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caddy/caddyhttp/proxy/reverseproxy.go

652 lines
18 KiB
Go

// This file is adapted from code in the net/http/httputil
// package of the Go standard library, which is by the
// Go Authors, and bears this copyright and license info:
//
// Copyright 2011 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//
// This file has been modified from the standard lib to
// meet the needs of the application.
package proxy
import (
"crypto/tls"
"io"
"net"
"net/http"
"net/url"
"strings"
"sync"
"time"
"golang.org/x/net/http2"
"github.com/mholt/caddy/caddyhttp/httpserver"
)
var (
defaultDialer = &net.Dialer{
Timeout: 30 * time.Second,
KeepAlive: 30 * time.Second,
}
bufferPool = sync.Pool{New: createBuffer}
)
func createBuffer() interface{} {
return make([]byte, 0, 32*1024)
}
func pooledIoCopy(dst io.Writer, src io.Reader) {
buf := bufferPool.Get().([]byte)
defer bufferPool.Put(buf)
// CopyBuffer only uses buf up to its length and panics if it's 0.
// Due to that we extend buf's length to its capacity here and
// ensure it's always non-zero.
bufCap := cap(buf)
io.CopyBuffer(dst, src, buf[0:bufCap:bufCap])
}
// onExitFlushLoop is a callback set by tests to detect the state of the
// flushLoop() goroutine.
var onExitFlushLoop func()
// ReverseProxy is an HTTP Handler that takes an incoming request and
// sends it to another server, proxying the response back to the
// client.
type ReverseProxy struct {
// Director must be a function which modifies
// the request into a new request to be sent
// using Transport. Its response is then copied
// back to the original client unmodified.
Director func(*http.Request)
// The transport used to perform proxy requests.
// If nil, http.DefaultTransport is used.
Transport http.RoundTripper
// FlushInterval specifies the flush interval
// to flush to the client while copying the
// response body.
// If zero, no periodic flushing is done.
FlushInterval time.Duration
}
// Though the relevant directive prefix is just "unix:", url.Parse
// will - assuming the regular URL scheme - add additional slashes
// as if "unix" was a request protocol.
// What we need is just the path, so if "unix:/var/run/www.socket"
// was the proxy directive, the parsed hostName would be
// "unix:///var/run/www.socket", hence the ambiguous trimming.
func socketDial(hostName string) func(network, addr string) (conn net.Conn, err error) {
return func(network, addr string) (conn net.Conn, err error) {
return net.Dial("unix", hostName[len("unix://"):])
}
}
func singleJoiningSlash(a, b string) string {
aslash := strings.HasSuffix(a, "/")
bslash := strings.HasPrefix(b, "/")
switch {
case aslash && bslash:
return a + b[1:]
case !aslash && !bslash && b != "":
return a + "/" + b
}
return a + b
}
// NewSingleHostReverseProxy returns a new ReverseProxy that rewrites
// URLs to the scheme, host, and base path provided in target. If the
// target's path is "/base" and the incoming request was for "/dir",
// the target request will be for /base/dir.
// Without logic: target's path is "/", incoming is "/api/messages",
// without is "/api", then the target request will be for /messages.
func NewSingleHostReverseProxy(target *url.URL, without string, keepalive int) *ReverseProxy {
targetQuery := target.RawQuery
director := func(req *http.Request) {
if target.Scheme == "unix" {
// to make Dial work with unix URL,
// scheme and host have to be faked
req.URL.Scheme = "http"
req.URL.Host = "socket"
} else {
req.URL.Scheme = target.Scheme
req.URL.Host = target.Host
}
// remove the `without` prefix
if without != "" {
req.URL.Path = strings.TrimPrefix(req.URL.Path, without)
if req.URL.Opaque != "" {
req.URL.Opaque = strings.TrimPrefix(req.URL.Opaque, without)
}
if req.URL.RawPath != "" {
req.URL.RawPath = strings.TrimPrefix(req.URL.RawPath, without)
}
}
// prefer returns val if it isn't empty, otherwise def
prefer := func(val, def string) string {
if val != "" {
return val
}
return def
}
// Make up the final URL by concatenating the request and target URL.
//
// If there is encoded part in request or target URL,
// the final URL should also be in encoded format.
// Here, we concatenate their encoded parts which are stored
// in URL.Opaque and URL.RawPath, if it is empty use
// URL.Path instead.
if req.URL.Opaque != "" || target.Opaque != "" {
req.URL.Opaque = singleJoiningSlash(
prefer(target.Opaque, target.Path),
prefer(req.URL.Opaque, req.URL.Path))
}
if req.URL.RawPath != "" || target.RawPath != "" {
req.URL.RawPath = singleJoiningSlash(
prefer(target.RawPath, target.Path),
prefer(req.URL.RawPath, req.URL.Path))
}
req.URL.Path = singleJoiningSlash(target.Path, req.URL.Path)
// Trims the path of the socket from the URL path.
// This is done because req.URL passed to your proxied service
// will have the full path of the socket file prefixed to it.
// Calling /test on a server that proxies requests to
// unix:/var/run/www.socket will thus set the requested path
// to /var/run/www.socket/test, rendering paths useless.
if target.Scheme == "unix" {
// See comment on socketDial for the trim
socketPrefix := target.String()[len("unix://"):]
req.URL.Path = strings.TrimPrefix(req.URL.Path, socketPrefix)
if req.URL.Opaque != "" {
req.URL.Opaque = strings.TrimPrefix(req.URL.Opaque, socketPrefix)
}
if req.URL.RawPath != "" {
req.URL.RawPath = strings.TrimPrefix(req.URL.RawPath, socketPrefix)
}
}
if targetQuery == "" || req.URL.RawQuery == "" {
req.URL.RawQuery = targetQuery + req.URL.RawQuery
} else {
req.URL.RawQuery = targetQuery + "&" + req.URL.RawQuery
}
}
rp := &ReverseProxy{Director: director, FlushInterval: 250 * time.Millisecond} // flushing good for streaming & server-sent events
if target.Scheme == "unix" {
rp.Transport = &http.Transport{
Dial: socketDial(target.String()),
}
} else if keepalive != http.DefaultMaxIdleConnsPerHost {
// if keepalive is equal to the default,
// just use default transport, to avoid creating
// a brand new transport
transport := &http.Transport{
Proxy: http.ProxyFromEnvironment,
Dial: defaultDialer.Dial,
TLSHandshakeTimeout: 10 * time.Second,
ExpectContinueTimeout: 1 * time.Second,
}
if keepalive == 0 {
transport.DisableKeepAlives = true
} else {
transport.MaxIdleConnsPerHost = keepalive
}
if httpserver.HTTP2 {
http2.ConfigureTransport(transport)
}
rp.Transport = transport
}
return rp
}
// UseInsecureTransport is used to facilitate HTTPS proxying
// when it is OK for upstream to be using a bad certificate,
// since this transport skips verification.
func (rp *ReverseProxy) UseInsecureTransport() {
if rp.Transport == nil {
transport := &http.Transport{
Proxy: http.ProxyFromEnvironment,
Dial: defaultDialer.Dial,
TLSHandshakeTimeout: 10 * time.Second,
TLSClientConfig: &tls.Config{InsecureSkipVerify: true},
}
if httpserver.HTTP2 {
http2.ConfigureTransport(transport)
}
rp.Transport = transport
} else if transport, ok := rp.Transport.(*http.Transport); ok {
if transport.TLSClientConfig == nil {
transport.TLSClientConfig = &tls.Config{}
}
transport.TLSClientConfig.InsecureSkipVerify = true
// No http2.ConfigureTransport() here.
// For now this is only added in places where
// an http.Transport is actually created.
}
}
// ServeHTTP serves the proxied request to the upstream by performing a roundtrip.
// It is designed to handle websocket connection upgrades as well.
func (rp *ReverseProxy) ServeHTTP(rw http.ResponseWriter, outreq *http.Request, respUpdateFn respUpdateFn) error {
transport := rp.Transport
if requestIsWebsocket(outreq) {
transport = newConnHijackerTransport(transport)
} else if transport == nil {
transport = http.DefaultTransport
}
rp.Director(outreq)
res, err := transport.RoundTrip(outreq)
if err != nil {
return err
}
isWebsocket := res.StatusCode == http.StatusSwitchingProtocols && strings.ToLower(res.Header.Get("Upgrade")) == "websocket"
// Remove hop-by-hop headers listed in the
// "Connection" header of the response.
if c := res.Header.Get("Connection"); c != "" {
for _, f := range strings.Split(c, ",") {
if f = strings.TrimSpace(f); f != "" {
res.Header.Del(f)
}
}
}
for _, h := range hopHeaders {
res.Header.Del(h)
}
if respUpdateFn != nil {
respUpdateFn(res)
}
if isWebsocket {
res.Body.Close()
hj, ok := rw.(http.Hijacker)
if !ok {
panic(httpserver.NonHijackerError{Underlying: rw})
}
conn, brw, err := hj.Hijack()
if err != nil {
return err
}
defer conn.Close()
var backendConn net.Conn
if hj, ok := transport.(*connHijackerTransport); ok {
backendConn = hj.Conn
if _, err := conn.Write(hj.Replay); err != nil {
return err
}
bufferPool.Put(hj.Replay)
} else {
backendConn, err = net.Dial("tcp", outreq.URL.Host)
if err != nil {
return err
}
outreq.Write(backendConn)
}
defer backendConn.Close()
// Proxy backend -> frontend.
go pooledIoCopy(conn, backendConn)
// Proxy frontend -> backend.
//
// NOTE: Hijack() sometimes returns buffered up bytes in brw which
// would be lost if we didn't read them out manually below.
if brw != nil {
if n := brw.Reader.Buffered(); n > 0 {
rbuf, err := brw.Reader.Peek(n)
if err != nil {
return err
}
backendConn.Write(rbuf)
}
}
pooledIoCopy(backendConn, conn)
} else {
// NOTE:
// Closing the Body involves acquiring a mutex, which is a
// unnecessarily heavy operation, considering that this defer will
// pretty much never be executed with the Body still unclosed.
bodyOpen := true
closeBody := func() {
if bodyOpen {
res.Body.Close()
bodyOpen = false
}
}
defer closeBody()
// Copy all headers over.
// res.Header does not include the "Trailer" header,
// which means we will have to do that manually below.
copyHeader(rw.Header(), res.Header)
// The "Trailer" header isn't included in res' Header map, which
// is why we have to build one ourselves from res.Trailer.
//
// But res.Trailer does not necessarily contain all trailer keys at this
// point yet. The HTTP spec allows one to send "unannounced trailers"
// after a request and certain systems like gRPC make use of that.
announcedTrailerKeyCount := len(res.Trailer)
if announcedTrailerKeyCount > 0 {
vv := make([]string, 0, announcedTrailerKeyCount)
for k := range res.Trailer {
vv = append(vv, k)
}
rw.Header()["Trailer"] = vv
}
// Now copy over the status code as well as the response body.
rw.WriteHeader(res.StatusCode)
if announcedTrailerKeyCount > 0 {
// Force chunking if we saw a response trailer.
// This prevents net/http from calculating the length
// for short bodies and adding a Content-Length.
if fl, ok := rw.(http.Flusher); ok {
fl.Flush()
}
}
rp.copyResponse(rw, res.Body)
// Now close the body to fully populate res.Trailer.
closeBody()
// Since Go does not remove keys from res.Trailer we
// can safely do a length comparison to check wether
// we received further, unannounced trailers.
//
// Most of the time forceSetTrailers should be false.
forceSetTrailers := len(res.Trailer) != announcedTrailerKeyCount
shallowCopyTrailers(rw.Header(), res.Trailer, forceSetTrailers)
}
return nil
}
func (rp *ReverseProxy) copyResponse(dst io.Writer, src io.Reader) {
if rp.FlushInterval != 0 {
if wf, ok := dst.(writeFlusher); ok {
mlw := &maxLatencyWriter{
dst: wf,
latency: rp.FlushInterval,
done: make(chan bool),
}
go mlw.flushLoop()
defer mlw.stop()
dst = mlw
}
}
pooledIoCopy(dst, src)
}
// skip these headers if they already exist.
// see https://github.com/mholt/caddy/pull/1112#discussion_r80092582
var skipHeaders = map[string]struct{}{
"Content-Type": {},
"Content-Disposition": {},
"Accept-Ranges": {},
"Set-Cookie": {},
"Cache-Control": {},
"Expires": {},
}
func copyHeader(dst, src http.Header) {
for k, vv := range src {
if _, ok := dst[k]; ok {
// skip some predefined headers
// see https://github.com/mholt/caddy/issues/1086
if _, shouldSkip := skipHeaders[k]; shouldSkip {
continue
}
// otherwise, overwrite
dst.Del(k)
}
for _, v := range vv {
dst.Add(k, v)
}
}
}
// shallowCopyTrailers copies all headers from srcTrailer to dstHeader.
//
// If forceSetTrailers is set to true, the http.TrailerPrefix will be added to
// all srcTrailer key names. Otherwise the Go stdlib will ignore all keys
// which weren't listed in the Trailer map before submitting the Response.
//
// WARNING: Only a shallow copy will be created!
func shallowCopyTrailers(dstHeader, srcTrailer http.Header, forceSetTrailers bool) {
for k, vv := range srcTrailer {
if forceSetTrailers {
k = http.TrailerPrefix + k
}
dstHeader[k] = vv
}
}
// Hop-by-hop headers. These are removed when sent to the backend.
// http://www.w3.org/Protocols/rfc2616/rfc2616-sec13.html
var hopHeaders = []string{
"Alt-Svc",
"Alternate-Protocol",
"Connection",
"Keep-Alive",
"Proxy-Authenticate",
"Proxy-Authorization",
"Proxy-Connection", // non-standard but still sent by libcurl and rejected by e.g. google
"Te", // canonicalized version of "TE"
"Trailer", // not Trailers per URL above; http://www.rfc-editor.org/errata_search.php?eid=4522
"Transfer-Encoding",
"Upgrade",
}
type respUpdateFn func(resp *http.Response)
type hijackedConn struct {
net.Conn
hj *connHijackerTransport
}
func (c *hijackedConn) Read(b []byte) (n int, err error) {
n, err = c.Conn.Read(b)
c.hj.Replay = append(c.hj.Replay, b[:n]...)
return
}
func (c *hijackedConn) Close() error {
return nil
}
type connHijackerTransport struct {
*http.Transport
Conn net.Conn
Replay []byte
}
func newConnHijackerTransport(base http.RoundTripper) *connHijackerTransport {
t := &http.Transport{
MaxIdleConnsPerHost: -1,
}
if b, _ := base.(*http.Transport); b != nil {
tlsClientConfig := b.TLSClientConfig
if tlsClientConfig != nil && tlsClientConfig.NextProtos != nil {
tlsClientConfig = tlsClientConfig.Clone()
tlsClientConfig.NextProtos = nil
}
t.Proxy = b.Proxy
t.TLSClientConfig = tlsClientConfig
t.TLSHandshakeTimeout = b.TLSHandshakeTimeout
t.Dial = b.Dial
t.DialTLS = b.DialTLS
} else {
t.Proxy = http.ProxyFromEnvironment
t.TLSHandshakeTimeout = 10 * time.Second
}
hj := &connHijackerTransport{t, nil, bufferPool.Get().([]byte)[:0]}
dial := getTransportDial(t)
dialTLS := getTransportDialTLS(t)
t.Dial = func(network, addr string) (net.Conn, error) {
c, err := dial(network, addr)
hj.Conn = c
return &hijackedConn{c, hj}, err
}
t.DialTLS = func(network, addr string) (net.Conn, error) {
c, err := dialTLS(network, addr)
hj.Conn = c
return &hijackedConn{c, hj}, err
}
return hj
}
// getTransportDial always returns a plain Dialer
// and defaults to the existing t.Dial.
func getTransportDial(t *http.Transport) func(network, addr string) (net.Conn, error) {
if t.Dial != nil {
return t.Dial
}
return defaultDialer.Dial
}
// getTransportDial always returns a TLS Dialer
// and defaults to the existing t.DialTLS.
func getTransportDialTLS(t *http.Transport) func(network, addr string) (net.Conn, error) {
if t.DialTLS != nil {
return t.DialTLS
}
// newConnHijackerTransport will modify t.Dial after calling this method
// => Create a backup reference.
plainDial := getTransportDial(t)
// The following DialTLS implementation stems from the Go stdlib and
// is identical to what happens if DialTLS is not provided.
// Source: https://github.com/golang/go/blob/230a376b5a67f0e9341e1fa47e670ff762213c83/src/net/http/transport.go#L1018-L1051
return func(network, addr string) (net.Conn, error) {
plainConn, err := plainDial(network, addr)
if err != nil {
return nil, err
}
tlsClientConfig := t.TLSClientConfig
if tlsClientConfig == nil {
tlsClientConfig = &tls.Config{}
}
if !tlsClientConfig.InsecureSkipVerify && tlsClientConfig.ServerName == "" {
tlsClientConfig.ServerName = stripPort(addr)
}
tlsConn := tls.Client(plainConn, tlsClientConfig)
errc := make(chan error, 2)
var timer *time.Timer
if d := t.TLSHandshakeTimeout; d != 0 {
timer = time.AfterFunc(d, func() {
errc <- tlsHandshakeTimeoutError{}
})
}
go func() {
err := tlsConn.Handshake()
if timer != nil {
timer.Stop()
}
errc <- err
}()
if err := <-errc; err != nil {
plainConn.Close()
return nil, err
}
if !tlsClientConfig.InsecureSkipVerify {
hostname := tlsClientConfig.ServerName
if hostname == "" {
hostname = stripPort(addr)
}
if err := tlsConn.VerifyHostname(hostname); err != nil {
plainConn.Close()
return nil, err
}
}
return tlsConn, nil
}
}
// stripPort returns address without its port if it has one and
// works with IP addresses as well as hostnames formatted as host:port.
//
// IPv6 addresses (excluding the port) must be enclosed in
// square brackets similar to the requirements of Go's stdlib.
func stripPort(address string) string {
// Keep in mind that the address might be a IPv6 address
// and thus contain a colon, but not have a port.
portIdx := strings.LastIndex(address, ":")
ipv6Idx := strings.LastIndex(address, "]")
if portIdx > ipv6Idx {
address = address[:portIdx]
}
return address
}
type tlsHandshakeTimeoutError struct{}
func (tlsHandshakeTimeoutError) Timeout() bool { return true }
func (tlsHandshakeTimeoutError) Temporary() bool { return true }
func (tlsHandshakeTimeoutError) Error() string { return "net/http: TLS handshake timeout" }
func requestIsWebsocket(req *http.Request) bool {
return strings.ToLower(req.Header.Get("Upgrade")) == "websocket" && strings.Contains(strings.ToLower(req.Header.Get("Connection")), "upgrade")
}
type writeFlusher interface {
io.Writer
http.Flusher
}
type maxLatencyWriter struct {
dst writeFlusher
latency time.Duration
lk sync.Mutex // protects Write + Flush
done chan bool
}
func (m *maxLatencyWriter) Write(p []byte) (int, error) {
m.lk.Lock()
defer m.lk.Unlock()
return m.dst.Write(p)
}
func (m *maxLatencyWriter) flushLoop() {
t := time.NewTicker(m.latency)
defer t.Stop()
for {
select {
case <-m.done:
if onExitFlushLoop != nil {
onExitFlushLoop()
}
return
case <-t.C:
m.lk.Lock()
m.dst.Flush()
m.lk.Unlock()
}
}
}
func (m *maxLatencyWriter) stop() { m.done <- true }