// 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. // Package url parses URLs and implements query escaping. // See RFC 3986. package url import ( "bytes" "errors" "sort" "strconv" "strings" ) // Error reports an error and the operation and URL that caused it. type Error struct { Op string URL string Err error } func (e *Error) Error() string { return e.Op + " " + e.URL + ": " + e.Err.Error() } func ishex(c byte) bool { switch { case '0' <= c && c <= '9': return true case 'a' <= c && c <= 'f': return true case 'A' <= c && c <= 'F': return true } return false } func unhex(c byte) byte { switch { case '0' <= c && c <= '9': return c - '0' case 'a' <= c && c <= 'f': return c - 'a' + 10 case 'A' <= c && c <= 'F': return c - 'A' + 10 } return 0 } type encoding int const ( encodePath encoding = 1 + iota encodeUserPassword encodeQueryComponent encodeFragment ) type EscapeError string func (e EscapeError) Error() string { return "invalid URL escape " + strconv.Quote(string(e)) } // Return true if the specified character should be escaped when // appearing in a URL string, according to RFC 3986. func shouldEscape(c byte, mode encoding) bool { // §2.3 Unreserved characters (alphanum) if 'A' <= c && c <= 'Z' || 'a' <= c && c <= 'z' || '0' <= c && c <= '9' { return false } switch c { case '-', '_', '.', '~': // §2.3 Unreserved characters (mark) return false case '$', '&', '+', ',', '/', ':', ';', '=', '?', '@': // §2.2 Reserved characters (reserved) // Different sections of the URL allow a few of // the reserved characters to appear unescaped. switch mode { case encodePath: // §3.3 // The RFC allows : @ & = + $ but saves / ; , for assigning // meaning to individual path segments. This package // only manipulates the path as a whole, so we allow those // last two as well. That leaves only ? to escape. return c == '?' case encodeUserPassword: // §3.2.1 // The RFC allows ';', ':', '&', '=', '+', '$', and ',' in // userinfo, so we must escape only '@', '/', and '?'. // The parsing of userinfo treats ':' as special so we must escape // that too. return c == '@' || c == '/' || c == '?' || c == ':' case encodeQueryComponent: // §3.4 // The RFC reserves (so we must escape) everything. return true case encodeFragment: // §4.1 // The RFC text is silent but the grammar allows // everything, so escape nothing. return false } } // Everything else must be escaped. return true } // QueryUnescape does the inverse transformation of QueryEscape, converting // %AB into the byte 0xAB and '+' into ' ' (space). It returns an error if // any % is not followed by two hexadecimal digits. func QueryUnescape(s string) (string, error) { return unescape(s, encodeQueryComponent) } // unescape unescapes a string; the mode specifies // which section of the URL string is being unescaped. func unescape(s string, mode encoding) (string, error) { // Count %, check that they're well-formed. n := 0 hasPlus := false for i := 0; i < len(s); { switch s[i] { case '%': n++ if i+2 >= len(s) || !ishex(s[i+1]) || !ishex(s[i+2]) { s = s[i:] if len(s) > 3 { s = s[0:3] } return "", EscapeError(s) } i += 3 case '+': hasPlus = mode == encodeQueryComponent i++ default: i++ } } if n == 0 && !hasPlus { return s, nil } t := make([]byte, len(s)-2*n) j := 0 for i := 0; i < len(s); { switch s[i] { case '%': t[j] = unhex(s[i+1])<<4 | unhex(s[i+2]) j++ i += 3 case '+': if mode == encodeQueryComponent { t[j] = ' ' } else { t[j] = '+' } j++ i++ default: t[j] = s[i] j++ i++ } } return string(t), nil } // QueryEscape escapes the string so it can be safely placed // inside a URL query. func QueryEscape(s string) string { return escape(s, encodeQueryComponent) } func escape(s string, mode encoding) string { spaceCount, hexCount := 0, 0 for i := 0; i < len(s); i++ { c := s[i] if shouldEscape(c, mode) { if c == ' ' && mode == encodeQueryComponent { spaceCount++ } else { hexCount++ } } } if spaceCount == 0 && hexCount == 0 { return s } t := make([]byte, len(s)+2*hexCount) j := 0 for i := 0; i < len(s); i++ { switch c := s[i]; { case c == ' ' && mode == encodeQueryComponent: t[j] = '+' j++ case shouldEscape(c, mode): t[j] = '%' t[j+1] = "0123456789ABCDEF"[c>>4] t[j+2] = "0123456789ABCDEF"[c&15] j += 3 default: t[j] = s[i] j++ } } return string(t) } // A URL represents a parsed URL (technically, a URI reference). // The general form represented is: // // scheme://[userinfo@]host/path[?query][#fragment] // // URLs that do not start with a slash after the scheme are interpreted as: // // scheme:opaque[?query][#fragment] // // Note that the Path field is stored in decoded form: /%47%6f%2f becomes /Go/. // A consequence is that it is impossible to tell which slashes in the Path were // slashes in the raw URL and which were %2f. This distinction is rarely important, // but when it is a client must use other routines to parse the raw URL or construct // the parsed URL. For example, an HTTP server can consult req.RequestURI, and // an HTTP client can use URL{Host: "example.com", Opaque: "//example.com/Go%2f"} // instead of URL{Host: "example.com", Path: "/Go/"}. type URL struct { Scheme string Opaque string // encoded opaque data User *Userinfo // username and password information Host string // host or host:port Path string RawQuery string // encoded query values, without '?' Fragment string // fragment for references, without '#' } // User returns a Userinfo containing the provided username // and no password set. func User(username string) *Userinfo { return &Userinfo{username, "", false} } // UserPassword returns a Userinfo containing the provided username // and password. // This functionality should only be used with legacy web sites. // RFC 2396 warns that interpreting Userinfo this way // ``is NOT RECOMMENDED, because the passing of authentication // information in clear text (such as URI) has proven to be a // security risk in almost every case where it has been used.'' func UserPassword(username, password string) *Userinfo { return &Userinfo{username, password, true} } // The Userinfo type is an immutable encapsulation of username and // password details for a URL. An existing Userinfo value is guaranteed // to have a username set (potentially empty, as allowed by RFC 2396), // and optionally a password. type Userinfo struct { username string password string passwordSet bool } // Username returns the username. func (u *Userinfo) Username() string { return u.username } // Password returns the password in case it is set, and whether it is set. func (u *Userinfo) Password() (string, bool) { if u.passwordSet { return u.password, true } return "", false } // String returns the encoded userinfo information in the standard form // of "username[:password]". func (u *Userinfo) String() string { s := escape(u.username, encodeUserPassword) if u.passwordSet { s += ":" + escape(u.password, encodeUserPassword) } return s } // Maybe rawurl is of the form scheme:path. // (Scheme must be [a-zA-Z][a-zA-Z0-9+-.]*) // If so, return scheme, path; else return "", rawurl. func getscheme(rawurl string) (scheme, path string, err error) { for i := 0; i < len(rawurl); i++ { c := rawurl[i] switch { case 'a' <= c && c <= 'z' || 'A' <= c && c <= 'Z': // do nothing case '0' <= c && c <= '9' || c == '+' || c == '-' || c == '.': if i == 0 { return "", rawurl, nil } case c == ':': if i == 0 { return "", "", errors.New("missing protocol scheme") } return rawurl[0:i], rawurl[i+1:], nil default: // we have encountered an invalid character, // so there is no valid scheme return "", rawurl, nil } } return "", rawurl, nil } // Maybe s is of the form t c u. // If so, return t, c u (or t, u if cutc == true). // If not, return s, "". func split(s string, c string, cutc bool) (string, string) { i := strings.Index(s, c) if i < 0 { return s, "" } if cutc { return s[0:i], s[i+len(c):] } return s[0:i], s[i:] } // Parse parses rawurl into a URL structure. // The rawurl may be relative or absolute. func Parse(rawurl string) (url *URL, err error) { // Cut off #frag u, frag := split(rawurl, "#", true) if url, err = parse(u, false); err != nil { return nil, err } if frag == "" { return url, nil } if url.Fragment, err = unescape(frag, encodeFragment); err != nil { return nil, &Error{"parse", rawurl, err} } return url, nil } // ParseRequestURI parses rawurl into a URL structure. It assumes that // rawurl was received in an HTTP request, so the rawurl is interpreted // only as an absolute URI or an absolute path. // The string rawurl is assumed not to have a #fragment suffix. // (Web browsers strip #fragment before sending the URL to a web server.) func ParseRequestURI(rawurl string) (url *URL, err error) { return parse(rawurl, true) } // parse parses a URL from a string in one of two contexts. If // viaRequest is true, the URL is assumed to have arrived via an HTTP request, // in which case only absolute URLs or path-absolute relative URLs are allowed. // If viaRequest is false, all forms of relative URLs are allowed. func parse(rawurl string, viaRequest bool) (url *URL, err error) { var rest string if rawurl == "" && viaRequest { err = errors.New("empty url") goto Error } url = new(URL) if rawurl == "*" { url.Path = "*" return } // Split off possible leading "http:", "mailto:", etc. // Cannot contain escaped characters. if url.Scheme, rest, err = getscheme(rawurl); err != nil { goto Error } url.Scheme = strings.ToLower(url.Scheme) rest, url.RawQuery = split(rest, "?", true) if !strings.HasPrefix(rest, "/") { if url.Scheme != "" { // We consider rootless paths per RFC 3986 as opaque. url.Opaque = rest return url, nil } if viaRequest { err = errors.New("invalid URI for request") goto Error } } if (url.Scheme != "" || !viaRequest && !strings.HasPrefix(rest, "///")) && strings.HasPrefix(rest, "//") { var authority string authority, rest = split(rest[2:], "/", false) url.User, url.Host, err = parseAuthority(authority) if err != nil { goto Error } if strings.Contains(url.Host, "%") { err = errors.New("hexadecimal escape in host") goto Error } } if url.Path, err = unescape(rest, encodePath); err != nil { goto Error } return url, nil Error: return nil, &Error{"parse", rawurl, err} } func parseAuthority(authority string) (user *Userinfo, host string, err error) { i := strings.LastIndex(authority, "@") if i < 0 { host = authority return } userinfo, host := authority[:i], authority[i+1:] if strings.Index(userinfo, ":") < 0 { if userinfo, err = unescape(userinfo, encodeUserPassword); err != nil { return } user = User(userinfo) } else { username, password := split(userinfo, ":", true) if username, err = unescape(username, encodeUserPassword); err != nil { return } if password, err = unescape(password, encodeUserPassword); err != nil { return } user = UserPassword(username, password) } return } // String reassembles the URL into a valid URL string. // The general form of the result is one of: // // scheme:opaque // scheme://userinfo@host/path?query#fragment // // If u.Opaque is non-empty, String uses the first form; // otherwise it uses the second form. // // In the second form, the following rules apply: // - if u.Scheme is empty, scheme: is omitted. // - if u.User is nil, userinfo@ is omitted. // - if u.Host is empty, host/ is omitted. // - if u.Scheme and u.Host are empty and u.User is nil, // the entire scheme://userinfo@host/ is omitted. // - if u.Host is non-empty and u.Path begins with a /, // the form host/path does not add its own /. // - if u.RawQuery is empty, ?query is omitted. // - if u.Fragment is empty, #fragment is omitted. func (u *URL) String() string { var buf bytes.Buffer if u.Scheme != "" { buf.WriteString(u.Scheme) buf.WriteByte(':') } if u.Opaque != "" { buf.WriteString(u.Opaque) } else { if u.Scheme != "" || u.Host != "" || u.User != nil { buf.WriteString("//") if ui := u.User; ui != nil { buf.WriteString(ui.String()) buf.WriteByte('@') } if h := u.Host; h != "" { buf.WriteString(h) } } if u.Path != "" && u.Path[0] != '/' && u.Host != "" { buf.WriteByte('/') } buf.WriteString(escape(u.Path, encodePath)) } if u.RawQuery != "" { buf.WriteByte('?') buf.WriteString(u.RawQuery) } if u.Fragment != "" { buf.WriteByte('#') buf.WriteString(escape(u.Fragment, encodeFragment)) } return buf.String() } // Values maps a string key to a list of values. // It is typically used for query parameters and form values. // Unlike in the http.Header map, the keys in a Values map // are case-sensitive. type Values map[string][]string // Get gets the first value associated with the given key. // If there are no values associated with the key, Get returns // the empty string. To access multiple values, use the map // directly. func (v Values) Get(key string) string { if v == nil { return "" } vs, ok := v[key] if !ok || len(vs) == 0 { return "" } return vs[0] } // Set sets the key to value. It replaces any existing // values. func (v Values) Set(key, value string) { v[key] = []string{value} } // Add adds the value to key. It appends to any existing // values associated with key. func (v Values) Add(key, value string) { v[key] = append(v[key], value) } // Del deletes the values associated with key. func (v Values) Del(key string) { delete(v, key) } // ParseQuery parses the URL-encoded query string and returns // a map listing the values specified for each key. // ParseQuery always returns a non-nil map containing all the // valid query parameters found; err describes the first decoding error // encountered, if any. func ParseQuery(query string) (m Values, err error) { m = make(Values) err = parseQuery(m, query) return } func parseQuery(m Values, query string) (err error) { for query != "" { key := query if i := strings.IndexAny(key, "&;"); i >= 0 { key, query = key[:i], key[i+1:] } else { query = "" } if key == "" { continue } value := "" if i := strings.Index(key, "="); i >= 0 { key, value = key[:i], key[i+1:] } key, err1 := QueryUnescape(key) if err1 != nil { if err == nil { err = err1 } continue } value, err1 = QueryUnescape(value) if err1 != nil { if err == nil { err = err1 } continue } m[key] = append(m[key], value) } return err } // Encode encodes the values into ``URL encoded'' form // ("bar=baz&foo=quux") sorted by key. func (v Values) Encode() string { if v == nil { return "" } var buf bytes.Buffer keys := make([]string, 0, len(v)) for k := range v { keys = append(keys, k) } sort.Strings(keys) for _, k := range keys { vs := v[k] prefix := QueryEscape(k) + "=" for _, v := range vs { if buf.Len() > 0 { buf.WriteByte('&') } buf.WriteString(prefix) buf.WriteString(QueryEscape(v)) } } return buf.String() } // resolvePath applies special path segments from refs and applies // them to base, per RFC 3986. func resolvePath(base, ref string) string { var full string if ref == "" { full = base } else if ref[0] != '/' { i := strings.LastIndex(base, "/") full = base[:i+1] + ref } else { full = ref } if full == "" { return "" } var dst []string src := strings.Split(full, "/") for _, elem := range src { switch elem { case ".": // drop case "..": if len(dst) > 0 { dst = dst[:len(dst)-1] } default: dst = append(dst, elem) } } if last := src[len(src)-1]; last == "." || last == ".." { // Add final slash to the joined path. dst = append(dst, "") } return "/" + strings.TrimLeft(strings.Join(dst, "/"), "/") } // IsAbs returns true if the URL is absolute. func (u *URL) IsAbs() bool { return u.Scheme != "" } // Parse parses a URL in the context of the receiver. The provided URL // may be relative or absolute. Parse returns nil, err on parse // failure, otherwise its return value is the same as ResolveReference. func (u *URL) Parse(ref string) (*URL, error) { refurl, err := Parse(ref) if err != nil { return nil, err } return u.ResolveReference(refurl), nil } // ResolveReference resolves a URI reference to an absolute URI from // an absolute base URI, per RFC 3986 Section 5.2. The URI reference // may be relative or absolute. ResolveReference always returns a new // URL instance, even if the returned URL is identical to either the // base or reference. If ref is an absolute URL, then ResolveReference // ignores base and returns a copy of ref. func (u *URL) ResolveReference(ref *URL) *URL { url := *ref if ref.Scheme == "" { url.Scheme = u.Scheme } if ref.Scheme != "" || ref.Host != "" || ref.User != nil { // The "absoluteURI" or "net_path" cases. url.Path = resolvePath(ref.Path, "") return &url } if ref.Opaque != "" { url.User = nil url.Host = "" url.Path = "" return &url } if ref.Path == "" { if ref.RawQuery == "" { url.RawQuery = u.RawQuery if ref.Fragment == "" { url.Fragment = u.Fragment } } } // The "abs_path" or "rel_path" cases. url.Host = u.Host url.User = u.User url.Path = resolvePath(u.Path, ref.Path) return &url } // Query parses RawQuery and returns the corresponding values. func (u *URL) Query() Values { v, _ := ParseQuery(u.RawQuery) return v } // RequestURI returns the encoded path?query or opaque?query // string that would be used in an HTTP request for u. func (u *URL) RequestURI() string { result := u.Opaque if result == "" { result = escape(u.Path, encodePath) if result == "" { result = "/" } } else { if strings.HasPrefix(result, "//") { result = u.Scheme + ":" + result } } if u.RawQuery != "" { result += "?" + u.RawQuery } return result }