/*
**
** Copyright 2017, The Android Open Source Project
**
** Licensed under the Apache License, Version 2.0 (the "License");
** you may not use this file except in compliance with the License.
** You may obtain a copy of the License at
**
** http://www.apache.org/licenses/LICENSE-2.0
**
** Unless required by applicable law or agreed to in writing, software
** distributed under the License is distributed on an "AS IS" BASIS,
** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
** See the License for the specific language governing permissions and
** limitations under the License.
*/
#include <keymaster/km_openssl/attestation_utils.h>
#include <hardware/keymaster_defs.h>
#include <keymaster/authorization_set.h>
#include <keymaster/attestation_record.h>
#include <keymaster/km_openssl/asymmetric_key.h>
#include <keymaster/km_openssl/openssl_utils.h>
#include <keymaster/km_openssl/openssl_err.h>
#include <openssl/x509v3.h>
#include <openssl/evp.h>
namespace keymaster {
namespace {
constexpr int kDigitalSignatureKeyUsageBit = 0;
constexpr int kKeyEnciphermentKeyUsageBit = 2;
constexpr int kDataEnciphermentKeyUsageBit = 3;
constexpr int kMaxKeyUsageBit = 8;
template <typename T> T && min(T && a, T && b) {
return (a < b) ? std::forward<T>(a) : std::forward<T>(b);
}
struct emptyCert {};
__attribute__((__unused__))
inline keymaster_blob_t certBlobifier(const emptyCert&, bool*){ return {}; }
template <size_t N>
inline keymaster_blob_t certBlobifier(const uint8_t (&cert)[N], bool* fail){
keymaster_blob_t result = { dup_array(cert), N };
if (!result.data) {
*fail = true;
return {};
}
return result;
}
inline keymaster_blob_t certBlobifier(const keymaster_blob_t& blob, bool* fail){
if (blob.data == nullptr || blob.data_length == 0) return {};
keymaster_blob_t result = { dup_array(blob.data, blob.data_length), blob.data_length };
if (!result.data) {
*fail = true;
return {};
}
return result;
}
inline keymaster_blob_t certBlobifier(keymaster_blob_t&& blob, bool*){
if (blob.data == nullptr || blob.data_length == 0) return {};
keymaster_blob_t result = blob;
blob = {};
return result;
}
inline keymaster_blob_t certBlobifier(X509* certificate, bool* fail){
int len = i2d_X509(certificate, nullptr);
if (len < 0) {
*fail = true;
return {};
}
uint8_t* data = new(std::nothrow) uint8_t[len];
if (!data) {
*fail = true;
return {};
}
uint8_t* p = data;
i2d_X509(certificate, &p);
return { data, (size_t)len };
}
inline bool certCopier(keymaster_blob_t** out, const keymaster_cert_chain_t& chain,
bool* fail) {
for (size_t i = 0; i < chain.entry_count; ++i) {
*(*out)++ = certBlobifier(chain.entries[i], fail);
}
return *fail;
}
__attribute__((__unused__))
inline bool certCopier(keymaster_blob_t** out, keymaster_cert_chain_t&& chain, bool* fail) {
for (size_t i = 0; i < chain.entry_count; ++i) {
*(*out)++ = certBlobifier(std::move(chain.entries[i]), fail);
}
delete[] chain.entries;
chain.entries = nullptr;
chain.entry_count = 0;
return *fail;
}
template <typename CERT>
inline bool certCopier(keymaster_blob_t** out, CERT&& cert, bool* fail) {
*(*out)++ = certBlobifier(std::forward<CERT>(cert), fail);
return *fail;
}
inline bool certCopyHelper(keymaster_blob_t**, bool* fail) {
return *fail;
}
template <typename CERT, typename... CERTS>
inline bool certCopyHelper(keymaster_blob_t** out, bool* fail, CERT&& cert, CERTS&&... certs) {
certCopier(out, std::forward<CERT>(cert), fail);
return certCopyHelper(out, fail, std::forward<CERTS>(certs)...);
}
template <typename T>
inline size_t noOfCert(T &&) { return 1; }
inline size_t noOfCert(const keymaster_cert_chain_t& cert_chain) { return cert_chain.entry_count; }
inline size_t certCount() { return 0; }
template <typename CERT, typename... CERTS>
inline size_t certCount(CERT&& cert, CERTS&&... certs) {
return noOfCert(std::forward<CERT>(cert)) + certCount(std::forward<CERTS>(certs)...);
}
/*
* makeCertChain creates a new keymaster_cert_chain_t from all the certs that get thrown at it
* in the given order. A cert may be a X509*, uint8_t[], a keymaster_blob_t, an instance of
* emptyCert, or another keymater_cert_chain_t in which case the certs of the chain are included
* in the new chain. emptyCert is a placeholder which results in an empty slot at the given
* position in the newly created certificate chain. E.g., makeCertChain(emptyCert(), someCertChain)
* allocates enough slots to accommodate all certificates of someCertChain plus one empty slot and
* copies in someCertChain starting at index 1 so that the slot with index 0 can be used for a new
* leaf entry.
*
* makeCertChain respects move semantics. E.g., makeCertChain(emptyCert(), std::move(someCertChain))
* will take possession of secondary resources for the certificate blobs so that someCertChain is
* empty after the call. Also, because no allocation happens this cannot fail. Note, however, that
* if another cert is passed to makeCertChain, that needs to be copied and thus requires
* allocation, and this allocation fails, all resources - allocated or moved - will be reaped.
*/
template <typename... CERTS>
CertChainPtr makeCertChain(CERTS&&... certs) {
CertChainPtr result(new (std::nothrow) keymaster_cert_chain_t);
if (!result.get()) return {};
result->entries = new (std::nothrow) keymaster_blob_t[certCount(std::forward<CERTS>(certs)...)];
if (!result->entries) return {};
result->entry_count = certCount(std::forward<CERTS>(certs)...);
bool allocation_failed = false;
keymaster_blob_t* entries = result->entries;
certCopyHelper(&entries, &allocation_failed, std::forward<CERTS>(certs)...);
if (allocation_failed) return {};
return result;
}
keymaster_error_t build_attestation_extension(const AuthorizationSet& attest_params,
const AuthorizationSet& tee_enforced,
const AuthorizationSet& sw_enforced,
const AttestationRecordContext& context,
X509_EXTENSION_Ptr* extension) {
ASN1_OBJECT_Ptr oid(
OBJ_txt2obj(kAttestionRecordOid, 1 /* accept numerical dotted string form only */));
if (!oid.get())
return TranslateLastOpenSslError();
UniquePtr<uint8_t[]> attest_bytes;
size_t attest_bytes_len;
keymaster_error_t error = build_attestation_record(attest_params, sw_enforced, tee_enforced,
context, &attest_bytes, &attest_bytes_len);
if (error != KM_ERROR_OK)
return error;
ASN1_OCTET_STRING_Ptr attest_str(ASN1_OCTET_STRING_new());
if (!attest_str.get() ||
!ASN1_OCTET_STRING_set(attest_str.get(), attest_bytes.get(), attest_bytes_len))
return TranslateLastOpenSslError();
extension->reset(
X509_EXTENSION_create_by_OBJ(nullptr, oid.get(), 0 /* not critical */, attest_str.get()));
if (!extension->get())
return TranslateLastOpenSslError();
return KM_ERROR_OK;
}
keymaster_error_t add_key_usage_extension(const AuthorizationSet& tee_enforced,
const AuthorizationSet& sw_enforced,
X509* certificate) {
// Build BIT_STRING with correct contents.
ASN1_BIT_STRING_Ptr key_usage(ASN1_BIT_STRING_new());
for (size_t i = 0; i <= kMaxKeyUsageBit; ++i) {
if (!ASN1_BIT_STRING_set_bit(key_usage.get(), i, 0)) {
return TranslateLastOpenSslError();
}
}
if (tee_enforced.Contains(TAG_PURPOSE, KM_PURPOSE_SIGN) ||
tee_enforced.Contains(TAG_PURPOSE, KM_PURPOSE_VERIFY) ||
sw_enforced.Contains(TAG_PURPOSE, KM_PURPOSE_SIGN) ||
sw_enforced.Contains(TAG_PURPOSE, KM_PURPOSE_VERIFY)) {
if (!ASN1_BIT_STRING_set_bit(key_usage.get(), kDigitalSignatureKeyUsageBit, 1)) {
return TranslateLastOpenSslError();
}
}
if (tee_enforced.Contains(TAG_PURPOSE, KM_PURPOSE_ENCRYPT) ||
tee_enforced.Contains(TAG_PURPOSE, KM_PURPOSE_DECRYPT) ||
sw_enforced.Contains(TAG_PURPOSE, KM_PURPOSE_ENCRYPT) ||
sw_enforced.Contains(TAG_PURPOSE, KM_PURPOSE_DECRYPT)) {
if (!ASN1_BIT_STRING_set_bit(key_usage.get(), kKeyEnciphermentKeyUsageBit, 1) ||
!ASN1_BIT_STRING_set_bit(key_usage.get(), kDataEnciphermentKeyUsageBit, 1)) {
return TranslateLastOpenSslError();
}
}
// Convert to octets
int len = i2d_ASN1_BIT_STRING(key_usage.get(), nullptr);
if (len < 0) {
return TranslateLastOpenSslError();
}
UniquePtr<uint8_t[]> asn1_key_usage(new(std::nothrow) uint8_t[len]);
if (!asn1_key_usage.get()) {
return KM_ERROR_MEMORY_ALLOCATION_FAILED;
}
uint8_t* p = asn1_key_usage.get();
len = i2d_ASN1_BIT_STRING(key_usage.get(), &p);
if (len < 0) {
return TranslateLastOpenSslError();
}
// Build OCTET_STRING
ASN1_OCTET_STRING_Ptr key_usage_str(ASN1_OCTET_STRING_new());
if (!key_usage_str.get() ||
!ASN1_OCTET_STRING_set(key_usage_str.get(), asn1_key_usage.get(), len)) {
return TranslateLastOpenSslError();
}
X509_EXTENSION_Ptr key_usage_extension(X509_EXTENSION_create_by_NID(nullptr, //
NID_key_usage, //
false /* critical */,
key_usage_str.get()));
if (!key_usage_extension.get()) {
return TranslateLastOpenSslError();
}
if (!X509_add_ext(certificate, key_usage_extension.get() /* Don't release; copied */,
-1 /* insert at end */)) {
return TranslateLastOpenSslError();
}
return KM_ERROR_OK;
}
bool add_public_key(EVP_PKEY* key, X509* certificate, keymaster_error_t* error) {
if (!X509_set_pubkey(certificate, key)) {
*error = TranslateLastOpenSslError();
return false;
}
return true;
}
bool add_attestation_extension(const AuthorizationSet& attest_params,
const AuthorizationSet& tee_enforced,
const AuthorizationSet& sw_enforced,
const AttestationRecordContext& context,
X509* certificate,
keymaster_error_t* error) {
X509_EXTENSION_Ptr attest_extension;
*error = build_attestation_extension(attest_params, tee_enforced, sw_enforced, context,
&attest_extension);
if (*error != KM_ERROR_OK)
return false;
if (!X509_add_ext(certificate, attest_extension.get() /* Don't release; copied */,
-1 /* insert at end */)) {
*error = TranslateLastOpenSslError();
return false;
}
return true;
}
} // anonymous namespace
keymaster_error_t generate_attestation(const AsymmetricKey& key,
const AuthorizationSet& attest_params, const keymaster_cert_chain_t& attestation_chain,
const keymaster_key_blob_t& attestation_signing_key,
const AttestationRecordContext& context, CertChainPtr* cert_chain_out) {
if (!cert_chain_out)
return KM_ERROR_UNEXPECTED_NULL_POINTER;
keymaster_algorithm_t sign_algorithm;
if ((!key.sw_enforced().GetTagValue(TAG_ALGORITHM, &sign_algorithm) &&
!key.hw_enforced().GetTagValue(TAG_ALGORITHM, &sign_algorithm)))
return KM_ERROR_UNKNOWN_ERROR;
EVP_PKEY_Ptr pkey(EVP_PKEY_new());
if (!key.InternalToEvp(pkey.get()))
return TranslateLastOpenSslError();
X509_Ptr certificate(X509_new());
if (!certificate.get())
return TranslateLastOpenSslError();
if (!X509_set_version(certificate.get(), 2 /* version 3, but zero-based */))
return TranslateLastOpenSslError();
ASN1_INTEGER_Ptr serialNumber(ASN1_INTEGER_new());
if (!serialNumber.get() || !ASN1_INTEGER_set(serialNumber.get(), 1) ||
!X509_set_serialNumber(certificate.get(), serialNumber.get() /* Don't release; copied */))
return TranslateLastOpenSslError();
X509_NAME_Ptr subjectName(X509_NAME_new());
if (!subjectName.get() ||
!X509_NAME_add_entry_by_txt(subjectName.get(), "CN", MBSTRING_ASC,
reinterpret_cast<const uint8_t*>("Android Keystore Key"),
-1 /* len */, -1 /* loc */, 0 /* set */) ||
!X509_set_subject_name(certificate.get(), subjectName.get() /* Don't release; copied */))
return TranslateLastOpenSslError();
ASN1_TIME_Ptr notBefore(ASN1_TIME_new());
uint64_t activeDateTime = 0;
key.authorizations().GetTagValue(TAG_ACTIVE_DATETIME, &activeDateTime);
if (!notBefore.get() || !ASN1_TIME_set(notBefore.get(), activeDateTime / 1000) ||
!X509_set_notBefore(certificate.get(), notBefore.get() /* Don't release; copied */))
return TranslateLastOpenSslError();
ASN1_TIME_Ptr notAfter(ASN1_TIME_new());
uint64_t usageExpireDateTime = UINT64_MAX;
key.authorizations().GetTagValue(TAG_USAGE_EXPIRE_DATETIME, &usageExpireDateTime);
// TODO(swillden): When trusty can use the C++ standard library change the calculation of
// notAfterTime to use std::numeric_limits<time_t>::max(), rather than assuming that time_t is
// 32 bits.
time_t notAfterTime = min(static_cast<uint64_t>(UINT32_MAX), usageExpireDateTime / 1000);
if (!notAfter.get() || !ASN1_TIME_set(notAfter.get(), notAfterTime) ||
!X509_set_notAfter(certificate.get(), notAfter.get() /* Don't release; copied */))
return TranslateLastOpenSslError();
keymaster_error_t error = add_key_usage_extension(key.hw_enforced(), key.sw_enforced(), certificate.get());
if (error != KM_ERROR_OK) {
return error;
}
// We have established above that it is one of the two. So if it is not RSA its EC.
int evp_key_type = (sign_algorithm == KM_ALGORITHM_RSA) ? EVP_PKEY_RSA : EVP_PKEY_EC;
const uint8_t* key_material = attestation_signing_key.key_material;
EVP_PKEY_Ptr sign_key(
d2i_PrivateKey(evp_key_type, nullptr,
const_cast<const uint8_t**>(&key_material),
attestation_signing_key.key_material_size));
if (!sign_key.get()) return TranslateLastOpenSslError();
if (!add_public_key(pkey.get(), certificate.get(), &error) ||
!add_attestation_extension(attest_params, key.hw_enforced(), key.sw_enforced(),
context, certificate.get(), &error))
return error;
if (attestation_chain.entry_count < 1) {
// the attestation chain must have at least the cert for the key that signs the new cert.
return KM_ERROR_UNKNOWN_ERROR;
}
const uint8_t* p = attestation_chain.entries[0].data;
X509_Ptr signing_cert(d2i_X509(nullptr, &p, attestation_chain.entries[0].data_length));
if (!signing_cert.get()) {
return TranslateLastOpenSslError();
}
// Set issuer to subject of batch certificate.
X509_NAME* issuerSubject = X509_get_subject_name(signing_cert.get());
if (!issuerSubject) {
return KM_ERROR_UNKNOWN_ERROR;
}
if (!X509_set_issuer_name(certificate.get(), issuerSubject)) {
return TranslateLastOpenSslError();
}
UniquePtr<X509V3_CTX> x509v3_ctx(new(std::nothrow) X509V3_CTX);
if (!x509v3_ctx.get())
return KM_ERROR_MEMORY_ALLOCATION_FAILED;
*x509v3_ctx = {};
X509V3_set_ctx(x509v3_ctx.get(), signing_cert.get(), certificate.get(), nullptr /* req */,
nullptr /* crl */, 0 /* flags */);
X509_EXTENSION_Ptr auth_key_id(X509V3_EXT_nconf_nid(nullptr /* conf */, x509v3_ctx.get(),
NID_authority_key_identifier,
const_cast<char*>("keyid:always")));
if (!auth_key_id.get() ||
!X509_add_ext(certificate.get(), auth_key_id.get() /* Don't release; copied */,
-1 /* insert at end */)) {
return TranslateLastOpenSslError();
}
if (!X509_sign(certificate.get(), sign_key.get(), EVP_sha256()))
return TranslateLastOpenSslError();
*cert_chain_out = makeCertChain(certificate.get(), attestation_chain);
if (!cert_chain_out->get())
return KM_ERROR_MEMORY_ALLOCATION_FAILED;
return KM_ERROR_OK;
}
} // namespace keymaster