9693c382a8
instead upon any error in renameData(), we still preserve the existing dataDir in some form for recoverability in strange situations such as out of disk space type errors. Bonus: avoid running list and heal() instead allow versions disparity to return the actual versions, uuid to heal. Currently limit this to 100 versions and lesser disparate objects. an undo now reverts back the xl.meta from xl.meta.bkp during overwrites on such flaky setups. Bonus: Save N depth syscalls via skipping the parents upon overwrites and versioned updates. Flaky setup examples are stretch clusters with regular packet drops etc, we need to add some defensive code around to avoid dangling objects. |
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.. | ||
benchmark_test.go | ||
connection_test.go | ||
connection.go | ||
debug.go | ||
debugmsg_string.go | ||
errors.go | ||
grid_test.go | ||
grid_types_msgp_test.go | ||
grid_types_test.go | ||
grid.go | ||
handlers_string.go | ||
handlers.go | ||
manager.go | ||
msg_gen_test.go | ||
msg_gen.go | ||
msg_string.go | ||
msg.go | ||
muxclient.go | ||
muxserver.go | ||
README.md | ||
stats.go | ||
stream.go | ||
trace.go | ||
types_test.go | ||
types.go |
MinIO Grid
The MinIO Grid is a package that provides two-way communication between servers. It uses a single two-way connection to send and receive messages between servers.
It includes built in muxing of concurrent requests as well as congestion handling for streams.
Requests can be "Single Payload" or "Streamed".
Use the MinIO Grid for:
- Small, frequent requests with low latency requirements.
- Long-running requests with small/medium payloads.
Do not use the MinIO Grid for:
- Large payloads.
Only a single connection is ever made between two servers. Likely this means that this connection will not be able to saturate network bandwidth. Therefore, using this for large payloads will likely be slower than using a separate connection, and other connections will be blocked while the large payload is being sent.
Handlers & Routes
Handlers have a predefined Handler ID. In addition, there can be several static subroutes used to differentiate between different handlers of the same ID. A subroute on a client must match a subroute on the server. So routes cannot be used for dynamic routing, unlike HTTP.
Handlers should remain backwards compatible. If a breaking API change is required, a new handler ID should be created.
Setup & Configuration
A Manager is used to manage all incoming and outgoing connections to a server.
On startup all remote servers must be specified. From that individual connections will be spawned to each remote server, or incoming requests will be hooked up to the appropriate connection.
To get a connection to a specific server, use Manager.Connection(host)
to get a connection to the specified host.
From this connection individual requests can be made.
Each handler, with optional subroutes can be registered with the manager using
Manager.RegisterXHandler(handlerID, handler, subroutes...)
.
A Handler()
function provides an HTTP handler, which should be hooked up to the appropriate route on the server.
On startup, the manager will start connecting to remotes and also starts listening for incoming connections.
Until a connection is established, all outgoing requests will return ErrDisconnected
.
Usage
Single Payload Requests
Single payload requests are requests and responses that are sent in a single message.
In essence, they are []byte
-> []byte, error
functions.
It is not possible to return both an error and a response.
Handlers are registered on the manager using (*Manager).RegisterSingleHandler(id HandlerID, h SingleHandlerFn, subroute ...string)
.
The server handler function has this signature: type SingleHandlerFn func(payload []byte) ([]byte, *RemoteErr)
.
Sample handler:
handler := func(payload []byte) ([]byte, *grid.RemoteErr) {
// Do something with payload
return []byte("response"), nil
}
err := manager.RegisterSingleHandler(grid.HandlerDiskInfo, handler)
Sample call:
// Get a connection to the remote host
conn := manager.Connection(host)
payload := []byte("request")
response, err := conn.SingleRequest(ctx, grid.HandlerDiskInfo, payload)
If the error type is *RemoteErr
, then the error was returned by the remote server. Otherwise it is a local error.
Context timeouts are propagated, and a default timeout of 1 minute is added if none is specified.
There is no cancellation propagation for single payload requests. When the context is canceled, the request will return at once with an appropriate error. However, the remote call will not see the cancellation - as can be seen from the 'missing' context on the handler. The result will be discarded.
Typed handlers
Typed handlers are handlers that have a specific type for the request and response payloads.
These must provide msgp
serialization and deserialization.
In the examples we use a MSS
type, which is a map[string]string
that is msgp
serializable.
handler := func(request *grid.MSS) (*grid.MSS, *grid.RemoteErr) {
fmt.Println("Got request with field", request["myfield"])
// Do something with payload
return NewMSSWith(map[string]string{"result": "ok"}), nil
}
// Create a typed handler.
// Due to current generics limitations, a constructor of the empty type must be provided.
instance := grid.NewSingleHandler[*grid.MSS, *grid.MSS](h, grid.NewMSS, grid.NewMSS)
// Register the handler on the manager
instance.Register(manager, handler)
// The typed instance is also used for calls
conn := manager.Connection("host")
resp, err := instance.Call(ctx, conn, grid.NewMSSWith(map[string]string{"myfield": "myvalue"}))
if err == nil {
fmt.Println("Got response with field", resp["result"])
}
The wrapper will handle all serialization and de-seralization of the request and response, and furthermore provides reuse of the structs used for the request and response.
Note that Responses sent for serialization are automatically reused for similar requests.
If the response contains shared data it will cause issues, since each unique response is reused.
To disable this behavior, use (SingleHandler).WithSharedResponse()
to disable it.
Streaming Requests
Streams consists of an initial request with payload and allows for full two-way communication between the client and server.
The handler function has this signature.
Sample handler:
handler := func(ctx context.Context, payload []byte, in <-chan []byte, out chan<- []byte) *RemoteErr {
fmt.Println("Got request with initial payload", p, "from", GetCaller(ctx context.Context))
fmt.Println("Subroute:", GetSubroute(ctx))
for {
select {
case <-ctx.Done():
return nil
case req, ok := <-in:
if !ok {
break
}
// Do something with payload
out <- []byte("response")
// Return the request for reuse
grid.PutByteBuffer(req)
}
}
// out is closed by the caller and should never be closed by the handler.
return nil
}
err := manager.RegisterStreamingHandler(grid.HandlerDiskInfo, StreamHandler{
Handle: handler,
Subroute: "asubroute",
OutCapacity: 1,
InCapacity: 1,
})
Sample call:
// Get a connection to the remote host
conn := manager.Connection(host).Subroute("asubroute")
payload := []byte("request")
stream, err := conn.NewStream(ctx, grid.HandlerDiskInfo, payload)
if err != nil {
return err
}
// Read results from the stream
err = stream.Results(func(result []byte) error {
fmt.Println("Got result", string(result))
// Return the response for reuse
grid.PutByteBuffer(result)
return nil
})
Context cancellation and timeouts are propagated to the handler. The client does not wait for the remote handler to finish before returning. Returning any error will also cancel the stream remotely.
CAREFUL: When utilizing two-way communication, it is important to ensure that the remote handler is not blocked on a send. If the remote handler is blocked on a send, and the client is trying to send without the remote receiving, the operation would become deadlocked if the channels are full.
Typed handlers
Typed handlers are handlers that have a specific type for the request and response payloads.
// Create a typed handler.
handler := func(ctx context.Context, p *Payload, in <-chan *Req, out chan<- *Resp) *RemoteErr {
fmt.Println("Got request with initial payload", p, "from", GetCaller(ctx context.Context))
fmt.Println("Subroute:", GetSubroute(ctx))
for {
select {
case <-ctx.Done():
return nil
case req, ok := <-in:
if !ok {
break
}
fmt.Println("Got request", in)
// Do something with payload
out <- Resp{"response"}
}
// out is closed by the caller and should never be closed by the handler.
return nil
}
// Create a typed handler.
// Due to current generics limitations, a constructor of the empty type must be provided.
instance := grid.NewStream[*Payload, *Req, *Resp](h, newPayload, newReq, newResp)
// Tweakable options
instance.WithPayload = true // default true when newPayload != nil
instance.OutCapacity = 1 // default
instance.InCapacity = 1 // default true when newReq != nil
// Register the handler on the manager
instance.Register(manager, handler, "asubroute")
// The typed instance is also used for calls
conn := manager.Connection("host").Subroute("asubroute")
stream, err := instance.Call(ctx, conn, &Payload{"request payload"})
if err != nil { ... }
// Read results from the stream
err = stream.Results(func(resp *Resp) error {
fmt.Println("Got result", resp)
// Return the response for reuse
instance.PutResponse(resp)
return nil
})
There are handlers for requests with:
- No input stream:
RegisterNoInput
. - No initial payload:
RegisterNoPayload
.
Note that Responses sent for serialization are automatically reused for similar requests.
If the response contains shared data it will cause issues, since each unique response is reused.
To disable this behavior, use (StreamTypeHandler).WithSharedResponse()
to disable it.