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/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/*
* Copyright (c) 2013-2022 Regents of the University of California.
*
* This file is part of ndn-cxx library (NDN C++ library with eXperimental eXtensions).
*
* ndn-cxx library is free software: you can redistribute it and/or modify it under the
* terms of the GNU Lesser General Public License as published by the Free Software
* Foundation, either version 3 of the License, or (at your option) any later version.
*
* ndn-cxx library 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 Lesser General Public License for more details.
*
* You should have received copies of the GNU General Public License and GNU Lesser
* General Public License along with ndn-cxx, e.g., in COPYING.md file. If not, see
* <http://www.gnu.org/licenses/>.
*
* See AUTHORS.md for complete list of ndn-cxx authors and contributors.
*/
#include "ndn-cxx/security/validation-policy-command-interest.hpp"
#include "ndn-cxx/security/interest-signer.hpp"
#include "ndn-cxx/security/validation-policy-accept-all.hpp"
#include "ndn-cxx/security/validation-policy-simple-hierarchy.hpp"
#include "tests/test-common.hpp"
#include "tests/unit/security/validator-fixture.hpp"
#include <boost/mpl/vector.hpp>
namespace ndn {
namespace security {
inline namespace v2 {
namespace tests {
using namespace ndn::tests;
BOOST_AUTO_TEST_SUITE(Security)
struct CommandInterestDefaultOptions
{
static ValidationPolicyCommandInterest::Options
getOptions()
{
return {};
}
};
template<class T, class InnerPolicy>
class CommandInterestPolicyWrapper : public ValidationPolicyCommandInterest
{
public:
CommandInterestPolicyWrapper()
: ValidationPolicyCommandInterest(make_unique<InnerPolicy>(), T::getOptions())
{
}
};
template<class T, class InnerPolicy = ValidationPolicySimpleHierarchy>
class ValidationPolicyCommandInterestFixture
: public HierarchicalValidatorFixture<CommandInterestPolicyWrapper<T, InnerPolicy>>
{
protected:
Interest
makeCommandInterest(const Identity& identity, SignedInterestFormat format = SignedInterestFormat::V02)
{
Name name = identity.getName();
name.append("CMD");
switch (format) {
case SignedInterestFormat::V02:
return m_signer.makeCommandInterest(name, signingByIdentity(identity));
case SignedInterestFormat::V03: {
Interest interest(name);
m_signer.makeSignedInterest(interest, signingByIdentity(identity));
return interest;
}
}
NDN_CXX_UNREACHABLE;
}
protected:
InterestSigner m_signer{this->m_keyChain};
};
BOOST_FIXTURE_TEST_SUITE(TestValidationPolicyCommandInterest,
ValidationPolicyCommandInterestFixture<CommandInterestDefaultOptions>)
template<int secs>
struct GracePeriodSeconds
{
static ValidationPolicyCommandInterest::Options
getOptions()
{
ValidationPolicyCommandInterest::Options options;
options.gracePeriod = time::seconds(secs);
return options;
}
};
BOOST_AUTO_TEST_SUITE(Accepts)
BOOST_AUTO_TEST_CASE(BasicV02)
{
auto i1 = makeCommandInterest(identity, SignedInterestFormat::V02);
VALIDATE_SUCCESS(i1, "Should succeed (within grace period)");
VALIDATE_FAILURE(i1, "Should fail (replay attack)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
advanceClocks(5_ms);
auto i2 = makeCommandInterest(identity, SignedInterestFormat::V02);
VALIDATE_SUCCESS(i2, "Should succeed (timestamp larger than previous)");
auto i3 = m_signer.makeCommandInterest(Name(identity.getName()).append("CMD"), signingWithSha256());
VALIDATE_FAILURE(i3, "Should fail (Sha256 signature violates policy)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
}
BOOST_AUTO_TEST_CASE(BasicV03)
{
auto i1 = makeCommandInterest(identity, SignedInterestFormat::V03);
VALIDATE_SUCCESS(i1, "Should succeed (within grace period)");
VALIDATE_FAILURE(i1, "Should fail (replay attack)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
advanceClocks(5_ms);
auto i2 = makeCommandInterest(identity, SignedInterestFormat::V03);
VALIDATE_SUCCESS(i2, "Should succeed (timestamp larger than previous)");
Interest i3(Name(identity.getName()).append("CMD"));
m_signer.makeSignedInterest(i3, signingWithSha256());
VALIDATE_FAILURE(i3, "Should fail (Sha256 signature violates policy)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
}
BOOST_AUTO_TEST_CASE(DataPassthrough)
{
Data d1("/Security/ValidatorFixture/Sub1");
m_keyChain.sign(d1);
VALIDATE_SUCCESS(d1, "Should succeed (fallback on inner validation policy for data)");
}
using ValidationPolicyAcceptAllCommands = ValidationPolicyCommandInterestFixture<CommandInterestDefaultOptions,
ValidationPolicyAcceptAll>;
BOOST_FIXTURE_TEST_CASE(SignedWithSha256, ValidationPolicyAcceptAllCommands) // Bug 4635
{
auto i1 = m_signer.makeCommandInterest("/hello/world/CMD", signingWithSha256());
VALIDATE_SUCCESS(i1, "Should succeed (within grace period)");
VALIDATE_FAILURE(i1, "Should fail (replay attack)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
advanceClocks(5_ms);
auto i2 = m_signer.makeCommandInterest("/hello/world/CMD", signingWithSha256());
VALIDATE_SUCCESS(i2, "Should succeed (timestamp larger than previous)");
}
BOOST_AUTO_TEST_SUITE_END() // Accepts
BOOST_AUTO_TEST_SUITE(Rejects)
BOOST_AUTO_TEST_CASE(NotSigned)
{
auto i1 = Interest("/short");
BOOST_TEST_REQUIRE(i1.getName().size() < signed_interest::MIN_SIZE);
VALIDATE_FAILURE(i1, "Should fail (not signed / name too short)");
BOOST_TEST(lastError.getCode() == ValidationError::NO_SIGNATURE);
}
BOOST_AUTO_TEST_CASE(BadSigInfo)
{
auto i1 = makeCommandInterest(identity, SignedInterestFormat::V02);
setNameComponent(i1, command_interest::POS_SIG_INFO, "not-SignatureInfo");
BOOST_TEST_REQUIRE(i1.getName().size() >= command_interest::MIN_SIZE);
VALIDATE_FAILURE(i1, "Should fail (signature info is missing)");
BOOST_TEST(lastError.getCode() == ValidationError::NO_SIGNATURE);
}
BOOST_AUTO_TEST_CASE(BadTimestampV02)
{
// i1 is a valid signed interest (in v0.2 format) but is not a valid command interest
auto i1 = Interest("/short");
m_keyChain.sign(i1, signingByIdentity(identity).setSignedInterestFormat(SignedInterestFormat::V02));
BOOST_TEST_REQUIRE((i1.getName().size() >= signed_interest::MIN_SIZE &&
i1.getName().size() < command_interest::MIN_SIZE));
VALIDATE_FAILURE(i1, "Should fail (timestamp is missing)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
auto i2 = makeCommandInterest(identity, SignedInterestFormat::V02);
setNameComponent(i2, command_interest::POS_TIMESTAMP, "not-timestamp");
BOOST_TEST_REQUIRE(i2.getName().size() >= command_interest::MIN_SIZE);
VALIDATE_FAILURE(i2, "Should fail (timestamp is malformed)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
}
BOOST_AUTO_TEST_CASE(BadTimestampV03)
{
auto i1 = makeCommandInterest(identity, SignedInterestFormat::V03);
auto si = i1.getSignatureInfo().value();
si.setTime(nullopt);
i1.setSignatureInfo(si);
VALIDATE_FAILURE(i1, "Should fail (timestamp is missing)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
}
BOOST_AUTO_TEST_CASE(MissingKeyLocatorV02)
{
auto i1 = makeCommandInterest(identity, SignedInterestFormat::V02);
SignatureInfo sigInfo(tlv::SignatureSha256WithRsa);
setNameComponent(i1, command_interest::POS_SIG_INFO,
sigInfo.wireEncode().begin(), sigInfo.wireEncode().end());
VALIDATE_FAILURE(i1, "Should fail (missing KeyLocator)");
BOOST_TEST(lastError.getCode() == ValidationError::INVALID_KEY_LOCATOR);
}
BOOST_AUTO_TEST_CASE(MissingKeyLocatorV03)
{
auto i1 = makeCommandInterest(identity, SignedInterestFormat::V03);
auto si = i1.getSignatureInfo().value();
si.setKeyLocator(nullopt);
i1.setSignatureInfo(si);
VALIDATE_FAILURE(i1, "Should fail (missing KeyLocator)");
BOOST_TEST(lastError.getCode() == ValidationError::INVALID_KEY_LOCATOR);
}
BOOST_AUTO_TEST_CASE(BadKeyLocatorType)
{
auto i1 = makeCommandInterest(identity, SignedInterestFormat::V02);
KeyLocator kl;
kl.setKeyDigest(makeBinaryBlock(tlv::KeyDigest, {0xDD, 0xDD, 0xDD, 0xDD, 0xDD, 0xDD, 0xDD, 0xDD}));
SignatureInfo sigInfo(tlv::SignatureSha256WithRsa, kl);
setNameComponent(i1, command_interest::POS_SIG_INFO,
sigInfo.wireEncode().begin(), sigInfo.wireEncode().end());
VALIDATE_FAILURE(i1, "Should fail (bad KeyLocator type)");
BOOST_TEST(lastError.getCode() == ValidationError::INVALID_KEY_LOCATOR);
}
BOOST_AUTO_TEST_CASE(BadCertName)
{
auto i1 = makeCommandInterest(identity, SignedInterestFormat::V02);
SignatureInfo sigInfo(tlv::SignatureSha256WithEcdsa, KeyLocator("/bad/cert/name"));
setNameComponent(i1, command_interest::POS_SIG_INFO,
sigInfo.wireEncode().begin(), sigInfo.wireEncode().end());
VALIDATE_FAILURE(i1, "Should fail (bad certificate name)");
BOOST_TEST(lastError.getCode() == ValidationError::INVALID_KEY_LOCATOR);
}
BOOST_AUTO_TEST_CASE(InnerPolicyReject)
{
auto i1 = makeCommandInterest(otherIdentity, SignedInterestFormat::V02);
VALIDATE_FAILURE(i1, "Should fail (inner policy should reject)");
BOOST_TEST(lastError.getCode() == ValidationError::LOOP_DETECTED);
auto i2 = makeCommandInterest(otherIdentity, SignedInterestFormat::V03);
VALIDATE_FAILURE(i2, "Should fail (inner policy should reject)");
BOOST_TEST(lastError.getCode() == ValidationError::LOOP_DETECTED);
}
BOOST_FIXTURE_TEST_CASE(TimestampOutOfGracePositive,
ValidationPolicyCommandInterestFixture<GracePeriodSeconds<15>>)
{
auto i1 = makeCommandInterest(identity); // signed at 0s
advanceClocks(16_s); // verifying at +16s
VALIDATE_FAILURE(i1, "Should fail (timestamp outside the grace period)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
rewindClockAfterValidation();
auto i2 = makeCommandInterest(identity); // signed at +16s
VALIDATE_SUCCESS(i2, "Should succeed");
}
BOOST_FIXTURE_TEST_CASE(TimestampOutOfGraceNegative,
ValidationPolicyCommandInterestFixture<GracePeriodSeconds<15>>)
{
auto i1 = makeCommandInterest(identity); // signed at 0s
advanceClocks(1_s);
auto i2 = makeCommandInterest(identity); // signed at +1s
advanceClocks(1_s);
auto i3 = makeCommandInterest(identity); // signed at +2s
m_systemClock->advance(-18_s); // verifying at -16s
VALIDATE_FAILURE(i1, "Should fail (timestamp outside the grace period)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
rewindClockAfterValidation();
// CommandInterestValidator should not remember i1's timestamp
VALIDATE_FAILURE(i2, "Should fail (timestamp outside the grace period)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
rewindClockAfterValidation();
// CommandInterestValidator should not remember i2's timestamp, and should treat i3 as initial
advanceClocks(18_s); // verifying at +2s
VALIDATE_SUCCESS(i3, "Should succeed");
}
BOOST_AUTO_TEST_CASE(TimestampReorderEqual)
{
auto i1 = makeCommandInterest(identity); // signed at 0s
VALIDATE_SUCCESS(i1, "Should succeed");
auto i2 = makeCommandInterest(identity); // signed at 0s
setNameComponent(i2, command_interest::POS_TIMESTAMP, i1.getName()[command_interest::POS_TIMESTAMP]);
VALIDATE_FAILURE(i2, "Should fail (timestamp reordered)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
advanceClocks(2_s);
auto i3 = makeCommandInterest(identity); // signed at +2s
VALIDATE_SUCCESS(i3, "Should succeed");
}
BOOST_AUTO_TEST_CASE(TimestampReorderNegative)
{
auto i2 = makeCommandInterest(identity); // signed at 0ms
advanceClocks(200_ms);
auto i3 = makeCommandInterest(identity); // signed at +200ms
advanceClocks(900_ms);
auto i1 = makeCommandInterest(identity); // signed at +1100ms
advanceClocks(300_ms);
auto i4 = makeCommandInterest(identity); // signed at +1400ms
m_systemClock->advance(-300_ms); // verifying at +1100ms
VALIDATE_SUCCESS(i1, "Should succeed");
rewindClockAfterValidation();
m_systemClock->advance(-1100_ms); // verifying at 0ms
VALIDATE_FAILURE(i2, "Should fail (timestamp reordered)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
rewindClockAfterValidation();
// CommandInterestValidator should not remember i2's timestamp
advanceClocks(200_ms); // verifying at +200ms
VALIDATE_FAILURE(i3, "Should fail (timestamp reordered)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
rewindClockAfterValidation();
advanceClocks(1200_ms); // verifying at 1400ms
VALIDATE_SUCCESS(i4, "Should succeed");
}
BOOST_AUTO_TEST_SUITE_END() // Rejects
BOOST_AUTO_TEST_SUITE(Options)
using NonPositiveGracePeriods = boost::mpl::vector<
GracePeriodSeconds<0>,
GracePeriodSeconds<-1>
>;
BOOST_FIXTURE_TEST_CASE_TEMPLATE(GraceNonPositive, GracePeriod, NonPositiveGracePeriods,
ValidationPolicyCommandInterestFixture<GracePeriod>)
{
auto i1 = this->makeCommandInterest(this->identity); // signed at 0ms
auto i2 = this->makeCommandInterest(this->subIdentity); // signed at 0ms
for (auto interest : {&i1, &i2}) {
setNameComponent(*interest, command_interest::POS_TIMESTAMP,
name::Component::fromNumber(time::toUnixTimestamp(time::system_clock::now()).count()));
} // ensure timestamps are exactly 0ms
VALIDATE_SUCCESS(i1, "Should succeed when validating at 0ms");
this->rewindClockAfterValidation();
this->advanceClocks(1_ms);
VALIDATE_FAILURE(i2, "Should fail when validating at 1ms");
BOOST_TEST(this->lastError.getCode() == ValidationError::POLICY_ERROR);
}
class LimitedRecordsOptions
{
public:
static ValidationPolicyCommandInterest::Options
getOptions()
{
ValidationPolicyCommandInterest::Options options;
options.gracePeriod = 15_s;
options.maxRecords = 3;
return options;
}
};
BOOST_FIXTURE_TEST_CASE(LimitedRecords, ValidationPolicyCommandInterestFixture<LimitedRecordsOptions>)
{
Identity id1 = this->addSubCertificate("/Security/ValidatorFixture/Sub1", identity);
this->cache.insert(id1.getDefaultKey().getDefaultCertificate());
Identity id2 = this->addSubCertificate("/Security/ValidatorFixture/Sub2", identity);
this->cache.insert(id2.getDefaultKey().getDefaultCertificate());
Identity id3 = this->addSubCertificate("/Security/ValidatorFixture/Sub3", identity);
this->cache.insert(id3.getDefaultKey().getDefaultCertificate());
Identity id4 = this->addSubCertificate("/Security/ValidatorFixture/Sub4", identity);
this->cache.insert(id4.getDefaultKey().getDefaultCertificate());
auto i1 = makeCommandInterest(id2);
auto i2 = makeCommandInterest(id3);
auto i3 = makeCommandInterest(id4);
auto i00 = makeCommandInterest(id1); // signed at 0s
advanceClocks(1_s);
auto i01 = makeCommandInterest(id1); // signed at 1s
advanceClocks(1_s);
auto i02 = makeCommandInterest(id1); // signed at 2s
VALIDATE_SUCCESS(i00, "Should succeed");
rewindClockAfterValidation();
VALIDATE_SUCCESS(i02, "Should succeed");
rewindClockAfterValidation();
VALIDATE_SUCCESS(i1, "Should succeed");
rewindClockAfterValidation();
VALIDATE_SUCCESS(i2, "Should succeed");
rewindClockAfterValidation();
VALIDATE_SUCCESS(i3, "Should succeed, forgets identity id1");
rewindClockAfterValidation();
VALIDATE_SUCCESS(i01, "Should succeed despite timestamp is reordered, because record has been evicted");
}
class UnlimitedRecordsOptions
{
public:
static ValidationPolicyCommandInterest::Options
getOptions()
{
ValidationPolicyCommandInterest::Options options;
options.gracePeriod = 15_s;
options.maxRecords = -1;
return options;
}
};
BOOST_FIXTURE_TEST_CASE(UnlimitedRecords, ValidationPolicyCommandInterestFixture<UnlimitedRecordsOptions>)
{
std::vector<Identity> identities;
for (size_t i = 0; i < 20; ++i) {
Identity id = this->addSubCertificate("/Security/ValidatorFixture/Sub" + to_string(i), identity);
this->cache.insert(id.getDefaultKey().getDefaultCertificate());
identities.push_back(id);
}
auto i1 = makeCommandInterest(identities.at(0)); // signed at 0s
advanceClocks(1_s);
for (size_t i = 0; i < 20; ++i) {
auto i2 = makeCommandInterest(identities.at(i)); // signed at +1s
VALIDATE_SUCCESS(i2, "Should succeed");
rewindClockAfterValidation();
}
VALIDATE_FAILURE(i1, "Should fail (timestamp reorder)");
BOOST_TEST(lastError.getCode() == ValidationError::POLICY_ERROR);
}
class ZeroRecordsOptions
{
public:
static ValidationPolicyCommandInterest::Options
getOptions()
{
ValidationPolicyCommandInterest::Options options;
options.gracePeriod = 15_s;
options.maxRecords = 0;
return options;
}
};
BOOST_FIXTURE_TEST_CASE(ZeroRecords, ValidationPolicyCommandInterestFixture<ZeroRecordsOptions>)
{
auto i1 = makeCommandInterest(identity); // signed at 0s
advanceClocks(1_s);
auto i2 = makeCommandInterest(identity); // signed at +1s
VALIDATE_SUCCESS(i2, "Should succeed");
rewindClockAfterValidation();
VALIDATE_SUCCESS(i1, "Should succeed despite timestamp is reordered, because record isn't kept");
}
class LimitedRecordLifetimeOptions
{
public:
static ValidationPolicyCommandInterest::Options
getOptions()
{
ValidationPolicyCommandInterest::Options options;
options.gracePeriod = 400_s;
options.recordLifetime = 300_s;
return options;
}
};
BOOST_FIXTURE_TEST_CASE(LimitedRecordLifetime, ValidationPolicyCommandInterestFixture<LimitedRecordLifetimeOptions>)
{
auto i1 = makeCommandInterest(identity); // signed at 0s
advanceClocks(240_s);
auto i2 = makeCommandInterest(identity); // signed at +240s
advanceClocks(120_s);
auto i3 = makeCommandInterest(identity); // signed at +360s
m_systemClock->advance(-360_s); // rewind system clock to 0s
VALIDATE_SUCCESS(i1, "Should succeed");
rewindClockAfterValidation();
VALIDATE_SUCCESS(i3, "Should succeed");
rewindClockAfterValidation();
advanceClocks(30_s, 301_s); // advance steady clock by 301s, and system clock to +301s
VALIDATE_SUCCESS(i2, "Should succeed despite timestamp is reordered, because record has been expired");
}
class ZeroRecordLifetimeOptions
{
public:
static ValidationPolicyCommandInterest::Options
getOptions()
{
ValidationPolicyCommandInterest::Options options;
options.gracePeriod = 15_s;
options.recordLifetime = time::seconds::zero();
return options;
}
};
BOOST_FIXTURE_TEST_CASE(ZeroRecordLifetime, ValidationPolicyCommandInterestFixture<ZeroRecordLifetimeOptions>)
{
auto i1 = makeCommandInterest(identity); // signed at 0s
advanceClocks(1_s);
auto i2 = makeCommandInterest(identity); // signed at +1s
VALIDATE_SUCCESS(i2, "Should succeed");
rewindClockAfterValidation();
VALIDATE_SUCCESS(i1, "Should succeed despite timestamp is reordered, because record has been expired");
}
BOOST_AUTO_TEST_SUITE_END() // Options
BOOST_AUTO_TEST_SUITE_END() // TestValidationPolicyCommandInterest
BOOST_AUTO_TEST_SUITE_END() // Security
} // namespace tests
} // inline namespace v2
} // namespace security
} // namespace ndn