Gitiles
Code Review Sign In
gerrit.named-data.net / NFD / a1939ba99397651be8cd03ed24c86661c655f7e6 / . / tests / rib / auto-prefix-propagator.t.cpp
blob: 67e7b1b67fde64a25658d725ca290bfa9c334570 [file] [log] [blame]
/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/**
* Copyright (c) 2014-2015, Regents of the University of California,
* Arizona Board of Regents,
* Colorado State University,
* University Pierre & Marie Curie, Sorbonne University,
* Washington University in St. Louis,
* Beijing Institute of Technology,
* The University of Memphis.
*
* This file is part of NFD (Named Data Networking Forwarding Daemon).
* See AUTHORS.md for complete list of NFD authors and contributors.
*
* NFD is free software: you can redistribute it and/or modify it under the terms
* of the GNU General Public License as published by the Free Software Foundation,
* either version 3 of the License, or (at your option) any later version.
*
* NFD 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License along with
* NFD, e.g., in COPYING.md file. If not, see <http://www.gnu.org/licenses/>.
*/
#include "rib/auto-prefix-propagator.hpp"
#include "tests/test-common.hpp"
#include "tests/identity-management-fixture.hpp"
#include <ndn-cxx/util/dummy-client-face.hpp>
namespace nfd {
namespace rib {
namespace tests {
NFD_LOG_INIT("AutoPrefixPropagatorTest");
const Name TEST_LINK_LOCAL_NFD_PREFIX("/localhop/nfd");
const time::milliseconds TEST_PREFIX_PROPAGATION_TIMEOUT(1000);
class AutoPrefixPropagatorFixture : public nfd::tests::IdentityManagementFixture
, public nfd::tests::UnitTestTimeFixture
{
public:
AutoPrefixPropagatorFixture()
: m_face(ndn::util::makeDummyClientFace(nfd::tests::UnitTestTimeFixture::g_io, {true, true}))
, m_controller(*m_face, m_keyChain)
, m_propagator(m_controller, m_keyChain, m_rib)
, m_requests(m_face->sentInterests)
, m_entries(m_propagator.m_propagatedEntries)
{
m_propagator.enable();
m_propagator.m_controlParameters
.setCost(15)
.setOrigin(ndn::nfd::ROUTE_ORIGIN_CLIENT)// set origin to client.
.setFaceId(0);// the remote hub will take the input face as the faceId.
m_propagator.m_commandOptions
.setPrefix(TEST_LINK_LOCAL_NFD_PREFIX)
.setTimeout(TEST_PREFIX_PROPAGATION_TIMEOUT);
}
public: // helpers for test
bool
insertEntryToRib(const Name& name, const uint64_t& faceId = 0)
{
if (m_rib.find(name) != m_rib.end()) {
NFD_LOG_INFO("RIB entry already exists: " << name);
return false;
}
Route route;
route.faceId = faceId;
m_rib.insert(name, route);
advanceClocks(time::milliseconds(1));
return m_rib.find(name) != m_rib.end(); // return whether afterInserEntry will be triggered
}
bool
eraseEntryFromRib(const Name& name)
{
if (m_rib.find(name) == m_rib.end()) {
NFD_LOG_INFO("RIB entry does not exist: " << name);
return false;
}
std::vector<Route> routeList;
std::copy(m_rib.find(name)->second->begin(), m_rib.find(name)->second->end(),
std::back_inserter(routeList));
for (auto&& route : routeList) {
m_rib.erase(name, route);
}
advanceClocks(time::milliseconds(1));
return m_rib.find(name) == m_rib.end(); // return whether afterEraseEntry will be triggered
}
void
connectToHub()
{
insertEntryToRib("/localhop/nfd");
}
void
disconnectFromHub()
{
eraseEntryFromRib("/localhop/nfd");
}
public: // helpers for check
enum class CheckRequestResult {
OK,
OUT_OF_BOUNDARY,
INVALID_N_COMPONENTS,
WRONG_COMMAND_PREFIX,
WRONG_VERB,
INVALID_PARAMETERS,
WRONG_REGISTERING_PREFIX
};
/**
* @brief check a request at specified index
*
* @param idx the index of the specified request in m_requests
* @param verb the expected verb of request
* @param registeringPrefix the expected registering prefix of request
* @retval OK the specified request has a valid name, the right verb, a valid ControlParameters
* and the right registering prefix
* @retval OUT_OF_BOUNDARY the specified index out of boundary
* @retval INVALID_N_COMPONENTS the number of components of the request name is invalid
* @retval WRONG_COMMAND_PREFIX the command prefix of the request is wrong
* @retval WRONG_VERB the command verb of the request is wrong
* @retval INVALID_PARAMETERS no valid parameters can be decoded from the request's name
* @retval WRONG_REGISTERING_PREFIX the registering prefix of the request is wrong
*/
CheckRequestResult
checkRequest(size_t idx, const std::string& verb, const Name& registeringPrefix)
{
Name requestName;
try {
requestName = m_requests.at(idx).getName();
}
catch (const std::out_of_range&) {
return CheckRequestResult::OUT_OF_BOUNDARY;
}
if (requestName.size() < 5) {
return CheckRequestResult::INVALID_N_COMPONENTS;
}
if (requestName.getPrefix(2) != TEST_LINK_LOCAL_NFD_PREFIX) {
return CheckRequestResult::WRONG_COMMAND_PREFIX;
}
if (requestName.get(3) != Name::Component(verb)) {
return CheckRequestResult::WRONG_VERB;
}
ControlParameters parameters;
try {
parameters.wireDecode(requestName.get(4).blockFromValue());
}
catch (const tlv::Error&) {
return CheckRequestResult::INVALID_PARAMETERS;
}
if (parameters.getName() != registeringPrefix) {
return CheckRequestResult::WRONG_REGISTERING_PREFIX;
}
return CheckRequestResult::OK;
}
protected:
shared_ptr<ndn::util::DummyClientFace> m_face;
ndn::nfd::Controller m_controller;
Rib m_rib;
AutoPrefixPropagator m_propagator;
std::vector<Interest>& m_requests; // store sent out requests
AutoPrefixPropagator::PropagatedEntryList& m_entries; // store propagated entries
};
std::ostream&
operator<<(std::ostream &os, const AutoPrefixPropagatorFixture::CheckRequestResult& result)
{
switch (result) {
case AutoPrefixPropagatorFixture::CheckRequestResult::OK:
os << "OK";
break;
case AutoPrefixPropagatorFixture::CheckRequestResult::OUT_OF_BOUNDARY:
os << "OUT_OF_BOUNDARY";
break;
case AutoPrefixPropagatorFixture::CheckRequestResult::INVALID_N_COMPONENTS:
os << "INVALID_N_COMPONENTS";
break;
case AutoPrefixPropagatorFixture::CheckRequestResult::WRONG_COMMAND_PREFIX:
os << "WRONG_COMMAND_PREFIX";
break;
case AutoPrefixPropagatorFixture::CheckRequestResult::WRONG_VERB:
os << "WRONG_VERB";
break;
case AutoPrefixPropagatorFixture::CheckRequestResult::INVALID_PARAMETERS:
os << "INVALID_PARAMETERS";
break;
case AutoPrefixPropagatorFixture::CheckRequestResult::WRONG_REGISTERING_PREFIX:
os << "WRONG_REGISTERING_PREFIX";
break;
default:
break;
}
return os;
}
BOOST_AUTO_TEST_SUITE(Rib)
BOOST_FIXTURE_TEST_SUITE(TestAutoPrefixPropagator, AutoPrefixPropagatorFixture)
BOOST_AUTO_TEST_CASE(EnableDisable)
{
connectToHub();
BOOST_REQUIRE(addIdentity("/test/A"));
auto testPropagateRevokeBasic = [this] () -> bool {
m_propagator.m_propagatedEntries.clear();
if (!insertEntryToRib("/test/A/app")) {
return false;
}
m_entries["/test/A"].succeed(nullptr);
if (!eraseEntryFromRib("/test/A/app")) {
return false;
}
return true;
};
m_propagator.disable();
BOOST_REQUIRE(testPropagateRevokeBasic());
BOOST_CHECK(m_requests.empty());
m_propagator.enable();
BOOST_REQUIRE(testPropagateRevokeBasic());
BOOST_REQUIRE_EQUAL(m_requests.size(), 2);
BOOST_CHECK_EQUAL(checkRequest(0, "register", "/test/A"), CheckRequestResult::OK);
BOOST_CHECK_EQUAL(checkRequest(1, "unregister", "/test/A"), CheckRequestResult::OK);
}
BOOST_AUTO_TEST_CASE(LoadConfiguration)
{
ConfigFile config;
config.addSectionHandler("auto_prefix_propagate",
bind(&AutoPrefixPropagator::loadConfig, &m_propagator, _1));
const std::string CONFIG_STRING =
"auto_prefix_propagate\n"
"{\n"
" cost 11\n"
" timeout 22\n"
" refresh_interval 33\n"
" base_retry_wait 44\n"
" max_retry_wait 55\n"
"}";
config.parse(CONFIG_STRING, true, "test-auto-prefix-propagator");
BOOST_CHECK_EQUAL(m_propagator.m_controlParameters.getCost(), 11);
BOOST_CHECK_EQUAL(m_propagator.m_controlParameters.getOrigin(), ndn::nfd::ROUTE_ORIGIN_CLIENT);
BOOST_CHECK_EQUAL(m_propagator.m_controlParameters.getFaceId(), 0);
BOOST_CHECK_EQUAL(m_propagator.m_commandOptions.getPrefix(), TEST_LINK_LOCAL_NFD_PREFIX);
BOOST_CHECK_EQUAL(m_propagator.m_commandOptions.getTimeout(), time::milliseconds(22));
BOOST_CHECK_EQUAL(m_propagator.m_refreshInterval, time::seconds(33));
BOOST_CHECK_EQUAL(m_propagator.m_baseRetryWait, time::seconds(44));
BOOST_CHECK_EQUAL(m_propagator.m_maxRetryWait, time::seconds(55));
}
BOOST_AUTO_TEST_SUITE(Helpers)
BOOST_AUTO_TEST_CASE(GetPrefixPropagationParameters)
{
BOOST_REQUIRE(addIdentity("/test/A"));
BOOST_REQUIRE(addIdentity("/test/A/B"));
BOOST_REQUIRE(addIdentity("/test/C/nrd"));
auto parameters1 = m_propagator.getPrefixPropagationParameters("/none/A/B/app");
auto parameters2 = m_propagator.getPrefixPropagationParameters("/test/A/B/app");
auto parameters3 = m_propagator.getPrefixPropagationParameters("/test/C/D/app");
BOOST_CHECK(!parameters1.isValid);
BOOST_CHECK(parameters2.isValid);
BOOST_CHECK_EQUAL(parameters2.parameters.getName(), "/test/A");
BOOST_CHECK_EQUAL(parameters2.options.getSigningInfo().getSignerName(), "/test/A");
BOOST_CHECK(parameters3.isValid);
BOOST_CHECK_EQUAL(parameters3.parameters.getName(), "/test/C");
BOOST_CHECK_EQUAL(parameters3.options.getSigningInfo().getSignerName(), "/test/C/nrd");
}
BOOST_AUTO_TEST_CASE(CheckCurrentPropagatedPrefix)
{
BOOST_REQUIRE(addIdentity("/test/A"));
BOOST_REQUIRE(addIdentity("/test/B/nrd"));
BOOST_REQUIRE(addIdentity("/test/A/B"));
BOOST_CHECK(!m_propagator.doesCurrentPropagatedPrefixWork("/test/E")); // does not exist
BOOST_CHECK(!m_propagator.doesCurrentPropagatedPrefixWork("/test/A/B")); // has a better option
BOOST_CHECK(m_propagator.doesCurrentPropagatedPrefixWork("/test/A"));
BOOST_CHECK(m_propagator.doesCurrentPropagatedPrefixWork("/test/B"));
}
BOOST_AUTO_TEST_CASE(RedoPropagation)
{
connectToHub();
BOOST_REQUIRE(addIdentity("/test/A"));
BOOST_REQUIRE(addIdentity("/test/B"));
BOOST_REQUIRE(addIdentity("/test/B/C"));
BOOST_REQUIRE(insertEntryToRib("/test/A/app"));
BOOST_REQUIRE(insertEntryToRib("/test/B/C/app"));
BOOST_REQUIRE(insertEntryToRib("/test/B/D/app"));
auto testRedoPropagation = [this] (const Name& signingIdentity) {
m_requests.clear();
m_entries[signingIdentity].setSigningIdentity(signingIdentity);
auto parameters = m_propagator.m_controlParameters;
auto options = m_propagator.m_commandOptions;
ndn::security::SigningInfo info(ndn::security::SigningInfo::SIGNER_TYPE_ID, signingIdentity);
m_propagator.redoPropagation(m_entries.find(signingIdentity),
parameters.setName(signingIdentity),
options.setSigningInfo(info),
time::seconds(0));
advanceClocks(time::milliseconds(1));
};
testRedoPropagation("/test/A"); // current propagated prefix still works
BOOST_REQUIRE_EQUAL(m_requests.size(), 1);
BOOST_CHECK_EQUAL(checkRequest(0, "register", "/test/A"), CheckRequestResult::OK);
BOOST_CHECK(m_entries.find("test/A") != m_entries.end());
BOOST_CHECK_NO_THROW(m_keyChain.deleteIdentity("/test/B"));
testRedoPropagation("/test/B"); // signingIdentity no longer exists
BOOST_REQUIRE_EQUAL(m_requests.size(), 1);
BOOST_CHECK_EQUAL(checkRequest(0, "register", "/test/B/C"), CheckRequestResult::OK);
BOOST_CHECK(m_entries.find("/test/B") == m_entries.end());
BOOST_CHECK(m_entries.find("/test/B/C") != m_entries.end());
testRedoPropagation("/test/B"); // no alternative identity
BOOST_CHECK(m_requests.empty());
BOOST_CHECK(m_entries.find("/test/B") == m_entries.end());
m_entries["/test/B/C"].succeed(nullptr);
testRedoPropagation("/test/B"); // alternative identity has been propagated
BOOST_CHECK(m_requests.empty());
BOOST_CHECK(m_entries.find("/test/B") == m_entries.end());
BOOST_REQUIRE(addIdentity("/test/B/"));
testRedoPropagation("/test/B/C"); // better option exists: /test/B
BOOST_REQUIRE_EQUAL(m_requests.size(), 1);
BOOST_CHECK_EQUAL(checkRequest(0, "register", "/test/B"), CheckRequestResult::OK);
BOOST_CHECK(m_entries.find("test/B/C") == m_entries.end());
}
BOOST_AUTO_TEST_SUITE_END() // Helpers
BOOST_AUTO_TEST_SUITE(PropagateRevokeSemantics)
BOOST_AUTO_TEST_CASE(Basic)
{
connectToHub(); // ensure connectivity to the hub
BOOST_REQUIRE(addIdentity("/test/A"));
BOOST_REQUIRE(insertEntryToRib("/test/A/app")); // ensure afterInsertEntry signal emitted
m_entries["/test/A"].succeed(nullptr); // ensure there is a valid entry inserted
BOOST_REQUIRE(eraseEntryFromRib("/test/A/app")); // ensure afterEraseEntry signal emitted
BOOST_REQUIRE_EQUAL(m_requests.size(), 2);
BOOST_CHECK_EQUAL(checkRequest(0, "register", "/test/A"), CheckRequestResult::OK);
BOOST_CHECK_EQUAL(checkRequest(1, "unregister", "/test/A"), CheckRequestResult::OK);
}
BOOST_AUTO_TEST_CASE(LocalPrefix)
{
connectToHub();
BOOST_REQUIRE(addIdentity("/localhost/A"));
BOOST_REQUIRE(insertEntryToRib("/localhost/A/app"));
BOOST_CHECK(m_requests.empty());
m_propagator.m_propagatedEntries["/localhost/A"].succeed(nullptr);
BOOST_REQUIRE(eraseEntryFromRib("/localhost/A/app"));
BOOST_CHECK(m_requests.empty());
}
BOOST_AUTO_TEST_CASE(InvalidPropagationParameters)
{
connectToHub();
// no identity can be found
BOOST_CHECK(!m_propagator.getPrefixPropagationParameters("/test/A/app").isValid);
BOOST_REQUIRE(insertEntryToRib("/test/A/app"));
BOOST_CHECK(m_requests.empty());
m_entries["/test/A"].succeed(nullptr);
BOOST_REQUIRE(eraseEntryFromRib("/test/A/app"));
BOOST_CHECK(m_requests.empty());
}
BOOST_AUTO_TEST_CASE(NoHubConnectivity)
{
BOOST_REQUIRE(addIdentity("/test/A"));
BOOST_REQUIRE(insertEntryToRib("/test/A/app"));
BOOST_CHECK(m_requests.empty());
m_entries["/test/A"].succeed(nullptr);
BOOST_REQUIRE(eraseEntryFromRib("/test/A/app"));
BOOST_CHECK(m_requests.empty());
}
BOOST_AUTO_TEST_CASE(PropagatedEntryExists)
{
connectToHub();
BOOST_REQUIRE(addIdentity("/test/A"));
BOOST_REQUIRE(insertEntryToRib("/test/A/app1"));
m_requests.clear();
BOOST_REQUIRE(insertEntryToRib("/test/A/app2")); // /test/A has been propagated by /test/A/app1
BOOST_CHECK(m_requests.empty());
}
BOOST_AUTO_TEST_CASE(PropagatedEntryShouldKeep)
{
connectToHub();
BOOST_REQUIRE(addIdentity("/test/A"));
BOOST_REQUIRE(insertEntryToRib("/test/A/app1"));
BOOST_REQUIRE(insertEntryToRib("/test/A/app2"));
m_requests.clear();
BOOST_REQUIRE(eraseEntryFromRib("/test/A/app2")); // /test/A should be kept for /test/A/app1
BOOST_CHECK(m_requests.empty());
}
BOOST_AUTO_TEST_CASE(BackOffRetryPolicy)
{
m_propagator.m_commandOptions.setTimeout(time::milliseconds(1));
m_propagator.m_baseRetryWait = time::seconds(1);
m_propagator.m_maxRetryWait = time::seconds(2);
connectToHub();
BOOST_REQUIRE(addIdentity("/test/A"));
BOOST_REQUIRE(insertEntryToRib("/test/A/app"));
BOOST_REQUIRE_EQUAL(m_requests.size(), 1);
BOOST_CHECK_EQUAL(checkRequest(0, "register", "/test/A"), CheckRequestResult::OK);
advanceClocks(time::milliseconds(1), 1050); // wait for the 1st retry
BOOST_REQUIRE_EQUAL(m_requests.size(), 2);
BOOST_CHECK_EQUAL(checkRequest(1, "register", "/test/A"), CheckRequestResult::OK);
advanceClocks(time::milliseconds(1), 2050); // wait for the 2nd retry, 2 times
BOOST_REQUIRE_EQUAL(m_requests.size(), 3);
BOOST_CHECK_EQUAL(checkRequest(2, "register", "/test/A"), CheckRequestResult::OK);
advanceClocks(time::milliseconds(1), 2050); // wait for the 3rd retry, reach the upper bound
BOOST_REQUIRE_EQUAL(m_requests.size(), 4);
BOOST_CHECK_EQUAL(checkRequest(3, "register", "/test/A"), CheckRequestResult::OK);
}
BOOST_AUTO_TEST_SUITE_END() // PropagateRevokeSemantics
BOOST_AUTO_TEST_SUITE(PropagatedEntryStateChanges)
BOOST_AUTO_TEST_CASE(AfterRibInsert)
{
BOOST_REQUIRE(addIdentity("/test/A"));
auto testAfterRibInsert = [this] (const Name& ribEntryPrefix) {
m_requests.clear();
m_propagator.m_propagatedEntries.clear(); // ensure entry does not exist
auto propagateParameters = m_propagator.getPrefixPropagationParameters(ribEntryPrefix);
m_propagator.afterRibInsert(propagateParameters.parameters, propagateParameters.options);
advanceClocks(time::milliseconds(1));
};
testAfterRibInsert("/test/A/app1");
BOOST_CHECK(m_requests.empty()); // no connectivity now
BOOST_CHECK(m_entries.find("/test/A") != m_entries.end());
connectToHub();
testAfterRibInsert("/test/A/app2");
BOOST_REQUIRE_EQUAL(m_requests.size(), 1);
BOOST_CHECK_EQUAL(checkRequest(0, "register", "/test/A"), CheckRequestResult::OK);
BOOST_CHECK(m_entries.find("/test/A") != m_entries.end());
}
BOOST_AUTO_TEST_CASE(AfterRibErase)
{
BOOST_REQUIRE(addIdentity("/test/A"));
auto testAfterRibInsert = [this] (const Name& localUnregPrefix) {
m_requests.clear();
auto propagateParameters = m_propagator.getPrefixPropagationParameters(localUnregPrefix);
m_propagator.afterRibErase(propagateParameters.parameters.unsetCost(),
propagateParameters.options);
advanceClocks(time::milliseconds(1));
};
m_entries["/test/A"].succeed(nullptr);
testAfterRibInsert("/test/A/app");
BOOST_CHECK(m_requests.empty()); // no connectivity
BOOST_CHECK(m_entries.find("/test/A") == m_entries.end()); // has been erased
connectToHub();
m_entries["/test/A"].fail(nullptr);
testAfterRibInsert("/test/A/app");
BOOST_CHECK(m_requests.empty()); // previous propagation has not succeeded
BOOST_CHECK(m_entries.find("/test/A") == m_entries.end()); // has been erased
m_entries["/test/A"].succeed(nullptr);
testAfterRibInsert("/test/A/app");
BOOST_REQUIRE_EQUAL(m_requests.size(), 1);
BOOST_CHECK_EQUAL(checkRequest(0, "unregister", "/test/A"), CheckRequestResult::OK);
BOOST_CHECK(m_entries.find("/test/A") == m_entries.end()); // has been erased
}
BOOST_AUTO_TEST_CASE(AfterHubConnectDisconnect)
{
BOOST_REQUIRE(addIdentity("/test/A"));
BOOST_REQUIRE(addIdentity("/test/B"));
BOOST_REQUIRE(addIdentity("/test/C"));
BOOST_REQUIRE(insertEntryToRib("/test/A/app"));
BOOST_REQUIRE(insertEntryToRib("/test/B/app"));
// recorder the prefixes that will be propagated in order
std::vector<Name> propagatedPrefixes;
BOOST_CHECK(m_requests.empty()); // no request because there is no connectivity to the hub now
BOOST_REQUIRE_EQUAL(m_entries.size(), 2); // valid entries will be kept
connectToHub(); // 2 cached entries will be processed
for (auto&& entry : m_entries) {
propagatedPrefixes.push_back(entry.first);
}
BOOST_REQUIRE(insertEntryToRib("/test/C/app")); // will be processed directly
propagatedPrefixes.push_back("/test/C");
BOOST_REQUIRE_EQUAL(m_entries.size(), 3);
BOOST_REQUIRE(m_entries["/test/A"].isPropagating());
BOOST_REQUIRE(m_entries["/test/B"].isPropagating());
BOOST_REQUIRE(m_entries["/test/C"].isPropagating());
disconnectFromHub(); // all 3 entries are initialized
BOOST_CHECK(m_entries["/test/A"].isNew());
BOOST_CHECK(m_entries["/test/B"].isNew());
BOOST_CHECK(m_entries["/test/C"].isNew());
connectToHub(); // all 3 entries will be processed
for (auto&& entry : m_entries) {
propagatedPrefixes.push_back(entry.first);
}
BOOST_REQUIRE_EQUAL(m_requests.size(), 6);
BOOST_REQUIRE_EQUAL(propagatedPrefixes.size(), 6);
BOOST_CHECK_EQUAL(checkRequest(0, "register", propagatedPrefixes[0]), CheckRequestResult::OK);
BOOST_CHECK_EQUAL(checkRequest(1, "register", propagatedPrefixes[1]), CheckRequestResult::OK);
BOOST_CHECK_EQUAL(checkRequest(2, "register", propagatedPrefixes[2]), CheckRequestResult::OK);
BOOST_CHECK_EQUAL(checkRequest(3, "register", propagatedPrefixes[3]), CheckRequestResult::OK);
BOOST_CHECK_EQUAL(checkRequest(4, "register", propagatedPrefixes[4]), CheckRequestResult::OK);
BOOST_CHECK_EQUAL(checkRequest(5, "register", propagatedPrefixes[5]), CheckRequestResult::OK);
}
BOOST_AUTO_TEST_CASE(AfterPropagateSucceed)
{
bool wasRefreshEventTriggered = false;
auto testAfterPropagateSucceed = [&] (const Name& ribEntryPrefix) {
m_requests.clear();
wasRefreshEventTriggered = false;
auto propagateParameters = m_propagator.getPrefixPropagationParameters(ribEntryPrefix);
m_propagator.afterPropagateSucceed(propagateParameters.parameters, propagateParameters.options,
[&]{ wasRefreshEventTriggered = true; });
advanceClocks(time::milliseconds(1));
};
BOOST_REQUIRE(addIdentity("/test/A"));
m_propagator.m_refreshInterval = time::seconds(0); // event will be executed at once
m_entries["/test/A"].startPropagation(); // set to be in PROPAGATING state
testAfterPropagateSucceed("/test/A/app"); // will trigger refresh event
BOOST_CHECK(wasRefreshEventTriggered);
BOOST_CHECK(m_requests.empty());
m_entries.erase(m_entries.find("/test/A")); // set to be in RELEASED state
testAfterPropagateSucceed("/test/A/app"); // will call startRevocation
BOOST_CHECK(!wasRefreshEventTriggered);
BOOST_REQUIRE_EQUAL(m_requests.size(), 1);
BOOST_CHECK_EQUAL(checkRequest(0, "unregister", "/test/A"), CheckRequestResult::OK);
}
BOOST_AUTO_TEST_CASE(AfterPropagateFail)
{
bool wasRetryEventTriggered = false;
auto testAfterPropagateFail = [&] (const Name& ribEntryPrefix) {
m_requests.clear();
wasRetryEventTriggered = false;
auto propagateParameters = m_propagator.getPrefixPropagationParameters(ribEntryPrefix);
m_propagator.afterPropagateFail(400, "test", propagateParameters.parameters, propagateParameters.options,
time::seconds(0), [&]{ wasRetryEventTriggered = true; });
advanceClocks(time::milliseconds(1));
};
BOOST_REQUIRE(addIdentity("/test/A"));
m_entries["/test/A"].startPropagation(); // set to be in PROPAGATING state
testAfterPropagateFail("/test/A/app"); // will trigger retry event
BOOST_CHECK(wasRetryEventTriggered);
BOOST_CHECK(m_requests.empty());
m_entries.erase(m_entries.find("/test/A")); // set to be in RELEASED state
testAfterPropagateFail("/test/A/app"); // will do nothing
BOOST_CHECK(!wasRetryEventTriggered);
BOOST_CHECK(m_requests.empty());
}
BOOST_AUTO_TEST_CASE(AfterRevokeSucceed)
{
auto testAfterRevokeSucceed = [&] (const Name& ribEntryPrefix) {
m_requests.clear();
auto propagateParameters = m_propagator.getPrefixPropagationParameters(ribEntryPrefix);
m_propagator.afterRevokeSucceed(propagateParameters.parameters,
propagateParameters.options,
time::seconds(0));
advanceClocks(time::milliseconds(1));
};
BOOST_REQUIRE(addIdentity("/test/A"));
testAfterRevokeSucceed("/test/A/app"); // in RELEASED state
BOOST_CHECK(m_requests.empty());
m_entries["/test/A"].fail(nullptr); // in PROPAGATE_FAIL state
testAfterRevokeSucceed("/test/A/app");
BOOST_CHECK(m_requests.empty());
m_entries["/test/A"].succeed(nullptr); // in PROPAGATED state
testAfterRevokeSucceed("/test/A/app");
BOOST_REQUIRE_EQUAL(m_requests.size(), 1);
BOOST_CHECK_EQUAL(checkRequest(0, "register", "/test/A"), CheckRequestResult::OK);
m_entries["/test/A"].startPropagation(); // in PROPAGATING state
testAfterRevokeSucceed("/test/A/app");
BOOST_REQUIRE_EQUAL(m_requests.size(), 1);
BOOST_CHECK_EQUAL(checkRequest(0, "register", "/test/A"), CheckRequestResult::OK);
}
BOOST_AUTO_TEST_SUITE_END() // PropagatedEntryStateChanges
BOOST_AUTO_TEST_SUITE_END() // TestAutoPrefixPropagator
BOOST_AUTO_TEST_SUITE_END() // Rib
} // namespace tests
} // namespace rib
} // namespace nfd