unleashed-firmware/lib/lfrfid/lfrfid_raw_worker.c

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[FL-2529][FL-1628] New LF-RFID subsystem (#1601) * Makefile: unit tests pack * RFID: pulse joiner and its unit test * Move pulse protocol helpers to appropriate place * Drop pulse_joiner tests * Generic protocol, protocols dictionary, unit test * Protocol dict unit test * iButton: protocols dictionary * Lib: varint * Lib: profiler * Unit test: varint * rfid: worker mockup * LFRFID: em4100 unit test * Storage: file_exist function * rfid: fsk osc * rfid: generic fsk demodulator * rfid: protocol em4100 * rfid: protocol h10301 * rfid: protocol io prox xsf * Unit test: rfid protocols * rfid: new hal * rfid: raw worker * Unit test: fix error output * rfid: worker * rfid: plain c cli * fw: migrate to scons * lfrfid: full io prox support * unit test: io prox protocol * SubGHZ: move bit defines to source * FSK oscillator: level duration compability * libs: bit manipulation library * lfrfid: ioprox protocol, use bit library and new level duration method of FSK ocillator * bit lib: unit tests * Bit lib: parity tests, remove every nth bit, copy bits * Lfrfid: awid protocol * bit lib: uint16 and uint32 getters, unit tests * lfrfid: FDX-B read, draft version * Minunit: better memeq assert * bit lib: reverse, print, print regions * Protocol dict: get protocol features, get protocol validate count * lfrfid worker: improved read * lfrfid raw worker: psk support * Cli: rfid plain C cli * protocol AWID: render * protocol em4100: render * protocol h10301: render * protocol indala26: support every indala 26 scramble * Protocol IO Prox: render * Protocol FDX-B: advanced read * lfrfid: remove unused test function * lfrfid: fix os primitives * bit lib: crc16 and unit tests * FDX-B: save data * lfrfid worker: increase stream size. Alloc raw worker only when needed. * lfrfid: indala26 emulation * lfrfid: prepare to write * lfrfid: fdx-b emulation * lfrfid: awid, ioprox write * lfrfid: write t55xx w\o validation * lfrfid: better t55xx block0 handling * lfrfid: use new t5577 functions in worker * lfrfid: improve protocol description * lfrfid: write and verify * lfrfid: delete cpp cli * lfrfid: improve worker usage * lfrfid-app: step to new worker * lfrfid: old indala (I40134) load fallback * lfrfid: indala26, recover wrong synced data * lfrfid: remove old worker * lfrfid app: dummy read screen * lfrfid app: less dummy read screen * lfrfid: generic 96-bit HID protocol (covers up to HID 37-bit) * rename * lfrfid: improve indala26 read * lfrfid: generic 192-bit HID protocol (covers all HID extended) * lfrfid: TODO about HID render * lfrfid: new protocol FDX-A * lfrfid-app: correct worker stop on exit * misc fixes * lfrfid: FDX-A and HID distinguishability has been fixed. * lfrfid: decode HID size header and render it (#1612) * lfrfid: rename HID96 and HID192 to HIDProx and HIDExt * lfrfid: extra actions scene * lfrfid: decode generic HID Proximity size lazily (#1618) * lib: stream of data buffers concept * lfrfid: raw file helper * lfrfid: changed raw worker api * lfrfid: packed varint pair * lfrfid: read stream speedup * lfrfid app: show read mode * Documentation * lfrfid app: raw read gui * lfrfid app: storage check for raw read * memleak fix * review fixes * lfrfid app: read blink color * lfrfid app: reset key name after read * review fixes * lfrfid app: fix copypasted text * review fixes * lfrfid: disable debug gpio * lfrfid: card detection events * lfrfid: change validation color from magenta to green * Update core_defines. * lfrfid: prefix fdx-b id by zeroes * lfrfid: parse up to 43-bit HID Proximity keys (#1640) * Fbt: downgrade toolchain and fix PS1 * lfrfid: fix unit tests * lfrfid app: remove printf * lfrfid: indala26, use bit 55 as data * lfrfid: indala26, better brief format * lfrfid: indala26, loading fallback * lfrfid: read timing tuning Co-authored-by: James Ide <ide@users.noreply.github.com> Co-authored-by: あく <alleteam@gmail.com>
2022-08-23 15:57:39 +00:00
#include <furi_hal_rfid.h>
#include <toolbox/stream/file_stream.h>
#include <toolbox/buffer_stream.h>
#include <toolbox/varint.h>
#include <stream_buffer.h>
#include "lfrfid_raw_worker.h"
#include "lfrfid_raw_file.h"
#include "tools/varint_pair.h"
#define EMULATE_BUFFER_SIZE 1024
#define RFID_DATA_BUFFER_SIZE 2048
#define READ_DATA_BUFFER_COUNT 4
#define TAG_EMULATE "RAW EMULATE"
// emulate mode
typedef struct {
size_t overrun_count;
StreamBufferHandle_t stream;
} RfidEmulateCtx;
typedef struct {
uint32_t emulate_buffer_arr[EMULATE_BUFFER_SIZE];
uint32_t emulate_buffer_ccr[EMULATE_BUFFER_SIZE];
RfidEmulateCtx ctx;
} LFRFIDRawWorkerEmulateData;
typedef enum {
HalfTransfer,
TransferComplete,
} LFRFIDRawEmulateDMAEvent;
// read mode
#define READ_TEMP_DATA_SIZE 10
typedef struct {
BufferStream* stream;
VarintPair* pair;
} LFRFIDRawWorkerReadData;
// main worker
struct LFRFIDRawWorker {
string_t file_path;
FuriThread* thread;
FuriEventFlag* events;
LFRFIDWorkerEmulateRawCallback emulate_callback;
LFRFIDWorkerReadRawCallback read_callback;
void* context;
float frequency;
float duty_cycle;
};
typedef enum {
LFRFIDRawWorkerEventStop,
} LFRFIDRawWorkerEvent;
static int32_t lfrfid_raw_read_worker_thread(void* thread_context);
static int32_t lfrfid_raw_emulate_worker_thread(void* thread_context);
LFRFIDRawWorker* lfrfid_raw_worker_alloc() {
LFRFIDRawWorker* worker = malloc(sizeof(LFRFIDRawWorker));
worker->thread = furi_thread_alloc();
furi_thread_set_name(worker->thread, "lfrfid_raw_worker");
furi_thread_set_context(worker->thread, worker);
furi_thread_set_stack_size(worker->thread, 2048);
worker->events = furi_event_flag_alloc(NULL);
string_init(worker->file_path);
return worker;
}
void lfrfid_raw_worker_free(LFRFIDRawWorker* worker) {
furi_thread_free(worker->thread);
furi_event_flag_free(worker->events);
string_clear(worker->file_path);
free(worker);
}
void lfrfid_raw_worker_start_read(
LFRFIDRawWorker* worker,
const char* file_path,
float freq,
float duty_cycle,
LFRFIDWorkerReadRawCallback callback,
void* context) {
furi_check(furi_thread_get_state(worker->thread) == FuriThreadStateStopped);
string_set(worker->file_path, file_path);
worker->frequency = freq;
worker->duty_cycle = duty_cycle;
worker->read_callback = callback;
worker->context = context;
furi_thread_set_callback(worker->thread, lfrfid_raw_read_worker_thread);
furi_thread_start(worker->thread);
}
void lfrfid_raw_worker_start_emulate(
LFRFIDRawWorker* worker,
const char* file_path,
LFRFIDWorkerEmulateRawCallback callback,
void* context) {
furi_check(furi_thread_get_state(worker->thread) == FuriThreadStateStopped);
string_set(worker->file_path, file_path);
worker->emulate_callback = callback;
worker->context = context;
furi_thread_set_callback(worker->thread, lfrfid_raw_emulate_worker_thread);
furi_thread_start(worker->thread);
}
void lfrfid_raw_worker_stop(LFRFIDRawWorker* worker) {
worker->emulate_callback = NULL;
worker->context = NULL;
worker->read_callback = NULL;
worker->context = NULL;
furi_event_flag_set(worker->events, 1 << LFRFIDRawWorkerEventStop);
furi_thread_join(worker->thread);
}
static void lfrfid_raw_worker_capture(bool level, uint32_t duration, void* context) {
LFRFIDRawWorkerReadData* ctx = context;
BaseType_t xHigherPriorityTaskWoken = pdFALSE;
bool need_to_send = varint_pair_pack(ctx->pair, level, duration);
if(need_to_send) {
buffer_stream_send_from_isr(
ctx->stream,
varint_pair_get_data(ctx->pair),
varint_pair_get_size(ctx->pair),
&xHigherPriorityTaskWoken);
varint_pair_reset(ctx->pair);
}
portYIELD_FROM_ISR(xHigherPriorityTaskWoken);
}
static int32_t lfrfid_raw_read_worker_thread(void* thread_context) {
LFRFIDRawWorker* worker = (LFRFIDRawWorker*)thread_context;
Storage* storage = furi_record_open(RECORD_STORAGE);
LFRFIDRawFile* file = lfrfid_raw_file_alloc(storage);
const char* filename = string_get_cstr(worker->file_path);
bool file_valid = lfrfid_raw_file_open_write(file, filename);
LFRFIDRawWorkerReadData* data = malloc(sizeof(LFRFIDRawWorkerReadData));
data->stream = buffer_stream_alloc(RFID_DATA_BUFFER_SIZE, READ_DATA_BUFFER_COUNT);
data->pair = varint_pair_alloc();
if(file_valid) {
// write header
file_valid = lfrfid_raw_file_write_header(
file, worker->frequency, worker->duty_cycle, RFID_DATA_BUFFER_SIZE);
}
if(file_valid) {
// setup carrier
furi_hal_rfid_pins_read();
furi_hal_rfid_tim_read(worker->frequency, worker->duty_cycle);
furi_hal_rfid_tim_read_start();
// stabilize detector
furi_delay_ms(1500);
// start capture
furi_hal_rfid_tim_read_capture_start(lfrfid_raw_worker_capture, data);
while(1) {
Buffer* buffer = buffer_stream_receive(data->stream, 100);
if(buffer != NULL) {
file_valid = lfrfid_raw_file_write_buffer(
file, buffer_get_data(buffer), buffer_get_size(buffer));
buffer_reset(buffer);
}
if(!file_valid) {
if(worker->read_callback != NULL) {
// message file_error to worker
worker->read_callback(LFRFIDWorkerReadRawFileError, worker->context);
}
break;
}
if(buffer_stream_get_overrun_count(data->stream) > 0 &&
worker->read_callback != NULL) {
// message overrun to worker
worker->read_callback(LFRFIDWorkerReadRawOverrun, worker->context);
}
uint32_t flags = furi_event_flag_get(worker->events);
if(FURI_BIT(flags, LFRFIDRawWorkerEventStop)) {
break;
}
}
furi_hal_rfid_tim_read_capture_stop();
furi_hal_rfid_tim_read_stop();
} else {
if(worker->read_callback != NULL) {
// message file_error to worker
worker->read_callback(LFRFIDWorkerReadRawFileError, worker->context);
}
}
if(!file_valid) {
const uint32_t available_flags = (1 << LFRFIDRawWorkerEventStop);
while(true) {
uint32_t flags = furi_event_flag_wait(
worker->events, available_flags, FuriFlagWaitAny, FuriWaitForever);
if(FURI_BIT(flags, LFRFIDRawWorkerEventStop)) {
break;
}
}
}
varint_pair_free(data->pair);
buffer_stream_free(data->stream);
lfrfid_raw_file_free(file);
furi_record_close(RECORD_STORAGE);
free(data);
return 0;
}
static void rfid_emulate_dma_isr(bool half, void* context) {
RfidEmulateCtx* ctx = context;
uint32_t flag = half ? HalfTransfer : TransferComplete;
size_t len = xStreamBufferSendFromISR(ctx->stream, &flag, sizeof(uint32_t), pdFALSE);
if(len != sizeof(uint32_t)) {
ctx->overrun_count++;
}
}
static int32_t lfrfid_raw_emulate_worker_thread(void* thread_context) {
LFRFIDRawWorker* worker = thread_context;
bool file_valid = true;
LFRFIDRawWorkerEmulateData* data = malloc(sizeof(LFRFIDRawWorkerEmulateData));
Storage* storage = furi_record_open(RECORD_STORAGE);
data->ctx.overrun_count = 0;
data->ctx.stream = xStreamBufferCreate(sizeof(uint32_t), sizeof(uint32_t));
LFRFIDRawFile* file = lfrfid_raw_file_alloc(storage);
do {
file_valid = lfrfid_raw_file_open_read(file, string_get_cstr(worker->file_path));
if(!file_valid) break;
file_valid = lfrfid_raw_file_read_header(file, &worker->frequency, &worker->duty_cycle);
if(!file_valid) break;
for(size_t i = 0; i < EMULATE_BUFFER_SIZE; i++) {
file_valid = lfrfid_raw_file_read_pair(
file, &data->emulate_buffer_arr[i], &data->emulate_buffer_ccr[i], NULL);
if(!file_valid) break;
data->emulate_buffer_arr[i] /= 8;
data->emulate_buffer_arr[i] -= 1;
data->emulate_buffer_ccr[i] /= 8;
}
} while(false);
furi_hal_rfid_tim_emulate_dma_start(
data->emulate_buffer_arr,
data->emulate_buffer_ccr,
EMULATE_BUFFER_SIZE,
rfid_emulate_dma_isr,
&data->ctx);
if(!file_valid && worker->emulate_callback != NULL) {
// message file_error to worker
worker->emulate_callback(LFRFIDWorkerEmulateRawFileError, worker->context);
}
if(file_valid) {
uint32_t flag = 0;
while(true) {
size_t size = xStreamBufferReceive(data->ctx.stream, &flag, sizeof(uint32_t), 100);
if(size == sizeof(uint32_t)) {
size_t start = 0;
if(flag == TransferComplete) {
start = (EMULATE_BUFFER_SIZE / 2);
}
for(size_t i = 0; i < (EMULATE_BUFFER_SIZE / 2); i++) {
file_valid = lfrfid_raw_file_read_pair(
file,
&data->emulate_buffer_arr[start + i],
&data->emulate_buffer_ccr[start + i],
NULL);
if(!file_valid) break;
data->emulate_buffer_arr[i] /= 8;
data->emulate_buffer_arr[i] -= 1;
data->emulate_buffer_ccr[i] /= 8;
}
} else if(size != 0) {
data->ctx.overrun_count++;
}
if(!file_valid) {
if(worker->emulate_callback != NULL) {
// message file_error to worker
worker->emulate_callback(LFRFIDWorkerEmulateRawFileError, worker->context);
}
break;
}
if(data->ctx.overrun_count > 0 && worker->emulate_callback != NULL) {
// message overrun to worker
worker->emulate_callback(LFRFIDWorkerEmulateRawOverrun, worker->context);
}
uint32_t flags = furi_event_flag_get(worker->events);
if(FURI_BIT(flags, LFRFIDRawWorkerEventStop)) {
break;
};
}
}
furi_hal_rfid_tim_emulate_dma_stop();
if(!file_valid) {
const uint32_t available_flags = (1 << LFRFIDRawWorkerEventStop);
while(true) {
uint32_t flags = furi_event_flag_wait(
worker->events, available_flags, FuriFlagWaitAny, FuriWaitForever);
if(FURI_BIT(flags, LFRFIDRawWorkerEventStop)) {
break;
};
}
}
if(data->ctx.overrun_count) {
FURI_LOG_E(TAG_EMULATE, "overruns: %lu", data->ctx.overrun_count);
}
vStreamBufferDelete(data->ctx.stream);
lfrfid_raw_file_free(file);
furi_record_close(RECORD_STORAGE);
free(data);
return 0;
}