// Copyright 2019 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 stack import ( "fmt" "gvisor.dev/gvisor/pkg/sync" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/header" ) type headerType int const ( linkHeader headerType = iota networkHeader transportHeader numHeaderType ) // PacketBufferOptions specifies options for PacketBuffer creation. type PacketBufferOptions struct { // ReserveHeaderBytes is the number of bytes to reserve for headers. Total // number of bytes pushed onto the headers must not exceed this value. ReserveHeaderBytes int // Data is the initial unparsed data for the new packet. If set, it will be // owned by the new packet. Data buffer.VectorisedView } // A PacketBuffer contains all the data of a network packet. // // As a PacketBuffer traverses up the stack, it may be necessary to pass it to // multiple endpoints. // // The whole packet is expected to be a series of bytes in the following order: // LinkHeader, NetworkHeader, TransportHeader, and Data. Any of them can be // empty. Use of PacketBuffer in any other order is unsupported. // // PacketBuffer must be created with NewPacketBuffer. type PacketBuffer struct { _ sync.NoCopy // PacketBufferEntry is used to build an intrusive list of // PacketBuffers. PacketBufferEntry // data holds the payload of the packet. // // For inbound packets, Data is initially the whole packet. Then gets moved to // headers via PacketHeader.Consume, when the packet is being parsed. // // For outbound packets, Data is the innermost layer, defined by the protocol. // Headers are pushed in front of it via PacketHeader.Push. // // The bytes backing Data are immutable, a.k.a. users shouldn't write to its // backing storage. data buffer.VectorisedView // headers stores metadata about each header. headers [numHeaderType]headerInfo // header is the internal storage for outbound packets. Headers will be pushed // (prepended) on this storage as the packet is being constructed. // // TODO(gvisor.dev/issue/2404): Switch to an implementation that header and // data are held in the same underlying buffer storage. header buffer.Prependable // NetworkProtocolNumber is only valid when NetworkHeader().View().IsEmpty() // returns false. // TODO(gvisor.dev/issue/3574): Remove the separately passed protocol // numbers in registration APIs that take a PacketBuffer. NetworkProtocolNumber tcpip.NetworkProtocolNumber // TransportProtocol is only valid if it is non zero. // TODO(gvisor.dev/issue/3810): This and the network protocol number should // be moved into the headerinfo. This should resolve the validity issue. TransportProtocolNumber tcpip.TransportProtocolNumber // Hash is the transport layer hash of this packet. A value of zero // indicates no valid hash has been set. Hash uint32 // Owner is implemented by task to get the uid and gid. // Only set for locally generated packets. Owner tcpip.PacketOwner // The following fields are only set by the qdisc layer when the packet // is added to a queue. EgressRoute RouteInfo GSOOptions *GSO // NatDone indicates if the packet has been manipulated as per NAT // iptables rule. NatDone bool // PktType indicates the SockAddrLink.PacketType of the packet as defined in // https://www.man7.org/linux/man-pages/man7/packet.7.html. PktType tcpip.PacketType // NICID is the ID of the interface the network packet was received at. NICID tcpip.NICID // RXTransportChecksumValidated indicates that transport checksum verification // may be safely skipped. RXTransportChecksumValidated bool // NetworkPacketInfo holds an incoming packet's network-layer information. NetworkPacketInfo NetworkPacketInfo } // NewPacketBuffer creates a new PacketBuffer with opts. func NewPacketBuffer(opts PacketBufferOptions) *PacketBuffer { pk := &PacketBuffer{ data: opts.Data, } if opts.ReserveHeaderBytes != 0 { pk.header = buffer.NewPrependable(opts.ReserveHeaderBytes) } return pk } // ReservedHeaderBytes returns the number of bytes initially reserved for // headers. func (pk *PacketBuffer) ReservedHeaderBytes() int { return pk.header.UsedLength() + pk.header.AvailableLength() } // AvailableHeaderBytes returns the number of bytes currently available for // headers. This is relevant to PacketHeader.Push method only. func (pk *PacketBuffer) AvailableHeaderBytes() int { return pk.header.AvailableLength() } // LinkHeader returns the handle to link-layer header. func (pk *PacketBuffer) LinkHeader() PacketHeader { return PacketHeader{ pk: pk, typ: linkHeader, } } // NetworkHeader returns the handle to network-layer header. func (pk *PacketBuffer) NetworkHeader() PacketHeader { return PacketHeader{ pk: pk, typ: networkHeader, } } // TransportHeader returns the handle to transport-layer header. func (pk *PacketBuffer) TransportHeader() PacketHeader { return PacketHeader{ pk: pk, typ: transportHeader, } } // HeaderSize returns the total size of all headers in bytes. func (pk *PacketBuffer) HeaderSize() int { // Note for inbound packets (Consume called), headers are not stored in // pk.header. Thus, calculation of size of each header is needed. var size int for i := range pk.headers { size += len(pk.headers[i].buf) } return size } // Size returns the size of packet in bytes. func (pk *PacketBuffer) Size() int { return pk.HeaderSize() + pk.data.Size() } // MemSize returns the estimation size of the pk in memory, including backing // buffer data. func (pk *PacketBuffer) MemSize() int { return pk.HeaderSize() + pk.data.MemSize() + packetBufferStructSize } // Data returns the handle to data portion of pk. func (pk *PacketBuffer) Data() PacketData { return PacketData{pk: pk} } // Views returns the underlying storage of the whole packet. func (pk *PacketBuffer) Views() []buffer.View { // Optimization for outbound packets that headers are in pk.header. useHeader := true for i := range pk.headers { if !canUseHeader(&pk.headers[i]) { useHeader = false break } } dataViews := pk.data.Views() var vs []buffer.View if useHeader { vs = make([]buffer.View, 0, 1+len(dataViews)) vs = append(vs, pk.header.View()) } else { vs = make([]buffer.View, 0, len(pk.headers)+len(dataViews)) for i := range pk.headers { if v := pk.headers[i].buf; len(v) > 0 { vs = append(vs, v) } } } return append(vs, dataViews...) } func canUseHeader(h *headerInfo) bool { // h.offset will be negative if the header was pushed in to prependable // portion, or doesn't matter when it's empty. return len(h.buf) == 0 || h.offset < 0 } func (pk *PacketBuffer) push(typ headerType, size int) buffer.View { h := &pk.headers[typ] if h.buf != nil { panic(fmt.Sprintf("push must not be called twice: type %s", typ)) } h.buf = buffer.View(pk.header.Prepend(size)) h.offset = -pk.header.UsedLength() return h.buf } func (pk *PacketBuffer) consume(typ headerType, size int) (v buffer.View, consumed bool) { h := &pk.headers[typ] if h.buf != nil { panic(fmt.Sprintf("consume must not be called twice: type %s", typ)) } v, ok := pk.data.PullUp(size) if !ok { return } pk.data.TrimFront(size) h.buf = v return h.buf, true } // Clone makes a shallow copy of pk. // // Clone should be called in such cases so that no modifications is done to // underlying packet payload. func (pk *PacketBuffer) Clone() *PacketBuffer { return &PacketBuffer{ PacketBufferEntry: pk.PacketBufferEntry, data: pk.data.Clone(nil), headers: pk.headers, header: pk.header, Hash: pk.Hash, Owner: pk.Owner, GSOOptions: pk.GSOOptions, NetworkProtocolNumber: pk.NetworkProtocolNumber, NatDone: pk.NatDone, TransportProtocolNumber: pk.TransportProtocolNumber, PktType: pk.PktType, NICID: pk.NICID, RXTransportChecksumValidated: pk.RXTransportChecksumValidated, NetworkPacketInfo: pk.NetworkPacketInfo, } } // Network returns the network header as a header.Network. // // Network should only be called when NetworkHeader has been set. func (pk *PacketBuffer) Network() header.Network { switch netProto := pk.NetworkProtocolNumber; netProto { case header.IPv4ProtocolNumber: return header.IPv4(pk.NetworkHeader().View()) case header.IPv6ProtocolNumber: return header.IPv6(pk.NetworkHeader().View()) default: panic(fmt.Sprintf("unknown network protocol number %d", netProto)) } } // CloneToInbound makes a shallow copy of the packet buffer to be used as an // inbound packet. // // See PacketBuffer.Data for details about how a packet buffer holds an inbound // packet. func (pk *PacketBuffer) CloneToInbound() *PacketBuffer { return NewPacketBuffer(PacketBufferOptions{ Data: buffer.NewVectorisedView(pk.Size(), pk.Views()), }) } // headerInfo stores metadata about a header in a packet. type headerInfo struct { // buf is the memorized slice for both prepended and consumed header. // When header is prepended, buf serves as memorized value, which is a slice // of pk.header. When header is consumed, buf is the slice pulled out from // pk.Data, which is the only place to hold this header. buf buffer.View // offset will be a negative number denoting the offset where this header is // from the end of pk.header, if it is prepended. Otherwise, zero. offset int } // PacketHeader is a handle object to a header in the underlying packet. type PacketHeader struct { pk *PacketBuffer typ headerType } // View returns the underlying storage of h. func (h PacketHeader) View() buffer.View { return h.pk.headers[h.typ].buf } // Push pushes size bytes in the front of its residing packet, and returns the // backing storage. Callers may only call one of Push or Consume once on each // header in the lifetime of the underlying packet. func (h PacketHeader) Push(size int) buffer.View { return h.pk.push(h.typ, size) } // Consume moves the first size bytes of the unparsed data portion in the packet // to h, and returns the backing storage. In the case of data is shorter than // size, consumed will be false, and the state of h will not be affected. // Callers may only call one of Push or Consume once on each header in the // lifetime of the underlying packet. func (h PacketHeader) Consume(size int) (v buffer.View, consumed bool) { return h.pk.consume(h.typ, size) } // PacketData represents the data portion of a PacketBuffer. type PacketData struct { pk *PacketBuffer } // PullUp returns a contiguous view of size bytes from the beginning of d. // Callers should not write to or keep the view for later use. func (d PacketData) PullUp(size int) (buffer.View, bool) { return d.pk.data.PullUp(size) } // TrimFront removes count from the beginning of d. It panics if count > // d.Size(). func (d PacketData) TrimFront(count int) { d.pk.data.TrimFront(count) } // CapLength reduces d to at most length bytes. func (d PacketData) CapLength(length int) { d.pk.data.CapLength(length) } // Views returns the underlying storage of d in a slice of Views. Caller should // not modify the returned slice. func (d PacketData) Views() []buffer.View { return d.pk.data.Views() } // AppendView appends v into d, taking the ownership of v. func (d PacketData) AppendView(v buffer.View) { d.pk.data.AppendView(v) } // ReadFromData moves at most count bytes from the beginning of srcData to the // end of d and returns the number of bytes moved. func (d PacketData) ReadFromData(srcData PacketData, count int) int { return srcData.pk.data.ReadToVV(&d.pk.data, count) } // ReadFromVV moves at most count bytes from the beginning of srcVV to the end // of d and returns the number of bytes moved. func (d PacketData) ReadFromVV(srcVV *buffer.VectorisedView, count int) int { return srcVV.ReadToVV(&d.pk.data, count) } // Size returns the number of bytes in the data payload of the packet. func (d PacketData) Size() int { return d.pk.data.Size() } // AsRange returns a Range representing the current data payload of the packet. func (d PacketData) AsRange() Range { return Range{ pk: d.pk, offset: d.pk.HeaderSize(), length: d.Size(), } } // ExtractVV returns a VectorisedView of d. This method has the semantic to // destruct the underlying packet, hence the packet cannot be used again. // // This method exists for compatibility between PacketBuffer and VectorisedView. // It may be removed later and should be used with care. func (d PacketData) ExtractVV() buffer.VectorisedView { return d.pk.data } // Replace replaces the data portion of the packet with vv, taking the ownership // of vv. // // This method exists for compatibility between PacketBuffer and VectorisedView. // It may be removed later and should be used with care. func (d PacketData) Replace(vv buffer.VectorisedView) { d.pk.data = vv } // Range represents a contiguous subportion of a PacketBuffer. type Range struct { pk *PacketBuffer offset int length int } // Size returns the number of bytes in r. func (r Range) Size() int { return r.length } // SubRange returns a new Range starting at off bytes of r. It returns an empty // range if off is out-of-bounds. func (r Range) SubRange(off int) Range { if off > r.length { return Range{pk: r.pk} } return Range{ pk: r.pk, offset: r.offset + off, length: r.length - off, } } // Capped returns a new Range with the same starting point of r and length // capped at max. func (r Range) Capped(max int) Range { if r.length <= max { return r } return Range{ pk: r.pk, offset: r.offset, length: max, } } // AsView returns the backing storage of r if possible. It will allocate a new // View if r spans multiple pieces internally. Caller should not write to the // returned View in any way. func (r Range) AsView() buffer.View { var allocated bool var v buffer.View r.iterate(func(b []byte) { if v == nil { // v has not been assigned, allowing first view to be returned. v = b } else { // v has been assigned. This range spans more than a view, a new view // needs to be allocated. if !allocated { allocated = true all := make([]byte, 0, r.length) all = append(all, v...) v = all } v = append(v, b...) } }) return v } // ToOwnedView returns a owned copy of data in r. func (r Range) ToOwnedView() buffer.View { if r.length == 0 { return nil } all := make([]byte, 0, r.length) r.iterate(func(b []byte) { all = append(all, b...) }) return all } // Checksum calculates the RFC 1071 checksum for the underlying bytes of r. func (r Range) Checksum() uint16 { var c header.Checksumer r.iterate(c.Add) return c.Checksum() } // iterate calls fn for each piece in r. fn is always called with a non-empty // slice. func (r Range) iterate(fn func([]byte)) { w := window{ offset: r.offset, length: r.length, } // Header portion. for i := range r.pk.headers { if b := w.process(r.pk.headers[i].buf); len(b) > 0 { fn(b) } if w.isDone() { break } } // Data portion. if !w.isDone() { for _, v := range r.pk.data.Views() { if b := w.process(v); len(b) > 0 { fn(b) } if w.isDone() { break } } } } // window represents contiguous region of byte stream. User would call process() // to input bytes, and obtain a subslice that is inside the window. type window struct { offset int length int } // isDone returns true if the window has passed and further process() calls will // always return an empty slice. This can be used to end processing early. func (w *window) isDone() bool { return w.length == 0 } // process feeds b in and returns a subslice that is inside the window. The // returned slice will be a subslice of b, and it does not keep b after method // returns. This method may return an empty slice if nothing in b is inside the // window. func (w *window) process(b []byte) (inWindow []byte) { if w.offset >= len(b) { w.offset -= len(b) return nil } if w.offset > 0 { b = b[w.offset:] w.offset = 0 } if w.length < len(b) { b = b[:w.length] } w.length -= len(b) return b } // PayloadSince returns packet payload starting from and including a particular // header. // // The returned View is owned by the caller - its backing buffer is separate // from the packet header's underlying packet buffer. func PayloadSince(h PacketHeader) buffer.View { size := h.pk.data.Size() for _, hinfo := range h.pk.headers[h.typ:] { size += len(hinfo.buf) } v := make(buffer.View, 0, size) for _, hinfo := range h.pk.headers[h.typ:] { v = append(v, hinfo.buf...) } for _, view := range h.pk.data.Views() { v = append(v, view...) } return v }