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[/] [openrisc/] [trunk/] [gnu-dev/] [or1k-gcc/] [libgo/] [go/] [net/] [http/] [server.go] - Rev 858

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// Copyright 2009 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.

// HTTP server.  See RFC 2616.

// TODO(rsc):
//      logging

package http

import (
        "bufio"
        "bytes"
        "crypto/rand"
        "crypto/tls"
        "errors"
        "fmt"
        "io"
        "io/ioutil"
        "log"
        "net"
        "net/url"
        "path"
        "runtime/debug"
        "strconv"
        "strings"
        "sync"
        "time"
)

// Errors introduced by the HTTP server.
var (
        ErrWriteAfterFlush = errors.New("Conn.Write called after Flush")
        ErrBodyNotAllowed  = errors.New("http: response status code does not allow body")
        ErrHijacked        = errors.New("Conn has been hijacked")
        ErrContentLength   = errors.New("Conn.Write wrote more than the declared Content-Length")
)

// Objects implementing the Handler interface can be
// registered to serve a particular path or subtree
// in the HTTP server.
//
// ServeHTTP should write reply headers and data to the ResponseWriter
// and then return.  Returning signals that the request is finished
// and that the HTTP server can move on to the next request on
// the connection.
type Handler interface {
        ServeHTTP(ResponseWriter, *Request)
}

// A ResponseWriter interface is used by an HTTP handler to
// construct an HTTP response.
type ResponseWriter interface {
        // Header returns the header map that will be sent by WriteHeader.
        // Changing the header after a call to WriteHeader (or Write) has
        // no effect.
        Header() Header

        // Write writes the data to the connection as part of an HTTP reply.
        // If WriteHeader has not yet been called, Write calls WriteHeader(http.StatusOK)
        // before writing the data.
        Write([]byte) (int, error)

        // WriteHeader sends an HTTP response header with status code.
        // If WriteHeader is not called explicitly, the first call to Write
        // will trigger an implicit WriteHeader(http.StatusOK).
        // Thus explicit calls to WriteHeader are mainly used to
        // send error codes.
        WriteHeader(int)
}

// The Flusher interface is implemented by ResponseWriters that allow
// an HTTP handler to flush buffered data to the client.
//
// Note that even for ResponseWriters that support Flush,
// if the client is connected through an HTTP proxy,
// the buffered data may not reach the client until the response
// completes.
type Flusher interface {
        // Flush sends any buffered data to the client.
        Flush()
}

// The Hijacker interface is implemented by ResponseWriters that allow
// an HTTP handler to take over the connection.
type Hijacker interface {
        // Hijack lets the caller take over the connection.
        // After a call to Hijack(), the HTTP server library
        // will not do anything else with the connection.
        // It becomes the caller's responsibility to manage
        // and close the connection.
        Hijack() (net.Conn, *bufio.ReadWriter, error)
}

// A conn represents the server side of an HTTP connection.
type conn struct {
        remoteAddr string               // network address of remote side
        server     *Server              // the Server on which the connection arrived
        rwc        net.Conn             // i/o connection
        lr         *io.LimitedReader    // io.LimitReader(rwc)
        buf        *bufio.ReadWriter    // buffered(lr,rwc), reading from bufio->limitReader->rwc
        hijacked   bool                 // connection has been hijacked by handler
        tlsState   *tls.ConnectionState // or nil when not using TLS
        body       []byte
}

// A response represents the server side of an HTTP response.
type response struct {
        conn          *conn
        req           *Request // request for this response
        chunking      bool     // using chunked transfer encoding for reply body
        wroteHeader   bool     // reply header has been written
        wroteContinue bool     // 100 Continue response was written
        header        Header   // reply header parameters
        written       int64    // number of bytes written in body
        contentLength int64    // explicitly-declared Content-Length; or -1
        status        int      // status code passed to WriteHeader
        needSniff     bool     // need to sniff to find Content-Type

        // close connection after this reply.  set on request and
        // updated after response from handler if there's a
        // "Connection: keep-alive" response header and a
        // Content-Length.
        closeAfterReply bool

        // requestBodyLimitHit is set by requestTooLarge when
        // maxBytesReader hits its max size. It is checked in
        // WriteHeader, to make sure we don't consume the the
        // remaining request body to try to advance to the next HTTP
        // request. Instead, when this is set, we stop doing
        // subsequent requests on this connection and stop reading
        // input from it.
        requestBodyLimitHit bool
}

// requestTooLarge is called by maxBytesReader when too much input has
// been read from the client.
func (w *response) requestTooLarge() {
        w.closeAfterReply = true
        w.requestBodyLimitHit = true
        if !w.wroteHeader {
                w.Header().Set("Connection", "close")
        }
}

type writerOnly struct {
        io.Writer
}

func (w *response) ReadFrom(src io.Reader) (n int64, err error) {
        // Call WriteHeader before checking w.chunking if it hasn't
        // been called yet, since WriteHeader is what sets w.chunking.
        if !w.wroteHeader {
                w.WriteHeader(StatusOK)
        }
        if !w.chunking && w.bodyAllowed() && !w.needSniff {
                w.Flush()
                if rf, ok := w.conn.rwc.(io.ReaderFrom); ok {
                        n, err = rf.ReadFrom(src)
                        w.written += n
                        return
                }
        }
        // Fall back to default io.Copy implementation.
        // Use wrapper to hide w.ReadFrom from io.Copy.
        return io.Copy(writerOnly{w}, src)
}

// noLimit is an effective infinite upper bound for io.LimitedReader
const noLimit int64 = (1 << 63) - 1

// Create new connection from rwc.
func (srv *Server) newConn(rwc net.Conn) (c *conn, err error) {
        c = new(conn)
        c.remoteAddr = rwc.RemoteAddr().String()
        c.server = srv
        c.rwc = rwc
        c.body = make([]byte, sniffLen)
        c.lr = io.LimitReader(rwc, noLimit).(*io.LimitedReader)
        br := bufio.NewReader(c.lr)
        bw := bufio.NewWriter(rwc)
        c.buf = bufio.NewReadWriter(br, bw)
        return c, nil
}

// DefaultMaxHeaderBytes is the maximum permitted size of the headers
// in an HTTP request.
// This can be overridden by setting Server.MaxHeaderBytes.
const DefaultMaxHeaderBytes = 1 << 20 // 1 MB

func (srv *Server) maxHeaderBytes() int {
        if srv.MaxHeaderBytes > 0 {
                return srv.MaxHeaderBytes
        }
        return DefaultMaxHeaderBytes
}

// wrapper around io.ReaderCloser which on first read, sends an
// HTTP/1.1 100 Continue header
type expectContinueReader struct {
        resp       *response
        readCloser io.ReadCloser
        closed     bool
}

func (ecr *expectContinueReader) Read(p []byte) (n int, err error) {
        if ecr.closed {
                return 0, errors.New("http: Read after Close on request Body")
        }
        if !ecr.resp.wroteContinue && !ecr.resp.conn.hijacked {
                ecr.resp.wroteContinue = true
                io.WriteString(ecr.resp.conn.buf, "HTTP/1.1 100 Continue\r\n\r\n")
                ecr.resp.conn.buf.Flush()
        }
        return ecr.readCloser.Read(p)
}

func (ecr *expectContinueReader) Close() error {
        ecr.closed = true
        return ecr.readCloser.Close()
}

// TimeFormat is the time format to use with
// time.Parse and time.Time.Format when parsing
// or generating times in HTTP headers.
// It is like time.RFC1123 but hard codes GMT as the time zone.
const TimeFormat = "Mon, 02 Jan 2006 15:04:05 GMT"

var errTooLarge = errors.New("http: request too large")

// Read next request from connection.
func (c *conn) readRequest() (w *response, err error) {
        if c.hijacked {
                return nil, ErrHijacked
        }
        c.lr.N = int64(c.server.maxHeaderBytes()) + 4096 /* bufio slop */
        var req *Request
        if req, err = ReadRequest(c.buf.Reader); err != nil {
                if c.lr.N == 0 {
                        return nil, errTooLarge
                }
                return nil, err
        }
        c.lr.N = noLimit

        req.RemoteAddr = c.remoteAddr
        req.TLS = c.tlsState

        w = new(response)
        w.conn = c
        w.req = req
        w.header = make(Header)
        w.contentLength = -1
        c.body = c.body[:0]
        return w, nil
}

func (w *response) Header() Header {
        return w.header
}

// maxPostHandlerReadBytes is the max number of Request.Body bytes not
// consumed by a handler that the server will read from the client
// in order to keep a connection alive.  If there are more bytes than
// this then the server to be paranoid instead sends a "Connection:
// close" response.
//
// This number is approximately what a typical machine's TCP buffer
// size is anyway.  (if we have the bytes on the machine, we might as
// well read them)
const maxPostHandlerReadBytes = 256 << 10

func (w *response) WriteHeader(code int) {
        if w.conn.hijacked {
                log.Print("http: response.WriteHeader on hijacked connection")
                return
        }
        if w.wroteHeader {
                log.Print("http: multiple response.WriteHeader calls")
                return
        }
        w.wroteHeader = true
        w.status = code

        // Check for a explicit (and valid) Content-Length header.
        var hasCL bool
        var contentLength int64
        if clenStr := w.header.Get("Content-Length"); clenStr != "" {
                var err error
                contentLength, err = strconv.ParseInt(clenStr, 10, 64)
                if err == nil {
                        hasCL = true
                } else {
                        log.Printf("http: invalid Content-Length of %q sent", clenStr)
                        w.header.Del("Content-Length")
                }
        }

        if w.req.wantsHttp10KeepAlive() && (w.req.Method == "HEAD" || hasCL) {
                _, connectionHeaderSet := w.header["Connection"]
                if !connectionHeaderSet {
                        w.header.Set("Connection", "keep-alive")
                }
        } else if !w.req.ProtoAtLeast(1, 1) {
                // Client did not ask to keep connection alive.
                w.closeAfterReply = true
        }

        if w.header.Get("Connection") == "close" {
                w.closeAfterReply = true
        }

        // Per RFC 2616, we should consume the request body before
        // replying, if the handler hasn't already done so.  But we
        // don't want to do an unbounded amount of reading here for
        // DoS reasons, so we only try up to a threshold.
        if w.req.ContentLength != 0 && !w.closeAfterReply {
                ecr, isExpecter := w.req.Body.(*expectContinueReader)
                if !isExpecter || ecr.resp.wroteContinue {
                        n, _ := io.CopyN(ioutil.Discard, w.req.Body, maxPostHandlerReadBytes+1)
                        if n >= maxPostHandlerReadBytes {
                                w.requestTooLarge()
                                w.header.Set("Connection", "close")
                        } else {
                                w.req.Body.Close()
                        }
                }
        }

        if code == StatusNotModified {
                // Must not have body.
                for _, header := range []string{"Content-Type", "Content-Length", "Transfer-Encoding"} {
                        if w.header.Get(header) != "" {
                                // TODO: return an error if WriteHeader gets a return parameter
                                // or set a flag on w to make future Writes() write an error page?
                                // for now just log and drop the header.
                                log.Printf("http: StatusNotModified response with header %q defined", header)
                                w.header.Del(header)
                        }
                }
        } else {
                // If no content type, apply sniffing algorithm to body.
                if w.header.Get("Content-Type") == "" && w.req.Method != "HEAD" {
                        w.needSniff = true
                }
        }

        if _, ok := w.header["Date"]; !ok {
                w.Header().Set("Date", time.Now().UTC().Format(TimeFormat))
        }

        te := w.header.Get("Transfer-Encoding")
        hasTE := te != ""
        if hasCL && hasTE && te != "identity" {
                // TODO: return an error if WriteHeader gets a return parameter
                // For now just ignore the Content-Length.
                log.Printf("http: WriteHeader called with both Transfer-Encoding of %q and a Content-Length of %d",
                        te, contentLength)
                w.header.Del("Content-Length")
                hasCL = false
        }

        if w.req.Method == "HEAD" || code == StatusNotModified {
                // do nothing
        } else if hasCL {
                w.contentLength = contentLength
                w.header.Del("Transfer-Encoding")
        } else if w.req.ProtoAtLeast(1, 1) {
                // HTTP/1.1 or greater: use chunked transfer encoding
                // to avoid closing the connection at EOF.
                // TODO: this blows away any custom or stacked Transfer-Encoding they
                // might have set.  Deal with that as need arises once we have a valid
                // use case.
                w.chunking = true
                w.header.Set("Transfer-Encoding", "chunked")
        } else {
                // HTTP version < 1.1: cannot do chunked transfer
                // encoding and we don't know the Content-Length so
                // signal EOF by closing connection.
                w.closeAfterReply = true
                w.header.Del("Transfer-Encoding") // in case already set
        }

        // Cannot use Content-Length with non-identity Transfer-Encoding.
        if w.chunking {
                w.header.Del("Content-Length")
        }
        if !w.req.ProtoAtLeast(1, 0) {
                return
        }
        proto := "HTTP/1.0"
        if w.req.ProtoAtLeast(1, 1) {
                proto = "HTTP/1.1"
        }
        codestring := strconv.Itoa(code)
        text, ok := statusText[code]
        if !ok {
                text = "status code " + codestring
        }
        io.WriteString(w.conn.buf, proto+" "+codestring+" "+text+"\r\n")
        w.header.Write(w.conn.buf)

        // If we need to sniff the body, leave the header open.
        // Otherwise, end it here.
        if !w.needSniff {
                io.WriteString(w.conn.buf, "\r\n")
        }
}

// sniff uses the first block of written data,
// stored in w.conn.body, to decide the Content-Type
// for the HTTP body.
func (w *response) sniff() {
        if !w.needSniff {
                return
        }
        w.needSniff = false

        data := w.conn.body
        fmt.Fprintf(w.conn.buf, "Content-Type: %s\r\n\r\n", DetectContentType(data))

        if len(data) == 0 {
                return
        }
        if w.chunking {
                fmt.Fprintf(w.conn.buf, "%x\r\n", len(data))
        }
        _, err := w.conn.buf.Write(data)
        if w.chunking && err == nil {
                io.WriteString(w.conn.buf, "\r\n")
        }
}

// bodyAllowed returns true if a Write is allowed for this response type.
// It's illegal to call this before the header has been flushed.
func (w *response) bodyAllowed() bool {
        if !w.wroteHeader {
                panic("")
        }
        return w.status != StatusNotModified && w.req.Method != "HEAD"
}

func (w *response) Write(data []byte) (n int, err error) {
        if w.conn.hijacked {
                log.Print("http: response.Write on hijacked connection")
                return 0, ErrHijacked
        }
        if !w.wroteHeader {
                w.WriteHeader(StatusOK)
        }
        if len(data) == 0 {
                return 0, nil
        }
        if !w.bodyAllowed() {
                return 0, ErrBodyNotAllowed
        }

        w.written += int64(len(data)) // ignoring errors, for errorKludge
        if w.contentLength != -1 && w.written > w.contentLength {
                return 0, ErrContentLength
        }

        var m int
        if w.needSniff {
                // We need to sniff the beginning of the output to
                // determine the content type.  Accumulate the
                // initial writes in w.conn.body.
                // Cap m so that append won't allocate.
                m = cap(w.conn.body) - len(w.conn.body)
                if m > len(data) {
                        m = len(data)
                }
                w.conn.body = append(w.conn.body, data[:m]...)
                data = data[m:]
                if len(data) == 0 {
                        // Copied everything into the buffer.
                        // Wait for next write.
                        return m, nil
                }

                // Filled the buffer; more data remains.
                // Sniff the content (flushes the buffer)
                // and then proceed with the remainder
                // of the data as a normal Write.
                // Calling sniff clears needSniff.
                w.sniff()
        }

        // TODO(rsc): if chunking happened after the buffering,
        // then there would be fewer chunk headers.
        // On the other hand, it would make hijacking more difficult.
        if w.chunking {
                fmt.Fprintf(w.conn.buf, "%x\r\n", len(data)) // TODO(rsc): use strconv not fmt
        }
        n, err = w.conn.buf.Write(data)
        if err == nil && w.chunking {
                if n != len(data) {
                        err = io.ErrShortWrite
                }
                if err == nil {
                        io.WriteString(w.conn.buf, "\r\n")
                }
        }

        return m + n, err
}

func (w *response) finishRequest() {
        // If this was an HTTP/1.0 request with keep-alive and we sent a Content-Length
        // back, we can make this a keep-alive response ...
        if w.req.wantsHttp10KeepAlive() {
                sentLength := w.header.Get("Content-Length") != ""
                if sentLength && w.header.Get("Connection") == "keep-alive" {
                        w.closeAfterReply = false
                }
        }
        if !w.wroteHeader {
                w.WriteHeader(StatusOK)
        }
        if w.needSniff {
                w.sniff()
        }
        if w.chunking {
                io.WriteString(w.conn.buf, "0\r\n")
                // trailer key/value pairs, followed by blank line
                io.WriteString(w.conn.buf, "\r\n")
        }
        w.conn.buf.Flush()
        // Close the body, unless we're about to close the whole TCP connection
        // anyway.
        if !w.closeAfterReply {
                w.req.Body.Close()
        }
        if w.req.MultipartForm != nil {
                w.req.MultipartForm.RemoveAll()
        }

        if w.contentLength != -1 && w.contentLength != w.written {
                // Did not write enough. Avoid getting out of sync.
                w.closeAfterReply = true
        }
}

func (w *response) Flush() {
        if !w.wroteHeader {
                w.WriteHeader(StatusOK)
        }
        w.sniff()
        w.conn.buf.Flush()
}

// Close the connection.
func (c *conn) close() {
        if c.buf != nil {
                c.buf.Flush()
                c.buf = nil
        }
        if c.rwc != nil {
                c.rwc.Close()
                c.rwc = nil
        }
}

// Serve a new connection.
func (c *conn) serve() {
        defer func() {
                err := recover()
                if err == nil {
                        return
                }

                var buf bytes.Buffer
                fmt.Fprintf(&buf, "http: panic serving %v: %v\n", c.remoteAddr, err)
                buf.Write(debug.Stack())
                log.Print(buf.String())

                if c.rwc != nil { // may be nil if connection hijacked
                        c.rwc.Close()
                }
        }()

        if tlsConn, ok := c.rwc.(*tls.Conn); ok {
                if err := tlsConn.Handshake(); err != nil {
                        c.close()
                        return
                }
                c.tlsState = new(tls.ConnectionState)
                *c.tlsState = tlsConn.ConnectionState()
        }

        for {
                w, err := c.readRequest()
                if err != nil {
                        msg := "400 Bad Request"
                        if err == errTooLarge {
                                // Their HTTP client may or may not be
                                // able to read this if we're
                                // responding to them and hanging up
                                // while they're still writing their
                                // request.  Undefined behavior.
                                msg = "413 Request Entity Too Large"
                        } else if err == io.ErrUnexpectedEOF {
                                break // Don't reply
                        } else if neterr, ok := err.(net.Error); ok && neterr.Timeout() {
                                break // Don't reply
                        }
                        fmt.Fprintf(c.rwc, "HTTP/1.1 %s\r\n\r\n", msg)
                        break
                }

                // Expect 100 Continue support
                req := w.req
                if req.expectsContinue() {
                        if req.ProtoAtLeast(1, 1) {
                                // Wrap the Body reader with one that replies on the connection
                                req.Body = &expectContinueReader{readCloser: req.Body, resp: w}
                        }
                        if req.ContentLength == 0 {
                                w.Header().Set("Connection", "close")
                                w.WriteHeader(StatusBadRequest)
                                w.finishRequest()
                                break
                        }
                        req.Header.Del("Expect")
                } else if req.Header.Get("Expect") != "" {
                        // TODO(bradfitz): let ServeHTTP handlers handle
                        // requests with non-standard expectation[s]? Seems
                        // theoretical at best, and doesn't fit into the
                        // current ServeHTTP model anyway.  We'd need to
                        // make the ResponseWriter an optional
                        // "ExpectReplier" interface or something.
                        //
                        // For now we'll just obey RFC 2616 14.20 which says
                        // "If a server receives a request containing an
                        // Expect field that includes an expectation-
                        // extension that it does not support, it MUST
                        // respond with a 417 (Expectation Failed) status."
                        w.Header().Set("Connection", "close")
                        w.WriteHeader(StatusExpectationFailed)
                        w.finishRequest()
                        break
                }

                handler := c.server.Handler
                if handler == nil {
                        handler = DefaultServeMux
                }

                // HTTP cannot have multiple simultaneous active requests.[*]
                // Until the server replies to this request, it can't read another,
                // so we might as well run the handler in this goroutine.
                // [*] Not strictly true: HTTP pipelining.  We could let them all process
                // in parallel even if their responses need to be serialized.
                handler.ServeHTTP(w, w.req)
                if c.hijacked {
                        return
                }
                w.finishRequest()
                if w.closeAfterReply {
                        break
                }
        }
        c.close()
}

// Hijack implements the Hijacker.Hijack method. Our response is both a ResponseWriter
// and a Hijacker.
func (w *response) Hijack() (rwc net.Conn, buf *bufio.ReadWriter, err error) {
        if w.conn.hijacked {
                return nil, nil, ErrHijacked
        }
        w.conn.hijacked = true
        rwc = w.conn.rwc
        buf = w.conn.buf
        w.conn.rwc = nil
        w.conn.buf = nil
        return
}

// The HandlerFunc type is an adapter to allow the use of
// ordinary functions as HTTP handlers.  If f is a function
// with the appropriate signature, HandlerFunc(f) is a
// Handler object that calls f.
type HandlerFunc func(ResponseWriter, *Request)

// ServeHTTP calls f(w, r).
func (f HandlerFunc) ServeHTTP(w ResponseWriter, r *Request) {
        f(w, r)
}

// Helper handlers

// Error replies to the request with the specified error message and HTTP code.
func Error(w ResponseWriter, error string, code int) {
        w.Header().Set("Content-Type", "text/plain; charset=utf-8")
        w.WriteHeader(code)
        fmt.Fprintln(w, error)
}

// NotFound replies to the request with an HTTP 404 not found error.
func NotFound(w ResponseWriter, r *Request) { Error(w, "404 page not found", StatusNotFound) }

// NotFoundHandler returns a simple request handler
// that replies to each request with a ``404 page not found'' reply.
func NotFoundHandler() Handler { return HandlerFunc(NotFound) }

// StripPrefix returns a handler that serves HTTP requests
// by removing the given prefix from the request URL's Path
// and invoking the handler h. StripPrefix handles a
// request for a path that doesn't begin with prefix by
// replying with an HTTP 404 not found error.
func StripPrefix(prefix string, h Handler) Handler {
        return HandlerFunc(func(w ResponseWriter, r *Request) {
                if !strings.HasPrefix(r.URL.Path, prefix) {
                        NotFound(w, r)
                        return
                }
                r.URL.Path = r.URL.Path[len(prefix):]
                h.ServeHTTP(w, r)
        })
}

// Redirect replies to the request with a redirect to url,
// which may be a path relative to the request path.
func Redirect(w ResponseWriter, r *Request, urlStr string, code int) {
        if u, err := url.Parse(urlStr); err == nil {
                // If url was relative, make absolute by
                // combining with request path.
                // The browser would probably do this for us,
                // but doing it ourselves is more reliable.

                // NOTE(rsc): RFC 2616 says that the Location
                // line must be an absolute URI, like
                // "http://www.google.com/redirect/",
                // not a path like "/redirect/".
                // Unfortunately, we don't know what to
                // put in the host name section to get the
                // client to connect to us again, so we can't
                // know the right absolute URI to send back.
                // Because of this problem, no one pays attention
                // to the RFC; they all send back just a new path.
                // So do we.
                oldpath := r.URL.Path
                if oldpath == "" { // should not happen, but avoid a crash if it does
                        oldpath = "/"
                }
                if u.Scheme == "" {
                        // no leading http://server
                        if urlStr == "" || urlStr[0] != '/' {
                                // make relative path absolute
                                olddir, _ := path.Split(oldpath)
                                urlStr = olddir + urlStr
                        }

                        var query string
                        if i := strings.Index(urlStr, "?"); i != -1 {
                                urlStr, query = urlStr[:i], urlStr[i:]
                        }

                        // clean up but preserve trailing slash
                        trailing := urlStr[len(urlStr)-1] == '/'
                        urlStr = path.Clean(urlStr)
                        if trailing && urlStr[len(urlStr)-1] != '/' {
                                urlStr += "/"
                        }
                        urlStr += query
                }
        }

        w.Header().Set("Location", urlStr)
        w.WriteHeader(code)

        // RFC2616 recommends that a short note "SHOULD" be included in the
        // response because older user agents may not understand 301/307.
        // Shouldn't send the response for POST or HEAD; that leaves GET.
        if r.Method == "GET" {
                note := "<a href=\"" + htmlEscape(urlStr) + "\">" + statusText[code] + "</a>.\n"
                fmt.Fprintln(w, note)
        }
}

var htmlReplacer = strings.NewReplacer(
        "&", "&amp;",
        "<", "&lt;",
        ">", "&gt;",
        `"`, "&quot;",
        "'", "&apos;",
)

func htmlEscape(s string) string {
        return htmlReplacer.Replace(s)
}

// Redirect to a fixed URL
type redirectHandler struct {
        url  string
        code int
}

func (rh *redirectHandler) ServeHTTP(w ResponseWriter, r *Request) {
        Redirect(w, r, rh.url, rh.code)
}

// RedirectHandler returns a request handler that redirects
// each request it receives to the given url using the given
// status code.
func RedirectHandler(url string, code int) Handler {
        return &redirectHandler{url, code}
}

// ServeMux is an HTTP request multiplexer.
// It matches the URL of each incoming request against a list of registered
// patterns and calls the handler for the pattern that
// most closely matches the URL.
//
// Patterns named fixed, rooted paths, like "/favicon.ico",
// or rooted subtrees, like "/images/" (note the trailing slash).
// Longer patterns take precedence over shorter ones, so that
// if there are handlers registered for both "/images/"
// and "/images/thumbnails/", the latter handler will be
// called for paths beginning "/images/thumbnails/" and the
// former will receiver requests for any other paths in the
// "/images/" subtree.
//
// Patterns may optionally begin with a host name, restricting matches to
// URLs on that host only.  Host-specific patterns take precedence over
// general patterns, so that a handler might register for the two patterns
// "/codesearch" and "codesearch.google.com/" without also taking over
// requests for "http://www.google.com/".
//
// ServeMux also takes care of sanitizing the URL request path,
// redirecting any request containing . or .. elements to an
// equivalent .- and ..-free URL.
type ServeMux struct {
        m map[string]Handler
}

// NewServeMux allocates and returns a new ServeMux.
func NewServeMux() *ServeMux { return &ServeMux{make(map[string]Handler)} }

// DefaultServeMux is the default ServeMux used by Serve.
var DefaultServeMux = NewServeMux()

// Does path match pattern?
func pathMatch(pattern, path string) bool {
        if len(pattern) == 0 {
                // should not happen
                return false
        }
        n := len(pattern)
        if pattern[n-1] != '/' {
                return pattern == path
        }
        return len(path) >= n && path[0:n] == pattern
}

// Return the canonical path for p, eliminating . and .. elements.
func cleanPath(p string) string {
        if p == "" {
                return "/"
        }
        if p[0] != '/' {
                p = "/" + p
        }
        np := path.Clean(p)
        // path.Clean removes trailing slash except for root;
        // put the trailing slash back if necessary.
        if p[len(p)-1] == '/' && np != "/" {
                np += "/"
        }
        return np
}

// Find a handler on a handler map given a path string
// Most-specific (longest) pattern wins
func (mux *ServeMux) match(path string) Handler {
        var h Handler
        var n = 0
        for k, v := range mux.m {
                if !pathMatch(k, path) {
                        continue
                }
                if h == nil || len(k) > n {
                        n = len(k)
                        h = v
                }
        }
        return h
}

// ServeHTTP dispatches the request to the handler whose
// pattern most closely matches the request URL.
func (mux *ServeMux) ServeHTTP(w ResponseWriter, r *Request) {
        // Clean path to canonical form and redirect.
        if p := cleanPath(r.URL.Path); p != r.URL.Path {
                w.Header().Set("Location", p)
                w.WriteHeader(StatusMovedPermanently)
                return
        }
        // Host-specific pattern takes precedence over generic ones
        h := mux.match(r.Host + r.URL.Path)
        if h == nil {
                h = mux.match(r.URL.Path)
        }
        if h == nil {
                h = NotFoundHandler()
        }
        h.ServeHTTP(w, r)
}

// Handle registers the handler for the given pattern.
func (mux *ServeMux) Handle(pattern string, handler Handler) {
        if pattern == "" {
                panic("http: invalid pattern " + pattern)
        }

        mux.m[pattern] = handler

        // Helpful behavior:
        // If pattern is /tree/, insert permanent redirect for /tree.
        n := len(pattern)
        if n > 0 && pattern[n-1] == '/' {
                mux.m[pattern[0:n-1]] = RedirectHandler(pattern, StatusMovedPermanently)
        }
}

// HandleFunc registers the handler function for the given pattern.
func (mux *ServeMux) HandleFunc(pattern string, handler func(ResponseWriter, *Request)) {
        mux.Handle(pattern, HandlerFunc(handler))
}

// Handle registers the handler for the given pattern
// in the DefaultServeMux.
// The documentation for ServeMux explains how patterns are matched.
func Handle(pattern string, handler Handler) { DefaultServeMux.Handle(pattern, handler) }

// HandleFunc registers the handler function for the given pattern
// in the DefaultServeMux.
// The documentation for ServeMux explains how patterns are matched.
func HandleFunc(pattern string, handler func(ResponseWriter, *Request)) {
        DefaultServeMux.HandleFunc(pattern, handler)
}

// Serve accepts incoming HTTP connections on the listener l,
// creating a new service thread for each.  The service threads
// read requests and then call handler to reply to them.
// Handler is typically nil, in which case the DefaultServeMux is used.
func Serve(l net.Listener, handler Handler) error {
        srv := &Server{Handler: handler}
        return srv.Serve(l)
}

// A Server defines parameters for running an HTTP server.
type Server struct {
        Addr           string        // TCP address to listen on, ":http" if empty
        Handler        Handler       // handler to invoke, http.DefaultServeMux if nil
        ReadTimeout    time.Duration // maximum duration before timing out read of the request
        WriteTimeout   time.Duration // maximum duration before timing out write of the response
        MaxHeaderBytes int           // maximum size of request headers, DefaultMaxHeaderBytes if 0
}

// ListenAndServe listens on the TCP network address srv.Addr and then
// calls Serve to handle requests on incoming connections.  If
// srv.Addr is blank, ":http" is used.
func (srv *Server) ListenAndServe() error {
        addr := srv.Addr
        if addr == "" {
                addr = ":http"
        }
        l, e := net.Listen("tcp", addr)
        if e != nil {
                return e
        }
        return srv.Serve(l)
}

// Serve accepts incoming connections on the Listener l, creating a
// new service thread for each.  The service threads read requests and
// then call srv.Handler to reply to them.
func (srv *Server) Serve(l net.Listener) error {
        defer l.Close()
        for {
                rw, e := l.Accept()
                if e != nil {
                        if ne, ok := e.(net.Error); ok && ne.Temporary() {
                                log.Printf("http: Accept error: %v", e)
                                continue
                        }
                        return e
                }
                if srv.ReadTimeout != 0 {
                        rw.SetReadDeadline(time.Now().Add(srv.ReadTimeout))
                }
                if srv.WriteTimeout != 0 {
                        rw.SetWriteDeadline(time.Now().Add(srv.WriteTimeout))
                }
                c, err := srv.newConn(rw)
                if err != nil {
                        continue
                }
                go c.serve()
        }
        panic("not reached")
}

// ListenAndServe listens on the TCP network address addr
// and then calls Serve with handler to handle requests
// on incoming connections.  Handler is typically nil,
// in which case the DefaultServeMux is used.
//
// A trivial example server is:
//
//      package main
//
//      import (
//              "io"
//              "net/http"
//              "log"
//      )
//
//      // hello world, the web server
//      func HelloServer(w http.ResponseWriter, req *http.Request) {
//              io.WriteString(w, "hello, world!\n")
//      }
//
//      func main() {
//              http.HandleFunc("/hello", HelloServer)
//              err := http.ListenAndServe(":12345", nil)
//              if err != nil {
//                      log.Fatal("ListenAndServe: ", err)
//              }
//      }
func ListenAndServe(addr string, handler Handler) error {
        server := &Server{Addr: addr, Handler: handler}
        return server.ListenAndServe()
}

// ListenAndServeTLS acts identically to ListenAndServe, except that it
// expects HTTPS connections. Additionally, files containing a certificate and
// matching private key for the server must be provided. If the certificate
// is signed by a certificate authority, the certFile should be the concatenation
// of the server's certificate followed by the CA's certificate.
//
// A trivial example server is:
//
//      import (
//              "log"
//              "net/http"
//      )
//
//      func handler(w http.ResponseWriter, req *http.Request) {
//              w.Header().Set("Content-Type", "text/plain")
//              w.Write([]byte("This is an example server.\n"))
//      }
//
//      func main() {
//              http.HandleFunc("/", handler)
//              log.Printf("About to listen on 10443. Go to https://127.0.0.1:10443/")
//              err := http.ListenAndServeTLS(":10443", "cert.pem", "key.pem", nil)
//              if err != nil {
//                      log.Fatal(err)
//              }
//      }
//
// One can use generate_cert.go in crypto/tls to generate cert.pem and key.pem.
func ListenAndServeTLS(addr string, certFile string, keyFile string, handler Handler) error {
        server := &Server{Addr: addr, Handler: handler}
        return server.ListenAndServeTLS(certFile, keyFile)
}

// ListenAndServeTLS listens on the TCP network address srv.Addr and
// then calls Serve to handle requests on incoming TLS connections.
//
// Filenames containing a certificate and matching private key for
// the server must be provided. If the certificate is signed by a
// certificate authority, the certFile should be the concatenation
// of the server's certificate followed by the CA's certificate.
//
// If srv.Addr is blank, ":https" is used.
func (srv *Server) ListenAndServeTLS(certFile, keyFile string) error {
        addr := srv.Addr
        if addr == "" {
                addr = ":https"
        }
        config := &tls.Config{
                Rand:       rand.Reader,
                NextProtos: []string{"http/1.1"},
        }

        var err error
        config.Certificates = make([]tls.Certificate, 1)
        config.Certificates[0], err = tls.LoadX509KeyPair(certFile, keyFile)
        if err != nil {
                return err
        }

        conn, err := net.Listen("tcp", addr)
        if err != nil {
                return err
        }

        tlsListener := tls.NewListener(conn, config)
        return srv.Serve(tlsListener)
}

// TimeoutHandler returns a Handler that runs h with the given time limit.
//
// The new Handler calls h.ServeHTTP to handle each request, but if a
// call runs for more than ns nanoseconds, the handler responds with
// a 503 Service Unavailable error and the given message in its body.
// (If msg is empty, a suitable default message will be sent.)
// After such a timeout, writes by h to its ResponseWriter will return
// ErrHandlerTimeout.
func TimeoutHandler(h Handler, dt time.Duration, msg string) Handler {
        f := func() <-chan time.Time {
                return time.After(dt)
        }
        return &timeoutHandler{h, f, msg}
}

// ErrHandlerTimeout is returned on ResponseWriter Write calls
// in handlers which have timed out.
var ErrHandlerTimeout = errors.New("http: Handler timeout")

type timeoutHandler struct {
        handler Handler
        timeout func() <-chan time.Time // returns channel producing a timeout
        body    string
}

func (h *timeoutHandler) errorBody() string {
        if h.body != "" {
                return h.body
        }
        return "<html><head><title>Timeout</title></head><body><h1>Timeout</h1></body></html>"
}

func (h *timeoutHandler) ServeHTTP(w ResponseWriter, r *Request) {
        done := make(chan bool)
        tw := &timeoutWriter{w: w}
        go func() {
                h.handler.ServeHTTP(tw, r)
                done <- true
        }()
        select {
        case <-done:
                return
        case <-h.timeout():
                tw.mu.Lock()
                defer tw.mu.Unlock()
                if !tw.wroteHeader {
                        tw.w.WriteHeader(StatusServiceUnavailable)
                        tw.w.Write([]byte(h.errorBody()))
                }
                tw.timedOut = true
        }
}

type timeoutWriter struct {
        w ResponseWriter

        mu          sync.Mutex
        timedOut    bool
        wroteHeader bool
}

func (tw *timeoutWriter) Header() Header {
        return tw.w.Header()
}

func (tw *timeoutWriter) Write(p []byte) (int, error) {
        tw.mu.Lock()
        timedOut := tw.timedOut
        tw.mu.Unlock()
        if timedOut {
                return 0, ErrHandlerTimeout
        }
        return tw.w.Write(p)
}

func (tw *timeoutWriter) WriteHeader(code int) {
        tw.mu.Lock()
        if tw.timedOut || tw.wroteHeader {
                tw.mu.Unlock()
                return
        }
        tw.wroteHeader = true
        tw.mu.Unlock()
        tw.w.WriteHeader(code)
}

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