/* * keyid.c - Routines to calculate key IDs. * * Copyright 2002,2011 Jonathan McDowell * * This program is free software: you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the Free * Software Foundation; version 2 of the License. * * This program is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for * more details. * * You should have received a copy of the GNU General Public License along with * this program; if not, write to the Free Software Foundation, Inc., 51 * Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include #include #include #include "config.h" #include "keyid.h" #include "keystructs.h" #include "onak.h" #include "parsekey.h" #include "mem.h" #include "merge.h" #ifdef HAVE_NETTLE #include #include #else #include "md5.h" #include "sha1.h" #endif /** * get_keyid - Given a public key returns the keyid. * @publickey: The key to calculate the id for. */ onak_status_t get_keyid(struct openpgp_publickey *publickey, uint64_t *keyid) { return (get_packetid(publickey->publickey, keyid)); } /** * get_fingerprint - Given a public key returns the fingerprint. * @publickey: The key to calculate the id for. * @fingerprint: The fingerprint (must be at least 20 bytes of space). * @len: The length of the returned fingerprint. * * This function returns the fingerprint for a given public key. As Type 3 * fingerprints are 16 bytes and Type 4 are 20 the len field indicates * which we've returned. */ onak_status_t get_fingerprint(struct openpgp_packet *packet, unsigned char *fingerprint, size_t *len) { struct sha1_ctx sha_ctx; struct md5_ctx md5_context; unsigned char c; size_t modlen, explen; if (fingerprint == NULL) return ONAK_E_INVALID_PARAM; if (len == NULL) return ONAK_E_INVALID_PARAM; *len = 0; switch (packet->data[0]) { case 2: case 3: md5_init(&md5_context); /* * MD5 the modulus and exponent. */ modlen = ((packet->data[8] << 8) + packet->data[9] + 7) >> 3; md5_update(&md5_context, modlen, &packet->data[10]); explen = ((packet->data[10+modlen] << 8) + packet->data[11+modlen] + 7) >> 3; md5_update(&md5_context, explen, &packet->data[12 + modlen]); *len = 16; md5_digest(&md5_context, *len, fingerprint); break; case 4: sha1_init(&sha_ctx); /* * TODO: Can this be 0x99? Are all public key packets old * format with 2 bytes of length data? */ c = 0x99; sha1_update(&sha_ctx, sizeof(c), &c); c = packet->length >> 8; sha1_update(&sha_ctx, sizeof(c), &c); c = packet->length & 0xFF; sha1_update(&sha_ctx, sizeof(c), &c); sha1_update(&sha_ctx, packet->length, packet->data); *len = 20; sha1_digest(&sha_ctx, *len, fingerprint); break; default: return ONAK_E_UNKNOWN_VER; } return ONAK_E_OK; } /** * get_packetid - Given a PGP packet returns the keyid. * @packet: The packet to calculate the id for. */ onak_status_t get_packetid(struct openpgp_packet *packet, uint64_t *keyid) { int offset = 0; int i = 0; size_t length = 0; unsigned char buff[20]; if (packet == NULL) return ONAK_E_INVALID_PARAM; switch (packet->data[0]) { case 2: case 3: /* * For a type 2 or 3 key the keyid is the last 64 bits of the * public modulus n, which is stored as an MPI from offset 8 * onwards. */ offset = (packet->data[8] << 8) + packet->data[9]; offset = ((offset + 7) / 8) + 2; for (*keyid = 0, i = 0; i < 8; i++) { *keyid <<= 8; *keyid += packet->data[offset++]; } /* * Check for an RSA key; if not return an error. * 1 == RSA * 2 == RSA Encrypt-Only * 3 == RSA Sign-Only */ if (packet->data[7] < 1 || packet->data[7] > 3) { return ONAK_E_INVALID_PKT; } break; case 4: get_fingerprint(packet, buff, &length); for (*keyid = 0, i = 12; i < 20; i++) { *keyid <<= 8; *keyid += buff[i]; } break; default: return ONAK_E_UNKNOWN_VER; } return ONAK_E_OK; } static struct openpgp_packet_list *sortpackets(struct openpgp_packet_list *packets) { struct openpgp_packet_list *sorted, **cur, *next; sorted = NULL; while (packets != NULL) { cur = &sorted; while (*cur != NULL && compare_packets((*cur)->packet, packets->packet) < 0) { cur = &((*cur)->next); } next = *cur; *cur = packets; packets = packets->next; (*cur)->next = next; } return sorted; } onak_status_t get_skshash(struct openpgp_publickey *key, struct skshash *hash) { struct openpgp_packet_list *packets = NULL, *list_end = NULL; struct openpgp_packet_list *curpacket; struct md5_ctx md5_context; struct openpgp_publickey *next; uint32_t tmp; /* * We only want a single key, so clear any link to the next * one for the period during the flatten. */ next = key->next; key->next = NULL; flatten_publickey(key, &packets, &list_end); key->next = next; packets = sortpackets(packets); md5_init(&md5_context); for (curpacket = packets; curpacket != NULL; curpacket = curpacket->next) { tmp = htonl(curpacket->packet->tag); md5_update(&md5_context, sizeof(tmp), (void *) &tmp); tmp = htonl(curpacket->packet->length); md5_update(&md5_context, sizeof(tmp), (void *) &tmp); md5_update(&md5_context, curpacket->packet->length, curpacket->packet->data); } md5_digest(&md5_context, 16, (uint8_t *) &hash->hash); free_packet_list(packets); return ONAK_E_OK; } uint8_t hexdigit(char c) { if (c >= '0' && c <= '9') return c - '0'; else if (c >= 'a' && c <= 'f') return c - 'a' + 10; else if (c >= 'A' && c <= 'F') return c - 'A' + 10; else return 0; } int parse_skshash(char *search, struct skshash *hash) { int i, len; len = strlen(search); if (len > 32) { return 0; } for (i = 0; i < len; i += 2) { hash->hash[i >> 1] = (hexdigit(search[i]) << 4) + hexdigit(search[i + 1]); } return 1; }