proxmark3/armsrc/iso14443b.c
2021-08-21 23:45:46 +02:00

2261 lines
72 KiB
C

//-----------------------------------------------------------------------------
// Jonathan Westhues, split Nov 2006
// piwi 2018
//
// This code is licensed to you under the terms of the GNU GPL, version 2 or,
// at your option, any later version. See the LICENSE.txt file for the text of
// the license.
//-----------------------------------------------------------------------------
// Routines to support ISO 14443B. This includes both the reader software and
// the `fake tag' modes.
//-----------------------------------------------------------------------------
#include "iso14443b.h"
#include "proxmark3_arm.h"
#include "common.h" // access to global variable: g_dbglevel
#include "util.h"
#include "string.h"
#include "crc16.h"
#include "protocols.h"
#include "appmain.h"
#include "BigBuf.h"
#include "cmd.h"
#include "fpgaloader.h"
#include "commonutil.h"
#include "dbprint.h"
#include "ticks.h"
#include "iso14b.h" // defines for ETU conversions
/*
* Current timing issues with ISO14443-b implementation
* Proxmark3
* Carrier Frequency 13.56MHz
* SSP_CLK runs at 13.56MHz / 4 = 3,39MHz
*
*
* PROBLEM 1.
* ----------
* one way of calculating time, that relates both to PM3 ssp_clk 3.39MHz, ISO freq of 13.56Mhz and ETUs
* convert from µS -> our SSP_CLK units which is used in the DEFINES..
* convert from ms -> our SSP_CLK units...
* convert from ETU -> our SSP_CLK units...
* All ETU -> µS -> ms should be diveded by for to match Proxmark3 FPGA SSP_CLK :)
*
*
* PROBLEM 2.
* ----------
* all DEFINES is in SSP_CLK ticks
* all delays is in SSP_CLK ticks
*/
#ifndef RECEIVE_MASK
# define RECEIVE_MASK (DMA_BUFFER_SIZE - 1)
#endif
// SSP_CLK runs at 13,56MHz / 32 = 423.75kHz when simulating a tag
// All values should be multiples of 2 (?)
#define DELAY_READER_TO_ARM 8
#define DELAY_ARM_TO_READER 0
// SSP_CLK runs at 13.56MHz / 4 = 3,39MHz when acting as reader.
// All values should be multiples of 16
#define DELAY_ARM_TO_TAG 16
#define DELAY_TAG_TO_ARM 32
// SSP_CLK runs at 13.56MHz / 4 = 3,39MHz when sniffing.
// All values should be multiples of 16
#define DELAY_TAG_TO_ARM_SNIFF 32
#define DELAY_READER_TO_ARM_SNIFF 32
/* ISO14443-4
*
* Frame Waiting Time Integer (FWI)
* can be between 0 and 14.
* FWI_default = 4
* FWI_max = 14
*
* Frame Waiting Time (FWT) formula
* --------------------------------
* FWT = (256 x 16 / fc) * 2 to the power for FWI
*
* sample:
* ------- 2 to the power of FWI(4)
* FWT = (256 x 16 / fc) * (2*2*2*2) == 4.833 ms
* FTW(default) == FWT(4) == 4.822ms
*
* FWI_max == 2^14 = 16384
* FWT(max) = (256 x 16 / fc) * 16384 == 4949
*
* Which gives a maximum Frame Waiting time of FWT(max) == 4949 ms
* FWT(max) in ETU 4949000 / 9.4395 µS = 524286 ETU
*
* Simple calc to convert to ETU or µS
* -----------------------------------
* uint32_t fwt_time_etu = (32 << fwt);
* uint32_t fwt_time_us = (302 << fwt);
*
*/
#ifndef MAX_14B_TIMEOUT
// FWT(max) = 4949 ms or 4.95 seconds.
// SSP_CLK = 4949000 * 3.39 = 16777120
# define MAX_14B_TIMEOUT (16777120U)
#endif
// Activation frame waiting time
// 512 ETU?
// 65536/fc == 4833 µS or 4.833ms
// SSP_CLK = 4833 µS * 3.39 = 16384
#ifndef FWT_TIMEOUT_14B
# define FWT_TIMEOUT_14B (16384)
#endif
// ETU 14 * 9.4395 µS = 132 µS == 0.132ms
// TR2, counting from start of PICC EOF 14 ETU.
#define DELAY_ISO14443B_PICC_TO_PCD_READER ETU_TO_SSP(14)
#define DELAY_ISO14443B_PCD_TO_PICC_READER ETU_TO_SSP(15)
/* Guard Time (per 14443-2) in ETU
*
* Transition time. TR0 - guard time
* TR0 - 8 ETU's minimum.
* TR0 - 32 ETU's maximum for ATQB only
* TR0 - FWT for all other commands
* 32,64,128,256,512, ... , 262144, 524288 ETU
* TR0 = FWT(1), FWT(2), FWT(3) .. FWT(14)
*
*
* TR0
*/
#ifndef ISO14B_TR0
# define ISO14B_TR0 ETU_TO_SSP(32)
#endif
#ifndef ISO14B_TR0_MAX
# define ISO14B_TR0_MAX ETU_TO_SSP(32)
// * TR0 - 32 ETU's maximum for ATQB only
// * TR0 - FWT for all other commands
// TR0 max is 151/fsc = 151/848kHz = 302us or 64 samples from FPGA
// 32 ETU * 9.4395 µS == 302 µS
// 32 * 8 = 256 sub carrier cycles,
// 256 / 4 = 64 I/Q pairs.
// since 1 I/Q pair after 4 subcarrier cycles at 848kHz subcarrier
#endif
// 8 ETU = 75 µS == 256 SSP_CLK
#ifndef ISO14B_TR0_MIN
# define ISO14B_TR0_MIN ETU_TO_SSP(8)
#endif
// Synchronization time (per 14443-2) in ETU
// 10 ETU = 94,39 µS == 320 SSP_CLK
#ifndef ISO14B_TR1_MIN
# define ISO14B_TR1_MIN ETU_TO_SSP(10)
#endif
// Synchronization time (per 14443-2) in ETU
// 25 ETU == 236 µS == 800 SSP_CLK
#ifndef ISO14B_TR1_MAX
# define ISO14B_TR1 ETU_TO_SSP(25)
#endif
// Frame Delay Time PICC to PCD (per 14443-3 Amendment 1) in ETU
// 14 ETU == 132 µS == 448 SSP_CLK
#ifndef ISO14B_TR2
# define ISO14B_TR2 ETU_TO_SSP(14)
#endif
// 4sample
#define SEND4STUFFBIT(x) tosend_stuffbit(x);tosend_stuffbit(x);tosend_stuffbit(x);tosend_stuffbit(x);
static void iso14b_set_timeout(uint32_t timeout_etu);
static void iso14b_set_maxframesize(uint16_t size);
static void iso14b_set_fwt(uint8_t fwt);
// the block number for the ISO14443-4 PCB (used with APDUs)
static uint8_t iso14b_pcb_blocknum = 0;
static uint8_t iso14b_fwt = 9;
static uint32_t iso14b_timeout = FWT_TIMEOUT_14B;
/*
* ISO 14443-B communications
* --------------------------
* Reader to card | ASK - Amplitude Shift Keying Modulation (PCD to PICC for Type B) (NRZ-L encodig)
* Card to reader | BPSK - Binary Phase Shift Keying Modulation, (PICC to PCD for Type B)
*
* It uses half duplex with a 106 kbit per second data rate in each direction.
* Data transmitted by the card is load modulated with a 847.5 kHz subcarrier.
*
* fc - carrier frequency 13.56 MHz
* TR0 - Guard Time per 14443-2
* TR1 - Synchronization Time per 14443-2
* TR2 - PICC to PCD Frame Delay Time (per 14443-3 Amendment 1)
*
* Elementary Time Unit (ETU)
* --------------------------
* ETU is used to denotate 1 bit period i.e. how long one bit transfer takes.
*
* - 128 Carrier cycles / 13.56MHz = 8 Subcarrier units / 848kHz = 1/106kHz = 9.4395 µS
* - 16 Carrier cycles = 1 Subcarrier unit = 1.17 µS
*
* Definition
* ----------
* 1 ETU = 128 / ( D x fc )
* where
* D = divisor. Which inital is 1
* fc = carrier frequency
* gives
* 1 ETU = 128 / fc
* 1 ETU = 128 / 13 560 000 = 9.4395 µS
* 1 ETU = 9.4395 µS
*
* (note: It seems we are using the subcarrier as base for our time calculations rather than the field clock)
*
* - 1 ETU = 1/106 KHz
* - 1 ETU = 8 subcarrier units ( 8 / 848kHz )
* - 1 ETU = 1 bit period
*
*
* Card sends data at 848kHz subcarrier
* subcar |duration| FC division| I/Q pairs
* -------+--------+------------+--------
* 106kHz | 9.44µS | FC/128 | 16
* 212kHz | 4.72µS | FC/64 | 8
* 424kHz | 2.36µS | FC/32 | 4
* 848kHz | 1.18µS | FC/16 | 2
* -------+--------+------------+--------
*
*
* One Character consists of 1 start, 1 stop, 8 databit with a total length of 10bits.
* - 1 Character = 10 ETU = 1 startbit, 8 databits, 1 stopbit
* - startbit is a 0
* - stopbit is a 1
*
* Start of frame (SOF) is
* - [10-11] ETU of ZEROS, unmodulated time
* - [2-3] ETU of ONES,
*
* End of frame (EOF) is
* - [10-11] ETU of ZEROS, unmodulated time
*
* Reader data transmission
* ------------------------
* - no modulation ONES
* - SOF
* - Command, data and CRC_B (1 Character)
* - EOF
* - no modulation ONES
*
* Card data transmission
* ----------------------
* - TR1
* - SOF
* - data (1 Character)
* - CRC_B
* - EOF
*
* Transfer times
* --------------
* let calc how long it takes the reader to send a message
* SOF 10 ETU + 4 data bytes + 2 crc bytes + EOF 2 ETU
* 10 + (4+2 * 10) + 2 = 72 ETU
* 72 * 9.4395 = 680 µS or 0.68 ms
*
*
* -> TO VERIFY THIS BELOW <-
* --------------------------
* The mode FPGA_MAJOR_MODE_HF_SIMULATOR | FPGA_HF_SIMULATOR_MODULATE_BPSK which we use to simulate tag
* works like this:
* Simulation per definition is "inversed" effect on the reader antenna.
* - A 1-bit input to the FPGA becomes 8 pulses at 847.5kHz (1.18µS / pulse) == 9.44us
* - A 0-bit input to the FPGA becomes an unmodulated time of 1.18µS or does it become 8 nonpulses for 9.44us
*
*
* FPGA implementation
* -------------------
* Piwi implemented a I/Q sampling mode for the FPGA, where...
*
* FPGA doesn't seem to work with ETU. It seems to work with pulse / duration instead.
*
* This means that we are using a bit rate of 106 kbit/s, or fc/128.
* Oversample by 4, which ought to make things practical for the ARM
* (fc/32, 423.8 kbits/s, ~52 kbytes/s)
*
* We are sampling the signal at FC/32, we are reporting over SSP to PM3 each
*
* Current I/Q pair sampling
* -------------------------
* Let us report a correlation every 64 samples. I.e.
* 1 I/Q pair after 4 subcarrier cycles for the 848kHz subcarrier,
* 1 I/Q pair after 2 subcarrier cycles for the 424kHz subcarrier,
*/
/*
* Formula to calculate FWT (in ETUs) by timeout (in ms):
*
* 1 tick is about 1.5µS
* 1000 ms/s
*
* FWT = 13560000 * 1000 / (8*16) * timeout
* FWT = 13560000 * 1000 / 128 * timeout
*
* sample: 3sec == 3000ms
*
* 13560000 * 1000 / 128 * 3000 == 13560000000 / 384000 ==
* 13560000 / 384 = 35312 FWT
*
* 35312 * 9.4395 ==
*
* @param timeout is in frame wait time, fwt, measured in ETUs
*
* However we need to compensate for SSP_CLK ...
*/
//=============================================================================
// An ISO 14443 Type B tag. We listen for commands from the reader, using
// a UART kind of thing that's implemented in software. When we get a
// frame (i.e., a group of bytes between SOF and EOF), we check the CRC.
// If it's good, then we can do something appropriate with it, and send
// a response.
//=============================================================================
//-----------------------------------------------------------------------------
// Code up a string of octets at layer 2 (including CRC, we don't generate
// that here) so that they can be transmitted to the reader. Doesn't transmit
// them yet, just leaves them ready to send in ToSend[].
//-----------------------------------------------------------------------------
static void CodeIso14443bAsTag(const uint8_t *cmd, int len) {
int i;
tosend_reset();
// Transmit a burst of ones, as the initial thing that lets the
// reader get phase sync.
// This loop is TR1, per specification
// TR1 minimum must be > 80/fs
// TR1 maximum 200/fs
// 80/fs < TR1 < 200/fs
// 10 ETU < TR1 < 24 ETU
// Send TR1.
// 10-11 ETU * 4times samples ONES
for (i = 0; i < 10; i++) {
SEND4STUFFBIT(1);
}
// Send SOF.
// 10-11 ETU * 4times samples ZEROS
for (i = 0; i < 10; i++) {
SEND4STUFFBIT(0);
}
// 2-3 ETU * 4times samples ONES
for (i = 0; i < 2; i++) {
SEND4STUFFBIT(1);
}
// data
for (i = 0; i < len; i++) {
// Start bit
SEND4STUFFBIT(0);
// Data bits
uint8_t b = cmd[i];
for (int j = 0; j < 8; j++) {
SEND4STUFFBIT(b & 1);
b >>= 1;
}
// Stop bit
SEND4STUFFBIT(1);
// Extra Guard bit
// For PICC it ranges 0-18us (1etu = 9us)
//SEND4STUFFBIT(1);
}
// Send EOF.
// 10-11 ETU * 4 sample rate = ZEROS
for (i = 0; i < 10; i++) {
SEND4STUFFBIT(0);
}
// why this? push out transfers between arm and fpga?
//for (i = 0; i < 2; i++) {
// SEND4STUFFBIT(1);
//}
tosend_t *ts = get_tosend();
// Convert from last byte pos to length
ts->max++;
}
//-----------------------------------------------------------------------------
// The software UART that receives commands from the reader, and its state
// variables.
//-----------------------------------------------------------------------------
static struct {
enum {
STATE_14B_UNSYNCD,
STATE_14B_GOT_FALLING_EDGE_OF_SOF,
STATE_14B_AWAITING_START_BIT,
STATE_14B_RECEIVING_DATA
} state;
uint16_t shiftReg;
int bitCnt;
int byteCnt;
int byteCntMax;
int posCnt;
uint8_t *output;
} Uart;
static void Uart14bReset(void) {
Uart.state = STATE_14B_UNSYNCD;
Uart.shiftReg = 0;
Uart.bitCnt = 0;
Uart.byteCnt = 0;
Uart.byteCntMax = MAX_FRAME_SIZE;
Uart.posCnt = 0;
}
static void Uart14bInit(uint8_t *data) {
Uart.output = data;
Uart14bReset();
}
// param timeout accepts ETU
static void iso14b_set_timeout(uint32_t timeout_etu) {
uint32_t ssp = ETU_TO_SSP(timeout_etu);
if (ssp > MAX_14B_TIMEOUT)
ssp = MAX_14B_TIMEOUT;
iso14b_timeout = ssp;
if (g_dbglevel >= DBG_DEBUG) {
Dbprintf("ISO14443B Timeout set to %ld fwt", iso14b_timeout);
}
}
// keep track of FWT, also updates the timeout
static void iso14b_set_fwt(uint8_t fwt) {
iso14b_fwt = fwt;
iso14b_set_timeout(32 << fwt);
}
static void iso14b_set_maxframesize(uint16_t size) {
if (size > 256)
size = MAX_FRAME_SIZE;
Uart.byteCntMax = size;
if (g_dbglevel >= DBG_DEBUG) Dbprintf("ISO14443B Max frame size set to %d bytes", Uart.byteCntMax);
}
//-----------------------------------------------------------------------------
// The software Demod that receives commands from the tag, and its state variables.
//-----------------------------------------------------------------------------
#define NOISE_THRESHOLD 80 // don't try to correlate noise
#define MAX_PREVIOUS_AMPLITUDE (-1 - NOISE_THRESHOLD)
static struct {
enum {
DEMOD_UNSYNCD,
DEMOD_PHASE_REF_TRAINING,
WAIT_FOR_RISING_EDGE_OF_SOF,
DEMOD_AWAITING_START_BIT,
DEMOD_RECEIVING_DATA
} state;
uint16_t bitCount;
int posCount;
int thisBit;
uint16_t shiftReg;
uint16_t max_len;
uint8_t *output;
uint16_t len;
int sumI;
int sumQ;
} Demod;
// Clear out the state of the "UART" that receives from the tag.
static void Demod14bReset(void) {
Demod.state = DEMOD_UNSYNCD;
Demod.bitCount = 0;
Demod.posCount = 0;
Demod.thisBit = 0;
Demod.shiftReg = 0;
Demod.len = 0;
Demod.sumI = 0;
Demod.sumQ = 0;
}
static void Demod14bInit(uint8_t *data, uint16_t max_len) {
Demod.output = data;
Demod.max_len = max_len;
Demod14bReset();
}
/* Receive & handle a bit coming from the reader.
*
* This function is called 4 times per bit (every 2 subcarrier cycles).
* Subcarrier frequency fs is 848kHz, 1/fs = 1,18us, i.e. function is called every 2,36us
*
* LED handling:
* LED A -> ON once we have received the SOF and are expecting the rest.
* LED A -> OFF once we have received EOF or are in error state or unsynced
*
* Returns: true if we received a EOF
* false if we are still waiting for some more
*/
static RAMFUNC int Handle14443bSampleFromReader(uint8_t bit) {
switch (Uart.state) {
case STATE_14B_UNSYNCD:
if (bit == false) {
// we went low, so this could be the beginning of an SOF
Uart.state = STATE_14B_GOT_FALLING_EDGE_OF_SOF;
Uart.posCnt = 0;
Uart.bitCnt = 0;
}
break;
case STATE_14B_GOT_FALLING_EDGE_OF_SOF:
Uart.posCnt++;
if (Uart.posCnt == 2) { // sample every 4 1/fs in the middle of a bit
if (bit) {
if (Uart.bitCnt > 9) {
// we've seen enough consecutive
// zeros that it's a valid SOF
Uart.posCnt = 0;
Uart.byteCnt = 0;
Uart.state = STATE_14B_AWAITING_START_BIT;
LED_A_ON(); // Indicate we got a valid SOF
} else {
// didn't stay down long enough before going high, error
Uart.state = STATE_14B_UNSYNCD;
}
} else {
// do nothing, keep waiting
}
Uart.bitCnt++;
}
if (Uart.posCnt >= 4) {
Uart.posCnt = 0;
}
if (Uart.bitCnt > 12) {
// Give up if we see too many zeros without a one, too.
LED_A_OFF();
Uart.state = STATE_14B_UNSYNCD;
}
break;
case STATE_14B_AWAITING_START_BIT:
Uart.posCnt++;
if (bit) {
// max 57us between characters = 49 1/fs,
// max 3 etus after low phase of SOF = 24 1/fs
if (Uart.posCnt > 50 / 2) {
// stayed high for too long between characters, error
Uart.state = STATE_14B_UNSYNCD;
}
} else {
// falling edge, this starts the data byte
Uart.posCnt = 0;
Uart.bitCnt = 0;
Uart.shiftReg = 0;
Uart.state = STATE_14B_RECEIVING_DATA;
}
break;
case STATE_14B_RECEIVING_DATA:
Uart.posCnt++;
if (Uart.posCnt == 2) {
// time to sample a bit
Uart.shiftReg >>= 1;
if (bit) {
Uart.shiftReg |= 0x200;
}
Uart.bitCnt++;
}
if (Uart.posCnt >= 4) {
Uart.posCnt = 0;
}
if (Uart.bitCnt == 10) {
if ((Uart.shiftReg & 0x200) && !(Uart.shiftReg & 0x001)) {
// this is a data byte, with correct
// start and stop bits
Uart.output[Uart.byteCnt] = (Uart.shiftReg >> 1) & 0xFF;
Uart.byteCnt++;
if (Uart.byteCnt >= Uart.byteCntMax) {
// Buffer overflowed, give up
LED_A_OFF();
Uart.state = STATE_14B_UNSYNCD;
} else {
// so get the next byte now
Uart.posCnt = 0;
Uart.state = STATE_14B_AWAITING_START_BIT;
}
} else if (Uart.shiftReg == 0x000) {
// this is an EOF byte
LED_A_OFF(); // Finished receiving
Uart.state = STATE_14B_UNSYNCD;
if (Uart.byteCnt != 0)
return true;
} else {
// this is an error
LED_A_OFF();
Uart.state = STATE_14B_UNSYNCD;
}
}
break;
default:
LED_A_OFF();
Uart.state = STATE_14B_UNSYNCD;
break;
}
return false;
}
//-----------------------------------------------------------------------------
// Receive a command (from the reader to us, where we are the simulated tag),
// and store it in the given buffer, up to the given maximum length. Keeps
// spinning, waiting for a well-framed command, until either we get one
// (returns true) or someone presses the pushbutton on the board (false).
//
// Assume that we're called with the SSC (to the FPGA) and ADC path set
// correctly.
//-----------------------------------------------------------------------------
static int GetIso14443bCommandFromReader(uint8_t *received, uint16_t *len) {
// Set FPGA mode to "simulated ISO 14443B tag", no modulation (listen
// only, since we are receiving, not transmitting).
// Signal field is off with the appropriate LED
LED_D_OFF();
FpgaWriteConfWord(FPGA_MAJOR_MODE_HF_SIMULATOR | FPGA_HF_SIMULATOR_NO_MODULATION);
// Now run a `software UART' on the stream of incoming samples.
Uart14bInit(received);
while (BUTTON_PRESS() == false) {
WDT_HIT();
if (AT91C_BASE_SSC->SSC_SR & (AT91C_SSC_RXRDY)) {
uint8_t b = (uint8_t)AT91C_BASE_SSC->SSC_RHR;
for (uint8_t mask = 0x80; mask != 0x00; mask >>= 1) {
if (Handle14443bSampleFromReader(b & mask)) {
*len = Uart.byteCnt;
return true;
}
}
}
}
return false;
}
static void TransmitFor14443b_AsTag(uint8_t *response, uint16_t len) {
// Signal field is off with the appropriate LED
LED_D_OFF();
// Modulate BPSK
FpgaWriteConfWord(FPGA_MAJOR_MODE_HF_SIMULATOR | FPGA_HF_SIMULATOR_MODULATE_BPSK);
AT91C_BASE_SSC->SSC_THR = 0xFF;
FpgaSetupSsc(FPGA_MAJOR_MODE_HF_SIMULATOR);
// Transmit the response.
for (uint16_t i = 0; i < len;) {
// Put byte into tx holding register as soon as it is ready
if (AT91C_BASE_SSC->SSC_SR & AT91C_SSC_TXRDY) {
AT91C_BASE_SSC->SSC_THR = response[i++];
}
}
}
//-----------------------------------------------------------------------------
// Main loop of simulated tag: receive commands from reader, decide what
// response to send, and send it.
//-----------------------------------------------------------------------------
void SimulateIso14443bTag(uint8_t *pupi) {
LED_A_ON();
// the only commands we understand is WUPB, AFI=0, Select All, N=1:
// static const uint8_t cmdWUPB[] = { ISO14443B_REQB, 0x00, 0x08, 0x39, 0x73 }; // WUPB
// ... and REQB, AFI=0, Normal Request, N=1:
// static const uint8_t cmdREQB[] = { ISO14443B_REQB, 0x00, 0x00, 0x71, 0xFF }; // REQB
// ... and HLTB
// static const uint8_t cmdHLTB[] = { 0x50, 0xff, 0xff, 0xff, 0xff }; // HLTB
// ... and ATTRIB
// static const uint8_t cmdATTRIB[] = { ISO14443B_ATTRIB, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff}; // ATTRIB
// ... if not PUPI/UID is supplied we always respond with ATQB, PUPI = 820de174, Application Data = 0x20381922,
// supports only 106kBit/s in both directions, max frame size = 32Bytes,
// supports ISO14443-4, FWI=8 (77ms), NAD supported, CID not supported:
uint8_t respATQB[] = {
0x50,
0x82, 0x0d, 0xe1, 0x74,
0x20, 0x38, 0x19,
0x22, 0x00, 0x21, 0x85,
0x5e, 0xd7
};
// ...PUPI/UID supplied from user. Adjust ATQB response accordingly
if (memcmp("\x00\x00\x00\x00", pupi, 4) != 0) {
memcpy(respATQB + 1, pupi, 4);
AddCrc14B(respATQB, 12);
}
// response to HLTB and ATTRIB
static const uint8_t respOK[] = {0x00, 0x78, 0xF0};
// setup device.
FpgaDownloadAndGo(FPGA_BITSTREAM_HF);
// connect Demodulated Signal to ADC:
SetAdcMuxFor(GPIO_MUXSEL_HIPKD);
// Set up the synchronous serial port
FpgaSetupSsc(FPGA_MAJOR_MODE_HF_SIMULATOR);
// allocate command receive buffer
BigBuf_free();
BigBuf_Clear_ext(false);
clear_trace();
set_tracing(true);
uint16_t len, cmdsReceived = 0;
int cardSTATE = SIM_NOFIELD;
int vHf = 0; // in mV
tosend_t *ts = get_tosend();
uint8_t *receivedCmd = BigBuf_malloc(MAX_FRAME_SIZE);
// prepare "ATQB" tag answer (encoded):
CodeIso14443bAsTag(respATQB, sizeof(respATQB));
uint8_t *encodedATQB = BigBuf_malloc(ts->max);
uint16_t encodedATQBLen = ts->max;
memcpy(encodedATQB, ts->buf, ts->max);
// prepare "OK" tag answer (encoded):
CodeIso14443bAsTag(respOK, sizeof(respOK));
uint8_t *encodedOK = BigBuf_malloc(ts->max);
uint16_t encodedOKLen = ts->max;
memcpy(encodedOK, ts->buf, ts->max);
// Simulation loop
while (BUTTON_PRESS() == false) {
WDT_HIT();
//iceman: limit with 2000 times..
if (data_available()) {
break;
}
// find reader field
if (cardSTATE == SIM_NOFIELD) {
vHf = (MAX_ADC_HF_VOLTAGE * SumAdc(ADC_CHAN_HF, 32)) >> 15;
if (vHf > MF_MINFIELDV) {
cardSTATE = SIM_IDLE;
LED_A_ON();
}
}
if (cardSTATE == SIM_NOFIELD) continue;
// Get reader command
if (!GetIso14443bCommandFromReader(receivedCmd, &len)) {
Dbprintf("button pressed, received %d commands", cmdsReceived);
break;
}
// ISO14443-B protocol states:
// REQ or WUP request in ANY state
// WUP in HALTED state
if (len == 5) {
if ((receivedCmd[0] == ISO14443B_REQB && (receivedCmd[2] & 0x8) == 0x8 && cardSTATE == SIM_HALTED) ||
receivedCmd[0] == ISO14443B_REQB) {
LogTrace(receivedCmd, len, 0, 0, NULL, true);
cardSTATE = SIM_SELECTING;
}
}
/*
* How should this flow go?
* REQB or WUPB
* send response ( waiting for Attrib)
* ATTRIB
* send response ( waiting for commands 7816)
* HALT
send halt response ( waiting for wupb )
*/
switch (cardSTATE) {
//case SIM_NOFIELD:
case SIM_HALTED:
case SIM_IDLE: {
LogTrace(receivedCmd, len, 0, 0, NULL, true);
break;
}
case SIM_SELECTING: {
TransmitFor14443b_AsTag(encodedATQB, encodedATQBLen);
LogTrace(respATQB, sizeof(respATQB), 0, 0, NULL, false);
cardSTATE = SIM_WORK;
break;
}
case SIM_HALTING: {
TransmitFor14443b_AsTag(encodedOK, encodedOKLen);
LogTrace(respOK, sizeof(respOK), 0, 0, NULL, false);
cardSTATE = SIM_HALTED;
break;
}
case SIM_ACKNOWLEDGE: {
TransmitFor14443b_AsTag(encodedOK, encodedOKLen);
LogTrace(respOK, sizeof(respOK), 0, 0, NULL, false);
cardSTATE = SIM_IDLE;
break;
}
case SIM_WORK: {
if (len == 7 && receivedCmd[0] == ISO14443B_HALT) {
cardSTATE = SIM_HALTED;
} else if (len == 11 && receivedCmd[0] == ISO14443B_ATTRIB) {
cardSTATE = SIM_ACKNOWLEDGE;
} else {
// Todo:
// - SLOT MARKER
// - ISO7816
// - emulate with a memory dump
if (g_dbglevel >= DBG_DEBUG)
Dbprintf("new cmd from reader: len=%d, cmdsRecvd=%d", len, cmdsReceived);
// CRC Check
if (len >= 3) { // if crc exists
if (!check_crc(CRC_14443_B, receivedCmd, len)) {
if (g_dbglevel >= DBG_DEBUG) {
DbpString("CRC fail");
}
}
} else {
if (g_dbglevel >= DBG_DEBUG) {
DbpString("CRC passed");
}
}
cardSTATE = SIM_IDLE;
}
break;
}
default:
break;
}
++cmdsReceived;
}
if (g_dbglevel >= DBG_DEBUG)
Dbprintf("Emulator stopped. Trace length: %d ", BigBuf_get_traceLen());
switch_off(); //simulate
}
/*
void Simulate_iso14443b_srx_tag(uint8_t *uid) {
LED_A_ON();
/ SRI512
> initiate 06 00 ISO14443B_INITIATE
< xx crc crc
> select 0e xx ISO14443B_SELECT
< xx nn nn
> readblock 08 blck_no ISO14443B_READ_BLK
< d0 d1 d2 d3 2byte crc
> get uid ISO14443B_GET_UID
< 81 93 99 20 92 11 02 (8byte UID in MSB D002 199220 999381)
#define ISO14443B_REQB 0x05
#define ISO14443B_ATTRIB 0x1D
#define ISO14443B_HALT 0x50
#define ISO14443B_INITIATE 0x06
#define ISO14443B_SELECT 0x0E
#define ISO14443B_GET_UID 0x0B
#define ISO14443B_READ_BLK 0x08
#define ISO14443B_WRITE_BLK 0x09
#define ISO14443B_RESET 0x0C
#define ISO14443B_COMPLETION 0x0F
#define ISO14443B_AUTHENTICATE 0x0A
#define ISO14443B_PING 0xBA
#define ISO14443B_PONG 0xAB
static const uint8_t resp_init_srx[] = { 0x73, 0x64, 0xb1 };
uint8_t resp_select_srx[] = { 0x73, 0x64, 0xb1 };
// a default uid, or user supplied
uint8_t resp_getuid_srx[10] = {
0x81, 0x93, 0x99, 0x20, 0x92, 0x11, 0x02, 0xD0, 0x00, 0x00
};
// ...UID supplied from user. Adjust ATQB response accordingly
if (memcmp("\x00\x00\x00\x00\x00\x00\x00\x00", uid, 8) != 0) {
memcpy(resp_getuid_srx, uid, 8);
AddCrc14B(resp_getuid_srx, 8);
}
// response to HLTB and ATTRIB
static const uint8_t respOK[] = {0x00, 0x78, 0xF0};
// setup device.
FpgaDownloadAndGo(FPGA_BITSTREAM_HF);
// connect Demodulated Signal to ADC:
SetAdcMuxFor(GPIO_MUXSEL_HIPKD);
// Set up the synchronous serial port
FpgaSetupSsc(FPGA_MAJOR_MODE_HF_SIMULATOR);
// allocate command receive buffer
BigBuf_free();
BigBuf_Clear_ext(false);
clear_trace();
set_tracing(true);
uint16_t len, cmdsReceived = 0;
int cardSTATE = SIM_NOFIELD;
int vHf = 0; // in mV
tosend_t *ts = get_tosend();
uint8_t *receivedCmd = BigBuf_malloc(MAX_FRAME_SIZE);
// prepare "ATQB" tag answer (encoded):
CodeIso14443bAsTag(respATQB, sizeof(respATQB));
uint8_t *encodedATQB = BigBuf_malloc(ts->max);
uint16_t encodedATQBLen = ts->max;
memcpy(encodedATQB, ts->buf, ts->max);
// prepare "OK" tag answer (encoded):
CodeIso14443bAsTag(respOK, sizeof(respOK));
uint8_t *encodedOK = BigBuf_malloc(ts->max);
uint16_t encodedOKLen = ts->max;
memcpy(encodedOK, ts->buf, ts->max);
// Simulation loop
while (BUTTON_PRESS() == false) {
WDT_HIT();
//iceman: limit with 2000 times..
if (data_available()) {
break;
}
// find reader field
if (cardSTATE == SIM_NOFIELD) {
vHf = (MAX_ADC_HF_VOLTAGE * SumAdc(ADC_CHAN_HF, 32)) >> 15;
if (vHf > MF_MINFIELDV) {
cardSTATE = SIM_IDLE;
LED_A_ON();
}
}
if (cardSTATE == SIM_NOFIELD) continue;
// Get reader command
if (!GetIso14443bCommandFromReader(receivedCmd, &len)) {
Dbprintf("button pressed, received %d commands", cmdsReceived);
break;
}
// ISO14443-B protocol states:
// REQ or WUP request in ANY state
// WUP in HALTED state
if (len == 5) {
if ((receivedCmd[0] == ISO14443B_REQB && (receivedCmd[2] & 0x8) == 0x8 && cardSTATE == SIM_HALTED) ||
receivedCmd[0] == ISO14443B_REQB) {
LogTrace(receivedCmd, len, 0, 0, NULL, true);
cardSTATE = SIM_SELECTING;
}
}
/
* How should this flow go?
* REQB or WUPB
* send response ( waiting for Attrib)
* ATTRIB
* send response ( waiting for commands 7816)
* HALT
send halt response ( waiting for wupb )
/
switch (cardSTATE) {
//case SIM_NOFIELD:
case SIM_HALTED:
case SIM_IDLE: {
LogTrace(receivedCmd, len, 0, 0, NULL, true);
break;
}
case SIM_SELECTING: {
TransmitFor14443b_AsTag(encodedATQB, encodedATQBLen);
LogTrace(respATQB, sizeof(respATQB), 0, 0, NULL, false);
cardSTATE = SIM_WORK;
break;
}
case SIM_HALTING: {
TransmitFor14443b_AsTag(encodedOK, encodedOKLen);
LogTrace(respOK, sizeof(respOK), 0, 0, NULL, false);
cardSTATE = SIM_HALTED;
break;
}
case SIM_ACKNOWLEDGE: {
TransmitFor14443b_AsTag(encodedOK, encodedOKLen);
LogTrace(respOK, sizeof(respOK), 0, 0, NULL, false);
cardSTATE = SIM_IDLE;
break;
}
case SIM_WORK: {
if (len == 7 && receivedCmd[0] == ISO14443B_HALT) {
cardSTATE = SIM_HALTED;
} else if (len == 11 && receivedCmd[0] == ISO14443B_ATTRIB) {
cardSTATE = SIM_ACKNOWLEDGE;
} else {
// Todo:
// - SLOT MARKER
// - ISO7816
// - emulate with a memory dump
if (g_dbglevel >= DBG_DEBUG)
Dbprintf("new cmd from reader: len=%d, cmdsRecvd=%d", len, cmdsReceived);
// CRC Check
if (len >= 3) { // if crc exists
if (!check_crc(CRC_14443_B, receivedCmd, len)) {
if (g_dbglevel >= DBG_DEBUG) {
DbpString("CRC fail");
}
}
} else {
if (g_dbglevel >= DBG_DEBUG) {
DbpString("CRC passed");
}
}
cardSTATE = SIM_IDLE;
}
break;
}
default:
break;
}
++cmdsReceived;
}
if (g_dbglevel >= DBG_DEBUG)
Dbprintf("Emulator stopped. Trace length: %d ", BigBuf_get_traceLen());
switch_off(); //simulate
}
*/
//=============================================================================
// An ISO 14443 Type B reader. We take layer two commands, code them
// appropriately, and then send them to the tag. We then listen for the
// tag's response, which we leave in the buffer to be demodulated on the
// PC side.
//=============================================================================
// We support both 14b framing and 14b' framing.
// 14b framing looks like:
// xxxxxxxx1111111111111111-000000000011-0........1-0........1-0........1-1-0........1-0........1-1000000000011xxxxxx
// TR1 SOF 10*0+2*1 start-stop ^^^^^^^^byte ^ occasional stuff bit EOF 10*0+N*1
// 14b' framing looks like:
// xxxxxxxxxxxxxxxx111111111111111111111-0........1-0........1-0........1-1-0........1-0........1-000000000000xxxxxxx
// SOF? start-stop ^^^^^^^^byte ^ occasional stuff bit EOF
/*
* Handles reception of a bit from the tag
*
* This function is called 2 times per bit (every 4 subcarrier cycles).
* Subcarrier frequency fs is 848kHz, 1/fs = 1,18us, i.e. function is called every 4,72us
*
* LED handling:
* LED C -> ON once we have received the SOF and are expecting the rest.
* LED C -> OFF once we have received EOF or are unsynced
*
* Returns: true if we received a EOF
* false if we are still waiting for some more
*
*/
static RAMFUNC int Handle14443bSamplesFromTag(int ci, int cq) {
int v = 0;
// The soft decision on the bit uses an estimate of just the
// quadrant of the reference angle, not the exact angle.
#define MAKE_SOFT_DECISION() { \
if(Demod.sumI > 0) { \
v = ci; \
} else { \
v = -ci; \
} \
if(Demod.sumQ > 0) { \
v += cq; \
} else { \
v -= cq; \
} \
}
#define SUBCARRIER_DETECT_THRESHOLD 8
// Subcarrier amplitude v = sqrt(ci^2 + cq^2), approximated here by max(abs(ci),abs(cq)) + 1/2*min(abs(ci),abs(cq)))
#define AMPLITUDE(ci,cq) (MAX(ABS(ci),ABS(cq)) + (MIN(ABS(ci),ABS(cq))/2))
switch (Demod.state) {
case DEMOD_UNSYNCD: {
if (AMPLITUDE(ci, cq) > SUBCARRIER_DETECT_THRESHOLD) { // subcarrier detected
Demod.state = DEMOD_PHASE_REF_TRAINING;
Demod.sumI = ci;
Demod.sumQ = cq;
Demod.posCount = 1;
}
break;
}
case DEMOD_PHASE_REF_TRAINING: {
// While we get a constant signal
if (AMPLITUDE(ci, cq) > SUBCARRIER_DETECT_THRESHOLD) {
if (((ABS(Demod.sumI) > ABS(Demod.sumQ)) && (((ci > 0) && (Demod.sumI > 0)) || ((ci < 0) && (Demod.sumI < 0)))) || // signal closer to horizontal, polarity check based on on I
((ABS(Demod.sumI) <= ABS(Demod.sumQ)) && (((cq > 0) && (Demod.sumQ > 0)) || ((cq < 0) && (Demod.sumQ < 0))))) { // signal closer to vertical, polarity check based on on Q
if (Demod.posCount < 10) { // refine signal approximation during first 10 samples
Demod.sumI += ci;
Demod.sumQ += cq;
}
Demod.posCount += 1;
} else {
// transition
if (Demod.posCount < 10) {
// subcarrier lost
Demod.state = DEMOD_UNSYNCD;
break;
} else {
// at this point it can be start of 14b' data or start of 14b SOF
MAKE_SOFT_DECISION();
Demod.posCount = 1; // this was the first half
Demod.thisBit = v;
Demod.shiftReg = 0;
Demod.state = DEMOD_RECEIVING_DATA;
}
}
} else {
// subcarrier lost
Demod.state = DEMOD_UNSYNCD;
}
break;
}
case DEMOD_AWAITING_START_BIT: {
Demod.posCount++;
MAKE_SOFT_DECISION();
if (v > 0) {
if (Demod.posCount > 3 * 2) { // max 19us between characters = 16 1/fs, max 3 etu after low phase of SOF = 24 1/fs
LED_C_OFF();
if (Demod.bitCount == 0 && Demod.len == 0) { // received SOF only, this is valid for iClass/Picopass
return true;
} else {
Demod.state = DEMOD_UNSYNCD;
}
}
} else { // start bit detected
Demod.posCount = 1; // this was the first half
Demod.thisBit = v;
Demod.shiftReg = 0;
Demod.state = DEMOD_RECEIVING_DATA;
}
break;
}
case WAIT_FOR_RISING_EDGE_OF_SOF: {
Demod.posCount++;
MAKE_SOFT_DECISION();
if (v > 0) {
if (Demod.posCount < 9 * 2) { // low phase of SOF too short (< 9 etu). Note: spec is >= 10, but FPGA tends to "smear" edges
Demod.state = DEMOD_UNSYNCD;
} else {
LED_C_ON(); // Got SOF
Demod.posCount = 0;
Demod.bitCount = 0;
Demod.len = 0;
Demod.state = DEMOD_AWAITING_START_BIT;
}
} else {
if (Demod.posCount > 12 * 2) { // low phase of SOF too long (> 12 etu)
Demod.state = DEMOD_UNSYNCD;
LED_C_OFF();
}
}
break;
}
case DEMOD_RECEIVING_DATA: {
MAKE_SOFT_DECISION();
if (Demod.posCount == 0) { // first half of bit
Demod.thisBit = v;
Demod.posCount = 1;
} else { // second half of bit
Demod.thisBit += v;
Demod.shiftReg >>= 1;
if (Demod.thisBit > 0) { // logic '1'
Demod.shiftReg |= 0x200;
}
Demod.bitCount++;
if (Demod.bitCount == 10) {
uint16_t s = Demod.shiftReg;
if ((s & 0x200) && !(s & 0x001)) { // stop bit == '1', start bit == '0'
Demod.output[Demod.len] = (s >> 1);
Demod.len++;
Demod.bitCount = 0;
Demod.state = DEMOD_AWAITING_START_BIT;
} else {
if (s == 0x000) {
if (Demod.len > 0) {
LED_C_OFF();
// This is EOF (start, stop and all data bits == '0'
return true;
} else {
// Zeroes but no data acquired yet?
// => Still in SOF of 14b, wait for raising edge
Demod.posCount = 10 * 2;
Demod.bitCount = 0;
Demod.len = 0;
Demod.state = WAIT_FOR_RISING_EDGE_OF_SOF;
break;
}
}
if (AMPLITUDE(ci, cq) < SUBCARRIER_DETECT_THRESHOLD) {
LED_C_OFF();
// subcarrier lost
Demod.state = DEMOD_UNSYNCD;
if (Demod.len > 0) { // no EOF but no signal anymore and we got data, e.g. ASK CTx
return true;
}
}
// we have still signal but no proper byte or EOF? this shouldn't happen
//Demod.posCount = 10 * 2;
Demod.bitCount = 0;
Demod.len = 0;
Demod.state = WAIT_FOR_RISING_EDGE_OF_SOF;
break;
}
}
Demod.posCount = 0;
}
break;
}
default: {
Demod.state = DEMOD_UNSYNCD;
LED_C_OFF();
break;
}
}
return false;
}
/*
* Demodulate the samples we received from the tag, also log to tracebuffer
*/
static int Get14443bAnswerFromTag(uint8_t *response, uint16_t max_len, uint32_t timeout, uint32_t *eof_time) {
// Set up the demodulator for tag -> reader responses.
Demod14bInit(response, max_len);
// The DMA buffer, used to stream samples from the FPGA
dmabuf16_t *dma = get_dma16();
if (FpgaSetupSscDma((uint8_t *) dma->buf, DMA_BUFFER_SIZE) == false) {
if (g_dbglevel > DBG_ERROR) Dbprintf("FpgaSetupSscDma failed. Exiting");
return -1;
}
uint32_t dma_start_time = 0;
uint16_t *upTo = dma->buf;
int samples = 0, ret = 0;
// Put FPGA in the appropriate mode
LED_D_ON();
FpgaWriteConfWord(FPGA_MAJOR_MODE_HF_READER | FPGA_HF_READER_SUBCARRIER_848_KHZ | FPGA_HF_READER_MODE_RECEIVE_IQ);
for (;;) {
volatile uint16_t behindBy = ((uint16_t *)AT91C_BASE_PDC_SSC->PDC_RPR - upTo) & (DMA_BUFFER_SIZE - 1);
if (behindBy == 0)
continue;
samples++;
if (samples == 1) {
// DMA has transferred the very first data
dma_start_time = GetCountSspClk() & 0xfffffff0;
}
volatile int8_t ci = *upTo >> 8;
volatile int8_t cq = *upTo;
upTo++;
// we have read all of the DMA buffer content.
if (upTo >= dma->buf + DMA_BUFFER_SIZE) {
// start reading the circular buffer from the beginning again
upTo = dma->buf;
// DMA Counter Register had reached 0, already rotated.
if (AT91C_BASE_SSC->SSC_SR & (AT91C_SSC_ENDRX)) {
// primary buffer was stopped
if (AT91C_BASE_PDC_SSC->PDC_RCR == false) {
AT91C_BASE_PDC_SSC->PDC_RPR = (uint32_t) dma->buf;
AT91C_BASE_PDC_SSC->PDC_RCR = DMA_BUFFER_SIZE;
}
// secondary buffer sets as primary, secondary buffer was stopped
if (AT91C_BASE_PDC_SSC->PDC_RNCR == false) {
AT91C_BASE_PDC_SSC->PDC_RNPR = (uint32_t) dma->buf;
AT91C_BASE_PDC_SSC->PDC_RNCR = DMA_BUFFER_SIZE;
}
WDT_HIT();
if (BUTTON_PRESS()) {
DbpString("stopped");
break;
}
}
}
if (Handle14443bSamplesFromTag(ci, cq)) {
*eof_time = GetCountSspClkDelta(dma_start_time) - DELAY_TAG_TO_ARM; // end of EOF
if (Demod.len > Demod.max_len) {
ret = -2; // overflow
}
break;
}
if (((GetCountSspClkDelta(dma_start_time)) > timeout) && Demod.state < DEMOD_PHASE_REF_TRAINING) {
ret = -1;
break;
}
}
FpgaDisableSscDma();
if (ret < 0) {
return ret;
}
if (Demod.len > 0) {
uint32_t sof_time = *eof_time
- (Demod.len * (8 + 2)) // time for byte transfers
- (10) // time for TR1
- (10 + 2) // time for SOF transfer
- (10); // time for EOF transfer
LogTrace(Demod.output, Demod.len, sof_time, *eof_time, NULL, false);
}
return Demod.len;
}
//-----------------------------------------------------------------------------
// Transmit the command (to the tag) that was placed in ToSend[].
//-----------------------------------------------------------------------------
// param start_time in SSP_CLK
static void TransmitFor14443b_AsReader(uint32_t *start_time) {
tosend_t *ts = get_tosend();
FpgaWriteConfWord(FPGA_MAJOR_MODE_HF_READER | FPGA_HF_READER_MODE_SEND_SHALLOW_MOD);
// TR2 minimum 14 ETUs
if (*start_time < ISO14B_TR0) {
// *start_time = DELAY_ARM_TO_TAG;
*start_time = ISO14B_TR0;
}
// *start_time = (*start_time - DELAY_ARM_TO_TAG) & 0xfffffff0;
*start_time = (*start_time & 0xfffffff0);
if (GetCountSspClk() > *start_time) { // we may miss the intended time
*start_time = (GetCountSspClk() + 32) & 0xfffffff0; // next possible time
}
// wait
while (GetCountSspClk() < *start_time);
LED_B_ON();
for (int c = 0; c < ts->max; c++) {
volatile uint8_t data = ts->buf[c];
for (uint8_t i = 0; i < 8; i++) {
volatile uint16_t send_word = (data & 0x80) ? 0x0000 : 0xFFFF;
while (!(AT91C_BASE_SSC->SSC_SR & (AT91C_SSC_TXRDY))) ;
AT91C_BASE_SSC->SSC_THR = send_word;
while (!(AT91C_BASE_SSC->SSC_SR & (AT91C_SSC_TXRDY))) ;
AT91C_BASE_SSC->SSC_THR = send_word;
data <<= 1;
}
WDT_HIT();
}
LED_B_OFF();
*start_time += DELAY_ARM_TO_TAG;
// wait for last transfer to complete
while (!(AT91C_BASE_SSC->SSC_SR & AT91C_SSC_TXEMPTY)) {};
}
//-----------------------------------------------------------------------------
// Code a layer 2 command (string of octets, including CRC) into ToSend[],
// so that it is ready to transmit to the tag using TransmitFor14443b().
//-----------------------------------------------------------------------------
static void CodeIso14443bAsReader(const uint8_t *cmd, int len) {
/*
* QUESTION: how long is a 1 or 0 in pulses in the xcorr_848 mode?
* 1 "stuffbit" = 1ETU (9us)
*
* TR2 - After the PICC response, the PCD is required to wait the Frame Delay Time (TR2)
before transmission of the next command. The minimum frame delay time required for
all commands is 14 ETUs
*
*/
int i;
tosend_reset();
// Send SOF
// 10-11 ETUs of ZERO
for (i = 0; i < 10; i++) {
tosend_stuffbit(0);
}
// 2-3 ETUs of ONE
tosend_stuffbit(1);
tosend_stuffbit(1);
// Sending cmd, LSB
// from here we add BITS
for (i = 0; i < len; i++) {
// Start bit
tosend_stuffbit(0);
// Data bits
volatile uint8_t b = cmd[i];
tosend_stuffbit(b & 1);
tosend_stuffbit((b >> 1) & 1);
tosend_stuffbit((b >> 2) & 1);
tosend_stuffbit((b >> 3) & 1);
tosend_stuffbit((b >> 4) & 1);
tosend_stuffbit((b >> 5) & 1);
tosend_stuffbit((b >> 6) & 1);
tosend_stuffbit((b >> 7) & 1);
// Stop bit
tosend_stuffbit(1);
// EGT extra guard time 1 ETU = 9us
// For PCD it ranges 0-57us === 0 - 6 ETU
// FOR PICC it ranges 0-19us == 0 - 2 ETU
}
// Send EOF
// 10-11 ETUs of ZERO
for (i = 0; i < 10; i++) {
tosend_stuffbit(0);
}
int pad = (10 + 2 + (len * 10) + 10) & 0x7;
for (i = 0; i < 16 - pad; ++i)
tosend_stuffbit(1);
}
/*
* Convenience function to encode, transmit and trace iso 14443b comms
*/
static void CodeAndTransmit14443bAsReader(const uint8_t *cmd, int len, uint32_t *start_time, uint32_t *eof_time) {
tosend_t *ts = get_tosend();
CodeIso14443bAsReader(cmd, len);
TransmitFor14443b_AsReader(start_time);
if (g_trigger) LED_A_ON();
*eof_time = *start_time + (10 * ts->max) + 10 + 2 + 10;
LogTrace(cmd, len, *start_time, *eof_time, NULL, true);
}
/* Sends an APDU to the tag
* TODO: check CRC and preamble
*/
int iso14443b_apdu(uint8_t const *msg, size_t msg_len, bool send_chaining, void *rxdata, uint16_t rxmaxlen, uint8_t *res) {
uint8_t real_cmd[msg_len + 4];
if (msg_len) {
// ISO 14443 APDU frame: PCB [CID] [NAD] APDU CRC PCB=0x02
real_cmd[0] = 0x02; // bnr, nad, cid, chn=0; i-block(0x00)
if (send_chaining) {
real_cmd[0] |= 0x10;
}
// put block number into the PCB
real_cmd[0] |= iso14b_pcb_blocknum;
memcpy(real_cmd + 1, msg, msg_len);
} else {
// R-block. ACK
real_cmd[0] = 0xA2; // r-block + ACK
real_cmd[0] |= iso14b_pcb_blocknum;
}
AddCrc14B(real_cmd, msg_len + 1);
// send
uint32_t start_time = 0;
uint32_t eof_time = 0;
CodeAndTransmit14443bAsReader(real_cmd, msg_len + 3, &start_time, &eof_time);
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
int len = Get14443bAnswerFromTag(rxdata, rxmaxlen, iso14b_timeout, &eof_time);
FpgaDisableTracing();
uint8_t *data_bytes = (uint8_t *) rxdata;
if (len <= 0) {
return 0; //DATA LINK ERROR
} else {
// S-Block WTX
while (len && ((data_bytes[0] & 0xF2) == 0xF2)) {
uint32_t save_iso14b_timeout_spp = iso14b_timeout;
// 2 high bits mandatory set to 0b
// byte1 - WTXM [1..59].
uint8_t wtxm = data_bytes[1] & 0x3F;
// command FWT = FWT * WTXM
uint32_t fwt_temp = iso14b_fwt * wtxm;
// temporarily increase timeout
iso14b_set_timeout((32 << fwt_temp));
// Transmit WTX back
data_bytes[1] = wtxm;
// now need to fix CRC.
AddCrc14B(data_bytes, len - 2);
// transmit S-Block
CodeAndTransmit14443bAsReader(data_bytes, len, &start_time, &eof_time);
// retrieve the result again (with increased timeout)
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
len = Get14443bAnswerFromTag(rxdata, rxmaxlen, iso14b_timeout, &eof_time);
FpgaDisableTracing();
data_bytes = rxdata;
// restore timeout
iso14b_timeout = save_iso14b_timeout_spp;
}
// if we received an I- or R(ACK)-Block with a block number equal to the
// current block number, toggle the current block number
if (len >= 3 // PCB + CRC = 3 bytes
&& ((data_bytes[0] & 0xC0) == 0 // I-Block
|| (data_bytes[0] & 0xD0) == 0x80) // R-Block with ACK bit set to 0
&& (data_bytes[0] & 0x01) == iso14b_pcb_blocknum) { // equal block numbers
iso14b_pcb_blocknum ^= 1;
}
// if we received I-block with chaining we need to send ACK and receive another block of data
if (res)
*res = data_bytes[0];
// crc check
if (len >= 3 && !check_crc(CRC_14443_B, data_bytes, len)) {
return -1;
}
}
if (len) {
// cut frame byte
len -= 1;
// memmove(data_bytes, data_bytes + 1, len);
for (int i = 0; i < len; i++)
data_bytes[i] = data_bytes[i + 1];
}
return len;
}
/**
* ASK CTS initialise.
*/
static int iso14443b_select_cts_card(iso14b_cts_card_select_t *card) {
// INITIATE command: wake up the tag using the INITIATE
uint8_t cmdINIT[] = {ASK_REQT, 0xF9, 0xE0};
uint8_t cmdMSBUID[] = {ASK_SELECT, 0xFF, 0xFF, 0x00, 0x00};
uint8_t cmdLSBUID[] = {0xC4, 0x00, 0x00};
AddCrc14B(cmdMSBUID, 3);
AddCrc14B(cmdLSBUID, 1);
uint8_t r[8];
uint32_t start_time = 0;
uint32_t eof_time = 0;
CodeAndTransmit14443bAsReader(cmdINIT, sizeof(cmdINIT), &start_time, &eof_time);
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
int retlen = Get14443bAnswerFromTag(r, sizeof(r), iso14b_timeout, &eof_time);
FpgaDisableTracing();
if (retlen != 4) {
return -1;
}
if (check_crc(CRC_14443_B, r, retlen) == false) {
return -2;
}
if (card) {
// pc. fc Product code, Facility code
card->pc = r[0];
card->fc = r[1];
}
start_time = eof_time + ISO14B_TR2;
CodeAndTransmit14443bAsReader(cmdMSBUID, sizeof(cmdMSBUID), &start_time, &eof_time);
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
retlen = Get14443bAnswerFromTag(r, sizeof(r), iso14b_timeout, &eof_time);
FpgaDisableTracing();
if (retlen != 4) {
return -1;
}
if (check_crc(CRC_14443_B, r, retlen) == false) {
return -2;
}
if (card) {
memcpy(card->uid, r, 2);
}
start_time = eof_time + ISO14B_TR2;
CodeAndTransmit14443bAsReader(cmdLSBUID, sizeof(cmdLSBUID), &start_time, &eof_time);
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
retlen = Get14443bAnswerFromTag(r, sizeof(r), iso14b_timeout, &eof_time);
FpgaDisableTracing();
if (retlen != 4) {
return -1;
}
if (check_crc(CRC_14443_B, r, retlen) == false) {
return -2;
}
if (card) {
memcpy(card->uid + 2, r, 2);
}
return 0;
}
/**
* SRx Initialise.
*/
static int iso14443b_select_srx_card(iso14b_card_select_t *card) {
// INITIATE command: wake up the tag using the INITIATE
static const uint8_t init_srx[] = { ISO14443B_INITIATE, 0x00, 0x97, 0x5b };
uint8_t r_init[3] = {0x0};
uint8_t r_select[3] = {0x0};
uint8_t r_papid[10] = {0x0};
uint32_t start_time = 0;
uint32_t eof_time = 0;
CodeAndTransmit14443bAsReader(init_srx, sizeof(init_srx), &start_time, &eof_time);
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
int retlen = Get14443bAnswerFromTag(r_init, sizeof(r_init), iso14b_timeout, &eof_time);
FpgaDisableTracing();
if (retlen <= 0) {
return -1;
}
// Randomly generated Chip ID
if (card) {
card->chipid = Demod.output[0];
}
// SELECT command (with space for CRC)
uint8_t select_srx[] = { ISO14443B_SELECT, 0x00, 0x00, 0x00};
select_srx[1] = r_init[0];
AddCrc14B(select_srx, 2);
start_time = eof_time + ISO14B_TR2;
CodeAndTransmit14443bAsReader(select_srx, sizeof(select_srx), &start_time, &eof_time);
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
retlen = Get14443bAnswerFromTag(r_select, sizeof(r_select), iso14b_timeout, &eof_time);
FpgaDisableTracing();
if (retlen != 3) {
return -1;
}
if (check_crc(CRC_14443_B, r_select, retlen) == false) {
return -2;
}
// Check response from the tag: should be the same UID as the command we just sent:
if (select_srx[1] != r_select[0]) {
return -3;
}
// First get the tag's UID:
select_srx[0] = ISO14443B_GET_UID;
AddCrc14B(select_srx, 1);
start_time = eof_time + ISO14B_TR2;
CodeAndTransmit14443bAsReader(select_srx, 3, &start_time, &eof_time); // Only first three bytes for this one
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
retlen = Get14443bAnswerFromTag(r_papid, sizeof(r_papid), iso14b_timeout, &eof_time);
FpgaDisableTracing();
if (retlen != 10) {
return -1;
}
if (!check_crc(CRC_14443_B, r_papid, retlen)) {
return -2;
}
if (card) {
card->uidlen = 8;
memcpy(card->uid, r_papid, 8);
}
return 0;
}
/* Perform the ISO 14443 B Card Selection procedure
* Currently does NOT do any collision handling.
* It expects 0-1 cards in the device's range.
* TODO: Support multiple cards (perform anticollision)
* TODO: Verify CRC checksums
*/
int iso14443b_select_card(iso14b_card_select_t *card) {
// WUPB command (including CRC)
// Note: WUPB wakes up all tags, REQB doesn't wake up tags in HALT state
// WUTB or REQB is denoted in the third byte, lower nibble. 0 vs 8
//static const uint8_t wupb[] = { ISO14443B_REQB, 0x00, 0x08, 0x39, 0x73 };
static const uint8_t wupb[] = { ISO14443B_REQB, 0x00, 0x00, 0x71, 0xff };
// ATTRIB command (with space for CRC)
uint8_t attrib[] = { ISO14443B_ATTRIB, 0x00, 0x00, 0x00, 0x00, 0x00, 0x08, 0x00, 0x00, 0x00, 0x00};
uint8_t r_pupid[14] = {0x0};
uint8_t r_attrib[3] = {0x0};
// first, wake up the tag
uint32_t start_time = 0;
uint32_t eof_time = 0;
CodeAndTransmit14443bAsReader(wupb, sizeof(wupb), &start_time, &eof_time);
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
int retlen = Get14443bAnswerFromTag(r_pupid, sizeof(r_pupid), iso14b_timeout, &eof_time);
FpgaDisableTracing();
// ATQB too short?
if (retlen < 14) {
return -1;
}
// VALIDATE CRC
if (check_crc(CRC_14443_B, r_pupid, retlen) == false) {
return -2;
}
if (card) {
card->uidlen = 4;
memcpy(card->uid, r_pupid + 1, 4);
memcpy(card->atqb, r_pupid + 5, 7);
}
// copy the PUPI to ATTRIB ( PUPI == UID )
memcpy(attrib + 1, r_pupid + 1, 4);
// copy the protocol info from ATQB (Protocol Info -> Protocol_Type) into ATTRIB (Param 3)
attrib[7] = r_pupid[10] & 0x0F;
AddCrc14B(attrib, 9);
start_time = eof_time + ISO14B_TR2;
CodeAndTransmit14443bAsReader(attrib, sizeof(attrib), &start_time, &eof_time);
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
retlen = Get14443bAnswerFromTag(r_attrib, sizeof(r_attrib), iso14b_timeout, &eof_time);
FpgaDisableTracing();
// Answer to ATTRIB too short?
if (retlen < 3) {
return -1;
}
// VALIDATE CRC
if (check_crc(CRC_14443_B, r_attrib, retlen) == false) {
return -2;
}
if (card) {
// CID
card->cid = r_attrib[0];
// MAX FRAME
uint16_t maxFrame = card->atqb[5] >> 4;
if (maxFrame < 5) maxFrame = 8 * maxFrame + 16;
else if (maxFrame == 5) maxFrame = 64;
else if (maxFrame == 6) maxFrame = 96;
else if (maxFrame == 7) maxFrame = 128;
else if (maxFrame == 8) maxFrame = 256;
else maxFrame = 257;
iso14b_set_maxframesize(maxFrame);
// FWT
uint8_t fwt = card->atqb[6] >> 4;
if (fwt < 15) {
iso14b_set_fwt(fwt);
}
}
// reset PCB block number
iso14b_pcb_blocknum = 0;
return 0;
}
// Set up ISO 14443 Type B communication (similar to iso14443a_setup)
// field is setup for "Sending as Reader"
void iso14443b_setup(void) {
LEDsoff();
FpgaDownloadAndGo(FPGA_BITSTREAM_HF);
// allocate command receive buffer
BigBuf_free();
BigBuf_Clear_ext(false);
// Initialize Demod and Uart structs
Demod14bInit(BigBuf_malloc(MAX_FRAME_SIZE), MAX_FRAME_SIZE);
Uart14bInit(BigBuf_malloc(MAX_FRAME_SIZE));
// connect Demodulated Signal to ADC:
SetAdcMuxFor(GPIO_MUXSEL_HIPKD);
// Set up the synchronous serial port
FpgaSetupSsc(FPGA_MAJOR_MODE_HF_READER);
// Signal field is on with the appropriate LED
FpgaWriteConfWord(FPGA_MAJOR_MODE_HF_READER | FPGA_HF_READER_MODE_SEND_SHALLOW_MOD);
SpinDelay(100);
// Start the timer
StartCountSspClk();
// reset timeout
iso14b_set_fwt(8);
LED_D_ON();
}
//-----------------------------------------------------------------------------
// Read a SRI512 ISO 14443B tag.
//
// SRI512 tags are just simple memory tags, here we're looking at making a dump
// of the contents of the memory. No anticollision algorithm is done, we assume
// we have a single tag in the field.
//
// I tried to be systematic and check every answer of the tag, every CRC, etc...
//-----------------------------------------------------------------------------
static int read_srx_block(uint8_t blocknr, uint8_t *block) {
uint8_t cmd[] = {ISO14443B_READ_BLK, blocknr, 0x00, 0x00};
AddCrc14B(cmd, 2);
uint8_t r_block[6] = {0};
uint32_t start_time = 0;
uint32_t eof_time = 0;
CodeAndTransmit14443bAsReader(cmd, sizeof(cmd), &start_time, &eof_time);
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
int retlen = Get14443bAnswerFromTag(r_block, sizeof(r_block), iso14b_timeout, &eof_time);
FpgaDisableTracing();
// Check if we got an answer from the tag
if (retlen != 6) {
DbpString("[!] expected 6 bytes from tag, got less...");
return PM3_EWRONGANSWER;
}
// The check the CRC of the answer
if (check_crc(CRC_14443_B, r_block, retlen) == false) {
DbpString("CRC fail");
return PM3_ECRC;
}
if (block) {
memcpy(block, r_block, 4);
}
if (g_dbglevel >= DBG_DEBUG) {
Dbprintf("Address=%02x, Contents=%08x, CRC=%04x",
blocknr,
(r_block[3] << 24) + (r_block[2] << 16) + (r_block[1] << 8) + r_block[0],
(r_block[4] << 8) + r_block[5]
);
}
return PM3_SUCCESS;
}
void ReadSTBlock(uint8_t blocknr) {
iso14443b_setup();
iso14b_card_select_t card;
int res = iso14443b_select_srx_card(&card);
// 0: OK -1 wrong len, -2: attrib fail, -3:crc fail,
switch (res) {
case -1:
case -3: {
reply_ng(CMD_HF_SRI_READ, PM3_EWRONGANSWER, NULL, 0);
goto out;
}
case -2: {
reply_ng(CMD_HF_SRI_READ, PM3_ECRC, NULL, 0);
goto out;
}
}
uint8_t *data = BigBuf_malloc(4);
res = read_srx_block(blocknr, data);
reply_ng(CMD_HF_SRI_READ, res, data, 4);
out:
BigBuf_free();
switch_off();
}
//=============================================================================
// Finally, the `sniffer' combines elements from both the reader and
// simulated tag, to show both sides of the conversation.
//=============================================================================
//-----------------------------------------------------------------------------
// Record the sequence of commands sent by the reader to the tag, with
// triggering so that we start recording at the point that the tag is moved
// near the reader.
//-----------------------------------------------------------------------------
/*
* Memory usage for this function, (within BigBuf)
* Last Received command (reader->tag) - MAX_FRAME_SIZE
* Last Received command (tag->reader) - MAX_FRAME_SIZE
* DMA Buffer - ISO14443B_DMA_BUFFER_SIZE
* Demodulated samples received - all the rest
*/
void SniffIso14443b(void) {
LEDsoff();
LED_A_ON();
FpgaDownloadAndGo(FPGA_BITSTREAM_HF);
DbpString("Starting to sniff. Press PM3 Button to stop.");
BigBuf_free();
clear_trace();
set_tracing(true);
// Initialize Demod and Uart structs
uint8_t dm_buf[MAX_FRAME_SIZE] = {0};
Demod14bInit(dm_buf, sizeof(dm_buf));
uint8_t ua_buf[MAX_FRAME_SIZE] = {0};
Uart14bInit(ua_buf);
//Demod14bInit(BigBuf_malloc(MAX_FRAME_SIZE), MAX_FRAME_SIZE);
//Uart14bInit(BigBuf_malloc(MAX_FRAME_SIZE));
// Set FPGA in the appropriate mode
FpgaWriteConfWord(FPGA_MAJOR_MODE_HF_READER | FPGA_HF_READER_SUBCARRIER_848_KHZ | FPGA_HF_READER_MODE_SNIFF_IQ);
// FpgaWriteConfWord(FPGA_MAJOR_MODE_HF_READER | FPGA_HF_READER_SUBCARRIER_848_KHZ | FPGA_HF_READER_MODE_SNIFF_AMPLITUDE);
// connect Demodulated Signal to ADC:
SetAdcMuxFor(GPIO_MUXSEL_HIPKD);
FpgaSetupSsc(FPGA_MAJOR_MODE_HF_READER);
StartCountSspClk();
// The DMA buffer, used to stream samples from the FPGA
dmabuf16_t *dma = get_dma16();
// Setup and start DMA.
if (!FpgaSetupSscDma((uint8_t *) dma->buf, DMA_BUFFER_SIZE)) {
if (g_dbglevel > DBG_ERROR) DbpString("FpgaSetupSscDma failed. Exiting");
switch_off();
return;
}
// We won't start recording the frames that we acquire until we trigger;
// a good trigger condition to get started is probably when we see a
// response from the tag.
bool tag_is_active = false;
bool reader_is_active = false;
bool expect_tag_answer = false;
int dma_start_time = 0;
// Count of samples received so far, so that we can include timing
int samples = 0;
uint16_t *upTo = dma->buf;
for (;;) {
volatile int behind_by = ((uint16_t *)AT91C_BASE_PDC_SSC->PDC_RPR - upTo) & (DMA_BUFFER_SIZE - 1);
if (behind_by < 1) continue;
samples++;
if (samples == 1) {
// DMA has transferred the very first data
dma_start_time = GetCountSspClk() & 0xfffffff0;
}
volatile int8_t ci = *upTo >> 8;
volatile int8_t cq = *upTo;
upTo++;
// we have read all of the DMA buffer content.
if (upTo >= dma->buf + DMA_BUFFER_SIZE) {
// start reading the circular buffer from the beginning again
upTo = dma->buf;
// DMA Counter Register had reached 0, already rotated.
if (AT91C_BASE_SSC->SSC_SR & (AT91C_SSC_ENDRX)) {
// primary buffer was stopped
if (AT91C_BASE_PDC_SSC->PDC_RCR == false) {
AT91C_BASE_PDC_SSC->PDC_RPR = (uint32_t) dma->buf;
AT91C_BASE_PDC_SSC->PDC_RCR = DMA_BUFFER_SIZE;
}
// secondary buffer sets as primary, secondary buffer was stopped
if (AT91C_BASE_PDC_SSC->PDC_RNCR == false) {
AT91C_BASE_PDC_SSC->PDC_RNPR = (uint32_t) dma->buf;
AT91C_BASE_PDC_SSC->PDC_RNCR = DMA_BUFFER_SIZE;
}
WDT_HIT();
if (BUTTON_PRESS()) {
DbpString("Sniff stopped");
break;
}
}
}
// no need to try decoding reader data if the tag is sending
if (tag_is_active == false) {
if (Handle14443bSampleFromReader(ci & 0x01)) {
uint32_t eof_time = dma_start_time + (samples * 16) + 8; // - DELAY_READER_TO_ARM_SNIFF; // end of EOF
if (Uart.byteCnt > 0) {
uint32_t sof_time = eof_time
- Uart.byteCnt * 1 // time for byte transfers
- 32 * 16 // time for SOF transfer
- 16 * 16; // time for EOF transfer
LogTrace(Uart.output, Uart.byteCnt, (sof_time * 4), (eof_time * 4), NULL, true);
}
// And ready to receive another command.
Uart14bReset();
Demod14bReset();
reader_is_active = false;
expect_tag_answer = true;
}
if (Handle14443bSampleFromReader(cq & 0x01)) {
uint32_t eof_time = dma_start_time + (samples * 16) + 16; // - DELAY_READER_TO_ARM_SNIFF; // end of EOF
if (Uart.byteCnt > 0) {
uint32_t sof_time = eof_time
- Uart.byteCnt * 1 // time for byte transfers
- 32 * 16 // time for SOF transfer
- 16 * 16; // time for EOF transfer
LogTrace(Uart.output, Uart.byteCnt, (sof_time * 4), (eof_time * 4), NULL, true);
}
// And ready to receive another command
Uart14bReset();
Demod14bReset();
reader_is_active = false;
expect_tag_answer = true;
}
reader_is_active = (Uart.state > STATE_14B_GOT_FALLING_EDGE_OF_SOF);
}
// no need to try decoding tag data if the reader is sending - and we cannot afford the time
if (reader_is_active == false && expect_tag_answer) {
if (Handle14443bSamplesFromTag((ci >> 1), (cq >> 1))) {
uint32_t eof_time = dma_start_time + (samples * 16); // - DELAY_TAG_TO_ARM_SNIFF; // end of EOF
uint32_t sof_time = eof_time
- Demod.len * 8 * 8 * 16 // time for byte transfers
- (32 * 16) // time for SOF transfer
- 0; // time for EOF transfer
LogTrace(Demod.output, Demod.len, (sof_time * 4), (eof_time * 4), NULL, false);
// And ready to receive another response.
Uart14bReset();
Demod14bReset();
expect_tag_answer = false;
tag_is_active = false;
} else {
tag_is_active = (Demod.state > WAIT_FOR_RISING_EDGE_OF_SOF);
}
}
}
FpgaDisableTracing();
switch_off();
DbpString("");
DbpString(_CYAN_("Sniff statistics"));
DbpString("=================================");
Dbprintf(" DecodeTag State........%d", Demod.state);
Dbprintf(" DecodeTag byteCnt......%d", Demod.len);
Dbprintf(" DecodeTag posCount.....%d", Demod.posCount);
Dbprintf(" DecodeReader State.....%d", Uart.state);
Dbprintf(" DecodeReader byteCnt...%d", Uart.byteCnt);
Dbprintf(" DecodeReader posCount..%d", Uart.posCnt);
Dbprintf(" Trace length..........." _YELLOW_("%d"), BigBuf_get_traceLen());
DbpString("");
}
static void iso14b_set_trigger(bool enable) {
g_trigger = enable;
}
void SendRawCommand14443B_Ex(iso14b_raw_cmd_t *p) {
// receive buffer
uint8_t buf[PM3_CMD_DATA_SIZE];
memset(buf, 0, sizeof(buf));
if (g_dbglevel > DBG_DEBUG) {
Dbprintf("14b raw: param, %04x", p->flags);
}
// turn on trigger (LED_A)
if ((p->flags & ISO14B_REQUEST_TRIGGER) == ISO14B_REQUEST_TRIGGER)
iso14b_set_trigger(true);
if ((p->flags & ISO14B_CONNECT) == ISO14B_CONNECT) {
iso14443b_setup();
}
if ((p->flags & ISO14B_SET_TIMEOUT) == ISO14B_SET_TIMEOUT) {
iso14b_set_timeout(p->timeout);
}
if ((p->flags & ISO14B_CLEARTRACE) == ISO14B_CLEARTRACE) {
clear_trace();
}
set_tracing(true);
int status;
uint32_t sendlen = sizeof(iso14b_card_select_t);
iso14b_card_select_t card;
memset((void *)&card, 0x00, sizeof(card));
if ((p->flags & ISO14B_SELECT_STD) == ISO14B_SELECT_STD) {
status = iso14443b_select_card(&card);
reply_mix(CMD_HF_ISO14443B_COMMAND, status, sendlen, 0, (uint8_t *)&card, sendlen);
// 0: OK -1: attrib fail, -2:crc fail,
if (status != 0) goto out;
}
if ((p->flags & ISO14B_SELECT_SR) == ISO14B_SELECT_SR) {
status = iso14443b_select_srx_card(&card);
reply_mix(CMD_HF_ISO14443B_COMMAND, status, sendlen, 0, (uint8_t *)&card, sendlen);
// 0: OK 2: demod fail, 3:crc fail,
if (status > 0) goto out;
}
if ((p->flags & ISO14B_SELECT_CTS) == ISO14B_SELECT_CTS) {
iso14b_cts_card_select_t cts;
sendlen = sizeof(iso14b_cts_card_select_t);
status = iso14443b_select_cts_card(&cts);
reply_mix(CMD_HF_ISO14443B_COMMAND, status, sendlen, 0, (uint8_t *)&cts, sendlen);
// 0: OK 2: demod fail, 3:crc fail,
if (status > 0) goto out;
}
if ((p->flags & ISO14B_APDU) == ISO14B_APDU) {
uint8_t res;
status = iso14443b_apdu(p->raw, p->rawlen, (p->flags & ISO14B_SEND_CHAINING), buf, sizeof(buf), &res);
sendlen = MIN(Demod.len, PM3_CMD_DATA_SIZE);
reply_mix(CMD_HF_ISO14443B_COMMAND, status, res, 0, buf, sendlen);
}
if ((p->flags & ISO14B_RAW) == ISO14B_RAW) {
if ((p->flags & ISO14B_APPEND_CRC) == ISO14B_APPEND_CRC) {
if (p->rawlen > 0) {
AddCrc14B(p->raw, p->rawlen);
p->rawlen += 2;
}
}
uint32_t start_time = 0;
uint32_t eof_time = 0;
CodeAndTransmit14443bAsReader(p->raw, p->rawlen, &start_time, &eof_time);
if (tearoff_hook() == PM3_ETEAROFF) { // tearoff occurred
FpgaDisableTracing();
reply_mix(CMD_HF_ISO14443B_COMMAND, -2, 0, 0, NULL, 0);
} else {
eof_time += DELAY_ISO14443B_PCD_TO_PICC_READER;
status = Get14443bAnswerFromTag(buf, sizeof(buf), iso14b_timeout, &eof_time); // raw
FpgaDisableTracing();
sendlen = MIN(Demod.len, PM3_CMD_DATA_SIZE);
reply_mix(CMD_HF_ISO14443B_COMMAND, status, sendlen, 0, Demod.output, sendlen);
}
}
out:
// turn off trigger (LED_A)
if ((p->flags & ISO14B_REQUEST_TRIGGER) == ISO14B_REQUEST_TRIGGER)
iso14b_set_trigger(false);
// turn off antenna et al
// we don't send a HALT command.
if ((p->flags & ISO14B_DISCONNECT) == ISO14B_DISCONNECT) {
switch_off(); // disconnect raw
SpinDelay(20);
}
}