/* Same as make_canon_sexp but pad the buffer to multiple of 64 bits. If SECURE is set, secure memory will be allocated. */ gpg_error_t make_canon_sexp_pad (gcry_sexp_t sexp, int secure, unsigned char **r_buffer, size_t *r_buflen) { size_t len; unsigned char *buf; *r_buffer = NULL; if (r_buflen) *r_buflen = 0;; len = gcry_sexp_sprint (sexp, GCRYSEXP_FMT_CANON, NULL, 0); if (!len) return gpg_error (GPG_ERR_BUG); len += (8 - len % 8) % 8; buf = secure? xtrycalloc_secure (1, len) : xtrycalloc (1, len); if (!buf) return gpg_error_from_syserror (); if (!gcry_sexp_sprint (sexp, GCRYSEXP_FMT_CANON, buf, len)) return gpg_error (GPG_ERR_BUG); *r_buffer = buf; if (r_buflen) *r_buflen = len; return 0; }
/* Compute the A value as used by EdDSA. The caller needs to provide the context EC and the actual secret D as an MPI. The function returns a newly allocated 64 byte buffer at r_digest; the first 32 bytes represent the A value. NULL is returned on error and NULL stored at R_DIGEST. */ gpg_err_code_t _gcry_ecc_eddsa_compute_h_d (unsigned char **r_digest, gcry_mpi_t d, mpi_ec_t ec) { gpg_err_code_t rc; unsigned char *rawmpi = NULL; unsigned int rawmpilen; unsigned char *digest; gcry_buffer_t hvec[2]; int hashalgo, b; *r_digest = NULL; hashalgo = GCRY_MD_SHA512; if (hashalgo != GCRY_MD_SHA512) return GPG_ERR_DIGEST_ALGO; b = (ec->nbits+7)/8; if (b != 256/8) return GPG_ERR_INTERNAL; /* We only support 256 bit. */ /* Note that we clear DIGEST so we can use it as input to left pad the key with zeroes for hashing. */ digest = xtrycalloc_secure (2, b); if (!digest) return gpg_err_code_from_syserror (); memset (hvec, 0, sizeof hvec); rawmpi = _gcry_mpi_get_buffer (d, 0, &rawmpilen, NULL); if (!rawmpi) { xfree (digest); return gpg_err_code_from_syserror (); } hvec[0].data = digest; hvec[0].off = 0; hvec[0].len = b > rawmpilen? b - rawmpilen : 0; hvec[1].data = rawmpi; hvec[1].off = 0; hvec[1].len = rawmpilen; rc = _gcry_md_hash_buffers (hashalgo, 0, digest, hvec, 2); xfree (rawmpi); if (rc) { xfree (digest); return rc; } /* Compute the A value. */ reverse_buffer (digest, 32); /* Only the first half of the hash. */ digest[0] = (digest[0] & 0x7f) | 0x40; digest[31] &= 0xf8; *r_digest = digest; return 0; }
gcry_err_code_t _gcry_cipher_open_internal (gcry_cipher_hd_t *handle, int algo, int mode, unsigned int flags) { int secure = (flags & GCRY_CIPHER_SECURE); gcry_cipher_spec_t *spec; gcry_cipher_hd_t h = NULL; gcry_err_code_t err; /* If the application missed to call the random poll function, we do it here to ensure that it is used once in a while. */ _gcry_fast_random_poll (); spec = spec_from_algo (algo); if (!spec) err = GPG_ERR_CIPHER_ALGO; else if (spec->flags.disabled) err = GPG_ERR_CIPHER_ALGO; else err = 0; /* check flags */ if ((! err) && ((flags & ~(0 | GCRY_CIPHER_SECURE | GCRY_CIPHER_ENABLE_SYNC | GCRY_CIPHER_CBC_CTS | GCRY_CIPHER_CBC_MAC)) || (flags & GCRY_CIPHER_CBC_CTS & GCRY_CIPHER_CBC_MAC))) err = GPG_ERR_CIPHER_ALGO; /* check that a valid mode has been requested */ if (! err) switch (mode) { case GCRY_CIPHER_MODE_CCM: #ifdef HAVE_U64_TYPEDEF if (spec->blocksize != GCRY_CCM_BLOCK_LEN) err = GPG_ERR_INV_CIPHER_MODE; if (!spec->encrypt || !spec->decrypt) err = GPG_ERR_INV_CIPHER_MODE; break; #else err = GPG_ERR_NOT_SUPPORTED; #endif case GCRY_CIPHER_MODE_ECB: case GCRY_CIPHER_MODE_CBC: case GCRY_CIPHER_MODE_CFB: case GCRY_CIPHER_MODE_OFB: case GCRY_CIPHER_MODE_CTR: case GCRY_CIPHER_MODE_AESWRAP: case GCRY_CIPHER_MODE_CMAC: case GCRY_CIPHER_MODE_GCM: if (!spec->encrypt || !spec->decrypt) err = GPG_ERR_INV_CIPHER_MODE; break; case GCRY_CIPHER_MODE_POLY1305: if (!spec->stencrypt || !spec->stdecrypt || !spec->setiv) err = GPG_ERR_INV_CIPHER_MODE; else if (spec->algo != GCRY_CIPHER_CHACHA20) err = GPG_ERR_INV_CIPHER_MODE; break; case GCRY_CIPHER_MODE_OCB: /* Note that our implementation allows only for 128 bit block length algorithms. Lower block lengths would be possible but we do not implement them because they limit the security too much. */ if (!spec->encrypt || !spec->decrypt) err = GPG_ERR_INV_CIPHER_MODE; else if (spec->blocksize != (128/8)) err = GPG_ERR_INV_CIPHER_MODE; break; case GCRY_CIPHER_MODE_STREAM: if (!spec->stencrypt || !spec->stdecrypt) err = GPG_ERR_INV_CIPHER_MODE; break; case GCRY_CIPHER_MODE_NONE: /* This mode may be used for debugging. It copies the main text verbatim to the ciphertext. We do not allow this in fips mode or if no debug flag has been set. */ if (fips_mode () || !_gcry_get_debug_flag (0)) err = GPG_ERR_INV_CIPHER_MODE; break; default: err = GPG_ERR_INV_CIPHER_MODE; } /* Perform selftest here and mark this with a flag in cipher_table? No, we should not do this as it takes too long. Further it does not make sense to exclude algorithms with failing selftests at runtime: If a selftest fails there is something seriously wrong with the system and thus we better die immediately. */ if (! err) { size_t size = (sizeof (*h) + 2 * spec->contextsize - sizeof (cipher_context_alignment_t) #ifdef NEED_16BYTE_ALIGNED_CONTEXT + 15 /* Space for leading alignment gap. */ #endif /*NEED_16BYTE_ALIGNED_CONTEXT*/ ); if (secure) h = xtrycalloc_secure (1, size); else h = xtrycalloc (1, size); if (! h) err = gpg_err_code_from_syserror (); else { size_t off = 0; #ifdef NEED_16BYTE_ALIGNED_CONTEXT if ( ((uintptr_t)h & 0x0f) ) { /* The malloced block is not aligned on a 16 byte boundary. Correct for this. */ off = 16 - ((uintptr_t)h & 0x0f); h = (void*)((char*)h + off); } #endif /*NEED_16BYTE_ALIGNED_CONTEXT*/ h->magic = secure ? CTX_MAGIC_SECURE : CTX_MAGIC_NORMAL; h->actual_handle_size = size - off; h->handle_offset = off; h->spec = spec; h->algo = algo; h->mode = mode; h->flags = flags; /* Setup bulk encryption routines. */ switch (algo) { #ifdef USE_AES case GCRY_CIPHER_AES128: case GCRY_CIPHER_AES192: case GCRY_CIPHER_AES256: h->bulk.cfb_enc = _gcry_aes_cfb_enc; h->bulk.cfb_dec = _gcry_aes_cfb_dec; h->bulk.cbc_enc = _gcry_aes_cbc_enc; h->bulk.cbc_dec = _gcry_aes_cbc_dec; h->bulk.ctr_enc = _gcry_aes_ctr_enc; h->bulk.ocb_crypt = _gcry_aes_ocb_crypt; h->bulk.ocb_auth = _gcry_aes_ocb_auth; break; #endif /*USE_AES*/ #ifdef USE_BLOWFISH case GCRY_CIPHER_BLOWFISH: h->bulk.cfb_dec = _gcry_blowfish_cfb_dec; h->bulk.cbc_dec = _gcry_blowfish_cbc_dec; h->bulk.ctr_enc = _gcry_blowfish_ctr_enc; break; #endif /*USE_BLOWFISH*/ #ifdef USE_CAST5 case GCRY_CIPHER_CAST5: h->bulk.cfb_dec = _gcry_cast5_cfb_dec; h->bulk.cbc_dec = _gcry_cast5_cbc_dec; h->bulk.ctr_enc = _gcry_cast5_ctr_enc; break; #endif /*USE_CAMELLIA*/ #ifdef USE_CAMELLIA case GCRY_CIPHER_CAMELLIA128: case GCRY_CIPHER_CAMELLIA192: case GCRY_CIPHER_CAMELLIA256: h->bulk.cbc_dec = _gcry_camellia_cbc_dec; h->bulk.cfb_dec = _gcry_camellia_cfb_dec; h->bulk.ctr_enc = _gcry_camellia_ctr_enc; h->bulk.ocb_crypt = _gcry_camellia_ocb_crypt; h->bulk.ocb_auth = _gcry_camellia_ocb_auth; break; #endif /*USE_CAMELLIA*/ #ifdef USE_DES case GCRY_CIPHER_3DES: h->bulk.cbc_dec = _gcry_3des_cbc_dec; h->bulk.cfb_dec = _gcry_3des_cfb_dec; h->bulk.ctr_enc = _gcry_3des_ctr_enc; break; #endif /*USE_DES*/ #ifdef USE_SERPENT case GCRY_CIPHER_SERPENT128: case GCRY_CIPHER_SERPENT192: case GCRY_CIPHER_SERPENT256: h->bulk.cbc_dec = _gcry_serpent_cbc_dec; h->bulk.cfb_dec = _gcry_serpent_cfb_dec; h->bulk.ctr_enc = _gcry_serpent_ctr_enc; h->bulk.ocb_crypt = _gcry_serpent_ocb_crypt; h->bulk.ocb_auth = _gcry_serpent_ocb_auth; break; #endif /*USE_SERPENT*/ #ifdef USE_TWOFISH case GCRY_CIPHER_TWOFISH: case GCRY_CIPHER_TWOFISH128: h->bulk.cbc_dec = _gcry_twofish_cbc_dec; h->bulk.cfb_dec = _gcry_twofish_cfb_dec; h->bulk.ctr_enc = _gcry_twofish_ctr_enc; h->bulk.ocb_crypt = _gcry_twofish_ocb_crypt; h->bulk.ocb_auth = _gcry_twofish_ocb_auth; break; #endif /*USE_TWOFISH*/ default: break; } /* Setup defaults depending on the mode. */ switch (mode) { case GCRY_CIPHER_MODE_OCB: h->u_mode.ocb.taglen = 16; /* Bytes. */ break; default: break; } } } /* Done. */ *handle = err ? NULL : h; return err; }
/* Perform an encrypt operation. Encrypt the data received on DATA-FD and write it to OUT_FP. The recipients are take from the certificate given in recplist; if this is NULL it will be encrypted for a default recipient */ int gpgsm_encrypt (ctrl_t ctrl, certlist_t recplist, int data_fd, FILE *out_fp) { int rc = 0; Base64Context b64writer = NULL; gpg_error_t err; ksba_writer_t writer; ksba_reader_t reader = NULL; ksba_cms_t cms = NULL; ksba_stop_reason_t stopreason; KEYDB_HANDLE kh = NULL; struct encrypt_cb_parm_s encparm; DEK dek = NULL; int recpno; FILE *data_fp = NULL; certlist_t cl; int count; memset (&encparm, 0, sizeof encparm); audit_set_type (ctrl->audit, AUDIT_TYPE_ENCRYPT); /* Check that the certificate list is not empty and that at least one certificate is not flagged as encrypt_to; i.e. is a real recipient. */ for (cl = recplist; cl; cl = cl->next) if (!cl->is_encrypt_to) break; if (!cl) { log_error(_("no valid recipients given\n")); gpgsm_status (ctrl, STATUS_NO_RECP, "0"); audit_log_i (ctrl->audit, AUDIT_GOT_RECIPIENTS, 0); rc = gpg_error (GPG_ERR_NO_PUBKEY); goto leave; } for (count = 0, cl = recplist; cl; cl = cl->next) count++; audit_log_i (ctrl->audit, AUDIT_GOT_RECIPIENTS, count); kh = keydb_new (0); if (!kh) { log_error (_("failed to allocated keyDB handle\n")); rc = gpg_error (GPG_ERR_GENERAL); goto leave; } data_fp = fdopen ( dup (data_fd), "rb"); if (!data_fp) { rc = gpg_error (gpg_err_code_from_errno (errno)); log_error ("fdopen() failed: %s\n", strerror (errno)); goto leave; } err = ksba_reader_new (&reader); if (err) rc = err; if (!rc) rc = ksba_reader_set_cb (reader, encrypt_cb, &encparm); if (rc) goto leave; encparm.fp = data_fp; ctrl->pem_name = "ENCRYPTED MESSAGE"; rc = gpgsm_create_writer (&b64writer, ctrl, out_fp, NULL, &writer); if (rc) { log_error ("can't create writer: %s\n", gpg_strerror (rc)); goto leave; } err = ksba_cms_new (&cms); if (err) { rc = err; goto leave; } err = ksba_cms_set_reader_writer (cms, reader, writer); if (err) { log_debug ("ksba_cms_set_reader_writer failed: %s\n", gpg_strerror (err)); rc = err; goto leave; } audit_log (ctrl->audit, AUDIT_GOT_DATA); /* We are going to create enveloped data with uninterpreted data as inner content */ err = ksba_cms_set_content_type (cms, 0, KSBA_CT_ENVELOPED_DATA); if (!err) err = ksba_cms_set_content_type (cms, 1, KSBA_CT_DATA); if (err) { log_debug ("ksba_cms_set_content_type failed: %s\n", gpg_strerror (err)); rc = err; goto leave; } /* Create a session key */ dek = xtrycalloc_secure (1, sizeof *dek); if (!dek) rc = out_of_core (); else { dek->algoid = opt.def_cipher_algoid; rc = init_dek (dek); } if (rc) { log_error ("failed to create the session key: %s\n", gpg_strerror (rc)); goto leave; } err = ksba_cms_set_content_enc_algo (cms, dek->algoid, dek->iv, dek->ivlen); if (err) { log_error ("ksba_cms_set_content_enc_algo failed: %s\n", gpg_strerror (err)); rc = err; goto leave; } encparm.dek = dek; /* Use a ~8k (AES) or ~4k (3DES) buffer */ encparm.bufsize = 500 * dek->ivlen; encparm.buffer = xtrymalloc (encparm.bufsize); if (!encparm.buffer) { rc = out_of_core (); goto leave; } audit_log_s (ctrl->audit, AUDIT_SESSION_KEY, dek->algoid); /* Gather certificates of recipients, encrypt the session key for each and store them in the CMS object */ for (recpno = 0, cl = recplist; cl; recpno++, cl = cl->next) { unsigned char *encval; rc = encrypt_dek (dek, cl->cert, &encval); if (rc) { audit_log_cert (ctrl->audit, AUDIT_ENCRYPTED_TO, cl->cert, rc); log_error ("encryption failed for recipient no. %d: %s\n", recpno, gpg_strerror (rc)); goto leave; } err = ksba_cms_add_recipient (cms, cl->cert); if (err) { audit_log_cert (ctrl->audit, AUDIT_ENCRYPTED_TO, cl->cert, err); log_error ("ksba_cms_add_recipient failed: %s\n", gpg_strerror (err)); rc = err; xfree (encval); goto leave; } err = ksba_cms_set_enc_val (cms, recpno, encval); xfree (encval); audit_log_cert (ctrl->audit, AUDIT_ENCRYPTED_TO, cl->cert, err); if (err) { log_error ("ksba_cms_set_enc_val failed: %s\n", gpg_strerror (err)); rc = err; goto leave; } } /* Main control loop for encryption. */ recpno = 0; do { err = ksba_cms_build (cms, &stopreason); if (err) { log_debug ("ksba_cms_build failed: %s\n", gpg_strerror (err)); rc = err; goto leave; } } while (stopreason != KSBA_SR_READY); if (encparm.readerror) { log_error ("error reading input: %s\n", strerror (encparm.readerror)); rc = gpg_error (gpg_err_code_from_errno (encparm.readerror)); goto leave; } rc = gpgsm_finish_writer (b64writer); if (rc) { log_error ("write failed: %s\n", gpg_strerror (rc)); goto leave; } audit_log (ctrl->audit, AUDIT_ENCRYPTION_DONE); log_info ("encrypted data created\n"); leave: ksba_cms_release (cms); gpgsm_destroy_writer (b64writer); ksba_reader_release (reader); keydb_release (kh); xfree (dek); if (data_fp) fclose (data_fp); xfree (encparm.buffer); return rc; }