| ABSQ_SAT_IMPL(qs8x16) |
| ABSQ_SAT_IMPL(qs16x8) |
| |
| #define ABS_SAT_OP_EXPAND_STR(a, type, size) abs_##type##x##size##_sat((a)) |
| #define ABS_SAT_OP_EXPAND(a, type, size) ABS_SAT_OP_EXPAND_STR(a, type, size) |
| |
| /** Computes max of fixed point types. |
| * |
| * @param[in] type the actual data type. |
| * |
| * @return The result of the fixed point maximum. |
| */ |
| #define MAXQ_IMPL(type) \ |
| inline type max_##type(type VopA, type VopB) \ |
| { \ |
| return max(VopA, VopB); \ |
| } |
| |
| MAXQ_IMPL(qs8x1) |
| MAXQ_IMPL(qs8x2) |
| MAXQ_IMPL(qs8x4) |
| MAXQ_IMPL(qs8x8) |
| MAXQ_IMPL(qs8x16) |
| MAXQ_IMPL(qs16x1) |
| MAXQ_IMPL(qs16x2) |
| MAXQ_IMPL(qs16x4) |
| MAXQ_IMPL(qs16x8) |
| MAXQ_IMPL(qs16x16) |
| |
| #define MAX_OP_EXPAND_STR(a, b, type, size) max_##type##x##size((a), (b)) |
| #define MAX_OP_EXPAND(a, b, type, size) MAX_OP_EXPAND_STR(a, b, type, size) |
| |
| /** Computes saturated addition of fixed point types. |
| * |
| * @param[in] type the actual data type. |
| * |
| * @return The result of the fixed point addition. The result is saturated in case of overflow |
| */ |
| #define ADDQ_SAT_IMPL(type) \ |
| inline type add_sat_##type(type VopA, type VopB) \ |
| { \ |
| return add_sat(VopA, VopB); \ |
| } |
| |
| ADDQ_SAT_IMPL(qs8x1) |
| ADDQ_SAT_IMPL(qs8x2) |
| ADDQ_SAT_IMPL(qs8x4) |
| ADDQ_SAT_IMPL(qs8x8) |
| ADDQ_SAT_IMPL(qs8x16) |
| ADDQ_SAT_IMPL(qs16x1) |
| ADDQ_SAT_IMPL(qs16x2) |
| ADDQ_SAT_IMPL(qs16x4) |
| ADDQ_SAT_IMPL(qs16x8) |
| ADDQ_SAT_IMPL(qs16x16) |
| |
| #define ADD_SAT_OP_EXPAND_STR(a, b, type, size) add_sat_##type##x##size((a), (b)) |
| #define ADD_SAT_OP_EXPAND(a, b, type, size) ADD_SAT_OP_EXPAND_STR(a, b, type, size) |
| |
| /** Computes saturated subtraction of fixed point types. |
| * |
| * @param[in] type the actual data type. |
| * |
| * @return The result of the fixed point subtraction. The result is saturated in case of overflow |
| */ |
| #define SUBQ_SAT_IMPL(type) \ |
| inline type sub_sat_##type(type VopA, type VopB) \ |
| { \ |
| return sub_sat(VopA, VopB); \ |
| } |
| |
| SUBQ_SAT_IMPL(qs8x1) |
| SUBQ_SAT_IMPL(qs8x2) |
| SUBQ_SAT_IMPL(qs8x4) |
| SUBQ_SAT_IMPL(qs8x8) |
| SUBQ_SAT_IMPL(qs8x16) |
| SUBQ_SAT_IMPL(qs16x1) |
| SUBQ_SAT_IMPL(qs16x2) |
| SUBQ_SAT_IMPL(qs16x4) |
| SUBQ_SAT_IMPL(qs16x8) |
| SUBQ_SAT_IMPL(qs16x16) |
| |
| #define SUB_SAT_OP_EXPAND_STR(a, b, type, size) sub_sat_##type##x##size((a), (b)) |
| #define SUB_SAT_OP_EXPAND(a, b, type, size) SUB_SAT_OP_EXPAND_STR(a, b, type, size) |
| |
| /* Multiply of two fixed point numbers |
| * |
| * @param[in] type the actual data type. |
| * @param[in] itype the intermediate data type. |
| * |
| * @return The result of the fixed point multiplication. |
| */ |
| #define MULQ_IMPL(type, itype) \ |
| inline type mul_##type(type VopA, type VopB, int fixed_point_position) \ |
| { \ |
| itype round_val = (itype)(1 << (fixed_point_position - 1)); \ |
| itype res = CONVERT((VopA), itype) * CONVERT((VopB), itype) + round_val; \ |
| return CONVERT((res >> (itype)fixed_point_position), type); \ |
| } |
| |
| MULQ_IMPL(qs8x16, qs16x16) |
| MULQ_IMPL(qs16x16, qs32x16) |
| |
| #define MUL_OP_EXPAND_STR(a, b, type, size, position) mul_##type##x##size((a), (b), (position)) |
| #define MUL_OP_EXPAND(a, b, type, size, position) MUL_OP_EXPAND_STR(a, b, type, size, position) |
| |
| /* Saturate multiply of two fixed point numbers |
| * |
| * @param[in] type the actual data type. |
| * @param[in] itype the intermediate data type. |
| * |
| * @return The result of the fixed point multiplication. The result is saturated in case of overflow |
| */ |
| #define MULQ_SAT_IMPL(type, itype) \ |
| inline type mul_sat_##type(type VopA, type VopB, int fixed_point_position) \ |
| { \ |
| itype round_val = (itype)(1 << (fixed_point_position - 1)); \ |
| itype res = mad_sat(CONVERT((VopA), itype), CONVERT((VopB), itype), round_val); \ |
| return CONVERT_SAT((res >> (itype)fixed_point_position), type); \ |
| } |
| |
| MULQ_SAT_IMPL(qs8x16, qs16x16) |
| MULQ_SAT_IMPL(qs16x8, qs32x8) |
| MULQ_SAT_IMPL(qs16x16, qs32x16) |
| |
| #define MUL_SAT_OP_EXPAND_STR(a, b, type, size, position) mul_sat_##type##x##size((a), (b), (position)) |
| #define MUL_SAT_OP_EXPAND(a, b, type, size, position) MUL_SAT_OP_EXPAND_STR(a, b, type, size, position) |
| |
| /** Saturate multiply-accumulate |
| * |
| * @param[in] type the actual data type. |
| * @param[in] itype the intermediate data type. |
| * |
| * @return The result of the fixed point multiply-accumulate. The result is saturated in case of overflow |
| */ |
| #define MLAQ_SAT_IMPL(type, itype) \ |
| type mla_sat_##type(type VopA, type VopB, type VopC, int fixed_point_position) \ |
| { \ |
| itype res = mad_sat(CONVERT(VopB, itype), CONVERT(VopC, itype), (itype)(1 << (fixed_point_position - 1))); \ |
| return add_sat(VopA, CONVERT_SAT(res >> (itype)fixed_point_position, type)); \ |
| } |
| |
| MLAQ_SAT_IMPL(qs8x8, qs16x8) |
| MLAQ_SAT_IMPL(qs8x16, qs16x16) |
| MLAQ_SAT_IMPL(qs16x8, qs32x8) |
| |
| #define MLA_SAT_OP_EXPAND_STR(a, b, c, type, size, position) mla_sat_##type##x##size((a), (b), (c), (position)) |
| #define MLA_SAT_OP_EXPAND(a, b, c, type, size, position) MLA_SAT_OP_EXPAND_STR(a, b, c, type, size, position) |
| |
| /** Saturate multiply-accumulate long |
| * |
| * @param[in] type the actual data type. |
| * @param[in] itype the intermediate data type. |
| * |
| * @return The result of the fixed point multiply-accumulate long. The result is saturated in case of overflow |
| */ |
| #define MLALQ_SAT_IMPL(type, itype) \ |
| itype mlal_sat_##type(itype VopA, type VopB, type VopC, int fixed_point_position) \ |
| { \ |
| itype res = mad_sat(CONVERT(VopB, itype), CONVERT(VopC, itype), (itype)(1 << (fixed_point_position - 1))); \ |
| return add_sat(VopA, res >> (itype)fixed_point_position); \ |
| } |
| |
| MLALQ_SAT_IMPL(qs8x8, qs16x8) |
| MLALQ_SAT_IMPL(qs16x8, qs32x8) |
| |
| #define MLAL_SAT_OP_EXPAND_STR(a, b, c, type, size, position) mlal_sat_##type##x##size((a), (b), (c), (position)) |
| #define MLAL_SAT_OP_EXPAND(a, b, c, type, size, position) MLAL_SAT_OP_EXPAND_STR(a, b, c, type, size, position) |
| |
| /** Saturate division of two fixed point numbers |
| * |
| * @param[in] stype the actual scalar data type. |
| * @param[in] type the actual data type. |
| * @param[in] itype the intermediate data type. |
| * |
| * @return The result of the fixed point division. The result is saturated in case of overflow |
| */ |
| #define DIVQ_SAT_IMPL(stype, type, itype) \ |
| inline type div_sat_##type(type VopA, type VopB, int fixed_point_position) \ |
| { \ |
| itype conv_a = CONVERT((VopA), itype); \ |
| itype denominator = CONVERT((VopB), itype); \ |
| itype numerator = conv_a << (itype)(fixed_point_position); \ |
| itype res = select(numerator / denominator, select((itype)stype##_MAX, (itype)stype##_MIN, conv_a < (itype)0), denominator == (itype)0); \ |
| return CONVERT_SAT((res), type); \ |
| } |
| |
| DIVQ_SAT_IMPL(qs8, qs8x16, qs16x16) |
| DIVQ_SAT_IMPL(qs16, qs16x8, qs32x8) |
| DIVQ_SAT_IMPL(qs16, qs16x16, qs32x16) |
| |
| #define DIV_SAT_OP_EXPAND_STR(a, b, type, size, position) div_sat_##type##x##size((a), (b), (position)) |
| #define DIV_SAT_OP_EXPAND(a, b, type, size, position) DIV_SAT_OP_EXPAND_STR(a, b, type, size, position) |
| |
| /** Saturate exponential of a fixed point vector |
| * |
| * @note Implemented approach uses taylor polynomial to approximate the exponential function. |
| * |
| * @param[in] stype the actual scalar data type. |
| * @param[in] type the actual data type. |
| * @param[in] size the number of the calculated elements. |
| * |
| * @return The result of the fixed point exponential. The result is saturated in case of overflow |
| */ |
| #define EXPQ_IMPL(stype, type, size) \ |
| inline type exp_sat_##type(type VopA, int fixed_point_position) \ |
| { \ |
| type const_one = (type)(1 << (fixed_point_position)); \ |
| type ln2 = (type)((((0x58B9 >> (14 - fixed_point_position))) + 1) >> 1); \ |
| type inv_ln2 = (type)((((0x38AA >> (14 - fixed_point_position)) + 1) >> 1)) | const_one; \ |
| type A = (type)(((0x7FBA >> (14 - fixed_point_position)) + 1) >> 1); \ |
| type B = (type)(((0x3FE9 >> (14 - fixed_point_position)) + 1) >> 1); \ |
| type C = (type)(((0x1693 >> (14 - fixed_point_position)) + 1) >> 1); \ |
| type D = (type)(((0x0592 >> (14 - fixed_point_position)) + 1) >> 1); \ |
| type m = MUL_SAT_OP_EXPAND(VopA, inv_ln2, stype, size, fixed_point_position); \ |
| type dec_m = m >> (type)fixed_point_position; \ |
| type alpha = MUL_SAT_OP_EXPAND(dec_m << (type)fixed_point_position, ln2, stype, size, fixed_point_position); \ |
| alpha = CONVERT(abs_diff(VopA, alpha), type); \ |
| type sum = add_sat(MUL_SAT_OP_EXPAND(alpha, D, stype, size, fixed_point_position), C); \ |
| sum = add_sat(MUL_SAT_OP_EXPAND(alpha, sum, stype, size, fixed_point_position), B); \ |
| sum = add_sat(MUL_SAT_OP_EXPAND(alpha, sum, stype, size, fixed_point_position), A); \ |
| sum = add_sat(MUL_SAT_OP_EXPAND(alpha, sum, stype, size, fixed_point_position), const_one); \ |
| return select((type)stype##_MAX, select(sum << dec_m, sum >> -dec_m, dec_m < (type)0), clz(sum) > dec_m); /* Saturate result if needed */ \ |
| } |
| |
| EXPQ_IMPL(qs8, qs8x16, 16) |
| EXPQ_IMPL(qs16, qs16x8, 8) |
| EXPQ_IMPL(qs16, qs16x16, 16) |
| |
| #define EXP_OP_EXPAND_STR(a, type, size, position) exp_sat_##type##x##size((a), (position)) |
| #define EXP_OP_EXPAND(a, type, size, position) EXP_OP_EXPAND_STR(a, type, size, position) |
| |
| /** Saturate logarithm of a fixed point vector |
| * |
| * @note Implemented approach uses taylor polynomial to approximate the logarithm function. |
| * |
| * @param[in] stype the actual scalar data type. |
| * @param[in] type the actual data type. |
| * @param[in] size the number of the calculated elements. |
| * |
| * @return The result of the fixed point logarithm. The result is saturated in case of overflow |
| */ |
| #define LOGQ_IMPL(stype, type, size) \ |
| inline type log_sat_##type(type VopA, int fixed_point_position) \ |
| { \ |
| type const_one = (type)(1 << (fixed_point_position)); \ |
| type ln2 = (type)(0x58B9 >> (15 - fixed_point_position)); /* 1.4384189 */ \ |
| type A = (type)(0x5C0F >> (14 - fixed_point_position)); /* 1.4384189 */ \ |
| type B = -(type)(0x56AE >> (15 - fixed_point_position)); /* -0.6771900 */ \ |
| type C = (type)(0x2933 >> (15 - fixed_point_position)); /* 0.3218538 */ \ |
| type D = -(type)(0x0AA7 >> (15 - fixed_point_position)); /* -0.0832229 */ \ |
| type inter_a = select(VopA, DIV_SAT_OP_EXPAND(const_one, VopA, stype, size, fixed_point_position), VopA < const_one); \ |
| type shift_val = (type)(15 - stype##_SHIFT) - clz(inter_a >> (type)fixed_point_position); \ |
| inter_a = inter_a >> shift_val; \ |
| inter_a = sub_sat(inter_a, const_one); \ |
| type sum = add_sat(MUL_SAT_OP_EXPAND(inter_a, D, stype, size, fixed_point_position), C); \ |
| sum = add_sat(MUL_SAT_OP_EXPAND(inter_a, sum, stype, size, fixed_point_position), B); \ |
| sum = add_sat(MUL_SAT_OP_EXPAND(inter_a, sum, stype, size, fixed_point_position), A); \ |
| sum = MUL_SAT_OP_EXPAND(inter_a, sum, stype, size, fixed_point_position); \ |
| sum = MUL_SAT_OP_EXPAND(add_sat(sum, shift_val << (type)fixed_point_position), ln2, stype, size, fixed_point_position); \ |
| return select(select(sum, -sum, VopA < const_one), (type)0, VopA < (type)0); /* Saturate result if needed */ \ |
| } |
| |
| LOGQ_IMPL(qs8, qs8x16, 16) |
| LOGQ_IMPL(qs16, qs16x8, 8) |
| LOGQ_IMPL(qs16, qs16x16, 16) |
| |
| #define LOG_OP_EXPAND_STR(a, type, size, position) log_sat_##type##x##size((a), (position)) |
| #define LOG_OP_EXPAND(a, type, size, position) LOG_OP_EXPAND_STR(a, type, size, position) |
| |
| /** Saturate inverse square root of a fixed point vector |
| * |
| * @note Implemented approach uses Newton's method to approximate the inverse square root function. |
| * |
| * @param[in] stype the actual scalar data type. |
| * @param[in] type the actual data type. |
| * @param[in] size the number of the calculated elements. |
| * |
| * @return The result of the fixed point inverse square root. The result is saturated in case of overflow |
| */ |
| #define INVSQRTQ_IMPL(stype, type, size) \ |
| inline type invsqrt_sat_##type(type VopA, int fixed_point_position) \ |
| { \ |
| type const_three = (type)(3 << (fixed_point_position)); \ |
| type shift_value = (type)(16 - stype##_SHIFT) - (clz(VopA) + (type)fixed_point_position); \ |
| type temp = select(VopA >> shift_value, select((type)stype##_MAX, VopA << (-shift_value), clz(VopA) > (-shift_value)), shift_value < (type)0); \ |
| type x = temp; \ |
| x = MUL_SAT_OP_EXPAND(x, sub_sat(const_three, MUL_SAT_OP_EXPAND(MUL_SAT_OP_EXPAND(x, x, stype, size, fixed_point_position), temp, stype, size, fixed_point_position)), stype, size, fixed_point_position) >> 1; \ |
| x = MUL_SAT_OP_EXPAND(x, sub_sat(const_three, MUL_SAT_OP_EXPAND(MUL_SAT_OP_EXPAND(x, x, stype, size, fixed_point_position), temp, stype, size, fixed_point_position)), stype, size, fixed_point_position) >> 1; \ |
| x = MUL_SAT_OP_EXPAND(x, sub_sat(const_three, MUL_SAT_OP_EXPAND(MUL_SAT_OP_EXPAND(x, x, stype, size, fixed_point_position), temp, stype, size, fixed_point_position)), stype, size, fixed_point_position) >> 1; \ |
| if(sizeof((stype)(1)) > 1) /* Perform more iterations if datatype is QS16 */ \ |
| { \ |
| x = MUL_SAT_OP_EXPAND(x, sub_sat(const_three, MUL_SAT_OP_EXPAND(MUL_SAT_OP_EXPAND(x, x, stype, size, fixed_point_position), temp, stype, size, fixed_point_position)), stype, size, fixed_point_position) >> 1; \ |
| x = MUL_SAT_OP_EXPAND(x, sub_sat(const_three, MUL_SAT_OP_EXPAND(MUL_SAT_OP_EXPAND(x, x, stype, size, fixed_point_position), temp, stype, size, fixed_point_position)), stype, size, fixed_point_position) >> 1; \ |
| } \ |
| type shift_value2 = select(shift_value >> 1, (-shift_value) >> 1, shift_value < (type)0); \ |
| return select(x >> shift_value2, select((type)stype##_MAX, x << shift_value2, clz(x) > shift_value2), shift_value < (type)0); /* Saturate result if needed */ \ |
| } |
| |
| INVSQRTQ_IMPL(qs8, qs8x16, 16) |
| INVSQRTQ_IMPL(qs16, qs16x8, 8) |
| |
| #define INVSQRT_OP_EXPAND_STR(a, type, size, position) invsqrt_sat_##type##x##size((a), (position)) |
| #define INVSQRT_OP_EXPAND(a, type, size, position) INVSQRT_OP_EXPAND_STR(a, type, size, position) |
| |
| /** Saturate hyperbolic tangent of a fixed point vector |
| * |
| * tanh(x) = (e^2x - 1)/(e^2x + 1) |
| * |
| * @param[in] stype the actual scalar data type. |
| * @param[in] type the actual data type. |
| * @param[in] size the number of the calculated elements. |
| * |
| * @return The result of the fixed point hyperbolic tangent. The result is saturated in case of overflow |
| */ |
| #define TANHQ_IMPL(stype, type, size) \ |
| inline type tanh_sat_##type(type VopA, int fixed_point_position) \ |
| { \ |
| type const_one = (type)(1 << (fixed_point_position)); \ |
| type const_two = (type)(2 << (fixed_point_position)); \ |
| type exp2x = EXP_OP_EXPAND(MUL_SAT_OP_EXPAND(const_two, VopA, stype, size, fixed_point_position), stype, size, fixed_point_position); \ |
| type num = SUB_SAT_OP_EXPAND(exp2x, const_one, stype, size); \ |
| type den = ADD_SAT_OP_EXPAND(exp2x, const_one, stype, size); \ |
| return DIV_SAT_OP_EXPAND(num, den, stype, size, fixed_point_position); \ |
| } |
| |
| TANHQ_IMPL(qs8, qs8x16, 16) |
| TANHQ_IMPL(qs16, qs16x8, 8) |
| |
| #define TANH_OP_EXPAND_STR(a, type, size, position) tanh_sat_##type##x##size((a), (position)) |
| #define TANH_OP_EXPAND(a, type, size, position) TANH_OP_EXPAND_STR(a, type, size, position) |
| |
| #define floatx16 float16 |
| #define float16_TYPE float16 |
| |
| #define CONVERTQ_DOWN_IMPL(in_type, out_type) \ |
| inline out_type convert_##out_type##_##in_type(in_type a, int fixed_point_position) \ |
| { \ |
| return CONVERT(a * (1 << fixed_point_position) + select((in_type)-0.5, (in_type)0.5, isgreater(a, (in_type)0)), out_type); \ |
| } |
| |
| CONVERTQ_DOWN_IMPL(float16, qs8x16) |
| CONVERTQ_DOWN_IMPL(float16, qs16x16) |
| |
| #define CONVERTQ_DOWN_SAT_IMPL(in_type, out_type) \ |
| inline out_type convert_##out_type##_##in_type##_sat(in_type a, int fixed_point_position) \ |
| { \ |
| return CONVERT_SAT(a * (1 << fixed_point_position) + select((in_type)-0.5, (in_type)0.5, isgreater(a, (in_type)0)), out_type); \ |
| } |
| |
| CONVERTQ_DOWN_SAT_IMPL(float16, qs8x16) |
| CONVERTQ_DOWN_SAT_IMPL(float16, qs16x16) |
| |
| #define CONVERTQ_UP_IMPL(in_type, out_type) \ |
| inline out_type convert_##out_type##_##in_type(in_type a, int fixed_point_position) \ |
| { \ |
| return CONVERT(a, out_type) / (1 << fixed_point_position); \ |
| } |
| |
| CONVERTQ_UP_IMPL(qs8x16, float16) |
| CONVERTQ_UP_IMPL(qs16x16, float16) |
| |
| #define SQCVT_SAT_IMPL(type) \ |
| inline type sqcvt_##type##_sat(float a, int fixed_point_position) \ |
| { \ |
| return CONVERT_SAT((a * (1 << fixed_point_position) + ((a < 0) ? -0.5f : 0.5f)), type); \ |
| } |
| |
| SQCVT_SAT_IMPL(qs8) |
| SQCVT_SAT_IMPL(qs16) |
| |
| #define SQCVT_SAT_OP_EXPAND_STR(a, type, position) sqcvt_##type##_sat((a), (position)) |
| #define SQCVT_SAT_OP_EXPAND(a, type, position) SQCVT_SAT_OP_EXPAND_STR((a), type, position) |
| |
| #endif // ARM_COMPUTE_FIXED_POINT_H |