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-rw-r--r--hal_internal.h10
-rw-r--r--hashsig.c334
-rw-r--r--hashsig.h4
-rw-r--r--tests/test-rpc_hashsig.c20
4 files changed, 296 insertions, 72 deletions
diff --git a/hal_internal.h b/hal_internal.h
index d3bf706..ae62ff0 100644
--- a/hal_internal.h
+++ b/hal_internal.h
@@ -125,17 +125,17 @@ static inline hal_error_t hal_io_wait_valid2(const hal_core_t *core1, const hal_
/*
* Static memory allocation on start-up. Don't use this except where
- * really necessary. By design, there's no way to free this, we don't
- * want to have to manage a heap. Intent is just to allow allocation
- * things like the large-ish ks_index arrays used by ks_flash.c from a
- * memory source external to the executable image file (eg, from the
- * secondary SDRAM chip on the Cryptech Alpha board).
+ * really necessary. Intent is just to allow allocation of things like
+ * the large-ish ks_index arrays used by ks_flash.c from a memory source
+ * external to the executable image file (eg, from the secondary SDRAM
+ * chip on the Cryptech Alpha board).
*
* We shouldn't need this except on the HSM, so for now we don't bother
* with implementing a version of this based on malloc() or sbrk().
*/
extern void *hal_allocate_static_memory(const size_t size);
+extern hal_error_t hal_free_static_memory(const void * const ptr);
/*
* Longest hash block and digest we support at the moment.
diff --git a/hashsig.c b/hashsig.c
index 5ffbb12..0396ff7 100644
--- a/hashsig.c
+++ b/hashsig.c
@@ -185,7 +185,7 @@ static inline size_t lmots_signature_len(lmots_parameter_t * const lmots)
#if RPC_CLIENT == RPC_CLIENT_LOCAL
/* Given a key with most fields filled in, generate the lmots private and
- * public key components.
+ * public key components (x and K).
* Let the caller worry about storage.
*/
static hal_error_t lmots_generate(lmots_key_t * const key)
@@ -502,8 +502,8 @@ static hal_error_t lmots_private_key_to_der(const lmots_key_t * const key,
if (key == NULL || key->type != HAL_KEY_TYPE_HASHSIG_LMOTS)
return HAL_ERROR_BAD_ARGUMENTS;
- // u32str(lmots_type) || I || u32str(q) || x[0] || x[1] || ... || x[p-1]
- /* we also store K, to speed up restart */
+ // u32str(lmots_type) || I || u32str(q) || K || x[0] || x[1] || ... || x[p-1]
+ /* K is not an integral part of the private key, but we store it to speed up restart */
/*
* Calculate data length.
@@ -514,10 +514,10 @@ static hal_error_t lmots_private_key_to_der(const lmots_key_t * const key,
check(hal_asn1_encode_lmots_algorithm(key->lmots->type, NULL, &len, 0)); vlen += len;
check(hal_asn1_encode_bytestring16(&key->I, NULL, &len, 0)); vlen += len;
check(hal_asn1_encode_size_t(key->q, NULL, &len, 0)); vlen += len;
+ check(hal_asn1_encode_bytestring32(&key->K, NULL, &len, 0)); vlen += len;
for (size_t i = 0; i < key->lmots->p; ++i) {
check(hal_asn1_encode_bytestring32(&key->x[i], NULL, &len, 0)); vlen += len;
}
- check(hal_asn1_encode_bytestring32(&key->K, NULL, &len, 0)); vlen += len;
check(hal_asn1_encode_header(ASN1_SEQUENCE, vlen, NULL, &hlen, 0));
@@ -539,10 +539,10 @@ static hal_error_t lmots_private_key_to_der(const lmots_key_t * const key,
check(hal_asn1_encode_lmots_algorithm(key->lmots->type, d, &len, vlen)); d += len; vlen -= len;
check(hal_asn1_encode_bytestring16(&key->I, d, &len, vlen)); d += len; vlen -= len;
check(hal_asn1_encode_size_t(key->q, d, &len, vlen)); d += len; vlen -= len;
+ check(hal_asn1_encode_bytestring32(&key->K, d, &len, vlen)); d += len; vlen -= len;
for (size_t i = 0; i < key->lmots->p; ++i) {
check(hal_asn1_encode_bytestring32(&key->x[i], d, &len, vlen)); d += len; vlen -= len;
}
- check(hal_asn1_encode_bytestring32(&key->K, d, &len, vlen)); d += len; vlen -= len;
return hal_asn1_encode_pkcs8_privatekeyinfo(hal_asn1_oid_mts_hashsig, hal_asn1_oid_mts_hashsig_len,
NULL, 0, der, d - der, der, der_len, der_max);
@@ -580,20 +580,22 @@ static hal_error_t lmots_private_key_from_der(lmots_key_t *key,
const uint8_t *d = privkey + hlen;
size_t len;
- // u32str(lmots_type) || I || u32str(q) || x[0] || x[1] || ... || x[p-1]
+ // u32str(lmots_type) || I || u32str(q) || K || x[0] || x[1] || ... || x[p-1]
lmots_algorithm_t lmots_type;
check(hal_asn1_decode_lmots_algorithm(&lmots_type, d, &len, vlen)); d += len; vlen -= len;
key->lmots = lmots_select_parameter_set(lmots_type);
check(hal_asn1_decode_bytestring16(&key->I, d, &len, vlen)); d += len; vlen -= len;
check(hal_asn1_decode_size_t(&key->q, d, &len, vlen)); d += len; vlen -= len;
- for (size_t i = 0; i < key->lmots->p; ++i) {
- check(hal_asn1_decode_bytestring32(&key->x[i], d, &len, vlen)); d += len; vlen -= len;
- }
check(hal_asn1_decode_bytestring32(&key->K, d, &len, vlen)); d += len; vlen -= len;
+ if (key->x != NULL) {
+ for (size_t i = 0; i < key->lmots->p; ++i) {
+ check(hal_asn1_decode_bytestring32(&key->x[i], d, &len, vlen)); d += len; vlen -= len;
+ }
- if (d != privkey + privkey_len)
- return HAL_ERROR_ASN1_PARSE_FAILED;
+ if (d != privkey + privkey_len)
+ return HAL_ERROR_ASN1_PARSE_FAILED;
+ }
return HAL_OK;
}
@@ -677,7 +679,7 @@ static hal_error_t lms_generate(lms_key_t *key)
hal_pkey_slot_t slot = {
.type = HAL_KEY_TYPE_HASHSIG_LMOTS,
.curve = HAL_CURVE_NONE,
- .flags = (key->level == 0) ? HAL_KEY_FLAG_TOKEN: 0
+ .flags = HAL_KEY_FLAG_USAGE_DIGITALSIGNATURE | ((key->level == 0) ? HAL_KEY_FLAG_TOKEN: 0)
};
hal_ks_t *ks = (key->level == 0) ? hal_ks_token : hal_ks_volatile;
@@ -745,10 +747,7 @@ static hal_error_t lms_generate(lms_key_t *key)
static hal_error_t lms_delete(const lms_key_t * const key)
{
- hal_pkey_slot_t slot;
- memset(&slot, 0, sizeof(slot));
- slot.flags = (key->level == 0) ? HAL_KEY_FLAG_TOKEN: 0;
-
+ hal_pkey_slot_t slot = {0};
hal_ks_t *ks = (key->level == 0) ? hal_ks_token : hal_ks_volatile;
/* delete the lmots keys */
@@ -787,7 +786,6 @@ static hal_error_t lms_sign(lms_key_t * const key,
/* fetch and decode the lmots signing key from the keystore */
hal_pkey_slot_t slot;
memset(&slot, 0, sizeof(slot));
- slot.flags = (key->level == 0) ? HAL_KEY_FLAG_TOKEN : 0;
memcpy(&slot.name, &key->lmots_keys[key->q], sizeof(slot.name));
lmots_key_t lmots_key;
@@ -823,6 +821,8 @@ static hal_error_t lms_sign(lms_key_t * const key,
/* update and store q before returning the signature */
++key->q;
check(lms_private_key_to_der(key, der, &der_len, sizeof(der)));
+ slot.type = HAL_KEY_TYPE_HASHSIG_LMS;
+ slot.flags = HAL_KEY_FLAG_USAGE_DIGITALSIGNATURE | ((key->level == 0) ? HAL_KEY_FLAG_TOKEN : 0);
memcpy(&slot.name, &key->I, sizeof(slot.name));
check(hal_ks_rewrite_der(ks, &slot, der, der_len));
@@ -1069,10 +1069,7 @@ static size_t lms_private_key_to_der_len(const lms_key_t * const key)
size_t len = 0;
return lms_private_key_to_der(key, NULL, &len, 0) == HAL_OK ? len : 0;
}
-#endif
-#if 0
-// used in restart - caller will have to allocate and attach storage for lmots_keys[] and T[]
static hal_error_t lms_private_key_from_der(lms_key_t *key,
const uint8_t *der, const size_t der_len)
{
@@ -1132,6 +1129,7 @@ typedef struct hal_hashsig_key hss_key_t;
struct hal_hashsig_key {
hal_key_type_t type;
hss_key_t *next;
+ hal_uuid_t name;
size_t L;
lms_parameter_t *lms;
lmots_parameter_t *lmots;
@@ -1191,12 +1189,10 @@ static inline void *gnaw(uint8_t **mem, size_t *len, const size_t size)
return ret;
}
-/* called from pkey_local_generate_hashsig */
-hal_error_t hal_hashsig_key_gen(hal_core_t *core,
- hal_hashsig_key_t **key_,
- const size_t L,
- const lms_algorithm_t lms_type,
- const lmots_algorithm_t lmots_type)
+static hal_error_t hss_alloc(hal_hashsig_key_t **key_,
+ const size_t L,
+ const lms_algorithm_t lms_type,
+ const lmots_algorithm_t lmots_type)
{
if (key_ == NULL)
return HAL_ERROR_BAD_ARGUMENTS;
@@ -1221,19 +1217,11 @@ hal_error_t hal_hashsig_key_gen(hal_core_t *core,
if (lmots_private_key_len(lmots) > HAL_KS_BLOCK_SIZE)
return HAL_ERROR_UNSUPPORTED_KEY;
- /* w=2 fails on the Alpha, as does w=4 with L=2, because the signature
- * exceeds the meagre 4096-byte RPC packet size.
- */
if (hss_signature_len(L, lms, lmots) > HAL_RPC_MAX_PKT_SIZE)
return HAL_ERROR_UNSUPPORTED_KEY;
- /* check flash keystore for space to store the root tree */
- size_t available;
- check(hal_ks_available(hal_ks_token, &available));
- if (available < h2 + 2)
- return HAL_ERROR_NO_KEY_INDEX_SLOTS;
-
/* check volatile keystore for space to store the lower-level trees */
+ size_t available;
check(hal_ks_available(hal_ks_volatile, &available));
if (available < (L - 1) * (h2 + 1))
return HAL_ERROR_NO_KEY_INDEX_SLOTS;
@@ -1247,7 +1235,7 @@ hal_error_t hal_hashsig_key_gen(hal_core_t *core,
L * lms_sig_len +
L * lms_pub_len +
L * h2 * sizeof(hal_uuid_t) +
- L * (2 * h2 - 1) * sizeof(bytestring32));
+ L * (2 * h2) * sizeof(bytestring32));
uint8_t *mem = hal_allocate_static_memory(len);
if (mem == NULL)
return HAL_ERROR_ALLOCATION_FAILURE;
@@ -1255,6 +1243,7 @@ hal_error_t hal_hashsig_key_gen(hal_core_t *core,
/* allocate the key that will stay in working memory */
hss_key_t *key = gnaw(&mem, &len, sizeof(hss_key_t));
+ *key_ = key;
key->type = HAL_KEY_TYPE_HASHSIG_PRIVATE;
key->L = L;
key->lms = lms;
@@ -1266,34 +1255,62 @@ hal_error_t hal_hashsig_key_gen(hal_core_t *core,
/* allocate the list of lms trees */
key->lms_keys = gnaw(&mem, &len, L * sizeof(lms_key_t));
-
- /* generate the lms trees */
for (size_t i = 0; i < L; ++i) {
+ /* XXX some of this is redundant to lms_private_key_from_der */
lms_key_t * lms_key = &key->lms_keys[i];
lms_key->type = HAL_KEY_TYPE_HASHSIG_LMS;
lms_key->lms = lms;
lms_key->lmots = lmots;
lms_key->level = i;
lms_key->lmots_keys = (hal_uuid_t *)gnaw(&mem, &len, h2 * sizeof(hal_uuid_t));
- lms_key->T = gnaw(&mem, &len, (2 * h2 - 1) * sizeof(bytestring32));
+ lms_key->T = gnaw(&mem, &len, (2 * h2) * sizeof(bytestring32));
lms_key->signature = gnaw(&mem, &len, lms_sig_len);
lms_key->signature_len = lms_sig_len;
lms_key->pubkey = gnaw(&mem, &len, lms_pub_len);
lms_key->pubkey_len = lms_pub_len;
+ }
+
+ return HAL_OK;
+}
+
+/* called from pkey_local_generate_hashsig */
+hal_error_t hal_hashsig_key_gen(hal_core_t *core,
+ hal_hashsig_key_t **key_,
+ const size_t L,
+ const lms_algorithm_t lms_type,
+ const lmots_algorithm_t lmots_type)
+{
+ /* hss_alloc does most of the checks */
+
+ /* check flash keystore for space to store the root tree */
+ lms_parameter_t *lms = lms_select_parameter_set(lms_type);
+ if (lms == NULL)
+ return HAL_ERROR_BAD_ARGUMENTS;
+ size_t available;
+ check(hal_ks_available(hal_ks_token, &available));
+ if (available < (1U << lms->h) + 2)
+ return HAL_ERROR_NO_KEY_INDEX_SLOTS;
+
+ check(hss_alloc(key_, L, lms_type, lmots_type));
+ hss_key_t *key = *key_;
+
+ /* generate the lms trees */
+ for (size_t i = 0; i < L; ++i) {
+ lms_key_t * lms_key = &key->lms_keys[i];
check(lms_generate(lms_key));
if (i > 0)
/* sign this tree with the previous */
check(lms_sign(&key->lms_keys[i-1],
- (const uint8_t * const)lms_key->pubkey, lms_pub_len,
- lms_key->signature, NULL, lms_sig_len));
+ (const uint8_t * const)lms_key->pubkey, lms_public_key_len(key->lms),
+ lms_key->signature, NULL, lms_signature_len(key->lms, key->lmots)));
/* store the lms key */
hal_pkey_slot_t slot = {
.type = HAL_KEY_TYPE_HASHSIG_LMS,
.curve = HAL_CURVE_NONE,
- .flags = (i == 0) ? HAL_KEY_FLAG_TOKEN: 0
+ .flags = HAL_KEY_FLAG_USAGE_DIGITALSIGNATURE | ((i == 0) ? HAL_KEY_FLAG_TOKEN: 0)
};
hal_ks_t *ks = (i == 0) ? hal_ks_token : hal_ks_volatile;
uint8_t der[lms_private_key_to_der_len(lms_key)];
@@ -1307,13 +1324,12 @@ hal_error_t hal_hashsig_key_gen(hal_core_t *core,
memcpy(&key->I, &key->lms_keys[0].I, sizeof(key->I));
memcpy(&key->T1, &key->lms_keys[0].T1, sizeof(key->T1));
- *key_ = key;
-
/* pkey_local_generate_hashsig stores the key */
return HAL_OK;
}
+/* caller will delete the hss key from the keystore */
hal_error_t hal_hashsig_key_delete(const hal_hashsig_key_t * const key)
{
if (key == NULL || key->type != HAL_KEY_TYPE_HASHSIG_PRIVATE)
@@ -1324,6 +1340,7 @@ hal_error_t hal_hashsig_key_delete(const hal_hashsig_key_t * const key)
check(lms_delete(&key->lms_keys[level]));
/* XXX free memory, if supported */
+ (void)hal_free_static_memory(key);
/* remove from global hss_keys linked list */
/* XXX or mark it unused, for possible re-use */
@@ -1536,10 +1553,11 @@ hal_error_t hal_hashsig_private_key_to_der(const hal_hashsig_key_t * const key,
size_t len, vlen = 0, hlen;
- check(hal_asn1_encode_size_t(key->L, NULL, &len, 0)); vlen += len;
- check(hal_asn1_encode_lms_algorithm(key->lms->type, NULL, &len, 0)); vlen += len;
- check(hal_asn1_encode_lmots_algorithm(key->lmots->type, NULL, &len, 0)); vlen += len;
- check(hal_asn1_encode_uuid((hal_uuid_t *)&key->lms_keys[0].I, NULL, &len, 0)); vlen += len;
+ check(hal_asn1_encode_size_t(key->L, NULL, &len, 0)); vlen += len;
+ check(hal_asn1_encode_lms_algorithm(key->lms->type, NULL, &len, 0)); vlen += len;
+ check(hal_asn1_encode_lmots_algorithm(key->lmots->type, NULL, &len, 0)); vlen += len;
+ check(hal_asn1_encode_bytestring16(&key->I, NULL, &len, 0)); vlen += len;
+ check(hal_asn1_encode_bytestring32(&key->T1, NULL, &len, 0)); vlen += len;
check(hal_asn1_encode_header(ASN1_SEQUENCE, vlen, NULL, &hlen, 0));
@@ -1558,10 +1576,11 @@ hal_error_t hal_hashsig_private_key_to_der(const hal_hashsig_key_t * const key,
uint8_t *d = der + hlen;
memset(d, 0, vlen);
- check(hal_asn1_encode_size_t(key->L, d, &len, vlen)); d += len; vlen -= len;
- check(hal_asn1_encode_lms_algorithm(key->lms->type, d, &len, vlen)); d += len; vlen -= len;
- check(hal_asn1_encode_lmots_algorithm(key->lmots->type, d, &len, vlen)); d += len; vlen -= len;
- check(hal_asn1_encode_uuid((hal_uuid_t *)&key->lms_keys[0].I, d, &len, vlen)); d += len; vlen -= len;
+ check(hal_asn1_encode_size_t(key->L, d, &len, vlen)); d += len; vlen -= len;
+ check(hal_asn1_encode_lms_algorithm(key->lms->type, d, &len, vlen)); d += len; vlen -= len;
+ check(hal_asn1_encode_lmots_algorithm(key->lmots->type, d, &len, vlen)); d += len; vlen -= len;
+ check(hal_asn1_encode_bytestring16(&key->I, d, &len, vlen)); d += len; vlen -= len;
+ check(hal_asn1_encode_bytestring32(&key->T1, d, &len, vlen)); d += len; vlen -= len;
return hal_asn1_encode_pkcs8_privatekeyinfo(hal_asn1_oid_mts_hashsig, hal_asn1_oid_mts_hashsig_len,
NULL, 0, der, d - der, der, der_len, der_max);
@@ -1582,7 +1601,7 @@ hal_error_t hal_hashsig_private_key_from_der(hal_hashsig_key_t **key_,
memset(keybuf, 0, keybuf_len);
- hss_key_t *key = keybuf;
+ hss_key_t *key = *key_ = keybuf;
key->type = HAL_KEY_TYPE_HASHSIG_PRIVATE;
@@ -1614,8 +1633,8 @@ hal_error_t hal_hashsig_private_key_from_der(hal_hashsig_key_t **key_,
lmots_algorithm_t lmots_type;
check(hal_asn1_decode_lmots_algorithm(&lmots_type, d, &n, vlen)); d += n; vlen -= n;
key->lmots = lmots_select_parameter_set(lmots_type);
- hal_uuid_t I;
- check(hal_asn1_decode_uuid(&I, d, &n, vlen)); d += n; vlen -= n;
+ check(hal_asn1_decode_bytestring16(&key->I, d, &n, vlen)); d += n; vlen -= n;
+ check(hal_asn1_decode_bytestring32(&key->T1, d, &n, vlen)); d += n; vlen -= n;
if (d != privkey + privkey_len)
return HAL_ERROR_ASN1_PARSE_FAILED;
@@ -1626,12 +1645,12 @@ hal_error_t hal_hashsig_private_key_from_der(hal_hashsig_key_t **key_,
* and not molest ours.)
*/
for (hss_key_t *hss_key = hss_keys; hss_key != NULL; hss_key = hss_key->next) {
- if (hal_uuid_cmp(&I, (hal_uuid_t *)&hss_key->lms_keys[0].I) == 0) {
+ if (memcmp(&key->I, &hss_key->lms_keys[0].I, sizeof(key->I)) == 0) {
*key_ = hss_key;
- return HAL_OK;
}
}
- return HAL_ERROR_KEY_NOT_FOUND; // or IMPOSSIBLE?
+
+ return HAL_OK;
}
hal_error_t hal_hashsig_public_key_to_der(const hal_hashsig_key_t * const key,
@@ -1838,3 +1857,202 @@ hal_error_t hal_hashsig_public_key_der_to_xdr(const uint8_t * const der, const s
return HAL_OK;
}
+
+#if RPC_CLIENT == RPC_CLIENT_LOCAL
+/* Reinitialize the hashsig key structures after a device restart */
+hal_error_t hal_hashsig_ks_init(void)
+{
+ const hal_client_handle_t client = { -1 };
+ const hal_session_handle_t session = { HAL_HANDLE_NONE };
+ hal_uuid_t prev_name = {{0}};
+ unsigned len;
+ hal_pkey_slot_t slot = {0};
+ uint8_t der[HAL_KS_WRAPPED_KEYSIZE];
+ size_t der_len;
+
+ /* Find all hss private keys */
+ while ((hal_ks_match(hal_ks_token, client, session,
+ HAL_KEY_TYPE_HASHSIG_PRIVATE, HAL_CURVE_NONE, 0, 0, NULL, 0,
+ &slot.name, &len, 1, &prev_name) == HAL_OK) && (len > 0)) {
+ hal_hashsig_key_t keybuf, *key;
+ if (hal_ks_fetch(hal_ks_token, &slot, der, &der_len, sizeof(der)) != HAL_OK ||
+ hal_hashsig_private_key_from_der(&key, (void *)&keybuf, sizeof(keybuf), der, der_len) != HAL_OK) {
+ (void)hal_ks_delete(hal_ks_token, &slot);
+ continue;
+ }
+
+ /* Make sure we have the lms key */
+ hal_pkey_slot_t lms_slot = {0};
+ lms_key_t lms_key;
+ memcpy(&lms_slot.name, &key->I, sizeof(lms_slot.name));
+ if (hal_ks_fetch(hal_ks_token, &lms_slot, der, &der_len, sizeof(der)) != HAL_OK ||
+ lms_private_key_from_der(&lms_key, der, der_len) != HAL_OK ||
+ /* check keys for consistency */
+ lms_key.lms != key->lms ||
+ lms_key.lmots != key->lmots ||
+ memcmp(&lms_key.I, &key->I, sizeof(lms_key.I)) != 0 ||
+ /* optimistically allocate the full hss key structure */
+ hss_alloc(&key, key->L, key->lms->type, key->lmots->type) != HAL_OK) {
+ (void)hal_ks_delete(hal_ks_token, &slot);
+ (void)hal_ks_delete(hal_ks_token, &lms_slot);
+ continue;
+ }
+
+ /* hss_alloc redefines key, so copy fields from the old version of the key */
+ memcpy(&key->I, &keybuf.I, sizeof(key->I));
+ memcpy(&key->T1, &keybuf.T1, sizeof(key->T1));
+ key->name = slot.name;
+
+ /* initialize top-level lms key (beyond what hss_alloc did) */
+ memcpy(&key->lms_keys[0].I, &lms_key.I, sizeof(lms_key.I));
+ key->lms_keys[0].q = lms_key.q;
+
+ prev_name = slot.name;
+ }
+
+ /* Delete orphaned lms keys */
+ memset(&prev_name, 0, sizeof(prev_name));
+ while ((hal_ks_match(hal_ks_token, client, session,
+ HAL_KEY_TYPE_HASHSIG_LMS, HAL_CURVE_NONE, 0, 0, NULL, 0,
+ &slot.name, &len, 1, &prev_name) == HAL_OK) && (len > 0)) {
+ hss_key_t *hss_key;
+ for (hss_key = hss_keys; hss_key != NULL; hss_key = hss_key->next) {
+ if (memcmp(&slot.name, &hss_key->I, sizeof(slot.name)) == 0)
+ break;
+ }
+ if (hss_key == NULL) {
+ (void)hal_ks_delete(hal_ks_token, &slot);
+ continue;
+ }
+
+ prev_name = slot.name;
+ }
+
+ /* Find all lmots keys */
+ memset(&prev_name, 0, sizeof(prev_name));
+ while ((hal_ks_match(hal_ks_token, client, session,
+ HAL_KEY_TYPE_HASHSIG_LMOTS, HAL_CURVE_NONE, 0, 0, NULL, 0,
+ &slot.name, &len, 1, &prev_name) == HAL_OK) && (len > 0)) {
+ if (hss_keys == NULL) {
+ /* if no hss keys were recovered, all lmots keys are orphaned */
+ (void)hal_ks_delete(hal_ks_token, &slot);
+ continue;
+ }
+
+ lmots_key_t lmots_key = {0};
+ if (hal_ks_fetch(hal_ks_token, &slot, der, &der_len, sizeof(der)) != HAL_OK ||
+ lmots_private_key_from_der(&lmots_key, der, der_len) != HAL_OK) {
+ (void)hal_ks_delete(hal_ks_token, &slot);
+ continue;
+ }
+
+ hss_key_t *hss_key;
+ for (hss_key = hss_keys; hss_key != NULL; hss_key = hss_key->next) {
+ if (memcmp(&hss_key->I, &lmots_key.I, sizeof(lmots_key.I)) == 0)
+ break;
+ }
+ if (hss_key == NULL) {
+ /* delete orphaned key */
+ (void)hal_ks_delete(hal_ks_token, &slot);
+ continue;
+ }
+
+ /* record this lmots key in the top-level lms key */
+ memcpy(&hss_key->lms_keys[0].lmots_keys[lmots_key.q], &slot.name, sizeof(slot.name));
+
+ /* compute T[r] = H(I || u32str(r) || u16str(D_LEAF) || K) */
+ size_t r = (1U << hss_key->lms->h) + lmots_key.q;
+ uint8_t statebuf[512];
+ hal_hash_state_t *state = NULL;
+ hal_hash_initialize(NULL, hal_hash_sha256, &state, statebuf, sizeof(statebuf));
+ hal_hash_update(state, (const uint8_t *)&hss_key->I, sizeof(hss_key->I));
+ uint32_t l = u32str(r); hal_hash_update(state, (const uint8_t *)&l, sizeof(l));
+ uint16_t s = u16str(D_LEAF); hal_hash_update(state, (const uint8_t *)&s, sizeof(s));
+ hal_hash_update(state, (const uint8_t *)&lmots_key.K, sizeof(lmots_key.K));
+ hal_hash_finalize(state, (uint8_t *)&hss_key->lms_keys[0].T[r], sizeof(hss_key->lms_keys[0].T[r]));
+
+ prev_name = slot.name;
+ }
+
+ /* After all keys have been read, scan for completeness. */
+ hal_uuid_t uuid_0 = {{0}};
+ hss_key_t *hss_key, *hss_next = NULL;
+ for (hss_key = hss_keys; hss_key != NULL; hss_key = hss_next) {
+ hss_next = hss_key->next;
+ int fail = 0;
+ for (size_t i = 0; i < (1U << hss_key->lms->h); ++i) {
+ if (hal_uuid_cmp(&hss_key->lms_keys[0].lmots_keys[i], &uuid_0) == 0) {
+ fail = 1;
+ break;
+ }
+ }
+ if (fail) {
+ fail:
+ /* lms key is incomplete, give up on it */
+ /* delete lmots keys */
+ for (size_t i = 0; i < (1U << hss_key->lms->h); ++i) {
+ if (hal_uuid_cmp(&hss_key->lms_keys[0].lmots_keys[i], &uuid_0) != 0) {
+ memcpy(&slot.name, &hss_key->lms_keys[0].lmots_keys[i], sizeof(slot.name));
+ (void)hal_ks_delete(hal_ks_token, &slot);
+ }
+ }
+ /* delete lms key */
+ memcpy(&slot.name, &hss_key->I, sizeof(slot.name));
+ (void)hal_ks_delete(hal_ks_token, &slot);
+ /* delete hss key */
+ slot.name = hss_key->name;
+ (void)hal_ks_delete(hal_ks_token, &slot);
+ /* remove the hss key from the key list */
+ if (hss_keys == hss_key) {
+ hss_keys = hss_key->next;
+ }
+ else {
+ for (hss_key_t *prev = hss_keys; prev != NULL; prev = prev->next) {
+ if (prev->next == hss_key) {
+ prev->next = hss_key->next;
+ break;
+ }
+ }
+ }
+ (void)hal_free_static_memory(hss_key);
+ continue;
+ }
+
+ /* generate the rest of T[] */
+ for (size_t r = (1U << hss_key->lms->h) - 1; r > 0; --r) {
+ uint8_t statebuf[512];
+ hal_hash_state_t *state = NULL;
+ hal_hash_initialize(NULL, hal_hash_sha256, &state, statebuf, sizeof(statebuf));
+ hal_hash_update(state, (const uint8_t *)&hss_key->I, sizeof(hss_key->I));
+ uint32_t l = u32str(r); hal_hash_update(state, (const uint8_t *)&l, sizeof(l));
+ uint16_t s = u16str(D_INTR); check(hal_hash_update(state, (const uint8_t *)&s, sizeof(s)));
+ hal_hash_update(state, (const uint8_t *)&hss_key->lms_keys[0].T[2*r], sizeof(hss_key->lms_keys[0].T[r]));
+ hal_hash_update(state, (const uint8_t *)&hss_key->lms_keys[0].T[2*r+1], sizeof(hss_key->lms_keys[0].T[r]));
+ hal_hash_finalize(state, (uint8_t *)&hss_key->lms_keys[0].T[r], sizeof(hss_key->lms_keys[0].T[r]));
+ }
+ if (memcmp(&hss_key->lms_keys[0].T[1], &hss_key->T1, sizeof(hss_key->lms_keys[0].T[1])) != 0)
+ goto fail;
+
+ /* generate the lower-level lms keys */
+ for (size_t i = 1; i < hss_key->L; ++i) {
+ lms_key_t * lms_key = &hss_key->lms_keys[i];
+ if (lms_generate(lms_key) != HAL_OK)
+ goto fail;
+
+ /* store the lms key */
+ slot.type = HAL_KEY_TYPE_HASHSIG_LMS;
+ slot.flags = HAL_KEY_FLAG_USAGE_DIGITALSIGNATURE;
+ memcpy(&slot.name, &lms_key->I, sizeof(slot.name));
+ if (lms_private_key_to_der(lms_key, der, &der_len, sizeof(der)) != HAL_OK ||
+ hal_ks_store(hal_ks_volatile, &slot, der, der_len) != HAL_OK ||
+ /* sign this lms key with the previous */
+ lms_sign(&hss_key->lms_keys[i-1],
+ (const uint8_t * const)lms_key->pubkey, lms_key->pubkey_len,
+ lms_key->signature, NULL, lms_key->signature_len) != HAL_OK)
+ goto fail;
+ }
+ }
+
+ return HAL_OK;
+}
+#endif
diff --git a/hashsig.h b/hashsig.h
index 7bae86e..3753496 100644
--- a/hashsig.h
+++ b/hashsig.h
@@ -1,5 +1,5 @@
/*
- * hashsig.c
+ * hashsig.h
* ---------
* Implementation of draft-mcgrew-hash-sigs-08.txt
*
@@ -113,6 +113,6 @@ extern size_t hal_hashsig_lmots_private_key_len(const lmots_algorithm_t lmots_ty
extern hal_error_t hal_hashsig_public_key_der_to_xdr(const uint8_t * const der, const size_t der_len,
uint8_t * const xdr, size_t * const xdr_len , const size_t xdr_max);
-//extern hal_error_t hal_hashsig_restart(...);
+extern hal_error_t hal_hashsig_ks_init(void);
#endif /* _HAL_HASHSIG_H_ */
diff --git a/tests/test-rpc_hashsig.c b/tests/test-rpc_hashsig.c
index b93f11e..00728c3 100644
--- a/tests/test-rpc_hashsig.c
+++ b/tests/test-rpc_hashsig.c
@@ -264,7 +264,7 @@ static int test_hashsig_sign(const size_t L,
const lms_algorithm_t lms_type,
const lmots_algorithm_t lmots_type,
size_t iterations,
- int save)
+ int save, int keep)
{
const hal_client_handle_t client = {HAL_HANDLE_NONE};
const hal_session_handle_t session = {HAL_HANDLE_NONE};
@@ -287,7 +287,7 @@ static int test_hashsig_sign(const size_t L,
lose("Error closing %s: %s\n", save_name, strerror(errno));
}
- hal_key_flags_t flags = HAL_KEY_FLAG_USAGE_DIGITALSIGNATURE;
+ hal_key_flags_t flags = HAL_KEY_FLAG_USAGE_DIGITALSIGNATURE | HAL_KEY_FLAG_TOKEN;
printf("Starting hashsig key test: L %lu, lms type %u (h=%lu), lmots type %u (w=%lu)\n",
L, lms_type, lms_type_to_h(lms_type), lmots_type, lmots_type_to_w(lmots_type));
@@ -399,8 +399,10 @@ static int test_hashsig_sign(const size_t L,
}
}
- if ((err = hal_rpc_pkey_delete(private_key)) != HAL_OK)
- lose("Could not delete private key: %s\n", hal_error_string(err));
+ if (!keep) {
+ if ((err = hal_rpc_pkey_delete(private_key)) != HAL_OK)
+ lose("Could not delete private key: %s\n", hal_error_string(err));
+ }
if ((err = hal_rpc_pkey_delete(public_key)) != HAL_OK)
lose("Could not delete public key: %s\n", hal_error_string(err));
@@ -460,7 +462,7 @@ int main(int argc, char *argv[])
size_t L_lo = 0, L_hi = 0;
size_t lms_lo = 5, lms_hi = 0;
size_t lmots_lo = 3, lmots_hi = 0;
- int save = 0;
+ int save = 0, keep = 0;
char *p;
hal_error_t err;
int ok = 1;
@@ -476,11 +478,12 @@ Usage: %s [-d] [-i] [-p pin] [-t] [-L n] [-l n] [-o n] [-n n] [-s] [-r file]\n\
-o: LM-OTS type (1..4)\n\
-n: number of signatures to generate (0..'max')\n\
-s: save generated public key and signatures\n\
+ -k: keep (don't delete) the generated keys on the hsm\n\
-r: read and pretty-print a saved signature file\n\
Numeric arguments can be a single number or a range, e.g. '1..4'\n";
int opt;
- while ((opt = getopt(argc, argv, "ditp:L:l:o:n:sr:h?")) != -1) {
+ while ((opt = getopt(argc, argv, "ditp:L:l:o:n:skr:h?")) != -1) {
switch (opt) {
case 'd':
debug = 1;
@@ -526,6 +529,9 @@ Numeric arguments can be a single number or a range, e.g. '1..4'\n";
case's':
save = 1;
break;
+ case 'k':
+ keep = 1;
+ break;
case 'r':
ok &= read_sig(optarg);
do_default = 0;
@@ -572,7 +578,7 @@ Numeric arguments can be a single number or a range, e.g. '1..4'\n";
for (size_t L = L_lo; L <= L_hi; ++L) {
for (lms_algorithm_t lms_type = lms_lo; lms_type <= lms_hi; ++lms_type) {
for (lmots_algorithm_t lmots_type = lmots_lo; lmots_type <= lmots_hi; ++lmots_type) {
- ok &= test_hashsig_sign(L, lms_type, lmots_type, iterations, save);
+ ok &= test_hashsig_sign(L, lms_type, lmots_type, iterations, save, keep);
}
}
}