spicetools/reader/reader.cpp

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2024-08-28 15:10:34 +00:00
#include "reader.h"
#include <filesystem>
#include <thread>
#include <cstring>
#include <vector>
#include "util/logging.h"
#include "misc/eamuse.h"
#include "util/utils.h"
#include "structuredmessage.h"
static std::vector<std::thread *> READER_THREADS;
static bool READER_THREAD_RUNNING = false;
Reader::Reader(const std::string &port) : port(port) {
// open port using an NT path to support COM ports past 9
std::filesystem::path serial_path = fmt::format("\\\\.\\{}", this->port);
this->serial_handle = CreateFileW(
serial_path.c_str(),
GENERIC_READ | GENERIC_WRITE,
0,
nullptr,
OPEN_EXISTING,
0,
nullptr);
// check if valid
this->valid = this->serial_handle != INVALID_HANDLE_VALUE;
if (!this->valid) {
auto last_error = get_last_error_string();
log_warning("reader", "{}: failed to open serial connection for reader: {}",
this->port,
last_error);
}
}
Reader::~Reader() {
if (this->serial_handle) {
CloseHandle(this->serial_handle);
log_info("reader", "closed reader on {}", this->port);
}
}
bool Reader::is_valid() {
return this->valid;
}
bool Reader::initialize() {
if (!this->set_comm_state(CBR_57600) || !this->wait_for_handshake())
return false;
log_info("reader", "{}: card reader connected", this->port);
// assign reader ID
std::vector<uint8_t> set_id_data;
set_id_data.push_back(0x00);
if (this->msg_write_read(StructuredMessage(
0,
this->reinitialized,
READER_CMD_SET_ID,
this->gen_msg_id(),
set_id_data)).empty())
return false;
// get version
std::vector<Message> ret = this->msg_write_cmd_read(READER_CMD_VERSION);
if (ret.empty())
return false;
// print version info
std::vector<uint8_t> version_data = ret[ret.size() - 1].get_data();
std::ostringstream model;
model << version_data[13] << version_data[14] << version_data[15] << version_data[16];
log_info("reader", "{}: card reader model: {}", this->port, model.str());
std::ostringstream date;
date << (const char *) &version_data[17];
log_info("reader", "{}: card reader date: {}", this->port, date.str());
std::ostringstream clock;
clock << (const char *) &version_data[33];
log_info("reader", "{}: card reader clock: {}", this->port, clock.str());
// init 2
if (this->msg_write_cmd_read(READER_CMD_INIT2).empty())
return false;
// reinitialize
this->reinitialized = 1;
std::vector<uint8_t> reinitialize_data;
reinitialize_data.push_back(0x00);
if (this->msg_write_cmd_read(READER_CMD_REINITIALIZE, reinitialize_data).empty())
return false;
log_info("reader", "{}: card reader init done", this->port);
return true;
}
bool Reader::init_crypt() {
// generate game key
std::vector<uint8_t> gk;
for (int i = 0; i < 4; i++)
gk.push_back((uint8_t) (rand() % 256));
// reader crypt init
std::vector<Message> ret = this->msg_write_cmd_read(READER_CMD_KEY_EXCHANGE, gk);
if (ret.empty())
return false;
// validate message
Message msg = ret[ret.size() - 1];
std::vector<uint8_t> md = msg.get_data();
if (md.size() != 9)
return false;
// convert keys to int32
uint32_t game_key = gk[0] << 24 | gk[1] << 16 | gk[2] << 8 | gk[3];
uint32_t reader_key = md[5] << 24 | md[6] << 16 | md[7] << 8 | md[8];
log_info("reader", "{}: reader crypt client key: {}", this->port, bin2hex((char *) &gk[0], 4));
log_info("reader", "{}: reader crypt reader key: {}", this->port, bin2hex((char *) &md[5], 4));
// set crypt keys
this->crypt.set_keys(reader_key, game_key);
// crypt done
log_info("reader", "{}: reader crypt init done", this->port);
return true;
}
bool Reader::read_card() {
// read card UID
std::vector<uint8_t> status_ruid_data;
status_ruid_data.push_back(0x00);
status_ruid_data.push_back(0x03);
status_ruid_data.push_back(0xFF);
status_ruid_data.push_back(0xFF);
if (this->msg_write_cmd_read(READER_CMD_RFID_READ_UID, status_ruid_data).empty()) {
this->valid = false;
return false;
}
Sleep(200);
// get reader status
std::vector<uint8_t> status_req_data;
status_req_data.push_back(0x10);
std::vector<Message> ret = this->msg_write_cmd_read(READER_CMD_GET_STATUS_ENC, status_req_data);
if (ret.empty()) {
this->valid = false;
return false;
}
// get data
Message status_msg = ret[ret.size() - 1];
std::vector<uint8_t> status_data = status_msg.get_data();
if (status_data.size() != 23)
return false;
// decrypt data
this->crypt.crypt(&status_data[5], 18);
// check CRC
uint16_t crc_old = status_data[21] << 8 | status_data[22];
uint16_t crc_new = this->crypt.crc(&status_data[5], 16);
if (crc_old != crc_new) {
this->valid = false;
return false;
}
// get keypad state
this->keypad_started = status_data[16];
this->keypad_state = status_data[19] << 8 | status_data[20];
// check for card input
if (status_data[5] == 2) {
memcpy(this->card_uid, &status_data[7], 8);
return true;
}
return false;
}
bool Reader::set_comm_state(DWORD BaudRate) {
// settings
DCB serial_params{};
serial_params.DCBlength = sizeof(serial_params);
if (!GetCommState(this->serial_handle, &serial_params)) {
log_warning("reader", "{}: unable to get COM port state: 0x{:x}", this->port, GetLastError());
return false;
}
serial_params.BaudRate = BaudRate;
serial_params.ByteSize = 8;
serial_params.StopBits = ONESTOPBIT;
serial_params.Parity = NOPARITY;
if (!SetCommState(this->serial_handle, &serial_params)) {
log_warning("reader", "{}: unable to set COM port state: 0x{:x}", this->port, GetLastError());
return false;
}
// timeouts
COMMTIMEOUTS timeouts{};
timeouts.ReadIntervalTimeout = 30;
timeouts.ReadTotalTimeoutConstant = 30;
timeouts.ReadTotalTimeoutMultiplier = 5;
timeouts.WriteTotalTimeoutConstant = 30;
timeouts.WriteTotalTimeoutMultiplier = 5;
if (!SetCommTimeouts(this->serial_handle, &timeouts)) {
log_warning("reader", "{}: unable to set COM port timeouts: 0x{:x}", this->port, GetLastError());
return false;
}
return true;
}
bool Reader::wait_for_handshake() {
// baud rates
DWORD baud_rates[] = { CBR_57600, CBR_38400, CBR_19200, CBR_9600 };
// variables
DWORD bytes_written = 0;
DWORD bytes_read = 0;
uint8_t read_buffer[565];
// generate handshake buffer
uint8_t handshake_buffer[565];
memset(handshake_buffer, 0, 525);
memset(handshake_buffer + 525, 0xAA, 40);
// try all the baud rates
for (size_t i = 0; i < 4; i++) {
this->set_comm_state(baud_rates[i]);
// handshake loop
for (size_t n = 0; n < 10; n++) {
// write handshake
if (!WriteFile(
this->serial_handle,
handshake_buffer,
sizeof(handshake_buffer),
&bytes_written,
nullptr))
{
break;
}
// read handshake
bytes_read = 0;
if (!ReadFile(
this->serial_handle,
read_buffer,
sizeof(read_buffer),
&bytes_read,
nullptr))
{
break;
}
// check handshake
if (bytes_read > 0 && read_buffer[bytes_read - 1] == 0xAA) {
return true;
}
// sleep
Sleep(50);
}
log_warning("reader", "{}: no handshake received for {} baud", this->port, baud_rates[i]);
}
// no handshake on all baud rates
log_warning("reader", "{}: no handshake received for any attempted baud rate", this->port);
return false;
}
bool Reader::msg_write(Message msg) {
// get message data
std::vector<uint8_t> msg_encoded = msg.get_data_encoded();
uint8_t chk_sum = msg.chk_sum();
// create write buffer
uint8_t write_buffer[512];
DWORD write_buffer_len = 0;
// fill write buffer
write_buffer[write_buffer_len++] = 0xAA;
for (const uint8_t c : msg_encoded) {
write_buffer[write_buffer_len++] = c;
}
// write checksum
if (chk_sum == 0xAA || chk_sum == 0xFF) {
write_buffer[write_buffer_len++] = 0xFF;
write_buffer[write_buffer_len++] = ~chk_sum;
} else {
write_buffer[write_buffer_len++] = chk_sum;
}
// write buffer
DWORD bytes_written = 0;
return WriteFile(this->serial_handle,
write_buffer,
write_buffer_len,
&bytes_written,
nullptr) != 0;
}
std::vector<Message> Reader::msg_write_read(Message msg) {
this->msg_write(msg);
return this->msg_read();
}
std::vector<Message> Reader::msg_write_cmd_read(uint8_t cmd) {
return this->msg_write_cmd_read(cmd, std::vector<uint8_t>());
}
std::vector<Message> Reader::msg_write_cmd_read(uint8_t cmd, std::vector<uint8_t> data) {
this->msg_write(StructuredMessage(
this->node,
this->reinitialized,
cmd,
this->gen_msg_id(),
data
));
return this->msg_read();
}
std::vector<Message> Reader::msg_read() {
// create buffer
std::vector<Message> msgs;
uint8_t read_buffer[4096];
DWORD read_buffer_len = 0;
// read to buffer
if (ReadFile(
this->serial_handle,
read_buffer,
sizeof(read_buffer),
&read_buffer_len,
nullptr) && read_buffer_len > 0)
{
std::vector<uint8_t> msg_data;
size_t msg_remaining = 0;
bool escape = false;
for (size_t i = 0; i < read_buffer_len; i++) {
uint8_t b = read_buffer[i];
if (msg_remaining > 0) {
// add msg data length
if (msg_data.size() < 6 && msg_remaining == 1)
msg_remaining += msg_data[4];
if (escape) { // escaped byte
b = ~b;
msg_data.push_back(b);
msg_remaining--;
escape = false;
} else if (b == 0xAA) { // message start
msg_remaining = 6;
msg_data.clear();
} else if (b == 0xFF) { // escape
escape = true;
} else { // normal data
msg_data.push_back(b);
msg_remaining--;
}
} else if (b == 0xAA) { // message start
msg_remaining = 6;
msg_data.clear();
}
if (msg_remaining == 0 && msg_data.size() >= 6) { // message done
std::vector<uint8_t> msg_ext_data;
for (size_t n = 0; n < msg_data[4] && n < msg_data.size() - 6; n++) {
msg_ext_data.push_back(msg_data[5 + n]);
}
StructuredMessage msg(
msg_data[0],
msg_data[1],
msg_data[2],
msg_data[3],
msg_ext_data
);
if (msg.chk_sum() == msg_data[msg_data.size() - 1]) {
msgs.push_back(msg);
}
msg_data.clear();
}
}
}
// return message buffer
return msgs;
}
void start_reader_thread(const std::string &port, int id) {
READER_THREAD_RUNNING = true;
READER_THREADS.push_back(new std::thread([port, id]() {
log_info("reader", "{}: starting reader thread", port);
while (READER_THREAD_RUNNING) {
// create reader
Reader reader(port);
// check if serial handle is still valid
if (!reader.is_valid()) {
log_warning("reader", "{}: serial handle no longer valid", port);
} else if (!reader.initialize()) {
log_warning("reader", "{}: unable to initialize reader", port);
} else if (reader.init_crypt()) {
// reader loop
while (READER_THREAD_RUNNING && reader.is_valid()) {
bool did_read_card = reader.read_card();
if (did_read_card) {
const uint8_t *uid = reader.get_card_uid();
log_info("reader", "{}: reader input: {}", port, bin2hex(uid, 8));
if (id >= 0) {
eamuse_card_insert(id, uid);
} else {
eamuse_card_insert(GetKeyState(VK_NUMLOCK) & 1, uid);
}
}
if (reader.keypad_started > 0) {
if (id >= 0) {
eamuse_set_keypad_overrides_reader(id, reader.keypad_state);
} else {
auto unit = GetKeyState(VK_NUMLOCK) & 1;
eamuse_set_keypad_overrides_reader(unit, reader.keypad_state);
}
}
if (did_read_card) {
Sleep(2500);
}
Sleep(20);
}
}
// sleep between reader connection retries
if (READER_THREAD_RUNNING)
Sleep(5000);
}
}));
// wait for thread to start
Sleep(10);
}
void stop_reader_thread() {
// stop threads
if (READER_THREAD_RUNNING) {
READER_THREAD_RUNNING = false;
}
// kill threads
while (!READER_THREADS.empty()) {
delete READER_THREADS.back();
READER_THREADS.pop_back();
}
}