mirror of
https://github.com/eried/portapack-mayhem.git
synced 2024-10-01 01:26:06 -04:00
033c4e9a5b
* Updated style * Updated files * fixed new line * Updated spacing * File fix WIP * Updated to clang 13 * updated comment style * Removed old comment code
416 lines
16 KiB
C++
416 lines
16 KiB
C++
/*
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* Copyright (C) 2015 Jared Boone, ShareBrained Technology, Inc.
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* Copyright (C) 2017 Furrtek
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* Early 2023 joyel24 added meteomodem M20 support
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*
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* This file is part of PortaPack.
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2, or (at your option)
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* any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; see the file COPYING. If not, write to
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* the Free Software Foundation, Inc., 51 Franklin Street,
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* Boston, MA 02110-1301, USA.
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*/
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#include "sonde_packet.hpp"
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#include "string_format.hpp"
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#include <cstring>
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// #include <complex>
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namespace sonde {
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static uint8_t calibytes[51 * 16]; // need these vars to survive
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static uint8_t calfrchk[51]; // so subframes are preserved while populated
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// Defines for Vaisala RS41, from https://github.com/rs1729/RS/blob/master/rs41/rs41sg.c
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#define MASK_LEN 64
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// Following values include the 4 bytes less shift, consumed in detecting the header on proc_sonde
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#define block_status 0x35 // 0x039 // 40 bytes
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#define block_gpspos 0x10E // 0x112 // 21 bytes
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#define block_meas 0x61 // 0x65 // 42 bytes
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#define pos_FrameNb 0x37 // 0x03B // 2 byte
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#define pos_SondeID 0x39 // 0x03D // 8 byte
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#define pos_Voltage 0x041 // 0x045 // 3 bytes (but first one is the important one) voltage x 10 ie: 26 = 2.6v
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#define pos_CalData 0x04E // 0x052 // 1 byte, counter 0x00..0x32
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#define pos_temp 0x063 // 0x067 // 3 bytes (uint24_t)
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#define pos_GPSecefX 0x110 // 0x114 // 4 byte
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#define pos_GPSecefY 0x114 // 0x118 // 4 byte (not actually used since Y and Z are following X, and grabbed in that same loop)
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#define pos_GPSecefZ 0x118 // 0x11C // 4 byte (same as Y)
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#define PI 3.1415926535897932384626433832795 // 3.1416 //(3.1415926535897932384626433832795)
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Packet::Packet(
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const baseband::Packet& packet,
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const Type type)
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: packet_{packet},
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decoder_{packet_},
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reader_bi_m{decoder_},
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type_{type} {
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if (type_ == Type::Meteomodem_unknown) {
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// Right now we're just sure that the sync is from a Meteomodem sonde, differentiate between models now
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const uint32_t id_byte = reader_bi_m.read(0 * 8, 16);
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if (id_byte == 0x649F)
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type_ = Type::Meteomodem_M10;
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else if (id_byte == 0x648F)
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type_ = Type::Meteomodem_M2K2;
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else if (id_byte == 0x4520) // https://raw.githubusercontent.com/projecthorus/radiosonde_auto_rx/master/demod/mod/m20mod.c
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type_ = Type::Meteomodem_M20;
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}
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}
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size_t Packet::length() const {
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return decoder_.symbols_count();
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}
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Timestamp Packet::received_at() const {
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return packet_.timestamp();
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}
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Packet::Type Packet::type() const {
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return type_;
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}
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// euquiq here:
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// RS41SG 320 bits header, 320bytes frame (or more if it is an "extended frame")
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// The raw data is xor-scrambled with the values in the 64 bytes vaisala_mask (see.hpp)
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// from 0x008 to 0x037 (48 bytes reed-solomon error correction data)
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uint8_t Packet::vaisala_descramble(const uint32_t pos) const { // vaisala_descramble(const uint32_t pos) const {
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// packet_[i]; its a bit; packet_.size the total (should be 2560 bits)
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uint8_t value = 0;
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for (uint8_t i = 0; i < 8; i++)
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value = (value << 1) | packet_[(pos * 8) + (7 - i)]; // get the byte from the bits collection
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// packetReader reader { packet_ }; //This works just as above.
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// value = reader.read(pos * 8,8);
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// shift pos because first 4 bytes are consumed by proc_sonde in finding the vaisala signature
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uint32_t mask_pos = pos + 4;
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value = value ^ vaisala_mask[mask_pos % MASK_LEN]; // descramble with the xor pseudorandom table
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return value;
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};
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GPS_data Packet::get_GPS_data() const {
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GPS_data result;
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if ((type_ == Type::Meteomodem_M10) || (type_ == Type::Meteomodem_M2K2)) {
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result.alt = (reader_bi_m.read(22 * 8, 32) / 1000) - 48;
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result.lat = reader_bi_m.read(14 * 8, 32) / ((1ULL << 32) / 360.0);
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result.lon = reader_bi_m.read(18 * 8, 32) / ((1ULL << 32) / 360.0);
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} else if (type_ == Type::Meteomodem_M20) {
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result.alt = reader_bi_m.read(8 * 8, 24) / 100.0; // <|
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result.lat = reader_bi_m.read(28 * 8, 32) / 1000000.0; // <| Inspired by https://raw.githubusercontent.com/projecthorus/radiosonde_auto_rx/master/demod/mod/m20mod.c
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result.lon = reader_bi_m.read(32 * 8, 32) / 1000000.0; // <|
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} else if (type_ == Type::Vaisala_RS41_SG) {
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uint8_t XYZ_bytes[4];
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int32_t XYZ; // 32bit
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double_t X[3];
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for (int32_t k = 0; k < 3; k++) { // Get X,Y,Z ECEF position from GPS
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for (int32_t i = 0; i < 4; i++) // each one is 4 bytes (32 bits)
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XYZ_bytes[i] = vaisala_descramble(pos_GPSecefX + (4 * k) + i);
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memcpy(&XYZ, XYZ_bytes, 4);
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X[k] = XYZ / 100.0;
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}
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double_t a = 6378137.0;
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double_t b = 6356752.31424518;
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double_t e = sqrt((a * a - b * b) / (a * a));
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double_t ee = sqrt((a * a - b * b) / (b * b));
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double_t lam = atan2(X[1], X[0]);
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double_t p = sqrt(X[0] * X[0] + X[1] * X[1]);
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double_t t = atan2(X[2] * a, p * b);
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double_t phi = atan2(X[2] + ee * ee * b * sin(t) * sin(t) * sin(t),
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p - e * e * a * cos(t) * cos(t) * cos(t));
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double_t R = a / sqrt(1 - e * e * sin(phi) * sin(phi));
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result.alt = p / cos(phi) - R;
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result.lat = phi * 180 / PI;
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result.lon = lam * 180 / PI;
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}
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return result;
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}
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uint32_t Packet::battery_voltage() const {
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if (type_ == Type::Meteomodem_M10)
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return (reader_bi_m.read(69 * 8, 8) + (reader_bi_m.read(70 * 8, 8) << 8)) * 1000 / 150;
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else if (type_ == Type::Meteomodem_M20) {
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return 0; // NOT SUPPPORTED YET
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} else if (type_ == Type::Meteomodem_M2K2)
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return reader_bi_m.read(69 * 8, 8) * 66; // Actually 65.8
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else if (type_ == Type::Vaisala_RS41_SG) {
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uint32_t voltage = vaisala_descramble(pos_Voltage) * 100; // byte 69 = voltage * 10 (check if this value needs to be multiplied)
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return voltage;
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} else {
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return 0; // Unknown
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}
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}
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uint32_t Packet::frame() const {
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if (type_ == Type::Vaisala_RS41_SG) {
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uint32_t frame_number = vaisala_descramble(pos_FrameNb) | (vaisala_descramble(pos_FrameNb + 1) << 8);
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return frame_number;
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} else {
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return 0; // Unknown
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}
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}
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temp_humid Packet::get_temp_humid() const {
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temp_humid result;
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result.humid = 0;
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result.temp = 0;
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if (type_ == Type::Vaisala_RS41_SG && crc_ok_RS41()) // Only process if packet is healthy
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{
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// memset(calfrchk, 0, 51); // is this necessary ? only if the sondeID changes (new sonde)
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// original code from https://github.com/rs1729/RS/blob/master/rs41/rs41ptu.c
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float Rf1, // ref-resistor f1 (750 Ohm)
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Rf2, // ref-resistor f2 (1100 Ohm)
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co1[3], // { -243.911 , 0.187654 , 8.2e-06 }
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calT1[3], // calibration T1
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co2[3], // { -243.911 , 0.187654 , 8.2e-06 }
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calT2[3], // calibration T2-Hum
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calH[2]; // calibration Hum
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uint32_t meas[12], i;
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//-------------- get_CalData
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//-------------- populate calibytes (from getFrameConf)
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uint8_t calfr = vaisala_descramble(pos_CalData); // get subframe #slot
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for (i = 0; i < 16; i++) // Load subrfame calibration page (16 bytes) into #slot
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calibytes[calfr * 16 + i] = vaisala_descramble(pos_CalData + 1 + i); // pos = pos_CalData + 1 + i ; vaisala_descramble(pos)
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calfrchk[calfr] = 1; // flag this #slot as populated
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memcpy(&Rf1, calibytes + 61, 4); // 0x03*0x10+13
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memcpy(&Rf2, calibytes + 65, 4); // 0x04*0x10+ 1
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memcpy(co1 + 0, calibytes + 77, 4); // 0x04*0x10+13
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memcpy(co1 + 1, calibytes + 81, 4); // 0x05*0x10+ 1
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memcpy(co1 + 2, calibytes + 85, 4); // 0x05*0x10+ 5
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memcpy(calT1 + 0, calibytes + 89, 4); // 0x05*0x10+ 9
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memcpy(calT1 + 1, calibytes + 93, 4); // 0x05*0x10+13
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memcpy(calT1 + 2, calibytes + 97, 4); // 0x06*0x10+ 1
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memcpy(calH + 0, calibytes + 117, 4); // 0x07*0x10+ 5
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memcpy(calH + 1, calibytes + 121, 4); // 0x07*0x10+ 9
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memcpy(co2 + 0, calibytes + 293, 4); // 0x12*0x10+ 5
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memcpy(co2 + 1, calibytes + 297, 4); // 0x12*0x10+ 9
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memcpy(co2 + 2, calibytes + 301, 4); // 0x12*0x10+13
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memcpy(calT2 + 0, calibytes + 305, 4); // 0x13*0x10+ 1
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memcpy(calT2 + 1, calibytes + 309, 4); // 0x13*0x10+ 5
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memcpy(calT2 + 2, calibytes + 313, 4); // 0x13*0x10+ 9
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//---------------------------------------
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for (i = 0; i < 12; i++)
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meas[i] = vaisala_descramble(pos_temp + (3 * i)) |
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(vaisala_descramble(pos_temp + (3 * i) + 1) << 8) |
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(vaisala_descramble(pos_temp + (3 * i) + 2) << 16);
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//----Check if necessary calibytes are already present for calculation
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if (calfrchk[0x03] && calfrchk[0x04] && calfrchk[0x04] && calfrchk[0x05] && calfrchk[0x05] && calfrchk[0x06]) // Calibites OK for Temperature
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{
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//----------get_Tc------------------------
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float* p = co1;
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float* c = calT1;
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float g = (float)(meas[2] - meas[1]) / (Rf2 - Rf1), // gain
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Rb = (meas[1] * Rf2 - meas[2] * Rf1) / (float)(meas[2] - meas[1]), // ofs
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Rc = meas[0] / g - Rb,
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R = Rc * c[0],
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T = (p[0] + p[1] * R + p[2] * R * R + c[1]) * (1.0 + c[2]);
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result.temp = T;
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}
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if (calfrchk[0x07]) {
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//----------get_RH------------------------
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float a0 = 7.5; // empirical
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float a1 = 350.0 / calH[0]; // empirical
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float fh = (meas[3] - meas[4]) / (float)(meas[5] - meas[4]);
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float rh = 100.0 * (a1 * fh - a0);
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float T0 = 0.0, T1 = -25.0; // T/C
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rh += T0 - result.temp / 5.5; // empir. temperature compensation
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if (result.temp < T1)
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rh *= 1.0 + (T1 - result.temp) / 90.0; // empir. temperature compensation
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if (rh < 0.0)
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rh = 0.0;
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if (rh > 100.0)
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rh = 100.0;
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if (result.temp < -273.0)
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rh = -1.0;
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result.humid = rh;
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}
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}
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return result;
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}
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std::string Packet::type_string() const {
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switch (type_) {
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case Type::Unknown:
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return "Unknown";
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case Type::Meteomodem_unknown:
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return "Meteomodem ???";
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case Type::Meteomodem_M10:
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return "Meteomodem M10";
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case Type::Meteomodem_M20:
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return "Meteomodem M20";
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case Type::Meteomodem_M2K2:
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return "Meteomodem M2K2";
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case Type::Vaisala_RS41_SG:
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return "Vaisala RS41-SG";
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default:
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return "? 0x" + symbols_formatted().data.substr(0, 6);
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}
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}
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std::string Packet::serial_number() const {
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if (type_ == Type::Meteomodem_M10) {
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// See https://github.com/rs1729/RS/blob/master/m10/m10x.c line 606
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// Starting at byte #93: 00000000 11111111 22222222 33333333 44444444
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// CCCC AAAABBBB
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// 44444444 33333333
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// DDDEEEEE EEEEEEEE
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return to_string_hex(reader_bi_m.read(93 * 8 + 16, 4), 1) +
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to_string_dec_uint(reader_bi_m.read(93 * 8 + 20, 4), 2, '0') + " " +
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to_string_hex(reader_bi_m.read(93 * 8 + 4, 4), 1) + " " +
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to_string_dec_uint(reader_bi_m.read(93 * 8 + 24, 3), 1) +
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to_string_dec_uint(reader_bi_m.read(93 * 8 + 27, 13), 4, '0');
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} else if (type_ == Type::Vaisala_RS41_SG) {
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std::string serial_id = "";
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uint8_t achar;
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for (uint8_t i = 0; i < 8; i++) { // euquiq: Serial ID is 8 bytes long, each byte a char
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achar = vaisala_descramble(pos_SondeID + i);
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if (achar < 32 || achar > 126)
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return "?"; // Maybe there are ids with less than 8 bytes and this is not OK.
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serial_id += (char)achar;
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}
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return serial_id;
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} else {
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return "?";
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}
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}
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FormattedSymbols Packet::symbols_formatted() const {
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if (type_ == Type::Vaisala_RS41_SG) { // Euquiq: now we distinguish different types
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uint32_t bytes = packet_.size() / 8; // Need the byte amount, which if full, it SHOULD be 320 size() should return 2560
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std::string hex_data;
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std::string hex_error;
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hex_data.reserve(bytes * 2); // 2 hexa chars per byte
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hex_error.reserve(1);
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for (uint32_t i = 0; i < bytes; i++) // log will show the packet starting on the last 4 bytes from signature 93DF1A60
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hex_data += to_string_hex(vaisala_descramble(i), 2);
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return {hex_data, hex_error};
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} else {
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return format_symbols(decoder_);
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}
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}
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bool Packet::crc_ok() const {
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switch (type_) {
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case Type::Meteomodem_M10:
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return crc_ok_M10();
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case Type::Vaisala_RS41_SG:
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return crc_ok_RS41();
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default:
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return true; // euquiq: it was false, but if no crc routine, then no way to check
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}
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}
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// each data block has a 2 byte header, data, and 2 byte tail:
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// 1st byte: block ID
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// 2nd byte: data length (without header or tail)
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// <data>
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// 2 bytes CRC16 over the data.
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bool Packet::crc_ok_RS41() const // check CRC for the data blocks we need
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{
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if (!crc16rs41(block_status))
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return false;
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if (!crc16rs41(block_gpspos))
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return false;
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if (!crc16rs41(block_meas))
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return false;
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return true;
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}
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// Checks CRC16 on a RS41 field:
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bool Packet::crc16rs41(uint32_t field_start) const {
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int crc16poly = 0x1021;
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int rem = 0xFFFF, b, j;
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int xbyte;
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uint32_t pos = field_start + 1;
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uint8_t length = vaisala_descramble(pos);
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if (pos + length + 2 > packet_.size() / 8)
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return false; // Out of packet!
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for (b = 0; b < length; b++) {
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pos++;
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xbyte = vaisala_descramble(pos);
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rem = rem ^ (xbyte << 8);
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for (j = 0; j < 8; j++) {
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if (rem & 0x8000) {
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rem = (rem << 1) ^ crc16poly;
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} else {
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rem = (rem << 1);
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}
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rem &= 0xFFFF;
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}
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}
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// Check calculated CRC against packet's one
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pos++;
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int crcok = vaisala_descramble(pos) | (vaisala_descramble(pos + 1) << 8);
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if (crcok != rem)
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return false;
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return true;
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}
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bool Packet::crc_ok_M10() const {
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uint16_t cs{0};
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uint32_t c0, c1, t, t6, t7, s, b;
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for (size_t i = 0; i < packet_.size(); i++) {
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b = packet_[i];
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c1 = cs & 0xFF;
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// B
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b = (b >> 1) | ((b & 1) << 7);
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b ^= (b >> 2) & 0xFF;
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// A1
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t6 = (cs & 1) ^ ((cs >> 2) & 1) ^ ((cs >> 4) & 1);
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t7 = ((cs >> 1) & 1) ^ ((cs >> 3) & 1) ^ ((cs >> 5) & 1);
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t = (cs & 0x3F) | (t6 << 6) | (t7 << 7);
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// A2
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s = (cs >> 7) & 0xFF;
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s ^= (s >> 2) & 0xFF;
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c0 = b ^ t ^ s;
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cs = ((c1 << 8) | c0) & 0xFFFF;
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}
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return ((cs & 0xFFFF) == ((packet_[0x63] << 8) | (packet_[0x63 + 1])));
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}
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} /* namespace sonde */
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