caddy/listeners.go

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// Copyright 2015 Matthew Holt and The Caddy Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package caddy
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import (
"fmt"
"log"
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"net"
"strconv"
"strings"
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"sync"
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"sync/atomic"
"time"
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)
// Listen returns a listener suitable for use in a Caddy module.
// Always be sure to close listeners when you are done with them.
func Listen(network, addr string) (net.Listener, error) {
lnKey := network + "/" + addr
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listenersMu.Lock()
defer listenersMu.Unlock()
// if listener already exists, increment usage counter, then return listener
if lnGlobal, ok := listeners[lnKey]; ok {
atomic.AddInt32(&lnGlobal.usage, 1)
return &fakeCloseListener{
usage: &lnGlobal.usage,
deadline: &lnGlobal.deadline,
deadlineMu: &lnGlobal.deadlineMu,
key: lnKey,
Listener: lnGlobal.ln,
}, nil
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}
// or, create new one and save it
ln, err := net.Listen(network, addr)
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if err != nil {
return nil, err
}
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// make sure to start its usage counter at 1
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lnGlobal := &globalListener{usage: 1, ln: ln}
listeners[lnKey] = lnGlobal
return &fakeCloseListener{
usage: &lnGlobal.usage,
deadline: &lnGlobal.deadline,
deadlineMu: &lnGlobal.deadlineMu,
key: lnKey,
Listener: ln,
}, nil
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}
// ListenPacket returns a net.PacketConn suitable for use in a Caddy module.
// Always be sure to close the PacketConn when you are done.
func ListenPacket(network, addr string) (net.PacketConn, error) {
lnKey := network + "/" + addr
listenersMu.Lock()
defer listenersMu.Unlock()
// if listener already exists, increment usage counter, then return listener
if lnGlobal, ok := listeners[lnKey]; ok {
atomic.AddInt32(&lnGlobal.usage, 1)
log.Printf("[DEBUG] %s: Usage counter should not go above 2 or maybe 3, is now: %d", lnKey, atomic.LoadInt32(&lnGlobal.usage)) // TODO: remove
return &fakeClosePacketConn{usage: &lnGlobal.usage, key: lnKey, PacketConn: lnGlobal.pc}, nil
}
// or, create new one and save it
pc, err := net.ListenPacket(network, addr)
if err != nil {
return nil, err
}
// make sure to start its usage counter at 1
lnGlobal := &globalListener{usage: 1, pc: pc}
listeners[lnKey] = lnGlobal
return &fakeClosePacketConn{usage: &lnGlobal.usage, key: lnKey, PacketConn: pc}, nil
}
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// fakeCloseListener's Close() method is a no-op. This allows
// stopping servers that are using the listener without giving
// up the socket; thus, servers become hot-swappable while the
// listener remains running. Listeners should be re-wrapped in
// a new fakeCloseListener each time the listener is reused.
// Other than the 'closed' field (which pertains to this value
// only), the other fields in this struct should be pointers to
// the associated globalListener's struct fields (except 'key'
// which is there for read-only purposes, so it can be a copy).
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type fakeCloseListener struct {
closed int32 // accessed atomically; belongs to this struct only
usage *int32 // accessed atomically; global
deadline *bool // protected by deadlineMu; global
deadlineMu *sync.Mutex // global
key string // global, but read-only, so can be copy
net.Listener // global
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}
// Accept accepts connections until Close() is called.
func (fcl *fakeCloseListener) Accept() (net.Conn, error) {
// if the listener is already "closed", return error
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if atomic.LoadInt32(&fcl.closed) == 1 {
return nil, fcl.fakeClosedErr()
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}
// wrap underlying accept
conn, err := fcl.Listener.Accept()
if err == nil {
return conn, nil
}
// accept returned with error
// TODO: This may be better as a condition variable so the deadline is cleared only once?
fcl.deadlineMu.Lock()
if *fcl.deadline {
switch ln := fcl.Listener.(type) {
case *net.TCPListener:
ln.SetDeadline(time.Time{})
case *net.UnixListener:
ln.SetDeadline(time.Time{})
}
*fcl.deadline = false
}
fcl.deadlineMu.Unlock()
if atomic.LoadInt32(&fcl.closed) == 1 {
// if we canceled the Accept() by setting a deadline
// on the listener, we need to make sure any callers of
// Accept() think the listener was actually closed;
// if we return the timeout error instead, callers might
// simply retry, leaking goroutines for longer
if netErr, ok := err.(net.Error); ok && netErr.Timeout() {
return nil, fcl.fakeClosedErr()
}
}
return nil, err
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}
// Close stops accepting new connections without
// closing the underlying listener, unless no one
// else is using it.
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func (fcl *fakeCloseListener) Close() error {
if atomic.CompareAndSwapInt32(&fcl.closed, 0, 1) {
// unfortunately, there is no way to cancel any
// currently-blocking calls to Accept() that are
// awaiting connections since we're not actually
// closing the listener; so we cheat by setting
// a deadline in the past, which forces it to
// time out; note that this only works for
// certain types of listeners...
fcl.deadlineMu.Lock()
if !*fcl.deadline {
switch ln := fcl.Listener.(type) {
case *net.TCPListener:
ln.SetDeadline(time.Now().Add(-1 * time.Minute))
case *net.UnixListener:
ln.SetDeadline(time.Now().Add(-1 * time.Minute))
}
*fcl.deadline = true
}
fcl.deadlineMu.Unlock()
// since we're no longer using this listener,
// decrement the usage counter and, if no one
// else is using it, close underlying listener
if atomic.AddInt32(fcl.usage, -1) == 0 {
listenersMu.Lock()
delete(listeners, fcl.key)
listenersMu.Unlock()
err := fcl.Listener.Close()
if err != nil {
return err
}
}
}
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return nil
}
func (fcl *fakeCloseListener) fakeClosedErr() error {
return &net.OpError{
Op: "accept",
Net: fcl.Listener.Addr().Network(),
Addr: fcl.Listener.Addr(),
Err: errFakeClosed,
}
}
type fakeClosePacketConn struct {
closed int32 // accessed atomically
usage *int32 // accessed atomically
key string
net.PacketConn
}
func (fcpc *fakeClosePacketConn) Close() error {
log.Println("[DEBUG] Fake-closing underlying packet conn") // TODO: remove this
if atomic.CompareAndSwapInt32(&fcpc.closed, 0, 1) {
// since we're no longer using this listener,
// decrement the usage counter and, if no one
// else is using it, close underlying listener
if atomic.AddInt32(fcpc.usage, -1) == 0 {
listenersMu.Lock()
delete(listeners, fcpc.key)
listenersMu.Unlock()
err := fcpc.PacketConn.Close()
if err != nil {
return err
}
}
}
return nil
}
// ErrFakeClosed is the underlying error value returned by
// fakeCloseListener.Accept() after Close() has been called,
// indicating that it is pretending to be closed so that the
// server using it can terminate, while the underlying
// socket is actually left open.
var errFakeClosed = fmt.Errorf("listener 'closed' 😉")
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// globalListener keeps global state for a listener
// that may be shared by multiple servers. In other
// words, values in this struct exist only once and
// all other uses of these values point to the ones
// in this struct. In particular, the usage count
// (how many callers are using the listener), the
// actual listener, and synchronization of the
// listener's deadline changes are singular, global
// values that must not be copied.
type globalListener struct {
usage int32 // accessed atomically
deadline bool
deadlineMu sync.Mutex
ln net.Listener
pc net.PacketConn
}
// NetworkAddress contains the individual components
// for a parsed network address of the form accepted
// by ParseNetworkAddress(). Network should be a
// network value accepted by Go's net package. Port
// ranges are given by [StartPort, EndPort].
type NetworkAddress struct {
Network string
Host string
StartPort uint
EndPort uint
}
// IsUnixNetwork returns true if na.Network is
// unix, unixgram, or unixpacket.
func (na NetworkAddress) IsUnixNetwork() bool {
return isUnixNetwork(na.Network)
}
// JoinHostPort is like net.JoinHostPort, but where the port
// is StartPort + offset.
func (na NetworkAddress) JoinHostPort(offset uint) string {
if na.IsUnixNetwork() {
return na.Host
}
return net.JoinHostPort(na.Host, strconv.Itoa(int(na.StartPort+offset)))
}
// PortRangeSize returns how many ports are in
// pa's port range. Port ranges are inclusive,
// so the size is the difference of start and
// end ports plus one.
func (na NetworkAddress) PortRangeSize() uint {
return (na.EndPort - na.StartPort) + 1
}
func (na NetworkAddress) isLoopback() bool {
if na.IsUnixNetwork() {
return true
}
if na.Host == "localhost" {
return true
}
if ip := net.ParseIP(na.Host); ip != nil {
return ip.IsLoopback()
}
return false
}
func (na NetworkAddress) port() string {
if na.StartPort == na.EndPort {
return strconv.FormatUint(uint64(na.StartPort), 10)
}
return fmt.Sprintf("%d-%d", na.StartPort, na.EndPort)
}
// String reconstructs the address string to the form expected
// by ParseNetworkAddress(). If the address is a unix socket,
// any non-zero port will be dropped.
func (na NetworkAddress) String() string {
return JoinNetworkAddress(na.Network, na.Host, na.port())
}
func isUnixNetwork(netw string) bool {
return netw == "unix" || netw == "unixgram" || netw == "unixpacket"
}
// ParseNetworkAddress parses addr into its individual
// components. The input string is expected to be of
// the form "network/host:port-range" where any part is
// optional. The default network, if unspecified, is tcp.
// Port ranges are inclusive.
//
// Network addresses are distinct from URLs and do not
// use URL syntax.
func ParseNetworkAddress(addr string) (NetworkAddress, error) {
var host, port string
network, host, port, err := SplitNetworkAddress(addr)
if network == "" {
network = "tcp"
}
if err != nil {
return NetworkAddress{}, err
}
if isUnixNetwork(network) {
return NetworkAddress{
Network: network,
Host: host,
}, nil
}
ports := strings.SplitN(port, "-", 2)
if len(ports) == 1 {
ports = append(ports, ports[0])
}
var start, end uint64
start, err = strconv.ParseUint(ports[0], 10, 16)
if err != nil {
return NetworkAddress{}, fmt.Errorf("invalid start port: %v", err)
}
end, err = strconv.ParseUint(ports[1], 10, 16)
if err != nil {
return NetworkAddress{}, fmt.Errorf("invalid end port: %v", err)
}
if end < start {
return NetworkAddress{}, fmt.Errorf("end port must not be less than start port")
}
if (end - start) > maxPortSpan {
return NetworkAddress{}, fmt.Errorf("port range exceeds %d ports", maxPortSpan)
}
return NetworkAddress{
Network: network,
Host: host,
StartPort: uint(start),
EndPort: uint(end),
}, nil
}
// SplitNetworkAddress splits a into its network, host, and port components.
// Note that port may be a port range (:X-Y), or omitted for unix sockets.
func SplitNetworkAddress(a string) (network, host, port string, err error) {
if idx := strings.Index(a, "/"); idx >= 0 {
network = strings.ToLower(strings.TrimSpace(a[:idx]))
a = a[idx+1:]
}
if isUnixNetwork(network) {
host = a
return
}
host, port, err = net.SplitHostPort(a)
return
}
// JoinNetworkAddress combines network, host, and port into a single
// address string of the form accepted by ParseNetworkAddress(). For
// unix sockets, the network should be "unix" (or "unixgram" or
// "unixpacket") and the path to the socket should be given as the
// host parameter.
func JoinNetworkAddress(network, host, port string) string {
var a string
if network != "" {
a = network + "/"
}
if (host != "" && port == "") || isUnixNetwork(network) {
a += host
} else if port != "" {
a += net.JoinHostPort(host, port)
}
return a
}
// ListenerWrapper is a type that wraps a listener
// so it can modify the input listener's methods.
// Modules that implement this interface are found
// in the caddy.listeners namespace. Usually, to
// wrap a listener, you will define your own struct
// type that embeds the input listener, then
// implement your own methods that you want to wrap,
// calling the underlying listener's methods where
// appropriate.
type ListenerWrapper interface {
WrapListener(net.Listener) net.Listener
}
var (
listeners = make(map[string]*globalListener)
listenersMu sync.Mutex
)
const maxPortSpan = 65535