From 5d1646d90e1f2cceb9f0828f4b28318cd0ec7744 Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Sat, 27 Apr 2024 12:05:51 +0200 Subject: Adding upstream version 5.10.209. Signed-off-by: Daniel Baumann --- Documentation/networking/l2tp.rst | 677 ++++++++++++++++++++++++++++++++++++++ 1 file changed, 677 insertions(+) create mode 100644 Documentation/networking/l2tp.rst (limited to 'Documentation/networking/l2tp.rst') diff --git a/Documentation/networking/l2tp.rst b/Documentation/networking/l2tp.rst new file mode 100644 index 000000000..498b382d2 --- /dev/null +++ b/Documentation/networking/l2tp.rst @@ -0,0 +1,677 @@ +.. SPDX-License-Identifier: GPL-2.0 + +==== +L2TP +==== + +Layer 2 Tunneling Protocol (L2TP) allows L2 frames to be tunneled over +an IP network. + +This document covers the kernel's L2TP subsystem. It documents kernel +APIs for application developers who want to use the L2TP subsystem and +it provides some technical details about the internal implementation +which may be useful to kernel developers and maintainers. + +Overview +======== + +The kernel's L2TP subsystem implements the datapath for L2TPv2 and +L2TPv3. L2TPv2 is carried over UDP. L2TPv3 is carried over UDP or +directly over IP (protocol 115). + +The L2TP RFCs define two basic kinds of L2TP packets: control packets +(the "control plane"), and data packets (the "data plane"). The kernel +deals only with data packets. The more complex control packets are +handled by user space. + +An L2TP tunnel carries one or more L2TP sessions. Each tunnel is +associated with a socket. Each session is associated with a virtual +netdevice, e.g. ``pppN``, ``l2tpethN``, through which data frames pass +to/from L2TP. Fields in the L2TP header identify the tunnel or session +and whether it is a control or data packet. When tunnels and sessions +are set up using the Linux kernel API, we're just setting up the L2TP +data path. All aspects of the control protocol are to be handled by +user space. + +This split in responsibilities leads to a natural sequence of +operations when establishing tunnels and sessions. The procedure looks +like this: + + 1) Create a tunnel socket. Exchange L2TP control protocol messages + with the peer over that socket in order to establish a tunnel. + + 2) Create a tunnel context in the kernel, using information + obtained from the peer using the control protocol messages. + + 3) Exchange L2TP control protocol messages with the peer over the + tunnel socket in order to establish a session. + + 4) Create a session context in the kernel using information + obtained from the peer using the control protocol messages. + +L2TP APIs +========= + +This section documents each userspace API of the L2TP subsystem. + +Tunnel Sockets +-------------- + +L2TPv2 always uses UDP. L2TPv3 may use UDP or IP encapsulation. + +To create a tunnel socket for use by L2TP, the standard POSIX +socket API is used. + +For example, for a tunnel using IPv4 addresses and UDP encapsulation:: + + int sockfd = socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP); + +Or for a tunnel using IPv6 addresses and IP encapsulation:: + + int sockfd = socket(AF_INET6, SOCK_DGRAM, IPPROTO_L2TP); + +UDP socket programming doesn't need to be covered here. + +IPPROTO_L2TP is an IP protocol type implemented by the kernel's L2TP +subsystem. The L2TPIP socket address is defined in struct +sockaddr_l2tpip and struct sockaddr_l2tpip6 at +`include/uapi/linux/l2tp.h`_. The address includes the L2TP tunnel +(connection) id. To use L2TP IP encapsulation, an L2TPv3 application +should bind the L2TPIP socket using the locally assigned +tunnel id. When the peer's tunnel id and IP address is known, a +connect must be done. + +If the L2TP application needs to handle L2TPv3 tunnel setup requests +from peers using L2TPIP, it must open a dedicated L2TPIP +socket to listen for those requests and bind the socket using tunnel +id 0 since tunnel setup requests are addressed to tunnel id 0. + +An L2TP tunnel and all of its sessions are automatically closed when +its tunnel socket is closed. + +Netlink API +----------- + +L2TP applications use netlink to manage L2TP tunnel and session +instances in the kernel. The L2TP netlink API is defined in +`include/uapi/linux/l2tp.h`_. + +L2TP uses `Generic Netlink`_ (GENL). Several commands are defined: +Create, Delete, Modify and Get for tunnel and session +instances, e.g. ``L2TP_CMD_TUNNEL_CREATE``. The API header lists the +netlink attribute types that can be used with each command. + +Tunnel and session instances are identified by a locally unique +32-bit id. L2TP tunnel ids are given by ``L2TP_ATTR_CONN_ID`` and +``L2TP_ATTR_PEER_CONN_ID`` attributes and L2TP session ids are given +by ``L2TP_ATTR_SESSION_ID`` and ``L2TP_ATTR_PEER_SESSION_ID`` +attributes. If netlink is used to manage L2TPv2 tunnel and session +instances, the L2TPv2 16-bit tunnel/session id is cast to a 32-bit +value in these attributes. + +In the ``L2TP_CMD_TUNNEL_CREATE`` command, ``L2TP_ATTR_FD`` tells the +kernel the tunnel socket fd being used. If not specified, the kernel +creates a kernel socket for the tunnel, using IP parameters set in +``L2TP_ATTR_IP[6]_SADDR``, ``L2TP_ATTR_IP[6]_DADDR``, +``L2TP_ATTR_UDP_SPORT``, ``L2TP_ATTR_UDP_DPORT`` attributes. Kernel +sockets are used to implement unmanaged L2TPv3 tunnels (iproute2's "ip +l2tp" commands). If ``L2TP_ATTR_FD`` is given, it must be a socket fd +that is already bound and connected. There is more information about +unmanaged tunnels later in this document. + +``L2TP_CMD_TUNNEL_CREATE`` attributes:- + +================== ======== === +Attribute Required Use +================== ======== === +CONN_ID Y Sets the tunnel (connection) id. +PEER_CONN_ID Y Sets the peer tunnel (connection) id. +PROTO_VERSION Y Protocol version. 2 or 3. +ENCAP_TYPE Y Encapsulation type: UDP or IP. +FD N Tunnel socket file descriptor. +UDP_CSUM N Enable IPv4 UDP checksums. Used only if FD is + not set. +UDP_ZERO_CSUM6_TX N Zero IPv6 UDP checksum on transmit. Used only + if FD is not set. +UDP_ZERO_CSUM6_RX N Zero IPv6 UDP checksum on receive. Used only if + FD is not set. +IP_SADDR N IPv4 source address. Used only if FD is not + set. +IP_DADDR N IPv4 destination address. Used only if FD is + not set. +UDP_SPORT N UDP source port. Used only if FD is not set. +UDP_DPORT N UDP destination port. Used only if FD is not + set. +IP6_SADDR N IPv6 source address. Used only if FD is not + set. +IP6_DADDR N IPv6 destination address. Used only if FD is + not set. +DEBUG N Debug flags. +================== ======== === + +``L2TP_CMD_TUNNEL_DESTROY`` attributes:- + +================== ======== === +Attribute Required Use +================== ======== === +CONN_ID Y Identifies the tunnel id to be destroyed. +================== ======== === + +``L2TP_CMD_TUNNEL_MODIFY`` attributes:- + +================== ======== === +Attribute Required Use +================== ======== === +CONN_ID Y Identifies the tunnel id to be modified. +DEBUG N Debug flags. +================== ======== === + +``L2TP_CMD_TUNNEL_GET`` attributes:- + +================== ======== === +Attribute Required Use +================== ======== === +CONN_ID N Identifies the tunnel id to be queried. + Ignored in DUMP requests. +================== ======== === + +``L2TP_CMD_SESSION_CREATE`` attributes:- + +================== ======== === +Attribute Required Use +================== ======== === +CONN_ID Y The parent tunnel id. +SESSION_ID Y Sets the session id. +PEER_SESSION_ID Y Sets the parent session id. +PW_TYPE Y Sets the pseudowire type. +DEBUG N Debug flags. +RECV_SEQ N Enable rx data sequence numbers. +SEND_SEQ N Enable tx data sequence numbers. +LNS_MODE N Enable LNS mode (auto-enable data sequence + numbers). +RECV_TIMEOUT N Timeout to wait when reordering received + packets. +L2SPEC_TYPE N Sets layer2-specific-sublayer type (L2TPv3 + only). +COOKIE N Sets optional cookie (L2TPv3 only). +PEER_COOKIE N Sets optional peer cookie (L2TPv3 only). +IFNAME N Sets interface name (L2TPv3 only). +================== ======== === + +For Ethernet session types, this will create an l2tpeth virtual +interface which can then be configured as required. For PPP session +types, a PPPoL2TP socket must also be opened and connected, mapping it +onto the new session. This is covered in "PPPoL2TP Sockets" later. + +``L2TP_CMD_SESSION_DESTROY`` attributes:- + +================== ======== === +Attribute Required Use +================== ======== === +CONN_ID Y Identifies the parent tunnel id of the session + to be destroyed. +SESSION_ID Y Identifies the session id to be destroyed. +IFNAME N Identifies the session by interface name. If + set, this overrides any CONN_ID and SESSION_ID + attributes. Currently supported for L2TPv3 + Ethernet sessions only. +================== ======== === + +``L2TP_CMD_SESSION_MODIFY`` attributes:- + +================== ======== === +Attribute Required Use +================== ======== === +CONN_ID Y Identifies the parent tunnel id of the session + to be modified. +SESSION_ID Y Identifies the session id to be modified. +IFNAME N Identifies the session by interface name. If + set, this overrides any CONN_ID and SESSION_ID + attributes. Currently supported for L2TPv3 + Ethernet sessions only. +DEBUG N Debug flags. +RECV_SEQ N Enable rx data sequence numbers. +SEND_SEQ N Enable tx data sequence numbers. +LNS_MODE N Enable LNS mode (auto-enable data sequence + numbers). +RECV_TIMEOUT N Timeout to wait when reordering received + packets. +================== ======== === + +``L2TP_CMD_SESSION_GET`` attributes:- + +================== ======== === +Attribute Required Use +================== ======== === +CONN_ID N Identifies the tunnel id to be queried. + Ignored for DUMP requests. +SESSION_ID N Identifies the session id to be queried. + Ignored for DUMP requests. +IFNAME N Identifies the session by interface name. + If set, this overrides any CONN_ID and + SESSION_ID attributes. Ignored for DUMP + requests. Currently supported for L2TPv3 + Ethernet sessions only. +================== ======== === + +Application developers should refer to `include/uapi/linux/l2tp.h`_ for +netlink command and attribute definitions. + +Sample userspace code using libmnl_: + + - Open L2TP netlink socket:: + + struct nl_sock *nl_sock; + int l2tp_nl_family_id; + + nl_sock = nl_socket_alloc(); + genl_connect(nl_sock); + genl_id = genl_ctrl_resolve(nl_sock, L2TP_GENL_NAME); + + - Create a tunnel:: + + struct nlmsghdr *nlh; + struct genlmsghdr *gnlh; + + nlh = mnl_nlmsg_put_header(buf); + nlh->nlmsg_type = genl_id; /* assigned to genl socket */ + nlh->nlmsg_flags = NLM_F_REQUEST | NLM_F_ACK; + nlh->nlmsg_seq = seq; + + gnlh = mnl_nlmsg_put_extra_header(nlh, sizeof(*gnlh)); + gnlh->cmd = L2TP_CMD_TUNNEL_CREATE; + gnlh->version = L2TP_GENL_VERSION; + gnlh->reserved = 0; + + mnl_attr_put_u32(nlh, L2TP_ATTR_FD, tunl_sock_fd); + mnl_attr_put_u32(nlh, L2TP_ATTR_CONN_ID, tid); + mnl_attr_put_u32(nlh, L2TP_ATTR_PEER_CONN_ID, peer_tid); + mnl_attr_put_u8(nlh, L2TP_ATTR_PROTO_VERSION, protocol_version); + mnl_attr_put_u16(nlh, L2TP_ATTR_ENCAP_TYPE, encap); + + - Create a session:: + + struct nlmsghdr *nlh; + struct genlmsghdr *gnlh; + + nlh = mnl_nlmsg_put_header(buf); + nlh->nlmsg_type = genl_id; /* assigned to genl socket */ + nlh->nlmsg_flags = NLM_F_REQUEST | NLM_F_ACK; + nlh->nlmsg_seq = seq; + + gnlh = mnl_nlmsg_put_extra_header(nlh, sizeof(*gnlh)); + gnlh->cmd = L2TP_CMD_SESSION_CREATE; + gnlh->version = L2TP_GENL_VERSION; + gnlh->reserved = 0; + + mnl_attr_put_u32(nlh, L2TP_ATTR_CONN_ID, tid); + mnl_attr_put_u32(nlh, L2TP_ATTR_PEER_CONN_ID, peer_tid); + mnl_attr_put_u32(nlh, L2TP_ATTR_SESSION_ID, sid); + mnl_attr_put_u32(nlh, L2TP_ATTR_PEER_SESSION_ID, peer_sid); + mnl_attr_put_u16(nlh, L2TP_ATTR_PW_TYPE, pwtype); + /* there are other session options which can be set using netlink + * attributes during session creation -- see l2tp.h + */ + + - Delete a session:: + + struct nlmsghdr *nlh; + struct genlmsghdr *gnlh; + + nlh = mnl_nlmsg_put_header(buf); + nlh->nlmsg_type = genl_id; /* assigned to genl socket */ + nlh->nlmsg_flags = NLM_F_REQUEST | NLM_F_ACK; + nlh->nlmsg_seq = seq; + + gnlh = mnl_nlmsg_put_extra_header(nlh, sizeof(*gnlh)); + gnlh->cmd = L2TP_CMD_SESSION_DELETE; + gnlh->version = L2TP_GENL_VERSION; + gnlh->reserved = 0; + + mnl_attr_put_u32(nlh, L2TP_ATTR_CONN_ID, tid); + mnl_attr_put_u32(nlh, L2TP_ATTR_SESSION_ID, sid); + + - Delete a tunnel and all of its sessions (if any):: + + struct nlmsghdr *nlh; + struct genlmsghdr *gnlh; + + nlh = mnl_nlmsg_put_header(buf); + nlh->nlmsg_type = genl_id; /* assigned to genl socket */ + nlh->nlmsg_flags = NLM_F_REQUEST | NLM_F_ACK; + nlh->nlmsg_seq = seq; + + gnlh = mnl_nlmsg_put_extra_header(nlh, sizeof(*gnlh)); + gnlh->cmd = L2TP_CMD_TUNNEL_DELETE; + gnlh->version = L2TP_GENL_VERSION; + gnlh->reserved = 0; + + mnl_attr_put_u32(nlh, L2TP_ATTR_CONN_ID, tid); + +PPPoL2TP Session Socket API +--------------------------- + +For PPP session types, a PPPoL2TP socket must be opened and connected +to the L2TP session. + +When creating PPPoL2TP sockets, the application provides information +to the kernel about the tunnel and session in a socket connect() +call. Source and destination tunnel and session ids are provided, as +well as the file descriptor of a UDP or L2TPIP socket. See struct +pppol2tp_addr in `include/linux/if_pppol2tp.h`_. For historical reasons, +there are unfortunately slightly different address structures for +L2TPv2/L2TPv3 IPv4/IPv6 tunnels and userspace must use the appropriate +structure that matches the tunnel socket type. + +Userspace may control behavior of the tunnel or session using +setsockopt and ioctl on the PPPoX socket. The following socket +options are supported:- + +========= =========================================================== +DEBUG bitmask of debug message categories. See below. +SENDSEQ - 0 => don't send packets with sequence numbers + - 1 => send packets with sequence numbers +RECVSEQ - 0 => receive packet sequence numbers are optional + - 1 => drop receive packets without sequence numbers +LNSMODE - 0 => act as LAC. + - 1 => act as LNS. +REORDERTO reorder timeout (in millisecs). If 0, don't try to reorder. +========= =========================================================== + +In addition to the standard PPP ioctls, a PPPIOCGL2TPSTATS is provided +to retrieve tunnel and session statistics from the kernel using the +PPPoX socket of the appropriate tunnel or session. + +Sample userspace code: + + - Create session PPPoX data socket:: + + struct sockaddr_pppol2tp sax; + int fd; + + /* Note, the tunnel socket must be bound already, else it + * will not be ready + */ + sax.sa_family = AF_PPPOX; + sax.sa_protocol = PX_PROTO_OL2TP; + sax.pppol2tp.fd = tunnel_fd; + sax.pppol2tp.addr.sin_addr.s_addr = addr->sin_addr.s_addr; + sax.pppol2tp.addr.sin_port = addr->sin_port; + sax.pppol2tp.addr.sin_family = AF_INET; + sax.pppol2tp.s_tunnel = tunnel_id; + sax.pppol2tp.s_session = session_id; + sax.pppol2tp.d_tunnel = peer_tunnel_id; + sax.pppol2tp.d_session = peer_session_id; + + /* session_fd is the fd of the session's PPPoL2TP socket. + * tunnel_fd is the fd of the tunnel UDP / L2TPIP socket. + */ + fd = connect(session_fd, (struct sockaddr *)&sax, sizeof(sax)); + if (fd < 0 ) { + return -errno; + } + return 0; + +Old L2TPv2-only API +------------------- + +When L2TP was first added to the Linux kernel in 2.6.23, it +implemented only L2TPv2 and did not include a netlink API. Instead, +tunnel and session instances in the kernel were managed directly using +only PPPoL2TP sockets. The PPPoL2TP socket is used as described in +section "PPPoL2TP Session Socket API" but tunnel and session instances +are automatically created on a connect() of the socket instead of +being created by a separate netlink request: + + - Tunnels are managed using a tunnel management socket which is a + dedicated PPPoL2TP socket, connected to (invalid) session + id 0. The L2TP tunnel instance is created when the PPPoL2TP + tunnel management socket is connected and is destroyed when the + socket is closed. + + - Session instances are created in the kernel when a PPPoL2TP + socket is connected to a non-zero session id. Session parameters + are set using setsockopt. The L2TP session instance is destroyed + when the socket is closed. + +This API is still supported but its use is discouraged. Instead, new +L2TPv2 applications should use netlink to first create the tunnel and +session, then create a PPPoL2TP socket for the session. + +Unmanaged L2TPv3 tunnels +------------------------ + +The kernel L2TP subsystem also supports static (unmanaged) L2TPv3 +tunnels. Unmanaged tunnels have no userspace tunnel socket, and +exchange no control messages with the peer to set up the tunnel; the +tunnel is configured manually at each end of the tunnel. All +configuration is done using netlink. There is no need for an L2TP +userspace application in this case -- the tunnel socket is created by +the kernel and configured using parameters sent in the +``L2TP_CMD_TUNNEL_CREATE`` netlink request. The ``ip`` utility of +``iproute2`` has commands for managing static L2TPv3 tunnels; do ``ip +l2tp help`` for more information. + +Debugging +--------- + +The L2TP subsystem offers a range of debugging interfaces through the +debugfs filesystem. + +To access these interfaces, the debugfs filesystem must first be mounted:: + + # mount -t debugfs debugfs /debug + +Files under the l2tp directory can then be accessed, providing a summary +of the current population of tunnel and session contexts existing in the +kernel:: + + # cat /debug/l2tp/tunnels + +The debugfs files should not be used by applications to obtain L2TP +state information because the file format is subject to change. It is +implemented to provide extra debug information to help diagnose +problems. Applications should instead use the netlink API. + +In addition the L2TP subsystem implements tracepoints using the standard +kernel event tracing API. The available L2TP events can be reviewed as +follows:: + + # find /debug/tracing/events/l2tp + +Finally, /proc/net/pppol2tp is also provided for backwards compatibility +with the original pppol2tp code. It lists information about L2TPv2 +tunnels and sessions only. Its use is discouraged. + +Internal Implementation +======================= + +This section is for kernel developers and maintainers. + +Sockets +------- + +UDP sockets are implemented by the networking core. When an L2TP +tunnel is created using a UDP socket, the socket is set up as an +encapsulated UDP socket by setting encap_rcv and encap_destroy +callbacks on the UDP socket. l2tp_udp_encap_recv is called when +packets are received on the socket. l2tp_udp_encap_destroy is called +when userspace closes the socket. + +L2TPIP sockets are implemented in `net/l2tp/l2tp_ip.c`_ and +`net/l2tp/l2tp_ip6.c`_. + +Tunnels +------- + +The kernel keeps a struct l2tp_tunnel context per L2TP tunnel. The +l2tp_tunnel is always associated with a UDP or L2TP/IP socket and +keeps a list of sessions in the tunnel. When a tunnel is first +registered with L2TP core, the reference count on the socket is +increased. This ensures that the socket cannot be removed while L2TP's +data structures reference it. + +Tunnels are identified by a unique tunnel id. The id is 16-bit for +L2TPv2 and 32-bit for L2TPv3. Internally, the id is stored as a 32-bit +value. + +Tunnels are kept in a per-net list, indexed by tunnel id. The tunnel +id namespace is shared by L2TPv2 and L2TPv3. The tunnel context can be +derived from the socket's sk_user_data. + +Handling tunnel socket close is perhaps the most tricky part of the +L2TP implementation. If userspace closes a tunnel socket, the L2TP +tunnel and all of its sessions must be closed and destroyed. Since the +tunnel context holds a ref on the tunnel socket, the socket's +sk_destruct won't be called until the tunnel sock_put's its +socket. For UDP sockets, when userspace closes the tunnel socket, the +socket's encap_destroy handler is invoked, which L2TP uses to initiate +its tunnel close actions. For L2TPIP sockets, the socket's close +handler initiates the same tunnel close actions. All sessions are +first closed. Each session drops its tunnel ref. When the tunnel ref +reaches zero, the tunnel puts its socket ref. When the socket is +eventually destroyed, it's sk_destruct finally frees the L2TP tunnel +context. + +Sessions +-------- + +The kernel keeps a struct l2tp_session context for each session. Each +session has private data which is used for data specific to the +session type. With L2TPv2, the session always carries PPP +traffic. With L2TPv3, the session can carry Ethernet frames (Ethernet +pseudowire) or other data types such as PPP, ATM, HDLC or Frame +Relay. Linux currently implements only Ethernet and PPP session types. + +Some L2TP session types also have a socket (PPP pseudowires) while +others do not (Ethernet pseudowires). We can't therefore use the +socket reference count as the reference count for session +contexts. The L2TP implementation therefore has its own internal +reference counts on the session contexts. + +Like tunnels, L2TP sessions are identified by a unique +session id. Just as with tunnel ids, the session id is 16-bit for +L2TPv2 and 32-bit for L2TPv3. Internally, the id is stored as a 32-bit +value. + +Sessions hold a ref on their parent tunnel to ensure that the tunnel +stays extant while one or more sessions references it. + +Sessions are kept in a per-tunnel list, indexed by session id. L2TPv3 +sessions are also kept in a per-net list indexed by session id, +because L2TPv3 session ids are unique across all tunnels and L2TPv3 +data packets do not contain a tunnel id in the header. This list is +therefore needed to find the session context associated with a +received data packet when the tunnel context cannot be derived from +the tunnel socket. + +Although the L2TPv3 RFC specifies that L2TPv3 session ids are not +scoped by the tunnel, the kernel does not police this for L2TPv3 UDP +tunnels and does not add sessions of L2TPv3 UDP tunnels into the +per-net session list. In the UDP receive code, we must trust that the +tunnel can be identified using the tunnel socket's sk_user_data and +lookup the session in the tunnel's session list instead of the per-net +session list. + +PPP +--- + +`net/l2tp/l2tp_ppp.c`_ implements the PPPoL2TP socket family. Each PPP +session has a PPPoL2TP socket. + +The PPPoL2TP socket's sk_user_data references the l2tp_session. + +Userspace sends and receives PPP packets over L2TP using a PPPoL2TP +socket. Only PPP control frames pass over this socket: PPP data +packets are handled entirely by the kernel, passing between the L2TP +session and its associated ``pppN`` netdev through the PPP channel +interface of the kernel PPP subsystem. + +The L2TP PPP implementation handles the closing of a PPPoL2TP socket +by closing its corresponding L2TP session. This is complicated because +it must consider racing with netlink session create/destroy requests +and pppol2tp_connect trying to reconnect with a session that is in the +process of being closed. Unlike tunnels, PPP sessions do not hold a +ref on their associated socket, so code must be careful to sock_hold +the socket where necessary. For all the details, see commit +3d609342cc04129ff7568e19316ce3d7451a27e8. + +Ethernet +-------- + +`net/l2tp/l2tp_eth.c`_ implements L2TPv3 Ethernet pseudowires. It +manages a netdev for each session. + +L2TP Ethernet sessions are created and destroyed by netlink request, +or are destroyed when the tunnel is destroyed. Unlike PPP sessions, +Ethernet sessions do not have an associated socket. + +Miscellaneous +============= + +RFCs +---- + +The kernel code implements the datapath features specified in the +following RFCs: + +======= =============== =================================== +RFC2661 L2TPv2 https://tools.ietf.org/html/rfc2661 +RFC3931 L2TPv3 https://tools.ietf.org/html/rfc3931 +RFC4719 L2TPv3 Ethernet https://tools.ietf.org/html/rfc4719 +======= =============== =================================== + +Implementations +--------------- + +A number of open source applications use the L2TP kernel subsystem: + +============ ============================================== +iproute2 https://github.com/shemminger/iproute2 +go-l2tp https://github.com/katalix/go-l2tp +tunneldigger https://github.com/wlanslovenija/tunneldigger +xl2tpd https://github.com/xelerance/xl2tpd +============ ============================================== + +Limitations +----------- + +The current implementation has a number of limitations: + + 1) Multiple UDP sockets with the same 5-tuple address cannot be + used. The kernel's tunnel context is identified using private + data associated with the socket so it is important that each + socket is uniquely identified by its address. + + 2) Interfacing with openvswitch is not yet implemented. It may be + useful to map OVS Ethernet and VLAN ports into L2TPv3 tunnels. + + 3) VLAN pseudowires are implemented using an ``l2tpethN`` interface + configured with a VLAN sub-interface. Since L2TPv3 VLAN + pseudowires carry one and only one VLAN, it may be better to use + a single netdevice rather than an ``l2tpethN`` and ``l2tpethN``:M + pair per VLAN session. The netlink attribute + ``L2TP_ATTR_VLAN_ID`` was added for this, but it was never + implemented. + +Testing +------- + +Unmanaged L2TPv3 Ethernet features are tested by the kernel's built-in +selftests. See `tools/testing/selftests/net/l2tp.sh`_. + +Another test suite, l2tp-ktest_, covers all +of the L2TP APIs and tunnel/session types. This may be integrated into +the kernel's built-in L2TP selftests in the future. + +.. Links +.. _Generic Netlink: generic_netlink.html +.. _libmnl: https://www.netfilter.org/projects/libmnl +.. _include/uapi/linux/l2tp.h: ../../../include/uapi/linux/l2tp.h +.. _include/linux/if_pppol2tp.h: ../../../include/linux/if_pppol2tp.h +.. _net/l2tp/l2tp_ip.c: ../../../net/l2tp/l2tp_ip.c +.. _net/l2tp/l2tp_ip6.c: ../../../net/l2tp/l2tp_ip6.c +.. _net/l2tp/l2tp_ppp.c: ../../../net/l2tp/l2tp_ppp.c +.. _net/l2tp/l2tp_eth.c: ../../../net/l2tp/l2tp_eth.c +.. _tools/testing/selftests/net/l2tp.sh: ../../../tools/testing/selftests/net/l2tp.sh +.. _l2tp-ktest: https://github.com/katalix/l2tp-ktest -- cgit v1.2.3