RRG-Proxmark3/armsrc/cmd.c
2024-10-04 23:25:15 +08:00

267 lines
8.9 KiB
C

//-----------------------------------------------------------------------------
// Copyright (C) Proxmark3 contributors. See AUTHORS.md for details.
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// See LICENSE.txt for the text of the license.
//-----------------------------------------------------------------------------
#include "cmd.h"
#include "usb_cdc.h"
#include "usart.h"
#include "crc16.h"
#include "string.h"
#include "BigBuf.h"
// Flags to tell where to add CRC on sent replies
bool g_reply_with_crc_on_usb = false;
bool g_reply_with_crc_on_fpc = true;
// "Session" flag, to tell via which interface next msgs should be sent: USB or FPC USART
bool g_reply_via_fpc = false;
bool g_reply_via_usb = false;
int reply_old(uint64_t cmd, uint64_t arg0, uint64_t arg1, uint64_t arg2, const void *data, size_t len) {
PacketResponseOLD txcmd = {CMD_UNKNOWN, {0, 0, 0}, {{0}}};
for (size_t i = 0; i < sizeof(PacketResponseOLD); i++)
((uint8_t *)&txcmd)[i] = 0x00;
// Compose the outgoing command frame
txcmd.cmd = cmd;
txcmd.arg[0] = arg0;
txcmd.arg[1] = arg1;
txcmd.arg[2] = arg2;
// Add the (optional) content to the frame, with a maximum size of PM3_CMD_DATA_SIZE
if (data && len) {
len = MIN(len, PM3_CMD_DATA_SIZE);
for (size_t i = 0; i < len; i++) {
txcmd.d.asBytes[i] = ((const uint8_t *)data)[i];
}
}
#ifdef WITH_FPC_USART_HOST
int resultfpc = PM3_EUNDEF;
#endif
int resultusb = PM3_EUNDEF;
// Send frame and make sure all bytes are transmitted
if (g_reply_via_usb) {
resultusb = usb_write((uint8_t *)&txcmd, sizeof(PacketResponseOLD));
}
if (g_reply_via_fpc) {
#ifdef WITH_FPC_USART_HOST
resultfpc = usart_writebuffer_sync((uint8_t *)&txcmd, sizeof(PacketResponseOLD));
#else
return PM3_EDEVNOTSUPP;
#endif
}
// we got two results, let's prioritize the faulty one and USB over FPC.
if (g_reply_via_usb && (resultusb != PM3_SUCCESS)) return resultusb;
#ifdef WITH_FPC_USART_HOST
if (g_reply_via_fpc && (resultfpc != PM3_SUCCESS)) return resultfpc;
#endif
return PM3_SUCCESS;
}
static int reply_ng_internal(uint16_t cmd, int8_t status, uint8_t reason, const uint8_t *data, size_t len, bool ng) {
PacketResponseNGRaw txBufferNG;
size_t txBufferNGLen;
// Compose the outgoing command frame
txBufferNG.pre.magic = RESPONSENG_PREAMBLE_MAGIC;
txBufferNG.pre.cmd = cmd;
txBufferNG.pre.status = status;
txBufferNG.pre.reason = reason;
txBufferNG.pre.ng = ng;
if (len > PM3_CMD_DATA_SIZE) {
len = PM3_CMD_DATA_SIZE;
// overwrite status
txBufferNG.pre.status = PM3_EOVFLOW;
}
// length is only 15bit (32768)
txBufferNG.pre.length = (len & 0x7FFF);
// Add the (optional) content to the frame, with a maximum size of PM3_CMD_DATA_SIZE
if (data && len) {
memcpy(txBufferNG.data, data, len);
}
PacketResponseNGPostamble *tx_post = (PacketResponseNGPostamble *)((uint8_t *)&txBufferNG + sizeof(PacketResponseNGPreamble) + len);
// Note: if we send to both FPC & USB, we'll set CRC for both if any of them require CRC
if ((g_reply_via_fpc && g_reply_with_crc_on_fpc) || ((g_reply_via_usb) && g_reply_with_crc_on_usb)) {
uint8_t first, second;
compute_crc(CRC_14443_A, (uint8_t *)&txBufferNG, sizeof(PacketResponseNGPreamble) + len, &first, &second);
tx_post->crc = ((first << 8) | second);
} else {
tx_post->crc = RESPONSENG_POSTAMBLE_MAGIC;
}
txBufferNGLen = sizeof(PacketResponseNGPreamble) + len + sizeof(PacketResponseNGPostamble);
#ifdef WITH_FPC_USART_HOST
int resultfpc = PM3_EUNDEF;
#endif
int resultusb = PM3_EUNDEF;
// Send frame and make sure all bytes are transmitted
if (g_reply_via_usb) {
resultusb = usb_write((uint8_t *)&txBufferNG, txBufferNGLen);
}
if (g_reply_via_fpc) {
#ifdef WITH_FPC_USART_HOST
resultfpc = usart_writebuffer_sync((uint8_t *)&txBufferNG, txBufferNGLen);
#else
return PM3_EDEVNOTSUPP;
#endif
}
// we got two results, let's prioritize the faulty one and USB over FPC.
if (g_reply_via_usb && (resultusb != PM3_SUCCESS)) {
return resultusb;
}
#ifdef WITH_FPC_USART_HOST
if (g_reply_via_fpc && (resultfpc != PM3_SUCCESS)) {
return resultfpc;
}
#endif
return PM3_SUCCESS;
}
int reply_ng(uint16_t cmd, int8_t status, const uint8_t *data, size_t len) {
return reply_ng_internal(cmd, status, PM3_REASON_UNKNOWN, data, len, true);
}
int reply_mix(uint64_t cmd, uint64_t arg0, uint64_t arg1, uint64_t arg2, const void *data, size_t len) {
int8_t status = PM3_SUCCESS;
uint64_t arg[3] = {arg0, arg1, arg2};
if (len > PM3_CMD_DATA_SIZE - sizeof(arg)) {
len = PM3_CMD_DATA_SIZE - sizeof(arg);
status = PM3_EOVFLOW;
}
uint8_t cmddata[PM3_CMD_DATA_SIZE];
memcpy(cmddata, arg, sizeof(arg));
if (len && data) {
memcpy(cmddata + sizeof(arg), data, (int)len);
}
return reply_ng_internal((cmd & 0xFFFF), status, PM3_REASON_UNKNOWN, cmddata, len + sizeof(arg), false);
}
int reply_reason(uint16_t cmd, int8_t status, int8_t reason, const uint8_t *data, size_t len) {
return reply_ng_internal(cmd, status, reason, data, len, true);
}
static int receive_ng_internal(PacketCommandNG *rx, uint32_t read_ng(uint8_t *data, size_t len), bool usb, bool fpc) {
PacketCommandNGRaw rx_raw;
size_t bytes = read_ng((uint8_t *)&rx_raw.pre, sizeof(PacketCommandNGPreamble));
if (bytes == 0) {
return PM3_ENODATA;
}
if (bytes != sizeof(PacketCommandNGPreamble)) {
return PM3_EIO;
}
rx->magic = rx_raw.pre.magic;
rx->ng = rx_raw.pre.ng;
rx->cmd = rx_raw.pre.cmd;
uint16_t length = rx_raw.pre.length;
if (rx->magic == COMMANDNG_PREAMBLE_MAGIC) { // New style NG command
if (length > PM3_CMD_DATA_SIZE) {
return PM3_EOVFLOW;
}
// Get the core and variable length payload
bytes = read_ng((uint8_t *)&rx_raw.data, length);
if (bytes != length) {
return PM3_EIO;
}
if (rx->ng) {
memcpy(rx->data.asBytes, rx_raw.data, length);
rx->length = length;
} else {
uint64_t arg[3] = {0};
if (length < sizeof(arg)) {
return PM3_EIO;
}
memcpy(arg, rx_raw.data, sizeof(arg));
rx->oldarg[0] = arg[0];
rx->oldarg[1] = arg[1];
rx->oldarg[2] = arg[2];
memcpy(rx->data.asBytes, rx_raw.data + sizeof(arg), length - sizeof(arg));
rx->length = length - sizeof(arg);
}
// Get the postamble
bytes = read_ng((uint8_t *)&rx_raw.foopost, sizeof(PacketCommandNGPostamble));
if (bytes != sizeof(PacketCommandNGPostamble)) {
return PM3_EIO;
}
// Check CRC, accept MAGIC as placeholder
rx->crc = rx_raw.foopost.crc;
if (rx->crc != COMMANDNG_POSTAMBLE_MAGIC) {
uint8_t first, second;
compute_crc(CRC_14443_A, (uint8_t *)&rx_raw, sizeof(PacketCommandNGPreamble) + length, &first, &second);
if ((first << 8) + second != rx->crc) {
return PM3_EIO;
}
}
g_reply_via_usb = usb;
g_reply_via_fpc = fpc;
} else { // Old style command
PacketCommandOLD rx_old;
memcpy(&rx_old, &rx_raw.pre, sizeof(PacketCommandNGPreamble));
bytes = read_ng(((uint8_t *)&rx_old) + sizeof(PacketCommandNGPreamble), sizeof(PacketCommandOLD) - sizeof(PacketCommandNGPreamble));
if (bytes != sizeof(PacketCommandOLD) - sizeof(PacketCommandNGPreamble)) {
return PM3_EIO;
}
g_reply_via_usb = usb;
g_reply_via_fpc = fpc;
rx->ng = false;
rx->magic = 0;
rx->crc = 0;
rx->cmd = (rx_old.cmd & 0xFFFF);
rx->oldarg[0] = rx_old.arg[0];
rx->oldarg[1] = rx_old.arg[1];
rx->oldarg[2] = rx_old.arg[2];
rx->length = PM3_CMD_DATA_SIZE;
memcpy(&rx->data, &rx_old.d.asBytes, rx->length);
}
return PM3_SUCCESS;
}
int receive_ng(PacketCommandNG *rx) {
// Check if there is a packet available
if (usb_poll_validate_length()) {
return receive_ng_internal(rx, usb_read_ng, true, false);
}
#ifdef WITH_FPC_USART_HOST
// Check if there is a FPC packet available
if (usart_rxdata_available() > 0)
return receive_ng_internal(rx, usart_read_ng, false, true);
#endif
return PM3_ENODATA;
}