package dns import ( "io" "log" "os" "strconv" "strings" ) type debugging bool const debug debugging = false func (d debugging) Printf(format string, args ...interface{}) { if d { log.Printf(format, args...) } } const maxTok = 2048 // Largest token we can return. const maxUint16 = 1<<16 - 1 // Tokinize a RFC 1035 zone file. The tokenizer will normalize it: // * Add ownernames if they are left blank; // * Suppress sequences of spaces; // * Make each RR fit on one line (_NEWLINE is send as last) // * Handle comments: ; // * Handle braces - anywhere. const ( // Zonefile zEOF = iota zString zBlank zQuote zNewline zRrtpe zOwner zClass zDirOrigin // $ORIGIN zDirTtl // $TTL zDirInclude // $INCLUDE zDirGenerate // $GENERATE // Privatekey file zValue zKey zExpectOwnerDir // Ownername zExpectOwnerBl // Whitespace after the ownername zExpectAny // Expect rrtype, ttl or class zExpectAnyNoClass // Expect rrtype or ttl zExpectAnyNoClassBl // The whitespace after _EXPECT_ANY_NOCLASS zExpectAnyNoTtl // Expect rrtype or class zExpectAnyNoTtlBl // Whitespace after _EXPECT_ANY_NOTTL zExpectRrtype // Expect rrtype zExpectRrtypeBl // Whitespace BEFORE rrtype zExpectRdata // The first element of the rdata zExpectDirTtlBl // Space after directive $TTL zExpectDirTtl // Directive $TTL zExpectDirOriginBl // Space after directive $ORIGIN zExpectDirOrigin // Directive $ORIGIN zExpectDirIncludeBl // Space after directive $INCLUDE zExpectDirInclude // Directive $INCLUDE zExpectDirGenerate // Directive $GENERATE zExpectDirGenerateBl // Space after directive $GENERATE ) // ParseError is a parsing error. It contains the parse error and the location in the io.Reader // where the error occurred. type ParseError struct { file string err string lex lex } func (e *ParseError) Error() (s string) { if e.file != "" { s = e.file + ": " } s += "dns: " + e.err + ": " + strconv.QuoteToASCII(e.lex.token) + " at line: " + strconv.Itoa(e.lex.line) + ":" + strconv.Itoa(e.lex.column) return } type lex struct { token string // text of the token tokenUpper string // uppercase text of the token length int // length of the token err bool // when true, token text has lexer error value uint8 // value: zString, _BLANK, etc. line int // line in the file column int // column in the file torc uint16 // type or class as parsed in the lexer, we only need to look this up in the grammar comment string // any comment text seen } // Token holds the token that are returned when a zone file is parsed. type Token struct { // The scanned resource record when error is not nil. RR // When an error occurred, this has the error specifics. Error *ParseError // A potential comment positioned after the RR and on the same line. Comment string } // ttlState describes the state necessary to fill in an omitted RR TTL type ttlState struct { ttl uint32 // ttl is the current default TTL isByDirective bool // isByDirective indicates whether ttl was set by a $TTL directive } // NewRR reads the RR contained in the string s. Only the first RR is // returned. If s contains no RR, return nil with no error. The class // defaults to IN and TTL defaults to 3600. The full zone file syntax // like $TTL, $ORIGIN, etc. is supported. All fields of the returned // RR are set, except RR.Header().Rdlength which is set to 0. func NewRR(s string) (RR, error) { if len(s) > 0 && s[len(s)-1] != '\n' { // We need a closing newline return ReadRR(strings.NewReader(s+"\n"), "") } return ReadRR(strings.NewReader(s), "") } // ReadRR reads the RR contained in q. // See NewRR for more documentation. func ReadRR(q io.Reader, filename string) (RR, error) { defttl := &ttlState{defaultTtl, false} r := <-parseZoneHelper(q, ".", defttl, filename, 1) if r == nil { return nil, nil } if r.Error != nil { return nil, r.Error } return r.RR, nil } // ParseZone reads a RFC 1035 style zonefile from r. It returns *Tokens on the // returned channel, each consisting of either a parsed RR and optional comment // or a nil RR and an error. The string file is only used // in error reporting. The string origin is used as the initial origin, as // if the file would start with an $ORIGIN directive. // The directives $INCLUDE, $ORIGIN, $TTL and $GENERATE are supported. // The channel t is closed by ParseZone when the end of r is reached. // // Basic usage pattern when reading from a string (z) containing the // zone data: // // for x := range dns.ParseZone(strings.NewReader(z), "", "") { // if x.Error != nil { // // log.Println(x.Error) // } else { // // Do something with x.RR // } // } // // Comments specified after an RR (and on the same line!) are returned too: // // foo. IN A 10.0.0.1 ; this is a comment // // The text "; this is comment" is returned in Token.Comment. Comments inside the // RR are discarded. Comments on a line by themselves are discarded too. func ParseZone(r io.Reader, origin, file string) chan *Token { return parseZoneHelper(r, origin, nil, file, 10000) } func parseZoneHelper(r io.Reader, origin string, defttl *ttlState, file string, chansize int) chan *Token { t := make(chan *Token, chansize) go parseZone(r, origin, defttl, file, t, 0) return t } func parseZone(r io.Reader, origin string, defttl *ttlState, f string, t chan *Token, include int) { defer func() { if include == 0 { close(t) } }() s := scanInit(r) c := make(chan lex) // Start the lexer go zlexer(s, c) // 6 possible beginnings of a line, _ is a space // 0. zRRTYPE -> all omitted until the rrtype // 1. zOwner _ zRrtype -> class/ttl omitted // 2. zOwner _ zString _ zRrtype -> class omitted // 3. zOwner _ zString _ zClass _ zRrtype -> ttl/class // 4. zOwner _ zClass _ zRrtype -> ttl omitted // 5. zOwner _ zClass _ zString _ zRrtype -> class/ttl (reversed) // After detecting these, we know the zRrtype so we can jump to functions // handling the rdata for each of these types. if origin != "" { origin = Fqdn(origin) if _, ok := IsDomainName(origin); !ok { t <- &Token{Error: &ParseError{f, "bad initial origin name", lex{}}} return } } st := zExpectOwnerDir // initial state var h RR_Header var prevName string for l := range c { // Lexer spotted an error already if l.err == true { t <- &Token{Error: &ParseError{f, l.token, l}} return } switch st { case zExpectOwnerDir: // We can also expect a directive, like $TTL or $ORIGIN if defttl != nil { h.Ttl = defttl.ttl } h.Class = ClassINET switch l.value { case zNewline: st = zExpectOwnerDir case zOwner: h.Name = l.token name, ok := toAbsoluteName(l.token, origin) if !ok { t <- &Token{Error: &ParseError{f, "bad owner name", l}} return } h.Name = name prevName = h.Name st = zExpectOwnerBl case zDirTtl: st = zExpectDirTtlBl case zDirOrigin: st = zExpectDirOriginBl case zDirInclude: st = zExpectDirIncludeBl case zDirGenerate: st = zExpectDirGenerateBl case zRrtpe: h.Name = prevName h.Rrtype = l.torc st = zExpectRdata case zClass: h.Name = prevName h.Class = l.torc st = zExpectAnyNoClassBl case zBlank: // Discard, can happen when there is nothing on the // line except the RR type case zString: ttl, ok := stringToTtl(l.token) if !ok { t <- &Token{Error: &ParseError{f, "not a TTL", l}} return } h.Ttl = ttl if defttl == nil || !defttl.isByDirective { defttl = &ttlState{ttl, false} } st = zExpectAnyNoTtlBl default: t <- &Token{Error: &ParseError{f, "syntax error at beginning", l}} return } case zExpectDirIncludeBl: if l.value != zBlank { t <- &Token{Error: &ParseError{f, "no blank after $INCLUDE-directive", l}} return } st = zExpectDirInclude case zExpectDirInclude: if l.value != zString { t <- &Token{Error: &ParseError{f, "expecting $INCLUDE value, not this...", l}} return } neworigin := origin // There may be optionally a new origin set after the filename, if not use current one switch l := <-c; l.value { case zBlank: l := <-c if l.value == zString { name, ok := toAbsoluteName(l.token, origin) if !ok { t <- &Token{Error: &ParseError{f, "bad origin name", l}} return } neworigin = name } case zNewline, zEOF: // Ok default: t <- &Token{Error: &ParseError{f, "garbage after $INCLUDE", l}} return } // Start with the new file r1, e1 := os.Open(l.token) if e1 != nil { t <- &Token{Error: &ParseError{f, "failed to open `" + l.token + "'", l}} return } if include+1 > 7 { t <- &Token{Error: &ParseError{f, "too deeply nested $INCLUDE", l}} return } parseZone(r1, neworigin, defttl, l.token, t, include+1) st = zExpectOwnerDir case zExpectDirTtlBl: if l.value != zBlank { t <- &Token{Error: &ParseError{f, "no blank after $TTL-directive", l}} return } st = zExpectDirTtl case zExpectDirTtl: if l.value != zString { t <- &Token{Error: &ParseError{f, "expecting $TTL value, not this...", l}} return } if e, _ := slurpRemainder(c, f); e != nil { t <- &Token{Error: e} return } ttl, ok := stringToTtl(l.token) if !ok { t <- &Token{Error: &ParseError{f, "expecting $TTL value, not this...", l}} return } defttl = &ttlState{ttl, true} st = zExpectOwnerDir case zExpectDirOriginBl: if l.value != zBlank { t <- &Token{Error: &ParseError{f, "no blank after $ORIGIN-directive", l}} return } st = zExpectDirOrigin case zExpectDirOrigin: if l.value != zString { t <- &Token{Error: &ParseError{f, "expecting $ORIGIN value, not this...", l}} return } if e, _ := slurpRemainder(c, f); e != nil { t <- &Token{Error: e} } name, ok := toAbsoluteName(l.token, origin) if !ok { t <- &Token{Error: &ParseError{f, "bad origin name", l}} return } origin = name st = zExpectOwnerDir case zExpectDirGenerateBl: if l.value != zBlank { t <- &Token{Error: &ParseError{f, "no blank after $GENERATE-directive", l}} return } st = zExpectDirGenerate case zExpectDirGenerate: if l.value != zString { t <- &Token{Error: &ParseError{f, "expecting $GENERATE value, not this...", l}} return } if errMsg := generate(l, c, t, origin); errMsg != "" { t <- &Token{Error: &ParseError{f, errMsg, l}} return } st = zExpectOwnerDir case zExpectOwnerBl: if l.value != zBlank { t <- &Token{Error: &ParseError{f, "no blank after owner", l}} return } st = zExpectAny case zExpectAny: switch l.value { case zRrtpe: if defttl == nil { t <- &Token{Error: &ParseError{f, "missing TTL with no previous value", l}} return } h.Rrtype = l.torc st = zExpectRdata case zClass: h.Class = l.torc st = zExpectAnyNoClassBl case zString: ttl, ok := stringToTtl(l.token) if !ok { t <- &Token{Error: &ParseError{f, "not a TTL", l}} return } h.Ttl = ttl if defttl == nil || !defttl.isByDirective { defttl = &ttlState{ttl, false} } st = zExpectAnyNoTtlBl default: t <- &Token{Error: &ParseError{f, "expecting RR type, TTL or class, not this...", l}} return } case zExpectAnyNoClassBl: if l.value != zBlank { t <- &Token{Error: &ParseError{f, "no blank before class", l}} return } st = zExpectAnyNoClass case zExpectAnyNoTtlBl: if l.value != zBlank { t <- &Token{Error: &ParseError{f, "no blank before TTL", l}} return } st = zExpectAnyNoTtl case zExpectAnyNoTtl: switch l.value { case zClass: h.Class = l.torc st = zExpectRrtypeBl case zRrtpe: h.Rrtype = l.torc st = zExpectRdata default: t <- &Token{Error: &ParseError{f, "expecting RR type or class, not this...", l}} return } case zExpectAnyNoClass: switch l.value { case zString: ttl, ok := stringToTtl(l.token) if !ok { t <- &Token{Error: &ParseError{f, "not a TTL", l}} return } h.Ttl = ttl if defttl == nil || !defttl.isByDirective { defttl = &ttlState{ttl, false} } st = zExpectRrtypeBl case zRrtpe: h.Rrtype = l.torc st = zExpectRdata default: t <- &Token{Error: &ParseError{f, "expecting RR type or TTL, not this...", l}} return } case zExpectRrtypeBl: if l.value != zBlank { t <- &Token{Error: &ParseError{f, "no blank before RR type", l}} return } st = zExpectRrtype case zExpectRrtype: if l.value != zRrtpe { t <- &Token{Error: &ParseError{f, "unknown RR type", l}} return } h.Rrtype = l.torc st = zExpectRdata case zExpectRdata: r, e, c1 := setRR(h, c, origin, f) if e != nil { // If e.lex is nil than we have encounter a unknown RR type // in that case we substitute our current lex token if e.lex.token == "" && e.lex.value == 0 { e.lex = l // Uh, dirty } t <- &Token{Error: e} return } t <- &Token{RR: r, Comment: c1} st = zExpectOwnerDir } } // If we get here, we and the h.Rrtype is still zero, we haven't parsed anything, this // is not an error, because an empty zone file is still a zone file. } // zlexer scans the sourcefile and returns tokens on the channel c. func zlexer(s *scan, c chan lex) { var l lex str := make([]byte, maxTok) // Should be enough for any token stri := 0 // Offset in str (0 means empty) com := make([]byte, maxTok) // Hold comment text comi := 0 quote := false escape := false space := false commt := false rrtype := false owner := true brace := 0 x, err := s.tokenText() defer close(c) for err == nil { l.column = s.position.Column l.line = s.position.Line if stri >= maxTok { l.token = "token length insufficient for parsing" l.err = true debug.Printf("[%+v]", l.token) c <- l return } if comi >= maxTok { l.token = "comment length insufficient for parsing" l.err = true debug.Printf("[%+v]", l.token) c <- l return } switch x { case ' ', '\t': if escape { escape = false str[stri] = x stri++ break } if quote { // Inside quotes this is legal str[stri] = x stri++ break } if commt { com[comi] = x comi++ break } if stri == 0 { // Space directly in the beginning, handled in the grammar } else if owner { // If we have a string and its the first, make it an owner l.value = zOwner l.token = string(str[:stri]) l.tokenUpper = strings.ToUpper(l.token) l.length = stri // escape $... start with a \ not a $, so this will work switch l.tokenUpper { case "$TTL": l.value = zDirTtl case "$ORIGIN": l.value = zDirOrigin case "$INCLUDE": l.value = zDirInclude case "$GENERATE": l.value = zDirGenerate } debug.Printf("[7 %+v]", l.token) c <- l } else { l.value = zString l.token = string(str[:stri]) l.tokenUpper = strings.ToUpper(l.token) l.length = stri if !rrtype { if t, ok := StringToType[l.tokenUpper]; ok { l.value = zRrtpe l.torc = t rrtype = true } else { if strings.HasPrefix(l.tokenUpper, "TYPE") { t, ok := typeToInt(l.token) if !ok { l.token = "unknown RR type" l.err = true c <- l return } l.value = zRrtpe l.torc = t } } if t, ok := StringToClass[l.tokenUpper]; ok { l.value = zClass l.torc = t } else { if strings.HasPrefix(l.tokenUpper, "CLASS") { t, ok := classToInt(l.token) if !ok { l.token = "unknown class" l.err = true c <- l return } l.value = zClass l.torc = t } } } debug.Printf("[6 %+v]", l.token) c <- l } stri = 0 // I reverse space stuff here if !space && !commt { l.value = zBlank l.token = " " l.length = 1 debug.Printf("[5 %+v]", l.token) c <- l } owner = false space = true case ';': if escape { escape = false str[stri] = x stri++ break } if quote { // Inside quotes this is legal str[stri] = x stri++ break } if stri > 0 { l.value = zString l.token = string(str[:stri]) l.tokenUpper = strings.ToUpper(l.token) l.length = stri debug.Printf("[4 %+v]", l.token) c <- l stri = 0 } commt = true com[comi] = ';' comi++ case '\r': escape = false if quote { str[stri] = x stri++ break } // discard if outside of quotes case '\n': escape = false // Escaped newline if quote { str[stri] = x stri++ break } // inside quotes this is legal if commt { // Reset a comment commt = false rrtype = false stri = 0 // If not in a brace this ends the comment AND the RR if brace == 0 { owner = true owner = true l.value = zNewline l.token = "\n" l.tokenUpper = l.token l.length = 1 l.comment = string(com[:comi]) debug.Printf("[3 %+v %+v]", l.token, l.comment) c <- l l.comment = "" comi = 0 break } com[comi] = ' ' // convert newline to space comi++ break } if brace == 0 { // If there is previous text, we should output it here if stri != 0 { l.value = zString l.token = string(str[:stri]) l.tokenUpper = strings.ToUpper(l.token) l.length = stri if !rrtype { if t, ok := StringToType[l.tokenUpper]; ok { l.value = zRrtpe l.torc = t rrtype = true } } debug.Printf("[2 %+v]", l.token) c <- l } l.value = zNewline l.token = "\n" l.tokenUpper = l.token l.length = 1 debug.Printf("[1 %+v]", l.token) c <- l stri = 0 commt = false rrtype = false owner = true comi = 0 } case '\\': // comments do not get escaped chars, everything is copied if commt { com[comi] = x comi++ break } // something already escaped must be in string if escape { str[stri] = x stri++ escape = false break } // something escaped outside of string gets added to string str[stri] = x stri++ escape = true case '"': if commt { com[comi] = x comi++ break } if escape { str[stri] = x stri++ escape = false break } space = false // send previous gathered text and the quote if stri != 0 { l.value = zString l.token = string(str[:stri]) l.tokenUpper = strings.ToUpper(l.token) l.length = stri debug.Printf("[%+v]", l.token) c <- l stri = 0 } // send quote itself as separate token l.value = zQuote l.token = "\"" l.tokenUpper = l.token l.length = 1 c <- l quote = !quote case '(', ')': if commt { com[comi] = x comi++ break } if escape { str[stri] = x stri++ escape = false break } if quote { str[stri] = x stri++ break } switch x { case ')': brace-- if brace < 0 { l.token = "extra closing brace" l.tokenUpper = l.token l.err = true debug.Printf("[%+v]", l.token) c <- l return } case '(': brace++ } default: escape = false if commt { com[comi] = x comi++ break } str[stri] = x stri++ space = false } x, err = s.tokenText() } if stri > 0 { // Send remainder l.token = string(str[:stri]) l.tokenUpper = strings.ToUpper(l.token) l.length = stri l.value = zString debug.Printf("[%+v]", l.token) c <- l } if brace != 0 { l.token = "unbalanced brace" l.tokenUpper = l.token l.err = true c <- l } } // Extract the class number from CLASSxx func classToInt(token string) (uint16, bool) { offset := 5 if len(token) < offset+1 { return 0, false } class, err := strconv.ParseUint(token[offset:], 10, 16) if err != nil { return 0, false } return uint16(class), true } // Extract the rr number from TYPExxx func typeToInt(token string) (uint16, bool) { offset := 4 if len(token) < offset+1 { return 0, false } typ, err := strconv.ParseUint(token[offset:], 10, 16) if err != nil { return 0, false } return uint16(typ), true } // Parse things like 2w, 2m, etc, Return the time in seconds. func stringToTtl(token string) (uint32, bool) { s := uint32(0) i := uint32(0) for _, c := range token { switch c { case 's', 'S': s += i i = 0 case 'm', 'M': s += i * 60 i = 0 case 'h', 'H': s += i * 60 * 60 i = 0 case 'd', 'D': s += i * 60 * 60 * 24 i = 0 case 'w', 'W': s += i * 60 * 60 * 24 * 7 i = 0 case '0', '1', '2', '3', '4', '5', '6', '7', '8', '9': i *= 10 i += uint32(c) - '0' default: return 0, false } } return s + i, true } // Parse LOC records' [.][mM] into a // mantissa exponent format. Token should contain the entire // string (i.e. no spaces allowed) func stringToCm(token string) (e, m uint8, ok bool) { if token[len(token)-1] == 'M' || token[len(token)-1] == 'm' { token = token[0 : len(token)-1] } s := strings.SplitN(token, ".", 2) var meters, cmeters, val int var err error switch len(s) { case 2: if cmeters, err = strconv.Atoi(s[1]); err != nil { return } fallthrough case 1: if meters, err = strconv.Atoi(s[0]); err != nil { return } case 0: // huh? return 0, 0, false } ok = true if meters > 0 { e = 2 val = meters } else { e = 0 val = cmeters } for val > 10 { e++ val /= 10 } if e > 9 { ok = false } m = uint8(val) return } func toAbsoluteName(name, origin string) (absolute string, ok bool) { // check for an explicit origin reference if name == "@" { // require a nonempty origin if origin == "" { return "", false } return origin, true } // require a valid domain name _, ok = IsDomainName(name) if !ok || name == "" { return "", false } // check if name is already absolute if name[len(name)-1] == '.' { return name, true } // require a nonempty origin if origin == "" { return "", false } return appendOrigin(name, origin), true } func appendOrigin(name, origin string) string { if origin == "." { return name + origin } return name + "." + origin } // LOC record helper function func locCheckNorth(token string, latitude uint32) (uint32, bool) { switch token { case "n", "N": return LOC_EQUATOR + latitude, true case "s", "S": return LOC_EQUATOR - latitude, true } return latitude, false } // LOC record helper function func locCheckEast(token string, longitude uint32) (uint32, bool) { switch token { case "e", "E": return LOC_EQUATOR + longitude, true case "w", "W": return LOC_EQUATOR - longitude, true } return longitude, false } // "Eat" the rest of the "line". Return potential comments func slurpRemainder(c chan lex, f string) (*ParseError, string) { l := <-c com := "" switch l.value { case zBlank: l = <-c com = l.comment if l.value != zNewline && l.value != zEOF { return &ParseError{f, "garbage after rdata", l}, "" } case zNewline: com = l.comment case zEOF: default: return &ParseError{f, "garbage after rdata", l}, "" } return nil, com } // Parse a 64 bit-like ipv6 address: "0014:4fff:ff20:ee64" // Used for NID and L64 record. func stringToNodeID(l lex) (uint64, *ParseError) { if len(l.token) < 19 { return 0, &ParseError{l.token, "bad NID/L64 NodeID/Locator64", l} } // There must be three colons at fixes postitions, if not its a parse error if l.token[4] != ':' && l.token[9] != ':' && l.token[14] != ':' { return 0, &ParseError{l.token, "bad NID/L64 NodeID/Locator64", l} } s := l.token[0:4] + l.token[5:9] + l.token[10:14] + l.token[15:19] u, err := strconv.ParseUint(s, 16, 64) if err != nil { return 0, &ParseError{l.token, "bad NID/L64 NodeID/Locator64", l} } return u, nil }