portapack-mayhem/firmware/baseband/dsp_decimate.cpp
2016-01-02 10:35:23 -08:00

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/*
* Copyright (C) 2014 Jared Boone, ShareBrained Technology, Inc.
*
* This file is part of PortaPack.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2, or (at your option)
* any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street,
* Boston, MA 02110-1301, USA.
*/
#include "dsp_decimate.hpp"
#include <hal.h>
namespace dsp {
namespace decimate {
static inline complex32_t mac_fs4_shift(
const vec2_s16* const z,
const vec2_s16* const t,
const size_t index,
const complex32_t accum
) {
/* Accumulate sample * tap results for samples already in z buffer.
* Multiply using swap/negation to achieve Fs/4 shift.
* For iterations where samples are shifting out of z buffer (being discarded).
* Expect negated tap t[2] to accomodate instruction set limitations.
*/
const bool negated_t2 = index & 1;
const auto q1_i0 = z[index*2 + 0];
const auto i1_q0 = z[index*2 + 1];
const auto t1_t0 = t[index];
const auto real = negated_t2 ? smlsd(q1_i0, t1_t0, accum.real()) : smlad(q1_i0, t1_t0, accum.real());
const auto imag = negated_t2 ? smlad(i1_q0, t1_t0, accum.imag()) : smlsd(i1_q0, t1_t0, accum.imag());
return { real, imag };
}
static inline complex32_t mac_shift(
const vec2_s16* const z,
const vec2_s16* const t,
const size_t index,
const complex32_t accum
) {
/* Accumulate sample * tap results for samples already in z buffer.
* For iterations where samples are shifting out of z buffer (being discarded).
* real += i1 * t1 + i0 * t0
* imag += q1 * t1 + q0 * t0
*/
const auto i1_i0 = z[index*2 + 0];
const auto q1_q0 = z[index*2 + 1];
const auto t1_t0 = t[index];
const auto real = smlad(i1_i0, t1_t0, accum.real());
const auto imag = smlad(q1_q0, t1_t0, accum.imag());
return { real, imag };
}
static inline complex32_t mac_fs4_shift_and_store(
vec2_s16* const z,
const vec2_s16* const t,
const size_t decimation_factor,
const size_t index,
const complex32_t accum
) {
/* Accumulate sample * tap results for samples already in z buffer.
* Place new samples into z buffer.
* Expect negated tap t[2] to accomodate instruction set limitations.
*/
const bool negated_t2 = index & 1;
const auto q1_i0 = z[decimation_factor + index*2 + 0];
const auto i1_q0 = z[decimation_factor + index*2 + 1];
const auto t1_t0 = t[decimation_factor / 2 + index];
z[index*2 + 0] = q1_i0;
const auto real = negated_t2 ? smlsd(q1_i0, t1_t0, accum.real()) : smlad(q1_i0, t1_t0, accum.real());
z[index*2 + 1] = i1_q0;
const auto imag = negated_t2 ? smlad(i1_q0, t1_t0, accum.imag()) : smlsd(i1_q0, t1_t0, accum.imag());
return { real, imag };
}
static inline complex32_t mac_shift_and_store(
vec2_s16* const z,
const vec2_s16* const t,
const size_t decimation_factor,
const size_t index,
const complex32_t accum
) {
/* Accumulate sample * tap results for samples already in z buffer.
* Place new samples into z buffer.
* Expect negated tap t[2] to accomodate instruction set limitations.
*/
const auto i1_i0 = z[decimation_factor + index*2 + 0];
const auto q1_q0 = z[decimation_factor + index*2 + 1];
const auto t1_t0 = t[decimation_factor / 2 + index];
z[index*2 + 0] = i1_i0;
const auto real = smlad(i1_i0, t1_t0, accum.real());
z[index*2 + 1] = q1_q0;
const auto imag = smlad(q1_q0, t1_t0, accum.imag());
return { real, imag };
}
static inline complex32_t mac_fs4_shift_and_store_new_c8_samples(
vec2_s16* const z,
const vec2_s16* const t,
const vec4_s8* const in,
const size_t decimation_factor,
const size_t index,
const size_t length,
const complex32_t accum
) {
/* Accumulate sample * tap results for new samples.
* Place new samples into z buffer.
* Expect negated tap t[2] to accomodate instruction set limitations.
*/
const bool negated_t2 = index & 1;
const auto q1_i1_q0_i0 = in[index];
const auto t1_t0 = t[(length - decimation_factor) / 2 + index];
const auto i1_q1_i0_q0 = rev16(q1_i1_q0_i0);
const auto i1_q1_q0_i0 = pkhbt(q1_i1_q0_i0, i1_q1_i0_q0);
const auto q1_i0 = sxtb16(i1_q1_q0_i0);
const auto i1_q0 = sxtb16(i1_q1_q0_i0, 8);
z[length - decimation_factor * 2 + index*2 + 0] = q1_i0;
const auto real = negated_t2 ? smlsd(q1_i0, t1_t0, accum.real()) : smlad(q1_i0, t1_t0, accum.real());
z[length - decimation_factor * 2 + index*2 + 1] = i1_q0;
const auto imag = negated_t2 ? smlad(i1_q0, t1_t0, accum.imag()) : smlsd(i1_q0, t1_t0, accum.imag());
return { real, imag };
}
static inline complex32_t mac_shift_and_store_new_c16_samples(
vec2_s16* const z,
const vec2_s16* const t,
const vec2_s16* const in,
const size_t decimation_factor,
const size_t index,
const size_t length,
const complex32_t accum
) {
/* Accumulate sample * tap results for new samples.
* Place new samples into z buffer.
* Expect negated tap t[2] to accomodate instruction set limitations.
*/
const auto q0_i0 = in[index*2+0];
const auto q1_i1 = in[index*2+1];
const auto i1_i0 = pkhbt(q0_i0, q1_i1, 16);
const auto q1_q0 = pkhtb(q1_i1, q0_i0, 16);
const auto t1_t0 = t[(length - decimation_factor) / 2 + index];
z[length - decimation_factor * 2 + index*2 + 0] = i1_i0;
const auto real = smlad(i1_i0, t1_t0, accum.real());
z[length - decimation_factor * 2 + index*2 + 1] = q1_q0;
const auto imag = smlad(q1_q0, t1_t0, accum.imag());
return { real, imag };
}
static inline uint32_t scale_round_and_pack(
const complex32_t value,
const int32_t scale_factor
) {
/* Multiply 32-bit components of the complex<int32_t> by a scale factor,
* into int64_ts, then round to nearest LSB (1 << 32), saturate to 16 bits,
* and pack into a complex<int16_t>.
*/
const auto scaled_real = __SMMULR(value.real(), scale_factor);
const auto saturated_real = __SSAT(scaled_real, 16);
const auto scaled_imag = __SMMULR(value.imag(), scale_factor);
const auto saturated_imag = __SSAT(scaled_imag, 16);
return __PKHBT(saturated_real, saturated_imag, 16);
}
// FIRC8xR16x24FS4Decim4 //////////////////////////////////////////////////
FIRC8xR16x24FS4Decim4::FIRC8xR16x24FS4Decim4() {
z_.fill({});
}
void FIRC8xR16x24FS4Decim4::configure(
const std::array<tap_t, taps_count>& taps,
const int32_t scale,
const Shift shift
) {
const int negate_factor = (shift == Shift::Up) ? -1 : 1;
for(size_t i=0; i<taps.size(); i+=4) {
taps_[i+0] = taps[i+0];
taps_[i+1] = taps[i+1] * negate_factor;
taps_[i+2] = -taps[i+2];
taps_[i+3] = taps[i+3] * negate_factor;
}
output_scale = scale;
}
buffer_c16_t FIRC8xR16x24FS4Decim4::execute(
buffer_c8_t src,
buffer_c16_t dst
) {
vec2_s16* const z = static_cast<vec2_s16*>(__builtin_assume_aligned(z_.data(), 4));
const vec2_s16* const t = static_cast<vec2_s16*>(__builtin_assume_aligned(taps_.data(), 4));
uint32_t* const d = static_cast<uint32_t*>(__builtin_assume_aligned(dst.p, 4));
const auto k = output_scale;
const size_t count = src.count / decimation_factor;
for(size_t i=0; i<count; i++) {
const vec4_s8* const in = static_cast<const vec4_s8*>(__builtin_assume_aligned(&src.p[i * decimation_factor], 4));
complex32_t accum;
// Oldest samples are discarded.
accum = mac_fs4_shift(z, t, 0, accum);
accum = mac_fs4_shift(z, t, 1, accum);
// Middle samples are shifted earlier in the "z" delay buffer.
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 0, accum);
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 1, accum);
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 2, accum);
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 3, accum);
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 4, accum);
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 5, accum);
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 6, accum);
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 7, accum);
// Newest samples come from "in" buffer, are copied to "z" delay buffer.
accum = mac_fs4_shift_and_store_new_c8_samples(z, t, in, decimation_factor, 0, taps_count, accum);
accum = mac_fs4_shift_and_store_new_c8_samples(z, t, in, decimation_factor, 1, taps_count, accum);
d[i] = scale_round_and_pack(accum, k);
}
return {
dst.p,
count,
src.sampling_rate / decimation_factor
};
}
// FIRC8xR16x24FS4Decim8 //////////////////////////////////////////////////
FIRC8xR16x24FS4Decim8::FIRC8xR16x24FS4Decim8() {
z_.fill({});
}
void FIRC8xR16x24FS4Decim8::configure(
const std::array<tap_t, taps_count>& taps,
const int32_t scale,
const Shift shift
) {
const int negate_factor = (shift == Shift::Up) ? -1 : 1;
for(size_t i=0; i<taps.size(); i+=4) {
taps_[i+0] = taps[i+0];
taps_[i+1] = taps[i+1] * negate_factor;
taps_[i+2] = -taps[i+2];
taps_[i+3] = taps[i+3] * negate_factor;
}
output_scale = scale;
}
buffer_c16_t FIRC8xR16x24FS4Decim8::execute(
buffer_c8_t src,
buffer_c16_t dst
) {
vec2_s16* const z = static_cast<vec2_s16*>(__builtin_assume_aligned(z_.data(), 4));
const vec2_s16* const t = static_cast<vec2_s16*>(__builtin_assume_aligned(taps_.data(), 4));
uint32_t* const d = static_cast<uint32_t*>(__builtin_assume_aligned(dst.p, 4));
const auto k = output_scale;
const size_t count = src.count / decimation_factor;
for(size_t i=0; i<count; i++) {
const vec4_s8* const in = static_cast<const vec4_s8*>(__builtin_assume_aligned(&src.p[i * decimation_factor], 4));
complex32_t accum;
// Oldest samples are discarded.
accum = mac_fs4_shift(z, t, 0, accum);
accum = mac_fs4_shift(z, t, 1, accum);
accum = mac_fs4_shift(z, t, 2, accum);
accum = mac_fs4_shift(z, t, 3, accum);
// Middle samples are shifted earlier in the "z" delay buffer.
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 0, accum);
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 1, accum);
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 2, accum);
accum = mac_fs4_shift_and_store(z, t, decimation_factor, 3, accum);
// Newest samples come from "in" buffer, are copied to "z" delay buffer.
accum = mac_fs4_shift_and_store_new_c8_samples(z, t, in, decimation_factor, 0, taps_count, accum);
accum = mac_fs4_shift_and_store_new_c8_samples(z, t, in, decimation_factor, 1, taps_count, accum);
accum = mac_fs4_shift_and_store_new_c8_samples(z, t, in, decimation_factor, 2, taps_count, accum);
accum = mac_fs4_shift_and_store_new_c8_samples(z, t, in, decimation_factor, 3, taps_count, accum);
d[i] = scale_round_and_pack(accum, k);
}
return {
dst.p,
count,
src.sampling_rate / decimation_factor
};
}
// FIRC16xR16x16Decim2 ////////////////////////////////////////////////////
FIRC16xR16x16Decim2::FIRC16xR16x16Decim2() {
z_.fill({});
}
void FIRC16xR16x16Decim2::configure(
const std::array<tap_t, taps_count>& taps,
const int32_t scale
) {
std::copy(taps.cbegin(), taps.cend(), taps_.begin());
output_scale = scale;
}
buffer_c16_t FIRC16xR16x16Decim2::execute(
buffer_c16_t src,
buffer_c16_t dst
) {
vec2_s16* const z = static_cast<vec2_s16*>(__builtin_assume_aligned(z_.data(), 4));
const vec2_s16* const t = static_cast<vec2_s16*>(__builtin_assume_aligned(taps_.data(), 4));
uint32_t* const d = static_cast<uint32_t*>(__builtin_assume_aligned(dst.p, 4));
const auto k = output_scale;
const size_t count = src.count / decimation_factor;
for(size_t i=0; i<count; i++) {
const vec2_s16* const in = static_cast<const vec2_s16*>(__builtin_assume_aligned(&src.p[i * decimation_factor], 4));
complex32_t accum;
// Oldest samples are discarded.
accum = mac_shift(z, t, 0, accum);
// Middle samples are shifted earlier in the "z" delay buffer.
accum = mac_shift_and_store(z, t, decimation_factor, 0, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 1, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 2, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 3, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 4, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 5, accum);
// Newest samples come from "in" buffer, are copied to "z" delay buffer.
accum = mac_shift_and_store_new_c16_samples(z, t, in, decimation_factor, 0, taps_count, accum);
d[i] = scale_round_and_pack(accum, k);
}
return {
dst.p,
count,
src.sampling_rate / decimation_factor
};
}
// FIRC16xR16x32Decim8 ////////////////////////////////////////////////////
FIRC16xR16x32Decim8::FIRC16xR16x32Decim8() {
z_.fill({});
}
void FIRC16xR16x32Decim8::configure(
const std::array<tap_t, taps_count>& taps,
const int32_t scale
) {
std::copy(taps.cbegin(), taps.cend(), taps_.begin());
output_scale = scale;
}
buffer_c16_t FIRC16xR16x32Decim8::execute(
buffer_c16_t src,
buffer_c16_t dst
) {
vec2_s16* const z = static_cast<vec2_s16*>(__builtin_assume_aligned(z_.data(), 4));
const vec2_s16* const t = static_cast<vec2_s16*>(__builtin_assume_aligned(taps_.data(), 4));
uint32_t* const d = static_cast<uint32_t*>(__builtin_assume_aligned(dst.p, 4));
const auto k = output_scale;
const size_t count = src.count / decimation_factor;
for(size_t i=0; i<count; i++) {
const vec2_s16* const in = static_cast<const vec2_s16*>(__builtin_assume_aligned(&src.p[i * decimation_factor], 4));
complex32_t accum;
// Oldest samples are discarded.
accum = mac_shift(z, t, 0, accum);
accum = mac_shift(z, t, 1, accum);
accum = mac_shift(z, t, 2, accum);
accum = mac_shift(z, t, 3, accum);
// Middle samples are shifted earlier in the "z" delay buffer.
accum = mac_shift_and_store(z, t, decimation_factor, 0, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 1, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 2, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 3, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 4, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 5, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 6, accum);
accum = mac_shift_and_store(z, t, decimation_factor, 7, accum);
// Newest samples come from "in" buffer, are copied to "z" delay buffer.
accum = mac_shift_and_store_new_c16_samples(z, t, in, decimation_factor, 0, taps_count, accum);
accum = mac_shift_and_store_new_c16_samples(z, t, in, decimation_factor, 1, taps_count, accum);
accum = mac_shift_and_store_new_c16_samples(z, t, in, decimation_factor, 2, taps_count, accum);
accum = mac_shift_and_store_new_c16_samples(z, t, in, decimation_factor, 3, taps_count, accum);
d[i] = scale_round_and_pack(accum, k);
}
return {
dst.p,
count,
src.sampling_rate / decimation_factor
};
}
buffer_c16_t Complex8DecimateBy2CIC3::execute(buffer_c8_t src, buffer_c16_t dst) {
/* Decimates by two using a non-recursive third-order CIC filter.
*/
/* CIC filter (decimating by two):
* D_I0 = i3 * 1 + i2 * 3 + i1 * 3 + i0 * 1
* D_Q0 = q3 * 1 + q2 * 3 + q1 * 3 + q0 * 1
*
* D_I1 = i5 * 1 + i4 * 3 + i3 * 3 + i2 * 1
* D_Q1 = q5 * 1 + q4 * 3 + q3 * 3 + q2 * 1
*/
uint32_t i1_i0 = _i1_i0;
uint32_t q1_q0 = _q1_q0;
/* 3:1 Scaled by 32 to normalize output to +/-32768-ish. */
constexpr uint32_t scale_factor = 32;
constexpr uint32_t k_3_1 = 0x00030001 * scale_factor;
uint32_t* src_p = reinterpret_cast<uint32_t*>(&src.p[0]);
uint32_t* const src_end = reinterpret_cast<uint32_t*>(&src.p[src.count]);
uint32_t* dst_p = reinterpret_cast<uint32_t*>(&dst.p[0]);
while(src_p < src_end) {
const uint32_t q3_i3_q2_i2 = *(src_p++); // 3
const uint32_t q5_i5_q4_i4 = *(src_p++);
const uint32_t d_i0_partial = __SMUAD(k_3_1, i1_i0); // 1: = 3 * i1 + 1 * i0
const uint32_t i3_i2 = __SXTB16(q3_i3_q2_i2, 0); // 1: (q3_i3_q2_i2 ror 0)[23:16]:(q3_i3_q2_i2 ror 0)[7:0]
const uint32_t d_i0 = __SMLADX(k_3_1, i3_i2, d_i0_partial); // 1: + 3 * i2 + 1 * i3
const uint32_t d_q0_partial = __SMUAD(k_3_1, q1_q0); // 1: = 3 * q1 * 1 * q0
const uint32_t q3_q2 = __SXTB16(q3_i3_q2_i2, 8); // 1: (q3_i3_q2_i2 ror 8)[23:16]:(q3_i3_q2_i2 ror 8)[7:0]
const uint32_t d_q0 = __SMLADX(k_3_1, q3_q2, d_q0_partial); // 1: + 3 * q2 + 1 * q3
const uint32_t d_q0_i0 = __PKHBT(d_i0, d_q0, 16); // 1: (Rm<<16)[31:16]:Rn[15:0]
const uint32_t d_i1_partial = __SMUAD(k_3_1, i3_i2); // 1: = 3 * i3 + 1 * i2
const uint32_t i5_i4 = __SXTB16(q5_i5_q4_i4, 0); // 1: (q5_i5_q4_i4 ror 0)[23:16]:(q5_i5_q4_i4 ror 0)[7:0]
const uint32_t d_i1 = __SMLADX(k_3_1, i5_i4, d_i1_partial); // 1: + 1 * i5 + 3 * i4
const uint32_t d_q1_partial = __SMUAD(k_3_1, q3_q2); // 1: = 3 * q3 * 1 * q2
const uint32_t q5_q4 = __SXTB16(q5_i5_q4_i4, 8); // 1: (q5_i5_q4_i4 ror 8)[23:16]:(q5_i5_q4_i4 ror 8)[7:0]
const uint32_t d_q1 = __SMLADX(k_3_1, q5_q4, d_q1_partial); // 1: + 1 * q5 + 3 * q4
const uint32_t d_q1_i1 = __PKHBT(d_i1, d_q1, 16); // 1: (Rm<<16)[31:16]:Rn[15:0]
*(dst_p++) = d_q0_i0; // 3
*(dst_p++) = d_q1_i1;
i1_i0 = i5_i4;
q1_q0 = q5_q4;
}
_i1_i0 = i1_i0;
_q1_q0 = q1_q0;
return { dst.p, src.count / 2, src.sampling_rate / 2 };
}
buffer_c16_t TranslateByFSOver4AndDecimateBy2CIC3::execute(buffer_c8_t src, buffer_c16_t dst) {
/* Translates incoming complex<int8_t> samples by -fs/4,
* decimates by two using a non-recursive third-order CIC filter.
*/
/* Derivation of algorithm:
* Original CIC filter (decimating by two):
* D_I0 = i3 * 1 + i2 * 3 + i1 * 3 + i0 * 1
* D_Q0 = q3 * 1 + q2 * 3 + q1 * 3 + q0 * 1
*
* D_I1 = i5 * 1 + i4 * 3 + i3 * 3 + i2 * 1
* D_Q1 = q5 * 1 + q4 * 3 + q3 * 3 + q2 * 1
*
* Translate -fs/4, phased 180 degrees, accomplished by complex multiplication
* of complex length-4 sequence:
*
* Substitute:
* i0 = -i0, q0 = -q0
* i1 = -q1, q1 = i1
* i2 = i2, q2 = q2
* i3 = q3, q3 = -i3
* i4 = -i4, q4 = -q4
* i5 = -q5, q5 = i5
*
* Resulting taps (with decimation by 2, four samples in, two samples out):
* D_I0 = q3 * 1 + i2 * 3 + -q1 * 3 + -i0 * 1
* D_Q0 = -i3 * 1 + q2 * 3 + i1 * 3 + -q0 * 1
*
* D_I1 = -q5 * 1 + -i4 * 3 + q3 * 3 + i2 * 1
* D_Q1 = i5 * 1 + -q4 * 3 + -i3 * 3 + q2 * 1
*/
// 6 cycles per complex input sample, not including loop overhead.
uint32_t q1_i0 = _q1_i0;
uint32_t q0_i1 = _q0_i1;
/* 3:1 Scaled by 32 to normalize output to +/-32768-ish. */
constexpr uint32_t scale_factor = 32;
const uint32_t k_3_1 = 0x00030001 * scale_factor;
uint32_t* src_p = reinterpret_cast<uint32_t*>(&src.p[0]);
uint32_t* const src_end = reinterpret_cast<uint32_t*>(&src.p[src.count]);
uint32_t* dst_p = reinterpret_cast<uint32_t*>(&dst.p[0]);
while(src_p < src_end) {
const uint32_t q3_i3_q2_i2 = *(src_p++); // 3
const uint32_t q5_i5_q4_i4 = *(src_p++);
const uint32_t i2_i3 = __SXTB16(q3_i3_q2_i2, 16); // 1: (q3_i3_q2_i2 ror 16)[23:16]:(q3_i3_q2_i2 ror 16)[7:0]
const uint32_t q3_q2 = __SXTB16(q3_i3_q2_i2, 8); // 1: (q3_i3_q2_i2 ror 8)[23:16]:(q3_i3_q2_i2 ror 8)[7:0]
const uint32_t i2_q3 = __PKHTB(i2_i3, q3_q2, 16); // 1: Rn[31:16]:(Rm>>16)[15:0]
const uint32_t i3_q2 = __PKHBT(q3_q2, i2_i3, 16); // 1:(Rm<<16)[31:16]:Rn[15:0]
// D_I0 = 3 * (i2 - q1) + (q3 - i0)
const uint32_t i2_m_q1_q3_m_i0 = __QSUB16(i2_q3, q1_i0); // 1: Rn[31:16]-Rm[31:16]:Rn[15:0]-Rm[15:0]
const uint32_t d_i0 = __SMUAD(k_3_1, i2_m_q1_q3_m_i0); // 1: Rm[15:0]*Rs[15:0]+Rm[31:16]*Rs[31:16]
// D_Q0 = 3 * (q2 + i1) - (i3 + q0)
const uint32_t i3_p_q0_q2_p_i1 = __QADD16(i3_q2, q0_i1); // 1: Rn[31:16]+Rm[31:16]:Rn[15:0]+Rm[15:0]
const uint32_t d_q0 = __SMUSDX(i3_p_q0_q2_p_i1, k_3_1); // 1: Rm[15:0]*Rs[31:16]Rm[31:16]*RsX[15:0]
const uint32_t d_q0_i0 = __PKHBT(d_i0, d_q0, 16); // 1: (Rm<<16)[31:16]:Rn[15:0]
const uint32_t i5_i4 = __SXTB16(q5_i5_q4_i4, 0); // 1: (q5_i5_q4_i4 ror 0)[23:16]:(q5_i5_q4_i4 ror 0)[7:0]
const uint32_t q4_q5 = __SXTB16(q5_i5_q4_i4, 24); // 1: (q5_i5_q4_i4 ror 24)[23:16]:(q5_i5_q4_i4 ror 24)[7:0]
const uint32_t q4_i5 = __PKHTB(q4_q5, i5_i4, 16); // 1: Rn[31:16]:(Rm>>16)[15:0]
const uint32_t q5_i4 = __PKHBT(i5_i4, q4_q5, 16); // 1: (Rm<<16)[31:16]:Rn[15:0]
// D_I1 = (i2 - q5) + 3 * (q3 - i4)
const uint32_t i2_m_q5_q3_m_i4 = __QSUB16(i2_q3, q5_i4); // 1: Rn[31:16]-Rm[31:16]:Rn[15:0]-Rm[15:0]
const uint32_t d_i1 = __SMUADX(i2_m_q5_q3_m_i4, k_3_1); // 1: Rm[15:0]*Rs[31:16]+Rm[31:16]*Rs[15:0]
// D_Q1 = (i5 + q2) - 3 * (q4 + i3)
const uint32_t q4_p_i3_i5_p_q2 = __QADD16(q4_i5, i3_q2); // 1: Rn[31:16]+Rm[31:16]:Rn[15:0]+Rm[15:0]
const uint32_t d_q1 = __SMUSD(k_3_1, q4_p_i3_i5_p_q2); // 1: Rm[15:0]*Rs[15:0]Rm[31:16]*Rs[31:16]
const uint32_t d_q1_i1 = __PKHBT(d_i1, d_q1, 16); // 1: (Rm<<16)[31:16]:Rn[15:0]
*(dst_p++) = d_q0_i0; // 3
*(dst_p++) = d_q1_i1;
q1_i0 = q5_i4;
q0_i1 = q4_i5;
}
_q1_i0 = q1_i0;
_q0_i1 = q0_i1;
return { dst.p, src.count / 2, src.sampling_rate / 2 };
}
buffer_c16_t DecimateBy2CIC3::execute(
buffer_c16_t src,
buffer_c16_t dst
) {
/* Complex non-recursive 3rd-order CIC filter (taps 1,3,3,1).
* Gain of 8.
* Consumes 16 bytes (4 s16:s16 samples) per loop iteration,
* Produces 8 bytes (2 s16:s16 samples) per loop iteration.
*/
uint32_t t1 = _iq0;
uint32_t t2 = _iq1;
uint32_t t3, t4;
const uint32_t taps = 0x00000003;
auto s = src.p;
auto d = dst.p;
const auto d_end = &dst.p[src.count / 2];
uint32_t i, q;
while(d < d_end) {
i = __SXTH(t1, 0); /* 1: I0 */
q = __SXTH(t1, 16); /* 1: Q0 */
i = __SMLABB(t2, taps, i); /* 1: I1*3 + I0 */
q = __SMLATB(t2, taps, q); /* 1: Q1*3 + Q0 */
t3 = *__SIMD32(s)++; /* 3: Q2:I2 */
t4 = *__SIMD32(s)++; /* Q3:I3 */
i = __SMLABB(t3, taps, i); /* 1: I2*3 + I1*3 + I0 */
q = __SMLATB(t3, taps, q); /* 1: Q2*3 + Q1*3 + Q0 */
int32_t si0 = __SXTAH(i, t4, 0); /* 1: I3 + Q2*3 + Q1*3 + Q0 */
int32_t sq0 = __SXTAH(q, t4, 16); /* 1: Q3 + Q2*3 + Q1*3 + Q0 */
i = __BFI(si0 / 8, sq0 / 8, 16, 16); /* 1: D2_Q0:D2_I0 */
*__SIMD32(d)++ = i; /* D2_Q0:D2_I0 */
i = __SXTH(t3, 0); /* 1: I2 */
q = __SXTH(t3, 16); /* 1: Q2 */
i = __SMLABB(t4, taps, i); /* 1: I3*3 + I2 */
q = __SMLATB(t4, taps, q); /* 1: Q3*3 + Q2 */
t1 = *__SIMD32(s)++; /* 3: Q4:I4 */
t2 = *__SIMD32(s)++; /* Q5:I5 */
i = __SMLABB(t1, taps, i); /* 1: I4*3 + I3*3 + I2 */
q = __SMLATB(t1, taps, q); /* 1: Q4*3 + Q3*3 + Q2 */
int32_t si1 = __SXTAH(i, t2, 0) ; /* 1: I5 + Q4*3 + Q3*3 + Q2 */
int32_t sq1 = __SXTAH(q, t2, 16); /* 1: Q5 + Q4*3 + Q3*3 + Q2 */
i = __BFI(si1 / 8, sq1 / 8, 16, 16); /* 1: D2_Q1:D2_I1 */
*__SIMD32(d)++ = i; /* D2_Q1:D2_I1 */
}
_iq0 = t1;
_iq1 = t2;
return { dst.p, src.count / 2, src.sampling_rate / 2 };
}
void FIR64AndDecimateBy2Real::configure(
const std::array<int16_t, taps_count>& new_taps
) {
std::copy(new_taps.cbegin(), new_taps.cend(), taps.begin());
}
buffer_s16_t FIR64AndDecimateBy2Real::execute(
buffer_s16_t src,
buffer_s16_t dst
) {
/* int16_t input (sample count "n" must be multiple of 4)
* -> int16_t output, decimated by 2.
* taps are normalized to 1 << 16 == 1.0.
*/
auto src_p = src.p;
auto dst_p = dst.p;
int32_t n = src.count;
for(; n>0; n-=2) {
z[taps_count-2] = *(src_p++);
z[taps_count-1] = *(src_p++);
int32_t t = 0;
for(size_t j=0; j<taps_count; j+=4) {
t += z[j+0] * taps[j+0];
t += z[j+1] * taps[j+1];
t += z[j+2] * taps[j+2];
t += z[j+3] * taps[j+3];
z[j+0] = z[j+0+2];
z[j+1] = z[j+1+2];
z[j+2] = z[j+2+2];
z[j+3] = z[j+3+2];
}
*(dst_p++) = t / 65536;
}
return { dst.p, src.count / 2, src.sampling_rate / 2 };
}
buffer_c16_t FIRAndDecimateComplex::execute(
buffer_c16_t src,
buffer_c16_t dst
) {
/* int16_t input (sample count "n" must be multiple of decimation_factor)
* -> int16_t output, decimated by decimation_factor.
* taps are normalized to 1 << 16 == 1.0.
*/
const auto output_sampling_rate = src.sampling_rate / decimation_factor_;
const size_t output_samples = src.count / decimation_factor_;
sample_t* dst_p = dst.p;
const buffer_c16_t result { dst.p, output_samples, output_sampling_rate };
const sample_t* src_p = src.p;
size_t outer_count = output_samples;
while(outer_count > 0) {
/* Put new samples into delay buffer */
auto z_new_p = &samples_[taps_count_ - decimation_factor_];
for(size_t i=0; i<decimation_factor_; i++) {
*__SIMD32(z_new_p)++ = *__SIMD32(src_p)++;
}
size_t loop_count = taps_count_ / 8;
auto t_p = &taps_reversed_[0];
auto z_p = &samples_[0];
int64_t t_real = 0;
int64_t t_imag = 0;
while(loop_count > 0) {
const auto tap0 = *__SIMD32(t_p)++;
const auto sample0 = *__SIMD32(z_p)++;
const auto tap1 = *__SIMD32(t_p)++;
const auto sample1 = *__SIMD32(z_p)++;
t_real = __SMLSLD(sample0, tap0, t_real);
t_imag = __SMLALDX(sample0, tap0, t_imag);
t_real = __SMLSLD(sample1, tap1, t_real);
t_imag = __SMLALDX(sample1, tap1, t_imag);
const auto tap2 = *__SIMD32(t_p)++;
const auto sample2 = *__SIMD32(z_p)++;
const auto tap3 = *__SIMD32(t_p)++;
const auto sample3 = *__SIMD32(z_p)++;
t_real = __SMLSLD(sample2, tap2, t_real);
t_imag = __SMLALDX(sample2, tap2, t_imag);
t_real = __SMLSLD(sample3, tap3, t_real);
t_imag = __SMLALDX(sample3, tap3, t_imag);
const auto tap4 = *__SIMD32(t_p)++;
const auto sample4 = *__SIMD32(z_p)++;
const auto tap5 = *__SIMD32(t_p)++;
const auto sample5 = *__SIMD32(z_p)++;
t_real = __SMLSLD(sample4, tap4, t_real);
t_imag = __SMLALDX(sample4, tap4, t_imag);
t_real = __SMLSLD(sample5, tap5, t_real);
t_imag = __SMLALDX(sample5, tap5, t_imag);
const auto tap6 = *__SIMD32(t_p)++;
const auto sample6 = *__SIMD32(z_p)++;
const auto tap7 = *__SIMD32(t_p)++;
const auto sample7 = *__SIMD32(z_p)++;
t_real = __SMLSLD(sample6, tap6, t_real);
t_imag = __SMLALDX(sample6, tap6, t_imag);
t_real = __SMLSLD(sample7, tap7, t_real);
t_imag = __SMLALDX(sample7, tap7, t_imag);
loop_count--;
}
/* TODO: Re-evaluate whether saturation is performed, normalization,
* all that jazz.
*/
const int32_t r = t_real >> 16;
const int32_t i = t_imag >> 16;
const int32_t r_sat = __SSAT(r, 16);
const int32_t i_sat = __SSAT(i, 16);
*__SIMD32(dst_p)++ = __PKHBT(
r_sat,
i_sat,
16
);
/* Shift sample buffer left/down by decimation factor. */
const size_t unroll_factor = 4;
size_t shift_count = (taps_count_ - decimation_factor_) / unroll_factor;
sample_t* t = &samples_[0];
const sample_t* s = &samples_[decimation_factor_];
while(shift_count > 0) {
*__SIMD32(t)++ = *__SIMD32(s)++;
*__SIMD32(t)++ = *__SIMD32(s)++;
*__SIMD32(t)++ = *__SIMD32(s)++;
*__SIMD32(t)++ = *__SIMD32(s)++;
shift_count--;
}
shift_count = (taps_count_ - decimation_factor_) % unroll_factor;
while(shift_count > 0) {
*(t++) = *(s++);
shift_count--;
}
outer_count--;
}
return result;
}
buffer_s16_t DecimateBy2CIC4Real::execute(
buffer_s16_t src,
buffer_s16_t dst
) {
auto src_p = src.p;
auto dst_p = dst.p;
int32_t n = src.count;
for(; n>0; n-=2) {
/* TODO: Probably a lot of room to optimize... */
z[0] = z[2];
z[1] = z[3];
z[2] = z[4];
z[3] = *(src_p++);
z[4] = *(src_p++);
int32_t t = z[0] + z[1] * 4 + z[2] * 6 + z[3] * 4 + z[4];
*(dst_p++) = t / 16;
}
return { dst.p, src.count / 2, src.sampling_rate / 2 };
}
} /* namespace decimate */
} /* namespace dsp */