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diff --git a/docs/testing/user/testspecification/highavailability/index.rst b/docs/testing/user/testspecification/highavailability/index.rst
index e69de29b..715f84d0 100644
--- a/docs/testing/user/testspecification/highavailability/index.rst
+++ b/docs/testing/user/testspecification/highavailability/index.rst
@@ -0,0 +1,743 @@
+.. This work is licensed under a Creative Commons Attribution 4.0 International
+.. License.
+.. http://creativecommons.org/licenses/by/4.0
+.. (c) OPNFV, China Mobile and others.
+
+==========================================
+OpenStack Services HA test specification
+==========================================
+
+.. toctree::
+:maxdepth:
+
+Scope
+=====
+
+The HA test area evaluates the ability of the System Under Test to support service
+continuity and recovery from component failures on part of OpenStack controller services("nova-api",
+"neutron-server", "keystone", "glance-api", "cinder-api") and on "load balancer" service.
+
+The tests in this test area will emulate component failures by killing the
+processes of above target services, stressing the CPU load or blocking
+disk I/O on the selected controller node, and then check if the impacted
+services are still available and the killed processes are recovered on the
+selected controller node within a given time interval.
+
+
+References
+================
+
+This test area references the following specifications:
+
+- ETSI GS NFV-REL 001
+
+ - http://www.etsi.org/deliver/etsi_gs/NFV-REL/001_099/001/01.01.01_60/gs_nfv-rel001v010101p.pdf
+
+- OpenStack High Availability Guide
+
+ - https://docs.openstack.org/ha-guide/
+
+
+Definitions and abbreviations
+=============================
+
+The following terms and abbreviations are used in conjunction with this test area
+
+- SUT - system under test
+- Monitor - tools used to measure the service outage time and the process
+ outage time
+- Service outage time - the outage time (seconds) of the specific OpenStack
+ service
+- Process outage time - the outage time (seconds) from the specific processes
+ being killed to recovered
+
+
+System Under Test (SUT)
+=======================
+
+The system under test is assumed to be the NFVi and VIM in operation on a
+Pharos compliant infrastructure.
+
+SUT is assumed to be in high availability configuration, which typically means
+more than one controller nodes are in the System Under Test.
+
+Test Area Structure
+====================
+
+The HA test area is structured with the following test cases in a sequential
+manner.
+
+Each test case is able to run independently. Preceding test case's failure will
+not affect the subsequent test cases.
+
+Preconditions of each test case will be described in the following test
+descriptions.
+
+
+Test Descriptions
+=================
+
+---------------------------------------------------------------
+Test Case 1 - Controller node OpenStack service down - nova-api
+---------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ha.tc001.nova-api_service_down
+
+Use case specification
+----------------------
+
+This test case verifies the service continuity capability in the face of the
+software process failure. It kills the processes of OpenStack "nova-api"
+service on the selected controller node, then checks whether the "nova-api"
+service is still available during the failure, by creating a VM then deleting
+the VM, and checks whether the killed processes are recovered within a given
+time interval.
+
+
+Test preconditions
+------------------
+
+There is more than one controller node, which is providing the "nova-api"
+service for API end-point.
+Denoted a controller node as Node1 in the following configuration.
+
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for verifying service continuity and recovery
+'''''''''''''''''''''''''''''''''''''''''''''''''''''''''
+
+The service continuity and process recovery capabilities of "nova-api" service
+is evaluated by monitoring service outage time, process outage time, and results
+of nova operations.
+
+Service outage time is measured by continuously executing "openstack server list"
+command in loop and checking if the response of the command request is returned
+with no failure.
+When the response fails, the "nova-api" service is considered in outage.
+The time between the first response failure and the last response failure is
+considered as service outage time.
+
+Process outage time is measured by checking the status of "nova-api" processes on
+the selected controller node. The time of "nova-api" processes being killed to
+the time of the "nova-api" processes being recovered is the process outage time.
+Process recovery is verified by checking the existence of "nova-api" processes.
+
+All nova operations are carried out correctly within a given time interval which
+suggests that the "nova-api" service is continuously available.
+
+Test execution
+''''''''''''''
+* Test action 1: Connect to Node1 through SSH, and check that "nova-api"
+ processes are running on Node1
+* Test action 2: Create a image with "openstack image create test-cirros
+ --file cirros-0.3.5-x86_64-disk.img --disk-format qcow2 --container-format bare"
+* Test action 3: Execute"openstack flavor create m1.test --id auto --ram 512
+ --disk 1 --vcpus 1" to create flavor "m1.test".
+* Test action 4: Start two monitors: one for "nova-api" processes and the other
+ for "openstack server list" command.
+ Each monitor will run as an independent process
+* Test action 5: Connect to Node1 through SSH, and then kill the "nova-api"
+ processes
+* Test action 6: When "openstack server list" returns with no error, calculate
+ the service outage time, and execute command "openstack server create
+ --flavor m1.test --image test-cirros test-instance"
+* Test action 7: Continuously Execute "openstack server show test-instance"
+ to check if the status of VM "test-instance" is "Active"
+* Test action 8: If VM "test-instance" is "Active", execute "openstack server
+ delete test-instance", then execute "openstack server list" to check if the
+ VM is not in the list
+* Test action 9: Continuously measure process outage time from the monitor until
+ the process outage time is more than 30s
+
+Pass / fail criteria
+''''''''''''''''''''
+
+The process outage time is less than 30s.
+
+The service outage time is less than 5s.
+
+The nova operations are carried out in above order and no errors occur.
+
+A negative result will be generated if the above is not met in completion.
+
+Post conditions
+---------------
+
+Restart the process of "nova-api" if they are not running.
+Delete image with "openstack image delete test-cirros"
+Delete flavor with "openstack flavor delete m1.test"
+
+
+---------------------------------------------------------------------
+Test Case 2 - Controller node OpenStack service down - neutron-server
+---------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ha.tc002.neutron-server_service_down
+
+Use case specification
+----------------------
+
+This test verifies the high availability of the "neutron-server" service
+provided by OpenStack controller nodes. It kills the processes of OpenStack
+"neutron-server" service on the selected controller node, then checks whether
+the "neutron-server" service is still available, by creating a network and
+deleting the network, and checks whether the killed processes are recovered.
+
+Test preconditions
+------------------
+
+There is more than one controller node, which is providing the "neutron-server"
+service for API end-point.
+Denoted a controller node as Node1 in the following configuration.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for monitoring high availability
+''''''''''''''''''''''''''''''''''''''''''''
+
+The high availability of "neutron-server" service is evaluated by monitoring
+service outage time, process outage time, and results of neutron operations.
+
+Service outage time is tested by continuously executing "openstack router list"
+command in loop and checking if the response of the command request is returned
+with no failure.
+When the response fails, the "neutron-server" service is considered in outage.
+The time between the first response failure and the last response failure is
+considered as service outage time.
+
+Process outage time is tested by checking the status of "neutron-server"
+processes on the selected controller node. The time of "neutron-server"
+processes being killed to the time of the "neutron-server" processes being
+recovered is the process outage time. Process recovery is verified by checking
+the existence of "neutron-server" processes.
+
+Test execution
+''''''''''''''
+
+* Test action 1: Connect to Node1 through SSH, and check that "neutron-server"
+ processes are running on Node1
+* Test action 2: Start two monitors: one for "neutron-server" process and the
+ other for "openstack router list" command.
+ Each monitor will run as an independent process.
+* Test action 3: Connect to Node1 through SSH, and then kill the
+ "neutron-server" processes
+* Test action 4: When "openstack router list" returns with no error, calculate
+ the service outage time, and execute "openstack network create test-network"
+* Test action 5: Continuously executing "openstack network show test-network",
+ check if the status of "test-network" is "Active"
+* Test action 6: If "test-network" is "Active", execute "openstack network
+ delete test-network", then execute "openstack network list" to check if the
+ "test-network" is not in the list
+* Test action 7: Continuously measure process outage time from the monitor until
+ the process outage time is more than 30s
+
+Pass / fail criteria
+''''''''''''''''''''
+
+The process outage time is less than 30s.
+
+The service outage time is less than 5s.
+
+The neutron operations are carried out in above order and no errors occur.
+
+A negative result will be generated if the above is not met in completion.
+
+Post conditions
+---------------
+
+Restart the processes of "neutron-server" if they are not running.
+
+
+---------------------------------------------------------------
+Test Case 3 - Controller node OpenStack service down - keystone
+---------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ha.tc003.keystone_service_down
+
+Use case specification
+----------------------
+
+This test verifies the high availability of the "keystone" service provided by
+OpenStack controller nodes. It kills the processes of OpenStack "keystone"
+service on the selected controller node, then checks whether the "keystone"
+service is still available by executing command "openstack user list" and
+whether the killed processes are recovered.
+
+Test preconditions
+------------------
+
+There is more than one controller node, which is providing the "keystone"
+service for API end-point.
+Denoted a controller node as Node1 in the following configuration.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for monitoring high availability
+''''''''''''''''''''''''''''''''''''''''''''
+
+The high availability of "keystone" service is evaluated by monitoring service
+outage time and process outage time
+
+Service outage time is tested by continuously executing "openstack user list"
+command in loop and checking if the response of the command request is reutrned
+with no failure.
+When the response fails, the "keystone" service is considered in outage.
+The time between the first response failure and the last response failure is
+considered as service outage time.
+
+Process outage time is tested by checking the status of "keystone" processes on
+the selected controller node. The time of "keystone" processes being killed to
+the time of the "keystone" processes being recovered is the process outage
+time. Process recovery is verified by checking the existence of "keystone"
+processes.
+
+Test execution
+''''''''''''''
+
+* Test action 1: Connect to Node1 through SSH, and check that "keystone"
+ processes are running on Node1
+* Test action 2: Start two monitors: one for "keystone" process and the other
+ for "openstack user list" command.
+ Each monitor will run as an independent process.
+* Test action 3: Connect to Node1 through SSH, and then kill the "keystone"
+ processes
+* Test action 4: Calculate the service outage time and process outage time
+* Test action 5: The test passes if process outage time is less than 20s and
+ service outage time is less than 5s
+* Test action 6: Continuously measure process outage time from the monitor until
+ the process outage time is more than 30s
+
+Pass / fail criteria
+''''''''''''''''''''
+
+The process outage time is less than 30s.
+
+The service outage time is less than 5s.
+
+A negative result will be generated if the above is not met in completion.
+
+Post conditions
+---------------
+
+Restart the processes of "keystone" if they are not running.
+
+
+-----------------------------------------------------------------
+Test Case 4 - Controller node OpenStack service down - glance-api
+-----------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ha.tc004.glance-api_service_down
+
+Use case specification
+----------------------
+
+This test verifies the high availability of the "glance-api" service provided
+by OpenStack controller nodes. It kills the processes of OpenStack "glance-api"
+service on the selected controller node, then checks whether the "glance-api"
+service is still available, by creating image and deleting image, and checks
+whether the killed processes are recovered.
+
+Test preconditions
+------------------
+
+There is more than one controller node, which is providing the "glance-api"
+service for API end-point.
+Denoted a controller node as Node1 in the following configuration.
+
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for monitoring high availability
+''''''''''''''''''''''''''''''''''''''''''''
+
+The high availability of "glance-api" service is evaluated by monitoring
+service outage time, process outage time, and results of glance operations.
+
+Service outage time is tested by continuously executing "openstack image list"
+command in loop and checking if the response of the command request is returned
+with no failure.
+When the response fails, the "glance-api" service is considered in outage.
+The time between the first response failure and the last response failure is
+considered as service outage time.
+
+Process outage time is tested by checking the status of "glance-api" processes
+on the selected controller node. The time of "glance-api" processes being
+killed to the time of the "glance-api" processes being recovered is the process
+outage time. Process recovery is verified by checking the existence of
+"glance-api" processes.
+
+Test execution
+''''''''''''''
+
+* Test action 1: Connect to Node1 through SSH, and check that "glance-api"
+ processes are running on Node1
+* Test action 2: Start two monitors: one for "glance-api" process and the other
+ for "openstack image list" command.
+ Each monitor will run as an independent process.
+* Test action 3: Connect to Node1 through SSH, and then kill the "glance-api"
+ processes
+* Test action 4: When "openstack image list" returns with no error, calculate
+ the service outage time, and execute "openstack image create test-image
+ --file cirros-0.3.5-x86_64-disk.img --disk-format qcow2 --container-format bare"
+* Test action 5: Continuously execute "openstack image show test-image", check
+ if status of "test-image" is "active"
+* Test action 6: If "test-image" is "active", execute "openstack image delete
+ test-image". Then execute "openstack image list" to check if "test-image" is
+ not in the list
+* Test action 7: Continuously measure process outage time from the monitor until
+ the process outage time is more than 30s
+
+Pass / fail criteria
+''''''''''''''''''''
+
+The process outage time is less than 30s.
+
+The service outage time is less than 5s.
+
+The glance operations are carried out in above order and no errors occur.
+
+A negative result will be generated if the above is not met in completion.
+
+Post conditions
+---------------
+
+Restart the processes of "glance-api" if they are not running.
+
+Delete image with "openstack image delete test-image".
+
+
+-----------------------------------------------------------------
+Test Case 5 - Controller node OpenStack service down - cinder-api
+-----------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ha.tc005.cinder-api_service_down
+
+Use case specification
+----------------------
+
+This test verifies the high availability of the "cinder-api" service provided
+by OpenStack controller nodes. It kills the processes of OpenStack "cinder-api"
+service on the selected controller node, then checks whether the "cinder-api"
+service is still available by executing command "openstack volume list" and
+whether the killed processes are recovered.
+
+Test preconditions
+------------------
+
+There is more than one controller node, which is providing the "cinder-api"
+service for API end-point.
+Denoted a controller node as Node1 in the following configuration.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for monitoring high availability
+''''''''''''''''''''''''''''''''''''''''''''
+
+The high availability of "cinder-api" service is evaluated by monitoring
+service outage time and process outage time
+
+Service outage time is tested by continuously executing "openstack volume list"
+command in loop and checking if the response of the command request is returned
+with no failure.
+When the response fails, the "cinder-api" service is considered in outage.
+The time between the first response failure and the last response failure is
+considered as service outage time.
+
+Process outage time is tested by checking the status of "cinder-api" processes
+on the selected controller node. The time of "cinder-api" processes being
+killed to the time of the "cinder-api" processes being recovered is the process
+outage time. Process recovery is verified by checking the existence of
+"cinder-api" processes.
+
+Test execution
+''''''''''''''
+
+* Test action 1: Connect to Node1 through SSH, and check that "cinder-api"
+ processes are running on Node1
+* Test action 2: Start two monitors: one for "cinder-api" process and the other
+ for "openstack volume list" command.
+ Each monitor will run as an independent process.
+* Test action 3: Connect to Node1 through SSH, and then execute kill the
+ "cinder-api" processes
+* Test action 4: Continuously measure service outage time from the monitor until
+ the service outage time is more than 5s
+* Test action 5: Continuously measure process outage time from the monitor until
+ the process outage time is more than 30s
+
+Pass / fail criteria
+''''''''''''''''''''
+
+The process outage time is less than 30s.
+
+The service outage time is less than 5s.
+
+The cinder operations are carried out in above order and no errors occur.
+
+A negative result will be generated if the above is not met in completion.
+
+Post conditions
+---------------
+
+Restart the processes of "cinder-api" if they are not running.
+
+
+------------------------------------------------------------
+Test Case 6 - Controller Node CPU Overload High Availability
+------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ha.tc006.cpu_overload
+
+Use case specification
+----------------------
+
+This test verifies the availability of services when one of the controller node
+suffers from heavy CPU overload. When the CPU usage of the specified controller
+node is up to 100%, which breaks down the OpenStack services on this node,
+the Openstack services should continue to be available. This test case stresses
+the CPU usage of a specific controller node to 100%, then checks whether all
+services provided by the SUT are still available with the monitor tools.
+
+Test preconditions
+------------------
+
+There is more than one controller node, which is providing the "cinder-api",
+"neutron-server", "glance-api" and "keystone" services for API end-point.
+Denoted a controller node as Node1 in the following configuration.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for monitoring high availability
+''''''''''''''''''''''''''''''''''''''''''''
+
+The high availability of related OpenStack service is evaluated by monitoring service
+outage time
+
+Service outage time is tested by continuously executing "openstack router list",
+"openstack stack list", "openstack volume list", "openstack image list" commands
+in loop and checking if the response of the command request is returned with no
+failure.
+When the response fails, the related service is considered in outage. The time
+between the first response failure and the last response failure is considered
+as service outage time.
+
+
+Methodology for stressing CPU usage
+'''''''''''''''''''''''''''''''''''
+
+To evaluate the high availability of target OpenStack service under heavy CPU
+load, the test case will first get the number of logical CPU cores on the
+target controller node by shell command, then use the number to execute 'dd'
+command to continuously copy from /dev/zero and output to /dev/null in loop.
+The 'dd' operation only uses CPU, no I/O operation, which is ideal for
+stressing the CPU usage.
+
+Since the 'dd' command is continuously executed and the CPU usage rate is
+stressed to 100%, the scheduler will schedule each 'dd' command to be
+processed on a different logical CPU core. Eventually to achieve all logical
+CPU cores usage rate to 100%.
+
+Test execution
+''''''''''''''
+
+* Test action 1: Start four monitors: one for "openstack image list" command,
+ one for "openstack router list" command, one for "openstack stack list"
+ command and the last one for "openstack volume list" command. Each monitor
+ will run as an independent process.
+* Test action 2: Connect to Node1 through SSH, and then stress all logical CPU
+ cores usage rate to 100%
+* Test action 3: Continuously measure all the service outage times until they are
+ more than 5s
+* Test action 4: Kill the process that stresses the CPU usage
+
+Pass / fail criteria
+''''''''''''''''''''
+
+All the service outage times are less than 5s.
+
+A negative result will be generated if the above is not met in completion.
+
+Post conditions
+---------------
+
+No impact on the SUT.
+
+
+-----------------------------------------------------------------
+Test Case 7 - Controller Node Disk I/O Overload High Availability
+-----------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ha.tc007.disk_I/O_overload
+
+Use case specification
+----------------------
+
+This test verifies the high availability of control node. When the disk I/O of
+the specific disk is overload, which breaks down the OpenStack services on this
+node, the read and write services should continue to be available. This test
+case blocks the disk I/O of the specific controller node, then checks whether
+the services that need to read or write the disk of the controller node are
+available with some monitor tools.
+
+Test preconditions
+------------------
+
+There is more than one controller node.
+Denoted a controller node as Node1 in the following configuration.
+The controller node has at least 20GB free disk space.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for monitoring high availability
+''''''''''''''''''''''''''''''''''''''''''''
+
+The high availability of nova service is evaluated by monitoring
+service outage time
+
+Service availability is tested by continuously executing
+"openstack flavor list" command in loop and checking if the response of the
+command request is returned with no failure.
+When the response fails, the related service is considered in outage.
+
+
+Methodology for stressing disk I/O
+''''''''''''''''''''''''''''''''''
+
+To evaluate the high availability of target OpenStack service under heavy I/O
+load, the test case will execute shell command on the selected controller node
+to continuously writing 8kb blocks to /test.dbf
+
+Test execution
+''''''''''''''
+
+* Test action 1: Connect to Node1 through SSH, and then stress disk I/O by
+ continuously writing 8kb blocks to /test.dbf
+* Test action 2: Start a monitor: for "openstack flavor list" command
+* Test action 3: Create a flavor called "test-001"
+* Test action 4: Check whether the flavor "test-001" is created
+* Test action 5: Continuously measure service outage time from the monitor
+ until the service outage time is more than 5s
+* Test action 6: Stop writing to /test.dbf and delete file /test.dbf
+
+Pass / fail criteria
+''''''''''''''''''''
+
+The service outage time is less than 5s.
+
+The nova operations are carried out in above order and no errors occur.
+
+A negative result will be generated if the above is not met in completion.
+
+Post conditions
+---------------
+
+Delete flavor with "openstack flavor delete test-001".
+
+--------------------------------------------------------------------
+Test Case 8 - Controller Load Balance as a Service High Availability
+--------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ha.tc008.load_balance_service_down
+
+Use case specification
+----------------------
+
+This test verifies the high availability of "load balancer" service. When
+the "load balancer" service of a specified controller node is killed, whether
+"load balancer" service on other controller nodes will work, and whether the
+controller node will restart the "load balancer" service are checked. This
+test case kills the processes of "load balancer" service on the selected
+controller node, then checks whether the request of the related OpenStack
+command is processed with no failure and whether the killed processes are
+recovered.
+
+Test preconditions
+------------------
+
+There is more than one controller node, which is providing the "load balancer"
+service for rest-api. Denoted as Node1 in the following configuration.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for monitoring high availability
+''''''''''''''''''''''''''''''''''''''''''''
+
+The high availability of "load balancer" service is evaluated by monitoring
+service outage time and process outage time
+
+Service outage time is tested by continuously executing "openstack image list"
+command in loop and checking if the response of the command request is returned
+with no failure.
+When the response fails, the "load balancer" service is considered in outage.
+The time between the first response failure and the last response failure is
+considered as service outage time.
+
+Process outage time is tested by checking the status of processes of "load
+balancer" service on the selected controller node. The time of those processes
+being killed to the time of those processes being recovered is the process
+outage time.
+Process recovery is verified by checking the existence of processes of "load
+balancer" service.
+
+Test execution
+''''''''''''''
+
+* Test action 1: Connect to Node1 through SSH, and check that processes of
+ "load balancer" service are running on Node1
+* Test action 2: Start two monitors: one for processes of "load balancer"
+ service and the other for "openstack image list" command. Each monitor will
+ run as an independent process
+* Test action 3: Connect to Node1 through SSH, and then kill the processes of
+ "load balancer" service
+* Test action 4: Continuously measure service outage time from the monitor until
+ the service outage time is more than 5s
+* Test action 5: Continuously measure process outage time from the monitor until
+ the process outage time is more than 30s
+
+Pass / fail criteria
+''''''''''''''''''''
+
+The process outage time is less than 30s.
+
+The service outage time is less than 5s.
+
+A negative result will be generated if the above is not met in completion.
+
+Post conditions
+---------------
+Restart the processes of "load balancer" if they are not running.
+
+
+
diff --git a/docs/testing/user/testspecification/ipv6/index.rst b/docs/testing/user/testspecification/ipv6/index.rst
new file mode 100644
index 00000000..c3dc844b
--- /dev/null
+++ b/docs/testing/user/testspecification/ipv6/index.rst
@@ -0,0 +1,1787 @@
+.. This work is licensed under a Creative Commons Attribution 4.0 International License.
+.. http://creativecommons.org/licenses/by/4.0
+.. (c) OPNFV
+
+========================
+IPv6 test specification
+========================
+
+.. toctree::
+ :maxdepth: 2
+
+Scope
+=====
+
+The IPv6 test area will evaluate the ability for a SUT to support IPv6
+Tenant Network features and functionality. The tests in this test area will
+evaluate,
+
+- network, subnet, port, router API CRUD operations
+- interface add and remove operations
+- security group and security group rule API CRUD operations
+- IPv6 address assignment with dual stack, dual net, multiprefix in mode DHCPv6 stateless or SLAAC
+
+References
+================
+
+- upstream openstack API reference
+
+ - http://developer.openstack.org/api-ref
+
+- upstream openstack IPv6 reference
+
+ - https://docs.openstack.org/newton/networking-guide/config-ipv6.html
+
+Definitions and abbreviations
+=============================
+
+The following terms and abbreviations are used in conjunction with this test area
+
+- API - Application Programming Interface
+- CIDR - Classless Inter-Domain Routing
+- CRUD - Create, Read, Update, and Delete
+- DHCP - Dynamic Host Configuration Protocol
+- DHCPv6 - Dynamic Host Configuration Protocol version 6
+- ICMP - Internet Control Message Protocol
+- NFVI - Network Functions Virtualization Infrastructure
+- NIC - Network Interface Controller
+- RA - Router Advertisements
+- radvd - The Router Advertisement Daemon
+- SDN - Software Defined Network
+- SLAAC - Stateless Address Auto Configuration
+- TCP - Transmission Control Protocol
+- UDP - User Datagram Protocol
+- VM - Virtual Machine
+- vNIC - virtual Network Interface Card
+
+System Under Test (SUT)
+=======================
+
+The system under test is assumed to be the NFVI and VIM deployed with a Pharos compliant infrastructure.
+
+Test Area Structure
+====================
+
+The test area is structured based on network, port and subnet operations. Each test case
+is able to run independently, i.e. irrelevant of the state created by a previous test.
+
+Test Descriptions
+=================
+
+API Used and Reference
+----------------------
+
+Networks: https://developer.openstack.org/api-ref/networking/v2/index.html#networks
+
+- show network details
+- update network
+- delete network
+- list networks
+- create netowrk
+- bulk create networks
+
+Subnets: https://developer.openstack.org/api-ref/networking/v2/index.html#subnets
+
+- list subnets
+- create subnet
+- bulk create subnet
+- show subnet details
+- update subnet
+- delete subnet
+
+Routers and interface: https://developer.openstack.org/api-ref/networking/v2/index.html#routers-routers
+
+- list routers
+- create router
+- show router details
+- update router
+- delete router
+- add interface to router
+- remove interface from router
+
+Ports: https://developer.openstack.org/api-ref/networking/v2/index.html#ports
+
+- show port details
+- update port
+- delete port
+- list port
+- create port
+- bulk create ports
+
+Security groups: https://developer.openstack.org/api-ref/networking/v2/index.html#security-groups-security-groups
+
+- list security groups
+- create security groups
+- show security group
+- update security group
+- delete security group
+
+Security groups rules: https://developer.openstack.org/api-ref/networking/v2/index.html#security-group-rules-security-group-rules
+
+- list security group rules
+- create security group rule
+- show security group rule
+- delete security group rule
+
+Servers: https://developer.openstack.org/api-ref/compute/
+
+- list servers
+- create server
+- create multiple servers
+- list servers detailed
+- show server details
+- update server
+- delete server
+
+------------------------------------------------------------------
+Test Case 1 - Create and Delete Bulk Network, IPv6 Subnet and Port
+------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.bulk_network_subnet_port_create_delete
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of creating and deleting multiple networks,
+IPv6 subnets, ports in one request, the reference is,
+
+tempest.api.network.test_networks.BulkNetworkOpsIpV6Test.test_bulk_create_delete_network
+tempest.api.network.test_networks.BulkNetworkOpsIpV6Test.test_bulk_create_delete_subnet
+tempest.api.network.test_networks.BulkNetworkOpsIpV6Test.test_bulk_create_delete_port
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create 2 networks using bulk create, storing the "id" parameters returned in the response
+* Test action 2: List all networks, verifying the two network id's are found in the list
+* **Test assertion 1:** The two "id" parameters are found in the network list
+* Test action 3: Delete the 2 created networks using the stored network ids
+* Test action 4: List all networks, verifying the network ids are no longer present
+* **Test assertion 2:** The two "id" parameters are not present in the network list
+* Test action 5: Create 2 networks using bulk create, storing the "id" parameters returned in the response
+* Test action 6: Create an IPv6 subnets on each of the two networks using bulk create commands,
+ storing the associated "id" parameters
+* Test action 7: List all subnets, verify the IPv6 subnets are found in the list
+* **Test assertion 3:** The two IPv6 subnet "id" parameters are found in the network list
+* Test action 8: Delete the 2 IPv6 subnets using the stored "id" parameters
+* Test action 9: List all subnets, verify the IPv6 subnets are no longer present in the list
+* **Test assertion 4:** The two IPv6 subnet "id" parameters, are not present in list
+* Test action 10: Delete the 2 networks created in test action 5, using the stored network ids
+* Test action 11: List all networks, verifying the network ids are no longer present
+* **Test assertion 5:** The two "id" parameters are not present in the network list
+* Test action 12: Create 2 networks using bulk create, storing the "id" parameters returned in the response
+* Test action 13: Create a port on each of the two networks using bulk create commands,
+ storing the associated "port_id" parameters
+* Test action 14: List all ports, verify the port_ids are found in the list
+* **Test assertion 6:** The two "port_id" parameters are found in the ports list
+* Test action 15: Delete the 2 ports using the stored "port_id" parameters
+* Test action 16: List all ports, verify port_ids are no longer present in the list
+* **Test assertion 7:** The two "port_id" parameters, are not present in list
+* Test action 17: Delete the 2 networks created in test action 12, using the stored network ids
+* Test action 18: List all networks, verifying the network ids are no longer present
+* **Test assertion 8:** The two "id" parameters are not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to use bulk create commands to create networks, IPv6 subnets and ports on
+the SUT API. Specifically it verifies that:
+
+* Bulk network create commands return valid "id" parameters which are reported in the list commands
+* Bulk IPv6 subnet commands return valid "id" parameters which are reported in the list commands
+* Bulk port commands return valid "port_id" parameters which are reported in the list commands
+* All items created using bulk create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+N/A
+
+-------------------------------------------------------------------
+Test Case 2 - Create, Update and Delete an IPv6 Network and Subnet
+-------------------------------------------------------------------
+
+Short name
+-----------
+
+opnfv.ipv6.network_subnet_create_update_delete
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of creating, updating, deleting
+network and IPv6 subnet with the network, the reference is
+
+tempest.api.network.test_networks.NetworksIpV6Test.test_create_update_delete_network_subnet
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a network, storing the "id" and "status" parameters returned
+ in the response
+* Test action 2: Verify the value of the created network's "status" is ACTIVE
+* **Test assertion 1:** The created network's "status" is ACTIVE
+* Test action 3: Update this network with a new_name
+* Test action 4: Verify the network's name equals the new_name
+* **Test assertion 2:** The network's name equals to the new_name after name updating
+* Test action 5: Create an IPv6 subnet within the network, storing the "id" parameters
+ returned in the response
+* Test action 6: Update this IPv6 subnet with a new_name
+* Test action 7: Verify the IPv6 subnet's name equals the new_name
+* **Test assertion 3:** The IPv6 subnet's name equals to the new_name after name updating
+* Test action 8: Delete the IPv6 subnet created in test action 5, using the stored subnet id
+* Test action 9: List all subnets, verifying the subnet id is no longer present
+* **Test assertion 4:** The IPv6 subnet "id" is not present in the subnet list
+* Test action 10: Delete the network created in test action 1, using the stored network id
+* Test action 11: List all networks, verifying the network id is no longer present
+* **Test assertion 5:** The network "id" is not present in the network list
+
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to create, update, delete network, IPv6 subnet on the
+SUT API. Specifically it verifies that:
+
+* Create network commands return ACTIVE "status" parameters which are reported in the list commands
+* Update network commands return updated "name" parameters which equals to the "name" used
+* Update subnet commands return updated "name" parameters which equals to the "name" used
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+-------------------------------------------------
+Test Case 3 - Check External Network Visibility
+-------------------------------------------------
+
+Short name
+-----------
+
+opnfv.ipv6.external_network_visibility
+
+Use case specification
+----------------------
+
+This test case verifies user can see external networks but not subnets, the reference is,
+
+tempest.api.network.test_networks.NetworksIpV6Test.test_external_network_visibility
+
+Test preconditions
+------------------
+
+1. The SUT has at least one external network.
+2. In the external network list, there is no network without external router, i.e.,
+all networks in this list are with external router.
+3. There is one external network with configured public network id and there is
+no subnet on this network
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: List all networks with external router, storing the "id"s parameters returned in the response
+* Test action 2: Verify list in test action 1 is not empty
+* **Test assertion 1:** The network with external router list is not empty
+* Test action 3: List all netowrks without external router in test action 1 list
+* Test action 4: Verify list in test action 3 is empty
+* **Test assertion 2:** networks without external router in the external network
+ list is empty
+* Test action 5: Verify the configured public network id is found in test action 1 stored "id"s
+* **Test assertion 3:** the public network id is found in the external network "id"s
+* Test action 6: List the subnets of the external network with the configured
+ public network id
+* Test action 7: Verify list in test action 6 is empty
+* **Test assertion 4:** There is no subnet of the external network with the configured
+ public network id
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to use list commands to list external networks, pre-configured
+public network. Specifically it verifies that:
+
+* Network list commands to find visible networks with external router
+* Network list commands to find visible network with pre-configured public network id
+* Subnet list commands to find no subnet on the pre-configured public network
+
+Post conditions
+---------------
+
+None
+
+---------------------------------------------
+Test Case 4 - List IPv6 Networks and Subnets
+---------------------------------------------
+
+Short name
+-----------
+
+opnfv.ipv6.network_subnet_list
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of listing netowrks,
+subnets after creating a network and an IPv6 subnet, the reference is
+
+tempest.api.network.test_networks.NetworksIpV6Test.test_list_networks
+tempest.api.network.test_networks.NetworksIpV6Test.test_list_subnets
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a network, storing the "id" parameter returned in the response
+* Test action 2: List all networks, verifying the network id is found in the list
+* **Test assertion 1:** The "id" parameter is found in the network list
+* Test action 3: Create an IPv6 subnet of the network created in test action 1.
+ storing the "id" parameter returned in the response
+* Test action 4: List all subnets of this network, verifying the IPv6 subnet id
+ is found in the list
+* **Test assertion 2:** The "id" parameter is found in the IPv6 subnet list
+* Test action 5: Delete the IPv6 subnet using the stored "id" parameters
+* Test action 6: List all subnets, verify subnet_id is no longer present in the list
+* **Test assertion 3:** The IPv6 subnet "id" parameter is not present in list
+* Test action 7: Delete the network created in test action 1, using the stored network ids
+* Test action 8: List all networks, verifying the network id is no longer present
+* **Test assertion 4:** The network "id" parameter is not present in the network list
+
+Pass / fail criteria
+''''''''''''''''''''
+
+This test evaluates the ability to use create commands to create network, IPv6 subnet, list
+commands to list the created networks, IPv6 subnet on the SUT API. Specifically it verifies that:
+
+* Create commands to create network, IPv6 subnet
+* List commands to find that netowrk, IPv6 subnet in the all networks, subnets list after creating
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+-------------------------------------------------------------
+Test Case 5 - Show Details of an IPv6 Network and Subnet
+-------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.network_subnet_show
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of showing the network, subnet
+details, the reference is,
+
+tempest.api.network.test_networks.NetworksIpV6Test.test_show_network
+tempest.api.network.test_networks.NetworksIpV6Test.test_show_subnet
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a network, storing the "id" and "name" parameter returned in the response
+* Test action 2: Show the network id and name, verifying the network id and name equal to the
+ "id" and "name" stored in test action 1
+* **Test assertion 1:** The id and name equal to the "id" and "name" stored in test action 1
+* Test action 3: Create an IPv6 subnet of the network, storing the "id" and CIDR parameter
+ returned in the response
+* Test action 4: Show the details of the created IPv6 subnet, verifying the
+ id and CIDR in the details are equal to the stored id and CIDR in test action 3.
+* **Test assertion 2:** The "id" and CIDR in show details equal to "id" and CIDR stored in test action 3
+* Test action 5: Delete the IPv6 subnet using the stored "id" parameter
+* Test action 6: List all subnets on the network, verify the IPv6 subnet id is no longer present in the list
+* **Test assertion 3:** The IPv6 subnet "id" parameter is not present in list
+* Test action 7: Delete the network created in test action 1, using the stored network id
+* Test action 8: List all networks, verifying the network id is no longer present
+* **Test assertion 4:** The "id" parameter is not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to use create commands to create network, IPv6 subnet and show
+commands to show network, IPv6 subnet details on the SUT API. Specifically it verifies that:
+
+* Network show commands return correct "id" and "name" parameter which equal to the returned response in the create commands
+* IPv6 subnet show commands return correct "id" and CIDR parameter which equal to the returned response in the create commands
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+-------------------------------------------------------------
+Test Case 6 - Create an IPv6 Port in Allowed Allocation Pools
+-------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.port_create_in_allocation_pool
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of creating
+an IPv6 subnet within allowed IPv6 address allocation pool and creating
+a port whose address is in the range of the pool, the reference is,
+
+tempest.api.network.test_ports.PortsIpV6TestJSON.test_create_port_in_allowed_allocation_pools
+
+Test preconditions
+------------------
+
+There should be an IPv6 CIDR configuration, which prefixlen is less than 126.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a network, storing the "id" parameter returned in the response
+* Test action 2: Check the allocation pools configuration, verifying the prefixlen
+ of the IPv6 CIDR configuration is less than 126.
+* **Test assertion 1:** The prefixlen of the IPv6 CIDR configuration is less than 126
+* Test action 3: Get the allocation pool by setting the start_ip and end_ip
+ based on the IPv6 CIDR configuration.
+* Test action 4: Create an IPv6 subnet of the network within the allocation pools,
+ storing the "id" parameter returned in the response
+* Test action 5: Create a port of the network, storing the "id" parameter returned in the response
+* Test action 6: Verify the port's id is in the range of the allocation pools which is got is test action 3
+* **Test assertion 2:** the port's id is in the range of the allocation pools
+* Test action 7: Delete the port using the stored "id" parameter
+* Test action 8: List all ports, verify the port id is no longer present in the list
+* **Test assertion 3:** The port "id" parameter is not present in list
+* Test action 9: Delete the IPv6 subnet using the stored "id" parameter
+* Test action 10: List all subnets on the network, verify the IPv6 subnet id is no longer present in the list
+* **Test assertion 4:** The IPv6 subnet "id" parameter is not present in list
+* Test action 11: Delete the network created in test action 1, using the stored network id
+* Test action 12: List all networks, verifying the network id is no longer present
+* **Test assertion 5:** The "id" parameter is not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to use create commands to create an IPv6 subnet within allowed
+IPv6 address allocation pool and create a port whose address is in the range of the pool. Specifically it verifies that:
+
+* IPv6 subnet create command to create an IPv6 subnet within allowed IPv6 address allocation pool
+* Port create command to create a port whose id is in the range of the allocation pools
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+-------------------------------------------------------------
+Test Case 7 - Create an IPv6 Port with Empty Security Groups
+-------------------------------------------------------------
+
+Short name
+-----------
+
+opnfv.ipv6.port_create_empty_security_group
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of creating port with empty
+security group, the reference is,
+
+tempest.api.network.test_ports.PortsIpV6TestJSON.test_create_port_with_no_securitygroups
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a network, storing the "id" parameter returned in the response
+* Test action 2: Create an IPv6 subnet of the network, storing the "id" parameter returned in the response
+* Test action 3: Create a port of the network with an empty security group, storing the "id" parameter returned in the response
+* Test action 4: Verify the security group of the port is not none but is empty
+* **Test assertion 1:** the security group of the port is not none but is empty
+* Test action 5: Delete the port using the stored "id" parameter
+* Test action 6: List all ports, verify the port id is no longer present in the list
+* **Test assertion 2:** The port "id" parameter is not present in list
+* Test action 7: Delete the IPv6 subnet using the stored "id" parameter
+* Test action 8: List all subnets on the network, verify the IPv6 subnet id is no longer present in the list
+* **Test assertion 3:** The IPv6 subnet "id" parameter is not present in list
+* Test action 9: Delete the network created in test action 1, using the stored network id
+* Test action 10: List all networks, verifying the network id is no longer present
+* **Test assertion 4:** The "id" parameter is not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to use create commands to create port with
+empty security group of the SUT API. Specifically it verifies that:
+
+* Port create commands to create a port with an empty security group
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+-----------------------------------------------------
+Test Case 8 - Create, Update and Delete an IPv6 Port
+-----------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.port_create_update_delete
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of creating, updating,
+deleting IPv6 port, the reference is,
+
+tempest.api.network.test_ports.PortsIpV6TestJSON.test_create_update_delete_port
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a network, storing the "id" parameter returned in the response
+* Test action 2: Create a port of the network, storing the "id" and "admin_state_up" parameters
+ returned in the response
+* Test action 3: Verify the value of port's 'admin_state_up' is True
+* **Test assertion 1:** the value of port's 'admin_state_up' is True after creating
+* Test action 4: Update the port's name with a new_name and set port's admin_state_up to False,
+ storing the name and admin_state_up parameters returned in the response
+* Test action 5: Verify the stored port's name equals to new_name and the port's admin_state_up is False.
+* **Test assertion 2:** the stored port's name equals to new_name and the port's admin_state_up is False
+* Test action 6: Delete the port using the stored "id" parameter
+* Test action 7: List all ports, verify the port is no longer present in the list
+* **Test assertion 3:** The port "id" parameter is not present in list
+* Test action 8: Delete the network created in test action 1, using the stored network id
+* Test action 9: List all networks, verifying the network id is no longer present
+* **Test assertion 4:** The "id" parameter is not present in the network list
+
+Pass / fail criteria
+''''''''''''''''''''
+
+This test evaluates the ability to use create/update/delete commands to create/update/delete port
+of the SUT API. Specifically it verifies that:
+
+* Port create commands return True of 'admin_state_up' in response
+* Port update commands to update 'name' to new_name and 'admin_state_up' to false
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+------------------------------
+Test Case 9 - List IPv6 Ports
+------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.tc009.port_list
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT ability of creating a port on a network and
+finding the port in the all ports list, the reference is,
+
+tempest.api.network.test_ports.PortsIpV6TestJSON.test_list_ports
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a network, storing the "id" parameter returned in the response
+* Test action 2: Create a port of the network, storing the "id" parameter returned in the response
+* Test action 3: List all ports, verify the port id is found in the list
+* **Test assertion 1:** The "id" parameter is found in the port list
+* Test action 4: Delete the port using the stored "id" parameter
+* Test action 5: List all ports, verify the port is no longer present in the list
+* **Test assertion 2:** The port "id" parameter is not present in list
+* Test action 6: Delete the network created in test action 1, using the stored network id
+* Test action 7: List all networks, verifying the network id is no longer present
+* **Test assertion 3:** The "id" parameter is not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to use list commands to list the networks and ports on
+the SUT API. Specifically it verifies that:
+
+* Port list command to list all ports, the created port is found in the list.
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+-------------------------------------------------------
+Test Case 10 - Show Key/Valus Details of an IPv6 Port
+-------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.tc010.port_show_details
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT ability of showing the port
+details, the values in the details should be equal to the values to create the port,
+the reference is,
+
+tempest.api.network.test_ports.PortsIpV6TestJSON.test_show_port
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a network, storing the "id" parameter returned in the response
+* Test action 2: Create a port of the network, storing the "id" parameter returned in the response
+* Test action 3: Show the details of the port, verify the stored port's id
+ in test action 2 exists in the details
+* **Test assertion 1:** The "id" parameter is found in the port shown details
+* Test action 4: Verify the values in the details of the port are the same as the values
+ to create the port
+* **Test assertion 2:** The values in the details of the port are the same as the values
+ to create the port
+* Test action 5: Delete the port using the stored "id" parameter
+* Test action 6: List all ports, verify the port is no longer present in the list
+* **Test assertion 3:** The port "id" parameter is not present in list
+* Test action 7: Delete the network created in test action 1, using the stored network id
+* Test action 8: List all networks, verifying the network id is no longer present
+* **Test assertion 4:** The "id" parameter is not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to use show commands to show port details on the SUT API.
+Specifically it verifies that:
+
+* Port show commands to show the details of the port, whose id is in the details
+* Port show commands to show the details of the port, whose values are the same as the values
+ to create the port
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+---------------------------------------------------------
+Test Case 11 - Add Multiple Interfaces for an IPv6 Router
+---------------------------------------------------------
+
+Short name
+-----------
+
+opnfv.ipv6.router_add_multiple_interface
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT ability of adding multiple interface
+to a router, the reference is,
+
+tempest.api.network.test_routers.RoutersIpV6Test.test_add_multiple_router_interfaces
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create 2 networks named network01 and network02 sequentially,
+ storing the "id" parameters returned in the response
+* Test action 2: Create an IPv6 subnet01 in network01, an IPv6 subnet02 in network02 sequentially,
+ storing the "id" parameters returned in the response
+* Test action 3: Create a router, storing the "id" parameter returned in the response
+* Test action 4: Create interface01 with subnet01 and the router
+* Test action 5: Verify the router_id stored in test action 3 equals to the interface01's 'device_id'
+ and subnet01_id stored in test action 2 equals to the interface01's 'subnet_id'
+* **Test assertion 1:** the router_id equals to the interface01's 'device_id'
+ and subnet01_id equals to the interface01's 'subnet_id'
+* Test action 5: Create interface02 with subnet02 and the router
+* Test action 6: Verify the router_id stored in test action 3 equals to the interface02's 'device_id'
+ and subnet02_id stored in test action 2 equals to the interface02's 'subnet_id'
+* **Test assertion 2:** the router_id equals to the interface02's 'device_id'
+ and subnet02_id equals to the interface02's 'subnet_id'
+* Test action 7: Delete the interfaces, router, IPv6 subnets and networks, networks, subnets, then list
+ all interfaces, ports, IPv6 subnets, networks, the test passes if the deleted ones
+ are not found in the list.
+* **Test assertion 3:** The interfaces, router, IPv6 subnets and networks ids are not present in the lists
+ after deleting
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to use bulk create commands to create networks, IPv6 subnets and ports on
+the SUT API. Specifically it verifies that:
+
+* Interface create commands to create interface with IPv6 subnet and router, interface 'device_id' and
+ 'subnet_id' should equal to the router id and IPv6 subnet id, respectively.
+* Interface create commands to create multiple interface with the same router and multiple IPv6 subnets.
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+-------------------------------------------------------------------
+Test Case 12 - Add and Remove an IPv6 Router Interface with port_id
+-------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.router_interface_add_remove_with_port
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT abiltiy of adding, removing router interface to
+a port, the subnet_id and port_id of the interface will be checked,
+the port's device_id will be checked if equals to the router_id or not. The
+reference is,
+
+tempest.api.network.test_routers.RoutersIpV6Test.test_add_remove_router_interface_with_port_id
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a network, storing the "id" parameter returned in the response
+* Test action 2: Create an IPv6 subnet of the network, storing the "id" parameter returned in the response
+* Test action 3: Create a router, storing the "id" parameter returned in the response
+* Test action 4: Create a port of the network, storing the "id" parameter returned in the response
+* Test action 5: Add router interface to the port created, storing the "id" parameter returned in the response
+* Test action 6: Verify the interface's keys include 'subnet_id' and 'port_id'
+* **Test assertion 1:** the interface's keys include 'subnet_id' and 'port_id'
+* Test action 7: Show the port details, verify the 'device_id' in port details equals to the router id stored
+ in test action 3
+* **Test assertion 2:** 'device_id' in port details equals to the router id
+* Test action 8: Delete the interface, port, router, subnet and network, then list
+ all interfaces, ports, routers, subnets and networks, the test passes if the deleted
+ ones are not found in the list.
+* **Test assertion 3:** interfaces, ports, routers, subnets and networks are not found in the lists after deleting
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to use add/remove commands to add/remove router interface to the port,
+show commands to show port details on the SUT API. Specifically it verifies that:
+
+* Router_interface add commands to add router interface to a port, the interface's keys should include 'subnet_id' and 'port_id'
+* Port show commands to show 'device_id' in port details, which should be equal to the router id
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+---------------------------------------------------------------------
+Test Case 13 - Add and Remove an IPv6 Router Interface with subnet_id
+---------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.router_interface_add_remove
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of adding and removing a router interface with
+the IPv6 subnet id, the reference is
+
+tempest.api.network.test_routers.RoutersIpV6Test.test_add_remove_router_interface_with_subnet_id
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a network, storing the "id" parameter returned in the response
+* Test action 2: Create an IPv6 subnet with the network created, storing the "id" parameter
+ returned in the response
+* Test action 3: Create a router, storing the "id" parameter returned in the response
+* Test action 4: Add a router interface with the stored ids of the router and IPv6 subnet
+* **Test assertion 1:** Key 'subnet_id' is included in the added interface's keys
+* **Test assertion 2:** Key 'port_id' is included in the added interface's keys
+* Test action 5: Show the port info with the stored interface's port id
+* **Test assertion 3:**: The stored router id is equal to the device id shown in the port info
+* Test action 6: Delete the router interface created in test action 4, using the stored subnet id
+* Test action 7: List all router interfaces, verifying the router interface is no longer present
+* **Test assertion 4:** The router interface with the stored subnet id is not present
+ in the router interface list
+* Test action 8: Delete the router created in test action 3, using the stored router id
+* Test action 9: List all routers, verifying the router id is no longer present
+* **Test assertion 5:** The router "id" parameter is not present in the router list
+* Test action 10: Delete the subnet created in test action 2, using the stored subnet id
+* Test action 11: List all subnets, verifying the subnet id is no longer present
+* **Test assertion 6:** The subnet "id" parameter is not present in the subnet list
+* Test action 12: Delete the network created in test action 1, using the stored network id
+* Test action 13: List all networks, verifying the network id is no longer present
+* **Test assertion 7:** The network "id" parameter is not present in the network list
+
+Pass / fail criteria
+''''''''''''''''''''
+
+This test evaluates the ability to add and remove router interface with the subnet id on the
+SUT API. Specifically it verifies that:
+
+* Router interface add command returns valid 'subnet_id' parameter which is reported
+ in the interface's keys
+* Router interface add command returns valid 'port_id' parameter which is reported
+ in the interface's keys
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+-------------------------------------------------------------------
+Test Case 14 - Create, Show, List, Update and Delete an IPv6 router
+-------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.router_create_show_list_update_delete
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of creating, showing, listing, updating
+and deleting routers, the reference is
+
+tempest.api.network.test_routers.RoutersIpV6Test.test_create_show_list_update_delete_router
+
+Test preconditions
+------------------
+
+There should exist an OpenStack external network.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a router, set the admin_state_up to be False and external_network_id
+ to be public network id, storing the "id" parameter returned in the response
+* **Test assertion 1:** The created router's admin_state_up is False
+* **Test assertion 2:** The created router's external network id equals to the public network id
+* Test action 2: Show details of the router created in test action 1, using the stored router id
+* **Test assertion 3:** The router's name shown is the same as the router created
+* **Test assertion 4:** The router's external network id shown is the same as the public network id
+* Test action 3: List all routers and verify if created router is in response message
+* **Test assertion 5:** The stored router id is in the router list
+* Test action 4: Update the name of router and verify if it is updated
+* **Test assertion 6:** The name of router equals to the name used to update in test action 4
+* Test action 5: Show the details of router, using the stored router id
+* **Test assertion 7:** The router's name shown equals to the name used to update in test action 4
+* Test action 6: Delete the router created in test action 1, using the stored router id
+* Test action 7: List all routers, verifying the router id is no longer present
+* **Test assertion 8:** The "id" parameter is not present in the router list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to create, show, list, update and delete router on
+the SUT API. Specifically it verifies that:
+
+* Router create command returns valid "admin_state_up" and "id" parameters which equal to the
+ "admin_state_up" and "id" returned in the response
+* Router show command returns valid "name" parameter which equals to the "name" returned in the response
+* Router show command returns valid "external network id" parameters which equals to the public network id
+* Router list command returns valid "id" parameter which equals to the stored router "id"
+* Router update command returns updated "name" parameters which equals to the "name" used to update
+* Router created using create command is able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+---------------------------------------------------------------------------
+Test Case 15 - Create, List, Update, Show and Delete an IPv6 security group
+---------------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.security_group_create_list_update_show_delete
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of creating, listing, updating, showing
+and deleting security groups, the reference is
+
+tempest.api.network.test_security_groups.SecGroupIPv6Test.test_create_list_update_show_delete_security_group
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a security group, storing the "id" parameter returned in the response
+* Test action 2: List all security groups and verify if created security group is there in response
+* **Test assertion 1:** The created security group's "id" is found in the list
+* Test action 3: Update the name and description of this security group, using the stored id
+* Test action 4: Verify if the security group's name and description are updated
+* **Test assertion 2:** The security group's name equals to the name used in test action 3
+* **Test assertion 3:** The security group's description equals to the description used in test action 3
+* Test action 5: Show details of the updated security group, using the stored id
+* **Test assertion 4:** The security group's name shown equals to the name used in test action 3
+* **Test assertion 5:** The security group's description shown equals to the description used in test action 3
+* Test action 6: Delete the security group created in test action 1, using the stored id
+* Test action 7: List all security groups, verifying the security group's id is no longer present
+* **Test assertion 6:** The "id" parameter is not present in the security group list
+
+Pass / fail criteria
+''''''''''''''''''''
+
+This test evaluates the ability to create list, update, show and delete security group on
+the SUT API. Specifically it verifies that:
+
+* Security group create commands return valid "id" parameter which is reported in the list commands
+* Security group update commands return valid "name" and "description" parameters which are
+ reported in the show commands
+* Security group created using create command is able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+---------------------------------------------------------------
+Test Case 16 - Create, Show and Delete IPv6 security group rule
+---------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.security_group_rule_create_show_delete
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of creating, showing, listing and deleting
+security group rules, the reference is
+
+tempest.api.network.test_security_groups.SecGroupIPv6Test.test_create_show_delete_security_group_rule
+
+Test preconditions
+------------------
+
+None
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create a security group, storing the "id" parameter returned in the response
+* Test action 2: Create a rule of the security group with protocol tcp, udp and icmp, respectively,
+ using the stored security group's id, storing the "id" parameter returned in the response
+* Test action 3: Show details of the created security group rule, using the stored id of the
+ security group rule
+* **Test assertion 1:** All the created security group rule's values equal to the rule values
+ shown in test action 3
+* Test action 4: List all security group rules
+* **Test assertion 2:** The stored security group rule's id is found in the list
+* Test action 5: Delete the security group rule, using the stored security group rule's id
+* Test action 6: List all security group rules, verifying the security group rule's id is no longer present
+* **Test assertion 3:** The security group rule "id" parameter is not present in the list
+* Test action 7: Delete the security group, using the stored security group's id
+* Test action 8: List all security groups, verifying the security group's id is no longer present
+* **Test assertion 4:** The security group "id" parameter is not present in the list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to create, show, list and delete security group rules on
+the SUT API. Specifically it verifies that:
+
+* Security group rule create command returns valid values which are reported in the show command
+* Security group rule created using create command is able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+----------------------------------------
+Test Case 17 - List IPv6 Security Groups
+----------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.security_group_list
+
+Use case specification
+----------------------
+
+This test case evaluates the SUT API ability of listing security groups, the reference is
+
+tempest.api.network.test_security_groups.SecGroupIPv6Test.test_list_security_groups
+
+Test preconditions
+------------------
+
+There should exist a default security group.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: List all security groups
+* Test action 2: Verify the default security group exists in the list, the test passes
+ if the default security group exists
+* **Test assertion 1:** The default security group is in the list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to list security groups on the SUT API.
+Specifically it verifies that:
+
+* Security group list command return valid security groups which include the default security group
+
+Post conditions
+---------------
+
+None
+
+----------------------------------------------------------------------------
+Test Case 18 - IPv6 Address Assignment - Dual Stack, SLAAC, DHCPv6 Stateless
+----------------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.dhcpv6_stateless
+
+Use case specification
+----------------------
+
+This test case evaluates IPv6 address assignment in ipv6_ra_mode 'dhcpv6_stateless'
+and ipv6_address_mode 'dhcpv6_stateless'.
+In this case, guest instance obtains IPv6 address from OpenStack managed radvd
+using SLAAC and optional info from dnsmasq using DHCPv6 stateless. This test case then
+verifies the ping6 available VM can ping the other VM's v4 and v6 addresses
+as well as the v6 subnet's gateway ip in the same network, the reference is
+
+tempest.scenario.test_network_v6.TestGettingAddress.test_dhcp6_stateless_from_os
+
+Test preconditions
+------------------
+
+There should exist a public router or a public network.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create one network, storing the "id" parameter returned in the response
+* Test action 2: Create one IPv4 subnet of the created network, storing the "id"
+ parameter returned in the response
+* Test action 3: If there exists a public router, use it as the router. Otherwise,
+ use the public network to create a router
+* Test action 4: Connect the IPv4 subnet to the router, using the stored IPv4 subnet id
+* Test action 5: Create one IPv6 subnet of the network created in test action 1 in
+ ipv6_ra_mode 'dhcpv6_stateless' and ipv6_address_mode 'dhcpv6_stateless',
+ storing the "id" parameter returned in the response
+* Test action 6: Connect the IPv6 subnet to the router, using the stored IPv6 subnet id
+* Test action 7: Boot two VMs on this network, storing the "id" parameters returned in the response
+* **Test assertion 1:** The vNIC of each VM gets one v4 address and one v6 address actually assigned
+* **Test assertion 2:** Each VM can ping the other's v4 private address
+* **Test assertion 3:** The ping6 available VM can ping the other's v6 address
+ as well as the v6 subnet's gateway ip
+* Test action 8: Delete the 2 VMs created in test action 7, using the stored ids
+* Test action 9: List all VMs, verifying the ids are no longer present
+* **Test assertion 4:** The two "id" parameters are not present in the VM list
+* Test action 10: Delete the IPv4 subnet created in test action 2, using the stored id
+* Test action 11: Delete the IPv6 subnet created in test action 5, using the stored id
+* Test action 12: List all subnets, verifying the ids are no longer present
+* **Test assertion 5:** The "id" parameters of IPv4 and IPv6 are not present in the list
+* Test action 13: Delete the network created in test action 1, using the stored id
+* Test action 14: List all networks, verifying the id is no longer present
+* **Test assertion 6:** The "id" parameter is not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to assign IPv6 addresses in ipv6_ra_mode
+'dhcpv6_stateless' and ipv6_address_mode 'dhcpv6_stateless',
+and verify the ping6 available VM can ping the other VM's v4 and v6 addresses as well as
+the v6 subnet's gateway ip in the same network. Specifically it verifies that:
+
+* The IPv6 addresses in mode 'dhcpv6_stateless' assigned successfully
+* The VM can ping the other VM's IPv4 and IPv6 private addresses as well as the v6 subnet's gateway ip
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+--------------------------------------------------------------------------------------
+Test Case 19 - IPv6 Address Assignment - Dual Net, Dual Stack, SLAAC, DHCPv6 Stateless
+--------------------------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.dualnet_dhcpv6_stateless
+
+Use case specification
+----------------------
+
+This test case evaluates IPv6 address assignment in ipv6_ra_mode 'dhcpv6_stateless'
+and ipv6_address_mode 'dhcpv6_stateless'.
+In this case, guest instance obtains IPv6 address from OpenStack managed radvd
+using SLAAC and optional info from dnsmasq using DHCPv6 stateless. This test case then
+verifies the ping6 available VM can ping the other VM's v4 address in one network
+and v6 address in another network as well as the v6 subnet's gateway ip, the reference is
+
+tempest.scenario.test_network_v6.TestGettingAddress.test_dualnet_dhcp6_stateless_from_os
+
+Test preconditions
+------------------
+
+There should exists a public router or a public network.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create one network, storing the "id" parameter returned in the response
+* Test action 2: Create one IPv4 subnet of the created network, storing the "id"
+ parameter returned in the response
+* Test action 3: If there exists a public router, use it as the router. Otherwise,
+ use the public network to create a router
+* Test action 4: Connect the IPv4 subnet to the router, using the stored IPv4 subnet id
+* Test action 5: Create another network, storing the "id" parameter returned in the response
+* Test action 6: Create one IPv6 subnet of network created in test action 5 in
+ ipv6_ra_mode 'dhcpv6_stateless' and ipv6_address_mode 'dhcpv6_stateless',
+ storing the "id" parameter returned in the response
+* Test action 7: Connect the IPv6 subnet to the router, using the stored IPv6 subnet id
+* Test action 8: Boot two VMs on these two networks, storing the "id" parameters returned in the response
+* Test action 9: Turn on 2nd NIC of each VM for the network created in test action 5
+* **Test assertion 1:** The 1st vNIC of each VM gets one v4 address assigned and
+ the 2nd vNIC of each VM gets one v6 address actually assigned
+* **Test assertion 2:** Each VM can ping the other's v4 private address
+* **Test assertion 3:** The ping6 available VM can ping the other's v6 address
+ as well as the v6 subnet's gateway ip
+* Test action 10: Delete the 2 VMs created in test action 8, using the stored ids
+* Test action 11: List all VMs, verifying the ids are no longer present
+* **Test assertion 4:** The two "id" parameters are not present in the VM list
+* Test action 12: Delete the IPv4 subnet created in test action 2, using the stored id
+* Test action 13: Delete the IPv6 subnet created in test action 6, using the stored id
+* Test action 14: List all subnets, verifying the ids are no longer present
+* **Test assertion 5:** The "id" parameters of IPv4 and IPv6 are not present in the list
+* Test action 15: Delete the 2 networks created in test action 1 and 5, using the stored ids
+* Test action 16: List all networks, verifying the ids are no longer present
+* **Test assertion 6:** The two "id" parameters are not present in the network list
+
+Pass / fail criteria
+''''''''''''''''''''
+
+This test evaluates the ability to assign IPv6 addresses in ipv6_ra_mode 'dhcpv6_stateless'
+and ipv6_address_mode 'dhcpv6_stateless', and verify the ping6 available VM can ping
+the other VM's v4 address in one network and v6 address in another network as well as
+the v6 subnet's gateway ip. Specifically it verifies that:
+
+* The IPv6 addresses in mode 'dhcpv6_stateless' assigned successfully
+* The VM can ping the other VM's IPv4 address in one network and IPv6 address in another
+ network as well as the v6 subnet's gateway ip
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+-----------------------------------------------------------------------------------------------
+Test Case 20 - IPv6 Address Assignment - Multiple Prefixes, Dual Stack, SLAAC, DHCPv6 Stateless
+-----------------------------------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.multiple_prefixes_dhcpv6_stateless
+
+Use case specification
+----------------------
+
+This test case evaluates IPv6 address assignment in ipv6_ra_mode 'dhcpv6_stateless'
+and ipv6_address_mode 'dhcpv6_stateless'.
+In this case, guest instance obtains IPv6 addresses from OpenStack managed radvd
+using SLAAC and optional info from dnsmasq using DHCPv6 stateless. This test case then
+verifies the ping6 available VM can ping the other VM's one v4 address and two v6
+addresses with different prefixes as well as the v6 subnets' gateway ips in the
+same network, the reference is
+
+tempest.scenario.test_network_v6.TestGettingAddress.test_multi_prefix_dhcpv6_stateless
+
+Test preconditions
+------------------
+
+There should exist a public router or a public network.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create one network, storing the "id" parameter returned in the response
+* Test action 2: Create one IPv4 subnet of the created network, storing the "id"
+ parameter returned in the response
+* Test action 3: If there exists a public router, use it as the router. Otherwise,
+ use the public network to create a router
+* Test action 4: Connect the IPv4 subnet to the router, using the stored IPv4 subnet id
+* Test action 5: Create two IPv6 subnets of the network created in test action 1 in
+ ipv6_ra_mode 'dhcpv6_stateless' and ipv6_address_mode 'dhcpv6_stateless',
+ storing the "id" parameters returned in the response
+* Test action 6: Connect the two IPv6 subnets to the router, using the stored IPv6 subnet ids
+* Test action 7: Boot two VMs on this network, storing the "id" parameters returned in the response
+* **Test assertion 1:** The vNIC of each VM gets one v4 address and two v6 addresses with
+ different prefixes actually assigned
+* **Test assertion 2:** Each VM can ping the other's v4 private address
+* **Test assertion 3:** The ping6 available VM can ping the other's v6 addresses
+ as well as the v6 subnets' gateway ips
+* Test action 8: Delete the 2 VMs created in test action 7, using the stored ids
+* Test action 9: List all VMs, verifying the ids are no longer present
+* **Test assertion 4:** The two "id" parameters are not present in the VM list
+* Test action 10: Delete the IPv4 subnet created in test action 2, using the stored id
+* Test action 11: Delete two IPv6 subnets created in test action 5, using the stored ids
+* Test action 12: List all subnets, verifying the ids are no longer present
+* **Test assertion 5:** The "id" parameters of IPv4 and IPv6 are not present in the list
+* Test action 13: Delete the network created in test action 1, using the stored id
+* Test action 14: List all networks, verifying the id is no longer present
+* **Test assertion 6:** The "id" parameter is not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to assign IPv6 addresses in ipv6_ra_mode 'dhcpv6_stateless'
+and ipv6_address_mode 'dhcpv6_stateless',
+and verify the ping6 available VM can ping the other VM's v4 address and two
+v6 addresses with different prefixes as well as the v6 subnets' gateway ips in the same network.
+Specifically it verifies that:
+
+* The different prefixes IPv6 addresses in mode 'dhcpv6_stateless' assigned successfully
+* The VM can ping the other VM's IPv4 and IPv6 private addresses as well as the v6 subnets' gateway ips
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+---------------------------------------------------------------------------------------------------------
+Test Case 21 - IPv6 Address Assignment - Dual Net, Multiple Prefixes, Dual Stack, SLAAC, DHCPv6 Stateless
+---------------------------------------------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.dualnet_multiple_prefixes_dhcpv6_stateless
+
+Use case specification
+----------------------
+
+This test case evaluates IPv6 address assignment in ipv6_ra_mode 'dhcpv6_stateless'
+and ipv6_address_mode 'dhcpv6_stateless'.
+In this case, guest instance obtains IPv6 addresses from OpenStack managed radvd
+using SLAAC and optional info from dnsmasq using DHCPv6 stateless. This test case then
+verifies the ping6 available VM can ping the other VM's v4 address in one network
+and two v6 addresses with different prefixes in another network as well as the
+v6 subnets' gateway ips, the reference is
+
+tempest.scenario.test_network_v6.TestGettingAddress.test_dualnet_multi_prefix_dhcpv6_stateless
+
+Test preconditions
+------------------
+
+There should exist a public router or a public network.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create one network, storing the "id" parameter returned in the response
+* Test action 2: Create one IPv4 subnet of the created network, storing the "id"
+ parameter returned in the response
+* Test action 3: If there exists a public router, use it as the router. Otherwise,
+ use the public network to create a router
+* Test action 4: Connect the IPv4 subnet to the router, using the stored IPv4 subnet id
+* Test action 5: Create another network, storing the "id" parameter returned in the response
+* Test action 6: Create two IPv6 subnets of network created in test action 5 in
+ ipv6_ra_mode 'dhcpv6_stateless' and ipv6_address_mode 'dhcpv6_stateless',
+ storing the "id" parameters returned in the response
+* Test action 7: Connect the two IPv6 subnets to the router, using the stored IPv6 subnet ids
+* Test action 8: Boot two VMs on these two networks, storing the "id" parameters returned in the response
+* Test action 9: Turn on 2nd NIC of each VM for the network created in test action 5
+* **Test assertion 1:** The vNIC of each VM gets one v4 address and two v6 addresses
+ with different prefixes actually assigned
+* **Test assertion 2:** Each VM can ping the other's v4 private address
+* **Test assertion 3:** The ping6 available VM can ping the other's v6 addresses
+ as well as the v6 subnets' gateway ips
+* Test action 10: Delete the 2 VMs created in test action 8, using the stored ids
+* Test action 11: List all VMs, verifying the ids are no longer present
+* **Test assertion 4:** The two "id" parameters are not present in the VM list
+* Test action 12: Delete the IPv4 subnet created in test action 2, using the stored id
+* Test action 13: Delete two IPv6 subnets created in test action 6, using the stored ids
+* Test action 14: List all subnets, verifying the ids are no longer present
+* **Test assertion 5:** The "id" parameters of IPv4 and IPv6 are not present in the list
+* Test action 15: Delete the 2 networks created in test action 1 and 5, using the stored ids
+* Test action 16: List all networks, verifying the ids are no longer present
+* **Test assertion 6:** The two "id" parameters are not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to assign IPv6 addresses in ipv6_ra_mode 'dhcpv6_stateless'
+and ipv6_address_mode 'dhcpv6_stateless',
+and verify the ping6 available VM can ping the other VM's v4 address in one network and two
+v6 addresses with different prefixes in another network as well as the v6 subnets'
+gateway ips. Specifically it verifies that:
+
+* The IPv6 addresses in mode 'dhcpv6_stateless' assigned successfully
+* The VM can ping the other VM's IPv4 and IPv6 private addresses as well as the v6 subnets' gateway ips
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+----------------------------------------------------------
+Test Case 22 - IPv6 Address Assignment - Dual Stack, SLAAC
+----------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.slaac
+
+Use case specification
+----------------------
+
+This test case evaluates IPv6 address assignment in ipv6_ra_mode 'slaac' and
+ipv6_address_mode 'slaac'.
+In this case, guest instance obtains IPv6 address from OpenStack managed radvd
+using SLAAC. This test case then verifies the ping6 available VM can ping the other
+VM's v4 and v6 addresses as well as the v6 subnet's gateway ip in the
+same network, the reference is
+
+tempest.scenario.test_network_v6.TestGettingAddress.test_slaac_from_os
+
+Test preconditions
+------------------
+
+There should exist a public router or a public network.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create one network, storing the "id" parameter returned in the response
+* Test action 2: Create one IPv4 subnet of the created network, storing the "id"
+ parameter returned in the response
+* Test action 3: If there exists a public router, use it as the router. Otherwise,
+ use the public network to create a router
+* Test action 4: Connect the IPv4 subnet to the router, using the stored IPv4 subnet id
+* Test action 5: Create one IPv6 subnet of the network created in test action 1 in
+ ipv6_ra_mode 'slaac' and ipv6_address_mode 'slaac', storing the "id" parameter returned in the response
+* Test action 6: Connect the IPv6 subnet to the router, using the stored IPv6 subnet id
+* Test action 7: Boot two VMs on this network, storing the "id" parameters returned in the response
+* **Test assertion 1:** The vNIC of each VM gets one v4 address and one v6 address actually assigned
+* **Test assertion 2:** Each VM can ping the other's v4 private address
+* **Test assertion 3:** The ping6 available VM can ping the other's v6 address
+ as well as the v6 subnet's gateway ip
+* Test action 8: Delete the 2 VMs created in test action 7, using the stored ids
+* Test action 9: List all VMs, verifying the ids are no longer present
+* **Test assertion 4:** The two "id" parameters are not present in the VM list
+* Test action 10: Delete the IPv4 subnet created in test action 2, using the stored id
+* Test action 11: Delete the IPv6 subnet created in test action 5, using the stored id
+* Test action 12: List all subnets, verifying the ids are no longer present
+* **Test assertion 5:** The "id" parameters of IPv4 and IPv6 are not present in the list
+* Test action 13: Delete the network created in test action 1, using the stored id
+* Test action 14: List all networks, verifying the id is no longer present
+* **Test assertion 6:** The "id" parameter is not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to assign IPv6 addresses in ipv6_ra_mode 'slaac'
+and ipv6_address_mode 'slaac',
+and verify the ping6 available VM can ping the other VM's v4 and v6 addresses as well as
+the v6 subnet's gateway ip in the same network. Specifically it verifies that:
+
+* The IPv6 addresses in mode 'slaac' assigned successfully
+* The VM can ping the other VM's IPv4 and IPv6 private addresses as well as the v6 subnet's gateway ip
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+--------------------------------------------------------------------
+Test Case 23 - IPv6 Address Assignment - Dual Net, Dual Stack, SLAAC
+--------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.dualnet_slaac
+
+Use case specification
+----------------------
+
+This test case evaluates IPv6 address assignment in ipv6_ra_mode 'slaac' and
+ipv6_address_mode 'slaac'.
+In this case, guest instance obtains IPv6 address from OpenStack managed radvd
+using SLAAC. This test case then verifies the ping6 available VM can ping the other
+VM's v4 address in one network and v6 address in another network as well as the
+v6 subnet's gateway ip, the reference is
+
+tempest.scenario.test_network_v6.TestGettingAddress.test_dualnet_slaac_from_os
+
+Test preconditions
+------------------
+
+There should exist a public router or a public network.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create one network, storing the "id" parameter returned in the response
+* Test action 2: Create one IPv4 subnet of the created network, storing the "id"
+ parameter returned in the response
+* Test action 3: If there exists a public router, use it as the router. Otherwise,
+ use the public network to create a router
+* Test action 4: Connect the IPv4 subnet to the router, using the stored IPv4 subnet id
+* Test action 5: Create another network, storing the "id" parameter returned in the response
+* Test action 6: Create one IPv6 subnet of network created in test action 5 in
+ ipv6_ra_mode 'slaac' and ipv6_address_mode 'slaac', storing the "id" parameter returned in the response
+* Test action 7: Connect the IPv6 subnet to the router, using the stored IPv6 subnet id
+* Test action 8: Boot two VMs on these two networks, storing the "id" parameters returned in the response
+* Test action 9: Turn on 2nd NIC of each VM for the network created in test action 5
+* **Test assertion 1:** The 1st vNIC of each VM gets one v4 address assigned and
+ the 2nd vNIC of each VM gets one v6 address actually assigned
+* **Test assertion 2:** Each VM can ping the other's v4 private address
+* **Test assertion 3:** The ping6 available VM can ping the other's v6 address
+ as well as the v6 subnet's gateway ip
+* Test action 10: Delete the 2 VMs created in test action 8, using the stored ids
+* Test action 11: List all VMs, verifying the ids are no longer present
+* **Test assertion 4:** The two "id" parameters are not present in the VM list
+* Test action 12: Delete the IPv4 subnet created in test action 2, using the stored id
+* Test action 13: Delete the IPv6 subnet created in test action 6, using the stored id
+* Test action 14: List all subnets, verifying the ids are no longer present
+* **Test assertion 5:** The "id" parameters of IPv4 and IPv6 are not present in the list
+* Test action 15: Delete the 2 networks created in test action 1 and 5, using the stored ids
+* Test action 16: List all networks, verifying the ids are no longer present
+* **Test assertion 6:** The two "id" parameters are not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to assign IPv6 addresses in ipv6_ra_mode 'slaac'
+and ipv6_address_mode 'slaac',
+and verify the ping6 available VM can ping the other VM's v4 address in one network and
+v6 address in another network as well as the v6 subnet's gateway ip. Specifically it verifies that:
+
+* The IPv6 addresses in mode 'slaac' assigned successfully
+* The VM can ping the other VM's IPv4 address in one network and IPv6 address
+ in another network as well as the v6 subnet's gateway ip
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+-----------------------------------------------------------------------------
+Test Case 24 - IPv6 Address Assignment - Multiple Prefixes, Dual Stack, SLAAC
+-----------------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.multiple_prefixes_slaac
+
+Use case specification
+----------------------
+
+This test case evaluates IPv6 address assignment in ipv6_ra_mode 'slaac' and
+ipv6_address_mode 'slaac'.
+In this case, guest instance obtains IPv6 addresses from OpenStack managed radvd
+using SLAAC. This test case then verifies the ping6 available VM can ping the other
+VM's one v4 address and two v6 addresses with different prefixes as well as the v6
+subnets' gateway ips in the same network, the reference is
+
+tempest.scenario.test_network_v6.TestGettingAddress.test_multi_prefix_slaac
+
+Test preconditions
+------------------
+
+There should exists a public router or a public network.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create one network, storing the "id" parameter returned in the response
+* Test action 2: Create one IPv4 subnet of the created network, storing the "id
+ parameter returned in the response
+* Test action 3: If there exists a public router, use it as the router. Otherwise,
+ use the public network to create a router
+* Test action 4: Connect the IPv4 subnet to the router, using the stored IPv4 subnet id
+* Test action 5: Create two IPv6 subnets of the network created in test action 1 in
+ ipv6_ra_mode 'slaac' and ipv6_address_mode 'slaac', storing the "id" parameters returned in the response
+* Test action 6: Connect the two IPv6 subnets to the router, using the stored IPv6 subnet ids
+* Test action 7: Boot two VMs on this network, storing the "id" parameters returned in the response
+* **Test assertion 1:** The vNIC of each VM gets one v4 address and two v6 addresses with
+ different prefixes actually assigned
+* **Test assertion 2:** Each VM can ping the other's v4 private address
+* **Test assertion 3:** The ping6 available VM can ping the other's v6 addresses
+ as well as the v6 subnets' gateway ips
+* Test action 8: Delete the 2 VMs created in test action 7, using the stored ids
+* Test action 9: List all VMs, verifying the ids are no longer present
+* **Test assertion 4:** The two "id" parameters are not present in the VM list
+* Test action 10: Delete the IPv4 subnet created in test action 2, using the stored id
+* Test action 11: Delete two IPv6 subnets created in test action 5, using the stored ids
+* Test action 12: List all subnets, verifying the ids are no longer present
+* **Test assertion 5:** The "id" parameters of IPv4 and IPv6 are not present in the list
+* Test action 13: Delete the network created in test action 1, using the stored id
+* Test action 14: List all networks, verifying the id is no longer present
+* **Test assertion 6:** The "id" parameter is not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to assign IPv6 addresses in ipv6_ra_mode 'slaac'
+and ipv6_address_mode 'slaac',
+and verify the ping6 available VM can ping the other VM's v4 address and two
+v6 addresses with different prefixes as well as the v6 subnets' gateway ips in the same network.
+Specifically it verifies that:
+
+* The different prefixes IPv6 addresses in mode 'slaac' assigned successfully
+* The VM can ping the other VM's IPv4 and IPv6 private addresses as well as the v6 subnets' gateway ips
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+---------------------------------------------------------------------------------------
+Test Case 25 - IPv6 Address Assignment - Dual Net, Dual Stack, Multiple Prefixes, SLAAC
+---------------------------------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.ipv6.dualnet_multiple_prefixes_slaac
+
+Use case specification
+----------------------
+
+This test case evaluates IPv6 address assignment in ipv6_ra_mode 'slaac' and
+ipv6_address_mode 'slaac'.
+In this case, guest instance obtains IPv6 addresses from OpenStack managed radvd
+using SLAAC. This test case then verifies the ping6 available VM can ping the other
+VM's v4 address in one network and two v6 addresses with different prefixes in another
+network as well as the v6 subnets' gateway ips, the reference is
+
+tempest.scenario.test_network_v6.TestGettingAddress.test_dualnet_multi_prefix_slaac
+
+Test preconditions
+------------------
+
+There should exist a public router or a public network.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Test execution
+'''''''''''''''
+
+* Test action 1: Create one network, storing the "id" parameter returned in the response
+* Test action 2: Create one IPv4 subnet of the created network, storing the "id"
+ parameter returned in the response
+* Test action 3: If there exists a public router, use it as the router. Otherwise,
+ use the public network to create a router
+* Test action 4: Connect the IPv4 subnet to the router, using the stored IPv4 subnet id
+* Test action 5: Create another network, storing the "id" parameter returned in the response
+* Test action 6: Create two IPv6 subnets of network created in test action 5 in
+ ipv6_ra_mode 'slaac' and ipv6_address_mode 'slaac', storing the "id" parameters returned in the response
+* Test action 7: Connect the two IPv6 subnets to the router, using the stored IPv6 subnet ids
+* Test action 8: Boot two VMs on these two networks, storing the "id" parameters returned in the response
+* Test action 9: Turn on 2nd NIC of each VM for the network created in test action 5
+* **Test assertion 1:** The vNIC of each VM gets one v4 address and two v6 addresses
+ with different prefixes actually assigned
+* **Test assertion 2:** Each VM can ping the other's v4 private address
+* **Test assertion 3:** The ping6 available VM can ping the other's v6 addresses
+ as well as the v6 subnets' gateway ips
+* Test action 10: Delete the 2 VMs created in test action 8, using the stored ids
+* Test action 11: List all VMs, verifying the ids are no longer present
+* **Test assertion 4:** The two "id" parameters are not present in the VM list
+* Test action 12: Delete the IPv4 subnet created in test action 2, using the stored id
+* Test action 13: Delete two IPv6 subnets created in test action 6, using the stored ids
+* Test action 14: List all subnets, verifying the ids are no longer present
+* **Test assertion 5:** The "id" parameters of IPv4 and IPv6 are not present in the list
+* Test action 15: Delete the 2 networks created in test action 1 and 5, using the stored ids
+* Test action 16: List all networks, verifying the ids are no longer present
+* **Test assertion 6:** The two "id" parameters are not present in the network list
+
+Pass / fail criteria
+'''''''''''''''''''''
+
+This test evaluates the ability to assign IPv6 addresses in ipv6_ra_mode 'slaac'
+and ipv6_address_mode 'slaac',
+and verify the ping6 available VM can ping the other VM's v4 address in one network and two
+v6 addresses with different prefixes in another network as well as the v6 subnets' gateway ips.
+Specifically it verifies that:
+
+* The IPv6 addresses in mode 'slaac' assigned successfully
+* The VM can ping the other VM's IPv4 and IPv6 private addresses as well as the v6 subnets' gateway ips
+* All items created using create commands are able to be removed using the returned identifiers
+
+Post conditions
+---------------
+
+None
+
+
+
diff --git a/docs/testing/user/testspecification/old_files/ipv6/designspecification.rst b/docs/testing/user/testspecification/old_files/ipv6/designspecification.rst
deleted file mode 100644
index 9e403472..00000000
--- a/docs/testing/user/testspecification/old_files/ipv6/designspecification.rst
+++ /dev/null
@@ -1,133 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International License.
-.. http://creativecommons.org/licenses/by/4.0
-.. (c) Christopher Price (Ericsson AB) and others
-
-==============================
-IPv6 test design specification
-==============================
-
-This document outlines the approach and method for testing IPv6 in the OPNFV compliance test
-suite. Providing a brief outline of the features to be tested, the methodology for testing,
-schema's and criteria.
-
-Features to be tested
-=====================
-
-The IPv6 compliance test plan outlines the method for testing IPv6 compliance to the OPNFV
-platform behaviours and features of IPv6 enabled VNFi platforms. The specific features to
-be tested by the IPv6 compliance test suite is outlined in the following table.
-
-.. table::
- :class: longtable
-
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|Features / Requirements |Tests available | Test Cases |
-+===========================================================+===================+====================================================================+
-|All topologies work in a multi-tenant environment |No | |
-| | | |
-| | | |
-| | | |
-| | | |
-| | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|IPv6 VM to VM only |No | |
-| | | |
-| | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|IPv6 external L2 VLAN directly attached to a VM |No | |
-| | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|IPv6 subnet routed via L3 agent to an external IPv6 network|No | |
-| | | |
-|1. Both VLAN and overlay (e.g. GRE, VXLAN) subnet attached | | |
-| to VMs; | | |
-|2. Must be able to support multiple L3 agents for a given | | |
-| external network to support scaling (neutron scheduler | | |
-| to assign vRouters to the L3 agents) | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|Ability for a NIC to support both IPv4 and IPv6 (dual |No | |
-|stack) address. | | |
-| | | |
-|1. VM with a single interface associated with a network, | | |
-| which is then associated with two subnets. | | |
-|2. VM with two different interfaces associated with two | | |
-| different networks and two different subnets. | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|Support IPv6 Address assignment modes. |No | |
-| | | |
-|1. SLAAC | | |
-|2. DHCPv6 Stateless | | |
-|3. DHCPv6 Stateful | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|Ability to create a port on an IPv6 DHCPv6 Stateful subnet |No | |
-|and assign a specific IPv6 address to the port and have it | | |
-|taken out of the DHCP address pool. | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|Full support for IPv6 matching (i.e., IPv6, ICMPv6, TCP, |No | |
-|UDP) in security groups. Ability to control and manage all | | |
-|IPv6 security group capabilities via Neutron/Nova API (REST| | |
-|and CLI) as well as via Horizon. | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|During network/subnet/router create, there should be an |No | |
-|option to allow user to specify the type of address | | |
-|management they would like. This includes all options | | |
-|including those low priority if implemented (e.g., toggle | | |
-|on/off router and address prefix advertisements); It must | | |
-|be supported via Neutron API (REST and CLI) as well as via | | |
-|Horizon | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|Security groups anti-spoofing: Prevent VM from using a |No | |
-|source IPv6/MAC address which is not assigned to the VM | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|Protect tenant and provider network from rogue RAs |No | |
-| | | |
-| | | |
-| | | |
-| | | |
-| | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|Support the ability to assign multiple IPv6 addresses to |No | |
-|an interface; both for Neutron router interfaces and VM | | |
-|interfaces. | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|Ability for a VM to support a mix of multiple IPv4 and IPv6|No | |
-|networks, including multiples of the same type. | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|Support for IPv6 Prefix Delegation. |No | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|IPv6 First-Hop Security, IPv6 ND spoofing |No | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-|IPv6 support in Neutron Layer3 High Availability |No | |
-|(keepalived+VRRP). | | |
-+-----------------------------------------------------------+-------------------+--------------------------------------------------------------------+
-
-
-Test approach for IPv6
-======================
-
-The most common approach for testing IPv6 capabilities in the test suite is through interaction with the SUT control plane.
-In this instance the test framework will exercise the NBI provided by the VIM to configure and leverage IPv6 related features
-in the platform, instantiate workloads, and invoke behaviours in the platform. The suite may also interact directly with the
-data plane to exercise platform capabilities and further invoke helper functions on the platform for the same purpose.
-
-Test result analysis
---------------------
-
-All functional tests in the IPv6 test suite will provide a pass/fail result on completion of the test. In addition test logs
-and relevant additional information will be provided as part of the test log, available on test suite completion.
-
-Some tests in the compliance suite measure such metrics as latency and performance. At this time these tests are intended to
-provide a feature based pass/fail metric not related to system performance.
-These tests may however provide detailed results of performance and latency in the 'test report'_ document.
-
-Test identification
-===================
-
-TBD: WE need to identify the test naming scheme we will use in DoveTail in order that we can cross reference to the test
-projects and maintain our suite effectively. This naming scheme needs to be externally relevant to non-OPNFV consumers and as
-such some consideration is required on the selection.
-
-Pass Fail Criteria
-==================
-
-This section requires some further work with the test teams to identify how and where we generate, store and provide results.
diff --git a/docs/testing/user/testspecification/old_files/ipv6/index.rst b/docs/testing/user/testspecification/old_files/ipv6/index.rst
deleted file mode 100644
index a806d644..00000000
--- a/docs/testing/user/testspecification/old_files/ipv6/index.rst
+++ /dev/null
@@ -1,19 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International License.
-.. http://creativecommons.org/licenses/by/4.0
-.. (c) OPNFV
-
-*******************************
-OPNFV IPv6 Compliance Test Plan
-*******************************
-
-.. toctree::
- :maxdepth: 2
-
- ./testplan.rst
- ./testprocedure.rst
- ./testspecification.rst
- ./designspecification.rst
- ./ipv6.tc001.specification.rst
- ./ipv6.tc026.specification.rst
- ./ipv6_all_testcases.rst
-
diff --git a/docs/testing/user/testspecification/old_files/ipv6/ipv6.tc001.specification.rst b/docs/testing/user/testspecification/old_files/ipv6/ipv6.tc001.specification.rst
deleted file mode 100644
index 5afb2095..00000000
--- a/docs/testing/user/testspecification/old_files/ipv6/ipv6.tc001.specification.rst
+++ /dev/null
@@ -1,59 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International License.
-.. http://creativecommons.org/licenses/by/4.0
-.. (c) OPNFV
-
-==================================================================================================
-Dovetail IPv6 tc001 specification - Bulk Creation and Deletion of IPv6 Networks, Ports and Subnets
-==================================================================================================
-
-
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|test case name |Bulk creation and deletion of IPv6 networks, ports and subnets |
-| | |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|id |dovetail.ipv6.tc001 |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|objective |To verify that platform is able to create/delete networks, ports and subnets in bulk operation |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|test items |tempest.api.network.test_networks.BulkNetworkOpsIpV6Test.test_bulk_create_delete_network |
-| |{idempotent_id('d4f9024d-1e28-4fc1-a6b1-25dbc6fa11e2')} |
-| |tempest.api.network.test_networks.BulkNetworkOpsIpV6Test.test_bulk_create_delete_port |
-| |{idempotent_id('48037ff2-e889-4c3b-b86a-8e3f34d2d060')} |
-| |tempest.api.network.test_networks.BulkNetworkOpsIpV6Test.test_bulk_create_delete_subnet |
-| |{idempotent_id('8936533b-c0aa-4f29-8e53-6cc873aec489')} |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|environmental | |
-|requirements & | environment can be deployed on bare metal of virtualized infrastructure |
-|preconditions | deployment can be HA or non-HA |
-| | |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|scenario dependencies | NA |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|procedural |Step 1: create/delete network: |
-|requirements | create 2 networks in one request |
-| | asserting that the networks are found in the list after creation |
-| | |
-| |Step 2: create/delete subnet: |
-| | create 2 subnets in one request |
-| | asserting that the subnets are found in the list after creation |
-| | |
-| |Step 3: create/delete port: |
-| | create 2 ports in one request |
-| | asserting that the ports are found in the list after creation |
-| | |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|input specifications |The parameters needed to execute Neutron network APIs. |
-| |Refer to Neutron Networking API v2.0 `[1]`_ `[2]`_ |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|output specifications |The responses after executing Network network APIs. |
-| |Refer to Neutron Networking API v2.0 `[1]`_ `[2]`_ |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|pass/fail criteria |If normal response code 200 is returned, the test passes. |
-| |Otherwise, the test fails with various error codes. |
-| |Refer to Neutron Networking API v2.0 `[1]`_ `[2]`_ |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-|test report |TBD |
-+-----------------------+----------------------------------------------------------------------------------------------------+
-
-.. _`[1]`: http://developer.openstack.org/api-ref/networking/v2/
-.. _`[2]`: http://wiki.openstack.org/wiki/Neutron/APIv2-specification
diff --git a/docs/testing/user/testspecification/old_files/ipv6/ipv6.tc026.specification.rst b/docs/testing/user/testspecification/old_files/ipv6/ipv6.tc026.specification.rst
deleted file mode 100644
index e7fd82e7..00000000
--- a/docs/testing/user/testspecification/old_files/ipv6/ipv6.tc026.specification.rst
+++ /dev/null
@@ -1,54 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International License.
-.. http://creativecommons.org/licenses/by/4.0
-.. (c) OPNFV
-
-==============================================================
-Dovetail IPv6 tc026 specification - Service VM as IPv6 vRouter
-==============================================================
-
-
-+-----------------------+--------------------------------------------------------------------------+
-|test case name |Service VM as IPv6 vRouter |
-| | |
-+-----------------------+--------------------------------------------------------------------------+
-|id |dovetail.ipv6.tc026 |
-+-----------------------+--------------------------------------------------------------------------+
-|objective |IPv6 connnectivity, service VM as IPv6 vRouter |
-+-----------------------+--------------------------------------------------------------------------+
-|modules under test |neutron, nova, etc |
-+-----------------------+--------------------------------------------------------------------------+
-|dependent test project |yardstick |
-+-----------------------+--------------------------------------------------------------------------+
-|test items |yardstick_tc027 |
-+-----------------------+--------------------------------------------------------------------------+
-|environmental | OpenStack-only environment |
-|requirements & | environment can be deplyed on bare metal of virtualized infrastructure |
-|preconditions | deployment can be HA or non-HA |
-| | test case image needs to be installed into Glance with ping6 included |
-+-----------------------+--------------------------------------------------------------------------+
-|scenario dependencies | nosdn |
-+-----------------------+--------------------------------------------------------------------------+
-|procedural |step 1: to setup IPv6 testing environment |
-|requirements | 1.1 disable security group |
-| | 1.2 create (ipv6, ipv4) router, network and subnet |
-| | 1.3 create vRouter, VM1, VM2 |
-| |step 2: to run ping6 to verify IPv6 connectivity |
-| | 2.1 ssh to VM1 |
-| | 2.2 ping6 to ipv6 router from VM1 |
-| | 2.3 get the result and store the logs |
-| |step 3: to teardown IPv6 testing environment |
-| | 3.1 delete vRouter, VM1, VM2 |
-| | 3.2 delete (ipv6, ipv4) router, network and subnet |
-| | 3.3 enable security group |
-+-----------------------+--------------------------------------------------------------------------+
-|input specifications |packetsize: 56 |
-| |ping_count: 5 |
-| | |
-+-----------------------+--------------------------------------------------------------------------+
-|output specifications |output includes max_rtt, min_rtt, average_rtt |
-+-----------------------+--------------------------------------------------------------------------+
-|pass/fail criteria |ping6 connectivity success, no SLA |
-+-----------------------+--------------------------------------------------------------------------+
-|test report | dovetail dashboard DB here |
-+-----------------------+--------------------------------------------------------------------------+
-
diff --git a/docs/testing/user/testspecification/old_files/ipv6/ipv6_all_testcases.rst b/docs/testing/user/testspecification/old_files/ipv6/ipv6_all_testcases.rst
deleted file mode 100644
index 462219a8..00000000
--- a/docs/testing/user/testspecification/old_files/ipv6/ipv6_all_testcases.rst
+++ /dev/null
@@ -1,249 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International License.
-.. http://creativecommons.org/licenses/by/4.0
-.. (c) OPNFV
-
-==================================================
-IPv6 Compliance Testing Methodology and Test Cases
-==================================================
-
-IPv6 Compliance Testing focuses on overlay IPv6 capabilities, i.e. to validate that
-IPv6 capability is supported in tenant networks, subnets and routers. Both Tempest API
-testing and Tempest Scenario testing are reused as much as we can in IPv6 Compliance
-Testing. In addition, Yardstick Test Case 027 is also used to validate a specific use case
-of using a Service VM as an IPv6 vRouter.
-
-IPv6 Compliance Testing test cases are described as follows:
-
----------------------------------------------------------------
-Test Case 1: Create and Delete an IPv6 Network, Port and Subnet
----------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_networks.BulkNetworkOpsIpV6Test.test_bulk_create_delete_network
- tempest.api.network.test_networks.BulkNetworkOpsIpV6Test.test_bulk_create_delete_port
- tempest.api.network.test_networks.BulkNetworkOpsIpV6Test.test_bulk_create_delete_subnet
-
------------------------------------------------------------------
-Test Case 2: Create, Update and Delete an IPv6 Network and Subnet
------------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_networks.NetworksIpV6Test.test_create_update_delete_network_subnet
- tempest.api.network.test_networks.NetworksIpV6TestAttrs.test_create_update_delete_network_subnet
-
-----------------------------------------------
-Test Case 3: Check External Network Visibility
-----------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_networks.NetworksIpV6Test.test_external_network_visibility
- tempest.api.network.test_networks.NetworksIpV6TestAttrs.test_external_network_visibility
-
--------------------------------------------------------
-Test Case 4: List IPv6 Networks and Subnets of a Tenant
--------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_networks.NetworksIpV6Test.test_list_networks
- tempest.api.network.test_networks.NetworksIpV6Test.test_list_subnets
- tempest.api.network.test_networks.NetworksIpV6TestAttrs.test_list_networks
- tempest.api.network.test_networks.NetworksIpV6TestAttrs.test_list_subnets
-
------------------------------------------------------------
-Test Case 5: Show Information of an IPv6 Network and Subnet
------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_networks.NetworksIpV6Test.test_show_network
- tempest.api.network.test_networks.NetworksIpV6Test.test_show_subnet
- tempest.api.network.test_networks.NetworksIpV6TestAttrs.test_show_network
- tempest.api.network.test_networks.NetworksIpV6TestAttrs.test_show_subnet
-
-------------------------------------------------------------
-Test Case 6: Create an IPv6 Port in Allowed Allocation Pools
-------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_ports.PortsIpV6TestJSON.test_create_port_in_allowed_allocation_pools
-
---------------------------------------------------------
-Test Case 7: Create an IPv6 Port without Security Groups
---------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_ports.PortsIpV6TestJSON.test_create_port_with_no_securitygroups
-
----------------------------------------------------
-Test Case 8: Create, Update and Delete an IPv6 Port
----------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_ports.PortsIpV6TestJSON.test_create_update_delete_port
-
-----------------------------------------
-Test Case 9: List IPv6 Ports of a Tenant
-----------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_ports.PortsIpV6TestJSON.test_list_ports
-
-----------------------------------------------
-Test Case 10: Show Information of an IPv6 Port
-----------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_ports.PortsIpV6TestJSON.test_show_port
-
---------------------------------------------------------
-Test Case 11: Add Multiple Interfaces for an IPv6 Router
---------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_routers.RoutersIpV6Test.test_add_multiple_router_interfaces
-
-------------------------------------------------------------------
-Test Case 12: Add and Remove an IPv6 Router Interface with port_id
-------------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_routers.RoutersIpV6Test.test_add_remove_router_interface_with_port_id
-
---------------------------------------------------------------------
-Test Case 13: Add and Remove an IPv6 Router Interface with subnet_id
---------------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_routers.RoutersIpV6Test.test_add_remove_router_interface_with_subnet_id
-
-------------------------------------------------------------------
-Test Case 14: Create, Update, Delete, List and Show an IPv6 Router
-------------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_routers.RoutersIpV6Test.test_create_show_list_update_delete_router
-
---------------------------------------------------------------------------
-Test Case 15: Create, Update, Delete, List and Show an IPv6 Security Group
---------------------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_security_groups.SecGroupIPv6Test.test_create_list_update_show_delete_security_group
-
-----------------------------------------------------------
-Test Case 16: Create, Delete and Show Security Group Rules
-----------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_security_groups.SecGroupIPv6Test.test_create_show_delete_security_group_rule
-
---------------------------------------
-Test Case 17: List All Security Groups
---------------------------------------
-
-.. code-block:: bash
-
- tempest.api.network.test_security_groups.SecGroupIPv6Test.test_list_security_groups
-
---------------------------------------------------------
-Test Case 18: IPv6 Address Assignment - DHCPv6 Stateless
---------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.scenario.test_network_v6.TestGettingAddress.test_dhcp6_stateless_from_os
-
---------------------------------------------------------------------
-Test Case 19: IPv6 Address Assignment - Dual Stack, DHCPv6 Stateless
---------------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.scenario.test_network_v6.TestGettingAddress.test_dualnet_dhcp6_stateless_from_os
-
----------------------------------------------------------------------------
-Test Case 20: IPv6 Address Assignment - Multiple Prefixes, DHCPv6 Stateless
----------------------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.scenario.test_network_v6.TestGettingAddress.test_multi_prefix_dhcpv6_stateless
-
----------------------------------------------------------------------------------------
-Test Case 21: IPv6 Address Assignment - Dual Stack, Multiple Prefixes, DHCPv6 Stateless
----------------------------------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.scenario.test_network_v6.TestGettingAddress.test_dualnet_multi_prefix_dhcpv6_stateless
-
----------------------------------------------
-Test Case 22: IPv6 Address Assignment - SLAAC
----------------------------------------------
-
-.. code-block:: bash
-
- tempest.scenario.test_network_v6.TestGettingAddress.test_slaac_from_os
-
----------------------------------------------------------
-Test Case 23: IPv6 Address Assignment - Dual Stack, SLAAC
----------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.scenario.test_network_v6.TestGettingAddress.test_dualnet_slaac_from_os
-
-----------------------------------------------------------------
-Test Case 24: IPv6 Address Assignment - Multiple Prefixes, SLAAC
-----------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.scenario.test_network_v6.TestGettingAddress.test_multi_prefix_slaac
-
-----------------------------------------------------------------------------
-Test Case 25: IPv6 Address Assignment - Dual Stack, Multiple Prefixes, SLAAC
-----------------------------------------------------------------------------
-
-.. code-block:: bash
-
- tempest.scenario.test_network_v6.TestGettingAddress.test_dualnet_multi_prefix_slaac
-
--------------------------------------------
-Test Case 26: Service VM as an IPv6 vRouter
--------------------------------------------
-
-.. code-block:: bash
-
- # Refer to Yardstick Test Case 027
- # Instruction: http://artifacts.opnfv.org/ipv6/docs/configurationguide/index.html
- # Step 1: Set up Service VM as an IPv6 vRouter
- # 1.1: Install OPNFV and Preparation
- # 1.2: Disable Security Groups in OpenStack ML2 Setup
- # 1.3: Create IPv4 and IPv6 Neutron routers, networks and subnets
- # 1.4: Boot vRouter VM, and Guest VM1 and Guest VM2
- # Step 2: Verify IPv6 Connectivity
- # 2.1: ssh to Guest VM1
- # 2.2: Ping6 from Guest VM1 to Guest VM2
- # 2.3: Ping6 from Guest VM1 to vRouter VM
- # 2.4: Ping6 from Guest VM1 to Neutron IPv6 Router Namespace
- # Step 3: Tear down Setup
- # 3.1: Delete Guest VM1, Guest VM2 and vRouter VM
- # 3.2: Delete IPv4 and IPv6 Neutron routers, networks and subnets
- # 3.3: Enable Security Groups
-
diff --git a/docs/testing/user/testspecification/old_files/ipv6/testplan.rst b/docs/testing/user/testspecification/old_files/ipv6/testplan.rst
deleted file mode 100644
index 3470e7a6..00000000
--- a/docs/testing/user/testspecification/old_files/ipv6/testplan.rst
+++ /dev/null
@@ -1,34 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International License.
-.. http://creativecommons.org/licenses/by/4.0
-.. (c) OPNFV
-
-===============================
-OPNFV IPv6 Compliance Test Plan
-===============================
-
-Introduction
-============
-
-The IPv6 compliance test plan outlines the method for testing IPv6 Tenant Network feature
-compliance with the OPNFV platform.
-
-Scope
------
-
-This test, and other tests in the test suite, are designed to verify an entire SUT,
-and not any individual component of the system.
-
-Test suite scope and procedures
-===============================
-
-The IPv6 compliance test suite will evaluate the ability for a SUT to support IPv6
-Tenant Network features and functionality provided by OPNFV platform.
-
-Please refer to the complete list of the test cases for details.
-
-Test suite execution
-====================
-
-Please refer to each test case for specific setup and execution procedure.
-
-.._[1]: http://www.opnfv.org
diff --git a/docs/testing/user/testspecification/old_files/ipv6/testprocedure.rst b/docs/testing/user/testspecification/old_files/ipv6/testprocedure.rst
deleted file mode 100644
index 2119ed61..00000000
--- a/docs/testing/user/testspecification/old_files/ipv6/testprocedure.rst
+++ /dev/null
@@ -1,9 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International License.
-.. http://creativecommons.org/licenses/by/4.0
-.. (c) Christopher Price (Ericsson AB) and others
-
-===================
-IPv6 test procedure
-===================
-
-Draft to be patched this week, someone feel free to work on this in parallel.
diff --git a/docs/testing/user/testspecification/old_files/ipv6/testspecification.rst b/docs/testing/user/testspecification/old_files/ipv6/testspecification.rst
deleted file mode 100644
index 6f7caba8..00000000
--- a/docs/testing/user/testspecification/old_files/ipv6/testspecification.rst
+++ /dev/null
@@ -1,54 +0,0 @@
-.. This work is licensed under a Creative Commons Attribution 4.0 International License.
-.. http://creativecommons.org/licenses/by/4.0
-.. (c) Christopher Price (Ericsson AB) and others
-
-===============================================
-Test specification - Service VM as IPv6 vRouter
-===============================================
-
-Draft to be worked on, this represents the YardStick test but I would suggest we need to break
-this into a set of tests which provide more details per action with boundary validation.
-
-Test Item
-=========
-
-TBD -> IPv6 Ping...
-
-Identify the items or features to be tested by this test case. The item description and
-definition can be referenced from any one of several sources, depending on the level of the
-test case specification. It may be a good idea to reference the source documents as well.
-
-Environmental requirements
-==========================
-
-TBD
-
-Preconditions and procedural requirements
-=========================================
-
-TBD
-
-.. <Start>
-.. this section may be iterated over for a set of simillar test cases that would be run as one.
-
-Input Specifications
-====================
-
-TBD
-
-Output Specifications
-=====================
-
-TBD
-
-.. <End>
-
-Test Reporting
-==============
-
-The test report for this test case will be generated with links to relevant data sources.
-This section can be updated once we have a template for the report in place.
-
-http://testresults.opnfv.org/grafana/dashboard/db/yardstick-tc027
-
-
diff --git a/docs/testing/user/testspecification/vimoperationscompute/index.rst b/docs/testing/user/testspecification/vimoperationscompute/index.rst
index f8dc5870..4ed37809 100644
--- a/docs/testing/user/testspecification/vimoperationscompute/index.rst
+++ b/docs/testing/user/testspecification/vimoperationscompute/index.rst
@@ -9,11 +9,31 @@ VIM compute operations test specification
.. toctree::
:maxdepth: 2
-Each test case requires documentation according to:
-* Use case specification
-* Test preconditions
-* Basic test flow execution descriptor
-* Post conditions and pass fail criteria
+Scope
+=====
+
+References
+================
+
+
+Definitions and abbreviations
+=============================
+
+
+Use case description
+====================
+
+
+System Under Test (SUT)
+=======================
+
+
+Test Suite Structure
+====================
+
+
+Test Descriptions
+=================
tempest.api.compute.servers.test_create_server.ServersTestJSON.test_host_name_is_same_as_server_name
tempest.api.compute.servers.test_create_server.ServersTestJSON.test_list_servers
diff --git a/docs/testing/user/testspecification/vpn/index.rst b/docs/testing/user/testspecification/vpn/index.rst
new file mode 100644
index 00000000..0a8a8d17
--- /dev/null
+++ b/docs/testing/user/testspecification/vpn/index.rst
@@ -0,0 +1,532 @@
+.. This work is licensed under a Creative Commons Attribution 4.0 International License.
+.. http://creativecommons.org/licenses/by/4.0
+.. (c) Ericsson AB
+
+======================
+VPN test specification
+======================
+
+.. toctree::
+ :maxdepth: 2
+
+Scope
+=====
+
+The VPN test area evaluates the ability of the system under test to support VPN
+networking for virtual workloads. The tests in this test area will evaluate
+establishing VPN networks, publishing and communication between endpoints using
+BGP and tear down of the networks.
+
+References
+==========
+
+This test area evaluates the ability of the system to perform selected actions
+defined in the following specifications. Details of specific features evaluated
+are described in the test descriptions.
+
+- RFC 4364 - BGP/MPLS IP Virtual Private Networks
+
+ - https://tools.ietf.org/html/rfc4364
+
+- RFC 4659 - BGP-MPLS IP Virtual Private Network
+
+ - https://tools.ietf.org/html/rfc4659
+
+- RFC 2547 - BGP/MPLS VPNs
+
+ - https://tools.ietf.org/html/rfc2547
+
+
+Definitions and abbreviations
+=============================
+
+The following terms and abbreviations are used in conjunction with this test
+area
+
+- BGP - Border gateway protocol
+- eRT - Export route target
+- IETF - Internet Engineering Task Force
+- iRT - Import route target
+- NFVi - Network functions virtualization infrastructure
+- Tenant - An isolated set of virtualized infrastructures
+- VM - Virtual machine
+- VPN - Virtual private network
+- VLAN - Virtual local area network
+
+
+System Under Test (SUT)
+=======================
+
+The system under test is assumed to be the NFVi and VIM in operation on a
+Pharos compliant infrastructure.
+
+
+Test Area Structure
+===================
+
+The test area is structured in four separate tests which are executed
+sequentially. The order of the tests is arbitrary as there are no dependencies
+across the tests. Specifially, every test performs clean-up operations which
+return the system to the same state as before the test.
+
+The test area evaluates the ability of the SUT to establish connectivity
+between Virtual Machines using an appropriate route target configuration,
+reconfigure the route targets to remove connectivity between the VMs, then
+reestablish connectivity by re-association.
+
+
+Test Descriptions
+=================
+
+----------------------------------------------------------------
+Test Case 1 - VPN provides connectivity between Neutron subnets
+----------------------------------------------------------------
+
+Short name
+----------
+
+opnfv.sdnvpn.subnet_connectivity
+
+
+Use case specification
+----------------------
+
+This test evaluates the use case where an NFVi tenant uses a BGPVPN to provide
+connectivity between VMs on different Neutron networks and subnets that reside
+on different hosts.
+
+
+Test preconditions
+------------------
+
+2 compute nodes are available, denoted Node1 and Node2 in the following.
+
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for verifying connectivity
+''''''''''''''''''''''''''''''''''''''
+
+Connectivity between VMs is tested by sending ICMP ping packets between
+selected VMs. The target IPs are passed to the VMs sending pings by means of a
+custom user data script. Whether or not a ping was successful is determined by
+checking the console output of the source VMs.
+
+
+Test execution
+''''''''''''''
+
+* Create Neutron network N1 and subnet SN1 with IP range 10.10.10.0/24
+* Create Neutron network N2 and subnet SN2 with IP range 10.10.11.0/24
+
+* Create VM1 on Node1 with a port in network N1
+* Create VM2 on Node1 with a port in network N1
+* Create VM3 on Node2 with a port in network N1
+* Create VM4 on Node1 with a port in network N2
+* Create VM5 on Node2 with a port in network N2
+
+* Create VPN1 with eRT<>iRT
+* Create network association between network N1 and VPN1
+
+* VM1 sends ICMP packets to VM2 using ``ping``
+
+* **Test assertion 1:** Ping from VM1 to VM2 succeeds: ``ping`` exits with return code 0
+
+* VM1 sends ICMP packets to VM3 using ``ping``
+
+* **Test assertion 2:** Ping from VM1 to VM3 succeeds: ``ping`` exits with return code 0
+
+* VM1 sends ICMP packets to VM4 using ``ping``
+
+* **Test assertion 3:** Ping from VM1 to VM4 fails: ``ping`` exits with a non-zero return code
+
+* Create network association between network N2 and VPN1
+
+* VM4 sends ICMP packets to VM5 using ``ping``
+
+* **Test assertion 4:** Ping from VM4 to VM5 succeeds: ``ping`` exits with return code 0
+
+* Configure iRT=eRT in VPN1
+
+* VM1 sends ICMP packets to VM4 using ``ping``
+
+* **Test assertion 5:** Ping from VM1 to VM4 succeeds: ``ping`` exits with return code 0
+
+* VM1 sends ICMP packets to VM5 using ``ping``
+
+* **Test assertion 6:** Ping from VM1 to VM5 succeeds: ``ping`` exits with return code 0
+
+* Delete all instances: VM1, VM2, VM3, VM4 and VM5
+
+* Delete all networks and subnets: networks N1 and N2 including subnets SN1 and SN2
+
+* Delete all network associations and VPN1
+
+
+Pass / fail criteria
+''''''''''''''''''''
+
+This test evaluates the capability of the NFVi and VIM to provide routed IP
+connectivity between VMs by means of BGP/MPLS VPNs. Specifically, the test
+verifies that:
+
+* VMs in the same Neutron subnet have IP connectivity regardless of BGP/MPLS
+ VPNs (test assertion 1, 2, 4)
+
+* VMs in different Neutron subnets do not have IP connectivity by default - in
+ this case without associating VPNs with the same import and export route
+ targets to the Neutron networks (test assertion 3)
+
+* VMs in different Neutron subnets have routed IP connectivity after
+ associating both networks with BGP/MPLS VPNs which have been configured with
+ the same import and export route targets (test assertion 5, 6). Hence,
+ adjusting the ingress and egress route targets enables as well as prohibits
+ routing.
+
+In order to pass this test, all test assertions listed in the test execution
+above need to pass.
+
+
+Post conditions
+---------------
+
+N/A
+
+------------------------------------------------------------
+Test Case 2 - VPNs ensure traffic separation between tenants
+------------------------------------------------------------
+
+Short Name
+----------
+
+opnfv.sdnvpn.tenant_separation
+
+
+Use case specification
+----------------------
+
+This test evaluates if VPNs provide separation of traffic such that overlapping
+IP ranges can be used.
+
+
+Test preconditions
+------------------
+
+2 compute nodes are available, denoted Node1 and Node2 in the following.
+
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for verifying connectivity
+''''''''''''''''''''''''''''''''''''''
+
+Connectivity between VMs is tested by establishing an SSH connection. Moreover,
+the command "hostname" is executed at the remote VM in order to retrieve the
+hostname of the remote VM. The retrieved hostname is furthermore compared
+against an expected value. This is used to verify tenant traffic separation,
+i.e., despite overlapping IPs, a connection is made to the correct VM as
+determined by means of the hostname of the target VM.
+
+
+
+Test execution
+''''''''''''''
+
+* Create Neutron network N1
+* Create subnet SN1a of network N1 with IP range 10.10.10.0/24
+* Create subnet SN1b of network N1 with IP range 10.10.11.0/24
+
+* Create Neutron network N2
+* Create subnet SN2a of network N2 with IP range 10.10.10.0/24
+* Create subnet SN2b of network N2 with IP range 10.10.11.0/24
+
+* Create VM1 on Node1 with a port in network N1 and IP 10.10.10.11.
+* Create VM2 on Node1 with a port in network N1 and IP 10.10.10.12.
+* Create VM3 on Node2 with a port in network N1 and IP 10.10.11.13.
+* Create VM4 on Node1 with a port in network N2 and IP 10.10.10.12.
+* Create VM5 on Node2 with a port in network N2 and IP 10.10.11.13.
+
+* Create VPN1 with iRT=eRT=RT1
+* Create network association between network N1 and VPN1
+
+* VM1 attempts to execute the command ``hostname`` on the VM with IP 10.10.10.12 via SSH.
+
+* **Test assertion 1:** VM1 can successfully connect to the VM with IP
+ 10.10.10.12. via SSH and execute the remote command ``hostname``. The
+ retrieved hostname equals the hostname of VM2.
+
+* VM1 attempts to execute the command ``hostname`` on the VM with IP 10.10.11.13 via SSH.
+
+* **Test assertion 2:** VM1 can successfully connect to the VM with IP
+ 10.10.11.13 via SSH and execute the remote command ``hostname``. The
+ retrieved hostname equals the hostname of VM3.
+
+* Create VPN2 with iRT=eRT=RT2
+* Create network association between network N2 and VPN2
+
+* VM4 attempts to execute the command ``hostname`` on the VM with IP 10.10.11.13 via SSH.
+
+* **Test assertion 3:** VM4 can successfully connect to the VM with IP
+ 10.10.11.13 via SSH and execute the remote command ``hostname``. The
+ retrieved hostname equals the hostname of VM5.
+
+* VM4 attempts to execute the command ``hostname`` on the VM with IP 10.10.11.11 via SSH.
+
+* **Test assertion 4:** VM4 cannot connect to the VM with IP 10.10.11.11 via SSH.
+
+* Delete all instances: VM1, VM2, VM3, VM4 and VM5
+
+* Delete all networks and subnets: networks N1 and N2 including subnets SN1a, SN1b, SN2a and SN2b
+
+* Delete all network associations, VPN1 and VPN2
+
+
+Pass / fail criteria
+''''''''''''''''''''
+
+This test evaluates the capability of the NFVi and VIM to provide routed IP
+connectivity between VMs by means of BGP/MPLS VPNs. Specifically, the test
+verifies that:
+
+* VMs in the same Neutron subnet (still) have IP connectivity between each
+ other when a BGP/MPLS VPN is associated with the network (test assertion 1).
+
+* VMs in different Neutron subnets have routed IP connectivity between each
+ other when BGP/MPLS VPNs with the same import and expert route targets are
+ associated with both networks (assertion 2).
+
+* VMs in different Neutron networks and BGP/MPLS VPNs with different import and
+ export route targets can have overlapping IP ranges. The BGP/MPLS VPNs
+ provide traffic separation (assertion 3 and 4).
+
+In order to pass this test, all test assertions listed in the test execution
+above need to pass.
+
+
+Post conditions
+---------------
+
+N/A
+
+--------------------------------------------------------------------------------
+Test Case 3 - VPN provides connectivity between subnets using router association
+--------------------------------------------------------------------------------
+
+Short Name
+----------
+
+opnfv.sdnvpn.router_association
+
+
+Use case specification
+----------------------
+
+This test evaluates if a VPN provides connectivity between two subnets by
+utilizing two different VPN association mechanisms: a router association and a
+network association.
+
+Specifically, the test network topology comprises two networks N1 and N2 with
+corresponding subnets. Additionally, network N1 is connected to a router R1.
+This test verifies that a VPN V1 provides connectivity between both networks
+when applying a router association to router R1 and a network association to
+network N2.
+
+
+Test preconditions
+------------------
+
+2 compute nodes are available, denoted Node1 and Node2 in the following.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for verifying connectivity
+''''''''''''''''''''''''''''''''''''''
+
+Connectivity between VMs is tested by sending ICMP ping packets between
+selected VMs. The target IPs are passed to the VMs sending pings by means of a
+custom user data script. Whether or not a ping was successful is determined by
+checking the console output of the source VMs.
+
+
+Test execution
+''''''''''''''
+
+* Create a network N1, a subnet SN1 with IP range 10.10.10.0/24 and a connected router R1
+* Create a network N2, a subnet SN2 with IP range 10.10.11.0/24
+
+* Create VM1 on Node1 with a port in network N1
+* Create VM2 on Node1 with a port in network N1
+* Create VM3 on Node2 with a port in network N1
+* Create VM4 on Node1 with a port in network N2
+* Create VM5 on Node2 with a port in network N2
+
+* Create VPN1 with eRT<>iRT so that connected subnets should not reach each other
+
+* Create route association between router R1 and VPN1
+
+* VM1 sends ICMP packets to VM2 using ``ping``
+
+* **Test assertion 1:** Ping from VM1 to VM2 succeeds: ``ping`` exits with return code 0
+
+* VM1 sends ICMP packets to VM3 using ``ping``
+
+* **Test assertion 2:** Ping from VM1 to VM3 succeeds: ``ping`` exits with return code 0
+
+* VM1 sends ICMP packets to VM4 using ``ping``
+
+* **Test assertion 3:** Ping from VM1 to VM4 fails: ``ping`` exits with a non-zero return code
+
+* Create network association between network N2 and VPN1
+
+* VM4 sends ICMP packets to VM5 using ``ping``
+
+* **Test assertion 4:** Ping from VM4 to VM5 succeeds: ``ping`` exits with return code 0
+
+* Change VPN1 so that iRT=eRT
+
+* VM1 sends ICMP packets to VM4 using ``ping``
+
+* **Test assertion 5:** Ping from VM1 to VM4 succeeds: ``ping`` exits with return code 0
+
+* VM1 sends ICMP packets to VM5 using ``ping``
+
+* **Test assertion 6:** Ping from VM1 to VM5 succeeds: ``ping`` exits with return code 0
+
+* Delete all instances: VM1, VM2, VM3, VM4 and VM5
+
+* Delete all networks, subnets and routers: networks N1 and N2 including subnets SN1 and SN2, router R1
+
+* Delete all network and router associations and VPN1
+
+
+Pass / fail criteria
+''''''''''''''''''''
+
+This test evaluates the capability of the NFVi and VIM to provide routed IP
+connectivity between VMs by means of BGP/MPLS VPNs. Specifically, the test
+verifies that:
+
+* VMs in the same Neutron subnet have IP connectivity regardless of the import
+ and export route target configuration of BGP/MPLS VPNs (test assertion 1, 2, 4)
+
+* VMs in different Neutron subnets do not have IP connectivity by default - in
+ this case without associating VPNs with the same import and export route
+ targets to the Neutron networks or connected Neutron routers (test assertion 3).
+
+* VMs in two different Neutron subnets have routed IP connectivity after
+ associating the first network and a router connected to the second network
+ with BGP/MPLS VPNs which have been configured with the same import and export
+ route targets (test assertion 5, 6). Hence, adjusting the ingress and egress
+ route targets enables as well as prohibits routing.
+
+* Network and router associations are equivalent methods for binding Neutron networks
+ to VPN.
+
+In order to pass this test, all test assertions listed in the test execution
+above need to pass.
+
+
+Post conditions
+---------------
+
+N/A
+
+---------------------------------------------------------------------------------------------------
+Test Case 4 - Verify interworking of router and network associations with floating IP functionality
+---------------------------------------------------------------------------------------------------
+
+Short Name
+----------
+
+opnfv.sdnvpn.router_association_floating_ip
+
+
+Use case specification
+----------------------
+
+This test evaluates if both the router association and network association
+mechanisms interwork with floating IP functionality.
+
+Specifically, the test network topology comprises two networks N1 and N2 with
+corresponding subnets. Additionally, network N1 is connected to a router R1.
+This test verifies that i) a VPN V1 provides connectivity between both networks
+when applying a router association to router R1 and a network association to
+network N2 and ii) a VM in network N1 is reachable externally by means of a
+floating IP.
+
+
+Test preconditions
+------------------
+
+At least one compute node is available.
+
+Basic test flow execution description and pass/fail criteria
+------------------------------------------------------------
+
+Methodology for verifying connectivity
+''''''''''''''''''''''''''''''''''''''
+
+Connectivity between VMs is tested by sending ICMP ping packets between
+selected VMs. The target IPs are passed to the VMs sending pings by means of a
+custom user data script. Whether or not a ping was successful is determined by
+checking the console output of the source VMs.
+
+
+Test execution
+''''''''''''''
+
+* Create a network N1, a subnet SN1 with IP range 10.10.10.0/24 and a connected router R1
+* Create a network N2 with IP range 10.10.20.0/24
+
+* Create VM1 with a port in network N1
+* Create VM2 with a port in network N2
+
+* Create VPN1
+* Create a router association between router R1 and VPN1
+* Create a network association between network N2 and VPN1
+
+
+* VM1 sends ICMP packets to VM2 using ``ping``
+
+* **Test assertion 1:** Ping from VM1 to VM2 succeeds: ``ping`` exits with return code 0
+
+* Assign a floating IP to VM1
+
+* The host running the test framework sends ICMP packets to VM1 using ``ping``
+
+* **Test assertion 2:** Ping from the host running the test framework to the
+ floating IP of VM1 succeeds: ``ping`` exits with return code 0
+
+* Delete floating IP assigned to VM1
+
+* Delete all instances: VM1, VM2
+
+* Delete all networks, subnets and routers: networks N1 and N2 including subnets SN1 and SN2, router R1
+
+* Delete all network and router associations as well as VPN1
+
+
+Pass / fail criteria
+''''''''''''''''''''
+
+This test evaluates the capability of the NFVi and VIM to provide routed IP
+connectivity between VMs by means of BGP/MPLS VPNs. Specifically, the test
+verifies that:
+
+* VMs in the same Neutron subnet have IP connectivity regardless of the import
+ and export route target configuration of BGP/MPLS VPNs (test assertion 1)
+
+* VMs connected to a network which has been associated with a BGP/MPLS VPN are
+ reachable through floating IPs.
+
+In order to pass this test, all test assertions listed in the test execution
+above need to pass.
+
+
+Post conditions
+---------------
+
+N/A