mirror of
https://github.com/caddyserver/caddy.git
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531 lines
14 KiB
Go
531 lines
14 KiB
Go
package dns
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// A client implementation.
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import (
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"bytes"
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"context"
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"crypto/tls"
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"encoding/binary"
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"io"
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"net"
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"time"
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)
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const dnsTimeout time.Duration = 2 * time.Second
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const tcpIdleTimeout time.Duration = 8 * time.Second
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// A Conn represents a connection to a DNS server.
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type Conn struct {
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net.Conn // a net.Conn holding the connection
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UDPSize uint16 // minimum receive buffer for UDP messages
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TsigSecret map[string]string // secret(s) for Tsig map[<zonename>]<base64 secret>, zonename must be fully qualified
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rtt time.Duration
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t time.Time
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tsigRequestMAC string
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}
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// A Client defines parameters for a DNS client.
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type Client struct {
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Net string // if "tcp" or "tcp-tls" (DNS over TLS) a TCP query will be initiated, otherwise an UDP one (default is "" for UDP)
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UDPSize uint16 // minimum receive buffer for UDP messages
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TLSConfig *tls.Config // TLS connection configuration
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Timeout time.Duration // a cumulative timeout for dial, write and read, defaults to 0 (disabled) - overrides DialTimeout, ReadTimeout and WriteTimeout when non-zero
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DialTimeout time.Duration // net.DialTimeout, defaults to 2 seconds - overridden by Timeout when that value is non-zero
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ReadTimeout time.Duration // net.Conn.SetReadTimeout value for connections, defaults to 2 seconds - overridden by Timeout when that value is non-zero
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WriteTimeout time.Duration // net.Conn.SetWriteTimeout value for connections, defaults to 2 seconds - overridden by Timeout when that value is non-zero
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TsigSecret map[string]string // secret(s) for Tsig map[<zonename>]<base64 secret>, zonename must be fully qualified
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SingleInflight bool // if true suppress multiple outstanding queries for the same Qname, Qtype and Qclass
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group singleflight
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}
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// Exchange performs a synchronous UDP query. It sends the message m to the address
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// contained in a and waits for a reply. Exchange does not retry a failed query, nor
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// will it fall back to TCP in case of truncation.
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// See client.Exchange for more information on setting larger buffer sizes.
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func Exchange(m *Msg, a string) (r *Msg, err error) {
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var co *Conn
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co, err = DialTimeout("udp", a, dnsTimeout)
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if err != nil {
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return nil, err
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}
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defer co.Close()
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opt := m.IsEdns0()
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// If EDNS0 is used use that for size.
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if opt != nil && opt.UDPSize() >= MinMsgSize {
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co.UDPSize = opt.UDPSize()
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}
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co.SetWriteDeadline(time.Now().Add(dnsTimeout))
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if err = co.WriteMsg(m); err != nil {
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return nil, err
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}
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co.SetReadDeadline(time.Now().Add(dnsTimeout))
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r, err = co.ReadMsg()
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if err == nil && r.Id != m.Id {
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err = ErrId
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}
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return r, err
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}
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// ExchangeContext performs a synchronous UDP query, like Exchange. It
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// additionally obeys deadlines from the passed Context.
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func ExchangeContext(ctx context.Context, m *Msg, a string) (r *Msg, err error) {
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// Combine context deadline with built-in timeout. Context chooses whichever
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// is sooner.
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timeoutCtx, cancel := context.WithTimeout(ctx, dnsTimeout)
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defer cancel()
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deadline, _ := timeoutCtx.Deadline()
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co := new(Conn)
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dialer := net.Dialer{}
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co.Conn, err = dialer.DialContext(timeoutCtx, "udp", a)
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if err != nil {
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return nil, err
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}
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defer co.Conn.Close()
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opt := m.IsEdns0()
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// If EDNS0 is used use that for size.
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if opt != nil && opt.UDPSize() >= MinMsgSize {
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co.UDPSize = opt.UDPSize()
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}
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co.SetWriteDeadline(deadline)
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if err = co.WriteMsg(m); err != nil {
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return nil, err
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}
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co.SetReadDeadline(deadline)
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r, err = co.ReadMsg()
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if err == nil && r.Id != m.Id {
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err = ErrId
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}
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return r, err
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}
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// ExchangeConn performs a synchronous query. It sends the message m via the connection
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// c and waits for a reply. The connection c is not closed by ExchangeConn.
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// This function is going away, but can easily be mimicked:
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//
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// co := &dns.Conn{Conn: c} // c is your net.Conn
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// co.WriteMsg(m)
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// in, _ := co.ReadMsg()
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// co.Close()
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//
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func ExchangeConn(c net.Conn, m *Msg) (r *Msg, err error) {
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println("dns: this function is deprecated")
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co := new(Conn)
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co.Conn = c
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if err = co.WriteMsg(m); err != nil {
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return nil, err
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}
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r, err = co.ReadMsg()
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if err == nil && r.Id != m.Id {
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err = ErrId
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}
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return r, err
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}
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// Exchange performs a synchronous query. It sends the message m to the address
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// contained in a and waits for a reply. Basic use pattern with a *dns.Client:
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//
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// c := new(dns.Client)
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// in, rtt, err := c.Exchange(message, "127.0.0.1:53")
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//
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// Exchange does not retry a failed query, nor will it fall back to TCP in
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// case of truncation.
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// It is up to the caller to create a message that allows for larger responses to be
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// returned. Specifically this means adding an EDNS0 OPT RR that will advertise a larger
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// buffer, see SetEdns0. Messages without an OPT RR will fallback to the historic limit
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// of 512 bytes.
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func (c *Client) Exchange(m *Msg, a string) (r *Msg, rtt time.Duration, err error) {
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return c.ExchangeContext(context.Background(), m, a)
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}
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// ExchangeContext acts like Exchange, but honors the deadline on the provided
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// context, if present. If there is both a context deadline and a configured
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// timeout on the client, the earliest of the two takes effect.
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func (c *Client) ExchangeContext(ctx context.Context, m *Msg, a string) (
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r *Msg,
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rtt time.Duration,
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err error) {
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if !c.SingleInflight {
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return c.exchange(ctx, m, a)
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}
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// This adds a bunch of garbage, TODO(miek).
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t := "nop"
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if t1, ok := TypeToString[m.Question[0].Qtype]; ok {
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t = t1
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}
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cl := "nop"
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if cl1, ok := ClassToString[m.Question[0].Qclass]; ok {
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cl = cl1
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}
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r, rtt, err, shared := c.group.Do(m.Question[0].Name+t+cl, func() (*Msg, time.Duration, error) {
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return c.exchange(ctx, m, a)
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})
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if r != nil && shared {
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r = r.Copy()
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}
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if err != nil {
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return r, rtt, err
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}
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return r, rtt, nil
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}
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func (c *Client) dialTimeout() time.Duration {
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if c.Timeout != 0 {
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return c.Timeout
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}
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if c.DialTimeout != 0 {
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return c.DialTimeout
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}
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return dnsTimeout
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}
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func (c *Client) readTimeout() time.Duration {
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if c.ReadTimeout != 0 {
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return c.ReadTimeout
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}
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return dnsTimeout
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}
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func (c *Client) writeTimeout() time.Duration {
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if c.WriteTimeout != 0 {
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return c.WriteTimeout
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}
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return dnsTimeout
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}
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func (c *Client) exchange(ctx context.Context, m *Msg, a string) (r *Msg, rtt time.Duration, err error) {
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var co *Conn
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network := "udp"
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tls := false
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switch c.Net {
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case "tcp-tls":
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network = "tcp"
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tls = true
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case "tcp4-tls":
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network = "tcp4"
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tls = true
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case "tcp6-tls":
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network = "tcp6"
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tls = true
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default:
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if c.Net != "" {
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network = c.Net
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}
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}
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var deadline time.Time
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if c.Timeout != 0 {
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deadline = time.Now().Add(c.Timeout)
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}
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dialDeadline := deadlineOrTimeoutOrCtx(ctx, deadline, c.dialTimeout())
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dialTimeout := dialDeadline.Sub(time.Now())
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if tls {
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co, err = DialTimeoutWithTLS(network, a, c.TLSConfig, dialTimeout)
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} else {
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co, err = DialTimeout(network, a, dialTimeout)
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}
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if err != nil {
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return nil, 0, err
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}
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defer co.Close()
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opt := m.IsEdns0()
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// If EDNS0 is used use that for size.
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if opt != nil && opt.UDPSize() >= MinMsgSize {
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co.UDPSize = opt.UDPSize()
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}
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// Otherwise use the client's configured UDP size.
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if opt == nil && c.UDPSize >= MinMsgSize {
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co.UDPSize = c.UDPSize
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}
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co.TsigSecret = c.TsigSecret
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co.SetWriteDeadline(deadlineOrTimeoutOrCtx(ctx, deadline, c.writeTimeout()))
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if err = co.WriteMsg(m); err != nil {
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return nil, 0, err
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}
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co.SetReadDeadline(deadlineOrTimeoutOrCtx(ctx, deadline, c.readTimeout()))
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r, err = co.ReadMsg()
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if err == nil && r.Id != m.Id {
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err = ErrId
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}
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return r, co.rtt, err
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}
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// ReadMsg reads a message from the connection co.
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// If the received message contains a TSIG record the transaction
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// signature is verified.
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func (co *Conn) ReadMsg() (*Msg, error) {
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p, err := co.ReadMsgHeader(nil)
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if err != nil {
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return nil, err
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}
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m := new(Msg)
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if err := m.Unpack(p); err != nil {
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// If ErrTruncated was returned, we still want to allow the user to use
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// the message, but naively they can just check err if they don't want
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// to use a truncated message
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if err == ErrTruncated {
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return m, err
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}
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return nil, err
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}
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if t := m.IsTsig(); t != nil {
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if _, ok := co.TsigSecret[t.Hdr.Name]; !ok {
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return m, ErrSecret
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}
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// Need to work on the original message p, as that was used to calculate the tsig.
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err = TsigVerify(p, co.TsigSecret[t.Hdr.Name], co.tsigRequestMAC, false)
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}
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return m, err
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}
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// ReadMsgHeader reads a DNS message, parses and populates hdr (when hdr is not nil).
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// Returns message as a byte slice to be parsed with Msg.Unpack later on.
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// Note that error handling on the message body is not possible as only the header is parsed.
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func (co *Conn) ReadMsgHeader(hdr *Header) ([]byte, error) {
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var (
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p []byte
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n int
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err error
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)
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switch t := co.Conn.(type) {
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case *net.TCPConn, *tls.Conn:
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r := t.(io.Reader)
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// First two bytes specify the length of the entire message.
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l, err := tcpMsgLen(r)
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if err != nil {
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return nil, err
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}
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p = make([]byte, l)
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n, err = tcpRead(r, p)
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co.rtt = time.Since(co.t)
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default:
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if co.UDPSize > MinMsgSize {
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p = make([]byte, co.UDPSize)
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} else {
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p = make([]byte, MinMsgSize)
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}
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n, err = co.Read(p)
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co.rtt = time.Since(co.t)
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}
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if err != nil {
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return nil, err
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} else if n < headerSize {
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return nil, ErrShortRead
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}
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p = p[:n]
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if hdr != nil {
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dh, _, err := unpackMsgHdr(p, 0)
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if err != nil {
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return nil, err
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}
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*hdr = dh
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}
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return p, err
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}
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// tcpMsgLen is a helper func to read first two bytes of stream as uint16 packet length.
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func tcpMsgLen(t io.Reader) (int, error) {
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p := []byte{0, 0}
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n, err := t.Read(p)
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if err != nil {
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return 0, err
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}
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// As seen with my local router/switch, retursn 1 byte on the above read,
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// resulting a a ShortRead. Just write it out (instead of loop) and read the
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// other byte.
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if n == 1 {
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n1, err := t.Read(p[1:])
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if err != nil {
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return 0, err
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}
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n += n1
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}
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if n != 2 {
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return 0, ErrShortRead
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}
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l := binary.BigEndian.Uint16(p)
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if l == 0 {
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return 0, ErrShortRead
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}
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return int(l), nil
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}
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// tcpRead calls TCPConn.Read enough times to fill allocated buffer.
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func tcpRead(t io.Reader, p []byte) (int, error) {
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n, err := t.Read(p)
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if err != nil {
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return n, err
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}
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for n < len(p) {
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j, err := t.Read(p[n:])
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if err != nil {
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return n, err
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}
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n += j
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}
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return n, err
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}
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// Read implements the net.Conn read method.
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func (co *Conn) Read(p []byte) (n int, err error) {
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if co.Conn == nil {
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return 0, ErrConnEmpty
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}
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if len(p) < 2 {
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return 0, io.ErrShortBuffer
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}
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switch t := co.Conn.(type) {
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case *net.TCPConn, *tls.Conn:
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r := t.(io.Reader)
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l, err := tcpMsgLen(r)
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if err != nil {
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return 0, err
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}
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if l > len(p) {
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return int(l), io.ErrShortBuffer
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}
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return tcpRead(r, p[:l])
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}
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// UDP connection
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n, err = co.Conn.Read(p)
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if err != nil {
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return n, err
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}
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return n, err
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}
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// WriteMsg sends a message through the connection co.
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// If the message m contains a TSIG record the transaction
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// signature is calculated.
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func (co *Conn) WriteMsg(m *Msg) (err error) {
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var out []byte
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if t := m.IsTsig(); t != nil {
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mac := ""
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if _, ok := co.TsigSecret[t.Hdr.Name]; !ok {
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return ErrSecret
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}
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out, mac, err = TsigGenerate(m, co.TsigSecret[t.Hdr.Name], co.tsigRequestMAC, false)
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// Set for the next read, although only used in zone transfers
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co.tsigRequestMAC = mac
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} else {
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out, err = m.Pack()
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}
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if err != nil {
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return err
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}
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co.t = time.Now()
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if _, err = co.Write(out); err != nil {
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return err
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}
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return nil
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}
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|
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// Write implements the net.Conn Write method.
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func (co *Conn) Write(p []byte) (n int, err error) {
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switch t := co.Conn.(type) {
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case *net.TCPConn, *tls.Conn:
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w := t.(io.Writer)
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lp := len(p)
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if lp < 2 {
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return 0, io.ErrShortBuffer
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}
|
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if lp > MaxMsgSize {
|
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return 0, &Error{err: "message too large"}
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}
|
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l := make([]byte, 2, lp+2)
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binary.BigEndian.PutUint16(l, uint16(lp))
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p = append(l, p...)
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n, err := io.Copy(w, bytes.NewReader(p))
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return int(n), err
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}
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n, err = co.Conn.Write(p)
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return n, err
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}
|
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|
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// Dial connects to the address on the named network.
|
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func Dial(network, address string) (conn *Conn, err error) {
|
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conn = new(Conn)
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conn.Conn, err = net.Dial(network, address)
|
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if err != nil {
|
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return nil, err
|
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}
|
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return conn, nil
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}
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|
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// DialTimeout acts like Dial but takes a timeout.
|
|
func DialTimeout(network, address string, timeout time.Duration) (conn *Conn, err error) {
|
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conn = new(Conn)
|
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conn.Conn, err = net.DialTimeout(network, address, timeout)
|
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if err != nil {
|
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return nil, err
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}
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return conn, nil
|
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}
|
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|
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// DialWithTLS connects to the address on the named network with TLS.
|
|
func DialWithTLS(network, address string, tlsConfig *tls.Config) (conn *Conn, err error) {
|
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conn = new(Conn)
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conn.Conn, err = tls.Dial(network, address, tlsConfig)
|
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if err != nil {
|
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return nil, err
|
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}
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return conn, nil
|
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}
|
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|
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// DialTimeoutWithTLS acts like DialWithTLS but takes a timeout.
|
|
func DialTimeoutWithTLS(network, address string, tlsConfig *tls.Config, timeout time.Duration) (conn *Conn, err error) {
|
|
var dialer net.Dialer
|
|
dialer.Timeout = timeout
|
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|
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conn = new(Conn)
|
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conn.Conn, err = tls.DialWithDialer(&dialer, network, address, tlsConfig)
|
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if err != nil {
|
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return nil, err
|
|
}
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return conn, nil
|
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}
|
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|
|
// deadlineOrTimeout chooses between the provided deadline and timeout
|
|
// by always preferring the deadline so long as it's non-zero (regardless
|
|
// of which is bigger), and returns the equivalent deadline value.
|
|
func deadlineOrTimeout(deadline time.Time, timeout time.Duration) time.Time {
|
|
if deadline.IsZero() {
|
|
return time.Now().Add(timeout)
|
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}
|
|
return deadline
|
|
}
|
|
|
|
// deadlineOrTimeoutOrCtx returns the earliest of: a context deadline, or the
|
|
// output of deadlineOrtimeout.
|
|
func deadlineOrTimeoutOrCtx(ctx context.Context, deadline time.Time, timeout time.Duration) time.Time {
|
|
result := deadlineOrTimeout(deadline, timeout)
|
|
if ctxDeadline, ok := ctx.Deadline(); ok && ctxDeadline.Before(result) {
|
|
result = ctxDeadline
|
|
}
|
|
return result
|
|
}
|