640 lines
16 KiB
Go
640 lines
16 KiB
Go
// Copyright (c) Liam Stanley <me@liamstanley.io>. All rights reserved. Use
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// of this source code is governed by the MIT license that can be found in
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// the LICENSE file.
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package girc
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import (
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"bytes"
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"encoding/base64"
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"fmt"
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"io"
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"sort"
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"strings"
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)
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var possibleCap = map[string][]string{
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"account-notify": nil,
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"account-tag": nil,
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"away-notify": nil,
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"batch": nil,
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"cap-notify": nil,
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"chghost": nil,
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"extended-join": nil,
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"invite-notify": nil,
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"message-tags": nil,
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"multi-prefix": nil,
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"userhost-in-names": nil,
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}
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func (c *Client) listCAP() {
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if !c.Config.disableTracking {
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c.write(&Event{Command: CAP, Params: []string{CAP_LS, "302"}})
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}
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}
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func possibleCapList(c *Client) map[string][]string {
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out := make(map[string][]string)
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if c.Config.SASL != nil {
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out["sasl"] = nil
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}
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for k := range c.Config.SupportedCaps {
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out[k] = c.Config.SupportedCaps[k]
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}
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for k := range possibleCap {
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out[k] = possibleCap[k]
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}
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return out
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}
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func parseCap(raw string) map[string][]string {
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out := make(map[string][]string)
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parts := strings.Split(raw, " ")
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var val int
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for i := 0; i < len(parts); i++ {
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val = strings.IndexByte(parts[i], prefixTagValue) // =
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// No value splitter, or has splitter but no trailing value.
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if val < 1 || len(parts[i]) < val+1 {
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// The capability doesn't contain a value.
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out[parts[i]] = nil
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continue
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}
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out[parts[i][:val]] = strings.Split(parts[i][val+1:], ",")
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}
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return out
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}
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// handleCAP attempts to find out what IRCv3 capabilities the server supports.
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// This will lock further registration until we have acknowledged the
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// capabilities.
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func handleCAP(c *Client, e Event) {
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if len(e.Params) >= 2 && (e.Params[1] == CAP_NEW || e.Params[1] == CAP_DEL) {
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c.listCAP()
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return
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}
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// We can assume there was a failure attempting to enable a capability.
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if len(e.Params) == 2 && e.Params[1] == CAP_NAK {
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// Let the server know that we're done.
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c.write(&Event{Command: CAP, Params: []string{CAP_END}})
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return
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}
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possible := possibleCapList(c)
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if len(e.Params) >= 2 && len(e.Trailing) > 1 && e.Params[1] == CAP_LS {
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c.state.Lock()
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caps := parseCap(e.Trailing)
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for k := range caps {
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if _, ok := possible[k]; !ok {
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continue
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}
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if len(possible[k]) == 0 || len(caps[k]) == 0 {
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c.state.tmpCap = append(c.state.tmpCap, k)
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continue
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}
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var contains bool
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for i := 0; i < len(caps[k]); i++ {
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for j := 0; j < len(possible[k]); j++ {
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if caps[k][i] == possible[k][j] {
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// Assume we have a matching split value.
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contains = true
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goto checkcontains
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}
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}
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}
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checkcontains:
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if !contains {
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continue
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}
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c.state.tmpCap = append(c.state.tmpCap, k)
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}
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c.state.Unlock()
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// Indicates if this is a multi-line LS. (2 args means it's the
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// last LS).
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if len(e.Params) == 2 {
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// If we support no caps, just ack the CAP message and END.
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if len(c.state.tmpCap) == 0 {
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c.write(&Event{Command: CAP, Params: []string{CAP_END}})
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return
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}
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// Let them know which ones we'd like to enable.
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c.write(&Event{Command: CAP, Params: []string{CAP_REQ}, Trailing: strings.Join(c.state.tmpCap, " "), EmptyTrailing: true})
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// Re-initialize the tmpCap, so if we get multiple 'CAP LS' requests
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// due to cap-notify, we can re-evaluate what we can support.
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c.state.Lock()
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c.state.tmpCap = []string{}
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c.state.Unlock()
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}
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}
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if len(e.Params) == 2 && len(e.Trailing) > 1 && e.Params[1] == CAP_ACK {
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c.state.Lock()
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c.state.enabledCap = strings.Split(e.Trailing, " ")
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// Do we need to do sasl auth?
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wantsSASL := false
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for i := 0; i < len(c.state.enabledCap); i++ {
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if c.state.enabledCap[i] == "sasl" {
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wantsSASL = true
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break
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}
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}
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c.state.Unlock()
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if wantsSASL {
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c.write(&Event{Command: AUTHENTICATE, Params: []string{c.Config.SASL.Method()}})
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// Don't "CAP END", since we want to authenticate.
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return
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}
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// Let the server know that we're done.
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c.write(&Event{Command: CAP, Params: []string{CAP_END}})
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return
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}
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}
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// SASLMech is an representation of what a SASL mechanism should support.
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// See SASLExternal and SASLPlain for implementations of this.
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type SASLMech interface {
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// Method returns the uppercase version of the SASL mechanism name.
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Method() string
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// Encode returns the response that the SASL mechanism wants to use. If
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// the returned string is empty (e.g. the mechanism gives up), the handler
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// will attempt to panic, as expectation is that if SASL authentication
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// fails, the client will disconnect.
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Encode(params []string) (output string)
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}
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// SASLExternal implements the "EXTERNAL" SASL type.
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type SASLExternal struct {
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// Identity is an optional field which allows the client to specify
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// pre-authentication identification. This means that EXTERNAL will
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// supply this in the initial response. This usually isn't needed (e.g.
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// CertFP).
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Identity string `json:"identity"`
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}
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// Method identifies what type of SASL this implements.
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func (sasl *SASLExternal) Method() string {
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return "EXTERNAL"
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}
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// Encode for external SALS authentication should really only return a "+",
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// unless the user has specified pre-authentication or identification data.
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// See https://tools.ietf.org/html/rfc4422#appendix-A for more info.
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func (sasl *SASLExternal) Encode(params []string) string {
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if len(params) != 1 || params[0] != "+" {
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return ""
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}
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if sasl.Identity != "" {
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return sasl.Identity
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}
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return "+"
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}
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// SASLPlain contains the user and password needed for PLAIN SASL authentication.
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type SASLPlain struct {
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User string `json:"user"` // User is the username for SASL.
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Pass string `json:"pass"` // Pass is the password for SASL.
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}
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// Method identifies what type of SASL this implements.
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func (sasl *SASLPlain) Method() string {
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return "PLAIN"
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}
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// Encode encodes the plain user+password into a SASL PLAIN implementation.
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// See https://tools.ietf.org/rfc/rfc4422.txt for more info.
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func (sasl *SASLPlain) Encode(params []string) string {
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if len(params) != 1 || params[0] != "+" {
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return ""
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}
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in := []byte(sasl.User)
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in = append(in, 0x0)
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in = append(in, []byte(sasl.User)...)
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in = append(in, 0x0)
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in = append(in, []byte(sasl.Pass)...)
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return base64.StdEncoding.EncodeToString(in)
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}
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const saslChunkSize = 400
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func handleSASL(c *Client, e Event) {
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if e.Command == RPL_SASLSUCCESS || e.Command == ERR_SASLALREADY {
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// Let the server know that we're done.
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c.write(&Event{Command: CAP, Params: []string{CAP_END}})
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return
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}
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// Assume they want us to handle sending auth.
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auth := c.Config.SASL.Encode(e.Params)
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if auth == "" {
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// Assume the SASL authentication method doesn't want to respond for
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// some reason. The SASL spec and IRCv3 spec do not define a clear
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// way to abort a SASL exchange, other than to disconnect, or proceed
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// with CAP END.
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c.rx <- &Event{Command: ERROR, Trailing: fmt.Sprintf(
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"closing connection: invalid %s SASL configuration provided: %s",
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c.Config.SASL.Method(), e.Trailing,
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)}
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return
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}
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// Send in "saslChunkSize"-length byte chunks. If the last chuck is
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// exactly "saslChunkSize" bytes, send a "AUTHENTICATE +" 0-byte
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// acknowledgement response to let the server know that we're done.
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for {
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if len(auth) > saslChunkSize {
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c.write(&Event{Command: AUTHENTICATE, Params: []string{auth[0 : saslChunkSize-1]}, Sensitive: true})
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auth = auth[saslChunkSize:]
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continue
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}
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if len(auth) <= saslChunkSize {
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c.write(&Event{Command: AUTHENTICATE, Params: []string{auth}, Sensitive: true})
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if len(auth) == 400 {
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c.write(&Event{Command: AUTHENTICATE, Params: []string{"+"}})
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}
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break
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}
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}
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return
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}
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func handleSASLError(c *Client, e Event) {
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if c.Config.SASL == nil {
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c.write(&Event{Command: CAP, Params: []string{CAP_END}})
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return
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}
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// Authentication failed. The SASL spec and IRCv3 spec do not define a
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// clear way to abort a SASL exchange, other than to disconnect, or
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// proceed with CAP END.
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c.rx <- &Event{Command: ERROR, Trailing: "closing connection: " + e.Trailing}
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}
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// handleCHGHOST handles incoming IRCv3 hostname change events. CHGHOST is
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// what occurs (when enabled) when a servers services change the hostname of
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// a user. Traditionally, this was simply resolved with a quick QUIT and JOIN,
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// however CHGHOST resolves this in a much cleaner fashion.
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func handleCHGHOST(c *Client, e Event) {
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if len(e.Params) != 2 {
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return
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}
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c.state.Lock()
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user := c.state.lookupUser(e.Source.Name)
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if user != nil {
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user.Ident = e.Params[0]
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user.Host = e.Params[1]
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}
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c.state.Unlock()
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c.state.notify(c, UPDATE_STATE)
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}
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// handleAWAY handles incoming IRCv3 AWAY events, for which are sent both
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// when users are no longer away, or when they are away.
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func handleAWAY(c *Client, e Event) {
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c.state.Lock()
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user := c.state.lookupUser(e.Source.Name)
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if user != nil {
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user.Extras.Away = e.Trailing
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}
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c.state.Unlock()
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c.state.notify(c, UPDATE_STATE)
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}
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// handleACCOUNT handles incoming IRCv3 ACCOUNT events. ACCOUNT is sent when
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// a user logs into an account, logs out of their account, or logs into a
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// different account. The account backend is handled server-side, so this
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// could be NickServ, X (undernet?), etc.
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func handleACCOUNT(c *Client, e Event) {
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if len(e.Params) != 1 {
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return
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}
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account := e.Params[0]
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if account == "*" {
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account = ""
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}
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c.state.Lock()
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user := c.state.lookupUser(e.Source.Name)
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if user != nil {
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user.Extras.Account = account
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}
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c.state.Unlock()
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c.state.notify(c, UPDATE_STATE)
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}
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// handleTags handles any messages that have tags that will affect state. (e.g.
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// 'account' tags.)
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func handleTags(c *Client, e Event) {
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if len(e.Tags) == 0 {
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return
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}
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account, ok := e.Tags.Get("account")
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if !ok {
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return
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}
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c.state.Lock()
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user := c.state.lookupUser(e.Source.Name)
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if user != nil {
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user.Extras.Account = account
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}
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c.state.Unlock()
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c.state.notify(c, UPDATE_STATE)
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}
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const (
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prefixTag byte = '@'
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prefixTagValue byte = '='
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prefixUserTag byte = '+'
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tagSeparator byte = ';'
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maxTagLength int = 511 // 510 + @ and " " (space), though space usually not included.
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)
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// Tags represents the key-value pairs in IRCv3 message tags. The map contains
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// the encoded message-tag values. If the tag is present, it may still be
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// empty. See Tags.Get() and Tags.Set() for use with getting/setting
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// information within the tags.
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//
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// Note that retrieving and setting tags are not concurrent safe. If this is
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// necessary, you will need to implement it yourself.
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type Tags map[string]string
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// ParseTags parses out the key-value map of tags. raw should only be the tag
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// data, not a full message. For example:
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// @aaa=bbb;ccc;example.com/ddd=eee
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// NOT:
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// @aaa=bbb;ccc;example.com/ddd=eee :nick!ident@host.com PRIVMSG me :Hello
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func ParseTags(raw string) (t Tags) {
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t = make(Tags)
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if len(raw) > 0 && raw[0] == prefixTag {
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raw = raw[1:]
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}
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parts := strings.Split(raw, string(tagSeparator))
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var hasValue int
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for i := 0; i < len(parts); i++ {
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hasValue = strings.IndexByte(parts[i], prefixTagValue)
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// The tag doesn't contain a value or has a splitter with no value.
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if hasValue < 1 || len(parts[i]) < hasValue+1 {
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if !validTag(parts[i]) {
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continue
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}
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t[parts[i]] = ""
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continue
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}
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// Check if tag key or decoded value are invalid.
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if !validTag(parts[i][:hasValue]) || !validTagValue(tagDecoder.Replace(parts[i][hasValue+1:])) {
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continue
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}
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t[parts[i][:hasValue]] = parts[i][hasValue+1:]
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}
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return t
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}
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// Len determines the length of the bytes representation of this tag map. This
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// does not include the trailing space required when creating an event, but
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// does include the tag prefix ("@").
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func (t Tags) Len() (length int) {
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if t == nil {
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return 0
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}
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return len(t.Bytes())
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}
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// Count finds how many total tags that there are.
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func (t Tags) Count() int {
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if t == nil {
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return 0
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}
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return len(t)
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}
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// Bytes returns a []byte representation of this tag map, including the tag
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// prefix ("@"). Note that this will return the tags sorted, regardless of
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// the order of how they were originally parsed.
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func (t Tags) Bytes() []byte {
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if t == nil {
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return []byte{}
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}
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max := len(t)
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if max == 0 {
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return nil
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}
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buffer := new(bytes.Buffer)
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buffer.WriteByte(prefixTag)
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var current int
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// Sort the writing of tags so we can at least guarantee that they will
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// be in order, and testable.
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var names []string
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for tagName := range t {
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names = append(names, tagName)
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}
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sort.Strings(names)
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for i := 0; i < len(names); i++ {
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// Trim at max allowed chars.
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if (buffer.Len() + len(names[i]) + len(t[names[i]]) + 2) > maxTagLength {
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return buffer.Bytes()
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}
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buffer.WriteString(names[i])
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// Write the value as necessary.
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if len(t[names[i]]) > 0 {
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buffer.WriteByte(prefixTagValue)
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buffer.WriteString(t[names[i]])
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}
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// add the separator ";" between tags.
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if current < max-1 {
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buffer.WriteByte(tagSeparator)
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}
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current++
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}
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return buffer.Bytes()
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}
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|
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// String returns a string representation of this tag map.
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|
func (t Tags) String() string {
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if t == nil {
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return ""
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}
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return string(t.Bytes())
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}
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// writeTo writes the necessary tag bytes to an io.Writer, including a trailing
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// space-separator.
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func (t Tags) writeTo(w io.Writer) (n int, err error) {
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b := t.Bytes()
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if len(b) == 0 {
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return n, err
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}
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n, err = w.Write(b)
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if err != nil {
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return n, err
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}
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var j int
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j, err = w.Write([]byte{eventSpace})
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n += j
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return n, err
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}
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|
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// tagDecode are encoded -> decoded pairs for replacement to decode.
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var tagDecode = []string{
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"\\:", ";",
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"\\s", " ",
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"\\\\", "\\",
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"\\r", "\r",
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"\\n", "\n",
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}
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var tagDecoder = strings.NewReplacer(tagDecode...)
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|
|
// tagEncode are decoded -> encoded pairs for replacement to decode.
|
|
var tagEncode = []string{
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";", "\\:",
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" ", "\\s",
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"\\", "\\\\",
|
|
"\r", "\\r",
|
|
"\n", "\\n",
|
|
}
|
|
var tagEncoder = strings.NewReplacer(tagEncode...)
|
|
|
|
// Get returns the unescaped value of given tag key. Note that this is not
|
|
// concurrent safe.
|
|
func (t Tags) Get(key string) (tag string, success bool) {
|
|
if t == nil {
|
|
return "", false
|
|
}
|
|
|
|
if _, ok := t[key]; ok {
|
|
tag = tagDecoder.Replace(t[key])
|
|
success = true
|
|
}
|
|
|
|
return tag, success
|
|
}
|
|
|
|
// Set escapes given value and saves it as the value for given key. Note that
|
|
// this is not concurrent safe.
|
|
func (t Tags) Set(key, value string) error {
|
|
if t == nil {
|
|
t = make(Tags)
|
|
}
|
|
|
|
if !validTag(key) {
|
|
return fmt.Errorf("tag key %q is invalid", key)
|
|
}
|
|
|
|
value = tagEncoder.Replace(value)
|
|
|
|
if len(value) > 0 && !validTagValue(value) {
|
|
return fmt.Errorf("tag value %q of key %q is invalid", value, key)
|
|
}
|
|
|
|
// Check to make sure it's not too long here.
|
|
if (t.Len() + len(key) + len(value) + 2) > maxTagLength {
|
|
return fmt.Errorf("unable to set tag %q [value %q]: tags too long for message", key, value)
|
|
}
|
|
|
|
t[key] = value
|
|
|
|
return nil
|
|
}
|
|
|
|
// Remove deletes the tag frwom the tag map.
|
|
func (t Tags) Remove(key string) (success bool) {
|
|
if t == nil {
|
|
return false
|
|
}
|
|
|
|
if _, success = t[key]; success {
|
|
delete(t, key)
|
|
}
|
|
|
|
return success
|
|
}
|
|
|
|
// validTag validates an IRC tag.
|
|
func validTag(name string) bool {
|
|
if len(name) < 1 {
|
|
return false
|
|
}
|
|
|
|
// Allow user tags to be passed to validTag.
|
|
if len(name) >= 2 && name[0] == prefixUserTag {
|
|
name = name[1:]
|
|
}
|
|
|
|
for i := 0; i < len(name); i++ {
|
|
// A-Z, a-z, 0-9, -/._
|
|
if (name[i] < 'A' || name[i] > 'Z') && (name[i] < 'a' || name[i] > 'z') && (name[i] < '-' || name[i] > '9') && name[i] != '_' {
|
|
return false
|
|
}
|
|
}
|
|
|
|
return true
|
|
}
|
|
|
|
// validTagValue valids a decoded IRC tag value. If the value is not decoded
|
|
// with tagDecoder first, it may be seen as invalid.
|
|
func validTagValue(value string) bool {
|
|
for i := 0; i < len(value); i++ {
|
|
// Don't allow any invisible chars within the tag, or semicolons.
|
|
if value[i] < '!' || value[i] > '~' || value[i] == ';' {
|
|
return false
|
|
}
|
|
}
|
|
return true
|
|
}
|