/*
* GnuTLS public key support
* Copyright (C) 2010-2012 Free Software Foundation, Inc.
* Copyright (C) 2017 Red Hat, Inc.
*
* Author: Nikos Mavrogiannopoulos
*
* The GnuTLS is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public License
* as published by the Free Software Foundation; either version 2.1 of
* the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program. If not, see
*/
#include "gnutls_int.h"
#include
#include
#include
#include "errors.h"
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include "urls.h"
#include
static int
pubkey_verify_hashed_data(const gnutls_sign_entry_st *se,
const mac_entry_st *me,
const gnutls_datum_t * hash,
const gnutls_datum_t * signature,
gnutls_pk_params_st * params,
gnutls_x509_spki_st * sign_params,
unsigned flags);
static
int pubkey_supports_sig(gnutls_pubkey_t pubkey,
const gnutls_sign_entry_st *se);
unsigned pubkey_to_bits(const gnutls_pk_params_st * params)
{
switch (params->algo) {
case GNUTLS_PK_RSA:
case GNUTLS_PK_RSA_PSS:
return _gnutls_mpi_get_nbits(params->params[RSA_MODULUS]);
case GNUTLS_PK_DSA:
return _gnutls_mpi_get_nbits(params->params[DSA_P]);
case GNUTLS_PK_ECDSA:
case GNUTLS_PK_EDDSA_ED25519:
case GNUTLS_PK_EDDSA_ED448:
case GNUTLS_PK_ECDH_X25519:
case GNUTLS_PK_ECDH_X448:
case GNUTLS_PK_GOST_01:
case GNUTLS_PK_GOST_12_256:
case GNUTLS_PK_GOST_12_512:
return gnutls_ecc_curve_get_size(params->curve) * 8;
default:
return 0;
}
}
/**
* gnutls_pubkey_get_pk_algorithm:
* @key: should contain a #gnutls_pubkey_t type
* @bits: If set will return the number of bits of the parameters (may be NULL)
*
* This function will return the public key algorithm of a public
* key and if possible will return a number of bits that indicates
* the security parameter of the key.
*
* Returns: a member of the #gnutls_pk_algorithm_t enumeration on
* success, or a negative error code on error.
*
* Since: 2.12.0
**/
int gnutls_pubkey_get_pk_algorithm(gnutls_pubkey_t key, unsigned int *bits)
{
if (bits)
*bits = key->bits;
return key->params.algo;
}
/**
* gnutls_pubkey_get_key_usage:
* @key: should contain a #gnutls_pubkey_t type
* @usage: If set will return the number of bits of the parameters (may be NULL)
*
* This function will return the key usage of the public key.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int gnutls_pubkey_get_key_usage(gnutls_pubkey_t key, unsigned int *usage)
{
if (usage)
*usage = key->key_usage;
return 0;
}
/**
* gnutls_pubkey_init:
* @key: A pointer to the type to be initialized
*
* This function will initialize a public key.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int gnutls_pubkey_init(gnutls_pubkey_t * key)
{
FAIL_IF_LIB_ERROR;
*key = gnutls_calloc(1, sizeof(struct gnutls_pubkey_st));
if (*key == NULL) {
gnutls_assert();
return GNUTLS_E_MEMORY_ERROR;
}
return 0;
}
/**
* gnutls_pubkey_deinit:
* @key: The key to be deinitialized
*
* This function will deinitialize a public key structure.
*
* Since: 2.12.0
**/
void gnutls_pubkey_deinit(gnutls_pubkey_t key)
{
if (!key)
return;
gnutls_pk_params_release(&key->params);
gnutls_free(key);
}
/**
* gnutls_pubkey_import_x509:
* @key: The public key
* @crt: The certificate to be imported
* @flags: should be zero
*
* This function will import the given public key to the abstract
* #gnutls_pubkey_t type.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int
gnutls_pubkey_import_x509(gnutls_pubkey_t key, gnutls_x509_crt_t crt,
unsigned int flags)
{
int ret;
gnutls_pk_params_release(&key->params);
/* params initialized in _gnutls_x509_crt_get_mpis */
ret = gnutls_x509_crt_get_pk_algorithm(crt, &key->bits);
if (ret < 0)
return gnutls_assert_val(ret);
key->params.algo = ret;
ret = gnutls_x509_crt_get_key_usage(crt, &key->key_usage, NULL);
if (ret < 0)
key->key_usage = 0;
ret = _gnutls_x509_crt_get_mpis(crt, &key->params);
if (ret < 0) {
gnutls_assert();
return ret;
}
return 0;
}
/**
* gnutls_pubkey_import_x509_crq:
* @key: The public key
* @crq: The certificate to be imported
* @flags: should be zero
*
* This function will import the given public key to the abstract
* #gnutls_pubkey_t type.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 3.1.5
**/
int
gnutls_pubkey_import_x509_crq(gnutls_pubkey_t key, gnutls_x509_crq_t crq,
unsigned int flags)
{
int ret;
gnutls_pk_params_release(&key->params);
/* params initialized in _gnutls_x509_crq_get_mpis */
key->params.algo = gnutls_x509_crq_get_pk_algorithm(crq, &key->bits);
ret = gnutls_x509_crq_get_key_usage(crq, &key->key_usage, NULL);
if (ret < 0)
key->key_usage = 0;
ret = _gnutls_x509_crq_get_mpis(crq, &key->params);
if (ret < 0) {
gnutls_assert();
return ret;
}
return 0;
}
/**
* gnutls_pubkey_import_privkey:
* @key: The public key
* @pkey: The private key
* @usage: GNUTLS_KEY_* key usage flags.
* @flags: should be zero
*
* Imports the public key from a private. This function will import
* the given public key to the abstract #gnutls_pubkey_t type.
*
* Note that in certain keys this operation may not be possible, e.g.,
* in other than RSA PKCS#11 keys.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int
gnutls_pubkey_import_privkey(gnutls_pubkey_t key, gnutls_privkey_t pkey,
unsigned int usage, unsigned int flags)
{
gnutls_pk_params_release(&key->params);
gnutls_pk_params_init(&key->params);
key->key_usage = usage;
key->params.algo = gnutls_privkey_get_pk_algorithm(pkey, &key->bits);
return _gnutls_privkey_get_public_mpis(pkey, &key->params);
}
/**
* gnutls_pubkey_get_preferred_hash_algorithm:
* @key: Holds the certificate
* @hash: The result of the call with the hash algorithm used for signature
* @mand: If non zero it means that the algorithm MUST use this hash. May be NULL.
*
* This function will read the certificate and return the appropriate digest
* algorithm to use for signing with this certificate. Some certificates (i.e.
* DSA might not be able to sign without the preferred algorithm).
*
* To get the signature algorithm instead of just the hash use gnutls_pk_to_sign()
* with the algorithm of the certificate/key and the provided @hash.
*
* Returns: the 0 if the hash algorithm is found. A negative error code is
* returned on error.
*
* Since: 2.12.0
**/
int
gnutls_pubkey_get_preferred_hash_algorithm(gnutls_pubkey_t key,
gnutls_digest_algorithm_t *
hash, unsigned int *mand)
{
int ret;
const mac_entry_st *me;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (mand)
*mand = 0;
switch (key->params.algo) {
case GNUTLS_PK_DSA:
if (mand)
*mand = 1;
FALLTHROUGH;
case GNUTLS_PK_ECDSA:
me = _gnutls_dsa_q_to_hash(&key->params, NULL);
if (hash)
*hash = (gnutls_digest_algorithm_t)me->id;
ret = 0;
break;
case GNUTLS_PK_EDDSA_ED25519:
if (hash)
*hash = GNUTLS_DIG_SHA512;
ret = 0;
break;
case GNUTLS_PK_EDDSA_ED448:
if (hash)
*hash = GNUTLS_DIG_SHAKE_256;
ret = 0;
break;
case GNUTLS_PK_GOST_01:
case GNUTLS_PK_GOST_12_256:
case GNUTLS_PK_GOST_12_512:
if (hash)
*hash = _gnutls_gost_digest(key->params.algo);
if (mand)
*mand = 1;
ret = 0;
break;
case GNUTLS_PK_RSA_PSS:
if (mand && key->params.spki.rsa_pss_dig)
*mand = 1;
if (hash) {
if (key->params.spki.rsa_pss_dig) {
*hash = key->params.spki.rsa_pss_dig;
} else {
*hash = _gnutls_pk_bits_to_sha_hash(pubkey_to_bits(&key->params));
}
}
ret = 0;
break;
case GNUTLS_PK_RSA:
if (hash)
*hash = _gnutls_pk_bits_to_sha_hash(pubkey_to_bits(&key->params));
ret = 0;
break;
default:
gnutls_assert();
ret = GNUTLS_E_INTERNAL_ERROR;
}
return ret;
}
#ifdef ENABLE_PKCS11
/* The EC_PARAMS attribute can contain either printable string with curve name
* or OID defined in RFC 8410 */
static int
gnutls_pubkey_parse_ecc_eddsa_params(const gnutls_datum_t *parameters,
gnutls_ecc_curve_t *outcurve)
{
gnutls_ecc_curve_t curve = GNUTLS_ECC_CURVE_INVALID;
asn1_node asn1 = NULL;
unsigned int etype = ASN1_ETYPE_INVALID;
char str[MAX_OID_SIZE];
int str_size;
int ret;
ret = asn1_create_element(_gnutls_get_gnutls_asn(),
"GNUTLS.pkcs-11-ec-Parameters", &asn1);
if (ret != ASN1_SUCCESS) {
gnutls_assert();
return _gnutls_asn2err(ret);
}
ret = asn1_der_decoding(&asn1, parameters->data, parameters->size,
NULL);
if (ret != ASN1_SUCCESS) {
gnutls_assert();
ret = _gnutls_asn2err(ret);
goto cleanup;
}
/* Read the type of choice.
*/
str_size = sizeof(str) - 1;
ret = asn1_read_value(asn1, "", str, &str_size);
if (ret != ASN1_SUCCESS) {
gnutls_assert();
ret = _gnutls_asn2err(ret);
goto cleanup;
}
str[str_size] = 0;
/* Convert the choice to enum type */
if (strcmp(str, "oId") == 0) {
etype = ASN1_ETYPE_OBJECT_ID;
} else if (strcmp(str, "curveName") == 0) {
etype = ASN1_ETYPE_PRINTABLE_STRING;
}
str_size = sizeof(str) - 1;
switch (etype) {
case ASN1_ETYPE_OBJECT_ID:
ret = asn1_read_value(asn1, "oId", str, &str_size);
if (ret != ASN1_SUCCESS) {
gnutls_assert();
ret = _gnutls_asn2err(ret);
break;
}
curve = gnutls_oid_to_ecc_curve(str);
if (curve != GNUTLS_ECC_CURVE_ED25519 &&
curve != GNUTLS_ECC_CURVE_ED448) {
_gnutls_debug_log("Curve %s is not supported for EdDSA\n", str);
gnutls_assert();
curve = GNUTLS_ECC_CURVE_INVALID;
ret = GNUTLS_E_ECC_UNSUPPORTED_CURVE;
break;
}
ret = GNUTLS_E_SUCCESS;
break;
case ASN1_ETYPE_PRINTABLE_STRING:
ret = asn1_read_value(asn1, "curveName", str, &str_size);
if (ret != ASN1_SUCCESS) {
gnutls_assert();
ret = _gnutls_asn2err(ret);
break;
}
if (str_size == strlen("edwards25519") &&
strncmp(str, "edwards25519", str_size) == 0) {
curve = GNUTLS_ECC_CURVE_ED25519;
ret = GNUTLS_E_SUCCESS;
break;
} else if (str_size == strlen("edwards448") &&
strncmp(str, "edwards448", str_size) == 0) {
curve = GNUTLS_ECC_CURVE_ED448;
ret = GNUTLS_E_SUCCESS;
break;
}
/* FALLTHROUGH */
default:
/* Neither of CHOICEs found. Fail */
gnutls_assert();
ret = GNUTLS_E_ECC_UNSUPPORTED_CURVE;
curve = GNUTLS_ECC_CURVE_INVALID;
break;
}
cleanup:
asn1_delete_structure(&asn1);
*outcurve = curve;
return ret;
}
static int
gnutls_pubkey_import_ecc_eddsa(gnutls_pubkey_t key,
const gnutls_datum_t * parameters,
const gnutls_datum_t * ecpoint)
{
int ret;
gnutls_ecc_curve_t curve = GNUTLS_ECC_CURVE_INVALID;
gnutls_datum_t raw_point = {NULL, 0};
ret = gnutls_pubkey_parse_ecc_eddsa_params(parameters, &curve);
if (ret < 0) {
return gnutls_assert_val(ret);
}
ret = _gnutls_x509_decode_string(ASN1_ETYPE_OCTET_STRING,
ecpoint->data, ecpoint->size,
&raw_point, 0);
if (ret < 0) {
gnutls_assert();
gnutls_free(raw_point.data);
return ret;
}
ret = gnutls_pubkey_import_ecc_raw(key, curve, &raw_point, NULL);
gnutls_free(raw_point.data);
return ret;
}
/* Same as above, but for Edwards key agreement */
static int
gnutls_pubkey_parse_ecc_ecdh_params(const gnutls_datum_t *parameters,
gnutls_ecc_curve_t *outcurve)
{
gnutls_ecc_curve_t curve = GNUTLS_ECC_CURVE_INVALID;
asn1_node asn1 = NULL;
unsigned int etype = ASN1_ETYPE_INVALID;
char str[MAX_OID_SIZE];
int str_size;
int ret;
ret = asn1_create_element(_gnutls_get_gnutls_asn(),
"GNUTLS.pkcs-11-ec-Parameters", &asn1);
if (ret != ASN1_SUCCESS) {
gnutls_assert();
return _gnutls_asn2err(ret);
}
ret = asn1_der_decoding(&asn1, parameters->data, parameters->size,
NULL);
if (ret != ASN1_SUCCESS) {
gnutls_assert();
ret = _gnutls_asn2err(ret);
goto cleanup;
}
/* Read the type of choice.
*/
str_size = sizeof(str) - 1;
ret = asn1_read_value(asn1, "", str, &str_size);
if (ret != ASN1_SUCCESS) {
gnutls_assert();
ret = _gnutls_asn2err(ret);
goto cleanup;
}
str[str_size] = 0;
/* Convert the choice to enum type */
if (strcmp(str, "oId") == 0) {
etype = ASN1_ETYPE_OBJECT_ID;
} else if (strcmp(str, "curveName") == 0) {
etype = ASN1_ETYPE_PRINTABLE_STRING;
}
str_size = sizeof(str) - 1;
switch (etype) {
case ASN1_ETYPE_OBJECT_ID:
ret = asn1_read_value(asn1, "oId", str, &str_size);
if (ret != ASN1_SUCCESS) {
gnutls_assert();
ret = _gnutls_asn2err(ret);
break;
}
curve = gnutls_oid_to_ecc_curve(str);
if (curve != GNUTLS_ECC_CURVE_X25519 &&
curve != GNUTLS_ECC_CURVE_X448) {
_gnutls_debug_log("Curve %s is not supported for Edwards-based key agreement\n", str);
gnutls_assert();
curve = GNUTLS_ECC_CURVE_INVALID;
ret = GNUTLS_E_ECC_UNSUPPORTED_CURVE;
break;
}
ret = GNUTLS_E_SUCCESS;
break;
case ASN1_ETYPE_PRINTABLE_STRING:
ret = asn1_read_value(asn1, "curveName", str, &str_size);
if (ret != ASN1_SUCCESS) {
gnutls_assert();
ret = _gnutls_asn2err(ret);
break;
}
if (str_size == strlen("x25519") &&
strncmp(str, "x25519", str_size) == 0) {
curve = GNUTLS_ECC_CURVE_X25519;
ret = GNUTLS_E_SUCCESS;
break;
} else if (str_size == strlen("x448") &&
strncmp(str, "x448", str_size) == 0) {
curve = GNUTLS_ECC_CURVE_X448;
ret = GNUTLS_E_SUCCESS;
break;
}
/* FALLTHROUGH */
default:
/* Neither of CHOICEs found. Fail */
gnutls_assert();
ret = GNUTLS_E_ECC_UNSUPPORTED_CURVE;
curve = GNUTLS_ECC_CURVE_INVALID;
break;
}
cleanup:
asn1_delete_structure(&asn1);
*outcurve = curve;
return ret;
}
static int
gnutls_pubkey_import_ecc_ecdh(gnutls_pubkey_t key,
const gnutls_datum_t * parameters,
const gnutls_datum_t * ecpoint)
{
int ret;
gnutls_ecc_curve_t curve = GNUTLS_ECC_CURVE_INVALID;
gnutls_datum_t raw_point = {NULL, 0};
ret = gnutls_pubkey_parse_ecc_ecdh_params(parameters, &curve);
if (ret < 0) {
return gnutls_assert_val(ret);
}
ret = _gnutls_x509_decode_string(ASN1_ETYPE_OCTET_STRING,
ecpoint->data, ecpoint->size,
&raw_point, 0);
if (ret < 0) {
gnutls_assert();
gnutls_free(raw_point.data);
return ret;
}
ret = gnutls_pubkey_import_ecc_raw(key, curve, &raw_point, NULL);
gnutls_free(raw_point.data);
return ret;
}
/**
* gnutls_pubkey_import_pkcs11:
* @key: The public key
* @obj: The parameters to be imported
* @flags: should be zero
*
* Imports a public key from a pkcs11 key. This function will import
* the given public key to the abstract #gnutls_pubkey_t type.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int
gnutls_pubkey_import_pkcs11(gnutls_pubkey_t key,
gnutls_pkcs11_obj_t obj, unsigned int flags)
{
int ret, type;
type = gnutls_pkcs11_obj_get_type(obj);
if (type != GNUTLS_PKCS11_OBJ_PUBKEY
&& type != GNUTLS_PKCS11_OBJ_X509_CRT) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (type == GNUTLS_PKCS11_OBJ_X509_CRT) {
gnutls_x509_crt_t xcrt;
ret = gnutls_x509_crt_init(&xcrt);
if (ret < 0) {
gnutls_assert()
return ret;
}
ret = gnutls_x509_crt_import_pkcs11(xcrt, obj);
if (ret < 0) {
gnutls_assert();
goto cleanup_crt;
}
ret = gnutls_pubkey_import_x509(key, xcrt, 0);
if (ret < 0) {
gnutls_assert();
goto cleanup_crt;
}
ret = gnutls_x509_crt_get_key_usage(xcrt, &key->key_usage, NULL);
if (ret < 0)
key->key_usage = 0;
ret = 0;
cleanup_crt:
gnutls_x509_crt_deinit(xcrt);
return ret;
}
key->key_usage = obj->key_usage;
switch (obj->pk_algorithm) {
case GNUTLS_PK_RSA:
case GNUTLS_PK_RSA_PSS:
ret = gnutls_pubkey_import_rsa_raw(key, &obj->pubkey[0],
&obj->pubkey[1]);
break;
case GNUTLS_PK_DSA:
ret = gnutls_pubkey_import_dsa_raw(key, &obj->pubkey[0],
&obj->pubkey[1],
&obj->pubkey[2],
&obj->pubkey[3]);
break;
case GNUTLS_PK_EC:
ret = gnutls_pubkey_import_ecc_x962(key, &obj->pubkey[0],
&obj->pubkey[1]);
break;
case GNUTLS_PK_EDDSA_ED25519:
ret = gnutls_pubkey_import_ecc_eddsa(key, &obj->pubkey[0],
&obj->pubkey[1]);
break;
case GNUTLS_PK_ECDH_X25519:
ret = gnutls_pubkey_import_ecc_ecdh(key, &obj->pubkey[0],
&obj->pubkey[1]);
break;
default:
gnutls_assert();
return GNUTLS_E_UNIMPLEMENTED_FEATURE;
}
if (ret < 0) {
gnutls_assert();
return ret;
}
return 0;
}
#endif /* ENABLE_PKCS11 */
/**
* gnutls_pubkey_export:
* @key: Holds the certificate
* @format: the format of output params. One of PEM or DER.
* @output_data: will contain a certificate PEM or DER encoded
* @output_data_size: holds the size of output_data (and will be
* replaced by the actual size of parameters)
*
* This function will export the public key to DER or PEM format.
* The contents of the exported data is the SubjectPublicKeyInfo
* X.509 structure.
*
* If the buffer provided is not long enough to hold the output, then
* *output_data_size is updated and %GNUTLS_E_SHORT_MEMORY_BUFFER will
* be returned.
*
* If the structure is PEM encoded, it will have a header
* of "BEGIN CERTIFICATE".
*
* Returns: In case of failure a negative error code will be
* returned, and 0 on success.
*
* Since: 2.12.0
**/
int
gnutls_pubkey_export(gnutls_pubkey_t key,
gnutls_x509_crt_fmt_t format, void *output_data,
size_t * output_data_size)
{
int result;
asn1_node spk = NULL;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if ((result = asn1_create_element
(_gnutls_get_pkix(), "PKIX1.SubjectPublicKeyInfo", &spk))
!= ASN1_SUCCESS) {
gnutls_assert();
return _gnutls_asn2err(result);
}
result =
_gnutls_x509_encode_and_copy_PKI_params(spk, "",
&key->params);
if (result < 0) {
gnutls_assert();
goto cleanup;
}
result = _gnutls_x509_export_int_named(spk, "",
format, PEM_PK,
output_data,
output_data_size);
if (result < 0) {
gnutls_assert();
goto cleanup;
}
result = 0;
cleanup:
asn1_delete_structure(&spk);
return result;
}
/**
* gnutls_pubkey_export2:
* @key: Holds the certificate
* @format: the format of output params. One of PEM or DER.
* @out: will contain a certificate PEM or DER encoded
*
* This function will export the public key to DER or PEM format.
* The contents of the exported data is the SubjectPublicKeyInfo
* X.509 structure.
*
* The output buffer will be allocated using gnutls_malloc().
*
* If the structure is PEM encoded, it will have a header
* of "BEGIN CERTIFICATE".
*
* Returns: In case of failure a negative error code will be
* returned, and 0 on success.
*
* Since: 3.1.3
**/
int
gnutls_pubkey_export2(gnutls_pubkey_t key,
gnutls_x509_crt_fmt_t format, gnutls_datum_t * out)
{
int result;
asn1_node spk = NULL;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if ((result = asn1_create_element
(_gnutls_get_pkix(), "PKIX1.SubjectPublicKeyInfo", &spk))
!= ASN1_SUCCESS) {
gnutls_assert();
return _gnutls_asn2err(result);
}
result =
_gnutls_x509_encode_and_copy_PKI_params(spk, "",
&key->params);
if (result < 0) {
gnutls_assert();
goto cleanup;
}
result = _gnutls_x509_export_int_named2(spk, "",
format, PEM_PK,
out);
if (result < 0) {
gnutls_assert();
goto cleanup;
}
result = 0;
cleanup:
asn1_delete_structure(&spk);
return result;
}
/**
* gnutls_pubkey_get_key_id:
* @key: Holds the public key
* @flags: should be one of the flags from %gnutls_keyid_flags_t
* @output_data: will contain the key ID
* @output_data_size: holds the size of output_data (and will be
* replaced by the actual size of parameters)
*
* This function will return a unique ID that depends on the public
* key parameters. This ID can be used in checking whether a
* certificate corresponds to the given public key.
*
* If the buffer provided is not long enough to hold the output, then
* *output_data_size is updated and %GNUTLS_E_SHORT_MEMORY_BUFFER will
* be returned. The output will normally be a SHA-1 hash output,
* which is 20 bytes.
*
* Returns: In case of failure a negative error code will be
* returned, and 0 on success.
*
* Since: 2.12.0
**/
int
gnutls_pubkey_get_key_id(gnutls_pubkey_t key, unsigned int flags,
unsigned char *output_data,
size_t * output_data_size)
{
int ret = 0;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
ret =
_gnutls_get_key_id(&key->params,
output_data, output_data_size, flags);
if (ret < 0) {
gnutls_assert();
return ret;
}
return 0;
}
/**
* gnutls_pubkey_export_rsa_raw2:
* @key: Holds the certificate
* @m: will hold the modulus (may be %NULL)
* @e: will hold the public exponent (may be %NULL)
* @flags: flags from %gnutls_abstract_export_flags_t
*
* This function will export the RSA public key's parameters found in
* the given structure. The new parameters will be allocated using
* gnutls_malloc() and will be stored in the appropriate datum.
*
* This function allows for %NULL parameters since 3.4.1.
*
* Returns: %GNUTLS_E_SUCCESS on success, otherwise a negative error code.
*
* Since: 3.6.0
**/
int
gnutls_pubkey_export_rsa_raw2(gnutls_pubkey_t key,
gnutls_datum_t * m, gnutls_datum_t * e,
unsigned flags)
{
int ret;
mpi_dprint_func dprint = _gnutls_mpi_dprint_lz;
if (flags & GNUTLS_EXPORT_FLAG_NO_LZ)
dprint = _gnutls_mpi_dprint;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (!GNUTLS_PK_IS_RSA(key->params.algo)) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (m) {
ret = dprint(key->params.params[0], m);
if (ret < 0) {
gnutls_assert();
return ret;
}
}
if (e) {
ret = dprint(key->params.params[1], e);
if (ret < 0) {
gnutls_assert();
_gnutls_free_datum(m);
return ret;
}
}
return 0;
}
/**
* gnutls_pubkey_export_rsa_raw:
* @key: Holds the certificate
* @m: will hold the modulus (may be %NULL)
* @e: will hold the public exponent (may be %NULL)
*
* This function will export the RSA public key's parameters found in
* the given structure. The new parameters will be allocated using
* gnutls_malloc() and will be stored in the appropriate datum.
*
* This function allows for %NULL parameters since 3.4.1.
*
* Returns: %GNUTLS_E_SUCCESS on success, otherwise a negative error code.
*
* Since: 3.3.0
**/
int
gnutls_pubkey_export_rsa_raw(gnutls_pubkey_t key,
gnutls_datum_t * m, gnutls_datum_t * e)
{
return gnutls_pubkey_export_rsa_raw2(key, m, e, 0);
}
/**
* gnutls_pubkey_export_dsa_raw:
* @key: Holds the public key
* @p: will hold the p (may be %NULL)
* @q: will hold the q (may be %NULL)
* @g: will hold the g (may be %NULL)
* @y: will hold the y (may be %NULL)
*
* This function will export the DSA public key's parameters found in
* the given certificate. The new parameters will be allocated using
* gnutls_malloc() and will be stored in the appropriate datum.
*
* This function allows for %NULL parameters since 3.4.1.
*
* Returns: %GNUTLS_E_SUCCESS on success, otherwise a negative error code.
*
* Since: 3.3.0
**/
int
gnutls_pubkey_export_dsa_raw(gnutls_pubkey_t key,
gnutls_datum_t * p, gnutls_datum_t * q,
gnutls_datum_t * g, gnutls_datum_t * y)
{
return gnutls_pubkey_export_dsa_raw2(key, p, q, g, y, 0);
}
/**
* gnutls_pubkey_export_dsa_raw2:
* @key: Holds the public key
* @p: will hold the p (may be %NULL)
* @q: will hold the q (may be %NULL)
* @g: will hold the g (may be %NULL)
* @y: will hold the y (may be %NULL)
* @flags: flags from %gnutls_abstract_export_flags_t
*
* This function will export the DSA public key's parameters found in
* the given certificate. The new parameters will be allocated using
* gnutls_malloc() and will be stored in the appropriate datum.
*
* This function allows for %NULL parameters since 3.4.1.
*
* Returns: %GNUTLS_E_SUCCESS on success, otherwise a negative error code.
*
* Since: 3.6.0
**/
int
gnutls_pubkey_export_dsa_raw2(gnutls_pubkey_t key,
gnutls_datum_t * p, gnutls_datum_t * q,
gnutls_datum_t * g, gnutls_datum_t * y,
unsigned flags)
{
int ret;
mpi_dprint_func dprint = _gnutls_mpi_dprint_lz;
if (flags & GNUTLS_EXPORT_FLAG_NO_LZ)
dprint = _gnutls_mpi_dprint;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (key->params.algo != GNUTLS_PK_DSA) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
/* P */
if (p) {
ret = dprint(key->params.params[0], p);
if (ret < 0) {
gnutls_assert();
return ret;
}
}
/* Q */
if (q) {
ret = dprint(key->params.params[1], q);
if (ret < 0) {
gnutls_assert();
_gnutls_free_datum(p);
return ret;
}
}
/* G */
if (g) {
ret = dprint(key->params.params[2], g);
if (ret < 0) {
gnutls_assert();
_gnutls_free_datum(p);
_gnutls_free_datum(q);
return ret;
}
}
/* Y */
if (y) {
ret = dprint(key->params.params[3], y);
if (ret < 0) {
gnutls_assert();
_gnutls_free_datum(p);
_gnutls_free_datum(g);
_gnutls_free_datum(q);
return ret;
}
}
return 0;
}
/**
* gnutls_pubkey_export_ecc_raw:
* @key: Holds the public key
* @curve: will hold the curve (may be %NULL)
* @x: will hold x-coordinate (may be %NULL)
* @y: will hold y-coordinate (may be %NULL)
*
* This function will export the ECC public key's parameters found in
* the given key. The new parameters will be allocated using
* gnutls_malloc() and will be stored in the appropriate datum.
*
* In EdDSA curves the @y parameter will be %NULL and the other parameters
* will be in the native format for the curve.
*
* This function allows for %NULL parameters since 3.4.1.
*
* Returns: %GNUTLS_E_SUCCESS on success, otherwise a negative error code.
*
* Since: 3.0
**/
int
gnutls_pubkey_export_ecc_raw(gnutls_pubkey_t key,
gnutls_ecc_curve_t * curve,
gnutls_datum_t * x, gnutls_datum_t * y)
{
return gnutls_pubkey_export_ecc_raw2(key, curve, x, y, 0);
}
/**
* gnutls_pubkey_export_ecc_raw2:
* @key: Holds the public key
* @curve: will hold the curve (may be %NULL)
* @x: will hold x-coordinate (may be %NULL)
* @y: will hold y-coordinate (may be %NULL)
* @flags: flags from %gnutls_abstract_export_flags_t
*
* This function will export the ECC public key's parameters found in
* the given key. The new parameters will be allocated using
* gnutls_malloc() and will be stored in the appropriate datum.
*
* In EdDSA curves the @y parameter will be %NULL and the other parameters
* will be in the native format for the curve.
*
* This function allows for %NULL parameters since 3.4.1.
*
* Returns: %GNUTLS_E_SUCCESS on success, otherwise a negative error code.
*
* Since: 3.6.0
**/
int
gnutls_pubkey_export_ecc_raw2(gnutls_pubkey_t key,
gnutls_ecc_curve_t * curve,
gnutls_datum_t * x, gnutls_datum_t * y,
unsigned int flags)
{
int ret;
mpi_dprint_func dprint = _gnutls_mpi_dprint_lz;
if (flags & GNUTLS_EXPORT_FLAG_NO_LZ)
dprint = _gnutls_mpi_dprint;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (!IS_EC(key->params.algo)) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (curve)
*curve = key->params.curve;
if (key->params.algo == GNUTLS_PK_EDDSA_ED25519 ||
key->params.algo == GNUTLS_PK_EDDSA_ED448 ||
key->params.algo == GNUTLS_PK_ECDH_X25519 ||
key->params.algo == GNUTLS_PK_ECDH_X448) {
if (x) {
ret = _gnutls_set_datum(x, key->params.raw_pub.data, key->params.raw_pub.size);
if (ret < 0)
return gnutls_assert_val(ret);
}
if (y) {
y->data = NULL;
y->size = 0;
}
return 0;
}
/* ECDSA */
/* X */
if (x) {
ret = dprint(key->params.params[ECC_X], x);
if (ret < 0) {
gnutls_assert();
return ret;
}
}
/* Y */
if (y) {
ret = dprint(key->params.params[ECC_Y], y);
if (ret < 0) {
gnutls_assert();
_gnutls_free_datum(x);
return ret;
}
}
return 0;
}
/**
* gnutls_pubkey_export_ecc_x962:
* @key: Holds the public key
* @parameters: DER encoding of an ANSI X9.62 parameters
* @ecpoint: DER encoding of ANSI X9.62 ECPoint
*
* This function will export the ECC public key's parameters found in
* the given certificate. The new parameters will be allocated using
* gnutls_malloc() and will be stored in the appropriate datum.
*
* Returns: %GNUTLS_E_SUCCESS on success, otherwise a negative error code.
*
* Since: 3.3.0
**/
int gnutls_pubkey_export_ecc_x962(gnutls_pubkey_t key,
gnutls_datum_t * parameters,
gnutls_datum_t * ecpoint)
{
int ret;
gnutls_datum_t raw_point = {NULL,0};
if (key == NULL || key->params.algo != GNUTLS_PK_EC)
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
ret = _gnutls_x509_write_ecc_pubkey(&key->params, &raw_point);
if (ret < 0)
return gnutls_assert_val(ret);
ret = _gnutls_x509_encode_string(ASN1_ETYPE_OCTET_STRING,
raw_point.data, raw_point.size, ecpoint);
if (ret < 0) {
gnutls_assert();
goto cleanup;
}
ret = _gnutls_x509_write_ecc_params(key->params.curve, parameters);
if (ret < 0) {
_gnutls_free_datum(ecpoint);
gnutls_assert();
goto cleanup;
}
ret = 0;
cleanup:
gnutls_free(raw_point.data);
return ret;
}
/**
* gnutls_pubkey_export_gost_raw2:
* @key: Holds the public key
* @curve: will hold the curve (may be %NULL)
* @digest: will hold the curve (may be %NULL)
* @paramset: will hold the parameters id (may be %NULL)
* @x: will hold the x-coordinate (may be %NULL)
* @y: will hold the y-coordinate (may be %NULL)
* @flags: flags from %gnutls_abstract_export_flags_t
*
* This function will export the GOST public key's parameters found in
* the given key. The new parameters will be allocated using
* gnutls_malloc() and will be stored in the appropriate datum.
*
* Note: parameters will be stored with least significant byte first. On
* version 3.6.3 this was incorrectly returned in big-endian format.
*
* Returns: %GNUTLS_E_SUCCESS on success, otherwise a negative error code.
*
* Since: 3.6.3
**/
int
gnutls_pubkey_export_gost_raw2(gnutls_pubkey_t key,
gnutls_ecc_curve_t * curve,
gnutls_digest_algorithm_t * digest,
gnutls_gost_paramset_t * paramset,
gnutls_datum_t * x, gnutls_datum_t * y,
unsigned int flags)
{
int ret;
mpi_dprint_func dprint = _gnutls_mpi_dprint_le;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (key->params.algo != GNUTLS_PK_GOST_01 &&
key->params.algo != GNUTLS_PK_GOST_12_256 &&
key->params.algo != GNUTLS_PK_GOST_12_512) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (curve)
*curve = key->params.curve;
if (digest)
*digest = _gnutls_gost_digest(key->params.algo);
if (paramset)
*paramset = key->params.gost_params;
/* X */
if (x) {
ret = dprint(key->params.params[GOST_X], x);
if (ret < 0) {
gnutls_assert();
return ret;
}
}
/* Y */
if (y) {
ret = dprint(key->params.params[GOST_Y], y);
if (ret < 0) {
gnutls_assert();
_gnutls_free_datum(x);
return ret;
}
}
return 0;
}
/**
* gnutls_pubkey_import:
* @key: The public key.
* @data: The DER or PEM encoded certificate.
* @format: One of DER or PEM
*
* This function will import the provided public key in
* a SubjectPublicKeyInfo X.509 structure to a native
* %gnutls_pubkey_t type. The output will be stored
* in @key. If the public key is PEM encoded it should have a header
* of "PUBLIC KEY".
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int
gnutls_pubkey_import(gnutls_pubkey_t key,
const gnutls_datum_t * data,
gnutls_x509_crt_fmt_t format)
{
int result = 0, need_free = 0;
gnutls_datum_t _data;
asn1_node spk;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
_data.data = data->data;
_data.size = data->size;
/* If the Certificate is in PEM format then decode it
*/
if (format == GNUTLS_X509_FMT_PEM) {
/* Try the first header */
result =
_gnutls_fbase64_decode(PEM_PK, data->data,
data->size, &_data);
if (result < 0) {
gnutls_assert();
return result;
}
need_free = 1;
}
if ((result = asn1_create_element
(_gnutls_get_pkix(), "PKIX1.SubjectPublicKeyInfo", &spk))
!= ASN1_SUCCESS) {
gnutls_assert();
result = _gnutls_asn2err(result);
goto cleanup;
}
result = _asn1_strict_der_decode(&spk, _data.data, _data.size, NULL);
if (result != ASN1_SUCCESS) {
gnutls_assert();
result = _gnutls_asn2err(result);
goto cleanup;
}
result = _gnutls_get_asn_mpis(spk, "", &key->params);
if (result < 0) {
gnutls_assert();
goto cleanup;
}
key->bits = pubkey_to_bits(&key->params);
result = 0;
cleanup:
asn1_delete_structure(&spk);
if (need_free)
_gnutls_free_datum(&_data);
return result;
}
/**
* gnutls_x509_crt_set_pubkey:
* @crt: should contain a #gnutls_x509_crt_t type
* @key: holds a public key
*
* This function will set the public parameters from the given public
* key to the certificate. The @key can be deallocated after that.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int gnutls_x509_crt_set_pubkey(gnutls_x509_crt_t crt, gnutls_pubkey_t key)
{
int result;
if (crt == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
result = _gnutls_x509_encode_and_copy_PKI_params(crt->cert,
"tbsCertificate.subjectPublicKeyInfo",
&key->params);
if (result < 0) {
gnutls_assert();
return result;
}
if (key->key_usage)
gnutls_x509_crt_set_key_usage(crt, key->key_usage);
return 0;
}
/**
* gnutls_x509_crq_set_pubkey:
* @crq: should contain a #gnutls_x509_crq_t type
* @key: holds a public key
*
* This function will set the public parameters from the given public
* key to the request. The @key can be deallocated after that.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int gnutls_x509_crq_set_pubkey(gnutls_x509_crq_t crq, gnutls_pubkey_t key)
{
int result;
if (crq == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
result = _gnutls_x509_encode_and_copy_PKI_params
(crq->crq,
"certificationRequestInfo.subjectPKInfo",
&key->params);
if (result < 0) {
gnutls_assert();
return result;
}
if (key->key_usage)
gnutls_x509_crq_set_key_usage(crq, key->key_usage);
return 0;
}
/**
* gnutls_pubkey_set_key_usage:
* @key: a certificate of type #gnutls_x509_crt_t
* @usage: an ORed sequence of the GNUTLS_KEY_* elements.
*
* This function will set the key usage flags of the public key. This
* is only useful if the key is to be exported to a certificate or
* certificate request.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int gnutls_pubkey_set_key_usage(gnutls_pubkey_t key, unsigned int usage)
{
key->key_usage = usage;
return 0;
}
#ifdef ENABLE_PKCS11
#if 0
/**
* gnutls_pubkey_import_pkcs11_url:
* @key: A key of type #gnutls_pubkey_t
* @url: A PKCS 11 url
* @flags: One of GNUTLS_PKCS11_OBJ_* flags
*
* This function will import a PKCS 11 certificate to a #gnutls_pubkey_t
* structure.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int
gnutls_pubkey_import_pkcs11_url(gnutls_pubkey_t key, const char *url,
unsigned int flags)
{
int x;
}
#endif
static int
_gnutls_pubkey_import_pkcs11_url(gnutls_pubkey_t key, const char *url,
unsigned int flags)
{
gnutls_pkcs11_obj_t pcrt;
int ret;
ret = gnutls_pkcs11_obj_init(&pcrt);
if (ret < 0) {
gnutls_assert();
return ret;
}
if (key->pin.cb)
gnutls_pkcs11_obj_set_pin_function(pcrt, key->pin.cb,
key->pin.data);
ret = gnutls_pkcs11_obj_import_url(pcrt, url, flags|GNUTLS_PKCS11_OBJ_FLAG_EXPECT_PUBKEY);
if (ret < 0) {
gnutls_assert();
goto cleanup;
}
ret = gnutls_pubkey_import_pkcs11(key, pcrt, flags);
if (ret < 0) {
gnutls_assert();
goto cleanup;
}
ret = 0;
cleanup:
gnutls_pkcs11_obj_deinit(pcrt);
return ret;
}
#endif /* ENABLE_PKCS11 */
/**
* gnutls_pubkey_import_url:
* @key: A key of type #gnutls_pubkey_t
* @url: A PKCS 11 url
* @flags: One of GNUTLS_PKCS11_OBJ_* flags
*
* This function will import a public key from the provided URL.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 3.1.0
**/
int
gnutls_pubkey_import_url(gnutls_pubkey_t key, const char *url,
unsigned int flags)
{
unsigned i;
for (i=0;i<_gnutls_custom_urls_size;i++) {
if (strncmp(url, _gnutls_custom_urls[i].name, _gnutls_custom_urls[i].name_size) == 0) {
if (_gnutls_custom_urls[i].import_pubkey)
return _gnutls_custom_urls[i].import_pubkey(key, url, flags);
}
}
if (strncmp(url, PKCS11_URL, PKCS11_URL_SIZE) == 0)
#ifdef ENABLE_PKCS11
return _gnutls_pubkey_import_pkcs11_url(key, url, flags);
#else
return gnutls_assert_val(GNUTLS_E_UNIMPLEMENTED_FEATURE);
#endif
if (strncmp(url, TPMKEY_URL, TPMKEY_URL_SIZE) == 0)
#ifdef HAVE_TROUSERS
return gnutls_pubkey_import_tpm_url(key, url, NULL, 0);
#else
return gnutls_assert_val(GNUTLS_E_UNIMPLEMENTED_FEATURE);
#endif
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
}
/**
* gnutls_pubkey_import_rsa_raw:
* @key: The key
* @m: holds the modulus
* @e: holds the public exponent
*
* This function will replace the parameters in the given structure.
* The new parameters should be stored in the appropriate
* gnutls_datum.
*
* Returns: %GNUTLS_E_SUCCESS on success, or an negative error code.
*
* Since: 2.12.0
**/
int
gnutls_pubkey_import_rsa_raw(gnutls_pubkey_t key,
const gnutls_datum_t * m,
const gnutls_datum_t * e)
{
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
gnutls_pk_params_release(&key->params);
gnutls_pk_params_init(&key->params);
if (_gnutls_mpi_init_scan_nz(&key->params.params[0], m->data, m->size)) {
gnutls_assert();
return GNUTLS_E_MPI_SCAN_FAILED;
}
if (_gnutls_mpi_init_scan_nz(&key->params.params[1], e->data, e->size)) {
gnutls_assert();
_gnutls_mpi_release(&key->params.params[0]);
return GNUTLS_E_MPI_SCAN_FAILED;
}
key->params.params_nr = RSA_PUBLIC_PARAMS;
key->params.algo = GNUTLS_PK_RSA;
key->bits = pubkey_to_bits(&key->params);
return 0;
}
/**
* gnutls_pubkey_import_ecc_raw:
* @key: The structure to store the parsed key
* @curve: holds the curve
* @x: holds the x-coordinate
* @y: holds the y-coordinate
*
* This function will convert the given elliptic curve parameters to a
* #gnutls_pubkey_t. The output will be stored in @key.
*
* In EdDSA curves the @y parameter should be %NULL and the @x parameter must
* be the value in the native format for the curve.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 3.0
**/
int
gnutls_pubkey_import_ecc_raw(gnutls_pubkey_t key,
gnutls_ecc_curve_t curve,
const gnutls_datum_t * x,
const gnutls_datum_t * y)
{
int ret;
if (key == NULL || x == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
gnutls_pk_params_release(&key->params);
gnutls_pk_params_init(&key->params);
if (curve_is_eddsa(curve)) {
unsigned size = gnutls_ecc_curve_get_size(curve);
if (x->size != size) {
ret = gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
goto cleanup;
}
ret = _gnutls_set_datum(&key->params.raw_pub, x->data, x->size);
if (ret < 0) {
gnutls_assert();
goto cleanup;
}
switch (curve) {
case GNUTLS_ECC_CURVE_ED25519:
key->params.algo = GNUTLS_PK_EDDSA_ED25519;
break;
case GNUTLS_ECC_CURVE_ED448:
key->params.algo = GNUTLS_PK_EDDSA_ED448;
break;
default:
break;
}
key->params.curve = curve;
key->bits = pubkey_to_bits(&key->params);
return 0;
}
/* ECDSA */
if (y == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
key->params.curve = curve;
if (_gnutls_mpi_init_scan_nz
(&key->params.params[ECC_X], x->data, x->size)) {
gnutls_assert();
ret = GNUTLS_E_MPI_SCAN_FAILED;
goto cleanup;
}
key->params.params_nr++;
if (_gnutls_mpi_init_scan_nz
(&key->params.params[ECC_Y], y->data, y->size)) {
gnutls_assert();
ret = GNUTLS_E_MPI_SCAN_FAILED;
goto cleanup;
}
key->params.params_nr++;
key->params.algo = GNUTLS_PK_ECDSA;
key->bits = pubkey_to_bits(&key->params);
return 0;
cleanup:
gnutls_pk_params_release(&key->params);
return ret;
}
/**
* gnutls_pubkey_import_ecc_x962:
* @key: The structure to store the parsed key
* @parameters: DER encoding of an ANSI X9.62 parameters
* @ecpoint: DER encoding of ANSI X9.62 ECPoint
*
* This function will convert the given elliptic curve parameters to a
* #gnutls_pubkey_t. The output will be stored in @key.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 3.0
**/
int
gnutls_pubkey_import_ecc_x962(gnutls_pubkey_t key,
const gnutls_datum_t * parameters,
const gnutls_datum_t * ecpoint)
{
int ret;
gnutls_datum_t raw_point = {NULL,0};
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
gnutls_pk_params_release(&key->params);
gnutls_pk_params_init(&key->params);
key->params.params_nr = 0;
ret =
_gnutls_x509_read_ecc_params(parameters->data,
parameters->size, &key->params.curve);
if (ret < 0) {
gnutls_assert();
goto cleanup;
}
ret = _gnutls_x509_decode_string(ASN1_ETYPE_OCTET_STRING,
ecpoint->data, ecpoint->size, &raw_point, 0);
if (ret < 0) {
gnutls_assert();
goto cleanup;
}
ret = _gnutls_ecc_ansi_x962_import(raw_point.data, raw_point.size,
&key->params.params[ECC_X],
&key->params.params[ECC_Y]);
if (ret < 0) {
gnutls_assert();
goto cleanup;
}
key->params.params_nr += 2;
key->params.algo = GNUTLS_PK_EC;
gnutls_free(raw_point.data);
return 0;
cleanup:
gnutls_pk_params_release(&key->params);
gnutls_free(raw_point.data);
return ret;
}
/**
* gnutls_pubkey_import_gost_raw:
* @key: The structure to store the parsed key
* @curve: holds the curve
* @digest: holds the digest
* @paramset: holds the parameters id
* @x: holds the x-coordinate
* @y: holds the y-coordinate
*
* This function will convert the given GOST public key's parameters to a
* #gnutls_pubkey_t. The output will be stored in @key. @digest should be
* one of GNUTLS_DIG_GOSR_94, GNUTLS_DIG_STREEBOG_256 or
* GNUTLS_DIG_STREEBOG_512. If @paramset is set to GNUTLS_GOST_PARAMSET_UNKNOWN
* default one will be selected depending on @digest.
*
* Note: parameters should be stored with least significant byte first. On
* version 3.6.3 big-endian format was used incorrectly.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 3.6.3
**/
int
gnutls_pubkey_import_gost_raw(gnutls_pubkey_t key,
gnutls_ecc_curve_t curve,
gnutls_digest_algorithm_t digest,
gnutls_gost_paramset_t paramset,
const gnutls_datum_t * x,
const gnutls_datum_t * y)
{
int ret;
gnutls_pk_algorithm_t pk_algo;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
pk_algo = _gnutls_digest_gost(digest);
if (pk_algo == GNUTLS_PK_UNKNOWN)
return GNUTLS_E_ILLEGAL_PARAMETER;
if (paramset == GNUTLS_GOST_PARAMSET_UNKNOWN)
paramset = _gnutls_gost_paramset_default(pk_algo);
gnutls_pk_params_release(&key->params);
gnutls_pk_params_init(&key->params);
key->params.curve = curve;
key->params.gost_params = paramset;
if (_gnutls_mpi_init_scan_le
(&key->params.params[GOST_X], x->data, x->size)) {
gnutls_assert();
ret = GNUTLS_E_MPI_SCAN_FAILED;
goto cleanup;
}
key->params.params_nr++;
if (_gnutls_mpi_init_scan_le
(&key->params.params[GOST_Y], y->data, y->size)) {
gnutls_assert();
ret = GNUTLS_E_MPI_SCAN_FAILED;
goto cleanup;
}
key->params.params_nr++;
key->params.algo = pk_algo;
return 0;
cleanup:
gnutls_pk_params_release(&key->params);
return ret;
}
/**
* gnutls_pubkey_import_dsa_raw:
* @key: The structure to store the parsed key
* @p: holds the p
* @q: holds the q
* @g: holds the g
* @y: holds the y
*
* This function will convert the given DSA raw parameters to the
* native #gnutls_pubkey_t format. The output will be stored
* in @key.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 2.12.0
**/
int
gnutls_pubkey_import_dsa_raw(gnutls_pubkey_t key,
const gnutls_datum_t * p,
const gnutls_datum_t * q,
const gnutls_datum_t * g,
const gnutls_datum_t * y)
{
size_t siz = 0;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
gnutls_pk_params_release(&key->params);
gnutls_pk_params_init(&key->params);
siz = p->size;
if (_gnutls_mpi_init_scan_nz(&key->params.params[0], p->data, siz)) {
gnutls_assert();
return GNUTLS_E_MPI_SCAN_FAILED;
}
siz = q->size;
if (_gnutls_mpi_init_scan_nz(&key->params.params[1], q->data, siz)) {
gnutls_assert();
_gnutls_mpi_release(&key->params.params[0]);
return GNUTLS_E_MPI_SCAN_FAILED;
}
siz = g->size;
if (_gnutls_mpi_init_scan_nz(&key->params.params[2], g->data, siz)) {
gnutls_assert();
_gnutls_mpi_release(&key->params.params[1]);
_gnutls_mpi_release(&key->params.params[0]);
return GNUTLS_E_MPI_SCAN_FAILED;
}
siz = y->size;
if (_gnutls_mpi_init_scan_nz(&key->params.params[3], y->data, siz)) {
gnutls_assert();
_gnutls_mpi_release(&key->params.params[2]);
_gnutls_mpi_release(&key->params.params[1]);
_gnutls_mpi_release(&key->params.params[0]);
return GNUTLS_E_MPI_SCAN_FAILED;
}
key->params.params_nr = DSA_PUBLIC_PARAMS;
key->params.algo = GNUTLS_PK_DSA;
key->bits = pubkey_to_bits(&key->params);
return 0;
}
/* Updates the gnutls_x509_spki_st parameters based on the signature
* information, and reports any incompatibilities between the existing
* parameters (if any) with the signature algorithm */
static
int fixup_spki_params(const gnutls_pk_params_st *key_params, const gnutls_sign_entry_st *se,
const mac_entry_st *me, gnutls_x509_spki_st *params)
{
unsigned bits;
if (se->pk != key_params->algo) {
if (!sign_supports_priv_pk_algorithm(se, key_params->algo)) {
_gnutls_debug_log("have key: %s/%d, with sign %s/%d\n",
gnutls_pk_get_name(key_params->algo), key_params->algo,
se->name, se->id);
return gnutls_assert_val(GNUTLS_E_CONSTRAINT_ERROR);
}
}
if (params->pk == GNUTLS_PK_RSA_PSS) {
int ret;
if (!GNUTLS_PK_IS_RSA(key_params->algo))
return gnutls_assert_val(GNUTLS_E_CONSTRAINT_ERROR);
/* The requested sign algorithm is RSA-PSS, while the
* pubkey doesn't include parameter information. Fill
* it with the same way as gnutls_privkey_sign*. */
if (key_params->algo == GNUTLS_PK_RSA || params->rsa_pss_dig == 0) {
bits = pubkey_to_bits(key_params);
params->rsa_pss_dig = se->hash;
ret = _gnutls_find_rsa_pss_salt_size(bits, me, 0);
if (ret < 0)
return gnutls_assert_val(ret);
params->salt_size = ret;
}
if (params->rsa_pss_dig != se->hash)
return gnutls_assert_val(GNUTLS_E_CONSTRAINT_ERROR);
}
return 0;
}
/**
* gnutls_pubkey_verify_data2:
* @pubkey: Holds the public key
* @algo: The signature algorithm used
* @flags: Zero or an OR list of #gnutls_certificate_verify_flags
* @data: holds the signed data
* @signature: contains the signature
*
* This function will verify the given signed data, using the
* parameters from the certificate.
*
* Returns: In case of a verification failure %GNUTLS_E_PK_SIG_VERIFY_FAILED
* is returned, and zero or positive code on success. For known to be insecure
* signatures this function will return %GNUTLS_E_INSUFFICIENT_SECURITY unless
* the flag %GNUTLS_VERIFY_ALLOW_BROKEN is specified.
*
* Since: 3.0
**/
int
gnutls_pubkey_verify_data2(gnutls_pubkey_t pubkey,
gnutls_sign_algorithm_t algo,
unsigned int flags,
const gnutls_datum_t * data,
const gnutls_datum_t * signature)
{
int ret;
const mac_entry_st *me;
gnutls_x509_spki_st params;
const gnutls_sign_entry_st *se;
if (pubkey == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (flags & GNUTLS_VERIFY_USE_TLS1_RSA)
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
memcpy(¶ms, &pubkey->params.spki, sizeof(gnutls_x509_spki_st));
se = _gnutls_sign_to_entry(algo);
if (se == NULL)
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
ret = pubkey_supports_sig(pubkey, se);
if (ret < 0)
return gnutls_assert_val(ret);
params.pk = se->pk;
if (flags & GNUTLS_VERIFY_RSA_PSS_FIXED_SALT_LENGTH) {
params.flags |= GNUTLS_PK_FLAG_RSA_PSS_FIXED_SALT_LENGTH;
}
me = hash_to_entry(se->hash);
if (me == NULL && !_gnutls_pk_is_not_prehashed(se->pk))
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
ret = pubkey_verify_data(se, me, data, signature, &pubkey->params,
¶ms, flags);
if (ret < 0) {
gnutls_assert();
return ret;
}
return 0;
}
/**
* gnutls_pubkey_verify_hash2:
* @key: Holds the public key
* @algo: The signature algorithm used
* @flags: Zero or an OR list of #gnutls_certificate_verify_flags
* @hash: holds the hash digest to be verified
* @signature: contains the signature
*
* This function will verify the given signed digest, using the
* parameters from the public key. Note that unlike gnutls_privkey_sign_hash(),
* this function accepts a signature algorithm instead of a digest algorithm.
* You can use gnutls_pk_to_sign() to get the appropriate value.
*
* Returns: In case of a verification failure %GNUTLS_E_PK_SIG_VERIFY_FAILED
* is returned, and zero or positive code on success. For known to be insecure
* signatures this function will return %GNUTLS_E_INSUFFICIENT_SECURITY unless
* the flag %GNUTLS_VERIFY_ALLOW_BROKEN is specified.
*
* Since: 3.0
**/
int
gnutls_pubkey_verify_hash2(gnutls_pubkey_t key,
gnutls_sign_algorithm_t algo,
unsigned int flags,
const gnutls_datum_t * hash,
const gnutls_datum_t * signature)
{
const mac_entry_st *me;
gnutls_x509_spki_st params;
const gnutls_sign_entry_st *se;
int ret;
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (_gnutls_pk_is_not_prehashed(key->params.algo)) {
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
}
memcpy(¶ms, &key->params.spki, sizeof(gnutls_x509_spki_st));
if (flags & GNUTLS_VERIFY_USE_TLS1_RSA) {
if (!GNUTLS_PK_IS_RSA(key->params.algo))
return gnutls_assert_val(GNUTLS_E_INCOMPATIBLE_SIG_WITH_KEY);
params.pk = GNUTLS_PK_RSA;
/* we do not check for insecure algorithms with this flag */
return _gnutls_pk_verify(params.pk, hash, signature,
&key->params, ¶ms);
} else {
se = _gnutls_sign_to_entry(algo);
if (se == NULL)
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
ret = pubkey_supports_sig(key, se);
if (ret < 0)
return gnutls_assert_val(ret);
params.pk = se->pk;
me = hash_to_entry(se->hash);
if (me == NULL && !_gnutls_pk_is_not_prehashed(se->pk))
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
ret = pubkey_verify_hashed_data(se, me, hash, signature,
&key->params,
¶ms, flags);
if (ret < 0) {
gnutls_assert();
return ret;
}
}
return 0;
}
/**
* gnutls_pubkey_encrypt_data:
* @key: Holds the public key
* @flags: should be 0 for now
* @plaintext: The data to be encrypted
* @ciphertext: contains the encrypted data
*
* This function will encrypt the given data, using the public
* key. On success the @ciphertext will be allocated using gnutls_malloc().
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 3.0
**/
int
gnutls_pubkey_encrypt_data(gnutls_pubkey_t key, unsigned int flags,
const gnutls_datum_t * plaintext,
gnutls_datum_t * ciphertext)
{
if (key == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
return _gnutls_pk_encrypt(key->params.algo, ciphertext,
plaintext, &key->params);
}
static
int pubkey_supports_sig(gnutls_pubkey_t pubkey,
const gnutls_sign_entry_st *se)
{
if (pubkey->params.algo == GNUTLS_PK_ECDSA && se->curve) {
gnutls_ecc_curve_t curve = pubkey->params.curve;
if (curve != se->curve) {
_gnutls_handshake_log("have key: ECDSA with %s/%d, with sign %s/%d\n",
gnutls_ecc_curve_get_name(curve), (int)curve,
se->name, se->id);
return gnutls_assert_val(GNUTLS_E_INCOMPATIBLE_SIG_WITH_KEY);
}
}
if (se->pk != pubkey->params.algo) { /* if the PK algorithm of the signature differs to the one on the pubkey */
if (!sign_supports_priv_pk_algorithm(se, pubkey->params.algo)) {
_gnutls_handshake_log("have key: %s/%d, with sign %s/%d\n",
gnutls_pk_get_name(pubkey->params.algo), pubkey->params.algo,
se->name, se->id);
return gnutls_assert_val(GNUTLS_E_INCOMPATIBLE_SIG_WITH_KEY);
}
}
return 0;
}
/* Checks whether the public key given is compatible with the
* signature algorithm used. The session is only used for audit logging, and
* it may be null.
*/
int _gnutls_pubkey_compatible_with_sig(gnutls_session_t session,
gnutls_pubkey_t pubkey,
const version_entry_st * ver,
gnutls_sign_algorithm_t sign)
{
unsigned int hash_size = 0;
unsigned int sig_hash_size;
const mac_entry_st *me;
const gnutls_sign_entry_st *se;
int ret;
se = _gnutls_sign_to_entry(sign);
if (se != NULL) {
ret = pubkey_supports_sig(pubkey, se);
if (ret < 0)
return gnutls_assert_val(ret);
} else if (_gnutls_version_has_selectable_sighash(ver)) {
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
}
if (pubkey->params.algo == GNUTLS_PK_DSA) {
me = _gnutls_dsa_q_to_hash(&pubkey->params, &hash_size);
/* DSA keys over 1024 bits cannot be used with TLS 1.x, x<2 */
if (!_gnutls_version_has_selectable_sighash(ver)) {
if (me->id != GNUTLS_MAC_SHA1)
return
gnutls_assert_val
(GNUTLS_E_INCOMPAT_DSA_KEY_WITH_TLS_PROTOCOL);
} else if (se != NULL) {
me = hash_to_entry(se->hash);
sig_hash_size = _gnutls_hash_get_algo_len(me);
if (sig_hash_size < hash_size)
_gnutls_audit_log(session,
"The hash size used in signature (%u) is less than the expected (%u)\n",
sig_hash_size,
hash_size);
}
} else if (pubkey->params.algo == GNUTLS_PK_ECDSA) {
if (_gnutls_version_has_selectable_sighash(ver)
&& se != NULL) {
_gnutls_dsa_q_to_hash(&pubkey->params, &hash_size);
me = hash_to_entry(se->hash);
sig_hash_size = _gnutls_hash_get_algo_len(me);
if (sig_hash_size < hash_size)
_gnutls_audit_log(session,
"The hash size used in signature (%u) is less than the expected (%u)\n",
sig_hash_size,
hash_size);
}
} else if (pubkey->params.algo == GNUTLS_PK_GOST_01 ||
pubkey->params.algo == GNUTLS_PK_GOST_12_256 ||
pubkey->params.algo == GNUTLS_PK_GOST_12_512) {
if (_gnutls_version_has_selectable_sighash(ver)
&& se != NULL) {
if (_gnutls_gost_digest(pubkey->params.algo) != se->hash) {
_gnutls_audit_log(session,
"The hash algo used in signature (%u) is not expected (%u)\n",
se->hash, _gnutls_gost_digest(pubkey->params.algo));
return gnutls_assert_val(GNUTLS_E_CONSTRAINT_ERROR);
}
}
} else if (pubkey->params.algo == GNUTLS_PK_RSA_PSS) {
if (!_gnutls_version_has_selectable_sighash(ver))
/* this should not have happened */
return gnutls_assert_val(GNUTLS_E_INTERNAL_ERROR);
/* RSA PSS public keys are restricted to a single digest, i.e., signature */
if (pubkey->params.spki.rsa_pss_dig && pubkey->params.spki.rsa_pss_dig != se->hash) {
return gnutls_assert_val(GNUTLS_E_CONSTRAINT_ERROR);
}
}
return 0;
}
/* Returns the public key.
*/
int
_gnutls_pubkey_get_mpis(gnutls_pubkey_t key, gnutls_pk_params_st * params)
{
return _gnutls_pk_params_copy(params, &key->params);
}
/* if hash==MD5 then we do RSA-MD5
* if hash==SHA then we do RSA-SHA
* params[0] is modulus
* params[1] is public key
*/
static int
_pkcs1_rsa_verify_sig(gnutls_pk_algorithm_t pk,
const mac_entry_st * me,
const gnutls_datum_t * text,
const gnutls_datum_t * prehash,
const gnutls_datum_t * signature,
gnutls_pk_params_st * params,
gnutls_x509_spki_st * sign_params)
{
int ret;
uint8_t md[MAX_HASH_SIZE], *cmp;
unsigned int digest_size;
gnutls_datum_t d, di;
if (unlikely(me == NULL))
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
digest_size = _gnutls_hash_get_algo_len(me);
if (prehash) {
if (prehash->data == NULL || prehash->size != digest_size)
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
cmp = prehash->data;
} else {
if (!text) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
ret = _gnutls_hash_fast((gnutls_digest_algorithm_t)me->id,
text->data, text->size, md);
if (ret < 0) {
gnutls_assert();
return ret;
}
cmp = md;
}
d.data = cmp;
d.size = digest_size;
if (pk == GNUTLS_PK_RSA) {
/* SHA-1 is allowed for SigVer in FIPS 140-3 in legacy
* mode */
switch (me->id) {
case GNUTLS_MAC_SHA1:
case GNUTLS_MAC_SHA256:
case GNUTLS_MAC_SHA384:
case GNUTLS_MAC_SHA512:
case GNUTLS_MAC_SHA224:
break;
default:
_gnutls_switch_fips_state(GNUTLS_FIPS140_OP_NOT_APPROVED);
}
/* decrypted is a BER encoded data of type DigestInfo
*/
ret = encode_ber_digest_info(me, &d, &di);
if (ret < 0)
return gnutls_assert_val(ret);
ret = _gnutls_pk_verify(pk, &di, signature, params,
sign_params);
_gnutls_free_datum(&di);
} else {
ret = _gnutls_pk_verify(pk, &d, signature, params,
sign_params);
}
return ret;
}
/* Hashes input data and verifies a signature.
*/
static int
dsa_verify_hashed_data(gnutls_pk_algorithm_t pk,
const mac_entry_st * algo,
const gnutls_datum_t * hash,
const gnutls_datum_t * signature,
gnutls_pk_params_st * params,
gnutls_x509_spki_st * sign_params)
{
gnutls_datum_t digest;
unsigned int hash_len;
if (algo == NULL)
algo = _gnutls_dsa_q_to_hash(params, &hash_len);
else
hash_len = _gnutls_hash_get_algo_len(algo);
/* SHA1 or better allowed */
if (!hash->data || hash->size < hash_len) {
gnutls_assert();
_gnutls_debug_log
("Hash size (%d) does not correspond to hash %s(%d) or better.\n",
(int) hash->size, _gnutls_mac_get_name(algo),
hash_len);
if (hash->size != 20) /* SHA1 is allowed */
return
gnutls_assert_val
(GNUTLS_E_PK_SIG_VERIFY_FAILED);
}
digest.data = hash->data;
digest.size = hash->size;
return _gnutls_pk_verify(pk, &digest, signature, params, sign_params);
}
static int
dsa_verify_data(gnutls_pk_algorithm_t pk,
const mac_entry_st * algo,
const gnutls_datum_t * data,
const gnutls_datum_t * signature,
gnutls_pk_params_st * params,
gnutls_x509_spki_st * sign_params)
{
int ret;
uint8_t _digest[MAX_HASH_SIZE];
gnutls_datum_t digest;
if (algo == NULL)
algo = _gnutls_dsa_q_to_hash(params, NULL);
ret = _gnutls_hash_fast((gnutls_digest_algorithm_t)algo->id,
data->data, data->size, _digest);
if (ret < 0)
return gnutls_assert_val(ret);
digest.data = _digest;
digest.size = _gnutls_hash_get_algo_len(algo);
return _gnutls_pk_verify(pk, &digest, signature, params, sign_params);
}
/* Verifies the signature data, and returns GNUTLS_E_PK_SIG_VERIFY_FAILED if
* not verified, or 1 otherwise.
*/
static int
pubkey_verify_hashed_data(const gnutls_sign_entry_st *se,
const mac_entry_st *me,
const gnutls_datum_t * hash,
const gnutls_datum_t * signature,
gnutls_pk_params_st * params,
gnutls_x509_spki_st * sign_params,
unsigned flags)
{
int ret;
if (unlikely(me==NULL))
return gnutls_assert_val(GNUTLS_E_UNKNOWN_HASH_ALGORITHM);
ret = fixup_spki_params(params, se, me, sign_params);
if (ret < 0)
return gnutls_assert_val(ret);
switch (se->pk) {
case GNUTLS_PK_RSA:
case GNUTLS_PK_RSA_PSS:
if (_pkcs1_rsa_verify_sig
(se->pk, me, NULL, hash, signature, params, sign_params) != 0)
{
gnutls_assert();
return GNUTLS_E_PK_SIG_VERIFY_FAILED;
}
break;
case GNUTLS_PK_ECDSA:
case GNUTLS_PK_GOST_01:
case GNUTLS_PK_GOST_12_256:
case GNUTLS_PK_GOST_12_512:
case GNUTLS_PK_DSA:
if (dsa_verify_hashed_data
(se->pk, me, hash, signature, params, sign_params) != 0) {
gnutls_assert();
return GNUTLS_E_PK_SIG_VERIFY_FAILED;
}
break;
default:
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (_gnutls_sign_is_secure2(se, 0) == 0 && _gnutls_is_broken_sig_allowed(se, flags) == 0) {
return gnutls_assert_val(GNUTLS_E_INSUFFICIENT_SECURITY);
}
return 1;
}
/* Verifies the signature data, and returns GNUTLS_E_PK_SIG_VERIFY_FAILED if
* not verified, or 1 otherwise.
*/
int
pubkey_verify_data(const gnutls_sign_entry_st *se,
const mac_entry_st *me,
const gnutls_datum_t * data,
const gnutls_datum_t * signature,
gnutls_pk_params_st * params,
gnutls_x509_spki_st * sign_params,
unsigned flags)
{
int ret;
if (unlikely(me == NULL))
return gnutls_assert_val(GNUTLS_E_UNKNOWN_HASH_ALGORITHM);
ret = fixup_spki_params(params, se, me, sign_params);
if (ret < 0)
return gnutls_assert_val(ret);
switch (se->pk) {
case GNUTLS_PK_RSA:
case GNUTLS_PK_RSA_PSS:
if (_pkcs1_rsa_verify_sig
(se->pk, me, data, NULL, signature, params, sign_params) != 0) {
gnutls_assert();
return GNUTLS_E_PK_SIG_VERIFY_FAILED;
}
break;
case GNUTLS_PK_EDDSA_ED25519:
case GNUTLS_PK_EDDSA_ED448:
if (_gnutls_pk_verify(se->pk, data, signature, params, sign_params) != 0) {
gnutls_assert();
return GNUTLS_E_PK_SIG_VERIFY_FAILED;
}
break;
case GNUTLS_PK_EC:
case GNUTLS_PK_DSA:
case GNUTLS_PK_GOST_01:
case GNUTLS_PK_GOST_12_256:
case GNUTLS_PK_GOST_12_512:
if (dsa_verify_data
(se->pk, me, data, signature, params, sign_params) != 0) {
gnutls_assert();
return GNUTLS_E_PK_SIG_VERIFY_FAILED;
}
break;
default:
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (_gnutls_sign_is_secure2(se,0) == 0 && _gnutls_is_broken_sig_allowed(se, flags) == 0) {
return gnutls_assert_val(GNUTLS_E_INSUFFICIENT_SECURITY);
}
return 1;
}
const mac_entry_st *_gnutls_dsa_q_to_hash(const gnutls_pk_params_st *
params, unsigned int *hash_len)
{
int bits = 0;
int ret;
if (params->algo == GNUTLS_PK_DSA)
bits = _gnutls_mpi_get_nbits(params->params[1]);
else if (params->algo == GNUTLS_PK_EC)
bits = gnutls_ecc_curve_get_size(params->curve) * 8;
if (bits <= 160) {
if (hash_len)
*hash_len = 20;
ret = GNUTLS_DIG_SHA1;
} else if (bits <= 192) {
if (hash_len)
*hash_len = 24;
ret = GNUTLS_DIG_SHA256;
} else if (bits <= 224) {
if (hash_len)
*hash_len = 28;
ret = GNUTLS_DIG_SHA256;
} else if (bits <= 256) {
if (hash_len)
*hash_len = 32;
ret = GNUTLS_DIG_SHA256;
} else if (bits <= 384) {
if (hash_len)
*hash_len = 48;
ret = GNUTLS_DIG_SHA384;
} else {
if (hash_len)
*hash_len = 64;
ret = GNUTLS_DIG_SHA512;
}
return mac_to_entry(ret);
}
/**
* gnutls_pubkey_set_pin_function:
* @key: A key of type #gnutls_pubkey_t
* @fn: the callback
* @userdata: data associated with the callback
*
* This function will set a callback function to be used when
* required to access the object. This function overrides any other
* global PIN functions.
*
* Note that this function must be called right after initialization
* to have effect.
*
* Since: 3.1.0
*
**/
void gnutls_pubkey_set_pin_function(gnutls_pubkey_t key,
gnutls_pin_callback_t fn,
void *userdata)
{
key->pin.cb = fn;
key->pin.data = userdata;
}
/**
* gnutls_pubkey_import_x509_raw:
* @pkey: The public key
* @data: The public key data to be imported
* @format: The format of the public key
* @flags: should be zero
*
* This function will import the given public key to the abstract
* #gnutls_pubkey_t type.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 3.1.3
**/
int gnutls_pubkey_import_x509_raw(gnutls_pubkey_t pkey,
const gnutls_datum_t * data,
gnutls_x509_crt_fmt_t format,
unsigned int flags)
{
gnutls_x509_crt_t xpriv;
int ret;
ret = gnutls_x509_crt_init(&xpriv);
if (ret < 0)
return gnutls_assert_val(ret);
ret = gnutls_x509_crt_import(xpriv, data, format);
if (ret < 0) {
gnutls_assert();
goto cleanup;
}
ret = gnutls_pubkey_import_x509(pkey, xpriv, flags);
if (ret < 0) {
gnutls_assert();
goto cleanup;
}
ret = 0;
cleanup:
gnutls_x509_crt_deinit(xpriv);
return ret;
}
/**
* gnutls_pubkey_verify_params:
* @key: should contain a #gnutls_pubkey_t type
*
* This function will verify the public key parameters.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 3.3.0
**/
int gnutls_pubkey_verify_params(gnutls_pubkey_t key)
{
int ret;
ret = _gnutls_pk_verify_pub_params(key->params.algo, &key->params);
if (ret < 0) {
gnutls_assert();
return ret;
}
return 0;
}
/**
* gnutls_pubkey_get_spki:
* @pubkey: a public key of type #gnutls_pubkey_t
* @spki: a SubjectPublicKeyInfo structure of type #gnutls_pubkey_spki_t
* @flags: must be zero
*
* This function will return the public key information if available.
* The provided @spki must be initialized.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 3.6.0
**/
int
gnutls_pubkey_get_spki(gnutls_pubkey_t pubkey, gnutls_x509_spki_t spki, unsigned int flags)
{
gnutls_x509_spki_t p = &pubkey->params.spki;
if (pubkey == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (p->pk == GNUTLS_PK_UNKNOWN)
return gnutls_assert_val(GNUTLS_E_REQUESTED_DATA_NOT_AVAILABLE);
memcpy(spki, p, sizeof(gnutls_x509_spki_st));
return 0;
}
/**
* gnutls_pubkey_set_spki:
* @pubkey: a public key of type #gnutls_pubkey_t
* @spki: a SubjectPublicKeyInfo structure of type #gnutls_pubkey_spki_t
* @flags: must be zero
*
* This function will set the public key information.
* The provided @spki must be initialized.
*
* Returns: On success, %GNUTLS_E_SUCCESS (0) is returned, otherwise a
* negative error value.
*
* Since: 3.6.0
**/
int
gnutls_pubkey_set_spki(gnutls_pubkey_t pubkey, const gnutls_x509_spki_t spki, unsigned int flags)
{
if (pubkey == NULL) {
gnutls_assert();
return GNUTLS_E_INVALID_REQUEST;
}
if (!_gnutls_pk_are_compat(pubkey->params.algo, spki->pk))
return gnutls_assert_val(GNUTLS_E_INVALID_REQUEST);
memcpy(&pubkey->params.spki, spki, sizeof(gnutls_x509_spki_st));
pubkey->params.algo = spki->pk;
return 0;
}