1 /* SPDX-License-Identifier: BSD-3-Clause
2 * Copyright(c) 2017 Intel Corporation
10 * Interface to GSO library
20 /* Minimum GSO segment size for TCP based packets. */
21 #define RTE_GSO_SEG_SIZE_MIN (sizeof(struct rte_ether_hdr) + \
22 sizeof(struct rte_ipv4_hdr) + sizeof(struct rte_tcp_hdr) + 1)
24 /* Minimum GSO segment size for UDP based packets. */
25 #define RTE_GSO_UDP_SEG_SIZE_MIN (sizeof(struct rte_ether_hdr) + \
26 sizeof(struct rte_ipv4_hdr) + sizeof(struct rte_udp_hdr) + 1)
28 /* GSO flags for rte_gso_ctx. */
29 #define RTE_GSO_FLAG_IPID_FIXED (1ULL << 0)
30 /**< Use fixed IP ids for output GSO segments. Setting
31 * 0 indicates using incremental IP ids.
35 * GSO context structure.
38 struct rte_mempool *direct_pool;
39 /**< MBUF pool for allocating direct buffers, which are used
40 * to store packet headers for GSO segments.
42 struct rte_mempool *indirect_pool;
43 /**< MBUF pool for allocating indirect buffers, which are used
44 * to locate packet payloads for GSO segments. The indirect
45 * buffer doesn't contain any data, but simply points to an
46 * offset within the packet to segment.
49 /**< flag that controls specific attributes of output segments,
50 * such as the type of IP ID generated (i.e. fixed or incremental).
53 /**< the bit mask of required GSO types. The GSO library
54 * uses the same macros as that of describing device TX
55 * offloading capabilities (i.e. DEV_TX_OFFLOAD_*_TSO) for
58 * For example, if applications want to segment TCP/IPv4
59 * packets, set DEV_TX_OFFLOAD_TCP_TSO in gso_types.
62 /**< maximum size of an output GSO segment, including packet
63 * header and payload, measured in bytes. Must exceed
64 * RTE_GSO_SEG_SIZE_MIN.
69 * Segmentation function, which supports processing of both single- and
70 * multi- MBUF packets.
72 * Note that we refer to the packets that are segmented from the input
73 * packet as 'GSO segments'. rte_gso_segment() doesn't check if the
74 * input packet has correct checksums, and doesn't update checksums for
75 * output GSO segments. Additionally, it doesn't process IP fragment
78 * Before calling rte_gso_segment(), applications must set proper ol_flags
79 * for the packet. The GSO library uses the same macros as that of TSO.
80 * For example, set PKT_TX_TCP_SEG and PKT_TX_IPV4 in ol_flags to segment
81 * a TCP/IPv4 packet. If rte_gso_segment() succeeds, the PKT_TX_TCP_SEG
82 * flag is removed for all GSO segments and the input packet.
84 * Each of the newly-created GSO segments is organized as a two-segment
85 * MBUF, where the first segment is a standard MBUF, which stores a copy
86 * of packet header, and the second is an indirect MBUF which points to
87 * a section of data in the input packet. Since each GSO segment has
88 * multiple MBUFs (i.e. typically 2 MBUFs), the driver of the interface which
89 * the GSO segments are sent to should support transmission of multi-segment
92 * If the input packet is GSO'd, all the indirect segments are attached to the
95 * rte_gso_segment() will not free the input packet no matter whether it is
96 * GSO'd or not, the application should free it after calling rte_gso_segment().
98 * If the memory space in pkts_out or MBUF pools is insufficient, this
99 * function fails, and it returns (-1) * errno. Otherwise, GSO succeeds,
100 * and this function returns the number of output GSO segments filled in
104 * The packet mbuf to segment.
106 * GSO context object pointer.
108 * Pointer array used to store the MBUF addresses of output GSO
109 * segments, when rte_gso_segment() succeeds.
111 * The max number of items that pkts_out can keep.
114 * - The number of GSO segments filled in pkts_out on success.
115 * - Return 0 if it does not need to be GSO'd.
116 * - Return -ENOMEM if run out of memory in MBUF pools.
117 * - Return -EINVAL for invalid parameters.
119 int rte_gso_segment(struct rte_mbuf *pkt,
120 const struct rte_gso_ctx *ctx,
121 struct rte_mbuf **pkts_out,
122 uint16_t nb_pkts_out);
127 #endif /* _RTE_GSO_H_ */