ADD: @go_tus simple bruteforce for t55xx, refactored a bit.

[proxmark3-svn] / armsrc / epa.c

//-----------------------------------------------------------------------------
// Frederik Möllers - August 2012
//
// 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 the German electronic "Personalausweis" (ID card)
// Note that the functions which do not implement USB commands do NOT initialize
// the card (with iso14443a_select_card etc.). If You want to use these
// functions, You need to do the setup before calling them!
//-----------------------------------------------------------------------------

#include "iso14443a.h"
#include "iso14443b.h"
#include "epa.h"
#include "cmd.h"

// Protocol and Parameter Selection Request for ISO 14443 type A cards
// use regular (1x) speed in both directions
// CRC is already included
static const uint8_t pps[] = {0xD0, 0x11, 0x00, 0x52, 0xA6};

// APDUs for communication with German Identification Card

// General Authenticate (request encrypted nonce) WITHOUT the Le at the end
static const uint8_t apdu_general_authenticate_pace_get_nonce[] = {
        0x10, // CLA
        0x86, // INS
        0x00, // P1
        0x00, // P2
        0x02, // Lc
        0x7C, // Type: Dynamic Authentication Data
        0x00, // Length: 0 bytes
};

// MSE: Set AT (only CLA, INS, P1 and P2)
static const uint8_t apdu_mse_set_at_start[] = {
        0x00, // CLA
        0x22, // INS
        0xC1, // P1
        0xA4, // P2
};

// SELECT BINARY with the ID for EF.CardAccess
static const uint8_t apdu_select_binary_cardaccess[] = {
        0x00, // CLA
        0xA4, // INS
        0x02, // P1
        0x0C, // P2
        0x02, // Lc
        0x01, // ID
        0x1C  // ID
};

// READ BINARY
static const uint8_t apdu_read_binary[] = {
        0x00, // CLA
        0xB0, // INS
        0x00, // P1
        0x00, // P2
        0x38  // Le
};


// the leading bytes of a PACE OID
static const uint8_t oid_pace_start[] = {
    0x04, // itu-t, identified-organization
    0x00, // etsi
    0x7F, // reserved
    0x00, // etsi-identified-organization
    0x07, // bsi-de
    0x02, // protocols
    0x02, // smartcard
    0x04 // id-PACE
};

// APDUs for replaying:
// MSE: Set AT (initiate PACE)
static uint8_t apdu_replay_mse_set_at_pace[41];
// General Authenticate (Get Nonce)
static uint8_t apdu_replay_general_authenticate_pace_get_nonce[8];
// General Authenticate (Map Nonce)
static uint8_t apdu_replay_general_authenticate_pace_map_nonce[75];
// General Authenticate (Mutual Authenticate)
static uint8_t apdu_replay_general_authenticate_pace_mutual_authenticate[75];
// General Authenticate (Perform Key Agreement)
static uint8_t apdu_replay_general_authenticate_pace_perform_key_agreement[18];
// pointers to the APDUs (for iterations)
static struct {
        uint8_t len;
        uint8_t *data;
} const apdus_replay[] = {
        {sizeof(apdu_replay_mse_set_at_pace), apdu_replay_mse_set_at_pace},
        {sizeof(apdu_replay_general_authenticate_pace_get_nonce), apdu_replay_general_authenticate_pace_get_nonce},
        {sizeof(apdu_replay_general_authenticate_pace_map_nonce), apdu_replay_general_authenticate_pace_map_nonce},
        {sizeof(apdu_replay_general_authenticate_pace_mutual_authenticate), apdu_replay_general_authenticate_pace_mutual_authenticate},
        {sizeof(apdu_replay_general_authenticate_pace_perform_key_agreement), apdu_replay_general_authenticate_pace_perform_key_agreement}
};

// lengths of the replay APDUs
static uint8_t apdu_lengths_replay[5];

// type of card (ISO 14443 A or B)
static char iso_type = 0;

//-----------------------------------------------------------------------------
// Wrapper for sending APDUs to type A and B cards
//-----------------------------------------------------------------------------
int EPA_APDU(uint8_t *apdu, size_t length, uint8_t *response)
{
        switch(iso_type)
        {
                case 'a':
                        return iso14_apdu(apdu, (uint16_t) length, response);
                        break;
                case 'b':
                        return iso14443b_apdu(apdu, length, response);
                        break;
                default:
                        return 0;
                        break;
        }
}

//-----------------------------------------------------------------------------
// Closes the communication channel and turns off the field
//-----------------------------------------------------------------------------
void EPA_Finish()
{
        FpgaWriteConfWord(FPGA_MAJOR_MODE_OFF);
        LEDsoff();
        iso_type = 0;
}

//-----------------------------------------------------------------------------
// Parses DER encoded data, e.g. from EF.CardAccess and fills out the given
// structs. If a pointer is 0, it is ignored.
// The function returns 0 on success and if an error occured, it returns the
// offset where it occured.
//
// TODO: This function can access memory outside of the given data if the DER
//       encoding is broken
// TODO: Support skipping elements with a length > 0x7F
// TODO: Support OIDs with a length > 7F
// TODO: Support elements with long tags (tag is longer than 1 byte)
// TODO: Support proprietary PACE domain parameters
//-----------------------------------------------------------------------------
size_t EPA_Parse_CardAccess(uint8_t *data,
                            size_t length,
                            pace_version_info_t *pace_info)
{
        size_t index = 0;

        while (index <= length - 2) {
                // determine type of element
                // SET or SEQUENCE
                if (data[index] == 0x31 || data[index] == 0x30) {
                        // enter the set (skip tag + length)
                        index += 2;
                        // check for extended length
                        if ((data[index - 1] & 0x80) != 0) {
                                index += (data[index-1] & 0x7F);
                        }
                }
                // OID
                else if (data[index] == 0x06) {
                        // is this a PACE OID?
                        if (data[index + 1] == 0x0A // length matches
                            && memcmp(data + index + 2,
                                      oid_pace_start,
                                      sizeof(oid_pace_start)) == 0 // content matches
                            && pace_info != NULL)
                        {
                                // first, clear the pace_info struct
                                memset(pace_info, 0, sizeof(pace_version_info_t));
                                memcpy(pace_info->oid, data + index + 2, sizeof(pace_info->oid));
                                // a PACE OID is followed by the version
                                index += data[index + 1] + 2;
                                if (data[index] == 02 && data[index + 1] == 01) {
                                        pace_info->version = data[index + 2];
                                        index += 3;
                                }
                                else {
                                        return index;
                                }
                                // after that there might(!) be the parameter ID
                                if (data[index] == 02 && data[index + 1] == 01) {
                                        pace_info->parameter_id = data[index + 2];
                                        index += 3;
                                }
                        }
                        else {
                                // skip this OID
                                index += 2 + data[index + 1];
                        }
                }
                // if the length is 0, something is wrong
                // TODO: This needs to be extended to support long tags
                else if (data[index + 1] == 0) {
                        return index;
                }
                else {
                        // skip this part
                        // TODO: This needs to be extended to support long tags
                        // TODO: This needs to be extended to support unknown elements with
                        //       a size > 0x7F
                        index += 2 + data[index + 1];
                }
        }

        // TODO: We should check whether we reached the end in error, but for that
        //       we need a better parser (e.g. with states like IN_SET or IN_PACE_INFO)
        return 0;
}

//-----------------------------------------------------------------------------
// Read the file EF.CardAccess and save it into a buffer (at most max_length bytes)
// Returns -1 on failure or the length of the data on success
// TODO: for the moment this sends only 1 APDU regardless of the requested length
//-----------------------------------------------------------------------------
int EPA_Read_CardAccess(uint8_t *buffer, size_t max_length)
{
        // the response APDU of the card
        // since the card doesn't always care for the expected length we send it,
        // we reserve 262 bytes here just to be safe (256-byte APDU + SW + ISO frame)
        uint8_t response_apdu[262];
        int rapdu_length = 0;

        // select the file EF.CardAccess
        rapdu_length = EPA_APDU((uint8_t *)apdu_select_binary_cardaccess,
                                  sizeof(apdu_select_binary_cardaccess),
                                  response_apdu);
        if (rapdu_length < 6
            || response_apdu[rapdu_length - 4] != 0x90
            || response_apdu[rapdu_length - 3] != 0x00)
        {
                DbpString("Failed to select EF.CardAccess!");
                return -1;
        }

        // read the file
        rapdu_length = EPA_APDU((uint8_t *)apdu_read_binary,
                                  sizeof(apdu_read_binary),
                                  response_apdu);
        if (rapdu_length <= 6
            || response_apdu[rapdu_length - 4] != 0x90
            || response_apdu[rapdu_length - 3] != 0x00)
        {
                Dbprintf("Failed to read EF.CardAccess!");
                return -1;
        }

        // copy the content into the buffer
        // length of data available: apdu_length - 4 (ISO frame) - 2 (SW)
        size_t to_copy = rapdu_length - 6;
        to_copy = to_copy < max_length ? to_copy : max_length;
        memcpy(buffer, response_apdu+2, to_copy);
        return to_copy;
}

//-----------------------------------------------------------------------------
// Abort helper function for EPA_PACE_Collect_Nonce
// sets relevant data in ack, sends the response
//-----------------------------------------------------------------------------
static void EPA_PACE_Collect_Nonce_Abort(uint8_t step, int func_return)
{
        // power down the field
        EPA_Finish();

        // send the USB packet
        cmd_send(CMD_ACK,step,func_return,0,0,0);
}

//-----------------------------------------------------------------------------
// Acquire one encrypted PACE nonce
//-----------------------------------------------------------------------------
void EPA_PACE_Collect_Nonce(UsbCommand *c)
{
        /*
         * ack layout:
         *      arg:
         *              1. element
         *           step where the error occured or 0 if no error occured
     *       2. element
     *           return code of the last executed function
         *      d:
         *              Encrypted nonce
         */

        // return value of a function
        int func_return = 0;

        // set up communication
        func_return = EPA_Setup();
        if (func_return != 0) { 
                EPA_PACE_Collect_Nonce_Abort(1, func_return);
                return;
        }

        // read the CardAccess file
        // this array will hold the CardAccess file
        uint8_t card_access[256] = {0};
        int card_access_length = EPA_Read_CardAccess(card_access, 256);
        // the response has to be at least this big to hold the OID
        if (card_access_length < 18) {
                EPA_PACE_Collect_Nonce_Abort(2, card_access_length);
                return;
        }

        // this will hold the PACE info of the card
        pace_version_info_t pace_version_info;
        // search for the PACE OID
        func_return = EPA_Parse_CardAccess(card_access,
                                           card_access_length,
                                           &pace_version_info);
        if (func_return != 0 || pace_version_info.version == 0) {
                EPA_PACE_Collect_Nonce_Abort(3, func_return);
                return;
        }

        // initiate the PACE protocol
        // use the CAN for the password since that doesn't change
        func_return = EPA_PACE_MSE_Set_AT(pace_version_info, 2);

        // now get the nonce
        uint8_t nonce[256] = {0};
        uint8_t requested_size = (uint8_t)c->arg[0];
        func_return = EPA_PACE_Get_Nonce(requested_size, nonce);
        // check if the command succeeded
        if (func_return < 0)
        {
                EPA_PACE_Collect_Nonce_Abort(4, func_return);
                return;
        }

        // all done, return
        EPA_Finish();

        // save received information
        cmd_send(CMD_ACK,0,func_return,0,nonce,func_return);
}

//-----------------------------------------------------------------------------
// Performs the "Get Nonce" step of the PACE protocol and saves the returned
// nonce. The caller is responsible for allocating enough memory to store the
// nonce. Note that the returned size might be less or than or greater than the
// requested size!
// Returns the actual size of the nonce on success or a less-than-zero error
// code on failure.
//-----------------------------------------------------------------------------
int EPA_PACE_Get_Nonce(uint8_t requested_length, uint8_t *nonce)
{
        // build the APDU
        uint8_t apdu[sizeof(apdu_general_authenticate_pace_get_nonce) + 1];
        // copy the constant part
        memcpy(apdu,
               apdu_general_authenticate_pace_get_nonce,
               sizeof(apdu_general_authenticate_pace_get_nonce));
        // append Le (requested length + 2 due to tag/length taking 2 bytes) in RAPDU
        apdu[sizeof(apdu_general_authenticate_pace_get_nonce)] = requested_length + 4;

        // send it
        uint8_t response_apdu[262];
        int send_return = EPA_APDU(apdu,
                                     sizeof(apdu),
                                     response_apdu);
        // check if the command succeeded
        if (send_return < 6
                || response_apdu[send_return - 4] != 0x90
                || response_apdu[send_return - 3] != 0x00)
        {
                return -1;
        }

        // if there is no nonce in the RAPDU, return here
        if (send_return < 10)
        {
                // no error
                return 0;
        }
        // get the actual length of the nonce
        uint8_t nonce_length = response_apdu[5];
        if (nonce_length > send_return - 10)
        {
                nonce_length = send_return - 10;
        }
        // copy the nonce
        memcpy(nonce, response_apdu + 6, nonce_length);

        return nonce_length;
}

//-----------------------------------------------------------------------------
// Initializes the PACE protocol by performing the "MSE: Set AT" step
// Returns 0 on success or a non-zero error code on failure
//-----------------------------------------------------------------------------
int EPA_PACE_MSE_Set_AT(pace_version_info_t pace_version_info, uint8_t password)
{
        // create the MSE: Set AT APDU
        uint8_t apdu[23];
        // the minimum length (will be increased as more data is added)
        size_t apdu_length = 20;
        // copy the constant part
        memcpy(apdu,
               apdu_mse_set_at_start,
               sizeof(apdu_mse_set_at_start));
        // type: OID
        apdu[5] = 0x80;
        // length of the OID
        apdu[6] = sizeof(pace_version_info.oid);
        // copy the OID
        memcpy(apdu + 7,
               pace_version_info.oid,
               sizeof(pace_version_info.oid));
        // type: password
        apdu[17] = 0x83;
        // length: 1
        apdu[18] = 1;
        // password
        apdu[19] = password;
        // if standardized domain parameters are used, copy the ID
        if (pace_version_info.parameter_id != 0) {
                apdu_length += 3;
                // type: domain parameter
                apdu[20] = 0x84;
                // length: 1
                apdu[21] = 1;
                // copy the parameter ID
                apdu[22] = pace_version_info.parameter_id;
        }
        // now set Lc to the actual length
        apdu[4] = apdu_length - 5;
        // send it
        uint8_t response_apdu[6];
        int send_return = EPA_APDU(apdu,
                                     apdu_length,
                                     response_apdu);
        // check if the command succeeded
        if (send_return != 6
                || response_apdu[send_return - 4] != 0x90
                || response_apdu[send_return - 3] != 0x00)
        {
                return 1;
        }
        return 0;
}

//-----------------------------------------------------------------------------
// Perform the PACE protocol by replaying given APDUs
//-----------------------------------------------------------------------------
void EPA_PACE_Replay(UsbCommand *c)
{
        uint32_t timings[sizeof(apdu_lengths_replay) / sizeof(apdu_lengths_replay[0])] = {0};

        // if an APDU has been passed, save it
        if (c->arg[0] != 0) {
                // make sure it's not too big
                if(c->arg[2] > apdus_replay[c->arg[0] - 1].len)
                {
                        cmd_send(CMD_ACK, 1, 0, 0, NULL, 0);
                }
                memcpy(apdus_replay[c->arg[0] - 1].data + c->arg[1],
                   c->d.asBytes,
                   c->arg[2]);
                // save/update APDU length
                if (c->arg[1] == 0) {
                        apdu_lengths_replay[c->arg[0] - 1] = c->arg[2];
                } else {
                        apdu_lengths_replay[c->arg[0] - 1] += c->arg[2];
                }
                cmd_send(CMD_ACK, 0, 0, 0, NULL, 0);
                return;
        }

        // return value of a function
        int func_return;

        // set up communication
        func_return = EPA_Setup();
        if (func_return != 0) {
                EPA_Finish();
                cmd_send(CMD_ACK, 2, func_return, 0, NULL, 0);
                return;
        }

        // increase the timeout (at least some cards really do need this!)/////////////
        // iso14a_set_timeout(0x0003FFFF);

        // response APDU
        uint8_t response_apdu[300] = {0};

        // now replay the data and measure the timings
        for (int i = 0; i < sizeof(apdu_lengths_replay); i++) {
                StartCountUS();
                func_return = EPA_APDU(apdus_replay[i].data,
                                         apdu_lengths_replay[i],
                                         response_apdu);
                timings[i] = GetCountUS();
                // every step but the last one should succeed
                if (i < sizeof(apdu_lengths_replay) - 1
                    && (func_return < 6
                        || response_apdu[func_return - 4] != 0x90
                        || response_apdu[func_return - 3] != 0x00))
                {
                        EPA_Finish();
                        cmd_send(CMD_ACK, 3 + i, func_return, 0, timings, 20);
                        return;
                }
        }
        EPA_Finish();
        cmd_send(CMD_ACK,0,0,0,timings,20);
        return;
}

//-----------------------------------------------------------------------------
// Set up a communication channel (Card Select, PPS)
// Returns 0 on success or a non-zero error code on failure
//-----------------------------------------------------------------------------
int EPA_Setup()
{
        int return_code = 0;
        uint8_t uid[10];
        uint8_t pps_response[3];
        uint8_t pps_response_par[1];
        iso14a_card_select_t card_select_info;

        // first, look for type A cards
        // power up the field
        iso14443a_setup(FPGA_HF_ISO14443A_READER_MOD);
        // select the card
        return_code = iso14443a_select_card(uid, &card_select_info, NULL, true, 0);
        if (return_code == 1) {
        // send the PPS request
        ReaderTransmit((uint8_t *)pps, sizeof(pps), NULL);
        return_code = ReaderReceive(pps_response, pps_response_par);
        if (return_code != 3 || pps_response[0] != 0xD0) {
                return return_code == 0 ? 2 : return_code;
        }
                Dbprintf("ISO 14443 Type A");
                iso_type = 'a';
        return 0;
        }

        // if we're here, there is no type A card, so we look for type B
        // power up the field
        iso14443b_setup();
        // select the card
        return_code = iso14443b_select_card();
        if (return_code == 1) {
                Dbprintf("ISO 14443 Type B");
                iso_type = 'b';
                return 0;
        }
        Dbprintf("No card found.");
        return 1;
}