/* * Data structure managing host keys in sessions based on GSSAPI KEX. * * In a session we started with a GSSAPI key exchange, the concept of * 'host key' has completely different lifetime and security semantics * from the usual ones. Per RFC 4462 section 2.1, we assume that any * host key delivered to us in the course of a GSSAPI key exchange is * _solely_ there to use as a transient fallback within the same * session, if at the time of a subsequent rekey the GSS credentials * are temporarily invalid and so a non-GSS KEX method has to be used. * * In particular, in a GSS-based SSH deployment, host keys may not * even _be_ persistent identities for the server; it would be * legitimate for a server to generate a fresh one routinely if it * wanted to, like SSH-1 server keys. * * So, in this mode, we never touch the persistent host key cache at * all, either to check keys against it _or_ to store keys in it. * Instead, we maintain an in-memory cache of host keys that have been * mentioned in GSS key exchanges within this particular session, and * we permit precisely those host keys in non-GSS rekeys. */ #include #include "putty.h" #include "ssh.h" struct ssh_transient_hostkey_cache { tree234 *cache; }; struct ssh_transient_hostkey_cache_entry { const ssh_keyalg *alg; strbuf *pub_blob; }; static int ssh_transient_hostkey_cache_cmp(void *av, void *bv) { const struct ssh_transient_hostkey_cache_entry *a = (const struct ssh_transient_hostkey_cache_entry *)av, *b = (const struct ssh_transient_hostkey_cache_entry *)bv; return strcmp(a->alg->ssh_id, b->alg->ssh_id); } static int ssh_transient_hostkey_cache_find(void *av, void *bv) { const ssh_keyalg *aalg = (const ssh_keyalg *)av; const struct ssh_transient_hostkey_cache_entry *b = (const struct ssh_transient_hostkey_cache_entry *)bv; return strcmp(aalg->ssh_id, b->alg->ssh_id); } ssh_transient_hostkey_cache *ssh_transient_hostkey_cache_new(void) { ssh_transient_hostkey_cache *thc = snew(ssh_transient_hostkey_cache); thc->cache = newtree234(ssh_transient_hostkey_cache_cmp); return thc; } void ssh_transient_hostkey_cache_free(ssh_transient_hostkey_cache *thc) { struct ssh_transient_hostkey_cache_entry *ent; while ((ent = delpos234(thc->cache, 0)) != NULL) { strbuf_free(ent->pub_blob); sfree(ent); } freetree234(thc->cache); sfree(thc); } void ssh_transient_hostkey_cache_add( ssh_transient_hostkey_cache *thc, ssh_key *key) { struct ssh_transient_hostkey_cache_entry *ent, *retd; if ((ent = find234(thc->cache, (void *)ssh_key_alg(key), ssh_transient_hostkey_cache_find)) != NULL) { del234(thc->cache, ent); strbuf_free(ent->pub_blob); sfree(ent); } ent = snew(struct ssh_transient_hostkey_cache_entry); ent->alg = ssh_key_alg(key); ent->pub_blob = strbuf_new(); ssh_key_public_blob(key, BinarySink_UPCAST(ent->pub_blob)); retd = add234(thc->cache, ent); assert(retd == ent); } bool ssh_transient_hostkey_cache_verify( ssh_transient_hostkey_cache *thc, ssh_key *key) { struct ssh_transient_hostkey_cache_entry *ent; bool toret = false; if ((ent = find234(thc->cache, (void *)ssh_key_alg(key), ssh_transient_hostkey_cache_find)) != NULL) { strbuf *this_blob = strbuf_new(); ssh_key_public_blob(key, BinarySink_UPCAST(this_blob)); if (this_blob->len == ent->pub_blob->len && !memcmp(this_blob->s, ent->pub_blob->s, this_blob->len)) toret = true; strbuf_free(this_blob); } return toret; } bool ssh_transient_hostkey_cache_has( ssh_transient_hostkey_cache *thc, const ssh_keyalg *alg) { struct ssh_transient_hostkey_cache_entry *ent = find234(thc->cache, (void *)alg, ssh_transient_hostkey_cache_find); return ent != NULL; } bool ssh_transient_hostkey_cache_non_empty(ssh_transient_hostkey_cache *thc) { return count234(thc->cache) > 0; }