@@ -99,6 +99,7 @@ Contents:
sysfs-tagging
tc-actions-env-rules
tcp-thin
+ tcp-ddp-offload
team
timestamping
tipc
new file mode 100644
@@ -0,0 +1,296 @@
+.. SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
+
+=================================
+TCP direct data placement offload
+=================================
+
+Overview
+========
+
+The Linux kernel TCP direct data placement (DDP) offload infrastructure
+provides tagged request-response protocols, such as NVMe-TCP, the ability to
+place response data directly in pre-registered buffers according to header
+tags. DDP is particularly useful for data-intensive pipelined protocols whose
+responses may be reordered.
+
+For example, in NVMe-TCP numerous read requests are sent together and each
+request is tagged using the PDU header CID field. Receiving servers process
+requests as fast as possible and sometimes responses for smaller requests
+bypasses responses to larger requests, i.e., read 4KB bypasses read 1GB.
+Thereafter, clients corrleate responses to requests using PDU header CID tags.
+The processing of each response requires copying data from SKBs to read
+request destination buffers; The offload avoids this copy. The offload is
+oblivious to destination buffers which can reside either in userspace
+(O_DIRECT) or in kernel pagecache.
+
+Request TCP byte-stream:
+
+.. parsed-literal::
+
+ +---------------+-------+---------------+-------+---------------+-------+
+ | PDU hdr CID=1 | Req 1 | PDU hdr CID=2 | Req 2 | PDU hdr CID=3 | Req 3 |
+ +---------------+-------+---------------+-------+---------------+-------+
+
+Response TCP byte-stream:
+
+.. parsed-literal::
+
+ +---------------+--------+---------------+--------+---------------+--------+
+ | PDU hdr CID=2 | Resp 2 | PDU hdr CID=3 | Resp 3 | PDU hdr CID=1 | Resp 1 |
+ +---------------+--------+---------------+--------+---------------+--------+
+
+Offloading requires no new SKB bits. Instead, the driver builds SKB page
+fragments that point destination buffers. Consequently, SKBs represent the
+original data on the wire, which enables *transparent* inter-operation with the
+network stack. To avoid copies between SKBs and destination buffers, the
+layer-5 protocol (L5P) will check ``if (src == dst)`` for SKB page fragments,
+success indicates that data is already placed there by NIC hardware and copy
+should be skipped.
+
+Offloading does require NIC hardware to track L5P procotol framing, similarly
+to RX TLS offload (see documentation at
+:ref:`Documentation/networking/tls-offload.rst <tls_offload>`). NIC hardware
+will parse PDU headers extract fields such as operation type, length, ,tag
+identifier, etc. and offload only segments that correspond to tags registered
+with the NIC, see the :ref:`buf_reg` section.
+
+Device configuration
+====================
+
+During driver initialization the device sets the ``NETIF_F_HW_TCP_DDP`` and
+feature and installs its
+:c:type:`struct tcp_ddp_ops <tcp_ddp_ops>`
+pointer in the :c:member:`tcp_ddp_ops` member of the
+:c:type:`struct net_device <net_device>`.
+
+Later, after the L5P completes its handshake offload is installed on the socket.
+If offload installation fails, then the connection is handled by software as if
+offload was not attempted. Offload installation should configure
+
+To request offload for a socket `sk`, the L5P calls :c:member:`tcp_ddp_sk_add`:
+
+.. code-block:: c
+
+ int (*tcp_ddp_sk_add)(struct net_device *netdev,
+ struct sock *sk,
+ struct tcp_ddp_config *config);
+
+The function return 0 for success. In case of failure, L5P software should
+fallback to normal non-offloaded operation. The `config` parameter indicates
+the L5P type and any metadata relevant for that protocol. For example, in
+NVMe-TCP the following config is used:
+
+.. code-block:: c
+
+ /**
+ * struct nvme_tcp_ddp_config - nvme tcp ddp configuration for an IO queue
+ *
+ * @pfv: pdu version (e.g., NVME_TCP_PFV_1_0)
+ * @cpda: controller pdu data alignmend (dwords, 0's based)
+ * @dgst: digest types enabled.
+ * The netdev will offload crc if ddp_crc is supported.
+ * @queue_size: number of nvme-tcp IO queue elements
+ * @queue_id: queue identifier
+ * @cpu_io: cpu core running the IO thread for this queue
+ */
+ struct nvme_tcp_ddp_config {
+ struct tcp_ddp_config cfg;
+
+ u16 pfv;
+ u8 cpda;
+ u8 dgst;
+ int queue_size;
+ int queue_id;
+ int io_cpu;
+ };
+
+When offload is not needed anymore, e.g., the socket is being released, the L5P
+calls :c:member:`tcp_ddp_sk_del` to release device contexts:
+
+.. code-block:: c
+
+ void (*tcp_ddp_sk_del)(struct net_device *netdev,
+ struct sock *sk);
+
+Normal operation
+================
+
+At the very least, the device maintains the following state for each connection:
+
+ * 5-tuple
+ * expected TCP sequence number
+ * mapping between tags and corresponding buffers
+ * current offset within PDU, PDU length, current PDU tag
+
+NICs should not assume any correleation between PDUs and TCP packets. Assuming
+that TCP packets arrive in-order, offload will place PDU payload directly
+inside corresponding registered buffers. No packets are to be delayed by NIC
+offload. If offload is not possible, than the packet is to be passed as-is to
+software. To perform offload on incoming packets without buffering packets in
+the NIC, the NIC stores some inter-packet state, such as partial PDU headers.
+
+RX data-path
+------------
+
+After the device validates TCP checksums, it can perform DDP offload. The
+packet is steered to the DDP offload context according to the 5-tuple.
+Thereafter, the expected TCP sequence number is checked against the packet's
+TCP sequence number. If there's a match, then offload is performed: PDU payload
+is DMA written to corresponding destination buffer according to the PDU header
+tag. The data should be DMAed only once, and the NIC receive ring will only
+store the remaining TCP and PDU headers.
+
+We remark that a single TCP packet may have numerous PDUs embedded inside. NICs
+can choose to offload one or more of these PDUs according to various
+trade-offs. Possibly, offloading such small PDUs is of little value, and it is
+better to leave it to software.
+
+Upon receiving a DDP offloaded packet, the driver reconstructs the original SKB
+using page frags, while pointing to the destination buffers whenever possible.
+This method enables seemless integration with the network stack, which can
+inspect and modify packet fields transperently to the offload.
+
+.. _buf_reg:
+
+Destination buffer registration
+-------------------------------
+
+To register the mapping betwteen tags and destination buffers for a socket
+`sk`, the L5P calls :c:member:`tcp_ddp_setup` of :c:type:`struct tcp_ddp_ops
+<tcp_ddp_ops>`:
+
+.. code-block:: c
+
+ int (*tcp_ddp_setup)(struct net_device *netdev,
+ struct sock *sk,
+ struct tcp_ddp_io *io);
+
+
+The `io` provides the buffer via scatter-gather list (`sg_table`) and
+corresponding tag (`command_id`):
+
+.. code-block:: c
+ /**
+ * struct tcp_ddp_io - tcp ddp configuration for an IO request.
+ *
+ * @command_id: identifier on the wire associated with these buffers
+ * @nents: number of entries in the sg_table
+ * @sg_table: describing the buffers for this IO request
+ * @first_sgl: first SGL in sg_table
+ */
+ struct tcp_ddp_io {
+ u32 command_id;
+ int nents;
+ struct sg_table sg_table;
+ struct scatterlist first_sgl[SG_CHUNK_SIZE];
+ };
+
+After the buffers have been consumed by the L5P, to release the NIC mapping of
+buffers the L5P calls :c:member:`tcp_ddp_teardown` of :c:type:`struct
+tcp_ddp_ops <tcp_ddp_ops>`:
+
+.. code-block:: c
+
+ int (*tcp_ddp_teardown)(struct net_device *netdev,
+ struct sock *sk,
+ struct tcp_ddp_io *io,
+ void *ddp_ctx);
+
+`tcp_ddp_teardown` receives the same `io` context and an additional opaque
+`ddp_ctx` that is used for asynchronous teardown, see the :ref:`async_release`
+section.
+
+.. _async_release:
+
+Asynchronous teardown
+---------------------
+
+To teardown the association between tags and buffers and allow tag reuse NIC HW
+is called by the NIC driver during `tcp_ddp_teardown`. This operation may be
+performed either synchronously or asynchronously. In asynchronous teardown,
+`tcp_ddp_teardown` returns immediately without unmapping NIC HW buffers. Later,
+when the unmapping completes by NIC HW, the NIC driver will call up to L5P
+using :c:member:`ddp_teardown_done` of :c:type:`struct tcp_ddp_ulp_ops`:
+
+.. code-block:: c
+
+ void (*ddp_teardown_done)(void *ddp_ctx);
+
+The `ddp_ctx` parameter passed in `ddp_teardown_done` is the same on provided
+in `tcp_ddp_teardown` and it is used to carry some context about the buffers
+and tags that are released.
+
+Resync handling
+===============
+
+In presence of packet drops or network packet reordering, the device may lose
+synchronization between the TCP stream and the L5P framing, and require a
+resync with the kernel's TCP stack. When the device is out of sync, no offload
+takes place, and packets are passed as-is to software. (resync is very similar
+to TLS offload (see documentation at
+:ref:`Documentation/networking/tls-offload.rst <tls_offload>`)
+
+If only packets with L5P data are lost or reordered, then resynchronization may
+be avoided by NIC HW that keeps tracking PDU headers. If, however, PDU headers
+are reordered, then resynchronization is necessary.
+
+To resynchronize hardware during traffic, we use a handshake between hardware
+and software. The NIC HW searches for a sequence of bytes that identifies L5P
+headers (i.e., magic pattern). For example, in NVMe-TCP, the PDU operation
+type can be used for this purpose. Using the PDU header length field, the NIC
+HW will continue to find and match magic patterns in subsequent PDU headers. If
+the pattern is missing in an expected position, then searching for the pattern
+starts anew.
+
+The NIC will not resume offload when the magic pattern is first identified.
+Instead, it will request L5P software to confirm that indeed this is a PDU
+header. To request confirmation the NIC driver calls up to L5P using
+:c:member:`*resync_request` of :c:type:`struct tcp_ddp_ulp_ops`:
+
+.. code-block:: c
+
+ bool (*resync_request)(struct sock *sk, u32 seq, u32 flags);
+
+The `seq` field contains the TCP sequence of the last byte in the PDU header.
+L5P software will respond to this request after observing the packet containing
+TCP sequence `seq` in-order. If the PDU header is indeed there, then L5P
+software calls the NIC driver using the :c:member:`tcp_ddp_resync` function of
+the :c:type:`struct tcp_ddp_ops <tcp_ddp_ops>` inside the :c:type:`struct
+net_device <net_device>` while passing the same `seq` to confirm it is a PDU
+header.
+
+.. code-block:: c
+
+ void (*tcp_ddp_resync)(struct net_device *netdev,
+ struct sock *sk, u32 seq);
+
+Statistics
+==========
+
+Per L5P protocol, the following NIC driver must report statistics for the above
+netdevice operations and packets processed by offload. For example, NVMe-TCP
+offload reports:
+
+ * ``rx_nvmeotcp_queue_init`` - number of NVMe-TCP offload contexts created.
+ * ``rx_nvmeotcp_queue_teardown`` - number of NVMe-TCP offload contexts
+ destroyed.
+ * ``rx_nvmeotcp_ddp_setup`` - number of DDP buffers mapped.
+ * ``rx_nvmeotcp_ddp_setup_fail`` - number of DDP buffers mapping that failed.
+ * ``rx_nvmeotcp_ddp_teardown`` - number of DDP buffers unmapped.
+ * ``rx_nvmeotcp_drop`` - number of packets dropped in the driver due to fatal
+ errors.
+ * ``rx_nvmeotcp_resync`` - number of packets with resync requests.
+ * ``rx_nvmeotcp_offload_packets`` - number of packets that used offload.
+ * ``rx_nvmeotcp_offload_bytes`` - number of bytes placed in DDP buffers.
+
+NIC requirements
+================
+
+NIC hardware should meet the following requirements to provide this offload:
+
+ * Offload must never buffer TCP packets.
+ * Offload must never modify TCP packet headers.
+ * Offload must never reorder TCP packets within a flow.
+ * Offload must never drop TCP packets.
+ * Offload must not depend on any TCP fields beyond the
+ 5-tuple and TCP sequence number.