// Copyright 2020 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 testbench import ( "fmt" "reflect" "strings" "github.com/google/go-cmp/cmp" "github.com/google/go-cmp/cmp/cmpopts" "github.com/imdario/mergo" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/header" ) // Layer is the interface that all encapsulations must implement. // // A Layer is an encapsulation in a packet, such as TCP, IPv4, IPv6, etc. A // Layer contains all the fields of the encapsulation. Each field is a pointer // and may be nil. type Layer interface { fmt.Stringer // toBytes converts the Layer into bytes. In places where the Layer's field // isn't nil, the value that is pointed to is used. When the field is nil, a // reasonable default for the Layer is used. For example, "64" for IPv4 TTL // and a calculated checksum for TCP or IP. Some layers require information // from the previous or next layers in order to compute a default, such as // TCP's checksum or Ethernet's type, so each Layer has a doubly-linked list // to the layer's neighbors. toBytes() ([]byte, error) // match checks if the current Layer matches the provided Layer. If either // Layer has a nil in a given field, that field is considered matching. // Otherwise, the values pointed to by the fields must match. The LayerBase is // ignored. match(Layer) bool // length in bytes of the current encapsulation length() int // next gets a pointer to the encapsulated Layer. next() Layer // prev gets a pointer to the Layer encapsulating this one. prev() Layer // setNext sets the pointer to the encapsulated Layer. setNext(Layer) // setPrev sets the pointer to the Layer encapsulating this one. setPrev(Layer) } // LayerBase is the common elements of all layers. type LayerBase struct { nextLayer Layer prevLayer Layer } func (lb *LayerBase) next() Layer { return lb.nextLayer } func (lb *LayerBase) prev() Layer { return lb.prevLayer } func (lb *LayerBase) setNext(l Layer) { lb.nextLayer = l } func (lb *LayerBase) setPrev(l Layer) { lb.prevLayer = l } // equalLayer compares that two Layer structs match while ignoring field in // which either input has a nil and also ignoring the LayerBase of the inputs. func equalLayer(x, y Layer) bool { // opt ignores comparison pairs where either of the inputs is a nil. opt := cmp.FilterValues(func(x, y interface{}) bool { for _, l := range []interface{}{x, y} { v := reflect.ValueOf(l) if (v.Kind() == reflect.Ptr || v.Kind() == reflect.Slice) && v.IsNil() { return true } } return false }, cmp.Ignore()) return cmp.Equal(x, y, opt, cmpopts.IgnoreTypes(LayerBase{})) } func stringLayer(l Layer) string { v := reflect.ValueOf(l).Elem() t := v.Type() var ret []string for i := 0; i < v.NumField(); i++ { t := t.Field(i) if t.Anonymous { // Ignore the LayerBase in the Layer struct. continue } v := v.Field(i) if v.IsNil() { continue } ret = append(ret, fmt.Sprintf("%s:%v", t.Name, reflect.Indirect(v))) } return fmt.Sprintf("&%s{%s}", t, strings.Join(ret, " ")) } // Ether can construct and match an ethernet encapsulation. type Ether struct { LayerBase SrcAddr *tcpip.LinkAddress DstAddr *tcpip.LinkAddress Type *tcpip.NetworkProtocolNumber } func (l *Ether) String() string { return stringLayer(l) } func (l *Ether) toBytes() ([]byte, error) { b := make([]byte, header.EthernetMinimumSize) h := header.Ethernet(b) fields := &header.EthernetFields{} if l.SrcAddr != nil { fields.SrcAddr = *l.SrcAddr } if l.DstAddr != nil { fields.DstAddr = *l.DstAddr } if l.Type != nil { fields.Type = *l.Type } else { switch n := l.next().(type) { case *IPv4: fields.Type = header.IPv4ProtocolNumber default: // TODO(b/150301488): Support more protocols, like IPv6. return nil, fmt.Errorf("can't deduce the ethernet header's next protocol: %d", n) } } h.Encode(fields) return h, nil } // LinkAddress is a helper routine that allocates a new tcpip.LinkAddress value // to store v and returns a pointer to it. func LinkAddress(v tcpip.LinkAddress) *tcpip.LinkAddress { return &v } // NetworkProtocolNumber is a helper routine that allocates a new // tcpip.NetworkProtocolNumber value to store v and returns a pointer to it. func NetworkProtocolNumber(v tcpip.NetworkProtocolNumber) *tcpip.NetworkProtocolNumber { return &v } // ParseEther parses the bytes assuming that they start with an ethernet header // and continues parsing further encapsulations. func ParseEther(b []byte) (Layers, error) { h := header.Ethernet(b) ether := Ether{ SrcAddr: LinkAddress(h.SourceAddress()), DstAddr: LinkAddress(h.DestinationAddress()), Type: NetworkProtocolNumber(h.Type()), } layers := Layers{ðer} switch h.Type() { case header.IPv4ProtocolNumber: moreLayers, err := ParseIPv4(b[ether.length():]) if err != nil { return nil, err } return append(layers, moreLayers...), nil default: // TODO(b/150301488): Support more protocols, like IPv6. return nil, fmt.Errorf("can't deduce the ethernet header's next protocol: %#v", b) } } func (l *Ether) match(other Layer) bool { return equalLayer(l, other) } func (l *Ether) length() int { return header.EthernetMinimumSize } // IPv4 can construct and match an IPv4 encapsulation. type IPv4 struct { LayerBase IHL *uint8 TOS *uint8 TotalLength *uint16 ID *uint16 Flags *uint8 FragmentOffset *uint16 TTL *uint8 Protocol *uint8 Checksum *uint16 SrcAddr *tcpip.Address DstAddr *tcpip.Address } func (l *IPv4) String() string { return stringLayer(l) } func (l *IPv4) toBytes() ([]byte, error) { b := make([]byte, header.IPv4MinimumSize) h := header.IPv4(b) fields := &header.IPv4Fields{ IHL: 20, TOS: 0, TotalLength: 0, ID: 0, Flags: 0, FragmentOffset: 0, TTL: 64, Protocol: 0, Checksum: 0, SrcAddr: tcpip.Address(""), DstAddr: tcpip.Address(""), } if l.TOS != nil { fields.TOS = *l.TOS } if l.TotalLength != nil { fields.TotalLength = *l.TotalLength } else { fields.TotalLength = uint16(l.length()) current := l.next() for current != nil { fields.TotalLength += uint16(current.length()) current = current.next() } } if l.ID != nil { fields.ID = *l.ID } if l.Flags != nil { fields.Flags = *l.Flags } if l.FragmentOffset != nil { fields.FragmentOffset = *l.FragmentOffset } if l.TTL != nil { fields.TTL = *l.TTL } if l.Protocol != nil { fields.Protocol = *l.Protocol } else { switch n := l.next().(type) { case *TCP: fields.Protocol = uint8(header.TCPProtocolNumber) case *UDP: fields.Protocol = uint8(header.UDPProtocolNumber) default: // TODO(b/150301488): Support more protocols as needed. return nil, fmt.Errorf("can't deduce the ip header's next protocol: %#v", n) } } if l.SrcAddr != nil { fields.SrcAddr = *l.SrcAddr } if l.DstAddr != nil { fields.DstAddr = *l.DstAddr } if l.Checksum != nil { fields.Checksum = *l.Checksum } h.Encode(fields) if l.Checksum == nil { h.SetChecksum(^h.CalculateChecksum()) } return h, nil } // Uint16 is a helper routine that allocates a new // uint16 value to store v and returns a pointer to it. func Uint16(v uint16) *uint16 { return &v } // Uint8 is a helper routine that allocates a new // uint8 value to store v and returns a pointer to it. func Uint8(v uint8) *uint8 { return &v } // Address is a helper routine that allocates a new tcpip.Address value to store // v and returns a pointer to it. func Address(v tcpip.Address) *tcpip.Address { return &v } // ParseIPv4 parses the bytes assuming that they start with an ipv4 header and // continues parsing further encapsulations. func ParseIPv4(b []byte) (Layers, error) { h := header.IPv4(b) tos, _ := h.TOS() ipv4 := IPv4{ IHL: Uint8(h.HeaderLength()), TOS: &tos, TotalLength: Uint16(h.TotalLength()), ID: Uint16(h.ID()), Flags: Uint8(h.Flags()), FragmentOffset: Uint16(h.FragmentOffset()), TTL: Uint8(h.TTL()), Protocol: Uint8(h.Protocol()), Checksum: Uint16(h.Checksum()), SrcAddr: Address(h.SourceAddress()), DstAddr: Address(h.DestinationAddress()), } layers := Layers{&ipv4} switch h.TransportProtocol() { case header.TCPProtocolNumber: moreLayers, err := ParseTCP(b[ipv4.length():]) if err != nil { return nil, err } return append(layers, moreLayers...), nil case header.UDPProtocolNumber: moreLayers, err := ParseUDP(b[ipv4.length():]) if err != nil { return nil, err } return append(layers, moreLayers...), nil } return nil, fmt.Errorf("can't deduce the ethernet header's next protocol: %d", h.Protocol()) } func (l *IPv4) match(other Layer) bool { return equalLayer(l, other) } func (l *IPv4) length() int { if l.IHL == nil { return header.IPv4MinimumSize } return int(*l.IHL) } // TCP can construct and match a TCP encapsulation. type TCP struct { LayerBase SrcPort *uint16 DstPort *uint16 SeqNum *uint32 AckNum *uint32 DataOffset *uint8 Flags *uint8 WindowSize *uint16 Checksum *uint16 UrgentPointer *uint16 } func (l *TCP) String() string { return stringLayer(l) } func (l *TCP) toBytes() ([]byte, error) { b := make([]byte, header.TCPMinimumSize) h := header.TCP(b) if l.SrcPort != nil { h.SetSourcePort(*l.SrcPort) } if l.DstPort != nil { h.SetDestinationPort(*l.DstPort) } if l.SeqNum != nil { h.SetSequenceNumber(*l.SeqNum) } if l.AckNum != nil { h.SetAckNumber(*l.AckNum) } if l.DataOffset != nil { h.SetDataOffset(*l.DataOffset) } else { h.SetDataOffset(uint8(l.length())) } if l.Flags != nil { h.SetFlags(*l.Flags) } if l.WindowSize != nil { h.SetWindowSize(*l.WindowSize) } else { h.SetWindowSize(32768) } if l.UrgentPointer != nil { h.SetUrgentPoiner(*l.UrgentPointer) } if l.Checksum != nil { h.SetChecksum(*l.Checksum) return h, nil } if err := setTCPChecksum(&h, l); err != nil { return nil, err } return h, nil } // totalLength returns the length of the provided layer and all following // layers. func totalLength(l Layer) int { var totalLength int for ; l != nil; l = l.next() { totalLength += l.length() } return totalLength } // layerChecksum calculates the checksum of the Layer header, including the // peusdeochecksum of the layer before it and all the bytes after it.. func layerChecksum(l Layer, protoNumber tcpip.TransportProtocolNumber) (uint16, error) { totalLength := uint16(totalLength(l)) var xsum uint16 switch s := l.prev().(type) { case *IPv4: xsum = header.PseudoHeaderChecksum(protoNumber, *s.SrcAddr, *s.DstAddr, totalLength) default: // TODO(b/150301488): Support more protocols, like IPv6. return 0, fmt.Errorf("can't get src and dst addr from previous layer: %#v", s) } var payloadBytes buffer.VectorisedView for current := l.next(); current != nil; current = current.next() { payload, err := current.toBytes() if err != nil { return 0, fmt.Errorf("can't get bytes for next header: %s", payload) } payloadBytes.AppendView(payload) } xsum = header.ChecksumVV(payloadBytes, xsum) return xsum, nil } // setTCPChecksum calculates the checksum of the TCP header and sets it in h. func setTCPChecksum(h *header.TCP, tcp *TCP) error { h.SetChecksum(0) xsum, err := layerChecksum(tcp, header.TCPProtocolNumber) if err != nil { return err } h.SetChecksum(^h.CalculateChecksum(xsum)) return nil } // Uint32 is a helper routine that allocates a new // uint32 value to store v and returns a pointer to it. func Uint32(v uint32) *uint32 { return &v } // ParseTCP parses the bytes assuming that they start with a tcp header and // continues parsing further encapsulations. func ParseTCP(b []byte) (Layers, error) { h := header.TCP(b) tcp := TCP{ SrcPort: Uint16(h.SourcePort()), DstPort: Uint16(h.DestinationPort()), SeqNum: Uint32(h.SequenceNumber()), AckNum: Uint32(h.AckNumber()), DataOffset: Uint8(h.DataOffset()), Flags: Uint8(h.Flags()), WindowSize: Uint16(h.WindowSize()), Checksum: Uint16(h.Checksum()), UrgentPointer: Uint16(h.UrgentPointer()), } layers := Layers{&tcp} moreLayers, err := ParsePayload(b[tcp.length():]) if err != nil { return nil, err } return append(layers, moreLayers...), nil } func (l *TCP) match(other Layer) bool { return equalLayer(l, other) } func (l *TCP) length() int { if l.DataOffset == nil { return header.TCPMinimumSize } return int(*l.DataOffset) } // merge overrides the values in l with the values from other but only in fields // where the value is not nil. func (l *TCP) merge(other TCP) error { return mergo.Merge(l, other, mergo.WithOverride) } // UDP can construct and match a UDP encapsulation. type UDP struct { LayerBase SrcPort *uint16 DstPort *uint16 Length *uint16 Checksum *uint16 } func (l *UDP) String() string { return stringLayer(l) } func (l *UDP) toBytes() ([]byte, error) { b := make([]byte, header.UDPMinimumSize) h := header.UDP(b) if l.SrcPort != nil { h.SetSourcePort(*l.SrcPort) } if l.DstPort != nil { h.SetDestinationPort(*l.DstPort) } if l.Length != nil { h.SetLength(*l.Length) } else { h.SetLength(uint16(totalLength(l))) } if l.Checksum != nil { h.SetChecksum(*l.Checksum) return h, nil } if err := setUDPChecksum(&h, l); err != nil { return nil, err } return h, nil } // setUDPChecksum calculates the checksum of the UDP header and sets it in h. func setUDPChecksum(h *header.UDP, udp *UDP) error { h.SetChecksum(0) xsum, err := layerChecksum(udp, header.UDPProtocolNumber) if err != nil { return err } h.SetChecksum(^h.CalculateChecksum(xsum)) return nil } // ParseUDP parses the bytes assuming that they start with a udp header and // continues parsing further encapsulations. func ParseUDP(b []byte) (Layers, error) { h := header.UDP(b) udp := UDP{ SrcPort: Uint16(h.SourcePort()), DstPort: Uint16(h.DestinationPort()), Length: Uint16(h.Length()), Checksum: Uint16(h.Checksum()), } layers := Layers{&udp} moreLayers, err := ParsePayload(b[udp.length():]) if err != nil { return nil, err } return append(layers, moreLayers...), nil } func (l *UDP) match(other Layer) bool { return equalLayer(l, other) } func (l *UDP) length() int { if l.Length == nil { return header.UDPMinimumSize } return int(*l.Length) } // merge overrides the values in l with the values from other but only in fields // where the value is not nil. func (l *UDP) merge(other UDP) error { return mergo.Merge(l, other, mergo.WithOverride) } // Payload has bytes beyond OSI layer 4. type Payload struct { LayerBase Bytes []byte } func (l *Payload) String() string { return stringLayer(l) } // ParsePayload parses the bytes assuming that they start with a payload and // continue to the end. There can be no further encapsulations. func ParsePayload(b []byte) (Layers, error) { payload := Payload{ Bytes: b, } return Layers{&payload}, nil } func (l *Payload) toBytes() ([]byte, error) { return l.Bytes, nil } func (l *Payload) match(other Layer) bool { return equalLayer(l, other) } func (l *Payload) length() int { return len(l.Bytes) } // Layers is an array of Layer and supports similar functions to Layer. type Layers []Layer func (ls *Layers) toBytes() ([]byte, error) { for i, l := range *ls { if i > 0 { l.setPrev((*ls)[i-1]) } if i+1 < len(*ls) { l.setNext((*ls)[i+1]) } } outBytes := []byte{} for _, l := range *ls { layerBytes, err := l.toBytes() if err != nil { return nil, err } outBytes = append(outBytes, layerBytes...) } return outBytes, nil } func (ls *Layers) match(other Layers) bool { if len(*ls) > len(other) { return false } for i := 0; i < len(*ls); i++ { if !equalLayer((*ls)[i], other[i]) { return false } } return true }