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package lifx
import ( "context" "encoding/binary" "errors" "git.aiterp.net/lucifer/new-server/models" "log" "math/rand" "net" "sync" "sync/atomic" "time")
type Client struct { mu sync.Mutex seq uint8 buf []byte lastN int
conn *net.UDPConn source uint32 debug bool
isHorrible uint32
addrMap map[string]*net.UDPAddr}
// Send sends the payload to the hardware addr specified. If it cannot find a mapped
// IP address from a past message, it will be broadcast and may be slow to use. If the
// address is left blank, the package is marked as tagged and broadcast.
//
// ErrInvalidAddress can be returned by this, and indicates a badly configured device.
// It should probably be logged.
func (c *Client) Send(addr string, payload Payload) (seq uint8, err error) { c.mu.Lock() seq = c.seq c.seq += 1 c.mu.Unlock()
packet := createPacket() packet.SetSource(c.source) packet.SetSequence(seq)
sendAddr := &net.UDPAddr{IP: net.IPv4(255, 255, 255, 255), Port: 56700} if addr == "" { packet.SetTagged(true)
if c.debug { log.Println("Broadcasting", payload, "seq", seq) } } else { err = packet.SetTarget(addr) if err != nil { return }
c.mu.Lock() if udpAddr, ok := c.addrMap[addr]; ok { sendAddr = udpAddr } c.mu.Unlock()
if c.debug { log.Println("Sending", payload, "to", addr, "seq", seq) } }
packet.SetPayload(payload)
_, err = c.conn.WriteToUDP(packet, sendAddr) if err != nil { return }
return}
// HorribleBroadcast "broadcasts" by blasting every IP address in the space with a tagged packet, because LIFX is LIFX.
func (c *Client) HorribleBroadcast(ctx context.Context, payload Payload) (seq uint8, err error) { c.mu.Lock() seq = c.seq c.seq += 1 c.mu.Unlock()
defer atomic.StoreUint32(&c.isHorrible, 0)
packet := createPacket() packet.SetSource(c.source) packet.SetSequence(seq) packet.SetPayload(payload) packet.SetTagged(true)
ifaces, err := net.Interfaces() if err != nil { return 0, err }
connIP := c.conn.LocalAddr().(*net.UDPAddr).IP
var minIPNum uint32 var maxIPNum uint32 for _, iface := range ifaces { addrs, err := iface.Addrs() if err != nil { continue }
for _, addr := range addrs { naddr, ok := addr.(*net.IPNet) if !ok || !naddr.Contains(connIP) { continue }
networkAddress := naddr.IP.Mask(naddr.Mask) cidr, bits := naddr.Mask.Size() minIPNum = binary.BigEndian.Uint32(networkAddress) + 1 maxIPNum = minIPNum + (1 << (bits - cidr)) - 2
break } } if minIPNum == maxIPNum { return } myIPNum := binary.BigEndian.Uint32(connIP)
if c.debug { ipBuf := make(net.IP, 8) binary.BigEndian.PutUint32(ipBuf, minIPNum) binary.BigEndian.PutUint32(ipBuf[4:], maxIPNum-1)
log.Println("Sending tagged", payload, "to range", ipBuf[:4], "-", ipBuf[4:])
defer func() { log.Println("Completed sending tagged", payload, "to range", ipBuf[:4], "-", ipBuf[4:]) }() }
for ipNum := minIPNum; ipNum < maxIPNum; ipNum++ { if ipNum == myIPNum { continue }
atomic.StoreUint32(&c.isHorrible, 1)
ipBuf := make(net.IP, 4) binary.BigEndian.PutUint32(ipBuf, ipNum) addr := &net.UDPAddr{IP: ipBuf, Port: 56700}
_, err = c.conn.WriteToUDP(packet, addr) if err != nil { if c.debug { log.Println("HorribleBroadcast™ aborted by error.") }
return }
if ipNum%256 == 0 { if c.debug { log.Println("Progress:", (ipNum-minIPNum)+1, "of", maxIPNum-minIPNum) }
time.Sleep(time.Millisecond * 100) }
if ctx.Err() != nil { if c.debug { log.Println("HorribleBroadcast™ aborted at call site.") }
return } }
return}
// LastPacket gets the last read packet. This data is valid until the next call to Recv. The Packet may
// not be valid, however!
func (c *Client) LastPacket() Packet { if c.lastN < 36 { return nil }
return c.buf[:c.lastN]}
// Recv reads a message from the UDP socket. The data returned is decoded and will always be valid.
//
// However, these should be handled specifically:
// - ErrPayloadTooShort, ErrInvalidPacketSize: Garbage was received, please ignore.
// - ErrUnrecognizedPacketType: Log these and see what's up
// - ErrReadTimeout: The connection gets a 50ms read deadline. It should be used to do other things than wait
func (c *Client) Recv(timeout time.Duration) (target string, seq uint8, payload Payload, err error) { if c.buf == nil { c.buf = make([]byte, 2048) }
if timeout > 0 { err = c.conn.SetReadDeadline(time.Now().Add(timeout)) } else { err = c.conn.SetReadDeadline(time.Time{}) } if err != nil { return }
n, addr, err := c.conn.ReadFromUDP(c.buf) if n > 0 { c.lastN = n } if err != nil { if netErr, ok := err.(*net.OpError); ok && netErr.Timeout() { err = models.ErrReadTimeout return }
return }
packet := Packet(c.buf[:n]) if n < 2 || packet.Size() != n && packet.Protocol() != 1024 { err = models.ErrInvalidAddress return }
seq = packet.Sequence() target = packet.Target().String()
payload, err = packet.Payload() if err != nil { return }
// Learn the IP address from state service or ack messages.
if service, ok := payload.(*StateService); ok && service.Service == 1 { c.mu.Lock() if c.addrMap == nil { c.addrMap = make(map[string]*net.UDPAddr) } c.addrMap[packet.Target().String()] = addr c.mu.Unlock() }
if c.debug { log.Println("Received", payload, "from", target, "seq", seq) }
return}
// createClient creates a client that will last as long as the context.
func createClient(ctx context.Context, bindAddr string, debug bool) (*Client, error) { addr := net.ParseIP(bindAddr) if addr == nil { return nil, errors.New("invalid addr") }
source := uint32(rand.Uint64()) if source < 2 { source = 2 }
conn, err := net.ListenUDP("udp", &net.UDPAddr{ IP: addr, Port: 0, Zone: "", }) if err != nil { return nil, err }
_ = conn.SetWriteBuffer(2048 * 1024)
go func() { <-ctx.Done() _ = conn.Close() }()
return &Client{conn: conn, source: source, debug: debug}, nil}
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