consul/vendor/github.com/hashicorp/go-connlimit/connlimit.go

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package connlimit
import (
"errors"
"fmt"
"net"
"net/http"
"sync"
"sync/atomic"
"time"
)
var (
// ErrPerClientIPLimitReached is returned if accepting a new conn would exceed
// the per-client-ip limit set.
ErrPerClientIPLimitReached = errors.New("client connection limit reached")
tooManyConnsMsg = "Your IP is issuing too many concurrent connections, please rate limit your calls\n"
tooManyRequestsResponse = []byte(fmt.Sprintf("HTTP/1.1 429 Too Many Requests\r\n"+
"Content-Type: text/plain\r\n"+
"Content-Length: %d\r\n"+
"Connection: close\r\n\r\n%s", len(tooManyConnsMsg), tooManyConnsMsg))
)
// Limiter implements a simple limiter that tracks the number of connections
// from each client IP. It may be used in it's zero value although no limits
// will be configured initially - they can be set later with SetConfig.
type Limiter struct {
// cs stores the map of active connections by IP address. We store a set of
// conn pointers not just a counter because http.Server.ConnState hook only
// gives us a connection object between calls so we need to know if a closed
// conn is one that was previously accepted or one we've just closed in the
// ConnState hook because the client has hit its limit.
cs map[string]map[net.Conn]struct{}
// l protects access to cs
l sync.Mutex
// cfg is stored atomically to provide non-blocking reads via Config. This
// might be important if this is called regularly in a health or metrics
// endpoint and shouldn't block new connections being established.
cfg atomic.Value
}
// Config is the configuration for the limiter.
type Config struct {
// MaxConnsPerClientIP limits how many concurrent connections are allowed from
// a given client IP. The IP is the one reported by the connection so cannot
// be relied upon if clients are connecting through multiple proxies or able
// to spoof their source IP address in some way. Similarly, multiple clients
// connected via a proxy or NAT gateway or similar will all be seen as coming
// from the same IP and so limited as one client.
MaxConnsPerClientIP int
}
// NewLimiter returns a limiter with the specified config.
func NewLimiter(cfg Config) *Limiter {
l := &Limiter{}
l.SetConfig(cfg)
return l
}
// Accept is called as early as possible when handling a new conn. If the
// connection should be accepted according to the Limiter's Config, it will
// return a free func and nil error. The free func must be called when the
// connection is no longer being handled - typically in a defer statement in the
// main connection handling goroutine, this will decrement the counter for that
// client IP. If the configured limit has been reached, a no-op func is returned
// (doesn't need to be called), and ErrPerClientIPLimitReached is returned.
//
// If any other error is returned it signifies something wrong with the config
// or transient failure to read or parse the remote IP. The free func will be a
// no-op in this case and need not be called.
func (l *Limiter) Accept(conn net.Conn) (func(), error) {
addrKey := connKey(conn)
// Load config outside locked section since it's not updated under lock anyway
// and the atomic Load might be slower/contented so better to do outside lock.
cfg := l.Config()
l.l.Lock()
defer l.l.Unlock()
if l.cs == nil {
l.cs = make(map[string]map[net.Conn]struct{})
}
cs := l.cs[addrKey]
if cs == nil {
cs = make(map[net.Conn]struct{})
l.cs[addrKey] = cs
}
n := len(cs)
// Might be greater since config is dynamic.
if cfg.MaxConnsPerClientIP > 0 && n >= cfg.MaxConnsPerClientIP {
return func() {}, ErrPerClientIPLimitReached
}
// Add the conn to the map
cs[conn] = struct{}{}
// Create a free func over the address key we used
free := func() {
l.freeConn(conn)
}
return free, nil
}
func (l *Limiter) NumOpen(addr net.Addr) int {
addrKey := addrKey(addr)
l.l.Lock()
defer l.l.Unlock()
if l.cs == nil {
return 0
}
cs := l.cs[addrKey]
if cs == nil {
return 0
}
return len(cs)
}
func connKey(conn net.Conn) string {
return addrKey(conn.RemoteAddr())
}
func addrKey(addr net.Addr) string {
switch a := addr.(type) {
case *net.TCPAddr:
return "ip:" + a.IP.String()
case *net.UDPAddr:
return "ip:" + a.IP.String()
case *net.IPAddr:
return "ip:" + a.IP.String()
default:
// not sure what to do with this, just assume whole Addr is relevant?
return addr.Network() + "/" + addr.String()
}
}
// freeConn removes a connection from the map if it's present. It is a no-op if
// the conn was never accepted by Accept.
func (l *Limiter) freeConn(conn net.Conn) {
addrKey := connKey(conn)
l.l.Lock()
defer l.l.Unlock()
cs, ok := l.cs[addrKey]
if !ok {
return
}
delete(cs, conn)
if len(cs) == 0 {
delete(l.cs, addrKey)
}
}
// Config returns the current limiter configuration. It is safe to call from any
// goroutine and does not block new connections being accepted.
func (l *Limiter) Config() Config {
cfgRaw := l.cfg.Load()
if cfg, ok := cfgRaw.(Config); ok {
return cfg
}
return Config{}
}
// SetConfig dynamically updates the limiter configuration. It is safe to call
// from any goroutine. Note that if the limit is lowered, active conns will not
// be closed and may remain over the limit until they close naturally.
func (l *Limiter) SetConfig(c Config) {
l.cfg.Store(c)
}
// HTTPConnStateFuncWithErrorHandler returns a func that can be passed as the ConnState field of
// an http.Server. This intercepts new HTTP connections to the server and
// applies the limiting to new connections.
//
// Note that if the conn is hijacked from the HTTP server then it will be freed
// in the limiter as if it was closed. Servers that use Hijacking must implement
// their own calls if they need to continue limiting the number of concurrent
// hijacked connections.
// errorHandler MUST close the connection itself
func (l *Limiter) HTTPConnStateFuncWithErrorHandler(errorHandler func(error, net.Conn)) func(net.Conn, http.ConnState) {
return func(conn net.Conn, state http.ConnState) {
switch state {
case http.StateNew:
_, err := l.Accept(conn)
if err != nil {
errorHandler(err, conn)
}
case http.StateHijacked:
l.freeConn(conn)
case http.StateClosed:
// Maybe free the conn. This might be a conn we closed in the case above
// that was never counted as it was over limit but freeConn will be a
// no-op in that case.
l.freeConn(conn)
}
}
}
// HTTPConnStateFunc is here for ascending compatibility reasons.
func (l *Limiter) HTTPConnStateFunc() func(net.Conn, http.ConnState) {
return l.HTTPConnStateFuncWithErrorHandler(func(err error, conn net.Conn) {
conn.Close()
})
}
// HTTPConnStateFuncWithDefault429Handler return an HTTP 429 if too many connections occur.
// BEWARE that returning HTTP 429 is done on critical path, you might choose to use
// HTTPConnStateFuncWithErrorHandler if you want to use a non-blocking strategy.
func (l *Limiter) HTTPConnStateFuncWithDefault429Handler(writeDeadlineMaxDelay time.Duration) func(net.Conn, http.ConnState) {
return l.HTTPConnStateFuncWithErrorHandler(func(err error, conn net.Conn) {
if err == ErrPerClientIPLimitReached {
// We don't care about slow players
if writeDeadlineMaxDelay > 0 {
conn.SetDeadline(time.Now().Add(writeDeadlineMaxDelay))
}
conn.Write(tooManyRequestsResponse)
}
conn.Close()
})
}