374 lines
13 KiB
C
374 lines
13 KiB
C
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#include <furi.h>
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#include "toolbox/level_duration.h"
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#include "protocol_fdx_b.h"
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#include <toolbox/manchester_decoder.h>
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#include <lfrfid/tools/bit_lib.h>
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#include "lfrfid_protocols.h"
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#define FDX_B_ENCODED_BIT_SIZE (128)
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#define FDX_B_ENCODED_BYTE_SIZE (((FDX_B_ENCODED_BIT_SIZE) / 8))
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#define FDX_B_PREAMBLE_BIT_SIZE (11)
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#define FDX_B_PREAMBLE_BYTE_SIZE (2)
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#define FDX_B_ENCODED_BYTE_FULL_SIZE (FDX_B_ENCODED_BYTE_SIZE + FDX_B_PREAMBLE_BYTE_SIZE)
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#define FDXB_DECODED_DATA_SIZE (11)
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#define FDX_B_SHORT_TIME (128)
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#define FDX_B_LONG_TIME (256)
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#define FDX_B_JITTER_TIME (60)
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#define FDX_B_SHORT_TIME_LOW (FDX_B_SHORT_TIME - FDX_B_JITTER_TIME)
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#define FDX_B_SHORT_TIME_HIGH (FDX_B_SHORT_TIME + FDX_B_JITTER_TIME)
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#define FDX_B_LONG_TIME_LOW (FDX_B_LONG_TIME - FDX_B_JITTER_TIME)
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#define FDX_B_LONG_TIME_HIGH (FDX_B_LONG_TIME + FDX_B_JITTER_TIME)
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typedef struct {
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bool last_short;
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bool last_level;
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size_t encoded_index;
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uint8_t encoded_data[FDX_B_ENCODED_BYTE_FULL_SIZE];
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uint8_t data[FDXB_DECODED_DATA_SIZE];
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} ProtocolFDXB;
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ProtocolFDXB* protocol_fdx_b_alloc(void) {
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ProtocolFDXB* protocol = malloc(sizeof(ProtocolFDXB));
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return protocol;
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};
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void protocol_fdx_b_free(ProtocolFDXB* protocol) {
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free(protocol);
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};
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uint8_t* protocol_fdx_b_get_data(ProtocolFDXB* proto) {
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return proto->data;
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};
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void protocol_fdx_b_decoder_start(ProtocolFDXB* protocol) {
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memset(protocol->encoded_data, 0, FDX_B_ENCODED_BYTE_FULL_SIZE);
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protocol->last_short = false;
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};
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static bool protocol_fdx_b_can_be_decoded(ProtocolFDXB* protocol) {
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bool result = false;
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/*
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msb lsb
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0 10000000000 Header pattern. 11 bits.
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11 1nnnnnnnn
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20 1nnnnnnnn 38 bit (12 digit) National code.
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29 1nnnnnnnn eg. 000000001008 (decimal).
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38 1nnnnnnnn
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47 1nnnnnncc 10 bit (3 digit) Country code.
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56 1cccccccc eg. 999 (decimal).
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65 1s------- 1 bit data block status flag.
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74 1-------a 1 bit animal application indicator.
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83 1xxxxxxxx 16 bit checksum.
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92 1xxxxxxxx
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101 1eeeeeeee 24 bits of extra data if present.
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110 1eeeeeeee eg. $123456.
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119 1eeeeeeee
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*/
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do {
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// check 11 bits preamble
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if(bit_lib_get_bits_16(protocol->encoded_data, 0, 11) != 0b10000000000) break;
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// check next 11 bits preamble
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if(bit_lib_get_bits_16(protocol->encoded_data, 128, 11) != 0b10000000000) break;
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// check control bits
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if(!bit_lib_test_parity(protocol->encoded_data, 3, 13 * 9, BitLibParityAlways1, 9)) break;
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// compute checksum
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uint8_t crc_data[8];
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for(size_t i = 0; i < 8; i++) {
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bit_lib_copy_bits(crc_data, i * 8, 8, protocol->encoded_data, 12 + 9 * i);
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}
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uint16_t crc_res = bit_lib_crc16(crc_data, 8, 0x1021, 0x0000, false, false, 0x0000);
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// read checksum
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uint16_t crc_ex = 0;
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bit_lib_copy_bits((uint8_t*)&crc_ex, 8, 8, protocol->encoded_data, 84);
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bit_lib_copy_bits((uint8_t*)&crc_ex, 0, 8, protocol->encoded_data, 93);
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// compare checksum
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if(crc_res != crc_ex) break;
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result = true;
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} while(false);
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return result;
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}
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void protocol_fdx_b_decode(ProtocolFDXB* protocol) {
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// remove parity
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bit_lib_remove_bit_every_nth(protocol->encoded_data, 3, 13 * 9, 9);
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// remove header pattern
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for(size_t i = 0; i < 11; i++)
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bit_lib_push_bit(protocol->encoded_data, FDX_B_ENCODED_BYTE_FULL_SIZE, 0);
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// 0 nnnnnnnn
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// 8 nnnnnnnn 38 bit (12 digit) National code.
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// 16 nnnnnnnn eg. 000000001008 (decimal).
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// 24 nnnnnnnn
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// 32 nnnnnncc 10 bit (3 digit) Country code.
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// 40 cccccccc eg. 999 (decimal).
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// 48 s------- 1 bit data block status flag.
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// 56 -------a 1 bit animal application indicator.
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// 64 xxxxxxxx 16 bit checksum.
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// 72 xxxxxxxx
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// 80 eeeeeeee 24 bits of extra data if present.
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// 88 eeeeeeee eg. $123456.
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// 92 eeeeeeee
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// copy data without checksum
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bit_lib_copy_bits(protocol->data, 0, 64, protocol->encoded_data, 0);
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bit_lib_copy_bits(protocol->data, 64, 24, protocol->encoded_data, 80);
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// const BitLibRegion regions_encoded[] = {
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// {'n', 0, 38},
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// {'c', 38, 10},
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// {'b', 48, 16},
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// {'x', 64, 16},
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// {'e', 80, 24},
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// };
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// bit_lib_print_regions(regions_encoded, 5, protocol->encoded_data, FDX_B_ENCODED_BIT_SIZE);
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// const BitLibRegion regions_decoded[] = {
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// {'n', 0, 38},
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// {'c', 38, 10},
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// {'b', 48, 16},
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// {'e', 64, 24},
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// };
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// bit_lib_print_regions(regions_decoded, 4, protocol->data, FDXB_DECODED_DATA_SIZE * 8);
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}
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bool protocol_fdx_b_decoder_feed(ProtocolFDXB* protocol, bool level, uint32_t duration) {
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bool result = false;
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UNUSED(level);
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bool pushed = false;
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// Bi-Phase Manchester decoding
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if(duration >= FDX_B_SHORT_TIME_LOW && duration <= FDX_B_SHORT_TIME_HIGH) {
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if(protocol->last_short == false) {
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protocol->last_short = true;
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} else {
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pushed = true;
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bit_lib_push_bit(protocol->encoded_data, FDX_B_ENCODED_BYTE_FULL_SIZE, false);
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protocol->last_short = false;
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}
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} else if(duration >= FDX_B_LONG_TIME_LOW && duration <= FDX_B_LONG_TIME_HIGH) {
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if(protocol->last_short == false) {
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pushed = true;
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bit_lib_push_bit(protocol->encoded_data, FDX_B_ENCODED_BYTE_FULL_SIZE, true);
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} else {
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// reset
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protocol->last_short = false;
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}
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} else {
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// reset
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protocol->last_short = false;
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}
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if(pushed && protocol_fdx_b_can_be_decoded(protocol)) {
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protocol_fdx_b_decode(protocol);
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result = true;
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}
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return result;
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};
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bool protocol_fdx_b_encoder_start(ProtocolFDXB* protocol) {
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memset(protocol->encoded_data, 0, FDX_B_ENCODED_BYTE_FULL_SIZE);
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bit_lib_set_bit(protocol->encoded_data, 0, 1);
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for(size_t i = 0; i < 13; i++) {
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bit_lib_set_bit(protocol->encoded_data, 11 + 9 * i, 1);
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if(i == 8 || i == 9) continue;
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if(i < 8) {
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bit_lib_copy_bits(protocol->encoded_data, 12 + 9 * i, 8, protocol->data, i * 8);
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} else {
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bit_lib_copy_bits(protocol->encoded_data, 12 + 9 * i, 8, protocol->data, (i - 2) * 8);
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}
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}
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uint16_t crc_res = bit_lib_crc16(protocol->data, 8, 0x1021, 0x0000, false, false, 0x0000);
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bit_lib_copy_bits(protocol->encoded_data, 84, 8, (uint8_t*)&crc_res, 8);
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bit_lib_copy_bits(protocol->encoded_data, 93, 8, (uint8_t*)&crc_res, 0);
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protocol->encoded_index = 0;
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protocol->last_short = false;
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protocol->last_level = false;
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return true;
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};
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LevelDuration protocol_fdx_b_encoder_yield(ProtocolFDXB* protocol) {
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uint32_t duration;
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protocol->last_level = !protocol->last_level;
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bool bit = bit_lib_get_bit(protocol->encoded_data, protocol->encoded_index);
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// Bi-Phase Manchester encoder
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if(bit) {
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// one long pulse for 1
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duration = FDX_B_LONG_TIME / 8;
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bit_lib_increment_index(protocol->encoded_index, FDX_B_ENCODED_BIT_SIZE);
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} else {
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// two short pulses for 0
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duration = FDX_B_SHORT_TIME / 8;
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if(protocol->last_short) {
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bit_lib_increment_index(protocol->encoded_index, FDX_B_ENCODED_BIT_SIZE);
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protocol->last_short = false;
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} else {
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protocol->last_short = true;
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}
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}
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return level_duration_make(protocol->last_level, duration);
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};
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// 0 nnnnnnnn
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// 8 nnnnnnnn 38 bit (12 digit) National code.
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// 16 nnnnnnnn eg. 000000001008 (decimal).
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// 24 nnnnnnnn
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// 32 nnnnnnnn 10 bit (3 digit) Country code.
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// 40 cccccccc eg. 999 (decimal).
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// 48 s------- 1 bit data block status flag.
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// 56 -------a 1 bit animal application indicator.
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// 64 eeeeeeee 24 bits of extra data if present.
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// 72 eeeeeeee eg. $123456.
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// 80 eeeeeeee
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static uint64_t protocol_fdx_b_get_national_code(const uint8_t* data) {
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uint64_t national_code = bit_lib_get_bits_32(data, 0, 32);
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national_code = national_code << 32;
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national_code |= bit_lib_get_bits_32(data, 32, 6) << (32 - 6);
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bit_lib_reverse_bits((uint8_t*)&national_code, 0, 64);
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return national_code;
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}
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static uint16_t protocol_fdx_b_get_country_code(const uint8_t* data) {
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uint16_t country_code = bit_lib_get_bits_16(data, 38, 10) << 6;
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bit_lib_reverse_bits((uint8_t*)&country_code, 0, 16);
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return country_code;
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}
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static bool protocol_fdx_b_get_temp(const uint8_t* data, float* temp) {
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uint32_t extended = bit_lib_get_bits_32(data, 64, 24) << 8;
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bit_lib_reverse_bits((uint8_t*)&extended, 0, 32);
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uint8_t ex_parity = (extended & 0x100) >> 8;
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uint8_t ex_temperature = extended & 0xff;
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uint8_t ex_calc_parity = bit_lib_test_parity_32(ex_temperature, BitLibParityOdd);
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bool ex_temperature_present = (ex_calc_parity == ex_parity) && !(extended & 0xe00);
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if(ex_temperature_present) {
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float temperature_f = 74 + ex_temperature * 0.2;
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*temp = temperature_f;
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return true;
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} else {
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return false;
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}
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}
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void protocol_fdx_b_render_data(ProtocolFDXB* protocol, string_t result) {
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// 38 bits of national code
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uint64_t national_code = protocol_fdx_b_get_national_code(protocol->data);
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// 10 bit of country code
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uint16_t country_code = protocol_fdx_b_get_country_code(protocol->data);
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bool block_status = bit_lib_get_bit(protocol->data, 48);
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bool rudi_bit = bit_lib_get_bit(protocol->data, 49);
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uint8_t reserved = bit_lib_get_bits(protocol->data, 50, 5);
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uint8_t user_info = bit_lib_get_bits(protocol->data, 55, 5);
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uint8_t replacement_number = bit_lib_get_bits(protocol->data, 60, 3);
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bool animal_flag = bit_lib_get_bit(protocol->data, 63);
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string_printf(result, "ID: %03u-%012llu\r\n", country_code, national_code);
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string_cat_printf(result, "Animal: %s, ", animal_flag ? "Yes" : "No");
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float temperature;
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if(protocol_fdx_b_get_temp(protocol->data, &temperature)) {
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float temperature_c = (temperature - 32) / 1.8;
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string_cat_printf(
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result, "T: %.2fF, %.2fC\r\n", (double)temperature, (double)temperature_c);
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} else {
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string_cat_printf(result, "T: ---\r\n");
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}
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string_cat_printf(
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result,
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"Bits: %X-%X-%X-%X-%X",
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block_status,
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rudi_bit,
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reserved,
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user_info,
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replacement_number);
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};
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void protocol_fdx_b_render_brief_data(ProtocolFDXB* protocol, string_t result) {
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// 38 bits of national code
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uint64_t national_code = protocol_fdx_b_get_national_code(protocol->data);
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// 10 bit of country code
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uint16_t country_code = protocol_fdx_b_get_country_code(protocol->data);
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bool animal_flag = bit_lib_get_bit(protocol->data, 63);
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string_printf(result, "ID: %03u-%012llu\r\n", country_code, national_code);
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string_cat_printf(result, "Animal: %s, ", animal_flag ? "Yes" : "No");
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float temperature;
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if(protocol_fdx_b_get_temp(protocol->data, &temperature)) {
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float temperature_c = (temperature - 32) / 1.8;
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string_cat_printf(result, "T: %.2fC", (double)temperature_c);
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} else {
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string_cat_printf(result, "T: ---");
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}
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};
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bool protocol_fdx_b_write_data(ProtocolFDXB* protocol, void* data) {
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LFRFIDWriteRequest* request = (LFRFIDWriteRequest*)data;
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bool result = false;
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protocol_fdx_b_encoder_start(protocol);
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if(request->write_type == LFRFIDWriteTypeT5577) {
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request->t5577.block[0] = LFRFID_T5577_MODULATION_DIPHASE | LFRFID_T5577_BITRATE_RF_32 |
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(4 << LFRFID_T5577_MAXBLOCK_SHIFT);
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request->t5577.block[1] = bit_lib_get_bits_32(protocol->encoded_data, 0, 32);
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request->t5577.block[2] = bit_lib_get_bits_32(protocol->encoded_data, 32, 32);
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request->t5577.block[3] = bit_lib_get_bits_32(protocol->encoded_data, 64, 32);
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request->t5577.block[4] = bit_lib_get_bits_32(protocol->encoded_data, 96, 32);
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request->t5577.blocks_to_write = 5;
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result = true;
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}
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return result;
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};
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const ProtocolBase protocol_fdx_b = {
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.name = "FDX-B",
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.manufacturer = "ISO",
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.data_size = FDXB_DECODED_DATA_SIZE,
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.features = LFRFIDFeatureASK,
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.validate_count = 3,
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.alloc = (ProtocolAlloc)protocol_fdx_b_alloc,
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.free = (ProtocolFree)protocol_fdx_b_free,
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.get_data = (ProtocolGetData)protocol_fdx_b_get_data,
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.decoder =
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{
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.start = (ProtocolDecoderStart)protocol_fdx_b_decoder_start,
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.feed = (ProtocolDecoderFeed)protocol_fdx_b_decoder_feed,
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},
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.encoder =
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{
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.start = (ProtocolEncoderStart)protocol_fdx_b_encoder_start,
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.yield = (ProtocolEncoderYield)protocol_fdx_b_encoder_yield,
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},
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.render_data = (ProtocolRenderData)protocol_fdx_b_render_data,
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.render_brief_data = (ProtocolRenderData)protocol_fdx_b_render_brief_data,
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.write_data = (ProtocolWriteData)protocol_fdx_b_write_data,
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};
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