// SoftEther VPN Source Code - Developer Edition Master Branch // Cedar Communication Module // Proto_L2TP.c // L2TP protocol stack #include "Proto_L2TP.h" #include "Connection.h" #include "Logging.h" #include "Proto_EtherIP.h" #include "Proto_IKE.h" #include "Proto_IPsec.h" #include "Proto_PPP.h" #include "Mayaqua/Memory.h" #include "Mayaqua/Network.h" #include "Mayaqua/Object.h" #include "Mayaqua/Str.h" #include "Mayaqua/TcpIp.h" // Release the L2TP AVP value void FreeL2TPAVP(L2TP_AVP *a) { // Validate arguments if (a == NULL) { return; } if (a->Data != NULL) { Free(a->Data); } Free(a); } // Release the L2TP packet void FreeL2TPPacket(L2TP_PACKET *p) { UINT i; // Validate arguments if (p == NULL) { return; } if (p->AvpList != NULL) { for (i = 0;i < LIST_NUM(p->AvpList);i++) { L2TP_AVP *a = LIST_DATA(p->AvpList, i); FreeL2TPAVP(a); } ReleaseList(p->AvpList); } if (p->Data != NULL) { Free(p->Data); } Free(p); } // Send an L2TP control packet void SendL2TPControlPacket(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, UINT session_id, L2TP_PACKET *p) { BUF *buf; L2TP_QUEUE *q; // Validate arguments if (l2tp == NULL || t == NULL || p == NULL) { return; } p->IsControl = true; p->TunnelId = t->TunnelId1; p->SessionId = session_id; p->Ns = t->NextNs; t->NextNs++; p->Nr = t->LastNr + 1; buf = BuildL2TPPacketData(p, t); q = ZeroMalloc(sizeof(L2TP_QUEUE)); q->Buf = buf; q->Ns = p->Ns; q->NextSendTick = l2tp->Now + (UINT64)L2TP_PACKET_RESEND_INTERVAL; SendL2TPControlPacketMain(l2tp, t, q); L2TPAddInterrupt(l2tp, q->NextSendTick); Add(t->SendQueue, q); } // Specify the interrupt occurrence time of the next void L2TPAddInterrupt(L2TP_SERVER *l2tp, UINT64 next_tick) { // Validate arguments if (l2tp == NULL || next_tick == 0) { return; } AddInterrupt(l2tp->Interrupts, next_tick); } // Send a L2TP data packet void SendL2TPDataPacket(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_SESSION *s, void *data, UINT size) { UDPPACKET *p; UCHAR *buf; UINT buf_size; // Validate arguments if (l2tp == NULL || t == NULL || s == NULL || (size != 0 && data == NULL)) { return; } // Build a L2TP data packet if (s->IsV3 == false) { // L2TP Ver 2 buf_size = 8 + size; buf = Malloc(buf_size); buf[0] = 0x40; buf[1] = 0x02; WRITE_USHORT(buf + 2, buf_size); WRITE_USHORT(buf + 4, t->TunnelId1); WRITE_USHORT(buf + 6, s->SessionId1); Copy(buf + 8, data, size); // Transmission p = NewUdpPacket(&t->ServerIp, t->ServerPort, &t->ClientIp, t->ClientPort, buf, buf_size); } else { // L2TPv3 if (t->IsYamahaV3 == false) { buf_size = 4 + size; buf = Malloc(buf_size); WRITE_UINT(buf, s->SessionId1); Copy(buf + 4, data, size); // Transmission p = NewUdpPacket(&t->ServerIp, IPSEC_PORT_L2TPV3_VIRTUAL, &t->ClientIp, IPSEC_PORT_L2TPV3_VIRTUAL, buf, buf_size); } else { UINT header = 0x00030000; buf_size = 8 + size; buf = Malloc(buf_size); WRITE_UINT(buf, header); WRITE_UINT(buf + 4, s->SessionId1); Copy(buf + 8, data, size); // Transmission p = NewUdpPacket(&t->ServerIp, t->ServerPort, &t->ClientIp, t->ClientPort, buf, buf_size); } } L2TPSendUDP(l2tp, p); } // L2TP packet transmission main void SendL2TPControlPacketMain(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_QUEUE *q) { UDPPACKET *p; // Validate arguments if (l2tp == NULL || t == NULL || q == NULL) { return; } p = NewUdpPacket(&t->ServerIp, t->ServerPort, &t->ClientIp, t->ClientPort, Clone(q->Buf->Buf, q->Buf->Size), q->Buf->Size); // Update the received sequence number WRITE_USHORT(((UCHAR *)p->Data) + (p->SrcPort == IPSEC_PORT_L2TPV3_VIRTUAL ? 14 : 10), t->LastNr + 1); L2TPSendUDP(l2tp, p); } // Send a UDP packet void L2TPSendUDP(L2TP_SERVER *l2tp, UDPPACKET *p) { // Validate arguments if (l2tp == NULL || p == NULL) { return; } Add(l2tp->SendPacketList, p); } // Build a L2TP packet BUF *BuildL2TPPacketData(L2TP_PACKET *pp, L2TP_TUNNEL *t) { BUF *ret; UCHAR c; USHORT us; UINT ui; // Validate arguments if (pp == NULL || t == NULL) { return NULL; } ret = NewBuf(); c = 0; if (pp->Ver == 3) { if (pp->SessionId != 0) { // Add the Remote Session ID AVP L2TP_AVP *a = GetAVPValue(pp, L2TP_AVP_TYPE_V3_SESSION_ID_REMOTE); if (a == NULL || a->DataSize != sizeof(UINT)) { UINT ui = Endian32(pp->SessionId); Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_V3_SESSION_ID_REMOTE, true, 0, &ui, sizeof(UINT))); if (GetAVPValueEx(pp, L2TPV3_CISCO_AVP_SESSION_ID_LOCAL, L2TP_AVP_VENDOR_ID_CISCO) != NULL) { Add(pp->AvpList, NewAVP(L2TPV3_CISCO_AVP_SESSION_ID_REMOTE, true, L2TP_AVP_VENDOR_ID_CISCO, &ui, sizeof(UINT))); } } } } if (pp->Ver == 3) { if (t->IsYamahaV3 == false) { // Zero as Session ID ui = 0; WriteBuf(ret, &ui, sizeof(UINT)); } } // Flags if (pp->IsControl) { c |= L2TP_HEADER_BIT_TYPE; c |= L2TP_HEADER_BIT_LENGTH; c |= L2TP_HEADER_BIT_SEQUENCE; } else { c |= L2TP_HEADER_BIT_OFFSET; } if (pp->IsControl == false && pp->Ver == 3 && t->IsYamahaV3) { c = 0; } WriteBuf(ret, &c, 1); // Ver c = 2; if (pp->Ver == 3) { c = 3; } WriteBuf(ret, &c, 1); // Length if (pp->IsControl) { us = 0; WriteBuf(ret, &us, sizeof(USHORT)); } // Reserved if (pp->IsControl == false && pp->Ver == 3 && t->IsYamahaV3) { us = 0; WriteBuf(ret, &us, sizeof(USHORT)); } // Tunnel ID if (pp->Ver != 3) { us = Endian16((USHORT)pp->TunnelId); WriteBuf(ret, &us, sizeof(USHORT)); } else { ui = Endian32(pp->TunnelId); WriteBuf(ret, &ui, sizeof(UINT)); } // Session ID if (pp->Ver != 3) { us = Endian16((USHORT)pp->SessionId); WriteBuf(ret, &us, sizeof(USHORT)); } if (pp->IsControl) { // Ns us = Endian16(pp->Ns); WriteBuf(ret, &us, sizeof(USHORT)); // Nr us = Endian16(pp->Nr); WriteBuf(ret, &us, sizeof(USHORT)); } else { if (!(pp->IsControl == false && pp->Ver == 3 && t->IsYamahaV3)) { // Offset Size = 0 us = 0; WriteBuf(ret, &us, sizeof(USHORT)); } } if (pp->IsControl) { // AVP UINT i; for (i = 0;i < LIST_NUM(pp->AvpList);i++) { L2TP_AVP *a = LIST_DATA(pp->AvpList, i); // Length and Flags us = Endian16(a->DataSize + 6); if (a->Mandatory) { *((UCHAR *)&us) |= L2TP_AVP_BIT_MANDATORY; } WriteBuf(ret, &us, sizeof(USHORT)); // Vendor ID us = Endian16(a->VendorID); WriteBuf(ret, &us, sizeof(USHORT)); // Type us = Endian16(a->Type); WriteBuf(ret, &us, sizeof(USHORT)); // Data WriteBuf(ret, a->Data, a->DataSize); } } else { // Payload WriteBuf(ret, pp->Data, pp->DataSize); } if (pp->IsControl) { // Update Length bool l2tpv3_non_yamaha = ((pp->Ver == 3) && (t->IsYamahaV3 == false)); WRITE_USHORT(((UCHAR *)ret->Buf) + 2 + (l2tpv3_non_yamaha ? sizeof(UINT) : 0), (USHORT)(ret->Size - (l2tpv3_non_yamaha ? sizeof(UINT) : 0))); } SeekBuf(ret, 0, 0); return ret; } // Parse the L2TP packet L2TP_PACKET *ParseL2TPPacket(UDPPACKET *p) { L2TP_PACKET *ret; UCHAR *buf; UINT size; bool is_l2tpv3 = false; bool is_l2tpv3_yamaha = false; // Validate arguments if (p == NULL) { return NULL; } ret = ZeroMalloc(sizeof(L2TP_PACKET)); if (p->SrcPort == IPSEC_PORT_L2TPV3_VIRTUAL) { // L2TPv3 (Cisco) is_l2tpv3 = true; } buf = p->Data; size = p->Size; if (size >= 2 && ((buf[1] & L2TP_HEADER_BIT_VER) == 3)) { if (p->SrcPort != IPSEC_PORT_L2TPV3_VIRTUAL) { // L2TPv3 (YAMAHA) is_l2tpv3 = true; is_l2tpv3_yamaha = true; } } if (is_l2tpv3 && (is_l2tpv3_yamaha == false)) { // L2TPv3 (Cisco) UINT session_id; if (size < 4) { goto LABEL_ERROR; } session_id = READ_UINT(buf); if (session_id != 0) { // L2TPv3 data packet reception ret->SessionId = session_id; buf += sizeof(UINT); size -= sizeof(UINT); ret->Data = Clone(buf, size); ret->DataSize = size; ret->Ver = 3; return ret; } else { // L2TPv3 control packet reception buf += sizeof(UINT); size -= sizeof(UINT); } } // L2TP if (size < 6) { goto LABEL_ERROR; } if (*buf & L2TP_HEADER_BIT_TYPE) { ret->IsControl = true; } if (*buf & L2TP_HEADER_BIT_LENGTH) { ret->HasLength = true; } if (*buf & L2TP_HEADER_BIT_SEQUENCE) { ret->HasSequence = true; } if (is_l2tpv3 == false) { if (*buf & L2TP_HEADER_BIT_OFFSET) { ret->HasOffset = true; } if (*buf & L2TP_HEADER_BIT_PRIORITY) { ret->IsPriority = true; } } buf++; size--; ret->Ver = *buf & L2TP_HEADER_BIT_VER; buf++; size--; if (is_l2tpv3 == false) { // L2TP if (ret->Ver != 2) { goto LABEL_ERROR; } } else { // L2TPv3 if (ret->Ver != 3) { goto LABEL_ERROR; } } if (ret->IsControl) { if (ret->HasLength == false || ret->HasSequence == false) { goto LABEL_ERROR; } } else { /*if (ret->HasSequence) { goto LABEL_ERROR; }*/ } if (ret->HasLength) { // Length if (size < 2) { goto LABEL_ERROR; } ret->Length = READ_USHORT(buf); buf += 2; size -= 2; if (size < (ret->Length - 4)) { goto LABEL_ERROR; } size = ret->Length - 4; } if (is_l2tpv3) { if (p->SrcPort != IPSEC_PORT_L2TPV3_VIRTUAL) { if (ret->IsControl == false) { // Reserved if (size < 2) { goto LABEL_ERROR; } buf += 2; size -= 2; } } } // Tunnel ID, Session ID if (size < 4) { goto LABEL_ERROR; } if (is_l2tpv3 == false) { // L2TP ret->TunnelId = READ_USHORT(buf); buf += 2; size -= 2; ret->SessionId = READ_USHORT(buf); buf += 2; size -= 2; } else { // L2TPv3: Only tunnel ID is written in the header ret->TunnelId = READ_UINT(buf); buf += 4; size -= 4; // The session ID is not written in the header ret->SessionId = 0; if (ret->IsControl == false) { ret->SessionId = ret->TunnelId; } } if (ret->HasSequence) { // Ns, Nr if (size < 4) { goto LABEL_ERROR; } ret->Ns = READ_USHORT(buf); buf += 2; size -= 2; ret->Nr = READ_USHORT(buf); buf += 2; size -= 2; } if (ret->HasOffset) { // Offset if (size < 2) { goto LABEL_ERROR; } ret->OffsetSize = READ_USHORT(buf); buf += 2; size -= 2; if (size < ret->OffsetSize) { goto LABEL_ERROR; } buf += ret->OffsetSize; size -= ret->OffsetSize; } ret->DataSize = size; ret->Data = Clone(buf, ret->DataSize); if (ret->IsControl == false) { if (ret->DataSize == 0) { goto LABEL_ERROR; } } if (ret->IsControl) { if (ret->DataSize == 0) { ret->IsZLB = true; } } if (ret->IsControl) { ret->AvpList = NewListFast(NULL); // Parse the AVP field while (size != 0) { L2TP_AVP a; Zero(&a, sizeof(a)); // Header if (size < 6) { goto LABEL_ERROR; } if (*buf & L2TP_AVP_BIT_MANDATORY) { a.Mandatory = true; } if (*buf & L2TP_AVP_BIT_HIDDEN) { goto LABEL_ERROR; } a.Length = READ_USHORT(buf) & L2TP_AVP_LENGTH; if (a.Length < 6) { goto LABEL_ERROR; } buf += 2; size -= 2; a.VendorID = READ_USHORT(buf); buf += 2; size -= 2; a.Type = READ_USHORT(buf); buf += 2; size -= 2; a.DataSize = a.Length - 6; if (a.DataSize > size) { goto LABEL_ERROR; } a.Data = Clone(buf, a.DataSize); buf += a.DataSize; size -= a.DataSize; Add(ret->AvpList, Clone(&a, sizeof(a))); } } if (ret->IsControl && ret->IsZLB == false) { // Get the MessageType in the case of Control packet L2TP_AVP *a = GetAVPValue(ret, L2TP_AVP_TYPE_MESSAGE_TYPE); if (a == NULL || a->DataSize != 2) { goto LABEL_ERROR; } ret->MessageType = READ_USHORT(a->Data); } if (ret->Ver == 3 && ret->IsControl) { // Get the Remote Session ID in the case of L2TPv3 L2TP_AVP *a = GetAVPValue(ret, L2TP_AVP_TYPE_V3_SESSION_ID_REMOTE); if (a != NULL && a->DataSize == sizeof(UINT)) { ret->SessionId = READ_UINT(a->Data); } } ret->IsYamahaV3 = is_l2tpv3_yamaha; return ret; LABEL_ERROR: FreeL2TPPacket(ret); return NULL; } // Get the AVP value L2TP_AVP *GetAVPValue(L2TP_PACKET *p, UINT type) { return GetAVPValueEx(p, type, 0); } L2TP_AVP *GetAVPValueEx(L2TP_PACKET *p, UINT type, UINT vendor_id) { UINT i; // Validate arguments if (p == NULL) { return NULL; } for (i = 0;i < LIST_NUM(p->AvpList);i++) { L2TP_AVP *a = LIST_DATA(p->AvpList, i); if (a->Type == type && a->VendorID == vendor_id) { return a; } } if (vendor_id == 0) { if (type == L2TP_AVP_TYPE_V3_TUNNEL_ID) { return GetAVPValueEx(p, L2TPV3_CISCO_AVP_TUNNEL_ID, L2TP_AVP_VENDOR_ID_CISCO); } else if (type == L2TP_AVP_TYPE_V3_SESSION_ID_LOCAL) { return GetAVPValueEx(p, L2TPV3_CISCO_AVP_SESSION_ID_LOCAL, L2TP_AVP_VENDOR_ID_CISCO); } else if (type == L2TP_AVP_TYPE_V3_SESSION_ID_REMOTE) { return GetAVPValueEx(p, L2TPV3_CISCO_AVP_SESSION_ID_REMOTE, L2TP_AVP_VENDOR_ID_CISCO); } } return NULL; } // Release the L2TP transmission queue void FreeL2TPQueue(L2TP_QUEUE *q) { // Validate arguments if (q == NULL) { return; } FreeBuf(q->Buf); FreeL2TPPacket(q->L2TPPacket); Free(q); } // Sort function of L2TP reception queue int CmpL2TPQueueForRecv(void *p1, void *p2) { L2TP_QUEUE *q1, *q2; // Validate arguments if (p1 == NULL || p2 == NULL) { return 0; } q1 = *(L2TP_QUEUE **)p1; q2 = *(L2TP_QUEUE **)p2; if (q1 == NULL || q2 == NULL) { return 0; } if (L2TP_SEQ_LT(q1->Ns, q2->Ns)) { return -1; } else if (q1->Ns == q2->Ns) { return 0; } else { return 1; } } // Create a L2TP tunnel L2TP_TUNNEL *NewL2TPTunnel(L2TP_SERVER *l2tp, L2TP_PACKET *p, UDPPACKET *udp) { L2TP_TUNNEL *t; L2TP_AVP *a; // Validate arguments if (l2tp == NULL || p == NULL || udp == NULL) { return NULL; } t = ZeroMalloc(sizeof(L2TP_TUNNEL)); if (p->Ver == 3) { t->IsV3 = true; } t->SessionList = NewList(NULL); Copy(&t->ClientIp, &udp->SrcIP, sizeof(IP)); t->ClientPort = udp->SrcPort; Copy(&t->ServerIp, &udp->DstIP, sizeof(IP)); t->ServerPort = udp->DestPort; // Hostname a = GetAVPValue(p, L2TP_AVP_TYPE_HOST_NAME); if (a != NULL && a->DataSize >= 1 && a->DataSize < sizeof(t->HostName)) { Copy(t->HostName, a->Data, a->DataSize); } else { IPToStr(t->HostName, sizeof(t->HostName), &t->ClientIp); } // Vendor Name a = GetAVPValue(p, L2TP_AVP_TYPE_VENDOR_NAME); if (a != NULL && a->DataSize >= 1 && a->DataSize < sizeof(t->VendorName)) { Copy(t->VendorName, a->Data, a->DataSize); } // Assigned Tunnel ID a = GetAVPValue(p, (p->Ver == 3 ? L2TP_AVP_TYPE_V3_TUNNEL_ID : L2TP_AVP_TYPE_ASSIGNED_TUNNEL)); if (a == NULL || a->DataSize != (t->IsV3 ? sizeof(UINT) : sizeof(USHORT))) { goto LABEL_ERROR; } t->TunnelId1 = (t->IsV3 ? READ_UINT(a->Data) : READ_USHORT(a->Data)); t->TunnelId2 = GenerateNewTunnelIdEx(l2tp, &t->ClientIp, t->IsV3); if (t->TunnelId2 == 0) { goto LABEL_ERROR; } if (p->Ver == 3) { // Identify whether it's Cisco a = GetAVPValueEx(p, L2TPV3_CISCO_AVP_TUNNEL_ID, L2TP_AVP_VENDOR_ID_CISCO); if (a != NULL) { t->IsCiscoV3 = true; } // L2TPv3 on YAMAHA t->IsYamahaV3 = p->IsYamahaV3; } // Transmission queue t->SendQueue = NewList(NULL); // Reception queue t->RecvQueue = NewList(CmpL2TPQueueForRecv); t->LastRecvTick = l2tp->Now; t->LastHelloSent = l2tp->Now; return t; LABEL_ERROR: FreeL2TPTunnel(t); return NULL; } // Search a tunnel L2TP_TUNNEL *GetTunnelFromId(L2TP_SERVER *l2tp, IP *client_ip, UINT tunnel_id, bool is_v3) { UINT i; // Validate arguments if (l2tp == NULL || client_ip == 0 || tunnel_id == 0) { return NULL; } for (i = 0;i < LIST_NUM(l2tp->TunnelList);i++) { L2TP_TUNNEL *t = LIST_DATA(l2tp->TunnelList, i); if (t->TunnelId2 == tunnel_id && CmpIpAddr(&t->ClientIp, client_ip) == 0) { if (EQUAL_BOOL(t->IsV3, is_v3)) { return t; } } } return NULL; } // Search the tunnel by the tunnel ID that is assigned by the client L2TP_TUNNEL *GetTunnelFromIdOfAssignedByClient(L2TP_SERVER *l2tp, IP *client_ip, UINT tunnel_id) { UINT i; // Validate arguments if (l2tp == NULL || client_ip == 0 || tunnel_id == 0) { return NULL; } for (i = 0;i < LIST_NUM(l2tp->TunnelList);i++) { L2TP_TUNNEL *t = LIST_DATA(l2tp->TunnelList, i); if (t->TunnelId1 == tunnel_id && CmpIpAddr(&t->ClientIp, client_ip) == 0) { return t; } } return NULL; } L2TP_TUNNEL *GetTunnelFromIdOfAssignedByClientEx(L2TP_SERVER *l2tp, IP *client_ip, UINT tunnel_id, bool is_v3) { UINT i; // Validate arguments if (l2tp == NULL || client_ip == 0 || tunnel_id == 0) { return NULL; } for (i = 0;i < LIST_NUM(l2tp->TunnelList);i++) { L2TP_TUNNEL *t = LIST_DATA(l2tp->TunnelList, i); if (t->TunnelId1 == tunnel_id && CmpIpAddr(&t->ClientIp, client_ip) == 0) { if (EQUAL_BOOL(t->IsV3, is_v3)) { return t; } } } return NULL; } // Create a new tunnel ID UINT GenerateNewTunnelId(L2TP_SERVER *l2tp, IP *client_ip) { return GenerateNewTunnelIdEx(l2tp, client_ip, false); } UINT GenerateNewTunnelIdEx(L2TP_SERVER *l2tp, IP *client_ip, bool is_32bit) { UINT id; UINT max_number = 0xffff; // Validate arguments if (l2tp == NULL || client_ip == NULL) { return 0; } if (is_32bit) { max_number = 0xfffffffe; } for (id = 1;id <= max_number;id++) { if (GetTunnelFromId(l2tp, client_ip, id, is_32bit) == NULL) { return id; } } return 0; } // Release the L2TP tunnel void FreeL2TPTunnel(L2TP_TUNNEL *t) { UINT i; // Validate arguments if (t == NULL) { return; } for (i = 0;i < LIST_NUM(t->SessionList);i++) { L2TP_SESSION *s = LIST_DATA(t->SessionList, i); FreeL2TPSession(s); } ReleaseList(t->SessionList); for (i = 0;i < LIST_NUM(t->SendQueue);i++) { L2TP_QUEUE *q = LIST_DATA(t->SendQueue, i); FreeL2TPQueue(q); } ReleaseList(t->SendQueue); for (i = 0;i < LIST_NUM(t->RecvQueue);i++) { L2TP_QUEUE *q = LIST_DATA(t->RecvQueue, i); FreeL2TPQueue(q); } ReleaseList(t->RecvQueue); Free(t); } // Generate a new L2TP control packet L2TP_PACKET *NewL2TPControlPacket(UINT message_type, bool is_v3) { L2TP_PACKET *p = ZeroMalloc(sizeof(L2TP_PACKET)); p->IsControl = true; p->HasLength = true; p->HasSequence = true; p->Ver = (is_v3 ? 3 : 2); p->MessageType = message_type; p->AvpList = NewListFast(NULL); if (message_type != 0) { L2TP_AVP *a; USHORT us; a = ZeroMalloc(sizeof(L2TP_AVP)); a->Type = L2TP_AVP_TYPE_MESSAGE_TYPE; a->Mandatory = true; us = Endian16(message_type); a->Data = Clone(&us, sizeof(USHORT)); a->DataSize = sizeof(USHORT); Add(p->AvpList, a); } return p; } // Create a new AVP value L2TP_AVP *NewAVP(USHORT type, bool mandatory, USHORT vendor_id, void *data, UINT data_size) { L2TP_AVP *a; // Validate arguments if (data_size != 0 && data == NULL) { return NULL; } a = ZeroMalloc(sizeof(L2TP_AVP)); a->Type = type; a->Mandatory = mandatory; a->VendorID = vendor_id; a->Data = Clone(data, data_size); a->DataSize = data_size; return a; } // Process a received L2TP packet void L2TPProcessRecvControlPacket(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_PACKET *p) { // Validate arguments if (l2tp == NULL || t == NULL || p == NULL) { return; } if (p->SessionId == 0) { if (p->MessageType == L2TP_MESSAGE_TYPE_SCCCN && l2tp->Halt == false) { // Tunnel establishment completed if (t->Established == false) { if (t->Disconnecting == false) { t->Established = true; t->LastHelloSent = l2tp->Now; } } } if (t->Established) { if (p->MessageType == L2TP_MESSAGE_TYPE_ICRQ && t->WantToDisconnect == false && l2tp->Halt == false) { // Request to establish a new session arrives L2TP_AVP *a = GetAVPValue(p, (t->IsV3 ? L2TP_AVP_TYPE_V3_SESSION_ID_LOCAL : L2TP_AVP_TYPE_ASSIGNED_SESSION)); if (a != NULL && a->DataSize == (t->IsV3 ? sizeof(UINT) : sizeof(USHORT)) && IsZero(a->Data, (t->IsV3 ? sizeof(UINT) : sizeof(USHORT))) == false) { UINT session_id = (t->IsV3 ? READ_UINT(a->Data) : READ_USHORT(a->Data)); // Check whether there is other same session ID if (GetSessionFromIdAssignedByClient(t, session_id) == NULL) { // Create a session L2TP_SESSION *s = NewL2TPSession(l2tp, t, session_id); if (s != NULL) { L2TP_PACKET *pp; USHORT us; UINT ui; // Get the PseudowireType if (t->IsV3) { s->PseudowireType = L2TPV3_PW_TYPE_ETHERNET; a = GetAVPValue(p, L2TP_AVP_TYPE_V3_PW_TYPE); if (a != NULL && a->DataSize == sizeof(USHORT)) { ui = READ_USHORT(a->Data); s->PseudowireType = ui; } } Add(t->SessionList, s); Debug("L2TP New Session: ID = %u/%u on Tunnel %u/%u\n", s->SessionId1, s->SessionId2, t->TunnelId1, t->TunnelId2); // Respond the session creation completion notice pp = NewL2TPControlPacket(L2TP_MESSAGE_TYPE_ICRP, s->IsV3); // Assigned Session AVP if (s->IsV3 == false) { us = Endian16(s->SessionId2); Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_ASSIGNED_SESSION, true, 0, &us, sizeof(USHORT))); } else { ui = Endian32(s->SessionId2); Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_V3_SESSION_ID_LOCAL, true, 0, &ui, sizeof(UINT))); if (s->IsCiscoV3) { Add(pp->AvpList, NewAVP(L2TPV3_CISCO_AVP_SESSION_ID_LOCAL, true, L2TP_AVP_VENDOR_ID_CISCO, &ui, sizeof(UINT))); } } if (s->IsV3) { if (t->IsYamahaV3 == false) { // Pseudowire AVP us = Endian16(s->PseudowireType); Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_V3_PW_TYPE, true, 0, &us, sizeof(USHORT))); } if (s->IsCiscoV3) { Add(pp->AvpList, NewAVP(L2TPV3_CISCO_AVP_PW_TYPE, true, L2TP_AVP_VENDOR_ID_CISCO, &us, sizeof(USHORT))); } if (t->IsYamahaV3) { us = Endian16(0x0003); Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_V3_CIRCUIT_STATUS, true, 0, &us, sizeof(USHORT))); } } SendL2TPControlPacket(l2tp, t, session_id, pp); FreeL2TPPacket(pp); } } } } else if (p->MessageType == L2TP_MESSAGE_TYPE_STOPCCN) { // Tunnel disconnect request arrives L2TP_AVP *a = GetAVPValue(p, (t->IsV3 ? L2TP_AVP_TYPE_V3_TUNNEL_ID : L2TP_AVP_TYPE_ASSIGNED_TUNNEL)); if (a != NULL && a->DataSize == (t->IsV3 ? sizeof(UINT) : sizeof(USHORT))) { UINT ui = (t->IsV3 ? READ_UINT(a->Data) : READ_USHORT(a->Data)); if (ui == t->TunnelId1) { // Disconnect the tunnel DisconnectL2TPTunnel(t); } } } } } else { // Search a session L2TP_SESSION *s = GetSessionFromId(t, p->SessionId); if (s != NULL) { if (s->Established == false) { if (p->MessageType == L2TP_MESSAGE_TYPE_ICCN) { // Session establishment completed if (s->Disconnecting == false) { s->Established = true; } } } else { if (p->MessageType == L2TP_MESSAGE_TYPE_CDN) { // Received a session disconnection request L2TP_AVP *a = GetAVPValue(p, (t->IsV3 ? L2TP_AVP_TYPE_V3_SESSION_ID_LOCAL : L2TP_AVP_TYPE_ASSIGNED_SESSION)); if (a != NULL && a->DataSize == (t->IsV3 ? sizeof(UINT) : sizeof(USHORT))) { UINT ui = (t->IsV3 ? READ_UINT(a->Data) : READ_USHORT(a->Data)); if (ui == s->SessionId1) { // Disconnect the session DisconnectL2TPSession(t, s); } } } } } else { Debug("Session ID %u not found in Tunnel ID %u/%u\n", p->SessionId, t->TunnelId1, t->TunnelId2); } } } // Disconnect the L2TP tunnel void DisconnectL2TPTunnel(L2TP_TUNNEL *t) { // Validate arguments if (t == NULL) { return; } if (/*t->Established && */t->Disconnecting == false && t->WantToDisconnect == false) { UINT i; Debug("Trying to Disconnect Tunnel ID %u/%u\n", t->TunnelId1, t->TunnelId2); t->WantToDisconnect = true; // Disconnect all sessions within the tunnel for (i = 0;i < LIST_NUM(t->SessionList);i++) { L2TP_SESSION *s = LIST_DATA(t->SessionList, i); DisconnectL2TPSession(t, s); } } } // Disconnect the L2TP session void DisconnectL2TPSession(L2TP_TUNNEL *t, L2TP_SESSION *s) { // Validate arguments if (t == NULL || s == NULL) { return; } if (s->Established && s->Disconnecting == false && s->WantToDisconnect == false) { Debug("Trying to Disconnect Session ID %u/%u on Tunnel %u/%u\n", s->SessionId1, s->SessionId2, t->TunnelId1, t->TunnelId2); s->WantToDisconnect = true; } } // Create a new session L2TP_SESSION *NewL2TPSession(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, UINT session_id_by_client) { L2TP_SESSION *s; UINT session_id_by_server; // Validate arguments if (l2tp == NULL || t == NULL || session_id_by_client == 0) { return NULL; } if (LIST_NUM(t->SessionList) >= L2TP_QUOTA_MAX_NUM_SESSIONS_PER_TUNNEL) { return NULL; } if (t->IsV3 == false) { session_id_by_server = GenerateNewSessionIdEx(t, t->IsV3); } else { session_id_by_server = GenerateNewSessionIdForL2TPv3(l2tp); } if (session_id_by_server == 0) { return NULL; } s = ZeroMalloc(sizeof(L2TP_SESSION)); s->SessionId1 = session_id_by_client; s->SessionId2 = session_id_by_server; s->IsV3 = t->IsV3; s->IsCiscoV3 = t->IsCiscoV3; s->Tunnel = t; return s; } // Retrieve a session from L2TP session ID L2TP_SESSION *SearchL2TPSessionById(L2TP_SERVER *l2tp, bool is_v3, UINT id) { UINT i, j; // Validate arguments if (l2tp == NULL || id == 0) { return NULL; } for (i = 0;i < LIST_NUM(l2tp->TunnelList);i++) { L2TP_TUNNEL *t = LIST_DATA(l2tp->TunnelList, i); for (j = 0;j < LIST_NUM(t->SessionList);j++) { L2TP_SESSION *s = LIST_DATA(t->SessionList, j); if (s->SessionId2 == id) { if (EQUAL_BOOL(s->IsV3, is_v3)) { return s; } } } } return NULL; } // Create a new session ID UINT GenerateNewSessionId(L2TP_TUNNEL *t) { return GenerateNewSessionIdEx(t, false); } UINT GenerateNewSessionIdEx(L2TP_TUNNEL *t, bool is_32bit) { UINT i; UINT max_number = 0xffff; // Validate arguments if (t == NULL) { return 0; } if (is_32bit) { max_number = 0xfffffffe; } for (i = 1;i <= max_number;i++) { if (GetSessionFromId(t, i) == NULL) { return i; } } return 0; } UINT GenerateNewSessionIdForL2TPv3(L2TP_SERVER *l2tp) { // Validate arguments if (l2tp == NULL) { return 0; } while (true) { UINT id = Rand32(); if (id == 0 || id == 0xffffffff) { continue; } if (SearchL2TPSessionById(l2tp, true, id) == false) { return id; } } } // Release the session void FreeL2TPSession(L2TP_SESSION *s) { // Validate arguments if (s == NULL) { return; } Free(s); } // Search a session from the session ID L2TP_SESSION *GetSessionFromId(L2TP_TUNNEL *t, UINT session_id) { UINT i; // Validate arguments if (t == NULL || session_id == 0) { return NULL; } for (i = 0;i < LIST_NUM(t->SessionList);i++) { L2TP_SESSION *s = LIST_DATA(t->SessionList, i); if (s->SessionId2 == session_id) { return s; } } return NULL; } // Search a session from the session ID (Search by ID assigned from the client side) L2TP_SESSION *GetSessionFromIdAssignedByClient(L2TP_TUNNEL *t, UINT session_id) { UINT i; // Validate arguments if (t == NULL || session_id == 0) { return NULL; } for (i = 0;i < LIST_NUM(t->SessionList);i++) { L2TP_SESSION *s = LIST_DATA(t->SessionList, i); if (s->SessionId1 == session_id) { return s; } } return NULL; } // Get the number of L2TP sessions connected from the client IP address UINT GetNumL2TPTunnelsByClientIP(L2TP_SERVER *l2tp, IP *client_ip) { UINT i, ret; // Validate arguments if (l2tp == NULL || client_ip == NULL) { return 0; } ret = 0; for (i = 0;i < LIST_NUM(l2tp->TunnelList);i++) { L2TP_TUNNEL *t = LIST_DATA(l2tp->TunnelList, i); if (CmpIpAddr(&t->ClientIp, client_ip) == 0) { ret++; } } return ret; } // Performs processing L2TP received packets. void ProcL2TPPacketRecv(L2TP_SERVER *l2tp, UDPPACKET *p) { L2TP_PACKET *pp; bool no_free = false; // Validate arguments if (l2tp == NULL || p == NULL) { return; } // Parse a packet. pp = ParseL2TPPacket(p); if (pp == NULL) { return; } if (pp->MessageType == L2TP_MESSAGE_TYPE_SCCRQ && pp->SessionId == 0 && pp->TunnelId == 0 && pp->Nr == 0 && pp->Ns == 0 && l2tp->Halt == false) { { L2TP_AVP *a = GetAVPValue(pp, (pp->Ver == 3 ? L2TP_AVP_TYPE_V3_TUNNEL_ID : L2TP_AVP_TYPE_ASSIGNED_TUNNEL)); if (a != NULL && a->DataSize == (pp->Ver == 3 ? sizeof(UINT) : sizeof(USHORT))) { UINT client_assigned_id = (pp->Ver == 3 ? READ_UINT(a->Data) : READ_USHORT(a->Data)); if (GetTunnelFromIdOfAssignedByClient(l2tp, &p->SrcIP, client_assigned_id) == NULL) { if (LIST_NUM(l2tp->TunnelList) < L2TP_QUOTA_MAX_NUM_TUNNELS && GetNumL2TPTunnelsByClientIP(l2tp, &p->SrcIP) < L2TP_QUOTA_MAX_NUM_TUNNELS_PER_IP) { char ipstr[MAX_SIZE]; L2TP_PACKET *pp2; UCHAR protocol_version[2]; UCHAR caps_data[4]; USHORT us; char hostname[MAX_SIZE]; // Begin Tunneling L2TP_TUNNEL *t = NewL2TPTunnel(l2tp, pp, p); if (t != NULL) { IPToStr(ipstr, sizeof(ipstr), &t->ClientIp); Debug("L2TP New Tunnel From %s (%s, %s): New Tunnel ID = %u/%u\n", ipstr, t->HostName, t->VendorName, t->TunnelId1, t->TunnelId2); // Add the tunnel to the list Add(l2tp->TunnelList, t); // Respond with SCCEP to SCCRQ pp2 = NewL2TPControlPacket(L2TP_MESSAGE_TYPE_SCCRP, t->IsV3); if (t->IsYamahaV3 == false) { // Protocol Version protocol_version[0] = 1; protocol_version[1] = 0; Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_PROTOCOL_VERSION, true, 0, protocol_version, sizeof(protocol_version))); // Framing Capabilities Zero(caps_data, sizeof(caps_data)); if (t->IsV3 == false) { caps_data[3] = 3; } Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_FRAME_CAP, false, 0, caps_data, sizeof(caps_data))); } if (t->IsV3 == false) { // Bearer Capabilities Zero(caps_data, sizeof(caps_data)); caps_data[3] = 3; Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_BEARER_CAP, false, 0, caps_data, sizeof(caps_data))); } // Host Name GetMachineHostName(hostname, sizeof(hostname)); if (IsEmptyStr(hostname)) { StrCpy(hostname, sizeof(hostname), "vpn"); } Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_HOST_NAME, true, 0, hostname, StrLen(hostname))); // Vendor Name if (t->IsYamahaV3 == false) { Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_VENDOR_NAME, false, 0, L2TP_VENDOR_NAME, StrLen(L2TP_VENDOR_NAME))); } else { char *yamaha_str = "YAMAHA Corporation"; Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_VENDOR_NAME, false, 0, yamaha_str, StrLen(yamaha_str))); } if (t->IsYamahaV3) { UINT zero = 0; Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_V3_ROUTER_ID, true, 0, &zero, sizeof(UINT))); } // Assigned Tunnel ID if (t->IsV3 == false) { us = Endian16(t->TunnelId2); Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_ASSIGNED_TUNNEL, true, 0, &us, sizeof(USHORT))); } else { UINT ui = Endian32(t->TunnelId2); Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_V3_TUNNEL_ID, true, 0, &ui, sizeof(UINT))); if (t->IsCiscoV3) { Add(pp2->AvpList, NewAVP(L2TPV3_CISCO_AVP_TUNNEL_ID, true, L2TP_AVP_VENDOR_ID_CISCO, &ui, sizeof(UINT))); } } // Pseudowire Capabilities List if (t->IsV3) { // Only Ethernet USHORT cap_list[2]; cap_list[0] = Endian16(L2TPV3_PW_TYPE_ETHERNET); cap_list[1] = Endian16(L2TPV3_PW_TYPE_ETHERNET_VLAN); Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_V3_PW_CAP_LIST, true, 0, cap_list, sizeof(cap_list))); if (t->IsCiscoV3) { Add(pp2->AvpList, NewAVP(L2TPV3_CISCO_AVP_PW_CAP_LIST, true, L2TP_AVP_VENDOR_ID_CISCO, cap_list, sizeof(cap_list))); } } // Cisco AVP if (t->IsCiscoV3) { USHORT us = Endian16(1); Add(pp2->AvpList, NewAVP(L2TPV3_CISCO_AVP_DRAFT_AVP_VERSION, true, L2TP_AVP_VENDOR_ID_CISCO, &us, sizeof(USHORT))); } // Recv Window Size if (t->IsYamahaV3 == false) { us = Endian16(L2TP_WINDOW_SIZE); Add(pp2->AvpList, NewAVP(L2TP_AVP_TYPE_RECV_WINDOW_SIZE, false, 0, &us, sizeof(USHORT))); } SendL2TPControlPacket(l2tp, t, 0, pp2); FreeL2TPPacket(pp2); } } } } } } else { // Process related to the existing tunnel // Find the tunnel L2TP_TUNNEL *t = NULL; L2TP_SESSION *l2tpv3_session = NULL; if (pp->IsControl || pp->Ver != 3) { t = GetTunnelFromId(l2tp, &p->SrcIP, pp->TunnelId, pp->Ver == 3); } else { l2tpv3_session = SearchL2TPSessionById(l2tp, true, pp->SessionId); if (l2tpv3_session != NULL) { t = l2tpv3_session->Tunnel; pp->TunnelId = t->TunnelId2; } } if (t == NULL) { char ipstr[MAX_SIZE]; IPToStr(ipstr, sizeof(ipstr), &p->SrcIP); Debug("L2TP Tunnel From %s ID=%u Not Found on the Table.\n", ipstr, pp->TunnelId); } else { // Update last reception time t->LastRecvTick = l2tp->Now; if (pp->IsControl) { // Control packet UINT i; LIST *o = NULL; L2TP_QUEUE *q; L2TP_QUEUE tt; // Delete the queue that the other party has already received from the retransmission queue for (i = 0;i < LIST_NUM(t->SendQueue);i++) { L2TP_QUEUE *q = LIST_DATA(t->SendQueue, i); if (L2TP_SEQ_LT(q->Ns, pp->Nr)) { if (o == NULL) { o = NewListFast(NULL); } Add(o, q); } } if (o != NULL) { for (i = 0;i < LIST_NUM(o);i++) { L2TP_QUEUE *q = LIST_DATA(o, i); Delete(t->SendQueue, q); FreeL2TPQueue(q); } ReleaseList(o); } if ((!L2TP_SEQ_LT(pp->Ns, t->LastNr)) && (pp->Ns != t->LastNr)) { // Add the packet received from the opposite to the queue if (LIST_NUM(t->RecvQueue) < L2TP_WINDOW_SIZE) { Zero(&tt, sizeof(tt)); tt.Ns = pp->Ns; if (Search(t->RecvQueue, &tt) == NULL) { q = ZeroMalloc(sizeof(L2TP_QUEUE)); q->Ns = pp->Ns; q->L2TPPacket = pp; no_free = true; Insert(t->RecvQueue, q); // Read to the end of completed part from the head of the queue while (true) { L2TP_QUEUE *q; if (LIST_NUM(t->RecvQueue) == 0) { break; } q = LIST_DATA(t->RecvQueue, 0); if (!L2TP_SEQ_EQ(q->Ns, t->LastNr + 1)) { break; } if (q->L2TPPacket->IsZLB == false) { t->LastNr = q->Ns; // The packet other than ZLB is treated t->StateChanged = true; } Delete(t->RecvQueue, q); // Process the received packet L2TPProcessRecvControlPacket(l2tp, t, q->L2TPPacket); FreeL2TPQueue(q); } } } } else { // Reply ACK for already-received packets if (pp->IsZLB == false) { // The packet other than ZLB is treated t->StateChanged = true; } } } else { // Data packet L2TP_SESSION *s = GetSessionFromId(t, pp->SessionId); if (s != NULL && s->Established) { if (s->IsV3 == false) { // Start the L2TP thread (If not already started) StartL2TPThread(l2tp, t, s); // Pass the data TubeSendEx(s->TubeRecv, pp->Data, pp->DataSize, NULL, true); AddTubeToFlushList(l2tp->FlushList, s->TubeRecv); } else { BLOCK *b; // Start the EtherIP session (If it's not have yet started) L2TPSessionManageEtherIPServer(l2tp, s); // Pass the data b = NewBlock(pp->Data, pp->DataSize, 0); EtherIPProcRecvPackets(s->EtherIP, b); Free(b); } } } } } if (no_free == false) { FreeL2TPPacket(pp); } } // Manage the EtherIP server that is associated with the L2TP session void L2TPSessionManageEtherIPServer(L2TP_SERVER *l2tp, L2TP_SESSION *s) { IKE_SERVER *ike; IKE_CLIENT *c; // Validate arguments if (l2tp == NULL || s == NULL) { return; } if (l2tp->IkeClient == NULL || l2tp->IkeServer == NULL) { return; } ike = l2tp->IkeServer; c = l2tp->IkeClient; if (s->EtherIP == NULL) { char crypt_name[MAX_SIZE]; UINT crypt_block_size = IKE_MAX_BLOCK_SIZE; Zero(crypt_name, sizeof(crypt_name)); if (c->CurrentIpSecSaRecv != NULL) { Format(crypt_name, sizeof(crypt_name), "IPsec - %s (%u bits)", c->CurrentIpSecSaRecv->TransformSetting.Crypto->Name, c->CurrentIpSecSaRecv->TransformSetting.CryptoKeySize * 8); crypt_block_size = c->CurrentIpSecSaRecv->TransformSetting.Crypto->BlockSize; } s->EtherIP = NewEtherIPServer(ike->Cedar, ike->IPsec, ike, &c->ClientIP, c->ClientPort, &c->ServerIP, c->ServerPort, crypt_name, c->IsL2TPOnIPsecTunnelMode, crypt_block_size, c->ClientId, ++ike->CurrentEtherId); StrCpy(s->EtherIP->VendorName, sizeof(s->EtherIP->VendorName), s->Tunnel->VendorName); s->EtherIP->L2TPv3 = true; Debug("IKE_CLIENT 0x%X: EtherIP Server Started.\n", c); IPsecLog(ike, c, NULL, NULL, NULL, "LI_ETHERIP_SERVER_STARTED", ike->CurrentEtherId); } else { StrCpy(s->EtherIP->ClientId, sizeof(s->EtherIP->ClientId), c->ClientId); } if (s->EtherIP->Interrupts == NULL) { s->EtherIP->Interrupts = l2tp->Interrupts; } if (s->EtherIP->SockEvent == NULL) { SetEtherIPServerSockEvent(s->EtherIP, l2tp->SockEvent); } s->EtherIP->Now = l2tp->Now; } // Calculate the appropriate MSS of the L2TP UINT CalcL2TPMss(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_SESSION *s) { UINT ret; // Validate arguments if (l2tp == NULL || t == NULL || s == NULL) { return 0; } ret = MTU_FOR_PPPOE; if (l2tp->IkeServer != NULL) { // On IPsec if (l2tp->IsIPsecIPv6) { ret -= 40; } else { ret -= 20; } // UDP ret -= 8; // ESP ret -= 20 + l2tp->CryptBlockSize * 2; } else { // Raw L2TP if (IsIP6(&t->ClientIp)) { ret -= 40; } else { ret -= 20; } } // L2TP UDP ret -= 8; // L2TP ret -= 8; // PPP ret -= 4; // Target communication ret -= 20; // TCP header ret -= 20; return ret; } // Start the L2TP thread void StartL2TPThread(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_SESSION *s) { PPP_SESSION* underlyingSession; // Validate arguments if (l2tp == NULL || t == NULL || s == NULL) { return; } if (s->HasThread == false) { char tmp[MAX_SIZE]; Debug("Thread Created for Session %u/%u on Tunnel %u/%u\n", s->SessionId1, s->SessionId2, t->TunnelId1, t->TunnelId2); s->HasThread = true; NewTubePair(&s->TubeSend, &s->TubeRecv, 0); SetTubeSockEvent(s->TubeSend, l2tp->SockEvent); if (IsEmptyStr(t->VendorName) == false) { Format(tmp, sizeof(tmp), L2TP_IPC_CLIENT_NAME_TAG, t->VendorName); } else { StrCpy(tmp, sizeof(tmp), L2TP_IPC_CLIENT_NAME_NO_TAG); } // Create a PPP thread underlyingSession = NewPPPSession(l2tp->Cedar, &t->ClientIp, t->ClientPort, &t->ServerIp, t->ServerPort, s->TubeSend, s->TubeRecv, L2TP_IPC_POSTFIX, tmp, t->HostName, l2tp->CryptName, CalcL2TPMss(l2tp, t, s)); s->Thread = underlyingSession->SessionThread; s->PPPSession = underlyingSession; } } // Stop the L2TP thread void StopL2TPThread(L2TP_SERVER *l2tp, L2TP_TUNNEL *t, L2TP_SESSION *s) { THREAD *thread; // Validate arguments if (l2tp == NULL || t == NULL || s == NULL) { return; } if (s->IsV3) { // Process the L2TPv3 if (s->EtherIP != NULL) { // Release the EtherIP server ReleaseEtherIPServer(s->EtherIP); s->EtherIP = NULL; } return; } if (s->HasThread == false) { return; } thread = s->Thread; s->Thread = NULL; s->HasThread = false; // Disconnect the tube TubeDisconnect(s->TubeRecv); TubeDisconnect(s->TubeSend); // Release the tube ReleaseTube(s->TubeRecv); ReleaseTube(s->TubeSend); s->TubeRecv = NULL; s->TubeSend = NULL; // Pass the thread to termination list if (l2tp->IkeServer == NULL) { AddThreadToThreadList(l2tp->ThreadList, thread); } else { AddThreadToThreadList(l2tp->IkeServer->ThreadList, thread); } Debug("Thread Stopped for Session %u/%u on Tunnel %u/%u\n", s->SessionId1, s->SessionId2, t->TunnelId1, t->TunnelId2); // Release the thread ReleaseThread(thread); } // Interrupt processing of L2TP server void L2TPProcessInterrupts(L2TP_SERVER *l2tp) { UINT i, j; LIST *delete_tunnel_list = NULL; // Validate arguments if (l2tp == NULL) { return; } if (l2tp->Halt) { if (l2tp->Halting == false) { l2tp->Halting = true; // Disconnect all tunnels for (i = 0;i < LIST_NUM(l2tp->TunnelList);i++) { L2TP_TUNNEL *t = LIST_DATA(l2tp->TunnelList, i); DisconnectL2TPTunnel(t); } } } // Flush FlushTubeFlushList(l2tp->FlushList); // Enumerate all tunnels for (i = 0;i < LIST_NUM(l2tp->TunnelList);i++) { L2TP_TUNNEL *t = LIST_DATA(l2tp->TunnelList, i); LIST *delete_session_list = NULL; UINT64 l2tpTimeout = L2TP_TUNNEL_TIMEOUT; // If we got on ANY session a higher timeout than the default L2TP tunnel timeout, increase it for (i = 0; i < LIST_NUM(t->SessionList); i++) { L2TP_SESSION* s = LIST_DATA(t->SessionList, i); if (s->PPPSession != NULL && s->PPPSession->DataTimeout > l2tpTimeout) { l2tpTimeout = s->PPPSession->DataTimeout; } } if ((l2tp->Now >= (t->LastRecvTick + (UINT64)l2tpTimeout)) && t->Timedout == false) { // Disconnect the tunnel forcibly if data can not be received for a certain period of time t->Timedout = true; Debug("L2TP Tunnel %u/%u Timed out.\n", t->TunnelId1, t->TunnelId2); DisconnectL2TPTunnel(t); } if (t->Established && (l2tp->Now >= (t->LastHelloSent + (UINT64)L2TP_HELLO_INTERVAL))) { if (LIST_NUM(t->SendQueue) <= L2TP_HELLO_SUPRESS_MAX_THRETHORD_NUM_SEND_QUEUE) { L2TP_PACKET *pp = NewL2TPControlPacket(L2TP_MESSAGE_TYPE_HELLO, t->IsV3); // Send a Hello message t->LastHelloSent = l2tp->Now; //Debug("L2TP Sending Hello %u/%u: tick=%I64u\n", t->TunnelId1, t->TunnelId2, l2tp->Now); SendL2TPControlPacket(l2tp, t, 0, pp); FreeL2TPPacket(pp); L2TPAddInterrupt(l2tp, t->LastHelloSent + (UINT64)L2TP_HELLO_INTERVAL); } } // Enumerate all sessions for (j = 0;j < LIST_NUM(t->SessionList);j++) { L2TP_SESSION *s = LIST_DATA(t->SessionList, j); if (s->HasThread) { // Send packet data while (true) { TUBEDATA *d = TubeRecvAsync(s->TubeSend); if (d == NULL) { break; } SendL2TPDataPacket(l2tp, t, s, d->Data, d->DataSize); FreeTubeData(d); } if (IsTubeConnected(s->TubeSend) == false) { // Disconnect the this session because the PPP thread ends DisconnectL2TPSession(t, s); } } if (s->IsV3) { if (s->EtherIP != NULL) { UINT k; L2TPSessionManageEtherIPServer(l2tp, s); // Notify an interrupt to the EtherIP module EtherIPProcInterrupts(s->EtherIP); // Send an EtherIP packet data for (k = 0;k < LIST_NUM(s->EtherIP->SendPacketList);k++) { BLOCK *b = LIST_DATA(s->EtherIP->SendPacketList, k); SendL2TPDataPacket(l2tp, t, s, b->Buf, b->Size); FreeBlock(b); } DeleteAll(s->EtherIP->SendPacketList); } } if (s->WantToDisconnect && s->Disconnecting == false) { // Disconnect the session UCHAR error_data[4]; USHORT us; UINT ui; UINT ppp_error_1 = 0, ppp_error_2 = 0; // Send the session disconnection response L2TP_PACKET *pp = NewL2TPControlPacket(L2TP_MESSAGE_TYPE_CDN, s->IsV3); if (s->TubeRecv != NULL) { ppp_error_1 = s->TubeRecv->IntParam1; ppp_error_2 = s->TubeRecv->IntParam2; } // Assigned Session ID if (s->IsV3 == false) { us = Endian16(s->SessionId2); Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_ASSIGNED_SESSION, true, 0, &us, sizeof(USHORT))); } else { ui = Endian16(s->SessionId2); Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_V3_SESSION_ID_LOCAL, true, 0, &ui, sizeof(UINT))); if (t->IsCiscoV3) { Add(pp->AvpList, NewAVP(L2TPV3_CISCO_AVP_SESSION_ID_LOCAL, true, L2TP_AVP_VENDOR_ID_CISCO, &ui, sizeof(UINT))); } } // Result-Error Code Zero(error_data, sizeof(error_data)); error_data[1] = 0x03; Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_RESULT_CODE, true, 0, error_data, sizeof(error_data))); if (ppp_error_1 != 0) { // PPP Disconnect Cause Code AVP BUF *b = NewBuf(); UCHAR uc; USHORT us; // Disconnect Code us = Endian16(ppp_error_1); WriteBuf(b, &us, sizeof(USHORT)); // Control Protocol Number us = Endian16(0xc021); WriteBuf(b, &us, sizeof(USHORT)); // Direction uc = (UCHAR)ppp_error_2; WriteBuf(b, &uc, sizeof(UCHAR)); Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_PPP_DISCONNECT_CAUSE, false, 0, b->Buf, b->Size)); FreeBuf(b); } SendL2TPControlPacket(l2tp, t, s->SessionId1, pp); FreeL2TPPacket(pp); // Disconnect the session Debug("L2TP Session %u/%u on Tunnel %u/%u Disconnected.\n", s->SessionId1, s->SessionId2, t->TunnelId1, t->TunnelId2); s->Disconnecting = true; s->Established = false; s->DisconnectTimeout = l2tp->Now + (UINT64)L2TP_TUNNEL_DISCONNECT_TIMEOUT; // Stop the thread StopL2TPThread(l2tp, t, s); L2TPAddInterrupt(l2tp, s->DisconnectTimeout); } if (s->Disconnecting && ((l2tp->Now >= s->DisconnectTimeout) || LIST_NUM(t->SendQueue) == 0)) { // Delete the session if synchronization between the client // and the server is complete or a time-out occurs if (delete_session_list == NULL) { delete_session_list = NewListFast(NULL); } Add(delete_session_list, s); } } if (delete_session_list != NULL) { // Session deletion process for (j = 0;j < LIST_NUM(delete_session_list);j++) { L2TP_SESSION *s = LIST_DATA(delete_session_list, j); Debug("L2TP Session %u/%u on Tunnel %u/%u Cleaned up.\n", s->SessionId1, s->SessionId2, t->TunnelId1, t->TunnelId2); FreeL2TPSession(s); Delete(t->SessionList, s); } ReleaseList(delete_session_list); } if (t->WantToDisconnect && t->Disconnecting == false) { // Disconnect the tunnel USHORT error_data[4]; USHORT us; UINT ui; // Reply the tunnel disconnection response L2TP_PACKET *pp = NewL2TPControlPacket(L2TP_MESSAGE_TYPE_STOPCCN, t->IsV3); // Assigned Tunnel ID if (t->IsV3 == false) { us = Endian16(t->TunnelId2); Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_ASSIGNED_TUNNEL, true, 0, &us, sizeof(USHORT))); } else { ui = Endian32(t->TunnelId2); Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_V3_TUNNEL_ID, true, 0, &ui, sizeof(UINT))); if (t->IsCiscoV3) { Add(pp->AvpList, NewAVP(L2TPV3_CISCO_AVP_TUNNEL_ID, true, L2TP_AVP_VENDOR_ID_CISCO, &ui, sizeof(UINT))); } } // Result-Error Code Zero(error_data, sizeof(error_data)); error_data[1] = 0x06; Add(pp->AvpList, NewAVP(L2TP_AVP_TYPE_RESULT_CODE, true, 0, error_data, sizeof(error_data))); SendL2TPControlPacket(l2tp, t, 0, pp); FreeL2TPPacket(pp); Debug("L2TP Tunnel %u/%u is Disconnected.\n", t->TunnelId1, t->TunnelId2); t->Disconnecting = true; t->Established = false; t->DisconnectTimeout = l2tp->Now + (UINT64)L2TP_TUNNEL_DISCONNECT_TIMEOUT; L2TPAddInterrupt(l2tp, t->DisconnectTimeout); } if (t->Disconnecting && (((LIST_NUM(t->SendQueue) == 0) && LIST_NUM(t->SessionList) == 0) || (l2tp->Now >= t->DisconnectTimeout))) { // Delete the tunnel if there is no session in the tunnel when synchronization // between the client and the server has been completed or a time-out occurs if (delete_tunnel_list == NULL) { delete_tunnel_list = NewListFast(NULL); } Add(delete_tunnel_list, t); } } if (delete_tunnel_list != NULL) { for (i = 0;i < LIST_NUM(delete_tunnel_list);i++) { L2TP_TUNNEL *t = LIST_DATA(delete_tunnel_list, i); Debug("L2TP Tunnel %u/%u Cleaned up.\n", t->TunnelId1, t->TunnelId2); FreeL2TPTunnel(t); Delete(l2tp->TunnelList, t); } ReleaseList(delete_tunnel_list); } // Re-transmit packets for (i = 0;i < LIST_NUM(l2tp->TunnelList);i++) { L2TP_TUNNEL *t = LIST_DATA(l2tp->TunnelList, i); UINT j; if (LIST_NUM(t->SendQueue) >= 1) { // Packet to be transmitted exists one or more for (j = 0;j < LIST_NUM(t->SendQueue);j++) { L2TP_QUEUE *q = LIST_DATA(t->SendQueue, j); if (l2tp->Now >= q->NextSendTick) { q->NextSendTick = l2tp->Now + (UINT64)L2TP_PACKET_RESEND_INTERVAL; L2TPAddInterrupt(l2tp, q->NextSendTick); SendL2TPControlPacketMain(l2tp, t, q); } } } else { // There is no packet to be transmitted, but the state of the tunnel is changed if (t->StateChanged) { // Send a ZLB L2TP_QUEUE *q = ZeroMalloc(sizeof(L2TP_QUEUE)); L2TP_PACKET *pp = NewL2TPControlPacket(0, t->IsV3); pp->TunnelId = t->TunnelId1; pp->Ns = t->NextNs; q->Buf = BuildL2TPPacketData(pp, t); SendL2TPControlPacketMain(l2tp, t, q); FreeL2TPQueue(q); FreeL2TPPacket(pp); } } t->StateChanged = false; } if (l2tp->Halting) { if (LIST_NUM(l2tp->TunnelList) == 0) { // Stop all the L2TP tunnel completed if (l2tp->HaltCompleted == false) { l2tp->HaltCompleted = true; Set(l2tp->HaltCompletedEvent); } } } // Maintenance the thread list if (l2tp->IkeServer == NULL) { MaintainThreadList(l2tp->ThreadList); //Debug("l2tp->ThreadList: %u\n", LIST_NUM(l2tp->ThreadList)); } } // Create a new L2TP server L2TP_SERVER *NewL2TPServer(CEDAR *cedar) { return NewL2TPServerEx(cedar, NULL, false, 0); } L2TP_SERVER *NewL2TPServerEx(CEDAR *cedar, IKE_SERVER *ike, bool is_ipv6, UINT crypt_block_size) { L2TP_SERVER *l2tp; // Validate arguments if (cedar == NULL) { return NULL; } l2tp = ZeroMalloc(sizeof(L2TP_SERVER)); l2tp->FlushList = NewTubeFlushList(); l2tp->Cedar = cedar; AddRef(l2tp->Cedar->ref); l2tp->SendPacketList = NewList(NULL); l2tp->TunnelList = NewList(NULL); l2tp->HaltCompletedEvent = NewEvent(); l2tp->ThreadList = NewThreadList(); l2tp->IkeServer = ike; l2tp->IsIPsecIPv6 = is_ipv6; l2tp->CryptBlockSize = crypt_block_size; return l2tp; } // Stop the L2TP server void StopL2TPServer(L2TP_SERVER *l2tp, bool no_wait) { // Validate arguments if (l2tp == NULL) { return; } if (l2tp->Halt) { return; } // Begin to shut down l2tp->Halt = true; Debug("Shutting down L2TP Server...\n"); // Hit the event SetSockEvent(l2tp->SockEvent); if (no_wait == false) { // Wait until complete stopping all tunnels Wait(l2tp->HaltCompletedEvent, INFINITE); } else { UINT i, j; // Kill the thread of all sessions for (i = 0;i < LIST_NUM(l2tp->TunnelList);i++) { L2TP_TUNNEL *t = LIST_DATA(l2tp->TunnelList, i); for (j = 0;j < LIST_NUM(t->SessionList);j++) { L2TP_SESSION *s = LIST_DATA(t->SessionList, j); StopL2TPThread(l2tp, t, s); } } } // Thread stop Debug("Stopping all L2TP PPP Threads...\n"); StopThreadList(l2tp->ThreadList); Debug("L2TP Server Shutdown Completed.\n"); } // Release the L2TP server void FreeL2TPServer(L2TP_SERVER *l2tp) { UINT i; // Validate arguments if (l2tp == NULL) { return; } FreeThreadList(l2tp->ThreadList); for (i = 0;i < LIST_NUM(l2tp->SendPacketList);i++) { UDPPACKET *p = LIST_DATA(l2tp->SendPacketList, i); FreeUdpPacket(p); } ReleaseList(l2tp->SendPacketList); for (i = 0;i < LIST_NUM(l2tp->TunnelList);i++) { L2TP_TUNNEL *t = LIST_DATA(l2tp->TunnelList, i); FreeL2TPTunnel(t); } ReleaseList(l2tp->TunnelList); ReleaseSockEvent(l2tp->SockEvent); ReleaseEvent(l2tp->HaltCompletedEvent); ReleaseCedar(l2tp->Cedar); FreeTubeFlushList(l2tp->FlushList); Free(l2tp); } // Set a SockEvent to the L2TP server void SetL2TPServerSockEvent(L2TP_SERVER *l2tp, SOCK_EVENT *e) { // Validate arguments if (l2tp == NULL) { return; } if (e != NULL) { AddRef(e->ref); } if (l2tp->SockEvent != NULL) { ReleaseSockEvent(l2tp->SockEvent); l2tp->SockEvent = NULL; } l2tp->SockEvent = e; }