openssl/crypto/ts/ts_asn1.c
Antonio Iacono e85d19c68e crypto/cms: Add support for CAdES Basic Electronic Signatures (CAdES-BES)
A CAdES Basic Electronic Signature (CAdES-BES) contains, among other
specifications, a collection of  Signing Certificate reference attributes,
stored in the signedData ether as ESS signing-certificate or as
ESS signing-certificate-v2. These are described in detail in Section 5.7.2
of RFC 5126 - CMS Advanced Electronic Signatures (CAdES).

This patch adds support for adding  ESS signing-certificate[-v2] attributes
to CMS signedData. Although it implements only a small part of the RFC, it
is sufficient many cases to enable the `openssl cms` app to create signatures
which comply with legal requirements of some European States (e.g Italy).

Reviewed-by: Richard Levitte <levitte@openssl.org>
Reviewed-by: Matthias St. Pierre <Matthias.St.Pierre@ncp-e.com>
(Merged from https://github.com/openssl/openssl/pull/7893)
2019-01-27 23:59:21 +01:00

236 lines
7.2 KiB
C

/*
* Copyright 2006-2016 The OpenSSL Project Authors. All Rights Reserved.
*
* Licensed under the Apache License 2.0 (the "License"). You may not use
* this file except in compliance with the License. You can obtain a copy
* in the file LICENSE in the source distribution or at
* https://www.openssl.org/source/license.html
*/
#include <openssl/ts.h>
#include <openssl/err.h>
#include <openssl/asn1t.h>
#include "ts_lcl.h"
ASN1_SEQUENCE(TS_MSG_IMPRINT) = {
ASN1_SIMPLE(TS_MSG_IMPRINT, hash_algo, X509_ALGOR),
ASN1_SIMPLE(TS_MSG_IMPRINT, hashed_msg, ASN1_OCTET_STRING)
} static_ASN1_SEQUENCE_END(TS_MSG_IMPRINT)
IMPLEMENT_ASN1_FUNCTIONS_const(TS_MSG_IMPRINT)
IMPLEMENT_ASN1_DUP_FUNCTION(TS_MSG_IMPRINT)
TS_MSG_IMPRINT *d2i_TS_MSG_IMPRINT_bio(BIO *bp, TS_MSG_IMPRINT **a)
{
return ASN1_d2i_bio_of(TS_MSG_IMPRINT, TS_MSG_IMPRINT_new,
d2i_TS_MSG_IMPRINT, bp, a);
}
int i2d_TS_MSG_IMPRINT_bio(BIO *bp, TS_MSG_IMPRINT *a)
{
return ASN1_i2d_bio_of_const(TS_MSG_IMPRINT, i2d_TS_MSG_IMPRINT, bp, a);
}
#ifndef OPENSSL_NO_STDIO
TS_MSG_IMPRINT *d2i_TS_MSG_IMPRINT_fp(FILE *fp, TS_MSG_IMPRINT **a)
{
return ASN1_d2i_fp_of(TS_MSG_IMPRINT, TS_MSG_IMPRINT_new,
d2i_TS_MSG_IMPRINT, fp, a);
}
int i2d_TS_MSG_IMPRINT_fp(FILE *fp, TS_MSG_IMPRINT *a)
{
return ASN1_i2d_fp_of_const(TS_MSG_IMPRINT, i2d_TS_MSG_IMPRINT, fp, a);
}
#endif
ASN1_SEQUENCE(TS_REQ) = {
ASN1_SIMPLE(TS_REQ, version, ASN1_INTEGER),
ASN1_SIMPLE(TS_REQ, msg_imprint, TS_MSG_IMPRINT),
ASN1_OPT(TS_REQ, policy_id, ASN1_OBJECT),
ASN1_OPT(TS_REQ, nonce, ASN1_INTEGER),
ASN1_OPT(TS_REQ, cert_req, ASN1_FBOOLEAN),
ASN1_IMP_SEQUENCE_OF_OPT(TS_REQ, extensions, X509_EXTENSION, 0)
} static_ASN1_SEQUENCE_END(TS_REQ)
IMPLEMENT_ASN1_FUNCTIONS_const(TS_REQ)
IMPLEMENT_ASN1_DUP_FUNCTION(TS_REQ)
TS_REQ *d2i_TS_REQ_bio(BIO *bp, TS_REQ **a)
{
return ASN1_d2i_bio_of(TS_REQ, TS_REQ_new, d2i_TS_REQ, bp, a);
}
int i2d_TS_REQ_bio(BIO *bp, TS_REQ *a)
{
return ASN1_i2d_bio_of_const(TS_REQ, i2d_TS_REQ, bp, a);
}
#ifndef OPENSSL_NO_STDIO
TS_REQ *d2i_TS_REQ_fp(FILE *fp, TS_REQ **a)
{
return ASN1_d2i_fp_of(TS_REQ, TS_REQ_new, d2i_TS_REQ, fp, a);
}
int i2d_TS_REQ_fp(FILE *fp, TS_REQ *a)
{
return ASN1_i2d_fp_of_const(TS_REQ, i2d_TS_REQ, fp, a);
}
#endif
ASN1_SEQUENCE(TS_ACCURACY) = {
ASN1_OPT(TS_ACCURACY, seconds, ASN1_INTEGER),
ASN1_IMP_OPT(TS_ACCURACY, millis, ASN1_INTEGER, 0),
ASN1_IMP_OPT(TS_ACCURACY, micros, ASN1_INTEGER, 1)
} static_ASN1_SEQUENCE_END(TS_ACCURACY)
IMPLEMENT_ASN1_FUNCTIONS_const(TS_ACCURACY)
IMPLEMENT_ASN1_DUP_FUNCTION(TS_ACCURACY)
ASN1_SEQUENCE(TS_TST_INFO) = {
ASN1_SIMPLE(TS_TST_INFO, version, ASN1_INTEGER),
ASN1_SIMPLE(TS_TST_INFO, policy_id, ASN1_OBJECT),
ASN1_SIMPLE(TS_TST_INFO, msg_imprint, TS_MSG_IMPRINT),
ASN1_SIMPLE(TS_TST_INFO, serial, ASN1_INTEGER),
ASN1_SIMPLE(TS_TST_INFO, time, ASN1_GENERALIZEDTIME),
ASN1_OPT(TS_TST_INFO, accuracy, TS_ACCURACY),
ASN1_OPT(TS_TST_INFO, ordering, ASN1_FBOOLEAN),
ASN1_OPT(TS_TST_INFO, nonce, ASN1_INTEGER),
ASN1_EXP_OPT(TS_TST_INFO, tsa, GENERAL_NAME, 0),
ASN1_IMP_SEQUENCE_OF_OPT(TS_TST_INFO, extensions, X509_EXTENSION, 1)
} static_ASN1_SEQUENCE_END(TS_TST_INFO)
IMPLEMENT_ASN1_FUNCTIONS_const(TS_TST_INFO)
IMPLEMENT_ASN1_DUP_FUNCTION(TS_TST_INFO)
TS_TST_INFO *d2i_TS_TST_INFO_bio(BIO *bp, TS_TST_INFO **a)
{
return ASN1_d2i_bio_of(TS_TST_INFO, TS_TST_INFO_new, d2i_TS_TST_INFO, bp,
a);
}
int i2d_TS_TST_INFO_bio(BIO *bp, TS_TST_INFO *a)
{
return ASN1_i2d_bio_of_const(TS_TST_INFO, i2d_TS_TST_INFO, bp, a);
}
#ifndef OPENSSL_NO_STDIO
TS_TST_INFO *d2i_TS_TST_INFO_fp(FILE *fp, TS_TST_INFO **a)
{
return ASN1_d2i_fp_of(TS_TST_INFO, TS_TST_INFO_new, d2i_TS_TST_INFO, fp,
a);
}
int i2d_TS_TST_INFO_fp(FILE *fp, TS_TST_INFO *a)
{
return ASN1_i2d_fp_of_const(TS_TST_INFO, i2d_TS_TST_INFO, fp, a);
}
#endif
ASN1_SEQUENCE(TS_STATUS_INFO) = {
ASN1_SIMPLE(TS_STATUS_INFO, status, ASN1_INTEGER),
ASN1_SEQUENCE_OF_OPT(TS_STATUS_INFO, text, ASN1_UTF8STRING),
ASN1_OPT(TS_STATUS_INFO, failure_info, ASN1_BIT_STRING)
} static_ASN1_SEQUENCE_END(TS_STATUS_INFO)
IMPLEMENT_ASN1_FUNCTIONS_const(TS_STATUS_INFO)
IMPLEMENT_ASN1_DUP_FUNCTION(TS_STATUS_INFO)
static int ts_resp_set_tst_info(TS_RESP *a)
{
long status;
status = ASN1_INTEGER_get(a->status_info->status);
if (a->token) {
if (status != 0 && status != 1) {
TSerr(TS_F_TS_RESP_SET_TST_INFO, TS_R_TOKEN_PRESENT);
return 0;
}
TS_TST_INFO_free(a->tst_info);
a->tst_info = PKCS7_to_TS_TST_INFO(a->token);
if (!a->tst_info) {
TSerr(TS_F_TS_RESP_SET_TST_INFO,
TS_R_PKCS7_TO_TS_TST_INFO_FAILED);
return 0;
}
} else if (status == 0 || status == 1) {
TSerr(TS_F_TS_RESP_SET_TST_INFO, TS_R_TOKEN_NOT_PRESENT);
return 0;
}
return 1;
}
static int ts_resp_cb(int op, ASN1_VALUE **pval, const ASN1_ITEM *it,
void *exarg)
{
TS_RESP *ts_resp = (TS_RESP *)*pval;
if (op == ASN1_OP_NEW_POST) {
ts_resp->tst_info = NULL;
} else if (op == ASN1_OP_FREE_POST) {
TS_TST_INFO_free(ts_resp->tst_info);
} else if (op == ASN1_OP_D2I_POST) {
if (ts_resp_set_tst_info(ts_resp) == 0)
return 0;
}
return 1;
}
ASN1_SEQUENCE_cb(TS_RESP, ts_resp_cb) = {
ASN1_SIMPLE(TS_RESP, status_info, TS_STATUS_INFO),
ASN1_OPT(TS_RESP, token, PKCS7),
} static_ASN1_SEQUENCE_END_cb(TS_RESP, TS_RESP)
IMPLEMENT_ASN1_FUNCTIONS_const(TS_RESP)
IMPLEMENT_ASN1_DUP_FUNCTION(TS_RESP)
TS_RESP *d2i_TS_RESP_bio(BIO *bp, TS_RESP **a)
{
return ASN1_d2i_bio_of(TS_RESP, TS_RESP_new, d2i_TS_RESP, bp, a);
}
int i2d_TS_RESP_bio(BIO *bp, TS_RESP *a)
{
return ASN1_i2d_bio_of_const(TS_RESP, i2d_TS_RESP, bp, a);
}
#ifndef OPENSSL_NO_STDIO
TS_RESP *d2i_TS_RESP_fp(FILE *fp, TS_RESP **a)
{
return ASN1_d2i_fp_of(TS_RESP, TS_RESP_new, d2i_TS_RESP, fp, a);
}
int i2d_TS_RESP_fp(FILE *fp, TS_RESP *a)
{
return ASN1_i2d_fp_of_const(TS_RESP, i2d_TS_RESP, fp, a);
}
#endif
/* Getting encapsulated TS_TST_INFO object from PKCS7. */
TS_TST_INFO *PKCS7_to_TS_TST_INFO(PKCS7 *token)
{
PKCS7_SIGNED *pkcs7_signed;
PKCS7 *enveloped;
ASN1_TYPE *tst_info_wrapper;
ASN1_OCTET_STRING *tst_info_der;
const unsigned char *p;
if (!PKCS7_type_is_signed(token)) {
TSerr(TS_F_PKCS7_TO_TS_TST_INFO, TS_R_BAD_PKCS7_TYPE);
return NULL;
}
if (PKCS7_get_detached(token)) {
TSerr(TS_F_PKCS7_TO_TS_TST_INFO, TS_R_DETACHED_CONTENT);
return NULL;
}
pkcs7_signed = token->d.sign;
enveloped = pkcs7_signed->contents;
if (OBJ_obj2nid(enveloped->type) != NID_id_smime_ct_TSTInfo) {
TSerr(TS_F_PKCS7_TO_TS_TST_INFO, TS_R_BAD_PKCS7_TYPE);
return NULL;
}
tst_info_wrapper = enveloped->d.other;
if (tst_info_wrapper->type != V_ASN1_OCTET_STRING) {
TSerr(TS_F_PKCS7_TO_TS_TST_INFO, TS_R_BAD_TYPE);
return NULL;
}
tst_info_der = tst_info_wrapper->value.octet_string;
p = tst_info_der->data;
return d2i_TS_TST_INFO(NULL, &p, tst_info_der->length);
}