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arikawa/utils/ws/op.go

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package ws
import (
"context"
"errors"
"fmt"
"sync"
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"github.com/diamondburned/arikawa/v3/utils/json"
)
// OpCode is the type for websocket Op codes. Op codes less than 0 are
// internal Op codes and should usually be ignored.
type OpCode int
// CloseEvent is an event that is given from wsutil when the websocket is
// closed.
type CloseEvent struct {
// Err is the underlying error.
Err error
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// Code is the websocket close code, if any. It is -1 otherwise.
Code int
}
// Unwrap returns err.Err.
func (e *CloseEvent) Unwrap() error { return e.Err }
// Error formats the CloseEvent. A CloseEvent is also an error.
func (e *CloseEvent) Error() string {
return fmt.Sprintf("websocket closed, reason: %s", e.Err)
}
// Op implements Event. It returns -1.
func (e *CloseEvent) Op() OpCode { return -1 }
// EventType implements Event. It returns an emty string.
func (e *CloseEvent) EventType() EventType { return "__ws.CloseEvent" }
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// EnableRawEvents, if true, will cause ws to generate a RawEvent for each
// regular Event. It should only be used for debugging.
var EnableRawEvents = false
// RawEvent is used if EnableRawEvents is true.
type RawEvent struct {
json.Raw
OriginalCode OpCode `json:"-"`
OriginalType EventType `json:"-"`
}
// Op implements Event. It returns -1.
func (e *RawEvent) Op() OpCode { return -1 }
// EventType implements Event. It returns an emty string.
func (e *RawEvent) EventType() EventType { return "__ws.RawEvent" }
// EventType is a type for event types, which is the "t" field in the payload.
type EventType string
// Event describes an Event data that comes from a gateway Operation.
type Event interface {
Op() OpCode
EventType() EventType
}
// OpFunc is a constructor function for an Operation.
type OpFunc func() Event
// OpUnmarshalers contains a map of event constructor function.
type OpUnmarshalers struct {
r map[opFuncID]OpFunc
}
type opFuncID struct {
Op OpCode `json:"op"`
T EventType `json:"t"`
}
// NewOpUnmarshalers creates a nwe OpUnmarshalers instance from the given
// constructor functions.
func NewOpUnmarshalers(funcs ...OpFunc) OpUnmarshalers {
m := OpUnmarshalers{r: make(map[opFuncID]OpFunc)}
m.Add(funcs...)
return m
}
// Each iterates over the marshaler map.
func (m OpUnmarshalers) Each(f func(OpCode, EventType, OpFunc) (done bool)) {
for id, fn := range m.r {
if f(id.Op, id.T, fn) {
return
}
}
}
// Add adds the given functions into the unmarshaler registry.
func (m OpUnmarshalers) Add(funcs ...OpFunc) {
for _, fn := range funcs {
ev := fn()
id := opFuncID{
Op: ev.Op(),
T: ev.EventType(),
}
m.r[id] = fn
}
}
// Lookup searches the OpMarshalers map for the given constructor function.
func (m OpUnmarshalers) Lookup(op OpCode, t EventType) OpFunc {
return m.r[opFuncID{op, t}]
}
// Op is a gateway Operation.
type Op struct {
Code OpCode `json:"op"`
Data Event `json:"d,omitempty"`
// Type is only for gateway dispatch events.
Type EventType `json:"t,omitempty"`
// Sequence is only for gateway dispatch events (Op 0).
Sequence int64 `json:"s,omitempty"`
}
// UnknownEventError is required by HandleOp if an event is encountered that is
// not known. Internally, unknown events are logged and ignored. It is not a
// fatal error.
type UnknownEventError struct {
Op OpCode
Type EventType
}
// Error formats the unknown event error to with the event name and payload
func (err UnknownEventError) Error() string {
return fmt.Sprintf("unknown op %d, event %s", err.Op, err.Type)
}
// IsBrokenConnection returns true if the error is a broken connection error.
func IsUnknownEvent(err error) bool {
var uevent *UnknownEventError
return errors.As(err, &uevent)
}
// ReadOps reads maximum n Ops and accumulate them into a slice.
func ReadOps(ctx context.Context, ch <-chan Op, n int) ([]Op, error) {
ops := make([]Op, 0, n)
for {
select {
case <-ctx.Done():
return ops, ctx.Err()
case op := <-ch:
ops = append(ops, op)
if len(ops) == n {
return ops, nil
}
}
}
}
// ReadOp reads a single Op.
func ReadOp(ctx context.Context, ch <-chan Op) (Op, error) {
select {
case <-ctx.Done():
return Op{}, ctx.Err()
case op := <-ch:
return op, nil
}
}
// Broadcaster is primarily used for debugging.
type Broadcaster struct {
src <-chan Op
dst map[chan<- Op]struct{}
mut sync.Mutex
void bool
}
// NewBroadcaster creates a new broadcaster.
func NewBroadcaster(src <-chan Op) *Broadcaster {
return &Broadcaster{
src: src,
dst: make(map[chan<- Op]struct{}),
}
}
// Start starts the broadcasting loop.
func (b *Broadcaster) Start() {
b.mut.Lock()
if b.void {
panic("Start called on voided Broadcaster")
}
b.mut.Unlock()
go func() {
for op := range b.src {
b.mut.Lock()
for ch := range b.dst {
ch <- op
}
b.mut.Unlock()
}
b.mut.Lock()
b.void = true
for ch := range b.dst {
close(ch)
}
b.mut.Unlock()
}()
}
// Subscribe subscribes the given channel
func (b *Broadcaster) Subscribe(ch chan<- Op) {
b.mut.Lock()
if b.void {
panic("Subscribe called on voided Broadcaster")
}
b.dst[ch] = struct{}{}
b.mut.Unlock()
}
// NewSubscribed creates a newly subscribed Op channel.
func (b *Broadcaster) NewSubscribed() <-chan Op {
ch := make(chan Op, 1)
b.Subscribe(ch)
return ch
}