fw-daemon/vendor/github.com/subgraph/go-nfnetlink/nfqueue/nfqueue.go

package nfqueue

import (
	"fmt"
	"errors"
	"encoding/binary"
	"github.com/google/gopacket"
	"github.com/google/gopacket/layers"
	"github.com/subgraph/go-nfnetlink"
	"syscall"
)

const (
	NFQNL_CFG_CMD_BIND   = 1
	NFQNL_CFG_CMD_UNBIND = 2

	NFQNL_COPY_META   = 1
	NFQNL_COPY_PACKET = 2

	NFNL_SUBSYS_QUEUE = 3

	NFQNL_MSG_PACKET  = 0
	NFQNL_MSG_VERDICT = 1
	NFQNL_MSG_CONFIG  = 2

	NFQA_CFG_COMMAND = 1
	NFQA_CFG_PARAMS  = 2

	NFQA_PACKET_HDR  = 1
	NFQA_VERDICT_HDR = 2
	NFQA_MARK        = 3
	NFQA_HWADDR      = 9
	NFQA_PAYLOAD     = 10

	NF_DROP   = 0
	NF_ACCEPT = 1
)

type NFQPacket struct {
	id      uint32          // packet id
	HwProto uint16          // hardware protocol
	Packet  gopacket.Packet // packet data
	q       *NFQueue        // queue instance
	hMark	bool		// whether mark should be set
	mark	uint32		// optional mark for verdict
	hwAddr []byte		// (optional) hardware address
}

type NFQueue struct {
	queue      uint16                   // queue number
	packets    chan *NFQPacket          // channel for delivering packets
	copySize   uint32                   // configured copy size
	pendingErr error                    // error which occured while receiving packet messages
	nls        *nfnetlink.NetlinkSocket // netlink socket to netfilter queue subsystem
	debug      bool                     // set to true if debugging enabled
	hwtrace    bool                     // set to true if hardware addresses are to be captured
}

const defaultCopySize = 0xFFFF

// NewNFQueue creates and returns a new NFQueue instance.
func NewNFQueue(queue uint16) *NFQueue {
	return &NFQueue{
		queue:    queue,
		copySize: defaultCopySize,
		packets:  make(chan *NFQPacket),
	}
}

// EnableDebug sets a flag on the associated NetlinkSocket causing it to dump information
// about each received and transmitted message.
func (q *NFQueue) EnableDebug() {
	if q.nls != nil {
		q.nls.SetFlag(nfnetlink.FlagDebug)
	}
	q.debug = true

}

func (q *NFQueue) EnableHWTrace() {
	q.hwtrace = true
}

// SetCopySize can be called before Open to set the packet capture size
func (q *NFQueue) SetCopySize(sz uint32) {
	q.copySize = sz
}

// open creates a netlink socket connection to the netfilter subsystem and
// configures the connection to receive packets from netfilter queue
func (q *NFQueue) open() error {
	nls, err := nfnetlink.NewNetlinkSocket(syscall.NETLINK_NETFILTER)
	if err != nil {
		return err
	}
	q.nls = nls
	if q.debug {
		q.nls.SetFlag(nfnetlink.FlagDebug)
	}

	err = q.sendAll(
		q.nfqRequestConfigCmd(NFQNL_CFG_CMD_BIND, q.queue, 0),
		q.nfqRequestConfigParams(q.copySize, NFQNL_COPY_PACKET),
	)
	if err != nil {
		q.Close()
		return err
	}
	return nil
}

// Close this queue instance
func (q *NFQueue) Close() {
	q.sendAll(
		q.nfqRequestConfigCmd(NFQNL_CFG_CMD_UNBIND, q.queue, 0),
	)
	q.nls.Close()
}

// sendAll sends a series of messages, returning the first error encountered if any.
func (q *NFQueue) sendAll(msgs ...*nfnetlink.NfNlMessage) error {
	for _, m := range msgs {
		if err := m.Send(); err != nil {
			return err
		}
	}
	return nil
}

// Open this queue instance.  Returns a channel for reading received packets.
func (q *NFQueue) Open() (<-chan *NFQPacket, error) {
	if err := q.open(); err != nil {
		return nil, err
	}
	go q.receivePackets()
	return q.packets, nil
}

// receivePackets reads messages from the channel returned by NetlinkSocket.Receive and
// processes them until the channel is closed.  If an error occurs, this error is assigned to
// q.pendingError
func (q *NFQueue) receivePackets() {
	for m := range q.nls.Receive() {
		if err := q.processPacket(m); err != nil {
			q.pendingErr = err
			close(q.packets)
			return
		}
	}
	if q.nls.RecvErr() != nil {
		q.pendingErr = q.nls.RecvErr()
	}
	close(q.packets)
}

// PendingError returns the error that was encountered while receiving packets if any.
func (q *NFQueue) PendingError() error {
	return q.pendingErr
}

// processPacket handles an incoming NfNlMessage which is assumed to contain a received packet.
func (q *NFQueue) processPacket(m *nfnetlink.NfNlMessage) error {
	hdr := m.Attr(NFQA_PACKET_HDR)
	if hdr == nil {
		return fmt.Errorf("No NFQA_PACKET_HDR\n")
	}
	p := &NFQPacket{q: q}
	p.hMark = false
	hdr.ReadFields(&p.id, &p.HwProto)
	payload := m.Attr(NFQA_PAYLOAD)
	if payload != nil {
		p.Packet = gopacket.NewPacket(payload.Data, layers.LayerTypeIPv4,
			gopacket.DecodeOptions{Lazy: true, NoCopy: true})
	}
	if q.hwtrace {
//		fmt.Println("XXX: Hardware tracing on")
		hwpkt := m.Attr(NFQA_HWADDR)
		if hwpkt != nil {
			//fmt.Println("XXX: HW TRACE DATA: %v / %p", hwpkt.Data, p.hwAddr)
			p.hwAddr = hwpkt.Data
		}
	}// else { fmt.Println("XXX: NO HWTRACING ON") }
	q.packets <- p
	return nil
}

// nfqRequestConfigCmd creates an NFQNL_MSG_CONFIG message with a NFQA_CFG_COMMAND attribute for
// the provided cmd, queue number, and protocol family.
func (q *NFQueue) nfqRequestConfigCmd(cmd uint8, queue uint16, pf uint16) *nfnetlink.NfNlMessage {
	nr := q.nfqNewRequest(NFQNL_MSG_CONFIG, queue)
	nr.AddAttributeFields(NFQA_CFG_COMMAND, cmd, uint8(0), pf)
	return nr
}

// nfqRequestConfigParams creates an NFQNL_MSG_CONFIG message with a NFQA_CFG_PARAMS attribute for
// the provided copyRange and copyMode values.
func (q *NFQueue) nfqRequestConfigParams(copyRange uint32, copyMode uint8) *nfnetlink.NfNlMessage {
	nr := q.nfqNewRequest(NFQNL_MSG_CONFIG, q.queue)
	nr.AddAttributeFields(NFQA_CFG_PARAMS, copyRange, copyMode)
	return nr
}

// nfqRequestVerdictMark creates an NFQNL_MSG_VERDICT with the provided id and verdict values.  If hasMark is set
// an optional NFQA_MARK attribute will be included to set a mark on the packet with value mark
func (q *NFQueue) nfqRequestVerdictMark(verdict uint32, id uint32, hasMark bool, mark uint32) *nfnetlink.NfNlMessage {
	nr := q.nfqNewRequest(NFQNL_MSG_VERDICT, q.queue)
	nr.AddAttributeFields(NFQA_VERDICT_HDR, verdict, id)
	if hasMark {
		nr.AddAttributeFields(NFQA_MARK, mark)
	}
	return nr
}

// nfqNewRequest creates a new message to the queue subsystem with the given type and queue number
func (q *NFQueue) nfqNewRequest(mtype uint8, queue uint16) *nfnetlink.NfNlMessage {
	nlm := q.nls.NewNfNlMsg()
	nlm.Type = uint16((NFNL_SUBSYS_QUEUE << 8) | uint16(mtype))
	nlm.Flags = syscall.NLM_F_REQUEST
	nlm.Family = syscall.AF_UNSPEC
	nlm.Version = nfnetlink.NFNETLINK_V0
	nlm.ResID = queue
	return nlm
}

// Drop sets the NF_DROP verdict on this packet
func (p *NFQPacket) Drop() error {
	return p.verdict(NF_DROP)
}

// Accept sets the NF_ACCEPT verdict on this packet
func (p *NFQPacket) Accept() error {
	return p.verdict(NF_ACCEPT)
}

// Set an optional mark to be set with the next verdict
func (p *NFQPacket) SetMark(mark uint32) {
	p.mark = mark
	p.hMark = true
}

// verdict sends a NFQNL_MSG_VERDICT message for the packet id with the verdict value v
func (p *NFQPacket) verdict(v uint32) error {
	return p.q.nfqRequestVerdictMark(v, p.id, p.hMark, p.mark).Send()
}

func (p *NFQPacket) GetHWAddr() ([]byte, error) {
//fmt.Printf("XXX: hwaddr address = %p\n", p.hwAddr)
	if len(p.hwAddr) != 12 {
//fmt.Println("XXX: length was: ", len(p.hwAddr))
		return nil, errors.New("Hardware data was unexpected length")
	}

	addrlen := int(binary.BigEndian.Uint16(p.hwAddr[0:2]))

	if len(p.hwAddr) < 4 + addrlen {
		return nil, errors.New("Hardware address overflow")
	}

	return p.hwAddr[addrlen:addrlen+4], nil
}
vendoring 7 years ago			`package nfqueue`

			`import (`
			`"fmt"`
			`"errors"`
			`"encoding/binary"`
			`"github.com/google/gopacket"`
			`"github.com/google/gopacket/layers"`
			`"github.com/subgraph/go-nfnetlink"`
			`"syscall"`
			`)`

			`const (`
			`NFQNL_CFG_CMD_BIND = 1`
			`NFQNL_CFG_CMD_UNBIND = 2`

			`NFQNL_COPY_META = 1`
			`NFQNL_COPY_PACKET = 2`

			`NFNL_SUBSYS_QUEUE = 3`

			`NFQNL_MSG_PACKET = 0`
			`NFQNL_MSG_VERDICT = 1`
			`NFQNL_MSG_CONFIG = 2`

			`NFQA_CFG_COMMAND = 1`
			`NFQA_CFG_PARAMS = 2`

			`NFQA_PACKET_HDR = 1`
			`NFQA_VERDICT_HDR = 2`
			`NFQA_MARK = 3`
			`NFQA_HWADDR = 9`
			`NFQA_PAYLOAD = 10`

			`NF_DROP = 0`
			`NF_ACCEPT = 1`
			`)`

			`type NFQPacket struct {`
			`id uint32 // packet id`
			`HwProto uint16 // hardware protocol`
			`Packet gopacket.Packet // packet data`
			`q *NFQueue // queue instance`
			`hMark bool // whether mark should be set`
			`mark uint32 // optional mark for verdict`
			`hwAddr []byte // (optional) hardware address`
			`}`

			`type NFQueue struct {`
			`queue uint16 // queue number`
			`packets chan *NFQPacket // channel for delivering packets`
			`copySize uint32 // configured copy size`
			`pendingErr error // error which occured while receiving packet messages`
			`nls *nfnetlink.NetlinkSocket // netlink socket to netfilter queue subsystem`
			`debug bool // set to true if debugging enabled`
			`hwtrace bool // set to true if hardware addresses are to be captured`
			`}`

			`const defaultCopySize = 0xFFFF`

			`// NewNFQueue creates and returns a new NFQueue instance.`
			`func NewNFQueue(queue uint16) *NFQueue {`
			`return &NFQueue{`
			`queue: queue,`
			`copySize: defaultCopySize,`
			`packets: make(chan *NFQPacket),`
			`}`
			`}`

			`// EnableDebug sets a flag on the associated NetlinkSocket causing it to dump information`
			`// about each received and transmitted message.`
			`func (q *NFQueue) EnableDebug() {`
			`if q.nls != nil {`
			`q.nls.SetFlag(nfnetlink.FlagDebug)`
			`}`
			`q.debug = true`

			`}`

			`func (q *NFQueue) EnableHWTrace() {`
			`q.hwtrace = true`
			`}`

			`// SetCopySize can be called before Open to set the packet capture size`
			`func (q *NFQueue) SetCopySize(sz uint32) {`
			`q.copySize = sz`
			`}`

			`// open creates a netlink socket connection to the netfilter subsystem and`
			`// configures the connection to receive packets from netfilter queue`
			`func (q *NFQueue) open() error {`
			`nls, err := nfnetlink.NewNetlinkSocket(syscall.NETLINK_NETFILTER)`
			`if err != nil {`
			`return err`
			`}`
			`q.nls = nls`
			`if q.debug {`
			`q.nls.SetFlag(nfnetlink.FlagDebug)`
			`}`

			`err = q.sendAll(`
			`q.nfqRequestConfigCmd(NFQNL_CFG_CMD_BIND, q.queue, 0),`
			`q.nfqRequestConfigParams(q.copySize, NFQNL_COPY_PACKET),`
			`)`
			`if err != nil {`
			`q.Close()`
			`return err`
			`}`
			`return nil`
			`}`

			`// Close this queue instance`
			`func (q *NFQueue) Close() {`
			`q.sendAll(`
			`q.nfqRequestConfigCmd(NFQNL_CFG_CMD_UNBIND, q.queue, 0),`
			`)`
			`q.nls.Close()`
			`}`

			`// sendAll sends a series of messages, returning the first error encountered if any.`
			`func (q NFQueue) sendAll(msgs ...nfnetlink.NfNlMessage) error {`
			`for _, m := range msgs {`
			`if err := m.Send(); err != nil {`
			`return err`
			`}`
			`}`
			`return nil`
			`}`

			`// Open this queue instance. Returns a channel for reading received packets.`
			`func (q NFQueue) Open() (<-chan NFQPacket, error) {`
			`if err := q.open(); err != nil {`
			`return nil, err`
			`}`
			`go q.receivePackets()`
			`return q.packets, nil`
			`}`

			`// receivePackets reads messages from the channel returned by NetlinkSocket.Receive and`
			`// processes them until the channel is closed. If an error occurs, this error is assigned to`
			`// q.pendingError`
			`func (q *NFQueue) receivePackets() {`
			`for m := range q.nls.Receive() {`
			`if err := q.processPacket(m); err != nil {`
			`q.pendingErr = err`
			`close(q.packets)`
			`return`
			`}`
			`}`
			`if q.nls.RecvErr() != nil {`
			`q.pendingErr = q.nls.RecvErr()`
			`}`
			`close(q.packets)`
			`}`

			`// PendingError returns the error that was encountered while receiving packets if any.`
			`func (q *NFQueue) PendingError() error {`
			`return q.pendingErr`
			`}`

			`// processPacket handles an incoming NfNlMessage which is assumed to contain a received packet.`
			`func (q NFQueue) processPacket(m nfnetlink.NfNlMessage) error {`
			`hdr := m.Attr(NFQA_PACKET_HDR)`
			`if hdr == nil {`
			`return fmt.Errorf("No NFQA_PACKET_HDR\n")`
			`}`
			`p := &NFQPacket{q: q}`
			`p.hMark = false`
			`hdr.ReadFields(&p.id, &p.HwProto)`
			`payload := m.Attr(NFQA_PAYLOAD)`
			`if payload != nil {`
			`p.Packet = gopacket.NewPacket(payload.Data, layers.LayerTypeIPv4,`
			`gopacket.DecodeOptions{Lazy: true, NoCopy: true})`
			`}`
			`if q.hwtrace {`
			`// fmt.Println("XXX: Hardware tracing on")`
			`hwpkt := m.Attr(NFQA_HWADDR)`
			`if hwpkt != nil {`
			`//fmt.Println("XXX: HW TRACE DATA: %v / %p", hwpkt.Data, p.hwAddr)`
			`p.hwAddr = hwpkt.Data`
			`}`
			`}// else { fmt.Println("XXX: NO HWTRACING ON") }`
			`q.packets <- p`
			`return nil`
			`}`

			`// nfqRequestConfigCmd creates an NFQNL_MSG_CONFIG message with a NFQA_CFG_COMMAND attribute for`
			`// the provided cmd, queue number, and protocol family.`
			`func (q NFQueue) nfqRequestConfigCmd(cmd uint8, queue uint16, pf uint16) nfnetlink.NfNlMessage {`
			`nr := q.nfqNewRequest(NFQNL_MSG_CONFIG, queue)`
			`nr.AddAttributeFields(NFQA_CFG_COMMAND, cmd, uint8(0), pf)`
			`return nr`
			`}`

			`// nfqRequestConfigParams creates an NFQNL_MSG_CONFIG message with a NFQA_CFG_PARAMS attribute for`
			`// the provided copyRange and copyMode values.`
			`func (q NFQueue) nfqRequestConfigParams(copyRange uint32, copyMode uint8) nfnetlink.NfNlMessage {`
			`nr := q.nfqNewRequest(NFQNL_MSG_CONFIG, q.queue)`
			`nr.AddAttributeFields(NFQA_CFG_PARAMS, copyRange, copyMode)`
			`return nr`
			`}`

			`// nfqRequestVerdictMark creates an NFQNL_MSG_VERDICT with the provided id and verdict values. If hasMark is set`
			`// an optional NFQA_MARK attribute will be included to set a mark on the packet with value mark`
			`func (q NFQueue) nfqRequestVerdictMark(verdict uint32, id uint32, hasMark bool, mark uint32) nfnetlink.NfNlMessage {`
			`nr := q.nfqNewRequest(NFQNL_MSG_VERDICT, q.queue)`
			`nr.AddAttributeFields(NFQA_VERDICT_HDR, verdict, id)`
			`if hasMark {`
			`nr.AddAttributeFields(NFQA_MARK, mark)`
			`}`
			`return nr`
			`}`

			`// nfqNewRequest creates a new message to the queue subsystem with the given type and queue number`
			`func (q NFQueue) nfqNewRequest(mtype uint8, queue uint16) nfnetlink.NfNlMessage {`
			`nlm := q.nls.NewNfNlMsg()`
			`nlm.Type = uint16((NFNL_SUBSYS_QUEUE << 8) \| uint16(mtype))`
			`nlm.Flags = syscall.NLM_F_REQUEST`
			`nlm.Family = syscall.AF_UNSPEC`
			`nlm.Version = nfnetlink.NFNETLINK_V0`
			`nlm.ResID = queue`
			`return nlm`
			`}`

			`// Drop sets the NF_DROP verdict on this packet`
			`func (p *NFQPacket) Drop() error {`
			`return p.verdict(NF_DROP)`
			`}`

			`// Accept sets the NF_ACCEPT verdict on this packet`
			`func (p *NFQPacket) Accept() error {`
			`return p.verdict(NF_ACCEPT)`
			`}`

			`// Set an optional mark to be set with the next verdict`
			`func (p *NFQPacket) SetMark(mark uint32) {`
			`p.mark = mark`
			`p.hMark = true`
			`}`

			`// verdict sends a NFQNL_MSG_VERDICT message for the packet id with the verdict value v`
			`func (p *NFQPacket) verdict(v uint32) error {`
			`return p.q.nfqRequestVerdictMark(v, p.id, p.hMark, p.mark).Send()`
			`}`

			`func (p *NFQPacket) GetHWAddr() ([]byte, error) {`
			`//fmt.Printf("XXX: hwaddr address = %p\n", p.hwAddr)`
			`if len(p.hwAddr) != 12 {`
			`//fmt.Println("XXX: length was: ", len(p.hwAddr))`
			`return nil, errors.New("Hardware data was unexpected length")`
			`}`

			`addrlen := int(binary.BigEndian.Uint16(p.hwAddr[0:2]))`

			`if len(p.hwAddr) < 4 + addrlen {`
			`return nil, errors.New("Hardware address overflow")`
			`}`

			`return p.hwAddr[addrlen:addrlen+4], nil`
			`}`