+/*
+ Bacula® - The Network Backup Solution
+
+ Copyright (C) 2005-2011 Free Software Foundation Europe e.V.
+
+ The main author of Bacula is Kern Sibbald, with contributions from
+ many others, a complete list can be found in the file AUTHORS.
+ This program is Free Software; you can redistribute it and/or
+ modify it under the terms of version three of the GNU Affero General Public
+ License as published by the Free Software Foundation and included
+ in the file LICENSE.
+
+ This program is distributed in the hope that it will be useful, but
+ WITHOUT ANY WARRANTY; without even the implied warranty of
+ MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ General Public License for more details.
+
+ You should have received a copy of the GNU Affero General Public License
+ along with this program; if not, write to the Free Software
+ Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
+ 02110-1301, USA.
+
+ Bacula® is a registered trademark of Kern Sibbald.
+ The licensor of Bacula is the Free Software Foundation Europe
+ (FSFE), Fiduciary Program, Sumatrastrasse 25, 8006 Zürich,
+ Switzerland, email:ftf@fsfeurope.org.
+*/
/*
* crypto.c Encryption support functions
*
* Author: Landon Fuller <landonf@opendarwin.org>
*
- * Version $Id$
- *
- * Copyright (C) 2005 Kern Sibbald
- *
* This file was contributed to the Bacula project by Landon Fuller.
*
* Landon Fuller has been granted a perpetual, worldwide, non-exclusive,
* If you wish to license these contributions under an alternate open source
* license please contact Landon Fuller <landonf@opendarwin.org>.
*/
-/*
- Copyright (C) 2005 Kern Sibbald
-
- This program is free software; you can redistribute it and/or
- modify it under the terms of the GNU General Public License
- version 2 as amended with additional clauses defined in the
- file LICENSE in the main source directory.
-
- This program is distributed in the hope that it will be useful,
- but WITHOUT ANY WARRANTY; without even the implied warranty of
- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- the file LICENSE for additional details.
-
- */
#include "bacula.h"
+#include "jcr.h"
#include <assert.h>
+/**
+ * For OpenSSL version 1.x, EVP_PKEY_encrypt no longer
+ * exists. It was not an official API.
+ */
+#ifdef HAVE_OPENSSLv1
+#define EVP_PKEY_encrypt EVP_PKEY_encrypt_old
+#define EVP_PKEY_decrypt EVP_PKEY_decrypt_old
+#endif
+
/*
* Bacula ASN.1 Syntax
*
ASN1_SEQUENCE(CryptoData) = {
ASN1_SIMPLE(CryptoData, version, ASN1_INTEGER),
+ ASN1_SIMPLE(CryptoData, contentEncryptionAlgorithm, ASN1_OBJECT),
ASN1_SIMPLE(CryptoData, iv, ASN1_OCTET_STRING),
ASN1_SET_OF(CryptoData, recipientInfo, RecipientInfo)
} ASN1_SEQUENCE_END(CryptoData);
/* Message Digest Structure */
struct Digest {
crypto_digest_t type;
+ JCR *jcr;
EVP_MD_CTX ctx;
};
/* Message Signature Structure */
struct Signature {
SignatureData *sigData;
+ JCR *jcr;
};
/* Encryption Session Data */
size_t session_key_len; /* Symmetric session key length */
};
+/* Symmetric Cipher Context */
+struct Cipher_Context {
+ EVP_CIPHER_CTX ctx;
+};
+
/* PEM Password Dispatch Context */
typedef struct PEM_CB_Context {
CRYPTO_PEM_PASSWD_CB *pem_callback;
* Returns: On success, an ASN1_OCTET_STRING that must be freed via M_ASN1_OCTET_STRING_free().
* NULL on failure.
*/
-static ASN1_OCTET_STRING *openssl_cert_keyid(X509 *cert){
+static ASN1_OCTET_STRING *openssl_cert_keyid(X509 *cert) {
X509_EXTENSION *ext;
- X509V3_EXT_METHOD *method;
+ const X509V3_EXT_METHOD *method;
ASN1_OCTET_STRING *keyid;
int i;
#if (OPENSSL_VERSION_NUMBER >= 0x0090800FL)
* Returns: A pointer to a X509 KEYPAIR object on success.
* NULL on failure.
*/
-X509_KEYPAIR *crypto_keypair_new (void) {
+X509_KEYPAIR *crypto_keypair_new(void)
+{
X509_KEYPAIR *keypair;
/* Allocate our keypair structure */
- keypair = (X509_KEYPAIR *) malloc(sizeof(X509_KEYPAIR));
- if (!keypair) {
- return NULL;
- }
+ keypair = (X509_KEYPAIR *)malloc(sizeof(X509_KEYPAIR));
/* Initialize our keypair structure */
keypair->keyid = NULL;
* API is available. Instead, the reference count is
* incremented.
*/
-X509_KEYPAIR *crypto_keypair_dup (X509_KEYPAIR *keypair)
+X509_KEYPAIR *crypto_keypair_dup(X509_KEYPAIR *keypair)
{
X509_KEYPAIR *newpair;
* Returns: true on success
* false on failure
*/
-int crypto_keypair_load_cert (X509_KEYPAIR *keypair, const char *file)
+int crypto_keypair_load_cert(X509_KEYPAIR *keypair, const char *file)
{
BIO *bio;
X509 *cert;
/* Extract the subjectKeyIdentifier extension field */
if ((keypair->keyid = openssl_cert_keyid(cert)) == NULL) {
- Emsg0(M_ERROR, 0, _("Provided certificate does not include the required subjectKeyIdentifier extension."));
+ Jmsg0(NULL, M_ERROR, 0,
+ _("Provided certificate does not include the required subjectKeyIdentifier extension."));
goto err;
}
/* Validate the public key type (only RSA is supported) */
if (EVP_PKEY_type(keypair->pubkey->type) != EVP_PKEY_RSA) {
- Emsg1(M_ERROR, 0, _("Unsupported key type provided: %d\n"), EVP_PKEY_type(keypair->pubkey->type));
+ Jmsg1(NULL, M_ERROR, 0,
+ _("Unsupported key type provided: %d\n"), EVP_PKEY_type(keypair->pubkey->type));
goto err;
}
+ X509_free(cert);
return true;
err:
* Returns: true if a private key is found
* false otherwise
*/
-bool crypto_keypair_has_key (const char *file) {
+bool crypto_keypair_has_key(const char *file) {
BIO *bio;
char *name = NULL;
char *header = NULL;
* Returns: true on success
* false on failure
*/
-int crypto_keypair_load_key (X509_KEYPAIR *keypair, const char *file,
+int crypto_keypair_load_key(X509_KEYPAIR *keypair, const char *file,
CRYPTO_PEM_PASSWD_CB *pem_callback,
const void *pem_userdata)
{
/*
* Free memory associated with a keypair object.
*/
-void crypto_keypair_free (X509_KEYPAIR *keypair)
+void crypto_keypair_free(X509_KEYPAIR *keypair)
{
if (keypair->pubkey) {
EVP_PKEY_free(keypair->pubkey);
* Returns: A pointer to a DIGEST object on success.
* NULL on failure.
*/
-DIGEST *crypto_digest_new (crypto_digest_t type)
+DIGEST *crypto_digest_new(JCR *jcr, crypto_digest_t type)
{
DIGEST *digest;
const EVP_MD *md = NULL; /* Quell invalid uninitialized warnings */
- digest = (DIGEST *) malloc(sizeof(DIGEST));
+ digest = (DIGEST *)malloc(sizeof(DIGEST));
digest->type = type;
+ digest->jcr = jcr;
+ Dmsg1(150, "crypto_digest_new jcr=%p\n", jcr);
/* Initialize the OpenSSL message digest context */
EVP_MD_CTX_init(&digest->ctx);
break;
#endif
default:
- Emsg1(M_ERROR, 0, _("Unsupported digest type: %d\n"), type);
+ Jmsg1(jcr, M_ERROR, 0, _("Unsupported digest type: %d\n"), type);
goto err;
}
err:
/* This should not happen, but never say never ... */
- openssl_post_errors(M_ERROR, _("OpenSSL digest initialization failed"));
+ Dmsg0(150, "Digest init failed.\n");
+ openssl_post_errors(jcr, M_ERROR, _("OpenSSL digest initialization failed"));
crypto_digest_free(digest);
return NULL;
}
* Returns: true on success
* false on failure
*/
-bool crypto_digest_update (DIGEST *digest, const void *data, size_t length) {
+bool crypto_digest_update(DIGEST *digest, const uint8_t *data, uint32_t length)
+{
if (EVP_DigestUpdate(&digest->ctx, data, length) == 0) {
- return true;
- } else {
+ Dmsg0(150, "digest update failed\n");
+ openssl_post_errors(digest->jcr, M_ERROR, _("OpenSSL digest update failed"));
return false;
+ } else {
+ return true;
}
}
* Returns: true on success
* false on failure
*/
-bool crypto_digest_finalize (DIGEST *digest, void *dest, size_t *length) {
- if (!EVP_DigestFinal(&digest->ctx, (unsigned char *) dest, (unsigned int *) length)) {
+bool crypto_digest_finalize(DIGEST *digest, uint8_t *dest, uint32_t *length)
+{
+ if (!EVP_DigestFinal(&digest->ctx, dest, (unsigned int *)length)) {
+ Dmsg0(150, "digest finalize failed\n");
+ openssl_post_errors(digest->jcr, M_ERROR, _("OpenSSL digest finalize failed"));
return false;
} else {
return true;
/*
* Free memory associated with a digest object.
*/
-void crypto_digest_free (DIGEST *digest)
+void crypto_digest_free(DIGEST *digest)
{
EVP_MD_CTX_cleanup(&digest->ctx);
- free (digest);
+ free(digest);
}
/*
* Returns: A pointer to a SIGNATURE object on success.
* NULL on failure.
*/
-SIGNATURE *crypto_sign_new (void)
+SIGNATURE *crypto_sign_new(JCR *jcr)
{
SIGNATURE *sig;
- sig = (SIGNATURE *) malloc(sizeof(SIGNATURE));
+ sig = (SIGNATURE *)malloc(sizeof(SIGNATURE));
if (!sig) {
return NULL;
}
sig->sigData = SignatureData_new();
+ sig->jcr = jcr;
+ Dmsg1(150, "crypto_sign_new jcr=%p\n", jcr);
if (!sig->sigData) {
/* Allocation failed in OpenSSL */
/*
* For a given public key, find the associated SignatureInfo record
- * and create a digest context for signature validation
+ * and create a digest context for signature validation
+ *
* Returns: CRYPTO_ERROR_NONE on success, with the newly allocated DIGEST in digest.
* A crypto_error_t value on failure.
*/
-crypto_error_t crypto_sign_get_digest(SIGNATURE *sig, X509_KEYPAIR *keypair, DIGEST **digest)
+crypto_error_t crypto_sign_get_digest(SIGNATURE *sig, X509_KEYPAIR *keypair,
+ crypto_digest_t &type, DIGEST **digest)
{
STACK_OF(SignerInfo) *signers;
SignerInfo *si;
si = sk_SignerInfo_value(signers, i);
if (M_ASN1_OCTET_STRING_cmp(keypair->keyid, si->subjectKeyIdentifier) == 0) {
/* Get the digest algorithm and allocate a digest context */
+ Dmsg1(150, "crypto_sign_get_digest jcr=%p\n", sig->jcr);
switch (OBJ_obj2nid(si->digestAlgorithm)) {
case NID_md5:
- *digest = crypto_digest_new(CRYPTO_DIGEST_MD5);
+ Dmsg0(100, "sign digest algorithm is MD5\n");
+ type = CRYPTO_DIGEST_MD5;
+ *digest = crypto_digest_new(sig->jcr, CRYPTO_DIGEST_MD5);
break;
case NID_sha1:
- *digest = crypto_digest_new(CRYPTO_DIGEST_SHA1);
+ Dmsg0(100, "sign digest algorithm is SHA1\n");
+ type = CRYPTO_DIGEST_SHA1;
+ *digest = crypto_digest_new(sig->jcr, CRYPTO_DIGEST_SHA1);
break;
#ifdef HAVE_SHA2
case NID_sha256:
- *digest = crypto_digest_new(CRYPTO_DIGEST_SHA256);
+ Dmsg0(100, "sign digest algorithm is SHA256\n");
+ type = CRYPTO_DIGEST_SHA256;
+ *digest = crypto_digest_new(sig->jcr, CRYPTO_DIGEST_SHA256);
break;
case NID_sha512:
- *digest = crypto_digest_new(CRYPTO_DIGEST_SHA512);
+ Dmsg0(100, "sign digest algorithm is SHA512\n");
+ type = CRYPTO_DIGEST_SHA512;
+ *digest = crypto_digest_new(sig->jcr, CRYPTO_DIGEST_SHA512);
break;
#endif
default:
+ type = CRYPTO_DIGEST_NONE;
*digest = NULL;
return CRYPTO_ERROR_INVALID_DIGEST;
}
/* Shouldn't happen */
if (*digest == NULL) {
+ openssl_post_errors(sig->jcr, M_ERROR, _("OpenSSL digest_new failed"));
return CRYPTO_ERROR_INVALID_DIGEST;
} else {
return CRYPTO_ERROR_NONE;
}
+ } else {
+ openssl_post_errors(sig->jcr, M_ERROR, _("OpenSSL sign get digest failed"));
}
+
}
return CRYPTO_ERROR_NOSIGNER;
if (ok >= 1) {
return CRYPTO_ERROR_NONE;
} else if (ok == 0) {
+ openssl_post_errors(sig->jcr, M_ERROR, _("OpenSSL digest Verify final failed"));
return CRYPTO_ERROR_BAD_SIGNATURE;
} else if (ok < 0) {
/* Shouldn't happen */
- openssl_post_errors(M_ERROR, _("OpenSSL error occured"));
+ openssl_post_errors(sig->jcr, M_ERROR, _("OpenSSL digest Verify final failed"));
return CRYPTO_ERROR_INTERNAL;
}
}
}
-
+ Jmsg(sig->jcr, M_ERROR, 0, _("No signers found for crypto verify.\n"));
/* Signer wasn't found. */
return CRYPTO_ERROR_NOSIGNER;
}
* Returns: true on success, stores the encoded data in dest, and the size in length.
* false on failure.
*/
-int crypto_sign_encode(SIGNATURE *sig, void *dest, size_t *length)
+int crypto_sign_encode(SIGNATURE *sig, uint8_t *dest, uint32_t *length)
{
if (*length == 0) {
*length = i2d_SignatureData(sig->sigData, NULL);
return true;
}
- *length = i2d_SignatureData(sig->sigData, (unsigned char **) &dest);
+ *length = i2d_SignatureData(sig->sigData, (unsigned char **)&dest);
return true;
}
*/
-SIGNATURE *crypto_sign_decode(const void *sigData, size_t length)
+SIGNATURE *crypto_sign_decode(JCR *jcr, const uint8_t *sigData, uint32_t length)
{
SIGNATURE *sig;
#if (OPENSSL_VERSION_NUMBER >= 0x0090800FL)
const unsigned char *p = (const unsigned char *) sigData;
#else
- unsigned char *p = (unsigned char *) sigData;
+ unsigned char *p = (unsigned char *)sigData;
#endif
- sig = (SIGNATURE *) malloc(sizeof(SIGNATURE));
+ sig = (SIGNATURE *)malloc(sizeof(SIGNATURE));
if (!sig) {
return NULL;
}
+ sig->jcr = jcr;
/* d2i_SignatureData modifies the supplied pointer */
sig->sigData = d2i_SignatureData(NULL, &p, length);
if (!sig->sigData) {
/* Allocation / Decoding failed in OpenSSL */
- openssl_post_errors(M_ERROR, _("Signature decoding failed"));
+ openssl_post_errors(jcr, M_ERROR, _("Signature decoding failed"));
+ free(sig);
return NULL;
}
* Create a new encryption session.
* Returns: A pointer to a CRYPTO_SESSION object on success.
* NULL on failure.
+ *
+ * Note! Bacula malloc() fails if out of memory.
*/
CRYPTO_SESSION *crypto_session_new (crypto_cipher_t cipher, alist *pubkeys)
{
int iv_len;
/* Allocate our session description structures */
- cs = (CRYPTO_SESSION *) malloc(sizeof(CRYPTO_SESSION));
- if (!cs) {
- return NULL;
- }
+ cs = (CRYPTO_SESSION *)malloc(sizeof(CRYPTO_SESSION));
/* Initialize required fields */
cs->session_key = NULL;
cs->cryptoData->contentEncryptionAlgorithm = OBJ_nid2obj(NID_aes_128_cbc);
ec = EVP_aes_128_cbc();
break;
+#ifndef HAVE_OPENSSL_EXPORT_LIBRARY
case CRYPTO_CIPHER_AES_192_CBC:
/* AES 192 bit CBC */
cs->cryptoData->contentEncryptionAlgorithm = OBJ_nid2obj(NID_aes_192_cbc);
cs->cryptoData->contentEncryptionAlgorithm = OBJ_nid2obj(NID_aes_256_cbc);
ec = EVP_aes_256_cbc();
break;
+#endif
case CRYPTO_CIPHER_BLOWFISH_CBC:
/* Blowfish CBC */
cs->cryptoData->contentEncryptionAlgorithm = OBJ_nid2obj(NID_bf_cbc);
ec = EVP_bf_cbc();
break;
default:
- Emsg0(M_ERROR, 0, _("Unsupported cipher type specified\n"));
+ Jmsg0(NULL, M_ERROR, 0, _("Unsupported cipher type specified\n"));
crypto_session_free(cs);
return NULL;
}
/* Generate an IV if possible */
if ((iv_len = EVP_CIPHER_iv_length(ec))) {
- iv = (unsigned char *) malloc(iv_len);
- if (!iv) {
- /* Malloc failure */
- crypto_session_free(cs);
- return NULL;
- }
+ iv = (unsigned char *)malloc(iv_len);
/* Generate random IV */
if (RAND_bytes(iv, iv_len) <= 0) {
ri->keyEncryptionAlgorithm = OBJ_nid2obj(NID_rsaEncryption);
/* Encrypt the session key */
- ekey = (unsigned char *) malloc(EVP_PKEY_size(keypair->pubkey));
- if (!ekey) {
- RecipientInfo_free(ri);
- crypto_session_free(cs);
- return NULL;
- }
+ ekey = (unsigned char *)malloc(EVP_PKEY_size(keypair->pubkey));
if ((ekey_len = EVP_PKEY_encrypt(ekey, cs->session_key, cs->session_key_len, keypair->pubkey)) <= 0) {
/* OpenSSL failure */
* Returns: true on success, stores the encoded data in dest, and the size in length.
* false on failure.
*/
-bool crypto_session_encode(CRYPTO_SESSION *cs, void *dest, size_t *length)
+bool crypto_session_encode(CRYPTO_SESSION *cs, uint8_t *dest, uint32_t *length)
{
if (*length == 0) {
*length = i2d_CryptoData(cs->cryptoData, NULL);
return true;
}
- *length = i2d_CryptoData(cs->cryptoData, (unsigned char **) &dest);
+ *length = i2d_CryptoData(cs->cryptoData, &dest);
return true;
}
* Returns: CRYPTO_ERROR_NONE and a pointer to a newly allocated CRYPTO_SESSION structure in *session on success.
* A crypto_error_t value on failure.
*/
-crypto_error_t crypto_session_decode(const void *data, size_t length, alist *keypairs, CRYPTO_SESSION **session)
+crypto_error_t crypto_session_decode(const uint8_t *data, uint32_t length, alist *keypairs, CRYPTO_SESSION **session)
{
CRYPTO_SESSION *cs;
X509_KEYPAIR *keypair;
STACK_OF(RecipientInfo) *recipients;
crypto_error_t retval = CRYPTO_ERROR_NONE;
#if (OPENSSL_VERSION_NUMBER >= 0x0090800FL)
- const unsigned char *p = (const unsigned char *) data;
+ const unsigned char *p = (const unsigned char *)data;
#else
- unsigned char *p = (unsigned char *) data;
+ unsigned char *p = (unsigned char *)data;
#endif
- cs = (CRYPTO_SESSION *) malloc(sizeof(CRYPTO_SESSION));
- if (!cs) {
- return CRYPTO_ERROR_INTERNAL;
+ /* bacula-fd.conf doesn't contains any key */
+ if (!keypairs) {
+ return CRYPTO_ERROR_NORECIPIENT;
}
+ cs = (CRYPTO_SESSION *)malloc(sizeof(CRYPTO_SESSION));
+
+ /* Initialize required fields */
+ cs->session_key = NULL;
+
/* d2i_CryptoData modifies the supplied pointer */
cs->cryptoData = d2i_CryptoData(NULL, &p, length);
/* Decrypt the session key */
/* Allocate sufficient space for the largest possible decrypted data */
- cs->session_key = (unsigned char *) malloc(EVP_PKEY_size(keypair->privkey));
+ cs->session_key = (unsigned char *)malloc(EVP_PKEY_size(keypair->privkey));
cs->session_key_len = EVP_PKEY_decrypt(cs->session_key, M_ASN1_STRING_data(ri->encryptedKey),
M_ASN1_STRING_length(ri->encryptedKey), keypair->privkey);
/*
* Free memory associated with a crypto session object.
*/
-void crypto_session_free (CRYPTO_SESSION *cs)
+void crypto_session_free(CRYPTO_SESSION *cs)
{
if (cs->cryptoData) {
CryptoData_free(cs->cryptoData);
free(cs);
}
+/*
+ * Create a new crypto cipher context with the specified session object
+ * Returns: A pointer to a CIPHER_CONTEXT object on success. The cipher block size is returned in blocksize.
+ * NULL on failure.
+ */
+CIPHER_CONTEXT *crypto_cipher_new(CRYPTO_SESSION *cs, bool encrypt, uint32_t *blocksize)
+{
+ CIPHER_CONTEXT *cipher_ctx;
+ const EVP_CIPHER *ec;
+
+ cipher_ctx = (CIPHER_CONTEXT *)malloc(sizeof(CIPHER_CONTEXT));
+
+ /*
+ * Acquire a cipher instance for the given ASN.1 cipher NID
+ */
+ if ((ec = EVP_get_cipherbyobj(cs->cryptoData->contentEncryptionAlgorithm)) == NULL) {
+ Jmsg1(NULL, M_ERROR, 0,
+ _("Unsupported contentEncryptionAlgorithm: %d\n"), OBJ_obj2nid(cs->cryptoData->contentEncryptionAlgorithm));
+ free(cipher_ctx);
+ return NULL;
+ }
+
+ /* Initialize the OpenSSL cipher context */
+ EVP_CIPHER_CTX_init(&cipher_ctx->ctx);
+ if (encrypt) {
+ /* Initialize for encryption */
+ if (!EVP_CipherInit_ex(&cipher_ctx->ctx, ec, NULL, NULL, NULL, 1)) {
+ openssl_post_errors(M_ERROR, _("OpenSSL cipher context initialization failed"));
+ goto err;
+ }
+ } else {
+ /* Initialize for decryption */
+ if (!EVP_CipherInit_ex(&cipher_ctx->ctx, ec, NULL, NULL, NULL, 0)) {
+ openssl_post_errors(M_ERROR, _("OpenSSL cipher context initialization failed"));
+ goto err;
+ }
+ }
+
+ /* Set the key size */
+ if (!EVP_CIPHER_CTX_set_key_length(&cipher_ctx->ctx, cs->session_key_len)) {
+ openssl_post_errors(M_ERROR, _("Encryption session provided an invalid symmetric key"));
+ goto err;
+ }
+
+ /* Validate the IV length */
+ if (EVP_CIPHER_iv_length(ec) != M_ASN1_STRING_length(cs->cryptoData->iv)) {
+ openssl_post_errors(M_ERROR, _("Encryption session provided an invalid IV"));
+ goto err;
+ }
+
+ /* Add the key and IV to the cipher context */
+ if (!EVP_CipherInit_ex(&cipher_ctx->ctx, NULL, NULL, cs->session_key, M_ASN1_STRING_data(cs->cryptoData->iv), -1)) {
+ openssl_post_errors(M_ERROR, _("OpenSSL cipher context key/IV initialization failed"));
+ goto err;
+ }
+
+ *blocksize = EVP_CIPHER_CTX_block_size(&cipher_ctx->ctx);
+ return cipher_ctx;
+
+err:
+ crypto_cipher_free(cipher_ctx);
+ return NULL;
+}
+
+
+/*
+ * Encrypt/Decrypt length bytes of data using the provided cipher context
+ * Returns: true on success, number of bytes output in written
+ * false on failure
+ */
+bool crypto_cipher_update(CIPHER_CONTEXT *cipher_ctx, const uint8_t *data, uint32_t length, const uint8_t *dest, uint32_t *written)
+{
+ if (!EVP_CipherUpdate(&cipher_ctx->ctx, (unsigned char *)dest, (int *)written, (const unsigned char *)data, length)) {
+ /* This really shouldn't fail */
+ return false;
+ } else {
+ return true;
+ }
+}
+
+/*
+ * Finalize the cipher context, writing any remaining data and necessary padding
+ * to dest, and the size in written.
+ * The result size will either be one block of data or zero.
+ *
+ * Returns: true on success
+ * false on failure
+ */
+bool crypto_cipher_finalize (CIPHER_CONTEXT *cipher_ctx, uint8_t *dest, uint32_t *written)
+{
+ if (!EVP_CipherFinal_ex(&cipher_ctx->ctx, (unsigned char *)dest, (int *) written)) {
+ /* This really shouldn't fail */
+ return false;
+ } else {
+ return true;
+ }
+}
+
+
+/*
+ * Free memory associated with a cipher context.
+ */
+void crypto_cipher_free (CIPHER_CONTEXT *cipher_ctx)
+{
+ EVP_CIPHER_CTX_cleanup(&cipher_ctx->ctx);
+ free (cipher_ctx);
+}
+
+
/*
* Perform global initialization of OpenSSL
* This function is not thread safe.
int stat;
if ((stat = openssl_init_threads()) != 0) {
- Emsg1(M_ABORT, 0, _("Unable to init OpenSSL threading: ERR=%s\n"), strerror(stat));
+ berrno be;
+ Jmsg1(NULL, M_ABORT, 0,
+ _("Unable to init OpenSSL threading: ERR=%s\n"), be.bstrerror(stat));
}
/* Load libssl and libcrypto human-readable error strings */
SSL_load_error_strings();
- /* Register OpenSSL ciphers */
+ /* Initialize OpenSSL SSL library */
SSL_library_init();
+ /* Register OpenSSL ciphers and digests */
+ OpenSSL_add_all_algorithms();
+
if (!openssl_seed_prng()) {
- Emsg0(M_ERROR_TERM, 0, _("Failed to seed OpenSSL PRNG\n"));
+ Jmsg0(NULL, M_ERROR_TERM, 0, _("Failed to seed OpenSSL PRNG\n"));
}
crypto_initialized = true;
}
if (!openssl_save_prng()) {
- Emsg0(M_ERROR, 0, _("Failed to save OpenSSL PRNG\n"));
+ Jmsg0(NULL, M_ERROR, 0, _("Failed to save OpenSSL PRNG\n"));
}
openssl_cleanup_threads();
/* Free libssl and libcrypto error strings */
ERR_free_strings();
+ /* Free all ciphers and digests */
+ EVP_cleanup();
+
/* Free memory used by PRNG */
RAND_cleanup();
/* Message Digest Structure */
struct Digest {
crypto_digest_t type;
+ JCR *jcr;
union {
SHA1Context sha1;
MD5Context md5;
/* Dummy Signature Structure */
struct Signature {
+ JCR *jcr;
};
-DIGEST *crypto_digest_new (crypto_digest_t type)
+DIGEST *crypto_digest_new(JCR *jcr, crypto_digest_t type)
{
DIGEST *digest;
- digest = (DIGEST *) malloc(sizeof(DIGEST));
+ digest = (DIGEST *)malloc(sizeof(DIGEST));
digest->type = type;
+ digest->jcr = jcr;
switch (type) {
case CRYPTO_DIGEST_MD5:
SHA1Init(&digest->sha1);
break;
default:
- Emsg0(M_ERROR, 0, _("Unsupported digest type specified\n"));
+ Jmsg1(jcr, M_ERROR, 0, _("Unsupported digest type=%d specified\n"), type);
free(digest);
return NULL;
}
return (digest);
}
-bool crypto_digest_update (DIGEST *digest, const void *data, size_t length) {
+bool crypto_digest_update(DIGEST *digest, const uint8_t *data, uint32_t length)
+{
switch (digest->type) {
case CRYPTO_DIGEST_MD5:
/* Doesn't return anything ... */
if ((ret = SHA1Update(&digest->sha1, (const u_int8_t *) data, length)) == shaSuccess) {
return true;
} else {
- Emsg1(M_ERROR, 0, _("SHA1Update() returned an error: %d\n"), ret);
+ Jmsg1(NULL, M_ERROR, 0, _("SHA1Update() returned an error: %d\n"), ret);
return false;
}
break;
}
}
-bool crypto_digest_finalize (DIGEST *digest, void *dest, size_t *length) {
-
+bool crypto_digest_finalize(DIGEST *digest, uint8_t *dest, uint32_t *length)
+{
switch (digest->type) {
case CRYPTO_DIGEST_MD5:
/* Guard against programmer error by either the API client or
assert(*length >= CRYPTO_DIGEST_MD5_SIZE);
*length = CRYPTO_DIGEST_MD5_SIZE;
/* Doesn't return anything ... */
- MD5Final((unsigned char *) dest, &digest->md5);
+ MD5Final((unsigned char *)dest, &digest->md5);
return true;
case CRYPTO_DIGEST_SHA1:
/* Guard against programmer error by either the API client or
return false;
}
-void crypto_digest_free (DIGEST *digest)
+void crypto_digest_free(DIGEST *digest)
{
- free (digest);
+ free(digest);
}
/* Dummy routines */
int init_crypto (void) { return 0; }
int cleanup_crypto (void) { return 0; }
-SIGNATURE *crypto_sign_new (void) { return NULL; }
+SIGNATURE *crypto_sign_new(JCR *jcr) { return NULL; }
+
+crypto_error_t crypto_sign_get_digest (SIGNATURE *sig, X509_KEYPAIR *keypair,
+ crypto_digest_t &type, DIGEST **digest)
+ { return CRYPTO_ERROR_INTERNAL; }
-crypto_error_t crypto_sign_get_digest (SIGNATURE *sig, X509_KEYPAIR *keypair, DIGEST **digest) { return CRYPTO_ERROR_INTERNAL; }
crypto_error_t crypto_sign_verify (SIGNATURE *sig, X509_KEYPAIR *keypair, DIGEST *digest) { return CRYPTO_ERROR_INTERNAL; }
int crypto_sign_add_signer (SIGNATURE *sig, DIGEST *digest, X509_KEYPAIR *keypair) { return false; }
-int crypto_sign_encode (SIGNATURE *sig, void *dest, size_t *length) { return false; }
+int crypto_sign_encode (SIGNATURE *sig, uint8_t *dest, uint32_t *length) { return false; }
-SIGNATURE *crypto_sign_decode (const void *sigData, size_t length) { return NULL; }
+SIGNATURE *crypto_sign_decode (JCR *jcr, const uint8_t *sigData, uint32_t length) { return NULL; }
void crypto_sign_free (SIGNATURE *sig) { }
-X509_KEYPAIR *crypto_keypair_new (void) { return NULL; }
+X509_KEYPAIR *crypto_keypair_new(void) { return NULL; }
X509_KEYPAIR *crypto_keypair_dup (X509_KEYPAIR *keypair) { return NULL; }
int crypto_keypair_load_cert (X509_KEYPAIR *keypair, const char *file) { return false; }
bool crypto_keypair_has_key (const char *file) { return false; }
CRYPTO_SESSION *crypto_session_new (crypto_cipher_t cipher, alist *pubkeys) { return NULL; }
void crypto_session_free (CRYPTO_SESSION *cs) { }
-bool crypto_session_encode(CRYPTO_SESSION *cs, void *dest, size_t *length) { return false; }
-crypto_error_t crypto_session_decode(const void *data, size_t length, alist *keypairs, CRYPTO_SESSION **session) { return CRYPTO_ERROR_INTERNAL; }
+bool crypto_session_encode (CRYPTO_SESSION *cs, uint8_t *dest, uint32_t *length) { return false; }
+crypto_error_t crypto_session_decode(const uint8_t *data, uint32_t length, alist *keypairs, CRYPTO_SESSION **session) { return CRYPTO_ERROR_INTERNAL; }
+
+CIPHER_CONTEXT *crypto_cipher_new (CRYPTO_SESSION *cs, bool encrypt, uint32_t *blocksize) { return NULL; }
+bool crypto_cipher_update (CIPHER_CONTEXT *cipher_ctx, const uint8_t *data, uint32_t length, const uint8_t *dest, uint32_t *written) { return false; }
+bool crypto_cipher_finalize (CIPHER_CONTEXT *cipher_ctx, uint8_t *dest, uint32_t *written) { return false; }
+void crypto_cipher_free (CIPHER_CONTEXT *cipher_ctx) { }
#endif /* HAVE_CRYPTO */
* Returns the ASCII name of the digest type.
* Returns: ASCII name of digest type.
*/
-const char *crypto_digest_name (DIGEST *digest) {
+const char *crypto_digest_name(DIGEST *digest)
+{
switch (digest->type) {
case CRYPTO_DIGEST_MD5:
return "MD5";
* Given a stream type, returns the associated
* crypto_digest_t value.
*/
-crypto_digest_t crypto_digest_stream_type (int stream) {
+crypto_digest_t crypto_digest_stream_type(int stream)
+{
switch (stream) {
case STREAM_MD5_DIGEST:
return CRYPTO_DIGEST_MD5;
const char *crypto_strerror(crypto_error_t error) {
switch (error) {
case CRYPTO_ERROR_NONE:
- return "No error";
+ return _("No error");
case CRYPTO_ERROR_NOSIGNER:
- return "Signer not found";
+ return _("Signer not found");
case CRYPTO_ERROR_NORECIPIENT:
- return "Recipient not found";
+ return _("Recipient not found");
case CRYPTO_ERROR_INVALID_DIGEST:
- return "Unsupported digest algorithm";
+ return _("Unsupported digest algorithm");
case CRYPTO_ERROR_INVALID_CRYPTO:
- return "Unsupported encryption algorithm";
+ return _("Unsupported encryption algorithm");
case CRYPTO_ERROR_BAD_SIGNATURE:
- return "Signature is invalid";
+ return _("Signature is invalid");
case CRYPTO_ERROR_DECRYPTION:
- return "Decryption error";
+ return _("Decryption error");
case CRYPTO_ERROR_INTERNAL:
/* This shouldn't happen */
- return "Internal error";
+ return _("Internal error");
default:
- return "Unknown error";
+ return _("Unknown error");
}
}