// Copyright 2018 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. // +build linux package fdbased import ( "golang.org/x/sys/unix" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/header" "gvisor.dev/gvisor/pkg/tcpip/link/rawfile" "gvisor.dev/gvisor/pkg/tcpip/stack" ) // BufConfig defines the shape of the vectorised view used to read packets from the NIC. var BufConfig = []int{128, 256, 256, 512, 1024, 2048, 4096, 8192, 16384, 32768} type iovecBuffer struct { // views are the actual buffers that hold the packet contents. views []buffer.View // iovecs are initialized with base pointers/len of the corresponding // entries in the views defined above, except when GSO is enabled // (skipsVnetHdr) then the first iovec points to a buffer for the vnet header // which is stripped before the views are passed up the stack for further // processing. iovecs []unix.Iovec // sizes is an array of buffer sizes for the underlying views. sizes is // immutable. sizes []int // skipsVnetHdr is true if virtioNetHdr is to skipped. skipsVnetHdr bool } func newIovecBuffer(sizes []int, skipsVnetHdr bool) *iovecBuffer { b := &iovecBuffer{ views: make([]buffer.View, len(sizes)), sizes: sizes, skipsVnetHdr: skipsVnetHdr, } niov := len(b.views) if b.skipsVnetHdr { niov++ } b.iovecs = make([]unix.Iovec, niov) return b } func (b *iovecBuffer) nextIovecs() []unix.Iovec { vnetHdrOff := 0 if b.skipsVnetHdr { var vnetHdr [virtioNetHdrSize]byte // The kernel adds virtioNetHdr before each packet, but // we don't use it, so so we allocate a buffer for it, // add it in iovecs but don't add it in a view. b.iovecs[0] = unix.Iovec{Base: &vnetHdr[0]} b.iovecs[0].SetLen(virtioNetHdrSize) vnetHdrOff++ } for i := range b.views { if b.views[i] != nil { break } v := buffer.NewView(b.sizes[i]) b.views[i] = v b.iovecs[i+vnetHdrOff] = unix.Iovec{Base: &v[0]} b.iovecs[i+vnetHdrOff].SetLen(len(v)) } return b.iovecs } func (b *iovecBuffer) pullViews(n int) buffer.VectorisedView { var views []buffer.View c := 0 if b.skipsVnetHdr { c += virtioNetHdrSize if c >= n { // Nothing in the packet. return buffer.NewVectorisedView(0, nil) } } for i, v := range b.views { c += len(v) if c >= n { b.views[i].CapLength(len(v) - (c - n)) views = append([]buffer.View(nil), b.views[:i+1]...) break } } // Remove the first len(views) used views from the state. for i := range views { b.views[i] = nil } if b.skipsVnetHdr { // Exclude the size of the vnet header. n -= virtioNetHdrSize } return buffer.NewVectorisedView(n, views) } // readVDispatcher uses readv() system call to read inbound packets and // dispatches them. type readVDispatcher struct { // fd is the file descriptor used to send and receive packets. fd int // e is the endpoint this dispatcher is attached to. e *endpoint // buf is the iovec buffer that contains the packet contents. buf *iovecBuffer } func newReadVDispatcher(fd int, e *endpoint) (linkDispatcher, error) { d := &readVDispatcher{fd: fd, e: e} skipsVnetHdr := d.e.Capabilities()&stack.CapabilityHardwareGSO != 0 d.buf = newIovecBuffer(BufConfig, skipsVnetHdr) return d, nil } // dispatch reads one packet from the file descriptor and dispatches it. func (d *readVDispatcher) dispatch() (bool, tcpip.Error) { n, err := rawfile.BlockingReadv(d.fd, d.buf.nextIovecs()) if n == 0 || err != nil { return false, err } pkt := stack.NewPacketBuffer(stack.PacketBufferOptions{ Data: d.buf.pullViews(n), }) var ( p tcpip.NetworkProtocolNumber remote, local tcpip.LinkAddress ) if d.e.hdrSize > 0 { hdr, ok := pkt.LinkHeader().Consume(d.e.hdrSize) if !ok { return false, nil } eth := header.Ethernet(hdr) p = eth.Type() remote = eth.SourceAddress() local = eth.DestinationAddress() } else { // We don't get any indication of what the packet is, so try to guess // if it's an IPv4 or IPv6 packet. // IP version information is at the first octet, so pulling up 1 byte. h, ok := pkt.Data().PullUp(1) if !ok { return true, nil } switch header.IPVersion(h) { case header.IPv4Version: p = header.IPv4ProtocolNumber case header.IPv6Version: p = header.IPv6ProtocolNumber default: return true, nil } } d.e.dispatcher.DeliverNetworkPacket(remote, local, p, pkt) return true, nil } // recvMMsgDispatcher uses the recvmmsg system call to read inbound packets and // dispatches them. type recvMMsgDispatcher struct { // fd is the file descriptor used to send and receive packets. fd int // e is the endpoint this dispatcher is attached to. e *endpoint // bufs is an array of iovec buffers that contain packet contents. bufs []*iovecBuffer // msgHdrs is an array of MMsgHdr objects where each MMsghdr is used to // reference an array of iovecs in the iovecs field defined above. This // array is passed as the parameter to recvmmsg call to retrieve // potentially more than 1 packet per unix. msgHdrs []rawfile.MMsgHdr } const ( // MaxMsgsPerRecv is the maximum number of packets we want to retrieve // in a single RecvMMsg call. MaxMsgsPerRecv = 8 ) func newRecvMMsgDispatcher(fd int, e *endpoint) (linkDispatcher, error) { d := &recvMMsgDispatcher{ fd: fd, e: e, bufs: make([]*iovecBuffer, MaxMsgsPerRecv), msgHdrs: make([]rawfile.MMsgHdr, MaxMsgsPerRecv), } skipsVnetHdr := d.e.Capabilities()&stack.CapabilityHardwareGSO != 0 for i := range d.bufs { d.bufs[i] = newIovecBuffer(BufConfig, skipsVnetHdr) } return d, nil } // recvMMsgDispatch reads more than one packet at a time from the file // descriptor and dispatches it. func (d *recvMMsgDispatcher) dispatch() (bool, tcpip.Error) { // Fill message headers. for k := range d.msgHdrs { if d.msgHdrs[k].Msg.Iovlen > 0 { break } iovecs := d.bufs[k].nextIovecs() iovLen := len(iovecs) d.msgHdrs[k].Len = 0 d.msgHdrs[k].Msg.Iov = &iovecs[0] d.msgHdrs[k].Msg.SetIovlen(iovLen) } nMsgs, err := rawfile.BlockingRecvMMsg(d.fd, d.msgHdrs) if err != nil { return false, err } // Process each of received packets. for k := 0; k < nMsgs; k++ { n := int(d.msgHdrs[k].Len) pkt := stack.NewPacketBuffer(stack.PacketBufferOptions{ Data: d.bufs[k].pullViews(n), }) // Mark that this iovec has been processed. d.msgHdrs[k].Msg.Iovlen = 0 var ( p tcpip.NetworkProtocolNumber remote, local tcpip.LinkAddress ) if d.e.hdrSize > 0 { hdr, ok := pkt.LinkHeader().Consume(d.e.hdrSize) if !ok { return false, nil } eth := header.Ethernet(hdr) p = eth.Type() remote = eth.SourceAddress() local = eth.DestinationAddress() } else { // We don't get any indication of what the packet is, so try to guess // if it's an IPv4 or IPv6 packet. // IP version information is at the first octet, so pulling up 1 byte. h, ok := pkt.Data().PullUp(1) if !ok { // Skip this packet. continue } switch header.IPVersion(h) { case header.IPv4Version: p = header.IPv4ProtocolNumber case header.IPv6Version: p = header.IPv6ProtocolNumber default: // Skip this packet. continue } } d.e.dispatcher.DeliverNetworkPacket(remote, local, p, pkt) } return true, nil }