/* * Copyright (c) 2019 Yubico AB. All rights reserved. * Use of this source code is governed by a BSD-style * license that can be found in the LICENSE file. */ #include #include #include #include #include #include #include "mutator_aux.h" #include "wiredata_fido2.h" #include "wiredata_u2f.h" #include "dummy.h" #include "fido.h" #include "fido/es256.h" #include "fido/rs256.h" #include "fido/eddsa.h" #include "../openbsd-compat/openbsd-compat.h" /* Parameter set defining a FIDO2 get assertion operation. */ struct param { char pin[MAXSTR]; char rp_id[MAXSTR]; int ext; int seed; struct blob cdh; struct blob cred; struct blob es256; struct blob rs256; struct blob eddsa; struct blob wire_data; uint8_t cred_count; uint8_t type; uint8_t u2f; uint8_t up; uint8_t uv; }; /* * Collection of HID reports from an authenticator issued with a FIDO2 * get assertion using the example parameters above. */ static const uint8_t dummy_wire_data_fido[] = { WIREDATA_CTAP_INIT, WIREDATA_CTAP_CBOR_INFO, WIREDATA_CTAP_CBOR_AUTHKEY, WIREDATA_CTAP_CBOR_PINTOKEN, WIREDATA_CTAP_CBOR_ASSERT, }; /* * Collection of HID reports from an authenticator issued with a U2F * authentication using the example parameters above. */ static const uint8_t dummy_wire_data_u2f[] = { WIREDATA_CTAP_INIT, WIREDATA_CTAP_U2F_6985, WIREDATA_CTAP_U2F_6985, WIREDATA_CTAP_U2F_6985, WIREDATA_CTAP_U2F_6985, WIREDATA_CTAP_U2F_AUTH, }; struct param * unpack(const uint8_t *ptr, size_t len) { cbor_item_t *item = NULL, **v; struct cbor_load_result cbor; struct param *p; int ok = -1; if ((p = calloc(1, sizeof(*p))) == NULL || (item = cbor_load(ptr, len, &cbor)) == NULL || cbor.read != len || cbor_isa_array(item) == false || cbor_array_is_definite(item) == false || cbor_array_size(item) != 15 || (v = cbor_array_handle(item)) == NULL) goto fail; if (unpack_byte(v[0], &p->uv) < 0 || unpack_byte(v[1], &p->up) < 0 || unpack_byte(v[2], &p->u2f) < 0 || unpack_byte(v[3], &p->type) < 0 || unpack_byte(v[4], &p->cred_count) < 0 || unpack_int(v[5], &p->ext) < 0 || unpack_int(v[6], &p->seed) < 0 || unpack_string(v[7], p->rp_id) < 0 || unpack_string(v[8], p->pin) < 0 || unpack_blob(v[9], &p->wire_data) < 0 || unpack_blob(v[10], &p->rs256) < 0 || unpack_blob(v[11], &p->es256) < 0 || unpack_blob(v[12], &p->eddsa) < 0 || unpack_blob(v[13], &p->cred) < 0 || unpack_blob(v[14], &p->cdh) < 0) goto fail; ok = 0; fail: if (ok < 0) { free(p); p = NULL; } if (item) cbor_decref(&item); return p; } size_t pack(uint8_t *ptr, size_t len, const struct param *p) { cbor_item_t *argv[15], *array = NULL; size_t cbor_alloc_len, cbor_len = 0; unsigned char *cbor = NULL; memset(argv, 0, sizeof(argv)); if ((array = cbor_new_definite_array(15)) == NULL || (argv[0] = pack_byte(p->uv)) == NULL || (argv[1] = pack_byte(p->up)) == NULL || (argv[2] = pack_byte(p->u2f)) == NULL || (argv[3] = pack_byte(p->type)) == NULL || (argv[4] = pack_byte(p->cred_count)) == NULL || (argv[5] = pack_int(p->ext)) == NULL || (argv[6] = pack_int(p->seed)) == NULL || (argv[7] = pack_string(p->rp_id)) == NULL || (argv[8] = pack_string(p->pin)) == NULL || (argv[9] = pack_blob(&p->wire_data)) == NULL || (argv[10] = pack_blob(&p->rs256)) == NULL || (argv[11] = pack_blob(&p->es256)) == NULL || (argv[12] = pack_blob(&p->eddsa)) == NULL || (argv[13] = pack_blob(&p->cred)) == NULL || (argv[14] = pack_blob(&p->cdh)) == NULL) goto fail; for (size_t i = 0; i < 15; i++) if (cbor_array_push(array, argv[i]) == false) goto fail; if ((cbor_len = cbor_serialize_alloc(array, &cbor, &cbor_alloc_len)) > len) { cbor_len = 0; goto fail; } memcpy(ptr, cbor, cbor_len); fail: for (size_t i = 0; i < 15; i++) if (argv[i]) cbor_decref(&argv[i]); if (array) cbor_decref(&array); free(cbor); return cbor_len; } size_t pack_dummy(uint8_t *ptr, size_t len) { struct param dummy; uint8_t blob[4096]; size_t blob_len; memset(&dummy, 0, sizeof(dummy)); dummy.type = 1; /* rsa */ dummy.ext = FIDO_EXT_HMAC_SECRET; strlcpy(dummy.pin, dummy_pin, sizeof(dummy.pin)); strlcpy(dummy.rp_id, dummy_rp_id, sizeof(dummy.rp_id)); dummy.cred.len = sizeof(dummy_cdh); /* XXX */ dummy.cdh.len = sizeof(dummy_cdh); dummy.es256.len = sizeof(dummy_es256); dummy.rs256.len = sizeof(dummy_rs256); dummy.eddsa.len = sizeof(dummy_eddsa); dummy.wire_data.len = sizeof(dummy_wire_data_fido); memcpy(&dummy.cred.body, &dummy_cdh, dummy.cred.len); /* XXX */ memcpy(&dummy.cdh.body, &dummy_cdh, dummy.cdh.len); memcpy(&dummy.wire_data.body, &dummy_wire_data_fido, dummy.wire_data.len); memcpy(&dummy.es256.body, &dummy_es256, dummy.es256.len); memcpy(&dummy.rs256.body, &dummy_rs256, dummy.rs256.len); memcpy(&dummy.eddsa.body, &dummy_eddsa, dummy.eddsa.len); assert((blob_len = pack(blob, sizeof(blob), &dummy)) != 0); if (blob_len > len) { memcpy(ptr, blob, len); return len; } memcpy(ptr, blob, blob_len); return blob_len; } static void get_assert(fido_assert_t *assert, uint8_t u2f, const struct blob *cdh, const char *rp_id, int ext, uint8_t up, uint8_t uv, const char *pin, uint8_t cred_count, const struct blob *cred) { fido_dev_t *dev; fido_dev_io_t io; memset(&io, 0, sizeof(io)); io.open = dev_open; io.close = dev_close; io.read = dev_read; io.write = dev_write; if ((dev = fido_dev_new()) == NULL || fido_dev_set_io_functions(dev, &io) != FIDO_OK || fido_dev_open(dev, "nodev") != FIDO_OK) { fido_dev_free(&dev); return; } if (u2f & 1) fido_dev_force_u2f(dev); if (ext & 1) fido_assert_set_extensions(assert, FIDO_EXT_HMAC_SECRET); if (up & 1) fido_assert_set_up(assert, FIDO_OPT_TRUE); else if (u2f &1) fido_assert_set_up(assert, FIDO_OPT_FALSE); if (uv & 1) fido_assert_set_uv(assert, FIDO_OPT_TRUE); for (uint8_t i = 0; i < cred_count; i++) fido_assert_allow_cred(assert, cred->body, cred->len); fido_assert_set_clientdata_hash(assert, cdh->body, cdh->len); fido_assert_set_rp(assert, rp_id); /* XXX reuse cred as hmac salt */ fido_assert_set_hmac_salt(assert, cred->body, cred->len); /* repeat memory operations to trigger reallocation paths */ fido_assert_set_clientdata_hash(assert, cdh->body, cdh->len); fido_assert_set_rp(assert, rp_id); fido_assert_set_hmac_salt(assert, cred->body, cred->len); if (strlen(pin) == 0) pin = NULL; fido_dev_get_assert(dev, assert, u2f & 1 ? NULL : pin); fido_dev_cancel(dev); fido_dev_close(dev); fido_dev_free(&dev); } static void verify_assert(int type, const unsigned char *cdh_ptr, size_t cdh_len, const char *rp_id, const unsigned char *authdata_ptr, size_t authdata_len, const unsigned char *sig_ptr, size_t sig_len, uint8_t up, uint8_t uv, int ext, void *pk) { fido_assert_t *assert = NULL; if ((assert = fido_assert_new()) == NULL) return; fido_assert_set_clientdata_hash(assert, cdh_ptr, cdh_len); fido_assert_set_rp(assert, rp_id); fido_assert_set_count(assert, 1); if (fido_assert_set_authdata(assert, 0, authdata_ptr, authdata_len) != FIDO_OK) { fido_assert_set_authdata_raw(assert, 0, authdata_ptr, authdata_len); } if (up & 1) fido_assert_set_up(assert, FIDO_OPT_TRUE); if (uv & 1) fido_assert_set_uv(assert, FIDO_OPT_TRUE); fido_assert_set_extensions(assert, ext); fido_assert_set_sig(assert, 0, sig_ptr, sig_len); /* repeat memory operations to trigger reallocation paths */ if (fido_assert_set_authdata(assert, 0, authdata_ptr, authdata_len) != FIDO_OK) { fido_assert_set_authdata_raw(assert, 0, authdata_ptr, authdata_len); } fido_assert_set_sig(assert, 0, sig_ptr, sig_len); assert(fido_assert_verify(assert, 0, type, pk) != FIDO_OK); fido_assert_free(&assert); } /* * Do a dummy conversion to exercise rs256_pk_from_RSA(). */ static void rs256_convert(const rs256_pk_t *k) { EVP_PKEY *pkey = NULL; rs256_pk_t *pk = NULL; RSA *rsa = NULL; volatile int r; if ((pkey = rs256_pk_to_EVP_PKEY(k)) == NULL || (pk = rs256_pk_new()) == NULL || (rsa = EVP_PKEY_get0_RSA(pkey)) == NULL) goto out; r = rs256_pk_from_RSA(pk, rsa); out: if (pk) rs256_pk_free(&pk); if (pkey) EVP_PKEY_free(pkey); } /* * Do a dummy conversion to exercise eddsa_pk_from_EVP_PKEY(). */ static void eddsa_convert(const eddsa_pk_t *k) { EVP_PKEY *pkey = NULL; eddsa_pk_t *pk = NULL; volatile int r; if ((pkey = eddsa_pk_to_EVP_PKEY(k)) == NULL || (pk = eddsa_pk_new()) == NULL) goto out; r = eddsa_pk_from_EVP_PKEY(pk, pkey); out: if (pk) eddsa_pk_free(&pk); if (pkey) EVP_PKEY_free(pkey); } void test(const struct param *p) { fido_assert_t *assert = NULL; es256_pk_t *es256_pk = NULL; rs256_pk_t *rs256_pk = NULL; eddsa_pk_t *eddsa_pk = NULL; uint8_t flags; uint32_t sigcount; int cose_alg = 0; void *pk; prng_init((unsigned int)p->seed); fido_init(FIDO_DEBUG); fido_set_log_handler(consume_str); switch (p->type & 3) { case 0: cose_alg = COSE_ES256; if ((es256_pk = es256_pk_new()) == NULL) return; es256_pk_from_ptr(es256_pk, p->es256.body, p->es256.len); pk = es256_pk; break; case 1: cose_alg = COSE_RS256; if ((rs256_pk = rs256_pk_new()) == NULL) return; rs256_pk_from_ptr(rs256_pk, p->rs256.body, p->rs256.len); pk = rs256_pk; rs256_convert(pk); break; default: cose_alg = COSE_EDDSA; if ((eddsa_pk = eddsa_pk_new()) == NULL) return; eddsa_pk_from_ptr(eddsa_pk, p->eddsa.body, p->eddsa.len); pk = eddsa_pk; eddsa_convert(pk); break; } if ((assert = fido_assert_new()) == NULL) goto out; set_wire_data(p->wire_data.body, p->wire_data.len); get_assert(assert, p->u2f, &p->cdh, p->rp_id, p->ext, p->up, p->uv, p->pin, p->cred_count, &p->cred); /* XXX +1 on purpose */ for (size_t i = 0; i <= fido_assert_count(assert); i++) { verify_assert(cose_alg, fido_assert_clientdata_hash_ptr(assert), fido_assert_clientdata_hash_len(assert), fido_assert_rp_id(assert), fido_assert_authdata_ptr(assert, i), fido_assert_authdata_len(assert, i), fido_assert_sig_ptr(assert, i), fido_assert_sig_len(assert, i), p->up, p->uv, p->ext, pk); consume(fido_assert_id_ptr(assert, i), fido_assert_id_len(assert, i)); consume(fido_assert_user_id_ptr(assert, i), fido_assert_user_id_len(assert, i)); consume(fido_assert_hmac_secret_ptr(assert, i), fido_assert_hmac_secret_len(assert, i)); consume(fido_assert_user_icon(assert, i), xstrlen(fido_assert_user_icon(assert, i))); consume(fido_assert_user_name(assert, i), xstrlen(fido_assert_user_name(assert, i))); consume(fido_assert_user_display_name(assert, i), xstrlen(fido_assert_user_display_name(assert, i))); flags = fido_assert_flags(assert, i); consume(&flags, sizeof(flags)); sigcount = fido_assert_sigcount(assert, i); consume(&sigcount, sizeof(sigcount)); } out: es256_pk_free(&es256_pk); rs256_pk_free(&rs256_pk); eddsa_pk_free(&eddsa_pk); fido_assert_free(&assert); } void mutate(struct param *p, unsigned int seed, unsigned int flags) NO_MSAN { if (flags & MUTATE_SEED) p->seed = (int)seed; if (flags & MUTATE_PARAM) { mutate_byte(&p->uv); mutate_byte(&p->up); mutate_byte(&p->u2f); mutate_byte(&p->type); mutate_byte(&p->cred_count); mutate_int(&p->ext); mutate_blob(&p->rs256); mutate_blob(&p->es256); mutate_blob(&p->eddsa); mutate_blob(&p->cred); mutate_blob(&p->cdh); mutate_string(p->rp_id); mutate_string(p->pin); } if (flags & MUTATE_WIREDATA) { if (p->u2f & 1) { p->wire_data.len = sizeof(dummy_wire_data_u2f); memcpy(&p->wire_data.body, &dummy_wire_data_u2f, p->wire_data.len); } else { p->wire_data.len = sizeof(dummy_wire_data_fido); memcpy(&p->wire_data.body, &dummy_wire_data_fido, p->wire_data.len); } mutate_blob(&p->wire_data); } }