flipperzero-firmware/lib/one_wire/ibutton/pulse_protocols/protocol_cyfral.c

#include "protocol_cyfral.h"
#include <stdlib.h>
#include <string.h>
#include <furi/check.h>
#include <furi_hal_delay.h>

#define CYFRAL_DATA_SIZE 2
#define CYFRAL_MAX_PERIOD_US 230

typedef enum {
    CYFRAL_BIT_WAIT_FRONT_HIGH,
    CYFRAL_BIT_WAIT_FRONT_LOW,
} CyfralBitState;

typedef enum {
    CYFRAL_WAIT_START_NIBBLE,
    CYFRAL_READ_NIBBLE,
    CYFRAL_READ_STOP_NIBBLE,
} CyfralState;

struct ProtocolCyfral {
    PulseProtocol* protocol;

    CyfralState state;
    CyfralBitState bit_state;

    // ready flag, key is read and valid
    // TODO: atomic access
    bool ready;
    // key data storage
    uint16_t key_data;
    // high + low period time
    uint32_t period_time;
    // temporary nibble storage
    uint8_t nibble;
    // data valid flag
    // MUST be checked only in READ_STOP_NIBBLE state
    bool data_valid;
    // nibble index, we expect 8 nibbles
    uint8_t index;
    // bit index in nibble, 4 bit per nibble
    uint8_t bit_index;
    // max period, 230us x clock per us
    uint32_t max_period;
};

static void cyfral_pulse(void* context, bool polarity, uint32_t length);
static void cyfral_reset(void* context);
static void cyfral_get_data(void* context, uint8_t* data, size_t length);
static bool cyfral_decoded(void* context);

ProtocolCyfral* protocol_cyfral_alloc() {
    ProtocolCyfral* cyfral = malloc(sizeof(ProtocolCyfral));
    cyfral_reset(cyfral);

    cyfral->protocol = pulse_protocol_alloc();

    pulse_protocol_set_context(cyfral->protocol, cyfral);
    pulse_protocol_set_pulse_cb(cyfral->protocol, cyfral_pulse);
    pulse_protocol_set_reset_cb(cyfral->protocol, cyfral_reset);
    pulse_protocol_set_get_data_cb(cyfral->protocol, cyfral_get_data);
    pulse_protocol_set_decoded_cb(cyfral->protocol, cyfral_decoded);

    return cyfral;
}

void protocol_cyfral_free(ProtocolCyfral* cyfral) {
    furi_assert(cyfral);
    pulse_protocol_free(cyfral->protocol);
    free(cyfral);
}

PulseProtocol* protocol_cyfral_get_protocol(ProtocolCyfral* cyfral) {
    furi_assert(cyfral);
    return cyfral->protocol;
}

static void cyfral_get_data(void* context, uint8_t* data, size_t length) {
    furi_assert(context);
    furi_check(length >= CYFRAL_DATA_SIZE);
    ProtocolCyfral* cyfral = context;
    memcpy(data, &cyfral->key_data, CYFRAL_DATA_SIZE);
}

static bool cyfral_decoded(void* context) {
    furi_assert(context);
    ProtocolCyfral* cyfral = context;
    bool decoded = cyfral->ready;
    return decoded;
}

static void cyfral_reset(void* context) {
    furi_assert(context);
    ProtocolCyfral* cyfral = context;
    cyfral->state = CYFRAL_WAIT_START_NIBBLE;
    cyfral->bit_state = CYFRAL_BIT_WAIT_FRONT_LOW;

    cyfral->period_time = 0;
    cyfral->bit_index = 0;
    cyfral->ready = false;
    cyfral->index = 0;

    cyfral->key_data = 0;
    cyfral->nibble = 0;
    cyfral->data_valid = true;

    cyfral->max_period = CYFRAL_MAX_PERIOD_US * instructions_per_us;
}

static bool cyfral_process_bit(
    ProtocolCyfral* cyfral,
    bool polarity,
    uint32_t length,
    bool* bit_ready,
    bool* bit_value) {
    bool result = true;
    *bit_ready = false;

    // bit start from low
    switch(cyfral->bit_state) {
    case CYFRAL_BIT_WAIT_FRONT_LOW:
        if(polarity == true) {
            cyfral->period_time += length;

            *bit_ready = true;
            if(cyfral->period_time <= cyfral->max_period) {
                if((cyfral->period_time / 2) > length) {
                    *bit_value = false;
                } else {
                    *bit_value = true;
                }
            } else {
                result = false;
            }

            cyfral->bit_state = CYFRAL_BIT_WAIT_FRONT_HIGH;
        } else {
            result = false;
        }
        break;
    case CYFRAL_BIT_WAIT_FRONT_HIGH:
        if(polarity == false) {
            cyfral->period_time = length;
            cyfral->bit_state = CYFRAL_BIT_WAIT_FRONT_LOW;
        } else {
            result = false;
        }
        break;
    }

    return result;
}

static void cyfral_pulse(void* context, bool polarity, uint32_t length) {
    furi_assert(context);
    ProtocolCyfral* cyfral = context;

    bool bit_ready;
    bool bit_value;

    if(cyfral->ready) return;

    switch(cyfral->state) {
    case CYFRAL_WAIT_START_NIBBLE:
        // wait for start word
        if(cyfral_process_bit(cyfral, polarity, length, &bit_ready, &bit_value)) {
            if(bit_ready) {
                cyfral->nibble = ((cyfral->nibble << 1) | bit_value) & 0x0F;
                if(cyfral->nibble == 0b0001) {
                    cyfral->nibble = 0;
                    cyfral->state = CYFRAL_READ_NIBBLE;
                }
            }
        } else {
            cyfral_reset(cyfral);
        }

        break;
    case CYFRAL_READ_NIBBLE:
        // read nibbles
        if(cyfral_process_bit(cyfral, polarity, length, &bit_ready, &bit_value)) {
            if(bit_ready) {
                cyfral->nibble = (cyfral->nibble << 1) | bit_value;

                cyfral->bit_index++;

                //convert every nibble to 2-bit index
                if(cyfral->bit_index == 4) {
                    switch(cyfral->nibble) {
                    case 0b1110:
                        cyfral->key_data = (cyfral->key_data << 2) | 0b11;
                        break;
                    case 0b1101:
                        cyfral->key_data = (cyfral->key_data << 2) | 0b10;
                        break;
                    case 0b1011:
                        cyfral->key_data = (cyfral->key_data << 2) | 0b01;
                        break;
                    case 0b0111:
                        cyfral->key_data = (cyfral->key_data << 2) | 0b00;
                        break;
                    default:
                        cyfral->data_valid = false;
                        break;
                    }

                    cyfral->nibble = 0;
                    cyfral->bit_index = 0;
                    cyfral->index++;
                }

                // succefully read 8 nibbles
                if(cyfral->index == 8) {
                    cyfral->state = CYFRAL_READ_STOP_NIBBLE;
                }
            }
        } else {
            cyfral_reset(cyfral);
        }
        break;
    case CYFRAL_READ_STOP_NIBBLE:
        // read stop nibble
        if(cyfral_process_bit(cyfral, polarity, length, &bit_ready, &bit_value)) {
            if(bit_ready) {
                cyfral->nibble = ((cyfral->nibble << 1) | bit_value) & 0x0F;
                cyfral->bit_index++;

                switch(cyfral->bit_index) {
                case 0:
                case 1:
                case 2:
                case 3:
                    break;
                case 4:
                    if(cyfral->nibble == 0b0001) {
                        // validate data
                        if(cyfral->data_valid) {
                            cyfral->ready = true;
                        } else {
                            cyfral_reset(cyfral);
                        }
                    } else {
                        cyfral_reset(cyfral);
                    }
                    break;
                default:
                    cyfral_reset(cyfral);
                    break;
                }
            }
        } else {
            cyfral_reset(cyfral);
        }
        break;
    }
}
[FL-2393][FL-2381] iButton, OneWire: move to plain C (#1068) * iButton: getting started on the worker concept * Hal delay: added global instructions_per_us variable * iButton: one wire slave * iButton: ibutton key setter * iButton: one wire host, use ibutton_hal * iButton\RFID: common pulse decoder concept * iButton: cyfral decoder * iButton: worker thread concept * iButton: metakom decoder * iButton: write key through worker * iButton: worker mode holder * iButton: worker improvements * iButton: Cyfral encoder * iButton: Metakom encoder * lib: pulse protocol helpers * iButton: Metakom decoder * iButton: Cyfral decoder * iButton worker: separate modes * iButton: libs documentation * HAL: iButton gpio modes * iButton worker: rename modes file * iButton worker, hal: move to LL * iButton CLI: worker for reading and emulation commands * iButton HAL: correct init and emulation sequence * iButton cli: moved to plain C * iButton: move to worker, small step to plain C * Libs, one wire: move to plain C * Libs: added forgotten files to compilation * iButton writer: get rid of manual disable/enable irq 2022-03-29 13:01:56 +00:00			`#include "protocol_cyfral.h"`
			`#include <stdlib.h>`
			`#include <string.h>`
			`#include <furi/check.h>`
			`#include <furi_hal_delay.h>`

			`#define CYFRAL_DATA_SIZE 2`
			`#define CYFRAL_MAX_PERIOD_US 230`

			`typedef enum {`
			`CYFRAL_BIT_WAIT_FRONT_HIGH,`
			`CYFRAL_BIT_WAIT_FRONT_LOW,`
			`} CyfralBitState;`

			`typedef enum {`
			`CYFRAL_WAIT_START_NIBBLE,`
			`CYFRAL_READ_NIBBLE,`
			`CYFRAL_READ_STOP_NIBBLE,`
			`} CyfralState;`

			`struct ProtocolCyfral {`
			`PulseProtocol* protocol;`

			`CyfralState state;`
			`CyfralBitState bit_state;`

			`// ready flag, key is read and valid`
			`// TODO: atomic access`
			`bool ready;`
			`// key data storage`
			`uint16_t key_data;`
			`// high + low period time`
			`uint32_t period_time;`
			`// temporary nibble storage`
			`uint8_t nibble;`
			`// data valid flag`
			`// MUST be checked only in READ_STOP_NIBBLE state`
			`bool data_valid;`
			`// nibble index, we expect 8 nibbles`
			`uint8_t index;`
			`// bit index in nibble, 4 bit per nibble`
			`uint8_t bit_index;`
			`// max period, 230us x clock per us`
			`uint32_t max_period;`
			`};`

			`static void cyfral_pulse(void* context, bool polarity, uint32_t length);`
			`static void cyfral_reset(void* context);`
			`static void cyfral_get_data(void* context, uint8_t* data, size_t length);`
			`static bool cyfral_decoded(void* context);`

			`ProtocolCyfral* protocol_cyfral_alloc() {`
			`ProtocolCyfral* cyfral = malloc(sizeof(ProtocolCyfral));`
			`cyfral_reset(cyfral);`

			`cyfral->protocol = pulse_protocol_alloc();`

			`pulse_protocol_set_context(cyfral->protocol, cyfral);`
			`pulse_protocol_set_pulse_cb(cyfral->protocol, cyfral_pulse);`
			`pulse_protocol_set_reset_cb(cyfral->protocol, cyfral_reset);`
			`pulse_protocol_set_get_data_cb(cyfral->protocol, cyfral_get_data);`
			`pulse_protocol_set_decoded_cb(cyfral->protocol, cyfral_decoded);`

			`return cyfral;`
			`}`

			`void protocol_cyfral_free(ProtocolCyfral* cyfral) {`
			`furi_assert(cyfral);`
			`pulse_protocol_free(cyfral->protocol);`
			`free(cyfral);`
			`}`

			`PulseProtocol* protocol_cyfral_get_protocol(ProtocolCyfral* cyfral) {`
			`furi_assert(cyfral);`
			`return cyfral->protocol;`
			`}`

			`static void cyfral_get_data(void* context, uint8_t* data, size_t length) {`
			`furi_assert(context);`
			`furi_check(length >= CYFRAL_DATA_SIZE);`
			`ProtocolCyfral* cyfral = context;`
			`memcpy(data, &cyfral->key_data, CYFRAL_DATA_SIZE);`
			`}`

			`static bool cyfral_decoded(void* context) {`
			`furi_assert(context);`
			`ProtocolCyfral* cyfral = context;`
			`bool decoded = cyfral->ready;`
			`return decoded;`
			`}`

			`static void cyfral_reset(void* context) {`
			`furi_assert(context);`
			`ProtocolCyfral* cyfral = context;`
			`cyfral->state = CYFRAL_WAIT_START_NIBBLE;`
			`cyfral->bit_state = CYFRAL_BIT_WAIT_FRONT_LOW;`

			`cyfral->period_time = 0;`
			`cyfral->bit_index = 0;`
			`cyfral->ready = false;`
			`cyfral->index = 0;`

			`cyfral->key_data = 0;`
			`cyfral->nibble = 0;`
			`cyfral->data_valid = true;`

			`cyfral->max_period = CYFRAL_MAX_PERIOD_US * instructions_per_us;`
			`}`

			`static bool cyfral_process_bit(`
			`ProtocolCyfral* cyfral,`
			`bool polarity,`
			`uint32_t length,`
			`bool* bit_ready,`
			`bool* bit_value) {`
			`bool result = true;`
			`*bit_ready = false;`

			`// bit start from low`
			`switch(cyfral->bit_state) {`
			`case CYFRAL_BIT_WAIT_FRONT_LOW:`
			`if(polarity == true) {`
			`cyfral->period_time += length;`

			`*bit_ready = true;`
			`if(cyfral->period_time <= cyfral->max_period) {`
			`if((cyfral->period_time / 2) > length) {`
			`*bit_value = false;`
			`} else {`
			`*bit_value = true;`
			`}`
			`} else {`
			`result = false;`
			`}`

			`cyfral->bit_state = CYFRAL_BIT_WAIT_FRONT_HIGH;`
			`} else {`
			`result = false;`
			`}`
			`break;`
			`case CYFRAL_BIT_WAIT_FRONT_HIGH:`
			`if(polarity == false) {`
			`cyfral->period_time = length;`
			`cyfral->bit_state = CYFRAL_BIT_WAIT_FRONT_LOW;`
			`} else {`
			`result = false;`
			`}`
			`break;`
			`}`

			`return result;`
			`}`

			`static void cyfral_pulse(void* context, bool polarity, uint32_t length) {`
			`furi_assert(context);`
			`ProtocolCyfral* cyfral = context;`

			`bool bit_ready;`
			`bool bit_value;`

			`if(cyfral->ready) return;`

			`switch(cyfral->state) {`
			`case CYFRAL_WAIT_START_NIBBLE:`
			`// wait for start word`
			`if(cyfral_process_bit(cyfral, polarity, length, &bit_ready, &bit_value)) {`
			`if(bit_ready) {`
			`cyfral->nibble = ((cyfral->nibble << 1) \| bit_value) & 0x0F;`
			`if(cyfral->nibble == 0b0001) {`
			`cyfral->nibble = 0;`
			`cyfral->state = CYFRAL_READ_NIBBLE;`
			`}`
			`}`
			`} else {`
			`cyfral_reset(cyfral);`
			`}`

			`break;`
			`case CYFRAL_READ_NIBBLE:`
			`// read nibbles`
			`if(cyfral_process_bit(cyfral, polarity, length, &bit_ready, &bit_value)) {`
			`if(bit_ready) {`
			`cyfral->nibble = (cyfral->nibble << 1) \| bit_value;`

			`cyfral->bit_index++;`

			`//convert every nibble to 2-bit index`
			`if(cyfral->bit_index == 4) {`
			`switch(cyfral->nibble) {`
			`case 0b1110:`
			`cyfral->key_data = (cyfral->key_data << 2) \| 0b11;`
			`break;`
			`case 0b1101:`
			`cyfral->key_data = (cyfral->key_data << 2) \| 0b10;`
			`break;`
			`case 0b1011:`
			`cyfral->key_data = (cyfral->key_data << 2) \| 0b01;`
			`break;`
			`case 0b0111:`
			`cyfral->key_data = (cyfral->key_data << 2) \| 0b00;`
			`break;`
			`default:`
			`cyfral->data_valid = false;`
			`break;`
			`}`

			`cyfral->nibble = 0;`
			`cyfral->bit_index = 0;`
			`cyfral->index++;`
			`}`

			`// succefully read 8 nibbles`
			`if(cyfral->index == 8) {`
			`cyfral->state = CYFRAL_READ_STOP_NIBBLE;`
			`}`
			`}`
			`} else {`
			`cyfral_reset(cyfral);`
			`}`
			`break;`
			`case CYFRAL_READ_STOP_NIBBLE:`
			`// read stop nibble`
			`if(cyfral_process_bit(cyfral, polarity, length, &bit_ready, &bit_value)) {`
			`if(bit_ready) {`
			`cyfral->nibble = ((cyfral->nibble << 1) \| bit_value) & 0x0F;`
			`cyfral->bit_index++;`

			`switch(cyfral->bit_index) {`
			`case 0:`
			`case 1:`
			`case 2:`
			`case 3:`
			`break;`
			`case 4:`
			`if(cyfral->nibble == 0b0001) {`
			`// validate data`
			`if(cyfral->data_valid) {`
			`cyfral->ready = true;`
			`} else {`
			`cyfral_reset(cyfral);`
			`}`
			`} else {`
			`cyfral_reset(cyfral);`
			`}`
			`break;`
			`default:`
			`cyfral_reset(cyfral);`
			`break;`
			`}`
			`}`
			`} else {`
			`cyfral_reset(cyfral);`
			`}`
			`break;`
			`}`
			`}`