1*5630257fSFerruh Yigit.. SPDX-License-Identifier: BSD-3-Clause 2*5630257fSFerruh Yigit Copyright(c) 2017 Intel Corporation. 3f6010c76SMark Kavanagh 4f6010c76SMark KavanaghGeneric Segmentation Offload Library 5f6010c76SMark Kavanagh==================================== 6f6010c76SMark Kavanagh 7f6010c76SMark KavanaghOverview 8f6010c76SMark Kavanagh-------- 9f6010c76SMark KavanaghGeneric Segmentation Offload (GSO) is a widely used software implementation of 10f6010c76SMark KavanaghTCP Segmentation Offload (TSO), which reduces per-packet processing overhead. 11f6010c76SMark KavanaghMuch like TSO, GSO gains performance by enabling upper layer applications to 12f6010c76SMark Kavanaghprocess a smaller number of large packets (e.g. MTU size of 64KB), instead of 13f6010c76SMark Kavanaghprocessing higher numbers of small packets (e.g. MTU size of 1500B), thus 14f6010c76SMark Kavanaghreducing per-packet overhead. 15f6010c76SMark Kavanagh 16f6010c76SMark KavanaghFor example, GSO allows guest kernel stacks to transmit over-sized TCP segments 17f6010c76SMark Kavanaghthat far exceed the kernel interface's MTU; this eliminates the need to segment 18f6010c76SMark Kavanaghpackets within the guest, and improves the data-to-overhead ratio of both the 19f6010c76SMark Kavanaghguest-host link, and PCI bus. The expectation of the guest network stack in this 20f6010c76SMark Kavanaghscenario is that segmentation of egress frames will take place either in the NIC 21f6010c76SMark KavanaghHW, or where that hardware capability is unavailable, either in the host 22f6010c76SMark Kavanaghapplication, or network stack. 23f6010c76SMark Kavanagh 24f6010c76SMark KavanaghBearing that in mind, the GSO library enables DPDK applications to segment 25f6010c76SMark Kavanaghpackets in software. Note however, that GSO is implemented as a standalone 26f6010c76SMark Kavanaghlibrary, and not via a 'fallback' mechanism (i.e. for when TSO is unsupported 27f6010c76SMark Kavanaghin the underlying hardware); that is, applications must explicitly invoke the 28f6010c76SMark KavanaghGSO library to segment packets. The size of GSO segments ``(segsz)`` is 29f6010c76SMark Kavanaghconfigurable by the application. 30f6010c76SMark Kavanagh 31f6010c76SMark KavanaghLimitations 32f6010c76SMark Kavanagh----------- 33f6010c76SMark Kavanagh 34f6010c76SMark Kavanagh#. The GSO library doesn't check if input packets have correct checksums. 35f6010c76SMark Kavanagh 36f6010c76SMark Kavanagh#. In addition, the GSO library doesn't re-calculate checksums for segmented 37f6010c76SMark Kavanagh packets (that task is left to the application). 38f6010c76SMark Kavanagh 39f6010c76SMark Kavanagh#. IP fragments are unsupported by the GSO library. 40f6010c76SMark Kavanagh 41f6010c76SMark Kavanagh#. The egress interface's driver must support multi-segment packets. 42f6010c76SMark Kavanagh 43f6010c76SMark Kavanagh#. Currently, the GSO library supports the following IPv4 packet types: 44f6010c76SMark Kavanagh 45f6010c76SMark Kavanagh - TCP 46f6010c76SMark Kavanagh - VxLAN 47f6010c76SMark Kavanagh - GRE 48f6010c76SMark Kavanagh 49f6010c76SMark Kavanagh See `Supported GSO Packet Types`_ for further details. 50f6010c76SMark Kavanagh 51f6010c76SMark KavanaghPacket Segmentation 52f6010c76SMark Kavanagh------------------- 53f6010c76SMark Kavanagh 54f6010c76SMark KavanaghThe ``rte_gso_segment()`` function is the GSO library's primary 55f6010c76SMark Kavanaghsegmentation API. 56f6010c76SMark Kavanagh 57f6010c76SMark KavanaghBefore performing segmentation, an application must create a GSO context object 58f6010c76SMark Kavanagh``(struct rte_gso_ctx)``, which provides the library with some of the 59f6010c76SMark Kavanaghinformation required to understand how the packet should be segmented. Refer to 60f6010c76SMark Kavanagh`How to Segment a Packet`_ for additional details on same. Once the GSO context 61f6010c76SMark Kavanaghhas been created, and populated, the application can then use the 62f6010c76SMark Kavanagh``rte_gso_segment()`` function to segment packets. 63f6010c76SMark Kavanagh 64f6010c76SMark KavanaghThe GSO library typically stores each segment that it creates in two parts: the 65f6010c76SMark Kavanaghfirst part contains a copy of the original packet's headers, while the second 66f6010c76SMark Kavanaghpart contains a pointer to an offset within the original packet. This mechanism 67f6010c76SMark Kavanaghis explained in more detail in `GSO Output Segment Format`_. 68f6010c76SMark Kavanagh 69f6010c76SMark KavanaghThe GSO library supports both single- and multi-segment input mbufs. 70f6010c76SMark Kavanagh 71f6010c76SMark KavanaghGSO Output Segment Format 72f6010c76SMark Kavanagh~~~~~~~~~~~~~~~~~~~~~~~~~ 73f6010c76SMark KavanaghTo reduce the number of expensive memcpy operations required when segmenting a 74f6010c76SMark Kavanaghpacket, the GSO library typically stores each segment that it creates as a 75f6010c76SMark Kavanaghtwo-part mbuf (technically, this is termed a 'two-segment' mbuf; however, since 76f6010c76SMark Kavanaghthe elements produced by the API are also called 'segments', for clarity the 77f6010c76SMark Kavanaghterm 'part' is used here instead). 78f6010c76SMark Kavanagh 79f6010c76SMark KavanaghThe first part of each output segment is a direct mbuf and contains a copy of 80f6010c76SMark Kavanaghthe original packet's headers, which must be prepended to each output segment. 81f6010c76SMark KavanaghThese headers are copied from the original packet into each output segment. 82f6010c76SMark Kavanagh 83f6010c76SMark KavanaghThe second part of each output segment, represents a section of data from the 84f6010c76SMark Kavanaghoriginal packet, i.e. a data segment. Rather than copy the data directly from 85f6010c76SMark Kavanaghthe original packet into the output segment (which would impact performance 86f6010c76SMark Kavanaghconsiderably), the second part of each output segment is an indirect mbuf, 87f6010c76SMark Kavanaghwhich contains no actual data, but simply points to an offset within the 88f6010c76SMark Kavanaghoriginal packet. 89f6010c76SMark Kavanagh 90f6010c76SMark KavanaghThe combination of the 'header' segment and the 'data' segment constitutes a 91f6010c76SMark Kavanaghsingle logical output GSO segment of the original packet. This is illustrated 92f6010c76SMark Kavanaghin :numref:`figure_gso-output-segment-format`. 93f6010c76SMark Kavanagh 94f6010c76SMark Kavanagh.. _figure_gso-output-segment-format: 95f6010c76SMark Kavanagh 967fe92871SThomas Monjalon.. figure:: img/gso-output-segment-format.* 97f6010c76SMark Kavanagh :align: center 98f6010c76SMark Kavanagh 99f6010c76SMark Kavanagh Two-part GSO output segment 100f6010c76SMark Kavanagh 101f6010c76SMark KavanaghIn one situation, the output segment may contain additional 'data' segments. 102f6010c76SMark KavanaghThis only occurs when: 103f6010c76SMark Kavanagh 104f6010c76SMark Kavanagh- the input packet on which GSO is to be performed is represented by a 105f6010c76SMark Kavanagh multi-segment mbuf. 106f6010c76SMark Kavanagh 107f6010c76SMark Kavanagh- the output segment is required to contain data that spans the boundaries 108f6010c76SMark Kavanagh between segments of the input multi-segment mbuf. 109f6010c76SMark Kavanagh 110f6010c76SMark KavanaghThe GSO library traverses each segment of the input packet, and produces 111f6010c76SMark Kavanaghnumerous output segments; for optimal performance, the number of output 112f6010c76SMark Kavanaghsegments is kept to a minimum. Consequently, the GSO library maximizes the 113f6010c76SMark Kavanaghamount of data contained within each output segment; i.e. each output segment 114f6010c76SMark Kavanagh``segsz`` bytes of data. The only exception to this is in the case of the very 115f6010c76SMark Kavanaghfinal output segment; if ``pkt_len`` % ``segsz``, then the final segment is 116f6010c76SMark Kavanaghsmaller than the rest. 117f6010c76SMark Kavanagh 118f6010c76SMark KavanaghIn order for an output segment to meet its MSS, it may need to include data from 119f6010c76SMark Kavanaghmultiple input segments. Due to the nature of indirect mbufs (each indirect mbuf 120f6010c76SMark Kavanaghcan point to only one direct mbuf), the solution here is to add another indirect 121f6010c76SMark Kavanaghmbuf to the output segment; this additional segment then points to the next 122f6010c76SMark Kavanaghinput segment. If necessary, this chaining process is repeated, until the sum of 123f6010c76SMark Kavanaghall of the data 'contained' in the output segment reaches ``segsz``. This 124f6010c76SMark Kavanaghensures that the amount of data contained within each output segment is uniform, 125f6010c76SMark Kavanaghwith the possible exception of the last segment, as previously described. 126f6010c76SMark Kavanagh 127f6010c76SMark Kavanagh:numref:`figure_gso-three-seg-mbuf` illustrates an example of a three-part 128f6010c76SMark Kavanaghoutput segment. In this example, the output segment needs to include data from 129f6010c76SMark Kavanaghthe end of one input segment, and the beginning of another. To achieve this, 130f6010c76SMark Kavanaghan additional indirect mbuf is chained to the second part of the output segment, 131f6010c76SMark Kavanaghand is attached to the next input segment (i.e. it points to the data in the 132f6010c76SMark Kavanaghnext input segment). 133f6010c76SMark Kavanagh 134f6010c76SMark Kavanagh.. _figure_gso-three-seg-mbuf: 135f6010c76SMark Kavanagh 1367fe92871SThomas Monjalon.. figure:: img/gso-three-seg-mbuf.* 137f6010c76SMark Kavanagh :align: center 138f6010c76SMark Kavanagh 139f6010c76SMark Kavanagh Three-part GSO output segment 140f6010c76SMark Kavanagh 141f6010c76SMark KavanaghSupported GSO Packet Types 142f6010c76SMark Kavanagh-------------------------- 143f6010c76SMark Kavanagh 144f6010c76SMark KavanaghTCP/IPv4 GSO 145f6010c76SMark Kavanagh~~~~~~~~~~~~ 146f6010c76SMark KavanaghTCP/IPv4 GSO supports segmentation of suitably large TCP/IPv4 packets, which 147f6010c76SMark Kavanaghmay also contain an optional VLAN tag. 148f6010c76SMark Kavanagh 149f6010c76SMark KavanaghVxLAN GSO 150f6010c76SMark Kavanagh~~~~~~~~~ 151f6010c76SMark KavanaghVxLAN packets GSO supports segmentation of suitably large VxLAN packets, 152f6010c76SMark Kavanaghwhich contain an outer IPv4 header, inner TCP/IPv4 headers, and optional 153f6010c76SMark Kavanaghinner and/or outer VLAN tag(s). 154f6010c76SMark Kavanagh 155f6010c76SMark KavanaghGRE GSO 156f6010c76SMark Kavanagh~~~~~~~ 157f6010c76SMark KavanaghGRE GSO supports segmentation of suitably large GRE packets, which contain 158f6010c76SMark Kavanaghan outer IPv4 header, inner TCP/IPv4 headers, and an optional VLAN tag. 159f6010c76SMark Kavanagh 160f6010c76SMark KavanaghHow to Segment a Packet 161f6010c76SMark Kavanagh----------------------- 162f6010c76SMark Kavanagh 163f6010c76SMark KavanaghTo segment an outgoing packet, an application must: 164f6010c76SMark Kavanagh 165f6010c76SMark Kavanagh#. First create a GSO context ``(struct rte_gso_ctx)``; this contains: 166f6010c76SMark Kavanagh 167f6010c76SMark Kavanagh - a pointer to the mbuf pool for allocating the direct buffers, which are 168f6010c76SMark Kavanagh used to store the GSO segments' packet headers. 169f6010c76SMark Kavanagh 170f6010c76SMark Kavanagh - a pointer to the mbuf pool for allocating indirect buffers, which are 171f6010c76SMark Kavanagh used to locate GSO segments' packet payloads. 172f6010c76SMark Kavanagh 173f6010c76SMark Kavanagh .. note:: 174f6010c76SMark Kavanagh 175f6010c76SMark Kavanagh An application may use the same pool for both direct and indirect 176653c9de1SMark Kavanagh buffers. However, since indirect mbufs simply store a pointer, the 177f6010c76SMark Kavanagh application may reduce its memory consumption by creating a separate memory 178f6010c76SMark Kavanagh pool, containing smaller elements, for the indirect pool. 179f6010c76SMark Kavanagh 180653c9de1SMark Kavanagh 181f6010c76SMark Kavanagh - the size of each output segment, including packet headers and payload, 182f6010c76SMark Kavanagh measured in bytes. 183f6010c76SMark Kavanagh 184f6010c76SMark Kavanagh - the bit mask of required GSO types. The GSO library uses the same macros as 185f6010c76SMark Kavanagh those that describe a physical device's TX offloading capabilities (i.e. 186f6010c76SMark Kavanagh ``DEV_TX_OFFLOAD_*_TSO``) for gso_types. For example, if an application 187f6010c76SMark Kavanagh wants to segment TCP/IPv4 packets, it should set gso_types to 188f6010c76SMark Kavanagh ``DEV_TX_OFFLOAD_TCP_TSO``. The only other supported values currently 189f6010c76SMark Kavanagh supported for gso_types are ``DEV_TX_OFFLOAD_VXLAN_TNL_TSO``, and 190f6010c76SMark Kavanagh ``DEV_TX_OFFLOAD_GRE_TNL_TSO``; a combination of these macros is also 191f6010c76SMark Kavanagh allowed. 192f6010c76SMark Kavanagh 193f6010c76SMark Kavanagh - a flag, that indicates whether the IPv4 headers of output segments should 194f6010c76SMark Kavanagh contain fixed or incremental ID values. 195f6010c76SMark Kavanagh 196f6010c76SMark Kavanagh2. Set the appropriate ol_flags in the mbuf. 197f6010c76SMark Kavanagh 198f6010c76SMark Kavanagh - The GSO library use the value of an mbuf's ``ol_flags`` attribute to 199f6010c76SMark Kavanagh to determine how a packet should be segmented. It is the application's 200f6010c76SMark Kavanagh responsibility to ensure that these flags are set. 201f6010c76SMark Kavanagh 202f6010c76SMark Kavanagh - For example, in order to segment TCP/IPv4 packets, the application should 203f6010c76SMark Kavanagh add the ``PKT_TX_IPV4`` and ``PKT_TX_TCP_SEG`` flags to the mbuf's 204f6010c76SMark Kavanagh ol_flags. 205f6010c76SMark Kavanagh 206f6010c76SMark Kavanagh - If checksum calculation in hardware is required, the application should 207f6010c76SMark Kavanagh also add the ``PKT_TX_TCP_CKSUM`` and ``PKT_TX_IP_CKSUM`` flags. 208f6010c76SMark Kavanagh 209f6010c76SMark Kavanagh#. Check if the packet should be processed. Packets with one of the 210f6010c76SMark Kavanagh following properties are not processed and are returned immediately: 211f6010c76SMark Kavanagh 212f6010c76SMark Kavanagh - Packet length is less than ``segsz`` (i.e. GSO is not required). 213f6010c76SMark Kavanagh 214f6010c76SMark Kavanagh - Packet type is not supported by GSO library (see 215f6010c76SMark Kavanagh `Supported GSO Packet Types`_). 216f6010c76SMark Kavanagh 217f6010c76SMark Kavanagh - Application has not enabled GSO support for the packet type. 218f6010c76SMark Kavanagh 219f6010c76SMark Kavanagh - Packet's ol_flags have been incorrectly set. 220f6010c76SMark Kavanagh 221f6010c76SMark Kavanagh#. Allocate space in which to store the output GSO segments. If the amount of 222f6010c76SMark Kavanagh space allocated by the application is insufficient, segmentation will fail. 223f6010c76SMark Kavanagh 224f6010c76SMark Kavanagh#. Invoke the GSO segmentation API, ``rte_gso_segment()``. 225f6010c76SMark Kavanagh 226f6010c76SMark Kavanagh#. If required, update the L3 and L4 checksums of the newly-created segments. 227f6010c76SMark Kavanagh For tunneled packets, the outer IPv4 headers' checksums should also be 228f6010c76SMark Kavanagh updated. Alternatively, the application may offload checksum calculation 229f6010c76SMark Kavanagh to HW. 230f6010c76SMark Kavanagh 231