blob: 75a26ad5068618de918c839ab7f8b6e185d2474f [file] [log] [blame]
/*
* Copyright 2018-present Open Networking Foundation
* 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 "gtest/gtest.h"
#include "Queue.h"
#include "bal_mocker.h"
#include "core.h"
#include "core_data.h"
#include "server.h"
#include <future>
#include <fstream>
#include "trx_eeprom_reader.h"
using namespace testing;
using namespace std;
class TestOltEnable : public Test {
protected:
virtual void SetUp() {
}
virtual void TearDown() {
// Code here will be called immediately after each test
// (right before the destructor).
}
};
// This is used to set custom bcmolt_cfg value to bcmolt_cfg pointer coming in
// bcmolt_cfg_get__bal_state_stub.
ACTION_P(SetArg1ToBcmOltCfg, value) { *static_cast<bcmolt_olt_cfg*>(arg1) = value; };
// This is used to set custom bcmolt_onu_cfg value to bcmolt_onu_cfg pointer coming in
// bcmolt_cfg_get__onu_state_stub.
ACTION_P(SetArg1ToBcmOltOnuCfg, value) { *static_cast<bcmolt_onu_cfg*>(arg1) = value; };
// This is used to set custom bcmolt_tm_sched_cfg value to bcmolt_tm_sched_cfg pointer coming in
// bcmolt_cfg_get__tm_sched_stub.
ACTION_P(SetArg1ToBcmOltTmSchedCfg, value) { *static_cast<bcmolt_tm_sched_cfg*>(arg1) = value; };
// This is used to set custom bcmolt_pon_interface_cfg value to bcmolt_pon_interface_cfg pointer coming in
// bcmolt_cfg_get__pon_intf_stub.
ACTION_P(SetArg1ToBcmOltPonCfg, value) { *static_cast<bcmolt_pon_interface_cfg*>(arg1) = value; };
// This is used to set custom bcmolt_nni_interface_cfg value to bcmolt_nni_interface_cfg pointer coming in
// bcmolt_cfg_get__nni_intf_stub.
ACTION_P(SetArg1ToBcmOltNniCfg, value) { *static_cast<bcmolt_nni_interface_cfg*>(arg1) = value; };
// This is used to set custom bcmolt_flow_cfg value to bcmolt_flow_cfg pointer coming in
// bcmolt_cfg_get__flow_stub.
ACTION_P(SetArg1ToBcmOltFlowCfg, value) { *static_cast<bcmolt_flow_cfg*>(arg1) = value; };
// Create a mock function for bcmolt_cfg_get__bal_state_stub C++ function
MOCK_GLOBAL_FUNC2(bcmolt_cfg_get__bal_state_stub, bcmos_errno(bcmolt_oltid, void*));
MOCK_GLOBAL_FUNC2(bcmolt_cfg_get__onu_state_stub, bcmos_errno(bcmolt_oltid, void*));
MOCK_GLOBAL_FUNC2(bcmolt_cfg_get__tm_sched_stub, bcmos_errno(bcmolt_oltid, void*));
MOCK_GLOBAL_FUNC2(bcmolt_cfg_get__pon_intf_stub, bcmos_errno(bcmolt_oltid, void*));
MOCK_GLOBAL_FUNC2(bcmolt_cfg_get__nni_intf_stub, bcmos_errno(bcmolt_oltid, void*));
MOCK_GLOBAL_FUNC2(bcmolt_cfg_get__flow_stub, bcmos_errno(bcmolt_oltid, void*));
// Test Fixture for OltEnable
// Test 1: OltEnableSuccess case
TEST_F(TestOltEnable, OltEnableSuccess){
// NiceMock is used to suppress 'WillByDefault' return errors.
// This is described in https://github.com/arangodb-helper/gtest/blob/master/googlemock/docs/CookBook.md
NiceMock<BalMocker> balMock;
bcmos_errno host_init_res = BCM_ERR_OK;
bcmos_errno bal_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno bal_cfg_get_res = BCM_ERR_NOT_CONNECTED;
bcmos_errno olt_oper_res = BCM_ERR_OK;
bcmolt_olt_cfg olt_cfg = { };
bcmolt_olt_key olt_key = { };
BCMOLT_CFG_INIT(&olt_cfg, olt, olt_key);
olt_cfg.data.bal_state = BCMOLT_BAL_STATE_BAL_AND_SWITCH_READY;
Status olt_enable_res;
ON_CALL(balMock, bcmolt_host_init(_)).WillByDefault(Return(host_init_res));
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__bal_state_stub, bcmolt_cfg_get__bal_state_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltCfg(olt_cfg), Return(bal_cfg_get_stub_res)));
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _))
.Times(BCM_MAX_DEVS_PER_LINE_CARD)
.WillRepeatedly(Return(bal_cfg_get_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_res));
olt_enable_res = Enable_(1, NULL);
ASSERT_TRUE( olt_enable_res.error_message() == Status::OK.error_message() );
}
// Test 2: OltEnableFail_host_init_fail
TEST_F(TestOltEnable, OltEnableFail_host_init_fail) {
// NiceMock is used to suppress 'WillByDefault' return errors.
// This is described in https://github.com/arangodb-helper/gtest/blob/master/googlemock/docs/CookBook.md
NiceMock<BalMocker> balMock;
bcmos_errno host_init_res = BCM_ERR_INTERNAL;
Status olt_enable_res;
// Ensure that the state of the OLT is in deactivated to start with..
state.deactivate();
ON_CALL(balMock, bcmolt_host_init(_)).WillByDefault(Return(host_init_res));
olt_enable_res = Enable_(1, NULL);
ASSERT_TRUE( olt_enable_res.error_message() != Status::OK.error_message() );
}
// Test 3: OltEnableSuccess_PON_Device_Connected
TEST_F(TestOltEnable, OltEnableSuccess_PON_Device_Connected) {
// NiceMock is used to suppress 'WillByDefault' return errors.
// This is described in https://github.com/arangodb-helper/gtest/blob/master/googlemock/docs/CookBook.md
NiceMock<BalMocker> balMock;
bcmos_errno host_init_res = BCM_ERR_OK;
bcmos_errno bal_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno bal_cfg_get_res = BCM_ERR_OK;
bcmos_errno olt_oper_res = BCM_ERR_OK;
bcmolt_olt_cfg olt_cfg = { };
bcmolt_olt_key olt_key = { };
BCMOLT_CFG_INIT(&olt_cfg, olt, olt_key);
olt_cfg.data.bal_state = BCMOLT_BAL_STATE_BAL_AND_SWITCH_READY;
Status olt_enable_res;
// Ensure that the state of the OLT is in deactivated to start with..
state.deactivate();
ON_CALL(balMock, bcmolt_host_init(_)).WillByDefault(Return(host_init_res));
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__bal_state_stub, bcmolt_cfg_get__bal_state_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltCfg(olt_cfg), Return(bal_cfg_get_stub_res)));
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _))
.Times(BCM_MAX_DEVS_PER_LINE_CARD)
.WillRepeatedly(Return(bal_cfg_get_res));
olt_enable_res = Enable_(1, NULL);
ASSERT_TRUE( olt_enable_res.error_message() == Status::OK.error_message() );
}
// Test 4: OltEnableFail_All_PON_Enable_Fail
TEST_F(TestOltEnable, OltEnableFail_All_PON_Enable_Fail) {
// NiceMock is used to suppress 'WillByDefault' return errors.
// This is described in https://github.com/arangodb-helper/gtest/blob/master/googlemock/docs/CookBook.md
NiceMock<BalMocker> balMock;
bcmos_errno host_init_res = BCM_ERR_OK;
bcmos_errno bal_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno bal_cfg_get_res = BCM_ERR_NOT_CONNECTED;
bcmos_errno olt_oper_res = BCM_ERR_INTERNAL;
bcmolt_olt_cfg olt_cfg = { };
bcmolt_olt_key olt_key = { };
BCMOLT_CFG_INIT(&olt_cfg, olt, olt_key);
olt_cfg.data.bal_state = BCMOLT_BAL_STATE_BAL_AND_SWITCH_READY;
Status olt_enable_res;
// Ensure that the state of the OLT is in deactivated to start with..
state.deactivate();
ON_CALL(balMock, bcmolt_host_init(_)).WillByDefault(Return(host_init_res));
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__bal_state_stub, bcmolt_cfg_get__bal_state_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltCfg(olt_cfg), Return(bal_cfg_get_stub_res)));
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _))
.Times(BCM_MAX_DEVS_PER_LINE_CARD)
.WillRepeatedly(Return(bal_cfg_get_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_res));
olt_enable_res = Enable_(1, NULL);
ASSERT_TRUE( olt_enable_res.error_message() != Status::OK.error_message() );
}
// Test 5 OltEnableSuccess_One_PON_Enable_Fail : One PON device enable fails, but all others succeed.
TEST_F(TestOltEnable, OltEnableSuccess_One_PON_Enable_Fail) {
// NiceMock is used to suppress 'WillByDefault' return errors.
// This is described in https://github.com/arangodb-helper/gtest/blob/master/googlemock/docs/CookBook.md
NiceMock<BalMocker> balMock;
bcmos_errno host_init_res = BCM_ERR_OK;
bcmos_errno bal_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno bal_cfg_get_res = BCM_ERR_NOT_CONNECTED;
bcmos_errno olt_oper_res_fail = BCM_ERR_INTERNAL;
bcmos_errno olt_oper_res_success = BCM_ERR_OK;
bcmolt_olt_cfg olt_cfg = { };
bcmolt_olt_key olt_key = { };
BCMOLT_CFG_INIT(&olt_cfg, olt, olt_key);
olt_cfg.data.bal_state = BCMOLT_BAL_STATE_BAL_AND_SWITCH_READY;
Status olt_enable_res;
// Ensure that the state of the OLT is in deactivated to start with..
state.deactivate();
ON_CALL(balMock, bcmolt_host_init(_)).WillByDefault(Return(host_init_res));
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__bal_state_stub, bcmolt_cfg_get__bal_state_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltCfg(olt_cfg), Return(bal_cfg_get_stub_res)));
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _))
.Times(BCM_MAX_DEVS_PER_LINE_CARD)
.WillRepeatedly(Return(bal_cfg_get_res));
// For the the first PON mac device, the activation result will fail, and will succeed for all other PON mac devices.
EXPECT_CALL(balMock, bcmolt_oper_submit(_, _))
.WillOnce(Return(olt_oper_res_fail))
.WillRepeatedly(Return(olt_oper_res_success));
olt_enable_res = Enable_(1, NULL);
ASSERT_TRUE( olt_enable_res.error_message() == Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////
// For testing Enable/Disable functionality
////////////////////////////////////////////////////////////////////////
int num_of_pon_port = 16;
// Create a mock function for bcmolt_cfg_get__olt_topology_stub C++ function
MOCK_GLOBAL_FUNC2(bcmolt_cfg_get__olt_topology_stub, bcmos_errno(bcmolt_oltid, void*));
class TestOltDisableReenable : public Test {
protected:
virtual void SetUp() {
NiceMock<BalMocker> balMock;
bcmos_errno bal_cfg_get_stub_res = BCM_ERR_OK;
bcmolt_olt_cfg olt_cfg = { };
bcmolt_olt_key olt_key = { };
BCMOLT_CFG_INIT(&olt_cfg, olt, olt_key);
olt_cfg.data.topology.topology_maps.len = num_of_pon_port;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__olt_topology_stub, bcmolt_cfg_get__olt_topology_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltCfg(olt_cfg), Return(bal_cfg_get_stub_res)));
ProbeDeviceCapabilities_();
}
virtual void TearDown() {
// Code here will be called immediately after each test
// (right before the destructor).
}
};
// Test Fixture for OltDisable
// Test 1: OltDisableSuccess case
TEST_F(TestOltDisableReenable, OltDisableSuccess){
// NiceMock is used to suppress 'WillByDefault' return errors.
// This is described in https://github.com/arangodb-helper/gtest/blob/master/googlemock/docs/CookBook.md
NiceMock<BalMocker> balMock;
bcmos_errno olt_oper_res = BCM_ERR_OK;
bcmos_errno olt_get_res = BCM_ERR_OK;
Status olt_disable_res;
state.deactivate();
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_res));
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Return(olt_get_res));
olt_disable_res = Disable_();
ASSERT_TRUE( olt_disable_res.error_message() == Status::OK.error_message() );
}
// Test 2: OltDisableAllPonFailed case
TEST_F(TestOltDisableReenable, OltDisableAllPonFailed){
// NiceMock is used to suppress 'WillByDefault' return errors.
// This is described in https://github.com/arangodb-helper/gtest/blob/master/googlemock/docs/CookBook.md
NiceMock<BalMocker> balMock;
bcmos_errno olt_oper_res = BCM_ERR_INTERNAL;
bcmos_errno pon_cfg_get_res = BCM_ERR_INTERNAL;
Status olt_disable_res;
state.deactivate();
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Return(pon_cfg_get_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_res));
olt_disable_res = Disable_();
ASSERT_TRUE( olt_disable_res.error_code() == grpc::StatusCode::INTERNAL);
}
// Test Fixture for OltReenable
// Test 1: OltReenableSuccess case
TEST_F(TestOltDisableReenable, OltReenableSuccess){
// NiceMock is used to suppress 'WillByDefault' return errors.
// This is described in https://github.com/arangodb-helper/gtest/blob/master/googlemock/docs/CookBook.md
NiceMock<BalMocker> balMock;
uint32_t pon_id = 0;
bcmos_errno olt_cfg_get_tmstub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
Status olt_reenable_res;
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_INACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.Times(num_of_pon_port)
.WillRepeatedly(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
bcmolt_tm_sched_cfg tm_sched_cfg;
bcmolt_tm_sched_key tm_sched_key = {.id = 1004};
BCMOLT_CFG_INIT(&tm_sched_cfg, tm_sched, tm_sched_key);
tm_sched_cfg.data.state = BCMOLT_CONFIG_STATE_NOT_CONFIGURED;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__tm_sched_stub, bcmolt_cfg_get__tm_sched_stub(_, _))
.Times(num_of_pon_port)
.WillRepeatedly(DoAll(SetArg1ToBcmOltTmSchedCfg(tm_sched_cfg), Return(olt_cfg_get_tmstub_res)));
olt_reenable_res = Reenable_();
ASSERT_TRUE( olt_reenable_res.error_message() == Status::OK.error_message() );
}
// Test 2: OltReenableAllPonFailed case
TEST_F(TestOltDisableReenable, OltReenableAllPonFailed){
// NiceMock is used to suppress 'WillByDefault' return errors.
// This is described in https://github.com/arangodb-helper/gtest/blob/master/googlemock/docs/CookBook.md
NiceMock<BalMocker> balMock;
uint32_t pon_id = 0;
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
bcmos_errno olt_oper_res = BCM_ERR_INTERNAL;
Status olt_reenable_res;
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_INACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.Times(num_of_pon_port)
.WillRepeatedly(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
EXPECT_CALL(balMock,bcmolt_oper_submit(_, _))
.Times(num_of_pon_port)
.WillRepeatedly(Return(olt_oper_res));
olt_reenable_res = Reenable_();
ASSERT_TRUE( olt_reenable_res.error_code() == grpc::StatusCode::INTERNAL);
}
////////////////////////////////////////////////////////////////////////////
// For testing ProbeDeviceCapabilities functionality
////////////////////////////////////////////////////////////////////////////
class TestProbeDevCapabilities : public Test {
protected:
NiceMock<BalMocker> balMock;
bcmos_errno olt_res_success = BCM_ERR_OK;
bcmos_errno olt_res_fail = BCM_ERR_COMM_FAIL;
bcmos_errno dev_res_success = BCM_ERR_OK;
bcmos_errno dev_res_fail = BCM_ERR_COMM_FAIL;
virtual void SetUp() {
bcmos_errno bal_cfg_get_stub_res = BCM_ERR_OK;
bcmolt_olt_cfg olt_cfg = { };
bcmolt_olt_key olt_key = { };
BCMOLT_CFG_INIT(&olt_cfg, olt, olt_key);
olt_cfg.data.topology.topology_maps.len = num_of_pon_port;
}
virtual void TearDown() {
}
};
// Test 1 - If querying the OLT fails, the method must return error
TEST_F(TestProbeDevCapabilities, ProbeDev_OltQueryFailed) {
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__olt_topology_stub, bcmolt_cfg_get__olt_topology_stub(_,_))
.WillOnce(Return(olt_res_fail));
Status query_status = ProbeDeviceCapabilities_();
ASSERT_TRUE( query_status.error_message() != Status::OK.error_message() );
}
// Test 2 - If all devices are queried successfully, the method must return Status::OK
TEST_F(TestProbeDevCapabilities, ProbeDev_OltQuerySucceeded_DevQueriesSucceeded) {
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__olt_topology_stub, bcmolt_cfg_get__olt_topology_stub(_,_))
.WillOnce(Return(olt_res_success));
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _))
.WillRepeatedly(Return(dev_res_success));
Status query_status = ProbeDeviceCapabilities_();
ASSERT_TRUE( query_status.error_message() == Status::OK.error_message() );
}
// Test 3 - After successfully probing the OLT, even if probing all devices failed, the method must return error
TEST_F(TestProbeDevCapabilities, ProbedDev_OltQuerySucceeded_AllDevQueriesFailed) {
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__olt_topology_stub, bcmolt_cfg_get__olt_topology_stub(_,_))
.WillOnce(Return(olt_res_success));
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _))
.WillRepeatedly(Return(dev_res_fail));
Status query_status = ProbeDeviceCapabilities_();
ASSERT_TRUE( query_status.error_message() != Status::OK.error_message() );
}
// Test 4 - After successfully probing the OLT, if probing some devices fail, the method returns success
TEST_F(TestProbeDevCapabilities, ProbedDev_OltQuerySucceeded_SomeDevQueriesFailed) {
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__olt_topology_stub, bcmolt_cfg_get__olt_topology_stub(_,_))
.WillOnce(Return(olt_res_success));
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _))
.WillOnce(Return(olt_res_success))
.WillRepeatedly(Return(dev_res_fail));
Status query_status = ProbeDeviceCapabilities_();
ASSERT_TRUE( query_status.error_message() == Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing EnablePonIf functionality
////////////////////////////////////////////////////////////////////////////
class TestEnablePonIf : public Test {
protected:
uint32_t pon_id = 0;
NiceMock<BalMocker> balMock;
virtual void SetUp() {
}
virtual void TearDown() {
}
};
// Test 1 - EnablePonIf, Downstream DefaultSched & DefaultQueues creation success case
TEST_F(TestEnablePonIf, EnablePonIfDefaultSchedQueuesSuccess) {
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
bcmos_errno olt_cfg_get_tmstub_res = BCM_ERR_OK;
bcmos_errno olt_oper_sub_res = BCM_ERR_OK;
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_INACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_sub_res));
bcmolt_tm_sched_cfg tm_sched_cfg;
bcmolt_tm_sched_key tm_sched_key = {.id = 1004};
BCMOLT_CFG_INIT(&tm_sched_cfg, tm_sched, tm_sched_key);
tm_sched_cfg.data.state = BCMOLT_CONFIG_STATE_NOT_CONFIGURED;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__tm_sched_stub, bcmolt_cfg_get__tm_sched_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltTmSchedCfg(tm_sched_cfg), Return(olt_cfg_get_tmstub_res)));
Status status = EnablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - EnablePonIf success but Downstream DefaultSched Query failure case
TEST_F(TestEnablePonIf, EnablePonIfSuccessDefaultSchedQueryFailure) {
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
bcmos_errno olt_cfg_get_tmstub_res = BCM_ERR_INTERNAL;
bcmos_errno olt_oper_sub_res = BCM_ERR_OK;
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_INACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_sub_res));
bcmolt_tm_sched_cfg tm_sched_cfg;
bcmolt_tm_sched_key tm_sched_key = {.id = 1004};
BCMOLT_CFG_INIT(&tm_sched_cfg, tm_sched, tm_sched_key);
tm_sched_cfg.data.state = BCMOLT_CONFIG_STATE_CONFIGURED;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__tm_sched_stub, bcmolt_cfg_get__tm_sched_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltTmSchedCfg(tm_sched_cfg), Return(olt_cfg_get_tmstub_res)));
Status status = EnablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 3 - EnablePonIf success but Downstream DefaultSched already in Configured state
TEST_F(TestEnablePonIf, EnablePonIfSuccessDefaultSchedAlreadyConfigured) {
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
bcmos_errno olt_cfg_get_res = BCM_ERR_OK;
bcmos_errno olt_cfg_get_tmstub_res = BCM_ERR_OK;
bcmos_errno olt_oper_sub_res = BCM_ERR_OK;
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_INACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_sub_res));
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Return(olt_cfg_get_res));
bcmolt_tm_sched_cfg tm_sched_cfg;
bcmolt_tm_sched_key tm_sched_key = {.id = 1004};
BCMOLT_CFG_INIT(&tm_sched_cfg, tm_sched, tm_sched_key);
tm_sched_cfg.data.state = BCMOLT_CONFIG_STATE_CONFIGURED;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__tm_sched_stub, bcmolt_cfg_get__tm_sched_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltTmSchedCfg(tm_sched_cfg), Return(olt_cfg_get_tmstub_res)));
Status status = EnablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 4 - EnablePonIf success but Downstream DefaultSched & DefaultQueues creation failed
TEST_F(TestEnablePonIf, EnablePonIfSuccessDefaultSchedQueuesFailed) {
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_err = BCM_ERR_INTERNAL;
bcmos_errno olt_cfg_get_res = BCM_ERR_OK;
bcmos_errno olt_cfg_get_tmstub_res = BCM_ERR_OK;
bcmos_errno olt_oper_sub_res = BCM_ERR_OK;
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_INACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
EXPECT_CALL(balMock, bcmolt_cfg_set(_, _))
.WillOnce(Return(olt_cfg_set_res))
.WillRepeatedly(Return(olt_cfg_set_err));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_sub_res));
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Return(olt_cfg_get_res));
bcmolt_tm_sched_cfg tm_sched_cfg;
bcmolt_tm_sched_key tm_sched_key = {.id = 1004};
BCMOLT_CFG_INIT(&tm_sched_cfg, tm_sched, tm_sched_key);
tm_sched_cfg.data.state = BCMOLT_CONFIG_STATE_NOT_CONFIGURED;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__tm_sched_stub, bcmolt_cfg_get__tm_sched_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltTmSchedCfg(tm_sched_cfg), Return(olt_cfg_get_tmstub_res)));
Status status = EnablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 5 - EnablePonIf already enabled success
TEST_F(TestEnablePonIf, EnablePonIfAlreadyEnabled) {
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
Status status = EnablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 6 - EnablePonIf - enable onu discovery failure case
TEST_F(TestEnablePonIf, EnablePonIfEnableOnuDiscFailed) {
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_INTERNAL;
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_INACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = EnablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 7 - EnablePonIf failure case
TEST_F(TestEnablePonIf, EnablePonIfFailed) {
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
bcmos_errno olt_oper_sub_res = BCM_ERR_INTERNAL;
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_INACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_sub_res));
Status status = EnablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing SetStateUplinkIf functionality
////////////////////////////////////////////////////////////////////////////
class TestSetStateUplinkIf : public Test {
protected:
uint32_t intf_id = 0;
NiceMock<BalMocker> balMock;
virtual void SetUp() {
}
virtual void TearDown() {
}
};
// Test 1 - SetStateUplinkIf NNI intf already enabled, Upstream DefaultSched & DefaultQueues creation success case
TEST_F(TestSetStateUplinkIf, SetStateUplinkIfAlreadyEnabledDefaultSchedQueuesSuccess) {
bcmos_errno olt_cfg_get_nni_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_get_tmstub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
bcmolt_nni_interface_key nni_key;
bcmolt_nni_interface_cfg nni_cfg;
nni_key.id = intf_id;
BCMOLT_CFG_INIT(&nni_cfg, nni_interface, nni_key);
nni_cfg.data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__nni_intf_stub, bcmolt_cfg_get__nni_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltNniCfg(nni_cfg), Return(olt_cfg_get_nni_stub_res)));
bcmolt_tm_sched_cfg tm_sched_cfg;
bcmolt_tm_sched_key tm_sched_key = {.id = 1004};
BCMOLT_CFG_INIT(&tm_sched_cfg, tm_sched, tm_sched_key);
tm_sched_cfg.data.state = BCMOLT_CONFIG_STATE_NOT_CONFIGURED;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__tm_sched_stub, bcmolt_cfg_get__tm_sched_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltTmSchedCfg(tm_sched_cfg), Return(olt_cfg_get_tmstub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = SetStateUplinkIf_(intf_id, true);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - SetStateUplinkIf, NNI interface already disabled case
TEST_F(TestSetStateUplinkIf, SetStateUplinkIfAlreadyDisabled) {
bcmos_errno olt_cfg_get_nni_stub_res = BCM_ERR_OK;
bcmolt_nni_interface_key nni_key;
bcmolt_nni_interface_cfg nni_cfg;
nni_key.id = intf_id;
BCMOLT_CFG_INIT(&nni_cfg, nni_interface, nni_key);
nni_cfg.data.state = BCMOLT_INTERFACE_STATE_INACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__nni_intf_stub, bcmolt_cfg_get__nni_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltNniCfg(nni_cfg), Return(olt_cfg_get_nni_stub_res)));
Status status = SetStateUplinkIf_(intf_id, false);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 3 - SetStateUplinkIf Enable success, Upstream DefaultSched & DefaultQueues creation success case
TEST_F(TestSetStateUplinkIf, SetStateUplinkIfDefaultSchedQueuesSuccess) {
bcmos_errno olt_cfg_get_nni_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_get_tmstub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
bcmos_errno olt_oper_sub_res = BCM_ERR_OK;
bcmolt_nni_interface_key nni_key;
bcmolt_nni_interface_cfg nni_cfg;
nni_key.id = intf_id;
BCMOLT_CFG_INIT(&nni_cfg, nni_interface, nni_key);
nni_cfg.data.state = BCMOLT_INTERFACE_STATE__BEGIN;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__nni_intf_stub, bcmolt_cfg_get__nni_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltNniCfg(nni_cfg), Return(olt_cfg_get_nni_stub_res)));
bcmolt_tm_sched_cfg tm_sched_cfg;
bcmolt_tm_sched_key tm_sched_key = {.id = 1004};
BCMOLT_CFG_INIT(&tm_sched_cfg, tm_sched, tm_sched_key);
tm_sched_cfg.data.state = BCMOLT_CONFIG_STATE_NOT_CONFIGURED;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__tm_sched_stub, bcmolt_cfg_get__tm_sched_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltTmSchedCfg(tm_sched_cfg), Return(olt_cfg_get_tmstub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_sub_res));
Status status = SetStateUplinkIf_(intf_id, true);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 4 - SetStateUplinkIf Enable failure case
TEST_F(TestSetStateUplinkIf, SetStateUplinkIfEnableFailure) {
bcmos_errno olt_cfg_get_nni_stub_res = BCM_ERR_OK;
bcmos_errno olt_oper_sub_res = BCM_ERR_INTERNAL;
bcmolt_nni_interface_key nni_key;
bcmolt_nni_interface_cfg nni_cfg;
nni_key.id = intf_id;
BCMOLT_CFG_INIT(&nni_cfg, nni_interface, nni_key);
nni_cfg.data.state = BCMOLT_INTERFACE_STATE__BEGIN;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__nni_intf_stub, bcmolt_cfg_get__nni_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltNniCfg(nni_cfg), Return(olt_cfg_get_nni_stub_res)));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_sub_res));
Status status = SetStateUplinkIf_(intf_id, true);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 5 - SetStateUplinkIf Disable success case
TEST_F(TestSetStateUplinkIf, SetStateUplinkIfDisableSuccess) {
bcmos_errno olt_cfg_get_nni_stub_res = BCM_ERR_OK;
bcmos_errno olt_oper_sub_res = BCM_ERR_OK;
bcmolt_nni_interface_key nni_key;
bcmolt_nni_interface_cfg nni_cfg;
nni_key.id = intf_id;
BCMOLT_CFG_INIT(&nni_cfg, nni_interface, nni_key);
nni_cfg.data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__nni_intf_stub, bcmolt_cfg_get__nni_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltNniCfg(nni_cfg), Return(olt_cfg_get_nni_stub_res)));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_sub_res));
Status status = SetStateUplinkIf_(intf_id, false);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 6 - SetStateUplinkIf Disable failure case
TEST_F(TestSetStateUplinkIf, SetStateUplinkIfDisableFailure) {
bcmos_errno olt_cfg_get_nni_stub_res = BCM_ERR_OK;
bcmos_errno olt_oper_sub_res = BCM_ERR_INTERNAL;
bcmolt_nni_interface_key nni_key;
bcmolt_nni_interface_cfg nni_cfg;
nni_key.id = intf_id;
BCMOLT_CFG_INIT(&nni_cfg, nni_interface, nni_key);
nni_cfg.data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__nni_intf_stub, bcmolt_cfg_get__nni_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltNniCfg(nni_cfg), Return(olt_cfg_get_nni_stub_res)));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_sub_res));
Status status = SetStateUplinkIf_(intf_id, false);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing DisablePonIf functionality
////////////////////////////////////////////////////////////////////////////
class TestDisablePonIf : public Test {
protected:
virtual void SetUp() {
}
virtual void TearDown() {
}
};
// Test 1 - DisablePonIf success case - PON port in BCMOLT_INTERFACE_STATE_ACTIVE_WORKING state
TEST_F(TestDisablePonIf, DisablePonIfSuccess) {
bcmos_errno olt_oper_res = BCM_ERR_OK;
bcmos_errno bal_cfg_set_res = BCM_ERR_OK;
NiceMock<BalMocker> balMock;
uint32_t pon_id=1;
bcmos_errno pon_intf_get_res = BCM_ERR_OK;
bcmolt_pon_interface_cfg interface_obj;
bcmolt_pon_interface_key intf_key = {.pon_ni = (bcmolt_interface)pon_id};
BCMOLT_CFG_INIT(&interface_obj, pon_interface, intf_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([pon_intf_get_res, &interface_obj] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_pon_interface_cfg* pon_cfg = (bcmolt_pon_interface_cfg*)cfg;
pon_cfg->data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
memcpy(&interface_obj, pon_cfg, sizeof(bcmolt_pon_interface_cfg));
return pon_intf_get_res;
}
));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_res));
state.deactivate();
Status status = DisablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - DisablePonIf Failure case - bcmolt_oper_submit returns BCM_ERR_INTERNAL
TEST_F(TestDisablePonIf, DisablePonIf_OperSubmitErrInternal) {
bcmos_errno olt_oper_res = BCM_ERR_INTERNAL;
NiceMock<BalMocker> balMock;
uint32_t pon_id=1;
bcmos_errno pon_intf_get_res = BCM_ERR_OK;
bcmolt_pon_interface_cfg interface_obj;
bcmolt_pon_interface_key intf_key = {.pon_ni = (bcmolt_interface)pon_id};
BCMOLT_CFG_INIT(&interface_obj, pon_interface, intf_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([pon_intf_get_res, &interface_obj] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_pon_interface_cfg* pon_cfg = (bcmolt_pon_interface_cfg*)cfg;
pon_cfg->data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
memcpy(&interface_obj, pon_cfg, sizeof(bcmolt_pon_interface_cfg));
return pon_intf_get_res;
}
));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(olt_oper_res));
state.deactivate();
Status status = DisablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 3 - DisablePonIf Failure case - bcmolt_oper_submit returns BCM_ERR_INTERNAL
TEST_F(TestDisablePonIf, DisablePonIf_CfgSetErrInternal) {
NiceMock<BalMocker> balMock;
uint32_t pon_id=1;
bcmos_errno bal_cfg_set_res= BCM_ERR_INTERNAL;
bcmos_errno pon_intf_get_res = BCM_ERR_OK;
bcmolt_pon_interface_cfg interface_obj;
bcmolt_pon_interface_key intf_key = {.pon_ni = (bcmolt_interface)pon_id};
BCMOLT_CFG_INIT(&interface_obj, pon_interface, intf_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([pon_intf_get_res, &interface_obj] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_pon_interface_cfg* pon_cfg = (bcmolt_pon_interface_cfg*)cfg;
pon_cfg->data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
memcpy(&interface_obj, pon_cfg, sizeof(bcmolt_pon_interface_cfg));
return pon_intf_get_res;
}
));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(bal_cfg_set_res));
state.deactivate();
Status status = DisablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 4 - DisablePonIf success case - PON port in BCMOLT_INTERFACE_STATE_INACTIVE state
TEST_F(TestDisablePonIf, DisablePonIfSuccess_PonIntfInactive) {
bcmos_errno olt_oper_res = BCM_ERR_OK;
bcmos_errno bal_cfg_set_res = BCM_ERR_OK;
NiceMock<BalMocker> balMock;
uint32_t pon_id=1;
bcmos_errno pon_intf_get_res = BCM_ERR_OK;
bcmolt_pon_interface_cfg interface_obj;
bcmolt_pon_interface_key intf_key = {.pon_ni = (bcmolt_interface)pon_id};
BCMOLT_CFG_INIT(&interface_obj, pon_interface, intf_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([pon_intf_get_res, &interface_obj] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_pon_interface_cfg* pon_cfg = (bcmolt_pon_interface_cfg*)cfg;
pon_cfg->data.state = BCMOLT_INTERFACE_STATE_INACTIVE;
memcpy(&interface_obj, pon_cfg, sizeof(bcmolt_pon_interface_cfg));
return pon_intf_get_res;
}
));
state.deactivate();
Status status = DisablePonIf_(pon_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing ActivateOnu functionality
////////////////////////////////////////////////////////////////////////////
class TestActivateOnu : public Test {
protected:
uint32_t pon_id = 0;
uint32_t onu_id = 1;
std::string vendor_id = "TWSH";
std::string vendor_specific = "80808080";
uint32_t pir = 1000000;
NiceMock<BalMocker> balMock;
virtual void SetUp() {
}
virtual void TearDown() {
}
};
// Test 1 - ActivateOnu success case - ONU in BCMOLT_ONU_STATE_NOT_CONFIGURED state
TEST_F(TestActivateOnu, ActivateOnuSuccessOnuNotConfigured) {
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmos_errno onu_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno onu_cfg_set_res = BCM_ERR_OK;
bcmos_errno onu_oper_submit_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg;
bcmolt_onu_key onu_key;
BCMOLT_CFG_INIT(&onu_cfg, onu, onu_key);
onu_cfg.data.onu_state = BCMOLT_ONU_STATE_NOT_CONFIGURED;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__onu_state_stub, bcmolt_cfg_get__onu_state_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltOnuCfg(onu_cfg), Return(onu_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Return(onu_cfg_get_res));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(onu_cfg_set_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_submit_res));
Status status = ActivateOnu_(pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str(), pir, true);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - ActivateOnu success case - ONU already in BCMOLT_ONU_STATE_ACTIVE state
TEST_F(TestActivateOnu, ActivateOnuSuccessOnuAlreadyActive) {
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmos_errno onu_cfg_get_stub_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg;
bcmolt_onu_key onu_key;
BCMOLT_CFG_INIT(&onu_cfg, onu, onu_key);
onu_cfg.data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__onu_state_stub, bcmolt_cfg_get__onu_state_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltOnuCfg(onu_cfg), Return(onu_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Return(onu_cfg_get_res));
Status status = ActivateOnu_(pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str(), pir, true);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 3 - ActivateOnu success case - ONU in BCMOLT_ONU_STATE_INACTIVE state
TEST_F(TestActivateOnu, ActivateOnuSuccessOnuInactive) {
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmos_errno onu_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno onu_oper_submit_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg;
bcmolt_onu_key onu_key;
BCMOLT_CFG_INIT(&onu_cfg, onu, onu_key);
onu_cfg.data.onu_state = BCMOLT_ONU_STATE_INACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__onu_state_stub, bcmolt_cfg_get__onu_state_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltOnuCfg(onu_cfg), Return(onu_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Return(onu_cfg_get_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_submit_res));
Status status = ActivateOnu_(pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str(), pir, true);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 4 - ActivateOnu failure case - ONU in invalid state (for this ex: BCMOLT_ONU_STATE_LOW_POWER_DOZE)
TEST_F(TestActivateOnu, ActivateOnuFailOnuInvalidState) {
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmos_errno onu_cfg_get_stub_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg;
bcmolt_onu_key onu_key;
BCMOLT_CFG_INIT(&onu_cfg, onu, onu_key);
onu_cfg.data.onu_state = BCMOLT_ONU_STATE_LOW_POWER_DOZE; // some invalid state which we dont recognize or process
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__onu_state_stub, bcmolt_cfg_get__onu_state_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltOnuCfg(onu_cfg), Return(onu_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Return(onu_cfg_get_res));
Status status = ActivateOnu_(pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str(), pir, true);
ASSERT_FALSE( status.error_message() == Status::OK.error_message() );
}
// Test 5 - ActivateOnu failure case - cfg_get failure
TEST_F(TestActivateOnu, ActivateOnuFailCfgGetFail) {
bcmos_errno onu_cfg_get_stub_res = BCM_ERR_INTERNAL;// return cfg_get failure
bcmolt_onu_cfg onu_cfg;
bcmolt_onu_key onu_key;
BCMOLT_CFG_INIT(&onu_cfg, onu, onu_key);
onu_cfg.data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__onu_state_stub, bcmolt_cfg_get__onu_state_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltOnuCfg(onu_cfg), Return(onu_cfg_get_stub_res)));
Status status = ActivateOnu_(pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str(), pir, true);
ASSERT_FALSE( status.error_message() == Status::OK.error_message() );
}
// Test 6 - ActivateOnu failure case - oper_submit failure
TEST_F(TestActivateOnu, ActivateOnuFailOperSubmitFail) {
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmos_errno onu_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno onu_cfg_set_res = BCM_ERR_OK;
bcmos_errno onu_oper_submit_res = BCM_ERR_INTERNAL; // return oper_submit failure
bcmolt_onu_cfg onu_cfg;
bcmolt_onu_key onu_key;
BCMOLT_CFG_INIT(&onu_cfg, onu, onu_key);
onu_cfg.data.onu_state = BCMOLT_ONU_STATE_NOT_CONFIGURED;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__onu_state_stub, bcmolt_cfg_get__onu_state_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltOnuCfg(onu_cfg), Return(onu_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Return(onu_cfg_get_res));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(onu_cfg_set_res));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_submit_res));
Status status = ActivateOnu_(pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str(), pir, true);
ASSERT_FALSE( status.error_message() == Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing DeactivateOnu functionality
////////////////////////////////////////////////////////////////////////////
class TestDeactivateOnu : public Test {
protected:
uint32_t pon_id = 0;
uint32_t onu_id = 1;
std::string vendor_id = "TWSH";
std::string vendor_specific = "80808080";
NiceMock<BalMocker> balMock;
virtual void SetUp() {
}
virtual void TearDown() {
}
};
// Test 1 - DeactivateOnu success case
TEST_F(TestDeactivateOnu, DeactivateOnuSuccess) {
bcmos_errno onu_oper_sub_res = BCM_ERR_OK;
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
Status status = DeactivateOnu_(pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str());
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - DeactivateOnu failure case
TEST_F(TestDeactivateOnu, DeactivateOnuFailure) {
bcmos_errno onu_oper_sub_res = BCM_ERR_INTERNAL;
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
Status status = DeactivateOnu_(pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str());
ASSERT_FALSE( status.error_message() == Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing DeleteOnu functionality
////////////////////////////////////////////////////////////////////////////
class TestDeleteOnu : public Test {
protected:
uint32_t pon_id = 0;
uint32_t onu_id = 1;
std::string vendor_id = "TWSH";
std::string vendor_specific = "80808080";
NiceMock<BalMocker> balMock;
virtual void SetUp() {
}
virtual void TearDown() {
}
public:
static int PushOnuDeactCompltResult(bcmolt_result result, bcmolt_deactivation_fail_reason reason) {
onu_deactivate_complete_result res;
res.pon_intf_id = 0;
res.onu_id = 1;
res.result = result;
res.reason = reason;
// We need to wait for some time to allow the Onu Deactivation Reqeuest to be triggered
// before we push the result.
std::this_thread::sleep_for(std::chrono::milliseconds(100));
bcmos_fastlock_lock(&onu_deactivate_wait_lock);
onu_deact_compltd_key k(0, 1);
std::map<onu_deact_compltd_key, Queue<onu_deactivate_complete_result> *>::iterator it = onu_deact_compltd_map.find(k);
if (it == onu_deact_compltd_map.end()) {
OPENOLT_LOG(ERROR, openolt_log_id, "onu deact key not found for pon_intf=%d, onu_id=%d\n", 0, 1);
} else {
it->second->push(res);
OPENOLT_LOG(INFO, openolt_log_id, "Pushed ONU deact completed result\n");
}
bcmos_fastlock_unlock(&onu_deactivate_wait_lock, 0);
return 0;
}
};
// Test 1 - DeleteOnu success case
TEST_F(TestDeleteOnu, DeleteOnuSuccess) {
bcmos_errno onu_oper_sub_res = BCM_ERR_OK;
bcmos_errno onu_cfg_clear_res = BCM_ERR_OK;
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(onu_cfg_clear_res));
future<int> push_onu_deact_complt_res = \
async(launch::async,TestDeleteOnu::PushOnuDeactCompltResult, BCMOLT_RESULT_SUCCESS, BCMOLT_DEACTIVATION_FAIL_REASON_NONE);
future<Status> future_res = async(launch::async, DeleteOnu_, pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str());
Status status = future_res.get();
int res = push_onu_deact_complt_res.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - DeleteOnu failure case - BAL Clear ONU fails
TEST_F(TestDeleteOnu, DeleteOnuFailureClearOnuFail) {
bcmos_errno onu_oper_sub_res = BCM_ERR_OK;
bcmos_errno onu_cfg_clear_res = BCM_ERR_INTERNAL;
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(onu_cfg_clear_res));
future<int> push_onu_deact_complt_res = \
async(launch::async,TestDeleteOnu::PushOnuDeactCompltResult, BCMOLT_RESULT_SUCCESS, BCMOLT_DEACTIVATION_FAIL_REASON_NONE);
future<Status> future_res = async(launch::async, DeleteOnu_, pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str());
Status status = future_res.get();
int res = push_onu_deact_complt_res.get();
ASSERT_FALSE( status.error_message() == Status::OK.error_message() );
}
// Test 3 - DeleteOnu failure case - onu deactivation fails
TEST_F(TestDeleteOnu, DeleteOnuFailureDeactivationFail) {
bcmos_errno onu_oper_sub_res = BCM_ERR_OK;
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
future<int> push_onu_deact_complt_res = \
async(launch::async,TestDeleteOnu::PushOnuDeactCompltResult, BCMOLT_RESULT_FAIL, BCMOLT_DEACTIVATION_FAIL_REASON_FAIL);
future<Status> future_res = async(launch::async, DeleteOnu_, pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str());
Status status = future_res.get();
int res = push_onu_deact_complt_res.get();
ASSERT_FALSE( status.error_message() == Status::OK.error_message() );
}
// Test 4 - DeleteOnu failure case - onu deactivation timesout
TEST_F(TestDeleteOnu, DeleteOnuFailureDeactivationTimeout) {
bcmos_errno onu_oper_sub_res = BCM_ERR_OK;
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
future<Status> future_res = async(launch::async, DeleteOnu_, pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str());
Status status = future_res.get();
ASSERT_FALSE( status.error_message() == Status::OK.error_message() );
}
// Test 5 - DeleteOnu success case - Onu is Inactive so won't wait for onu deactivation response
TEST_F(TestDeleteOnu, DeleteOnuSuccessDontwaitforDeactivationResp) {
bcmos_errno onu_oper_sub_res = BCM_ERR_OK;
bcmos_errno onu_cfg_clear_res = BCM_ERR_OK;
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_INACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(onu_cfg_clear_res));
future<Status> future_res = async(launch::async, DeleteOnu_, pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str());
Status status = future_res.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 6 - DeleteOnu failure case - Failed to fetch Onu status
TEST_F(TestDeleteOnu, DeleteOnuFailureFetchOnuStatusFailed) {
bcmos_errno onu_cfg_get_stub_res = BCM_ERR_INTERNAL;
bcmos_errno onu_cfg_get_res = BCM_ERR_INTERNAL;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_INACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
future<Status> future_res = async(launch::async, DeleteOnu_, pon_id, onu_id, vendor_id.c_str(), vendor_specific.c_str());
Status status = future_res.get();
ASSERT_FALSE( status.error_message() == Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing OmciMsgOut functionality
////////////////////////////////////////////////////////////////////////////
class TestOmciMsgOut : public Test {
protected:
uint32_t pon_id = 0;
uint32_t onu_id = 1;
std::string pkt = "omci-pkt";
NiceMock<BalMocker> balMock;
virtual void SetUp() {
}
virtual void TearDown() {
}
};
// Test 1 - OmciMsgOut success case
TEST_F(TestOmciMsgOut, OmciMsgOutSuccess) {
bcmos_errno onu_oper_sub_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
Status status = OmciMsgOut_(pon_id, onu_id, pkt);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 1 - OmciMsgOut failure case
TEST_F(TestOmciMsgOut, OmciMsgOutFailure) {
bcmos_errno onu_oper_sub_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
Status status = OmciMsgOut_(pon_id, onu_id, pkt);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing FlowAdd functionality
////////////////////////////////////////////////////////////////////////////
class TestFlowAdd : public Test {
protected:
int32_t access_intf_id = 0;
int32_t onu_id = 1;
int32_t uni_id = 0;
uint32_t port_no = 16;
uint32_t flow_id = 1;
std::string flow_type = "upstream";
int32_t alloc_id = 1024;
int32_t network_intf_id = 0;
int32_t gemport_id = 1024;
int32_t priority_value = 0;
uint64_t cookie = 0;
int32_t group_id = -1;
uint32_t tech_profile_id = 64;
bool enable_encryption = true;
NiceMock<BalMocker> balMock;
openolt::Flow* flow;
openolt::Classifier* classifier;
openolt::Action* action;
openolt::ActionCmd* cmd;
bcmolt_flow_key flow_key;
bcmolt_flow_cfg flow_cfg;
tech_profile::TrafficQueues* traffic_queues;
tech_profile::TrafficQueue* traffic_queue_1;
tech_profile::TrafficQueue* traffic_queue_2;
tech_profile::DiscardConfig* discard_config_1;
tech_profile::DiscardConfig* discard_config_2;
tech_profile::TailDropDiscardConfig* tail_drop_discard_config_1;
tech_profile::TailDropDiscardConfig* tail_drop_discard_config_2;
virtual void SetUp() {
classifier = new openolt::Classifier;
action = new openolt::Action;
cmd = new openolt::ActionCmd;
classifier->set_o_tpid(0);
classifier->set_o_vid(7);
classifier->set_i_tpid(0);
classifier->set_i_vid(0);
classifier->set_o_pbits(0);
classifier->set_i_pbits(0);
classifier->set_eth_type(0);
classifier->set_ip_proto(0);
classifier->set_src_port(0);
classifier->set_dst_port(0);
classifier->set_pkt_tag_type("single_tag");
classifier->set_src_mac("aabbccddeeff");
classifier->set_dst_mac("112233445566");
action->set_o_vid(12);
action->set_o_pbits(0);
action->set_o_tpid(0);
action->set_i_vid(0);
action->set_i_pbits(0);
action->set_i_tpid(0);
cmd->set_add_outer_tag(true);
cmd->set_remove_outer_tag(false);
cmd->set_trap_to_host(false);
action->set_allocated_cmd(cmd);
flow_key.flow_id = 1;
flow_key.flow_type = BCMOLT_FLOW_TYPE_UPSTREAM;
BCMOLT_CFG_INIT(&flow_cfg, flow, flow_key);
flow_cfg.data.onu_id=1;
flow_cfg.key.flow_type = BCMOLT_FLOW_TYPE_UPSTREAM;
flow_cfg.data.svc_port_id=1024;
flow_cfg.data.priority=0;
flow_cfg.data.cookie=0;
flow_cfg.data.ingress_intf.intf_type=BCMOLT_FLOW_INTERFACE_TYPE_PON;
flow_cfg.data.egress_intf.intf_type=BCMOLT_FLOW_INTERFACE_TYPE_NNI;
flow_cfg.data.ingress_intf.intf_id=0;
flow_cfg.data.egress_intf.intf_id=0;
flow_cfg.data.classifier.o_vid=7;
flow_cfg.data.classifier.o_pbits=0;
flow_cfg.data.classifier.i_vid=0;
flow_cfg.data.classifier.i_pbits=0;
flow_cfg.data.classifier.ether_type=0;
flow_cfg.data.classifier.ip_proto=0;
flow_cfg.data.classifier.src_port=0;
flow_cfg.data.classifier.dst_port=0;
flow_cfg.data.classifier.pkt_tag_type=BCMOLT_PKT_TAG_TYPE_SINGLE_TAG;
flow_cfg.data.egress_qos.type=BCMOLT_EGRESS_QOS_TYPE_FIXED_QUEUE;
flow_cfg.data.egress_qos.u.fixed_queue.queue_id=0;
flow_cfg.data.egress_qos.tm_sched.id=1020;
flow_cfg.data.action.cmds_bitmask=BCMOLT_ACTION_CMD_ID_ADD_OUTER_TAG;
flow_cfg.data.action.o_vid=12;
flow_cfg.data.action.o_pbits=0;
flow_cfg.data.action.i_vid=0;
flow_cfg.data.action.i_pbits=0;
flow_cfg.data.state=BCMOLT_FLOW_STATE_ENABLE;
traffic_queues = new tech_profile::TrafficQueues;
traffic_queues->set_intf_id(0);
traffic_queues->set_onu_id(2);
traffic_queue_1 = traffic_queues->add_traffic_queues();
traffic_queue_1->set_gemport_id(1024);
traffic_queue_1->set_pbit_map("0b00000101");
traffic_queue_1->set_aes_encryption(true);
traffic_queue_1->set_sched_policy(tech_profile::SchedulingPolicy::StrictPriority);
traffic_queue_1->set_priority(0);
traffic_queue_1->set_weight(0);
traffic_queue_1->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
discard_config_1 = new tech_profile::DiscardConfig;
discard_config_1->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
tail_drop_discard_config_1 = new tech_profile::TailDropDiscardConfig;
tail_drop_discard_config_1->set_queue_size(8);
discard_config_1->set_allocated_tail_drop_discard_config(tail_drop_discard_config_1);
traffic_queue_1->set_allocated_discard_config(discard_config_1);
traffic_queues->set_uni_id(0);
traffic_queues->set_port_no(16);
traffic_queue_2 = traffic_queues->add_traffic_queues();
traffic_queue_2->set_gemport_id(1025);
traffic_queue_2->set_pbit_map("0b00001010");
traffic_queue_2->set_aes_encryption(true);
traffic_queue_2->set_sched_policy(tech_profile::SchedulingPolicy::StrictPriority);
traffic_queue_2->set_priority(1);
traffic_queue_2->set_weight(0);
traffic_queue_2->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
discard_config_2 = new tech_profile::DiscardConfig;
discard_config_2->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
tail_drop_discard_config_2 = new tech_profile::TailDropDiscardConfig;
tail_drop_discard_config_2->set_queue_size(8);
discard_config_2->set_allocated_tail_drop_discard_config(tail_drop_discard_config_2);
traffic_queue_2->set_allocated_discard_config(discard_config_2);
}
virtual void TearDown() {
}
public:
static int PushGemCfgResult(GemObjectState state, GemCfgStatus status, uint32_t gem_port_id) {
gem_cfg_compltd_key k(0, gem_port_id);
gem_cfg_complete_result res;
res.pon_intf_id = 0;
res.gem_port_id = gem_port_id;
res.state = state;
res.status = status;
uint32_t gem_cfg_key_check_counter = 1;
std::map<gem_cfg_compltd_key, Queue<gem_cfg_complete_result> *>::iterator it;
while(true) {
bcmos_fastlock_lock(&gem_cfg_wait_lock);
it = gem_cfg_compltd_map.find(k);
if (it != gem_cfg_compltd_map.end()) {
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
break;
} else if (it == gem_cfg_compltd_map.end() && gem_cfg_key_check_counter < MAX_GEM_CFG_KEY_CHECK) {
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
// We need to wait for some time to allow the Gem Cfg Request to be triggered
// before we push the result.
bcmos_usleep(6000);
} else {
OPENOLT_LOG(ERROR, openolt_log_id, "gem config key not found for gem_port_id = %u, pon_intf = %u\n", gem_port_id, 0);
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
return 0;
}
gem_cfg_key_check_counter++;
}
bcmos_fastlock_lock(&gem_cfg_wait_lock);
if (it->second) {
it->second->push(res);
OPENOLT_LOG(INFO, openolt_log_id, "Pushed mocked gem cfg result\n");
}
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
return 0;
}
};
// Test 1 - FlowAdd - success case(HSIA-upstream FixedQueue)
TEST_F(TestFlowAdd, FlowAddHsiaFixedQueueUpstreamSuccess) {
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type,
alloc_id, network_intf_id, gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
#ifdef FLOW_CHECKER
// Test 2 - FlowAdd - Duplicate Flow case
TEST_F(TestFlowAdd, FlowAddHsiaFixedQueueUpstreamDuplicate) {
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
#endif
// Test 3 - FlowAdd - Failure case(bcmolt_cfg_set returns error)
TEST_F(TestFlowAdd, FlowAddHsiaFixedQueueUpstreamFailure) {
gemport_id = 1025;
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_INTERNAL;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 4 - FlowAdd - Failure case(Invalid flow direction)
TEST_F(TestFlowAdd, FlowAddFailureInvalidFlowDirection) {
flow_type = "bidirectional";
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 5 - FlowAdd - Failure case(Invalid network setting)
TEST_F(TestFlowAdd, FlowAddFailureInvalidNWCfg) {
network_intf_id = -1;
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 6 - FlowAdd - Success case(Single tag & EAP Ether type)
TEST_F(TestFlowAdd, FlowAddEapEtherTypeSuccess) {
flow_id = 2;
classifier->set_eth_type(34958);
action = new openolt::Action;
cmd = new openolt::ActionCmd;
cmd->set_trap_to_host(true);
action->set_allocated_cmd(cmd);
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id,
network_intf_id, gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 7 - FlowAdd - Success case(Single tag & DHCP flow)
TEST_F(TestFlowAdd, FlowAddDhcpSuccess) {
flow_id = 3;
gemport_id = 1025;
classifier->set_ip_proto(17);
classifier->set_src_port(68);
classifier->set_dst_port(67);
action = new openolt::Action;
cmd = new openolt::ActionCmd;
cmd->set_trap_to_host(true);
action->set_allocated_cmd(cmd);
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 8 - FlowAdd - success case(HSIA-downstream FixedQueue)
TEST_F(TestFlowAdd, FlowAddHsiaFixedQueueDownstreamSuccess) {
flow_id = 4;
flow_type = "downstream";
classifier->set_o_vid(12);
classifier->set_i_vid(7);
classifier->set_pkt_tag_type("double_tag");
action = new openolt::Action;
cmd = new openolt::ActionCmd;
action->set_o_vid(0);
cmd->set_remove_outer_tag(true);
action->set_allocated_cmd(cmd);
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 9 - FlowAdd - success case(HSIA-upstream PriorityQueue)
TEST_F(TestFlowAdd, FlowAddHsiaPriorityQueueUpstreamSuccess) {
onu_id = 2;
flow_id = 5;
alloc_id = 1025;
traffic_queue_1->set_direction(tech_profile::Direction::UPSTREAM);
traffic_queue_2->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
future<Status> future_res = async(launch::async, CreateTrafficQueues_, traffic_queues);
future<int> push_gem_cfg_complt = \
async(launch::async, TestFlowAdd::PushGemCfgResult, GEM_OBJECT_STATE_ACTIVE, GEM_CFG_STATUS_SUCCESS, 1024);
push_gem_cfg_complt = \
async(launch::async, TestFlowAdd::PushGemCfgResult, GEM_OBJECT_STATE_ACTIVE, GEM_CFG_STATUS_SUCCESS, 1025);
Status status = future_res.get();
int res = push_gem_cfg_complt.get();
status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 10 - FlowAdd - success case(HSIA-downstream PriorityQueue)
TEST_F(TestFlowAdd, FlowAddHsiaPriorityQueueDownstreamSuccess) {
onu_id = 2;
flow_id = 6;
flow_type = "downstream";
alloc_id = 1025;
classifier->set_o_vid(12);
classifier->set_i_vid(7);
classifier->set_pkt_tag_type("double_tag");
action = new openolt::Action;
cmd = new openolt::ActionCmd;
action->set_o_vid(0);
cmd->set_remove_outer_tag(true);
action->set_allocated_cmd(cmd);
traffic_queue_1->set_direction(tech_profile::Direction::DOWNSTREAM);
traffic_queue_2->set_direction(tech_profile::Direction::DOWNSTREAM);
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
CreateTrafficQueues_(traffic_queues);
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 11 - FlowAdd - success case (Downstream-Encrypted GEM)
TEST_F(TestFlowAdd, FlowAddDownstreamEncryptedGemSuccess) {
onu_id = 2;
flow_id = 7;
flow_type = "downstream";
alloc_id = 1025;
enable_encryption = true;
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
future<Status> future_res = async(launch::async, FlowAdd_, access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id, enable_encryption);
future<int> push_gem_cfg_complt = \
async(launch::async, TestFlowAdd::PushGemCfgResult, GEM_OBJECT_STATE_ACTIVE, GEM_CFG_STATUS_SUCCESS, 1024);
Status status = future_res.get();
int res = push_gem_cfg_complt.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 12 - FlowAdd - success case (Downstream-Unencrypted GEM - prints warning that encryption will not applied)
TEST_F(TestFlowAdd, FlowAddDownstreamUnencryptedGemWarning) {
onu_id = 2;
flow_id = 8;
flow_type = "downstream";
alloc_id = 1025;
enable_encryption = false;
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id, enable_encryption);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 13 - FlowAdd - success case (Upstream-Encrypted GEM - prints warning that encryption will not applied)
TEST_F(TestFlowAdd, FlowAddUpstreamEncryptedGemWarning) {
onu_id = 2;
flow_id = 9;
flow_type = "upstream";
alloc_id = 1025;
enable_encryption = true;
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id, enable_encryption);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 14 - FlowAdd - success case (Multicast-Encrypted GEM - prints warning that encryption will not applied)
TEST_F(TestFlowAdd, FlowAddMulticastEncryptedGemWarning) {
onu_id = 2;
flow_id = 10;
flow_type = "multicast";
alloc_id = 1025;
enable_encryption = true;
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = FlowAdd_(access_intf_id, onu_id, uni_id, port_no, flow_id, flow_type, alloc_id, network_intf_id,
gemport_id, *classifier, *action, priority_value, cookie, group_id, tech_profile_id, enable_encryption);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing OnuPacketOut functionality
////////////////////////////////////////////////////////////////////////////
class TestOnuPacketOut : public Test {
protected:
uint32_t pon_id = 0;
uint32_t onu_id = 1;
std::string pkt = "omci-pkt";
NiceMock<BalMocker> balMock;
virtual void SetUp() {
}
virtual void TearDown() {
}
};
// Test 1 - OnuPacketOut success case
TEST_F(TestOnuPacketOut, OnuPacketOutSuccess) {
uint32_t port_no = 16;
uint32_t gemport_id = 1024;
bcmos_errno onu_oper_sub_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
Status status = OnuPacketOut_(pon_id, onu_id, port_no, gemport_id, pkt);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - OnuPacketOut Port number as 0 case
TEST_F(TestOnuPacketOut, OnuPacketOutPortNo0) {
uint32_t port_no = 0;
uint32_t gemport_id = 1024;
Status status = OnuPacketOut_(pon_id, onu_id, port_no, gemport_id, pkt);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 3 - OnuPacketOut success, Finding Flow ID from port no and Gem from Flow ID case
TEST_F(TestOnuPacketOut, OnuPacketOutFindGemFromFlowSuccess) {
uint32_t port_no = 16;
uint32_t gemport_id = 0;
bcmos_errno onu_oper_sub_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
Status status = OnuPacketOut_(pon_id, onu_id, port_no, gemport_id, pkt);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 4 - OnuPacketOut success, Failure in finding Gem port case
TEST_F(TestOnuPacketOut, OnuPacketOutFindGemFromFlowFailure) {
uint32_t port_no = 64;
uint32_t gemport_id = 0;
bcmos_errno onu_oper_sub_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(onu_oper_sub_res));
Status status = OnuPacketOut_(pon_id, onu_id, port_no, gemport_id, pkt);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing FlowRemove functionality
////////////////////////////////////////////////////////////////////////////
class TestFlowRemove : public Test {
protected:
NiceMock<BalMocker> balMock;
virtual void SetUp() {
}
virtual void TearDown() {
}
};
// Test 1 - FlowRemove - Failure case
TEST_F(TestFlowRemove, FlowRemoveFailure) {
bcmos_errno olt_cfg_clear_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
Status status = FlowRemove_(1, "upstream");
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 2 - FlowRemove - success case
TEST_F(TestFlowRemove, FlowRemoveSuccess) {
bcmos_errno olt_cfg_clear_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
Status status = FlowRemove_(1, "upstream");
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing UplinkPacketOut functionality
////////////////////////////////////////////////////////////////////////////
class TestUplinkPacketOut : public Test {
protected:
uint32_t pon_id = 0;
std::string pkt = "omci-pkt";
NiceMock<BalMocker> balMock;
bcmolt_flow_key flow_key;
bcmolt_flow_cfg flow_cfg;
virtual void SetUp() {
flow_key.flow_id = 1;
flow_key.flow_type = BCMOLT_FLOW_TYPE_UPSTREAM;
BCMOLT_CFG_INIT(&flow_cfg, flow, flow_key);
flow_cfg.data.onu_id=1;
flow_cfg.key.flow_type = BCMOLT_FLOW_TYPE_UPSTREAM;
flow_cfg.data.svc_port_id=1024;
flow_cfg.data.priority=0;
flow_cfg.data.cookie=0;
flow_cfg.data.ingress_intf.intf_type=BCMOLT_FLOW_INTERFACE_TYPE_PON;
flow_cfg.data.egress_intf.intf_type=BCMOLT_FLOW_INTERFACE_TYPE_NNI;
flow_cfg.data.ingress_intf.intf_id=0;
flow_cfg.data.egress_intf.intf_id=0;
flow_cfg.data.classifier.o_vid=7;
flow_cfg.data.classifier.o_pbits=0;
flow_cfg.data.classifier.i_vid=0;
flow_cfg.data.classifier.i_pbits=0;
flow_cfg.data.classifier.ether_type=0;
flow_cfg.data.classifier.ip_proto=0;
flow_cfg.data.classifier.src_port=0;
flow_cfg.data.classifier.dst_port=0;
flow_cfg.data.classifier.pkt_tag_type=BCMOLT_PKT_TAG_TYPE_SINGLE_TAG;
flow_cfg.data.egress_qos.type=BCMOLT_EGRESS_QOS_TYPE_FIXED_QUEUE;
flow_cfg.data.egress_qos.u.fixed_queue.queue_id=0;
flow_cfg.data.egress_qos.tm_sched.id=1020;
flow_cfg.data.action.cmds_bitmask=BCMOLT_ACTION_CMD_ID_ADD_OUTER_TAG;
flow_cfg.data.action.o_vid=12;
flow_cfg.data.action.o_pbits=0;
flow_cfg.data.action.i_vid=0;
flow_cfg.data.action.i_pbits=0;
flow_cfg.data.state=BCMOLT_FLOW_STATE_ENABLE;
}
virtual void TearDown() {
}
};
// Test 1 - UplinkPacketOut success case
TEST_F(TestUplinkPacketOut, UplinkPacketOutSuccess) {
bcmos_errno send_eth_oper_sub_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(send_eth_oper_sub_res));
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
Status status = UplinkPacketOut_(pon_id, pkt);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - UplinkPacketOut Failure case
TEST_F(TestUplinkPacketOut, UplinkPacketOutFailure) {
bcmos_errno send_eth_oper_sub_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_oper_submit(_, _)).WillByDefault(Return(send_eth_oper_sub_res));
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
Status status = UplinkPacketOut_(pon_id, pkt);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 3 - UplinkPacketOut No matching flow id found for Uplink Packetout case
TEST_F(TestUplinkPacketOut, UplinkPacketOutFailureNoFlowIdFound) {
flow_cfg.key.flow_type = BCMOLT_FLOW_TYPE_DOWNSTREAM;
FlowRemove_(2, "upstream");
FlowRemove_(3, "upstream");
FlowRemove_(4, "downstream");
FlowRemove_(5, "upstream");
FlowRemove_(6, "downstream");
FlowRemove_(7, "downstream");
FlowRemove_(8, "downstream");
FlowRemove_(9, "upstream");
FlowRemove_(10, "multicast");
bcmos_errno flow_cfg_get_stub_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__flow_stub, bcmolt_cfg_get__flow_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltFlowCfg(flow_cfg), Return(flow_cfg_get_stub_res)));
Status status = UplinkPacketOut_(pon_id, pkt);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing CreateTrafficSchedulers functionality
////////////////////////////////////////////////////////////////////////////
class TestCreateTrafficSchedulers : public Test {
protected:
NiceMock<BalMocker> balMock;
tech_profile::TrafficSchedulers* traffic_scheds;
tech_profile::TrafficScheduler* traffic_sched;
tech_profile::SchedulerConfig* scheduler;
tech_profile::TrafficShapingInfo* traffic_shaping_info;
virtual void SetUp() {
traffic_scheds = new tech_profile::TrafficSchedulers;
traffic_scheds->set_intf_id(0);
traffic_scheds->set_onu_id(1);
traffic_scheds->set_uni_id(0);
traffic_scheds->set_port_no(16);
traffic_sched = traffic_scheds->add_traffic_scheds();
traffic_sched->set_alloc_id(1024);
scheduler = new tech_profile::SchedulerConfig;
scheduler->set_priority(0);
scheduler->set_weight(0);
scheduler->set_sched_policy(tech_profile::SchedulingPolicy::StrictPriority);
traffic_shaping_info = new tech_profile::TrafficShapingInfo;
traffic_shaping_info->set_cbs(60536);
traffic_shaping_info->set_pbs(65536);
traffic_shaping_info->set_gir(10000);
}
virtual void TearDown() {
}
public:
static int PushAllocCfgResult(AllocObjectState state, AllocCfgStatus status) {
alloc_cfg_compltd_key k(0, 1024);
alloc_cfg_complete_result res;
res.pon_intf_id = 0;
res.alloc_id = 1024;
res.state = state;
res.status = status;
// We need to wait for some time to allow the Alloc Cfg Request to be triggered
// before we push the result.
std::this_thread::sleep_for(std::chrono::milliseconds(100));
bcmos_fastlock_lock(&alloc_cfg_wait_lock);
std::map<alloc_cfg_compltd_key, Queue<alloc_cfg_complete_result> *>::iterator it = alloc_cfg_compltd_map.find(k);
if (it == alloc_cfg_compltd_map.end()) {
OPENOLT_LOG(ERROR, openolt_log_id, "alloc config key not found for alloc_id = %u, pon_intf = %u\n", 1024, 0);
} else {
it->second->push(res);
OPENOLT_LOG(INFO, openolt_log_id, "Pushed mocked alloc cfg result\n");
}
bcmos_fastlock_unlock(&alloc_cfg_wait_lock, 0);
return 0;
}
};
// Test 1 - CreateTrafficSchedulers-Upstream success case
TEST_F(TestCreateTrafficSchedulers, CreateTrafficSchedulersUpstreamSuccess) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
future<Status> future_res = async(launch::async, CreateTrafficSchedulers_, traffic_scheds);
future<int> push_alloc_cfg_complt = \
async(launch::async, TestCreateTrafficSchedulers::PushAllocCfgResult, ALLOC_OBJECT_STATE_ACTIVE, ALLOC_CFG_STATUS_SUCCESS);
Status status = future_res.get();
int res = push_alloc_cfg_complt.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - CreateTrafficSchedulers-Upstream failure case(timeout waiting for alloc cfg indication)
TEST_F(TestCreateTrafficSchedulers, UpstreamAllocCfgTimeout) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
bcmos_errno alloc_cfg_get_res = BCM_ERR_OK;
bcmolt_itupon_alloc_cfg alloc_cfg;
bcmolt_itupon_alloc_key alloc_key;
alloc_key.pon_ni = 0;
alloc_key.alloc_id = 1024;
BCMOLT_CFG_INIT(&alloc_cfg, itupon_alloc, alloc_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).Times(2)
.WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
))
.WillOnce(Invoke([alloc_cfg_get_res, &alloc_cfg] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_itupon_alloc_cfg* o_cfg = (bcmolt_itupon_alloc_cfg*)cfg;
o_cfg->data.state = BCMOLT_ACTIVATION_STATE_PROCESSING;
memcpy(&alloc_cfg, o_cfg, sizeof(bcmolt_itupon_alloc_cfg));
return alloc_cfg_get_res;
}
));
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 2A - CreateTrafficSchedulers-Upstream success case(ONU not in ACTIVE state)
TEST_F(TestCreateTrafficSchedulers, CreateTrafficSchedulersUpstreamSuccessOnuNotInActive) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_INACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2B - CreateTrafficSchedulers-Upstream failure case. cfg-get failure
TEST_F(TestCreateTrafficSchedulers, CreateTrafficSchedulersUpstreamCfgGetFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
bcmos_errno olt_cfg_get_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
ON_CALL(balMock, bcmolt_cfg_get(_, _)).WillByDefault(Return(olt_cfg_get_res));
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 2C - CreateTrafficSchedulers-Upstream Succes case(timeout waiting for alloc cfg indication, but itupon-alloc object is ACTIVE)
TEST_F(TestCreateTrafficSchedulers, UpstreamAllocCfgTimeoutSuccess) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
bcmos_errno alloc_cfg_get_res = BCM_ERR_OK;
bcmolt_itupon_alloc_cfg alloc_cfg;
bcmolt_itupon_alloc_key alloc_key;
alloc_key.pon_ni = 0;
alloc_key.alloc_id = 1024;
BCMOLT_CFG_INIT(&alloc_cfg, itupon_alloc, alloc_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).Times(2)
.WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
))
.WillOnce(Invoke([alloc_cfg_get_res, &alloc_cfg] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_itupon_alloc_cfg* o_cfg = (bcmolt_itupon_alloc_cfg*)cfg;
o_cfg->data.state = BCMOLT_ACTIVATION_STATE_ACTIVE;
memcpy(&alloc_cfg, o_cfg, sizeof(bcmolt_itupon_alloc_cfg));
return alloc_cfg_get_res;
}
));
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 3 - CreateTrafficSchedulers-Upstream failure case(error processing alloc cfg request)
TEST_F(TestCreateTrafficSchedulers, UpstreamErrorProcessingAllocCfg) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
future<Status> future_res = async(launch::async, CreateTrafficSchedulers_, traffic_scheds);
future<int> push_alloc_cfg_complt = \
async(launch::async, TestCreateTrafficSchedulers::PushAllocCfgResult, ALLOC_OBJECT_STATE_ACTIVE, ALLOC_CFG_STATUS_FAIL);
Status status = future_res.get();
int res = push_alloc_cfg_complt.get();
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 4 - CreateTrafficSchedulers-Upstream failure case(alloc object not in active state)
TEST_F(TestCreateTrafficSchedulers, UpstreamAllocObjNotinActiveState) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
future<Status> future_res = async(launch::async, CreateTrafficSchedulers_, traffic_scheds);
future<int> push_alloc_cfg_complt = \
async(launch::async, TestCreateTrafficSchedulers::PushAllocCfgResult, ALLOC_OBJECT_STATE_INACTIVE, ALLOC_CFG_STATUS_SUCCESS);
Status status = future_res.get();
int res = push_alloc_cfg_complt.get();
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 5 - CreateTrafficSchedulers-Upstream Failure case
TEST_F(TestCreateTrafficSchedulers, CreateTrafficSchedulersUpstreamFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 6 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_BestEffort-Max BW set to 0) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_BestEffortMaxBWZeroFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(0);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 7 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_BestEffort-Max BW < Guaranteed BW) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_BestEffortMaxBWLtGuaranteedBwFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(32000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 8 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_BestEffort-Max BW = Guaranteed BW) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_BestEffortMaxBWEqGuaranteedBwFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(64000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 9 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_NA-Max BW set to 0) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_NAMaxBWZeroFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_NA);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(0);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 10 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_NA-Guaranteed BW set to 0) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_NAGuaranteedBwZeroFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_NA);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(0);
traffic_shaping_info->set_pir(32000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 11 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_NA-Max BW < Guaranteed BW) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_NAMaxBWLtGuaranteedBwFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_NA);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(32000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 12 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_NA-Max BW = Guaranteed BW) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_NAMaxBWEqGuaranteedBwFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_NA);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(64000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 13 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_None-Max BW set to 0) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_NoneMaxBWZeroFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_None);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(0);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 14 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_None-Guaranteed BW set to 0) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_NoneGuaranteedBwZeroFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_None);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(0);
traffic_shaping_info->set_pir(32000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 15 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_None-Max BW > Guaranteed BW) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_NoneMaxBWGtGuaranteedBwFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_None);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 16 - CreateTrafficSchedulers-Upstream Failure (AdditionalBW_None-Max BW < Guaranteed BW) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_NoneMaxBWLtGuaranteedBwFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_None);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(32000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 17 - CreateTrafficSchedulers-Upstream Failure (Invalid AdditionalBW value) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_InvalidValueFailure) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(9);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(0);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 18 - CreateTrafficSchedulers-Upstream Success (AdditionalBW_None-Max BW = Fixed BW) case
TEST_F(TestCreateTrafficSchedulers, AdditionalBW_NoneMaxBWEqFixedBwSuccess) {
scheduler->set_direction(tech_profile::Direction::UPSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_None);
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_gir(64000);
traffic_shaping_info->set_cir(0);
traffic_shaping_info->set_pir(64000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
future<Status> future_res = async(launch::async, CreateTrafficSchedulers_, traffic_scheds);
future<int> push_alloc_cfg_complt = \
async(launch::async, TestCreateTrafficSchedulers::PushAllocCfgResult, ALLOC_OBJECT_STATE_ACTIVE, ALLOC_CFG_STATUS_SUCCESS);
Status status = future_res.get();
int res = push_alloc_cfg_complt.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 19 - CreateTrafficSchedulers-Downstream success case
TEST_F(TestCreateTrafficSchedulers, CreateTrafficSchedulersDownstreamSuccess) {
scheduler->set_direction(tech_profile::Direction::DOWNSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::DOWNSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 20 - CreateTrafficSchedulers-Downstream Failure case
TEST_F(TestCreateTrafficSchedulers, CreateTrafficSchedulersDownstreamFailure) {
scheduler->set_direction(tech_profile::Direction::DOWNSTREAM);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::DOWNSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 21 - CreateTrafficSchedulers-Invalid direction Failure case
TEST_F(TestCreateTrafficSchedulers, CreateTrafficSchedulersInvalidDirectionFailure) {
scheduler->set_direction(tech_profile::Direction::BIDIRECTIONAL);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_sched->set_direction(tech_profile::Direction::BIDIRECTIONAL);
traffic_sched->set_allocated_scheduler(scheduler);
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
Status status = CreateTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing RemoveTrafficSchedulers functionality
////////////////////////////////////////////////////////////////////////////
class TestRemoveTrafficSchedulers : public Test {
protected:
NiceMock<BalMocker> balMock;
tech_profile::TrafficSchedulers* traffic_scheds;
tech_profile::TrafficScheduler* traffic_sched;
tech_profile::SchedulerConfig* scheduler;
tech_profile::TrafficShapingInfo* traffic_shaping_info;
alloc_cfg_complete_result res;
uint32_t pon_id = 0;
virtual void SetUp() {
traffic_scheds = new tech_profile::TrafficSchedulers;
traffic_scheds->set_intf_id(0);
traffic_scheds->set_onu_id(1);
traffic_scheds->set_uni_id(0);
traffic_scheds->set_port_no(16);
traffic_sched = traffic_scheds->add_traffic_scheds();
traffic_sched->set_alloc_id(1025);
scheduler = new tech_profile::SchedulerConfig;
scheduler->set_priority(0);
scheduler->set_weight(0);
scheduler->set_sched_policy(tech_profile::SchedulingPolicy::StrictPriority);
scheduler->set_additional_bw(tech_profile::AdditionalBW::AdditionalBW_BestEffort);
traffic_shaping_info = new tech_profile::TrafficShapingInfo;
traffic_shaping_info->set_cir(64000);
traffic_shaping_info->set_pir(128000);
traffic_shaping_info->set_cbs(60536);
traffic_shaping_info->set_pbs(65536);
traffic_shaping_info->set_gir(10000);
traffic_sched->set_allocated_traffic_shaping_info(traffic_shaping_info);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
}
virtual void TearDown() {
}
public:
static int PushAllocCfgResult(AllocObjectState state, AllocCfgStatus status) {
alloc_cfg_compltd_key k(0, 1025);
alloc_cfg_complete_result res;
res.pon_intf_id = 0;
res.alloc_id = 1025;
res.state = state;
res.status = status;
// We need to wait for some time to allow the Alloc Cfg Request to be triggered
// before we push the result.
std::this_thread::sleep_for(std::chrono::milliseconds(100));
bcmos_fastlock_lock(&alloc_cfg_wait_lock);
std::map<alloc_cfg_compltd_key, Queue<alloc_cfg_complete_result> *>::iterator it = alloc_cfg_compltd_map.find(k);
if (it == alloc_cfg_compltd_map.end()) {
OPENOLT_LOG(ERROR, openolt_log_id, "alloc config key not found for alloc_id = %u, pon_intf = %u\n", 1025, 0);
} else {
it->second->push(res);
OPENOLT_LOG(INFO, openolt_log_id, "Pushed mocked alloc cfg result\n");
}
bcmos_fastlock_unlock(&alloc_cfg_wait_lock, 0);
return 0;
}
};
// Test 1 - RemoveTrafficSchedulers-Upstream success case
TEST_F(TestRemoveTrafficSchedulers, RemoveTrafficSchedulersUpstreamSuccess) {
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_clear_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
future<Status> future_res = async(launch::async, RemoveTrafficSchedulers_, traffic_scheds);
future<int> push_alloc_cfg_complt = \
async(launch::async, TestRemoveTrafficSchedulers::PushAllocCfgResult, ALLOC_OBJECT_STATE_NOT_CONFIGURED, ALLOC_CFG_STATUS_SUCCESS);
Status status = future_res.get();
int res = push_alloc_cfg_complt.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - RemoveTrafficSchedulers-Upstream success case(alloc object is not reset)
TEST_F(TestRemoveTrafficSchedulers, UpstreamAllocObjNotReset) {
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_clear_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
future<Status> future_res = async(launch::async, RemoveTrafficSchedulers_, traffic_scheds);
future<int> push_alloc_cfg_complt = \
async(launch::async, TestRemoveTrafficSchedulers::PushAllocCfgResult, ALLOC_OBJECT_STATE_INACTIVE, ALLOC_CFG_STATUS_SUCCESS);
Status status = future_res.get();
int res = push_alloc_cfg_complt.get();
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 3 - RemoveTrafficSchedulers-Upstream success case(ONU case - Don't wait for alloc object delete response)
TEST_F(TestRemoveTrafficSchedulers, UpstreamAllocObjPonDisable) {
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_clear_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
bcmos_errno onu_cfg_get_res = BCM_ERR_OK;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_INACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
future<Status> future_res = async(launch::async, RemoveTrafficSchedulers_, traffic_scheds);
Status status = future_res.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 4 - RemoveTrafficSchedulers-Upstream success case(Get PON State failure case)
TEST_F(TestRemoveTrafficSchedulers, UpstreamAllocObjGetPonStateFailure) {
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_clear_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
bcmos_errno onu_cfg_get_res = BCM_ERR_INTERNAL;
bcmolt_onu_cfg onu_cfg_out;
bcmolt_onu_key onu_key;
onu_key.pon_ni = 0;
onu_key.onu_id = 1;
BCMOLT_CFG_INIT(&onu_cfg_out, onu, onu_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([onu_cfg_get_res, &onu_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_onu_cfg* o_cfg = (bcmolt_onu_cfg*)cfg;
o_cfg->data.onu_state = BCMOLT_ONU_STATE_INACTIVE;
memcpy(&onu_cfg_out, o_cfg, sizeof(bcmolt_onu_cfg));
return onu_cfg_get_res;
}
));
future<Status> future_res = async(launch::async, RemoveTrafficSchedulers_, traffic_scheds);
Status status = future_res.get();
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 5 - RemoveTrafficSchedulers-Upstream Failure case
TEST_F(TestRemoveTrafficSchedulers, RemoveTrafficSchedulersUpstreamFailure) {
traffic_sched->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_clear_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
Status status = RemoveTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 6 - RemoveTrafficSchedulers-Downstream Failure case
TEST_F(TestRemoveTrafficSchedulers, RemoveTrafficSchedulersDownstreamFailure) {
//Create Scheduler
scheduler->set_direction(tech_profile::Direction::DOWNSTREAM);
traffic_sched->set_direction(tech_profile::Direction::DOWNSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
CreateTrafficSchedulers_(traffic_scheds);
bcmos_errno olt_cfg_clear_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
Status status = RemoveTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 7 - RemoveTrafficSchedulers-Downstream success case
TEST_F(TestRemoveTrafficSchedulers, RemoveTrafficSchedulersDownstreamSuccess) {
//Create Scheduler
scheduler->set_direction(tech_profile::Direction::DOWNSTREAM);
traffic_sched->set_direction(tech_profile::Direction::DOWNSTREAM);
traffic_sched->set_allocated_scheduler(scheduler);
CreateTrafficSchedulers_(traffic_scheds);
bcmos_errno olt_cfg_clear_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
Status status = RemoveTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 8 - RemoveTrafficSchedulers-Downstream Scheduler not present case
TEST_F(TestRemoveTrafficSchedulers, RemoveTrafficSchedulersDownstreamSchedNotpresent) {
traffic_sched->set_direction(tech_profile::Direction::DOWNSTREAM);
Status status = RemoveTrafficSchedulers_(traffic_scheds);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing CreateTrafficQueues functionality
////////////////////////////////////////////////////////////////////////////
class TestCreateTrafficQueues : public Test {
protected:
NiceMock<BalMocker> balMock;
tech_profile::TrafficQueues* traffic_queues;
tech_profile::TrafficQueue* traffic_queue_1;
tech_profile::TrafficQueue* traffic_queue_2;
tech_profile::DiscardConfig* discard_config_1;
tech_profile::DiscardConfig* discard_config_2;
tech_profile::TailDropDiscardConfig* tail_drop_discard_config_1;
tech_profile::TailDropDiscardConfig* tail_drop_discard_config_2;
virtual void SetUp() {
traffic_queues = new tech_profile::TrafficQueues;
traffic_queues->set_intf_id(0);
traffic_queues->set_onu_id(1);
traffic_queue_1 = traffic_queues->add_traffic_queues();
traffic_queue_1->set_gemport_id(1024);
traffic_queue_1->set_pbit_map("0b00000101");
traffic_queue_1->set_aes_encryption(true);
traffic_queue_1->set_sched_policy(tech_profile::SchedulingPolicy::StrictPriority);
traffic_queue_1->set_priority(0);
traffic_queue_1->set_weight(0);
traffic_queue_1->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
discard_config_1 = new tech_profile::DiscardConfig;
discard_config_1->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
tail_drop_discard_config_1 = new tech_profile::TailDropDiscardConfig;
tail_drop_discard_config_1->set_queue_size(8);
discard_config_1->set_allocated_tail_drop_discard_config(tail_drop_discard_config_1);
traffic_queue_1->set_allocated_discard_config(discard_config_1);
}
virtual void TearDown() {
}
public:
static int PushGemCfgResult(GemObjectState state, GemCfgStatus status, uint32_t gem_port_id) {
gem_cfg_compltd_key k(0, gem_port_id);
gem_cfg_complete_result res;
res.pon_intf_id = 0;
res.gem_port_id = gem_port_id;
res.state = state;
res.status = status;
uint32_t gem_cfg_key_check_counter = 1;
std::map<gem_cfg_compltd_key, Queue<gem_cfg_complete_result> *>::iterator it;
while(true) {
bcmos_fastlock_lock(&gem_cfg_wait_lock);
it = gem_cfg_compltd_map.find(k);
if (it != gem_cfg_compltd_map.end()) {
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
break;
} else if (it == gem_cfg_compltd_map.end() && gem_cfg_key_check_counter < MAX_GEM_CFG_KEY_CHECK) {
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
// We need to wait for some time to allow the Gem Cfg Request to be triggered
// before we push the result.
bcmos_usleep(6000);
} else {
OPENOLT_LOG(ERROR, openolt_log_id, "gem config key not found for gem_port_id = %u, pon_intf = %u\n", gem_port_id, 0);
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
return 0;
}
gem_cfg_key_check_counter++;
}
bcmos_fastlock_lock(&gem_cfg_wait_lock);
if (it->second) {
it->second->push(res);
OPENOLT_LOG(INFO, openolt_log_id, "Pushed mocked gem cfg result\n");
}
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
return 0;
}
};
// Test 1 - CreateTrafficQueues-Upstream/Downstream FIXED_QUEUE success case
TEST_F(TestCreateTrafficQueues, CreateUpstreamDownstreamFixedQueueSuccess) {
traffic_queues->set_uni_id(0);
traffic_queues->set_port_no(16);
traffic_queue_1->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
future<Status> future_res = async(launch::async, CreateTrafficQueues_, traffic_queues);
future<int> push_gem_cfg_complt = \
async(launch::async, TestCreateTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_ACTIVE, GEM_CFG_STATUS_SUCCESS, 1024);
Status status = future_res.get();
int res = push_gem_cfg_complt.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
traffic_queue_1->set_direction(tech_profile::Direction::DOWNSTREAM);
status = CreateTrafficQueues_(traffic_queues);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - CreateTrafficQueues-Upstream PRIORITY_TO_QUEUE success case
TEST_F(TestCreateTrafficQueues, CreateUpstreamPriorityQueueSuccess) {
traffic_queues->set_uni_id(1);
traffic_queues->set_port_no(32);
traffic_queue_1->set_direction(tech_profile::Direction::UPSTREAM);
traffic_queue_2 = traffic_queues->add_traffic_queues();
traffic_queue_2->set_gemport_id(1025);
traffic_queue_2->set_pbit_map("0b00001010");
traffic_queue_2->set_aes_encryption(true);
traffic_queue_2->set_sched_policy(tech_profile::SchedulingPolicy::StrictPriority);
traffic_queue_2->set_priority(1);
traffic_queue_2->set_weight(0);
traffic_queue_2->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
discard_config_2 = new tech_profile::DiscardConfig;
discard_config_2->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
tail_drop_discard_config_2 = new tech_profile::TailDropDiscardConfig;
tail_drop_discard_config_2->set_queue_size(8);
discard_config_2->set_allocated_tail_drop_discard_config(tail_drop_discard_config_2);
traffic_queue_2->set_allocated_discard_config(discard_config_2);
traffic_queue_2->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
future<Status> future_res = async(launch::async, CreateTrafficQueues_, traffic_queues);
future<int> push_gem_cfg_complt = \
async(launch::async, TestCreateTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_ACTIVE, GEM_CFG_STATUS_SUCCESS, 1024);
std::this_thread::sleep_for(std::chrono::milliseconds(100));
push_gem_cfg_complt = \
async(launch::async, TestCreateTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_ACTIVE, GEM_CFG_STATUS_SUCCESS, 1025);
Status status = future_res.get();
int res = push_gem_cfg_complt.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 3 - CreateTrafficQueues-Upstream create tm queue mapping profile failure case
TEST_F(TestCreateTrafficQueues, CreateUpstreamPriorityQueueTMQMPCreationFailure) {
traffic_queues->set_uni_id(2);
traffic_queues->set_port_no(16);
traffic_queue_1->set_direction(tech_profile::Direction::UPSTREAM);
traffic_queue_2 = traffic_queues->add_traffic_queues();
traffic_queue_2->set_gemport_id(1025);
traffic_queue_2->set_pbit_map("0b10001010");
traffic_queue_2->set_aes_encryption(true);
traffic_queue_2->set_sched_policy(tech_profile::SchedulingPolicy::StrictPriority);
traffic_queue_2->set_priority(1);
traffic_queue_2->set_weight(0);
traffic_queue_2->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
discard_config_2 = new tech_profile::DiscardConfig;
discard_config_2->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
tail_drop_discard_config_2 = new tech_profile::TailDropDiscardConfig;
tail_drop_discard_config_2->set_queue_size(8);
discard_config_2->set_allocated_tail_drop_discard_config(tail_drop_discard_config_2);
traffic_queue_2->set_allocated_discard_config(discard_config_2);
traffic_queue_2->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_set_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = CreateTrafficQueues_(traffic_queues);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 4 - CreateTrafficQueues-Upstream PRIORITY_TO_QUEUE TM QMP already present case
TEST_F(TestCreateTrafficQueues, CreateUpstreamPriorityQueueTMQMPAlreadyPresent) {
traffic_queues->set_uni_id(3);
traffic_queues->set_port_no(16);
traffic_queue_1->set_direction(tech_profile::Direction::UPSTREAM);
traffic_queue_2 = traffic_queues->add_traffic_queues();
traffic_queue_2->set_gemport_id(1025);
traffic_queue_2->set_pbit_map("0b00001010");
traffic_queue_2->set_aes_encryption(true);
traffic_queue_2->set_sched_policy(tech_profile::SchedulingPolicy::StrictPriority);
traffic_queue_2->set_priority(1);
traffic_queue_2->set_weight(0);
traffic_queue_2->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
discard_config_2 = new tech_profile::DiscardConfig;
discard_config_2->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
tail_drop_discard_config_2 = new tech_profile::TailDropDiscardConfig;
tail_drop_discard_config_2->set_queue_size(8);
discard_config_2->set_allocated_tail_drop_discard_config(tail_drop_discard_config_2);
traffic_queue_2->set_allocated_discard_config(discard_config_2);
traffic_queue_2->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
future<Status> future_res = async(launch::async, CreateTrafficQueues_, traffic_queues);
future<int> push_gem_cfg_complt = \
async(launch::async, TestCreateTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_ACTIVE, GEM_CFG_STATUS_SUCCESS, 1024);
std::this_thread::sleep_for(std::chrono::milliseconds(100));
push_gem_cfg_complt = \
async(launch::async, TestCreateTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_ACTIVE, GEM_CFG_STATUS_SUCCESS, 1025);
Status status = future_res.get();
int res = push_gem_cfg_complt.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 5 - CreateTrafficQueues-Downstream PRIORITY_TO_QUEUE TM QMP Max count reached case
TEST_F(TestCreateTrafficQueues, CreateDownstreamPriorityQueueReachedMaxTMQMPCount) {
int uni_ids[17] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17};
int port_nos[17] = {16, 32, 48, 64, 80, 96, 112, 128, 144, 160, 176, 192, 208, 224, 240, 256, 272};
std::string pbit_maps[17] = {"0b00001010", "0b10001010", "0b00000001", "0b00000010", "0b00000100", "0b00001000", "0b00010000", "0b00100000", "0b01000000", "0b10000000", "0b10000001", "0b10000010", "0b10000100", "0b10001000", "0b10010000", "0b10100000", "0b11000000"};
traffic_queue_2 = traffic_queues->add_traffic_queues();
for(int i=0; i<sizeof(uni_ids)/sizeof(uni_ids[0]); i++) {
traffic_queues->set_uni_id(uni_ids[i]);
traffic_queues->set_port_no(port_nos[i]);
traffic_queue_1->set_direction(tech_profile::Direction::DOWNSTREAM);
traffic_queue_2->set_gemport_id(1025);
traffic_queue_2->set_pbit_map(pbit_maps[i]);
traffic_queue_2->set_aes_encryption(true);
traffic_queue_2->set_sched_policy(tech_profile::SchedulingPolicy::StrictPriority);
traffic_queue_2->set_priority(1);
traffic_queue_2->set_weight(0);
traffic_queue_2->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
discard_config_2 = new tech_profile::DiscardConfig;
discard_config_2->set_discard_policy(tech_profile::DiscardPolicy::TailDrop);
tail_drop_discard_config_2 = new tech_profile::TailDropDiscardConfig;
tail_drop_discard_config_2->set_queue_size(8);
discard_config_2->set_allocated_tail_drop_discard_config(tail_drop_discard_config_2);
traffic_queue_2->set_allocated_discard_config(discard_config_2);
traffic_queue_2->set_direction(tech_profile::Direction::DOWNSTREAM);
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
future<Status> future_res = async(launch::async, CreateTrafficQueues_, traffic_queues);
future<int> push_gem_cfg_complt = \
async(launch::async, TestCreateTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_ACTIVE, GEM_CFG_STATUS_SUCCESS, 1024);
std::this_thread::sleep_for(std::chrono::milliseconds(100));
push_gem_cfg_complt = \
async(launch::async, TestCreateTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_ACTIVE, GEM_CFG_STATUS_SUCCESS, 1025);
Status status = future_res.get();
int res = push_gem_cfg_complt.get();
if(i==16)
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
else
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
}
// Test 6 - CreateTrafficQueues-Upstream FIXED_QUEUE failure case
TEST_F(TestCreateTrafficQueues, CreateUpstreamFixedQueueFailure) {
traffic_queues->set_uni_id(0);
traffic_queues->set_port_no(16);
traffic_queue_1->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_set_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = CreateTrafficQueues_(traffic_queues);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing RemoveTrafficQueues functionality
////////////////////////////////////////////////////////////////////////////
class TestRemoveTrafficQueues : public Test {
protected:
NiceMock<BalMocker> balMock;
tech_profile::TrafficQueues* traffic_queues;
tech_profile::TrafficQueue* traffic_queue_1;
tech_profile::TrafficQueue* traffic_queue_2;
uint32_t pon_id = 0;
virtual void SetUp() {
traffic_queues = new tech_profile::TrafficQueues;
traffic_queues->set_intf_id(0);
traffic_queues->set_onu_id(1);
traffic_queue_1 = traffic_queues->add_traffic_queues();
traffic_queue_1->set_gemport_id(1024);
traffic_queue_1->set_priority(0);
}
virtual void TearDown() {
}
public:
static int PushGemCfgResult(GemObjectState state, GemCfgStatus status, uint32_t gem_port_id) {
gem_cfg_compltd_key k(0, gem_port_id);
gem_cfg_complete_result res;
res.pon_intf_id = 0;
res.gem_port_id = gem_port_id;
res.state = state;
res.status = status;
uint32_t gem_cfg_key_check_counter = 1;
std::map<gem_cfg_compltd_key, Queue<gem_cfg_complete_result> *>::iterator it;
while(true) {
bcmos_fastlock_lock(&gem_cfg_wait_lock);
it = gem_cfg_compltd_map.find(k);
if (it != gem_cfg_compltd_map.end()) {
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
break;
} else if (it == gem_cfg_compltd_map.end() && gem_cfg_key_check_counter < MAX_GEM_CFG_KEY_CHECK) {
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
// We need to wait for some time to allow the Gem Cfg Request to be triggered
// before we push the result.
bcmos_usleep(6000);
} else {
OPENOLT_LOG(ERROR, openolt_log_id, "gem config key not found for gem_port_id = %u, pon_intf = %u\n", gem_port_id, 0);
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
return 0;
}
gem_cfg_key_check_counter++;
}
bcmos_fastlock_lock(&gem_cfg_wait_lock);
if (it->second) {
it->second->push(res);
OPENOLT_LOG(INFO, openolt_log_id, "Pushed mocked gem cfg result\n");
}
bcmos_fastlock_unlock(&gem_cfg_wait_lock, 0);
return 0;
}
};
// Test 1 - RemoveTrafficQueues-Upstream/Downstream FIXED_QUEUE success case
TEST_F(TestRemoveTrafficQueues, RemoveUpstreamDownstreamFixedQueueSuccess) {
traffic_queues->set_uni_id(0);
traffic_queues->set_port_no(16);
traffic_queue_1->set_direction(tech_profile::Direction::UPSTREAM);
bcmos_errno olt_cfg_clear_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
future<Status> future_res = async(launch::async, RemoveTrafficQueues_, traffic_queues);
future<int> push_gem_cfg_complt = \
async(launch::async, TestRemoveTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_NOT_CONFIGURED, GEM_CFG_STATUS_SUCCESS, 1024);
Status status = future_res.get();
int res = push_gem_cfg_complt.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
traffic_queue_1->set_direction(tech_profile::Direction::DOWNSTREAM);
status = RemoveTrafficQueues_(traffic_queues);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - RemoveTrafficQueues-Downstream FIXED_QUEUE failure case
TEST_F(TestRemoveTrafficQueues, RemoveUpstreamDownstreamFixedQueueFailure) {
traffic_queues->set_uni_id(0);
traffic_queues->set_port_no(16);
traffic_queue_1->set_direction(tech_profile::Direction::DOWNSTREAM);
bcmos_errno olt_cfg_clear_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
Status status = RemoveTrafficQueues_(traffic_queues);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 3 - RemoveTrafficQueues-Downstream_QUEUE not present case
TEST_F(TestRemoveTrafficQueues, RemoveDownstreamFixedQueueNotPresent) {
//Remove scheduler so that is_tm_sched_id_present api call will return false
tech_profile::TrafficSchedulers* traffic_scheds;
tech_profile::TrafficScheduler* traffic_sched;
traffic_scheds = new tech_profile::TrafficSchedulers;
traffic_scheds->set_intf_id(0);
traffic_scheds->set_onu_id(1);
traffic_scheds->set_uni_id(0);
traffic_scheds->set_port_no(16);
traffic_sched = traffic_scheds->add_traffic_scheds();
traffic_sched->set_alloc_id(1024);
traffic_sched->set_direction(tech_profile::Direction::DOWNSTREAM);
bcmos_errno olt_cfg_clear_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
RemoveTrafficSchedulers_(traffic_scheds);
traffic_queues->set_uni_id(0);
traffic_queues->set_port_no(16);
traffic_queue_1->set_direction(tech_profile::Direction::DOWNSTREAM);
Status status = RemoveTrafficQueues_(traffic_queues);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
/* Test 4 - RemoveTrafficQueues-Upstream PRIORITY_TO_QUEUE, not removing TM QMP
as it is getting referred by some other queues case */
TEST_F(TestRemoveTrafficQueues, RemoveUpstreamPriorityQueueNotRemovingTMQMP) {
traffic_queues->set_uni_id(3);
traffic_queues->set_port_no(16);
traffic_queue_1->set_direction(tech_profile::Direction::UPSTREAM);
traffic_queue_2 = traffic_queues->add_traffic_queues();
traffic_queue_2->set_gemport_id(1025);
traffic_queue_2->set_priority(1);
traffic_queue_2->set_direction(tech_profile::Direction::UPSTREAM);
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
future<Status> future_res = async(launch::async, RemoveTrafficQueues_, traffic_queues);
future<int> push_gem_cfg_complt = \
async(launch::async, TestRemoveTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_NOT_CONFIGURED, GEM_CFG_STATUS_SUCCESS, 1024);
std::this_thread::sleep_for(std::chrono::milliseconds(100));
push_gem_cfg_complt = \
async(launch::async, TestRemoveTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_NOT_CONFIGURED, GEM_CFG_STATUS_SUCCESS, 1025);
Status status = future_res.get();
int res = push_gem_cfg_complt.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
/* Test 5 - RemoveTrafficQueues-Downstream PRIORITY_TO_QUEUE, removing TM QMP as it
is not getting referred by any other queues case */
TEST_F(TestRemoveTrafficQueues, RemoveDownstreamPriorityQueueRemovingTMQMP) {
traffic_queues->set_uni_id(5);
traffic_queues->set_port_no(80);
traffic_queue_1->set_direction(tech_profile::Direction::DOWNSTREAM);
traffic_queue_2 = traffic_queues->add_traffic_queues();
traffic_queue_2->set_gemport_id(1025);
traffic_queue_2->set_priority(1);
traffic_queue_2->set_direction(tech_profile::Direction::DOWNSTREAM);
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
bcmos_errno olt_cfg_clear_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_cfg_clear(_, _)).WillByDefault(Return(olt_cfg_clear_res));
future<Status> future_res = async(launch::async, RemoveTrafficQueues_, traffic_queues);
future<int> push_gem_cfg_complt = \
async(launch::async, TestRemoveTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_NOT_CONFIGURED, GEM_CFG_STATUS_SUCCESS, 1024);
std::this_thread::sleep_for(std::chrono::milliseconds(100));
push_gem_cfg_complt = \
async(launch::async, TestRemoveTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_NOT_CONFIGURED, GEM_CFG_STATUS_SUCCESS, 1025);
Status status = future_res.get();
int res = push_gem_cfg_complt.get();
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
/* Test 6 - RemoveTrafficQueues-Downstream PRIORITY_TO_QUEUE, error while removing TM QMP
having no reference to any other queues case */
TEST_F(TestRemoveTrafficQueues, RemoveDownstreamPriorityQueueErrorRemovingTMQMP) {
traffic_queues->set_uni_id(4);
traffic_queues->set_port_no(64);
traffic_queue_1->set_direction(tech_profile::Direction::DOWNSTREAM);
traffic_queue_2 = traffic_queues->add_traffic_queues();
traffic_queue_2->set_gemport_id(1025);
traffic_queue_2->set_priority(1);
traffic_queue_2->set_direction(tech_profile::Direction::DOWNSTREAM);
bcmolt_pon_interface_key pon_key;
bcmolt_pon_interface_cfg pon_cfg;
pon_key.pon_ni = pon_id;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, pon_key);
pon_cfg.data.state = BCMOLT_INTERFACE_STATE_ACTIVE_WORKING;
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
bcmos_errno olt_cfg_clear_res_success = BCM_ERR_OK;
bcmos_errno olt_cfg_clear_res_failure = BCM_ERR_INTERNAL;
EXPECT_CALL(balMock, bcmolt_cfg_clear(_, _))
.WillOnce(Return(olt_cfg_clear_res_success))
.WillOnce(Return(olt_cfg_clear_res_success))
.WillOnce(Return(olt_cfg_clear_res_success))
.WillOnce(Return(olt_cfg_clear_res_success))
.WillRepeatedly(Return(olt_cfg_clear_res_failure));
future<Status> future_res = async(launch::async, RemoveTrafficQueues_, traffic_queues);
future<int> push_gem_cfg_complt = \
async(launch::async, TestRemoveTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_NOT_CONFIGURED, GEM_CFG_STATUS_SUCCESS, 1024);
std::this_thread::sleep_for(std::chrono::milliseconds(100));
push_gem_cfg_complt = \
async(launch::async, TestRemoveTrafficQueues::PushGemCfgResult, GEM_OBJECT_STATE_NOT_CONFIGURED, GEM_CFG_STATUS_SUCCESS, 1025);
Status status = future_res.get();
int res = push_gem_cfg_complt.get();
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing OnuItuPonAlarmSet functionality
////////////////////////////////////////////////////////////////////////////
class TestOnuItuPonAlarmSet : public Test {
protected:
bcmolt_pon_ni pon_ni = 0;
bcmolt_onu_id onu_id = 1;
config::OnuItuPonAlarm *onu_itu_pon_alarm_rt;
config::OnuItuPonAlarm::RateThresholdConfig *rate_threshold_config;
config::OnuItuPonAlarm::SoakTime *soak_time_rt;
config::OnuItuPonAlarm *onu_itu_pon_alarm_rr;
config::OnuItuPonAlarm::RateRangeConfig *rate_range_config;
config::OnuItuPonAlarm::SoakTime *soak_time_rr;
config::OnuItuPonAlarm *onu_itu_pon_alarm_tc;
config::OnuItuPonAlarm::ValueThresholdConfig *value_threshold_config;
config::OnuItuPonAlarm::SoakTime *soak_time_tc;
NiceMock<BalMocker> balMock;
virtual void SetUp() {
onu_itu_pon_alarm_rt = new config::OnuItuPonAlarm;
rate_threshold_config = new config::OnuItuPonAlarm::RateThresholdConfig;
soak_time_rt = new config::OnuItuPonAlarm::SoakTime;
onu_itu_pon_alarm_rt->set_pon_ni(0);
onu_itu_pon_alarm_rt->set_onu_id(1);
onu_itu_pon_alarm_rt->set_alarm_id(config::OnuItuPonAlarm_AlarmID::OnuItuPonAlarm_AlarmID_RDI_ERRORS);
onu_itu_pon_alarm_rt->set_alarm_reporting_condition(config::OnuItuPonAlarm_AlarmReportingCondition::OnuItuPonAlarm_AlarmReportingCondition_RATE_THRESHOLD);
rate_threshold_config->set_rate_threshold_rising(1);
rate_threshold_config->set_rate_threshold_falling(4);
soak_time_rt->set_active_soak_time(2);
soak_time_rt->set_clear_soak_time(2);
rate_threshold_config->set_allocated_soak_time(soak_time_rt);
onu_itu_pon_alarm_rt->set_allocated_rate_threshold_config(rate_threshold_config);
onu_itu_pon_alarm_rr = new config::OnuItuPonAlarm;
rate_range_config = new config::OnuItuPonAlarm::RateRangeConfig;
soak_time_rr = new config::OnuItuPonAlarm::SoakTime;
onu_itu_pon_alarm_rr->set_pon_ni(0);
onu_itu_pon_alarm_rr->set_onu_id(1);
onu_itu_pon_alarm_rr->set_alarm_id(config::OnuItuPonAlarm_AlarmID::OnuItuPonAlarm_AlarmID_RDI_ERRORS);
onu_itu_pon_alarm_rr->set_alarm_reporting_condition(config::OnuItuPonAlarm_AlarmReportingCondition::OnuItuPonAlarm_AlarmReportingCondition_RATE_RANGE);
rate_range_config->set_rate_range_lower(1);
rate_range_config->set_rate_range_upper(4);
soak_time_rr->set_active_soak_time(2);
soak_time_rr->set_clear_soak_time(2);
rate_range_config->set_allocated_soak_time(soak_time_rr);
onu_itu_pon_alarm_rr->set_allocated_rate_range_config(rate_range_config);
onu_itu_pon_alarm_tc = new config::OnuItuPonAlarm;
value_threshold_config = new config::OnuItuPonAlarm::ValueThresholdConfig;
soak_time_tc = new config::OnuItuPonAlarm::SoakTime;
onu_itu_pon_alarm_tc->set_pon_ni(0);
onu_itu_pon_alarm_tc->set_onu_id(1);
onu_itu_pon_alarm_tc->set_alarm_id(config::OnuItuPonAlarm_AlarmID::OnuItuPonAlarm_AlarmID_RDI_ERRORS);
onu_itu_pon_alarm_tc->set_alarm_reporting_condition(config::OnuItuPonAlarm_AlarmReportingCondition::OnuItuPonAlarm_AlarmReportingCondition_VALUE_THRESHOLD);
value_threshold_config->set_threshold_limit(6);
soak_time_tc->set_active_soak_time(2);
soak_time_tc->set_clear_soak_time(2);
value_threshold_config->set_allocated_soak_time(soak_time_tc);
onu_itu_pon_alarm_tc->set_allocated_value_threshold_config(value_threshold_config);
}
virtual void TearDown() {
}
};
// Test 1 - OnuItuPonAlarmSet-Set RDI_errors to rate threshold type success case
// rate_threshold: The alarm is triggered if the stats delta value between samples crosses
// the configured threshold boundary.
TEST_F(TestOnuItuPonAlarmSet, OnuItuPonAlarmSetRdiErrorsRateThresholdTypeSuccess) {
bcmolt_onu_itu_pon_stats_cfg stat_cfg;
bcmolt_onu_key key = {};
BCMOLT_STAT_CFG_INIT(&stat_cfg, onu, itu_pon_stats, key);
stat_cfg.data.rdi_errors.trigger.type = BCMOLT_STAT_CONDITION_TYPE_RATE_THRESHOLD;
stat_cfg.data.rdi_errors.trigger.u.rate_threshold.rising = 50;
stat_cfg.data.rdi_errors.trigger.u.rate_threshold.falling = 100;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_stat_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = OnuItuPonAlarmSet_(onu_itu_pon_alarm_rt);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - OnuItuPonAlarmSet-Set RDI_errors to rate threshold type failure case
// rate_threshold: The alarm is triggered if the stats delta value between samples crosses
// the configured threshold boundary.
TEST_F(TestOnuItuPonAlarmSet, OnuItuPonAlarmSetRdiErrorsRateThresholdTypeFailure) {
bcmolt_onu_itu_pon_stats_cfg stat_cfg;
bcmolt_onu_key key = {};
BCMOLT_STAT_CFG_INIT(&stat_cfg, onu, itu_pon_stats, key);
stat_cfg.data.rdi_errors.trigger.type = BCMOLT_STAT_CONDITION_TYPE_RATE_THRESHOLD;
stat_cfg.data.rdi_errors.trigger.u.rate_threshold.rising = 50;
stat_cfg.data.rdi_errors.trigger.u.rate_threshold.falling = 100;
bcmos_errno olt_cfg_set_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_stat_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = OnuItuPonAlarmSet_(onu_itu_pon_alarm_rt);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 3 - OnuItuPonAlarmSet-Set RDI_errors to rate range type success case
// rate_range: The alarm is triggered if the stats delta value between samples deviates
// from the configured range.
TEST_F(TestOnuItuPonAlarmSet, OnuItuPonAlarmSetRdiErrorsRateRangeTypeSuccess) {
bcmolt_onu_itu_pon_stats_cfg stat_cfg;
bcmolt_onu_key key = {};
BCMOLT_STAT_CFG_INIT(&stat_cfg, onu, itu_pon_stats, key);
stat_cfg.data.rdi_errors.trigger.type = BCMOLT_STAT_CONDITION_TYPE_RATE_RANGE;
stat_cfg.data.rdi_errors.trigger.u.rate_range.upper = 100;
stat_cfg.data.rdi_errors.trigger.u.rate_range.lower = 50;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_stat_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = OnuItuPonAlarmSet_(onu_itu_pon_alarm_rr);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 4 - OnuItuPonAlarmSet-Set RDI_errors to rate range type failure case
// rate_range: The alarm is triggered if the stats delta value between samples deviates
// from the configured range.
TEST_F(TestOnuItuPonAlarmSet, OnuItuPonAlarmSetRdiErrorsRateRangeTypeFailure) {
bcmolt_onu_itu_pon_stats_cfg stat_cfg;
bcmolt_onu_key key = {};
BCMOLT_STAT_CFG_INIT(&stat_cfg, onu, itu_pon_stats, key);
stat_cfg.data.rdi_errors.trigger.type = BCMOLT_STAT_CONDITION_TYPE_RATE_RANGE;
stat_cfg.data.rdi_errors.trigger.u.rate_range.upper = 50;
stat_cfg.data.rdi_errors.trigger.u.rate_range.lower = 100;
bcmos_errno olt_cfg_set_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_stat_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = OnuItuPonAlarmSet_(onu_itu_pon_alarm_rr);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 5 - OnuItuPonAlarmSet-Set RDI_errors to value threshold type success case
// value_threshold: The alarm is raised if the stats sample value becomes greater than this
// level. The alarm is cleared when the host read the stats.
TEST_F(TestOnuItuPonAlarmSet, OnuItuPonAlarmSetRdiErrorsValueThresholdTypeSuccess) {
bcmolt_onu_itu_pon_stats_cfg stat_cfg;
bcmolt_onu_key key = {};
BCMOLT_STAT_CFG_INIT(&stat_cfg, onu, itu_pon_stats, key);
stat_cfg.data.rdi_errors.trigger.type = BCMOLT_STAT_CONDITION_TYPE_VALUE_THRESHOLD;
stat_cfg.data.rdi_errors.trigger.u.value_threshold.limit = 100;
bcmos_errno olt_cfg_set_res = BCM_ERR_OK;
ON_CALL(balMock, bcmolt_stat_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = OnuItuPonAlarmSet_(onu_itu_pon_alarm_tc);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 6 - OnuItuPonAlarmSet-Set RDI_errors to value threshold type failure case
// value_threshold: The alarm is raised if the stats sample value becomes greater than this
// level. The alarm is cleared when the host read the stats.
TEST_F(TestOnuItuPonAlarmSet, OnuItuPonAlarmSetRdiErrorsValueThresholdTypeFailure) {
bcmolt_onu_itu_pon_stats_cfg stat_cfg;
bcmolt_onu_key key = {};
BCMOLT_STAT_CFG_INIT(&stat_cfg, onu, itu_pon_stats, key);
stat_cfg.data.rdi_errors.trigger.type = BCMOLT_STAT_CONDITION_TYPE_VALUE_THRESHOLD;
stat_cfg.data.rdi_errors.trigger.u.value_threshold.limit = -1;
bcmos_errno olt_cfg_set_res = BCM_ERR_INTERNAL;
ON_CALL(balMock, bcmolt_stat_cfg_set(_, _)).WillByDefault(Return(olt_cfg_set_res));
Status status = OnuItuPonAlarmSet_(onu_itu_pon_alarm_tc);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing DeleteGroup functionality
////////////////////////////////////////////////////////////////////////////
class TestDeleteGroup : public Test {
protected:
uint32_t group_id = 1;
NiceMock<BalMocker> balMock;
virtual void SetUp() {
}
};
// Test 1 - DeleteGroup success case
TEST_F(TestDeleteGroup, DeleteGroupSuccess) {
bcmos_errno group_cfg_get_res = BCM_ERR_OK;
bcmos_errno group_cfg_clear_res = BCM_ERR_OK;
bcmolt_group_cfg grp_cfg_out;
bcmolt_group_key grp_key = {};
grp_key.id = group_id;
BCMOLT_CFG_INIT(&grp_cfg_out, group, grp_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([group_cfg_get_res, &grp_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_group_cfg* grp_cfg = (bcmolt_group_cfg*)cfg;
grp_cfg->data.state = BCMOLT_GROUP_STATE_CONFIGURED;
memcpy(&grp_cfg_out, grp_cfg, sizeof(bcmolt_group_cfg));
return group_cfg_get_res;
}
));
EXPECT_CALL(balMock, bcmolt_cfg_clear(_, _)).WillOnce(Return(group_cfg_clear_res));
Status status = DeleteGroup_(group_id);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - DeleteGroup failure case: Group does not exist
TEST_F(TestDeleteGroup, DeleteGroupFailure_NotFound) {
bcmos_errno group_cfg_get_res = BCM_ERR_OK;
bcmolt_group_cfg grp_cfg_out;
bcmolt_group_key grp_key = {};
grp_key.id = group_id;
BCMOLT_CFG_INIT(&grp_cfg_out, group, grp_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([group_cfg_get_res, &grp_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_group_cfg* grp_cfg = (bcmolt_group_cfg*)cfg;
grp_cfg->data.state = BCMOLT_GROUP_STATE_NOT_CONFIGURED;
memcpy(&grp_cfg_out, grp_cfg, sizeof(bcmolt_group_cfg));
return group_cfg_get_res;
}
));
Status status = DeleteGroup_(group_id);
ASSERT_TRUE( status.error_code() == grpc::StatusCode::NOT_FOUND );
}
// Test 3 - DeleteGroup failure case: Group exists but cannot be deleted (due to flow association etc.)
TEST_F(TestDeleteGroup, DeleteGroupFailure_CannotDelete) {
bcmos_errno group_cfg_get_res = BCM_ERR_OK;
bcmos_errno group_cfg_clear_res = BCM_ERR_INTERNAL;
bcmolt_group_cfg grp_cfg_out;
bcmolt_group_key grp_key = {};
grp_key.id = group_id;
BCMOLT_CFG_INIT(&grp_cfg_out, group, grp_key);
EXPECT_CALL(balMock, bcmolt_cfg_get(_, _)).WillOnce(Invoke([group_cfg_get_res, &grp_cfg_out] (bcmolt_oltid olt, bcmolt_cfg *cfg) {
bcmolt_group_cfg* grp_cfg = (bcmolt_group_cfg*)cfg;
grp_cfg->data.state = BCMOLT_GROUP_STATE_CONFIGURED;
memcpy(&grp_cfg_out, grp_cfg, sizeof(bcmolt_group_cfg));
return group_cfg_get_res;
}
));
EXPECT_CALL(balMock, bcmolt_cfg_clear(_, _)).WillOnce(Return(group_cfg_clear_res));
Status status = DeleteGroup_(group_id);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing OnuLogicalDistanceZero functionality
////////////////////////////////////////////////////////////////////////////
class TestOnuLogicalDistanceZero : public Test {
protected:
NiceMock<BalMocker> balMock;
bcmolt_pon_ni pon_ni = 0;
openolt::OnuLogicalDistance *onu_logical_distance_zero;
virtual void SetUp() {
onu_logical_distance_zero = new openolt::OnuLogicalDistance;
onu_logical_distance_zero->set_intf_id(pon_ni);
}
virtual void TearDown() {
}
};
//
// Test 1 - GetLogicalOnuDistanceZero-Get 0KM logical ONU distance success case
//
TEST_F(TestOnuLogicalDistanceZero, OnuLogicalDistanceZeroSuccess) {
bcmolt_pon_distance pon_distance = {};
bcmolt_pon_interface_cfg pon_cfg;
bcmolt_pon_interface_key key = {};
key.pon_ni = pon_ni;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, key);
state.activate();
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
Status status = GetLogicalOnuDistanceZero_(pon_ni, onu_logical_distance_zero);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - GetLogicalOnuDistanceZero-Get 0KM logical ONU distance failure case
// The PON state is not ready for failure case
//
TEST_F(TestOnuLogicalDistanceZero, OnuLogicalDistanceZeroPonStateFailure) {
bcmolt_pon_distance pon_distance = {};
bcmolt_pon_interface_cfg pon_cfg;
bcmolt_pon_interface_key key = {};
key.pon_ni = pon_ni;
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, key);
state.deactivate();
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_INTERNAL;
Status status = GetLogicalOnuDistanceZero_(pon_ni, onu_logical_distance_zero);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
class TestOnuLogicalDistance : public Test {
protected:
NiceMock<BalMocker> balMock;
bcmolt_pon_ni pon_ni = 0;
bcmolt_onu_id onu_id = 1;
openolt::OnuLogicalDistance *onu_logical_distance;
virtual void SetUp() {
onu_logical_distance = new openolt::OnuLogicalDistance;
onu_logical_distance->set_intf_id(pon_ni);
onu_logical_distance->set_onu_id(onu_id);
}
virtual void TearDown() {
}
};
//
// Test 1 - GetLogicalOnuDistance-Get logical ONU distance success case
//
TEST_F(TestOnuLogicalDistance, OnuLogicalDistanceSuccess) {
bcmolt_pon_distance pon_distance = {};
bcmolt_pon_interface_cfg pon_cfg;
bcmolt_pon_interface_key key = {};
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
key.pon_ni = pon_ni;
state.activate();
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, key);
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
bcmolt_onu_cfg onu_cfg;
bcmolt_onu_key onu_key = {};
bcmos_errno onu_cfg_get_stub_res = BCM_ERR_OK;
onu_key.pon_ni = pon_ni;
onu_key.onu_id = onu_id;
BCMOLT_CFG_INIT(&onu_cfg, onu, onu_key);
onu_cfg.data.onu_state = BCMOLT_ONU_STATE_ACTIVE;
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__onu_state_stub, bcmolt_cfg_get__onu_state_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltOnuCfg(onu_cfg), Return(onu_cfg_get_stub_res)));
Status status = GetLogicalOnuDistance_(pon_ni, onu_id, onu_logical_distance);
ASSERT_TRUE( status.error_message() == Status::OK.error_message() );
}
// Test 2 - GetLogicalOnuDistance-Get logical ONU distance failure case
// The failure case is for retrieving ONU ranging time
//
TEST_F(TestOnuLogicalDistance, OnuLogicalDistanceRetrieveOnuRangingTimeFailure) {
bcmolt_pon_distance pon_distance = {};
bcmolt_pon_interface_cfg pon_cfg;
bcmolt_pon_interface_key key = {};
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
key.pon_ni = pon_ni;
state.activate();
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, key);
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
bcmolt_onu_cfg onu_cfg;
bcmolt_onu_key onu_key = {};
bcmos_errno onu_cfg_get_stub_res = BCM_ERR_INTERNAL;
onu_key.pon_ni = pon_ni;
onu_key.onu_id = onu_id;
BCMOLT_CFG_INIT(&onu_cfg, onu, onu_key);
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__onu_state_stub, bcmolt_cfg_get__onu_state_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltOnuCfg(onu_cfg), Return(onu_cfg_get_stub_res)));
Status status = GetLogicalOnuDistance_(pon_ni, onu_id, onu_logical_distance);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
// Test 3 - GetLogicalOnuDistance-Get logical ONU distance failure case
// The failure case is for ONU is not yet activated
//
TEST_F(TestOnuLogicalDistance, OnuLogicalDistanceOnuNotActivatedFailure) {
bcmolt_pon_distance pon_distance = {};
bcmolt_pon_interface_cfg pon_cfg;
bcmolt_pon_interface_key key = {};
bcmos_errno olt_cfg_get_pon_stub_res = BCM_ERR_OK;
key.pon_ni = pon_ni;
state.activate();
BCMOLT_CFG_INIT(&pon_cfg, pon_interface, key);
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__pon_intf_stub, bcmolt_cfg_get__pon_intf_stub(_, _))
.WillOnce(DoAll(SetArg1ToBcmOltPonCfg(pon_cfg), Return(olt_cfg_get_pon_stub_res)));
bcmolt_onu_cfg onu_cfg;
bcmolt_onu_key onu_key = {};
bcmos_errno onu_cfg_get_stub_res = BCM_ERR_OK;
onu_key.pon_ni = pon_ni;
onu_key.onu_id = onu_id;
BCMOLT_CFG_INIT(&onu_cfg, onu, onu_key);
EXPECT_GLOBAL_CALL(bcmolt_cfg_get__onu_state_stub, bcmolt_cfg_get__onu_state_stub(_, _))
.WillRepeatedly(DoAll(SetArg1ToBcmOltOnuCfg(onu_cfg), Return(onu_cfg_get_stub_res)));
onu_cfg.data.onu_state = BCMOLT_ONU_STATE_INACTIVE;
Status status = GetLogicalOnuDistance_(pon_ni, onu_id, onu_logical_distance);
ASSERT_TRUE( status.error_message() != Status::OK.error_message() );
}
////////////////////////////////////////////////////////////////////////////
// For testing Secure Server functionality
////////////////////////////////////////////////////////////////////////////
class TestSecureServer : public Test {
protected:
virtual void SetUp() {}
virtual void TearDown() {}
};
TEST_F(TestSecureServer, StartInsecureServer) {
// const to prevent the following warning:
// warning: deprecated conversion from string constant to 'char*' [-Wwrite-strings]
const char *args[] = {"./openolt"};
int argc = sizeof(args) / sizeof(args[0]);
char **argv = const_cast<char**>(args);
bool ok = RunServer(argc, argv);
ASSERT_TRUE(ok);
OPENOLT_LOG(INFO, openolt_log_id, "insecure gRPC server has been started and shut down successfully\n");
}
TEST_F(TestSecureServer, StartWithInvalidTLSOption) {
const char *args[] = {"./openolt", "--enable-tls", "DUMMY_GRPC_SSL_DONT_REQUEST_CLIENT_CERTIFICATE"};
int argc = sizeof(args) / sizeof(args[0]);
char **argv = const_cast<char**>(args);
bool ok = RunServer(argc, argv);
ASSERT_FALSE(ok);
OPENOLT_LOG(INFO, openolt_log_id, "secure gRPC server could not be started due to invalid TLS option\n");
}
TEST_F(TestSecureServer, CertificatesAreMissing) {
const char *args[] = {"./openolt", "--enable-tls", "GRPC_SSL_DONT_REQUEST_CLIENT_CERTIFICATE"};
int argc = sizeof(args) / sizeof(args[0]);
char **argv = const_cast<char**>(args);
const std::string cmd = "exec [ -d './keystore' ] && rm -rf './keystore'";
int res = std::system(cmd.c_str());
if (res == 0) {
std::cout << "directory ./keystore is deleted\n";
} else {
std::cout << "directory ./keystore is not existing\n";
}
bool ok = RunServer(argc, argv);
ASSERT_FALSE(ok);
OPENOLT_LOG(INFO, openolt_log_id, "secure gRPC server could not be started due to missing certificates\n");
}
TEST_F(TestSecureServer, StartWithValidTLSOption) {
const char *args[] = {"./openolt", "--enable-tls", "GRPC_SSL_DONT_REQUEST_CLIENT_CERTIFICATE"};
int argc = sizeof(args) / sizeof(args[0]);
char **argv = const_cast<char**>(args);
const std::string cmd_1 = "exec cp -r ./keystore-test ./keystore";
const std::string cmd_2 = "exec rm -rf './keystore'";
int res = std::system(cmd_1.c_str());
if (res == 0) {
std::cout << "directory ./keystore is copied from ./keystore-test\n";
bool ok = RunServer(argc, argv);
ASSERT_TRUE(ok);
OPENOLT_LOG(INFO, openolt_log_id, "secure gRPC server has been started with the given certificates and TLS options, and shut down successfully\n");
res = std::system(cmd_2.c_str());
if (res == 0) {
std::cout << "directory ./keystore is deleted\n";
} else {
std::cerr << "directory ./keystore could not be deleted\n";
}
} else {
std::cerr << "directory ./keystore could not be prepared, err: " << res << '\n';
FAIL();
}
}
////////////////////////////////////////////////////////////////////////////
// For testing RxTx Power Read functionality
////////////////////////////////////////////////////////////////////////////
class TestPowerRead : public Test {
protected:
virtual void SetUp() {
std::array<char, 600> content = {};
content.fill(0x00); // not required for 0x00
// for asfvolt16
content[102] = 0x5D;
content[103] = 0x38;
content[104] = 0x1A;
content[105] = 0xB5;
// for asgvolt64
content[358] = 0x5C;
content[359] = 0x82;
content[360] = 0x04;
content[361] = 0xBE;
std::ofstream test_file;
test_file.open(file_name, std::ios::binary | std::ios::out);
test_file.write(content.data(), content.size());
test_file.close();
const std::string cmd = "exec hexdump -C " + file_name + " > " + hex_dump;
int res = std::system(cmd.c_str());
if (res == 0) {
std::ifstream dump_file(hex_dump) ;
std::string hexdump = { std::istreambuf_iterator<char>(dump_file), std::istreambuf_iterator<char>() };
std::cout << cmd << '\n';
std::cout << hexdump << '\n';
} else {
std::cerr << "hexdump capture failed\n";
}
}
virtual void TearDown() {
std::remove(file_name.c_str());
std::remove(hex_dump.c_str());
}
const std::string file_name = "eeprom.bin";
const std::string hex_dump = file_name + ".hexdump";
};
TEST_F(TestPowerRead, TestAsfvolt16) {
std::cout << "Test Power Reads on XGS-PON OLT:\n";
int port = 20;
auto trx_eeprom_reader1 = TrxEepromReader{TrxEepromReader::DEVICE_XGSPON, TrxEepromReader::RX_AND_TX_POWER, port};
std::cout << "\tis port #" << port << " valid? " << std::boolalpha << trx_eeprom_reader1.is_valid_port() << '\n';
ASSERT_FALSE(trx_eeprom_reader1.is_valid_port());
port = 0;
auto trx_eeprom_reader2 = TrxEepromReader{TrxEepromReader::DEVICE_XGSPON, TrxEepromReader::RX_AND_TX_POWER, port};
std::cout << "\tis port #" << port << " valid? " << trx_eeprom_reader2.is_valid_port() << '\n';
std::cout << "\tbuffer size: " << trx_eeprom_reader2.get_buf_size() << '\n';
std::cout << "\tread offset: " << trx_eeprom_reader2.get_read_offset() << '\n';
std::cout << "\tread num bytes: " << trx_eeprom_reader2.get_read_num_bytes() << '\n';
std::cout << "\tmax ports: " << trx_eeprom_reader2.get_max_ports() << '\n';
auto rxtx_power_raw = trx_eeprom_reader2.read_power_raw();
ASSERT_TRUE(rxtx_power_raw.second);
std::cout << "\tRx power - raw: (hex) " << std::hex << std::uppercase << std::setfill('0') << std::setw(4) << rxtx_power_raw.first.first
<< ", (dec) " << std::dec << std::setfill(' ') << std::setw(5) << rxtx_power_raw.first.first
<< " | " << std::dec << std::fixed << std::setprecision(5) << std::setw(8) << trx_eeprom_reader2.raw_rx_to_mw(rxtx_power_raw.first.first) << " mW, "
<< std::dec << std::setw(9) << trx_eeprom_reader2.mw_to_dbm(trx_eeprom_reader2.raw_rx_to_mw(rxtx_power_raw.first.first)) << " dBm\n";
std::cout << "\tTx power - raw: (hex) " << std::hex << std::uppercase << std::setfill('0') << std::setw(4) << rxtx_power_raw.first.second
<< ", (dec) " << std::dec << std::setfill(' ') << std::setw(5) << rxtx_power_raw.first.second
<< " | " << std::dec << std::fixed << std::setprecision(5) << std::setw(8) << trx_eeprom_reader2.raw_tx_to_mw(rxtx_power_raw.first.second) << " mW, "
<< std::dec << std::setw(9) << trx_eeprom_reader2.mw_to_dbm(trx_eeprom_reader2.raw_tx_to_mw(rxtx_power_raw.first.second)) << " dBm\n";
std::cout << "\tnode path: " << trx_eeprom_reader2.get_node_path() << '\n';
ASSERT_TRUE(trx_eeprom_reader2.is_valid_port());
ASSERT_EQ(trx_eeprom_reader2.get_buf_size(), 256);
ASSERT_EQ(trx_eeprom_reader2.get_read_offset(), 104);
ASSERT_EQ(trx_eeprom_reader2.get_read_num_bytes(), 2);
ASSERT_EQ(trx_eeprom_reader2.get_max_ports(), 20);
ASSERT_EQ(rxtx_power_raw.first.first, 0x1AB5); // 6837
ASSERT_EQ(rxtx_power_raw.first.second, 0x5D38); // 23864
ASSERT_STREQ(trx_eeprom_reader2.get_node_path(), "/sys/bus/i2c/devices/47-0050/sfp_eeprom");
}
TEST_F(TestPowerRead, TestAsgvolt64) {
std::cout << "Test Power Reads on GPON OLT:\n";
int port = 80;
auto trx_eeprom_reader1 = TrxEepromReader{TrxEepromReader::DEVICE_GPON, TrxEepromReader::RX_AND_TX_POWER, port};
std::cout << "\tis port #" << port << " valid? " << std::boolalpha << trx_eeprom_reader1.is_valid_port() << '\n';
ASSERT_FALSE(trx_eeprom_reader1.is_valid_port());
port = 0;
auto trx_eeprom_reader2 = TrxEepromReader{TrxEepromReader::DEVICE_GPON, TrxEepromReader::RX_AND_TX_POWER, port};
std::cout << "\tis port #" << port << " valid? " << trx_eeprom_reader2.is_valid_port() << '\n';
std::cout << "\tbuffer size: " << trx_eeprom_reader2.get_buf_size() << '\n';
std::cout << "\tread offset: " << trx_eeprom_reader2.get_read_offset() << '\n';
std::cout << "\tread num bytes: " << trx_eeprom_reader2.get_read_num_bytes() << '\n';
std::cout << "\tmax ports: " << trx_eeprom_reader2.get_max_ports() << '\n';
auto rxtx_power_raw = trx_eeprom_reader2.read_power_raw();
ASSERT_TRUE(rxtx_power_raw.second);
std::cout << "\tRx power - raw: (hex) " << std::hex << std::uppercase << std::setfill('0') << std::setw(4) << rxtx_power_raw.first.first
<< ", (dec) " << std::dec << std::setfill(' ') << std::setw(5) << rxtx_power_raw.first.first
<< " | " << std::dec << std::fixed << std::setprecision(5) << std::setw(8) << trx_eeprom_reader2.raw_rx_to_mw(rxtx_power_raw.first.first) << " mW, "
<< std::dec << std::setw(9) << trx_eeprom_reader2.mw_to_dbm(trx_eeprom_reader2.raw_rx_to_mw(rxtx_power_raw.first.first)) << " dBm\n";
std::cout << "\tTx power - raw: (hex) " << std::hex << std::uppercase << std::setfill('0') << std::setw(4) << rxtx_power_raw.first.second
<< ", (dec) " << std::dec << std::setfill(' ') << std::setw(5) << rxtx_power_raw.first.second
<< " | " << std::dec << std::fixed << std::setprecision(5) << std::setw(8) << trx_eeprom_reader2.raw_tx_to_mw(rxtx_power_raw.first.second) << " mW, "
<< std::dec << std::setw(9) << trx_eeprom_reader2.mw_to_dbm(trx_eeprom_reader2.raw_tx_to_mw(rxtx_power_raw.first.second)) << " dBm\n";
std::cout << "\tnode path: " << trx_eeprom_reader2.get_node_path() << '\n';
ASSERT_TRUE(trx_eeprom_reader2.is_valid_port());
ASSERT_EQ(trx_eeprom_reader2.get_buf_size(), 600);
ASSERT_EQ(trx_eeprom_reader2.get_read_offset(), 360);
ASSERT_EQ(trx_eeprom_reader2.get_read_num_bytes(), 2);
ASSERT_EQ(trx_eeprom_reader2.get_max_ports(), 74);
ASSERT_EQ(rxtx_power_raw.first.first, 0x04BE); // 1214
ASSERT_EQ(rxtx_power_raw.first.second, 0x5C82); // 23682
ASSERT_STREQ(trx_eeprom_reader2.get_node_path(), "/sys/bus/i2c/devices/41-0050/eeprom");
}