syncproto

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Published: Nov 8, 2018 License: Apache-2.0 Imports: 8 Imported by: 37

Documentation

Overview

The syncproto package defines the structs used in the Felix/Typha protocol.

Overview

Felix connects to Typha over a TCP socket, then Felix initiates the (synchronous) handshake consisting of a ClientHello then a ServerHello message.

Once the handshake is complete, Typha sends a series of KV pairs to Felix, amounting to a complete snapshot of the datastore. It may send more than one KV message, each containing one or more KV pairs.

Once a complete snapshot has been sent, Typha sends a SyncStatus message with its current sync status. This is typically "InSync" but it may be another status, such as "Resync" if Typha itself is resyncing with the datastore.

At any point after the handshake, Typha may send a Ping message, which Felix should respond to as quickly as possible with a Pong (if Typha doesn't receive a timely response it may terminate the connection).

After the initial snapshot is sent, Typha sends KVs and SyncStatus messages as new updates are received from the datastore.

+-------+                +-------+
| Felix |                | Typha |
+-------+                +-------+
|                        |
| connect                |
|----------------------->|
|                        | -------------------------------\
|                        |-| accept, wait for ClientHello |
|                        | |------------------------------|
|                        |
| ClientHello            |
|----------------------->|
|                        |
|            ServerHello |
|<-----------------------|
|                        | ------------------------------------\
|                        |-| start KV send & pinger goroutines |
|                        | |-----------------------------------|
|                        |
|                KVs * n |
|<-----------------------|
|                        |
|                   Ping |
|<-----------------------|
|                        |
| Pong                   |
|----------------------->|
|                        |
|                KVs * n |
|<-----------------------|
|                        |
|     SyncStatus(InSync) |
|<-----------------------|
|                        |
|                KVs * n |
|<-----------------------|
|                        |

Wire format

The protocol uses gob to encode messages. Each message is wrapped in an Envelope struct to simplify decoding.

Key/value pairs are encoded as SerializedUpdate objects. These contain the KV pair along with the Syncer metadata about the update (such as its revision and update type). The key and value are encoded to the libcalico-go "default" encoding, as used when storing data in, for example, etcd. I.e. the gob struct contains string and []byte fields to hold the key and value, respectively. Doing this has some advantages:

(1) It avoids any subtle incompatibility between our datamodel and gob.

(2) It removes the need to register all our datatypes with the gob en/decoder.

(3) It re-uses known-good serialization code with known semantics around
    data-model upgrade.  I.e. since that serialization is based on the JSON
    marshaller, we know how it treats added/removed fields.

(4) It allows us to do the serialization of each KV pair once and send it to
    all listening clients.  (Doing this in gob is not easy because the gob
    connection is stateful.)

Upgrading the datamodel

Some care needs to be taken when upgrading Felix and Typha to ensure that datamodel changes are correctly handled.

Since Typha parses resources from the datamodel and then serializes them again,

  • Typha can only pass through resources (and fields) that were present in the version of libcalico-go that it was compiled against.

  • Similarly, Felix can only parse resources and fields that were present in the version of libcalico-go that it was compiled against.

  • It is important that even synthesized resources (for example, those that are generated by the Kubernetes datastore driver) are serializable, even if we never normally write them to a key/value based datastore such as etcd.

In the common case, where a new field is added to the datamodel:

  • If a new Felix connects to an old Typha then Typha will strip the new field at parse-time and pass the object through to Felix. Hence Felix will behave as if the field wasn't present. As long as the field was added in a back-compatible way, Felix should default to its old behaviour and the overall outcome will be that new Felix will behave as if it was an old Felix.

  • If an old Felix connects to a new Typha, then Typha will pass through the new field to Felix but Felix will strip it out when it parses the update.

Where a whole new resource is added:

  • If a new Felix connects to an old Typha then Typha will ignore the new resource so it is important that Felix is engineered to allow for missing resources in that case.

  • If an old Felix connects to a new Typha then Typha will send the resource but the old Felix will fail to parse it. In that case, the Typha client code used by Felix drops the KV pair and logs an error.

In more complicated cases: it's important to think through how the above cases play out. For example, removing one synthesized resource type and adding another to take its place may no longer work as intended since the new one will get stripped out when a mixed Typha/Felix version connection occurs.

If such a change does need to be made, we could treat it as a Typha protocol upgrade as described below.

Upgrading the Typha protocol

Currently, the Typha protocol is unversioned. It is important that an uplevel Typha doesn't send a new uplevel message to a downlevel Felix or vice-versa since the gob decoder would fail to parse the message, resulting in closing the connection.

If we need to add new unsolicited messages in either direction, we could add a ProtocolVersion field to the handshake messages. Since gob defaults fields to their zero value if they're not present on the wire, a Typha with a ProtocolVersion field that receives a connection from an old Felix with no field would see 0 as the value of the field and could act accordingly.

If a more serious upgrade is needed (such as replacing gob), we could use a second port for the new protocol.

Index

Constants

View Source
const DefaultPort = 5473

Variables

View Source
var ErrBadKey = errors.New("Unable to parse key.")

Functions

This section is empty.

Types

type Envelope

type Envelope struct {
	Message interface{}
}

type MsgClientHello

type MsgClientHello struct {
	Hostname string
	Info     string
	Version  string
}

type MsgKVs

type MsgKVs struct {
	KVs []SerializedUpdate
}

type MsgPing

type MsgPing struct {
	Timestamp time.Time
}

type MsgPong

type MsgPong struct {
	PingTimestamp time.Time
	PongTimestamp time.Time
}

type MsgServerHello

type MsgServerHello struct {
	Version string
}

type MsgSyncStatus

type MsgSyncStatus struct {
	SyncStatus api.SyncStatus
}

type SerializedUpdate

type SerializedUpdate struct {
	Key        string
	Value      []byte
	Revision   interface{}
	TTL        time.Duration
	UpdateType api.UpdateType
}

func SerializeUpdate

func SerializeUpdate(u api.Update) (su SerializedUpdate, err error)

func (SerializedUpdate) String

func (s SerializedUpdate) String() string

func (SerializedUpdate) ToUpdate

func (s SerializedUpdate) ToUpdate() (api.Update, error)

func (SerializedUpdate) WouldBeNoOp

func (s SerializedUpdate) WouldBeNoOp(previous SerializedUpdate) bool

WouldBeNoOp returns true if this update would be a no-op given that previous has already been sent.

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