platform_system_security/identity/WritableCredential.cpp
David Zeuthen 62d43bf7cb identity: Use "credstore" for LOG_TAG everywhere.
Currently we're using file-specific tags which makes it hard for
people looking at logcat to infer it's actually from credstore and it
also complicates filtering. Just use "credstore" everywhere.

Also change logging level from ERROR to INFO in the message
"Registered binder service" which is logged on startup.

Bug: None
Test: Compiles + manual inspection via logcat
Test: atest android.security.identity.cts (on goldfish)
Change-Id: I336d1a4e4e10b87fd3f08a5046cf5e13f09c9cb6
2021-03-31 10:46:42 -04:00

281 lines
11 KiB
C++

/*
* Copyright (c) 2019, 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.
*/
#define LOG_TAG "credstore"
#include <android-base/logging.h>
#include <android/hardware/identity/support/IdentityCredentialSupport.h>
#include <android/security/identity/ICredentialStore.h>
#include <binder/IPCThreadState.h>
#include <cppbor.h>
#include <cppbor_parse.h>
#include <keystore/keystore_attestation_id.h>
#include "CredentialData.h"
#include "Util.h"
#include "WritableCredential.h"
namespace android {
namespace security {
namespace identity {
using ::std::pair;
using ::android::hardware::identity::SecureAccessControlProfile;
using ::android::hardware::identity::support::chunkVector;
WritableCredential::WritableCredential(const string& dataPath, const string& credentialName,
const string& docType, bool isUpdate,
HardwareInformation hwInfo,
sp<IWritableIdentityCredential> halBinder)
: dataPath_(dataPath), credentialName_(credentialName), docType_(docType), isUpdate_(isUpdate),
hwInfo_(std::move(hwInfo)), halBinder_(halBinder) {}
WritableCredential::~WritableCredential() {}
void WritableCredential::setCredentialToReloadWhenUpdated(sp<Credential> credential) {
credentialToReloadWhenUpdated_ = credential;
}
Status WritableCredential::ensureAttestationCertificateExists(const vector<uint8_t>& challenge) {
if (!attestationCertificate_.empty()) {
return Status::ok();
}
const int32_t callingUid = IPCThreadState::self()->getCallingUid();
auto asn1AttestationId = android::security::gather_attestation_application_id(callingUid);
if (!asn1AttestationId.isOk()) {
LOG(ERROR) << "Failed gathering AttestionApplicationId";
return Status::fromServiceSpecificError(ICredentialStore::ERROR_GENERIC,
"Failed gathering AttestionApplicationId");
}
vector<Certificate> certificateChain;
Status status = halBinder_->getAttestationCertificate(asn1AttestationId.value(), challenge,
&certificateChain);
if (!status.isOk()) {
LOG(ERROR) << "Error calling getAttestationCertificate()";
return halStatusToGenericError(status);
}
vector<vector<uint8_t>> splitCerts;
for (const auto& cert : certificateChain) {
splitCerts.push_back(cert.encodedCertificate);
}
attestationCertificate_ =
::android::hardware::identity::support::certificateChainJoin(splitCerts);
return Status::ok();
}
Status WritableCredential::getCredentialKeyCertificateChain(const vector<uint8_t>& challenge,
vector<uint8_t>* _aidl_return) {
if (isUpdate_) {
return Status::fromServiceSpecificError(ICredentialStore::ERROR_GENERIC,
"Cannot be called for an update");
}
Status ensureStatus = ensureAttestationCertificateExists(challenge);
if (!ensureStatus.isOk()) {
return ensureStatus;
}
*_aidl_return = attestationCertificate_;
return Status::ok();
}
void WritableCredential::setAttestationCertificate(const vector<uint8_t>& attestationCertificate) {
attestationCertificate_ = attestationCertificate;
}
void WritableCredential::setAvailableAuthenticationKeys(int keyCount, int maxUsesPerKey) {
keyCount_ = keyCount;
maxUsesPerKey_ = maxUsesPerKey;
}
ssize_t WritableCredential::calcExpectedProofOfProvisioningSize(
const vector<AccessControlProfileParcel>& accessControlProfiles,
const vector<EntryNamespaceParcel>& entryNamespaces) {
// Right now, we calculate the size by simply just calculating the
// CBOR. There's a little bit of overhead associated with this (as compared
// to just adding up sizes) but it's a lot simpler and robust. In the future
// if this turns out to be a problem, we can optimize it.
//
cppbor::Array acpArray;
for (const AccessControlProfileParcel& profile : accessControlProfiles) {
cppbor::Map map;
map.add("id", profile.id);
if (profile.readerCertificate.size() > 0) {
map.add("readerCertificate", cppbor::Bstr(profile.readerCertificate));
}
if (profile.userAuthenticationRequired) {
map.add("userAuthenticationRequired", profile.userAuthenticationRequired);
map.add("timeoutMillis", profile.userAuthenticationTimeoutMillis);
}
acpArray.add(std::move(map));
}
cppbor::Map dataMap;
for (const EntryNamespaceParcel& ensParcel : entryNamespaces) {
cppbor::Array entriesArray;
for (const EntryParcel& eParcel : ensParcel.entries) {
// TODO: ideally do do this without parsing the data (but still validate data is valid
// CBOR).
auto [itemForValue, _, _2] = cppbor::parse(eParcel.value);
if (itemForValue == nullptr) {
return -1;
}
cppbor::Map entryMap;
entryMap.add("name", eParcel.name);
entryMap.add("value", std::move(itemForValue));
cppbor::Array acpIdsArray;
for (int32_t id : eParcel.accessControlProfileIds) {
acpIdsArray.add(id);
}
entryMap.add("accessControlProfiles", std::move(acpIdsArray));
entriesArray.add(std::move(entryMap));
}
dataMap.add(ensParcel.namespaceName, std::move(entriesArray));
}
cppbor::Array array;
array.add("ProofOfProvisioning");
array.add(docType_);
array.add(std::move(acpArray));
array.add(std::move(dataMap));
array.add(false); // testCredential
return array.encode().size();
}
Status
WritableCredential::personalize(const vector<AccessControlProfileParcel>& accessControlProfiles,
const vector<EntryNamespaceParcel>& entryNamespaces,
int64_t secureUserId, vector<uint8_t>* _aidl_return) {
if (!isUpdate_) {
Status ensureStatus =
ensureAttestationCertificateExists({0x00}); // Challenge cannot be empty.
if (!ensureStatus.isOk()) {
return ensureStatus;
}
}
uid_t callingUid = android::IPCThreadState::self()->getCallingUid();
CredentialData data = CredentialData(dataPath_, callingUid, credentialName_);
// Note: The value 0 is used to convey that no user-authentication is needed for this
// credential. This is to allow creating credentials w/o user authentication on devices
// where Secure lock screen is not enabled.
data.setSecureUserId(secureUserId);
data.setAttestationCertificate(attestationCertificate_);
vector<int32_t> entryCounts;
for (const EntryNamespaceParcel& ensParcel : entryNamespaces) {
entryCounts.push_back(ensParcel.entries.size());
}
ssize_t expectedPoPSize =
calcExpectedProofOfProvisioningSize(accessControlProfiles, entryNamespaces);
if (expectedPoPSize < 0) {
return Status::fromServiceSpecificError(ICredentialStore::ERROR_GENERIC,
"Data is not valid CBOR");
}
// This is not catastrophic, we might be dealing with a version 1 implementation which
// doesn't have this method.
Status status = halBinder_->setExpectedProofOfProvisioningSize(expectedPoPSize);
if (!status.isOk()) {
LOG(INFO) << "Failed setting expected ProofOfProvisioning size, assuming V1 HAL "
<< "and continuing";
}
status = halBinder_->startPersonalization(accessControlProfiles.size(), entryCounts);
if (!status.isOk()) {
return halStatusToGenericError(status);
}
for (const AccessControlProfileParcel& acpParcel : accessControlProfiles) {
Certificate certificate;
certificate.encodedCertificate = acpParcel.readerCertificate;
SecureAccessControlProfile profile;
status = halBinder_->addAccessControlProfile(
acpParcel.id, certificate, acpParcel.userAuthenticationRequired,
acpParcel.userAuthenticationTimeoutMillis, secureUserId, &profile);
if (!status.isOk()) {
return halStatusToGenericError(status);
}
data.addSecureAccessControlProfile(profile);
}
for (const EntryNamespaceParcel& ensParcel : entryNamespaces) {
for (const EntryParcel& eParcel : ensParcel.entries) {
vector<vector<uint8_t>> chunks = chunkVector(eParcel.value, hwInfo_.dataChunkSize);
vector<int32_t> ids;
std::copy(eParcel.accessControlProfileIds.begin(),
eParcel.accessControlProfileIds.end(), std::back_inserter(ids));
status = halBinder_->beginAddEntry(ids, ensParcel.namespaceName, eParcel.name,
eParcel.value.size());
if (!status.isOk()) {
return halStatusToGenericError(status);
}
vector<vector<uint8_t>> encryptedChunks;
for (const auto& chunk : chunks) {
vector<uint8_t> encryptedChunk;
status = halBinder_->addEntryValue(chunk, &encryptedChunk);
if (!status.isOk()) {
return halStatusToGenericError(status);
}
encryptedChunks.push_back(encryptedChunk);
}
EntryData eData;
eData.size = eParcel.value.size();
eData.accessControlProfileIds = std::move(ids);
eData.encryptedChunks = std::move(encryptedChunks);
data.addEntryData(ensParcel.namespaceName, eParcel.name, eData);
}
}
vector<uint8_t> credentialData;
vector<uint8_t> proofOfProvisioningSignature;
status = halBinder_->finishAddingEntries(&credentialData, &proofOfProvisioningSignature);
if (!status.isOk()) {
return halStatusToGenericError(status);
}
data.setCredentialData(credentialData);
data.setAvailableAuthenticationKeys(keyCount_, maxUsesPerKey_);
if (!data.saveToDisk()) {
return Status::fromServiceSpecificError(ICredentialStore::ERROR_GENERIC,
"Error saving credential data to disk");
}
if (credentialToReloadWhenUpdated_) {
credentialToReloadWhenUpdated_->writableCredentialPersonalized();
credentialToReloadWhenUpdated_.clear();
}
*_aidl_return = proofOfProvisioningSignature;
return Status::ok();
}
} // namespace identity
} // namespace security
} // namespace android