/* $OpenBSD: scard.c,v 1.35 2006/08/03 03:34:42 deraadt Exp $ */ /* * Copyright (c) 2001 Markus Friedl. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #ifdef SMARTCARD #include #include #include #include #include "xmalloc.h" #include "key.h" #include "log.h" #include "misc.h" #include "scard.h" #if OPENSSL_VERSION_NUMBER < 0x00907000L #define USE_ENGINE #define RSA_get_default_method RSA_get_default_openssl_method #else #endif #ifdef USE_ENGINE #include #define sc_get_rsa sc_get_engine #else #define sc_get_rsa sc_get_rsa_method #endif #define CLA_SSH 0x05 #define INS_DECRYPT 0x10 #define INS_GET_KEYLENGTH 0x20 #define INS_GET_PUBKEY 0x30 #define INS_GET_RESPONSE 0xc0 #define MAX_BUF_SIZE 256 u_char DEFAUT0[] = {0xad, 0x9f, 0x61, 0xfe, 0xfa, 0x20, 0xce, 0x63}; static int sc_fd = -1; static char *sc_reader_id = NULL; static char *sc_pin = NULL; static int cla = 0x00; /* class */ static void sc_mk_digest(const char *pin, u_char *digest); static int get_AUT0(u_char *aut0); static int try_AUT0(void); /* interface to libsectok */ static int sc_open(void) { int sw; if (sc_fd >= 0) return sc_fd; sc_fd = sectok_friendly_open(sc_reader_id, STONOWAIT, &sw); if (sc_fd < 0) { error("sectok_open failed: %s", sectok_get_sw(sw)); return SCARD_ERROR_FAIL; } if (! sectok_cardpresent(sc_fd)) { debug("smartcard in reader %s not present, skipping", sc_reader_id); sc_close(); return SCARD_ERROR_NOCARD; } if (sectok_reset(sc_fd, 0, NULL, &sw) <= 0) { error("sectok_reset failed: %s", sectok_get_sw(sw)); sc_fd = -1; return SCARD_ERROR_FAIL; } if ((cla = cyberflex_inq_class(sc_fd)) < 0) cla = 0; debug("sc_open ok %d", sc_fd); return sc_fd; } static int sc_enable_applet(void) { static u_char aid[] = {0xfc, 0x53, 0x73, 0x68, 0x2e, 0x62, 0x69, 0x6e}; int sw = 0; /* select applet id */ sectok_apdu(sc_fd, cla, 0xa4, 0x04, 0, sizeof aid, aid, 0, NULL, &sw); if (!sectok_swOK(sw)) { error("sectok_apdu failed: %s", sectok_get_sw(sw)); sc_close(); return -1; } return 0; } static int sc_init(void) { int status; status = sc_open(); if (status == SCARD_ERROR_NOCARD) { return SCARD_ERROR_NOCARD; } if (status < 0) { error("sc_open failed"); return status; } if (sc_enable_applet() < 0) { error("sc_enable_applet failed"); return SCARD_ERROR_APPLET; } return 0; } static int sc_read_pubkey(Key * k) { u_char buf[2], *n; char *p; int len, sw, status = -1; len = sw = 0; n = NULL; if (sc_fd < 0) { if (sc_init() < 0) goto err; } /* get key size */ sectok_apdu(sc_fd, CLA_SSH, INS_GET_KEYLENGTH, 0, 0, 0, NULL, sizeof(buf), buf, &sw); if (!sectok_swOK(sw)) { error("could not obtain key length: %s", sectok_get_sw(sw)); goto err; } len = (buf[0] << 8) | buf[1]; len /= 8; debug("INS_GET_KEYLENGTH: len %d sw %s", len, sectok_get_sw(sw)); n = xmalloc(len); /* get n */ sectok_apdu(sc_fd, CLA_SSH, INS_GET_PUBKEY, 0, 0, 0, NULL, len, n, &sw); if (sw == 0x6982) { if (try_AUT0() < 0) goto err; sectok_apdu(sc_fd, CLA_SSH, INS_GET_PUBKEY, 0, 0, 0, NULL, len, n, &sw); } if (!sectok_swOK(sw)) { error("could not obtain public key: %s", sectok_get_sw(sw)); goto err; } debug("INS_GET_KEYLENGTH: sw %s", sectok_get_sw(sw)); if (BN_bin2bn(n, len, k->rsa->n) == NULL) { error("c_read_pubkey: BN_bin2bn failed"); goto err; } /* currently the java applet just stores 'n' */ if (!BN_set_word(k->rsa->e, 35)) { error("c_read_pubkey: BN_set_word(e, 35) failed"); goto err; } status = 0; p = key_fingerprint(k, SSH_FP_MD5, SSH_FP_HEX); debug("fingerprint %u %s", key_size(k), p); xfree(p); err: if (n != NULL) xfree(n); sc_close(); return status; } /* private key operations */ static int sc_private_decrypt(int flen, u_char *from, u_char *to, RSA *rsa, int padding) { u_char *padded = NULL; int sw, len, olen, status = -1; debug("sc_private_decrypt called"); olen = len = sw = 0; if (sc_fd < 0) { status = sc_init(); if (status < 0) goto err; } if (padding != RSA_PKCS1_PADDING) goto err; len = BN_num_bytes(rsa->n); padded = xmalloc(len); sectok_apdu(sc_fd, CLA_SSH, INS_DECRYPT, 0, 0, len, from, len, padded, &sw); if (sw == 0x6982) { if (try_AUT0() < 0) goto err; sectok_apdu(sc_fd, CLA_SSH, INS_DECRYPT, 0, 0, len, from, len, padded, &sw); } if (!sectok_swOK(sw)) { error("sc_private_decrypt: INS_DECRYPT failed: %s", sectok_get_sw(sw)); goto err; } olen = RSA_padding_check_PKCS1_type_2(to, len, padded + 1, len - 1, len); err: if (padded) xfree(padded); sc_close(); return (olen >= 0 ? olen : status); } static int sc_private_encrypt(int flen, u_char *from, u_char *to, RSA *rsa, int padding) { u_char *padded = NULL; int sw, len, status = -1; len = sw = 0; if (sc_fd < 0) { status = sc_init(); if (status < 0) goto err; } if (padding != RSA_PKCS1_PADDING) goto err; debug("sc_private_encrypt called"); len = BN_num_bytes(rsa->n); padded = xmalloc(len); if (RSA_padding_add_PKCS1_type_1(padded, len, (u_char *)from, flen) <= 0) { error("RSA_padding_add_PKCS1_type_1 failed"); goto err; } sectok_apdu(sc_fd, CLA_SSH, INS_DECRYPT, 0, 0, len, padded, len, to, &sw); if (sw == 0x6982) { if (try_AUT0() < 0) goto err; sectok_apdu(sc_fd, CLA_SSH, INS_DECRYPT, 0, 0, len, padded, len, to, &sw); } if (!sectok_swOK(sw)) { error("sc_private_encrypt: INS_DECRYPT failed: %s", sectok_get_sw(sw)); goto err; } err: if (padded) xfree(padded); sc_close(); return (len >= 0 ? len : status); } /* called on free */ static int (*orig_finish)(RSA *rsa) = NULL; static int sc_finish(RSA *rsa) { if (orig_finish) orig_finish(rsa); sc_close(); return 1; } /* engine for overloading private key operations */ static RSA_METHOD * sc_get_rsa_method(void) { static RSA_METHOD smart_rsa; const RSA_METHOD *def = RSA_get_default_method(); /* use the OpenSSL version */ memcpy(&smart_rsa, def, sizeof(smart_rsa)); smart_rsa.name = "sectok"; /* overload */ smart_rsa.rsa_priv_enc = sc_private_encrypt; smart_rsa.rsa_priv_dec = sc_private_decrypt; /* save original */ orig_finish = def->finish; smart_rsa.finish = sc_finish; return &smart_rsa; } #ifdef USE_ENGINE static ENGINE * sc_get_engine(void) { static ENGINE *smart_engine = NULL; if ((smart_engine = ENGINE_new()) == NULL) fatal("ENGINE_new failed"); ENGINE_set_id(smart_engine, "sectok"); ENGINE_set_name(smart_engine, "libsectok"); ENGINE_set_RSA(smart_engine, sc_get_rsa_method()); ENGINE_set_DSA(smart_engine, DSA_get_default_openssl_method()); ENGINE_set_DH(smart_engine, DH_get_default_openssl_method()); ENGINE_set_RAND(smart_engine, RAND_SSLeay()); ENGINE_set_BN_mod_exp(smart_engine, BN_mod_exp); return smart_engine; } #endif void sc_close(void) { if (sc_fd >= 0) { sectok_close(sc_fd); sc_fd = -1; } } Key ** sc_get_keys(const char *id, const char *pin) { Key *k, *n, **keys; int status, nkeys = 2; if (sc_reader_id != NULL) xfree(sc_reader_id); sc_reader_id = xstrdup(id); if (sc_pin != NULL) xfree(sc_pin); sc_pin = (pin == NULL) ? NULL : xstrdup(pin); k = key_new(KEY_RSA); if (k == NULL) { return NULL; } status = sc_read_pubkey(k); if (status == SCARD_ERROR_NOCARD) { key_free(k); return NULL; } if (status < 0) { error("sc_read_pubkey failed"); key_free(k); return NULL; } keys = xcalloc((nkeys+1), sizeof(Key *)); n = key_new(KEY_RSA1); BN_copy(n->rsa->n, k->rsa->n); BN_copy(n->rsa->e, k->rsa->e); RSA_set_method(n->rsa, sc_get_rsa()); n->flags |= KEY_FLAG_EXT; keys[0] = n; n = key_new(KEY_RSA); BN_copy(n->rsa->n, k->rsa->n); BN_copy(n->rsa->e, k->rsa->e); RSA_set_method(n->rsa, sc_get_rsa()); n->flags |= KEY_FLAG_EXT; keys[1] = n; keys[2] = NULL; key_free(k); return keys; } #define NUM_RSA_KEY_ELEMENTS 5+1 #define COPY_RSA_KEY(x, i) \ do { \ len = BN_num_bytes(prv->rsa->x); \ elements[i] = xmalloc(len); \ debug("#bytes %d", len); \ if (BN_bn2bin(prv->rsa->x, elements[i]) < 0) \ goto done; \ } while (0) static void sc_mk_digest(const char *pin, u_char *digest) { const EVP_MD *evp_md = EVP_sha1(); EVP_MD_CTX md; EVP_DigestInit(&md, evp_md); EVP_DigestUpdate(&md, pin, strlen(pin)); EVP_DigestFinal(&md, digest, NULL); } static int get_AUT0(u_char *aut0) { char *pass; pass = read_passphrase("Enter passphrase for smartcard: ", RP_ALLOW_STDIN); if (pass == NULL) return -1; if (!strcmp(pass, "-")) { memcpy(aut0, DEFAUT0, sizeof DEFAUT0); return 0; } sc_mk_digest(pass, aut0); memset(pass, 0, strlen(pass)); xfree(pass); return 0; } static int try_AUT0(void) { u_char aut0[EVP_MAX_MD_SIZE]; /* permission denied; try PIN if provided */ if (sc_pin && strlen(sc_pin) > 0) { sc_mk_digest(sc_pin, aut0); if (cyberflex_verify_AUT0(sc_fd, cla, aut0, 8) < 0) { error("smartcard passphrase incorrect"); return (-1); } } else { /* try default AUT0 key */ if (cyberflex_verify_AUT0(sc_fd, cla, DEFAUT0, 8) < 0) { /* default AUT0 key failed; prompt for passphrase */ if (get_AUT0(aut0) < 0 || cyberflex_verify_AUT0(sc_fd, cla, aut0, 8) < 0) { error("smartcard passphrase incorrect"); return (-1); } } } return (0); } int sc_put_key(Key *prv, const char *id) { u_char *elements[NUM_RSA_KEY_ELEMENTS]; u_char key_fid[2]; u_char AUT0[EVP_MAX_MD_SIZE]; int len, status = -1, i, fd = -1, ret; int sw = 0, cla = 0x00; for (i = 0; i < NUM_RSA_KEY_ELEMENTS; i++) elements[i] = NULL; COPY_RSA_KEY(q, 0); COPY_RSA_KEY(p, 1); COPY_RSA_KEY(iqmp, 2); COPY_RSA_KEY(dmq1, 3); COPY_RSA_KEY(dmp1, 4); COPY_RSA_KEY(n, 5); len = BN_num_bytes(prv->rsa->n); fd = sectok_friendly_open(id, STONOWAIT, &sw); if (fd < 0) { error("sectok_open failed: %s", sectok_get_sw(sw)); goto done; } if (! sectok_cardpresent(fd)) { error("smartcard in reader %s not present", id); goto done; } ret = sectok_reset(fd, 0, NULL, &sw); if (ret <= 0) { error("sectok_reset failed: %s", sectok_get_sw(sw)); goto done; } if ((cla = cyberflex_inq_class(fd)) < 0) { error("cyberflex_inq_class failed"); goto done; } memcpy(AUT0, DEFAUT0, sizeof(DEFAUT0)); if (cyberflex_verify_AUT0(fd, cla, AUT0, sizeof(DEFAUT0)) < 0) { if (get_AUT0(AUT0) < 0 || cyberflex_verify_AUT0(fd, cla, AUT0, sizeof(DEFAUT0)) < 0) { memset(AUT0, 0, sizeof(DEFAUT0)); error("smartcard passphrase incorrect"); goto done; } } memset(AUT0, 0, sizeof(DEFAUT0)); key_fid[0] = 0x00; key_fid[1] = 0x12; if (cyberflex_load_rsa_priv(fd, cla, key_fid, 5, 8*len, elements, &sw) < 0) { error("cyberflex_load_rsa_priv failed: %s", sectok_get_sw(sw)); goto done; } if (!sectok_swOK(sw)) goto done; logit("cyberflex_load_rsa_priv done"); key_fid[0] = 0x73; key_fid[1] = 0x68; if (cyberflex_load_rsa_pub(fd, cla, key_fid, len, elements[5], &sw) < 0) { error("cyberflex_load_rsa_pub failed: %s", sectok_get_sw(sw)); goto done; } if (!sectok_swOK(sw)) goto done; logit("cyberflex_load_rsa_pub done"); status = 0; done: memset(elements[0], '\0', BN_num_bytes(prv->rsa->q)); memset(elements[1], '\0', BN_num_bytes(prv->rsa->p)); memset(elements[2], '\0', BN_num_bytes(prv->rsa->iqmp)); memset(elements[3], '\0', BN_num_bytes(prv->rsa->dmq1)); memset(elements[4], '\0', BN_num_bytes(prv->rsa->dmp1)); memset(elements[5], '\0', BN_num_bytes(prv->rsa->n)); for (i = 0; i < NUM_RSA_KEY_ELEMENTS; i++) if (elements[i]) xfree(elements[i]); if (fd != -1) sectok_close(fd); return (status); } char * sc_get_key_label(Key *key) { return xstrdup("smartcard key"); } #endif /* SMARTCARD */