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|
// Copyright 2021 The gVisor Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package header
import (
"encoding/binary"
"fmt"
"time"
"gvisor.dev/gvisor/pkg/tcpip"
)
// RFC 971 defines the fields of the IPv4 header on page 11 using the following
// diagram: ("Figure 4")
// 0 1 2 3
// 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// |Version| IHL |Type of Service| Total Length |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | Identification |Flags| Fragment Offset |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | Time to Live | Protocol | Header Checksum |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | Source Address |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | Destination Address |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// | Options | Padding |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
const (
versIHL = 0
tos = 1
// IPv4TotalLenOffset is the offset of the total length field in the
// IPv4 header.
IPv4TotalLenOffset = 2
id = 4
flagsFO = 6
ttl = 8
protocol = 9
checksum = 10
srcAddr = 12
dstAddr = 16
options = 20
)
// IPv4Fields contains the fields of an IPv4 packet. It is used to describe the
// fields of a packet that needs to be encoded. The IHL field is not here as
// it is totally defined by the size of the options.
type IPv4Fields struct {
// TOS is the "type of service" field of an IPv4 packet.
TOS uint8
// TotalLength is the "total length" field of an IPv4 packet.
TotalLength uint16
// ID is the "identification" field of an IPv4 packet.
ID uint16
// Flags is the "flags" field of an IPv4 packet.
Flags uint8
// FragmentOffset is the "fragment offset" field of an IPv4 packet.
FragmentOffset uint16
// TTL is the "time to live" field of an IPv4 packet.
TTL uint8
// Protocol is the "protocol" field of an IPv4 packet.
Protocol uint8
// Checksum is the "checksum" field of an IPv4 packet.
Checksum uint16
// SrcAddr is the "source ip address" of an IPv4 packet.
SrcAddr tcpip.Address
// DstAddr is the "destination ip address" of an IPv4 packet.
DstAddr tcpip.Address
// Options must be 40 bytes or less as they must fit along with the
// rest of the IPv4 header into the maximum size describable in the
// IHL field. RFC 791 section 3.1 says:
// IHL: 4 bits
//
// Internet Header Length is the length of the internet header in 32
// bit words, and thus points to the beginning of the data. Note that
// the minimum value for a correct header is 5.
//
// That leaves ten 32 bit (4 byte) fields for options. An attempt to encode
// more will fail.
Options IPv4OptionsSerializer
}
// IPv4 is an IPv4 header.
// Most of the methods of IPv4 access to the underlying slice without
// checking the boundaries and could panic because of 'index out of range'.
// Always call IsValid() to validate an instance of IPv4 before using other
// methods.
type IPv4 []byte
const (
// IPv4MinimumSize is the minimum size of a valid IPv4 packet;
// i.e. a packet header with no options.
IPv4MinimumSize = 20
// IPv4MaximumHeaderSize is the maximum size of an IPv4 header. Given
// that there are only 4 bits (max 0xF (15)) to represent the header length
// in 32-bit (4 byte) units, the header cannot exceed 15*4 = 60 bytes.
IPv4MaximumHeaderSize = 60
// IPv4MaximumOptionsSize is the largest size the IPv4 options can be.
IPv4MaximumOptionsSize = IPv4MaximumHeaderSize - IPv4MinimumSize
// IPv4MaximumPayloadSize is the maximum size of a valid IPv4 payload.
//
// Linux limits this to 65,515 octets (the max IP datagram size - the IPv4
// header size). But RFC 791 section 3.2 discusses the design of the IPv4
// fragment "allows 2**13 = 8192 fragments of 8 octets each for a total of
// 65,536 octets. Note that this is consistent with the datagram total
// length field (of course, the header is counted in the total length and not
// in the fragments)."
IPv4MaximumPayloadSize = 65536
// MinIPFragmentPayloadSize is the minimum number of payload bytes that
// the first fragment must carry when an IPv4 packet is fragmented.
MinIPFragmentPayloadSize = 8
// IPv4AddressSize is the size, in bytes, of an IPv4 address.
IPv4AddressSize = 4
// IPv4ProtocolNumber is IPv4's network protocol number.
IPv4ProtocolNumber tcpip.NetworkProtocolNumber = 0x0800
// IPv4Version is the version of the IPv4 protocol.
IPv4Version = 4
// IPv4AllSystems is the all systems IPv4 multicast address as per
// IANA's IPv4 Multicast Address Space Registry. See
// https://www.iana.org/assignments/multicast-addresses/multicast-addresses.xhtml.
IPv4AllSystems tcpip.Address = "\xe0\x00\x00\x01"
// IPv4Broadcast is the broadcast address of the IPv4 procotol.
IPv4Broadcast tcpip.Address = "\xff\xff\xff\xff"
// IPv4Any is the non-routable IPv4 "any" meta address.
IPv4Any tcpip.Address = "\x00\x00\x00\x00"
// IPv4AllRoutersGroup is a multicast address for all routers.
IPv4AllRoutersGroup tcpip.Address = "\xe0\x00\x00\x02"
// IPv4MinimumProcessableDatagramSize is the minimum size of an IP
// packet that every IPv4 capable host must be able to
// process/reassemble.
IPv4MinimumProcessableDatagramSize = 576
// IPv4MinimumMTU is the minimum MTU required by IPv4, per RFC 791,
// section 3.2:
// Every internet module must be able to forward a datagram of 68 octets
// without further fragmentation. This is because an internet header may be
// up to 60 octets, and the minimum fragment is 8 octets.
IPv4MinimumMTU = 68
)
// Flags that may be set in an IPv4 packet.
const (
IPv4FlagMoreFragments = 1 << iota
IPv4FlagDontFragment
)
// ipv4LinkLocalUnicastSubnet is the IPv4 link local unicast subnet as defined
// by RFC 3927 section 1.
var ipv4LinkLocalUnicastSubnet = func() tcpip.Subnet {
subnet, err := tcpip.NewSubnet("\xa9\xfe\x00\x00", "\xff\xff\x00\x00")
if err != nil {
panic(err)
}
return subnet
}()
// ipv4LinkLocalMulticastSubnet is the IPv4 link local multicast subnet as
// defined by RFC 5771 section 4.
var ipv4LinkLocalMulticastSubnet = func() tcpip.Subnet {
subnet, err := tcpip.NewSubnet("\xe0\x00\x00\x00", "\xff\xff\xff\x00")
if err != nil {
panic(err)
}
return subnet
}()
// IPv4EmptySubnet is the empty IPv4 subnet.
var IPv4EmptySubnet = func() tcpip.Subnet {
subnet, err := tcpip.NewSubnet(IPv4Any, tcpip.AddressMask(IPv4Any))
if err != nil {
panic(err)
}
return subnet
}()
// IPv4LoopbackSubnet is the loopback subnet for IPv4.
var IPv4LoopbackSubnet = func() tcpip.Subnet {
subnet, err := tcpip.NewSubnet(tcpip.Address("\x7f\x00\x00\x00"), tcpip.AddressMask("\xff\x00\x00\x00"))
if err != nil {
panic(err)
}
return subnet
}()
// IPVersion returns the version of IP used in the given packet. It returns -1
// if the packet is not large enough to contain the version field.
func IPVersion(b []byte) int {
// Length must be at least offset+length of version field.
if len(b) < versIHL+1 {
return -1
}
return int(b[versIHL] >> ipVersionShift)
}
// RFC 791 page 11 shows the header length (IHL) is in the lower 4 bits
// of the first byte, and is counted in multiples of 4 bytes.
//
// 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// |Version| IHL |Type of Service| Total Length |
// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// (...)
// Version: 4 bits
// The Version field indicates the format of the internet header. This
// document describes version 4.
//
// IHL: 4 bits
// Internet Header Length is the length of the internet header in 32
// bit words, and thus points to the beginning of the data. Note that
// the minimum value for a correct header is 5.
const (
ipVersionShift = 4
ipIHLMask = 0x0f
IPv4IHLStride = 4
)
// HeaderLength returns the value of the "header length" field of the IPv4
// header. The length returned is in bytes.
func (b IPv4) HeaderLength() uint8 {
return (b[versIHL] & ipIHLMask) * IPv4IHLStride
}
// SetHeaderLength sets the value of the "Internet Header Length" field.
func (b IPv4) SetHeaderLength(hdrLen uint8) {
if hdrLen > IPv4MaximumHeaderSize {
panic(fmt.Sprintf("got IPv4 Header size = %d, want <= %d", hdrLen, IPv4MaximumHeaderSize))
}
b[versIHL] = (IPv4Version << ipVersionShift) | ((hdrLen / IPv4IHLStride) & ipIHLMask)
}
// ID returns the value of the identifier field of the IPv4 header.
func (b IPv4) ID() uint16 {
return binary.BigEndian.Uint16(b[id:])
}
// Protocol returns the value of the protocol field of the IPv4 header.
func (b IPv4) Protocol() uint8 {
return b[protocol]
}
// Flags returns the "flags" field of the IPv4 header.
func (b IPv4) Flags() uint8 {
return uint8(binary.BigEndian.Uint16(b[flagsFO:]) >> 13)
}
// More returns whether the more fragments flag is set.
func (b IPv4) More() bool {
return b.Flags()&IPv4FlagMoreFragments != 0
}
// TTL returns the "TTL" field of the IPv4 header.
func (b IPv4) TTL() uint8 {
return b[ttl]
}
// FragmentOffset returns the "fragment offset" field of the IPv4 header.
func (b IPv4) FragmentOffset() uint16 {
return binary.BigEndian.Uint16(b[flagsFO:]) << 3
}
// TotalLength returns the "total length" field of the IPv4 header.
func (b IPv4) TotalLength() uint16 {
return binary.BigEndian.Uint16(b[IPv4TotalLenOffset:])
}
// Checksum returns the checksum field of the IPv4 header.
func (b IPv4) Checksum() uint16 {
return binary.BigEndian.Uint16(b[checksum:])
}
// SourceAddress returns the "source address" field of the IPv4 header.
func (b IPv4) SourceAddress() tcpip.Address {
return tcpip.Address(b[srcAddr : srcAddr+IPv4AddressSize])
}
// DestinationAddress returns the "destination address" field of the IPv4
// header.
func (b IPv4) DestinationAddress() tcpip.Address {
return tcpip.Address(b[dstAddr : dstAddr+IPv4AddressSize])
}
// SetSourceAddressWithChecksumUpdate implements ChecksummableNetwork.
func (b IPv4) SetSourceAddressWithChecksumUpdate(new tcpip.Address) {
b.SetChecksum(^checksumUpdate2ByteAlignedAddress(^b.Checksum(), b.SourceAddress(), new))
b.SetSourceAddress(new)
}
// SetDestinationAddressWithChecksumUpdate implements ChecksummableNetwork.
func (b IPv4) SetDestinationAddressWithChecksumUpdate(new tcpip.Address) {
b.SetChecksum(^checksumUpdate2ByteAlignedAddress(^b.Checksum(), b.DestinationAddress(), new))
b.SetDestinationAddress(new)
}
// padIPv4OptionsLength returns the total length for IPv4 options of length l
// after applying padding according to RFC 791:
// The internet header padding is used to ensure that the internet
// header ends on a 32 bit boundary.
func padIPv4OptionsLength(length uint8) uint8 {
return (length + IPv4IHLStride - 1) & ^uint8(IPv4IHLStride-1)
}
// IPv4Options is a buffer that holds all the raw IP options.
type IPv4Options []byte
// Options returns a buffer holding the options.
func (b IPv4) Options() IPv4Options {
hdrLen := b.HeaderLength()
return IPv4Options(b[options:hdrLen:hdrLen])
}
// TransportProtocol implements Network.TransportProtocol.
func (b IPv4) TransportProtocol() tcpip.TransportProtocolNumber {
return tcpip.TransportProtocolNumber(b.Protocol())
}
// Payload implements Network.Payload.
func (b IPv4) Payload() []byte {
return b[b.HeaderLength():][:b.PayloadLength()]
}
// PayloadLength returns the length of the payload portion of the IPv4 packet.
func (b IPv4) PayloadLength() uint16 {
return b.TotalLength() - uint16(b.HeaderLength())
}
// TOS returns the "type of service" field of the IPv4 header.
func (b IPv4) TOS() (uint8, uint32) {
return b[tos], 0
}
// SetTOS sets the "type of service" field of the IPv4 header.
func (b IPv4) SetTOS(v uint8, _ uint32) {
b[tos] = v
}
// SetTTL sets the "Time to Live" field of the IPv4 header.
func (b IPv4) SetTTL(v byte) {
b[ttl] = v
}
// SetTotalLength sets the "total length" field of the IPv4 header.
func (b IPv4) SetTotalLength(totalLength uint16) {
binary.BigEndian.PutUint16(b[IPv4TotalLenOffset:], totalLength)
}
// SetChecksum sets the checksum field of the IPv4 header.
func (b IPv4) SetChecksum(v uint16) {
binary.BigEndian.PutUint16(b[checksum:], v)
}
// SetFlagsFragmentOffset sets the "flags" and "fragment offset" fields of the
// IPv4 header.
func (b IPv4) SetFlagsFragmentOffset(flags uint8, offset uint16) {
v := (uint16(flags) << 13) | (offset >> 3)
binary.BigEndian.PutUint16(b[flagsFO:], v)
}
// SetID sets the identification field.
func (b IPv4) SetID(v uint16) {
binary.BigEndian.PutUint16(b[id:], v)
}
// SetSourceAddress sets the "source address" field of the IPv4 header.
func (b IPv4) SetSourceAddress(addr tcpip.Address) {
copy(b[srcAddr:srcAddr+IPv4AddressSize], addr)
}
// SetDestinationAddress sets the "destination address" field of the IPv4
// header.
func (b IPv4) SetDestinationAddress(addr tcpip.Address) {
copy(b[dstAddr:dstAddr+IPv4AddressSize], addr)
}
// CalculateChecksum calculates the checksum of the IPv4 header.
func (b IPv4) CalculateChecksum() uint16 {
return Checksum(b[:b.HeaderLength()], 0)
}
// Encode encodes all the fields of the IPv4 header.
func (b IPv4) Encode(i *IPv4Fields) {
// The size of the options defines the size of the whole header and thus the
// IHL field. Options are rare and this is a heavily used function so it is
// worth a bit of optimisation here to keep the serializer out of the fast
// path.
hdrLen := uint8(IPv4MinimumSize)
if len(i.Options) != 0 {
hdrLen += i.Options.Serialize(b[options:])
}
if hdrLen > IPv4MaximumHeaderSize {
panic(fmt.Sprintf("%d is larger than maximum IPv4 header size of %d", hdrLen, IPv4MaximumHeaderSize))
}
b.SetHeaderLength(hdrLen)
b[tos] = i.TOS
b.SetTotalLength(i.TotalLength)
binary.BigEndian.PutUint16(b[id:], i.ID)
b.SetFlagsFragmentOffset(i.Flags, i.FragmentOffset)
b[ttl] = i.TTL
b[protocol] = i.Protocol
b.SetChecksum(i.Checksum)
copy(b[srcAddr:srcAddr+IPv4AddressSize], i.SrcAddr)
copy(b[dstAddr:dstAddr+IPv4AddressSize], i.DstAddr)
}
// EncodePartial updates the total length and checksum fields of IPv4 header,
// taking in the partial checksum, which is the checksum of the header without
// the total length and checksum fields. It is useful in cases when similar
// packets are produced.
func (b IPv4) EncodePartial(partialChecksum, totalLength uint16) {
b.SetTotalLength(totalLength)
checksum := Checksum(b[IPv4TotalLenOffset:IPv4TotalLenOffset+2], partialChecksum)
b.SetChecksum(^checksum)
}
// IsValid performs basic validation on the packet.
func (b IPv4) IsValid(pktSize int) bool {
if len(b) < IPv4MinimumSize {
return false
}
hlen := int(b.HeaderLength())
tlen := int(b.TotalLength())
if hlen < IPv4MinimumSize || hlen > tlen || tlen > pktSize {
return false
}
if IPVersion(b) != IPv4Version {
return false
}
return true
}
// IsV4LinkLocalUnicastAddress determines if the provided address is an IPv4
// link-local unicast address.
func IsV4LinkLocalUnicastAddress(addr tcpip.Address) bool {
return ipv4LinkLocalUnicastSubnet.Contains(addr)
}
// IsV4LinkLocalMulticastAddress determines if the provided address is an IPv4
// link-local multicast address.
func IsV4LinkLocalMulticastAddress(addr tcpip.Address) bool {
return ipv4LinkLocalMulticastSubnet.Contains(addr)
}
// IsChecksumValid returns true iff the IPv4 header's checksum is valid.
func (b IPv4) IsChecksumValid() bool {
// There has been some confusion regarding verifying checksums. We need
// just look for negative 0 (0xffff) as the checksum, as it's not possible to
// get positive 0 (0) for the checksum. Some bad implementations could get it
// when doing entry replacement in the early days of the Internet,
// however the lore that one needs to check for both persists.
//
// RFC 1624 section 1 describes the source of this confusion as:
// [the partial recalculation method described in RFC 1071] computes a
// result for certain cases that differs from the one obtained from
// scratch (one's complement of one's complement sum of the original
// fields).
//
// However RFC 1624 section 5 clarifies that if using the verification method
// "recommended by RFC 1071, it does not matter if an intermediate system
// generated a -0 instead of +0".
//
// RFC1071 page 1 specifies the verification method as:
// (3) To check a checksum, the 1's complement sum is computed over the
// same set of octets, including the checksum field. If the result
// is all 1 bits (-0 in 1's complement arithmetic), the check
// succeeds.
return b.CalculateChecksum() == 0xffff
}
// IsV4MulticastAddress determines if the provided address is an IPv4 multicast
// address (range 224.0.0.0 to 239.255.255.255). The four most significant bits
// will be 1110 = 0xe0.
func IsV4MulticastAddress(addr tcpip.Address) bool {
if len(addr) != IPv4AddressSize {
return false
}
return (addr[0] & 0xf0) == 0xe0
}
// IsV4LoopbackAddress determines if the provided address is an IPv4 loopback
// address (belongs to 127.0.0.0/8 subnet). See RFC 1122 section 3.2.1.3.
func IsV4LoopbackAddress(addr tcpip.Address) bool {
if len(addr) != IPv4AddressSize {
return false
}
return addr[0] == 0x7f
}
// ========================= Options ==========================
// An IPv4OptionType can hold the valuse for the Type in an IPv4 option.
type IPv4OptionType byte
// These constants are needed to identify individual options in the option list.
// While RFC 791 (page 31) says "Every internet module must be able to act on
// every option." This has not generally been adhered to and some options have
// very low rates of support. We do not support options other than those shown
// below.
const (
// IPv4OptionListEndType is the option type for the End Of Option List
// option. Anything following is ignored.
IPv4OptionListEndType IPv4OptionType = 0
// IPv4OptionNOPType is the No-Operation option. May appear between other
// options and may appear multiple times.
IPv4OptionNOPType IPv4OptionType = 1
// IPv4OptionRouterAlertType is the option type for the Router Alert option,
// defined in RFC 2113 Section 2.1.
IPv4OptionRouterAlertType IPv4OptionType = 20 | 0x80
// IPv4OptionRecordRouteType is used by each router on the path of the packet
// to record its path. It is carried over to an Echo Reply.
IPv4OptionRecordRouteType IPv4OptionType = 7
// IPv4OptionTimestampType is the option type for the Timestamp option.
IPv4OptionTimestampType IPv4OptionType = 68
// ipv4OptionTypeOffset is the offset in an option of its type field.
ipv4OptionTypeOffset = 0
// IPv4OptionLengthOffset is the offset in an option of its length field.
IPv4OptionLengthOffset = 1
)
// IPv4OptParameterProblem indicates that a Parameter Problem message
// should be generated, and gives the offset in the current entity
// that should be used in that packet.
type IPv4OptParameterProblem struct {
Pointer uint8
NeedICMP bool
}
// IPv4Option is an interface representing various option types.
type IPv4Option interface {
// Type returns the type identifier of the option.
Type() IPv4OptionType
// Size returns the size of the option in bytes.
Size() uint8
// Contents returns a slice holding the contents of the option.
Contents() []byte
}
var _ IPv4Option = (*IPv4OptionGeneric)(nil)
// IPv4OptionGeneric is an IPv4 Option of unknown type.
type IPv4OptionGeneric []byte
// Type implements IPv4Option.
func (o *IPv4OptionGeneric) Type() IPv4OptionType {
return IPv4OptionType((*o)[ipv4OptionTypeOffset])
}
// Size implements IPv4Option.
func (o *IPv4OptionGeneric) Size() uint8 { return uint8(len(*o)) }
// Contents implements IPv4Option.
func (o *IPv4OptionGeneric) Contents() []byte { return *o }
// IPv4OptionIterator is an iterator pointing to a specific IP option
// at any point of time. It also holds information as to a new options buffer
// that we are building up to hand back to the caller.
// TODO(https://gvisor.dev/issues/5513): Add unit tests for IPv4OptionIterator.
type IPv4OptionIterator struct {
options IPv4Options
// ErrCursor is where we are while parsing options. It is exported as any
// resulting ICMP packet is supposed to have a pointer to the byte within
// the IP packet where the error was detected.
ErrCursor uint8
nextErrCursor uint8
newOptions [IPv4MaximumOptionsSize]byte
writePoint int
}
// MakeIterator sets up and returns an iterator of options. It also sets up the
// building of a new option set.
func (o IPv4Options) MakeIterator() IPv4OptionIterator {
return IPv4OptionIterator{
options: o,
nextErrCursor: IPv4MinimumSize,
}
}
// InitReplacement copies the option into the new option buffer.
func (i *IPv4OptionIterator) InitReplacement(option IPv4Option) IPv4Options {
replacementOption := i.RemainingBuffer()[:option.Size()]
if copied := copy(replacementOption, option.Contents()); copied != len(replacementOption) {
panic(fmt.Sprintf("copied %d bytes in the replacement option buffer, expected %d bytes", copied, len(replacementOption)))
}
return replacementOption
}
// RemainingBuffer returns the remaining (unused) part of the new option buffer,
// into which a new option may be written.
func (i *IPv4OptionIterator) RemainingBuffer() IPv4Options {
return i.newOptions[i.writePoint:]
}
// ConsumeBuffer marks a portion of the new buffer as used.
func (i *IPv4OptionIterator) ConsumeBuffer(size int) {
i.writePoint += size
}
// PushNOPOrEnd puts one of the single byte options onto the new options.
// Only values 0 or 1 (ListEnd or NOP) are valid input.
func (i *IPv4OptionIterator) PushNOPOrEnd(val IPv4OptionType) {
if val > IPv4OptionNOPType {
panic(fmt.Sprintf("invalid option type %d pushed onto option build buffer", val))
}
i.newOptions[i.writePoint] = byte(val)
i.writePoint++
}
// Finalize returns the completed replacement options buffer padded
// as needed.
func (i *IPv4OptionIterator) Finalize() IPv4Options {
// RFC 791 page 31 says:
// The options might not end on a 32-bit boundary. The internet header
// must be filled out with octets of zeros. The first of these would
// be interpreted as the end-of-options option, and the remainder as
// internet header padding.
// Since the buffer is already zero filled we just need to step the write
// pointer up to the next multiple of 4.
options := IPv4Options(i.newOptions[:(i.writePoint+0x3) & ^0x3])
// Poison the write pointer.
i.writePoint = len(i.newOptions)
return options
}
// Next returns the next IP option in the buffer/list of IP options.
// It returns
// - A slice of bytes holding the next option or nil if there is error.
// - A boolean which is true if parsing of all the options is complete.
// Undefined in the case of error.
// - An error indication which is non-nil if an error condition was found.
func (i *IPv4OptionIterator) Next() (IPv4Option, bool, *IPv4OptParameterProblem) {
// The opts slice gets shorter as we process the options. When we have no
// bytes left we are done.
if len(i.options) == 0 {
return nil, true, nil
}
i.ErrCursor = i.nextErrCursor
optType := IPv4OptionType(i.options[ipv4OptionTypeOffset])
if optType == IPv4OptionNOPType || optType == IPv4OptionListEndType {
optionBody := i.options[:1]
i.options = i.options[1:]
i.nextErrCursor = i.ErrCursor + 1
retval := IPv4OptionGeneric(optionBody)
return &retval, false, nil
}
// There are no more single byte options defined. All the rest have a length
// field so we need to sanity check it.
if len(i.options) == 1 {
return nil, false, &IPv4OptParameterProblem{
Pointer: i.ErrCursor,
NeedICMP: true,
}
}
optLen := i.options[IPv4OptionLengthOffset]
if optLen <= IPv4OptionLengthOffset || optLen > uint8(len(i.options)) {
// The actual error is in the length (2nd byte of the option) but we
// return the start of the option for compatibility with Linux.
return nil, false, &IPv4OptParameterProblem{
Pointer: i.ErrCursor,
NeedICMP: true,
}
}
optionBody := i.options[:optLen]
i.nextErrCursor = i.ErrCursor + optLen
i.options = i.options[optLen:]
// Check the length of some option types that we know.
switch optType {
case IPv4OptionTimestampType:
if optLen < IPv4OptionTimestampHdrLength {
i.ErrCursor++
return nil, false, &IPv4OptParameterProblem{
Pointer: i.ErrCursor,
NeedICMP: true,
}
}
retval := IPv4OptionTimestamp(optionBody)
return &retval, false, nil
case IPv4OptionRecordRouteType:
if optLen < IPv4OptionRecordRouteHdrLength {
i.ErrCursor++
return nil, false, &IPv4OptParameterProblem{
Pointer: i.ErrCursor,
NeedICMP: true,
}
}
retval := IPv4OptionRecordRoute(optionBody)
return &retval, false, nil
case IPv4OptionRouterAlertType:
if optLen != IPv4OptionRouterAlertLength {
i.ErrCursor++
return nil, false, &IPv4OptParameterProblem{
Pointer: i.ErrCursor,
NeedICMP: true,
}
}
retval := IPv4OptionRouterAlert(optionBody)
return &retval, false, nil
}
retval := IPv4OptionGeneric(optionBody)
return &retval, false, nil
}
//
// IP Timestamp option - RFC 791 page 22.
// +--------+--------+--------+--------+
// |01000100| length | pointer|oflw|flg|
// +--------+--------+--------+--------+
// | internet address |
// +--------+--------+--------+--------+
// | timestamp |
// +--------+--------+--------+--------+
// | ... |
//
// Type = 68
//
// The Option Length is the number of octets in the option counting
// the type, length, pointer, and overflow/flag octets (maximum
// length 40).
//
// The Pointer is the number of octets from the beginning of this
// option to the end of timestamps plus one (i.e., it points to the
// octet beginning the space for next timestamp). The smallest
// legal value is 5. The timestamp area is full when the pointer
// is greater than the length.
//
// The Overflow (oflw) [4 bits] is the number of IP modules that
// cannot register timestamps due to lack of space.
//
// The Flag (flg) [4 bits] values are
//
// 0 -- time stamps only, stored in consecutive 32-bit words,
//
// 1 -- each timestamp is preceded with internet address of the
// registering entity,
//
// 3 -- the internet address fields are prespecified. An IP
// module only registers its timestamp if it matches its own
// address with the next specified internet address.
//
// Timestamps are defined in RFC 791 page 22 as milliseconds since midnight UTC.
//
// The Timestamp is a right-justified, 32-bit timestamp in
// milliseconds since midnight UT. If the time is not available in
// milliseconds or cannot be provided with respect to midnight UT
// then any time may be inserted as a timestamp provided the high
// order bit of the timestamp field is set to one to indicate the
// use of a non-standard value.
// IPv4OptTSFlags sefines the values expected in the Timestamp
// option Flags field.
type IPv4OptTSFlags uint8
//
// Timestamp option specific related constants.
const (
// IPv4OptionTimestampHdrLength is the length of the timestamp option header.
IPv4OptionTimestampHdrLength = 4
// IPv4OptionTimestampSize is the size of an IP timestamp.
IPv4OptionTimestampSize = 4
// IPv4OptionTimestampWithAddrSize is the size of an IP timestamp + Address.
IPv4OptionTimestampWithAddrSize = IPv4AddressSize + IPv4OptionTimestampSize
// IPv4OptionTimestampMaxSize is limited by space for options
IPv4OptionTimestampMaxSize = IPv4MaximumOptionsSize
// IPv4OptionTimestampOnlyFlag is a flag indicating that only timestamp
// is present.
IPv4OptionTimestampOnlyFlag IPv4OptTSFlags = 0
// IPv4OptionTimestampWithIPFlag is a flag indicating that both timestamps and
// IP are present.
IPv4OptionTimestampWithIPFlag IPv4OptTSFlags = 1
// IPv4OptionTimestampWithPredefinedIPFlag is a flag indicating that
// predefined IP is present.
IPv4OptionTimestampWithPredefinedIPFlag IPv4OptTSFlags = 3
)
// ipv4TimestampTime provides the current time as specified in RFC 791.
func ipv4TimestampTime(clock tcpip.Clock) uint32 {
// Per RFC 791 page 21:
// The Timestamp is a right-justified, 32-bit timestamp in
// milliseconds since midnight UT.
now := clock.Now().UTC()
midnight := now.Truncate(24 * time.Hour)
return uint32(now.Sub(midnight).Milliseconds())
}
// IP Timestamp option fields.
const (
// IPv4OptTSPointerOffset is the offset of the Timestamp pointer field.
IPv4OptTSPointerOffset = 2
// IPv4OptTSPointerOffset is the offset of the combined Flag and Overflow
// fields, (each being 4 bits).
IPv4OptTSOFLWAndFLGOffset = 3
// These constants define the sub byte fields of the Flag and OverFlow field.
ipv4OptionTimestampOverflowshift = 4
ipv4OptionTimestampFlagsMask byte = 0x0f
)
var _ IPv4Option = (*IPv4OptionTimestamp)(nil)
// IPv4OptionTimestamp is a Timestamp option from RFC 791.
type IPv4OptionTimestamp []byte
// Type implements IPv4Option.Type().
func (ts *IPv4OptionTimestamp) Type() IPv4OptionType { return IPv4OptionTimestampType }
// Size implements IPv4Option.
func (ts *IPv4OptionTimestamp) Size() uint8 { return uint8(len(*ts)) }
// Contents implements IPv4Option.
func (ts *IPv4OptionTimestamp) Contents() []byte { return *ts }
// Pointer returns the pointer field in the IP Timestamp option.
func (ts *IPv4OptionTimestamp) Pointer() uint8 {
return (*ts)[IPv4OptTSPointerOffset]
}
// Flags returns the flags field in the IP Timestamp option.
func (ts *IPv4OptionTimestamp) Flags() IPv4OptTSFlags {
return IPv4OptTSFlags((*ts)[IPv4OptTSOFLWAndFLGOffset] & ipv4OptionTimestampFlagsMask)
}
// Overflow returns the Overflow field in the IP Timestamp option.
func (ts *IPv4OptionTimestamp) Overflow() uint8 {
return (*ts)[IPv4OptTSOFLWAndFLGOffset] >> ipv4OptionTimestampOverflowshift
}
// IncOverflow increments the Overflow field in the IP Timestamp option. It
// returns the incremented value. If the return value is 0 then the field
// overflowed.
func (ts *IPv4OptionTimestamp) IncOverflow() uint8 {
(*ts)[IPv4OptTSOFLWAndFLGOffset] += 1 << ipv4OptionTimestampOverflowshift
return ts.Overflow()
}
// UpdateTimestamp updates the fields of the next free timestamp slot.
func (ts *IPv4OptionTimestamp) UpdateTimestamp(addr tcpip.Address, clock tcpip.Clock) {
slot := (*ts)[ts.Pointer()-1:]
switch ts.Flags() {
case IPv4OptionTimestampOnlyFlag:
binary.BigEndian.PutUint32(slot, ipv4TimestampTime(clock))
(*ts)[IPv4OptTSPointerOffset] += IPv4OptionTimestampSize
case IPv4OptionTimestampWithIPFlag:
if n := copy(slot, addr); n != IPv4AddressSize {
panic(fmt.Sprintf("copied %d bytes, expected %d bytes", n, IPv4AddressSize))
}
binary.BigEndian.PutUint32(slot[IPv4AddressSize:], ipv4TimestampTime(clock))
(*ts)[IPv4OptTSPointerOffset] += IPv4OptionTimestampWithAddrSize
case IPv4OptionTimestampWithPredefinedIPFlag:
if tcpip.Address(slot[:IPv4AddressSize]) == addr {
binary.BigEndian.PutUint32(slot[IPv4AddressSize:], ipv4TimestampTime(clock))
(*ts)[IPv4OptTSPointerOffset] += IPv4OptionTimestampWithAddrSize
}
}
}
// RecordRoute option specific related constants.
//
// from RFC 791 page 20:
// Record Route
//
// +--------+--------+--------+---------//--------+
// |00000111| length | pointer| route data |
// +--------+--------+--------+---------//--------+
// Type=7
//
// The record route option provides a means to record the route of
// an internet datagram.
//
// The option begins with the option type code. The second octet
// is the option length which includes the option type code and the
// length octet, the pointer octet, and length-3 octets of route
// data. The third octet is the pointer into the route data
// indicating the octet which begins the next area to store a route
// address. The pointer is relative to this option, and the
// smallest legal value for the pointer is 4.
const (
// IPv4OptionRecordRouteHdrLength is the length of the Record Route option
// header.
IPv4OptionRecordRouteHdrLength = 3
// IPv4OptRRPointerOffset is the offset to the pointer field in an RR
// option, which points to the next free slot in the list of addresses.
IPv4OptRRPointerOffset = 2
)
var _ IPv4Option = (*IPv4OptionRecordRoute)(nil)
// IPv4OptionRecordRoute is an IPv4 RecordRoute option defined by RFC 791.
type IPv4OptionRecordRoute []byte
// Pointer returns the pointer field in the IP RecordRoute option.
func (rr *IPv4OptionRecordRoute) Pointer() uint8 {
return (*rr)[IPv4OptRRPointerOffset]
}
// StoreAddress stores the given IPv4 address into the next free slot.
func (rr *IPv4OptionRecordRoute) StoreAddress(addr tcpip.Address) {
start := rr.Pointer() - 1 // A one based number.
// start and room checked by caller.
if n := copy((*rr)[start:], addr); n != IPv4AddressSize {
panic(fmt.Sprintf("copied %d bytes, expected %d bytes", n, IPv4AddressSize))
}
(*rr)[IPv4OptRRPointerOffset] += IPv4AddressSize
}
// Type implements IPv4Option.
func (rr *IPv4OptionRecordRoute) Type() IPv4OptionType { return IPv4OptionRecordRouteType }
// Size implements IPv4Option.
func (rr *IPv4OptionRecordRoute) Size() uint8 { return uint8(len(*rr)) }
// Contents implements IPv4Option.
func (rr *IPv4OptionRecordRoute) Contents() []byte { return *rr }
// Router Alert option specific related constants.
//
// from RFC 2113 section 2.1:
//
// +--------+--------+--------+--------+
// |10010100|00000100| 2 octet value |
// +--------+--------+--------+--------+
//
// Type:
// Copied flag: 1 (all fragments must carry the option)
// Option class: 0 (control)
// Option number: 20 (decimal)
//
// Length: 4
//
// Value: A two octet code with the following values:
// 0 - Router shall examine packet
// 1-65535 - Reserved
const (
// IPv4OptionRouterAlertLength is the length of a Router Alert option.
IPv4OptionRouterAlertLength = 4
// IPv4OptionRouterAlertValue is the only permissible value of the 16 bit
// payload of the router alert option.
IPv4OptionRouterAlertValue = 0
// IPv4OptionRouterAlertValueOffset is the offset for the value of a
// RouterAlert option.
IPv4OptionRouterAlertValueOffset = 2
)
var _ IPv4Option = (*IPv4OptionRouterAlert)(nil)
// IPv4OptionRouterAlert is an IPv4 RouterAlert option defined by RFC 2113.
type IPv4OptionRouterAlert []byte
// Type implements IPv4Option.
func (*IPv4OptionRouterAlert) Type() IPv4OptionType { return IPv4OptionRouterAlertType }
// Size implements IPv4Option.
func (ra *IPv4OptionRouterAlert) Size() uint8 { return uint8(len(*ra)) }
// Contents implements IPv4Option.
func (ra *IPv4OptionRouterAlert) Contents() []byte { return *ra }
// Value returns the value of the IPv4OptionRouterAlert.
func (ra *IPv4OptionRouterAlert) Value() uint16 {
return binary.BigEndian.Uint16(ra.Contents()[IPv4OptionRouterAlertValueOffset:])
}
// IPv4SerializableOption is an interface to represent serializable IPv4 option
// types.
type IPv4SerializableOption interface {
// optionType returns the type identifier of the option.
optionType() IPv4OptionType
}
// IPv4SerializableOptionPayload is an interface providing serialization of the
// payload of an IPv4 option.
type IPv4SerializableOptionPayload interface {
// length returns the size of the payload.
length() uint8
// serializeInto serializes the payload into the provided byte buffer.
//
// Note, the caller MUST provide a byte buffer with size of at least
// Length. Implementers of this function may assume that the byte buffer
// is of sufficient size. serializeInto MUST panic if the provided byte
// buffer is not of sufficient size.
//
// serializeInto will return the number of bytes that was used to
// serialize the receiver. Implementers must only use the number of
// bytes required to serialize the receiver. Callers MAY provide a
// larger buffer than required to serialize into.
serializeInto(buffer []byte) uint8
}
// IPv4OptionsSerializer is a serializer for IPv4 options.
type IPv4OptionsSerializer []IPv4SerializableOption
// Length returns the total number of bytes required to serialize the options.
func (s IPv4OptionsSerializer) Length() uint8 {
var total uint8
for _, opt := range s {
total++
if withPayload, ok := opt.(IPv4SerializableOptionPayload); ok {
// Add 1 to reported length to account for the length byte.
total += 1 + withPayload.length()
}
}
return padIPv4OptionsLength(total)
}
// Serialize serializes the provided list of IPV4 options into b.
//
// Note, b must be of sufficient size to hold all the options in s. See
// IPv4OptionsSerializer.Length for details on the getting the total size
// of a serialized IPv4OptionsSerializer.
//
// Serialize panics if b is not of sufficient size to hold all the options in s.
func (s IPv4OptionsSerializer) Serialize(b []byte) uint8 {
var total uint8
for _, opt := range s {
ty := opt.optionType()
if withPayload, ok := opt.(IPv4SerializableOptionPayload); ok {
// Serialize first to reduce bounds checks.
l := 2 + withPayload.serializeInto(b[2:])
b[0] = byte(ty)
b[1] = l
b = b[l:]
total += l
continue
}
// Options without payload consist only of the type field.
//
// NB: Repeating code from the branch above is intentional to minimize
// bounds checks.
b[0] = byte(ty)
b = b[1:]
total++
}
// According to RFC 791:
//
// The internet header padding is used to ensure that the internet
// header ends on a 32 bit boundary. The padding is zero.
padded := padIPv4OptionsLength(total)
b = b[:padded-total]
for i := range b {
b[i] = 0
}
return padded
}
var _ IPv4SerializableOptionPayload = (*IPv4SerializableRouterAlertOption)(nil)
var _ IPv4SerializableOption = (*IPv4SerializableRouterAlertOption)(nil)
// IPv4SerializableRouterAlertOption provides serialization of the Router Alert
// IPv4 option according to RFC 2113.
type IPv4SerializableRouterAlertOption struct{}
// Type implements IPv4SerializableOption.
func (*IPv4SerializableRouterAlertOption) optionType() IPv4OptionType {
return IPv4OptionRouterAlertType
}
// Length implements IPv4SerializableOption.
func (*IPv4SerializableRouterAlertOption) length() uint8 {
return IPv4OptionRouterAlertLength - IPv4OptionRouterAlertValueOffset
}
// SerializeInto implements IPv4SerializableOption.
func (o *IPv4SerializableRouterAlertOption) serializeInto(buffer []byte) uint8 {
binary.BigEndian.PutUint16(buffer, IPv4OptionRouterAlertValue)
return o.length()
}
var _ IPv4SerializableOption = (*IPv4SerializableNOPOption)(nil)
// IPv4SerializableNOPOption provides serialization for the IPv4 no-op option.
type IPv4SerializableNOPOption struct{}
// Type implements IPv4SerializableOption.
func (*IPv4SerializableNOPOption) optionType() IPv4OptionType {
return IPv4OptionNOPType
}
var _ IPv4SerializableOption = (*IPv4SerializableListEndOption)(nil)
// IPv4SerializableListEndOption provides serialization for the IPv4 List End
// option.
type IPv4SerializableListEndOption struct{}
// Type implements IPv4SerializableOption.
func (*IPv4SerializableListEndOption) optionType() IPv4OptionType {
return IPv4OptionListEndType
}
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