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SoftEtherVPN/src/Cedar/Proto_L2TP.h

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// SoftEther VPN Source Code - Developer Edition Master Branch
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// Cedar Communication Module
// Proto_L2TP.h
// Header of Proto_L2TP.c
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#ifndef PROTO_L2TP_H
#define PROTO_L2TP_H
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#include "CedarType.h"
#include "Mayaqua/Network.h"
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// Check the sequence number
#define L2TP_SEQ_LT(a, b) (((USHORT)(((USHORT)(a)) - ((USHORT)(b)))) & 0x8000)
#define L2TP_SEQ_EQ(a, b) ((USHORT)(a) == (USHORT)(b))
//// Constants
// Client string
#define L2TP_IPC_CLIENT_NAME_TAG "L2TP VPN Client - %s"
#define L2TP_IPC_CLIENT_NAME_NO_TAG "L2TP VPN Client"
#define L2TP_IPC_POSTFIX "L2TP"
// L2TP vendor name
#define L2TP_VENDOR_NAME "L2TP"
// L2TP packet retransmission interval
#define L2TP_PACKET_RESEND_INTERVAL 500
// Timeout for L2TP tunnel disconnecting completion
#define L2TP_TUNNEL_DISCONNECT_TIMEOUT 3000
// Timeout for L2TP session disconnection completion
#define L2TP_SESSION_DISCONNECT_TIMEOUT 3000
// Time-out interval of L2TP tunnel
#define L2TP_TUNNEL_TIMEOUT (60 * 1000)
// Transmission interval of L2TP Hello
#define L2TP_HELLO_INTERVAL (8801)
// Threshold number of registered items in the transmission queue for suppressing the L2TP Hello transmission
#define L2TP_HELLO_SUPRESS_MAX_THRETHORD_NUM_SEND_QUEUE 32
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// Quota
#define L2TP_QUOTA_MAX_NUM_TUNNELS_PER_IP 1000 // Number of L2TP sessions per IP address
#define L2TP_QUOTA_MAX_NUM_TUNNELS 30000 // Limit of the number of sessions
#define L2TP_QUOTA_MAX_NUM_SESSIONS_PER_TUNNEL 1024 // Max sessions in a tunnel
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// L2TP window size
#define L2TP_WINDOW_SIZE 16
// L2TP packet header bit mask
#define L2TP_HEADER_BIT_TYPE 0x80 // Type
#define L2TP_HEADER_BIT_LENGTH 0x40 // Length
#define L2TP_HEADER_BIT_SEQUENCE 0x08 // Sequence
#define L2TP_HEADER_BIT_OFFSET 0x02 // Offset
#define L2TP_HEADER_BIT_PRIORITY 0x01 // Priority
#define L2TP_HEADER_BIT_VER 0x0F // Version
// L2TP AVP header bit mask
#define L2TP_AVP_BIT_MANDATORY 0x80 // Mandatory
#define L2TP_AVP_BIT_HIDDEN 0x40 // Hidden
#define L2TP_AVP_LENGTH 0x3FF // Length
// AVP value
#define L2TP_AVP_TYPE_MESSAGE_TYPE 0 // Message Type
#define L2TP_AVP_TYPE_RESULT_CODE 1 // Result Code
#define L2TP_AVP_TYPE_PROTOCOL_VERSION 2 // Protocol Version
#define L2TP_AVP_TYPE_FRAME_CAP 3 // Framing Capabilities
#define L2TP_AVP_TYPE_BEARER_CAP 4 // Bearer Capabilities
#define L2TP_AVP_TYPE_TIE_BREAKER 5 // Tie Breaker
#define L2TP_AVP_TYPE_HOST_NAME 7 // Host Name
#define L2TP_AVP_TYPE_VENDOR_NAME 8 // Vendor Name
#define L2TP_AVP_TYPE_ASSIGNED_TUNNEL 9 // Assigned Tunnel
#define L2TP_AVP_TYPE_RECV_WINDOW_SIZE 10 // Receive Window Size
#define L2TP_AVP_TYPE_ASSIGNED_SESSION 14 // Assigned Session ID
#define L2TP_AVP_TYPE_CALL_SERIAL 15 // Call Serial Number
#define L2TP_AVP_TYPE_PPP_DISCONNECT_CAUSE 46 // PPP Disconnect Cause Code
#define L2TP_AVP_TYPE_V3_ROUTER_ID 60 // Router ID
#define L2TP_AVP_TYPE_V3_TUNNEL_ID 61 // Assigned Control Connection ID
#define L2TP_AVP_TYPE_V3_PW_CAP_LIST 62 // Pseudowire Capabilities List
#define L2TP_AVP_TYPE_V3_SESSION_ID_LOCAL 63 // Local Session ID
#define L2TP_AVP_TYPE_V3_SESSION_ID_REMOTE 64 // Remote Session ID
#define L2TP_AVP_TYPE_V3_PW_TYPE 68 // Pseudowire Type
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#define L2TP_AVP_TYPE_V3_CIRCUIT_STATUS 71
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// Message Type value
#define L2TP_MESSAGE_TYPE_SCCRQ 1 // Start-Control-Connection-Request
#define L2TP_MESSAGE_TYPE_SCCRP 2 // Start-Control-Connection-Reply
#define L2TP_MESSAGE_TYPE_SCCCN 3 // Start-Control-Connection-Connected
#define L2TP_MESSAGE_TYPE_STOPCCN 4 // Stop-Control-Connection-Notification
#define L2TP_MESSAGE_TYPE_HELLO 6 // Hello
#define L2TP_MESSAGE_TYPE_ICRQ 10 // Incoming-Call-Request
#define L2TP_MESSAGE_TYPE_ICRP 11 // Incoming-Call-Reply
#define L2TP_MESSAGE_TYPE_ICCN 12 // Incoming-Call-Connected
#define L2TP_MESSAGE_TYPE_CDN 14 // Call-Disconnect-Notify
// Type of L2TPv3 virtual network
#define L2TPV3_PW_TYPE_ETHERNET 5 // Ethernet
#define L2TPV3_PW_TYPE_ETHERNET_VLAN 4 // Ethernet VLAN
// L2TPv3 vendor unique value
#define L2TP_AVP_VENDOR_ID_CISCO 9 // Cisco Systems
#define L2TPV3_CISCO_AVP_TUNNEL_ID 1 // Assigned Connection ID
#define L2TPV3_CISCO_AVP_PW_CAP_LIST 2 // Pseudowire Capabilities List
#define L2TPV3_CISCO_AVP_SESSION_ID_LOCAL 3 // Local Session ID
#define L2TPV3_CISCO_AVP_SESSION_ID_REMOTE 4 // Remote Session ID
#define L2TPV3_CISCO_AVP_PW_TYPE 7 // Pseudowire Type
#define L2TPV3_CISCO_AVP_DRAFT_AVP_VERSION 10 // Draft AVP Version
//// Types
// L2TP queue
struct L2TP_QUEUE
{
BUF *Buf; // Data
USHORT Ns; // Sequence number
UINT64 NextSendTick; // Scheduled time to be sent next
L2TP_PACKET *L2TPPacket; // L2TP packet data
};
// L2TP AVP value
struct L2TP_AVP
{
bool Mandatory; // Force bit
UINT Length; // Overall length
USHORT VendorID; // Vendor ID
USHORT Type; // Type
UINT DataSize; // Data size
void *Data; // Data body
};
// L2TP packet
struct L2TP_PACKET
{
bool IsControl; // Whether it's a control message
bool HasLength; // Whether there is length bit
bool HasSequence; // Whether there is sequence bit
bool HasOffset; // Whether there is offset bit
bool IsPriority; // Whether priority packet
bool IsZLB; // Zero Length Bit
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bool IsYamahaV3; // L2TPv3 on YAMAHA
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UINT Ver; // Version
UINT Length; // Length
UINT TunnelId; // Tunnel ID
UINT SessionId; // Session ID
USHORT Ns, Nr; // Sequence number
UINT OffsetSize; // Offset size
UINT DataSize; // Data size
void *Data; // Data body
LIST *AvpList; // AVP list
UINT MessageType; // Message type
};
// L2TP session
struct L2TP_SESSION
{
L2TP_TUNNEL *Tunnel; // Parent L2TP tunnel
bool IsV3; // L2TPv3
bool IsCiscoV3; // L2TPv3 for Cisco
UINT SessionId1; // Session ID (server -> client direction)
UINT SessionId2; // Session ID (client -> server direction)
bool Established; // Established
bool WantToDisconnect; // Whether to want to disconnect
bool Disconnecting; // Whether disconnected
UINT64 DisconnectTimeout; // Disconnection completion time-out
bool HasThread; // Whether have a thread
THREAD *Thread; // Thread
PPP_SESSION* PPPSession; // Underlying PPP session
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TUBE *TubeSend; // Tube of PPP to L2TP direction
TUBE *TubeRecv; // Tube of L2TP to PPP direction
UINT PseudowireType; // Type of L2TPv3 virtual line
ETHERIP_SERVER *EtherIP; // EtherIP server
};
// L2TP tunnel
struct L2TP_TUNNEL
{
bool IsV3; // L2TPv3
bool IsCiscoV3; // L2TPv3 for Cisco
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bool IsYamahaV3; // L2TPv3 for YAMAHA
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IP ClientIp; // Client IP address
UINT ClientPort; // Client port number
IP ServerIp; // Server IP address
UINT ServerPort; // Server port number
UINT TunnelId1; // Tunnel ID (server -> client direction)
UINT TunnelId2; // Tunnel ID (client -> server direction)
char HostName[MAX_SIZE]; // Destination host name
char VendorName[MAX_SIZE]; // Destination vendor name
LIST *SessionList; // L2TP session list
LIST *SendQueue; // Transmission queue
LIST *RecvQueue; // Reception queue
USHORT NextNs; // Value of Ns of the packet to be sent next
USHORT LastNr; // Value of NR received in the last
bool Established; // Whether the tunnel is established
bool StateChanged; // Whether the state have changed
bool WantToDisconnect; // Whether to want to disconnect
bool Disconnecting; // Whether disconnected
UINT64 DisconnectTimeout; // Disconnection completion time-out
UINT64 LastRecvTick; // Time which the data has been received at last
bool Timedout; // Whether the time-out
UINT64 LastHelloSent; // Time which the data has been sent at last
};
// L2TP server
struct L2TP_SERVER
{
CEDAR *Cedar;
UINT64 Now; // Current time
LIST *SendPacketList; // Transmission packet
LIST *TunnelList; // Tunnel list
INTERRUPT_MANAGER *Interrupts; // Interrupt manager
SOCK_EVENT *SockEvent; // SockEvent
bool Halt; // Start the shutdown
bool Halting; // During shutdown
bool HaltCompleted; // Shutdown is complete
EVENT *HaltCompletedEvent; // Stopping completion event
LIST *ThreadList; // Thread list
char CryptName[MAX_SIZE]; // Cipher algorithm name
IKE_SERVER *IkeServer; // IKE server (Only if associated)
IKE_CLIENT *IkeClient; // IKE client (Only if associated)
bool IsIPsecIPv6; // Whether it's IPv6
UINT CryptBlockSize; // Cipher block size of the upper layer
TUBE_FLUSH_LIST *FlushList; // Tube Flush List
};
//// Function prototype
L2TP_SERVER *NewL2TPServer(CEDAR *cedar);
L2TP_SERVER *NewL2TPServerEx(CEDAR *cedar, IKE_SERVER *ike, bool is_ipv6, UINT crypt_block_size);
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UINT GetNumL2TPTunnelsByClientIP(L2TP_SERVER *l2tp, IP *client_ip);
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void SetL2TPServerSockEvent(L2TP_SERVER *l2tp, SOCK_EVENT *e);
void FreeL2TPServer(L2TP_SERVER *l2tp);
void StopL2TPServer(L2TP_SERVER *l2tp, bool no_wait);
void ProcL2TPPacketRecv(L2TP_SERVER *l2tp, UDPPACKET *p);
L2TP_PACKET *ParseL2TPPacket(UDPPACKET *p);
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BUF *BuildL2TPPacketData(L2TP_PACKET *pp, L2TP_TUNNEL *t);
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L2TP_AVP *GetAVPValue(L2TP_PACKET *p, UINT type);
L2TP_AVP *GetAVPValueEx(L2TP_PACKET *p, UINT type, UINT vendor_id);
L2TP_TUNNEL *NewL2TPTunnel(L2TP_SERVER *l2tp, L2TP_PACKET *p, UDPPACKET *udp);
UINT GenerateNewTunnelId(L2TP_SERVER *l2tp, IP *client_ip);
UINT GenerateNewTunnelIdEx(L2TP_SERVER *l2tp, IP *client_ip, bool is_32bit);
void FreeL2TPTunnel(L2TP_TUNNEL *t);
L2TP_TUNNEL *GetTunnelFromId(L2TP_SERVER *l2tp, IP *client_ip, UINT tunnel_id, bool is_v3);
L2TP_TUNNEL *GetTunnelFromIdOfAssignedByClient(L2TP_SERVER *l2tp, IP *client_ip, UINT tunnel_id);
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L2TP_TUNNEL *GetTunnelFromIdOfAssignedByClientEx(L2TP_SERVER *l2tp, IP *client_ip, UINT tunnel_id, bool is_v3);
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void SendL2TPControlPacket(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, UINT session_id, L2TP_PACKET *p);
void SendL2TPControlPacketMain(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_QUEUE *q);
void SendL2TPDataPacket(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_SESSION *s, void *data, UINT size);
void FreeL2TPQueue(L2TP_QUEUE *q);
void L2TPAddInterrupt(L2TP_SERVER *l2tp, UINT64 next_tick);
void L2TPSendUDP(L2TP_SERVER *l2tp, UDPPACKET *p);
void L2TPProcessInterrupts(L2TP_SERVER *l2tp);
L2TP_PACKET *NewL2TPControlPacket(UINT message_type, bool is_v3);
L2TP_AVP *NewAVP(USHORT type, bool mandatory, USHORT vendor_id, void *data, UINT data_size);
int CmpL2TPQueueForRecv(void *p1, void *p2);
void L2TPProcessRecvControlPacket(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_PACKET *p);
L2TP_SESSION *GetSessionFromId(L2TP_TUNNEL *t, UINT session_id);
L2TP_SESSION *GetSessionFromIdAssignedByClient(L2TP_TUNNEL *t, UINT session_id);
L2TP_SESSION *NewL2TPSession(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, UINT session_id_by_client);
UINT GenerateNewSessionId(L2TP_TUNNEL *t);
UINT GenerateNewSessionIdEx(L2TP_TUNNEL *t, bool is_32bit);
void FreeL2TPSession(L2TP_SESSION *s);
void DisconnectL2TPSession(L2TP_TUNNEL *t, L2TP_SESSION *s);
void DisconnectL2TPTunnel(L2TP_TUNNEL *t);
void StartL2TPThread(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_SESSION *s);
void StopL2TPThread(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_SESSION *s);
UINT CalcL2TPMss(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_SESSION *s);
UINT GenerateNewSessionIdForL2TPv3(L2TP_SERVER *l2tp);
L2TP_SESSION *SearchL2TPSessionById(L2TP_SERVER *l2tp, bool is_v3, UINT id);
void L2TPSessionManageEtherIPServer(L2TP_SERVER *l2tp, L2TP_SESSION *s);
#endif // PROTO_L2TP_H