Quality of Service

Quality of Service advanced service is designed as a service plugin. The service is decoupled from the rest of Neutron code on multiple levels (see below).

QoS extends core resources (ports, networks) without using mixins inherited from plugins but through an ml2 extension driver.

Details about the DB models, API extension, and use cases can be found here: qos spec .

Service side design

  • neutron.extensions.qos: base extension + API controller definition. Note that rules are subattributes of policies and hence embedded into their URIs.
  • neutron.services.qos.qos_plugin: QoSPlugin, service plugin that implements ‘qos’ extension, receiving and handling API calls to create/modify policies and rules.
  • neutron.services.qos.drivers.manager: the manager that passes object actions down to every enabled QoS driver and issues RPC calls when any of the drivers require RPC push notifications.
  • neutron.services.qos.drivers.base: the interface class for pluggable QoS drivers that are used to update backends about new {create, update, delete} events on any rule or policy change. The drivers also declare which QoS rules, VIF drivers and VNIC types are supported.
  • neutron.core_extensions.base: Contains an interface class to implement core resource (port/network) extensions. Core resource extensions are then easily integrated into interested plugins. We may need to have a core resource extension manager that would utilize those extensions, to avoid plugin modifications for every new core resource extension.
  • neutron.core_extensions.qos: Contains QoS core resource extension that conforms to the interface described above.
  • neutron.plugins.ml2.extensions.qos: Contains ml2 extension driver that handles core resource updates by reusing the core_extensions.qos module mentioned above. In the future, we would like to see a plugin-agnostic core resource extension manager that could be integrated into other plugins with ease.

QoS plugin implementation guide

The neutron.extensions.qos.QoSPluginBase class uses method proxies for methods relating to QoS policy rules. Each of these such methods is generic in the sense that it is intended to handle any rule type. For example, QoSPluginBase has a create_policy_rule method instead of both create_policy_dscp_marking_rule and create_policy_bandwidth_limit_rule methods. The logic behind the proxies allows a call to a plugin’s create_policy_dscp_marking_rule to be handled by the create_policy_rule method, which will receive a QosDscpMarkingRule object as an argument in order to execute behavior specific to the DSCP marking rule type. This approach allows new rule types to be introduced without requiring a plugin to modify code as a result. As would be expected, any subclass of QoSPluginBase must override the base class’s abc.abstractmethod methods, even if to raise NotImplemented.

Supported QoS rule types

Each QoS driver has a property called supported_rule_types, where the driver exposes the rules it’s able to handle.

For a list of all rule types, see: neutron.services.qos.qos_consts.VALID_RULE_TYPES.

The list of supported QoS rule types exposed by neutron is calculated as the common subset of rules supported by all active QoS drivers.

Note: the list of supported rule types reported by core plugin is not enforced when accessing QoS rule resources. This is mostly because then we would not be able to create rules while at least one of the QoS driver in gate lacks support for the rules we’re trying to test.

Database models

QoS design defines the following two conceptual resources to apply QoS rules for a port or a network:

  • QoS policy
  • QoS rule (type specific)

Each QoS policy contains zero or more QoS rules. A policy is then applied to a network or a port, making all rules of the policy applied to the corresponding Neutron resource.

When applied through a network association, policy rules could apply or not to neutron internal ports (like router, dhcp, load balancer, etc..). The QosRule base object provides a default should_apply_to_port method which could be overridden. In the future we may want to have a flag in QoSNetworkPolicyBinding or QosRule to enforce such type of application (for example when limiting all the ingress of routers devices on an external network automatically).

From database point of view, following objects are defined in schema:

  • QosPolicy: directly maps to the conceptual policy resource.
  • QosNetworkPolicyBinding, QosPortPolicyBinding: defines attachment between a Neutron resource and a QoS policy.
  • QosBandwidthLimitRule: defines the rule to limit the maximum egress bandwidth.
  • QosDscpMarkingRule: defines the rule that marks the Differentiated Service bits for egress traffic.

All database models are defined under:

  • neutron.db.qos.models

QoS versioned objects

There is a long history of passing database dictionaries directly into business logic of Neutron. This path is not the one we wanted to take for QoS effort, so we’ve also introduced a new objects middleware to encapsulate the database logic from the rest of the Neutron code that works with QoS resources. For this, we’ve adopted oslo.versionedobjects library and introduced a new NeutronObject class that is a base for all other objects that will belong to the middle layer. There is an expectation that Neutron will evolve into using objects for all resources it handles, though that part was obviously out of scope for the QoS effort.

Every NeutronObject supports the following operations:

  • get_object: returns specific object that is represented by the id passed as an argument.
  • get_objects: returns all objects of the type, potentially with a filter applied.
  • create/update/delete: usual persistence operations.

Base object class is defined in:

  • neutron.objects.base

For QoS, new neutron objects were implemented:

  • QosPolicy: directly maps to the conceptual policy resource, as defined above.
  • QosBandwidthLimitRule: defines the instance-egress bandwidth limit rule type, characterized by a max kbps and a max burst kbits.
  • QosDscpMarkingRule: defines the DSCP rule type, characterized by an even integer between 0 and 56. These integers are the result of the bits in the DiffServ section of the IP header, and only certain configurations are valid. As a result, the list of valid DSCP rule types is: 0, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28, 30, 32, 34, 36, 38, 40, 46, 48, and 56.
  • QosMinimumBandwidthRule: defines the minimum assured bandwidth rule type, characterized by a min_kbps parameter. This rule has also a direction parameter to set the traffic direction, from the instance point of view. The only direction now implemented is egress.

Those are defined in:

  • neutron.objects.qos.policy
  • neutron.objects.qos.rule

For QosPolicy neutron object, the following public methods were implemented:

  • get_network_policy/get_port_policy: returns a policy object that is attached to the corresponding Neutron resource.
  • attach_network/attach_port: attach a policy to the corresponding Neutron resource.
  • detach_network/detach_port: detach a policy from the corresponding Neutron resource.

In addition to the fields that belong to QoS policy database object itself, synthetic fields were added to the object that represent lists of rules that belong to the policy. To get a list of all rules for a specific policy, a consumer of the object can just access the corresponding attribute via:

  • policy.rules

Implementation is done in a way that will allow adding a new rule list field with little or no modifications in the policy object itself. This is achieved by smart introspection of existing available rule object definitions and automatic definition of those fields on the policy class.

Note that rules are loaded in a non lazy way, meaning they are all fetched from the database on policy fetch.

For Qos<type>Rule objects, an extendable approach was taken to allow easy addition of objects for new rule types. To accommodate this, fields common to all types are put into a base class called QosRule that is then inherited into type-specific rule implementations that, ideally, only define additional fields and some other minor things.

Note that the QosRule base class is not registered with oslo.versionedobjects registry, because it’s not expected that ‘generic’ rules should be instantiated (and to suggest just that, the base rule class is marked as ABC).

QoS objects rely on some primitive database API functions that are added in:

  • neutron.db.api: those can be reused to fetch other models that do not have corresponding versioned objects yet, if needed.
  • neutron.db.qos.api: contains database functions that are specific to QoS models.

RPC communication

Details on RPC communication implemented in reference backend driver are discussed in a separate page.

One thing that should be mentioned here explicitly is that RPC callback endpoints communicate using real versioned objects (as defined by serialization for oslo.versionedobjects library), not vague json dictionaries. Meaning, oslo.versionedobjects are on the wire and not just used internally inside a component.

One more thing to note is that though RPC interface relies on versioned objects, it does not yet rely on versioning features the oslo.versionedobjects library provides. This is because Liberty is the first release where we start using the RPC interface, so we have no way to get different versions in a cluster. That said, the versioning strategy for QoS is thought through and described in the separate page.

There is expectation that after RPC callbacks are introduced in Neutron, we will be able to migrate propagation from server to agents for other resources (f.e. security groups) to the new mechanism. This will need to wait until those resources get proper NeutronObject implementations.

The flow of updates is as follows:

  • if a port that is bound to the agent is attached to a QoS policy, then ML2 plugin detects the change by relying on ML2 QoS extension driver, and notifies the agent about a port change. The agent proceeds with the notification by calling to get_device_details() and getting the new port dict that contains a new qos_policy_id. Each device details dict is passed into l2 agent extension manager that passes it down into every enabled extension, including QoS. QoS extension sees that there is a new unknown QoS policy for a port, so it uses ResourcesPullRpcApi to fetch the current state of the policy (with all the rules included) from the server. After that, the QoS extension applies the rules by calling into QoS driver that corresponds to the agent.
  • on existing QoS policy update (it includes any policy or its rules change), server pushes the new policy object state through ResourcesPushRpcApi interface. The interface fans out the serialized (dehydrated) object to any agent that is listening for QoS policy updates. If an agent have seen the policy before (it is attached to one of the ports it maintains), then it goes with applying the updates to the port. Otherwise, the agent silently ignores the update.

Agent side design

Reference agents implement QoS functionality using an L2 agent extension.

  • neutron.agent.l2.extensions.qos defines QoS L2 agent extension. It receives handle_port and delete_port events and passes them down into QoS agent backend driver (see below). The file also defines the QosAgentDriver interface. Note: each backend implements its own driver. The driver handles low level interaction with the underlying networking technology, while the QoS extension handles operations that are common to all agents.

Agent backends

At the moment, QoS is supported by Open vSwitch, SR-IOV and Linux bridge ml2 drivers.

Each agent backend defines a QoS driver that implements the QosAgentDriver interface:

  • Open vSwitch (QosOVSAgentDriver);
  • SR-IOV (QosSRIOVAgentDriver);
  • Linux bridge (QosLinuxbridgeAgentDriver).

Open vSwitch

Open vSwitch implementation relies on the new ovs_lib OVSBridge functions:

  • get_egress_bw_limit_for_port
  • create_egress_bw_limit_for_port
  • delete_egress_bw_limit_for_port

An egress bandwidth limit is effectively configured on the port by setting the port Interface parameters ingress_policing_rate and ingress_policing_burst.

That approach is less flexible than linux-htb, Queues and OvS QoS profiles, which we may explore in the future, but which will need to be used in combination with openflow rules.

The Open vSwitch DSCP marking implementation relies on the recent addition of the ovs_agent_extension_api OVSAgentExtensionAPI to request access to the integration bridge functions:

  • add_flow
  • mod_flow
  • delete_flows
  • dump_flows_for

The DSCP markings are in fact configured on the port by means of openflow rules.

SR-IOV

SR-IOV bandwidth limit implementation relies on the new pci_lib function:

  • set_vf_max_rate

As the name of the function suggests, the limit is applied on a Virtual Function (VF).

ip link interface has the following limitation for bandwidth limit: it uses Mbps as units of bandwidth measurement, not kbps, and does not support float numbers. So in case the limit is set to something less than 1000 kbps, it’s set to 1 Mbps only. If the limit is set to something that does not divide to 1000 kbps chunks, then the effective limit is rounded to the nearest integer Mbps value.

Linux bridge

The Linux bridge implementation relies on the new tc_lib functions:

  • set_bw_limit
  • update_bw_limit
  • delete_bw_limit

The ingress bandwidth limit is configured on the tap port by setting a simple tc-tbf queueing discipline (qdisc) on the port. It requires a value of HZ parameter configured in kernel on the host. This value is necessary to calculate the minimal burst value which is set in tc. Details about how it is calculated can be found in here. This solution is similar to Open vSwitch implementation.

QoS driver design

QoS framework is flexible enough to support any third-party vendor. To integrate a third party driver (that just wants to be aware of the QoS create/update/delete API calls), one needs to implement ‘neutron.services.qos.drivers.base’, and register the driver during the core plugin or mechanism driver load, see

neutron.services.qos.drivers.openvswitch.driver register method for an example.

Note

All the functionality MUST be implemented by the vendor, neutron’s QoS framework will just act as an interface to bypass the received QoS API request and help with database persistence for the API operations.

Configuration

To enable the service, the following steps should be followed:

On server side:

  • enable qos service in service_plugins;
  • for ml2, add ‘qos’ to extension_drivers in [ml2] section.

On agent side (OVS):

  • add ‘qos’ to extensions in [agent] section.

Testing strategy

All the code added or extended as part of the effort got reasonable unit test coverage.

Neutron objects

Base unit test classes to validate neutron objects were implemented in a way that allows code reuse when introducing a new object type.

There are two test classes that are utilized for that:

  • BaseObjectIfaceTestCase: class to validate basic object operations (mostly CRUD) with database layer isolated.
  • BaseDbObjectTestCase: class to validate the same operations with models in place and database layer unmocked.

Every new object implemented on top of one of those classes is expected to either inherit existing test cases as is, or reimplement it, if it makes sense in terms of how those objects are implemented. Specific test classes can obviously extend the set of test cases as they see needed (f.e. you need to define new test cases for those additional methods that you may add to your object implementations on top of base semantics common to all neutron objects).

Functional tests

Additions to ovs_lib to set bandwidth limits on ports are covered in:

  • neutron.tests.functional.agent.test_ovs_lib

New functional tests for tc_lib to set bandwidth limits on ports are in:

  • neutron.tests.functional.agent.linux.test_tc_lib

API tests

API tests for basic CRUD operations for ports, networks, policies, and rules were added in:

  • neutron.tests.tempest.api.test_qos