package dhcpv6 import ( "errors" "fmt" "net" "strings" "github.com/insomniacslk/dhcp/iana" "github.com/u-root/u-root/pkg/uio" ) type DHCPv6 interface { Type() MessageType ToBytes() []byte String() string Summary() string IsRelay() bool // GetInnerMessage returns the innermost encapsulated DHCPv6 message. // // If it is already a message, it will be returned. If it is a relay // message, the encapsulated message will be recursively extracted. GetInnerMessage() (*Message, error) GetOption(code OptionCode) []Option GetOneOption(code OptionCode) Option AddOption(Option) UpdateOption(Option) } // Modifier defines the signature for functions that can modify DHCPv6 // structures. This is used to simplify packet manipulation type Modifier func(d DHCPv6) // MessageFromBytes parses a DHCPv6 message from a byte stream. func MessageFromBytes(data []byte) (*Message, error) { buf := uio.NewBigEndianBuffer(data) messageType := MessageType(buf.Read8()) if messageType == MessageTypeRelayForward || messageType == MessageTypeRelayReply { return nil, fmt.Errorf("wrong message type") } d := &Message{ MessageType: messageType, } buf.ReadBytes(d.TransactionID[:]) if err := d.Options.FromBytes(buf.Data()); err != nil { return nil, err } return d, nil } // RelayMessageFromBytes parses a relay message from a byte stream. func RelayMessageFromBytes(data []byte) (*RelayMessage, error) { buf := uio.NewBigEndianBuffer(data) messageType := MessageType(buf.Read8()) if messageType != MessageTypeRelayForward && messageType != MessageTypeRelayReply { return nil, fmt.Errorf("wrong message type") } d := &RelayMessage{ MessageType: messageType, HopCount: buf.Read8(), } d.LinkAddr = net.IP(buf.CopyN(net.IPv6len)) d.PeerAddr = net.IP(buf.CopyN(net.IPv6len)) // TODO: fail if no OptRelayMessage is present. if err := d.Options.FromBytes(buf.Data()); err != nil { return nil, err } return d, nil } // FromBytes reads a DHCPv6 message from a byte stream. func FromBytes(data []byte) (DHCPv6, error) { buf := uio.NewBigEndianBuffer(data) messageType := MessageType(buf.Read8()) if messageType == MessageTypeRelayForward || messageType == MessageTypeRelayReply { return RelayMessageFromBytes(data) } else { return MessageFromBytes(data) } } // NewMessage creates a new DHCPv6 message with default options func NewMessage(modifiers ...Modifier) (*Message, error) { tid, err := GenerateTransactionID() if err != nil { return nil, err } msg := &Message{ MessageType: MessageTypeSolicit, TransactionID: tid, } // apply modifiers for _, mod := range modifiers { mod(msg) } return msg, nil } // DecapsulateRelay extracts the content of a relay message. It does not recurse // if there are nested relay messages. Returns the original packet if is not not // a relay message func DecapsulateRelay(l DHCPv6) (DHCPv6, error) { if !l.IsRelay() { return l, nil } opt := l.GetOneOption(OptionRelayMsg) if opt == nil { return nil, fmt.Errorf("malformed Relay message: no OptRelayMsg found") } relayOpt := opt.(*OptRelayMsg) if relayOpt.RelayMessage() == nil { return nil, fmt.Errorf("malformed Relay message: encapsulated message is empty") } return relayOpt.RelayMessage(), nil } // DecapsulateRelayIndex extracts the content of a relay message. It takes an // integer as index (e.g. if 0 return the outermost relay, 1 returns the // second, etc, and -1 returns the last). Returns the original packet if // it is not not a relay message. func DecapsulateRelayIndex(l DHCPv6, index int) (DHCPv6, error) { if !l.IsRelay() { return l, nil } if index < -1 { return nil, fmt.Errorf("Invalid index: %d", index) } else if index == -1 { for { d, err := DecapsulateRelay(l) if err != nil { return nil, err } if !d.IsRelay() { return l, nil } l = d } } for i := 0; i <= index; i++ { d, err := DecapsulateRelay(l) if err != nil { return nil, err } l = d } return l, nil } // EncapsulateRelay creates a RelayMessage message containing the passed DHCPv6 // message as payload. The passed message type must be either RELAY_FORW or // RELAY_REPL func EncapsulateRelay(d DHCPv6, mType MessageType, linkAddr, peerAddr net.IP) (*RelayMessage, error) { if mType != MessageTypeRelayForward && mType != MessageTypeRelayReply { return nil, fmt.Errorf("Message type must be either RELAY_FORW or RELAY_REPL") } outer := RelayMessage{ MessageType: mType, LinkAddr: linkAddr, PeerAddr: peerAddr, } if d.IsRelay() { relay := d.(*RelayMessage) outer.HopCount = relay.HopCount + 1 } else { outer.HopCount = 0 } orm := OptRelayMsg{relayMessage: d} outer.AddOption(&orm) return &outer, nil } // IsUsingUEFI function takes a DHCPv6 message and returns true if // the machine trying to netboot is using UEFI of false if it is not. func IsUsingUEFI(msg *Message) bool { // RFC 4578 says: // As of the writing of this document, the following pre-boot // architecture types have been requested. // Type Architecture Name // ---- ----------------- // 0 Intel x86PC // 1 NEC/PC98 // 2 EFI Itanium // 3 DEC Alpha // 4 Arc x86 // 5 Intel Lean Client // 6 EFI IA32 // 7 EFI BC // 8 EFI Xscale // 9 EFI x86-64 if opt := msg.GetOneOption(OptionClientArchType); opt != nil { optat := opt.(*OptClientArchType) for _, at := range optat.ArchTypes { // TODO investigate if other types are appropriate if at == iana.EFI_BC || at == iana.EFI_X86_64 { return true } } } if opt := msg.GetOneOption(OptionUserClass); opt != nil { optuc := opt.(*OptUserClass) for _, uc := range optuc.UserClasses { if strings.Contains(string(uc), "EFI") { return true } } } return false } // GetTransactionID returns a transactionID of a message or its inner message // in case of relay func GetTransactionID(packet DHCPv6) (TransactionID, error) { if message, ok := packet.(*Message); ok { return message.TransactionID, nil } if relay, ok := packet.(*RelayMessage); ok { message, err := relay.GetInnerMessage() if err != nil { return TransactionID{0, 0, 0}, err } return GetTransactionID(message) } return TransactionID{0, 0, 0}, errors.New("Invalid DHCPv6 packet") }