coelner/pico-hsm
1
0
Fork 0
mirror of https://github.com/polhenarejos/pico-hsm.git synced 2024-09-20 19:30:07 +00:00
Code Issues Packages Projects Releases Wiki Activity
df1f81c61c
pico-hsm/openpgp.c
Pol Henarejos df1f81c61c
Adding ISO 7816 select procedure. 
Signed-off-by: Pol Henarejos <pol.henarejos@cttc.es>
2022-02-03 11:27:10 +01:00

1864 lines
45 KiB
C
Raw Blame History

/*
* openpgp.c -- OpenPGP card protocol support
*
* Copyright (C) 2010, 2011, 2012, 2013, 2014, 2015, 2016, 2017, 2018
* 2019, 2021
* Free Software Initiative of Japan
* Author: NIIBE Yutaka <gniibe@fsij.org>
*
* This file is a part of Gnuk, a GnuPG USB Token implementation.
*
* Gnuk 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.
*
* Gnuk 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.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*
*/
#include <stdint.h>
#include <string.h>
#include "config.h"
#include "gnuk.h"
//#include "sys.h"
#include "status-code.h"
#include "mbedtls/sha256.h"
#include "random.h"
#include "pico/util/queue.h"
#include "pico/multicore.h"
static queue_t *openpgp_comm;
#define USER_PASSWD_MINLEN 6
#define ADMIN_PASSWD_MINLEN 8
#define INS_VERIFY 0x20
#define INS_CHANGE_REFERENCE_DATA 0x24
#define INS_PSO 0x2a
#define INS_RESET_RETRY_COUNTER 0x2c
#define INS_ACTIVATE_FILE 0x44
#define INS_PGP_GENERATE_ASYMMETRIC_KEY_PAIR 0x47
#define INS_EXTERNAL_AUTHENTICATE 0x82
#define INS_GET_CHALLENGE 0x84
#define INS_INTERNAL_AUTHENTICATE 0x88
#define INS_SELECT_FILE 0xa4
#define INS_READ_BINARY 0xb0
#define INS_READ_BINARY_ODD 0xb1
#define INS_GET_DATA 0xca
#define INS_WRITE_BINARY 0xd0
#define INS_UPDATE_BINARY 0xd6
#define INS_PUT_DATA 0xda
#define INS_PUT_DATA_ODD 0xdb /* For key import */
#define INS_TERMINATE_DF 0xe6
static const uint8_t *challenge; /* Random bytes */
static const uint8_t
select_file_TOP_result[] __attribute__ ((aligned (1))) = {
0x00, 0x00, /* unused */
0x00, 0x00, /* number of bytes in this directory: to be filled */
0x3f, 0x00, /* field of selected file: MF, 3f00 */
0x38, /* it's DF */
0xff, /* unused */
0xff, 0x44, 0x44, /* access conditions */
0x01, /* status of the selected file (OK, unblocked) */
0x05, /* number of bytes of data follow */
0x03, /* Features: unused */
0x01, /* number of subdirectories (OpenPGP) */
0x01, /* number of elementary files (SerialNo) */
0x00, /* number of secret codes */
0x00, /* Unused */
0x00, 0x00 /* PIN status: OK, PIN blocked?: No */
};
uint16_t set_res_sw (uint8_t sw1, uint8_t sw2)
{
apdu.sw = (sw1 << 8) | sw2;
return make_uint16_t(sw1, sw2);
}
#define FILE_NONE 0
#define FILE_DF_OPENPGP 1
#define FILE_MF 2
#define FILE_EF_DIR 3
#define FILE_EF_SERIAL_NO 4
#define FILE_EF_UPDATE_KEY_0 5
#define FILE_EF_UPDATE_KEY_1 6
#define FILE_EF_UPDATE_KEY_2 7
#define FILE_EF_UPDATE_KEY_3 8
#define FILE_EF_CH_CERTIFICATE 9
#define FILE_DF_SC_HSM 10
#define FILE_CARD_TERMINATED 255
#define FILE_TYPE_UNKNOWN 0x00
#define FILE_TYPE_DF 0x04
#define FILE_TYPE_INTERNAL_EF 0x03
#define FILE_TYPE_WORKING_EF 0x01
#define FILE_TYPE_BSO 0x10
/* EF structures */
#define FILE_EF_UNKNOWN 0x00
#define FILE_EF_TRANSPARENT 0x01
#define FILE_EF_LINEAR_FIXED 0x02
#define FILE_EF_LINEAR_FIXED_TLV 0x03
#define FILE_EF_LINEAR_VARIABLE 0x04
#define FILE_EF_LINEAR_VARIABLE_TLV 0x05
#define FILE_EF_CYCLIC 0x06
#define FILE_EF_CYCLIC_TLV 0x07
typedef struct pkcs15_entry
{
const uint16_t fid;
const uint8_t parent; //entry number in the whole table!!
const uint8_t *name;
const uint8_t type;
const uint8_t *data; //should include 2 bytes len at begining
const uint8_t ef_structure;
} pkcs15_entry_t;
//puts FCI in the RAPDU
void process_fci(const pkcs15_entry_t *pe) {
uint8_t *p = res_APDU;
uint8_t buf[64];
res_APDU_size = 0;
res_APDU[res_APDU_size++] = 0x6f;
res_APDU[res_APDU_size++] = 0x00; //computed later
res_APDU[res_APDU_size++] = 0x81;
res_APDU[res_APDU_size++] = 2;
if (pe->data)
memcpy(res_APDU+res_APDU_size, pe->data, 2);
else
memset(res_APDU+res_APDU_size, 0, 2);
res_APDU_size += 2;
res_APDU[res_APDU_size++] = 0x82;
res_APDU[res_APDU_size++] = 1;
res_APDU[res_APDU_size] = 0;
if (pe->type == FILE_TYPE_INTERNAL_EF)
res_APDU[res_APDU_size++] |= 0x08;
else if (pe->type == FILE_TYPE_WORKING_EF)
res_APDU[res_APDU_size++] |= pe->ef_structure & 0x7;
else if (pe->type == FILE_TYPE_DF)
res_APDU[res_APDU_size++] |= 0x38;
res_APDU[res_APDU_size++] = 0x83;
res_APDU[res_APDU_size++] = 2;
put_uint16_t(pe->fid, res_APDU+res_APDU_size);
res_APDU_size += 2;
res_APDU[1] = res_APDU_size-2;
}
const pkcs15_entry_t pkcs15_entries[] = {
{ 0x3f00, 0xff, NULL, FILE_TYPE_DF, NULL, 0 }, // MF
{ 0x2f00, 0, NULL, FILE_TYPE_WORKING_EF, NULL, FILE_EF_TRANSPARENT }, //EF.DIR
{ 0x2f01, 0, NULL, FILE_TYPE_WORKING_EF, NULL, FILE_EF_TRANSPARENT }, //EF.ATR
{ 0x2f02, 0, NULL, FILE_TYPE_WORKING_EF, NULL, FILE_EF_TRANSPARENT }, //EF.GDO
{ 0x5015, 0, NULL, FILE_TYPE_DF, NULL, 0 }, //DF.PKCS15
{ 0x5031, 0, NULL, FILE_TYPE_WORKING_EF, NULL, FILE_EF_TRANSPARENT }, //EF.ODF
{ 0x5032, 0, NULL, FILE_TYPE_WORKING_EF, NULL, FILE_EF_TRANSPARENT }, //EF.TokenInfo
{ 0x5033, 0, NULL, FILE_TYPE_WORKING_EF, NULL, FILE_EF_TRANSPARENT }, //EF.UnusedSpace
{ 0x0000, 0, openpgpcard_aid, FILE_TYPE_WORKING_EF, NULL, FILE_EF_TRANSPARENT },
{ 0x0000, 0, sc_hsm_aid, FILE_TYPE_WORKING_EF, NULL, FILE_EF_TRANSPARENT },
{ 0x0000, 0xff, NULL, FILE_TYPE_UNKNOWN, NULL, 0 } //end
};
const pkcs15_entry_t *MF = &pkcs15_entries[0];
const pkcs15_entry_t *pkcs15_last = &pkcs15_entries[sizeof(pkcs15_entries)/sizeof(pkcs15_entry_t)];
extern const pkcs15_entry_t *search_by_fid(const uint16_t, const pkcs15_entry_t *, const uint8_t);
bool card_terminated = false;
#define SPECIFY_EF 0x1
#define SPECIFY_DF 0x2
#define SPECIFY_ANY 0x3
#define MAX_DEPTH 4
bool is_parent(const pkcs15_entry_t *child, const pkcs15_entry_t *parent) {
if (child == parent)
return true;
if (child == MF)
return false;
return is_parent(&pkcs15_entries[child->parent], parent);
}
const pkcs15_entry_t *search_by_name(uint8_t *name, uint16_t namelen) {
for (const pkcs15_entry_t *p = pkcs15_entries; p != pkcs15_last; p++) {
if (p->name && *p->name == apdu.cmd_apdu_data_len && memcmp(p->name+1, name, namelen) == 0) {
return p;
}
}
return NULL;
}
const pkcs15_entry_t *search_by_fid(const uint16_t fid, const pkcs15_entry_t *parent, const uint8_t sp) {
for (const pkcs15_entry_t *p = pkcs15_entries; p != pkcs15_last; p++) {
if (p->fid != 0x0000 && p->fid == fid) {
if (!parent || (parent && is_parent(p, parent))) {
if (!sp || sp == SPECIFY_ANY || (((sp & SPECIFY_EF) && (p->type & FILE_TYPE_INTERNAL_EF)) || ((sp & SPECIFY_DF) && p->type == FILE_TYPE_DF)))
return p;
}
}
}
return NULL;
}
uint8_t make_path_buf(const pkcs15_entry_t *pe, uint8_t *buf, uint8_t buflen, const pkcs15_entry_t *top) {
if (!buflen)
return 0;
if (pe == top) //MF or relative DF
return 0;
put_uint16_t(pe->fid, buf);
return make_path_buf(&pkcs15_entries[pe->parent], buf+2, buflen-2, top)+2;
}
uint8_t make_path(const pkcs15_entry_t *pe, const pkcs15_entry_t *top, uint8_t *path) {
uint8_t buf[MAX_DEPTH*2], *p = path;
put_uint16_t(pe->fid, buf);
uint8_t depth = make_path_buf(&pkcs15_entries[pe->parent], buf+2, sizeof(buf)-2, top)+2;
for (int d = depth-2; d >= 0; d -= 2) {
memcpy(p, buf+d, 2);
p += 2;
}
return depth;
}
const pkcs15_entry_t *search_by_path(const uint8_t *pe_path, uint8_t pathlen, const pkcs15_entry_t *parent) {
uint8_t path[MAX_DEPTH*2];
if (pathlen > sizeof(path)) {
return NULL;
}
for (const pkcs15_entry_t *p = pkcs15_entries; p != pkcs15_last; p++) {
uint8_t depth = make_path(p, parent, path);
if (pathlen == depth && memcmp(path, pe_path, depth))
return p;
}
return NULL;
}
uint8_t file_selection;
const pkcs15_entry_t *currentEF = NULL;
const pkcs15_entry_t *currentDF = NULL;
static void gpg_init (void)
{
const uint8_t *flash_do_start;
const uint8_t *flash_do_end;
flash_do_storage_init (&flash_do_start, &flash_do_end);
if (flash_do_start == NULL)
card_terminated = true;
gpg_data_scan (flash_do_start, flash_do_end);
flash_key_storage_init ();
multicore_lockout_victim_init();
}
static void gpg_fini (void)
{
ac_fini ();
}
#if defined(PINPAD_SUPPORT)
/*
* Let user input PIN string.
* Return length of the string.
* The string itself is in PIN_INPUT_BUFFER.
*/
static int
get_pinpad_input (int msg_code)
{
int r;
led_blink (LED_START_COMMAND);
r = pinpad_getline (msg_code, 8000000);
led_blink (LED_FINISH_COMMAND);
return r;
}
#endif
static void
cmd_verify (queue_t *ccid_comm)
{
int len;
uint8_t p1 = P1 (apdu);
uint8_t p2 = P2 (apdu);
int r;
const uint8_t *pw;
(void)ccid_comm;
DEBUG_INFO (" - VERIFY\r\n");
DEBUG_BYTE (p2);
len = apdu.cmd_apdu_data_len;
pw = apdu.cmd_apdu_data;
if (len == 0)
{
if (p1 == 0)
{ /* This is to examine status. */
if (p2 == 0x81)
r = ac_check_status (AC_PSO_CDS_AUTHORIZED);
else if (p2 == 0x82)
r = ac_check_status (AC_OTHER_AUTHORIZED);
else
r = ac_check_status (AC_ADMIN_AUTHORIZED);
if (r)
/* If authentication done already, return success. */
GPG_SUCCESS ();
else
{ /* If not, return retry counter, encoded. */
r = gpg_pw_get_retry_counter (p2);
set_res_sw (0x63, 0xc0 | (r&0x0f));
}
}
else if (p1 == 0xff)
{ /* Reset the status. */
if (p2 == 0x81)
ac_reset_pso_cds ();
else if (p2 == 0x82)
ac_reset_other ();
else
ac_reset_admin ();
GPG_SUCCESS ();
}
else
GPG_BAD_P1_P2 ();
return;
}
if (gpg_do_kdf_check (len, 1) == 0)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
/* This is real authentication. */
if (p2 == 0x81)
r = verify_pso_cds (pw, len);
else if (p2 == 0x82)
r = verify_other (pw, len);
else
r = verify_admin (pw, len);
if (r < 0)
{
DEBUG_INFO ("failed\r\n");
GPG_SECURITY_FAILURE ();
}
else if (r == 0)
{
DEBUG_INFO ("blocked\r\n");
GPG_SECURITY_AUTH_BLOCKED ();
}
else
{
DEBUG_INFO ("good\r\n");
GPG_SUCCESS ();
}
}
int
gpg_change_keystring (int who_old, const uint8_t *old_ks,
int who_new, const uint8_t *new_ks)
{
int r;
int prv_keys_exist = 0;
r = gpg_do_load_prvkey (GPG_KEY_FOR_SIGNING, who_old, old_ks);
if (r < 0)
return r;
if (r > 0)
prv_keys_exist++;
r = gpg_do_chks_prvkey (GPG_KEY_FOR_SIGNING, who_old, old_ks,
who_new, new_ks);
if (r < 0)
return -2;
r = gpg_do_load_prvkey (GPG_KEY_FOR_DECRYPTION, who_old, old_ks);
if (r < 0)
return r;
if (r > 0)
prv_keys_exist++;
r = gpg_do_chks_prvkey (GPG_KEY_FOR_DECRYPTION, who_old, old_ks,
who_new, new_ks);
if (r < 0)
return -2;
r = gpg_do_load_prvkey (GPG_KEY_FOR_AUTHENTICATION, who_old, old_ks);
if (r < 0)
return r;
if (r > 0)
prv_keys_exist++;
r = gpg_do_chks_prvkey (GPG_KEY_FOR_AUTHENTICATION, who_old, old_ks,
who_new, new_ks);
if (r < 0)
return -2;
if (prv_keys_exist)
return 1;
else
return 0;
}
static void
cmd_change_password (queue_t *ccid_comm)
{
uint8_t old_ks[KEYSTRING_MD_SIZE];
uint8_t new_ks0[KEYSTRING_SIZE];
uint8_t *new_salt = KS_GET_SALT (new_ks0);
int newsalt_len = SALT_SIZE;
uint8_t *new_ks = KS_GET_KEYSTRING (new_ks0);
uint8_t p1 = P1 (apdu); /* 0: change (old+new), 1: exchange (new) */
uint8_t p2 = P2 (apdu);
int len;
uint8_t *pw, *newpw;
int pw_len, newpw_len;
int who = p2 - 0x80;
int who_old;
int r;
int pw3_null = 0;
const uint8_t *salt;
int salt_len;
const uint8_t *ks_pw3;
(void)ccid_comm;
DEBUG_INFO ("Change PW\r\n");
DEBUG_BYTE (who);
len = apdu.cmd_apdu_data_len;
pw = apdu.cmd_apdu_data;
if (p1 != 0)
{
GPG_FUNCTION_NOT_SUPPORTED ();
return;
}
if (gpg_do_kdf_check (len, 2) == 0)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
if (who == BY_USER) /* PW1 */
{
const uint8_t *ks_pw1 = gpg_do_read_simple (NR_DO_KEYSTRING_PW1);
who_old = who;
pw_len = verify_user_0 (AC_PSO_CDS_AUTHORIZED, pw, len, -1, ks_pw1, 0);
if (ks_pw1 == NULL)
{
salt = NULL;
salt_len = 0;
}
else
{
salt = KS_GET_SALT (ks_pw1);
salt_len = SALT_SIZE;
}
if (pw_len < 0)
{
DEBUG_INFO ("permission denied.\r\n");
GPG_SECURITY_FAILURE ();
return;
}
else if (pw_len == 0)
{
DEBUG_INFO ("blocked.\r\n");
GPG_SECURITY_AUTH_BLOCKED ();
return;
}
else
{
newpw = pw + pw_len;
newpw_len = len - pw_len;
ks_pw3 = gpg_do_read_simple (NR_DO_KEYSTRING_PW3);
/* Check length of password */
if ((ks_pw3 == NULL && newpw_len < ADMIN_PASSWD_MINLEN)
|| newpw_len < USER_PASSWD_MINLEN)
{
DEBUG_INFO ("new password length is too short.");
GPG_CONDITION_NOT_SATISFIED ();
return;
}
}
}
else /* PW3 (0x83) */
{
ks_pw3 = gpg_do_read_simple (NR_DO_KEYSTRING_PW3);
pw_len = verify_admin_0 (pw, len, -1, ks_pw3, 0);
if (ks_pw3 == NULL)
{
if (admin_authorized == BY_USER)
{
const uint8_t *ks_pw1 = gpg_do_read_simple (NR_DO_KEYSTRING_PW1);
if (ks_pw1 == NULL)
{
GPG_SECURITY_FAILURE ();
return;
}
salt = KS_GET_SALT (ks_pw1);
salt_len = SALT_SIZE;
}
else
{
salt = NULL;
salt_len = 0;
}
}
else
{
salt = KS_GET_SALT (ks_pw3);
salt_len = SALT_SIZE;
}
if (pw_len < 0)
{
DEBUG_INFO ("permission denied.\r\n");
GPG_SECURITY_FAILURE ();
return;
}
else if (pw_len == 0)
{
DEBUG_INFO ("blocked.\r\n");
GPG_SECURITY_AUTH_BLOCKED ();
return;
}
else
{
newpw = pw + pw_len;
newpw_len = len - pw_len;
if (newpw_len == 0 && admin_authorized == BY_ADMIN)
{
const uint8_t *initial_pw;
gpg_do_get_initial_pw_setting (1, &newpw_len, &initial_pw);
memcpy (newpw, initial_pw, newpw_len);
newsalt_len = 0;
pw3_null = 1;
}
else if (newpw_len < ADMIN_PASSWD_MINLEN)
{
DEBUG_INFO ("new password length is too short.");
GPG_CONDITION_NOT_SATISFIED ();
return;
}
who_old = admin_authorized;
}
}
if (newsalt_len != 0)
random_get_salt (new_salt);
s2k (salt, salt_len, pw, pw_len, old_ks);
s2k (new_salt, newsalt_len, newpw, newpw_len, new_ks);
new_ks0[0] = newpw_len;
r = gpg_change_keystring (who_old, old_ks, who, new_ks);
if (r <= -2)
{
DEBUG_INFO ("memory error.\r\n");
GPG_MEMORY_FAILURE ();
}
else if (r < 0)
{
DEBUG_INFO ("security error.\r\n");
GPG_SECURITY_FAILURE ();
}
else if (r == 0 && who == BY_USER) /* no prvkey */
{
DEBUG_INFO ("user pass change not supported with no keys.\r\n");
GPG_CONDITION_NOT_SATISFIED ();
}
else if (r > 0 && who == BY_USER)
{
/* When it was already admin-less mode, admin_authorized is
* BY_USER. If no PW3 keystring, it's becoming admin-less mode,
* now. For these two cases, we need to reset admin
* authorization status. */
if (admin_authorized == BY_USER)
ac_reset_admin ();
else if (ks_pw3 == NULL)
{
enum kind_of_key kk0;
/* Remove keystrings for BY_ADMIN. */
for (kk0 = 0; kk0 <= GPG_KEY_FOR_AUTHENTICATION; kk0++)
gpg_do_chks_prvkey (kk0, BY_ADMIN, NULL, 0, NULL);
ac_reset_admin ();
}
gpg_do_write_simple (NR_DO_KEYSTRING_PW1, new_ks0, KS_META_SIZE);
ac_reset_pso_cds ();
ac_reset_other ();
DEBUG_INFO ("Changed length of DO_KEYSTRING_PW1.\r\n");
GPG_SUCCESS ();
}
else if (r > 0 && who == BY_ADMIN)
{
if (pw3_null)
gpg_do_write_simple (NR_DO_KEYSTRING_PW3, NULL, 0);
else
gpg_do_write_simple (NR_DO_KEYSTRING_PW3, new_ks0, KS_META_SIZE);
ac_reset_admin ();
DEBUG_INFO ("Changed length of DO_KEYSTRING_PW3.\r\n");
GPG_SUCCESS ();
}
else /* r == 0 && who == BY_ADMIN */ /* no prvkey */
{
if (pw3_null)
gpg_do_write_simple (NR_DO_KEYSTRING_PW3, NULL, 0);
else
{
new_ks0[0] |= PW_LEN_KEYSTRING_BIT;
gpg_do_write_simple (NR_DO_KEYSTRING_PW3, new_ks0, KEYSTRING_SIZE);
}
DEBUG_INFO ("Changed DO_KEYSTRING_PW3.\r\n");
ac_reset_admin ();
GPG_SUCCESS ();
}
}
#ifndef S2KCOUNT
/*
* OpenPGP uses the value 65535 for the key on disk.
* Given the condition that the access to flash ROM is harder than disk,
* that is, the threat model is different, we chose the default value 192.
*/
#define S2KCOUNT 192
#endif
void
s2k (const unsigned char *salt, size_t slen,
const unsigned char *input, size_t ilen, unsigned char output[32])
{
mbedtls_sha256_context ctx;
mbedtls_sha256_init(&ctx);
size_t count = S2KCOUNT;
const uint8_t *unique = unique_device_id ();
mbedtls_sha256_starts (&ctx, 0);
mbedtls_sha256_update (&ctx, unique, 12);
while (count > slen + ilen)
{
if (slen)
mbedtls_sha256_update (&ctx, salt, slen);
mbedtls_sha256_update (&ctx, input, ilen);
count -= slen + ilen;
}
if (count <= slen)
mbedtls_sha256_update (&ctx, salt, count);
else
{
if (slen)
{
mbedtls_sha256_update (&ctx, salt, slen);
count -= slen;
}
mbedtls_sha256_update (&ctx, input, count);
}
mbedtls_sha256_finish (&ctx, output);
mbedtls_sha256_free (&ctx);
}
static void
cmd_reset_user_password (queue_t *ccid_comm)
{
uint8_t p1 = P1 (apdu);
int len;
const uint8_t *pw;
const uint8_t *newpw;
int pw_len, newpw_len;
int r;
uint8_t new_ks0[KEYSTRING_SIZE];
uint8_t *new_ks = KS_GET_KEYSTRING (new_ks0);
uint8_t *new_salt = KS_GET_SALT (new_ks0);
const uint8_t *ks_pw3 = gpg_do_read_simple (NR_DO_KEYSTRING_PW3);
const uint8_t *salt;
int salt_len;
(void)ccid_comm;
DEBUG_INFO ("Reset PW1\r\n");
DEBUG_BYTE (p1);
len = apdu.cmd_apdu_data_len;
pw = apdu.cmd_apdu_data;
if (p1 == 0x00) /* by User with Reseting Code */
{
const uint8_t *ks_rc = gpg_do_read_simple (NR_DO_KEYSTRING_RC);
uint8_t old_ks[KEYSTRING_MD_SIZE];
if (gpg_do_kdf_check (len, 2) == 0)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
if (gpg_pw_locked (PW_ERR_RC))
{
DEBUG_INFO ("blocked.\r\n");
GPG_SECURITY_AUTH_BLOCKED ();
return;
}
if (ks_rc == NULL)
{
DEBUG_INFO ("security error.\r\n");
GPG_SECURITY_FAILURE ();
return;
}
pw_len = ks_rc[0] & PW_LEN_MASK;
salt = KS_GET_SALT (ks_rc);
salt_len = SALT_SIZE;
newpw = pw + pw_len;
newpw_len = len - pw_len;
/* Check length of new password */
if ((ks_pw3 == NULL && newpw_len < ADMIN_PASSWD_MINLEN)
|| newpw_len < USER_PASSWD_MINLEN)
{
DEBUG_INFO ("new password length is too short.");
GPG_CONDITION_NOT_SATISFIED ();
return;
}
random_get_salt (new_salt);
s2k (salt, salt_len, pw, pw_len, old_ks);
s2k (new_salt, SALT_SIZE, newpw, newpw_len, new_ks);
new_ks0[0] = newpw_len;
r = gpg_change_keystring (BY_RESETCODE, old_ks, BY_USER, new_ks);
if (r <= -2)
{
DEBUG_INFO ("memory error.\r\n");
GPG_MEMORY_FAILURE ();
}
else if (r < 0)
{
DEBUG_INFO ("failed.\r\n");
gpg_pw_increment_err_counter (PW_ERR_RC);
GPG_SECURITY_FAILURE ();
}
else if (r == 0)
{
DEBUG_INFO ("user pass change not supported with no keys.\r\n");
GPG_CONDITION_NOT_SATISFIED ();
}
else
{
DEBUG_INFO ("done.\r\n");
gpg_do_write_simple (NR_DO_KEYSTRING_PW1, new_ks0, KS_META_SIZE);
ac_reset_pso_cds ();
ac_reset_other ();
if (admin_authorized == BY_USER)
ac_reset_admin ();
gpg_pw_reset_err_counter (PW_ERR_RC);
gpg_pw_reset_err_counter (PW_ERR_PW1);
GPG_SUCCESS ();
}
}
else /* by Admin (p1 == 0x02) */
{
const uint8_t *old_ks = keystring_md_pw3;
if (!ac_check_status (AC_ADMIN_AUTHORIZED))
{
DEBUG_INFO ("permission denied.\r\n");
GPG_SECURITY_FAILURE ();
return;
}
if (gpg_do_kdf_check (len, 1) == 0)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
newpw_len = len;
newpw = pw;
/* Check length of new password */
if ((ks_pw3 == NULL && newpw_len < ADMIN_PASSWD_MINLEN)
|| newpw_len < USER_PASSWD_MINLEN)
{
DEBUG_INFO ("new password length is too short.");
GPG_CONDITION_NOT_SATISFIED ();
return;
}
random_get_salt (new_salt);
s2k (new_salt, SALT_SIZE, newpw, newpw_len, new_ks);
new_ks0[0] = newpw_len;
r = gpg_change_keystring (admin_authorized, old_ks, BY_USER, new_ks);
if (r <= -2)
{
DEBUG_INFO ("memory error.\r\n");
GPG_MEMORY_FAILURE ();
}
else if (r < 0)
{
DEBUG_INFO ("security error.\r\n");
GPG_SECURITY_FAILURE ();
}
else if (r == 0)
{
DEBUG_INFO ("user pass change not supported with no keys.\r\n");
GPG_CONDITION_NOT_SATISFIED ();
}
else
{
DEBUG_INFO ("done.\r\n");
gpg_do_write_simple (NR_DO_KEYSTRING_PW1, new_ks0, KS_META_SIZE);
ac_reset_pso_cds ();
ac_reset_other ();
if (admin_authorized == BY_USER)
ac_reset_admin ();
gpg_pw_reset_err_counter (PW_ERR_PW1);
GPG_SUCCESS ();
}
}
}
static void
cmd_put_data (queue_t *ccid_comm)
{
uint8_t *data;
uint16_t tag;
int len;
(void)ccid_comm;
DEBUG_INFO (" - PUT DATA\r\n");
tag = ((P1 (apdu)<<8) | P2 (apdu));
len = apdu.cmd_apdu_data_len;
data = apdu.cmd_apdu_data;
gpg_do_put_data (tag, data, len);
}
static void
cmd_pgp_gakp (queue_t *ccid_comm)
{
(void)ccid_comm;
DEBUG_INFO (" - Generate Asymmetric Key Pair\r\n");
DEBUG_BYTE (P1 (apdu));
if (P1 (apdu) == 0x81)
/* Get public key */
gpg_do_public_key (apdu.cmd_apdu_data[0]);
else
{
if (!ac_check_status (AC_ADMIN_AUTHORIZED))
GPG_SECURITY_FAILURE ();
#ifdef KDF_DO_REQUIRED
else if (!gpg_do_kdf_check (0, 0))
GPG_CONDITION_NOT_SATISFIED ();
#endif
else
gpg_do_keygen (&apdu.cmd_apdu_data[0]);
}
}
#ifdef FLASH_UPGRADE_SUPPORT
const uint8_t *
gpg_get_firmware_update_key (uint8_t keyno)
{
extern uint8_t _updatekey_store[1024];
const uint8_t *p;
p = _updatekey_store + keyno * FIRMWARE_UPDATE_KEY_CONTENT_LEN;
return p;
}
#endif
#ifdef CERTDO_SUPPORT
#define FILEID_CH_CERTIFICATE_IS_VALID 1
#else
#define FILEID_CH_CERTIFICATE_IS_VALID 0
#endif
static void
cmd_read_binary (queue_t *ccid_comm)
{
int is_short_EF = (P1 (apdu) & 0x80) != 0;
uint8_t file_id;
uint16_t offset;
(void)ccid_comm;
DEBUG_INFO (" - Read binary\r\n");
if (is_short_EF)
file_id = (P1 (apdu) & 0x1f);
else
file_id = file_selection - FILE_EF_SERIAL_NO + FILEID_SERIAL_NO;
if (is_short_EF)
{
file_selection = file_id - FILEID_SERIAL_NO + FILE_EF_SERIAL_NO;
offset = P2 (apdu);
}
else
offset = (P1 (apdu) << 8) | P2 (apdu);
if (file_id == FILEID_SERIAL_NO)
{
if (offset != 0)
GPG_BAD_P1_P2 ();
else
{
gpg_do_get_data (0x004f, 1); /* Get AID... */
res_APDU[0] = 0x5a; /* ... and overwrite the first byte of data. */
}
return;
}
#ifdef FLASH_UPGRADE_SUPPORT
else if (file_id >= FILEID_UPDATE_KEY_0 && file_id <= FILEID_UPDATE_KEY_3)
{
if (offset != 0)
GPG_MEMORY_FAILURE ();
else
{
const uint8_t *p;
p = gpg_get_firmware_update_key (file_id - FILEID_UPDATE_KEY_0);
res_APDU_size = FIRMWARE_UPDATE_KEY_CONTENT_LEN;
memcpy (res_APDU, p, FIRMWARE_UPDATE_KEY_CONTENT_LEN);
GPG_SUCCESS ();
}
}
#endif
#if defined(CERTDO_SUPPORT)
else if (file_id == FILEID_CH_CERTIFICATE)
{
const uint8_t *p;
uint16_t len = 256;
p = ch_certificate_start;
if (offset >= FLASH_CH_CERTIFICATE_SIZE)
GPG_MEMORY_FAILURE ();
else
{
if (offset + len >= FLASH_CH_CERTIFICATE_SIZE)
len = FLASH_CH_CERTIFICATE_SIZE - offset;
res_APDU_size = len;
memcpy (res_APDU, p + offset, len);
GPG_SUCCESS ();
}
}
#endif
else
{
GPG_NO_FILE ();
return;
}
}
void select_file(const pkcs15_entry_t *pe) {
if (!pe)
{
currentDF = MF;
currentEF = NULL;
}
else if (pe->type & FILE_TYPE_INTERNAL_EF) {
currentEF = pe;
currentDF = &pkcs15_entries[pe->parent];
}
else {
currentDF = pe;
}
}
static uint16_t cmd_select_file (queue_t *ccid_comm)
{
(void)ccid_comm;
uint8_t p1 = P1(apdu);
uint8_t p2 = P2(apdu);
const pkcs15_entry_t *pe = NULL;
uint16_t fid = 0x0;
// Only "first or only occurence" supported
//if ((p2 & 0xF3) != 0x00) {
// return SW_INCORRECT_P1P2();
//}
if (apdu.cmd_apdu_data_len >= 2)
fid = get_uint16_t(apdu.cmd_apdu_data, 0);
if (p1 == 0x0) { //Select MF, DF or EF - File identifier or absent
if (apdu.cmd_apdu_data_len == 0) {
pe = MF;
ac_fini();
}
else if (apdu.cmd_apdu_data_len == 2) {
if (!(pe = search_by_fid(fid, NULL, SPECIFY_ANY))) {
return GPG_NO_FILE ();
}
}
}
else if (p1 == 0x01) { //Select child DF - DF identifier
if (!(pe = search_by_fid(fid, currentDF, SPECIFY_DF))) {
return GPG_NO_FILE ();
}
}
else if (p1 == 0x02) { //Select EF under the current DF - EF identifier
if (!(pe = search_by_fid(fid, currentDF, SPECIFY_EF))) {
return GPG_NO_FILE ();
}
}
else if (p1 == 0x03) { //Select parent DF of the current DF - Absent
if (apdu.cmd_apdu_data_len != 0)
return GPG_NO_FILE ();
}
else if (p1 == 0x04) { //Select by DF name - e.g., [truncated] application identifier
if (!(pe = search_by_name(apdu.cmd_apdu_data, apdu.cmd_apdu_data_len))) {
return GPG_NO_FILE ();
}
if (card_terminated) {
return GPG_APPLICATION_TERMINATED ();
}
}
else if (p1 == 0x08) { //Select from the MF - Path without the MF identifier
if (!(pe = search_by_path(apdu.cmd_apdu_data, apdu.cmd_apdu_data_len, MF))) {
return GPG_NO_FILE ();
}
}
else if (p1 == 0x09) { //Select from the current DF - Path without the current DF identifier
if (!(pe = search_by_path(apdu.cmd_apdu_data, apdu.cmd_apdu_data_len, currentDF))) {
return GPG_NO_FILE ();
}
}
if ((p2 & 0xfc) == 0x00 || (p2 & 0xfc) == 0x04) {
process_fci(pe);
}
else
return SW_INCORRECT_P1P2();
select_file(pe);
return GPG_SUCCESS ();
}
static void
cmd_get_data (queue_t *ccid_comm)
{
uint16_t tag = ((P1 (apdu)<<8) | P2 (apdu));
(void)ccid_comm;
DEBUG_INFO (" - Get Data\r\n");
gpg_do_get_data (tag, 0);
}
#define ECDSA_HASH_LEN 32
#define ECDSA_SIGNATURE_LENGTH 64
#define EDDSA_HASH_LEN_MAX 256
#define ED25519_SIGNATURE_LENGTH 64
#define ED448_SIGNATURE_LENGTH 114
#define ECC_CIPHER_DO_HEADER_SIZE 7
static void
cmd_pso (queue_t *ccid_comm)
{
int len = apdu.cmd_apdu_data_len;
int r = -1;
int attr;
int pubkey_len;
unsigned int result_len = 0;
int cs;
DEBUG_INFO (" - PSO: ");
DEBUG_WORD ((uint32_t)&r);
DEBUG_BINARY (apdu.cmd_apdu_data, apdu.cmd_apdu_data_len);
DEBUG_SHORT (len);
if (P1 (apdu) == 0x9e && P2 (apdu) == 0x9a)
{
attr = gpg_get_algo_attr (GPG_KEY_FOR_SIGNING);
pubkey_len = gpg_get_algo_attr_key_size (GPG_KEY_FOR_SIGNING,
GPG_KEY_PUBLIC);
if (!ac_check_status (AC_PSO_CDS_AUTHORIZED))
{
DEBUG_INFO ("security error.");
GPG_SECURITY_FAILURE ();
return;
}
#ifdef ACKBTN_SUPPORT
if (gpg_do_get_uif (GPG_KEY_FOR_SIGNING))
eventflag_signal (ccid_comm, EV_EXEC_ACK_REQUIRED);
#endif
if (attr == ALGO_RSA2K || attr == ALGO_RSA4K)
{
/* Check size of digestInfo */
if (len != 34 /* MD5 */
&& len != 35 /* SHA1 / RIPEMD-160 */
&& len != 47 /* SHA224 */
&& len != 51 /* SHA256 */
&& len != 67 /* SHA384 */
&& len != 83) /* SHA512 */
{
DEBUG_INFO (" wrong length");
GPG_CONDITION_NOT_SATISFIED ();
return;
}
DEBUG_BINARY (kd[GPG_KEY_FOR_SIGNING].data, pubkey_len);
result_len = pubkey_len;
r = rsa_sign (apdu.cmd_apdu_data, res_APDU, len,
&kd[GPG_KEY_FOR_SIGNING], pubkey_len);
}
else if (attr == ALGO_SECP256K1)
{
/* ECDSA with p256r1/p256k1 for signature */
if (len != ECDSA_HASH_LEN)
{
DEBUG_INFO (" wrong length");
GPG_CONDITION_NOT_SATISFIED ();
return;
}
//cs = chopstx_setcancelstate (0);
result_len = ECDSA_SIGNATURE_LENGTH;
r = ecdsa_sign_p256k1 (apdu.cmd_apdu_data, res_APDU,
kd[GPG_KEY_FOR_SIGNING].data);
//chopstx_setcancelstate (cs);
}
else if (attr == ALGO_ED25519)
{
uint32_t output[ED25519_SIGNATURE_LENGTH/4]; /* Require 4-byte alignment. */
//cs = chopstx_setcancelstate (0);
result_len = ED25519_SIGNATURE_LENGTH;
r = eddsa_sign_25519 (apdu.cmd_apdu_data, len, output,
kd[GPG_KEY_FOR_SIGNING].data,
kd[GPG_KEY_FOR_SIGNING].data+32,
kd[GPG_KEY_FOR_SIGNING].pubkey);
//chopstx_setcancelstate (cs);
memcpy (res_APDU, output, ED25519_SIGNATURE_LENGTH);
}
else if (attr == ALGO_ED448)
{
//cs = chopstx_setcancelstate (0);
result_len = ED448_SIGNATURE_LENGTH;
r = ed448_sign (res_APDU, apdu.cmd_apdu_data, len,
kd[GPG_KEY_FOR_SIGNING].data,
kd[GPG_KEY_FOR_SIGNING].data+57,
kd[GPG_KEY_FOR_SIGNING].pubkey);
//chopstx_setcancelstate (cs);
}
else
{
DEBUG_INFO ("unknown algo.");
GPG_FUNCTION_NOT_SUPPORTED ();
return;
}
if (r == 0)
{
res_APDU_size = result_len;
gpg_increment_digital_signature_counter ();
}
else /* Failure */
ac_reset_pso_cds ();
}
else if (P1 (apdu) == 0x80 && P2 (apdu) == 0x86)
{
attr = gpg_get_algo_attr (GPG_KEY_FOR_DECRYPTION);
pubkey_len = gpg_get_algo_attr_key_size (GPG_KEY_FOR_DECRYPTION,
GPG_KEY_PUBLIC);
DEBUG_BINARY (kd[GPG_KEY_FOR_DECRYPTION].data, pubkey_len);
if (!ac_check_status (AC_OTHER_AUTHORIZED))
{
DEBUG_INFO ("security error.");
GPG_SECURITY_FAILURE ();
return;
}
#ifdef ACKBTN_SUPPORT
if (gpg_do_get_uif (GPG_KEY_FOR_DECRYPTION))
eventflag_signal (ccid_comm, EV_EXEC_ACK_REQUIRED);
#else
(void)ccid_comm;
#endif
if (attr == ALGO_RSA2K || attr == ALGO_RSA4K)
{
/* Skip padding 0x00 */
len--;
if (len != pubkey_len)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
r = rsa_decrypt (apdu.cmd_apdu_data+1, res_APDU, len,
&kd[GPG_KEY_FOR_DECRYPTION], &result_len);
}
else if (attr == ALGO_SECP256K1)
{
int header = ECC_CIPHER_DO_HEADER_SIZE;
/* Format is in big endian MPI: 04 || x || y */
if (len != 65 + ECC_CIPHER_DO_HEADER_SIZE
|| apdu.cmd_apdu_data[header] != 0x04)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
//cs = chopstx_setcancelstate (0);
result_len = 65;
r = ecdh_decrypt_p256k1 (apdu.cmd_apdu_data + header, res_APDU,
kd[GPG_KEY_FOR_DECRYPTION].data);
//chopstx_setcancelstate (cs);
}
else if (attr == ALGO_CURVE25519)
{
int header = ECC_CIPHER_DO_HEADER_SIZE;
if (len != 32 + ECC_CIPHER_DO_HEADER_SIZE)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
//cs = chopstx_setcancelstate (0);
result_len = 32;
r = ecdh_decrypt_curve25519 (apdu.cmd_apdu_data + header, res_APDU,
kd[GPG_KEY_FOR_DECRYPTION].data);
//chopstx_setcancelstate (cs);
}
else if (attr == ALGO_X448)
{
int header = ECC_CIPHER_DO_HEADER_SIZE;
if (len != 56 + ECC_CIPHER_DO_HEADER_SIZE)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
//cs = chopstx_setcancelstate (0);
result_len = 56;
r = ecdh_decrypt_x448 (res_APDU, apdu.cmd_apdu_data + header,
kd[GPG_KEY_FOR_DECRYPTION].data);
//chopstx_setcancelstate (cs);
}
else
{
DEBUG_INFO ("unknown algo.");
GPG_FUNCTION_NOT_SUPPORTED ();
return;
}
if (r == 0)
res_APDU_size = result_len;
}
if (r < 0)
{
DEBUG_INFO (" - ??");
DEBUG_BYTE (P1 (apdu));
DEBUG_INFO (" - ??");
DEBUG_BYTE (P2 (apdu));
GPG_ERROR ();
}
DEBUG_INFO ("PSO done.\r\n");
}
#define MAX_RSA_DIGEST_INFO_LEN 102 /* 40% */
static void
cmd_internal_authenticate (queue_t *ccid_comm)
{
int attr = gpg_get_algo_attr (GPG_KEY_FOR_AUTHENTICATION);
int pubkey_len = gpg_get_algo_attr_key_size (GPG_KEY_FOR_AUTHENTICATION,
GPG_KEY_PUBLIC);
int len = apdu.cmd_apdu_data_len;
int r = -1;
unsigned int result_len = 0;
int cs;
DEBUG_INFO (" - INTERNAL AUTHENTICATE\r\n");
if (P1 (apdu) != 0x00 || P2 (apdu) != 0x00)
{
DEBUG_INFO (" - ??");
DEBUG_BYTE (P1 (apdu));
DEBUG_INFO (" - ??");
DEBUG_BYTE (P2 (apdu));
GPG_CONDITION_NOT_SATISFIED ();
return;
}
DEBUG_SHORT (len);
if (!ac_check_status (AC_OTHER_AUTHORIZED))
{
DEBUG_INFO ("security error.");
GPG_SECURITY_FAILURE ();
return;
}
#ifdef ACKBTN_SUPPORT
if (gpg_do_get_uif (GPG_KEY_FOR_AUTHENTICATION))
eventflag_signal (ccid_comm, EV_EXEC_ACK_REQUIRED);
#else
(void)ccid_comm;
#endif
if (attr == ALGO_RSA2K || attr == ALGO_RSA4K)
{
if (len > MAX_RSA_DIGEST_INFO_LEN)
{
DEBUG_INFO ("input is too long.");
GPG_CONDITION_NOT_SATISFIED ();
return;
}
result_len = pubkey_len;
r = rsa_sign (apdu.cmd_apdu_data, res_APDU, len,
&kd[GPG_KEY_FOR_AUTHENTICATION], pubkey_len);
}
else if (attr == ALGO_SECP256K1)
{
if (len != ECDSA_HASH_LEN)
{
DEBUG_INFO ("wrong hash length.");
GPG_CONDITION_NOT_SATISFIED ();
return;
}
//cs = chopstx_setcancelstate (0);
result_len = ECDSA_SIGNATURE_LENGTH;
r = ecdsa_sign_p256k1 (apdu.cmd_apdu_data, res_APDU,
kd[GPG_KEY_FOR_AUTHENTICATION].data);
//chopstx_setcancelstate (cs);
}
else if (attr == ALGO_ED25519)
{
uint32_t output[ED25519_SIGNATURE_LENGTH/4]; /* Require 4-byte alignment. */
//cs = chopstx_setcancelstate (0);
result_len = ED25519_SIGNATURE_LENGTH;
r = eddsa_sign_25519 (apdu.cmd_apdu_data, len, output,
kd[GPG_KEY_FOR_AUTHENTICATION].data,
kd[GPG_KEY_FOR_AUTHENTICATION].data+32,
kd[GPG_KEY_FOR_AUTHENTICATION].pubkey);
//chopstx_setcancelstate (cs);
memcpy (res_APDU, output, ED25519_SIGNATURE_LENGTH);
}
else if (attr == ALGO_ED448)
{
//cs = chopstx_setcancelstate (0);
result_len = ED448_SIGNATURE_LENGTH;
r = ed448_sign (res_APDU, apdu.cmd_apdu_data, len,
kd[GPG_KEY_FOR_AUTHENTICATION].data,
kd[GPG_KEY_FOR_AUTHENTICATION].data+57,
kd[GPG_KEY_FOR_AUTHENTICATION].pubkey);
//chopstx_setcancelstate (cs);
}
if (r == 0)
res_APDU_size = result_len;
else
GPG_ERROR ();
DEBUG_INFO ("INTERNAL AUTHENTICATE done.\r\n");
}
#define MBD_OPRATION_WRITE 0
#define MBD_OPRATION_UPDATE 1
static void
modify_binary (uint8_t op, uint8_t p1, uint8_t p2, int len)
{
uint8_t file_id;
uint16_t offset;
int is_short_EF = (p1 & 0x80) != 0;
int r;
if (!ac_check_status (AC_ADMIN_AUTHORIZED))
{
DEBUG_INFO ("security error.");
GPG_SECURITY_FAILURE ();
return;
}
if (is_short_EF)
file_id = (p1 & 0x1f);
else
file_id = file_selection - FILE_EF_SERIAL_NO + FILEID_SERIAL_NO;
if (!FILEID_CH_CERTIFICATE_IS_VALID && file_id == FILEID_CH_CERTIFICATE)
{
GPG_NO_FILE ();
return;
}
if (op == MBD_OPRATION_UPDATE && file_id != FILEID_CH_CERTIFICATE)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
if (file_id > FILEID_CH_CERTIFICATE)
{
GPG_NO_FILE ();
return;
}
if (is_short_EF)
{
file_selection = file_id - FILEID_SERIAL_NO + FILE_EF_SERIAL_NO;
offset = p2;
if (op == MBD_OPRATION_UPDATE)
{
r = flash_erase_binary (file_id);
if (r < 0)
{
DEBUG_INFO ("memory error.\r\n");
GPG_MEMORY_FAILURE ();
return;
}
}
}
else
offset = (p1 << 8) | p2;
DEBUG_SHORT (len);
DEBUG_SHORT (offset);
if (file_id == FILEID_CH_CERTIFICATE && (len&1))
/* It's OK the size of last write is odd. */
apdu.cmd_apdu_data[len++] = 0xff;
r = flash_write_binary (file_id, apdu.cmd_apdu_data, len, offset);
if (r < 0)
{
DEBUG_INFO ("memory error.\r\n");
GPG_MEMORY_FAILURE ();
return;
}
#ifdef FLASH_UPGRADE_SUPPORT
if (file_id >= FILEID_UPDATE_KEY_0 && file_id <= FILEID_UPDATE_KEY_3
&& len == 0 && offset == 0)
{
int i;
const uint8_t *p;
for (i = 0; i < 4; i++)
{
p = gpg_get_firmware_update_key (i);
if (p[0] != 0x00 || p[1] != 0x00) /* still valid */
break;
}
if (i == 4) /* all update keys are removed */
{
p = gpg_get_firmware_update_key (0);
flash_erase_page ((uintptr_t)p);
}
}
#endif
GPG_SUCCESS ();
}
#if defined(CERTDO_SUPPORT)
static void
cmd_update_binary (queue_t *ccid_comm)
{
int len = apdu.cmd_apdu_data_len;
(void)ccid_comm;
DEBUG_INFO (" - UPDATE BINARY\r\n");
modify_binary (MBD_OPRATION_UPDATE, P1 (apdu), P2 (apdu), len);
DEBUG_INFO ("UPDATE BINARY done.\r\n");
}
#endif
static void
cmd_write_binary (queue_t *ccid_comm)
{
int len = apdu.cmd_apdu_data_len;
(void)ccid_comm;
DEBUG_INFO (" - WRITE BINARY\r\n");
modify_binary (MBD_OPRATION_WRITE, P1 (apdu), P2 (apdu), len);
DEBUG_INFO ("WRITE BINARY done.\r\n");
}
#ifdef FLASH_UPGRADE_SUPPORT
static void
cmd_external_authenticate (queue_t *ccid_comm)
{
const uint8_t *pubkey;
const uint8_t *signature = apdu.cmd_apdu_data;
int len = apdu.cmd_apdu_data_len;
uint8_t keyno = P2 (apdu);
int r;
(void)ccid_comm;
DEBUG_INFO (" - EXTERNAL AUTHENTICATE\r\n");
if (keyno >= 4)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
pubkey = gpg_get_firmware_update_key (keyno);
if (len != 256
|| (pubkey[0] == 0xff && pubkey[1] == 0xff) /* not registered */
|| (pubkey[0] == 0x00 && pubkey[1] == 0x00) /* removed */)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
r = rsa_verify (pubkey, FIRMWARE_UPDATE_KEY_CONTENT_LEN,
challenge, signature);
random_bytes_free (challenge);
challenge = NULL;
if (r < 0)
{
GPG_SECURITY_FAILURE ();
return;
}
eventflag_signal (openpgp_comm, EV_EXIT); /* signal to self. */
set_res_sw (0xff, 0xff);
DEBUG_INFO ("EXTERNAL AUTHENTICATE done.\r\n");
}
#endif
static void
cmd_get_challenge (queue_t *ccid_comm)
{
int len = apdu.expected_res_size;
(void)ccid_comm;
DEBUG_INFO (" - GET CHALLENGE\r\n");
if (len > CHALLENGE_LEN)
{
GPG_CONDITION_NOT_SATISFIED ();
return;
}
else if (len == 0)
/* Le is not specified. Return full-sized challenge by GET_RESPONSE. */
len = CHALLENGE_LEN;
if (challenge)
random_bytes_free (challenge);
#ifdef ACKBTN_SUPPORT
if (gpg_do_get_uif (GPG_KEY_FOR_SIGNING)
|| gpg_do_get_uif (GPG_KEY_FOR_DECRYPTION)
|| gpg_do_get_uif (GPG_KEY_FOR_AUTHENTICATION))
eventflag_signal (ccid_comm, EV_EXEC_ACK_REQUIRED);
#endif
challenge = random_bytes_get ();
memcpy (res_APDU, challenge, len);
res_APDU_size = len;
GPG_SUCCESS ();
DEBUG_INFO ("GET CHALLENGE done.\r\n");
}
#ifdef LIFE_CYCLE_MANAGEMENT_SUPPORT
static void
cmd_activate_file (queue_t *ccid_comm)
{
(void)ccid_comm;
if (file_selection != FILE_CARD_TERMINATED)
{
GPG_NO_RECORD ();
return;
}
flash_activate ();
//file_selection = FILE_DF_OPENPGP;
file_selection = FILE_DF_SC_HSM;
GPG_SUCCESS ();
}
static void
cmd_terminate_df (queue_t *ccid_comm)
{
const uint8_t *ks_pw3;
uint8_t p1 = P1 (apdu);
uint8_t p2 = P2 (apdu);
(void)ccid_comm;
//if (file_selection != FILE_DF_OPENPGP)
if (file_selection != FILE_DF_SC_HSM)
{
GPG_NO_RECORD ();
return;
}
if (p1 != 0 || p2 != 0)
{
GPG_BAD_P1_P2();
return;
}
if (apdu.cmd_apdu_data_len != 0)
{
GPG_WRONG_LENGTH();
return;
}
ks_pw3 = gpg_do_read_simple (NR_DO_KEYSTRING_PW3);
if (!ac_check_status (AC_ADMIN_AUTHORIZED)
&& !((ks_pw3 && gpg_pw_locked (PW_ERR_PW3))
|| (ks_pw3 == NULL && gpg_pw_locked (PW_ERR_PW1))))
{
/* Only allow the case admin authorized, or, admin pass is locked. */
GPG_SECURITY_FAILURE();
return;
}
ac_reset_admin ();
ac_reset_pso_cds ();
ac_reset_other ();
gpg_do_terminate ();
flash_terminate ();
file_selection = FILE_CARD_TERMINATED;
GPG_SUCCESS ();
}
#endif
struct command
{
uint8_t command;
void (*cmd_handler) (queue_t *ccid_comm);
};
const struct command cmds[] = {
{ INS_VERIFY, cmd_verify },
{ INS_CHANGE_REFERENCE_DATA, cmd_change_password },
{ INS_PSO, cmd_pso },
{ INS_RESET_RETRY_COUNTER, cmd_reset_user_password },
#ifdef LIFE_CYCLE_MANAGEMENT_SUPPORT
{ INS_ACTIVATE_FILE, cmd_activate_file },
#endif
{ INS_PGP_GENERATE_ASYMMETRIC_KEY_PAIR, cmd_pgp_gakp },
#ifdef FLASH_UPGRADE_SUPPORT
{ INS_EXTERNAL_AUTHENTICATE, /* Not in OpenPGP card protocol */
cmd_external_authenticate },
#endif
{ INS_GET_CHALLENGE, cmd_get_challenge }, /* Not in OpenPGP card protocol */
{ INS_INTERNAL_AUTHENTICATE, cmd_internal_authenticate },
{ INS_SELECT_FILE, cmd_select_file },
{ INS_READ_BINARY, cmd_read_binary }, /* Not in OpenPGP card protocol */
{ INS_READ_BINARY_ODD, cmd_read_binary }, /* Not in OpenPGP card protocol */
{ INS_GET_DATA, cmd_get_data },
{ INS_WRITE_BINARY, cmd_write_binary}, /* Not in OpenPGP card protocol */
#if defined(CERTDO_SUPPORT)
{ INS_UPDATE_BINARY, cmd_update_binary }, /* Not in OpenPGP card protocol */
#endif
{ INS_PUT_DATA, cmd_put_data },
{ INS_PUT_DATA_ODD, cmd_put_data },
#ifdef LIFE_CYCLE_MANAGEMENT_SUPPORT
{ INS_TERMINATE_DF, cmd_terminate_df},
#endif
};
#define NUM_CMDS ((int)(sizeof (cmds) / sizeof (struct command)))
static void
process_command_apdu (queue_t *ccid_comm)
{
int i;
uint8_t cmd = INS (apdu);
for (i = 0; i < NUM_CMDS; i++)
if (cmds[i].command == cmd)
break;
DEBUG_BYTE(i);
if (i < NUM_CMDS)
{
if (file_selection == FILE_CARD_TERMINATED
&& cmd != INS_SELECT_FILE && cmd != INS_ACTIVATE_FILE
&& cmd != INS_GET_CHALLENGE && cmd != INS_EXTERNAL_AUTHENTICATE)
GPG_APPLICATION_TERMINATED ();
else if (file_selection != FILE_DF_SC_HSM
&& cmd != INS_SELECT_FILE && cmd != INS_ACTIVATE_FILE
&& cmd != INS_GET_CHALLENGE && cmd != INS_EXTERNAL_AUTHENTICATE
&& cmd != INS_WRITE_BINARY && cmd != INS_UPDATE_BINARY
&& cmd != INS_READ_BINARY && cmd != INS_READ_BINARY_ODD)
GPG_NO_RECORD ();
else
{
cmds[i].cmd_handler (ccid_comm);
}
}
else
{
DEBUG_INFO (" - ??");
DEBUG_BYTE (cmd);
GPG_NO_INS ();
}
}
void openpgp_card_thread ()
{
queue_t *ccid_comm = (queue_t *)multicore_fifo_pop_blocking();
openpgp_comm = (queue_t *)multicore_fifo_pop_blocking();
gpg_init ();
while (1)
{
#if defined(PINPAD_SUPPORT)
int len, pw_len, newpw_len;
#endif
uint32_t m;
queue_remove_blocking(openpgp_comm, &m);
DEBUG_INFO ("GPG!: ");
if (m == EV_VERIFY_CMD_AVAILABLE)
{
#if defined(PINPAD_SUPPORT)
if (INS (apdu) != INS_VERIFY)
{
GPG_CONDITION_NOT_SATISFIED ();
goto done;
}
pw_len = get_pinpad_input (PIN_INPUT_CURRENT);
if (pw_len < 0)
{
GPG_ERROR ();
goto done;
}
memcpy (apdu.cmd_apdu_data, pin_input_buffer, pw_len);
apdu.cmd_apdu_data_len = pw_len;
#else
GPG_ERROR ();
goto done;
#endif
}
else if (m == EV_MODIFY_CMD_AVAILABLE)
{
#if defined(PINPAD_SUPPORT)
uint8_t bConfirmPIN = apdu.cmd_apdu_data[0];
uint8_t *p = apdu.cmd_apdu_data;
if (INS (apdu) != INS_CHANGE_REFERENCE_DATA
&& INS (apdu) != INS_RESET_RETRY_COUNTER
&& INS (apdu) != INS_PUT_DATA)
{
GPG_CONDITION_NOT_SATISFIED ();
goto done;
}
if ((bConfirmPIN & 2)) /* Require old PIN */
{
pw_len = get_pinpad_input (PIN_INPUT_CURRENT);
if (pw_len < 0)
{
GPG_ERROR ();
goto done;
}
memcpy (p, pin_input_buffer, pw_len);
p += pw_len;
}
else
pw_len = 0;
newpw_len = get_pinpad_input (PIN_INPUT_NEW);
if (newpw_len < 0)
{
GPG_ERROR ();
goto done;
}
memcpy (p, pin_input_buffer, newpw_len);
if ((bConfirmPIN & 1)) /* New PIN twice */
{
len = get_pinpad_input (PIN_INPUT_CONFIRM);
if (len < 0)
{
GPG_ERROR ();
goto done;
}
if (len != newpw_len || memcmp (p, pin_input_buffer, len) != 0)
{
GPG_SECURITY_FAILURE ();
goto done;
}
}
apdu.cmd_apdu_data_len = pw_len + newpw_len;
#else
GPG_ERROR ();
goto done;
#endif
}
else if (m == EV_EXIT)
break;
process_command_apdu (ccid_comm);
done:;
uint32_t flag = EV_EXEC_FINISHED;
queue_add_blocking(ccid_comm, &flag);
}
gpg_fini ();
}
Reference in New Issue View Git Blame Copy Permalink