// 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 tls import "bytes" type clientHelloMsg struct { raw []byte vers uint16 random []byte sessionId []byte cipherSuites []uint16 compressionMethods []uint8 nextProtoNeg bool serverName string ocspStapling bool supportedCurves []uint16 supportedPoints []uint8 ticketSupported bool sessionTicket []uint8 signatureAndHashes []signatureAndHash } func (m *clientHelloMsg) equal(i interface{}) bool { m1, ok := i.(*clientHelloMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && m.vers == m1.vers && bytes.Equal(m.random, m1.random) && bytes.Equal(m.sessionId, m1.sessionId) && eqUint16s(m.cipherSuites, m1.cipherSuites) && bytes.Equal(m.compressionMethods, m1.compressionMethods) && m.nextProtoNeg == m1.nextProtoNeg && m.serverName == m1.serverName && m.ocspStapling == m1.ocspStapling && eqUint16s(m.supportedCurves, m1.supportedCurves) && bytes.Equal(m.supportedPoints, m1.supportedPoints) && m.ticketSupported == m1.ticketSupported && bytes.Equal(m.sessionTicket, m1.sessionTicket) && eqSignatureAndHashes(m.signatureAndHashes, m1.signatureAndHashes) } func (m *clientHelloMsg) marshal() []byte { if m.raw != nil { return m.raw } length := 2 + 32 + 1 + len(m.sessionId) + 2 + len(m.cipherSuites)*2 + 1 + len(m.compressionMethods) numExtensions := 0 extensionsLength := 0 if m.nextProtoNeg { numExtensions++ } if m.ocspStapling { extensionsLength += 1 + 2 + 2 numExtensions++ } if len(m.serverName) > 0 { extensionsLength += 5 + len(m.serverName) numExtensions++ } if len(m.supportedCurves) > 0 { extensionsLength += 2 + 2*len(m.supportedCurves) numExtensions++ } if len(m.supportedPoints) > 0 { extensionsLength += 1 + len(m.supportedPoints) numExtensions++ } if m.ticketSupported { extensionsLength += len(m.sessionTicket) numExtensions++ } if len(m.signatureAndHashes) > 0 { extensionsLength += 2 + 2*len(m.signatureAndHashes) numExtensions++ } if numExtensions > 0 { extensionsLength += 4 * numExtensions length += 2 + extensionsLength } x := make([]byte, 4+length) x[0] = typeClientHello x[1] = uint8(length >> 16) x[2] = uint8(length >> 8) x[3] = uint8(length) x[4] = uint8(m.vers >> 8) x[5] = uint8(m.vers) copy(x[6:38], m.random) x[38] = uint8(len(m.sessionId)) copy(x[39:39+len(m.sessionId)], m.sessionId) y := x[39+len(m.sessionId):] y[0] = uint8(len(m.cipherSuites) >> 7) y[1] = uint8(len(m.cipherSuites) << 1) for i, suite := range m.cipherSuites { y[2+i*2] = uint8(suite >> 8) y[3+i*2] = uint8(suite) } z := y[2+len(m.cipherSuites)*2:] z[0] = uint8(len(m.compressionMethods)) copy(z[1:], m.compressionMethods) z = z[1+len(m.compressionMethods):] if numExtensions > 0 { z[0] = byte(extensionsLength >> 8) z[1] = byte(extensionsLength) z = z[2:] } if m.nextProtoNeg { z[0] = byte(extensionNextProtoNeg >> 8) z[1] = byte(extensionNextProtoNeg) // The length is always 0 z = z[4:] } if len(m.serverName) > 0 { z[0] = byte(extensionServerName >> 8) z[1] = byte(extensionServerName) l := len(m.serverName) + 5 z[2] = byte(l >> 8) z[3] = byte(l) z = z[4:] // RFC 3546, section 3.1 // // struct { // NameType name_type; // select (name_type) { // case host_name: HostName; // } name; // } ServerName; // // enum { // host_name(0), (255) // } NameType; // // opaque HostName<1..2^16-1>; // // struct { // ServerName server_name_list<1..2^16-1> // } ServerNameList; z[0] = byte((len(m.serverName) + 3) >> 8) z[1] = byte(len(m.serverName) + 3) z[3] = byte(len(m.serverName) >> 8) z[4] = byte(len(m.serverName)) copy(z[5:], []byte(m.serverName)) z = z[l:] } if m.ocspStapling { // RFC 4366, section 3.6 z[0] = byte(extensionStatusRequest >> 8) z[1] = byte(extensionStatusRequest) z[2] = 0 z[3] = 5 z[4] = 1 // OCSP type // Two zero valued uint16s for the two lengths. z = z[9:] } if len(m.supportedCurves) > 0 { // http://tools.ietf.org/html/rfc4492#section-5.5.1 z[0] = byte(extensionSupportedCurves >> 8) z[1] = byte(extensionSupportedCurves) l := 2 + 2*len(m.supportedCurves) z[2] = byte(l >> 8) z[3] = byte(l) l -= 2 z[4] = byte(l >> 8) z[5] = byte(l) z = z[6:] for _, curve := range m.supportedCurves { z[0] = byte(curve >> 8) z[1] = byte(curve) z = z[2:] } } if len(m.supportedPoints) > 0 { // http://tools.ietf.org/html/rfc4492#section-5.5.2 z[0] = byte(extensionSupportedPoints >> 8) z[1] = byte(extensionSupportedPoints) l := 1 + len(m.supportedPoints) z[2] = byte(l >> 8) z[3] = byte(l) l-- z[4] = byte(l) z = z[5:] for _, pointFormat := range m.supportedPoints { z[0] = byte(pointFormat) z = z[1:] } } if m.ticketSupported { // http://tools.ietf.org/html/rfc5077#section-3.2 z[0] = byte(extensionSessionTicket >> 8) z[1] = byte(extensionSessionTicket) l := len(m.sessionTicket) z[2] = byte(l >> 8) z[3] = byte(l) z = z[4:] copy(z, m.sessionTicket) z = z[len(m.sessionTicket):] } if len(m.signatureAndHashes) > 0 { // https://tools.ietf.org/html/rfc5246#section-7.4.1.4.1 z[0] = byte(extensionSignatureAlgorithms >> 8) z[1] = byte(extensionSignatureAlgorithms) l := 2 + 2*len(m.signatureAndHashes) z[2] = byte(l >> 8) z[3] = byte(l) z = z[4:] l -= 2 z[0] = byte(l >> 8) z[1] = byte(l) z = z[2:] for _, sigAndHash := range m.signatureAndHashes { z[0] = sigAndHash.hash z[1] = sigAndHash.signature z = z[2:] } } m.raw = x return x } func (m *clientHelloMsg) unmarshal(data []byte) bool { if len(data) < 42 { return false } m.raw = data m.vers = uint16(data[4])<<8 | uint16(data[5]) m.random = data[6:38] sessionIdLen := int(data[38]) if sessionIdLen > 32 || len(data) < 39+sessionIdLen { return false } m.sessionId = data[39 : 39+sessionIdLen] data = data[39+sessionIdLen:] if len(data) < 2 { return false } // cipherSuiteLen is the number of bytes of cipher suite numbers. Since // they are uint16s, the number must be even. cipherSuiteLen := int(data[0])<<8 | int(data[1]) if cipherSuiteLen%2 == 1 || len(data) < 2+cipherSuiteLen { return false } numCipherSuites := cipherSuiteLen / 2 m.cipherSuites = make([]uint16, numCipherSuites) for i := 0; i < numCipherSuites; i++ { m.cipherSuites[i] = uint16(data[2+2*i])<<8 | uint16(data[3+2*i]) } data = data[2+cipherSuiteLen:] if len(data) < 1 { return false } compressionMethodsLen := int(data[0]) if len(data) < 1+compressionMethodsLen { return false } m.compressionMethods = data[1 : 1+compressionMethodsLen] data = data[1+compressionMethodsLen:] m.nextProtoNeg = false m.serverName = "" m.ocspStapling = false m.ticketSupported = false m.sessionTicket = nil m.signatureAndHashes = nil if len(data) == 0 { // ClientHello is optionally followed by extension data return true } if len(data) < 2 { return false } extensionsLength := int(data[0])<<8 | int(data[1]) data = data[2:] if extensionsLength != len(data) { return false } for len(data) != 0 { if len(data) < 4 { return false } extension := uint16(data[0])<<8 | uint16(data[1]) length := int(data[2])<<8 | int(data[3]) data = data[4:] if len(data) < length { return false } switch extension { case extensionServerName: if length < 2 { return false } numNames := int(data[0])<<8 | int(data[1]) d := data[2:] for i := 0; i < numNames; i++ { if len(d) < 3 { return false } nameType := d[0] nameLen := int(d[1])<<8 | int(d[2]) d = d[3:] if len(d) < nameLen { return false } if nameType == 0 { m.serverName = string(d[0:nameLen]) break } d = d[nameLen:] } case extensionNextProtoNeg: if length > 0 { return false } m.nextProtoNeg = true case extensionStatusRequest: m.ocspStapling = length > 0 && data[0] == statusTypeOCSP case extensionSupportedCurves: // http://tools.ietf.org/html/rfc4492#section-5.5.1 if length < 2 { return false } l := int(data[0])<<8 | int(data[1]) if l%2 == 1 || length != l+2 { return false } numCurves := l / 2 m.supportedCurves = make([]uint16, numCurves) d := data[2:] for i := 0; i < numCurves; i++ { m.supportedCurves[i] = uint16(d[0])<<8 | uint16(d[1]) d = d[2:] } case extensionSupportedPoints: // http://tools.ietf.org/html/rfc4492#section-5.5.2 if length < 1 { return false } l := int(data[0]) if length != l+1 { return false } m.supportedPoints = make([]uint8, l) copy(m.supportedPoints, data[1:]) case extensionSessionTicket: // http://tools.ietf.org/html/rfc5077#section-3.2 m.ticketSupported = true m.sessionTicket = data[:length] case extensionSignatureAlgorithms: // https://tools.ietf.org/html/rfc5246#section-7.4.1.4.1 if length < 2 || length&1 != 0 { return false } l := int(data[0])<<8 | int(data[1]) if l != length-2 { return false } n := l / 2 d := data[2:] m.signatureAndHashes = make([]signatureAndHash, n) for i := range m.signatureAndHashes { m.signatureAndHashes[i].hash = d[0] m.signatureAndHashes[i].signature = d[1] d = d[2:] } } data = data[length:] } return true } type serverHelloMsg struct { raw []byte vers uint16 random []byte sessionId []byte cipherSuite uint16 compressionMethod uint8 nextProtoNeg bool nextProtos []string ocspStapling bool ticketSupported bool } func (m *serverHelloMsg) equal(i interface{}) bool { m1, ok := i.(*serverHelloMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && m.vers == m1.vers && bytes.Equal(m.random, m1.random) && bytes.Equal(m.sessionId, m1.sessionId) && m.cipherSuite == m1.cipherSuite && m.compressionMethod == m1.compressionMethod && m.nextProtoNeg == m1.nextProtoNeg && eqStrings(m.nextProtos, m1.nextProtos) && m.ocspStapling == m1.ocspStapling && m.ticketSupported == m1.ticketSupported } func (m *serverHelloMsg) marshal() []byte { if m.raw != nil { return m.raw } length := 38 + len(m.sessionId) numExtensions := 0 extensionsLength := 0 nextProtoLen := 0 if m.nextProtoNeg { numExtensions++ for _, v := range m.nextProtos { nextProtoLen += len(v) } nextProtoLen += len(m.nextProtos) extensionsLength += nextProtoLen } if m.ocspStapling { numExtensions++ } if m.ticketSupported { numExtensions++ } if numExtensions > 0 { extensionsLength += 4 * numExtensions length += 2 + extensionsLength } x := make([]byte, 4+length) x[0] = typeServerHello x[1] = uint8(length >> 16) x[2] = uint8(length >> 8) x[3] = uint8(length) x[4] = uint8(m.vers >> 8) x[5] = uint8(m.vers) copy(x[6:38], m.random) x[38] = uint8(len(m.sessionId)) copy(x[39:39+len(m.sessionId)], m.sessionId) z := x[39+len(m.sessionId):] z[0] = uint8(m.cipherSuite >> 8) z[1] = uint8(m.cipherSuite) z[2] = uint8(m.compressionMethod) z = z[3:] if numExtensions > 0 { z[0] = byte(extensionsLength >> 8) z[1] = byte(extensionsLength) z = z[2:] } if m.nextProtoNeg { z[0] = byte(extensionNextProtoNeg >> 8) z[1] = byte(extensionNextProtoNeg) z[2] = byte(nextProtoLen >> 8) z[3] = byte(nextProtoLen) z = z[4:] for _, v := range m.nextProtos { l := len(v) if l > 255 { l = 255 } z[0] = byte(l) copy(z[1:], []byte(v[0:l])) z = z[1+l:] } } if m.ocspStapling { z[0] = byte(extensionStatusRequest >> 8) z[1] = byte(extensionStatusRequest) z = z[4:] } if m.ticketSupported { z[0] = byte(extensionSessionTicket >> 8) z[1] = byte(extensionSessionTicket) z = z[4:] } m.raw = x return x } func (m *serverHelloMsg) unmarshal(data []byte) bool { if len(data) < 42 { return false } m.raw = data m.vers = uint16(data[4])<<8 | uint16(data[5]) m.random = data[6:38] sessionIdLen := int(data[38]) if sessionIdLen > 32 || len(data) < 39+sessionIdLen { return false } m.sessionId = data[39 : 39+sessionIdLen] data = data[39+sessionIdLen:] if len(data) < 3 { return false } m.cipherSuite = uint16(data[0])<<8 | uint16(data[1]) m.compressionMethod = data[2] data = data[3:] m.nextProtoNeg = false m.nextProtos = nil m.ocspStapling = false m.ticketSupported = false if len(data) == 0 { // ServerHello is optionally followed by extension data return true } if len(data) < 2 { return false } extensionsLength := int(data[0])<<8 | int(data[1]) data = data[2:] if len(data) != extensionsLength { return false } for len(data) != 0 { if len(data) < 4 { return false } extension := uint16(data[0])<<8 | uint16(data[1]) length := int(data[2])<<8 | int(data[3]) data = data[4:] if len(data) < length { return false } switch extension { case extensionNextProtoNeg: m.nextProtoNeg = true d := data[:length] for len(d) > 0 { l := int(d[0]) d = d[1:] if l == 0 || l > len(d) { return false } m.nextProtos = append(m.nextProtos, string(d[:l])) d = d[l:] } case extensionStatusRequest: if length > 0 { return false } m.ocspStapling = true case extensionSessionTicket: if length > 0 { return false } m.ticketSupported = true } data = data[length:] } return true } type certificateMsg struct { raw []byte certificates [][]byte } func (m *certificateMsg) equal(i interface{}) bool { m1, ok := i.(*certificateMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && eqByteSlices(m.certificates, m1.certificates) } func (m *certificateMsg) marshal() (x []byte) { if m.raw != nil { return m.raw } var i int for _, slice := range m.certificates { i += len(slice) } length := 3 + 3*len(m.certificates) + i x = make([]byte, 4+length) x[0] = typeCertificate x[1] = uint8(length >> 16) x[2] = uint8(length >> 8) x[3] = uint8(length) certificateOctets := length - 3 x[4] = uint8(certificateOctets >> 16) x[5] = uint8(certificateOctets >> 8) x[6] = uint8(certificateOctets) y := x[7:] for _, slice := range m.certificates { y[0] = uint8(len(slice) >> 16) y[1] = uint8(len(slice) >> 8) y[2] = uint8(len(slice)) copy(y[3:], slice) y = y[3+len(slice):] } m.raw = x return } func (m *certificateMsg) unmarshal(data []byte) bool { if len(data) < 7 { return false } m.raw = data certsLen := uint32(data[4])<<16 | uint32(data[5])<<8 | uint32(data[6]) if uint32(len(data)) != certsLen+7 { return false } numCerts := 0 d := data[7:] for certsLen > 0 { if len(d) < 4 { return false } certLen := uint32(d[0])<<16 | uint32(d[1])<<8 | uint32(d[2]) if uint32(len(d)) < 3+certLen { return false } d = d[3+certLen:] certsLen -= 3 + certLen numCerts++ } m.certificates = make([][]byte, numCerts) d = data[7:] for i := 0; i < numCerts; i++ { certLen := uint32(d[0])<<16 | uint32(d[1])<<8 | uint32(d[2]) m.certificates[i] = d[3 : 3+certLen] d = d[3+certLen:] } return true } type serverKeyExchangeMsg struct { raw []byte key []byte } func (m *serverKeyExchangeMsg) equal(i interface{}) bool { m1, ok := i.(*serverKeyExchangeMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && bytes.Equal(m.key, m1.key) } func (m *serverKeyExchangeMsg) marshal() []byte { if m.raw != nil { return m.raw } length := len(m.key) x := make([]byte, length+4) x[0] = typeServerKeyExchange x[1] = uint8(length >> 16) x[2] = uint8(length >> 8) x[3] = uint8(length) copy(x[4:], m.key) m.raw = x return x } func (m *serverKeyExchangeMsg) unmarshal(data []byte) bool { m.raw = data if len(data) < 4 { return false } m.key = data[4:] return true } type certificateStatusMsg struct { raw []byte statusType uint8 response []byte } func (m *certificateStatusMsg) equal(i interface{}) bool { m1, ok := i.(*certificateStatusMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && m.statusType == m1.statusType && bytes.Equal(m.response, m1.response) } func (m *certificateStatusMsg) marshal() []byte { if m.raw != nil { return m.raw } var x []byte if m.statusType == statusTypeOCSP { x = make([]byte, 4+4+len(m.response)) x[0] = typeCertificateStatus l := len(m.response) + 4 x[1] = byte(l >> 16) x[2] = byte(l >> 8) x[3] = byte(l) x[4] = statusTypeOCSP l -= 4 x[5] = byte(l >> 16) x[6] = byte(l >> 8) x[7] = byte(l) copy(x[8:], m.response) } else { x = []byte{typeCertificateStatus, 0, 0, 1, m.statusType} } m.raw = x return x } func (m *certificateStatusMsg) unmarshal(data []byte) bool { m.raw = data if len(data) < 5 { return false } m.statusType = data[4] m.response = nil if m.statusType == statusTypeOCSP { if len(data) < 8 { return false } respLen := uint32(data[5])<<16 | uint32(data[6])<<8 | uint32(data[7]) if uint32(len(data)) != 4+4+respLen { return false } m.response = data[8:] } return true } type serverHelloDoneMsg struct{} func (m *serverHelloDoneMsg) equal(i interface{}) bool { _, ok := i.(*serverHelloDoneMsg) return ok } func (m *serverHelloDoneMsg) marshal() []byte { x := make([]byte, 4) x[0] = typeServerHelloDone return x } func (m *serverHelloDoneMsg) unmarshal(data []byte) bool { return len(data) == 4 } type clientKeyExchangeMsg struct { raw []byte ciphertext []byte } func (m *clientKeyExchangeMsg) equal(i interface{}) bool { m1, ok := i.(*clientKeyExchangeMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && bytes.Equal(m.ciphertext, m1.ciphertext) } func (m *clientKeyExchangeMsg) marshal() []byte { if m.raw != nil { return m.raw } length := len(m.ciphertext) x := make([]byte, length+4) x[0] = typeClientKeyExchange x[1] = uint8(length >> 16) x[2] = uint8(length >> 8) x[3] = uint8(length) copy(x[4:], m.ciphertext) m.raw = x return x } func (m *clientKeyExchangeMsg) unmarshal(data []byte) bool { m.raw = data if len(data) < 4 { return false } l := int(data[1])<<16 | int(data[2])<<8 | int(data[3]) if l != len(data)-4 { return false } m.ciphertext = data[4:] return true } type finishedMsg struct { raw []byte verifyData []byte } func (m *finishedMsg) equal(i interface{}) bool { m1, ok := i.(*finishedMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && bytes.Equal(m.verifyData, m1.verifyData) } func (m *finishedMsg) marshal() (x []byte) { if m.raw != nil { return m.raw } x = make([]byte, 4+len(m.verifyData)) x[0] = typeFinished x[3] = byte(len(m.verifyData)) copy(x[4:], m.verifyData) m.raw = x return } func (m *finishedMsg) unmarshal(data []byte) bool { m.raw = data if len(data) < 4 { return false } m.verifyData = data[4:] return true } type nextProtoMsg struct { raw []byte proto string } func (m *nextProtoMsg) equal(i interface{}) bool { m1, ok := i.(*nextProtoMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && m.proto == m1.proto } func (m *nextProtoMsg) marshal() []byte { if m.raw != nil { return m.raw } l := len(m.proto) if l > 255 { l = 255 } padding := 32 - (l+2)%32 length := l + padding + 2 x := make([]byte, length+4) x[0] = typeNextProtocol x[1] = uint8(length >> 16) x[2] = uint8(length >> 8) x[3] = uint8(length) y := x[4:] y[0] = byte(l) copy(y[1:], []byte(m.proto[0:l])) y = y[1+l:] y[0] = byte(padding) m.raw = x return x } func (m *nextProtoMsg) unmarshal(data []byte) bool { m.raw = data if len(data) < 5 { return false } data = data[4:] protoLen := int(data[0]) data = data[1:] if len(data) < protoLen { return false } m.proto = string(data[0:protoLen]) data = data[protoLen:] if len(data) < 1 { return false } paddingLen := int(data[0]) data = data[1:] if len(data) != paddingLen { return false } return true } type certificateRequestMsg struct { raw []byte // hasSignatureAndHash indicates whether this message includes a list // of signature and hash functions. This change was introduced with TLS // 1.2. hasSignatureAndHash bool certificateTypes []byte signatureAndHashes []signatureAndHash certificateAuthorities [][]byte } func (m *certificateRequestMsg) equal(i interface{}) bool { m1, ok := i.(*certificateRequestMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && bytes.Equal(m.certificateTypes, m1.certificateTypes) && eqByteSlices(m.certificateAuthorities, m1.certificateAuthorities) && eqSignatureAndHashes(m.signatureAndHashes, m1.signatureAndHashes) } func (m *certificateRequestMsg) marshal() (x []byte) { if m.raw != nil { return m.raw } // See http://tools.ietf.org/html/rfc4346#section-7.4.4 length := 1 + len(m.certificateTypes) + 2 casLength := 0 for _, ca := range m.certificateAuthorities { casLength += 2 + len(ca) } length += casLength if m.hasSignatureAndHash { length += 2 + 2*len(m.signatureAndHashes) } x = make([]byte, 4+length) x[0] = typeCertificateRequest x[1] = uint8(length >> 16) x[2] = uint8(length >> 8) x[3] = uint8(length) x[4] = uint8(len(m.certificateTypes)) copy(x[5:], m.certificateTypes) y := x[5+len(m.certificateTypes):] if m.hasSignatureAndHash { n := len(m.signatureAndHashes) * 2 y[0] = uint8(n >> 8) y[1] = uint8(n) y = y[2:] for _, sigAndHash := range m.signatureAndHashes { y[0] = sigAndHash.hash y[1] = sigAndHash.signature y = y[2:] } } y[0] = uint8(casLength >> 8) y[1] = uint8(casLength) y = y[2:] for _, ca := range m.certificateAuthorities { y[0] = uint8(len(ca) >> 8) y[1] = uint8(len(ca)) y = y[2:] copy(y, ca) y = y[len(ca):] } m.raw = x return } func (m *certificateRequestMsg) unmarshal(data []byte) bool { m.raw = data if len(data) < 5 { return false } length := uint32(data[1])<<16 | uint32(data[2])<<8 | uint32(data[3]) if uint32(len(data))-4 != length { return false } numCertTypes := int(data[4]) data = data[5:] if numCertTypes == 0 || len(data) <= numCertTypes { return false } m.certificateTypes = make([]byte, numCertTypes) if copy(m.certificateTypes, data) != numCertTypes { return false } data = data[numCertTypes:] if m.hasSignatureAndHash { if len(data) < 2 { return false } sigAndHashLen := uint16(data[0])<<8 | uint16(data[1]) data = data[2:] if sigAndHashLen&1 != 0 { return false } if len(data) < int(sigAndHashLen) { return false } numSigAndHash := sigAndHashLen / 2 m.signatureAndHashes = make([]signatureAndHash, numSigAndHash) for i := range m.signatureAndHashes { m.signatureAndHashes[i].hash = data[0] m.signatureAndHashes[i].signature = data[1] data = data[2:] } } if len(data) < 2 { return false } casLength := uint16(data[0])<<8 | uint16(data[1]) data = data[2:] if len(data) < int(casLength) { return false } cas := make([]byte, casLength) copy(cas, data) data = data[casLength:] m.certificateAuthorities = nil for len(cas) > 0 { if len(cas) < 2 { return false } caLen := uint16(cas[0])<<8 | uint16(cas[1]) cas = cas[2:] if len(cas) < int(caLen) { return false } m.certificateAuthorities = append(m.certificateAuthorities, cas[:caLen]) cas = cas[caLen:] } if len(data) > 0 { return false } return true } type certificateVerifyMsg struct { raw []byte hasSignatureAndHash bool signatureAndHash signatureAndHash signature []byte } func (m *certificateVerifyMsg) equal(i interface{}) bool { m1, ok := i.(*certificateVerifyMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && m.hasSignatureAndHash == m1.hasSignatureAndHash && m.signatureAndHash.hash == m1.signatureAndHash.hash && m.signatureAndHash.signature == m1.signatureAndHash.signature && bytes.Equal(m.signature, m1.signature) } func (m *certificateVerifyMsg) marshal() (x []byte) { if m.raw != nil { return m.raw } // See http://tools.ietf.org/html/rfc4346#section-7.4.8 siglength := len(m.signature) length := 2 + siglength if m.hasSignatureAndHash { length += 2 } x = make([]byte, 4+length) x[0] = typeCertificateVerify x[1] = uint8(length >> 16) x[2] = uint8(length >> 8) x[3] = uint8(length) y := x[4:] if m.hasSignatureAndHash { y[0] = m.signatureAndHash.hash y[1] = m.signatureAndHash.signature y = y[2:] } y[0] = uint8(siglength >> 8) y[1] = uint8(siglength) copy(y[2:], m.signature) m.raw = x return } func (m *certificateVerifyMsg) unmarshal(data []byte) bool { m.raw = data if len(data) < 6 { return false } length := uint32(data[1])<<16 | uint32(data[2])<<8 | uint32(data[3]) if uint32(len(data))-4 != length { return false } data = data[4:] if m.hasSignatureAndHash { m.signatureAndHash.hash = data[0] m.signatureAndHash.signature = data[1] data = data[2:] } if len(data) < 2 { return false } siglength := int(data[0])<<8 + int(data[1]) data = data[2:] if len(data) != siglength { return false } m.signature = data return true } type newSessionTicketMsg struct { raw []byte ticket []byte } func (m *newSessionTicketMsg) equal(i interface{}) bool { m1, ok := i.(*newSessionTicketMsg) if !ok { return false } return bytes.Equal(m.raw, m1.raw) && bytes.Equal(m.ticket, m1.ticket) } func (m *newSessionTicketMsg) marshal() (x []byte) { if m.raw != nil { return m.raw } // See http://tools.ietf.org/html/rfc5077#section-3.3 ticketLen := len(m.ticket) length := 2 + 4 + ticketLen x = make([]byte, 4+length) x[0] = typeNewSessionTicket x[1] = uint8(length >> 16) x[2] = uint8(length >> 8) x[3] = uint8(length) x[8] = uint8(ticketLen >> 8) x[9] = uint8(ticketLen) copy(x[10:], m.ticket) m.raw = x return } func (m *newSessionTicketMsg) unmarshal(data []byte) bool { m.raw = data if len(data) < 10 { return false } length := uint32(data[1])<<16 | uint32(data[2])<<8 | uint32(data[3]) if uint32(len(data))-4 != length { return false } ticketLen := int(data[8])<<8 + int(data[9]) if len(data)-10 != ticketLen { return false } m.ticket = data[10:] return true } func eqUint16s(x, y []uint16) bool { if len(x) != len(y) { return false } for i, v := range x { if y[i] != v { return false } } return true } func eqStrings(x, y []string) bool { if len(x) != len(y) { return false } for i, v := range x { if y[i] != v { return false } } return true } func eqByteSlices(x, y [][]byte) bool { if len(x) != len(y) { return false } for i, v := range x { if !bytes.Equal(v, y[i]) { return false } } return true } func eqSignatureAndHashes(x, y []signatureAndHash) bool { if len(x) != len(y) { return false } for i, v := range x { v2 := y[i] if v.hash != v2.hash || v.signature != v2.signature { return false } } return true }