mirror of
https://github.com/eried/portapack-mayhem.git
synced 2024-12-11 16:54:21 -05:00
2ccda5aebd
* Initial commit - wip
* Half part of the transition of baseband processor.
* More SGD
* WIP, Weather refactor, UI improv
* Rename
* Added 4msps, and fixes
* Fixes
* princeton working
* Renamed proc_weather, bc now multifunctional
* Proto: bett
* FPS_CAME = 4,
FPS_PRASTEL = 5,
FPS_AIRFORCE = 6,
* Came Atomo, fixes
* Separate weather and sgd, bc of baseband size limit
* Fix display
* Save space
* More protos
* Dooya proto added
* More protos
* add protos
* More protos
* Move weather to ext app
* nw
* Revert "Move weather to ext app"
This reverts commit 8a84aac2f5
.
* revert
* Fix merge
* Better naming
* More protos
* More protos
* Add protos
* Fix warning
* Add NeroRadio
* more protos
* more protos
* More protos
* Shrink a bit
* fixes
* More protos
* Nicer code
* Fix naming
* Fix format
* Remove unused
* Fix some protos, that needs a LOOOONG part with the same lo/high
* Modify key calculation
148 lines
5.8 KiB
C++
148 lines
5.8 KiB
C++
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#ifndef __FPROTO_CAMETWEE_H__
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#define __FPROTO_CAMETWEE_H__
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#include "subghzdbase.hpp"
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typedef enum : uint8_t {
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CameTweeDecoderStepReset = 0,
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CameTweeDecoderStepDecoderData,
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} CameTweeDecoderStep;
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class FProtoSubGhzDCameTwee : public FProtoSubGhzDBase {
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public:
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FProtoSubGhzDCameTwee() {
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sensorType = FPS_CAMETWEE;
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te_short = 500;
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te_long = 1000;
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te_delta = 250;
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min_count_bit_for_found = 54;
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}
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void feed(bool level, uint32_t duration) {
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ManchesterEvent event = ManchesterEventReset;
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switch (parser_step) {
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case CameTweeDecoderStepReset:
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if ((!level) && (DURATION_DIFF(duration, te_long * 51) < te_delta * 20)) {
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// Found header CAME
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parser_step = CameTweeDecoderStepDecoderData;
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decode_data = 0;
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decode_count_bit = 0;
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FProtoGeneral::manchester_advance(manchester_saved_state, ManchesterEventLongLow, &manchester_saved_state, NULL);
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FProtoGeneral::manchester_advance(manchester_saved_state, ManchesterEventLongHigh, &manchester_saved_state, NULL);
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FProtoGeneral::manchester_advance(manchester_saved_state, ManchesterEventShortLow, &manchester_saved_state, NULL);
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}
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break;
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case CameTweeDecoderStepDecoderData:
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if (!level) {
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if (DURATION_DIFF(duration, te_short) < te_delta) {
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event = ManchesterEventShortLow;
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} else if (
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DURATION_DIFF(duration, te_long) < te_delta) {
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event = ManchesterEventLongLow;
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} else if (
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duration >= ((uint32_t)te_long * 2 + te_delta)) {
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if (decode_count_bit == min_count_bit_for_found) {
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data = decode_data;
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data_count_bit = decode_count_bit;
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subghz_protocol_came_twee_remote_controller();
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if (callback) callback(this);
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}
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decode_data = 0;
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decode_count_bit = 0;
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FProtoGeneral::manchester_advance(manchester_saved_state, ManchesterEventLongLow, &manchester_saved_state, NULL);
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FProtoGeneral::manchester_advance(manchester_saved_state, ManchesterEventLongHigh, &manchester_saved_state, NULL);
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FProtoGeneral::manchester_advance(manchester_saved_state, ManchesterEventShortLow, &manchester_saved_state, NULL);
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} else {
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parser_step = CameTweeDecoderStepReset;
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}
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} else {
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if (DURATION_DIFF(duration, te_short) < te_delta) {
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event = ManchesterEventShortHigh;
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} else if (
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DURATION_DIFF(duration, te_long) < te_delta) {
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event = ManchesterEventLongHigh;
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} else {
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parser_step = CameTweeDecoderStepReset;
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}
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}
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if (event != ManchesterEventReset) {
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bool bit;
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if (FProtoGeneral::manchester_advance(manchester_saved_state, event, &manchester_saved_state, &bit)) {
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decode_data = (decode_data << 1) | !bit;
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decode_count_bit++;
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}
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}
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break;
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}
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}
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protected:
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ManchesterState manchester_saved_state = ManchesterStateMid1;
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void subghz_protocol_came_twee_remote_controller() {
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/* Came Twee 54 bit, rolling code 15 parcels with
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* a decreasing counter from 0xE to 0x0
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* with originally coded dip switches on the console 10 bit code
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*
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* 0x003FFF72E04A6FEE
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* 0x003FFF72D17B5EDD
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* 0x003FFF72C2684DCC
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* 0x003FFF72B3193CBB
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* 0x003FFF72A40E2BAA
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* 0x003FFF72953F1A99
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* 0x003FFF72862C0988
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* 0x003FFF7277DDF877
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* 0x003FFF7268C2E766
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* 0x003FFF7259F3D655
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* 0x003FFF724AE0C544
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* 0x003FFF723B91B433
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* 0x003FFF722C86A322
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* 0x003FFF721DB79211
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* 0x003FFF720EA48100
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*
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* decryption
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* the last 32 bits, do XOR by the desired number, divide the result by 4,
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* convert the first 16 bits of the resulting 32-bit number to bin and do
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* bit-by-bit mirroring, adding up to 10 bits
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*
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* Example
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* Step 1. 0x003FFF721DB79211 => 0x1DB79211
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* Step 4. 0x1DB79211 xor 0x1D1D1D11 => 0x00AA8F00
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* Step 4. 0x00AA8F00 / 4 => 0x002AA3C0
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* Step 5. 0x002AA3C0 => 0x002A
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* Step 6. 0x002A bin => b101010
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* Step 7. b101010 => b0101010000
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* Step 8. b0101010000 => (Dip) Off ON Off ON Off ON Off Off Off Off
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*/
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uint8_t cnt_parcel = (uint8_t)(data & 0xF);
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serial = (uint32_t)(data & 0x0FFFFFFFF);
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data = (data ^ came_twee_magic_numbers_xor[cnt_parcel]);
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data /= 4;
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btn = (data >> 4) & 0x0F;
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data >>= 16;
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data = (uint16_t)FProtoGeneral::subghz_protocol_blocks_reverse_key(data, 16);
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cnt = data >> 6;
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}
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inline static const uint32_t came_twee_magic_numbers_xor[15] = {
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0x0E0E0E00,
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0x1D1D1D11,
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0x2C2C2C22,
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0x3B3B3B33,
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0x4A4A4A44,
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0x59595955,
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0x68686866,
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0x77777777,
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0x86868688,
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0x95959599,
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0xA4A4A4AA,
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0xB3B3B3BB,
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0xC2C2C2CC,
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0xD1D1D1DD,
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0xE0E0E0EE,
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};
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};
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#endif
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